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COLOUR VISION 
 
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 THE TYNDALL LECTURES 
 
 COLOUR 
 
 BfiING 
 
 DELIVERED IN 1894 
 
 AT 
 
 THE ROYAL INSTITUTION 
 
 CAPT. W. DE W.^BNEY, C.B., D.C.L., F.R.S. 
 
 LATE ROYAL ENGINEERS 
 
 WITH COLOURED PLATE AND NUMEROUS DIAGRAMS 
 
 NEW YORK 
 
 wiivJtJAM 'WppD^: ;g:ompany 
 
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^9r 
 
 CONTENTS. 
 
 PAGE 
 
 Pkeface . vii 
 
 CHAPTER I. 
 The Eye 1 
 
 CHAPTER II. 
 Simple Colours and their Mixture 15 
 
 CHAPTER III. 
 Three Colour Sensations Possible 32 
 
 I 
 
 CHAPTER IV. 
 he Young and Bering Theories of Colour Vision ... 41 
 
 CHAPTER V. 
 General Aspect of Colour Blindness 58 
 
 CHAPTER VI. 
 
 Colour Blindness exhibited by Colour Discs and exhibited by 
 
 Luminosity Curves of the Spectrum 74 
 
 CHAPTER VII. 
 
 Luminosity of Colours to Different Parts of the Retina . . 88 
 
VI Contents. 
 
 CHAPTER yill. 
 
 Luminosity of a Feeble Spectrum and the Limit of the Per- 
 ception of Colour 98 
 
 CHAPTER IX. 
 The Extinction of Light from the Spectrum 108 
 
 CHAPTER X. 
 The Extinction of the Perception of Light by the Colour Blind 122 
 
 CHAPTER XL 
 Tobacco Blindness 137 
 
 ^. CHAPTER XII. 
 Examples of Colour Blindness due to Disease 148 
 
 CHAPTER XIII. 
 
 The Holmgren Test for Colour Blindness 167 
 
 CHAPTER XIY. 
 
 The Spectrum Test for Colour Blindness 180 
 
 CHAPTER XV. 
 The Young and Hering Theories of Colour Vision Compared , 187 
 
 Appendix 201 
 
 Index . 229 
 
PREFACE, 
 
 ' I 'HE writer had for some years past, in conjunc- 
 tion with General Festing, and recently as 
 Secretary and Member of the Colour Vision Com- 
 mittee of the Royal Society, carried out a series 
 of investigations on colour vision, and selected that 
 subject when he was invited, in 1894, to deliver the 
 Tyndall Lectures at the Royal Institution. 
 
 The brief time allotted for these lectures — an hour 
 
 on three successive Saturday afternoons — restricted 
 
 the discussion of some aspects of the question, and 
 confined its treatment in the main to those features 
 
 Kost readily explicable by the physicist, and to 
 inging into notice the latest results which had been 
 >tained from physical experiments. How J far the 
 
 364 
 
viii Preface. 
 
 writer has succeeded in the task which he then out- 
 lined it is for the reader to determine. 
 
 There was no intention in the first instance to 
 publish these lectures. After their delivery, many 
 persons expressed a desire that the information they 
 contained should be rendered accessible to such as 
 were interested in the theory of colour vision, and 
 in deference to that desire the lecture-notes have 
 been re-cast in book forrn. For the reader's con- 
 venience the matter is now divided into chapters 
 instead of into lectures, and a few additions have 
 been made in the text to explain some of the ex- 
 perimental work to those who have not facilities for 
 its repetition. 
 
 The writer has to acknowledge several debts of 
 gratitude. First, to Mr. E. Nettleship, for his kindness 
 in looking over the proofs, and making valuable sug- 
 gestions whilst the work was passing through the 
 press ; and also, as will be seen throughout its pages, 
 for many of the interesting cases of defective colour 
 perception which have been examined by the some- 
 
Preface. ix 
 
 what novel methods described. Next, the writer's 
 oratitude is due to Professor M. Foster for the per- 
 mission he has given to use his admirable description 
 «)f the Hering theory ; and, lastly, to the Koyal Society 
 for the permission it accorded to use various diagrams 
 which have served as illustrations to papers which 
 have appeared in its " Philosophical Transactions " 
 and " Proceedings." 
 
^ / "^"1 LI BR A '- 
 
 COLOUR VISION. 
 
 CHAPTER I. 
 
 T MUST commence this course by saying that I feel 
 the honour that has been done me in asking me 
 to undertake it, connected as it is with the name of 
 Tyndall, whose recent removal from our midst has 
 been deplored by all lovers of science, and by none 
 more than by those who have had the privilege of 
 listening to him at this Institution. It is my duty 
 to speak on some subject of physics, and the subject 
 I have chosen is Colour Vision. I hope it will not 
 be considered inappropriate, since it was Thomas 
 Young, the physicist, whose connection with this 
 Institution is well known, who first propounded a 
 really philosophical theory of the subject. Interesting 
 as it may be to trace how old theories have failed and 
 
 B 
 
2 Colour Vision, 
 
 new ones have started, I feel that for those who, like 
 myself, have but little time at command in which to 
 address you, the historical side of this question must 
 of necessity be treated incompletely. 
 
 Colour vision is a subject which enters into the 
 domains both of physics and physiology, and it is 
 thus difficult for any one individual to treat of it 
 exhaustively unless he be a Helmholtz, who was as 
 distinguished in the one branch of science as he was 
 in the other. I am not a physiologist, and at the 
 most can only pretend to an elementary knowledge 
 of the physiology of the eye, but I trust it is 
 sufficient to prevent myself from falling into any 
 grievous error. I shall try and show you, however, 
 that the subject is capable of being made subordinate 
 to physical methods of examination. I must neces- 
 sarily commence by a very brief description of those 
 parts of the eye in which it is supposed the seat of 
 vision lies, but in terms wdiich are not too technical. 
 As to the mere optical properties of the eye I shall say 
 but little, for they are not necessary for my purpose, j 
 although more particularly adapted to mathematical 
 treatment than the other properties 1 have to describe. ! 
 
 The eye may be diagrammatically represented as 
 in the figure which is supposed to be a horizontal 
 
The Eye. 
 
 Fig. 1. 
 
 section of it, the figure being reproduced from Professor 
 Michael Foster's Physiology. 
 
 As far as the perception of colour is concerned, the 
 principal part of the eye which is not distinctly optical 
 — i.e. for the produc- 
 tion of images — is 
 the retina, and this 
 it will be seen is in 
 reality an outcrop of 
 the brain, the connec- 
 tion between the two 
 being the optic nerve. 
 Owing to this connec- 
 tion, it is not easy to 
 determine where the 
 seat of colour percep- 
 tion is located ; but 
 for the purpose of 
 physical investigation 
 this is not of first- 
 
 8cl is the sclerotic coat. Ch the choroid coat, 
 with CP the ciliary process. I is the body 
 of the Iris. H is the retina or inner wall. 
 TE the pigment epithelium or outer wall. 
 Ij the lens held by th« suspensory ligament 
 «2>.Z. YH. is the vitreous humour. 0^ the 
 optic nerve, ox is the optic axis, in this 
 case made to pass through the fovea cen- 
 tralis, /.c. 
 
 rate importance, nor 
 does it afi'ect the discussion of rival theories except 
 in a minor degree. There are other subsidiary adjuncts 
 in the eye to which, however, I must call attention, as 
 they have a distinct bearing on the apparent intensity 
 
 B 2 
 
4 Colour Vision. 
 
 of some colours and of the hue that mixtures of 
 others are perceived. The first is what is called the 
 '* macula lutea," or yellow spot, a spot which it may 
 be assumed exists in every eye. It is horizontally 
 oval in form, and is situated in the very centre of 
 the retina, embracing some 6° to 8° in angular mea- 
 sure. It has a brownish or yellowish tint, and the 
 retina at this part is slightly depressed, being bounded 
 by a slightly raised rim. In the centre of this area 
 the retina becomes very thin, having a depression 
 about y^o" of an inch or '3 millimetres in diameter, 
 which is named the " fovea centralis," where it is 
 said that vision is the most acute. This statement 
 can be well credited when we come to consider where 
 the seat of the stimulation of sensation lies. The 
 colour which tints the yellow spot is strongest at the 
 crater-like rim, and fades away centrally and periphe- 
 rally, and is said to be wholly absent in the fovea 
 centralis. 
 
 As the colour of this spot is yellow or brown in 
 the living eye (and that it is probably brown the 
 absorption indicates), it follows that white light passing 
 through it must be deprived of some of its compo- 
 nents, though in differing degrees. If the seat of 
 sensation is at the outer layer of the retina, as we 
 
The Yellow Spot. 5 
 
 shall shortly see must be the case, it will further be 
 seen that when light of any colour which the brown 
 pigment will absorb more or less completely falls on 
 different parts of the oval area, the absorption must 
 vary at each part, and the intensity of the perceived 
 ligiit will be least at the rim and increase centrally and 
 peripherally. As the centre of the yellow spot or fovea 
 is coincident approximately with the point where the 
 axis of the eye cuts the retina, the image of an evenly 
 illuminated object, when looked at directly, must fall 
 on the yellow spot. If, therefore, a patch of such 
 light, the image of which more than covers the spot, 
 be observed, it ought to exhibit a varying brightness of 
 colour corresponding to the strength of the colouring 
 matter which exists at the different parts. This it 
 but rarely does, for habit and constant interpretation 
 of what should be seen prevents the mind from 
 distinguishing these variations ; but if the colour 
 brightness, as perceived by the different parts, be 
 submitted to measurement by proper means, the varia- 
 tions in brightness of the image can be readily 
 recognised. A very common method of exhibiting 
 the presence of the pigment is to look at a bright 
 white cloud through a layer of chrome alum. Chrome 
 alum transmits red and blue - green rays. Now as 
 
6 Colour Vision. 
 
 the spectrum-blue rays are those which the pigment 
 will absorb, it follows that the colour of the solution 
 should appear ruddy to the central part of the eye, 
 but on the rest of the retina it should appear of its 
 ordinary purplish colour. At a first glance, and before 
 the eye has become fatigued, this is the case, but the 
 phenomenon soon disappears. Another way of forming 
 an idea as to what the yellow spot absorbs is to throw 
 a feeble spectrum on a white surface and cause the 
 eye to travel along it. If the spectrum be viewed so 
 that it does not occupy more than about 40° of the 
 retina, the movement of the eye will show a dark 
 band travelling along the green, blue, and violet regions 
 as the image of these parts of the spectrum fall on the 
 yellow spot, and their apparent brightness will increase 
 as they fall outside the absorbing area. This proves 
 that an absorption takes place in this area. 
 
 The retina consists essentially of an inner and outer 
 wall, enclosing matter w^hich is similar to the grey 
 matter of the brain. On the inner wall are the 
 vessels which are connected with the optic nerve. 
 The outer wall is epithelium coloured with a pig- 
 ment, and it is here that the visual impulses begin, 
 although the rays of light giving rise to them 
 have tO; pass through the thickness of the retina 
 
Purkinjes Figures. 7 
 
 before so doing. It has already been stated that 
 the light has to pass through the thickness of the 
 yellow spot before a visual sensation is felt in the 
 centre of the field, and the experiments just given 
 offer a fair proof of the truth of the assertion, but 
 there is still another which is perhaps more conclusive. 
 Suppose we have a hollow reflecting ball, as shown 
 in Fig. 2, and through an orifice A we project a 
 beam of light to B, which meets 
 an obstruction, S, in its path, then 
 A B would be reflected from B to 
 C on a screen C F, and the ob- 
 struction S would be marked at C. 
 If another beam from D was di- 
 rected so as to meet the same 
 obstruction, its presence would be 
 marked at F. Knowing the distance of the centre 
 of the hollow sphere from F C and its diameter, 
 and measuring the distance between F and C and 
 their respective distances from the axis of the sphere, 
 the distances S B and S E can be calculated. This 
 method is applied in the formation of what are known 
 as Purkinje's figures. The simplest case is where a 
 beam of light is directed through the sclerotic and 
 transmitted through the lens. Images of the retinal 
 
8 Colour Vision. 
 
 vessels are distinguished as at S, and it is found 
 that they cast shadows, which are seen as dark lines 
 in the glare of the field of vision. The sensation 
 of light must therefore come from behind these 
 vessels, and calculation shows that the seat of the 
 sensation is close to the pigmented inner wall of the 
 retina. 
 
 Lying here is a layer of what are known as rods 
 and cones, which have a connection, either actual or 
 functional, with the optic fibres which largely compose 
 the inner wall of the retina, and are connected with 
 the optic nerve. In the yellow spot the cones are 
 much more numerous than the rods, but in the peri- 
 pheral part the reverse is the case. In the fovea the 
 rods appear to be altogether absent. The total number 
 of cones in the eye has been calculated to be about 
 3,000,000, of which about 7,000 are in the small fovea. 
 The number of cones will give an idea of their dimen- 
 sions. This detail has been entered into as it has been 
 supposed that these rods and cones are all-important 
 in translating light-waves into visual impulses. The 
 inner wall of the retina of most human eyes, as has 
 been mentioned, is stained with a black pigment, 
 fuscin, though in albinos it is absent. What its par- 
 ticular use may be is still unknown, for its change by 
 
Visual Purple. 9 
 
 light is so slow that it can scarcely be the cause of 
 vision. In the outer parts of the rods is, however, 
 diffused a substance highly sensitive to light, called 
 the " visual purple," from its colour, and a theory 
 founded on chemical action, produced by a change 
 in this substance, has been promulgated. Fascinating, 
 however, as such a theory must be, it lacks confirma- 
 tion. The fact that the cones do not contain it, 
 and that in the fovea are cones alone, renders it 
 difficult to reconcile the theory with the fact that 
 this part of the retina possesses, we are told, the 
 greatest acuteness of sensation as res^ards lio^ht and 
 colour. - 
 
 The eyes of most vertebrate animals, it may be 
 remarked, have this visual purple, but in those of 
 the bat, owl, hen, and some others the colouring 
 matter seems to be absent. Visual purple is an in- 
 teresting substance, however, and as it is found in 
 the eye it probably exercises some useful function, 
 though what that function may be is at present 
 unknown. That images of objects can be formed on 
 the retina, owing to the bleaching of this substance, 
 has been proved by experiment. The purple is first 
 changed to a yellow colour, and then passes into 
 white. These " optograms," as they are called, can 
 
 I 
 
lO Colour Vision, 
 
 be fixed in an excised eye if the retina be detached, 
 
 and then be treated 
 with a weak solution 
 of alum. 
 
 Many persons are 
 not aware of the 
 extent of the field 
 of view which the 
 eye embraces. Ver- 
 tically it takes in 
 about 100°, whilst 
 horizontally it will 
 take in some 145°, 
 more or less. The 
 field is smaller on 
 the nasal than on 
 the temporal side. 
 When both eyes are 
 used, the combined 
 field of view is 
 larger horizontally, 
 being about 180°. 
 The field of view 
 which is common 
 
 to both eyes is roughly a circle of about 90°. There 
 
Distinctness of Vision. 1 1 
 
 is, however, a marked difference in the distinctness 
 with which objects are perceived in the different parts 
 of field of view. On the fovea centralis two dots placed 
 so as to subtend an angle of 60" will be perceived as 
 double. That is to say, if a piece of paper, on which 
 are two dots -3^^ of an inch apart, be placed 10 feet 
 away from the observer, these dots will be seen as 
 separated, whilst dots (in this case they should be 
 black and of good dimensions) placed half - an - inch 
 apart would still appear as one if viewed at the same 
 distance near the periphery of the retina. In the 
 yellow spot the distance apart of the cones is such 
 that they subtend about the same angle as the dots 
 when they are seen separate, viz., about 60"; that is, 
 they are about ^q^qqq of an inch apart, and hence 
 may have something to say to the limit of separation. 
 The field for the perception of colour is different to 
 that for light. 
 
 The diagrams (Fig. 3) will show the fields in a 
 satisfactory manner. The concentric circles are sup- 
 posed to be circles lying on the retina corresponding 
 to parallels of latitude on a globe, and are not, there- 
 fore, equi-distant when seen in projection. To make 
 these circles it must be imagined that we have a bowl, 
 in the middle of which is a thin rod standing upright 
 
1 2 Colour Vision, 
 
 and passing through the centre, and another rod 
 attached to it at the centre of the sphere of exactly 
 the length of the radius. If this last arm be opened 
 to make an angle of 5° with the fixed rod, and Ije 
 twisted round like the leg of a compass against the 
 bowl, it will make a circle, the projection of which will 
 give the innermost circle of the diagram ; if opened 
 to 10° it will give the next circle, and so on for every 
 subsequent 10°. The lines passing through the centre 
 are 30° from one another, the line stretching from 
 360° to 180° being a line supposed to be vertical. 
 By means of an instrument called the perimeter, the 
 field of vision for each eye can be measured. With 
 its aid any small object can be made to fall on any 
 part of the retina by directing the axis of the eye 
 to a fixed point and moving the object along one 
 of the diameters. Suppose we wish to ascertain the 
 field for a white object, a small white disc is moved, 
 say, along the horizontal line, and the angles at which 
 the retina just no longer sees it are noted. This gives 
 two points in the field, and they are plotted on the 
 chart — in Fig. 3 one touches the outside circle, and the 
 other is at an angle of about 65°. The field of vision is 
 next tested along another line, say 300° to 120°, and 
 other points noted and marked on the chart. When 
 
Colour Fields, 13 
 
 the whole circle has been examined, the various points 
 are joined together, and we have the boundary of 
 vision for a white object. The boundaries of the colour 
 perception for (say) small red and green discs are found 
 in the same way. The former is depicted in the left- 
 hand chart and gives the field for the right eye, and 
 the latter with that for white in the right-hand chart 
 for the same eye. It will be noticed that two boun- 
 daries are given, one taken at mid-day and the other 
 at 6 p.m. The brighter the colour, the larger is the 
 boundary in both cases, showing that the field of colour 
 vision varies according to the illumination. Now it is 
 difficult from this method of experimenting to determine 
 whether the fields for different colours are the same 
 or differ in extent, as we have no information as to 
 whether the colours themselves which were used were 
 physiologically equal. The only way by which this can 
 be satisfactorily determined is by using spectrum colours 
 each of known brightness and area. (Some preliminary 
 experiments made by myself regarding the colour fields 
 w^ill be found in the appendix, and will be referred to 
 later.) It must not be thought that the various colour 
 boundaries mark the limit at which light is perceived, 
 but only the limit at which colour is seen ; outside the 
 boundaries the objects appear of a nondescript colour, 
 
14 Colour Vision. 
 
 to which we shall by-and-by call attention. The yellow 
 spot lies within the circle of 5°, and the blind spot on 
 which no sensation of light is stimulated is shown by 
 the black dot about 15° away from the centre. 
 
 I have only attempted to sketch, in unphysiological 
 language, the primary apparatus with which our 
 experiments in colour have perforce to be made. 
 
( 15 ) 
 
 CHAPTER 11. 
 
 It will be seen, then, that in measuring colour or 
 light several circumstances have to be taken into 
 account. These are not simple, and require differen- 
 tiating one from another before the results of colour 
 measures can be finally laid down as correct, or as 
 being held to be applicable to all cases. 
 
 We must naturally ask, w^hat is colour ? The answer 
 I should like to pass over entirely. It can only be 
 described as a sensation, just as we should describe 
 touch as a sensation. It has, however, one advantage 
 over most sensations, in that it is a sensation which 
 can be submitted to empyric measurement. The 
 question whether certain phenomena, such as the 
 colours produced by simultaneous contrast, are sub- 
 jective or real, does not require answering for the 
 purpose that we have in view, but the results recorded 
 may probably help to throw light on it. Colour is 
 an impression caused by the stimulation in the eye 
 
1 6 Colour Vision, 
 
 of some apparatus, that lies near the outer wall of 
 the retina, the effect of the stimulation being con- 
 veyed by the optic nerve to the brain. If this 
 apparatus be complicated by being made up of 
 distinct parts, each of which transmits its own kind 
 of impression to the brain, it is not only quite 
 possible, but more than probable, that when one part 
 is absent or injured the particular impression for which 
 it is responsible will be lacking, and that the sum of 
 the impressions due to the remainder will be unlike 
 that perceived when they are all working together. 
 
 In every investigation, whether it be in physical or 
 In any other branch of science, it is better to work 
 up from the simple to the more complicated ; and 
 acting on this plan, it is better to commence experi- 
 menting wdth simple rather than with complex colours, 
 though they may apparently produce precisely the 
 same sensations. I shall, with this in view, devote 
 most of the remaining part of this chapter to some 
 necessary experiments wdth simple colours. The simple 
 colours are those of the spectrum, and are the result 
 of motion in the ether, which pervades all space. The 
 motion is in the form of undulations or waves, and 
 each colour is due to a series of these waves, which 
 have a definite length. Thus, 6562 ten-million ths of 
 
Wave- Lengths of Light. 1.7 
 
 a millimetre produces to most of us a red colour in 
 the spectrum (see Plate L), occupying the position 
 indicated by a black line known as the C line in the 
 solar spectrum. 
 
 A table of wave-lengths of certain lines in the solar 
 spectrum is given below : — 
 
 TABLE OF WAVE-LENGTHS IN TEN-MI LLIONTHS 
 OF A MILLIMETKE. 
 
 B, deep red 
 
 6866 
 
 b, green . 
 
 5183 
 
 Lithium, cherry red 
 
 6705 
 
 F, bluish greeii 
 
 4861 
 
 C, red . 
 
 6562 
 
 Lithium, blue . 
 
 4603 
 
 D, orange 
 
 5892 
 
 G, violet. 
 
 4307 
 
 E, green . 
 
 5269 
 
 H, extreme violet 
 
 3968 
 
 The rays in the different parts of the spectrum 
 being due to these simple vibratory motions, cannot 
 be decomposed further. And it makes no matter 
 whether we see them as different colours or not, they 
 will always issue at the same angle from the same 
 prism (if the prism be used to form the spectrum), 
 when it is turned to the same angle to the incident 
 light. Milestones are useful along a road to tell us 
 where we are in reference to some central place, and 
 these black lines in the spectrum serve the same end. 
 But they have the advantage over the milestone, for 
 whilst the last will tell us how far we are from, say, 
 York or London, the former tell us our distance from 
 
 c 
 
1 8 Colour Vision. 
 
 a zero point. We thus have a scale of light of different 
 wave-lengths laid down for us, which we can apply 
 to the study of the sensations stimulated in the eye, 
 and so have the means of instituting a comparison 
 between the colour vision of different eyes. A mixed 
 or composite colour is in a different category, however, 
 to the simple colour, as you will see directly. It is 
 one which may be formed by any number of rays of 
 different wave-lengths falling on the eye. What these 
 rays are we can only tell by analysing the light and 
 referring them to the spectrum. 
 
 The instrument before you is one which I have 
 used before in this theatre ; but as the major part 
 of my experiments have been carried out with it, in 
 case those who are present may not be acquainted 
 with it, it will be necessary to describe it very briefly. 
 The general arrangement of the apparatus is given in 
 the accompanying diagram, Fig. 4. 
 
 R R are rays coming from the source of light, be it 
 sun light or the electric light, and an image of the one 
 or the other is formed by a lens L^ on the slit Si of 
 the collimator C. The parallel rays produced by the 
 lens L2 are partially refracted and partially reflected. 
 The former pass through the prisms Pi, P2, and are 
 focussed to form a spectrum at D by a lens L3. D is a 
 
Colour Patch Apparatus. 
 
 19 
 
 movable screen in which is an aperture S._,, the width 
 of which can be varied as desired. The rays are again 
 
 Fig. 4. 
 
 // A. 
 
 
 11 
 
 I 
 
 M 
 
 1 JE 
 
 collected by a lens L4, and form a white image of the 
 surface of the last prism on the screen E. If the light 
 passing through S2 is alone used, the image at E is 
 
 2 
 
^O Colour Vision, 
 
 formed of practically mono-chromatic light. Part of 
 the rays falling on Pi are, as just said, reflected, but) 
 as it and the refracted part are portions of the light 
 passing through the slit S^, they both must vary pro- 
 portionally. If then we use the reflected portion as 
 a comparison light to the spectrum colours, the rela- 
 tive intensities of the two, though they may vary 
 intrinsically, will remain the same. The rays reflected 
 from Pi fall on Gr, a silver or glass mirror, and, by 
 means of another lens L^, also can be caused to form 
 a white patch on the screen E, alongside the patch 
 of colour. At M, or anywhere in the path of the 
 beams, an electro-motor driving a sector with aper- 
 tures which can be opened or closed whilst rotating, 
 is placed, and the illumination of either beam can be 
 altered at will. To obtain a large spectrum on the 
 screen E, all that is necessary is to interpose a lens 
 of fairly short focus in front of L4, when a spectrum 
 of great purity and brightness can be formed. 
 
 If it be required to measure the width of the slits S2 
 (which we shall see further on is often necessary), a 
 small lens of short focal .length placed behind L4 and 
 near the slit will cast a magnified image on E, and by) 
 means of a scale placed there, the widths of each slit,: 
 if there are more than one, can be read ofl* on the 
 
p° 
 
 scale by bringing them 
 successively into the 
 same colour. 
 
 Originally the com- 
 parison light was a 
 candle, and it answered 
 its purpose fairly well, 
 and for obtaining abso- 
 lute measures is con- 
 venient at the present 
 time. Fig. 5 will show 
 its arrangement, but as 
 both the candle and the 
 electric light may vary 
 independently of each 
 other, it will be seen 
 that for merely the 
 comparison of the dif- 
 ferent spectrum colours, 
 the previous arrange - 
 ent is the better. In 
 both cases the two beams 
 — the direct and the 
 comparison — may be 
 made to cast shadows 
 
 Colour Patch Apparains. 
 
 Fig. 5. 
 
 21 
 
 I 
 
.2 2 Colour Vision. 
 
 by placing a rod in their path, the shadow cast 
 by one light is then illuminated by the other light. 
 By moving the rod towards or from the screen the 
 shadows can be brought side by side. 
 
 With this instrument it is easy to demonstrate that 
 a mixed colour may be mistaken for a simple colour 
 of the spectrum. In a glass cell with parallel sides 
 is a solution of potassium bichromate, which, to myself 
 and probably most of you, has a beautiful orange colour. 
 The spectrum of white light is now on the screen, and 
 if this orange liquid is placed in the path of the white 
 light before it reaches the prisms, all the violet, blue, 
 and most of the green is cut off, leaving some green- 
 yellow, orange and red only on the screen. That 
 these form the orange colour of the bichromate is 
 readily shown by removing the auxiliary lens. The 
 spectrum, which has its focus at D, is now recombined 
 into a patch of light, which is at once seen to be the 
 colour of the solution. 
 
 The colour of the bichromate is therefore a complex 
 or mixed colour according to our definition, for it is 
 made up of a large number of simple colours. What I 
 desire to show, however, is that this complex colour can 
 be mistaken by the eye for a simple colour. First, let 
 US interpose the cell with the bichromate in the path 
 
Simple and Complex Colo7trs. 23 
 
 of the reflected beam, and throw the patch of light 
 formed by it on a white surface A (Fig. 6), alongside 
 the patch of light B formed by the spectrum. Next 
 let us pass a single aperture (Fig. 7), which can be 
 opened and closed by a screw arrangement, through 
 the spectrum. By careful movement we at length 
 come to an orange ray, which is spread out by the 
 apparatus to form a patch on B, that to the majority 
 (and the word majority is Fig. 6. 
 
 used with intention) of people 
 exactly matches the colour 
 of the bichromate. Thus we 
 have a proof that, as far as 
 the eye is concerned, the 
 simple and the complex 
 colours are identical. This illustration of the want of 
 power of the eye to analyse colour might be repeated as 
 often as we like. We may pass coloured wools, for in- 
 stance, through the length of the spectrum and show 
 that they have the property of appearing bright in, 
 and therefore of reflecting, some colours and of almost 
 disappearing in others — a sure indication that these 
 colours are mixed colours as they are made up of the 
 rays which are reflected. Yet when viewed in white 
 light they can in many cases be matched with simple 
 
24 Colour Vision. 
 
 colours in the way we matched the colour of the 
 bichromate solution. This tells us that there is some- 
 thing which requires investigating as to the con- 
 stitution of the perceiving apparatus, and points to 
 the probability that it is less complicated than it would 
 be were it able to differentiate, without the aid of the 
 spectrum, between simple and complex colours. If 
 the eye had a separate apparatus — and when I say 
 apparatus I use the word for want of a better — for 
 taking up the impression of every simple colour, it 
 might well be assumed that a differentiation must take 
 place. 
 
 There is one class of colours, it must be remembered, 
 which can never be mistaken for simple colours. I refer 
 to the purples — mixtures of red and blue — for there are 
 no spectrum colours which unmixed can possibly match 
 them. All other colours, as no doubt will soon be 
 apparent, can be referred to some one spectrum colour, 
 either in its pure state or else mixed with some 
 variable quantity of white light. We are all familiar 
 with the fact that there are three primary colours, and 
 we are naturally led to consider these in the light of 
 the experiments just made. As good a definition as 
 any other of a primary colour is that it is a colour which 
 cannot be formed by the mixture of any two or more 
 
Primary Colours, : 5 
 
 colours. The original investigators in colour phenomena 
 were the artists, and they found that neither red, nor 
 yellow, nor blue could be formed by any mixture of 
 pigments on their palette, but that all other colours 
 could be made by a mixture of two or more of these 
 three. Hence to these three were given the name of 
 primary colours. When, however, the physicist began 
 to work with the simple colours of the spectrum, it 
 was speedily found that, at all events, the yellow was 
 not a primary colour, as it could be formed by a 
 mixture of green and red, whilst a green could not 
 be formed by a mixture of any other two colours. 
 This we can prove with our apparatus. 
 
 Three apertures, all of which can be opened or closed 
 as required (see Fig. 7), are placed 
 in the spectrum, one in the red, one 
 in the green, and one in the violet. 
 The last we shall not require at 
 present, so it is entirely closed ; but 
 we vary the width of the other two. 
 We find that with a little red added 
 to a bright green^ a yellow green is 
 produced ; wdth more red added we 
 have yellow ; with still more red, an 
 orange. The relative brightness of 
 
 Fig. 
 
26 Colour Vision. 
 
 the two colours mixed together can be shown by re- 
 moving the lens which recombines the spectrum to form 
 the patch of light. Each colour issues through its slit 
 and forms its own patch on a white screen which, for 
 the purpose, we make rather larger 
 than usual. The two patches overlap 
 in the middle (Fig. 8), and the pure 
 colours are seen one on each side of 
 the mixed colours. 
 
 Now% placing one slit in the yellow 
 and another in the blue of the spectrum, we find that 
 whatever width of slit we take, no green is produced, 
 but that, in fact, a yellowish or a bluish white results, 
 and that when the two slits are properly adjusted, a 
 pure white is produced. Evidently since none of the 
 intermediate spectrum colours between the blue and the 
 yellow can be made by their mixture, certainly green 
 cannot. Hence, with pure colours a green and not a 
 yellow is one of the primaries. 
 
 Further investigation on these lines has placed the 
 violet of the spectrum as a primary rather than the blue, 
 but this is still a matter of debate. Suffice it to say 
 that a red and a green in the spectrum are really two of 
 the primary colours, and most probably the violet the 
 third. Experiment shows that there is no other 
 
^^^V Pigments. %^^^m^^. 
 
 ^primary colour in the strict sense ^(^i^^^«»id^T^e ' ^ 
 thus arrive at the fact that, except tll^^^^I]^|f^o^^^^^^^^ 1 
 themselves, every colour in nature may 'lie ■ piad^xby ^tj 
 a mixture of two or three of these primaries. ** -'^-...--*^ 
 Just a word of explanation as to why, with pigments, 
 the primary colours appear to be red, yellow, and 
 blue, and not red, green, and blue. The colour of a 
 pigment, it must be recollected, is a complex one. If we 
 analyse a yellow — a yellow glass will be just as good 
 an example as anything else — w^e find it is m.ade up 
 of green, yellow, orange, and red. A blue is made 
 up of blue and green. If a yellow is placed behind 
 a blue glass, and we look at a white surface through 
 them, the only light that can get through the glass 
 is the green. If the light, coming through each glass 
 separately, falls on the same spot on a white surface, it 
 will be either colourless or bluish white, or yellowish 
 white, whichever colour preponderates. As the light 
 
 I reflected from mixed pigments is made up principally 
 by the light coming through the different particles, 
 first coming through one and then through another, 
 
 1 and only partially by mixed lights, it will be gathered 
 why the primary colour, when deduced from experi- 
 ments with pigments, was yellow, and not green. 
 With the spectrum colours there is this fact to 
 
28 Colour Vision. 
 
 remember, that though all intermediate colours between 
 the pairs of primaries can be formed by their mixture, 
 yet in some cases the resulting colours are slightly 
 diluted with white, and that they thus appear less 
 saturated than the spectrum colours themselves. The 
 reason for this we shall be able to account for when 
 we consider the colour sensations themselves. 
 
 When making matches to simple or other colours l)y 
 the method of mixtures, we have to be careful of the 
 conditions under which we experiment. This can be 
 shown by a very simple experiment. I will make a 
 match on B with the white light, which is thrown on 
 the surface A (Fig. 6), by mixing the red, green, and 
 violet that pass through the three adjustable apertures 
 or slits already described. The apertures are altered till 
 the match appears to myself perfect. From an appeal 
 made to those of the audience who are at least 25 feet 
 away from the patches of light, as to the correctness of 
 the match, I gather that the match is to them imperfect. 
 The mixed colours appear to them to give a pinkish 
 white. The reason of this defect in the match is due to 
 the fact that, as the lecturer is viewing the two square 
 patches of 2 in. side from a distance of 2 ft. 6 in., their 
 images on his retina extend beyond the boundary of 
 the yellow spot, whilst the audience receives the whole 
 
Colour Matches and the Yellow Spot. 29 
 
 of the image on that portion of the retina which is 
 completely covered by it. To the lecturer only part of 
 the blue and green is absorbed by the yellow spot, and 
 the part of the retina outside it on which the image 
 falls receives and records the full intensity of these^ 
 colours. To the audience the full amount of absorption 
 takes place, with the result that the patch of mixed 
 colours must appear too red when it is correct to the 
 lecturer. In this case habit makes the eye take an 
 average of the different intensities which must exist at 
 the various parts of the image. We can, however, cause 
 I perfect agreement between all parties if the experi- 
 menter views the surfaces in a mirror placed some 12 
 ^eet away and then makes the match, for he is viewing 
 ]he patches from what is practically a distance of 24 
 eet. If after making the match without the aid of the 
 nirror the lecturer's eyes are directed a little to one 
 ide of the illuminated surfaces, a match will no longer 
 xist ; the mixed colour, which is to the audience 
 )inkish, will now appear a bluish green to him. The 
 eason for this alteration in hue is that the whole of the 
 mages falls outside the yellow spot. t 
 
 It will now be quite apparent that we must discount 
 ny assertion in regard to colour matches, unless we are 
 old the distance of the eye from the surface on which 
 
30 Colour Vision. 
 
 the match is made, together with the size of that sur- 
 face. This yellow spot is often provokingly tiresome 
 in the study of colour mixtures, and one might almost 
 be justified in doubting whether any absolutely exact 
 matches can ever be vouched for, owing to the important 
 region of the retina which it occupies. 
 
 The fatigue of the retina to colour after it has 
 been presented to the eye for any length of time is a 
 •difficulty, but in a less degree. That the retina 
 does experience fatigue can be shown by a very simple 
 experiment. The lecture theatre is now illuminated 
 by the incandescent light, and if we throw an image 
 of the bright carbon points of the electric arc light 
 •on the screen and steadily fix the eyes on the image 
 of the white-hot crater for some (say) tw^enty seconds, 
 and then we suddenly withdraw it, a dark image of the 
 points will be seen on the partially lighted screen, and 
 will appear to travel with the eyes as they move away 
 from the fixed point. This phenomenon is due to the 
 fact that the perceiving apparatus for white light gets 
 fatigued on the parts of the retina on which the bright 
 image of the white carbon points thrown on the screen 
 fell, and that when the source of brightness was removed, 
 the less intense illumination of the screen failed to 
 .stimulate the vision apparatus at those parts to the 
 
Retinal Fatigue, 31 
 
 same extent that they were stimulated over the rest of 
 the field. We can vary the experiment by placing a red 
 glass in front of the electric light, and, following the 
 same course as before, we shall see a greenish-blue 
 image of the carbon points upon the screen. In this 
 case the retinal apparatus w^hich has not been stimu- 
 lated by the red sensation will be capable of the 
 maximum stimulation by the feeble white light, whilst 
 that part which has suffered fatigue will not respond so 
 freely to the red contained in the white light. If we 
 abstract a certain amount of red from the spectrum, 
 its recombination will give a white tinged with greenish 
 blue, which is a counterpart of the colour we feel when 
 .the eyes have been fatigued by the red light. 
 
(32 ) 
 
 CHAPTEE III. 
 
 Let mc take you back again to matches of colour. 
 "We will now, however, make the matches with 
 the primary colours in the guise of pigments. These 
 colours themselves are complex colours, but as the 
 eye cannot trace any difference, or at all events very 
 little difference, between them and simple colours, 
 a mixture of these complex colours should answer 
 nearly as well as do mixtures of the simpler colours. 
 We have here three discs, a red, a green, and a blue, 
 and we can very closely match these colours by a 
 red, a green, and a blue in the spectrum. 
 
 By having a radial slit cut to the centre of these card 
 discs, we can slip one over the other so as to expose 
 all three colours as sectors of a single disc. Then we 
 can place the compounded disc on the axis of a rapidly 
 rotating motor, and the colours will blend together, 
 giving an uniform colour. Any proportions of the 
 three colours can thus be mixed, and by a judicious 
 
Colour Discs. 33 
 
 alteration in them we now have them so arranged 
 that they give a grey. By inter-locking together 
 (Fig. 9) a black disc and a white disc, each with a 
 diameter slightly larger than that of the other discs, 
 but equal to each other, and rotating them on the 
 same spindle behind the three colour discs, we can, 
 by an alteration in the proportion of black to white, 
 form a grey which will match that Fig. 9. 
 
 produced by the rotation of the three 
 coloured sectors. In other words, white, 
 though degraded in tone, can be pro- 
 duced by the three complex pigment 
 colours, as we have seen can also be done by the 
 mixture of the three simple spectrum colours. 
 
 The mixture of the three spectrum colours can 
 match other colours than white. For instance, it 
 can be made to match the colour of brown paper. 
 By the colour discs also we can do exactly the same 
 by introducing, if necessary, a small quantity of white 
 or black, or both, to dilute the colour or to darken 
 its tone. 
 
 Another application of the same principles enables us 
 to produce an artificial spectrum by means of a red, a 
 green, and a blue glass. By fixing these three glasses 
 behind properly shaped apertures cut in a card disc at 
 
 D 
 
34 Colour Vision, 
 
 proper radial distances from the centre, and rotating 
 the disc, we have upon the screen when light is passed 
 through them a ring of rainbow colours. If the 
 beam of light be first passed through a suitable 
 rectangular aperture, the breadth of which is small 
 compared with its length, placed close to the rotating 
 disc, and an image of the aperture be focussed on the 
 screen by a suitable lens, we shall have a very fair 
 representation of the spectrum — every colour inter- 
 mediate between the red and green, or the green 
 and blue, being formed by mixtures of these pairs 
 respectively. 
 
 We have now given a very fair proof that vision is 
 really trichromic — that is, that it is unnecessary to 
 have more than the sensations of three colours to 
 produce the sensation of any of the others. 
 
 There is one colour, if it may be called so, that has 
 not been shown you, and whether it is a simple colour 
 or not cannot be stated. It seems, however, to be the 
 basis of all other colours, since they all commence with 
 it. It would, perhaps, be preferable to call it the first 
 perception of light instead of a colour. We can ex- 
 hibit this in a fairly easy manner by a little artifice. 
 An incandescent lamp is before you, and a current 
 from a battery passing through the carbon thread 
 
Fig. 10. 
 
 Fundamental Light. 35 
 
 causes it to glow brightly. In the circuit, however, 
 I have introduced what is known as a resistance, 
 which consists of a very large number of square pieces 
 of carbonized linen, pressed more or less tightly to- 
 gether. By means of a screw the pressure can be 
 varied. When the pressure is somewhat relaxed, the 
 resistance to the passage of the current is increased, and 
 the carbon thread glows less brightly ; and by a still 
 greater release of pressure, 
 the light can be made to dis- 
 appear altogether. A beaker 
 (Fig. 10) which we have 
 here is covered with thin 
 blotting paper, and when 
 placed over the incandescent 
 glow-lamp it appears as a luminous yellow cylinder, the 
 colour being due to that of the light within it. We 
 can next insert more resistance in the circuit, and it 
 becomes red, due to the ruddy light of the thread. 
 By inserting still more resistance into the circuit the 
 
 Ied fades away, but in the darkness of this lecture 
 heatre the beaker is still a luminous object, though 
 iaintly so. It has no colour, and the only sensation 
 fc provokes is one of light. Taking off the beaker, we 
 see that the carbon thread is a dull red and nothing 
 
 D 2 
 
36 Colour Vision, 
 
 more. The passage of tliis light through the white 
 blotting paper so reduces it that the red is non- 
 existent, and the initial sensation is all we perceive. 
 
 Placing a piece of red, green, or blue gelatine round 
 the lamp, we get the same effect, showing that the 
 basis of all colour, be it red, green, or any other colour, 
 is what appears to us to be colourless. This experi- 
 ment is one which is full of interest, as it has a very 
 distinct bearing on diagnosing our colour sensations, 
 and a variation of it will have to be repeated under 
 other conditions. 
 
 To go back, however, a little way, how does it arise 
 that only three sensations are necessary to give the 
 impression of all colours ? One can understand that 
 some definite period of the ether waves might be in 
 unison with the possible swing of one apparatus in 
 the eye, and another with another, but it is some- 
 what difficult at first sight to conceive that more 
 than one can be made to answer to wave motion of 
 a period with which it is out of tune, so to speak. A 
 couple of illustrations taken from physical experiments 
 may help to suggest how this can happen. 
 
 Fig. 11 is a double pendulum arranged as shown. 
 The pendulum A is heavily weighted, whilst the pen- 
 dulum B is light, being only a string with a small 
 
Penduhmi Motion. 
 
 37 
 
 weight attached. This difference in weight was made 
 designedly, to prevent any great effect of the move- 
 ment of B being shown on A, though Fkj h 
 that of A must necessarily exercise a 
 great influence on B. The two pendu- 
 lums are now of the same length. A 
 is set in motion, and as it swings, B 
 also begins to swing, and soon is os- 
 cillating with greater motion than A, 
 and continues to do so. The length of ^ 
 the pendulum B is next shortened, and A is again s^t 
 in motion. B takes up the motion, and increases its 
 swing more and more, but now the two pendulums 
 are in opposite phases, and the motion of A tends 
 to diminish the swing of B, and continues to do 
 so till, after an interval of time, B is once more 
 at rest, when it again will start swinging. The fact is, 
 that w^hen A commences to swing, B also commences ; 
 
 I ad as long as B and A are moving in the same direc- 
 ion the impulses tend to make B increase its swing, 
 ut when they are moving in the opposite direction, or 
 Either, perhaps it should be said, when A begins to start 
 from the highest point of its swing downwards whilst 
 B is travelling upwards, the swing of -B will gradually 
 diminish. This, of course, must happen when B is 
 
38 Colour Vision, 
 
 shorter or longer tlian A, since their times of oscillation 
 are then different. We can now picture to ourselves 
 that when in the perceiving apparatus in the retina 
 the moving parts — probably molecules or atoms — 
 arrive at a certain amplitude, there is then an im- 
 pression of light, and that it is quite possible that 
 not only those waves whose motion is exactly of the 
 same period as that of the apparatus will set them 
 in motion, but also those waves which are actually 
 of a very different period. If such be the case, it 
 can be seen that waves of light of some periods may 
 set each of the three kinds of perceiving apparatus in 
 motion, and that possibly the resulting impressions 
 given by the sum of all three for a Avave out of tune 
 with any of them may be even greater than when the 
 wave period is absolutely the same as one of them. 
 For in the last case a maximum effect may be pro- 
 duced on one apparatus, and the effects on the other 
 two may be insignificant ; whilst in the first case the 
 effects on two of them may be so large that their 
 combined effects may have a larger value. 
 
 The following diagram (Fig. 12), made on the prin- 
 ciple of Lissajou's figures, shows graphically the motion 
 of the pendulum. The pendulum, with a pen attached, 
 was started by an independent pendulum, which had a 
 
Graphic Periduhim Motion. 39 
 
 different period, and the amplitude of the former 
 registered itself on paper which moved by clockwork 
 round the axis of suspension. As the two pendulums 
 had different periods, the amplitude, as shown by the 
 traces made, first increased and then diminished till 
 there was no motion, and then started again. The trace 
 is very instructive, and deserves attention. It will 
 be noticed that the amplitude, or length of swing, 
 increased rapidly at first, and then very gradually 
 attained a maximum. ^^^- ^2- 
 
 Having attained this 
 maximum, the ampli- 
 tude diminiBhed very 
 slowly for some time, 
 and finally came rather rapidly to zero, and the 
 pendulum for an instant was at rest. 
 
 With the notion in our minds that the perceiving 
 apparatus might act in the way that the pendulum 
 acts, we naturally apply it to the theories which early 
 investigators on colour vision propounded. Thomas 
 Young, whose name has already been mentioned, had 
 propounded a theory of vision, which depended on 
 the existence of only three colour sensations, and 
 Von Helmholtz adopted it and explained the action 
 of the three sensations in reference to the spectrum as 
 
40 
 
 Colo7cr Vision. 
 
 shown in the diagram. These figures do not pretend 
 to be absolute measures of the sensations, but only 
 of the form which they might take (Fig. 13). The 
 height of the curve at each part of the spectrum is 
 supposed to represent the stimulation given to each 
 apparatus by the different colours. Looking at the 
 figures we see that each sensation has a place of 
 
 maximum stimula- 
 
 FiG. 13. ^^.^^^^^^ 
 
 tion, and that the 
 stimulation falls 
 off more or less 
 rapidly on each 
 side of this maxi- 
 mum. It will, how- 
 ever, be noticed 
 that whilst the green sensation takes very much the 
 form of the pendulum amplitudes (Fig. 12) between its 
 periods of rest, the other two differ from it. In the case 
 of the red sensation, the stimulation falls very rapidly 
 in the red as it reaches the limit of visibility of the 
 spectrum, and in that of the blue sensation the steep 
 descent is towards the extreme violet. When the three 
 sensation theory is examined in the light of the careful 
 measurements that have been made, the results^ tell us 
 that these diagrams can only be taken as suggest^ 
 
 V Bl. Gr. Y O R 
 
 The top figure is tlie red sensation on the Young 
 theory ; the middle is tlie green sensation, and 
 the lowest the violet or bhie sensation. 
 
(41 ) 
 
 CHAPTER IV. 
 
 An independent investigator of this subject was 
 Clerk Maxwell, who experimented with a " colour-box " 
 of his own design, by which he mixed the simple 
 colours of the spectrum, and the results he got are 
 really the first which are founded on measurement. 
 He measured something, but liardly arrived at the 
 colour sensation. His colour-box took two forms, 
 both on the same principles, so only one will be here 
 described, the diagram and description being taken 
 from his classic paper in the Philosophical Transactions 
 of the Poyal Society for 1860. 
 
 "The experimental method which I have used 
 consists in forming a combination of three colours 
 belonging to different portions of the spectrum, the 
 quantity of each l)eing so adjusted that the mixture 
 shall be white, and equal in intensity to a given white* 
 Fig. 14 represents the instrument for making the 
 observations. It consists of two tubes, or long boxes 
 
42 Colour Vision. 
 
 of deal, of rectangular section, joined, together at an 
 angle of about 100°. 
 
 " The part A K is about five feet long, seven inches 
 broad, and four deep; K N is about two feet long, 
 ^\^ inches broad, and four deep ; B D is a partition 
 parallel to the side of the long box. The whole of 
 the inside of the instrument is painted black, and the 
 only openings are at the end AC, and at E. At the 
 
 Fig. 14. 
 
 c,_ 
 
 Y< 
 
 Maxwell's colour-box. 
 
 angle there is a lid, which is opened when 
 the optical parts have to be adjusted or 
 cleaned. 
 
 " At E is a fine vertical slit, L is a lens ; at P there 
 are two equilateral prisms. The slit E, the lens L, 
 and the prisms P are so adjusted, that when light is 
 admitted at E, a pure spectrum is formed at A B, the 
 extremity of the long box. A mirror at M is also 
 adjusted so as to reflect the light from E, along the 
 narrow compartment of the box to B C. 
 
 "At A B is a rectangular frame of brass, having a 
 rectangular aperture of six inches by one. On this 
 
MaxweWs Colour-Box. 43 
 
 frame are placed six brass sliders, X Y Z. Each of 
 these carries a knife-edge of brass in the plane of the 
 surface of the frame. 
 
 '' These six movable knife-edges form three slits, 
 X Y Z, which may be so adjusted as to coincide with 
 any three portions of the pure spectrum formed by 
 light from E. The intervals behind the sliders are 
 closed by hinged shutters, which allow the sliders to 
 move without letting light pass between them. 
 
 " The inner edge of the brass frame is graduated to 
 twentieths of an inch, so that the position of any slit 
 can be read off. The breadth of the slit is ascertained 
 by means of a wedge-shaped piece of metal, six inches 
 long, and tapering to a point from a width of half an 
 inch. This is gently inserted into each slit, and the 
 breadth is determined by the distance to which it 
 enters, the divisions on the wedge corresponding to 
 the 200th of an inch difference in breadth, so that 
 the unit of breadth is '005 inch. 
 
 " Now suppose light to enter at E, to pass through 
 the lens, and to be refracted by the two prisms at P, 
 a pure spectrum, showing Fraunhofer's lines, is formed 
 at AB, but only that part is allowed to pass which 
 falls on the three slits, XYZ. The rest is stopped 
 by the shutters. Suppose that the portion falling on 
 
44 Colour Vision. 
 
 X belongs to the red part of tlie spectrum ; then, of 
 the white light entering at E, only the red will come 
 through the slit X. If we were to admit red light 
 at X, it would be refracted to E, by the principle in 
 optics that the course of the ray may be reversed. 
 
 " If, instead of red light, we were to admit white light 
 at X, still only red light would come to E ; for all 
 other light would be either more or less refracted, and 
 would not reach the slit at E. Applying the eye at 
 the slit E, we should see the prism P uniformly 
 illuminated with red light, of the kind corresponding 
 to the part of the spectrum which falls on the slit X, 
 when white light is admitted at E. 
 
 " Let the slit Y correspond to another portion of the 
 spectrum, say the green ; then if white light is admitted 
 at Y, the prism, as seen by an eye at E, will be uni- 
 formly illuminated with green light ; and if white 
 light be admitted at X and Y simultaneously, the 
 colour seen at E will be a compound of red and green, 
 the proportions depending on the breadth of the slits 
 and the intensity of the light which enters them. 
 The third slit Z, enables us to combine any three 
 kinds of light in any given proportions, so that an 
 eye at E shall see the face of the prism at P, 
 uniformly illuminated with the colour resulting from 
 
Maxwell's Coloiir-Box. 45 
 
 the combination of the three. The position of these 
 three rays in the spectrum is found by admitting the 
 light at E, and comparing the position of the slits 
 with the position of the principal fixed lines ; and the 
 breadth of the slits is determined by means of the 
 wedges. 
 
 " At the same time, white light is admitted through 
 BC to the mirror of black glass at M, whence it is 
 reflected to E, past the edge of the prism at P, so 
 that the eye at E sees through the lens a field con- 
 sisting of two portions, separated by the edge of the 
 prism ; that on the left hand being compounded of 
 three colours of the spectrum refracted by the prism, 
 while that on the right hand is white light reflected from 
 the mirror. By adjusting the slits properly, these two 
 portions of the field may be made equal, both in colour 
 and brightness, so that the edge of the prism becomes 
 almost invisible. 
 
 " In making experiments, the instrument was placed 
 on a table in a room moderately lighted, with the end 
 A B turned towards a large board covered with white 
 paper, and placed in the open air, so as to be uniformly 
 illuminated by the sun. In this way the three slits 
 and the mirror M were all illuminated with white 
 light of the same intensity, and all were afiected in the 
 
46 Colour Vision, 
 
 same ratio by any change of illumination ; so that if 
 the two halves of the field were rendered equal when 
 the sun was under a cloud, they were found nearly 
 correct when the sun again appeared. No experiments, 
 however, were considered good unless the sun remained 
 uniformly bright during the whole series of experi- 
 ments. 
 
 "After each set of experiments light was admitted 
 at E, and the position of the fixed lines D and F of 
 the spectrum was read oiff on the scale at AB. It 
 was found that after the instrument had been in use 
 some time these positions were invariable, showing that 
 the eye-hole, the prisms, and the scale might be con- 
 sidered as rigidly connected." 
 
 With this instrument he made mixtures of three 
 colours, to match with white. By shifting the slits 
 into various positions and taking as his three standard 
 colours a red near the C line, a green near E, and a 
 blue between F and G- (see frontispiece), he obtained a 
 variety of matches, from which he formed equations. 
 After eliminating, or rather reducing the errors to the 
 most probable value by the method of least squares, he 
 got from his matches with white a table of colour values 
 in terms of the three standard colours, from which the 
 diagram of the spectrum (Fig. 15) was made. (The 
 
Maxwell's Colour Curves. 
 
 47 
 
 heiahts of the dotted curves are derived from the 
 widths of the slits, and the continuous curve is the 
 sum of these heights.) Now what appears to be a 
 properly chosen colour does not necessarily stimulate 
 only one sensation. Indeed the probabilities are against 
 it, except in the extreme red and extreme violet. If 
 
 Fig. 15. 
 
 colours intermediate to the standard colours be 
 matched by a mixture of the latter, we do not arrive 
 at any solution of the amount of stimulation of each 
 
 Insation, since the chosen standard colours themselves 
 ay be due to a stimulation of all three sensations, 
 s a matter of fact. Clerk Maxwell chose colours 
 hich do not best represent the colour sensations. 
 The red is too near the yellow, as is also the green* 
 
48 Colour Vision. 
 
 The blue should also be nearer the violet end of the 
 spectrum than the position which lie chose for it. AVe 
 may take it, then, that except as a first approximation, 
 Olerk Maxwell's diagrams need not be seriously taken 
 into account. The diagram itself shows that the 
 colour sensations are not represented by the colours 
 he chose. Supposing any one in whom the sensation 
 of green is absent were examining the spectrum, there 
 would, according to the diagram, be no light visible 
 at the green at E. Anticipating for a moment what 
 we shall deal with in detail shortly, it may be stated 
 that in cases where it is proved that a green sen- 
 sation is absent, there is no position in any part of 
 the spectrum where there is an absence of light. Had -J 
 he chosen any other green, the same criticism would 
 have been valid. The diagram as it stands is really a 
 diagram of colour mixtures in terms of three arbitrarily 
 chosen colours, and not of colour sensations. It merely 
 indicates what proportions were needed of the three 
 colours, which he took as standards, to match the in- 
 termediate spectrum colours. The negative sign in 
 3ome of the equations — given in the appendix, page 201 
 — may be somewhat puzzling to those who have not 
 made colour matches, but not to those who have 
 .actually made experiments. It means that where it 
 
Young s Colour Vision Theory. 49 
 
 is present no matcli of colour by a mixture of the 
 standard colours is possible; and that it would be only 
 possible if a certain quantity of the colour to which is 
 attached a negative sign were to be abstracted — an 
 impossible condition to fulfil, but one which may 
 often occur in colour-matching experiments. Later you 
 
 will find that when colours are chosen as standards so 
 that the resulting equations give no negative sign for 
 any colour, we have a criterion as to the colours which 
 give the nearest approach to the true sensations. The 
 next diagram (Fig. 16) of colour sensations is due to 
 Koenig, who investigated the subject with Von Helm- 
 holtz. By a modified method, which perhaps need not 
 be explained in detail here, he produced them, and 
 they must be apparently not far from the actual 
 
 E 
 
50 Colour Vision, 
 
 state of things, supposing this theory be proved 
 to be true. For my own part, I am under the 
 impression that the positions of the colours which 
 most . nearly approach the colour sensations might be 
 slightly altered in regard to the green and the blue, 
 for reasons that will subsequently be given when the 
 later experiments of General Testing and myself come 
 to be described. For the immediate purpose of the 
 lecture, the curves are sufficiently accurate, and I 
 will ask you to notice what they tell us. It is 
 presupposed in these diagrams that, if the three 
 colour - perceiving apparatus are equally stimulated, 
 a sensation of white will be produced ; and the 
 reverse, of course, is true, in that white will give 
 rise to equal stimulation of the three apparatus. It 
 follows, then, that in the parts of the spectrum 
 where all three curves of sensation are seen to take 
 a part in the production of a colour, such as at the 
 E line, the colour is really due to the extra stimu- 
 lation of one or two of the apparatus above that 
 required to produce a certain amount of white. The 
 colour in every part of the spectrum may he represented 
 hy not more than two sensations^ with a proportion of 
 ^- . r 'liphiM>,^^ln the orange and scarlet there are only two 
 ^^'*^<?$^'^\^^"''/'^:^^^^%S^^-^^^*^^' without any sensible amount of 
 
The Three Colour Sensations. 51 
 
 white, as the amount of violet sensation is extremely 
 small. At the extreme ends of the spectrum only one 
 sensation — the red or the violet— is excited ; but in the 
 region of the green the colour must be largely diluted 
 with the sensation of white. As an example, we may 
 take the part of the spectrum where the red and the 
 violet sensation curves cut each other. At this point 
 the green sensation curve rises higher than the inter- 
 section of the other curves. The red and the violet 
 sensations have only to be mixed with an equal amount 
 of the green sensation to make white, so that the height 
 of the green sensation curve above the point of inter- 
 section represents the amount of pure green sensation 
 which is stimulated. The colour is therefore caused by 
 the green sensation, largely diluted with white. A 
 scrutiny of the curves will show that at no point is 
 the green sensation so free from any other as at this 
 point, if we regard white by itself as a neutral colour. 
 Looking at these figures, we can readily see w^hat effect 
 the removal of any one or two of the three Sensations 
 would have upon the colour vision of the individual. 
 The probabilities, however, against two of the three 
 sensations being absent must evidently be very much 
 smaller than that there should be an absence of only 
 one of the sensations, either red, green, or violet. 
 
 E 2 
 
52 Colour Vision. 
 
 It will be well that we should also have 1;)efore us 
 the theory which is the only serious rival to that 
 of Young, viz., that of Hering. In the report of 
 the Colour Vision Committee there is an excellent 
 description of this theory. As it was furnished by 
 Dr. Michael Foster, we may be sure that the ideas 
 of its originator are correctly given, and therefore I 
 will quote it in his words : — 
 
 *' Another theory, that of Hering, starts from the 
 observation that when we examine our own sensations 
 of light we find that certain of these seem to be quite 
 distinct in nature from each other, so that each is 
 something sui generis^ whereas we easily recognise all 
 other colour sensations as various mixtures of these. 
 Thus, the sensation of red and the sensation of yellow 
 are to us quite distinct ; we do not recognise anything 
 common to the two, but orange is obviously a mixture 
 of red and yellow. Green and blue are equally distinct 
 from each other and from red and yellow, but in violet 
 and purple we recognise a mixture of red and blue. 
 White again is quite distinct from all the colours in the 
 narrower sense of that word, and black, which we must 
 accept as a sensation, as an affection of consciousness, 
 even if we regard it as the absence of sensation from the 
 field of vision, is again distinct from everything else. 
 
Herings Colour Vision Theory. 53 
 
 Hence the sensations caused by different kinds of light 
 or by the absence of light, which thus appear to us 
 quite distinct, and which we may speak of as ' native ' 
 or ' fundamental ' sensations, are white, black, red, 
 yellow, green, blue. Each of these seems to us to have 
 nothing in common with any of the others, whereas in 
 all other colours we can recognise a mixture of two or 
 more of these. This result of common experience 
 suggests the idea that these fundamental sensations 
 are the primary sensations, concerning which we are 
 enquiring. And Hering's theory attempts to reconcile, 
 in some such way as follows, the various facts of 
 colour vision Avith the supposition that we possess 
 these six fundamental sensations. The six sensations 
 readily fall into three pairs, the members of each pair 
 having analogous relations to each other. In each pair 
 the one colour is complementary to the other — white to 
 black, red to green, and yellow to blue. Now, in the 
 chemical changes undergone by living subjects, we may 
 recognise two main phases, an upward constructive 
 phase, in which matter previously not living becomes 
 living, and a downward destructive phase, in which 
 living matter breaks down into dead or less living 
 matter. Adopting this view, we may, on the one hand, 
 suppose that rays of light, differing in their wave- 
 
54 Colo2ir Vision. 
 
 length, may affect the chemical changes of the visual 
 substance in different ways, some promoting construc- 
 tive changes (changes of assimilation), others promoting 
 destructive changes (changes of dissimilation) ; and on 
 the other hand, that the different changes in the visual 
 substance may give rise to different sensations. 
 
 " We may, for instance, suppose that there exists in 
 the retina a visual substance of such a kind that when 
 rays of light of certain wave-lengths — the longer ones, 
 for instance, of the red side of the spectrum — fall upon 
 it, dissimilative changes are induced or encouraged, 
 while assimilative changes are similarly promoted by 
 the incidence of rays of other wave-lengths, the shorter 
 ones of the blue side. But it must be remembered 
 that in dealing with sensations it is difficult to 
 determine what part of the apparatus causes them ; 
 we may accordingly extend the above view to the 
 whole visual apparatus, central as well as peripheral, 
 and suppose that when rays of a certain wave-length 
 fall upon the retina, they in some way or other, in 
 some part or other of the visual apparatus, induce or 
 promote dissimilative changes, and so give rise to sen- 
 sations of a certain kind, while rays of another wave- 
 length similarly induce or promote assimilative changes, 
 and so give rise to a sensation of a different kind. 
 
The Six Ftindamental Sensations, 
 
 " The hypothesis of Hering applies this 
 six fundamental sensations spoken of above, an< 
 supposes that each of the three pairs is the outcome 
 of a particular set of dissimilative and assimilative 
 changes. It supposes the existence of what we may 
 call a red-green visual substance of such a nature that 
 so long as dissimilative and assimilative changes are in 
 equilibrium, we experience no sensation ; but when 
 dissimilative changes are increased, we experience a 
 sensation of (fundamental) red, and when assimilative 
 changes are increased, we experience a sensation of 
 (fundamental) green. 
 
 " A similar yellow-blue visual substance is supposed 
 to furnish, through dissimilative changes a yellow, 
 through assimilative changes a blue sensation ; and a 
 white-black visual substance similarly provides for a 
 dissimilative sensation of white ' and an assimilative 
 sensation of black. The two members of each pair are 
 therefore not only complementary but also antagonistic. 
 Further, these substances are supposed to be of such a 
 kind that while the white-black substance is influenced 
 in the same way, though in different degrees, by rays 
 along the whole range of the spectrum, the two other 
 substances are differently influenced by rays of different 
 wave-length. Thus, in the part of the spectrum which 
 
56 
 
 Colour Vision. 
 
 we call red, rays promote great dissimilative changes of 
 the red-green substance with comparatively slight effect 
 on the yellow-blue substance ; hence our sensation of 
 red. 
 
 "In that part of the spectrum which we call yellow, 
 the rays eftect great dissimilative changes of the yellow- 
 
 FiG. 17. 
 
 B G Y O R 
 
 blue substance ; but their action on the red-green 
 substance does not lead to an excess of either dis- 
 similation or assimilation, this substance being neutral 
 to them ; hence our sensation of yellow. The green 
 rays, again, promote assimilation of the red- green 
 substance, leaving the assimilation of the yellow-blue 
 substance equal to its dissimilation ; and similarly blue 
 rays cause assimilation of the yellow-blue substance, 
 and leave the red-green substance neutral. , Finally, at 
 
Results of Disswiilation and Assimilation. 57 
 
 the extreme blue end of the spectrum, the rays once 
 more provoke dissimilation of the red-green substance, 
 and by adding red to blue give violet. When orange 
 rays fall on the retina, there is an excess of dissimilation 
 of both the red-green and the yellow-ljlue substance ; 
 when greenish-blue rays are perceived, there is an 
 excess of assimilation of both these substances ; and 
 other intermediate hues correspond to various degrees 
 of dissimilation or assimilation of the several visual 
 substances. When all the rays together fall upon the 
 retina, the red- green and yellow-blue substances remain 
 in equilibrium, but the white-black substance undergoes 
 great changes of dissimilation, and we say the light is 
 white." 
 
 It has been said by the same writer that this theory 
 is tri-chromic. For my own part I do not see that 
 it is so in the sense in which that word is used in 
 the theory of Young. It may be a tetra-chromic, for 
 as far as colour is concerned the black-white sensation 
 must be excluded ; but it appears to me that it cannot 
 be strictly brought under the head of tri-chromic. 
 
( 58 ) 
 
 CHAPTER V. 
 
 The readiest means of investigating tlie stimulation 
 of the different sensations necessary to produce colour 
 is evidently by eyes in which one or two sensations 
 are absent, and this applies not only to the Young 
 theory, but also to that of Hering. 
 
 In former days, not much more than a century ago, 
 the existence of colour blindness, as it is now named^ 
 was a matter of great curiosity, and in the Philo- 
 sophical Transactions of the Poyal Society of 1777,. 
 the case of a shoemaker named Harris is described 
 by a Mr. Huddart, who travelled all the way from 
 London to the Midlands on purpose to see if all the 
 alleged facts regarding the patient were true. Harris 
 mistook orange for green, brown he called black, and 
 he was unable to distinguish between red fruits and 
 the surrounding green leaves. At first, colour blind- 
 ness was called Daltonism, from the fact that the 
 great chemist Dalton suffered from it, and investi- 
 
Daltonism. 59 
 
 gated the variation which he found existed in his 
 vision from that of the majority of his fellow-creatures. 
 It was in 1794 that Dal ton described his own case of 
 colour blindness. He was quite unaware of his defect 
 till 1792, when he was convinced of its existence 
 from his observations of a pink geranium by candle- 
 light. " The flower," he says, " was pink ; but it 
 appeared to me almost an exact sky-blue by day. In 
 candle-light, however, it was astonishingly changed, 
 not having any blue in it ; but being what I call a 
 red colour which forms a striking contrast to blue." 
 He goes on to remark that all his friends except his 
 hrother (mark this relationship), said : there was not 
 any striking difference in the two colours by the two 
 lights. He then investigated his case by the solar 
 spectrum, and became convinced that instead of having 
 the normal sensations, he only had two or at most 
 three. These were yellow, blue, and perhaps purple. 
 In yellow, he included the red, orange, yellow, and 
 green of others, and his blue and purple coincided 
 with theirs. He says, that " part of the image which 
 others call red, appears to me little more than a shade 
 or defect of light ; after that, the orange, yellow and 
 green seem one colour, which descends pretty uniformly 
 from an intense and a rare yellow, making what I 
 
6o Colour Vision. 
 
 should call different shades of yellow. The difference 
 between the green part and the blue part is very 
 striking to my eye, they seem to be strongly con- 
 trasted. That between the blue and purple much less 
 so. The purple appears to be blue much darkened 
 and condensed." 
 
 Dalton said a florid complexion looked blackish-blue 
 on a white ground. Blood looked like bottle green, 
 grass appeared very little different from red. A laurel 
 leaf w^as a good match to a stick of sealing-wax. 
 Colours appeared to him much the same by moonlight 
 as they did by candle-light. By the electric light 
 and lightning, they appeared as in day light. Some 
 browns he called red, and others black. 
 
 Mr. Babbage, in Scientific London (1874), gives an 
 account of Dalton's presentation at Court. 
 
 Firstly, he w^as a Quaker, and would not wear a 
 aword, which is an indispensable appendage to 
 ordinary Court-dress. Secondly, the robe of a Doctor 
 of Civil Laws was known to be objectionable on ac- 
 count of its colour — scarlet, being one forbidden by 
 the Quakers. Luckily, it was recollected that Dalton 
 was affected with that peculiar colour blindness which 
 bore his name, and that as cherries and the leaves of a 
 cherry-tree were to him of the same colour, the scarlet 
 
Statistics of Colour Blindness. .61 
 
 gown would present no extraordinary appearance. So 
 perfect evidence was the colour blindness, tliat the 
 most modest and simple of men, after having received 
 the Doctor's gown at Oxford, actually wore it for 
 several days in happy unconsciousness of the effect 
 he produced in the street. The rest of the description 
 we need not reproduce. Both the above cases we shall 
 see shortly come under the category of red-blindness 
 in the Young theory. Eecent investigations tell us 
 that such colour blindness is by no means rare, nor can 
 it have been then. Statistics, derived from carefully 
 carried out examinations made in A^arious parts of the 
 w^orld by an approved method of testing, show that 
 about four out of every hundred males suffer from 
 some deficiency in colour perception, but that so far 
 as the more limited statistics regarding them are to 
 be depended upon, only about four out of every 1000 
 women suffer in the same manner. 
 
 Colour blindness in a healthy subject is usually 
 hereditary, and is always congenital. It is curious 
 to trace back in some instances the colour blindness, 
 where it is to be found, in a family. It often happens 
 that colour blindness — as the gout is said to do — 
 skips a generation. This is usually traced to the 
 fact that the generation skipped is through the 
 
62 Colour Vision. 
 
 motlier. Thus, the maternal grandfather may be 
 colour blind, as may be the grandsons, but the mother 
 will very frequently have perfectly normal vision for 
 colour. On the other hand, the paternal grandfather 
 may have defective colour perception, and this may 
 be inherited both by the grandsons and the father. 
 The remark made by Dalton regarding his brother's 
 eyesight points to the fact that his own colour blind- 
 ness was probably hereditary. Deaf mutes, Jews and 
 Quakers, seem to be more liable to colour blindness 
 than other people, statistics giving them 13*7, 4*9, 
 and 5 * 9 as the percentages. It may be well to point 
 out that the deficiency in colour perception to which 
 we are alluding is totally distinct from that which may 
 arise from disease. This last form has such marked 
 characteristics of its own that it can at once be dis- 
 tingfuished from the cone^enital form. 
 
 Of the four per cent, of males who suifer from 
 congenital colour deficiency of vision, a large number 
 are not totally lacking in any one or more colour 
 sensations. Those in which one sensation, on the 
 Young theory, is entirely missing are called " com- 
 pletely red-, green-, or violet-blind," whilst those in 
 which the sensation is but partially deadened are 
 called "partially red-, green-, or violet-blind." When 
 
Types of Colour Blindness. 63 
 
 two sensations are entirely absent, and such cases 
 are very rare indeed, they are generally said to have 
 monochromatic vision ; that is, every colour to them 
 is the same, as is also white, the only distinction 
 between any of them being the superior brightness of 
 some over others. The best illustration of this form 
 of colour vision is perhaps to say that the retina of 
 such people have the same characteristics in regard 
 to sensitiveness as has a photographic plate, the 
 resulting prints in black and white representing what 
 it sees in nature. When we have to adopt the 
 terms used by the followers of Hering's theory — 
 the theory which obtains most followers amongst 
 the physiologists, since it endeavours to explain 
 colour vision in a physiological way, though it fails 
 to meet all the requirements of the physicist — we 
 should restrict our terms to red- green and yellow- 
 blue blindness, still perhaps retaining the term mono- 
 chromatic vision for the rare cases specified above. 
 As we must employ some terms to express our mean- 
 ing, we shall in these lectures adopt those of the 
 Young theory. 
 
 Now taking a red-blind person and examining him 
 with the spectrum, we find that he sees no light at 
 all at the extreme limit of our red, and only when 
 
64 Colour Vision. 
 
 lie comes to the part wliere the red lithium line marks 
 a certain red does a glimmer commence ; he then sees 
 what he may call dark-green, or he may call dark- 
 yellow. When questioned about what to us are greens 
 he also calls them green or yellow, some being bright, 
 others saturated hues, and others again paler. When 
 he gets to the bluish-green he calls it grey, and will 
 say it is indistinguishable from, and in fact will match 
 with, a white degraded in tone. From this point he 
 will say he sees blue, near F pale-blue, and in the violet 
 dark-1)lue. Too much importance must not be attached 
 to the nomenclature adopted by the colour blind. They 
 have to take the names of the colours from the normal 
 eyed. Yellow objects are generally brighter than red, 
 and having annexed the idea that what to them is 
 bright red is called yellow, they give it that dis- 
 tinguishing name. His limit of vision at the violet 
 end will be the same as the majority of mankind, 
 but it will be considerably shortened at the red end. 
 The point in the spectrum which he calls grey is an 
 important point, and corresponds to the place where 
 the violet and green curves cut in Fig. 16. This 
 point can be very accurately determined by placing 
 alongside the colour patch A (Fig. 6) the white 
 patch, which is reduced in brightness as required by 
 
spectrum Examination of the Colour Blind. 65 
 
 rotating sectors. As the slit is moved along the 
 spectrum it will eventually reach a point where he will 
 say both patches of light are exactly similar in hue. 
 To the normal eye one will be white, and the other 
 the kind of green indicated above (see frontispiece). 
 
 If a similar examination be made of the green- 
 blind, the red end of the spectrum will be called 
 red or yellow, but the spectrum itself will be visible 
 between the same limits as it is to the person who has 
 the normal sense of vision. A grey stripe will be seen 
 in the spectrum, but in this case it will be a trifle 
 nearer the red end of the spectrum than the point 
 which the red-blind calls grey ; from this point to 
 the extreme violet, the green-blind will name the 
 spectrum colours similarly to the red-blind. The 
 part of the spectrum where grey exists to the green- 
 blind is even more important than that part at 
 which it exists to red-blind, for it marks the place 
 where the red and violet curves cut each other in 
 Fig. 16, and is in the majority of cases the place 
 in the spectrum where to the normal eye the green 
 sensation is unmixed with any sensation except that 
 of white, as quite recently explained. This green 
 evidently is the colour which is most usefully employed 
 in making colour mixtures in order to obtain the three 
 
66 Colour Vision. 
 
 sensation curves of the Young theory, since white can 
 be added to the colour matched. To avoid verbiage, 
 we shall call the points where the red- or green- 
 blind see a grey in the spectrum their neutral 
 points, and the grey they see at those points their 
 neutral colours. The three curves we shall call the 
 red, green, or violet curves, and the slits, when 
 placed in the red, green, or violet of the spectrum, 
 as the red, green, and violet slits. 
 
 We have already mentioned the case of those who 
 possess monochromatic vision, and shown in what 
 respect they will differ in their description of the 
 spectrum from those more common cases of defective 
 vision. If the visual sensation they possess be the 
 violet, they will see no light at the extreme red of 
 the spectrum, and very little in the orange. They 
 must match every colour with some shade of grey, 
 for they will only perceive that sensation, in what to 
 ordinary normal eyes is white. We need not detail 
 how those who possess monochromatic vision due to 
 some other sensation would describe the different 
 colours. The diagram will tell us. Suffice it to 
 say, that one colour will only differ from another 
 and from white in brightness. 
 
 It is a very remarkable fact how many people who 
 
I 
 
 Examples of Colour Blindness, 67 
 
 are defective in colour vision pass through a good 
 part of their lives without being definitely aware of it. 
 It is very doubtful whether, in the majority of cases, 
 they themselves discover it. They may quite possibly 
 attribute the descriptions of colour which they hear, 
 and which appear to them absolutely false or meaning- 
 less, as due to mental or moral defects in their friends. 
 I have had two cases of this recently. One was a 
 gentleman of seventy-four, who had no conception 
 that he had anything but normal colour vision ; 
 his daughters, however, had a suspicion that some- 
 thing was not quite right in it, and after a good 
 deal of persuasion brought him to me to examine. 
 The first mistake that he made was to state that 
 he was sitting on a black velvet chair, whereas 
 the seat was a deep crimson plush. He laughed 
 at his daughter's description of the mistake he 
 made, and declared he was only colour ignorant, and 
 that she was the one who was colour blind. The 
 examination showed that colour ignorant he was, but 
 that the ignorance was due to complete red-blindness. 
 For the seventy-four years he had lived he was un- 
 aware of his deficiency, suspecting it in others, and 
 it was only an accidental circumstance which made him 
 acquainted with the true state of his colour percep- 
 
 F 2 
 
68 Colour Vision, 
 
 tion. Another elderly gentleman, in a high position 
 in life, was also accidentally tested, and he proved 
 to be completely green-blind. He, too, was quite 
 unaware of his defect, and protested that, yachtsman 
 as he was, he would never mistake a ship's lights ; 
 but a very brief test showed his friends who were 
 with him that his declaration had to be received 
 with a certain amount of reservation. Others there 
 are who certainly do know that some peculiarity 
 exists in their sense of colour, and, foolish as it may 
 appear to be — though, after all, it is quite consistent 
 with a sensitive nature — they have tried to hide their 
 defect from their fellow-creatures. Such examples, no 
 doubt, some of my audience have met with, and 
 experience tells me that they have just as much 
 reluctance to pass an hour in my darkened room as 
 they would have to occupy a police cell. In those 
 few cases that have come voluntarily to me for 
 examination, the peculiarity in colour sense was first 
 brought to notice by the patient — if patient I may 
 call him — failing to distinguish between cherries and 
 the cherry leaves, or strawberries and the strawberry 
 leaves. Such mistakes committed publicly are usually 
 the source of unbounded merriment and curiosity to 
 schoolboys when made by their schoolfellows, and I 
 
Maxwell's Curves for Red Blindness, 69 
 
 am bound to say that even persons of graver years are 
 not unapt to be amused at what they consider to be 
 a shortcoming in their fellow-creatures. To the student 
 of colour vision the discovery of curious cases of colour 
 deficiency is looked upon in a very different light 
 — a good case of colour blindness, or still better one of 
 monochromatic vision, is eagerly sought after, with the 
 hope of submitting it to a rigid examination. When 
 
 Fig. 18. 
 
 we look at the diagram (Fig. 16) we shall find why it 
 is that the colour blind describe the spectrum as they 
 do. Literally for those whose vision is di-chromic, it is 
 made up of two sensations alone, and the colours to 
 which these sensations give rise are mixed throughout 
 a large part of the spectrum, the pure unmixed sensa- 
 tions being at each end of the spectrum as they are in 
 normal colour vision. The annexed diagram (Fig. 18) 
 gives the curves for a red-blind person as made by 
 observations under Clerk Maxwell's directions. The 
 
70 Colour Vision, 
 
 standard colours here have been badly selected, for one 
 of them stimulates the two sensations possessed. 
 
 An easy and instructive experiment can be made to 
 give an idea of the kind of colour that these colour 
 blind imagine as white, whether they be red-, green-, 
 or violet-blind. (For those who have only mono- 
 chromatic vision, as before stated, white is coloured 
 with the one colour they possess.) Three slits are now 
 in the spectrum, one near the extreme end of the red, 
 another well in the violet, and the third in that part of 
 the spectrum in which the green-blind see their neutral 
 colour (see page] 66). With the three colours issuing 
 from these apertures a match is made with the white 
 patch, and in this case the match is made as seen 
 from a distant point, so that the resulting deductions 
 may be true to the audience. If a colour-blind 
 person be in this theatre, he will agree with me 
 that the match is as correct to him as it is to 
 myself and the rest of you. So far we could not 
 distinguish his colour perception from the normal, 
 but if he be red-blind, and the red slit be covered, he 
 will still say that the match holds good, for, as a 
 matter of fact, the red with which we helped to 
 build up the white is non-existent to him. The 
 white that he now sees is to us the greenish-blue 
 
The Neutral Colours of the Colour Blind. 7 1 
 
 patch which the mixed violet and green make. 
 If he be a green-blind person he will tell us the 
 colour is a very pale blue, but when the green slit 
 is covered up and the red uncovered, the match will 
 once more be correct, though the purple, formed by 
 the mixture of red and blue, will appear to him to 
 be a little darker than the white. This is what one 
 would expect, for you must recollect this green in 
 the spectrum he would call white or grey. If then, 
 from what to him is also white, though formed by 
 the rays coming through the three slits, we take 
 away a certain amount of degraded white (green to 
 us), he must still see white, but darker. We have, 
 however, met with what is an apparent paradox. 
 The green, coming through the now covered slit, he 
 calls white, as he also does the purple. To impress 
 this point more strongly upon you, I will place in 
 front of the green slit a small prism which has an 
 angle of about one and a-half degrees. This is 
 just sufficient to throw the green colour on the 
 neighbouring white surface. Here we have both the 
 .colours which the green-blind calls white side by 
 side. If the brightness of each be the same, he 
 would see no difference in them. Is it possible that 
 on any theory this can be correct ? To explain 
 
 I 
 
72 Colour Vision. 
 
 this apparent paradox, and without reference to the 
 mathematical proof that white subtracted from white 
 leaves white, we have only to look at our diagram 
 (Fig. 16), and it is immediately apparent how it 
 arises. The red and the blue curves cut at this 
 point ; and if we take away the green sensation 
 entirely, the residue will be a mixture of the red and 
 blue, which is the identical purple colour forming 
 the patch. 
 
 If we are wishful to ascertain the colour that the 
 violet-blind calls white, we have only to cover up the 
 violet slit and a yellow is left behind as the result. 
 I would have you remark that these colours which 
 are seen as white would only be of the hues shown 
 you, supposing the colour sensations were identical 
 with those in normal vision. Whether this is the 
 case we cannot absolutely say, and the only way in 
 which this can be authoritatively settled is by 
 examining some person who has normal colour vision 
 in one eye and defective colour sense, not due to 
 disease, in the other. One such person has been exa- 
 mined abroad, but in what way I am unable to say. 
 It is recorded that he sees the red end of the spectrum 
 as yellow with the eye that is defective. Another 
 person I have heard of in England, but so far have not 
 
Violet Blindness. 73 
 
 had the good fortune to get hold of him for examina- 
 tion. When I can lay my hands on him, he will be 
 able to help to confirm or disprove what should be a 
 general rather than a particular case. 
 
 So far I have only met with what appears to be 
 one genuine case of violet blindness. It is very 
 remarkable, on account of the eccentricity of the 
 colour nomenclature. The only two colours which the 
 subject saw were red and hlack. He named all greens 
 and blues as black, the distinction between the two 
 being that the former was " bright black " and the 
 latter " dark black." Yellow he called white, and 
 a glance at Fig. 16 will show that at this place in 
 the spectrum the neutral point of a violet-blind 
 should occur. By shifting the slit gradually into 
 the green, he called it grey, instead of " bright black," 
 though it did not match the white patch when 
 darkened. He called a green light a " bright black " 
 light. We shall have to refer to this case when we 
 are describing other investigations. 
 
( 74) 
 
 CHAPTEE VL 
 
 Another mode of exhibiting colour blindness, and 
 one of the first adopted, is by making mixtures of 
 colours with rapidly rotating colour discs. In my 
 own experiments I have chosen a red, which is 
 scarlet, over which a wash of carmine has been 
 brushed. It has a dominant wave-length of 6300. 
 The green is an emerald-green, and has a dominant 
 wave-length of 5150. The blue is French ultra- 
 marine, with a dominant wave-length of 4700. The 
 card discs, of some 4 inches diameter, are coated 
 with these colours as pastes, and by making an 
 incision in them radially to the centre, as before 
 described, and inter-locking them, the compound 
 disc can be caused to show sectors of any angle 
 that may be required. Outside these are the discs 
 of black and white, the proportions of which can 
 be altered at will. 
 
 The light thrown on the rotating sectors being 
 
Matches with Discs. 75 
 
 that from an electric arc liglit, normal vision 
 requires 118° of red, 146° of green, and 96° of blue to 
 match a grey made up of 75 parts of white and 
 285 parts of black. For the last two numbers a cor- 
 rection has been made to allow for the small amount 
 of white light reflected from the black surface. This 
 correction has also been made in the subsequent 
 matches which will be described. Colour mixtures 
 such as these are conveniently put in the form of equa- 
 tions, and that given will then be shown as follows — 
 
 118 K 4- 146 G -f- 96 U = 75 W -f 285 B. 
 (Here R, G, U, W, and B are used to indicate Red, 
 Green, Blue, White, and Black.) 
 
 This match was exact also for all the colour blind, 
 for the deficiency in one grey is also a deficiency in 
 the other. With a red-blind, however, very different 
 matches can be made, as the red pigment is a 
 complex colour. There is in it, besides red, a certain 
 amount of yellow, whilst in the green there is, 
 besides green, a small amount of a red and a 
 larger amount of yellow. The yellow will not 
 only stimulate the green sensation, but also the red 
 where it is present. Although in complete red-blind- 
 ness the red sensation is totally absent, we may expect 
 that a mixture of red and blue, as well as of green and 
 
"j^ Colour Vision. 
 
 blue, will enable a match to be made of the grey 
 produced by the mixture of white and black. 
 
 This was the case. We have the following propor- 
 tions— 295 E + 65 U = 45 W 4- 315 B. 
 
 "When the green disc is substituted for the red, the red- 
 blind made the following mixture — 
 
 229 G -I- 131 U = 120 W -h 240 B. 
 It is worth noticing that the amount of blue in the 
 first mixture is about half that required for the 
 second. This tells us that the amount of green sen- 
 sation stimulated in the first case is much less than 
 in the second. As red can be substituted for green, 
 it should follow that green, when rendered darker, 
 should match the red. To try this a red disc re- 
 placed the black disc, and a black disc replaced the 
 blue. The following match was then made — 
 
 131 G + 229 B = 340 E + 20 W. 
 It seems impossible to believe that these mixtures, 
 so dissimilar in colour, could ever form a satisfactory 
 match. This last ecpation might have been derived 
 from the two first, in which case it would have stood — 
 
 137 G -f 223 B = 342 E -f 18 AV. 
 By a completely green-blind the following mixtures 
 were made — 
 
Matches with Discs, "jj 
 
 251 K + 109 U = 62 W + 298 B, . 
 
 and 
 277 G + 83 U = 107 W + 253 B. 
 
 In this case 363 Green are equivalent to 251 parts of 
 Red mixed with 78 of White and 34 Black. The 
 difference in the matches made by the two types 
 of colour blindness is very evident. In the one 
 case the amount of red required is much greater 
 than the green, and in the other vice versd. Another 
 instance may be given of colour matches made, by 
 means of discs, by a partially green-blind person, 
 whose case will be more fully described when we 
 treat of the luminosity of the spectrum to the different 
 classes of colour vision. 
 
 His matches were as follows — 1st, That of the 
 normal vision. 2nd, — 
 
 160 E + 80 G + 120 U = 72 W 4- 288 B. 
 The green was then altered to 200, when the following 
 made a match — 
 
 65 E + 200 G + 95 U = 72 W + 288 B. 
 Using these two equations, we have the following 
 curious result — that 120 G was matched by 95 E + 
 25 U. As the green disc is nearly twice as luminous 
 as the red to normal colour vision, this equation 
 confirms the result otherwise obtained, that his 
 
78 Colour Vision. 
 
 blindness to colour is a deficiency in the green sensa- 
 tion. No mixtures of blue and red, or blue and green, 
 would match a grey formed by the rotation of the black 
 and white sectors. 
 
 I must now introduce to your notice a different 
 method of experimenting with colour vision. If we 
 throw the whole spectrum on the screen, and ask a 
 person with normal vision to point out the brightest 
 part, he will indicate the yellow, whilst a red-blind 
 will say the green, and so on. This tells us that the 
 various types of colour blind must see their spectrum 
 colours with luminosity diiffering from that of the 
 normal eye. The dijBference can be measured by caus- 
 ing both to express their sense of the brightness of the 
 different parts of the spectrum in terms of white light, 
 or of one another. Brightness and luminosity are here 
 used synonymously. On the two small screens are a red 
 and a green patch of monochromatic light — a look at 
 the green shows that it is much brighter than the red. 
 Eotating sectors, the apertures of which can be opened 
 or closed at pleasure during rotation, are now placed in 
 the path of the green ray. The apertures are made 
 fairly small, and the green is now evidently dimmer 
 than the red. When they are well open the green is 
 once more brighter. Evidently at some time during 
 
Luminosity of the Spectrum. 79 
 
 the closing of tlie apertures there is one position in 
 which the red and green must be of the same bright- 
 ness, since the green passes through the stage of being 
 too light to that of being too dark. By gradually 
 diminishing the range of the '' too open " to " too 
 close " apertures we arrive at the aperture where the 
 two colours appear equally bright. The two patches 
 will cease to wink at the operator, if we may use 
 such an unscientific expression, when equality in 
 brightness is established. This operation of equalising 
 luminosities must be carried out quickly and with- 
 out concentrated thought, for if an observer stops to 
 think, a fancied equality of brightness may exist, which 
 other properly carried out observations will show to be 
 inexact. Now, instead of using two colours, we can 
 throw on a white surface a w^hite patch from the 
 reflected beam, and a patch of the colour coming 
 through the slit alongside and touching it. The white 
 is evidently the brighter, and so the sectors are placed 
 in this beam. The luminosity of (say) a red ray is first 
 measured, and the white is found to require a certain 
 sector aperture to secure a balance in brightness. We 
 then place another spectrum colour in the place of the 
 first, and measure off in degrees the brightness of this 
 colour in terms of white light, and we proceed similarly 
 
 I 
 
8o Colour Vision, 
 
 for the others. Now how are we to prove that the 
 measures for luminosity of the different colours are 
 correct ? Let us place three slits in the spectrum, and 
 by altering the aperture of the slits make a mixture of 
 the three rays so as to form white. The intensity of 
 this white we can match with the white of the reflected 
 beam. We can then measure the brightness (lumi- 
 nosity) of the three colours separately, and if our 
 measures are correct there is 'prima facie reason to 
 suppose that they will together make up the brightness 
 of the white. Without going through this experiment it 
 may at once be stated that the reasoning is correct, for 
 within the limits of error of observation they do so. 
 Having established this proposition, we can next com- 
 pare inter se, the brightness of any or all of the rays 
 of the spectrum by a preliminary comparison with the 
 reflected beam of white light. As in the colour patch 
 apparatus all colours and principal dark lines of the 
 solar spectrum are known by reference to a scale, 
 in making a graphic representation of the results, 
 we first of all plot on paper a scale of equal parts, 
 and at the scale number where a reading is made, 
 the aperture of the sectors in degrees is set up. Thus, 
 suppose with red light the scale number which marked 
 the position of the slit was 59, and the aperture 10°, 
 
Luminosity Curves. 8i 
 
 we should set up at that scale number on the paper 
 a height of 10 on any empyric scale. If in the green 
 at scale No. 38 the sectors had to be closed to 7°, 
 we should set up 7 at that number on the scale. 
 
 When observations have been made at numerous 
 places in the spectrum, the tops of these ordinates, as 
 they are called, should be joined, and we then get the 
 observed curve of luminosity for the whole spectrum. 
 For convenience' sake we make the highest point 100, 
 and reduce the other ordinates in proportion. For 
 some purposes it may be advantageous to give the 
 luminosity curve in terms of a scale of wave- 
 lengths. For our purpose, however, it is in general 
 sufficient to use the scale of the instrument. 
 
 Now, if we test the vision of the various types of 
 colour blind by this plan, we should expect to get 
 luminosities at different parts of the spectrum which 
 would give very different forms to these curves. We 
 cannot hope, for instance, that a red-blind who sees no 
 red in the extreme end of the spectrum would show any 
 luminosity in that region, nor that the green-blind 
 should show as much in the green part of the spectrum 
 as those who possess normal colour vision, since one of 
 the sensations is absent. With monochromatic vision 
 there should be a still further departure from the 
 
82 
 
 Colour Vision. 
 
 normal curve. That these differences do exist is fully 
 shown in Fig. 19. One of the most striking experi- 
 
 FiG. 19. 
 
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 ments in colour vision is to place a bright red patch on 
 the screen, and to ask a red-blind to make a match in 
 
I 
 
 Partial Colour Blindness. 83 
 
 luminosity with the white. The latter will have to be 
 reduced to almost darkness — a darkness, indeed, that 
 makes the match almost seem incredible. You will 
 notice that the places in the spectrum where the 
 red- and green-blind see grey are by no means places 
 of greatest luminosity. We shall find that these 
 luminosity curves are suggestive when making another 
 investigation into the form of the spectrum curves 
 of the colour sensations. 
 
 Besides cases of complete blindness due to the 
 absence of one or two sensations on the Young theory, 
 we have other cases, as was said when remarking on the 
 percentage of people who are colour deficient, in which 
 one or even two sensations are only more or less 
 deadened. It has often been said that with the theory 
 provisionally adopted, such cases are difficult to class as 
 red or green deficient. As far as my own observations 
 go, I have never found this difficulty. The luminosity 
 curves of such observers, combined with other indica- 
 tions, give a ready means of classing them. The main 
 difficulty to my mind is to state what is normal 
 colour vision, but, as I have found that the very large 
 majority of eyes give the same luminosity to colours as 
 my own, I have taken my own colour perception as 
 normal. In numerous experiments which Lord 
 
 G 2 
 
84 Colour Vision, 
 
 Kayleigh has made in matching orange by means of 
 a mixture of red and green, he has come across several 
 who have apparently normal vision, as they see colours 
 correctly in every part of the spectrum, and yet some 
 require much less red mixed with the green to make a 
 match with the orange than do others. What is yellow 
 to them is decidedly green to the majority. This has 
 been classed as another kind of normal vision ; but the 
 luminosity curves show that it may be equally well 
 due to a deficiency in the green sensation, and 
 which would require more green to make the 
 necessary match. The limits of the visible spectrum 
 to these persons, as far as my examination of their 
 cases goes, are the same as my own. 
 
 Again, there are others in which the spectrum 
 seems decidedly somewhat shortened at the red end 
 compared with my own, and the luminosity curves 
 point to them as being strictly colour deficient in the 
 red and nothing else. As they see all colours, they 
 have been classed as another form of normal 
 vision. The deficiency in both these cases is so 
 small that white is their neutral colour, but there 
 is evidence that the hues are slightly changed. I 
 do not wish any one to accept my deductions as being 
 more correct than those who hold differently, but the 
 
Partial Colour Blindness. 85 
 
 results of examination by the luminosity methods 
 appear to me difficult to reconcile with any other view. 
 There are, however, a large number of cases in which, 
 though complete red- or green-blindness is wanting, 
 there is no doubt that more than slight colour 
 deficiency exists. For instance, in Fig. 23 we have 
 the curve of luminosity of the spectrum as measured 
 by a very acute scientific observer, and it is compared 
 with that of normal colour vision. He certainly is 
 not completely blind to any sensation. An inspec- 
 ti(m and comparison of the two curves will show 
 that he is defective in the green sensation, although it 
 is present to a large extent. The deficiency is obvious 
 enough. An endeavour to ' find his neutral point was 
 most interesting. At 39 in the scale he saw a little 
 colour, but at 39*5 all colour had vanished, and 
 between the coloured patch and the white he saw no 
 difference. This similarity he saw till 47 * 3 in the 
 scale, w^hen he began to see a faint trace of colour. 
 There is a large piece of the spectrum, then, which 
 to him is grey. It must be recollected that all three 
 sensations were excited in this region, but some more 
 than others. Now, experiment has shown that, with 
 normal vision, two per cent, of any colour may be 
 
 mixed with a pure colour without its being perceived. 
 
86 Colour Vision. 
 
 It is not surprising, therefore, that although the red, 
 or the green, or the blue may be present in an in- 
 
 FiG. 23. 
 
 tensity above that required to form white, yet the 
 resulting sensation should pass for white. It may be 
 
Partial Colour Blindness, 87 
 
 remarked that red and white when mixed he never 
 mistook for yellow, and he always recognised yellows 
 and red ; yellowish green, however, he called pale 
 yellow. 
 
 Another example of partial red-blindness is also 
 instructive. Fig. 23 also shows it graphically. There 
 is no doubt as to the nature of the defect. The 
 spectrum is slightly shortened, and the luminosity 
 of this part of the spectrum is less than that of 
 normal vision. There was no difficulty in distin- 
 guishing every colour, though the positions of the 
 colours from yellow to green seemed to be shifted ; but 
 no neutral point could be traced. Apparently, both 
 this case and the former are about equally colour 
 defective ; but in this last the same reasons do not 
 apply for the existence of a neutral point. (For 
 measures see page 214.) 
 
 I 
 
( 88 ) 
 
 CHAPTER VIL 
 
 We are now in a position to carry the investigations 
 as to luminosity a little further. When we look at 
 small patches of light, we view the colour through the 
 yellow spot in the eye. If, when we have matched 
 the luminosity in the ordinary manner, we turn our 
 eyes some 10° away from the patches, we shall find 
 that except at one place in the green the equality in 
 brightness no longer exists. By a little practice we can 
 make matches of luminosity when the eyes are thus 
 diverted. This will give us a different curve of 
 luminosity, as the yellow spot absorption is absent, 
 and the difference in the heights of the ordinates 
 between the two curves will give us that absorption. 
 Fig. 20 shows this very well ; and it will be noticed 
 that the eye is appreciably not so sensitive to the red 
 and yellow at 10° from the axis as it is on its central 
 area. If we measure the areas of these two curves w^e 
 get the relative values of the light energy which is 
 
Sensitiveness of the Fovea to Colour. 
 
 89 
 
 active on the two parts of the eye, and these we found 
 to ])e as 167 to 156. The heights at which to put the 
 
 Fig 20. 
 
90 Colour Vision. 
 
 maxima of the two curves were found from various 
 considerations, and the correctness of the deductions 
 was verified by directly comparing the intensities of two 
 patches of white light some 10° apart, which, when 
 looked at direct, were of equal intensities. When one 
 was compared with the other, the eye receiving one 
 image centrally and the other outside the yellow 
 spot, the difference in values was closely proportional 
 to those of the above areas. The part of this last 
 curve showing a deficiency in red sensation is very 
 similar to that obtained from a person who is partially 
 colour blind. The absorption by the yellow spot 
 derived from these measures is graphically shown in 
 the next figure (Fig. 21). 
 
 The question of the visual sensation at the '' fovea 
 centralis " (if it be admitted that this is coincident with 
 the visual axis of the eye, as is usually accepted) may 
 be very easily studied. When the luminosity of the 
 spectrum is examined at five or six feet distance, by 
 throwing the two patches on the whitened face of a 
 small square of half-inch side, we get a result differing 
 from both of the above. The fovea appears to be 
 slightly more sensitive to red than the macula lutea, 
 and is generally less sensitive to the green rays (see 
 Fig. 20). If a star, or a distant light, be observed with 
 
Absorption by the Yellow Spot. 91 
 
 the part of the retina, on which the axis of the eye falls, 
 as is the case in ordinary vision, and then be observed 
 
 Fig. 21. 
 
92 Colour Vision. 
 
 with the eye slightly directed away, the difference 
 in the colours of the light is unmistakable. (The 
 tables giving the measured value of these curves 
 will be found in the appendix, page 211.) 
 
 Can we in any way find from these methods the 
 colour sensation curves ? I think wt can. Suppose we 
 have a second instrument exactly like the first placed 
 side by side with it, we can then throw two patches of 
 colour on the two adjacent white surfaces, and we can 
 mix with either, or both of them, as much white light 
 as w^e choose. From the second instrument let us 
 throw all the spectrum colours in succession on to 
 the one surface, and on to the other the three 
 primary colours mixed in such proportions as to match 
 them accurately. This plan is, I venture to think, 
 a better way of obtaining the value of colours in 
 terms of standard colours than that adopted by 
 Maxwell. This method gives the values directly, 
 and not by calculation from matches with white. 
 Let us place one slit near each of the extreme ends of 
 the spectrum ; that in the red near the red lithium 
 line, and another a little beyond Gr in the violet 
 of the spectrum, whilst the third slit should be in 
 the exact position in the green, where the green- 
 hlind sees grey. Now it might be a matter of dispute 
 
The Green Sensation. 93 
 
 as to whether one was entitled to make this last one 
 of the positions for the slits, for we use it entirely 
 on the assumption that two of the colour sensations 
 which we suppose we possess are identical with those of 
 the green-blind. This might be, or might not be, the 
 case ; but I think it can be shown very easily that the 
 assumption we are making is more than probably exact. 
 Having the slits in these positions, we may endeavour 
 to match the spectrum orange. We mix the red and the 
 green lights together, and find that the best mixture 
 is always paler than the orange, but by adding a small 
 quantity of white to the orange we at once form a 
 match. In the same way if we have a greenish -blue 
 to match, we shall find that we can only make the 
 match when we add a little white to the simple 
 colour. Now let us shift the position of the slit in 
 the green just a little — a very little — towards the 
 blue, and again try to match orange. Do what we 
 will we cannot find apertures to the slits which will 
 give us the colour, though it be diluted with white. 
 It will be too blue or too red, but never exactly orange. 
 This tells us that there is too much blue in the green 
 we are using. Next, shift the slit a little towards the 
 red below our fixed position, and endeavour to match 
 the blue. We shall find that this, too, becomes imprac- 
 
94 Colour Vision, 
 
 ticable. The blue is either too green or too violet, 
 telling us that our mixture contains too much green. 
 As the neutral point of the colour blind is the only 
 position for the green slit which enables us to make 
 a good match to both the orange and the blue, it 
 follows that this must be the point where these two 
 colour sensations are so arranged as to be in the pro- 
 portions required to form white when green is added ; 
 that is, that there is neither an excess of red nor an 
 excess of violet. To come back to our measures of 
 colour. We can make up every spectrum colour with 
 these three colours, and finally divide the luminosity 
 curve into the colour luminosity. In all these matches 
 the violet luminosity is very small indeed compared 
 with the red or green. A match with white is now 
 made by a mixture of all these colours, and you will 
 see, from the images of the slits on the screen, that the 
 luminosity of the violet is almost a negligible quantity 
 compared with the others. We may, therefore, as a 
 first approximation, divide up the luminosity curve into 
 two parts, one being the luminosity of the green in the 
 different colours and the other of the red. The green, 
 however, is made up of red, of violet, and of an excess 
 of green sensation, which in this case comes practically 
 to a mixture of white with the green sensation. How 
 
Colour Stusations in Terms of Luminosity . 95 
 
 can we tell how much is green and how much is white ? 
 Suppose I, as a normal-eyed person, compare the lumi- 
 nosity of the colour coming through the red slit with 
 that coming through the green slit, and then get the 
 green-blind to do the same, it is evident that any excess 
 in the luminosity as measured by myself over that 
 measured by the green-blind must be due to the green 
 sensation, and we can also see how 
 much red and violet make up his 
 white. We shall not be far wrong, 
 then, in apportioning the consti- 
 tuents of the white thus found 
 between the green and the red ; 
 the violet being, for 
 
 Fio. 22. 
 
 the time bein 
 
 o' 
 
 neg- 
 
 ligible. We must g 
 
 subtract the red sensation from the green colour curve and 
 add it to the red colour curve : the two curves will then 
 be very closely the curves of the red and green sensa- 
 tions. By causing the green-blind to make mixtures of 
 red and violet for all the colours of their spectrum, we 
 can arrive at what must be finally taken away or given 
 to these curves, though such addition or subtraction of 
 fHolet will be small when the luminosities are considered 
 The accompanying figure (Fig. 22) gives an idea of the 
 
96 Colour Vision, 
 
 shape and general features of these curves. It may he 
 remarked that we can check the general accuracy of 
 the measures of the colour mixtures by calculating or 
 measuring the areas of the two colour curves, the red 
 and the green. If accurate, they should bear the same 
 ratio that the luminosities of the two colours bear to 
 each other (when mixed with a little violet^ which is 
 practically negligible) to form white light. So far, then, 
 we can utilize the luminosity methods to calculate and 
 to trace the sensation curves for the normal eye. It 
 will not escape your notice that the maximum heights 
 of these two component curves are nowhere near the 
 parts of the spectrum where the colour is the purest. 
 Another check to these curves may also be made by 
 taking the difference in the ordinates of the luminosity 
 curves of the colour blind and the normal eyed. Too 
 much stress must not, however, for the moment, be 
 laid on this, as this method depends on the absolute 
 correctness of the scale of the ordinates in the curves. 
 It must be recollected that to the former white light 
 is deprived of at least one constituent sensation which 
 is perceived by normal eyes. This, in all probability, 
 renders the white less luminous to them than those 
 possessing normal vision, so that the comparisons of 
 luminosities are referred to different standards. 
 
Colour Sensation in Terms of Luminosity. 97 
 
 It may seem a very simple matter to ascertain the 
 correct scale, but it is not, except by the extinction 
 method, which will be described later. At one time 
 General Festing and myself tried to obtain a comparison 
 by finding the limiting illumination at which a book 
 could be read. We got results, but for the purpose 
 in question the values are not conclusive. What we 
 really were measuring was the acuteness of vision in 
 different coloured lights. As a good deal depends upon 
 the optical perfection of the eyes under examination, 
 besides the illumination, we must be on our guard, even 
 
 if there were nothing else against the method, against 
 taking any such measures as being conclusive. 
 
 H 
 
( 98 ) 
 
 CHAPTEE YIII. 
 
 Before quitting the measurement of luminosity, it 
 may be as well to see whether the curves described are 
 the same whatever the brilliancy of the spectrum may 
 be. We can easily experiment with a very reduced 
 brightness. Upon the screen we have an ordinarily 
 bright spectrum. As the slit, through which the white 
 light forming the spectrum comes, is narrowed, there is 
 an evident change in the relative brightness of the 
 different parts, though the energy of every ray must 
 be proportionally reduced. The red is much more 
 enfeebled than the green, and in brightness the green 
 part of the spectrum looks much more intense than 
 the yellow, which is ordinarily the brightest part. 
 This we have assured ourselves of not only by 
 casual observation, but also by direct Ineasurement* 
 Perhaps I can make this even more decisive to you. 
 Two slits are now in the ordinarily bright spectrum, 
 one in the red, and the other in a green which is 
 
Red-bli7id Spectrtim Ltunmosity . 99 
 
 near the E line of the solar spectrum. Instead of 
 using one lens to form a single colour patch of mixed 
 light, two parts of a lens, appropriately cut and of 
 the same focal length as the large combining lens, 
 are placed in front of the slits, one bit of lens before 
 each. This artifice enables us to throw the patch of 
 red on one white surface, and the patch of green light 
 on another adjacent to it. By opening or closing one 
 or other of the slits the brightness of the two patches 
 of light are so arranged that there is no manner 
 of doubt but that the red is the brighter of the 
 two. The absolute energies of the rays forming 
 each of the patches are proportionally reduced by 
 closing the slit of the collimator, as before. At one 
 stage both patches appear of about the same intensity. 
 This might be taken for an error in judgment, but 
 to make the change that takes place perfectly plain 
 to you, the rotating sectors are introduced in front of 
 the two slits, and the rays now pass through them. 
 The apertures of the sectors are gradually closed, and 
 we now come to such a reduction that the red is 
 absolutely invisible ; but the green still shines out. 
 It is losing its colour somewhat, and appears of a 
 bluish tint. The i-eason, Qf .thi^^^cbang^ of » hue in the 
 latter we shall, shortly ,se,e. , The sectors^ h^^ withdrawn 
 
lOO Colour Vision. 
 
 and the red re-appears, and is as bright as the green. 
 The slit of the collimator is next opened, and there 
 is no doubt that the red is much brighter than the 
 green, as it was purposely made at the beginning \ 
 of the experiment. The same class of experiment 
 might have been repeated with the green and violet 
 or the red and violet, and the same kind of results 
 would have been obtained. The violet would have 
 been the last to disappear when the green was so 
 reduced in luminosity that it appeared in the ordinary 
 brilliant spectrum to be equal to the violet ray 
 selected. When the green was of the luminosity 
 given by a slit equal in width to that of the violet, the 
 violet would have disappeared first, owing to its feeble 
 brightness to begin with. Now, if we measure a feebly 
 illuminated spectrum we must adopt some special 
 means to exclude all light, except that of the 
 comparison light and the ray to be measured. This 
 we can do by the box which is shown in the next 
 diagram (Fig. 24). 
 
 At one end of a box, shown in plan, is an eye- 
 piece, E. The other end has at its centre a white 
 square of paper of ij-inch scale. The mono- 
 chromatic \^^W.nCbl 'coijiiii'g fKoiii ^t^Q Spectrum through 
 
 vV wvv fi^^ ^^^4i^>^^ ^^ r reference. „be^m ^ *}), pi white light, 
 
Luminosity of a Feeble Spectrum. loi 
 
 are reflected from glass mirrors Mj, Mg to apertures 
 in opposite sides of the box, and from close to these 
 
 I 
 
 llppertures by the right-angled prisms Pj Pg, so as to 
 fall on and cover S. Eods Ki, Rg are inserted in the 
 
I02 Colour Vision. 
 
 box in the paths of the beams, so that the opposite 
 halos of S are illuminated. Diaphragms inside the 
 box cut off any stray light, and rotating sectors 
 placed at A and B regulate the intensity of the 
 beams as required. The sector A is rotated with a 
 previously determined-on aperture ; the white light 
 coming through B is altered till the luminosity of the 
 two on the screen, as seen through E, are the same. 
 Every part of the spectrum can be measured in this 
 way ; the result is shown in the diagram. Fig. 25 
 (the measures will be found at page 215 in the 
 appendix). In this case the orange light at D where 
 it fell on the screen was equal to y^^ of an amyl- 
 acetate light, which, in its turn, is closely * 8 of a 
 standard candle. In the same figure the luminosity 
 curve of the ordinary bright spectrum is given for 
 reference, and it can be seen how the point of 
 maximum luminosity is shifted into the green, lying 
 almost over the E line of the solar spectrum. The 
 maximum, of course, has been made 100 as before, for 
 had it been drawn to the same scale as the other, 
 the form of the curve would not have been demon- 
 strated. There is a remarkable resemblance between 
 it and the curve of luminosity of the monochromatic 
 vision, and such a resemblance ^ can scarcely be 
 
I04 Colour Vision, 
 
 and is almost the same as that observed when the 
 spectrum is reduced to such an extent that it is 
 colourless throughout, a condition that it can assume, 
 as we shall see very shortly. When the spectrum is 
 rather more luminous, it gives a curve of luminosity 
 which is similar to that of the ordinary spectrum 
 when measured by a red-blind person. Here, then, 
 we have an indication that a person with normal 
 vision passes through a stage of red-blindness, as the 
 intensity is diminished before he arrives at absolutely 
 monochromatic vision. 
 
 This investigation is of practical as well as 
 'theoretical interest, as General Festing and myself 
 'quickly discovered when we first made it. The 
 curious colour of a moonlight landscape is entirely 
 accounted for by it. White light becomes greenish- 
 blue as it diminishes in intensity, and the reds and 
 yellows, being reduced or absent, are not reflected by 
 surrounding objects. Hence, moonlight is cold, whilst 
 the sunlight is warm owing to their presence. 
 
 When measuring these low luminosities, the various 
 colours will in a great measure disappear. Part of 
 the spectrum will be of that peculiar grey which 
 was shown you in the experiment with the in- 
 candescent light (p. 34). By further experiment it 
 
Extinction of Colour, 105 
 
 is possible to arrive at an approximate determination 
 of the point where all colour vanishes from the 
 different parts of the spectrum. We use the same 
 apparatus (Fig. 24) as before, the only difference being 
 that each of the sectors is movable during rotation. 
 The apertures of those through which the colour 
 passes are reduced till all colour on the screen just 
 disappears, the point being arrived at by a com- 
 parison with the white, which is itself also reduced. 
 The apertures of the first sector alone need be noted, 
 and from these readings the diagram (Fig. 26) is. 
 made (for measures, see page 216). 
 
 This extinction of colour is one which often occurs, 
 but is seldom noticed. The figure tells us that the 
 orange is about the last colour of the spectrum 
 left, some of the others still appearing as greys. The 
 next to retain its colour is the green, and the most 
 rapid to lose them are the red and violet. It must 
 not be supposed that the colours remain of the same 
 hue up to the time that they vanish. Pure spectrum 
 red (red sensation) remains the same up to the last, 
 but the scarlet becomes orange, and the orange 
 yellower, and the green bluer. This is what would 
 be predicted from the Young theory if the order of 
 extinction of sensation be red, green, violet. This 
 
o6 
 
 Coloicr Vision^ 
 
 Fig. 2G. 
 
 ^7 \y/iu/i' / /^/^^,>, 
 
 
First Appearance of Colour, 107 
 
 we shall see is the case. At nightfall in the 
 summer the order of disappearance of colour may 
 often be seen ; orange flowers may be plainly visible, 
 yet a red geranium may appear black as night ; the 
 green grass will be grey when the colour of the 
 yellow flowers may yet be just visible. An early 
 morning start in the autumn before daybreak will 
 give an ample opportunity of satisfying oneself as to 
 the order in which colours gradually re-appear as 
 daybreak approaches. Ked flowers will be at the out- 
 set black, whilst other colours will be visible as grey. 
 As more light comes from the sky the pale yellow 
 and blue flowers will next be distinguished, though 
 the grass may still be a nondescript grey. Then^ 
 
 as the light still increases, every colour will burst 
 out, if not in their full brilliance, yet into their own 
 undoubted hue. 
 
 I 
 
( io8 ) 
 
 CHAPTER IX. 
 
 Not only, however, may we lose a sense of colour, 
 but we may also lose all sense of light by reducing 
 the energy of the different rays. We have seen that 
 Qolour goes unequally from the different parts of 
 the spectrum. We may therefore prognosticate that 
 the light itself may disappear more rapidly from some 
 parts than from others. You will scarcely, however, I 
 think, be prepared for the enormous difference which 
 exists in the stages of disappearance of the grey of 
 the reduced red and of that of the reduced green. 
 
 But how are we to measure this extinction of light 
 at the different parts of the spectrum? This is a 
 problem which I have attacked during the last few 
 years by a variety of methods ; but as is the case 
 with almost every scientific problem, when the mode 
 of attack is reduced to its simplest form, it yields 
 the more readily to solution. If we have a box, like 
 that figured in Fig. 27, and combine it with our 
 
Fm. 27. 
 
 B 
 
 Extinction of Light. lOo 
 
 colour patch apparatus, the problem is solved. B B 
 is a closed box 3 feet long and about 1 foot high 
 and wide, having two similar apertures \\ inch in 
 diameter in the positions shown. The aperture at 
 the side is covered on the inside 
 by a piece of glass a, ground on 
 both sides, and a tube T is in- 
 serted, in which diaphragms, D, of 
 various apertures can be inserted 
 at pleasure. The most convenient 
 form of diaphragm is that supplied 
 with photographic lenses — an iris 
 diaphragm. E is a tube fitted 
 
 at the end 
 ^ /^ of the box 
 
 through 
 which the 
 screen S is viewed. S is black 
 except in the centre, where a 
 white disc is fastened to it. A 
 mirror, M, placed as shown, reflects the light scattered 
 by the ground glass on to the screen S. The rotating 
 sectors are placed where shown, and are in such a 
 position that they can be readily adjusted by the 
 observer. The patch of any desired colour of the 
 
 % 
 
no Colour Vision, 
 
 spectrum is thrown on a, and an appropriate size 
 of diaphragm used, so that when the sectors are not 
 less than 5° to 10° open, the light totally disappears. 
 We can now make observations throughout the whole 
 spectrum, and knowing the value of the different 
 apertures of the diaphragm and the angular opening 
 of the rotating sectors, we can at once find the 
 amount of reduction of the particular part of the 
 spectrum that is being required in order to just 
 extinguish all traces of light from the white disc 
 at the end of the box. From these measures 
 we can readily construct a curve or curves which 
 will graphically show the reduction given to the 
 different parts of the spectrum. Fig. 28 gives the 
 curve of extinction for ordinary normal colour vision. 
 The spectrum was of such a brilliance that the 
 intensity of the square patch of light formed on a 
 of the orange light (D) was exactly that of an 
 amyl-acetate lamp, placed at one foot distance from 
 the receiving screen. Knowing this, the actual lumi- 
 nosity of all the other rays of the spectrum can be 
 derived from the curve of luminosity (see Fig. 20). 
 Extinguishing the various parts of the spectrum 
 by this plan, it is found that the red rays cease 
 to stimulate the retina sufficiently to give any 
 
 J 
 
Extinction of Light, 1 1 1 
 
 appearance of light long before the green rays are ex- 
 tinguished. It is only the rays in the extreme violet 
 
 riG.2s. 
 
 
 -^m^'mar-m 
 
 ■T^M '/M 
 
 SBaHB 
 
 ^il^^=^ 
 
 ■■■E9B 
 ■■■■SB 
 
 [grii 
 
 i)f the spectrum, and which consequently possess 
 very feeble luminosity, that make any approach 
 
 1 
 
112 Colour Vision, 
 
 towards requiring the same amount of reduction as 
 the red rays. 
 
 There is the fact to remember in making these 
 measures in the extreme red and the extreme violet, 
 that the luminosities of the colours are so small that 
 the illumination of the prism itself, by the white light 
 falling on it, has to be " taken into account, since it 
 forms an appreciable portion of the patch of feeble 
 colour. By placing a proper shade of blue or red glass 
 in the front of the collimator slit this white light dis- 
 appears or becomes negligible, and when the absorption 
 of the coloured glass is known from measurement, 
 we can get a very accurate measure of the extinction 
 of these parts. Some people may propound the idea 
 that the rotating sectors may in such kind of measure- 
 ments give a false result. Now such a criticism is 
 quite fair, and it is absolutely necessary that it should 
 be answered. Well, to test the accuracy or the reverse 
 of the assumption that such measures are correct, the 
 following small piece of simple apparatus was devised. 
 A and B (Fig. 29) are two mirrors placed at angles 
 of 45° to the angle of incidence of the beam. The 
 path the beam takes can be readily ascertained from 
 the figure. This piece of apparatus was placed in 
 position in front of the spectrum, and the reflected 
 
A Criticism Answered, 113 
 
 beams used to form the patches of colour. For 
 convenience only a small pencil of light was allowed 
 to issue from the prism, a diaphragm of some ^-inch 
 in diameter being placed in front of it. This allows 
 a spot of any desired colour to Fio. 29. 
 
 fall on the screen, the ground 
 glass being removed. The slit 
 through which the spectrum colours 
 pass is moved along the spectrum, 
 and a position is arrived at where 
 the last glimmer of light disap- 
 pears. 
 
 The mirrors A and B may both = 
 
 be of plain glass blackened with smoke on one side, 
 or one may be plain glass and one silvered, or they 
 both may be silvered. This, with the power possessed 
 of altering the aperture of the slit of collimator, puts us 
 in possession of ample means of making our measures. 
 We may also use the ground-glass arrangement and use 
 different diaphragms, which puts a further power of 
 variation in our hands. I may at once state that the 
 resulting measurements fell on the curves, obtained by 
 measurements made with the rotating sectors, a sufficient 
 proof that the sectors may be used with confidence. 
 There is still another method which avoids a resort 
 
114 Colour Vision, 
 
 to the sectors. A tapering wedge of black glass can 
 be moved in front of the colour slit, and a different 
 thickness of glass will be required to cause the extinc- 
 tion of each colour. Eecently I have modified the 
 extinction box, more particularly for the purpose of 
 using it where the spectrum is to be formed of a 
 feeble light, such as that of an incandescent lamp or 
 a candle. If a really black wedge could be obtained, 
 this would seem to be the best method, but no 
 glass is really black. We have, therefore, to make 
 a preliminary study of the wedge to ascertain ac- 
 curately the absorption co-efficients for the different 
 rays, a piece of work which requires a good deal of 
 patience, but which, when done, is always at com- 
 mand. 
 
 In Fig. 28 two branches of the curves are given 
 at the blue end of the spectrum ; one is shown as 
 the extinction for the centre of the eye, and the 
 other of the whole eye. Of course the former observa- 
 tions were made by looking direct at the spot. This 
 may appear a very easy matter, but it is not really 
 so simple as it sounds. It is curious how little control 
 there is over the absolute direction of the eyes when the 
 light has almost disappeared. The axes of the eyes 
 are often directed to quite a different point. When 
 
Extinction of Equal Luminosities. 1 1 5 
 
 the extinction for the whole eye is made, the readings 
 are really much easier, as then the eye roams where 
 it likes, and a final disg^ppearance is noted. When 
 the eye has once been invested with a roving commis- 
 sion, it is hard to control it. In making these observa- 
 tions it was therefore advisable to have data for the first 
 branch of the curve, before commencing to observe for 
 the later. The main cause of difi'erence between the two 
 branches of the curve is due to the absorption by 
 the yellow spot. 
 
 It might be thought that with the curves (Fig. 28) 
 before us, we have learnt all we can regarding the 
 extinction of light, but is it so ? Surely we ought 
 to know something as to the reduction necessary for 
 extinction of the difi'erent parts of the spectrum 
 when they are all of equal luminosities and of 
 ordinary brightness. 
 
 We arrive at this by simple calculation. Supposing 
 we have two luminosities, one double the other, it does 
 not require much thought to find out that you have 
 to reduce the greater luminosity twice as much as the 
 other in order for it to be just extinguished. In other * 
 words, if we multiply the extinction by the luminosity, 
 we get what we want. Now, in the curves before us. 
 we have taken the luminosity of the yellow light near 
 
 X 2 
 
ii6 Colour Vision, 
 
 D as one amyl-acetate lamp, and that lias a height in 
 the curve showing the spectrum luminosity very closely 
 approaching 100. We may, therefore, multiply the 
 extinctions of a ray by the value of its ordinate 
 in the luminosity curve and divide the result by 
 100, and this will give us the extinction of each 
 colour, supposing it had the luminosity of an amyl- 
 acetate lamp. A portion of the curve so calculated is 
 shown in the same diagram (Fig. 28) as a dotted line. 
 It appears at the violet end as an approximately 
 horizontal line, and then starts rapidly upwards, and 
 would, if carried on to the same scale, reach far out 
 of the diagram ; but at the extreme red it would be 
 found to bend and again become horizontal. I would 
 have you notice that the same is true not only for 
 the extinction observed with the centre of the eye 
 through the yellow spot, but also for the whole eye. 
 Such straight, horizontal parts of the curve must mean 
 something. 
 
 In the diagram (Fig. 16) of colour sensations we 
 see that in each of these two regions there is but one 
 sensation excited, viz. the violet and the red. Now, 
 if these sensation curves mean anything, the reduction 
 necessary to produce the extinction of the same sensa- 
 tion when equally stimulated should prove to be the 
 
Fig. 30. 
 
ii8 Colotir Vision, 
 
 same, for there is no reason to the contrary, but exactly 
 the reverse. Primd facie, then, taking the Young 
 theory as correct, we may suppose that these horizontal 
 parts are due to the extinction of one sensation. Let 
 us treat it as such, and go back to the original extinc- 
 tion curve shown in the continuous lines. The parts 
 of the curve which lie over the fairly horizontal dotted 
 line, at all events, should be the extinction curve 
 of the same sensation, but more or less stimulated or 
 excited. As before explained, if we have double the 
 stimulation at one part of the spectrum to that we 
 have at another, the reduction of the greater luminosity 
 to give extinction will be double that of the lesser. 
 If, then, we take the reciprocals of the extinction, it 
 ought to give us a curve which is of the form of 
 some colour sensation ; and when we arrive at 
 the maximum, we may for convenience make that 
 ordinate 100, and reduce the other ordinates pro- 
 portionally. This has been done in Fig. 30 in the 
 curves C and D. For the sake of a name my col- 
 league and myself have named such curves '' persis- 
 tency curves." Perhaps some other name might be 
 more fitting ; but still a poor name is better than 
 none at all. 
 
 When the persistency curve was scrutinized to see 
 
Persistency Curves, 119 
 
 what might be taken as its full signification, I 
 must confess that the result astonished us some- 
 what, though we ought not to have been surprised. 
 The persistency curve C, when applied (in a Euclidean 
 sense) to the curve of luminosity recorded for the 
 men who had monochromatic vision, almost exactly 
 coincided with it. In other words, by far the 
 largest part of the extinction was due to the extinc- 
 tion of the sensation which in the monochromatic 
 vision was alone excited. If this be not the case, 
 there is something in colour vision which no theory 
 which I am acquainted with can account for. Then, 
 again, the persistency curve agrees with the curve 
 of luminosity when the intensity of the spectrum is 
 very feeble, which is another coincidence of a remark- 
 able character which some theory should explain. 
 [Fig. 30 gives, besides the persistency curves, the 
 luminosity curves of the normal eye, of monochro- 
 matic vision, and of the violet-blind; and an ex- 
 aggerated curve of the difference between the normal 
 luminosity curve and that of the violet-blind, and 
 others which I think will be found useful for general 
 reference.] 
 
 What sensation is it that is last extinguished, and 
 which is possessed by a certain class of colour vision ? 
 
I20 Colour Vision. 
 
 In the Young theory it can only be the violet sen- 
 sation. It is certainly not the green, and much less 
 the red. It does not correspond, however, very well 
 with the violet sensation shown in Fig. 16, but more 
 with one which should be in the blue. 
 
 In making the extinctions of light, it is quite 
 necessary that certain precautions should be taken 
 to avoid error. All my audience know that when 
 going from bright daylight into a cellar, in which 
 only a glimmer of light is admitted, but little can 
 be seen at first, but that, as the eye " gets accus- 
 tomed " to the darkness, the surroundings will begin 
 to be seen, and after several minutes what before 
 was blackness comes to be invested with form and 
 detail. So it is with the extinction of light in the 
 apparatus described. Observations carried on before 
 the full sensibility of the eye is attained are of no 
 value. A recorded set of observations will show 
 this. A light of a certain character was thrown 
 on the extinction box, to be extinguished, and the 
 observer entered the darkened room from the full 
 glare of daylight. The eye was placed at the eye 
 end and kept there, and the extinctions were made 
 one after the other till they became very fairly con- 
 stant. The following is the result : — 
 
Proo^ressive Sensitiveness, 
 
 121 
 
 Times of Observation. 
 
 
 
 
 Readings. 
 
 At the commencement . . . . 1*0 
 
 After 38 sec. 
 
 
 
 
 3-2 
 
 After 53 sec. 
 
 
 
 
 4-9 
 
 After 1 min. 11 sec. 
 
 
 
 
 6-9 
 
 After 1 min. 44 sec. 
 
 
 
 
 10-5 
 
 After 2 min. 43 sec. 
 
 
 
 
 17-0 
 
 After 3 min. 44 sec. 
 
 
 
 
 27-5 
 
 After 4 min. 52 sec. 
 
 
 
 
 43-0 
 
 After 5 min. 59 sec. 
 
 
 
 
 63-0 
 
 After 6 min. 41 sec. 
 
 
 
 
 78-0 
 
 After 7 min. 28 sec. 
 
 
 
 
 89-0 
 
 After 8 min. 32 sec. 
 
 
 
 
 96-0 
 
 After 10 min. 46 sec. 
 
 
 
 
 103-0 
 
 After 12 min. 
 
 
 
 
 103-0 
 
 (For convenience the first reading is unity ; the other numbers arc 
 the inverse of the extinction value.) 
 
 The eye apparently, under the conditions in which 
 these observations were made, was at least 100 times 
 more sensitive to very faint light after twelve minutes 
 than it was at the beginning, and that then concordant 
 readings could be made. It will now be quite under- 
 
 I stood that before any serious measures can be made 
 this intei*val must elapse, and also that the light, 
 finding its way to the end of the box to illuminate 
 the spot, should never be strong, otherwise the eye 
 
( 122 ) 
 
 CHAPTER X. 
 
 Before considering the subject of the extinction of 
 light by other types of colour vision, attention must 
 be called to what has already been brought before you. 
 The various colours of the spectrum have to be reduced 
 to the following amounts before they sufifer extinction, 
 the orange light at D being of the value of one candle. 
 (See appendix, page 217, for complete tables.) 
 
 Reduction in ■d^«,„»i« 
 
 MiUionths. Remarks. 
 
 B 10,000 or yig^ approximately pure red 
 
 sensation 
 
 C 1,100 or 7^^ rather more scarlet 
 
 D 50 or 32^0^0- orange light 
 
 E 6*5 or x5¥Voi5" a green chosen by Maxwell 
 
 as a standard colour 
 
 F 15*0 or ^tooo beginning of the blue 
 
 Blue Lithium 85*0 or ttt^o^ a good sample of blue 
 
 G 300*0 or 3-300 approximately pure sensa- 
 
 tion of violet. 
 
 If we make these same colours all of the luminosity 
 of one amyl-acetate lamp ( • 8 of a candle), we find 
 that the numbers are as follows : — 
 
Visibility of Illumination, 123 
 
 
 Keduction in 
 Millionths. 
 
 
 Keduction in 
 Millionths. 
 
 B ... 
 
 300 1 
 
 F 
 
 •9 
 
 C ... 
 
 225 1 
 
 Blue Lithium 
 
 1-1 
 
 D ... 
 
 48 , 
 
 G 
 
 1-1 
 
 E ... 
 
 3-3 
 
 
 
 These numbers are remarkable, and we may enforce 
 what they mean in this way. The energy of radiation, 
 and of light also when of ordinary luminosity, varies 
 inversely as the square of the distance from an incan- 
 descent body when of small dimensions. But from the 
 above it seems that a white screen receiving the rays 
 from an amyl-acetate lamp in an otherwise perfectly 
 dark place, and having a colour which stimulates the red 
 sensation alone, would be invisible at 58 feet distance, 
 for there would not be enough energy transmitted to 
 stimulate the red perceiving apparatus sufficiently to 
 give the sensation of light. If it were an orange light, 
 such as sodium, of the same luminosity, we should have 
 to move it from the screen 142 feet before the same 
 result was attained. With the green light at E, the 
 distance would be 550 feet, and with the violet the 
 distance would be increased to 1000 feet. The re- 
 duction in intensity of white light, which, when of 
 ordinary brightness, is warm, would make it colder, for 
 the red would disappear, and finally the residue of 
 light, just before extinction, would become a cold grey, 
 
124 Colottr Vision. 
 
 due to tlie absence of all colour. The changes in hue 
 that would occur are variable, the variation being due 
 to the loss of colour of the different rays for different 
 amounts of reduction, and then their final extinction. 
 We can place two patches of white light on the screen, 
 and gradually reduce one in intensity, keeping the other 
 of its original value. No one would expect that the 
 two would be dissimilar in hue, as they appear to be 
 when the former is moderately near the extinction value. 
 If we wish to see this perfectly, we should use an 
 extinction box and view it away from the surroundings, 
 which must be more or less slightly illuminated. 
 
 It has already been stated that the persistency curve 
 for persons who have normal colour vision is closely 
 the same as that recorded for those who are of the 
 monochromatic type. As this is so, we must expect 
 to find that the persistency curve of these last is the 
 same as their luminosity curve. We put this to the 
 test of experiment and found that our reasoning 
 was correct, for the persistency curve could be almost 
 exactly fitted to it. (See table, pages 217 and 222.) 
 The slight difference between them can be credited to 
 the fact that the whole eye may have been brought 
 into use during the extinction observations, the centre 
 of the eye not being exclusively used. The Figure 31 
 
Monochromatic Vision. 
 
 125 
 
 shows both the extmction and the persistency curves, 
 and also the curve of luminosity for the normal eye. 
 
 Fig. 31. 
 
126 Colour Vision, 
 
 The former were derived from a case P. sent for 
 examination. P. and Q. are brothers, each of whom 
 possesses but one colour sensation, and examination 
 showed that their vision was identical. Mr. Nettleship 
 has kindly given me the following particulars regarding 
 them : — " Their acutes of vision (form vision) in ordinary- 
 daylight is only one-tenth of the normal. A younger 
 sister and brother are idiotic and almost totally blind, 
 and in one of these the optic nerves show clear evidence 
 of disease. Hence, the colour blindness of P. and Q. 
 must almost without doubt be considered as the result 
 of disease, perhaps ante-natal, involving some portion 
 of the visual apparatus." A lack of acuteness of 
 vision would be expected from the small amount 
 of light they perceive compared with normal vision. 
 The fact that two of a family, not twins, possess 
 exactly the same colour sense, and that their 
 extinction curves are entirely different to those 
 suffering from post-natal disease, but similar to 
 those of normal vision, point to their colour blind- 
 ness as falling in the same general category as 
 that of the congenital type. To this I shall refer 
 again. 
 
 We may reason still further. With the red- and 
 green-blind the violet sensation is still present, and we 
 
I 
 
 Extinction by the Colour Blind, 127 
 
 may therefore expect that their extinction curves, and 
 consequently their persistency curves, should be alike, 
 and should also agree with that made from your 
 lecturer's observations. A study of Figures 32 and 33 
 will tell you that such is practically the case. The 
 former shows the luminosity, the persistency, and the 
 extinction curves of a completely red-blind subject, and 
 the latter the same curves for a green-blind subject (see 
 pages 223 and 224). Both were excellent observers, and 
 their examination was easy, owing to the acquaintance 
 with scientific methods. The accuracy of their results 
 may be taken as unquestionable. Each of them may be 
 taken as a representative of their own particular type of 
 colour blindness. There is an agreement between them 
 at the violet end, but a deviation at the red end of the 
 spectrum. The general form of the curves indicates 
 that the same sensation is extinguished last in all. 
 Now, have we any other criterion to offer ? We have. 
 In the first instance, we have the violet-blind person 
 to compare with the others, and also another observer 
 who had monochromatic vision, but whose sensation 
 was different to that of the two monochromatic cases we 
 f have so far brought to your notice. We have already 
 stated the peculiarities in colour nomenclature of the 
 violet-blind case. His curve of luminosity for the spec- 
 
-^-^-^ p^hAi 
 
 ^ WH^m^i^ 
 
 •m^^ 
 
 128 Colour Vision. 
 
 trum was taken (page 227), and when compared with the 
 curve of normal luminosity, it became evident that in 
 
 Fig. 32. 
 
 m 
 
 ■■■■■■■■■■■li I I 
 
 ■■■■■■■■■■■■■■■Bai 
 
 Y/pWd 
 
Violet-blindness. 129 
 
 the red and up to the orange his measures were those 
 which a normal eye would make ; but that the lumi- 
 nosity fell off in the green, and finally disappeared 
 to an immeasurable quantity in the violet (see Fig. 
 30, curves M and F). If his measures of spectrum 
 luminosity are deducted from those of the normal eye, 
 and the ordinates be increased proportionately to 
 make the maximum difference 100, the figure so 
 produced, when compared with the luminosity curve 
 obtained from the monochromatic observers, was found 
 to be the same, and consequently with the persistency 
 curves above referred to. Endeavours were made to 
 gain a good extinction curve, but the results were not 
 as successful as could be desired ; but it was ascertained 
 that, without doubt, his most persistent sensation was 
 not more than -p|-g- as lasting as that of the normal 
 eye, or to put it in another way, his green at E was only 
 extinguished when the energy falling on his eye was 
 180 times greater than that at which it vanished with 
 the normal eye. This plainly teaches us that the 
 missing sensation was that which, when present, is 
 
 I ordinarily the most persistent. 
 The next is a case of monochromatic vision, which 
 differs from those previously brought before you, and I 
 cannot do better than describe it in the words which 
 
150 Colour Vision, 
 
 General Festing and myself employed in our paper in 
 the " Philosophical Transactions." 
 
 Fig. 33. 
 
Green Monochromatic Vision. 131 
 
 The patient (B. C.) had been examined by Mr. 
 Nettleship, who kindly secured his attendance at South 
 Kensington for the purpose of being examined by 
 the spectrum and other tests. [Mr. Nettleship states 
 that this case is without doubt a genuine case of 
 congenital colour blindness, without any trace what- 
 ever of disease.] B. C. is a youth of 19, who has 
 served as an apprentice at sea. His form vision is 
 perfect, and he is not night blind. He can see well 
 at all times, though he states that on a cloudy day 
 his vision seemed to be slightly more acute than in 
 sunshine. He was first requested to make matches 
 with the Holmgren wools in the usual manner, with 
 the result that he was found to possess monochromatic 
 vision. He matched reds, greens, blues, dark yellows, 
 browns, greys, and purples together ; and it was a mat- 
 ter of chance if he selected any proper match for any of 
 the test colours. Finally, when pressed, he admitted 
 that the whole of the heap of wools were "blue" to him, 
 any one only differing from another in brightness. The 
 brighter colours he called "dirty" or "pale" blue, terms 
 which eventually proved to be synonymous. We then 
 examined him with patches of monochromatic spectrum 
 colours by means of the colour patch apparatus. He de- 
 signated every colour as "blue," except a bright yellow, 
 
 K 2 
 
132 Colour Vision. 
 
 which he called white, but when the luminosity of this 
 colour was reduced he pronounced it a good blue. So with 
 white, as the illumination was decreased, he pronounced 
 it to pass first into dirty blue, and then into a full blue. 
 
 Colour discs were then brought into requisition, 
 and it was hard at first to know how to make the 
 necessary alterations, owing to the terms he employed 
 to express the difierence which existed between the inner 
 disc and the outer grey ring. By noting that a pale 
 "blue" passed into a pure blue when the amount of white 
 in the outer ring was diminished, and that the inner disc 
 was described as "pale" or "dirty" when the outer ring 
 was described as "a very full blue," we were enabled to 
 make him match accurately a red, a green, and a blue 
 disc separately with mixtures of black and white. 
 
 The following are the equations : — 
 
 360 red =315 black + 45 white. 
 360 green = 258 black + 102 white. 
 360 blue = 305 black + 55 white. 
 
 With these proportions he emphatically stated that 
 all were good blues, and that the inner disc and outer 
 ring were identical in brightness and in colour. 
 
 It may be remarked that this is a case of congenital 
 colour blindness, and that there is reason to believe that 
 some of his ancestors were colour blind. 
 
Gi^een Monochromatic Vision, 133 
 
 Before using the discs an attempt was made to ascer- 
 tain the luminosity of the spectrum as it appeared to 
 him. His readings, however, were so erratic that 
 nothing could be made out from these first observations, 
 except to ^n the place of maximum luminosity, the 
 terms " pale " and " dirty " puzzling us as to their real 
 meanings. After the experience with the discs we had 
 a clue as to what he wished to express by pale or dirty 
 blue, which only meant that the colour or white was 
 too bright, and on making a second attempt he matched 
 the luminosities of the two shadows as easily as did P. 
 and Q., the other cases of monochromatic vision. The 
 method adopted was to diminish the white light illu- 
 minating one shadow to the point at which he pro- 
 nounced it a good blue, when a slight alteration in the 
 intensity was always sufficient to secure to his eye 
 equality of luminosity between it and the coloured 
 shadow without his perceiving any alteration in the 
 saturation. 
 
 The curve of luminosity. Fig. 34, is a very remarkable 
 one, being different in character to that of P. and Q., the 
 maximum being well on the D side of E. A great falling 
 off in the luminosity when compared with that measured 
 by the normal eye will be noticed both in the blue and 
 
134 
 
 Colour Vision. 
 
 was therefore presumptive that B. C.'s colour sensation 
 was neither red nor blue, but probably a green. 
 
 Fig. 84. 
 
 I 
 
 ■I 
 ■ 
 
 I 
 
 ■■■■■■■■■■I 
 
 ■■■■■■ 
 ■■■■■n 
 
 ■■■■■RSh 
 
 iUHIi 
 
 wmummk 
 
 ■■■agnnnBassanisaiBia 
 ill 
 
 sanisaBH 
 
 —a 
 
 ■BHHl 
 
 B. C.'s Lumiuosity and Extiuction Curves. 
 
Extinction of Light b)^B^£:^ ^^i^^^ 
 
 The next test was made to tlirb^yii^%16^>; TO 
 
 V - 
 
 point. He made observations of the extmcticMi of th^ 
 different parts of the spectrum. His observatieiia- 
 were very fair, except on the violet side of F, where 
 they became slightly erratic, but by requesting him to 
 use all parts of his retina to obtain the last glimpse of 
 light, a very concordant curve resulted, as shown in Fig. 
 34. Some of his observations at this part were 
 evidently made with the centre of the retina, for they 
 gave readings which, when the " persistency " curve 
 was calculated, and these observations treated as part of 
 the extinction, agreed with the luminosity curve. We 
 may, therefore, conclude that B. C. has a region in the 
 retina in which there is an absorbing medium corre- 
 sponding to the yellow spot of the normal eyed. This 
 is diagrammatically shown in Fig. 34 by the difference 
 in height of ordinates in the persistency (dotted) and 
 the luminosity curves. On the red side of the maximum 
 the two curves are practically identical, except from 
 Scale number 54. At this point it is probable that the 
 white light which illuminated the prism vitiated the 
 readings to some degree. At the violet end something 
 similar, doubtless, occurs, but it is masked by the 
 difference that exists in the extinction by the central 
 part of the retina and that of the whole eye. 
 
136 Colour Vision, 
 
 It must, however, be remarked that the amount of 
 reduction of the intensity of a ray to produce extinction 
 is very different for B. C. and for the normal eyed, or 
 for the red- and green-blind or for P. and Q. B. C. 
 can bear nearly 200 times less reduction for the rays 
 near E. We have already pointed out that the same is 
 practically the case with M., whom we presume to be 
 violet-blind. We may therefore deduce the fact that 
 the monochromatic vision in this case is of a totally 
 different type to that of P. and Q., and that the last 
 sensation to be lost is the same as that of M. If any 
 violet sensation were present in either, the fact would 
 be made evident by the order of the extinction. The 
 sensation of B. C. is thus apparently the green sensation, 
 though that this particular sensation is exactly the same 
 as that absent in the green-blind is not certain. 
 
 The observations made by the different types of the 
 colour blind seem to me to throw great light on the 
 theory of colour vision. They show that when the 
 violet sensation is present, according to the Young 
 theory, the extinction shows its presence ; and that 
 where this sensation is absent, the reduction of light 
 necessary to produce extinction is greatly less, and 
 may with great certainty be attributed to a different 
 sensation being the final one to disappear. 
 
( ^37 ) 
 
 CHAPTEK XL 
 
 I HAVE SO far spoken only of normal, or physiological, 
 colour blindness ; a peculiarity, or defect, present at 
 birth, and, as far as is at present known, irremediable, 
 but not associated with any defect of the visual func- 
 tions, or with any disease or any optical peculiarities. 
 What the nature and seat of this defect may be — 
 whether in the eye or in the sensorium — is at present 
 unknown, although some of the characteristics of the 
 deficiency in colour sensation, I believe, seem to indi- 
 cate the existence of a special part of the brain endowed 
 with the functions for perceiving colour. 
 
 But cases are well known to medical men in which 
 colour vision, . normal to start with, fails in greater or 
 less degree in connection with disease. This part of 
 the subject is large and very complex, and requires for 
 its full elucidation an acquaintance with the diseases 
 and disorders of the eye. Many of the phenomena 
 accompanying acquired colour blindness, however, are 
 
i^S Colour Vision. 
 
 of great interest to the physicist in his study of colour 
 vision, more particularly in regard to the test of the 
 truth of any particular theory. Through the kindness 
 of several medical men, and Mr. Nettleship in par- 
 ticular, I have had the opportunity of examining by 
 the colour apparatus several types of colour blindness 
 due to disease. One feature, common, I understand, 
 to all, or nearly all, cases, is the presence of some 
 disease of the optic nerve. Defective sight — from loss 
 of transparency of the cornea, the crystalline lens, or 
 other transparent parts of the eye — does not interfere 
 with the perception of colour ; nor is true colour 
 blindness, as I am informed, well marked, if present 
 at all, in disease limited to the choroid and retina (see 
 Fig. 1). Even in cases of the disease of the optic 
 nerve, medical authorities tell us that great diifferences 
 exist in the amount of colour defect, and that although 
 the colour defect always goes along with some other serious 
 visual loss, either of form, light, or field, the relation 
 between these several factors of the visual defect is by 
 no means always the same, so far as can be judged by 
 the tests commonly used by ophthalmic surgeons. They 
 tell us that in some cases of disease of the optic nerve, 
 colour vision when tested by the wool test, which will 
 be described shortly, may be almost perfect, whilst the 
 
Tobacco Amblyopia. 139 
 
 capacity for reading test letters of the alphabet may be 
 extremely bad, and vice versa. It seems that in some 
 cases these discrepancies cannot be accounted for ; but 
 in others the facts can be explained by the limitation 
 of the disease to -certain fibres of the optic nerve. 
 Thus, if those fibres which supply the yellow spot 
 region of the retina are alone involved, direct, or 
 central, vision will be much damaged both for form and 
 colour, whilst a little further from the centre of the 
 field, the visual functions in such a case are often quite 
 normal. From what has been said in the opening 
 chapters, this will ibe understood to be that the colour 
 vision is perfect, but the definition of form more or less 
 imperfect. We are told that cases of this type have 
 long been known and are comparatively common, and 
 often favourable as regards recovery ; that the mischief 
 may affect one optic nerve, or both ; that when both 
 are diseased the malady is usually due to the action of 
 some toxic substance, and that of all substances known to 
 have this particular effect on the optic nerves tobacco 
 is the most important. I dwell a little on this variety 
 — damage to form and colour sense at the centre of the* 
 visual field of each eye from limited, and usually 
 
 t curable, disease of the optic nerve — on account of its 
 interest to myself in the investigations I have made, 
 I 
 
140 Colour Vision, 
 
 and also on account of the degree of practical impor- 
 tance which it assumes in connection with the proper 
 reading of signals and coloured lights. These cases 
 of " tobacco amblyopia," as it is pathologically called, 
 are, of course, always found in men; and it may 
 occasionally happen that such a man, if an engine 
 driver, signalman, or a look-out man on board ship, 
 may still see form sufficiently well to see his signals, 
 but may mistake their true colours. From evidence 
 given before the Committee of the Royal Society on 
 Colour Vision, it appears that the disease causing this 
 type of colour blindness is usually produced by the 
 over-use of tobacco, aided by mental depression and a 
 low state of health. As we have no sumptuary laws, 
 cases of tobacco blindness must frequently occur, and 
 it should be the care of all who have the management 
 of railways or shipping to take measures for preventing 
 persons suffering from this disease from occupying 
 posts which require perfect colour vision in order to 
 prevent the possibility of loss of life. 
 
 Congenital colour blindness can at once be discovered, 
 and its possessor be excluded from any post in which 
 normal colour perception is necessary, but with this 
 type a single examination is no safeguard, as it may 
 be developed at any period of a man's career. The 
 
Central Scotoma. 141 
 
 disease is, I believe, a progressive one, and at first is 
 most generally unrecognised, the deficiencies of vision 
 being usually slight at its commencement. It is 
 very often brought to the notice of the sufferer by 
 finding he is unable to read. The words at first 
 seem only slightly indistinct, but later become un- 
 decipherable, and as time goes on he is unable to 
 even see the letters. He or his friends then usually 
 think it time to consult the specialist. In tobacco 
 amblyopia the area of insensibility is central, and it 
 may subtend a very small angle or one which 
 covers a considerable portion of the field. I am not 
 aware that it ever extends over it all, but it very 
 generally covers the yellow spot. Now as the eye 
 naturally receives the image on the centre of the 
 retina, it follows that, as the ability to distinguish 
 some colours is absent in that particular region, the 
 patient is practically colour blind, though he can dis- 
 tinguish them on most parts of the retina which are not 
 affected. As regards form vision, it was mentioned 
 in the first chapter that in a healthy eye it is much 
 more acute at the centre than towards the periphery, 
 and instances were given of the angular distances 
 
 I apart that black dots on a white ground were required 
 
142 Colour Vision, 
 
 objects when the images were received on the centre 
 of the retina, and at the periphery. Sharp definition 
 may be said to be almost confined to 3° of angular 
 distance at the centre, and most probably this is a 
 happy state of affairs, for if we could see equally 
 distinctly with the whole field of vision, the mind 
 would be distracted from the object which it wished 
 primarily to contemplate. 
 
 Bearing in mind the want of definition beyond 3°, 
 and the indistinctness caused by a diseased central 
 area, it will not be surprising to find that form vision in 
 these cases is imperfect throughout, though the colour 
 perception outside such area may be unimpaired. But, 
 practically, men suff'ering from this disease are colour 
 blind to coloured objects, such as a signal light on a 
 railway or a ship's light at sea. They may see that 
 there is light at the distant signal or on the bow of a 
 vessel, but will be unable to interpret correctly the 
 colour. The colours which fail to make visual impres- 
 sions are the reds and greens. Some will distinguish 
 yellow, and very nearly all will distinguish blue with 
 the centre of the eye. If a bright spectrum be thrown 
 on the screen, and a tobacco-blind person be requested 
 to name the colours of the different parts pointed out to 
 him, it is often the case that as his eyes follow the 
 
Colour Fields of the Tobacco Blind. 1 43 
 
 pointer lie will tell you that in the extreme red he 
 sees no light, but in the bright red he sees dull white. 
 The bright yellow he will tell you is a pale yellow 
 or white, according as his case is a moderate or bad 
 one ; the green he will call white, and the blue and 
 violet he will designate correctly. At the same time 
 that his eye is turned away to another colour, he 
 will see the true colour of the part of the spectrum 
 which he has just incorrectly named, but it will dis- 
 appear again as he turns his eyes back again. This 
 tells us that his sense of colour is apparently unaffected 
 outside the diseased area. 
 
 At page 10, a description has been given of the 
 manner in which the field for colour and light has 
 been determined, and if this same method be pursued 
 with persons suffering from this form of colour blind- 
 ness we get some remarkable results. Fig. 35 is the 
 chart of the eye for red and for white, which was 
 made by a case of tobacco blindness. The yellow 
 spot is entirely affected, and, as is very common, 
 it extends to the blind spot in the eye. At no place 
 within that area can red be seen, though blue is imme- 
 diately recognised. The extent of the field for white 
 tis that found under normal conditions, and except for 
 the diseased area the same is true for the red. The 
 
144 
 
 Colour Vision, 
 
 fields for both eyes are given : that for the left eye in 
 the left-hand chart, and that for the right eye in the 
 right-hand chart. The small dark spots within the 5° 
 
 area are places 
 where the 
 colour sensa- 
 tion is most 
 defective. The 
 part in the 
 central dark 
 area shaded 
 with lines in 
 this direction 
 ////shows the 
 portion of the 
 field which is 
 insensitive to 
 red, though 
 not to light, 
 whilst the re- 
 mainder of the 
 shaded central 
 area indicates 
 the extent of 
 the field w^hich 
 
Testing for Colour, 145 
 
 is sensitive to red. The field for light generally is also 
 shown by the (approximately) rectangular unshaded 
 area. Although the area occupied by the insensitive 
 part of the retina is small compared with the whole, 
 yet it is in that part which is used for distinct vision. 
 
 For testing for colour the apparatus, Fig. 3, arranged 
 so that the patch of colour has the white patch along- 
 side, is the most useful, but it is as well then to use 
 a surface of patch about \ inch square only, and thus 
 to confine the image as nearly as may be to the spot 
 on the retina which is defective. These cases of central 
 scotoma are by no means very easy to test ; for it 
 frequently happens that before they are able to dis- 
 tinguish that there are two patches side by side, they 
 have to approach very close to the screen. If this be 
 the case, however, it will usually be found that the 
 patches of i inch side are still efficient, as the near 
 approach of the eyes to the screen indicates a wide 
 area as being affected, so that the image still lies 
 within the diseased retinal area. In some instances 
 the colours named will vary very considerably ; some- 
 times, for instance, a red will be named as grey, and 
 then immediately after as pale red. This is generally - 
 
 fiue to the diseased area being small, and a very slight 
 hange in the direction of the axis of the eye causes' 
 
146 Colour Vision. 
 
 it to be seen in nearly its true colour, part being 
 viewed with the diseased and part with the healthy 
 portion of the retina. With the wool test, which we 
 shall describe later, it is the commonest thing possible 
 for colour-blind persons who have a central scotoma 
 to match accurately the different test-skeins, for the 
 reason that the images of the skeins of wool are so 
 large that they are received on the parts of the 
 retina which are not diseased. These same colours, 
 however, if presented to them in small patches, will 
 inevitably show the defect in vision. 
 
 With this end in view, I have had a set of brick-clay 
 pellets some -^-inch in diameter, painted with water- 
 colours mixed with soluble glass solution of the same 
 colours as the wools. These are placed in a shallow 
 tray, and presented to patients affected with this 
 central colour blindness to pick out all the pellets 
 which match reds and greens. They will tell you 
 that they see neither one nor the other, though they 
 will pick out the blue pellets unerringly. A red pellet 
 they will match with a red, green, grey, or a brown 
 one, and a green one with the same. If, however, 
 you instruct them to direct their eyes a few degrees 
 away from the tray, they will tell you they see all 
 the colours, and as they endeavour to pick them out, 
 
Pellet Test. J47 
 
 they, with a natural instinct, direct their eyes again 
 to the collection, when once more the colours vanish. 
 It is almost piteous sometimes to see the distress 
 which this simple test occasions. The sight of the 
 colours for an instant and their immediate disappear- 
 ance in the cases that I have tried, seem indicative 
 of something terrible, for they usually have no idea 
 of the cause of this (to them almost miraculous) 
 phenomenon. I have seen these colour blind tested 
 with a pair of ordinary bull's-eye lanterns, placed side 
 by side, with diaphragms of moderate size with 
 coloured glasses, which can be changed at will, in 
 front. At twelve feet distance they will often see both 
 lights as one, but as they approach they will make out 
 two lights and call them both white, or sometimes 
 they will make a guess and call a green red. or vice 
 versd. It goes without saying that such eyesight is 
 useless for reading signals, and indeed for any 
 purpose whatever. Sometimes, but I believe this is 
 rare, no colour whatever can be distinguished. 
 
( h8 ) 
 
 CHAPTER XII. 
 
 I WILL now give in full the result of the examination 
 of a patient who was suffering from tobacco blindness. 
 X. , aged thirty-six, a commercial traveller, was suffering 
 from rather severe tobacco amblyopia. The scotoma 
 was a very marked one, and the loss of colour sensa- 
 tion most complete. Mr. Nettleship, who furnished 
 the case, has kindly added the following remarks on 
 the case : — 
 
 His acuteness of vision was -3% with the right eye 
 and -g^g- with the left. He smoked half-an-ounce of 
 " shag " daily and drank about four pints of beer. His 
 sight had been failing for about two months= As is 
 common in early stages of this disease the ophthalmo- 
 scope revealed no decided changes at the optic discs. 
 
 He passed the test of the Holmgren wools satis- 
 factorily, proving that the usual vision was normal for 
 colour, but failed at once with the pellet test. 
 
 The objects in view were to test his perception of 
 the spectrum colours, and then the extent of his retinal 
 
Luminosity Curves. 149 
 
 field for colour. This last is not recorded here. The 
 spectrum colours were reduced to uniform luminosity 
 
 Fig. 36. 
 
150 Colotcr Vision. 
 
 between X4600 and X6600. Diaphragms containing 
 holes of different sizes were placed in front of the last 
 
 prism, and thus a round spot of monochromatic light of 
 
 the same luminosity was produced upon the screen when 
 
 a slit was passed through the spectrum. From the red 
 
 end to X 5270 he called the whole of the colours white, 
 
 and from that point he began to see blue, called the 
 
 colours bluish and blue. When the full illumination 
 
 for all the colours was used, the same results were 
 
 obtained. From this examination it would appear 
 
 that he was totally deprived of the sensation of any 
 
 colour except of blue. A subsequent examination of 
 
 his perception of the luminosity of different rays, 
 
 however, has to be taken into account, for in the first 
 
 examination he had no light of pure white with which 
 
 to compare the colours. In the next experiments, a 
 
 strip of white light was placed in juxtaposition to the 
 
 colour, and the results were slightly different. The table 
 
 below gives his luminosity measures (Fig. 36). Col. I. 
 
 is the empyric scale number, 11. is the wave-length, III. 
 
 the luminosity of the colour to the normal eye, IV. the 
 
 luminosity to X., and V. the ratios of III. to IV. 
 
 In the diagram, his luminosity curve X. is shown, its 
 
 area being 1400 against 1650 for the normal eye. His 
 
 ceiitpd^ei:ception of light, as arrived at by the extinction 
 
Tobacco Blindness, 
 
 151 
 
 metliod, was only two-thirds of that of the normal eye ; 
 hence his area of luminosity should be 1100. As it is 
 1400, the ordinates of the above curve should be multi- 
 plied by 0*8, to compare with that of the normal eye. 
 
 I. 
 
 II. 
 
 HI. 
 
 IV. 
 
 V. 
 
 Colours to X. 
 
 
 
 2^ 
 
 Luminosity 
 to the 
 normal eye. 
 
 1 
 
 a 
 
 IV. 
 III. 
 
 Spectrum colour to 
 normal eye. 
 
 60 
 
 6730 
 
 7-3 
 
 
 
 
 
 Sees only the white 
 stripe 
 
 Eed. 
 
 67 
 
 6423 
 
 32 
 
 10 
 
 0-31 
 
 Calls red yellowish, 
 and white bluish 
 
 Scarlet. 
 
 55 
 
 6242 
 
 65 
 
 38 
 
 0-65 
 
 »» »> 
 
 
 53 
 
 6074 
 
 96 
 
 86 
 
 0-89 
 
 Both one colour 
 
 Eed-orauge. 
 
 51 
 
 5920 
 
 99 
 
 90 
 
 0-91 
 
 )5 ?> 
 
 Orange-yellow. 
 
 1 
 
 6660 
 
 92 
 
 83 
 
 0-90 
 
 Calls green a little 
 blue ; white he 
 sees as white 
 
 Greenish-yellow. 
 
 43 
 
 5430 
 
 69 
 
 625 
 
 0-90 
 
 >> 5» 
 
 Yellowish-green. 
 
 40 
 
 5270 
 
 50 
 
 46 
 
 0-92 
 
 »» »» 
 
 Green. 
 
 32 
 
 4910 
 
 8-5 
 
 9 
 
 1-06 
 
 Sees blue as blue, 
 and white yel- 
 lowish 
 
 Greenish-blue. 
 
 31 
 
 4960 
 
 7 
 
 8 
 
 1-14 
 
 5» J» 
 
 Blue. 
 
 26 
 
 4680 
 
 3 
 
 3 
 
 1-00 
 
 J> J> 
 
 Blue. 
 
 His readings of luminosity were made without any 
 hesitation, and were concordant for each observation, 
 which is not to be wondered at, as the matches, except 
 
152 Colour Vision. 
 
 at the blue end, were practically matches of different 
 mixtures of black and white. 
 
 It appears that the white which X. sees as white is 
 the same as the orange sodium light, and that the red 
 he sees is yellowish. The mixture of this yellowish- 
 white with the blue makes white. He sees a little 
 blue in the spectrum colour at X 5720, so it must be 
 taken that at that point of the spectrum he begins 
 to see colour — a point which is considerably lower than 
 that given by his preliminary examination of the 
 spectrum colour, and due, no doubt, to the fact that 
 in this experiment he had the white light of the 
 positive pole of the electric light to compare with it. 
 It seems probable that w^hat X. called yellowish was 
 really a sensation of white mixed with a very small 
 quantity of red sensation, for he saw no yellow in the 
 orange, in which that colour would be most easily 
 distinguished on account of its luminosity. Eed light, 
 when strongly diluted with white light, to 'the normal 
 eye is often called orange. 
 
 As, practically speaking, the colour vision of X. is 
 confined to blue and white, it is of interest to note the 
 difference in luminosity at the different parts of the 
 spectrum that is registered by him and by P., who had 
 blue (violet) monochromatic vision. To facilitate the 
 
Luminosity Curves. 153 
 
 comparison, the luminosity curve of the latter is shown 
 
 Fig. 37. 
 
 in the diagram. 
 
 The thin line curve is the normal' curve. 
 
154 
 
 Colour Visiofi. 
 
 Perhaps, another case of a patient suffering from 
 tobacco blindness may be quoted, as it will show the 
 differences that exist in recognising the colours of the 
 spectrum, and that the shorter the visible limit of the 
 
 Table of Luminosity for G. See page 153. 
 
 
 
 .9 
 
 Colours named by G. 
 
 Colour of spectrum 
 
 to the 
 
 normal eye. 
 
 57 
 
 6423 
 
 
 
 
 Scarlet. 
 
 55 
 
 6242 
 
 3 
 
 No colour 
 
 
 53 
 
 6074 
 
 11 
 
 Colour " yellow," white " blue " 
 
 Red-orange. 
 
 51 
 
 5919 
 
 34 
 
 »» >> »» j» 
 
 Orange-yellow. 
 
 50 
 
 5850 
 
 60 
 
 >» »» »» »» 
 
 
 49 
 
 5783 
 
 64 
 
 Colour "gold," white "sky-blue " 
 
 Yellow^ 
 
 45 
 
 5538 
 
 59 
 
 
 
 40 
 
 6270 
 
 40 
 
 Both white 
 
 Green. 
 
 35 
 
 5042 
 
 18 
 
 j» 
 
 
 30 
 
 4848 
 
 10 
 
 5> 
 
 
 29 
 
 4807 
 
 6 
 
 Colour " very pale blue," white 
 as white 
 
 Blue. 
 
 26 
 
 4707 
 
 4 
 
 Culour " blue," white " white " 
 
 
 20 
 
 4518 
 
 3 
 
 »» n »> )» 
 
 
 10 
 
 4248 
 
 2 
 
 »» »> j> >» 
 
 Violet. 
 
 spectrum at the red end, the more pronounced is the 
 extent of the colour blindness. G. suffered from a very 
 well-marked tobacco scotoma, occupying a consider- 
 able area. His curve of luminosity of the spectrum is 
 shown in Fig. 37. The horizontal band beneath will 
 
Progressive Atrophy. 155 
 
 show the colours which the spectrum colours appeared 
 to match. 
 
 G. was tested for light sense by the extinction 
 method, and it appears that the final sensitiveness to 
 light at the central part of the eye was nearly 12 times 
 less than a person possessing normal sense. I may 
 mention that I have examined one, if not two cases 
 in which the patient was not only tobacco blind, but 
 also congenitally colour blind. Though interesting fot 
 record, they need not be given in full here. 
 
 With these specimens of examination I must leave 
 the cases of tobacco blindness. Although very impor- 
 tant, they by no means constitute the sole cases of 
 colour deficiency due to disease. I will give as an 
 instance a case of loss of colour sensation due to pro- 
 gressive atrophy of both eyes which was examined, with 
 Mr- Nettleship's aid. When tested with spectrum 
 colours — a patch of white light being placed in juxta- 
 position with the colour — it was found that W. S. was 
 absolutely blind to colour from 26*75 (X 4733) on the 
 scale of the spectrum to the termination of the red of 
 his spectrum, which was close to 63 on the scale (\ 7082). 
 Above scale No. 26*75 W. S. saw blue, and his spectrum 
 was continued normally in the violet. His luminosity 
 curve (Fig. 37) was made without any difficulty, and, 
 
156 
 
 Colour Vision, 
 
 compared with my own, shows a slight deficiency in 
 brightness from the red to the yellow, but his percep- 
 tion of luminosity increases as the blue is approached. 
 
 Table of Luminosity for W. S. See page 155. 
 
 
 i:3 
 
 tb 
 
 n 
 
 Spectrum colours named by W. S. 
 
 Spectrum colours 
 to normal eye. 
 
 60 
 
 6728 
 
 3-4 
 
 Grey 
 
 Scarlet. 
 
 58 
 
 6520 
 
 15-0 
 
 »> 
 
 
 h^ 
 
 6330 
 
 41-0 
 
 »» 
 
 
 55 
 
 6242 
 
 43 
 
 »5 
 
 
 64 
 
 6152 
 
 69 
 
 
 
 52 
 
 5996 
 
 94 
 
 
 
 50 
 
 5850 
 
 100 
 
 >» 
 
 Orange. 
 
 48 
 
 5720 
 
 96 
 
 
 
 45 
 
 5538 
 
 88 
 
 
 
 -42 
 
 5373 
 
 74 
 
 
 
 40 
 
 5270 
 
 61-5 
 
 " 
 
 Green. 
 
 38 
 
 5172 
 
 45 
 
 
 
 35 
 
 5042 
 
 30 
 
 
 
 30 
 
 4848 
 
 12 
 
 ?? 
 
 Blue. 
 
 25 
 
 4675 
 
 6 
 
 Bluish 
 
 
 20 
 
 4518 
 
 4 
 
 
 
 15 
 
 4376 
 
 3 
 
 Blue 
 
 Violet. 
 
 10 
 
 4248 
 
 2-5 
 
 ?» 
 
 
 He was subsequently tested with colour discs — Ultra- 
 marine (U), Red-royal (R), Emerald-green (G), Chrome- 
 yellow (Y), White (W), and Black (B). . . 
 
Progressive Atrophy. 157- 
 
 It was found that — 
 165 (U) + 48 (K) + 147 (G) = 1^ (W) + 285 (B). 
 
 The black reflected 3 • 4 of white ; hence the true 
 equation is — 
 
 (i). 165 (U) + 48 (K) + 147 (G) = 84 • 7 (W) + 275 (B). 
 (ii). 120 (11)4-240 (Y) = 196 (W) + 164 (B) (corrected)— 
 With 260 (U) + 100 (Y) he sees blue. 
 
 250 (U) + 110 (Y) „ light-blue. 
 242 (U) + 118 (Y) „ no blue. 
 
 This last in connection with (ii) shows that his blue 
 perception is neutralised by the yellow, although the 
 yellow to him was matched with white. 
 
 I have already shown you a chart of the insensitive 
 area of the retina found in a tobacco-blind case, and it 
 may be advisable that you should see an example of 
 the curtailment that exists, both for light and colour, 
 in the field of vision of eyes in which there is 
 progressive atrophy of the optic nerves. The large 
 black area shows the part of the field that was en- 
 croached upon. The dark spots show small areas which 
 are also insensitive. The field for colour shown by 
 the inner shaded area is also encroached upon, and 
 practically the patient was blind in a great part of 
 his field. His form vision was also very bad, and 
 his colour perception feeble. The three charts given 
 
158 
 
 Colour Vision, 
 
 in these lectures were brought by Mr. Nettleship, 
 for the information of the Colour Vision Committee 
 oi the Eoyal Society, and by his permission they are re- 
 produced here. 
 
 detail, one in 
 which the sen- 
 sation of colour 
 is totally ab- 
 sent in the left 
 eye, the right 
 eye being nor- 
 mal ; and the 
 other in which 
 there is colour 
 blindness of a 
 very rare cha- 
 ^ racter. The 
 first case is 
 that of a lady, 
 whom we will 
 call Miss W. 
 It appears from 
 
Colourless Vision, 159 
 
 the history of this lady that she had a slight stroke 
 of paralysis which affected her left side, and that she 
 subsequently found her left eye was deprived of all 
 
 I sensation of colour. It is said by the specialists who 
 examined her retina that this is a case of atrophy 
 of the optic nerve. She had very little difficulty 
 in matching the most brilliant spectrum colours with 
 the white patch of light. Her curve of luminosity 
 is given in Fig. 39 (see table, page 228). At 19 of 
 the scale, which is well in the blue, she had very 
 little sense of light, though her extinction curve 
 shows that it extended to some distance beyond. The 
 eye in which normal vision existed was, during the 
 examination of the defective eye, bound up with a 
 handkerchief, and when occasionally she was allowed 
 to use both eyes, her astonishment was great to see the 
 colours which she had matched with the white. The 
 curve of luminosity taken with her right eye coincided 
 with my own, which throughout we have taken as 
 normal. From her extinction curve we gather that 
 there was a marked diminution of sensitiveness to light 
 in her left eye compared with that of normal vision. 
 Apparently, in that eye she only has -^^ of the normal 
 sensitiveness to light near E in the-; green, but her 
 extinction curve takes the same general form as that 
 
i6o 
 
 Colour Visio7i, 
 
 of the normal eye. The diflference between the sets of 
 ordinates of the two indicates the difference in sensi- 
 tiveness for each part of the spectrum. 
 
 
 
 
 
 
 
 
 
 Fig. 
 
 39. 
 
 
 
 
 
 
 
 
 
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 Her persistency curve as calculated occupies the same 
 position and is of about the same dimensions, when tl e 
 
Colourless Vision. 
 
 i6i 
 
 maximum is made 100, as that of the normal eye, 
 as it is therefore of red- and green-blind, and also of 
 
 FiCx. 40. 
 
 The thin line curve is the curve of luminosity for the normal eye. 
 
 M 
 
1 62 Colour Vision, 
 
 the two cases of monocliromatic vision. We have in 
 Miss W. a type of colour blindness which no present 
 theory of colour vision accounts for without straining ; 
 and it would probably have to refer it to the seat of 
 sensation rather than to the retina alone. 
 
 The second is a case of congenital colour blindness 
 and with no trace of disease, brought by Mr. Nettleship 
 to the same Committee. He found that this lady, 
 N. W., mistook blue for red, and it was with some 
 curiosity that this case was examined. Her first 
 examination was as to colour sense with the spectrum 
 colours, a patch of monochromatic light being placed in 
 juxtaposition with an equal patch of white light. At 
 62*5 (X6890) of the scale the light of the spectrum 
 disappeared. As the slit moved along the spectrum, 
 and the white was approximately reduced to equal 
 luminosity, she described all the red as grey, and of the . 
 same colour as the white until 53*5 (X 6110). At. 
 this point she said the colour was brownish compared 
 with the white, and this hue continued to her till 48 , 
 on the scale (X 5720), when she said the colour was ^ 
 " neither brown nor green, but both." From 48 on > 
 the scale she described the colour as green, when it 
 changed quite suddenly at 31*5 (X 4905). From this^ 
 point and in the blue she again began to see grey ; 
 
Abnormal Colour Vision. 
 
 163 
 
 1 
 
 id 
 
 
 Colours named by N. W. 
 
 Spectrum colours 
 to normal vision. 
 
 60 
 
 6728 
 
 3 
 
 Both grey 
 
 Red. 
 
 68 
 
 6520 
 
 10 
 
 j» 
 
 
 56 
 
 6330 
 
 30 
 
 »♦ 
 
 
 54 
 
 6152 
 
 52 
 
 Colour " brownish," white 
 " grey " 
 
 
 52 
 
 5996 
 
 70 
 
 ?» 5» )» 
 
 
 50 
 
 5850 
 
 81 
 
 ») >» )> 
 
 Orange. 
 
 48 
 
 5720 
 
 87 
 
 Colour " brownish - green," 
 white " grey " 
 
 
 46 
 
 5596 
 
 90 
 
 Colour " green," white 
 " grey " 
 
 
 44 
 
 5481 
 
 88 
 
 II >> 
 
 
 42 
 
 5373 
 
 82 
 
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 40 
 
 5270 
 
 62-5 
 
 »j >» 
 
 Green. 
 
 38 
 
 5172 
 
 46 
 
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 35 
 
 5042 
 
 23 
 
 »> »» 
 
 
 32 
 
 4924 
 
 12-5 
 
 " '♦ 
 
 
 31 
 
 4886 
 
 10 
 
 Colour " brownish - grey," 
 white '* brownish-green." 
 
 
 30-5 
 
 4862 
 
 8-5 
 
 ?> 5> ?> 
 
 Blue. 
 
 25 
 
 4675 
 
 5 
 
 ?» 1» )» 
 
 
 20 
 
 4518 
 
 3 
 
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 15 
 
 4376 
 
 2-5 
 
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 10 
 
 4248 
 
 1-5 
 
 5> J» »» 
 
 Violet. 
 
 
 
 4010 
 
 0.| 
 
 »> »> >> 
 
 
 the grey at this end of the spectrum, and also of the 
 white patch, she called brownish-grey. This name 
 must evidently have been a mental distinction, as she 
 
 M 2 
 
164 Colour Vision, 
 
 described the red end and the white as grey only, and 
 not brownish-grey ; and, indeed, she was tested again 
 over that part of the spectrum, and adhered to the 
 previous naming. It would appear to be due to low 
 luminosity, which made the grey appear to her what she 
 called brownish, rather than to any actual difference in 
 hue. 
 
 Her curve of luminosity in the spectrum was next 
 taken, and her readings are given in the table above. 
 The curve is shown in Fig. 40. The shaded band 
 beneath it applies to her curve. Miss W.'s luminosity 
 curve is also repeated in the same figure for the sake of 
 comparison. 
 
 An endeavour was made to form a series of colour 
 equations with her eyesight by placing three slits in 
 different parts of the spectrum, but without success, 
 although a match with white was made in two posi- 
 tions. One slit was in the orange-red (52 of the scale), 
 another at E, and the third at G ; mixtures were made 
 which she said matched the white, but they were so 
 erratic that it was useless to measure the apertures. 
 When the slit in the violet was covered up, a white 
 patch being alongside as a comparison, she called the 
 mixture of red and green " brownish-green " ; when 
 -the slit in the red was covered she called the mixed 
 
Abnormal Colour Vision. 165 
 
 light of green and violet " green " ; and when the 
 green slit was covered up she called the purple colour 
 a " different kind of brown." 
 
 When the first slit was moved into the red near the 
 lithium line she called the colours " green," whenever 
 the green slit was uncovered. A piece of red glass 
 was placed in the white reflected beam, forming a red 
 patch, and a patch of the blue at scale No. 30*5 
 (X 4862) was placed alongside, and she matched them 
 in luminosity and in colour. (The dominant colour 
 of the signal glass in question was X 6220.) She 
 finally was tested with colour discs. 
 
 To make white she required 
 
 130 G + 113 R + 117 U = 72 W + 218 B. 
 
 She was then tried with the blue and green discs 
 alone and made a match — 
 
 258 U + 102 G = 65 W + 295 B. 
 
 An attempt was made to match with the green and 
 red discs alone, but this failed. 
 
 She matched the red disc alone with black and white, 
 and also the blue disc alone — 
 
 360 R = 56 W + 304 B (corrected), 
 
 360 U = 60 W + 300 B (corrected). 
 
 With any proportion of R and U mixed together she 
 
 matched a grey of approximately the same intensity as 
 
1 66 Colour Vision, 
 
 above, as it might be supposed she would from the 
 last two equations. 
 
 Taking the intensity curve of the light reflected from 
 the red disc, it was found to contain a great deal of the 
 part of the spectrum which she called brownish, viz., 
 from 33 • 5 to 48 on the scale, whereas the blue reflected 
 a trifle of this portion of the spectrum, as did also the 
 green ; and this may account for her making a match to 
 grey of U and G, and not of R and Gr, but it is hard to 
 see why she matched U alone and also R with the grey. 
 ' Reviewing the case, it seems that any perception of 
 colour is very small, and that the sensations are green 
 and much less red. From the equations it also seems 
 that she would have matched green with white and black 
 alone, and that 360 G = 75 W + 285 B. Perhaps the 
 explanation of the matches and names of colours may 
 be that a. proportion of colour may be mixed with 
 another without being perceived, but this colour so 
 hidden has still the capability of neutralising a certain 
 quantity of the complementary colour. 
 
( i67 ) 
 
 CHAPTER XIII. 
 
 You have been taken through much experimental work, 
 and possibly it may be thought that there has been too 
 much of it ; but now that we are coming to the more 
 practical part of the subject, it will become apparent 
 that a good working hypothesis is absolutely necessary 
 before effectual tests for colour vision can be carried 
 out, and that the reasons for its adoption should be 
 given in full. The question of colour blindness is one of 
 very practical importance, as in certain occupations it is 
 essential that colours should be accurately and quickly 
 known, and that no guess-work should be allowed. 
 Lives have without doubt been lost by a want of proper 
 knowledge of colours, both at sea and on railways. 
 The evidence that such is the case is, as a rule, it is 
 true, merely negative, though there are cases extant 
 where great losses which have occurred can be traced 
 to a deficiency in colour perception. If there be no 
 proper system of tests for ascertaining the defects of 
 
1 68 Colour Vision, 
 
 signal or look-out men in their colour sense, it is 
 palpable that positive evidence cannot be forthcoming, 
 and this is very much the state of things which 
 exists up to the present time. We hear of collisions 
 at sea and vessels foundering in consequence of the 
 rule of the road not being followed, but at the in- 
 vestigations which follow we have no record that the 
 question of colour perception of the look-out man has 
 been gone into, though there may be conflicting evi- 
 dence as to whether a red light or a green light was 
 shown. That danger from colour blindness is incurred 
 has for some time been recognised by the Board of 
 Trade, as it insists that all officers of the Mercantile 
 Marine must be tested for their sense of colour, and 
 that their certificates must be endorsed as having failed 
 to pass the colour test should they do so. For my own 
 part, I think endorsement of their certificate is quite 
 inadequate, for it is still open for shipowners to employ 
 them (of course at their own risk). A rejection for 
 colour vision should entail a withholding of the certifi- 
 cate altogether ; for it surely is as dangerous that a 
 signal should be misread as it is that the logarithm of 
 the sine of an angle should be misunderstood. If a 
 candidate fails in theoretical navigation, he is not 
 allowed a certificate, but if he only fails in a very 
 
Holmgren Tests. 169 
 
 practical part of his examination, his certificate is 
 merely endorsed. 
 
 The system employed by this department was a 
 defective one, and we know of many instances in which 
 candidates have passed the colour test, though they 
 ought to have been rejected, and are at present in the 
 service. The subject of testing for colour vision was 
 brought prominently forward some two or three years 
 ago, and a Committee of the Eoyal Society, to which 
 I acted as secretary, was requested to consider the 
 methods at that time in force on the railways and in 
 the mercantile marine, and to find one which was not 
 open to objection. It recommended the system that 
 had been elaborated by Holmgren, a Swedish physicist, 
 and known as Holmgren's test, which has long been 
 in force in Sweden and elsewhere. This system has, 
 I am glad to say, been adopted by the Board of 
 Trade, and by most of the railway companies in the 
 United Kingdom. There have been numerous indica- 
 tions that this change of method was necessary. Only 
 within the last month (April, 1894), for instance, I was 
 informed by the Medical Officer who had to examine 
 the employes on a certain railway in Scotland by the 
 Holmgren test that he had found some, amongst others 
 an engine-driver, who were colour blind, and pre- 
 
170 Colour Vision, 
 
 sumably unfit for tlie posts they occupied owing to this 
 defect. 
 
 There is one popular objection which is always made 
 against this test, or indeed against any proper test, 
 viz., that the examination is not made under the 
 same conditions which absolutely exist, nor with the 
 very lights which the candidates have to distinguish 
 from one another — that is, the red and green lights. 
 Let me beg of you to remark, that as a mere matter 
 of guessing, the chances are equal thafc a man would 
 name the light shown correctly. If you turn a man's 
 back to the light, and if he has a coin in his pocket and 
 deliberately calls heads red and tails green, he will have 
 a good chance of passing the test ; for, if he guessed 
 rightly three or four times, no one would fail to pass 
 him on his answers. The great point in a test is to 
 cause the candidate to do something to show that he 
 appreciates colour. It is this doing something and 
 saying nothing which is the important feature in the 
 Holmgren test. A man may be ignorant of the names 
 of colours — colour ignorant it is called — but he cannot 
 be ignorant of the colours themselves if he has normal 
 colour vision. As a matter of fact, the colour blind 
 may possibly distinguish between red and green lights 
 by having carefully noted, under ordinary conditions 
 
Basis for Tests. 171 
 
 of atmosphere, their different brightness, and by their 
 rlifference in saturation with their neutral colour. If 
 external conditions are altered, as they are in actual 
 daily life, these slight indications vanish, and the quick 
 naming of the colour to be read becomes a mere matter 
 of chance. A proper test should include all variations 
 that can occur in these respects. It cannot be too 
 strongly impressed upon every one that a man who is 
 colour blind to colours in ordinary daylight is equally 
 so in lamplight, although some shades of colour which 
 are well distinguishable by daylight may disappear 
 when the artificial light is used as the source of 
 illumination. 
 
 Now, on what scientific principles should a colour 
 test be founded? We must hark back to a theory 
 for a moment, and as it has been shown that for all 
 essential purposes that of Young answers, we will use 
 it as a good working hypothesis, and it was from this 
 theory that Holmgren himself reasoned. The red- or 
 green-blind see a grey in a part of their spectrum, 
 which to us who possess normal colour vision is green. 
 If then we present such a green to them, they would 
 match it with a grey. If, however, we have a 
 yellowish-green, which is pure green mixed with red, the 
 complete green-blind will not see the green in it, but 
 
172 Colour Vision. 
 
 only the red. The colour to him would be very pale red, 
 and as he sees all such greens and yellows and reds as 
 red more or less saturated, that is, more or less mixed 
 with his neutral colour, any one of these he would match 
 with a green. The red-blind, on the other hand, would 
 see all these colours as green, and he too might make 
 similar matches with them. Suppose now we have a 
 pink skein : the green-blind would see it as a white or 
 bluish- white, for a purple is white to him, and he would 
 match with it either greys or colours having a slight 
 excess of blue in them ; for a green is to him a neutral 
 colour. The red-blind, on the other hand, would see 
 but little green in the pink ; blue would predominate, 
 so he would choose mauves or blues amongst other 
 matches. 
 
 Acting on these principles, Holmgren selected his 
 test colours. He chose wools as the most convenient 
 for handling, and also because they present the same 
 colour without sheen when looked at in any direction. 
 His first test colour is a very pale green which con- 
 tained no blue. Its paleness is a point in its favour. 
 The colour is quite distinguishable by us normal-visioned 
 persons, but it might appear as grey to the red- and 
 green-blind ; for as we who possess normal vision may 
 mix a small percentage of colour with our neutral colour 
 
Test Skeins, 173 
 
 (white) without it being perceived, so may they with 
 theirs (white and green). As the green, when it is to us 
 saturated, would be nearly neutral coloured to them, the 
 very diluted colour which we see in the skein would to 
 them be masked by the addition of white. In any case, 
 if any colour be visible to them, it must be on the red 
 side of the neutral points. A candidate is given this 
 skein of wool, and from a heap of over a hundred skeins, 
 of varying degrees of saturation, amongst which are 
 drabs, yellows, yellow-greens, blue-greens, purples, pinks, 
 greys, and so on, he is asked to select others which 
 appear to him to be of the same colour as the 
 test-skein, though they may be darker or lighter. 
 He will, if colour blind, select some of the colours 
 already indicated. The second test-skein is a pink, 
 which is a purple diluted with white, but much 
 less so than the green, to which it is nearly a com- 
 plementary in daylight. The candidate is required to 
 select colours which match this, and according to his 
 selections is he pronounced as having normal colour 
 vision or as being colour defective (either completely or 
 partially) to the red or to the green. The case of violet 
 blindness is not important in reading the signals or- 
 dinarily used, and therefore in this test no special test- 
 skein is employed. Let us consider what colour we 
 
174 Colour Vision. 
 
 should use. The neutral colour to this form of colour 
 blindness is yellow. If, therefore, we pick out a pale 
 yellow skein, the candidate would pick out greys to 
 match it; or if we gave him the pink skein to 
 match, since he has no blue (violet) sensation, he 
 would match it with a pure red or with a purple. 
 
 Where monochromatic vision is under examination, 
 all skeins would be matched with one another indis- 
 criminately — blues, reds, greens, greys will all be a 
 match, some lighter and some darker than the test- 
 skein. I have been told by some who have carried 
 out examinations for colour blindness that this matching 
 is by no means so uncommon as is often imagined. In 
 future it is hoped that most of those who make these 
 matches may be examined by the spectrum test, as it 
 may turn out that a proportion of them will be most 
 valuable theoretical cases. 
 
 In making an examination with the Holmgren 
 test, it is almost unnecessary that the candidate should 
 take up a skein out of the heap of wools to form 
 a preliminary diagnosis. The colour blind will not 
 at once pick out an evident match, but will hesitate 
 and evince a desire to appear very accurate in his 
 choice. This indicates at once that there is something 
 amiss. He probably will pick up a skein of the right 
 
Practical Testing. 175 
 
 colour, place it against the test-skein, lay it down 
 and again take it up. Or he will pick up a skein 
 which is evidently incorrect and do the same thing, 
 but perhaps he will return it to the heap and take 
 up another which is equally bad. 
 
 He will fumble over making his matches, and 
 eventually have a heap by him which will at once 
 tell the examiner that he is colour defective. I may 
 as well give you an idea of the colours which the 
 colour blind will pick out by a simple experiment. 
 The heap of wools is on the table, and in the pure 
 white of the electric arc light, which is thrown on it 
 from the lantern, every colour is distinct in hue and in 
 intensity. On one side are placed the two important 
 test-skeins, the pale green and the pink. There can 
 be no doubt but that in that heap of wools there are a 
 large number which can be matched with each of them. 
 The red-blind, be it recollected, sees no red, and if I 
 can place in front of the lens of the lantern some 
 medium which cuts off the red as completely as 
 possible, the audience as well as myself will see the 
 colours approximately as the red-blind would do. Such 
 a medium is found in the same blue-green glass that is 
 used for signals on most railways and on board ship. 
 The green-blind, on the other hand, see no green, and if 
 
176 Colour Vision, 
 
 a medium can be found which when placed in the path 
 of the light allows no green to pass, the colours in the 
 heap being deprived of the green would be such as 
 would very nearly be the same as this type of colour 
 blind would see. This glass is covered with a film of 
 collodion in which fuschin and blue have been dissolved. 
 It transmits a fine purple and should answer our pur- 
 pose. That these two media are what we require 
 can be readily demonstrated by placing them in front 
 of the slit of the collimator of our colour apparatus and 
 throwing the spectrum on the screen. The spectrum 
 of white light is now on the screen, and when we place 
 the blue-green glass in front of the slit, we see that the 
 red is very nearly entirely extinguished, w^hilst if we 
 substitute for it the dyed collodionized glass the green 
 is absent. Now, placing the first glass in front of the 
 lantern lens and switching on the current, the wools are 
 illuminated with the bluish-green light. The green test- 
 skein appears green, and we can proceed to make our 
 matches, picking out the colours which appear the same, 
 but taking no heed as to their lightness or darkness. 
 A dozen skeins are now picked out, and I think the 
 audience will agree with me that the matches as viewed 
 in the green light are accurate. The glass is now with- 
 drawn, and the ordinary white light falls upon the skeins 
 
Matching Colours. 177 
 
 m my hand. They are a strangely variegated lot as now 
 seen ; we have green shades, yellows, and browns, and 
 greys. Such a variety would tell me that I was colour 
 deficient, but would not be, perhaps, decisive as to what 
 was the exact character of the deficiency. For if the 
 pink glass is placed in front of the lantern you will find 
 the same matches, with one or two exceptions, might 
 have been made. The blue-green glass is once more 
 placed in the beam, and this time I match the pink skein 
 with the wools. A certain number are picked out, and 
 the audience will agree with me that the matches are fair 
 ones. When, however, the glass is withdrawn from the 
 light and we see what colours have been selected, we 
 find that they consist of pale blues, mauves, pinks of 
 various shades, and cerise, and violet. The red in the 
 pink did not afiect my eyes any more than would it 
 the red-blind. I am evidently then in this light red- 
 blind, for if the pink glass replaces the blue-green, the 
 matches are impossible. While this coloured light is 
 illuminating the heap I will make matches again. 
 When made, the w^hite light is again thrown on the 
 selected skeins, and this time we have bluish-green 
 and neutral tint together with pinks. The reason of 
 this is evident, there is no green visible ; the bluish - 
 green contains besides blue a certain amount of yellow, 
 
 N 
 
1 78 Colour Vision. 
 
 which, in its turn, contains red, and the grey must be 
 pink. To the green-blind, for reasons already given, 
 the blue-green looks white, as does the pink, and there- 
 fore the two are matched together. The grey is also 
 degraded white to him, and therefore he also matches 
 that with them. The matches which the violet-blind 
 would make can be well exemplified by placing in the 
 beam of light a yellow glass, or a glass coated with 
 collodion in which " brilliant yellow " has been dis- 
 solved. By this plan, then, we can in some measure 
 produce the effect of colour blindness on ourselves, 
 and very interesting it is to compare theory with 
 the results obtained in this manner. There is no ne- 
 cessity to have recourse to the electric light for this 
 purpose. If matches are made with such media held 
 before the eyes in ordinary daylight, the same results 
 will be obtained. I have often examined through these 
 same media the matches made by the colour blind, and 
 been able at once to settle the nature of the 
 defective vision from which they were suffering. 
 It must be remembered that the colours transmitted 
 through these two glasses are not absolutely like the 
 whites which the two classes of colour blind see respec- 
 tively, though they approach it. 
 
 We can imitate even more exactly the matches that 
 
Matching Colours. 179 
 
 they would make by matcliing white light with a 
 mixture of red, green, and violet of the proper hues, 
 and covering up the red or green slit, and then placing 
 the test-skein and the matches in the colour so formed. 
 From the other skeins viewed in the same light can 
 be picked out the matches which would be possible. 
 There is very little chance, if any, of a mistake about 
 them being made when this plan is adopted. 
 
 y 2 
 
( i8o ) 
 
 CHAPTER XIV. 
 
 Holmgren's test, although a qualitative one, is most 
 accurate in allowing a diagnosis to be formed, but it 
 sometimes happens that a candidate is not satisfied that 
 he has failed in passing the test, and wishes for another 
 examination. Such a re-examination is best carried out 
 by the spectrum method, which I will now describe. 
 
 The test with the spectrum is a very decisive one, 
 and can be carried out with the patch apparatus (Fig. 3), 
 page 19. Personally, I like to have some idea of the 
 kind of colour blindness, if any, which exists by first 
 using the Holmgren test. Should these tests show that a 
 candidate is colour blind in any degree, a very excellent 
 beginning is to try and find his neutral point in the 
 spectrum — if he has one. To arrive at it we place two 
 patches of light on the screen, one of colour and the 
 other of white, the rotating sectors being in the last- 
 named beam, and ask him to say when the two colours 
 appear alike. It must be remembered that white is 
 coloured from the efiect of contrast as long as the 
 
spectrum Test. i8i 
 
 colour alongside differs from it. A good point de 
 depart is with the slit in the yellow, then to move it 
 into the red, and then gradually to push it into the 
 green. When here, if colour blind, he will say, '^ The 
 two patches are nearly alike, but that the white is 
 rather pink or green," as the slit gets further towards 
 the blue. The operator, whilst changing the colour, 
 alters the sectors so that the luminosities are about the 
 same. A point will be reached when the colour blind 
 will say, '' Now they are both alike, but one is rather 
 darker than the other." The sectors are altered until 
 he says they are both alike, and the observation is 
 satisfactory when he declares the two patches of light 
 are both alike in colour and in darkness. It is curious 
 how misleading the word brightness is to some people 
 who are uneducated. I find it much safer to ask 
 which is the darker colour, rather than which is the 
 brighter. A little patience will always enable you to 
 get a good observation. The place in the spectrum 
 which is the neutral point is now noted. The neutral 
 point is again found, but this time commencing in 
 the blue. The same procedure is adopted as before, 
 and we thus get a second reading for it, and the 
 two will be found to be very close to one another. 
 In difficult cases, four or five observations may be 
 
1 82 Colour Vision. 
 
 made, and the mean taken as a close approximation. 
 So far the spectrum test has not shown whether the 
 observer is red- or green-blind, except by comparing 
 the position of the neutral point with that usually 
 found by the two types. We have, however, an un- 
 erring criterion by the luminosity method. The red 
 is placed beside the white, and he is asked to say 
 which he considers the darker ; he will give an answer 
 of some kind, and probably protest that the two 
 colours are not alike. A soothing answer will disarm 
 his objection, and he will quickly see what you mean. 
 If he be red-blind he will match in brightness a bril- 
 liant red and a feeble white ; if he be green-blind he 
 will make a match very similar to normal vision. In 
 the case of the red-blind the slit is then moved into 
 the extreme red, when he will say he sees but one 
 patch of light, whilst the green-blind will see it as a 
 person of normal vision would do. If time permits, the 
 whole luminosity curve may be taken and registered. 
 This is not essential, but interesting for reference. 
 Where complete colour blindness exists, it should be 
 possible to cause him to match a green with a red. 
 To do this a second instrument, as described in page 
 18, may be used, but it is quite sufficient if a piece 
 of red glass, such as is used for railway signals, or of 
 
Matching Green with Red. 183 
 
 bottle-green glass, be placed in the white beam. There 
 is then a red or green patch alongside the patch of 
 spectrum colour. The red will stimulate the red sen- 
 sation of the green-blind, but not being spectrum red it 
 contains a certain amount of yellow, which stimulates 
 the green sensation if the observer be red-blind. The 
 green is of such a colour that it will stimulate both 
 the red and the green sensations. In the path of the 
 reflected beam between G and the prisms (Fig. 3) a 
 sheet of plain glass is inserted, which reflects a propor- 
 tion of white on to the red patch. The sectors are placed 
 in this beam. If the red glass is being used, the slit is 
 moved into the green near E, and the colour blind will 
 say that both are the same colour, but one darker than 
 the other. By opening or closing the slit in the spec- 
 trum, he will possibly say that both colours are alike 
 and of the same darkness, but he may say one is paler 
 than the other, in which case the white light must be 
 increased or diminished by means of the sectors till 
 equality of tone is established. This applies to the 
 red-blind and the green-blind. The former will require 
 a very bright red to match a feeble green, whilst with 
 the latter the red will require a fairly light green. 
 When the green glass is used the spectrum colour patch 
 should be red, and the match be made as before. With 
 
184 Colou7' Vision. 
 
 the violet-blind the neutral point will be in the yellow, 
 and with monochromatic vision matches can be made 
 throughout the spectrum. So far it will be seen that 
 no mention of any colour is required. It may next 
 be advisable to ask him the names of colours. This is 
 best done by placing the white patch of light over the 
 spectrum colour patch, and opening and closing, as 
 may be required, the sectors. If the sectors are 
 closed it is very probable that correct guesses may be 
 made, for then the colours will be saturated, and the 
 colour blind, if they are intelligent, will know that a 
 green to them is white or pale in colour compared 
 with red, though of the same hue. If white be mixed 
 with the red the wrong name is bound to be given, for 
 they will be unable to distinguish it from the green, 
 because it is then a less saturated colour. Passing from 
 green to red and mixing the colour more or less with 
 white, the most — I was going to say grotesque — telling 
 mistakes are made. A further excellent test is to place 
 a cell containing a solution of bichromate in the path 
 of the reflected beam, and cause the observer to match 
 its colour with the light coming through two slits, one 
 in the red near C, and the other in the green near E. 
 Defective colour perception will be well demonstrated. 
 There are various other artifices which can be employed 
 
Malmgerers. 185 
 
 in the spectrum test, which would be too long to re- 
 count here, and if there be two sets of apparatus the 
 tests are practically unlimited in number. 
 
 There are cases in which an observer who may 
 have normal vision may wish to be reported as colour 
 blind. A seaman's life is not always a happy one, 
 and a boy on a training-ship, knowing that a failure in 
 colour vision will free him from a sea life, may be 
 anxious to be told he has failed in colour vision. By 
 " coaching " in the Holmgren test he might manage 
 to obtain a " failure," but a malingerer is sure to be 
 detected by the spectrum method of testing. He may 
 call diluted red green, and he may declare he sees 
 a neutral point in the spectrum, but if he be tested 
 with the diluted colours near his supposed neutral 
 point, he is sure to fall into a trap. He will make a 
 mistake in calling a patch green when it ought to 
 be white, or white when it ought to be green, if he 
 were truly colour deficient — indeed, a malingerer has no 
 chance of escaping detection with the spectrum tests. 
 It is not an uninteresting experiment to get an acute 
 observer who has normal colour vision, and is accus- 
 tomed to the spectrum test, to feign colour blindness, 
 and examine him in this manner. He never fails to 
 make such mistakes as would lead to his detection. 
 
1 86 Colour Vision. 
 
 With the partially colour blind the same procedure 
 may be adopted. In examination by the Holmgren 
 wool test, slight mistakes will be made in matching the 
 first two test-skeins. With the spectrum test the red 
 will require a greater dilution with white before it will 
 be matched with a green, even if it can be matched at 
 all. Measures of the luminosity at four or five posi- 
 tions in the spectrum, extending from near the extreme 
 red to the blue, will give an unerring criterion of the 
 kind and extent of colour blindness from which they 
 are sufiering. The existence of a neutral point in the 
 spectrum is sufiicient to indicate that their blindness 
 is of a nature to be dangerous in certain occupations. 
 To some it may be a difiiculty how a neutral point can 
 be found in such cases, since all sensations are more or 
 less present. The reason, however, was explained on 
 page 96. 
 
( iS7 ) 
 
 CHAPTER XV. 
 
 Examples of colour blindness have been brought to 
 your notice, and various measurements made by per- 
 sons possessing normal and defective colour vision have 
 been recorded, but no attempt has been made to 
 discuss the two leading rival theories that have been 
 laid before you. Regarding these theories you may 
 expect me to say something, and to avow myself a 
 partisan of one or the other. This last I must decline 
 to do, though it will have been seen by the line that 
 I have taken in these lectures that the Young theory 
 attracts me. There are, however, difficulties in adapting 
 it to explain several facts of colour vision which seem to 
 render it, to say the least, incomplete. For instance, to 
 explain the colours produced by simultaneous contrast, 
 the Young theory has to betake itself into psychological 
 ground. I will show you some excellent examples of 
 contrast colours. We have upon the screen a patch of 
 white reflected light, superposed over a patch of red 
 
1 88 Colour Vision. 
 
 light. Placing a thin rod in the paths of the two 
 beams, we have two shadows — one illuminated by white 
 and the other by red, and lying between them a mixed 
 light of red and wiiite. The shadow illuminated by 
 the white does not appear white, but a bluish-grey. 
 When the spectrum colour is changed to orange the 
 blue is intensified, whilst when it is green, what should 
 be white appears of an orange-salmon colour. Other 
 colours give the white different hues which I need not 
 describe. 
 
 These contrast colours are usually said to be comple- 
 mentary to the spectrum colours employed, though it 
 must be recollected that what a complementary colour 
 should be is determined by the quality of the white 
 light which the two, when mixed, are made to match. 
 But recent measures of my own show that they are 
 not truly complementary in most instances, whatever 
 the white light may be. But w^hether they are or not 
 does not much matter when the explanation offered by 
 the followers of the Young theory is considered, for it is 
 asserted that such contrast colours have no real existence, 
 but are psychological, or — -what this comes to be — simply 
 delusions. If they are not real colours felt by the 
 retina, they have a very good resemblance to them, and 
 the same series of delusions are so persistent and so 
 
Contrast Colours. 1S9 
 
 constant for all normal vision that they can always be 
 measuxed as having a constant value. I bear in mind 
 the experiment in which the contrast colour, after being 
 produced, is isolated in the eye from the colour pro- 
 ducing it and the background, and the continuance of 
 the hue produced by the contrast. This retention may 
 be psychological, but there are no grounds to my mind 
 for saying that its production is due to the same cause, 
 more especially as experiments have been arranged to 
 show that one eye may see a contrast colour, whilst the 
 other may see it of its uncontrasted hue. In this last 
 experiment it can scarcely be conceived that one eye 
 should be subject to delusion, whilst the other was free 
 from it. If, then, we may presume that they are real 
 colours, the Young theory fails to explain them, and 
 the explanation offered by the Hering theory is much 
 more acceptable, as it propounds the idea that the 
 retina has to be considered as a whole, and that if 
 (say) red light is at work at one part its complemen- 
 tary colour (blue-green) must be felt at another. It 
 would be still more acceptable had it happened that the 
 contrast colours w^ere truly complementary, and if the 
 same action was noticeable when the adjacent part of 
 the retina was not also stimulated. 
 
 For what I may call the straightforward part of 
 
19^ Colour Vision, 
 
 colour vision, dealing with ordinarily bright colours, the 
 Young theory is amply sufficient ; but when we come 
 to the feeble luminosities and the colour fields, it is 
 again difficult to adapt to explain the phenomena ob- 
 served. When we reduce the luminosity of a coloured 
 ray sufficiently we feel the sensation of grey light : no 
 colour is felt. Why is this ? On the Hering theory it 
 is capable of the explanation that we have the white 
 sensation left unextinguished, but I fail to see any 
 explanation on the Young theory. When we take 
 colour fields with pure colours (see appendix, page 
 208), we are met with the unexplained difficulty that 
 the colour from a bright spot of light vanishes almost 
 suddenly towards the periphery of the retina, and is 
 replaced by a bright white light, and that the extent 
 of the field depends on the brightness of the colour. 
 This, perhaps, is the most telling observation which 
 can be recorded against the Young theory as it stands 
 at present. It has this support, however, in the 
 sequence of the phenomena observed, viz., when the 
 boundary for the colour which we will suppose to be 
 pure red is being taken (as described at page 11), 
 that close to the point where it bursts into pure white, 
 it assumes a pink colour {i.e., a mixture of red and 
 white), whilst, if the red be scarlet, containing accord- 
 
Voting V. Hering. 191 
 
 ing to this theory a little green sensation, it becomes 
 orange before white, showing that the red sensation is 
 dimmed slightly before the green, and so with the 
 other colours. What are called ^' after images " I have 
 not touched upon so far, nor shall I here, for it is at 
 this point that we step into very debateable ground. 
 The colours perceived in them are, as yet, not capable 
 of being put to the test of physical measurement, and 
 I must leave the psychologist or the physiologist to 
 account for them in their own way. 
 
 Viewing the Hering theory from a physical stand- 
 point, and in the light of colour measurement, it 
 appears to be deficient in several respects. To take 
 one point. We have seen that when blue and yellow 
 are mixed together to make white the sum of the 
 luminosities of the two colours separately is equal to 
 the luminosity of the white produced. According to 
 the Hering theory, the yellow colour contains a cer- 
 tain amount of the white-black sensation besides the 
 yellow sensation, as does also the blue colour besides 
 the blue sensation. The theory tells us that when 
 white is produced by the mixture, the blue sensation 
 undoes the work that the yellow sensation has done, 
 and the white sensation is alone left behind. If this 
 be the case, the sum of the separate luminosities can- 
 
iQ^* Colour Vision: 
 
 not be the same as tliat of the white produced, but 
 should be greater. The theory also has to be strained 
 sometimes to make it fit in with other observed facts. 
 Take, for instance, the case of persons who are called 
 red-blind and green-blind on the Young theory. "We 
 are told by the Hering theory that both are red-green- 
 blind — that is, blind to both green and red, and only 
 see blue and yellow — and that the only difference be- 
 tween them is that the former has his spectrum slightly 
 shortened at the red end, the maxima of the yellow- 
 blue sensations being shifted a little further towards 
 the violet end of the spectrum. The natural question 
 to ask is : Why this shift occurs ? Surely it is more 
 rational to adopt a theory w^hich does not require such a 
 supposition ? If the sensitive matter acted upon by the 
 yellow-blue rays be always of the same chemical com- 
 position, the shift cannot occur. It might, perhaps, 
 be allowed that one shift was practicable, but, unfor- 
 tunately, the shifts must become numerous when the 
 cases of partial colour blindness are to be accounted 
 for, and this would necessitate a constantly varying 
 chemical composition of this matter, and of that acted 
 upon by the red-green rays. 
 
 Again, in the extinction of the spectrum, the red and 
 the green sensations in quantities to neutralize one 
 
You7ig V. Hering. 193 
 
 another sliould be extinguished nearly together, even 
 allowing for what physiologists tell us is the case, that 
 the breaking down, or dissimulation, of cell tissue con- 
 tinues longer than its building up, but we find a large 
 difference between the two. As already indicated, the 
 luminosity curve of the feeble spectrum favours the 
 theory of Hering being that here we only have the 
 white-black sensation, and naturally the persistency 
 curves must be scored in its favour. But the cases of 
 B. C. and M., it seems to me, cannot be explained by 
 the theory without any undue straining or assumptions. 
 If we try and fit the cases of colour blindness due to 
 tobacco scotoma to the theory, we find that in many 
 cases yellow is not recognised, though blue is invariably. 
 If the blue be active, the yellow should also be so. 
 
 And here I may remark that it has been assumed 
 that the two classes of colour blindness are due to 
 difi'erent causes. A question to ask ourselves is whether 
 all colour blindness may not have been caused originally 
 by disease. In the congenital form, it is true, no disease 
 of the retina is traceable in the eye, and it is usually 
 hereditary, but it does not follow that the want of 
 response of the perceiving apparatus to certain sensa- 
 tions may not have been due to what, for want of a 
 better expression, I may call an hereditary partial 
 
194 Colour Vision. 
 
 paralysis of the perceiving apparatus. If this be so, 
 we have a connecting link between the two classes, and 
 then a perfect theory should explain both classes on the 
 same grounds. The suspicion that the monochromatic 
 vision of P. and Q. might possibly be due to disease 
 before birth, owing to the behaviour of their eyes under 
 certain conditions, would then be explicable. I have 
 no desire to press this view, though it seems to me to 
 be one which is not out of all reason, taking analogies 
 from other defects which are hereditary. 
 
 It has been usually accepted that the fields for blue 
 and yellow in the eye are approximately the same, as 
 are those of the green and red, and this has been taken 
 as showing the interdependence between the two pairs 
 according to the Hering theory. It has already been 
 pointed out that the question of extent of fields re- 
 quires still further investigation beyond that which 
 it has received, and measures made by the method 
 given on page 208 seem to cast a doubt as to 
 whether this interdependence can be upheld. It will 
 be noticed that the fields do not extend proportion- 
 ately on the nasal and temporal sides (see also Fig. 3). 
 It should also be remarked that the order of extent 
 of field for the different colours does not follow the 
 same order as their disappearance. A point that is 
 
Young V. Hering. 195 
 
 sometimes raised in favour of Hering's theory is the 
 negative image formed after the eye is fatigued by 
 hooking at bright red or bright green. The negative 
 images (see page 30) are said to be the complementary 
 of these colours. The Young theory tells us ' that the 
 red or the green sensation suffers fatigue by one or 
 other colour, and that when the eye subsequently rests 
 on a grey surface the other two sensations are chiefly 
 stimulated and cause the complementary colour. It is 
 said that it is easier to produce a negative green image 
 than a negative red image, and the adherents of Hering 
 tell us that this is due to the fact that destructive 
 action is more readily carried out than constructive. 
 In the Young theory, it is held that the green 
 sensation is always mixed with white, whilst the red 
 is fairly pure, and thus, for equal luminosities, the 
 surplus green sensation is much less stimulated than 
 the red, which offers a consistent explanation of this 
 fact. There are several other minor difficulties in the 
 way of accepting Hering's theory as it stands from a phy- 
 sical point of view, but we need not discuss them now. 
 
 The final sensation curves for the spectrum colours 
 on the Young theory are still under consideration, and 
 are not definitely fixed, though the observations made 
 have been very numerous. Eecently Helmholtz, in the 
 
 2 
 
196 Colour Vision, 
 
 last edition of his " Physiological Optics," has calcu- 
 lated, from Koenig's observations, that no one of the 
 three sensations is singly stimulated by any colour, 
 even at the extreme ends of the spectrum, and he 
 makes the three fundamental sensations vary consider- 
 ably from those given in these pages. Every colour 
 he states is considerably mixed with white light. The 
 calculations by which he arrived at this conclusion are 
 of a complicated nature, and I think if he had had 
 besides the colour equations of Koenig, the luminosities 
 and the extinction measures before him, there might 
 have been a modification of his views, for these last 
 give evidence to the contrary. 
 
 There is a possible modification of the Young theory 
 which would account for a good many of the pheno- 
 mena that are unaccounted for by it in its present 
 form, though it may raise new difficulties in the minds 
 of some. Let us suppose that each of the three sensa- 
 tions were compounded of fundamental liglit and of 
 colour in fixed and definite proportions, and not in 
 the same proportion in each ; and further that the 
 apparatus in the eye which was responsible for each 
 sensation had two functions, one of which was to 
 respond to the fundamental light sensation and the 
 other to the colour. One essential difference between 
 
Modified Young Theory. 197 
 
 this modification of the Young theory and that of 
 Hering is that, whilst in the latter the white sensation 
 is a sensation distinct from the colour sensations, in the 
 former it is a definite part of them. The fact that the 
 sensation of colour is lost before the sensation of light 
 is one of the greatest significance, and any theory 
 to be accepted must offer a reasonable explanation of 
 it. If the modification suggested be made, it accounts 
 for the existence of this residuum of light equally 
 as well as Hering's theory, and without its drawback. 
 It is not hard to imagine the apparatus which gives rise 
 to two sensations, on the assumption of different kinds 
 of atomic motion, induced by the ether motion, or at 
 least three kinds are possible. When extinction of 
 colour is made, the ether vibrations would have suffi- 
 cient energy to induce but one kind of motion ; and 
 when all light was extinguished from the same ray, they 
 would not be capable of inducing any sensible motion 
 whatever. In the case of Miss W., who saw all colours 
 as white, it might be that disease had entirely prevented 
 the first kind of motion in all three sensations, and 
 that in P. and Q. the red and green sensations were 
 absent or paralysed in their entirety, whilst the blue 
 sensation was left in full operation. In B. C. the blue 
 and red sensations would be similarly absent, leaving 
 
igS ColoM r Vision . 
 
 the green sensation unchanged. The coincidence of 
 their persistency and luminosity curves would then 
 indicate that the proportions of fundamental light and 
 colour remained the same throughout. Other examples 
 and considerations seem to indicate that the proportion 
 of colour to fundamental light is greatest in the red 
 sensation, next in the green, and least in the blue. 
 This would explain why with increasing intensities blue 
 appears white sooner than green, and much sooner 
 than red. The proposed modification would also offer 
 the necessary explanation as to the disappearance of 
 colour from the field. 
 
 Looking at colour vision from what I may call an 
 evolutionary point of view, the " light-colour " theory 
 commends itself as probable. There are many reasons 
 for thinking that the visual sensation first evolved was 
 that of light, subsequently followed by that of colour. 
 The first evolved colour sensation would appear to have 
 been the blue, and the last the red. The discussion of 
 this hypothesis would carry me beyond my limits, and 
 I must leave it thus baldly expressed for your 
 consideration. 
 
 For my own part, whatever theory of colour sensations 
 may prove to be the right one, I lean strongly to the 
 idea that the cause of vision will be found in chemical 
 
Colour Sensation and Photographic Action. 199 
 
 actioD, induced by the impact of the different wave- 
 lengths of light falling on sensitive matter. A white 
 substance may absorb all the wave-lengths found in the 
 spectrum, and if it have three sets of molecules, one of 
 which has an atom or atoms vibrating with the same 
 period as the waves of light which show a maximum 
 for one sensation and another for another, and so on, the 
 requirements for the colour sensations are met. It may 
 be that the sensitive part of the retina is like a photo- 
 graphic plate, but with this essential difference — that the 
 sensitive material is constantly changing. A photo- 
 graphic plate receives an impression which is not 
 recognisable by the eye, though it can be shown that a 
 change in the material does take place during the 
 impact of light, by electrical and other means. When 
 the eye receives an impression of light, Dewar has 
 shown that in this case also a current of electricity is 
 generated. Kecent published experiments of my own 
 have demonstrated that with a low intensity of light, 
 the chemical change that occurs in a photographic salt 
 is by no means proportionate to that which takes place 
 with a greater intensity. In the eye, too, there is a 
 limit of sensibility to very feeble light. Again, the 
 curves of the stimulation of the colour sensations to the 
 spectrum are closely of the same form as the curves 
 
200 Colour Vision. 
 
 of sensitiveness of the various sensitive salts used by 
 photographers. These are analogies and, of course, 
 must not be pressed too far. There must be such a 
 complexity in the sensitive material in the eye, both 
 chemical and physiological, that it may be that the 
 changes induced by light on the sensitive surface of the 
 retina have to be considered from both aspects. The 
 purely chemical change is naturally that to which a 
 physicist is most prone to incline, and his bias must 
 be discounted, as must also that of the physiologist. 
 
( ^oi ) 
 
 APPENDIX. 
 
 The following is extracted from Maxwell's paper. 
 
 The following table contains the means of four sets 
 of observations by the same observer (K.) : — 
 
 Table IV. (K.) 
 
 44-3 (20) 4-31-0 (44) + 27-7 (68) = W. 
 16-1 (28) + 25-6 (44) + 30-6 (68) = W. 
 22-0 (32) 4- 12-] (44) + 30-6 (68) = W. 
 6-4 (24) + 25-2 (36) + 31-3 (68) = W. 
 15-3 (24) + 26-0 (40) + 30-7 (68) = W. 
 19-8 (24) 4-35-0 (46) 4-30-2 (68) = W. 
 21-2 (24) + 41-4 (48) 4- 27-0 (68) = W. 
 22-0 (24) 4- 62-0 (52) 4- 13-0 (68) = W. 
 21-7 (24) 4- 10-4 (44) 4- 61-7 (56) = W. 
 20-5 (24) + 23-7 (44) 4- 40-5 (60) = W. 
 19-7 (24) + 30-3 (44) + 33-7 (64) = W. 
 18-0 (24) + 31-2 (44) 4- 32-3 (72) = W. 
 17-5 (24) + 30-7 (44) 4- 44-0 (76) = W. 
 18-3 (24; + 33-2 (44) + 63-7 (80) = W. 
 
 X. — Keduction of the Observations. 
 
 By eliminating W from the equations; above hy 
 means of the standard equation/^^\>fc^^^^^4^ 
 
 .^^ 
 
202 Appendix, 
 
 involving each of the fourteen selected colours of the 
 spectrum, along with the three standard colours ; and 
 by transposing the selected colour to one side of the 
 equation, we obtain its value in terms of the three 
 standards. If any of the terms of these equations are 
 negative, the equation has no physical interpretation as 
 it stands ; but by transposing the negative term to the 
 other side it becomes positive, and then the equation 
 may be verified. 
 
 The following table contains the values of the four- 
 teen selected tints in terms of the standards. To avoid 
 repetition, the symbols of the standard colours are 
 placed at the head of each column : — 
 
 
 Table VI. 
 
 
 Observer (K.) 
 
 (24) 
 
 (44) 
 
 (G8) 
 
 44-3 (20) = 
 
 18-6 
 
 + 0-4 
 
 + 2-8 
 
 16-1 (28) = 
 
 18-6 
 
 + 5-8 
 
 - 0-1 
 
 22-0 (32) = 
 
 18-6 
 
 + 19-3 
 
 - 0-1 
 
 25-2 (36) = 
 
 12-2 
 
 + 31-4 
 
 - 0-8 
 
 26-0 (40) = 
 
 3-3 
 
 + 31-4 
 
 - 0-2 
 
 35-0 (46) = 
 
 - 1-2 
 
 + 31-4 
 
 + 0-3 
 
 41-4 (48) = 
 
 - 2-6 
 
 + 31-4 
 
 + 3-5 
 
 62-0 (52) = 
 
 - 3-4 
 
 + 31-4 
 
 + 17-5 
 
 61-7 (56) = 
 
 - 3-1 
 
 + 21-0 
 
 + 30-5 
 
 40-5 (60) = 
 
 - 1-9 
 
 + 7-7 
 
 + 30-5 
 
 33-7 (64) = 
 
 - 1-1 
 
 + 1-1 
 
 + 30-5 
 
 32-3 (72) = 
 
 + 0-6 
 
 + 0-2 
 
 + 30-5 
 
 44-0 (76) = 
 
 + 1-1 
 
 + 0-7 
 
 + 30-5 
 
 63-7 (80) = 
 
 + 0-3 
 
 - 1-8 
 
 + 30-5 
 
Appendix, 203 
 
 Mr. James Simpson, formerly student of Natural 
 Philosophy in my class, has furnished me with thirty - 
 three observations taken in good sunlight. Ten of 
 these were between the two standard colours, and give 
 the following result :— 
 
 33-7 (88) + 33-1 (68) = W. 
 
 The mean errors of these observations were as 
 follows : — 
 
 Error of (88) = 2 • 5 ; of (68) = 2 • 3 ; of (88) + (68) 
 = 4-8 ; of (88) - (68) = 1-3. 
 
 The fact that the mean error of the sum was so 
 much greater than the mean error of the difference, 
 indicates that in this' case, as in all others that I have 
 examined, observations of equality of tint can be 
 depended on much more than observations of equality 
 of illumination or brightness. 
 
 From six observations of my own, made at the same 
 time, I have deduced the "trichromic" equation — 
 
 22-6 (104) + 26 (88) + 37-4 (68) = W ... (2) 
 
 If we suppose that the light which reached the 
 organ of vision was the same in both cases, we may 
 combine these equations by subtraction, and so find 
 
 22-6 (104) - 7-7 (88) +4-3 (68) = D. . . . (3) 
 
204 Appendix, 
 
 where D is that colour, the absence of the sensation of 
 which constitutes the defect of the dichromic eye. 
 
 The sensation w^hich I have in addition to those of 
 the dichromic eye is therefore similar to the full red 
 (104), but different from it in that the red (104) has 
 "7 '1 of green (88) in it which must be removed, and 
 4*3 of blue (68) substituted. This agrees pretty w^ell 
 w^ith the colour which Mr. Pole* describes as neutral 
 to him, though crimson to others. It must be re- 
 membered, however, that different persons of ordinary 
 vision require different proportions of the standard 
 colours, probably owing to differences in the absorptive 
 powers of the media of the eye, and that the above 
 equation (2), if observed by K., would have been 
 
 23(104) + 32 (88) + 31 (68) = W (4) 
 
 and the value of D, as deduced from these observers, 
 would have been 
 
 23 (104) - 1-7 (88) -~ 1-1 (68) = D . . . . (5) 
 in which the defective sensation is much nearer to the 
 red of the spectrum. It is probably a colour to which 
 the extreme red of the spectrum tends, and which 
 differs from the extreme red only in not containing that 
 small proportion of " yellow " light which renders it 
 visible to the colour blind. 
 
 * PLilosophical Transactions, 1859, Part I., p. 329. 
 
Appendix. 205 
 
 From other observations by Mr. Simpson tbe follow- 
 
 ino; results have been deduced : — 
 
 
 
 Table A. 
 
 
 
 
 (88) 
 
 (68) 
 
 
 (88) 
 
 (68) 
 
 (99-2 +) = 
 
 33-7 
 
 1-9 
 
 100 (96) = 
 
 108 
 
 7 
 
 31-3 (96) = 
 
 33-7 
 
 2-1 
 
 100 (92) = 
 
 120 
 
 5 
 
 28 (92) = 
 
 33-7 
 
 1-4 
 
 100 (88) = 
 
 100 
 
 
 
 33-7 (88) = 
 
 33-7 
 
 
 
 100 (84) = 
 
 61 
 
 11 
 
 54-7 (84) = 
 
 33-7 
 
 6-1 
 
 100 (82) = 
 
 47 
 
 21 
 
 71 (82) = 
 
 33-7 
 
 15-1 
 
 100 (80) = 
 
 34 
 
 33 
 
 99 (80) = 
 
 33-7 
 
 33-1 
 
 100 (78) = 
 
 22 
 
 47 
 
 70 (78) = 
 
 15-7 
 
 33-1 
 
 100 (76) = 
 
 10 
 
 59 
 
 56 (76) = 
 
 5-7 
 
 33-1 
 
 100 (72) = 
 
 1 
 
 92 
 
 36 (72) = 
 
 0-3 
 
 33-1 
 
 100 (68) = 
 
 
 
 100 
 
 33-1 (68) = 
 
 
 
 33-1 
 
 100 (64) = 
 
 
 
 83 
 
 40 (64) = 
 
 0-2 
 
 33-1 
 
 100 (60) = 
 
 3 
 
 60 
 
 55-5 (60) = 
 
 1-7 
 
 33-1 
 
 
 
 
 57-) = 
 
 0-3 
 
 33-1 
 
 i 
 
 
 
 In the table on the left side (99*2 +) means the 
 whole of the spectrum beyond (99*2) on the scale, and 
 (57 — ) means the whole beyond {bl) on the scale. The 
 position of the fixed lines with reference to the scale 
 was as follows : — 
 
 A, 116 ; a, 112 ; B, 110 ; C, 106 ; D, 98*3 ; E, 88 ; 
 F, 79 ; Gl, 61 ; H, 44. 
 
 The values of the standard colours in different parts 
 of the spectrum are given on the right side of the 
 above table, and are represented by the curves of 
 
2o6 Appendix. 
 
 Fig. 9, Plate II., where the left-hand curve represents 
 the intensity of the '' yellow " element, and the right- 
 hand curve that of the " blue " element of colour as it 
 appears to the colour blind. 
 
 The appearance of the spectrum to the colour blind 
 is as follows : — 
 
 From A to E the colour is pure " yellow," very faint 
 up to D, and reaching a maximum between D and E. 
 From E to one-third beyond F towards G the colour is 
 mixed, varying from " yellow " to " blue," and becoming- 
 neutral or " white " at a point near F. In this part of 
 the spectrum the total intensity, as given by the dotted 
 line, is decidedly less than on either side of it, and near 
 the line F, the retina close to the " yellow spot " is less 
 sensible to light than the parts further from the axis 
 of the eye. This peculiarity of the light near F is 
 even more marked in the colour blind than in the 
 ordinary eye. Beyond F the " blue " element comes to 
 a maximum between F and G, and then diminishes 
 towards H, the spectrum from this maximum to the 
 end being pure " blue." 
 
 The results given above wxre all obtained with the 
 light of white paper, placed in clear sunshine. I have 
 obtained similar results when the sun was hidden, by 
 using the light of uniformly illuminated clouds, but I 
 
Appendix. 207 
 
 do not consider these observations sufficiently free from 
 disturbing circumstances to be employed in calculation. 
 It is easy, however, by means of such observations, to 
 verify the most remarkable phenomena of colour 
 blindness, as, for instance, that the colours from red to 
 green appear to differ only in brightness, and that the 
 brightness may be made identical by changing the 
 width of the slit ; that the colour near F is a neutral 
 tint, and that the eye in viewing it sees a dark spot in 
 the direction of the axis of vision ; that the colours 
 beyond are all blue of different intensities, and that 
 any " blue " may be combined with any " yellow " in 
 such proportions as to form " white." These results I 
 have verified by the observations of another colour- 
 blind gentleman, who did not obtain sunlight for his 
 observations ; and as I have now the means of carrying 
 the requisite apparatus easily, I hope to meet with 
 other colour-blind observers, and to obtain their obser- 
 vations under more favourable circumstances. 
 
 Measurements of Colour Fields. 
 
 Some experiments in the measurement of the colour 
 fields in the horizontal direction with the pure spectrum 
 colours will help to show what importance is to be attached 
 
2o8 Appendix, 
 
 to the luminosity of the colour and the size of the spot of 
 light with which the observations are made. A yellow 
 and a blue of the spectrum were taken of such hues 
 that when mixed they formed a patch of white light 
 similar to the electric light. Their luminosities 
 were measured, and the yellow found to be 1 • 6 of the 
 light of an amyl-acetate lamp or 1*28 standard candles ; 
 the blue was -^^ of this luminosity. The fields for these 
 two colours were measured by automatically throwing 
 spots of each colour separately on a white card which 
 moved round a centre over which the eye was placed. 
 The light was subsequently diminished to \, \, and -§- 
 of the above values, and readings again made. The 
 following results were obtained with a spot of • 7 inch 
 diameter : — 
 
 Yellow. Blue. 
 
 Light. 
 
 Nasal side. 
 
 Temporal side. 
 
 Nafcal side. 
 
 Temporal side. 
 
 Full 
 
 33° 
 
 45° 
 
 35° 
 
 45° 
 
 i- 
 
 24° 
 
 36° 
 
 26° 
 
 38° 
 
 i 
 
 18° 
 
 24° 
 
 22° 
 
 32° 
 
 With a spot of • 3 inch diameter the following were 
 obtained : — 
 
 Qll 
 
 24° 
 
 32° 
 
 21° 
 
 27° 
 
 i 
 
 17° 
 
 28° 
 
 16° 
 
 22° 
 
 i 
 
 13° 
 
 16° 
 
 14° 
 
 . 20° 
 
 i 
 
 8° 
 
 10° 
 
 13° 
 
 1G° 
 
Appendix, ^2,09 
 
 It will ■ be evident how the field contracts as the 
 light is diminished in brightness, and also that the blue 
 field does not diminish equally with the yellow field, 
 but is more persistent. Again, it will be noticed 
 that the luminosity of the blue, for the same extent of 
 field to be covered, has to be much lower than for 
 the yellow. 
 
 The diminished area of the spot of light also 
 diminishes the field, and the same order of diminution 
 of field is obtained as with the larger spot. 
 
 Another set of experiments, made with the same 
 aperture of slit passed through the spectrum, and the 
 field taken at difi*erent points, give the following 
 results : — 
 
 Spectrum scale. 
 (See Fig. 41, page 210.) 
 
 58-6 
 
 o4-rt 
 
 50-6 
 
 46-6 
 
 42-6 
 
 38-6 
 
 34-6 
 
 30-6 
 
 26-0 
 
 22-G 
 
 .18*6 
 
 14-6 
 
 8-6 
 
 'asal side. 
 
 Temporal side. 
 
 18° • 
 
 35° 
 
 27° 
 
 46° 
 
 88° 
 
 47° 
 
 2o° 
 
 30° 
 
 21° 
 
 21° 
 
 17° 
 
 17° 
 
 22° 
 
 30° 
 
 25° 
 
 33° 
 
 33° 
 
 40° 
 
 37° 
 
 44° 
 
 28° 
 
 40° 
 
 22° 
 
 34° 
 
 20° 
 
 30° 
 
2IO 
 
 Appendix, 
 
 Here we see that although the luminosity of the 
 colour spots varies at the spectrum luminosity, the 
 
 Fig. 41. 
 
 Horizontal Field for spectrum colours 
 
 
 Li F E 
 
 D CLt 
 
 44 48 52 56 60 
 
 jectrum Scale 
 
 fields do not vary proportionally ; when the lumin- 
 osities of the green, yellow and red are made equal, the 
 fields become nearly equal on the nasal side. The 
 field for the blue, however, then becomes vastly larger 
 than that for the others, showing a peculiarity which 
 is very remarkable. 
 
 Eecently published experiments on colour fields 
 have been so largely based on the exigencies of the 
 Hering theory, that it is somewhat difficult to decide 
 their significance from any other aspect. 
 
Appendix. 
 
 2l\ 
 
 Table I. — Luminosity Cueves for the Normal Eye (see Fig. 20). 
 
 I. 
 
 11. 
 
 III. 
 
 IV. 
 
 _ V. 
 
 Scale 
 number. 
 
 Wave-length. 
 
 Outside yellow 
 spot. 
 
 Yellow spot. 
 
 Fovea 
 centralis. 
 
 64 
 
 7217 
 
 
 ' 
 
 
 
 63 : 
 
 7082 
 
 
 1 
 
 
 
 62 
 
 6957 
 
 1 
 
 2 
 
 2 
 
 
 61 
 
 6839 
 
 2 
 
 4 
 
 4 
 
 
 60 • 
 
 6728 
 
 3-5 
 
 7 
 
 8. 
 
 
 59 
 
 6621 
 
 7-5 
 
 12-5 
 
 15-5 
 
 
 58, 
 
 6520 
 
 12-5 
 
 21 
 
 24 
 
 
 57 
 
 6423 
 
 19 
 
 33 
 
 37:5 
 
 
 56 
 
 6330 
 
 27-5 
 
 50 
 
 60. 
 
 
 55 
 
 6242 
 
 35 
 
 65 
 
 77 
 
 
 54 
 
 6152 
 
 43 
 
 80 
 
 90, 
 
 
 53 
 
 6074 
 
 52-5 
 
 90 
 
 97. 
 
 
 52 
 
 5996 
 
 61-0 
 
 96 
 
 100 
 
 
 51 
 
 5919 
 
 71-0 
 
 99 
 
 100, 
 
 
 50 
 
 5850 
 
 79-0 
 
 100 
 
 98 
 
 
 49 
 
 5783 
 
 84 
 
 99 
 
 95, 
 
 
 48 
 
 5720 
 
 85 
 
 97 
 
 90. 
 
 
 47 
 
 5658 
 
 83-5 
 
 92-5 
 
 i 85 
 
 
 46 
 
 5596 
 
 81-0 
 
 87 
 
 79 
 
 
 45 
 
 5538 
 
 77-0 
 
 81 
 
 72:5 
 
 
 44 
 
 5481 
 
 72.5 
 
 75 
 
 66 
 
 
 43 
 
 5427 
 
 68-0 
 
 69 
 
 59 
 
 
 42 
 
 5373 
 
 62.5 
 
 62-5 
 
 51 
 
 
 41 
 
 5321 
 
 57 
 
 57 
 
 45 
 
 
 P 2 
 
212 
 
 
 Appendix, 
 Table I. — continued. 
 
 
 I. 
 
 II. 
 
 III. 
 
 IV. 
 
 V. 
 
 Scale 
 number. 
 
 Wave-length. 
 
 Outside yellow 
 spot. 
 
 Yellow spot. 
 
 Fovea 
 centralis. 
 
 40 
 
 5270 
 
 52 
 
 50 
 
 40 
 
 39 
 
 5221 
 
 46 
 
 42-5 
 
 32 
 
 38 
 
 5172 
 
 41-5 
 
 36 
 
 27-5 
 
 37 
 
 5128 
 
 37-5 
 
 29-5 
 
 22^0 
 
 36 
 
 5085 
 
 33-5 
 
 24 
 
 18 
 
 35 
 
 5043 
 
 30-0 
 
 18-2 
 
 14 
 
 34 
 
 6002 
 
 26-5 
 
 14-2 
 
 10 
 
 33 
 
 4963 
 
 24 
 
 10-5 
 
 8^4 
 
 32 
 
 4924 
 
 21 
 
 8-5 
 
 6-5 
 
 31 
 
 4885 
 
 18-5 
 
 7-0 
 
 5-5 
 
 30 
 
 4848 
 
 16-5 
 
 5-5 
 
 4-0 
 
 29 
 
 4812 
 
 14-5 
 
 4-7 
 
 3^5 
 
 28 
 
 4776 
 
 13-0 
 
 4-0 
 
 3^0 
 
 27 
 
 4742 
 
 11-5 
 
 3-5 
 
 2^0 
 
 26 
 
 4707 
 
 10.5 
 
 2-8 
 
 2^4 
 
 25 
 
 4675 
 
 9-4 
 
 2-3 
 
 2^1 
 
 24 
 
 4639 
 
 8-2 
 
 1-82 
 
 1-9 
 
 23 
 
 4608 
 
 7-3 
 
 1-6 
 
 1^5 
 
 22 
 
 4578 
 
 6-3 
 
 1-4 
 
 
 21 
 
 4548 
 
 5-7 
 
 1-2 
 
 
 20 
 
 4517 
 
 5-0 
 
 1.08 
 
 1-0 
 
 19 
 
 4488 
 
 4-5 
 
 •94 
 
 
 18 
 
 4459 
 
 4-0 
 
 •86 
 
 
 17 
 
 4437 
 
 3-6 
 
 •78 
 
 
 16 
 
 4404 
 
 3-1 
 
 •70 
 
 
Appendix, 
 
 2I3r 
 
 
 f 
 
 Pable I. — continued 
 
 
 
 
 i: 
 
 II. 
 
 III. 
 
 IV. 
 
 V. 
 
 Scale 
 number. 
 
 "Wave-length. 
 
 Outside yellow 
 
 spot. 
 
 Yellow spot. 
 
 Fovea 
 centralis. 
 
 15 
 
 14 
 
 13 
 
 12 
 
 11 
 
 10 
 
 9 
 
 8 
 
 7 
 
 6 
 
 5 
 
 4 
 
 4377 
 4349 
 4323 
 ' 4296 
 4271 
 4245 
 4221 
 4197 
 4174 
 4151 
 4131 
 4106 
 
 2-7 
 
 2-3 
 
 2-1 
 
 1-9 
 
 1-65 
 
 1-4 
 
 1-2 
 
 1-0 
 •88 
 •75 
 •63 
 •50 
 
 
 •62 
 •56 
 •50 
 ■45 
 •40 
 •34 
 
 30 
 •26 
 
 22 
 •18 
 
 16 
 
 14 
 
 •62 
 
 :, 
 
 
 
 ^-' 
 
 
 
 
 <' c* 
 
 C^ 
 
M4 
 
 Appendix, 
 
 Tables II. Lm> 1X1. — Curves of Luminosity of a Partially 
 Eed-Blind and of a Partially Green-Blind Person (see 
 Fig. 23). 
 
 
 
 Luminosity, 
 
 Scale number* 
 
 Wave-length. 
 
 
 
 
 
 
 Red-blind. 
 
 Green-blind. 
 
 64 
 
 7217 
 
 
 
 1 
 
 62 
 
 6957 
 
 1 
 
 2 
 
 60 
 
 6728 
 
 2 
 
 7 
 
 68 
 
 6520 
 
 6 
 
 21 
 
 66 
 
 6330 
 
 12 
 
 50 
 
 64 
 
 6152 
 
 26 
 
 80 
 
 62 
 
 5996 
 
 49 
 
 96 
 
 60 
 
 5850 
 
 70 
 
 98 
 
 48 
 
 5720 
 
 77 
 
 93 
 
 46 
 
 5596 
 
 77 
 
 83 
 
 44 
 
 - 5481 
 6373 
 
 70 
 
 70 
 
 42 
 
 1 \r 
 
 61 
 
 55 
 
 40 
 
 6270 
 
 47 
 
 40 
 
 38 
 
 6172 
 
 34 
 
 27 
 
 36 
 
 6086 
 
 23 
 
 18 
 
 34 
 
 6002 
 
 14 
 
 10 
 
 32 
 
 4924 
 
 8-5 
 
 5-5 
 
 30 
 
 4848 
 
 5-5 
 
 3*0 
 
 28 
 
 4776 
 
 4-0 
 
 2-5 
 
 26 
 
 4707 
 
 2-7 
 
 2-0 
 
 24 
 
 4639 
 
 1-8 
 
 1*8 
 
 22 
 
 4678 
 
 1-35 
 
 1-4 
 
 20 
 
 4517 
 
 1-1 
 
 la 
 
Appendix. 
 
 21 
 
 Table IV. — Luminosity of SrEcxRUM Eeduced in Intensity, so 
 THAT D = ^y^^. Amyl Lamp 1 Foot Distant (see Fig. 25). 
 
 Scale 
 numberi 
 
 Mean 
 reading. 
 
 55-6 
 
 . *5 
 
 53-6 
 
 5-5 
 
 51-6 
 
 13 
 
 49-6 
 
 23 
 
 47-6 
 
 40 
 
 45-6 
 
 57 
 
 43-6 
 
 70 
 
 41-G 
 
 79 
 
 39-6 
 
 78 
 
 37-6 
 
 74 
 
 35-6 
 
 ^^ 
 
 33-6 
 
 65 
 
 31-6 
 
 44-5 
 
 29-6 
 
 35 
 
 27-6 
 
 24 
 
 25-6 
 
 17 
 
 23-6 
 
 13 
 
 21-6 
 
 10 
 
 19-6 
 
 8 
 
 13-6 
 
 3 
 
 9-6 
 
 2 
 
 Mean rcadin* 
 reduced to 
 100 max. 
 
 •6 
 7-0 
 lG-7 
 29-7 
 50-0 
 71-2 
 87-5 
 98-7 
 97-5 
 92-5 
 82-5 
 68-7 
 55-2 
 43-7 
 30-0 
 21-7 
 16-7 
 12-5 
 
 io-{r 
 
 3-7 
 2-5 
 
 P. and Q.' 
 
 readings, 
 100 max. 
 
 2 
 
 3-6 
 
 8 
 
 22 
 
 44 
 
 69 
 
 93 
 100 
 
 99-5 
 
 96 
 
 89 
 
 77-5 
 
 61 
 
 45*5 
 
 33-5 
 
 25 
 
 18 
 
 13 
 9-5 
 4-2 
 2-5 
 
 Persistency- 
 curve for the 
 centre of 
 the eye. 
 
 2 
 
 3-6 
 
 8 
 22 
 44 
 69 
 93 
 
 99-5 
 98-5 
 93 
 84 
 71 
 
 63»5 
 36-5 
 24 
 16 
 10 
 
 8 
 
 6 
 
 3 
 
 2 
 
2i6 Appendix, 
 
 Table V. — Limit of Colour Vision (see Fig. 26.) 
 
 Scale 
 Number. 
 
 Wave- 
 Length. 
 
 Mean reading 
 of the colour 
 limit of the 
 spectrum D. 
 
 being 1 amyl 
 lamp in T^gths. 
 
 Luminosity of 
 
 the ordinary 
 
 spectrum. 
 
 Luminosity of 
 the rays when 
 each colour dis- 
 appears, each 
 ray having 
 the original 
 luminosity of 
 1 amyl lamp 
 
 61 
 
 6839 
 
 120 . 
 
 4 
 
 48-0 
 
 60 
 
 6728 
 
 67 
 
 ' 7 
 
 46^9 
 
 58 
 
 6520 
 
 26 
 
 21 
 
 54^6 
 
 56 
 
 6330 
 
 13 
 
 50 
 
 65-0 
 
 54 
 
 6152 
 
 9-5 
 
 80 
 
 76-0 - 
 
 52 
 
 5996 
 
 9-0 
 
 96 
 
 86-4 
 
 50 
 
 5850 
 
 9-0 
 
 100 
 
 90^0 
 
 48 
 
 5720 
 
 9-0 
 
 97 
 
 87^3 
 
 44 
 
 5481 
 
 9-5 
 
 75 
 
 71-3 
 
 40 
 
 5270 
 
 10-5 
 
 50 
 
 52-5 
 
 36 
 
 5085 
 
 12-5 
 
 24 
 
 30-0 
 
 32 
 
 4924 
 
 18 
 
 8.5' 
 
 15^3 
 
 28 
 
 4776 
 
 32 
 
 4-0 
 
 12-8 
 
 24 
 
 4639 
 
 55 
 
 1-8 - 
 
 12-0 
 
 20 
 
 4517 
 
 90 . 
 
 1-08 
 
 9^7 
 
 16 
 
 4404 
 
 160 
 
 •70 
 
 11-2 
 
 12 
 
 4296 
 
 250 
 
 •45 
 
 11-0 
 
 8 , 
 
 4197 
 
 400 
 
 •26 
 
 10/4 
 
 4 ^ 
 
 4106 
 
 700 
 
 •14 , 
 
 9;8 , 
 
Appendix, 
 
 2XT- 
 
 Table VI. — Extinction by Central Portion of Normal Eye 
 (see Fig. 28). 
 
 I. 
 
 II. 
 
 III. 
 
 IV. 
 
 V. 
 
 VI. 
 
 Scale 
 number. 
 
 Wave- 
 lengtli. 
 
 E. 
 
 Reduction of 
 
 original 
 
 luminosity 
 
 in milliontliB 
 
 to cause 
 
 extinction. 
 
 L. 
 
 Lumino- 
 sity of 
 
 original 
 beam. 
 
 ExL 
 
 100 • 
 
 Persistency 
 
 curve 
 
 650 
 
 E 
 
 (Maximum = 
 
 100). 
 
 64 
 
 7217 
 
 55,000 
 
 
 
 
 63 
 
 7082 
 
 30,000 
 
 1 
 
 300-0 
 
 
 62 
 
 7957 
 
 15,000 
 
 2 
 
 300-0 
 
 
 61 
 
 6839 
 
 7500 
 
 4 
 
 300-0 
 
 
 60 
 
 6728 
 
 3750 
 
 7 
 
 262-5 
 
 
 59 
 
 6621 
 
 1900 
 
 12-5 
 
 237-5 
 
 •34 
 
 58 
 
 6520 
 
 1050 
 
 21 
 
 220-5 
 
 •62 
 
 57 
 
 6423 
 
 650 
 
 33 
 
 214-5 
 
 1-0 
 
 56 
 
 6333 
 
 380 
 
 50 
 
 190-0 
 
 1.71 
 
 55 
 
 6242 
 
 272 
 
 65 
 
 176-8 
 
 2-38 
 
 54 
 
 6152 
 
 196 
 
 80 
 
 156-0 
 
 3-32 
 
 53 
 
 6074 
 
 140 
 
 90 
 
 126-0 
 
 4-64 
 
 52 ^ 
 
 5996 
 
 97 
 
 96 
 
 93-12 
 
 6-70 
 
 51 
 
 5919 
 
 57 
 
 99 
 
 56-43 
 
 11-40 
 
 
 50 
 
 5850 
 
 35 
 
 100 
 
 35-0 
 
 18-6 
 
 
 49 
 
 5783 
 
 24 
 
 99 
 
 23-76 
 
 . 27-1 
 
 ' 
 
 48 
 
 5720 
 
 17 
 
 97 
 
 16.49 . 
 
 ... 38-2 
 
 
 47 " 
 
 5658 
 
 12-6 
 
 ;92-5 
 
 11'65 
 
 : 51-6' 
 
 
 46 ' 
 
 5596 
 
 10-2 
 
 -87 
 
 8-87 ' 
 
 63-7 
 
 
 45 
 
 5538 
 
 8-6 
 
 81 
 
 6-97 ; 
 
 1 75-6 
 
 
 441 
 
 5481 
 
 . 7-4 
 
 75 
 
 5-55 '<- 
 
 r 87-81-; 
 
 
21 8 
 
 Appendix, 
 
 Table YI.-^-*-continued. 
 
 I. 
 
 II. 
 
 III. 
 
 IV. 
 
 V. 
 
 VI. 
 
 Scale 
 number. 
 
 Wave- 
 length. 
 
 E. 
 
 Reduction of 
 
 original 
 
 luminosity 
 
 in millionths 
 
 to cause 
 
 extinction. 
 
 L. 
 
 Lumino- 
 sity of 
 
 original 
 beam. 
 
 ExL 
 
 100. ■ 
 
 Persistency 
 
 curve 
 
 650 
 
 E 
 
 (Maximum = 
 
 100). 
 
 43 
 
 5427 
 
 6-7 
 
 69 
 
 4-62 
 
 97-0 
 
 42 
 
 5373 
 
 6-55 
 
 62-5 
 
 4-09 
 
 99-5 
 
 41 
 
 5321 
 
 6-5 
 
 57 
 
 3-705 
 
 100 
 
 40 
 
 5270 
 
 6-55 
 
 50 
 
 3-27 
 
 98^5 
 
 39 
 
 5221 
 
 6-65 
 
 42-5 
 
 2.83 
 
 97-5 
 
 38 
 
 5172 
 
 6-85 
 
 36 
 
 2-46 
 
 95-0 
 
 SI 
 
 5128 
 
 - . 7-2 • 
 
 29-5 
 
 2-12 
 
 90-0 
 
 36 
 
 5085 
 
 7-6 
 
 24 
 
 1-82 
 
 81-3 
 
 35^ 
 
 5043 
 
 8-15 
 
 18-2 
 
 1-48 
 
 80-0 
 
 34- 
 
 5002 
 
 8-8 
 
 14-2 
 
 1-25 
 
 74-0 
 
 33 
 
 4963 
 
 10-2 
 
 10-5 
 
 .1-07 
 
 63*0 
 
 32 
 
 4924 
 
 11-6 
 
 8-5 
 
 •988 
 
 56-0 
 
 31 
 
 4885 
 
 ^ 13-6 
 
 7-0 
 
 •952 
 
 47-7 
 
 30. 
 
 4848 
 
 16-3 
 
 5-5 
 
 •896 
 
 40*0 
 
 29 
 
 4812 
 
 20-5 
 
 4-7 
 
 •963 
 
 31-7 , 
 
 28 
 
 4776 
 
 ' 26-0 
 
 4-0 
 
 1-040 
 
 25-0 
 
 27 i ^ . 
 
 4742 
 
 . 31-0 
 
 3-5 
 
 1-085 
 
 20-9 . 
 
 26 
 
 4707 
 
 38-5 
 
 ,2-8 
 
 1-078 
 
 16-9 
 
 25u ■ ■ 
 
 > 4674 . 
 
 ".46-0 
 
 2-3 
 
 1-058 
 
 14-1 . 
 
 24 : 
 
 4639 
 
 - 56-0 
 
 . 1-82 
 
 1-019 
 
 11*6 
 
 23 
 
 - 4608 . 
 
 r 67-0 
 
 . 1-6 
 
 1072 
 
 : 9-7,. 
 
 22> 
 
 4578 
 
 . ■ 80 
 
 1-4 
 
 1-120 
 
 8»41S 
 
Appendix. 
 Table VI. — continued. 
 
 219 
 
 I. 
 
 II. 
 
 III. 
 
 IV. 
 
 V. 
 
 VI. 
 
 Scale 
 number. 
 
 Wave- 
 length. 
 
 E. 
 
 Bednction of 
 
 original 
 
 luminosity 
 
 in millionths 
 
 to cause 
 extinction. 
 
 L. 
 
 Lumino- 
 sity of 
 
 original 
 beam. 
 
 E xL 
 
 100. * 
 
 Persistency 
 
 curve 
 
 650 
 
 E 
 
 (Maximum = 
 
 100). 
 
 21 . 
 
 4548 
 
 95 
 
 1-2 
 
 1^140 
 
 7*22 
 
 20 
 
 4517 
 
 107 
 
 1-08 
 
 1-156 
 
 6-1 
 
 19 
 
 4488 
 
 124 
 
 •94 
 
 1-165 
 
 5-23 
 
 18 
 
 4459 
 
 140 
 
 •86 
 
 1-204 
 
 4-64 
 
 17 
 
 4437 
 
 160 
 
 •78 
 
 1-228 
 
 4-1 
 
 16 
 
 4404 
 
 180 
 
 •70 
 
 1^260 
 
 3^60 
 
 15 
 
 4377 
 
 200 
 
 •62 
 
 1^240 
 
 3^25 
 
 14 
 
 4349 
 
 220 
 
 *bQ 
 
 1-232 
 
 2*95 
 
 13 
 
 4323 
 
 240 
 
 •50 
 
 1-200 
 
 2^7 
 
 12 
 
 4296 
 
 270 
 
 •45 
 
 1-215 
 
 2^4 
 
 11 
 
 4271 
 
 300 
 
 •40 
 
 1-200 
 
 2-18 
 
 10 
 
 4245 
 
 335 
 
 •34 
 
 1-139 
 
 1-94 
 
 9 
 
 4221 
 
 375 
 
 •30 
 
 1-125 
 
 1-73 
 
 8 
 
 4197 
 
 430 
 
 •26 
 
 1-118 
 
 1^51 
 
 T 
 
 4174 
 
 490 
 
 •22 
 
 1^078 
 
 1-32 
 
 6 
 
 4151 
 
 510 
 
 •18 
 
 •918 
 
 1^27 
 
 6 
 
 4131 
 
 640 
 
 •16 
 
 1-024 
 
 1^01 
 
 4- 
 
 4106 
 
 750 
 
 •14 
 
 1-050 
 
 0-86 
 
 
220 
 
 Appendix, 
 
 Table YII. — Extinction by Whole Eye 
 (see Fig. 28). 
 
 1. 
 
 11. 
 
 • III. 
 
 IV. 
 
 V. 
 
 VI. 
 
 Scale ' 
 number. 
 
 Wave- 
 length. 
 
 E. 
 
 Reduction of 
 
 original 
 
 luminosity 
 
 in millionths 
 to cause 
 extinction. 
 
 L. 
 
 Luminosity 
 
 of 
 
 original 
 
 beam. 
 
 ExL 
 
 ■ 160 • 
 
 Persistency 
 
 curve 
 
 650 
 
 E 
 
 (Maximums 
 
 100). 
 
 38 
 
 37 
 
 36 
 
 35 . 
 
 34 
 
 33 
 
 32; 
 
 31 
 
 30 , . 
 29 ,, 
 
 28 ;. 
 
 27, . 
 
 26; . 
 
 24: 
 2^ 
 20 
 18 
 16 
 
 5172 
 5128 
 5085 
 5043 
 5002 
 4963 
 4924 
 4885 
 4848 
 4812 
 4776 
 4742 
 ; 4707 
 4639 : 
 4578 
 4517 
 4459 
 4404 
 
 
 6-9 
 
 7-1 
 
 7-4 
 
 7-7 
 
 8-0 
 
 8-4 
 
 8-8 
 
 9-4 
 
 10-0 
 
 10-7 
 
 11-5 
 
 13-0 
 
 14-5 
 
 18-5 
 
 23-0 
 
 30-0 
 
 39-0 
 
 51 
 
 . 41-5 
 
 . 37-5 
 
 . 33-5 
 
 , 30-0 
 
 , 26-5 
 
 24-0 
 
 , 21-0 
 
 - 18-5 
 
 . 16-5 
 
 , 14-5 
 
 , 13-0 
 
 . 11-5 
 
 . 10-5 
 
 , 8-2 
 
 6-3 
 
 5-0 
 
 4-0 
 
 3-1 
 
 2-86 
 2-66 
 2-48 
 2-31 
 2-12 
 2-02 
 1-85 
 1-74 
 1-65 
 1-55 
 1-49 
 1-49 
 1-52 
 1-52 
 1-45 
 1-50 
 1-56 
 1-59 
 
 94-2 
 
 91-6 
 
 87-8 
 
 84-4 
 
 81-2 
 
 77-5 
 
 73-8 
 
 69-2 
 
 65-0 
 
 60-6 
 
 56*5^ 
 
 50-0, 
 
 44-8 
 
 34-1 
 
 28-3 
 
 21-7 
 
 16-7 
 
 12-3 
 
Appendix. 
 
 2T.I 
 
 Table YII. — continued. 
 
 Scale 
 number. 
 
 14 
 12 
 10 
 8 
 6 
 4 
 2 
 
 
 II. 
 
 Wave- 
 length. 
 
 4349 
 4296 
 4245 
 4197 
 4151 
 4106 
 4063 
 4020 
 
 III. 
 
 E. 
 
 Reduction of 
 
 originat 
 
 luminosity 
 
 in millionths 
 
 to cause 
 
 extinction. 
 
 66 
 80 
 110 
 154 
 204 
 307 
 513 
 770 
 
 IV. 
 
 V. 
 
 L. 
 
 
 Luminosity 
 
 of 
 
 original 
 
 beam. 
 
 ExL. 
 160 
 
 2-3 
 
 1-52 1 
 
 1-9 
 
 1-52 
 
 1-4 
 
 1-54 
 
 1-0 
 
 1-54 
 
 •75 
 
 1-54 
 
 •5 
 
 1-54 
 
 •3 
 
 1-54 
 
 •2 
 
 1-54 
 
 VI. 
 
 Persistency 
 
 curve 
 
 650 
 
 E 
 
 (Maximum = 
 
 100). 
 
 9-85 
 8-12 
 5-91 
 4-22 
 3-18 
 2-11 
 1-26 
 •84 
 
 From 38 to 64 the extinction is the same as with the central 
 part of the eye. 
 
222 
 
 Appendix. 
 Table VIIL— P.'s Curves* (see Fig. 31). 
 
 I. 
 
 II. 
 
 III. 
 
 IV. 
 
 V. 
 
 VI. 
 
 vn. 
 
 Scale 
 number. 
 
 Wave- 
 length. 
 
 Mean 
 reading of 
 extinction 
 
 in 
 millionths 
 of original 
 luminosity. 
 
 Adopted 
 leading in 
 millionths 
 of original 
 luminosity. 
 
 Persistency 
 
 curve 
 
 680 
 
 ad. reading' 
 
 P.'s 
 
 luminosity 
 curve. 
 
 Absolute 
 luminosity 
 
 of 
 extinction. 
 IV. X VI. 
 
 14 
 
 I 
 [ 
 
 52 
 
 5996 
 
 68 
 
 68 
 
 10 
 
 7 
 
 34 
 
 50 
 
 5850 
 
 35 
 
 35 
 
 19-4 
 
 19 
 
 47-5 
 
 K 
 
 5720 
 
 17 
 
 17 
 
 40 
 
 39 
 
 47-3 
 
 46 
 
 5596 
 
 10-2 
 
 10 
 
 68 
 
 65 
 
 46-4 
 
 45 
 
 5538 
 
 9-3 
 
 9-0 
 
 76 
 
 76 
 
 48-8 
 
 44 
 
 5481 
 
 8-0 
 
 8-1 
 
 84 
 
 90 
 
 52-8 
 
 42 
 
 5373 
 
 7-2 
 
 7-2 
 
 94-5 
 
 98 
 
 50-3 
 
 40 
 
 5270 
 
 6-7 
 
 6-8 
 
 100 
 
 99 
 
 48-1 
 
 38 
 
 5172 
 
 7-2 
 
 7-0 
 
 97 
 
 97-5 
 
 48-7 
 
 36 
 
 5085 
 
 8*05 
 
 7-7 
 
 90 
 
 90 
 
 49-5 
 
 34 
 
 5002 
 
 8-05 
 
 8-4 
 
 81 
 
 80 
 
 47-9 
 
 32 
 
 4924 
 
 9-9 
 
 9-8 
 
 69 
 
 65 
 
 45-5 
 
 30 
 
 4848 
 
 13-2 
 
 12-5 
 
 54 
 
 50 
 
 44-6 
 
 28 
 
 4776 
 
 13-9 
 
 15-0 
 
 45-3 
 
 36 
 
 38-6 
 
 27 
 
 4742 
 
 16-8 
 
 17-0 
 
 40 
 
 31-5 
 
 38-2 
 
 26 
 
 4707 
 
 21-6 
 
 20-5 
 
 32 
 
 26-5 
 
 38-8 
 
 24 
 
 4639 
 
 30 
 
 27 
 
 25 
 
 19-5 
 
 37-6 
 
 22 
 
 4578 
 
 36 
 
 35 
 
 19 
 
 14 
 
 35 
 
 20 
 
 4517 
 
 42 
 
 45 
 
 15-5 
 
 10 
 
 32-2 
 
 16 
 
 4404 
 
 79 
 
 79 
 
 8-5 
 
 5-5 
 
 31-2 
 
 10 
 
 4245 
 
 180 
 
 190 
 
 3-6 
 
 2-5 
 
 32-2 
 
 6 
 
 4151 
 
 270 
 
 270 
 
 2-7 
 
 
 
 * In this and the next two Tables the intensity of the illumination of the D 
 ray before reduction is equal to that of an amyl-acetate lamp at one foot from a 
 screen. The figures iu Col. VII. are in millionths of the illumination of an 
 amyl-acetate lamp at one foot distant, every ray being made of that intensity. 
 
Appendix., 
 Table IX.— H. R.'s Curves (see Fig. 32). 
 
 223 
 
 J 
 
 I. 
 
 II. 
 
 III. 
 
 IV. 
 
 V. 
 
 VI. 
 
 vir. 
 
 Scale 
 number. 
 
 Wave- 
 length. 
 
 Mean 
 
 reading of 
 
 extinction in 
 
 millionths of 
 
 original 
 luminosity. 
 
 Adopted 
 reading in 
 millionths 
 of original 
 lumi- 
 nosity. 
 
 Persistency 
 
 curve 
 
 590 
 
 ad. reading* 
 
 Lumi- 
 nosity 
 curve. 
 
 Absolute 
 luminosity 
 of ex- 
 tinction 
 IV. X VI. 
 48 
 
 57 
 
 6423 
 
 1200 
 
 1200 
 
 •49 
 
 5 
 
 125 
 
 56 
 
 6330 
 
 900 
 
 850' 
 
 ' -69 
 
 7 
 
 124 
 
 55 
 
 6242 
 
 500 
 
 550 
 
 1-07 
 
 10 
 
 115 
 
 54 
 
 6152 
 
 250 
 
 250 
 
 2-36 
 
 17 
 
 88 
 
 53 
 
 6074 
 
 .. 
 
 150 
 
 3-93 
 
 25 
 
 78 
 
 52 
 
 5996 
 
 90 
 
 90 
 
 6-56 
 
 35 
 
 ^^ 
 
 51 
 
 5919 
 
 60 
 
 45 
 
 13-1 
 
 47 
 
 44 
 
 50 
 
 5850 
 
 27 
 
 27 
 
 21-8 
 
 57 
 
 32 
 
 48 
 
 5720 
 
 18 
 
 15 
 
 39-3' 
 
 m 
 
 21 
 
 46 
 
 5596 
 
 10 
 
 10 
 
 59 
 
 69 
 
 14 
 
 44 
 
 5481 
 
 9-3 
 
 8 
 
 73-8 
 
 64 
 
 11 
 
 42 
 
 5373 
 
 6-5 
 
 6-2 
 
 95-1 
 
 56-5 
 
 7 
 
 40 
 
 5270 
 
 5-9 
 
 5-9 
 
 100 
 
 45 
 
 5-5 
 
 38 
 
 5172 
 
 6 
 
 6 
 
 98-3 
 
 32 
 
 4 
 
 36 
 
 5085 
 
 .. 
 
 ^'^ 
 
 89-4 
 
 20 
 
 2-7 
 
 35 
 
 5043 
 
 7 
 
 7-2 
 
 81-9 
 
 16 
 
 2-4 
 
 .34 
 
 5002 
 
 .. 
 
 8 
 
 73-8 
 
 12-5 
 
 2-1 
 
 -32 
 
 4924 
 
 10 
 
 9-6 
 
 61-5 
 
 8 
 
 1-6 
 
 30 
 
 4848 
 
 11-5 
 
 12 
 
 49-2 
 
 6 
 
 1-5 
 
 28 
 
 4776 
 
 14-5 
 
 14-5 
 
 40-7 
 
 5 
 
 1-5 
 
 26 
 
 4707 
 
 20 
 
 17-5 
 
 33-7 
 
 4 
 
 1-5 
 
 24 
 
 4639 
 
 20 
 
 22 
 
 26-8 
 
 3 
 
 1-4 
 
 22 
 
 4578 
 
 .. 
 
 30 
 
 19-7 
 
 2-4 
 
 1-5 
 
 18 
 
 4459 
 
 55 
 
 57 
 
 10-4 
 
 1-3 
 
 1-5 
 
 14 
 
 4349 
 
 115 
 
 115 
 
 5-1 
 
 •7 
 
 1-7 
 
 10 
 
 4245 
 
 .. 
 
 160 
 
 3-7 
 
 '5 
 
 1-7 
 
 G 
 
 4151 
 
 200 
 
 200 
 
 2-9 
 
 •4 
 
 1-7 
 
c^24 :Appendix, 
 
 — ' Table X.— V. H.'s Curves (see Fig. 33). 
 
 Scale 
 number. 
 
 II. 
 
 III. 
 
 IV. 
 
 Wave- 
 length. 
 
 Mean 
 
 reading of 
 
 extinction in 
 
 millionths of 
 
 original 
 luminosity* 
 
 Adopted 
 reading in 
 millionths 
 of original 
 lumi- 
 nosity. 
 
 y. 
 
 VI. 
 
 Persistency 
 curve 
 
 530 
 
 ad. readiog* 
 
 Lumi- 
 nosity 
 
 VII. 
 
 Absolute 
 luminosity 
 of ex- 
 tinction 
 IV. X VI . 
 75 • 
 
 67 
 
 6423 
 
 500 
 
 500 
 
 1-1 
 
 31 
 
 206 
 
 56 
 
 6330 
 
 350 
 
 350 
 
 1-5 
 
 43 
 
 200 
 
 54 
 
 6152 
 
 200 
 
 180 
 
 2-9 
 
 61 
 
 146-4 
 
 52 
 
 5996 
 
 100 
 
 100 
 
 5-3 
 
 70 
 
 93-3 
 
 50 
 
 5850 
 
 40 
 
 40 
 
 13-3 
 
 73 
 
 38^9 
 
 48 
 
 5720 
 
 'i 
 
 25 
 
 21-2 
 
 69 
 
 23 
 
 46 
 
 5596 
 
 10 
 
 10 
 
 53-0 
 
 63 
 
 8-4 
 
 45 
 
 5538 
 
 6-5 
 
 6-5 
 
 81-6 
 
 58 
 
 5^0 
 
 44 
 
 5481 
 
 6-0 
 
 5-7 
 
 93 
 
 54 
 
 4^1 
 
 42 
 
 5373 
 
 5-5 
 
 5-3 
 
 100 
 
 46 
 
 3^3 
 
 40 
 
 5270 
 
 5-5 
 
 5-4 
 
 98-2 
 
 36 
 
 2-6 
 
 38 
 
 5172 
 
 5-7 
 
 5-7 
 
 93 
 
 24 
 
 1-8 
 
 36 
 
 5085 
 
 6-7 
 
 6-5 
 
 81-6 
 
 15 
 
 1-3 
 
 34 
 
 5002 
 
 7-0 
 
 7-0 
 
 75-7 
 
 9-5 
 
 •89 
 
 32 
 
 4924 
 
 8-5 
 
 8-5 
 
 62-3 
 
 7-0 
 
 •79 
 
 30 
 
 4848 
 
 10-7 
 
 10-5 
 
 50-5 
 
 5*0 
 
 •70 
 
 28 
 
 4776 
 
 16 
 
 16 
 
 33-1 
 
 3-7 
 
 •79 
 
 26 
 
 4707 
 
 .. 
 
 22-5 
 
 23-5 
 
 2-7 
 
 •81 
 
 24 
 
 4639 
 
 30 
 
 31 
 
 17-1 
 
 1-82 
 
 •75 
 
 22 
 
 4578 
 
 42-5 
 
 42 
 
 12-6 
 
 1-4 
 
 •78 
 
 20 
 
 4517 
 
 55 
 
 55 
 
 9-6 
 
 1-0 
 
 •73 
 
 16 
 
 4404 
 
 105 
 
 100 
 
 5-3 
 
 •7 
 
 •93 
 
 12 
 
 4296 
 
 175 
 
 170 
 
 3-1 
 
 •45 
 
 1-02 
 
 10 
 
 4245 
 
 200 
 
 200 
 
 2-7 
 
 •34 
 
 •91 
 
Appendix. 
 
 225 
 
 Table XI.— B. C.'s Curves (see Fig. 34). 
 
 I. 
 
 XL 
 
 iir. 
 
 IV. 
 
 V. 
 
 \L 
 
 Scale 
 number. 
 
 Wave- 
 length. 
 
 Adopted 
 
 reading in 
 
 hundred 
 
 thousandths. 
 
 Persistency- 
 curve 
 12,500 
 readings in V. 
 
 Lumino- 
 sity of 
 
 original 
 beam. 
 
 Absolute 
 luminosity 
 
 of 
 extinction 
 III. and V. 
 
 61 
 
 6839 
 
 7500 
 
 1-6 
 
 
 
 60 
 
 6728 
 
 5500 
 
 2-3 
 
 •5 
 
 27-5 
 
 59 
 
 6622 
 
 4000 
 
 3.1 
 
 1 
 
 40 ' 
 
 58 
 
 6520 
 
 2800 
 
 4-5 
 
 2 
 
 56 
 
 57 
 
 6423 
 
 2000 
 
 6-2 
 
 4 
 
 80 
 
 56 
 
 6330 
 
 1500 
 
 8-3 
 
 6 
 
 90 
 
 55 
 
 6242 
 
 1150 
 
 10-8 
 
 8 
 
 92 
 
 54 
 
 6152 
 
 950 
 
 13-1 
 
 11-5 
 
 109-2 
 
 53 
 
 6074 
 
 750 
 
 16-6 
 
 16 
 
 120 
 
 52 
 
 5996 
 
 580 
 
 21-6 
 
 21-5 
 
 125 
 
 51 
 
 5919 
 
 4S0 
 
 29 
 
 28-5 
 
 122-5 
 
 50 
 
 5850 
 
 350 
 
 36 
 
 37 
 
 129-5 
 
 49 
 
 5783 
 
 275 
 
 45-5 
 
 47 
 
 129-2 
 
 48 
 
 5720 
 
 215 
 
 58 
 
 60 
 
 129 
 
 47 
 
 5658 
 
 170 
 
 73-4 
 
 76 
 
 129-2 
 
 46 
 
 5596 
 
 140 
 
 89-3 
 
 92 
 
 129 
 
 45 
 
 5538 
 
 125 
 
 100 
 
 98 
 
 122-5 
 
 44 
 
 5481 
 
 125 
 
 100 
 
 100 
 
 125 
 
 43 
 
 5427 
 
 130 
 
 96-1 
 
 97 
 
 126 
 
 42 
 
 5373 
 
 150 
 
 83 
 
 85 
 
 127-5 
 
 41 
 
 5321 
 
 180 
 
 69-4 
 
 65 
 
 117 
 
 40 
 
 5270 
 
 215 
 
 59 
 
 45 
 
 96-7 
 
 39 
 
 5221 
 
 250 
 
 50 
 
 30 
 
 75 
 
 Q 
 
226 
 
 Appendix, 
 Table XI. — continued. 
 
 I. 
 
 11. 
 
 HI. 
 
 IV. 
 
 V. 
 
 VI. 
 
 Scale 
 number. 
 
 Wave- 
 length. 
 
 Adopted 
 reading in 
 hundred 
 thousandths. 
 
 Persistency 
 
 curve 
 
 32,500 
 
 readings in V. 
 
 Lumino- 
 sity of 
 original 
 beam. 
 
 Absolute 
 luminosity 
 
 of 
 extinction 
 III. and V. 
 
 38 
 
 5172 
 
 290 
 
 43 
 
 1-5 
 
 723.2 
 
 37 
 
 5128 
 
 335 
 
 37 
 
 16 
 
 53-6 
 
 36 
 
 5055 
 
 380 
 
 33 
 
 11-5 
 
 43-7 
 
 34 
 
 5002 
 
 500 
 
 25 
 
 7 
 
 35 
 
 32 
 
 4994 
 
 650 
 
 19 
 
 4 
 
 26 
 
 30 
 
 4848 
 
 850 
 
 14 
 
 2-5 
 
 23-3 
 
 28 
 
 4776 
 
 1100 
 
 11-4 
 
 2 
 
 22 
 
 26 
 
 4707 
 
 1500 
 
 8-3 
 
 1-5 
 
 22 
 
 24 
 
 4639 
 
 2000 
 
 6-2 
 
 1 
 
 20 
 
 22 
 
 4578 
 
 2700 
 
 4-6 
 
 5 
 
 13-5 
 
 18 
 
 4459 
 
 4750 
 
 
 
 
 14 
 
 4349 
 
 7500 
 
 
 
 
 10 
 
 4245 
 
 11000 
 
 
 
 
Appendix, 
 
 227 
 
 Table XII. — M.'s Luminosity Curve compared with the Normal 
 
 (see Fig. 30). 
 
 I. 
 
 II. 
 
 III. 
 
 IV. 
 
 V. 
 
 VI. 
 
 VII. 
 
 Scale 
 number. 
 
 Wave- 
 length. 
 
 Mean 
 reading. 
 
 Mean 
 reading 
 X 1-8. 
 
 Normal 
 luminosity 
 
 curve, 
 
 centre of 
 
 eye. 
 
 Difference 
 
 of last two 
 
 columns. 
 
 Difference 
 X 5-15. 
 
 61 
 
 6839 
 
 2 
 
 3-6 
 
 4 
 
 •4 
 
 2-57 
 
 59 
 
 6621 
 
 7 
 
 12-6 
 
 12-5 
 
 — •1 
 
 •61 
 
 57 
 
 6423 
 
 18 
 
 32-4 
 
 33 
 
 + •6 
 
 3-09 
 
 55 
 
 6242 
 
 36 
 
 64-8 
 
 65 
 
 •2 
 
 1-03 
 
 53 
 
 6074 
 
 49 
 
 88-2 
 
 89-5 
 
 1-3 
 
 6-71 
 
 52 
 
 5996 
 
 52 
 
 95-4 
 
 96-5 
 
 1-1 
 
 5-66 
 
 51 
 
 5919 
 
 54 
 
 97-2 
 
 99-5 
 
 2-3 
 
 11-8 
 
 50 
 
 5850 
 
 54 
 
 97-2 
 
 100 
 
 2-8 
 
 14-4 
 
 49 
 
 5782 
 
 52-5 
 
 94-5 
 
 99-5 
 
 5-0 
 
 25-7 
 
 48 
 
 5720 
 
 50 
 
 90 
 
 97 
 
 7-0 
 
 36-0 
 
 47 
 
 5658 
 
 46 
 
 82-8 
 
 92-5 
 
 9-7 
 
 49-9 
 
 46 
 
 5596 
 
 41 
 
 73-8 
 
 87 
 
 13-2 
 
 68-0 
 
 44 
 
 5481 
 
 32 
 
 57-6 
 
 75 
 
 17-4 
 
 89 
 
 42 
 
 5373 
 
 23 
 
 43-2 
 
 62.5 
 
 19-3 
 
 99 
 
 40 
 
 5270 
 
 17 
 
 30-6 
 
 50 
 
 19-4 
 
 100 
 
 38 
 
 5172 
 
 10 
 
 17-5 
 
 35-5 
 
 18 
 
 93 
 
 36 
 
 5085 
 
 4 
 
 7-2 
 
 24 
 
 16-8 
 
 86-5 
 
 34 
 
 5002 
 
 1-0 
 
 1-8 
 
 14-5 
 
 12-7 
 
 65-5 
 
 31 
 
 4885 
 
 •5 
 
 •7 
 
 6-5 
 
 5-8 
 
 37-7 
 
 28 
 
 4776 
 
 
 
 
 
 4 
 
 4 
 
 20-6 
 
228 
 
 Appendix, 
 
 Table XIII.— Miss W.'s Curves (see Fig. 39). 
 
 Scale 
 number. 
 
 Wave- 
 length. 
 
 Eeadings. 
 
 Extinction in 
 
 TOO 000- 
 
 Persistency 
 curve. 
 
 63 
 
 7082 
 
 
 
 
 
 62 
 
 6957 
 
 1 
 
 
 
 60 
 
 6728 
 
 7 
 
 
 
 68 
 
 6520 
 
 18 
 
 
 
 57 
 
 6423 
 
 28 
 
 
 
 56 
 
 6330 
 
 43 
 
 
 
 54 
 
 6152 
 
 76 
 
 900 
 
 2 
 
 52 
 
 5996 
 
 90 
 
 250 
 
 7 
 
 50 
 
 5850 
 
 95 
 
 130 
 
 13-5 
 
 48 
 
 5720 
 
 93 
 
 60 
 
 29 
 
 46 
 
 5596 
 
 83 
 
 34 
 
 61 
 
 44 
 
 54S1 
 
 71 
 
 22 
 
 80 
 
 42 
 
 5321 
 
 58 
 
 18-5 
 
 92 
 
 40 
 
 5270 
 
 4. 
 
 17-5 
 
 100 
 
 38 
 
 5172 
 
 32 
 
 18 
 
 94 
 
 36 
 
 5085 
 
 21 
 
 19-5 
 
 90 
 
 34 
 
 5002 
 
 12-5 
 
 22 
 
 79 
 
 32 
 
 4924 
 
 7 
 
 27 
 
 65 
 
 30 
 
 4848 
 
 4-5 
 
 34 
 
 51 
 
 28 
 
 4776 
 
 3-0 
 
 40 
 
 38-5 
 
 25 
 
 4675 
 
 1-5 
 
 60 
 
 29 
 
 20 
 
 4518 
 
 0-4 
 
 250 
 
 7 
 
 19 
 
 4488 
 
 0-0 
 
 350 
 
 6 
 
 16 
 
 4404 
 
 — 
 
 600 
 
 
( 229 ) 
 
 INDEX 
 
 Absorption by the Yellow 
 
 Spot 90 
 
 Artificial Spectrum . . 8;^ 
 Cases of Defective Colour 
 
 Vision unrecognised . 67 
 Clerk Maxwell's Colour- 
 Box 42 
 
 Clerk Maxwell's Colour 
 
 Curves 47 
 
 Colour, and the Sensations 
 
 required to produce it . 60 
 Colour Blindness due to 
 
 Disease 137 
 
 Colour-Blind Persons see a 
 
 Grey in the Spectrum . 05 
 Colour Discs .... 82 
 Colour Fields .... 18 
 Colour Matches made by 
 
 the Colour Blind . . 70 
 Colour Patch Apparatus . 18 
 Colour Patch Apparatus, 
 
 Original Form of . . 19 
 Comparison of the Young 
 
 and Hering Theory . 189 
 Complex Colours matched 
 
 by Simple Colours . . 22 
 Contrast Colours . . . 187 
 
 164 
 
 58 
 
 57 
 
 188 
 
 11 
 
 98 
 
 Curious Case of Congenital 
 Colour Blindness, A 
 
 Dalton Colour Blindness . 
 
 Daltonism, or Colour 
 Blindness .... 
 
 Defective Form Yision 
 connected with Colour 
 Deficiency due to Disease 
 
 Definition at different parts 
 of the Eetina 
 
 Enfeebled Spectrum Lu- 
 minosity .... 
 
 Exhibiting Colour Blind- 
 ness by Colour Discs . 74 
 
 Extinction and Persistency 
 Curves of Green -Blind 
 Persons 127 
 
 Extinction and Persistency 
 Curves of Monochro- 
 matic Yision . . . 125 
 
 Extinction and Persistency 
 Curves of Eed - Blind 
 Persons 127 
 
 Extinction of Colour . . 105 
 
 Extinction of Light by the 
 Centre and Periphery of 
 the Eye 114 
 
230 
 
 Index, 
 
 Extinction of Colour of 
 
 
 Luminosity of the Spec- 
 
 
 equal Luminosity . 
 
 110 
 
 trum to the Colour Blind 
 
 81 
 
 Extinction of Light in the 
 
 
 Luminosity of the Spec- 
 
 
 Spectrum .... 
 
 109 
 
 trum to the IN'ormal Eyed 
 
 78 
 
 Eye : Explanation of its 
 
 
 Malingerers, Detection of 
 
 185 
 
 Functions .... 
 
 3 
 
 Matching Colours by Mix- 
 
 
 Fatigue of the Retina . 
 
 G, 30 
 
 tures of Simple Colours 
 
 26 
 
 Field of View .... 
 
 10 
 
 Maxwell's Colour Equations 
 
 202 
 
 Fovea Centralis 
 
 4 
 
 Maxwell's Curves for Red 
 
 
 Fundamental Light . 
 
 34 
 
 Blindness .... 
 
 69 
 
 Green - Blind Person's 
 
 
 Measurement of Colour 
 
 
 Description of the Spec- 
 
 
 Fields 
 
 207 
 
 trum, A 
 
 64 
 
 Monochromatic Vision and 
 
 
 Green Monochromatic 
 
 
 the Spectrum . . 
 
 66 
 
 Vision 
 
 131 
 
 Number of Cones in the 
 
 
 Helmholtz Diagram of 
 
 
 Eye 
 
 8 
 
 Sensations . 
 
 38 
 
 Optograms 
 
 9 
 
 Heredity in Colour Blind- 
 
 
 Pellet Tests .... 
 
 146 
 
 ness . . ... 
 
 58 
 
 Pendulum Experiments . 
 
 36 
 
 Hering's Colour Vision 
 
 
 Persistency Curves 
 
 119 
 
 Theory 
 
 52 
 
 Primary Colours . 
 
 25 
 
 Hering's Theory not tri- 
 
 
 Primary Pigment Colours 
 
 27 
 
 chromic 
 
 57 
 
 Progressive Atrophy of the 
 
 
 Holmgren's Colour Tests . 
 
 169 
 
 Optic Nerve 
 
 153 
 
 Koenig's Colour Sensation 
 
 
 Purkinje's Figures . . 
 
 7 
 
 Curves 
 
 49 
 
 Purples 
 
 24 
 
 Lissajou's Figures . 
 
 37 
 
 Red and Green matched . 
 
 72 
 
 Luminosity of the Spec- 
 
 
 Red-Blind Person's Descrip- 
 
 
 trum to the Centre of 
 
 
 tion of the Spectrum, A 
 
 63 
 
 the Eye, the Fovea Cen- 
 
 
 Retina, Structure of . 
 
 6 
 
 tralis, and outside the 
 
 
 Retinal Fatigue . . . 
 
 6,30 
 
 Yellow Spot . . . 
 
 88 
 
 Rods and Cones . . . 
 
 8 
 
 Luminosity of the Spec- 
 
 
 Seat of Visual Sensation . 
 
 7 
 
 trum to partially Colour 
 
 
 Sensation Curves in Terms 
 
 
 Blind 
 
 86 
 
 of Luminosity . 
 
 93 
 
Index. 
 
 231 
 
 Sensitiveness of the Eye . 121 
 
 Simple Colours ... 17 
 Simulation of Red and 
 
 Green Blindness . . 175 
 Spectrum described by the 
 
 Tobacco Blind, The . 143 
 Spectrum Test for Colour 
 
 Blindness . . . . 181 
 
 Table of Wave-Lengths . 17 
 
 Tables 211 
 
 Tobacco Ambyopia . . 140 
 Tobacco Blindness, Ex- 
 amples of .... 148 
 
 Yiolet Blindness ... 73 
 Yisifeility of an Object in 
 
 light of different Colours 123 
 
 Visual Purple .... 9 
 White Monochromatic 
 
 Yision 158 
 
 Wool Test, The . . . 170 
 
 Yellow Spot .... 4 
 Yellow Spot and Colour 
 
 Mixtures, The ... 28 
 Young's Theory, Modifica- 
 tion of 196 
 
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