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 http://www.arcliive.org/details/courseofpuregeomOOaskwricli 
 
A COURSE 
 
 OF 
 
 PURE GEOMETRY 
 
HouHou: C. J. CLAY and SONS, 
 
 CAMBRIDGE UNIVERSITY PRESS WAREHOUSE, 
 
 AVE MARIA LANE. 
 
 ©laggoto: 50, WELLINGTON STREET. 
 
 ILetpjifi: F. A. BROCKHAUS. 
 
 i^eto Horfe: THE MACMILLAN COMPANY. 
 
 JSombag mtj Calcutta: MACMILLAN AND CO., Ltd. 
 
 [All Rights reserved] 
 
A COURSE 
 
 OF 
 
 PURE GEOMETRY 
 
 BY 
 
 E. H. ASKWITH, D.D. 
 
 Chaplain of Trinity College, Cambridge 
 
 CAMBRIDGE 
 
 at the University Press 
 1903 
 
hi 2^ 
 
 ■lZ^ZK;^l 
 
 CamfariUge : 
 
 PRINTED BY J. AND C. F. CliAY, 
 AT THE UNIVERSITY PRESS. 
 
PEEFACE. 
 
 ri^HIS book, as is obvious from its size, is not intended 
 to be an exhaustive treatise on Pure Geometry. It 
 consists of a course of lessons on the subject, which are 
 adapted to the requirements of students who, after laying 
 the foundations of Geometry in Euclid or his equivalent, 
 have studied the properties of the Conic Sections as 
 derived from their focus and directrix definition. 
 
 It is assumed that the reader has had practice in the 
 working of examples, and that he is in a position to go on 
 to some of the more modern developments of Geometry. 
 
 The methods of Coordinate Geometry are excluded 
 from this work, but not so its ideas, with which it is 
 supposed that the reader is already acquainted. 
 
 The writer of this book has been led to put together 
 these chapters by the feeling, which is the result of some 
 experience in teaching the subject, that no book at 
 present exists which exactly meets the needs of the 
 particular class of students he has in mind. He hopes 
 however that the present course may serve to prepare 
 students who wish to specialise in Pure Geometry to 
 
 a 3 
 
 217203 
 
VI PREFACE. 
 
 study some of the books on it already in existence. 
 Students of mathematics who do not seek to be specialists 
 in this particular .branch of the science will, it is hoped, 
 find in this course what is needed for their purpose. No 
 student of mathematics, however analytical his bent may 
 be, can afford to be ignorant of the modern methods of 
 Pure Geometry. 
 
 It is impossible to draw a hard and fast line between 
 Pure and Analytical Geometry. The distinction between 
 the two has become one of method rather than of idea, 
 when the ' principle of continuity,' whereby we pass from 
 real to imaginary points and lines, is admitted into Pure 
 Geometry. The notion of imaginary points and lines 
 would never have been arrived at at all but for the 
 methods of Coordinate Geometry. We take over this 
 notion into the field of Pure Geometry and thereby 
 greatly enlarge our view. 
 
 Detailed reference to other writers in regard to the 
 proofs given here of the various propositions is not 
 attempted. The present course of lessons is the result 
 of some years' experience on the part of the writer in 
 teaching the subject. In the course of this experience 
 he has adopted different ideas and methods from different 
 writers, with the result that he hardly knows what he 
 owes to each. But he is sure that he is specially indebted 
 to Casey, Lachlan and J. W. Russell, all of whose text- 
 books he has had occasion to use with his pupils. It will 
 however be seen by those who have knowledge of text- 
 books at present existing that the course here offered for 
 
PREFACE. Vll 
 
 the use of the student has a character of its own. Were 
 this not so its publication would not be justified. 
 
 The exercises at the end of each chapter are for the 
 most part taken from papers set in the mathematical 
 tripos or in the college examinations. Some are original 
 and a few have been borrowed from other writers. Several 
 of the propositions set as exercises at the end of Chapter 
 VI. are given as book-work in Dr Lachlan's Modern Pure 
 Geometry. 
 
 Without considerable practice in the exercises the 
 student cannot hope to make the contents of the different 
 chapters his own. Each set of exercises should be taken 
 in hand after the reading of the chapter to which it 
 belongs. 
 
 The thanks of the author are due to his former pupil, 
 Miss Julia Bell, of Girton College, for kindly revising the 
 proof-sheets and suggesting several improvements. 
 
 In conclusion acknowledgment should be made of the 
 efficiency of the University Press in the carrying out of 
 their part of this work. 
 
 Cambridge. 
 May 1903. 
 
CONTENTS. 
 
 CHAPTER I. 
 
 SOME PROPERTIES OF THE TRIANGLE. 
 
 PAGE 
 
 Definitions 1 
 
 Orthocentre. Nine-points circle ...... 2 
 
 Pedal line 7 
 
 Medians 9 
 
 CHAPTER II. 
 
 SOME PROPERTIES OF CIRCLES. 
 
 Poles and polars 15 
 
 Radical axis 20 
 
 Coaxal circles . . " 22 
 
 Common tangents 25 
 
 CHAPTER III. 
 
 THE USE OF SIGNS. CONCURRENCE AND COLLINEARITY. 
 
 Signs of lines, areas, angles 32 
 
 Menelaus' and Ceva's theorems 36 
 
 Isogonal conjugates. Symmedians 42 
 
X CONTENTS. 
 
 CHAPTER lY. 
 
 PROJECTION. 
 
 General principles 
 
 Projection of conic into circle .... 
 
 Poles and polars 
 
 One range of three points projective with any other 
 
 CHAPTER V. 
 
 CROSS-RATIOS. 
 
 Definition 
 
 Twenty-four cross-ratios reducible to six 
 
 Projective property of cross-ratios 
 
 Equicross ranges and pencils mutually projective 
 
 CHAPTER VI. 
 
 PERSPECTIVE. 
 
 Definition 
 
 Ranges and pencils in perspective 
 nomographic ranges and pencils . 
 Triangles in perspective 
 
 CHAPTER VII. 
 
 HARMONIC SECTION. 
 
 Definition and properties of harmonic ranges 
 
 Harmonic property of pole and polar 
 
 Harmonic property of quadrilateral and quadrangle . 
 
 Self-polar triangle 
 
 Properties of parabola and hyperbola obtained by projection 
 
CONTENTS. XI 
 
 CHAPTER YIII. 
 
 SOME PROPERTIES OF CONICS. 
 
 PAGE 
 
 Camot's theorem 106 
 
 Newton's theorem 108 
 
 Constant cross-ratio property of conies . . . .109 
 Pascal's and Brianchon's theorems 114 
 
 CHAPTER TX. 
 
 RECIPROCATION. 
 
 Principles 119 
 
 Keciprocation applied to conies 124 
 
 Case where auxiliary or base conic is a circle . . .127 
 Reciprocation of coaxal circles into confocal conies . . 131 
 Self-conjugate triangles. Reciprocal triangles . . .133 
 
 CHAPTER X. 
 
 INVOLUTION. 
 
 Definition and criterion of involution range . . .140 
 
 Projection and reciprocation of range in involution . . 144 
 Involution property of quadrangle and quadrilateral . . 145 
 
 Involution properties of conies 147 
 
 Orthogonal involution 149 
 
 Involution range on conic 152 
 
 CHAPTER XL 
 
 CIRCULAR POINTS. FOCI OF CONICS. 
 
 Definition of circular points 157 
 
 Analytical point of view 158 
 
 Properties of conies obtained by using circular points . 160 
 Extended definition of focus and directrix , . . .161 
 
 Properties 162 
 
 Two triangles whose sides touch the same conies . . 166 
 
 Generalisation by projection 167 
 
Xll CONTENTS. 
 
 CHAPTER XII. 
 
 INVERSION. 
 
 PAGE 
 
 Inversion of circle and line 175 
 
 Inversion of sphere 178 
 
 Inversion of inverse points into inverse points . . .180 
 Feuerbach's theorem 182 
 
 CHAPTER XIII. 
 
 SIMILARITY OF FIGURES. 
 
 nomothetic figures 188 
 
 Figures directly similar 190 
 
 Figures inversely similar 193 
 
 Miscellaneous Examples 198 
 
CHAPTER I. 
 
 SOME PROPERTIES OF THE TRIANGLE. 
 
 1. Definition of terms. 
 
 (a) By lines, unless otherwise stated, will be meant 
 straight lines. 
 
 (b) The lines joining the vertices of a triangle to the 
 middle points of the oppos-ite sides are called its medians. 
 
 (c) By the circumcircle of a triangle is meant the 
 circle passing through its vertices. 
 
 The centre of this circle will be called the circiim- 
 centre of the triangle. 
 
 The reader already knows that the circumcentre is 
 the point of intersection of the perpendiculars to the 
 sides of the triangle drawn through their middle points. 
 
 (d) The incircle of a triangle is the circle touching 
 the sides of the triangle and lying within the triangle. 
 
 The centre of this circle is the incentre of the triangle* 
 The incentre is the point of intersection of the lines 
 bisecting the angles of the triangle. 
 
 {e) An ecircle of a triangle is a circle touching one 
 side of a triangle and the other two sides produced. 
 There are three ecircles. 
 
 A. G. 1 
 
"l SOME PROPERTIES OF THE TRIANGLE. 
 
 The centre of an ecircle is called an ecentre. 
 
 An ecentre is the point of intersection of the bisector 
 of one of the angles and of the bisectors of the other two 
 external angles. 
 
 (/) Two triangles which are such that the sides 
 and angles of the one are equal respectively to the sides 
 and angles of the other will be called congruent. 
 
 If ABC be congruent with A'B'C, we shall express 
 the fact by the notation: AABC= A A'B'C. 
 
 2. Proposition. The perpendiculars jrom the ver- 
 tices of a triangle on to the opposite sides meet in a point 
 {called the orthocentre) ; and the distance of each vertex 
 from the orthocentre is twice the perpendicidar distance 
 of the circumcentre from the side opposite to that vertex. 
 
 Through the vertices of the triangle ABC draw lines 
 parallel to the opposite sides. The triangle A'B'C thus 
 
SOME PROPERTIES OF THE TRIANGLE. 3 
 
 formed will be similar to the triangle ABG, and of double 
 its linear dimensions. 
 
 Moreover A, B, G being the middle points of the sides 
 of A'B'G\ the perpendiculars from these points to the 
 sides on which they lie will meet in the circumcentre of 
 A'B'G'. 
 
 But these perpendiculars are also the perpendiculars 
 from A, B, (7 to the opposite sides of the triangle ABG. 
 Hence the first part of our proposition is proved. 
 
 Now let P be the orthocentre and the circumcentre 
 of ABG. 
 
 Draw OD perpendicular to BG. 
 
 Then since P is also the circumcentre of the triangle 
 A'B'G\ PA and OD are corresponding lines in the two 
 similar triangles A'B'G\ ABG. 
 
 Hence AP is twice OD. 
 
 3. Definition. It will be convenient to speak of 
 the perpendiculars from the vertices on to the opposite 
 sides of a triangle as the perpendiculars of the triangle ; 
 and of the perpendiculars from the circumcentre on to the 
 sides as the 'peiyendiculai^s from the circumcentre. 
 
 4. Prop. The circle through the middle points of the 
 sides of a triangle passes also through the feet of the 
 perpendiculars of the triangle and through the middle 
 points of the three lines joining the orthocentre to the 
 vey^tices of the triangle. 
 
 Let D, E, F be the middle points of the sides of the 
 triangle ABG, L, M, N the feet of its perpendiculars, 
 the circumcentre, P the orthocentre. 
 
 Join FD, DE, FL, LE. 
 
 1—2 
 
SOME PROPERTIES OF THE TRIANGLE. 
 
 Then Ksince E is the circumcentre of ALC, 
 ZELA^ZEAL. 
 
 And for a like reason 
 
 ,::FLA=zFAL 
 .-. z.FLE = Z.FAE 
 
 =■ Z FDE since AFDE is a parallelogram. 
 
 .'. X is on the circumcircle oi DEF. 
 Similarly M and N lie on this circle. 
 
SOME PROPERTIES OF THE TRIANGLE. O 
 
 Further the centre of this circle lies on each of the 
 three lines bisecting DL, EM, FN at right angles. 
 
 Therefore the centre of the circle is at U the middle 
 point of OP, 
 
 Now join DU and produce it to meet AP in X. 
 
 The two triangles OUI), PUX are easily seen to be 
 congruent, so that UD = UX and XP = O.D. 
 
 Hence X lies on the circle through D, E, F, L, M, K 
 
 And since XP= OB =^AP, X is the middle point of 
 AP. 
 
 Similarly the circle goes through Y and Z, the middle 
 points of BP and CP. 
 
 Thus our proposition is proved. 
 
 5. The circle thus defined is known as the nine-points 
 circle of the triangle. Its radius is half that of the 
 circumcircle, as is obvious from the fact that the nine- 
 points circle is the circumcircle of BEF, which is similar 
 to ABG and of half its linear dimensions. Or the same 
 may be seen from our figure wherein BX= OA, for OBXA 
 is a parallelogram. 
 
 It will be proved in the chapter on Inversion that the 
 nine-points circle touches the incircle and the three ecircles 
 of the triangle. 
 
SOME PROPERTIES OF THE TRIANGLE. 
 
 6. Prop. If the 'perpendicular AL of a triangle 
 ABC he produced to meet the circumcircle in H, then 
 PL = LH, P being the orthocentre. 
 
 Join BH. 
 
 Then Z HBL — Z HAG in the same segment 
 
 = ZLBP since each is the complement 
 of Z^C^. 
 
 Thus the triangles PBL, HBL have their angles at B 
 equal, also their right angles at L equal, and the side BL 
 common. 
 
 .-. PL = LH. 
 
SOME PROPERTIES OF THE TRIANGLE. 7 
 
 7. Prop. The feet of the perpendiculars from any 
 point Q on the circumchxle of a triangle ABC on to the 
 sides of the triangle are collinear. 
 
 Let R, S, T be the feet of the perpendiculars as in the 
 figure. Join QA, QB. 
 
 QTAS is a cyclic quadrilateral since T and S are right 
 angles. 
 
 .-. ZATS=ZAQS 
 
 = complement of Z QAS 
 
 = complement of Z QBG (since QAC, QBG 
 
 are supplementary) 
 = zBQR 
 
 = Z BTR (since QBRT is cyclic). 
 .*. RTS is 8i straight line. 
 
 This line RTS is called the pedal line of the point Q. 
 It is known also as the Simson line. 
 
8 
 
 SOME PROPERTIES OF THE TRIANGLE. 
 
 8. Prop. The pedal line of Q bisects the line joining 
 Q to P, the orthocentre of the triangle. 
 
 Join QP cutting the pedal line of Q in K. 
 Let the perpendicular AL meet the circumcircle in H. 
 Join QH cutting the pedal line in M and BG in N. 
 Join PN and QB. 
 Then since QBRT is cyclic, 
 ZQRT^^^QBT 
 
 — Z QHA in same segment 
 = Z HQR since QR is parallel to AH. 
 .-. QM=MR. 
 .'. il/ is the middle point of QN. 
 But ZPNL = ZLNH since APNL=AHJSrL 
 = Z RNII 
 = zMRK 
 
 .'. Pi\^ is parallel to RT. 
 
 .-. QK:KP = QM: MN. 
 
 .-. QK = KP. 
 
SOME PROPERTIES OF THE TRIANGLE. 9 
 
 9. Prop. The three medians of a triangle meet in a 
 point, and this point is a point of trisection of each median, 
 and also of the line joining the circumcentre and the 
 orthocentre P. 
 
 Let the. median AD of the triangle ABC cut OP in G. 
 
 Then from the similarity of the triangles GAP, 
 GDO, we deduce, since AP=20D, that AG = 2GD and 
 PG = 2G0. 
 
 Thus the median AD cuts OP in G which is a point 
 of trisection of both lines. 
 
 Similarly the other medians cut OP in the same point 
 G, which will be a point of trisection of them also. 
 
 This point G is called the median point of the triangle. 
 The reader is probably already familiar with this point as 
 the centroid of the triangle. 
 
10 SOME PROPERTIES OF THE TRIANGLE. 
 
 10. Prop. If AD he a median of the triangle ABC, 
 
 then 
 
 AB^--{'AC' = 2AD' + 2BD\ 
 
 Draw AL perpendicular to BC. 
 Then AC' = AB' + BG' - 2BG.BL 
 
 and AD' = AB'^ + BD'' - 2BD . BL. 
 
 These equalities include the cases where both the 
 angles B and G are acute, and where one of them, B, is 
 obtuse, provided that BG and BL be considered to have 
 the same or opposite signs according as they are in the 
 same or opposite directions. 
 
 Multiply the second equation by 2 and subtract from 
 the first, then 
 
 AG'- 2AD" = BG' - AB' - 2BD\ 
 .'. AB' + AG'=^2AD' + BG'-2BD' 
 
 = 2AD'~+ 2BD\ since BG = 2BD. 
 
 11. The proposition proved in the last article is only 
 a special case of the following general one : 
 
 If D he a point iii the side BG of a triangle ABG such 
 
 that BD==-BG,then 
 
 n 
 
 {:n-l)AB' + AG' = n.AD'-\-{l-^BG\ 
 
SOME PROPERTIES OF THE TRIANGLE. 
 
 11 
 
 For proceeding as before, if we now multiply the 
 second of the equations by n and subtract from the first 
 we get 
 
 AG'-n.AD''={\-n)AB'- + BG''-n.BD\ 
 
 .-. {n-l)AB' + AG' = n.AD^-\-BG'^-n{-BG 
 
 n.AD'-+ 1 
 
 - -^ BG\ 
 
 nj 
 
 12. Prop. The distances of the points of contact of 
 the incircle of a triangle ABG with the sides from the 
 vertices A, B, G are s — a, s — b, s — c respectively; and 
 the distances of the points of contact of the ecircle opposite 
 to A are s, s — c, s — b respectively ; a, 6, c being the lengths 
 of the sides opposite to A, B, G and s half the sum of them. 
 
12 SOME PROPERTIES OF THE TRIANGLE. 
 
 Let the points of contact of the in circle be L, M, N. 
 Then since AM = AN, CL = CM and BL = BN, 
 .'. AM + BC — half the sum of the sides = s, 
 .'. A3I = s-a. 
 Similarly BL = BN = s-h, and GL = CM=s- c. 
 
 Next let L\ M\ N' be the points of contact of the 
 ecircle opposite to A. 
 
 Then AN' = AB + BN' = AB + BL' 
 
 and AM' = AC -^ CM' = AC + CL'. 
 
 .-. since AM' = AN', 
 2AN' = AB -\- AC + BC = 2s. 
 .-. AN' = s, 
 and BL' = BN' = s - c, and CL' = CM' = s-h. 
 
 Cor. BL' = CL, and thus IjL' and BC have the same 
 middle point. 
 
 EXERCISES. 
 
 1. Defining the pedal triangle as that formed by joining 
 the feet of the perpendiculars of a triangle, shew that the 
 pedal triangle has for its incentre the orthocentre of the 
 original triangle, and that its angles are the supplements 
 of twice the angles of the triangle. 
 
 2. A straight line FQ is drawn parallel to AB to meet 
 the circumcircle of the triangle ABC in the points P and Q, 
 shew that the pedal lines of F and Q intersect on the perpen- 
 dicular from C on AB. 
 
 3. Shew that the pedal lines of three points on the 
 jumcircle of a triangle f( 
 formed by the three points. 
 
 circumcircle of a triangle form a triangle similar to that 
 
SOME PROPERTIES OF THE TRIANGLE. 13 
 
 4. The pedal lines of the extremities of a chord of the 
 circumcircle of a triangle intersect at a constant angle. Find 
 the locus of the middle point of the chord. 
 
 5. Given the circumcircle of a triangle and two of its 
 vertices, prove that the loci of its orthocentre, centroid and 
 nine-points centre are circles. 
 
 6. The locus of a point which is such that the sum of the 
 squares of its distances from two given points is constant is a 
 sphere. 
 
 7. A', £', C are three points on the sides BC, CA^ AB oi 
 a triangle ABC. Prove that the circumcentres of the triangles 
 AB'C, BC'A\ CA'B' are the angular points of a triangle 
 which is similar to ABC. 
 
 8. A circle is described concentric with the circumcircle 
 of the triangle ABC, and it intercepts chords -^1^2? ^i^a 
 C1G2 on BC, CA, AB respectively; from A-^ perpendiculars 
 A-^b^, A-^c^ are drawn to CA, AB respectively, and from A.^, B^, 
 B.2, Ci, C2 similar perpendiculars are drawn. Shew that the 
 circumcentres of the six triangles, of which Ah-^^c^ is a typical 
 one, lie on a circle concentric with the nine-points circle, and 
 of radius one-half that of the original circle. 
 
 9. A plane quadrilateral is divided into four triangles by 
 its internal diagonals ; shew that the quadrilaterals having 
 for angular points (i) the orthocentres and (ii) the circum- 
 centres of the four triangles are similar parallelograms ; and 
 if their areas be A^ and A^, and A be that of the quadrilateral, 
 then 2A + Air=4A2. 
 
 10. Prove that the line joining the vertex of a triangle 
 to that point of the inscribed circle which is farthest from the 
 base passes through the point of contact of the escribed circle 
 with the base. 
 
 11. Given in magnitude and position the lines joining the 
 vertex of a triangle to the points in which the inscribed circle 
 and the circle escribed to the base touch the base, construct 
 the triangle. 
 
14 SOME PROPERTIES OF THE TRIANGLE. 
 
 12. Prove that when four points A, B, C, D lie on a 
 circle, tlie orthocentres of the triangles BCD^ CD A, DAB, 
 ABC lie on an equal circle. 
 
 13. Prove that the pedal lines of the extremities of a 
 diameter of the circumcircle of a triangle intersect at right 
 angles on the nine-points circle. 
 
 14. If a parabola touch the three sides of a triangle, its 
 directrix passes through the orthocentre of the triangle. 
 
 15. ABC is a triangle, its circumcentre ; OD perpen- 
 dicular to BC meets the circumcircle in K. Prove that the 
 line through D perpendicular to AK will bisect KP, P being 
 the orthocentre. 
 
 16. ABC is a triangle circumscribing a parabola. If A 
 lie on the axis of the parabola, prove that the line joining the 
 centre of the circle circumscribing ABC to the focus of the 
 parabola is perpendicular to BC. 
 
 17. If a conic touch the three sides of a triangle and 
 have one focus at the orthocentre, determine the position of 
 the other focus. 
 
 18. Having given the circumcircle and one angular point 
 of a triangle and also the lengths of the lines joining this 
 point to the orthocentre and centre of gravity, construct the 
 triangle. 
 
 19. The base and area of a triangle being given, shew 
 that the locus of its orthocentre is a parabola. 
 
 20. If AB be divided at in such a manner that 
 
 l.AO^m.OB, 
 and if P be any point, prove 
 
 I . AP' + m . BP'^ = {l + m) OP'' + LAO^ + m . B0\ 
 
 If a, b, c be the lengths of the sides of a triangle ABC, 
 find the locus of a point P such that a . PA^ + b . PB^ + c . PC^ 
 is constant. 
 
CHAPTER II. 
 
 SOME PROPERTIES OF CIRCLES. 
 
 13. Definition. When two points P and P' lie on 
 the same radius of a circle whose centre is and are on 
 the same side of and their distances from are such 
 that OP . OP' — square of the radius, they are called 
 inverse points with respect to the circle. 
 
 The reader can already prove for himself that if a pair 
 of tangents be drawn from an external point P to a circle, 
 centre 0, the chord joining the points of contact of these 
 tangents is at right angles to OP, and cuts OP in a point 
 which is the inverse of P. 
 
 14. The following proposition will give the definition 
 of the polar of a point with respect to a circle : 
 
 Prop. The locus of the points of intersection of pairs 
 of tangents drawn at the extremities of chords of a circle, 
 which pass through a fixed point, is a straight line, called 
 the polar of that point, and the point is called the pole 
 of the line. 
 
16 
 
 SOME PROPERTIES OF CIRCLES. 
 
 Let ^ be a fixed point in the plane of a circle, 
 centre 0. 
 
 Draw any chord QR of the circle to pass through A. 
 
 Let the tangents at Q and R meet in P. 
 
 Draw PL perpendicular to OA. 
 
 Let OP cut QR at right angles in M. 
 
 Then PMLA is cyclic. 
 
 .-. OL .OA- OM . OP = square of radius. 
 .-. X is a fixed point, viz. the inverse of A. 
 
 Thus the locus of P is a straight line perpendicular to 
 Oil, and cutting it in the inverse point of A. 
 
 15. It is clear from the above that the polar of an 
 external point coincides with the chord of contact of the 
 tangents from that point. And if we introduce the notion 
 of imaginary lines, with which Analytical ^Geometry has 
 furnished us, we may say that the polar of a point 
 
SOME PROPERTIES OF CIRCLES. 
 
 17 
 
 coincides with the chord of contact of tangents real or 
 imaginary from that point. 
 
 We may remark here that the polar of a point on the 
 circle is the tangent at that point. 
 
 Some writers define the polar of a point as the chord 
 of contact of the tangents drawn, from that point; others 
 again define it by means of its harmonic property, which 
 will be given in a later chapter. It is unfortunate that 
 this difference of treatment prevails. The present writer 
 is of opinion that the method he has here adopted is 
 the best. 
 
 . 16. Prop. If the polar of A goes through B, then 
 the polar of B goes through A . 
 
 Let BL be the polar of A cutting OA at right angles 
 in L. 
 Draw 
 
18 SOME PROPERTIES OF CIRCLES. 
 
 Then OM,OB = OL.OA = sq. of radius, 
 
 .'. AM is the polar of B, 
 
 that is, A lies on the polar of B. 
 
 Two points such that the polar of each goes through 
 the other are called conjugate points. 
 
 The reader will see for himself that inverse points 
 with respect to a circle are a special case of conjugate 
 points. 
 
 We leave it as an exercise for the student to prove 
 that if I, m be two lines such that the pole of I lies on m, 
 then the pole of m will lie on I. 
 
 Two such lines are called conjugate lines. 
 
 From the above property for conjugate points we see 
 that the polars of a number of collinear points all pass 
 through a common point, viz. the pole of the line on 
 which they lie. For if A, B, (7, D, &c., be points on 
 a line p whose pole is P; since the polar of P goes 
 through A, B, C, &c., .*. the polars of A, B, C\ &c., go 
 through P. 
 
 We observe that the intersection of the polars of two 
 points is the pole of the line joining them. 
 
 17. Prop. If P and Q be any two points in the plane 
 of a ciixle whose centre is 0, the7i 
 
 OP : OQ = j^erp. from P on polar of Q : perp. from Q 
 on polar of P. 
 
 Let P' and Q' be the inverse points of P and Q, 
 through which the polars of P and Q pass. 
 
SOME PROPERTIES OF CIRCLES. 
 
 19 
 
 Let the perpendiculars on the polars be PM and QN ; 
 draw PT and QR perp. to OQ and OP respectively. 
 
 Then we have OP.OP' = OQ.O Q\ 
 
 since each is the square of the radius, and 
 
 OR.OP=OT. OQ since PRQT is cyclic, 
 
 OQ' _OP_OT _ OQ' - OT ^PM 
 •'* OP' ~ 0Q~ 0R~ OP' - OR QN ' 
 
 Thus the proposition is proved. 
 
 This is known as Salmon's theorem. 
 
 2—2 
 
20 
 
 SOME PROPERTIES OF CIRCLES. 
 
 18. Prop. The locus of points from which the tan- 
 gents to two given coplanar circles are equal is a line 
 (called the radical axis of the circles) perpendicular to the 
 line of centres. 
 
 Let PK, PF be equal tangents to two circles, centres 
 A and B. 
 
 Draw PL perp. to AB. Join PA, PB, AK and BF. 
 Then PK'^ = AP^^-AK' = PL' + AL^ - AK\ 
 and PF' = PB' - BF' = PL' + LB' - BF', 
 
 .\AL'-AK'=^LB'-BF', 
 ..AL'-LB' = AK'-BF', 
 .-. (AL-LB)(AL-\-LB) = AK'-BF'. 
 Thus if be the middle point of AB, we have 
 20 L . AB = difference of sqq. of the radii, 
 .'. 7y is a fixed point, and the locus of P is a line 
 perp. to AB. 
 
 Since points on the common chord produced of two 
 intersecting circles are such that tangents from them to 
 
SOME PROPERTIES OF CIRCLES. 
 
 21 
 
 the two circles are equal, we see that the radical axis 
 of two intersecting circles goes through their common 
 points. And introducing the notion of imaginary points, 
 we may say that the radical axis of two circles goes 
 through their common points, real or imaginary. 
 
 19. The difference of the squares of the tangents to tivo 
 coplanar circles, from any point P in their plane, varies as 
 the perpendicular from P on their radical axis. 
 
 Let PQ and PR be the tangents from P to the circles, 
 centres A and B. 
 
 Let PN be perp. to radical axis NL, and PM io AB\ 
 let be the middle point of AB. Join PA, PB. 
 Then 
 
 PQ' - PR' = PA' -AQ"- {PB' - BR') 
 = PA'-PB'-AQ' + BR' 
 = AM'-MB'-AQ' + BR' 
 = 20M .AB-20L.AB (see § 18) 
 = 2AB.LM = 2AB.NP. 
 This proves the proposition. 
 
22 
 
 SOME PROPERTIES OF CIRCLES. 
 
 We may mention here that some writers use the term 
 " power of a point " with respect to a circle to mean the 
 square of the tangent from the point to the circle. 
 
 20. Prop. The radical axes of three coplanar circles 
 taken in pairs meet in a point. 
 
 Let the radical axis of the circles A and B meet that 
 of the circles A and in P. 
 
 Then the tangent from P to circle G 
 = tangent from P to circle A 
 = tangent from P to circle B. 
 .'. P is on the radical axis of B and G. 
 
 21. Coaxal circles. A system of coplanar circles 
 such that the radical axis for any pair of them is the 
 same is called coaxal. 
 
 Clearly such circles will all have their centres along 
 the same straight line. 
 
 Let the common radical axis of a system of coaxal 
 circles cut their line of centres in A. 
 
SOME PROPERTIES OF CIRCLES. 
 
 23 
 
 Then the tangents from A to all the circles will be 
 equal. 
 
 Let L, L' be two points on the line of centres on 
 opposite sides of ^, such that AL, AL' are equal in 
 length to the tangents from A to the circles ; L and L' 
 are called the limiting points of the system. 
 
 They are such that the distance of any point P on 
 the radical axis from either of them is equal to the length 
 of the tangent from P to the system of circles. 
 
 For if G be the centre of one of the circles which is 
 of radius r, 
 
 PL^=:PA^ + AL^ = PA^ + AC'-r' = PC'-r' 
 
 = square of tangent, from P to circle C. 
 
 The two points L and L' may be regarded as the 
 centres of circles of infinitely small radius, which belong 
 to the coaxal system. They are sometimes called the 
 point circles of the system. 
 
24 
 
 SOME PROPERTIES OF CIRCLES. 
 
 The student will have no difficulty in satisfying him- 
 self that of the two limiting points one is within and the 
 other without each circle of the system. 
 
 It must be observed that the limiting points are real 
 only in the case where the system of coaxal circles do 
 not intersect in real points. For if the circles intersect, 
 A will lie within them all and thus the tangents from A 
 will be imaginary. 
 
 Let it be noticed that if two circles of a coaxal system 
 intersect in points P and Q, then all the circles of the 
 system pass through F and Q. 
 
 22. Prop. The limiting points of a system of coaxal 
 circles are inverse points with respect to every ciyxle of the 
 system. 
 
 \L 
 
 L N C 
 
 Let G be the centre of one of the circles of the 
 system. Let L and L be the limiting points of which 
 L' is without the circle G. 
 
 Draw tangent L'T to circle C; this will be bisected 
 by the radical axis in P. 
 
SOME PROPERTIES OF CIRCLES. 25 
 
 Draw TN perpendicular to line of centres. 
 Then LA:AN = LT:PT, 
 
 .'.L'A=AN, 
 
 .'. N coincides with L. 
 Thus the chord of contact of tangents from L' cuts the 
 line of centres at right angles in L. 
 
 Therefore L and L' are inverse points. 
 
 23. The student will find it quite easy to establish 
 the two following propositions : 
 
 Evei^y circle passing through the limiting points cuts all 
 the circles of the system orthogonally. 
 
 A common tangent to tiuo circles of a coaxal systeiyi 
 subtends a right angle at either limiting point. 
 
 24. Common tangents to two circles. 
 
 In general four common tangents can be drawn to two 
 coplanar circles. 
 
 Of these two will cut the line joining their centres 
 externally ; these are called direct common tangents. 
 And two will cut the line joining the centres internally; 
 these are called transverse common tangents. 
 
 We shall now prove that the common tangents of two 
 circles cut the line joining their centres in two points which 
 divide that line internally and externally in the ratio of 
 the radii. 
 
26 SOME PROPERTIES OF CIRCLES. 
 
 Let a direct common tangent PQ cut the line joining 
 the centres A and B in 0. Join AP, BQ. 
 
 Then since P and Q are right angles, the triangles 
 APO, BQO are similar, 
 
 .-. AO:BO = AP:BQ. 
 
 Similarly, if P'Q' be a transverse common tangent 
 cutting AB in 0', we can prove -4 0' : 0'^ = ratio of the 
 radii. 
 
 We thus have a simple construction for drawing the 
 common tangents, viz. to divide AB internally and ex- 
 ternally at 0' and in the ratio of the radii, and then 
 from and 0' to draw a tangent to either circle ; this 
 will be also a tangent to the other circle. 
 
 If the circles intersect in real points, the tangents 
 from 0' will be imaginary. 
 
 If one circle lie wholly within the other, the tangents 
 from both and 0' will be imaginary. 
 
 25. Through the point 0, as defined at the end of 
 the last paragraph, let a line be drawn cutting the circles 
 in RS and R'S' as in the figure. 
 
 Consider the triangles OAR, OBR'. 
 
 We have OA.OB^AR: BR\ 
 
 also the angle at is common to both, and each of th( 
 remaining angles at R and R' is less than a right angle. 
 
SOME PROPERTIES OF CIRCLES. 27 
 
 Thus the triangles are similar, and 
 
 OR : OR = AR : BR', 
 
 the ratio of the radii. 
 
 In like manner, by considering the triangles OAS, 
 OBS\ in which each of the angles >Si and 8' is greater 
 than a right angle, we can prove that OS : OS' = ratio 
 of radii. 
 
 We thus see that the circle B could be constructed 
 from the circle A by means of the point by taking the 
 radii vectores from of all the points on the circle A and 
 dividing these in the ratio of the radii. 
 
 On account of this property is called a centre of 
 similitude of the two circles, and the point R' is said to 
 correspond to the point R. 
 
 The student can prove for himself in like manner that 
 0' is a centre of similitude. 
 
 26. In order to prove that the locus of a point 
 obeying some given law is a circle, it is often convenient 
 to make use of the ideas of the last paragraph. 
 
 If we can prove that our point P is such as to divide 
 the line joining a fixed point to a varying point Q, 
 which describes a circle, in a given ratio, then we know 
 that the locus of P must be a circle, which with the circle 
 on which Q lies has for a centre of similitude. 
 
 For example, suppose we have given the circumcircle 
 of a triangle and two of its vertices, and we require the 
 locus of the nine-points centre. It is quite easy to prove 
 that the locus of the orthocentre is a circle, and from this 
 it follows that the locus of the nine-points centre is a circle, 
 since, if be the circumcentre (which is given) and P the 
 orthocentre (which describes a circle) and U the nine- 
 
28 SOME PROPERTIES OF CIRCLES. 
 
 points centre, U lies on OP and OU = ^OP; therefore 
 the locus of t^ is a circle, having its centre in the line 
 joining to the centre of the circle on which P lies. 
 
 27. Prop. The locus of a point which moves in 
 a plane so that its distances from two fixed points in that 
 plane are in a constant ratio is a circle. 
 
 Let A and B be the two given points. Divide AB 
 internally and externally at G and B in the given ratio, 
 so that G and B are two points on the locus. 
 
 Let P be any other point on the locus. 
 
 Then since 
 
 AP : PB = AG : GB = AB : BB, 
 
 . ' . PG and PB are the internal and external bisectors 
 
 of the Z APB. 
 .'. GPB is a right angle. 
 .'. the locus of P is a circle on GB as diameter. 
 
 Cor. 1. If the point P be not confined to a plane, its 
 locus is the sphere on GB as diameter. 
 
 Cor. 2. If the line AB be divided internally and 
 externally at G and B in the same ratio, and P be any 
 point at which GB subtends a right angle, then PG and 
 PB are the internal and external bisectors of Z APB. 
 
SOME PROPERTIES OF CIRCLES. 29 
 
 28. If on the line 00' joining the two centres of 
 similitude of circles, centres A and B, as defined in § 25, 
 a circle be described, it follows from § 27 that if G be any 
 point on this circle, 
 
 CA : CB = radius of A circle : radius of B circle. 
 
 The circle on 00' as diameter is called the circle 
 of similitude. Its use will be explained in the last 
 chapter, when we treat of the similarity of figures. 
 
 EXERCISES. 
 
 1. If /* be any point on a given circle A, the square of 
 the tangent from F to another given circle B varies as the 
 perpendicular distance of F from the radical axis of A and £. 
 
 2. If A, B, C be three coaxal circles, the tangents drawn 
 from any point of (7 to -4 and B are in a given ratio. 
 
 3. If tangents drawn from a point F to two given circles 
 A and B are in a given ratio, the locus of P is a circle coaxal 
 with A and B. 
 
 4. li Aj B, C &c. be a system of coaxal circles and X be 
 any other circle, then the radical axes of A, X ; B, X ; C, X 
 &c. meet in a point. 
 
 5. The square of the line joining one of the limiting 
 points of a coaxal system of circles to a point F on any one of 
 the circles varies as the distance of F from the radical axis. 
 
 6. If two circles cut two others orthogonally, the radical 
 axis of either pair is the line joining the centres of the other 
 pair, and passes through their limiting points. 
 
30 SOME PROPERTIES OF CIRCLES. 
 
 7. If from any point on the circle of similitude (§ 28) of 
 two given circles, pairs of tangents be drawn to both circles, 
 the angle between one pair is equal to the angle between the 
 other pair. 
 
 8. The three circles of similitude of three given circles 
 taken in pairs are coaxal. 
 
 9. Find a pair of points on a given circle concyclic with 
 each of two given pairs of points. 
 
 10. If any line cut two given circles in P. Q and P', Q' 
 respectively, prove that the four points in which the tangents 
 at P and Q cut the tangents at P' and Q' lie on a circle coaxal 
 with the given circles. 
 
 11. A line PQ is drawn touching at /^ a circle of a 
 coaxal system of which the limiting points are K^ K', and Q is 
 a point on the line on the opposite side of the radical axis to 
 P. Shew that if T, T' be the lengths of the tangents drawn 
 from P to the two concentric circles of which the common 
 centre is Q^ and whose radii are respectively QK^ QK', then 
 
 T :T'^ PK : PK\ 
 
 12. is a j&xed point on the circumference of a circle C, 
 P any other point on G ', the inverse point ^ of P is taken 
 with respect to a fixed circle whose centre is at 0, prove that 
 the locus of ^ is a straight line. 
 
 13. Two circles have each double contact with an ellipse, 
 the one having its centre on the major axis, the other on the 
 minor axis ; the chords of contact with the ellipse intersect in 
 a point P. Shew that P is one of the limiting points of the 
 coaxal system to which the circles belong, and determine the 
 other. 
 
 14. Three circles Ci, Cg, C^ are such that the chord of 
 intersection of C^ and C^ passes through the centre of Cj, and 
 the chord of intersection of Cg and Ci through the centre of 
 C^; shew that the chord of intersection of C-^ and C^ passes 
 through the centre of Cg. 
 
SOME PROPERTIES OF CIRCLES. 31 
 
 15. Three circles A, B, C are touched externally by a 
 circle whose centre is P and internally by a circle whose 
 centre is Q. Shew that PQ passes through the point of con- 
 currence of the radical axes oi A, B, G taken in pairs. 
 
 16. AB is a diameter of a circle S, any point on AB or 
 AB produced, C a circle whose centre is at 0. A' and B' are 
 the inverse points of A and B with respect to C. Prove that 
 the pole with respect to C of the polar with respect to S of 
 the point is the middle point of A'B'. 
 
 17. If P and Q be two points on two circles *S'i and S^ 
 belonging to a coaxal system of which L is one of the limiting 
 points, such that the angle PLQ is a right angle, prove that 
 the foot of the perpendicular from L on PQ lies on one of the 
 circles of the system, and thus shew that the envelope of PQ 
 is a conic having a focus at L. 
 
 18. A system of spheres touch a plane at the same point 
 Oj prove that any plane, not through 0, will cut them in a 
 system of coaxal circles. 
 
 19. A point and its polar with respect to a variable circle 
 being given, prove that the polar of any other point A passes 
 through a fixed point B. 
 
 20. ^ is a given point in the plane of a system of coaxal 
 circles ; prove that the polars of A with respect to the circles 
 of the system all pass through a fixed point. 
 
CHAPTER III. 
 
 THE USE OF SIGNS. CONCURRENCE AND 
 COLLINEARITY. 
 
 29. The reader is already familiar with the convention 
 of signs adopted in Trigonometry and Analytical Geometry 
 in the measurement of straight lines. According to this 
 convention lengths measured along a line from a point are 
 counted positive or negative according as they proceed in 
 the one or the other direction. 
 
 With this convention we see that, if A, B, C he three 
 points in a line, then, in whatever order the points occur in 
 the line, 
 
 AB^BG = AG. 
 
 B 
 
 AC B 
 
 If C lie between A and B, BC is of opposite sign to 
 AB, and in this case AB -\- BC does not give the actual 
 distance travelled in passing from A to B, and then from 
 B to C, but gives the final distance reached from A. 
 
THE USE OF SIGNS. CONCURRENCE AND COLLINEARITY. 33 
 
 From the above equation we get 
 BG = AC-AB. 
 
 This is an important identity. By means of it we can 
 reduce all our lengths to depend on lengths measured 
 from a fixed point in the lines. This process it will be 
 convenient to speak of as inserting an origin. Thus, if we 
 insert the origin 0, 
 
 AB = OB- OA. 
 
 30. Prop. If M he the middle point of the line AB, 
 and he any other point in the line, then 
 
 20M = 0A-^ OB. 
 
 6 A M B 
 
 For since AM = MB, 
 
 by inserting the origin we have 
 
 OM-OA = OB-OM, 
 .-. 20M=0A-\-0B. 
 
 31. A number of collinear points are said to form 
 a range. 
 
 Prop. If A, B, G, Bhe a range of four points, then 
 
 AB.CD + BG.AD + GA.BD = 0. 
 
 A~ ' i" a b 
 
 For, inserting the origin A, we see that the above 
 ==AB{AD-'AG) + (AG-AB)AD--AG(AD-AB\ 
 and this is zero. 
 
 This is an important identity, which we shall use 
 later on. 
 
 A. G. 3 
 
34 THE USE OF SIGNS. 
 
 32. If A, B, C he a, range of points, and any point 
 outside their line, we know that the area of the triangle 
 OAB is to the area of the triangle OBG in the ratio of 
 the lengths of the bases AB, BG. 
 
 Now if we are taking account of the signs of our 
 lengths AB, BG and the ratio AB :BG occurs, we cannot 
 substitute for this ratio A OAB : A OBG unless we have 
 some convention respecting the signs of our areas, whereby 
 the proper sign of AB : BG will be retained when the 
 ratio of the areas is substituted for it. 
 
 The obvious convention is that the area of a triangle 
 PQR shall be accounted positive or negative according as 
 the triangle is to the one or the other side as the contour 
 FQR is described. 
 
 Thus if the triangle is to our left hand as we describe 
 the contour PQR, we shall consider A PQR to be a posi- 
 tive magnitude, while A PRQ will be a negative magnitude, 
 for in describing the contour PRQ the area is on our right 
 hand. 
 
 With this convention we see that in whatever order 
 the points A, B, G occur in the line on which they lie, 
 
 AB:BG = AOAB:AOBG, 
 or =AAOB:ABOG. 
 
CONCURRENCE AND COLLIN EARITY. 35 
 
 It is further clear that with our convention we may 
 say 
 
 AOAB-{-AOBC = AOAC, 
 
 and A OAB -AOAC = A OCB, 
 
 remembering always that A, B, G are coUinear. 
 
 33. Again, we know that the magnitude of the area 
 of a triangle OAB is ^OA . OBsinAOB, and it is some- 
 times convenient to make use of this value. But if we 
 are comparing the areas OAB, OBC by means of a ratio 
 we cannot substitute 
 
 ^OA.OBsmAOB and iOB.OCsinBOG 
 
 for them unless we have a further convention of signs 
 whereby the sign and not merely the magnitude of our 
 ratio will be retained. 
 
 The obvious convention here again will be to consider 
 angles positive if described in one sense and negative in 
 the opposite sense ; this being eifective for our purpose, 
 since sin (- ^) = — sin x. 
 
 ZBPA ^APB 
 
 In this case Z APB = - Z BPA. The angle APB is 
 to be regarded as obtained by the revolution of PB round 
 P from the position PA, and the angle BPA as the revo- 
 
 3—2 
 
86 THE USE OF SIGNS. 
 
 lution of PA round P from the position PB ; these are in 
 opposite senses and so of opposite signs. 
 
 With this convention as to the signs of our angles we 
 may argue from the figures of § eS2, 
 
 AB^ A AOB _ iOA . OB sin^ AOB 
 BC~ ABOC~iOB.OGsmzBOC 
 
 (the lines OA, OB, 00 being all regarded as positive) 
 
 ^OA sin Z A OB 
 ~ 00 • sin Z BOG ' 
 
 AB 
 
 In this way the sign of the ratio -^^ is retained in 
 
 BO 
 
 the process of transformation, since 
 
 sin Z^ 05 and sin Z 500 
 
 are of the same or opposite sign according as AB and BC 
 are of the same or opposite sign. 
 
 The student will see that our convention would have 
 been useless had the area depended directly on the cosine 
 of the angle instead of on the sine, since 
 
 cos(— ^) = + cos(J). 
 
 34. Test for coUinearity of three points on the 
 sides of a triangle. 
 
 The following proposition, known as Menelaus' theorem, 
 is of great importance. 
 
 The necessary and sufficient condition that the points 
 D, E, F on the sides of a triangle ABO opposite to the 
 vertices A, B, C respectively should he collinear is 
 
 AF:BD.GE = AE.CD.BF, 
 
 regard being had to the signs of these lines. 
 
CONCURRENCE AND COLLIN EARITY. 
 
 37 
 
 All these lines are along the sides of the triangle. 
 We shall consider any one of them to be positive or 
 negative according as the triangle is to our left or right 
 respectively as we travel along it. 
 
 We will first prove that the above condition is neces- 
 sary, if D, E, F are coUinear. 
 
 Let p, q, r be the perpendiculars from A^ B, C on to 
 the line DEF, and let these be accounted positive or 
 negative according as they are on the one or the other 
 side of the line DEF. 
 
 With this convention we have 
 
 
 
 AF p BD q GE 
 BF~q' CD r' AE' 
 
 r 
 
 Hence 
 
 AF.BD.GE 
 BF.CD . AE ' 
 
 
 that is, 
 
 AF.BD.CE = AE.GD. 
 
 Bl 
 
38 
 
 THE USE OF SIGNS. 
 
 Next let D, E, F be three points on the sides such that 
 AF.BD.CE = AE.GD.BF, 
 then shall D, E, F be collinear. 
 
 Let the line DE cut AB in F\ 
 
 .-. AF\BD.GE = AE.GD.BF', 
 AF' ^AF 
 ''BF'~BF' 
 .'.{AF^ FF') BF = AF (BF + FF'), 
 .■.FF'{BF-AF) = 0, 
 
 .'.FF'=:0, 
 
 .'. F coincides with F\ 
 Thus our proposition is completely proved. 
 
 35. Test for concurrency of lines through the 
 vertices of a triangle. 
 
 The following proposition, known as Ceva's theorem, 
 is fundamental. 
 
CONCURRENCE AND COLLINEARITY. 39 
 
 The necessary and sufficient condition that the lines 
 AD, BE, OF drawn through the vertices of a triangle 
 ABC to meet the opposite sides in D, E, F shoidd he 
 concurrent is 
 
 AF.BD.GE = -AE.CD.BF, 
 
 the same convention of signs being adopted as in the last 
 proposition. 
 
 First let the lines AD, BE, OF meet in P. 
 
 Then, regard being had to the signs of the areas, 
 AF _ A AFC _ A AFP _ A AFC -A AFP ^ AAPC 
 BF ~ ABFC ~ ABFP ~ ABFG-ABFP ~ aBPC 
 BD _ ABDA _ ABDP ^ ABDA - ABDP _ ABPA 
 CD ~ ACDA ~ ACDP ~ AGDA - ACDP~ AGFA ' 
 GE^ _ AGEB ^ AGEP ^ AGEB -AGEP ^ AGPB 
 AE~ AAEB~ AAEP~ AAEB-AAEP~ AAPB' 
 AF.BD.GE AAPG ABPA AGPB 
 
 AE.GD.BF AGFA ' AAPB' ABPG 
 = (-l)(-l)(-l) = -l. 
 
40 
 
 THE USE OF SIGNS. 
 
 Next let D, E, F be points on the sides of a triangle 
 ABC such that 
 
 AF. BD. CE^-AE. GD.BF, 
 
 then will AD, BE, OF be concurrent. 
 
 Let AD, BE meet in Q, and let CQ meet AB in F\ 
 
 .-. AF\BD,GE=-AE. GD.BF'. 
 
 AF' _AF 
 
 •*• BF'~BF' 
 
 .'. (AF+FF')BF={BF-\-FF')AF. 
 
 .-. FF'(BF-AF) = 0. 
 
 .-. FF' = 0. 
 .'. F' and i^ coincide. 
 
 Hence our proposition is completely proved. 
 
CONCURRENCE AND COLLINEARITY. 41 
 
 36. Prop. If D, E, F he three 'points on the sides of 
 a triangle ABC opposite to A, B, G respectively, 
 
 AF. BD. CE _ sin ACF sin BAD sin CBE 
 AE.CD.BF~ sin ABE sin GAD sin BGF' 
 
 For 
 
 BD _ ABAD _ ^AB . AD sin BAD _ AB sin BAD 
 GD~ A GAD ~ I AG. AD sin GAD ~ AG ' sin GAD ' 
 
 with our convention as to sign, and AB,AG being counted 
 positive. 
 
 and 
 
 c,. ., , AF AG sin AGF 
 
 Similarly bf'-BG'^^BCF 
 
 CE^W sin GBE 
 AE" AB' sin ABE' 
 
 AF.BD, GE sin A GF sin BAD sin GBE 
 
 ' ' AE.GD.BF sin ABE sin GAD sin BGF 
 
42 THE USE OF SIGNS. 
 
 Cor. The necessary and sufficient condition that AD, 
 BE, CF should be concurrent is 
 
 sin ACF sin BAD sin CBE 
 ' sin ABE sin GAD sin BGF~ 
 
 If be the point of concurrence this relation can be 
 written in the form 
 
 sin ABO sin BGO sin CAP _ 
 sin A GO sin GBO sin BAO~ ' 
 
 this being easy to remember. 
 
 37. Isogonal conjugates. Two lines AD, AD' 
 through the vertex A of a triangle which are such that 
 
 Z BAD = ^D'AG (not z GAD') 
 
 are called isogonal conjugates. 
 
 Prop. // AD, BE, GF he three concurrent lines 
 ihrougli the vertices of a triangle ABG, their isogonal 
 conjugates AD', BE', GF' luill also he concurrent. 
 
 sin BAD sin D'AG sin GAD' 
 
 For 
 
 sin GAD sin D'AB sin BAD' 
 
Similarly 
 and 
 
 CONCURRENCE AND COLLIN EARITY 
 
 sin CBE _ sin ABE ' 
 sin ABE ~ sin CBE' 
 
 sin AG F sin BCF' 
 
 43 
 
 sin BCF sm ACF' 
 
 BOD 
 
 sin CAD' sin ABE' sin BCF ' 
 
 sin BAD' sih<IBE' sin AGF' 
 
 _ ^sin BAD sin GBE sin AG F 
 ~ sin GAB sin ^i^ii^ sin i^Ci^ 
 
 .-. AD\ BE', GF' are" concurrent. 
 
 = -1. 
 
 38. The isogonal conjugates of the medians of a 
 triangle are called its syminedians. Since the medians 
 are concurrent, the symmediaiis are concurrent also. The 
 point where the symmedians intersect is called the sym- 
 median point of the triangle. 
 
 The student will see that the concurrence of the 
 medians and perpendiculars of a triangle follows at once 
 
44 THE USE OF SIGNS. 
 
 by the tests of this chapter (§§ 35 and 36). It was 
 thought better to prove them by independent methods 
 in the first chapter in order to bring out other properties 
 of the orthocentre and the median point. 
 
 39. We will conclude this chapter by introducing the 
 student to certain lines in the plane of a triangle which 
 are called by some writers antiparallel to the sides. 
 
 Let ABC be a triangle, D and E points in the sides 
 AB and AC such that zADE=zBCA and therefore 
 also Z AED — Z CBA. The line DE is said to be anti- 
 parallel to BG. 
 
 It will be seen at once that DBGE is cyclic, and that 
 all lines antiparallel to BG are parallel to one another. 
 
 It may be left as an exercise to the student to prove 
 that the symmedian line through A of the triangle ABG 
 bisects all lines antiparallel to BG. 
 
CONCURRENCE AND COLLINEARITY. 45 
 
 EXERCISES. 
 
 1. The lines joining the vertices of a triangle to its 
 circumcentre are isogonal conjugates with the perpendiculars 
 of the triangle. 
 
 2. The lines joining the vertices of a triangle to the 
 points of contact with the opposite sides of the incircle and 
 ecircles are respectively concurrent. 
 
 3. ABC is a triangle ; AD, BE, CF the perpendiculars 
 on the opposite sides. If AG, BR and CK be drawn perpen- 
 dicular to EF, FD, DE respectively, then AG, BH and CK 
 will be concurrent. 
 
 4. The midpoints of the sides BG and CA of the triangle 
 ABC are D and E : the trisecting points nearest B of the 
 sides BC and BA respectively are H and K. CK intersects 
 AD in L, and BL intersects -4^ in M, and CM intersects BE 
 in N. Prove that N is a trisecting point of BE. 
 
 5. If perpendiculars are drawn from the orthocentre of a 
 triangle ABC on the bisectors of the angle A, shew that their 
 feet are collinear with the middle point of BC. 
 
 6. The points of contact of the ecircles with the sides 
 BC, CA, AB of a triangle are respectively denoted by the 
 letters D, E, F with suffixes 1, 2, 3 according as they belong 
 to the ecircle opposite A, B, or C. BE. 2, CF.^ intersect at P ; 
 BE^, CF^ at Q', E^F., and BC at A"; F.,D^ and CA at T; 
 D^E^ and AB at Z. Prove that the groups of points A, P, 
 Z>i , ^ ; and X, Y, Z are respectively collinear. 
 
 7. Parallel tangents to a circle at A and B are cut in the 
 points G and D respectively by a tangent to the circle at E, 
 Prove that AD, BC and the line joining the middle points of 
 AE and BE are concurrent. 
 
46 THE USE OF SIGNS. 
 
 8. From the angular points of any triangle ABC lines 
 A Z>, BE^ CF are drawn cutting the opposite sides in Z>, E^ F^ 
 and making equal angles with the opposite sides measured 
 round the triangle in the same direction. The lines AD, BE, 
 GF form a triangle A'B'C Prove that 
 
 A'B. B'C.G' A _ A'C . B 'A . C'B _ B C.CA.AB 
 IeTBF. CD' ~ 'AFTBDTCE ~ AD. BETCF' 
 
 9. Through the symmedian point of a triangle lines are 
 drawn antiparallel to each of the sides, cutting the other two 
 sides. Prove that the six points so obtained are equidistant 
 from the symmedian point. 
 
 [The circle through these six points has been called the 
 cosine circlej from the property, which the student can verify, 
 that the intercepts it makes on the sides are proportional to 
 the cosines of the opposite angles,] 
 
 10. Through the symmedian point of a triangle lines are 
 drawn parallel to each of the sides, cutting the other sides. 
 Prove that the six points so obtained are equidistant from the 
 middle point of the line joining the symmedian point to the 
 circumcentre. 
 
 [The circle through these six points is called the Lemoi7ie 
 circle. See Lachlan's Modern Pure Geometry, § 131.] 
 
 11. AD, BE, GF are three concurrent lines through the 
 vertices of a triangle ABG, meeting the opposite sides in 
 D, E, F. The circle circumscribing DEF intersects the sides 
 of ABG again in D', E' , F' . Prove that AD', BE', GF' are 
 concurrent. 
 
 12. Prove that the tangents to the circumcircle at the 
 vertices of a triangle meet the opposite sides in three points 
 which are collinear. 
 
 13. If AD, BE, GF through the vertices of a triangle 
 ABG meeting the opposite sides in D, E, F are concurrent, 
 and points D' , E', F' be taken in the sides opposite to A, B, G 
 so that DD' and BG, EE' and GA, FF' and AB have respec- 
 
CONCURRENCE AND COLLINEARITY. 47 
 
 tively the same middle point, then AD', BE', CF' are con- 
 current. 
 
 14. I£ from the symmedian point ^S' of a triangle ABC, 
 perpendiculars SD, SE, SF be drawn to the sides of the 
 triangle, then JS will be the median point of the triangle 
 BEF. 
 
 15. Prove that the triangles formed by joining the 
 symmedian point to the vertices of a triangle are in the 
 duplicate ratio of the sides of the triangle. 
 
 16. The sides BC, CA, AB of a triangle ABC are divided 
 internally by points A', B', C so that 
 
 BA' : A'C = CB' : B'A = AC : C'B. 
 
 Also B'C produced cuts BC externally in A". Prove that 
 
 BA" : CA" = CA" : A'B^. 
 
 17. The tangent at P to an ellipse meets the equi- 
 conjugates in Q and Q'; shew that CF is a symmedian of 
 the triangle QCQ'. 
 
 18. If a conic touch the sides of a triangle at the feet of 
 the perpendiculars from the vertices on the opposite sides, the 
 centre of the conic must be at the symmedian point of the 
 triangle. 
 
CHAPTER IV. 
 
 PEOJECTION. 
 
 40. If V be any point in space, and A any other 
 point, then if VA, produced if necessary, meet a given 
 plane tt in A', A' is called the projection of A on the 
 plane tt by means of the vertex V. 
 
 It is clear at once that the projection of a straight 
 line on a plane tt is a straight line, namely the inter- 
 section of the plane tt with the plane containing V and 
 the line. 
 
 If the plane through V and a certain line be parallel 
 to the TT plane, then that line will be projected to infinity 
 on the TT plane. The line thus obtained on the tt plane 
 is called the line at infinity in that plane. 
 
 41. Suppose now we are projecting points in a plane p 
 by means of a vertex V on to another plane tt. 
 
 Let a plane through V parallel to the plane tt cut the 
 plane p in the line AB. 
 
 This line AB will project to infinity on the plane tt, 
 and for this reason AB is called the vanishing line on the 
 plane p. 
 
 The vanishing line is clearly parallel to the line of 
 intersection of the planes p and tt, which is called the 
 aods of projection. 
 
PROJECTION. 
 
 49 
 
 )F be an angle in the plane p and let 
 its lmes~XWancl DF cut the vanishing line AB in E and 
 F, then the angle EDF will project on to the ir plane 
 into an angle of magnitude EVF. 
 
 For let the plane VDE intersect the plane it in the 
 line de. 
 
 Then since the plane VEF is parallel to the plane it, 
 the intersections of these planes with the plane VDE are 
 parallel ; that is, de is parallel to VE. 
 
 Similarly df is parallel to VF. 
 
 Therefore Z edf= Z. EVF. 
 
 Hence we see that any angle in the plane p projects 
 on to the ir plane into an angle of magnitude equal to 
 that subtended at V by the portion of the vanishing line 
 intercepted by the lines containing the angle. 
 
 A. G. 4 
 
50 
 
 PROJECTION. 
 
 43. Prop. By a proper choice of the vertex V of 
 projection, any given line on a plane p can he projected 
 to infinity, while two given angles in the plane p are pro- 
 jected into angles of given magnitude on to a plane ir 
 properly chosen. 
 
 Let AB be the given line. Through AB draw any- 
 plane p'. 
 
 Let the plane ir be taken parallel to the plane p\ 
 
 Let EDF, E'D'F' be the angles in the plane p which 
 are to be projected into angles of magnitude a and /9 
 respectively. 
 
 Let E, F, E', F' be ox^ AB. 
 
 On EF, E'F' in the plane p' describe segments of 
 circles containing angles equal to a and /3 respectively. 
 Let these segments intersect in Y. 
 
PROJECTION. 61 
 
 Then if V be taken as the vertex of projection, AB 
 mil project to infinity, and EDF, E'D'F' into angles of 
 magnitude a and /9 respectively (§ 42). 
 
 Cor. 1. Any triangle can be projected into an equi- 
 lateral triangle. 
 
 For if we project two of its angles into angles of 60'' 
 the third angle will project into 60° also, since the sum of 
 the three angles of the triangle in projection is equal to 
 two right angles. 
 
 Cor. 2. A quadrilateral can be projected into a 
 square. 
 
 Let ABGD be the quadrilateral. Let EF be its third 
 diagonal, that is the line joining the intersection of oppo- 
 site pairs of sides. 
 
 Let J. (7 and BD intersect in Q. 
 
 Now if we project EF to infinity and at the same 
 time project Zs BAD and BQA into right angles, the 
 quadrilateral will be projected into a square. 
 
 4—2 
 
52 PROJECTION. 
 
 For the projection of EF to infinity, secures that the 
 projection shall be a parallelogram ; the projection of 
 Z BAD into a right angle makes this parallelogram rect- 
 angular; and the projection of /.AQB into a right angle 
 makes the rectangle a square. 
 
 44. It may happen that one of the lines DE, D'E' in 
 the preceding paragraph is parallel to the line AB which 
 is to be projected to infinity. Suppose that BE is parallel 
 to AB. In this case we must draw a line W in the 
 plane p' so that the angle EFV is the supplement of a. 
 The vertex of projection Y will be the intersection of the 
 line FY with the segment of the circle on E'F' , 
 
 If D'E is also parallel to AB, then the vertex Y will 
 be the intersection of the line FY just now obtained and 
 another line i'^'F so drawn that the angle E'F'Y is the 
 supplement of /3. 
 
 45. Again the segments of circles described on EF, 
 E'F' in the proposition of § 43 may not intersect in any 
 real point. In this case Y is an imaginary point, that 
 is to say it is a point algebraically significant, but not 
 capable of being presented to the eye in the figure. 
 The notion of imaginary points and lines which we take 
 over from Analytical Geometry into our present subject 
 will be of considerable use. 
 
 46. A further notion which we get from coordinate 
 Geometry and which we shall now make use of is that of 
 the order of a curve. A conic is a curve of the second 
 order, by which we mean that its equation referred to 
 axes in its plane is of the second degree. From this it 
 follows that every straight line in the plane of the conic 
 
PROJECTION. 53 
 
 cuts it in two points, real or imaginary. As then the 
 projection of a straight line is a straight line, it is clear 
 that the projection of a conic is a curve of the second 
 order, that is to say is a conic ; for the points of inter- 
 section of the line and conic will project into points of 
 intersection of the projection of the line and the projection 
 of the conic. 
 
 47. Since a tangent to a conic, or any curve, may 
 be regarded as a line through two infinitely near points 
 on the curve, and since such a line projects into a line 
 through two near points on the projection of the curve, 
 we see that tangents project into tangents. 
 
 A pair of tangents from a point P to a conic will 
 project into a pair of tangents from the projection of P 
 to the projection of the conic. 
 
 The chord of contact of tangents from a point P will 
 project into the chord of contact of tangents from the 
 projection of P. 
 
 It may be well to state here that the centre and foci 
 of a conic will not in general project into the centre and 
 foci of its projection, nor will its axes project into the axes 
 of its projection. 
 
 48. We come now to a proposition which is of the 
 greatest importance to our subject. 
 
 Prop. Any conic can he projected into a circle, and 
 any point in the plane of the conic into the centre of the 
 circle. 
 
 Let PAQ, P'AQ' be two chords of the conic V which 
 pass through A. 
 
64 
 
 PROJECTION. 
 
 Let the tangents at P and Q meet in T, and those at 
 P' and Q' in T. 
 
 Join TT\ and let PQ, FQ meet this line in R and E' 
 respectively. 
 
 Now project TT' to infinity and at the same time 
 project the angles TAR and T'AR' into right angles. 
 
 Let corresponding small letters be used to denote the 
 projections of the different points. 
 
 Then since the tangents at /) and q meet at infinity, 
 pq is a diameter of the projection of F. Similarly p'q' is 
 a diameter. 
 
PEOJECTION. 
 
 55 
 
 Therefore a is the centre. 
 
 Moreover, since the tangents at p and q meet on at, 
 at is the direction of the diameter conjugate to ap. 
 
 t cUco 
 
 i^eUco 
 
 Similarly at! is the direction of the diameter conjugate 
 to ap' . 
 
 Hence we have two pairs of perpendicular conjugate 
 diameters. 
 
 The conic 7 is therefore a circle. 
 
 The projection is seen to be real if A be within F. 
 
 49. Prop. The locus of the points of intersection 
 of tangents drawn at the extremities of chords of a conic 
 which pass through a fixed point in its plane is a straight 
 line, called the polar of that point with respect to the conic. 
 
 This is seen to follow from the corresponding property 
 of the circle (§ 14) by projecting the conic into a circle. 
 
56 PROJECTION. 
 
 We see also that the polar of a point is coincident 
 with the chord of contact of tangents drawn from that 
 point. 
 
 The polar of the centre of a conic is the line at 
 infinity in the plane of the conic. 
 
 50. Prop. If the 'polar of A with respect to a conic 
 passes through B, then the polar of B passes through A. 
 
 This follows at once by projection from § 16. 
 Two such points are called conjugate points with 
 respect to the conic. 
 
 From the corresponding property of the circle we can 
 deduce by projection that if the pole of a line a lies on 
 a line 6, then the pole of h lies on a. 
 
 Two such lines are called conjugate lines. 
 
 The student will realise that conjugate diameters are 
 only a special case of conjugate lines. The pole of each 
 of two conjugate diameters lies at infinity along the other 
 diameter. 
 
 51. We have seen that a conic can be projected into 
 a circle, with any point in its plane projected into the 
 centre of the circle. 
 
 It is clear then that a conic can he projected into a 
 circle, while any line in its plane is prvjected to infinity. 
 
 For we project so that the pole of the line becomes 
 the centre of the circle. 
 
 The projection is real if the vanishing line does not 
 cut the conic in real points. 
 
PROJECTION. 57 
 
 52. Prop. A range of three points is projective with 
 any other range of three points in space. 
 
 V 
 
 Let A, B, G he three collinear points, and A', B\ C 
 three others not necessarily in the same plane with the 
 first three. 
 
 Join AA'. 
 
 Take any point F in -4^'. 
 
 Join VB, VC and let them meet a line A' BE drawn 
 through A' in the plane VAC in D and E. 
 
 Join DB', EC. These are in one plane, viz. the plane 
 containing the lines A'C and A'E. 
 
 Let DB\ EC meet in V. Join V'A'. 
 
 Then by means of the vertex V, A, B, G can be pro- 
 jected into A', D, E; and these by means of the vertex V 
 can be projected into A', B\ G\ 
 
 Thus our proposition is proved. 
 
58 PROJECTION. 
 
 53. The student must understand that when we 
 speak of one range being projective with another, we do 
 not mean necessarily that the one can be projected into 
 the other by a single projection, but that we can pass 
 from one range to the other by successive projections. 
 
 A range of four points is not in general projective 
 with any other range of four points in space. We shall 
 in the next chapter set forth the condition that must be 
 satisfied to render the one projective with the other. 
 
 EXERCISES. 
 
 1. Prove that a system of parallel lines in a plane /? will 
 project on to another plane into a system of lines through the 
 same point. 
 
 2. Two angles such that the lines containing them meet 
 the vanishing line in the same points are projected into angles 
 which are equal to one another. 
 
 3. Shew that in general three angles can be projected 
 into angles of the same magnitude a. 
 
 4. Shew that a triangle can be so projected that any line 
 in its plane is projected to infinity while three given con- 
 current lines through its vertices become the perpendiculars 
 of the triangle in the projection. 
 
 5. Prove that any triangle can be projected into an 
 equilateral triangle by a real projection. 
 
 6. Examine the reality of the projection of a quadrilateral 
 into a square. 
 
PROJECTION. 59 
 
 7. Any three points A-^, B^, C^ are taken respectively in 
 the sides BO, CA, AB of the triangle ABC; B^C^ and BC 
 intersect in F; Cj-ij and CA in G ; and A^^B^ and AB in H. 
 Also FB and BB^ intersect in M, and FG and CC^ in iV. 
 Prove that MG, NH and BG are concurrent. 
 
 8. If AA\ BB\ CC be chords of a conic concurrent at 
 0, and P any point on the conic, then the points of inter- 
 section of the straight lines BG, PA', of GA, PB', and of AB, 
 PG' lie on a straight line through 0. 
 
 [Project to infinity the line joining to the point of 
 intersection of AB, PG' and the conic into a circle.] 
 
 9. A, B, G, D are four points on a conic ; AB, GD meet 
 in E ] AG and BD in F ; and the tangents at A and D in G ', 
 prove that E, F, G are collinear. 
 
 [Project AD and BG into parallel lines and the conic into 
 a circle.] 
 
 10. Prove that a triangle can be so projected that three 
 given concurrent lines through its vertices become the medians 
 of the triangle in the projection. 
 
 11. If AA^, BB^, GGi be three concurrent lines drawn 
 through the vertices of a triangle ABG to meet the opposite 
 sides in A^B^Gi ; and if B^Gi meet BG in A 2, Ci^i meet GA in 
 B2, and A^Bj^ meet AB in G^ ; then A^, B^, G^ will be collinear. 
 
 [Project the concurrent lines into medians.] 
 
 12. If a conic be inscribed in a quadrilateral, the line 
 joining two of the points of contact will pass through one of 
 the angular points of the triangle formed by the diagonals of 
 the quadrilateral. 
 
 13. Prove Pascal's theorem, that if a hexagon be inscribed 
 in a conic the pairs of opposite sides meet in three collinear 
 points. 
 
 [Project the conic into a circle so that the line joining the 
 points of intersection of two pairs of opposite sides is projected 
 to infinity.] 
 
60 PROJECTION. 
 
 14. ^ is a fixed point in the plane of a conic, and P any 
 point on the polar of A. The tangents from P to the conic 
 meet a given line in Q and R, Shew that AR^ PQ, and AQ, 
 PR intersect on a fixed line. 
 
 [Project the conic into a circle having the projection of A 
 for its centre.] 
 
 15. If a triangle be projected from one plane on to 
 another the three points of intersection of corresponding sides 
 are collinear. 
 
 16. Pairs of conjugate lines through a focus of a conic 
 are at right angles. 
 
 17. PQ and P'Q' are two chords of a conic intersecting 
 in 0, prove that the polar of is the line joining the points 
 of intersection of PP\ QQ' and of PQ' and P'Q. 
 
 18. A system of conies having a common focus and 
 directrix can be projected into concentric circles. 
 
CHAPTEE V. 
 
 CROSS-RATIOS. 
 
 54. Definition. If A, B, G, Dhe a, range of points, 
 
 the ratio . y^' ^„ is called a cross-ratio of the four points, 
 AB.GB ^ 
 
 and is conveniently represented by (ABGD), in which the 
 
 order of the letters is the same as their order in the 
 
 numerator of the cross-ratio. 
 
 Some writers call cross-ratios 'anharmonic ratios.' 
 This is however not a fortunate term to use, and it 
 will be best to avoid it. For the term 'anharmonic' 
 means not harmonic, so that an anharmonic ratio should 
 be one that is not harmonic, whereas a cross-ratio may be 
 harmonic, that is to say may be the cross- ratio of what 
 is called a harmonic range. The student will better 
 appreciate this point when he comes to Chapter VII. 
 
 55. The essentials of a cross-ratio of a range of four 
 points are: (1) that each letter occurs once in both 
 numerator and denominator; (2) that the elements of 
 the denominator are obtained by associating the first and 
 last letters of the numerator together, and the third and 
 second, and in this particular order. 
 
62 CROSS-RATIOS. 
 
 AB CD 
 
 . j' p^ is not a cross-ratio but the negative of one, 
 
 BA.GD ,, , , • , K 
 
 ^y^ — jrji} though not appearing to be a cross-ratio as 
 
 ^y><- it stands, becomes one on rearrangement, for it = tT t^ ' ^ a , 
 ^^ thsitis (BACI)). 
 
 t ^\ Since there are twenty-four permutations of four 
 
 letters taken all together, we see that there are twenty- 
 four cross-ratios which can be formed with a range of 
 four points. 
 
 56. Prop. The twenty-four cross-ratios of a range 
 of four points are equivalent to six, all of which can he 
 expressed in terms of any one of them. 
 
 Let (ABCD) = \. 
 
 First we observe that if the letters of a cross-ratio be 
 interchanged in pairs simultaneously, the cross-ratio is 
 unchanged. 
 
 For 
 
 r «.4 Dn - ^^ • ^^' - 4^^^ - (ABOD) 
 (BADC) - ^g^T^ - XdTOB - (^^^^)' 
 
 (GDAB)- ^^-^^ - ^^-^^ - (ABCD) 
 
 / r\/-irt A \ J^^ • BA AB . 01) , . 7-,/^T^\ 
 
CROSS-RATIOS. 63 
 
 Hence we get 
 
 (ABCD) = (BADG) = (CDAB) = (DCBA) = \ . . . (1). 
 
 Secondly we observe that a cross-ratio is inverted if 
 we interchange either the first and third letters, or the 
 second and fourth. 
 
 .-. (ADGB) = (BCBA) = (CBAD) = (DABC) = i . . . (2). 
 
 , A, 
 
 These we have obtained from (1) by interchange of 
 second and fourth letters ; the same result is obtained by 
 interchanging the first and third. 
 
 Thirdly, since by § 31 
 
 AB.CD + BG.AD + GA.BD = 0, 
 AB.GD GA.BD _ 
 
 ' ' AD.GB '^ AD.GB~ . 
 , ^ GA.BD AG.BD , ,^j,j.. 
 
 •'• ^'^"^^-adTcb^adTbg^^^^^^^' 
 
 Thus the interchange of the second and third letters 
 changes X into 1 — X. We may remark that the same 
 result is obtained by interchanging the first and fourth. 
 
 Thus from (1) 
 
 {AGBD) = {BDAC)^{GADB) = {DBGA) = \-\...{^), 
 
 and from this again by interchange of second and fourth 
 letters, 
 
 {ADBG) = {BGAD) = (GBDA) = (DA GB) = -^ . . . (4). 
 
 1 — A. 
 
 In these we interchange the second and third letters, 
 and get 
 
 (ABDG) = (BAGD) = (GDBA) = (DGAB) 
 
64 CROSS-RATIOS. 
 
 And now interchanging the second and fourth we get 
 (AGDB) = (BDCA) = (GABD) = (DBAC) = ^^—^ ...(6). 
 
 A. 
 
 We have thus expressed all the cross-ratios in terms 
 of X. And we see that if one cross-ratio of four collinear 
 points be equal to one cross-ratio of four other collinear 
 points, then each of the cross- ratios of the first range is 
 equal to the corresponding cross- ratio of the second. 
 
 Two such ranges may be called equi-cross. 
 
 57. Prop. If A, B, C be three separate collinear 
 points, and D, E other points in their line such that 
 
 (ABCD) = (ABGE), 
 then D must coincide with E. 
 
 ^ . AB.GD AB.GE 
 
 Forsmce 2^705 = 2^705- 
 
 .-. AE.GD = AD.GE. 
 
 .-. {AD + DE)GD = AD{GD-^J)E). 
 
 .-. DE(AD-GD) = 0. 
 
 .-. DE.AG=^0. 
 
 .'. DE=0 for AG^O, 
 
 that is, D and E coincide. 
 
 58. Prop. A range of four points is equi-cross with 
 its projection on any plane. 
 
 Let the range ABGD be projected by means of the 
 vertex V into A'B'G'D'. 
 
CROSS-RATIOS. 
 
 65 
 
 Then 
 
 AB.CD AAVB ACVD ,, . , , , ,, 
 
 ADTCB = AAVD ' ACVB ' ''^^'^ ^"^^^ ^^^ *" *^" 
 
 signs of the areas, 
 
 JVA. VB sin AVB JVC. VD sin CVD 
 ~iVA. VDsinAVD' ^VG . VB sin CVB ' 
 
 regard being had to the signs of the angles, 
 
 _ sin ^7^ sin CFi) 
 "sin^rasinCF^- 
 
 Similarly 
 
 A'B'.G'D' 
 
 Fig. 1. 
 
 sin ^'F^' sin O'Fi)' 
 
 A'B' . G'B' ~ sin A'VB' sin G'VB' ' 
 
 A. G. 
 
66 CROSS-RATIOS. 
 
 Now in all the cases that arise 
 
 sin A' VB' sin G'VD' _ sin AVB sin GVD 
 sin A'VD' sin G'VB' ~ sin A VD sin CVB ' 
 
 This is obvious in fig. 1. 
 
 Fig. 2. 
 
 Fig. 3. 
 
 In fig. 2 
 sin A ' YB' — sin 5' YA , these angles being suppl ementary, 
 
 = -- sin AYB, 
 and sin A'YD' ^ sin UYA=- sin A YD. 
 

 
 CROSS-RATIOS. 
 
 
 Further sin 
 
 C'VD' = sin CVD, 
 
 
 and 
 
 sin 
 
 C'VB'=^sinGVB. 
 
 
 In fig. 
 
 3 
 
 
 
 
 sin^'F^' 
 
 = sin A VB, 
 
 
 
 sin C"Fi)' = 
 
 ==sinGVD, 
 
 
 
 sinA'VD': 
 
 = sinD'F^=-sin 
 
 AVD, 
 
 
 sin C'VB' 
 
 = sin5FC' =-sin 
 
 GVB. 
 
 Thusi 
 
 in each case 
 
 
 
 
 {A'B'C'I)') = (ABGD). 
 
 
 67 
 
 59. A number of lines in a plane which meet in a 
 point F are said to form a pencil, and each constituent 
 line of the pencil is called a ray. V is called the vertex 
 of the pencil. 
 
 Any straight line in the plane cutting the rays of the 
 pencil is called a transversal of the pencil. 
 
 From the last article we see that if VP^, VP^, VPs, 
 FP4 form a pencil and any transversal cut the rays of the 
 pencil in A, B, G, D, then (ABGD) is constant for that 
 particular pencil ; that is to say it is independent of the 
 particular transversal. 
 
 It will be convenient to express this constant cross- 
 ratio by the notation V {P^P,,P^P^. 
 
 We easily see that a cross-ratio of the projection of 
 a pencil on to another plane is equal to the cross-ratio of 
 the original pencil. 
 
 For let F(Pi, P^, P^, P4) be the pencil, the vertex 
 of projection. 
 
 5—2 
 
68 
 
 CROSS-EATIOS. 
 
 Let the line of intersection of the p and ir planes cut 
 the rays of the pencil in A, B, G, D, and let V be the 
 projection of F, VP^, of FPj, and so on. 
 
 p,'"' 
 
 pt 
 
 ..^'^^ 
 
 Then A BCD is a transversal also of 
 .: r(P,P,P,P,) = (ABGD) = V (P,'P,'P,'P:). 
 
 60. We are now in a position to set forth the con- 
 dition that two ranges of four points should be mutually 
 projective. 
 
CROSS-RATIOS. 
 
 69 
 
 Prop. If ABCD be a range, and A' BCD' another 
 range such that {A'B'C'D') = {ABCD), then the two ranges 
 are projective. 
 
 B/ 
 
 >-6 
 
 / ,' 
 
 ^- 
 
 Join A A' and take any point Fupon it. 
 Join VB, VC, VD and let these lines meet a line 
 through A' in the plane VAD in P, Q, R respectively. 
 Join PB', QC and let these meet in V\ Join V'A\ 
 and V'R, the latter cutting A'D' in X. 
 
 Then (ABCD) = (A'PQR) = (A'BV'X). 
 ' But (ABCD) = {A' BCD') by hypothesis. 
 .-. {A'EC'X)=^{A'B'C'D'). 
 .'. X coincides with D' (§ 57). 
 
70 CROSS-RATIOS. 
 
 Thus, by means of the vertex V, A BCD can be pro- 
 jected into A'PQR, and these again by the vertex V into 
 A'B'G'U. 
 
 Thus our proposition is proved. 
 
 61. Def. Two ranges ABODE. . . and A'B'G'D'E'. . . 
 
 are said to be homographic when a cross-ratio of any four 
 points of the one is equal to the corresponding cross-ratio- 
 of the four corresponding points of the other. This is 
 conveniently expressed by the notation 
 
 {ABODE. . .) = {A'B'0'D'E\ ..). 
 
 The student will have no difficulty in proving by 
 means of § 60 that two homographic ranges are mutually 
 projective. 
 
 Two pencils 
 
 V(P,Q,E,S,T...) and V\P\ Q', E, S\ T ...) 
 
 are said to be homographic when a cross-ratio of the 
 pencil formed by any four lines or rays of the one is 
 equal to the corresponding cross-ratio of the pencil formed 
 by the four corresponding lines or rays of the other. 
 
 62. Prop. Two homographic pencils are mutually 
 projective. 
 
 For let PQRS..., P'Q'R'S'... be any two transversals 
 of the two pencils, V and V the vertices of the pencils. 
 
 Let PQ'R'S" ... be the common range into which 
 these can be projected by vertices and 0'. 
 
 Then by means of a vertex iT on OF the pencil 
 V{P, Q, R,S.. .) can be projected into (P, Q", R", S" . . .) ; 
 
CROSS-RATIOS. 
 
 71 
 
 and this last pencil can, by a vertex L on 00', be projected 
 into 0' (P, q\ R'\ S". . .), that is, 0' {F, Q\ R, S\..); and 
 
 ""■"fc: J? ._ 
 
 p 
 
 '^^x'^ \ ' / / 
 
 _ Nttn^ 
 
 V' 
 
 TO 
 
 this again by means of a vertex M on O'F' can be pro- 
 jected into V\F\ Q', E, S'...). 
 
 63. We will conclude this chapter with a construction 
 for drawing through a given point in the plane of two 
 given parallel lines a line parallel to them, the construction 
 being effected by means of the ruler only. 
 
 Let Act), A^co' be the two given lines, co and a)' being 
 the point at infinity upon them, at which they meet. 
 
 Let P be the given point in the plane of these lines. 
 
72 
 
 CROSS-RATIOS. 
 
 Draw any line AG to cut the given lines in A and G, 
 and take any point B upon it. 
 Join PA cutting A^co' in ^i. 
 Join PB cutting Aj^w in B^ and A co in B2. 
 Join PC. 
 
 Let Ay A and B^G meet in Q. 
 Let Q5 meet GP in 0. 
 Let AiO and J. (7 meet in D. 
 PD shall be the line required. 
 
 For 
 {A.BficD') = B (A,B,Gco') = {A.B^Aay) = A, {A,B,Aay) 
 = (BB.PB,) = G (BB.PB,) = (AQPA,) = (AQPA,) 
 
 = (ABGD). 
 .-. P(A,B,Gcd') = P(ABGD). 
 .'. PD and Po)' are in the same line, 
 that is, PD is parallel to the given lines. 
 
CROSS-RATIOS. 73 
 
 EXERCISES. 
 
 1. If (ABCD) = — ^ and B be the point of trisection of 
 AD towards A, then C is the other point of trisection of AD. 
 
 2. Given a range of three points A, B, C, find a fourth 
 point D on their line such that (A BOD) shall have a given 
 value. 
 
 3. If the transversal ABC be parallel to OD, one of the 
 rays of a pencil {A, B, C, D), then 
 
 0(ABCD) = '^. 
 
 4. If (ABCD) = {ABC'D'), then (ABCC) = (ABDD'). 
 
 5. If ^, B, C, /) be a range of four separate points and 
 
 (ABCD) = (ADCB), 
 then each of these ratios = — 1 . 
 
 6. Of the cross-ratios of the range formed by the circum- 
 centre, median point, nine -points centre and orthocentre of a 
 triangle, eight are equal to - 1, eight to 2, and eight to |-. 
 
 7. Any plane will cut four given planes all of which 
 meet in a common line in four lines which are concurrent, 
 and the cross-ratio of the pencil formed by these lines is 
 constant. 
 
 8. If chords PQ of a conic S pass through a fixed point 
 0, and a point Ji be taken in FQ such that (OPRQ) is 
 constant, the locus of ^ is a conic having double contact 
 with >S'. 
 
 9. Taking a, b, c, d to be the distances from to the 
 points A, B, C, D all in a line with 0, and 
 
 X = (a-d)(b — c), fi = (b - d) (c — a), v = (c — d) (a - b), 
 shew that the six possible cross-ratios of the ranges that can 
 be made up of the points A, B, C, D are 
 
 /X V V X X fX 
 
 , , — , , , — T-. 
 
 V fji K V fx A. 
 
CHAPTEE YI. 
 
 PERSPECTIVE. 
 
 64. Def. A figure consisting of an assemblage of 
 points P, Q, R, S, &c. is said to be in perspective with 
 another figure consisting of an assemblage of points P\ 
 Q\ R', 8', &c., if the lines joining corresponding points, 
 viz. PP\ QQ\ RR', &c. are concurrent in a point 0. The 
 point is called the centre of perspective. 
 
 It is clear from this definition that a figure when 
 projected on to a plane or surface is in perspective with 
 its projection, the vertex of projection being the centre of 
 perspective. 
 
 It seems perhaps at first sight that in introducing the 
 notion of perspective we have arrived at nothing further 
 than what we already had in projection. So it may be 
 well to compare the two things, with a view to making 
 this point clear. 
 
 Let it then be noticed that two figures which are in 
 the same plane may be in perspective, whereas we should 
 not in this case speak of one figure as the projection of 
 the other. 
 
 In projection we have a figure on one plane or surface 
 and project it by means of a vertex of projection on to 
 another plane or surface, whereas in perspective the 
 
PERSPECTIVE. 75 
 
 thought of the planes or surfaces on which the two 
 figures lie is absent, and all that is necessary is that 
 the lines joining corresponding points should be con- 
 current. 
 
 So then while two figures each of which is the 
 projection of the other are in perspective, it is not 
 necessarily the case that of two figures in perspective 
 each is the projection of the other. 
 
 65. It is clear from our definition of perspective that 
 if two ranges of points be in perspective, then' the two 
 lines of the ranges must be cbplang^r. 
 
 For it A,B, G, &c. are in perspective with A\ E, C\ &c., 
 and be the centre of perspective, A'B' a,nd AB are in 
 the same plane, viz. the plane containing the lines OA, 
 OB. 
 
 It is also clear that ranges in perspective are homo- 
 graphic. 
 
 But it is not necessarily the case that two homographic 
 ranges in the same plane are in perspective. The following 
 proposition will shew under what condition this is the 
 case. 
 
76 PERSPECTIVE. 
 
 66. Prop. If two homographic ranges in the same 
 plane be such that the point of intersection of their lines is 
 a point corresponding to itself in the ttuo ranges, then the 
 ranges are in perspective. 
 
 For let {ABODE. ..) = {AB'G'D'E'. ..). 
 
 Let BE', CC meet in 0. 
 
 Join OD to cut AB' in D". 
 
 Then {AB'G'U) = {ABGD) 
 
 = {AEG'D"). 
 .'. D' and D" coincide. 
 
 Thus the line joining any two corresponding points in 
 the two homographic ranges passes through ; therefore 
 they are in perspective. 
 
 67. Two pencils V{A, B,G,D...) and V\A\ B\ G\ D\..) 
 will according to our definition be in perspective when V 
 and V are in perspective, points in VA in perspective 
 with points in V'A\ points in VB in perspective with 
 points in VB' and so on. 
 
PERSPECTIVE. 
 
 77 
 
 We can at once prove the following proposition : 
 
 If two pencils in different planes he in perspective they 
 have a common transversal and are homographic. 
 
 .-->y 
 
 Let the pencils be V{A,B,G,D. . .) and V'{A\ B\ G\ U). 
 
 Let the point of intersection of YA and V'A', which 
 are coplanar (§ 65), be P ; let that of VB, VF be Q ; and 
 so on. 
 
 The points P, Q, R, S, &c. each lie in both of the 
 planes of the pencils, that is, they lie in the line of 
 intersection of these planes. 
 
 Thus the points are collinear, and since 
 
 V{ABCD. . .) = (PQRS. ..) = r {A'B'G'D'. . .), 
 the two pencils are homographic. 
 
 The line PQRS. . . containing the points of intersection 
 of corresponding rays is called the axis of perspective. 
 
78 PERSPECTIVE. 
 
 68. According to the definition of perspective given 
 at the beginning of this chapter, two pencils in the same 
 plane are always in perspective, with any point on the 
 line joining their vertices as centre. 
 
 Let the points of intersection of corresponding rays 
 be, as in the last paragraph, P, Q, R, S, &c. 
 
 We cannot now prove P, Q, R, S... to be collinear, for 
 indeed they are not so necessarily. 
 
 But if the points P, Q, &c. are collinear, then we say 
 that the pencils are coaxal. 
 
 If the pencils are coaxal they are at once seen to be 
 homographic. 
 
 69. It is usual with writers on this subject to define 
 two pencils as in perspective if their corresponding rays 
 intersect in collinear points. 
 
 The objection to this method is that you have a 
 different definition of perspective for different purposes. 
 
 We shall find it conducive to clearness to keep rigidly 
 to the definition we have already given, and we shall 
 speak of two pencils as coaxally in perspective if the 
 intersections of their corresponding rays are collinear. 
 
 As we have seen, two non-coplanar pencils in perspec- 
 tive are always coaxal ; but not so two coplanar pencils. 
 
 Writers, when they speak of two pencils as in perspec- 
 tive, mean what we here call ' coaxally in perspective.' 
 
 70. Prop. If two homographic pencils in the same 
 plane have a corresponding ray the same in both, they are 
 coaxally in perspective. 
 
 Let the pencils be 
 V{A,B,C,D,^c.) and V {A, B', C, D\ kc.) 
 with the common ray VV'A. 
 
PERSPECTIVE. 79 
 
 Let VB and V'B' intersect in jS, VG and V'C in 7, 
 VD and V'D' in S, and so on. 
 
 Let 7/S meet V'VA in a, and let it cut the rays^FD 
 and VD' in 81 and 82 respectively. 
 
 Then since the pencils are homographic, 
 V(ABGD)=V'(AB'C'D'). 
 
 .-. (a/3780 = («^7^2). 
 
 Therefore Bi and 83 coincide with S. 
 
 Thus the intersection of the corresponding rays VD 
 and VD' lies on the line ^y. 
 
 Similarly the intersection of any two other correspond- 
 ing rays lies on this same line. 
 
 Therefore the pencils are coaxally in perspective. 
 
80 
 
 PERSPECTIVE. 
 
 71. Prop. If ABC..., A'RG'..., he two coplanar 
 homographic ranges not having a common corresponding 
 point, then if two pairs of corresponding points he cross- 
 joined (e.g. AB' and A'B) all the points of intersection so 
 obtained are coUinear. 
 
 Let the lines of the ranges intersect in P. 
 
 Now according to our hypothesis P is not a corre- 
 sponding point in the two ranges. 
 
 It will be convenient to denote P by two different 
 letters, X and Y\ according as we consider it to belong to 
 the ABG... or to the A'B'C... range. 
 
 Let X'he the point of the A'B'C... range correspond- 
 ing to X in the other, and let Y be the point of the 
 ABG... range corresponding to Y' in the other. 
 
 Then {ABGXY...) = {A'EG'X'Y'...). 
 
 .'. A'(ABGXY...) = A(A'B'G'X'Y\..). 
 
PERSPECTIVE. 81 
 
 These two pencils have a common ray, viz. AA\ 
 therefore by the last proposition the intersections of 
 their corresponding rays are collinear, viz. 
 
 A'B, AB'; A'G, AC; A'X, AX'; A'Y, AY'; 
 
 and so on. 
 
 From this it will be seen that the locus of the inter- 
 sections of the cross-joins of A and A' with B and B\ 
 G and C and so on is the line X' Y. 
 
 Similarly the cross-joins of any two pairs of corre- 
 sponding points will lie on X'Y. 
 
 This line X'Y is called the homographic axis of the 
 two ranges. 
 
 72. The student may obtain practice in the methods 
 of this chapter by proving that if 
 
 V(A, B, C..,) and V {A\ E, G',..) 
 
 be two homographic coplanar pencils not having a 
 common corresponding ray, then if we take the inter- 
 sections of VP and V'Q\ and of VQ and V'P' {VP, VP' ; 
 and VQ, VQ being any two pairs of corresponding 
 lines) and join these, all the lines thus obtained are 
 concurrent. 
 
 It will be seen when we come to Reciprocation that 
 this proposition follows at once from that of § 71. 
 
 A. G. 
 
82 
 
 PERSPECTIVE. 
 
 TRIANGLES IN PERSPECTIVE. 
 
 73. Prop. If the vertices of two triangles are in 
 perspective, the intersections of their corresponding sides 
 are collinear, and conversely. 
 
 (1) Let the triangles be in different planes. 
 Let be the centre of perspective of the triangles 
 ABC, A'B'C. 
 
 Since EC, B'C are in a plane, viz. the plane containing 
 OB and 00, they will meet. Let X be their point of 
 intersection. 
 
 Similarly CA and G'A' will meet (in Y) and AB and 
 A'B' (in Z). 
 
 Now X, Y, Z are in the planes of both the triangles 
 ABC, A' B'C. 
 
 Therefore they lie on the line of intersection of these 
 planes. 
 
 Thus the first part of our proposition is proved. 
 
PERSPECTIVE. i83 
 
 Next let the triangles ABC, A'B'C be such that the 
 intersections of corresponding sides {X, Y, Z) are collinear. 
 
 Since EG and B'C meet they are coplanar, and 
 similarly for the other pairs of sides. 
 
 Thus we have three planes BCG'B\ GAA'C, ABBA', 
 of which AA', BB\ GG' are the lines of intersection. 
 
 But three planes meet in a point. 
 
 Therefore AA\ BB', GG' are concurrent, that is, the 
 triangles are in perspective. 
 
 (2) Let the triangles be in the same plane. 
 
 First let them be in perspective, centre 0. 
 
 Let X, Y, Z be the intersections of the corresponding 
 sides as before. 
 
 Project the figure so that XF is projected to infinity. 
 
 Denote the projections of, the different points by 
 corresponding small letters. 
 
 We have now 
 
 oh : oh' — oc : oc' since he is parallel to h'c' 
 = oa : oa since ca is parallel to cV. 
 .*. ah is parallel to a'h'. 
 .'. 2^ is at infinity also, 
 that is, X, y, z are collinear. 
 
 .*. X,Y, Z are collinear. 
 
 6—2 
 
84 PERSPECTIVE. 
 
 Next let X, Y, Z be collinear ; we will prove that the 
 triangles are in perspective. 
 
 Let A A' and BB' meet in 0. 
 Join OC and let it meet A'C in 0". 
 Then ABC and A'B'C" are in perspective. 
 .*. the intersection of BG and B'G'' lies on the line YZ. 
 But BG and B'G' meet the line YZ in X by hypo- 
 thesis. 
 
 .•. BV and 5'0' are in the same line, 
 i.e. C coincides with (7'. 
 Thus ABG and A'B'C are in perspective. 
 
 74. Prop. TAe necessary and sufficient condition that 
 the coplanar triangles ABG, A'B'G' should he in perspective 
 is 
 
 AB, . AB^\ GA, . GA, . BG, . BG, 
 
 = AG,.AG,.BA,.BA,.GB,.GB„ 
 
 Ai, A2 being the points in which A'B' and A'G' meet the 
 
 non-corresponding side BG, 
 Bi, B2 being the points in which B'G' and B'A' meet the 
 
 non-corresponding side GA, 
 
PERSPECTIVE. 
 
 85 
 
 6\, Ca being the points in which G'A' and G'B' meet the 
 non-co7'responding side AB. 
 
 First let the triangles be in perspective ; let X YZ be 
 the axis of perspective. 
 
86 PERSPECTIVE. 
 
 Then since X, ^i, C2 are collinear, 
 AB,.GX.BC, 
 ' ' AC\.BX.CB, 
 Since F, G^, A 2 are collinear, 
 
 AY.CA2.BC, 
 ' ■ AG,.BA,.GY 
 Since Z, Ai, B^ are collinear, 
 
 AB,.GA,.BZ 
 
 ^=1. 
 
 = 1. 
 
 = 1, 
 
 " AZ.BA^.GB.,'^' 
 
 Taking the product of these we have 
 AB,.AB,.GA,.GA2.BG,.BG,.AY.GX.BZ 
 AG^.AG^.BA^.BA^.GB^.GB^.AZ.BX.GY 
 
 But X, F, Z are collinear, 
 
 AY.GX.BZ 
 ' ' AZ.BX.GY~ 
 .'. AB,.AB2.GA,.GA2.BG,.BG2 
 
 = AG^.AG2.BA^.BA2.GB,.GB2. 
 
 Next we can shew that this condition is sufficient. 
 For it renders necessary that 
 
 AY.GX.B Z 
 AZ.BX.GY~ 
 
 .'. X, F, Z are collinear and the triangles are in 
 perspective. 
 
 Cor. If the triangle ABG be in perspective with 
 A'B'G\ and the points A^, A^, B^, B^, G^, Og be as defined 
 in the above proposition, it is clear that the three following 
 triangles must also be in perspective with ABG, viz. 
 
 (1) the triangle formed by the lines A^B^, B^G^, G^A^, 
 
 (2) „ „ „ „ AiBi, B^G^^GiAz, 
 
 (3) » » }) » -4iZ>i, ^2^1> C^2^2« 
 
PERSPECTIVE. 87 
 
 EXERCISES. 
 
 1. ABC, A'B'C are two ranges of three points in the 
 same plane ; BC and B'C intersect in J^, CA' and C'A in B^, 
 and AB' and A'B in C^ ; prove that A^, B^, Cj are collinear. 
 
 2. ABC and A'B'C are two coplanar triangles in per- 
 spective, centre 0, through any line is drawn not in the 
 plane of the triangle ; *S' and *S" are any two points on this 
 line. Prove that the triangle ABC by means of the centre aS', 
 and the triangle A'B'C by means of the centre S', are in 
 perspective with a common triangle. 
 
 3. Assuming that two non-coplanar triangles in perspec- 
 tive are coaxal, prove by means of Ex. 2 that two coplanar 
 triangles in perspective are coaxal also. 
 
 4. If ABC, A'B'C be two triangles in perspective, and if 
 BC and B'C intersect in A-^, CA' and CA in B^, AB' and 
 A'B in Ci, then the triangle A^B^Cj will be in perspective 
 with each of the given triangles, and the three triangles will 
 have a common axis of perspective. 
 
 5. When three triangles are in perspective two by two 
 and have the same axis of perspective, their three centres of 
 perspective are collinear. 
 
 6. The points Q and B lie on the straight line AC, and 
 the point V on the straight line AD ; VQ meets the straight 
 line ^^ in ^, and VB meets AB in Y ; X is another point on 
 AB', XQ meets ^Z> in U, and XR meets AD in W, prove 
 that YU, ZW, AC are concurrent. 
 
 7. The necessary and sufficient condition that the co- 
 planar triangles ABC, A'B'C should be in perspective is 
 
 Ah' . Be . Ca = Ac' . Ba . Ch', 
 where a', h', c denote the sides of the triangle A'B'C opposite 
 to A', B', C respectively, and Ah' denotes the perpendicular 
 from A on to h'. 
 
 [Let B'C and BC meet in X ', CA' and CA in Y ; A'B' 
 
88 PERSPECTIVE. 
 
 and AB in Z. The condition given ensures that X, Y, Z are 
 collinear.] 
 
 8. Prove that the necessary and sufficient condition that 
 the coplanar triangles ABC^ A'B'C should be in perspective is 
 
 sin ABC sin ^^^' sin BCA' sin BCB' sin CAB' sin CAC _ 
 sin ACB' sin ACA' sin CBA' sin CBC sin BAG' sin BAB' " ' 
 
 [This is proved in Lachlan's Modern Pure Geometry. The 
 student has enough resources at his command to establish the 
 test for himself. Let him turn to § 36 Cor., and take in turn 
 at A\ B', C and at the centre of perspective. The result is 
 easily obtained. Nor is it difficult to remember if the student 
 grasps the principle, by which all these formulae relating to 
 points on the sides of a triangle are best kept in mind — the 
 principle, that is, of travelling round the triangle in the two 
 opposite directions, (1) AB, BC, CA, (2) AC, CB, BA.] 
 
 9. If a conic be described cutting the sides of a triangle 
 ABC in .4i, A^', B^, B^\ C-^, C^', the triangle formed by the 
 lines -SjCo, C-^^A^, A^B^ is in perspective with ABC. 
 
 [Project into a circle and use § 74.] 
 
 10. Two triangles in plane perspective can be projected 
 into equilateral triangles. 
 
 11. ABC is a triangle, /j, /g, /g its ecentres opposite to 
 A, B, C respectively, /g/g meets BC in A^, I^li meets CA in 
 B^ and I^/^ meets AB in C^, prove that A^, B^, C^ are collinear. 
 
 12. If AD, BE, CF and AD', BE', CF' be two sets of 
 concurrent lines drawn through the vertices of a triangle 
 A BC and meeting the opposite sides in D, E, F and D' , E' , F' , 
 and if EF and E' F' intersect in X, FD and F' U in Y, and- 
 DE and D'E' in Z, then the triangle XYZ is in perspective 
 with each of the triangles ABC, DEF, D'E'F'. 
 
 [Project the triangle so that AD, BE, CF become the 
 perpendiculars in the projection and AD', BE', CF' the 
 medians, and then use Ex. 7.] 
 
CHAPTER VII. 
 
 HARMONIC SECTION. 
 
 75. Def. Four collinear points A, B, G, D are said 
 to form a harmonic range if 
 
 {ABCD) = -l. 
 
 y I n • 
 
 A b"' c b 
 
 We have in this case 
 
 AB.cn 
 
 = -1. 
 
 AD.GB 
 AB ^ AB-AG _ AB-AG 
 •'• AD AD-AG~AG-AD' 
 thus ^(7 is a harmonic mean between AB and AD. 
 
 Now reverting to the table of the twenty-four cross- 
 ratios of a range of four points (§ bQ)j we see that if 
 (ABGD) = — 1, then all the following cross-ratios = — 1 : 
 (ABGDJ, {BADG\ (GDAB), {DGBA)] 
 iADGB), \BGDA), \GBAD), {DABG)! 
 Hence not only is J.C a harmonic mean between AB 
 and AD, but also 
 
 BD is a harmonic mean between BA and BG, 
 DB „ „ „ DC and i)^, 
 
 GA „ „ „ GBsii^dGD. 
 
90 HARMONIC SECTION. 
 
 We shall then speak of A and C as harmonic con- 
 jugates to B and D, and express the fact symbolically 
 thus : 
 
 (AC,BD)=~1. 
 
 By this we mean that all the eight cross-ratios given 
 above, and in which, it will be observed, A and G are 
 alternate members, and B and D alternate, are equal 
 to -1. 
 
 When (AG, BD) = — 1 we sometimes speak of D as 
 the fourth harmonic of A, B and G ; or again we say that 
 AG is divided harmonically at B and D, and that BD is 
 so divided at A and G. Or again we may say that G is 
 harmonically conjugate with A with respect to B and D. 
 
 A pencil P(A, B, G, D) of four rays is called harmonic 
 when the points of intersection of its rays with a trans- 
 versal form a harmonic range. 
 
 The, student can easily prove for himself that the 
 internal and external bisectors of any angle form with 
 the lines containing it a harmonic pencil. 
 
 76. Prop. If (AG, BD) = - 1, and he the middle 
 point of AG, then 
 
 OB.OD = OG'=OA'. 
 
 A O i C D 
 
 For since (ABGD) = -l, 
 
 .-. AB.GD = -AD.GB. 
 
 Insert the origin 0. 
 ,-. {OB - OA){OD -0G) = - (OD - OA)(OB - OG). 
 
 But OA = -OG. 
 
 ,'. {OB + OG) {OD -0G) = - {OD + OG) {OB - OG). 
 
HARMONIC SECTION. 91 
 
 .-. OB.OD + OC.OD-OB.OG-OC' 
 
 ^-OD.OB + OG.OD-OB.OC-hOC. 
 
 .'. 20B.OD = 20C'. 
 .-. OB.OD = OG' = AO''=OA\ 
 Similarly if 0' be the middle point of BD, 
 0'C.O'A = 0'B^ = 0'D\ 
 
 Cor. The converse of the above proposition is true, 
 viz. that if A BCD be a range and the middle point of 
 AG and OG' = OB . OD, then (AG, BD) = - 1. 
 
 This follows by working the algebra backwards. 
 
 77. Propt. // {AG, BD) = -l,the circle on AG as 
 diameter will cut orthogonally every circle through B 
 and D. 
 
 Let be the middle point o{ AG and therefore the 
 centre of the circle on AG. 
 
 Let this circle cut any circle through B and 2) in P ; 
 then 
 
 OB.OD = OG'=OP\ 
 
92 
 
 HARMONIC SECTION. 
 
 Therefore OP is a tangent to the circle BPD ; thus 
 the circles cut orthogonally. 
 
 Similarly, of course, the circle on BD will cut ortho- 
 gonally every circle through A and C. 
 
 Cor. 1. If A BOB he a range, and if the ch'cle on 
 AG as diameter cut orthogonally some one circle passing 
 through B and D, then (AC, BD) = — 1. 
 
 For using the same figure as before, we have 
 OB.OD=^OP^=OC\ 
 .-. {AG,BD) = -\. 
 
 Cor. 2. If two circles cut orthogonally, any diameter 
 of one is divided harmonically hy the other. 
 
 78. Prop. If on a chord PQ of a circle two con- 
 jugate points A, A' with respect to the circle be taken, then 
 
 (PQ,AA') = -1. 
 
 Draw the diameter OB through A to cut the polar of 
 A, on which A' lies, in L. 
 
HARMONIC SECTION. 93 
 
 Let be the centre. 
 Then by the property of the polar, 
 OL.OA = 0G\ 
 .'. {GD,LA) = -1. 
 
 Therefore the circle on CD as diameter (i.e. the given 
 circle) will cut orthogonally every circle through A and L. 
 
 But the circle on AA' as diameter passes through A 
 and L. 
 
 Therefore the given circle cuts orthogonally the circle 
 on J. ^' as diameter. 
 
 But the given circle passes through P and Q. 
 .-. (PQ,AA') = -1. 
 
 Cor. The above property holds for any conic, for the 
 conic can be projected into a circle, and points forming a 
 harmonic range in the one figure will correspond to points 
 forming a harmonic range in the other, since cross-ratios 
 are unaltered by projection. 
 
 This harmonic property of conies is of great import- 
 ance and usefulness. It may be otherwise stated thus : 
 
 •^ Chords of a conic through a point A are harmonically 
 divided at A and at the point of intersection of the chord 
 with the polar of A. 
 
 The reader will easily see that the well-known 
 property of the ellipse or hyperbola, viz. GV .GT —GP^ 
 (see figure), is a particular case of the above proposition. 
 
 For QQ' is the polar of T. 
 
 .'. (Pp, Fr) = -i. 
 
 .-. GV.GT=GP\ 
 
94 HARMONIC SECTION. 
 
 This property can be proved for the ellipse by ortho- 
 gonal projection, but not so for the hyperbola. 
 
 Note that if TPp does not pass through the centre of 
 the conic, the above relation holds good, provided G be 
 the middle point of Pp. 
 
 79. Prop. Each of the three diagonals of a plane 
 quadrilateral is divided harmonically hy the other two. 
 
 Let AB, BG, GD, DA be the four lines of the quadri- 
 lateral; A, B, G, D, E, F its six vertices, that is, the 
 intersections of its lines taken in pairs. 
 
 Then AG, BD, EF are its diagonals. 
 
 Let FQR be the triangle formed by its diagonals. 
 
 Project EF to infinity. Denote the points in the 
 projection by corresponding small letters. 
 
 Then 
 
 bp . dq bp 
 
 {BPDQ) = {bpdq)^ 
 
 bq . dp dp 
 (since -^ = 1, q being at oo j 
 
 hq 
 -1. 
 
HARMONIC SECTION. 
 
 95 
 
 Similarly (APCR)=^-1. 
 
 Also (FQER) = B (FQER) = (A PGR) 
 
 Thus we have proved 
 {AG,PR)==-l, (BD,PQ) = -1, (EF,QR) = -1. 
 
 Cor. The circumcircle of PQR will cut orthogonally 
 the three circles described on the three diagonals as 
 diameters. 
 
 Note. It has been incidentally shewn in the above 
 proof that if M be the middle point of AB, and co the 
 point at infinity on the line, (AB, Mco) = — 1. 
 
 80. The harmonic property of the quadrilateral, 
 proved in the last article, is of very great importance. 
 It is important too that at this stage of the subject the 
 student should learn to take the * descriptive ' view of the 
 quadrilateral ; for in ' descriptive geometry,' the quadri- 
 lateral is not thought of as a closed figure containing an 
 area ; but as an assemblage of four lines in a plane, which 
 meet in paiiS-ULsix points called the vertices; and the 
 
 V^ 
 
 
 [(university 
 
9b HARMONIC SECTION. 
 
 three lines joining such of the vertices as are not already 
 joined by the lines of the quadrilateral are called diagonals. 
 By opposite vertices we mean two that are not joined by a 
 line of the quadrilateral. 
 
 81. A quadrilateral is to be distinguished from a 
 quadrangle. A quadrangle is to be thought of as an 
 assemblage of four points in a plane which can be joined 
 in pairs by six straight lines, called its sides or lines ; two 
 of these sides which do not meet in a point of the quad- 
 rangle are called opposite sides. And the intersection of 
 two opposite sides is called a diagonal point. This name 
 is not altogether a good one, but it is suggested by the 
 analogy of the quadrilateral. 
 
 Let us illustrate the leading features of a quadrangle 
 by the accompanying figure. 
 
 ABCD is the quadrangle. Its sides are AB, EG, CD, 
 DA, AC and BR 
 
 AB and CD, AG and BB, AD and BG are pairs of 
 opposite sides and the points P, Q, R where these intersect 
 are the diagonal points. 
 
 The triangle PQR may be called the diagonal triangle. 
 
HARMONIC SECTION. 97 
 
 The harmonic property of the quadrangle is that the 
 two sides of the diagonal triangle at each diagonal point 
 are harmonic conjugates with respect to the two sides of the 
 quadrangle meeting in that point. 
 
 The student will have no difficulty in seeing that this 
 can be deduced from the harmonic property of the quadri- 
 lateral proved in § 79. 
 
 On account of the harmonic property, the diagonal 
 triangle associated with a quadrangle has been called the 
 harmonic triangle. 
 
 82. Prop. If a conic pass through the four points of 
 a quadrangle, the diagonal or harmonic triangle is self- 
 polar with regard to the conic — that is, each vertex is the 
 pole of the opposite side. 
 
 Let A BCD be the quadrangle ; PQR the diagonal or 
 harmonic triangle. 
 
 Let FQ cut AD and BC in X and Y. 
 Then (AD,XR) = -1, 
 
 .'. the polar of R goes through X (§ 78), 
 
 A. G. 
 
98 HARMONIC SECTION. 
 
 and (BG,YR) = -1, 
 
 .'. the polar of M goes through F. 
 .*. PQ is the polar of R. 
 Similarly QR is the polar of P, and PR of Q. 
 Thus the proposition is proved. 
 
 Another way of stating this proposition would be to 
 say that the diagonal points when taken in pairs are 
 conjugate for the conic. 
 
 The triangle PQR is also called self-conjugate with 
 regard to the conic. 
 
 83. We might also prove that if a conic touch the 
 four lines of a quadrilateral, the triangle formed by the 
 diagonals of the quadrilateral isself-polar or self-conjugate 
 with regard to the conic. 
 
 The student will see when he comes to the chapter on 
 Reciprocation how this proposition may be at once inferred 
 from that proved in § 82. 
 
 84. We have seen that any conic can be projected 
 into a circle, therefore we may consider every conic to be 
 the projection of some circle. 
 
 Now the nature of the conic into which a circle is 
 projected will depend on the position of the vanishing 
 line in the plane of the circle. 
 
 If the vanishing line does not meet the circle in any 
 real points, then the projection of the circle has no real 
 points at infinity, that is, the projection will be an ellipse. 
 
 If the vanishing line cut the circle in two real points, 
 th^ projection of the circle will have two real points at 
 infinity and the tangents at these points will not be 
 wholly at infinity, that is, the curve will be a hyperbola, 
 
HARMONIC SECTION. 99 
 
 whose asymptotes are the projections of the tangents to 
 the circle at the points where the vanishing line cuts it. 
 
 If the vanishing line touch the circle the projection of 
 the circle will have one real point at infinity and will 
 touch the line at infinity at that point, that is, the curve 
 will be a parabola. 
 
 85. We will now set forth some of the properties of 
 the parabola, already well known by the ordinary methods 
 of elementary Geometry, by regarding it as the projection 
 of a circle, the vanishing line in the plane of the circle 
 being a tangent to it. 
 
 Let R be any point on the vanishing line, which is a 
 tangent to the circle at I). 
 
 Through R draw RQQ' to cut the circle in Q and Q\ 
 and let the tangents at Q and Q' meet in T. 
 
 Join TD to cut QQ' in V and the circle in P. 
 
 Now R lies on the polar of T, therefore the polar of R 
 goes through T. 
 
 But the polar of R goes through D. 
 
 7—2 
 
100 HARMONIC SECTION. 
 
 Therefore DT is the polar of K 
 
 .-. {VR,QQ') = -1. 
 And we have also 
 
 {VT,PD) = -l, 
 and farther PR is the tangent at P. 
 
 Now project, and let corresponding small letters be 
 used in the projection ; r and d are at infinity and we 
 have 
 
 (1) The tangent at p is parallel to qq'. 
 
 (2) {vt,pd) = — l, .•.tp=pv.^ 
 
 (3) (vr, qq') = — 1, .'. q'v = vq. 
 
 (4) The locus of the middle points of a system of 
 parallel chords is a straight line meeting the curve in the 
 point at infinity, that is, a straight line parallel to the axis. 
 
 These the reader will recognise as well-known pro- 
 perties of the parabola. 
 
 86. Next we will consider the hyperbola as the 
 projection of a circle, the vanishing line in the plane 
 of the circle cutting the circle in two real and non- 
 coincident points. 
 
 Let DE be the vanishing line cutting the circle in D 
 and E. 
 
 Let the tangents at D and E meet in G. 
 
 Let the chord QQ' meet the vanishing line in R and 
 the tangents at D and E in L and L'. 
 
 Since R lies on the polar of C, the polar of R goes 
 through G. 
 
 Let this polar be GPP' cutting QQ' in F, DE in K, 
 and the circle in P and P'. 
 
HARMONIC SECTION. 
 
 101 
 
 Let RP, which will be tangent at P, cut CD, GE in 
 T and T. 
 
 Y~il 
 
 Then we have 
 
 (FE, QQ0 = -1, 
 
 {GK,PF) = -1, 
 
 (RK, DE) = -\, 
 
 and from this last {RP, TT) = - 1. 
 
 Now CD and GE project into cd and ce, the asymptotes 
 of the hyperbola. 
 
 We have then the following properties, which the 
 reader will recognise as already familiar: 
 
 qq' being parallel to the tangent at p, and cutting the 
 diameter through p in v, 
 
 (vr, qq') = — l. 
 
102 
 
 HARMONIC SECTION. 
 .*. qv = vq\ since r is at oc 
 
 dat^ 
 
 e at)< 
 
 Hence 
 
 tp=pt' . 
 
 Iv = vr. 
 
 lq=q'l'. 
 
 EXERCISES. 
 
 1. If if and N be points in two coplanar lines AB, CD, 
 shew that it is possible to project so that M and N project 
 into the middle points of the projections oi AB and CD. 
 
 2. AA^, BB^j CG-^ are concurrent lines through the 
 vertices of a triangle meeting the opposite sides in Jj, B^, C^. 
 B^Ci meets BC in A^; C^Aj meets CA in B^; Aj^B^ meets AB 
 in Ca ; prove that 
 
 {BC,A,A,) = -l, {CA,BA) = -l, {AB,C,C,) = -l. 
 
HARMONIC SECTION. 103 
 
 3. Prove that the circles described on the lines ^^i-^g, 
 B^Bi^i Gfi^ (as defined in Ex. 2) as diameters are coaxal. 
 
 [Take P a point of intersection of circles on A-^A^, B^B^y 
 and shew that CjCg subtends a right angle at F. Use Ex. 2 
 and § 27.] 
 
 4. The collinear points A, D, C are given : GE is any- 
 other fixed line through C, E is a, fixed point, and B is any 
 moving point on CE. The lines AE and BD intersect in Qj 
 the lines CQ and BE in B, and the lines BR and AC in P. 
 Prove that P is a fixed point as B moves along CE. 
 
 5. From any point M in the side BC of a triangle ABC 
 lines MB' and MC are drawn parallel to AC and AB respec- 
 tively, and meeting AB and AC in B' and C. The lines ^C" 
 and CB' intersect in P, and AP intersects B'C in M'. Prove 
 that M'B' : M'C = MB : .IfC. 
 
 6. Pairs of harmonic conjugates [DD'), (EE'), {FF') are 
 respectively taken on the sides BC, CA, AB oi a triangle ABC 
 with respect to the pairs of points {BC), (CA), (AB). Prove 
 that the corresponding sides of the triangles DEF and D'E'F' 
 intersect on the sides of the triangle ABC, namely EF and 
 E'F' on BC, and so on. 
 
 7. The lines VA', VB', VC bisect the internal angles 
 formed by the lines joining any point V to the angular points 
 of the triangle ABC ; and A' lies on BC, B' on CA, C on AB. 
 Also A", B", C" are harmonic conjugates of A', B', C with 
 respect to B and 6', C and A, A and B. Prove that A!', B'\ 
 C" are collinear. 
 
 8. Prove that all conies with respect to which a given 
 triangle is self -con jugate and which pass through a fixed point 
 A , pass also through three other fixed points. 
 
 9. AA^, BB^, CCi are the perpendiculars of a triangle 
 ABC; AjB^ meets AB in C^', X is the middle point of line 
 joining A to the orthocentre ; C^K and BB^ meet in T. 
 Prove that C^T is perpendicular to BC. 
 
104 HARMONIC SECTION. 
 
 10. A system of conies touch AB and AC at B and C. 
 D is a. fixed point, and BD, CD meet one of the conies in 
 P, Q. Shew that FQ meets BC in a fixed point. 
 
 11. If ^, ^ be given points on a circle, and if CD be a 
 given diameter, shew how to find a point F on the circle such 
 that FA and FB shall cut CD in points equidistant from the 
 centre. 
 
 12. A line is drawn cutting two non-intersecting circles; 
 find a construction determining two points on this line such 
 that each is the point of intersection of the polar s of the other 
 point with respect to the two circles. 
 
 13. A^, B^, Ci are points on the sides of a triangle ABC 
 opposite to A, B, C. A.^, B^, Cg are points on the sides such 
 that Ai, A2 are harmonic conjugates with B and C : B^, B^, with 
 C and A', C-^, C2 with A and B. If A^, B.2, C^ are collinear, 
 then must AA-^, BB^, CC^ be concurrent. 
 
 14. -4^1, BB^, CCi are concurrent lines through the 
 vertices of a triangle ABC. B^Ci meets BC in A^, C-^A^ meets 
 CA in B^, A^B^ meets AB in C^. Prove that the circles on 
 A-^A^, B^B^, C1C2 as diameters all cut the circumcircle of ABC 
 orthogonally, and have their centres in the same straight line. 
 
 [Compare Ex. 3.] 
 
 15. When a triangle is self-conjugate for a conic, two and 
 only two of its sides cut the curve in real points. 
 
 16. Prove that of two conjugate diameters of a hyperbola, 
 one and only one can cut the curve in real points. 
 
 [Two conjugate diameters and the line at infinity form a 
 self -conjugate triangle.] 
 
 17. If ^ and B be conjugate points of a circle and M the 
 middle point of AB, the tangents from M to the circle are of 
 length MA. 
 
 18. If a system of circles have the same pair of points 
 conjugate for each circle of the system, then the radical axes 
 of the circles, taken in pairs, are concurrent. 
 
HARMONIC SECTION. 105 
 
 19. If a system of circles have a common pair of inverse 
 points the system must be a coaxal one. 
 
 20. Prove that if a rectangular hyperbola circumscribe a 
 triangle the pedal triangle is a self- conjugate one. 
 
 21. and 0' are the limiting points of a system of coaxal 
 circles, and A is any point in their plane ; shew that the chord 
 of contact of tangents drawn from A to any one of the circles 
 will pass through the other extremity of the diameter through 
 A of the circle AOO'. 
 
 22. Through a fixed point D inside a given ellipse another 
 ellipse is drawn touching the given ellipse at two points ; 
 prove that their common chord intersects the tangent at D to 
 the second ellipse in a point whose locus is a straight line. 
 
 23. ^ is a fixed point without a given circle and P a 
 variable point on the circumference. The line ^i^ at right 
 angles to AP meets in F the tangent at P. If the rectangle 
 FAPQ be completed the locus of ^ is a straight line. 
 
CHAPTER VIII. 
 
 SOME PEOPERTIES OF CONICS. 
 
 87. Prop. If a conic cut the sides of a triangle 
 ABC in A-^, A^; A, ^2; 0^, G^; then 
 AB, . AB^ . CA, . CA, . BO, . BO, 
 
 = AG,.AG,. BA, . BA, . GB, . GB,. 
 
 Project the conic into a circle ; and denote the points 
 in the projection by corresponding small letters. 
 Then since abi . ah^ = aci . ac^, 
 
 cdi . ca, = cbi . ch^y 
 bci.bc2 = bai.ba2, 
 .'. abi. ab, . ca^ . ca, . bci . bc^ = ac^ . ac^ . bai . ba,2 . cb^ . cb,. 
 
SOME PROPERTIES OF CONICS. 107 
 
 .*. the triangle formed by the lines aA, ^A, c^a.^ is in 
 perspective with the triangle ahc (§ 74). 
 
 .'. the triangle formed by the lines A^B^, Bfi^, G^A^ 
 is in perspective with the triangle ABC. 
 
 .-.by §74 
 
 AB, . AB, . GA, . CA, . BC, . BC, 
 
 = AC,.AG,. BA, . BA, . GB, . GB,. 
 
 This is known as Carnot's theorem. 
 
 CoR. If a conic cut the sides of a triangle ABG in 
 Ai, A^; Bi, B^\ (7i, G^\ then the triangle ABG is in 
 perspective with the four following triangles : 
 
 (1) that formed by the lines A^B^, Bfi^, G1A2, 
 
 (2) „ „ „ „ A1B2, BiGi, C2A2, 
 
 (3) „ „ „ „ ^1^1, B.2G2, G1A2, 
 
 (4) „ „ „ „ A,B,,B2G„'G^2r-'^^^. 
 
 We thus have that ^^^^ ^' ^'" ^ ^'' 
 
 the intersections of AB, A^B^; BG, B1G2', GA, GiA^ 
 are collinear, 
 
 the intersections of AB, A^B2\ BG, Bfi^; GA, G2A2 
 are collinear, 
 
 the intersections of AB, AjB^; BG, B2G2; CA, G-^A^ 
 are collinear, 
 
 the intersections of AB, A^By^\ BG, ^a^^i ; CA, Oa^la^- « 
 are collinear. 4^; ^^/3^ fbi b,^i C^ C,^ 
 
 It will be seen further on (§ 93) that all these lines 
 of collinearity are included in the Pascal lines of the 
 hexagons formed with A^, A^, B^, B2, Gi, G2. 
 
108 
 
 SOME PROPERTIES OF CONICS. 
 
 88. Prop. If he a variable point in the plane of a 
 conic, and FQ, RS be chords in fixed directions through 0, 
 
 then ?^^ is constant. 
 UK . (Jo 
 
 Let 0' be any other point and through 0' draw the 
 chords F'Q\ R'S' parallel respectively to PQ and BS. 
 
 Let QP, QP' meet in o) at infinity and SR, S'R' 
 in n. 
 
 Let P'Q' and RS meet in T. 
 
 Now apply Carnot's theorem to the triangle wOT and 
 
 get 
 
 (oP.wQ.OR.OS.TP'.TQ' 
 
 but 
 
 wF.ayQ'.TR.TS.OP.OQ 
 
 (oP T J ^Q -, 
 
 ■n, = l and -7y = l. 
 (oP coQ 
 
 TP'.TQ' _ OP.OQ 
 •*• TR.TS "OR. OS' 
 
 = 1, 
 
SOME PROPERTIES OF CONICS. 109 
 
 Next apply Carnot's theorem to the triangle UTO' 
 and get 
 
 nRMS. TP'.TQ'. O'R . O'S' _ 
 nR .nS'. O'P' . O'Q' .TR,T8 
 TF,TQ' O'F.O'Q' 
 
 Hence 
 
 TR.T8 O'R'.O'S" 
 OP.OQ _ 0'F.O'Q ' 
 OR. OS O'R'.O'S" 
 
 ^, ^. OP.OQ. 
 
 that IS, .^ -.^ .. ,^ IS constant. 
 (Jli . (Jo 
 
 This proposition is known as Newton's theorem. Some 
 special cases of it are given as examples at the end of the 
 chapter. 
 
 89. Prop. If A, B, G, D he four fixed points on a 
 conic, and P a variable point on the conic, P(ABGD) is 
 constant and equal to the corresponding cross-ratio of the 
 four points in which the tangents at A, B, C, D meet that 
 at P. 
 
 c?, c, -6, a, 
 
 Project the conic into a circle and use corresponding 
 small letters in the projection. 
 
110 SOME PROPERTIES OF CONICS. 
 
 Then P (ABGD) = p (abed). 
 
 But p(abcd) is constant since the angles aph, hpc, cpd 
 are constant or change to their supplements as p moves 
 on the circle ; therefore P(ABCD) is constant. 
 
 Let the tangents at a, h, c, d cut that in p in aj, 61, Ci, 
 di and let be the centre of the circle. 
 
 Then Oa^, Obi, Oci, Od^ are perpendicular to pa, pb, 
 pCy pd. 
 
 .'. p (abed) = (aJ)iCidj) = (aJ)iCidi). 
 .-. P(ABCD) = (AiBfiiD,). 
 
 Cor. If -4' be a point on the conic near to A, we 
 have 
 
 A'(ABGD) = P(ABCD). 
 .*. if ^T be the tangent at A, 
 
 A(TBCD) = P(ABGD). 
 
 Note. In the special case where the pencil formed 
 by joining any point P on the conic to the four fixed 
 points A, B, G, D is harmonic, we speak of the points on 
 the conic as harmonic. Thus if P(ABGD) = — 1, we say 
 that A and G are harmonic conjugates to B and D. 
 
 90. Prop. If A, B, G, D be four fixed non-eollinear 
 points in a plane and P a point such that P (ABGD) is 
 constant, the locus of P is a conic. 
 
 Let Q be a point such that 
 
 Q (ABGD) = P(ABGD) by § 89. 
 
 Then if the conic through the points A, B, G, D, P 
 does not pass through Q, let it cut QA in Q'. 
 
 .'. P (ABGD) = Q' (ABGD). 
 .-. Q' (ABGD) = Q (ABGD). 
 
SOME PROPEETIES OF CONICS. Ill 
 
 Thus the pencils Q(A, B, G, B) and Q' {A, B, G, B) 
 are homographic and have a common ray QQ'. 
 
 Therefore (§ 70) they are coaxally in perspective ; that 
 is, A, B, G, B are collinear. 
 
 But this is contrary to hypothesis. 
 
 Therefore the conic through A, B, G, B, P goes 
 through Q. 
 
 Thus our proposition is proved. 
 
 We see from the above that we may regard a conic 
 through the five points A, B, G, B, E as the locus of a 
 point P such that 
 
 P(ABGB) = E{ABGB). 
 
 91. Prop. The envelope of a line which cuts four 
 non-concurrent coplanar fixed straight lines in four points 
 forming a range of constant cross-ratio is a conic touching 
 the four lines. 
 
 This proposition will be seen, when we come to the 
 next chapter, to follow by Reciprocation directly from the 
 proposition of the last paragraph. 
 
 The following is an independent proof. 
 
112 
 
 SOME PROPERTIES OF CONICS. 
 
 Let the line p cut the four non-concurrent lines a, h, 
 c, d in the points A, B, G, D such that (ABGD) — the 
 given constant. 
 
 Let the line q cat the same four lines in A\ B', C, D' 
 such that {A'B'G'U) = {ABGD). 
 
 Then if q be not a tangent to the conic touching a, 6, 
 c, d, p, from A' in q draw q a tangent to the conic. 
 
 Let b, c, d cut q in B'\ G'\ D\ 
 
 .-. {A'B"G"D") = {ABGD) by § 89 
 = {A' BCD'). 
 
 The ranges A'F'G"D" and A'B'G'U are therefore 
 homographic and they have a common corresponding 
 point. 
 
SOME PROPERTIES OF CONICS. 113 
 
 Therefore they are in perspective (§ 66), which is con- 
 trary to our hypothesis that a, h, c, d are non-concurrent. 
 
 Thus q touches the same conic as that which touches 
 a, by c, d, p. 
 
 And our proposition is established. 
 
 92. Prop. If P(A, B, G, D) he a pencil in the plane 
 of a conic S, and J-i, B^, C^, D^ the poles of PA, PB, PC, 
 PD with respect to S, then 
 
 P{ABCD) = {A,B,G,D,). 
 
 We need only prove this in the case of a circle, into 
 which, as we have seen, a conic can be projected. - 
 
 Let be the centre of the circle. 
 Then OA^, OB^, OC^, OD^ are perpendiculars respec- 
 tively to PA, PB, PC, PD. 
 
 .-. P{ABCD) = {A.BfiM = {A,B,C:D,), 
 
 This proposition is of the greatest importance for the 
 purposes of Reciprocation. 
 
 A. G. 8 
 
114 
 
 SOME PROPERTIES OF CONICS. 
 
 We had already seen that the polars of a range of 
 points form a pencil ; we now see that the pencil is 
 homographic with the range. 
 
 93. PascaPs theorem. If a conic pass through six 
 points A, B, G, D, E, F, the opposite pairs of sides of each 
 of the sixty different hexagons (six-sided figures) that can 
 he formed with these points intersect in collinear points. 
 
 There are several proofs of this celebrated theorem. 
 One was suggested to the student in Ex. 1.3 of Chapter IV. 
 Another is practically contained in the Cor. of § 87. We 
 will here give a third. 
 
 Consider the hexagon or six-sided figure formed with 
 the sides AB, BG, GD, DE, EF, FA. 
 
SOME PROPERTIES OF CONICS. 115 
 
 The pairs of sides which are called opposite are AB 
 and DE; BG and EF) CD and FA. 
 
 Let these meet in X, F, Z respectively. 
 Let CD meet EF in H, and DE meet FA in 0. 
 Then since A (BDEF) = G(BDEF), 
 .-. {XDEG) = {YREF). 
 
 These homographic ranges XDEQ and YHEF have a 
 common corresponding point E, 
 
 .-. ZF, DH and i^G^ are concurrent (§ m), 
 that is, Z, the intersection of DH and FG, lies on Z F. 
 
 Thus the proposition is proved. 
 
 The student should satisfy himself that there are sixty 
 different hexagons that can be formed with the six given 
 vertices. 
 
 94. Brianchon's theorem. If a conic he inscribed 
 in a hexagon the lines joining opposite vertices are con- 
 current 
 
 This can be proved after a similar method to that of 
 § 93, and may be left as an exercise to the student. We 
 shall content ourselves with deriving this theorem from 
 Pascal's by Reciprocation. To the principles of this 
 important development of modern Geometry we shall 
 come in the chapter immediately following this. 
 
 8—2 
 
116 SOME PROPERTIES OF CONICS. 
 
 EXERCISES. 
 
 1. If a conic touch the three sides of a triangle, the lines 
 joining the vertices of the triangle to the points of contact 
 with the opposite sides are concurrent. 
 
 2. If a conic cut the sides BC, CA, AB oi a, triangle ABC 
 in A^A^, B^B2, CjCc,, and AAj, BB^, CG-^ are concurrent, then 
 will AAc^, BB.^^ CC^ be concurrent. 
 
 3. The two tangents from an external point to a central 
 conic are in the ratio of the diameters parallel to them. 
 
 4. The squares of the tangents from an external point to 
 a parabola are in the ratio of the focal chords parallel to them. 
 
 5. Deduce from Newton's theorem the property for a 
 central conic 
 
 ^P :FV.Vp=CD' : CF\ 
 
 6. If (P, F'), (Q, Q') be pairs of harmonic points on a 
 conic (see Note on § 89), prove that the tangent at F and FF' 
 are harmonic conjugates to FQ and FQ'. Hence shew that if 
 FF be normal at F, FQ and PQ' make equal angles with FF'. 
 
 7. The straight line FF' cuts a conic at F and F' and is 
 normal at P. The straight lines FQ and FQ' are equally 
 inclined to FF and cut the conic again in Q and Q'. Prove 
 that F'Q and FQ' are harmonic conjugates to F'F and the 
 tangent at F'. 
 
 8. Shew that if the pencil formed by joining any point 
 on a conic to four fixed points on the same be harmonic, two 
 sides of the quadrangle formed by the four fixed points are 
 conjugate to each other with respect to the conic. 
 
 9. The tangent at any point P of a hyperbola intersects 
 the asymptotes in i/j and M^ and the tangents at the vertices 
 in i/j and Zg, prove that 
 
 FM^^PL^.FL^. 
 
SOME PROPERTIES OF CONICS. 117 
 
 10. Deduce from Pascal's theorem that if a conic pass 
 through the vertices of a triangle the tangents at these points 
 meet the opposite sides in collinear points. 
 
 [Take a hexagon AA'BB'CC in the conic so that A\ B\ C 
 are near to A, B, C] 
 
 11. If a conic pass through the points A, B, C, B, the 
 points of intersection oi AC and BD, of AB and CD, of the 
 tangents at B and C, and of the tangents at A and J) are 
 collinear. 
 
 12. Given three points ^4, ^, C on a conic, determine a 
 fourth point D on the same so that A and B may be harmonic 
 conjugates to C and D. 
 
 13. Given three points of a hyperbola and the directions 
 of both asymptotes, find the point of intersection of the curve 
 with a given straight line drawn parallel to one of the 
 asymptotes. 
 
 14. Through a fixed point on a conic a line is drawn 
 cutting the conic again in P, and the sides of a given 
 inscribed triangle in A\ B\ C. Shew that (PA'B'C) is 
 constant. 
 
 15. A, B, C, D are any four points on a hyperbola; CK 
 parallel to one asymptote meets ^D in K, and i)Z parallel 
 to the other asymptote meets CB in L. Prove that KL is 
 parallel to AB. 
 
 16. The sixty Pascal lines corresponding to six points on 
 a conic intersect three by three. 
 
 17. Any two points D and E are taken on a hyperbola of 
 which the asymptotes are CA and CB; the parallels to CA 
 and CB through D and E respectively meet in Q ; the tangent 
 at D meets CB in R, and the tangent at E meets CA in T. 
 Prove that T, Q, R are collinear, lying on a line parallel to DE. 
 
 18. The lines CA and CB are tangents to a conic at A 
 and B, and D and E are two other points on the conic. The 
 line CD cuts AB in G, AE in H, and BE in K. Prove that 
 
 CD'' : (9Z)2 = CH . CK : GH. GK. 
 
118 SOME PROPERTIES OF CONICS. 
 
 19. Through a fixed point A on a conic two fixed straight 
 lines AI, AI' are drawn, S and *S" are two fixed points and P 
 a variable point on the conic; FS, PS' meet AI, AI' in Q, Q' 
 respectively, shew that QQ' passes through a fixed point. 
 
 20. If two triangles be in perspective, the six points of 
 intersection of their non-corresponding sides lie on a conic, 
 and the axis of perspective is one of the Pascal lines of the six 
 points. 
 
 21. If two chords PQ, PQ' of a conic through a fixed 
 point P are equally inclined to the tangent at P, the chord 
 QQ' passes through a fixed point. 
 
 22. If the lines AB, BC, CD, DA touch a conic at P, Q, 
 P, S respectively, shew that conies can be inscribed in the 
 hexagons APQCES and BQRDSP. 
 
 23. The tangent at P to an ellipse meets the auxiliary 
 circle in Y and Y' . ASS' A' is the major axis and SY, S'Y' 
 the perpendiculars from the foci. Prove that the points A, 
 Y, Y', A' subtend at any point on the circle a pencil whose 
 cross-ratio is independent of the position of P. 
 
CHAPTER IX. 
 
 EECIPROCATION. 
 
 95. If we have a number of points P, Q, R, &c. in a 
 plane and take the polars p, q, r, &c. of these points with 
 respect to a conic F in the plane, then the line joining 
 any two of the points P and Q is, as we have already 
 seen, the polar with respect to V of the intersection of the 
 corresponding lines p and q. 
 
 It will be convenient to represent the intersection of 
 the lines ^ and q by the symbol (pq), and the line joining 
 the points P and Q by (PQ). 
 
 The point P corresponds with the line p, in the sense 
 that P is the pole of p, and the line (PQ) corresponds 
 with the point (pq) in the sense that (PQ) is the polar of 
 
 Thus if we have a figure F consisting of an aggregate 
 of points and lines, then, corresponding to it, we have 
 a figure F' consisting of lines and points. Two such 
 figures F and F' are called in relation to one another 
 Reciprocal figures. The medium of their Reciprocity is 
 the conic T. 
 
 Using § 92, we see that a range of points in F 
 corresponds to a pencil of lines, homographic with the 
 range, in F\ 
 
120 RECIPROCATION. 
 
 96. By means of the principle of correspondence 
 enunciated in the last paragraph we are able from a 
 known property of a figure consisting of points and lines 
 to infer another property of a figure consisting of lines 
 and points. 
 
 The one property is called the Reciprocal of the other, 
 and the process of passing from the one to the other is 
 known as Reciprocation. 
 
 We will now give examples. 
 
 97. We know that if the vertices of two triangles 
 ABC, A'B'C be in perspective, the pairs of corresponding 
 sides (BG) {B'G'l {GA) {G'A'), (AB) (A'B') intersect in 
 collinear points X, Y, Z. 
 
 Fig. F. 
 
 Now if we draw the reciprocal figure, corresponding to 
 the vertices of the triangle ABG, we have three lines 
 a, 6, c forming a triangle whose vertices will be (6c), (ca), 
 (a6). And similarly for A'B'G'. 
 
 Corresponding to the concurrency of {A A'), {BB'), 
 {GG') in the figure F, we have the coUinearity of {aa!), 
 (bb'), (cc) in the figure F\ 
 
RECIPROCATION. 
 
 121 
 
 Corresponding to the collinearity of the intersections 
 of (BC) (BV'\ (CA) (C'A'l (AB) (A'B) in figure F, we 
 have the concurrency of the lines formed by joining the 
 pairs of points (6c) (b'c), (ca) {ca'), {ah) {aU) in the 
 figure F'. 
 
 Fig. F'. 
 
 Thus the theorem of the figure F reciprocates into the 
 following : 
 
 If two triangles whose sides are ahc, a'h'c respectively 
 be such that the three intersections of the corresponding 
 sides are collinear, then the lines joining corresponding 
 vertices, viz. (ah) and (a'b'), (he) and (6V), (ca) and (c'a'), 
 are concurrent. 
 
 The two reciprocal theorems placed side by side may 
 be stated thus : 
 
 Triangles in perspective 
 are coaxaL 
 
 Coaxal triangles are in 
 perspective. 
 
122 
 
 RECIPROCATION. 
 
 The student will of course have realised that a triangle 
 regarded as three lines does not reciprocate into another 
 triangle regarded as three lines, but into one regarded as 
 three points ; and vice versa. 
 
 98. Let us now connect together by reciprocation the 
 harmonic property of the quadrilateral and that of the 
 quadrangle. 
 
 Let a, h, c, d be the lines of the quadrilateral ; A, B, 
 C, D the corresponding points of the quadrangle. 
 
 iac) 
 
 (ab) 
 
 b 
 
 (be) 
 
 Fig. F. 
 
 Let the line 
 
 joining 
 
 ■ (ab) and (cd) be p, 
 
 }) 5 J 
 
 „ 
 
 (ac) and (bd) be q, 
 
 }* ») 
 
 „ 
 
 (ad) and (be) be r. 
 
 (bd) 
 
RECIPROCATION. 
 
 123 
 
 The harmonic property of the quadrilateral is expressed 
 symbolically thus : 
 
 [{ah){cd), (i>r)(pg)} = -l, 
 {{ad) {he), {pr){qr)\=-l, 
 [{ac){hd\ {pq){qr)} = -h 
 
 Fig. F'. 
 
 The reciprocation gives 
 
 {{AB)(GD),iPR)iPQ)}=-l, 
 
 {{AD){BG), (PR){QR)] = -1, 
 
 \{AG){BD), iPQ){QR)] = -l. 
 
 If these be interpreted on the figure we have the 
 
 harmonic property of the quadrangle, viz. that the two 
 
 sides of the diagonal triangle at each vertex are harmonic 
 
 conjugates with the two sides of the quadrangle which 
 
 pass through that vertex. 
 
124 RECIPROCATION. 
 
 The student sees now that the ' diagonal points ' of a 
 quadrangle are the reciprocals of the diagonal lines of the 
 quadrilateral from which it is derived. Hence the term 
 'diagonal points.' 
 
 99. We are now going on to explain how the principle 
 of Reciprocation is applied to conies. 
 
 Suppose the point P describes a curve S in the plane 
 of the conic V, the line p, which is the polar of P with 
 regard to F, will envelope some curve which we will 
 denote by S'. 
 
 Tangents to S' then correspond to points on >Sf ; but 
 we must observe further that tangents to >S correspond to 
 points on S'. 
 
 For let P and P' be two near points on 8, and let p 
 and p' be the corresponding lines. 
 
 Then the point {pp') corresponds to the line {PP'). 
 
 Now as P' moves up to P, {PP') becomes the tangent 
 to >Sf at P, and at the same time {pp') becomes the point 
 of contact of^ with its envelope. 
 
 Hence to tangents of 8 correspond points on S'. 
 
 Each of the curves S and S' is called the polar reci- 
 procal of the other with respect to the conic T. 
 
 100. Prop. If S be a conic then S' is another conic. 
 
 Let A, B, G, D be four fixed points on S, and P any 
 other point on 8. 
 
 Then P {ABCD) is constant. 
 
 But P (ABCD) = {(pa) (pb) (pc) (pd)] by § 92. 
 
 .". {(pa) (pb) (pc) (pd)] is constant. 
 
 .*. the envelope of jp is a conic touching the lines a, b, 
 c, d (§ 91). 
 
 Hence S' is a conic. 
 
RECIPROCATION. 125 
 
 This important proposition might have been proved as 
 follows. 
 
 S, being a conic, is a curve of the second order, that is, 
 straight lines in its plane cut it in two and only two 
 points, real or imaginary. 
 
 Therefore S' must be a curve of the second class, that 
 is a curve such that from each point in its plane two and 
 only two tangents can be drawn to it ; that is, S' is a conic. 
 
 101. Prop. If 8 and S' be two conies reciprocal to 
 each other with respect to a conic V, then pole and polar of 
 S correspond to polar and pole of S'. 
 
 Let P and TV he pole and polar of S. 
 
 [It is most important that the student should under- 
 stand that TU is the polar of P with respect to S, not 
 to r. The polar of P with respect to F is the line we 
 denote by p.] 
 
 Fig. F. 
 
 Let QR be any chord of >Si which passes through P ; 
 then the tangents at Q and E meet in the line Tf/',at T say. 
 
 Therefore in the reciprocal figure p and (tu) are so 
 related that if any point (qr) be taken on p, the chord of 
 contact t of tangents from it to S' passes through (tu). 
 
 .'. p and {tu) are polar and pole with respect to S'. 
 
126 
 
 RECIPROCATION. 
 
 Cor. 1. Conjugate points of S reciprocate into conju- 
 gate lines of S' and vice versa. 
 
 Cor. 2. A self-conjugate triangle of S will reciprocate 
 into a self-conjugate triangle of 8\ 
 
 102. We will now set forth some reciprocal theorems 
 in parallel columns. 
 
 1. If a conic be inscribed 
 in a triangle (i.e. a three- side 
 figure), the joining lines of the 
 vertices of the triangle and 
 the points of contact of the 
 conic with the opposite sides 
 are concurrent. 
 
 If a conic be circumscribed 
 to a triangle (a three-point 
 figure), the intersections of the 
 sides of the triangle with the 
 tangents at the opposite ver- 
 tices are collinear. 
 
 (aej a (ap) 
 
 (ab) 
 
 2. The six points of in- 
 tersection with the sides of a 
 triangle of the lines joining 
 the opposite vertices to two 
 fixed points lie on a conic. 
 
 3. The three points of 
 intersection of the opposite 
 
 The six lines joining the 
 vertices of a triangle to the 
 points of intersection of the 
 opposite sides and two fixed 
 lines envelope a conic. 
 
 The three lines joining the 
 opposite vertices of each of 
 
RECIPROCATION. 127 
 
 sides of each of the six-side the six-point figures formed 
 
 figures formed by joining six by the intersections of lines 
 
 points on a conic are collinear. touching a conic are concur- 
 
 — Pascal's theorem. rent. — Brianchon's theorem. 
 
 4. If a conic circumscribe If a conic be inscribed in 
 a quadrangle, the triangle a quadrilateral, the triangle 
 formed by its diagonal points formed by its diagonals is self- 
 is self -conjugate for the conic. conjugate for the conic. 
 
 103. Prop. The conic S' is an ellipse, parabola or 
 hyperbola, according as the centre of T is within, on, or 
 without S. 
 
 For the centre of T reciprocates into the line at 
 infinity, and lines through the centre of T into points 
 on the line at infinity. 
 
 Hence tangents to S from the centre of T will recipro- 
 cate into points at infinity on S', and the points of contact 
 of these tangents to S will reciprocate into the asymptotes 
 of^; 
 
 Hence if the centre of F be outside S, S' has two real 
 asymptotes and therefore is a hyperbola. 
 
 If the centre of F be on ^, >Sf' has one asymptote, viz. 
 the line at infinity, that is, S' is a parabola. 
 
 If the centre of F be within S, S' has no real 
 asymptote and is therefore an ellipse. 
 
 104. Case where F is a circle. 
 
 If the auxiliary or base conic F be a circle (in which 
 case we will denote it by G and its centre by 0) a further 
 relation exists between the two figures F and F' which 
 does not otherwise obtain. 
 
 The polar of a point P with respect to G being 
 perpendicular to OP^ we see that all the lines of the 
 
128 RECIPROCATION. 
 
 figure F or F' are perpendicular to the lines joining to 
 the corresponding points of the figure F' or F. 
 
 And thus the angle between any two lines in the one 
 figure is equal to the angle subtended at by the line 
 joining the corresponding points in the other. 
 
 In particular it may be noticed that if the tangents 
 from to >Sf are at right angles, then S' is a rectangular 
 hyperbola. 
 
 For if OP and OQ are the tangentJi to S, the 
 asymptotes of 8' are the polars of P and Q with respect 
 to G, and these are at right angles since POQ is a right 
 angle. 
 
 If then a parabola be reciprocated with respect to a 
 circle whose centre is on the directrix, or a central conic 
 be reciprocated with respect to a circle with its centre on 
 the director circle, a rectangular hyperbola is always 
 obtained. 
 
 Further let it be noticed that a triangle whose ortho- 
 centre is at will reciprocate into another triangle also 
 having its orthocentre at 0. This the student can easily 
 verify for himself 
 
 105. It can now be seen that the two following 
 propositions are connected by reciprocation: 
 
 1. The orthocentre of a triangle circumscribing a 
 parabola lies on the directrix. 
 
 2. The orthocentre of a triangle inscribed in a rect- 
 angular hyperbola lies on the curve. 
 
 These two propositions can be proved independently. 
 The first has been set as an exercise in Chapter I., the 
 second is given in most books on Geometrical Conies. 
 
 Let us now see how the second can be derived from 
 the first by reciprocation. 
 
RECIPROCATION. 129 
 
 Let the truth of (1) be assumed. 
 
 Reciprocate with respect to a circle C having its 
 centre at the orthocentre of the triangle. 
 
 Now the parabola touches the line at infinity, there- 
 fore the pole of the line at infinity with respect to (7, viz. 
 0, lies on the reciprocal curve. 
 
 And the reciprocal curve is a rectangular hyperbola 
 because is on the directrix of the parabola. 
 
 Further is also the orthocentre of the reciprocal of 
 the triangle circumscribing the parabola. 
 
 Thus w^e have that if a rectangular hyperbola be 
 circumscribed to a triangle, the orthocentre lies on the 
 curve. 
 
 It is also clear that no conies hut rectangular hyperbolas 
 can pass through the vertices of a triangle and its ortho- 
 centre. 
 
 106. Prop. If 8 he a circle and we reciprocate with 
 respect to a circle C whose centre is 0, S' will he a conic 
 having for a focus. 
 
 Let A be the centre of S. 
 
 Let p be any tangent to S, Q its point of contact. 
 
 Let P be the pole of p, and a the polar of A with 
 respect to G. 
 
 Draw PM perpendicular to a. 
 
 Then since ^Q is perpendicular to p, we have by 
 Salmon's theorem (§ 17) 
 
 OP PM 
 0A~ AQ' 
 
 OP ^, ^ ^ OA 
 
 • • -fnrf = the constant r7\ • 
 PM AQ 
 
 A. G. 9 
 
130 
 
 EECIPROCATION. 
 
 Thus the locus of P which is a point on the reciprocal 
 curve is a conic whose focus is (9, and corresponding 
 directrix the polar of the centre of ;S*. 
 
 OA 
 Since the eccentricity of S' is ^„ we see that S' is an 
 
 ellipse, parabola, or hyperbola according as is within, 
 on, or without S. This is in agreement with § 103. 
 
 Cor. The polar reciprocal of a conic with respect to 
 a circle having its centre at a focus of the conic is a 
 circle, whose centre is the reciprocal of the corresponding 
 directrix. 
 
 107. Let us now reciprocate with respect to a circle 
 the theorem that the angle in a semicircle is a right 
 angle. 
 
 Let A be the centre of S, KL any diameter, Q any 
 point on the circumference. 
 
 In the reciprocal figure we have corresponding to A 
 the directrix a, and ^ point {kl) on it corresponds to {KL). 
 
EECIPROCATION. 
 
 131 
 
 k and I are tangents from {kl) to S' which correspond 
 to K and L, and q is the tangent to >S" corresponding 
 to Q. 
 
 Now {QK) and {QL) are at right angles. 
 
 Therefore the line joining {qk) and {ql) subtends a 
 right angle at the focus of S'. 
 
 Hence the reciprocal theorem is that the intercept on 
 any tangent to a conic between two tangents which intersect 
 in the directrix subtends a right angle at the focus. 
 
 108. Prop. A system of non-intersecting coaxal 
 circles can be reciprocated into confocal conies. 
 
 Let L and L' be the limiting points of the system of 
 circles. 
 
 Reciprocate with respect to a circle G whose centre is 
 at L. 
 
 . 9—2 
 
132 RECIPROCATION. 
 
 Then all the circles will reciprocate into conies having 
 L for one focus. 
 
 Moreover the centre of the reciprocal couic of any one 
 of the circles is the reciprocal of the polar of L with 
 respect to that circle. 
 
 But the polar of L for all the circles is the same, viz. 
 the line through L' perpendicular to the line of centres 
 (i 22). 
 
 Therefore all the reciprocal conies have a common 
 centre as well as a common focus. 
 
 Therefore they all have a second common focus, that 
 is, they are confocal. 
 
 109. We know that if ^ be a common tangent to two 
 circles of the coaxal system touching them at P and Q, PQ 
 subtends a right angle at L. 
 
 Now reciprocate this with regard to a circle with its 
 centre L. The two circles of the system reciprocate into 
 confocal conies, the common tangent t reciprocates into a 
 common point of the confocals, and the points P and Q 
 into the tangents to the confocals at the common point. 
 
 Hence confocal conies cut at right angles. 
 
RECIPROCATION. 133 
 
 This fact is of course known and easily proved other- 
 wise. We are here merely illustrating the principles of 
 reciprocation. 
 
 110. Again it is known (see Ex. 17 of Chap. II.) that 
 if >S^i and S^ be two circles, L one of the limiting points, 
 and P and Q points on S^ and ^2 respectively such that 
 PLQ is a right angle, the envelope of PQ is a conic 
 having a focus at L. 
 
 Now reciprocate this property with respect to a circle 
 having its centre at L. 81 and >S\ reciprocate into 
 confocals with L as one focus; the points P and Q 
 reciprocate into tangents to S/ and >Si2', viz. p and q, which 
 will be at right angles ; and the line (PQ) reciprocates 
 into the point (pq). 
 
 As the envelope of (PQ) is a conic with a focus at L, 
 it follows that the locus of (pq) is a circle. 
 
 Hence we have the theorem : 
 
 If two tangents from a point T, one to each of two 
 confocals, be at right angles, the locus of T is a circle. 
 
 This also is a well-known property of confocals. 
 
 111. We will conclude this chapter by proving two 
 theorems, the one having reference to two triangles which 
 are self-conjugate for a conic, the other to two triangles 
 reciprocal for a conic. 
 
 Prop. If two triangles he self -conjugate to the same 
 conic their six vertices lie on a conic and their six sides 
 touch a conic. 
 
 Let ABC, A'B'C be the two triangles self-conjugate 
 with respect to a conic S. 
 
134 
 
 RECIPROCATION. 
 
 Project 8 into a circle with A projected into the 
 centre ; then (using small letters for the projections) 
 ab, ac are conjugate diameters and are therefore at right 
 angles, and b and c lie on the line at infinity. 
 
 Further a^b'c is a triangle self-conjugate for the circle. 
 .', a the centre of the circle is the orthocentre of this 
 triangle. 
 
 C atoo h ' 
 
 Let a conic be placed through the five points a', b\ c', 
 a and 6. 
 
RECIPROCATION. 
 
 135 
 
 This must be a rectangular hyperbola, since as we 
 have seen no conies but rectangular hyperbolas can pass 
 through the vertices of a triangle and its orthocentre. 
 
 .'. c also lies on the conic through the five points named 
 above, since the line joining the two points at infinity on 
 a rectangular hyperbola must subtend a right angle at 
 any point. 
 
 Hence the six points a, h, c, a, b\ c all lie on a conic. 
 
 .*. the six points A, B, G, A\ B\ C also lie on a conic. 
 
 The second part of the proposition follows at once by 
 reciprocating this which we have just proved. 
 
 112. Prop. If two triangles are reciprocal for a 
 conic, they are in perspective. 
 
 Let ABC, A'B'C be two triangles which are reciprocal 
 for the conic >S; that is to say, A is the pole of B'C, B the 
 
 pole of G'A', C the pole of A'B') and consequently also 
 A' is the pole of BG, E of GA, and G' of AB. 
 
136 RECIPROCATION. 
 
 Project S into a circle with the projection of A for its 
 centre. .*. B' and C are projected to infinity. 
 
 Using small letters for the projection, we have since 
 a' is the pole of be, .'. aa is perpendicular to he. 
 
 Also since h' is the pole of ac, ah' is perpendicular to 
 ac ; .' .hh' which is parallel to ah' is perpendicular to ac. 
 
 Similarly cc is perpendicular to ah. 
 
 .'. aa\ hh' , cc meet in the orthocentre of the triangle ahc. 
 
 .'. AA', BB', CC are concurrent. 
 
 EXERCISES. 
 
 1. If the conies S and S' be reciprocal polars with respect 
 to the conic V, the centre of S' corresponds to the polar of the 
 centre of V with respect to S. 
 
 2. Parallel lines reciprocate into points collinear with the 
 centre of the base conic V. 
 
 3. Shew that a quadrangle can be reciprocated into a 
 parallelogram. 
 
 4. Reciprocate with respect to any conic the theorem : 
 The locus of the poles of a given line with respect to conies 
 passing through four fixed points is a conic. 
 
 [The theorem which is here to be reciprocated will be set 
 as an exercise at the end of Chapter X.] 
 
 Reciprocate with respect to a circle the theorems contained 
 in Exx. 5 — 12 inclusive. 
 
 5. The perpendiculars from the vertices of a triangle on 
 the opposite sides are concurrent. 
 
 6. The tangent to a circle is perpendicular to the radius 
 through the point of contact. 
 
RECIPROCATION. 137 
 
 7. Angles in the same segment of a circle are equal. 
 
 8. The opposite angles of a quadrilateral inscribed in a 
 circle are together equal to two right angles. 
 
 9. The angle between the tangent at any point of a circle 
 and a chord through that point is equal to the angle in the 
 alternate segment of the circle. 
 
 10. The polar of a point with respect to a circle is 
 perpendicular to the line joining the point to the centre 
 of the circle. 
 
 11. The locus of the intersection of tangents to a circle 
 which cut at a given angle is a concentric circle. 
 
 12. Chords of a circle which subtend a constant angle at 
 the centre envelope a concentric circle. 
 
 13. Two conies having double contact will reciprocate 
 into conies having double contact. 
 
 14. A circle S is reciprocated by means of a circle C into 
 a conic S'. Prove that the radius of C is the geometric mean 
 between the radius of S and the semi-latus rectum of aS". 
 
 15. Prove that with a given point as focus four conies 
 can be drawn circumscribing a given triangle, and that the 
 sum of the latera recta of three of them will equal the latus 
 rectum of the fourth. 
 
 16. Conies have a focus and a pair of tangents common ; 
 prove that the corresponding directrices will pass through a 
 fixed point, and all the centres lie on the same straight line. 
 
 17. Prove, by reciprocating witli respect to a circle with 
 its centre at S, the theorem : If a triangle ABC circumscribe 
 a parabola whose focus is S, the lines through A, B, C per- 
 pendicular respectively to SA, SB, SO are concurrent. 
 
 18. Conies are described with one of their foci at a fixed 
 point aS', so that each of the four tangents from two fixed 
 points subtends the same angle of given magnitude at S. 
 
138 RECIPROCATION. 
 
 Prove that the directrices corresponding to the focus S pass 
 through a fixed point. 
 
 19. If be any point on the common tangent to two 
 parabolas with a common focus, prove that the angle between 
 the other tangents from to the parabolas is equal to the 
 angle between the axes of the parabolas. 
 
 20. A conic circumscribes the triangle ABC, and has one 
 focus at 0, the orthocentre; shew that the corresponding 
 directrix is perpendicular to 10 and meets it in a point X 
 such that lO.OX^AO. OD, where / is the centre of the 
 inscribed circle of the triangle, and D is the foot of the 
 perpendicular from A on BC. Shew also how to find the 
 centre of the conic. 
 
 21. Prove that chords of a conic which subtend a con- 
 stant angle at a given point on the conic will envelope a conic. 
 
 [Reciprocate into a parabola by means of a circle having 
 its centre at the fixed point.] 
 
 22. If a triangle be reciprocated with respect to a circle 
 having its centre on the circumcircle of the triangle, the 
 point will also lie on the circumcircle of the reciprocal 
 triangle. 
 
 23. Prove the following and obtain from it by reciproca- 
 tion a theorem applicable to coaxal circles : If from any point 
 pairs of tangents p, p' ; q, q\ be drawn to two confocals S^ and 
 S^, the angle between p and q is equal to the angle between 
 p' and q'. 
 
 24. Prove and reciprocate with respect to any conic the 
 following : If ABC be a triangle, and if the polars of A, B, C 
 with respect to any conic meet the opposite sides in P, Q, It, 
 then P, Q, R are collinear. 
 
 25. A fixed point in the plane of a given circle is 
 joined to the extremities A and B of any diameter, and OA, 
 OB meet the circle again in P and Q. Shew that the tangents 
 at P and Q intersect on a fixed line parallel to the polar of 0. 
 
RECIPROCATION. 139 
 
 26. All conies through four fixed points can be projected 
 into rectangular hyperbolas. 
 
 27. If two triangles be reciprocal for a conic (§ 112) their 
 centre of perspective is the pole of the axis of perspective with 
 regard to the conic. 
 
 28. Prove that the envelope of chords of an ellipse which 
 subtend a right angle at the centre is a concentric circle. 
 
 [Reciprocate with respect to a circle having its centre at 
 the centre of the ellipse.] 
 
 29. ABC is a triangle, / its incentre ; A-^, B^, Cx the 
 points of contact of the incircle with the sides. Prove that 
 the line joining / to the point of concurrency of AA^^ BB^, 
 CGx is perpendicular to the line of collinearity of the inter- 
 sections of ^iCi, B0\ Ci^i, CA ; A,B„ AB. 
 
 [Use Ex. 27.] 
 
CHAPTEE X. 
 
 INVOLUTION. 
 
 113. Definition. 
 
 If be a point on a line on which lie pairs of points 
 A, A^; B, B^; G, G-,; &c. such that 
 
 OA . 0A, = OB . 0B, = OG . 0G,= = k 
 
 the pairs of points are said to be in Involution. Two 
 associated points, such as A and A-^, are called conjugates) 
 and sometimes one of two conjugates is called the ' mate ' 
 of the other. 
 
 The point is called the Centre of the involution. 
 
 Kl_ i _j L_ 
 
 B, B d C A K A« Ci 
 
 If k, the constant of the involution, be positive, then 
 two conjugate points lie on the same side of 0, and there 
 will be two real points K, K' on the line on opposite 
 sides of such that each is its own mate in the involu- 
 tion; that is OK''=OK'^ = k. These points K and K' 
 are called the double points of the involution. 
 
INVOLUTION. 141 
 
 It is important to observe that K is not the mate of 
 K'\ that is why we write K' and not K^. 
 
 It is clear that (^^i, KK') = — \, and so for all the 
 pairs of points. 
 
 If k be negative, two conjugate points will lie on 
 opposite sides of 0, and the double points are now 
 imaginary. 
 
 If circles be described on AA^, BB^, CC^, &c. as 
 diameters they will form a coaxal system, whose axis cuts 
 the line on which the points lie in 0. 
 
 K and K' are the limiting points of this coaxal system. 
 
 Note also that for every pair of points, each point is 
 inverse to the other with respect to the circle on KK' as 
 diameter. 
 
 It is clear that an involution is completely determined 
 when two pairs of points are known, or, what is equivalent, 
 one pair of points and one double point, or the two double 
 points. 
 
 We must now proceed to establish the criterion that 
 three pairs of points on the same line may belong to the 
 same involution. 
 
 114. Prop. The necessary and sufficient condition 
 that a pair of points C, G-^ should belong to the involution 
 determined by A, A^; B, Bi is 
 
 {ABGA,) = (A,BAA), 
 First we will shew that this condition is necessary. 
 Suppose G and Cj do belong to the involution. Let 
 be its centre and k its constant. 
 
 ,'.0A. OA, = OB . OB, = OG . OG, = k 
 
142 INVOLUTION. 
 
 . ,,nn.._ ^B.CA ,_ (OB-OA)(OA-OC) 
 • ' V^^^^i^ -AA^.GB" {OA, - OA) {OB - OG) 
 
 / k k \( k ^\ 
 
 J\OA 
 
 \0B, OAJ \0A OCJ 
 f k k \ I k k 
 
 [oa~oaJ\ob,~og, 
 
 {OB,-OA,)(OA-OC,) _ A,B,.C,A 
 ~(0A - OA,){OB, - OG,) ~ A,A . G,B, -^^i^i^i^^ 
 
 Thus the condition is necessary. 
 
 [A more purely geometrical proof of this theorem will 
 be given in the next paragraph.] 
 
 Next the above condition is sufficient. 
 For let (ABGA,) = (A.BA^) 
 
 and let G' be the mate of G in the involution determined 
 hyA,A', B,B,. 
 
 .'.(ABGA,) = {A,B,G'A). 
 .'.{A,Bfi,A) = {A,B,G'A). 
 .'. (7i and G' coincide. 
 Hence the proposition is established. 
 
 Cor. 1. If A, A,; B, B,; G, G,-, D, A belong to the 
 same involution 
 
 {ABGD) = {A,Bfi,D,). 
 
 Cor. 2. If K, K' be the double points of the'involution 
 {AA^KK') = (A.AKK') and (ABKA,) = (A,B,KA). 
 
 115. We may prove the first part of the above 
 theorem as follows. 
 
 If the three pairs of points belong to the same involu- 
 tion, the circles on AA,, BB,, CG, as diameters will be 
 coaxal. 
 
INVOLUTION. 143 
 
 Let P be a point of intersection of these circles. 
 
 Then the angles APA^, BPB^, GPG^ are right angles 
 and therefore 
 
 P {ABGA,) = P {A,Bfi,A). 
 .\{ABGA,) = (A,B,C,A). 
 
 The circles may not cut in real points. But the 
 proposition still holds on the principle of continuity 
 adopted from Analysis. 
 
 116. The proposition we have just proved is of the 
 very greatest importance. 
 
 The critei'ion that three pairs of points belong to the 
 same involution is that a cross-ratio formed with three of 
 the points, one taken from each pair, and the mate of any 
 one of the three should he equal to the corresponding cross- 
 ratio formed by the mates of these four points. 
 
 It does not of course matter in what order we write 
 the letters provided that they correspond in the cross- 
 ratios. We could have had 
 
 {AA^GB) = {A,AC,B,) 
 or {AA,C,B) = {A,AGB,): 
 
144 INVOLUTION. 
 
 All that is essential is that of the four letters used in 
 the cross-ratio, three should furnish one letter of each pair. 
 
 117. Prop. A range of points in involution projects 
 into a range in involution. 
 
 For let A, A^; B, B^; C, G^ be an involution and let 
 the projections be denoted by corresponding small letters. 
 Then ' {ABCA,) = (A,B,C,A). 
 
 But (ABGA,) = {abca^) 
 
 and (A^BiCiA) = (aJ)iCia). 
 
 .'. (ahca^) = {aJ)iCia). 
 .'. a, ay; h,hy\ c, c^ form an involution. 
 
 Note. The centre of an involution does not project 
 into the centre of the involution obtained by projection ; 
 but the double points do project into double points. 
 
 118. Involution Pencil. 
 
 We now see that if we have a pencil consisting of 
 pairs of rays 
 
 VP, VF; VQ, VQ'; VR, VR &c. 
 such that any transversal cuts these in pairs of points 
 
 A, A,; B, B,; C, C^ &c. 
 forming an involution, then every transversal will cut the 
 pencil so. 
 
 Such a pencil will be called a Pencil in Involution or 
 simply an Involution Pencil. 
 
 The double lines of the involution pencil are the lines 
 through V on which the double points of the involutions 
 formed by different transversals lie. 
 
 Note that the double lines are harmonic conjugates 
 with any pair of conjugate rays. 
 
INVOLUTION. 145 
 
 From this fact it results that if VD and YD' he the 
 double lines of an involution to which VA, VA^ belong, then 
 VJD and VD' are a pair of conjugate lines for the in- 
 volution whose double lines are VA, VA^. 
 
 119. Prop. An involution range reciprocates with 
 respect to a conic into an involution pencil. 
 
 For let the involution range be 
 
 A,A^; B,B,; G,G^8zc. 
 on a line p. 
 
 The pencil obtained by reciprocation will be a, a^] 
 b, bi; c, Ci &c. through a point P. 
 
 Also (abca,) = (ABGA,) 
 
 and (aibiC^a) =^ (A^B^C^A) hy ^ 92. 
 
 But (ABGA,) = {A,Bfi,A) by § 114. 
 
 . • . (abcai) = {a-JbxCia). 
 
 Thus the pencil is in involution. 
 
 120. Involution property of the quadrangle and 
 quadrilateral. 
 
 Prop. Any transversal cuts the pairs of opposite sides 
 of a quadrangle in pairs of points which are in involution. 
 
 Let ABGD be the quadrangle (§81). 
 
 A. G. 10 
 
146 INVOLUTION. 
 
 Let a transversal t cut 
 
 the opposite pairs of sides AB, CD in E, E^, 
 „ „ „ „ AG,BDmF,F,, 
 
 AD,BG'mG,G,. 
 Let AD and BG meet in P. 
 Then {GEFG,) = A {GEFG,) 
 = {PBGG,) 
 = D{PBGG,) 
 = {GF,E,G,) 
 
 = (GiEiF-^G) by interchanging the 
 letters in pairs. 
 Hence E, E^; F, F^ ; G, G^ belong.to the same involution. 
 We have only to reciprocate the above theorem to 
 obtain this other : 
 
 The lines joining any 'point to the pairs of opposite 
 vertices of a complete quadrilateral form a pencil in 
 involution. 
 
 ibd) 
 (be) 
 
 Thus in our figure T, which corresponds to the trans- 
 versal ty joined to the opposite pairs of vertices {ac), (bd) : 
 (ad), {be) ; (ab), (cd) gives an involution pencil. 
 
INVOLUTION. 147 
 
 121. Involution properties of conies. 
 
 Prop. Pairs of points conjugate for a conic, which 
 lie along a line, form a range in involution, of which the 
 double points are the points of intersection of the line with 
 the conic. 
 
 Let I? be a line cutting a conic in K and K'\ and let 
 A, Ai\ B, Bi &c. be pairs of points on p conjugate for 
 the conic. 
 
 Let M be the middle point of KK\ 
 
 Then (AA„KK') = -1. 
 
 .'.MA. MA, = MK' = MK\ 
 
 Similarly MB . MB, = MK^ 
 and so on. 
 
 .*. the pairs of points belong to an involution of which 
 K and K' are the double points. 
 
 If the line p does not cut the conic in real points the 
 double points of the involution are imaginary. 
 
 We now reciprocate the above theorem and derive the 
 following : 
 
 Pairs of lines conjugate for a conic which are drawn 
 through a point form a pencil in involution, of which the 
 double lines are the tangents to the conic from the point. 
 
 10—2 
 
148 INVOLUTION. 
 
 122. Desargues' theorem. 
 
 Conies through four given points are cut by any trans- 
 versal in pairs of points belonging to the same involution. 
 
 Let a transversal t cut a conic through the four points 
 A, B, CDinP and P,. 
 
 Let the same transversal cut the two pairs of opposite 
 sides AB, CD; AC, BD of the quadrangle in E, E, ; F, F,, 
 We now have 
 
 {PEFF,) = A(PEFP,) 
 = A{PBCP,) 
 ^D(PBCP,).hy^89 
 = {PF,E,P,) 
 
 = (PiE^F^P) by interchanging the 
 letters in pairs. 
 .*. P, Pi belong to the involution determined by 
 F, E,; P, Pi. 
 
 Thus all the conies through A BCD will cut the trans- 
 versal t in pairs of points belonging to the same involution. 
 
 Note that the proposition of § 120 is only a special 
 case of Desargues' theorem, if the two lines AD, BC be 
 regarded as one of the conies through the four points. 
 
INVOLUTION. 149 
 
 We now reciprocate the above theorem and obtain 
 the following : 
 
 Pairs of tangents from a point to the conies touching 
 four given straight lines belong to the same involution, 
 namely that determined by joining the point to the pairs of 
 opposite vertices of the quadrilateral formed by the four lines. 
 
 123. Orthogonal pencil in Involution^ 
 
 A special case of an involution pencil is that in which 
 each of the pairs of lines contains a right angle. 
 
 That such a pencil is in involution is clear from the< 
 second theorem of § 121, for pairs of lines at right angles 
 at a point are conjugate diameters for any circle having 
 its centre at that point. 
 
 But we can also see that pairs of orthogonal lines 
 VP, VPt^ ; VQ, VQi &c. are in involution, by taking any 
 
 transversal t to cut these in A, A-^-, B, B^ &c. and 
 drawing the perpendicular VO on to t', then 
 OA.OA,^-OV''=OB.OB,. 
 
 Thus the pairs of points belong to an involution with 
 imaginary double points. 
 
 Hence pairs of orthogonal lines at a point form a 
 pencil in involution with imaginary double lines. 
 
 Such an involution is called an orthogonal involution. 
 
150 
 
 INVOLUTION. 
 
 Note that this property may give us a test whether 
 three pairs of lines through a point form an involution. 
 If they can be projected so that the angles contained by 
 each pair become right angles, they must be in involution. 
 
 124. Prop. If two of the pairs of lines of an invohi^ 
 tion pencil are at right angles, they all are. 
 
 For as we have seen two pairs of lines completely 
 determine an involution pencil. 
 
 125. We will conclude this chapter by proving three 
 propositions illustrative of the principles of Involution 
 that have been set forth. 
 
 Prop. The circles described on the three diagonals of 
 a complete quadrilateral are coaxal. 
 
 Let AB^ BC, CD, DA be the four sides of the quadri- 
 lateral. 
 
INVOLUTION. 151 
 
 The diagonals are AC, BD, EF. 
 
 Let P be a point of intersection of the circles on ^ 
 and BD as diameters. 
 
 .•. APC and BPD are right angles. 
 
 But PA, PC; PB, PD; PE, PF are in involution 
 (§ 120). 
 
 .-. by § 124 Z EPF is a right angle. 
 
 .*. the circle on EF sls diameter goes through P. 
 
 Similarly the circle on EF goes through the other 
 point of intersection of the circles on BD and A C. 
 
 That is, the three circles are coaxal. 
 
 Cor. The middle points of the three diagonals of a 
 quadrilateral are coUinear. 
 
 This important and well-known property follows at 
 once, since these middle points are the centres of three 
 coaxal circles. 
 
 The line containing these middle points is sometimes 
 called the diameter of the quadrilateral. 
 
 126. Prop. The locus of the centres of conies through 
 four fixed points is a conic. 
 
 Let be the centre of one of the conies passing 
 through the four points A, B, G, D. 
 
152 INVOLUTION. 
 
 Let M^, M^, Ms, M4, be the middle points of AB, BC, 
 CD, DA respectively. 
 
 ' Draw Oil//, OM;, OM;, OM; parallel to AB, BG, CD, 
 DA respectively. 
 
 Then 0M„ OM,'; 0M„ OM,'; 0M„ OM^; 0M„ OM: 
 are pairs of conjugate diameters. 
 
 Therefore they form an involution pencil. 
 
 .-.0 {M^M,M,M,) = (M;M^M:m:). 
 But the right-hand side is constant since OM^, OM^ 
 &c. are in fixed directions. 
 
 .-. 0{M^M^MsM^) is constant. 
 .'. the locus of is a conic through M^, M^, M^, M^. 
 
 Cor 1. The conic on which lies passes through 
 ilfg, Mq the middle points of the other two sides of the 
 quadrangle. 
 
 For if Oi, O2, O3, O4, Og be five positions of 0, these 
 five points lie on a conic through M^, M^, M^, M4 and also 
 on a conic through M^, M^, M5, M^. 
 
 But only one conic can be drawn through five points. 
 
 Therefore M^, M^, ifg, M^, M^, M^ all lie on one conic, 
 which is the locus of 0. 
 
 Cor. 2. The locus of also passes through P, Q, B 
 the diagonal points of the quadrangle. 
 
 For one of the conies through the four points is the 
 pair of lines AB, CD ; and the centre of this conic is P. 
 
 So for Q and R. 
 
 127. Prop. // {AA\ BB\ GC] he an invohition 
 pencil and if a conic he drawn through to cut the rays 
 in A, A\ B, F, C, G', then the chords AA', BB\ GG' are 
 co^icurrent. 
 
INVOLUTION. 153 
 
 Let A A' and BB' intersect in P. 
 
 Project the conic into a circle with the projection of P 
 for its centre. 
 
 Using small letters in the projection, we have that 
 aoa\ hob' are right angles, being in a semicircle. 
 
 Hence they determine an orthogonal involution. 
 
 .'. coc' is a right angle ; that is, cc goes through p. 
 
 .'. GO' goes through P. 
 
 It will be understood that the points AA', BB\ 
 CC when joined to any other point on the conic give 
 an involution pencil ; for this follows at once by the 
 application of § 89. 
 
 A system of points such as these on a conic is called 
 an involution range on the conic. 
 
 The point P where the corresponding chords intersect 
 is called the pole of the involution. 
 
154 INVOLUTION. 
 
 EXERCISES. 
 
 1. Any transversal is cut by a system of coaxal circles in, 
 pairs of points which are in involution, and the double points 
 of the involution are concyclic with the limiting points of the 
 system of circles. 
 
 2. If K, K' be the double points of an involution to 
 which A, A^ ; B, B^ belong ; then A, B^; A^, B ; K, K' are in 
 involution. 
 
 3. If the double lines of a pencil in involution be at right 
 angles, they must be the bisectors of the angles between each 
 pair of conjugate rays. 
 
 4. Reciprocate the theorem of § 127. 
 
 5. Given two pairs of points belonging to an involution 
 range on a conic, shew how to find the mate of another point 
 on the conic. 
 
 6. Given four points and a straight line, find a construc- 
 tion for the points of contact with the line of the conies 
 touching the line and passing through the four points. 
 
 7. The corresponding sides BC, B'C &c. of two triangles 
 ABG^ A' B'C in plane perspective intersect in P^ Q, R respec- 
 tively ; and AA\ BB', CC respectively intersect the line PQR 
 in P', Q\ W. Prove that the range {PF, QQ', BR') forms an 
 involution. 
 
 8. Prove that the director circles of all conies touching 
 the four sides of a quadrilateral belong to the coaxal system 
 determined by the circles on the three diagonals of the quadri- 
 lateral. 
 
 [Let P be one of the points of intersection of the circles 
 on the diagonals ; shew that the tangents from P to each of 
 the conies are at right angles. Use §§ 122, 124.] 
 
INVOLUTION. 155 
 
 9. The centre of the circumcircle of the triangle formed 
 by the three diagonals of a quadrilateral lies on the radical 
 axis of the system of circles on the three diagonals. 
 
 10. If a triangle be self-conjugate to a system of conies, 
 its circumcircle cuts the director circles of the conies ortlio- 
 gonally. 
 
 11. Prove that an asymptote of a hyperbola is cut by the 
 three pairs of opposite sides of a complete quadrangle inscribed 
 in it into three pairs of segments with a common middle point. 
 
 12. The sides BC, CA, AB of a triangle ABC, self- 
 conjugate with respect to a given conic, intersect any given 
 line p in A', B', C. Also is the pole of p. Prove that 
 OA, 0A'\ OB, OB' \ OC, 00' form a pencil in involution. 
 
 13. From points on a given straight line pairs of tangents 
 are drawn to a conic ; prove that these tangents meet any 
 fixed tangent to the conic in points which are in involution. 
 
 State the reciprocal of this theorem. 
 
 14. A, B, C, D are any four points on a given conic, and 
 the two conies which pass through A, B, C, D and touch a 
 directrix of the given conic are drawn. Shew that the portion, 
 of the directrix intercepted between the points of contact 
 subtends a right angle at the corresponding focus. 
 
 15. Shew that if each of two pairs of opposite vertices of 
 a quadrilateral is conjugate with regard to a circle, the third 
 pair is also ; and that the circle is one of a coaxal system of 
 which the line of collinearity of the middle points of the 
 diagonals is the radical axis. 
 
 16. Chords of a conic which subtend a right angle at a 
 fixed point on the curve will all intersect on the normal at the 
 point. 
 
 [Use §127.] 
 
 17. If ABO be a triangle which is self-conjugate for a 
 system of conies, the pairs of tangents drawn to the conies 
 
156 INVOLUTION. 
 
 of the system from each of the vertices of the triangle will 
 form a pencil in involution at that vertex. 
 
 18. The two pairs of tangents drawn from a point to two 
 circles, and the two lines joining the point to their centres of 
 similitude, form an involution. 
 
 19. Prove that there are two points in the plane of a 
 given triangle such that the distances of each from the 
 vertices of the triangle are in a given ratio. Prove also that 
 the line joining these points passes through the circumcentre 
 of the triangle 
 
 20. P is a point on a rectangular hyperbola whose centre 
 is C prove that the lines joining P to pairs of conjugate 
 points on the diameter perpendicular to CP form an orthogonal 
 involution. 
 
 21. A rectangular hyperbola whose centre is C is reci- 
 procated with respect to a circle which passes through C and 
 has its centre at a point P on the hyperbola, prove that the 
 reciprocal curve is a parabola whose focus is at C ; and 
 determine the directrix of the parabola. 
 
 [Prove that the conjugate lines through C for the reciprocal 
 curve are orthogonal.] 
 
 22. Prove that the locus of the poles of a given line with 
 respect to a system of conies through four given points is a 
 conic. 
 
 [Project the given line to infinity and use § 126.] 
 
CHAPTER XI. 
 
 CIRCULAR POINTS. FOCI OF CONICS. 
 
 128. We have seen (§ 121) that pairs of concurrent 
 lines which are conjugate for a conic form an involution, 
 of which the tangents from the point of concurrency are 
 the double lines. 
 
 Thus conjugate diameters of a conic are in involution, 
 and the double lines of the involution are its asymptotes. 
 
 Now the conjugate diameters of a circle are orthogonal. 
 
 Thus the asymptotes of a circle are the imaginary 
 double lines of the orthogonal involution at its centre. 
 
 But clearly the double lines of the orthogonal involu- 
 tion at one point must be parallel to the double lines of 
 the orthogonal involution at another, seeing that we may 
 by a motion of translation^ without rotation, move one into 
 the position of the other. 
 
 Hence the asymptotes of one circle are, each to each, 
 parallel to the asymptotes of any other circle in its plane. 
 
 Let a, h be the asymptotes of one circle C, a\ h' of 
 another G\ then a, a' being parallel meet on the line at 
 infinity, and 6, h' being parallel meet on the line at infinity. 
 
 But a and a' meet C and C on the line at infinity, 
 
 and h and h' „ C and C „ „ „ 
 Therefore G and C go through the same two imaginary 
 points on the line at infinity. 
 
158 CIRCULAR POINTS. FOCI OF CONICS. 
 
 Our conclusion then is that all circles in a plane go 
 through the same two imaginary points on the line at 
 infinity. These two points are called the circular points 
 at infinity or, simply, the circular points. 
 
 The circular lines at any point are the lines joining 
 that point to the circular points at infinity ; and they are 
 the imaginary double lines of the orthogonal involution 
 at that point. 
 
 129. Analytical point of view. 
 
 It may help the student to think of the circular lines 
 at any point if we digress for a moment to touch upon 
 the Analytical aspect of them. 
 
 The equation of a circle referred to its centre is of the 
 form 
 
 oo^ + y^ = a^. 
 
 The asymptotes of this circle are 
 ^.2 + 2/' = 0, 
 that is the pair of imaginary lines 
 
 y = ix and y — — ioc. 
 
 These two lines are the circular lines at the centre of 
 the circle. 
 
 The points where they meet the line at infinity are 
 the circular points. 
 
 If we rotate the axes of coordinates at the centre of 
 a circle through any angle, keeping them still rectangular, 
 the equation of the circle does not alter in form, so that 
 the asymptotes will make angles tan~^(^) and tan~^(— i) 
 with the new axis of x as well as with the old. 
 
 This at first sight is paradoxical. But the paradox is 
 explained by the fact that the line y = ix makes the same 
 angle tan~^ {i) with every line in the plane. 
 
CIRCULAR POINTS. FOCI OF CONICS. 159 
 
 For let y = mx be any other line through the origin. 
 Then the angle that y = ix makes with this, measured 
 in the positive sense from y = mx, is 
 
 tan-i ^ = tan-i ] -\-. — ; — -^ \ = tan-^ i. 
 
 VI + imj ( 1+im ) 
 
 130. Prop. If A OB be an angle of constant magnitude 
 and fl, fl' he the circular points, the cross-ratios of the 
 pencil (12, H', A, B) are constant. 
 
 T^ ^ /r^r^/ ^ r>x sin 11011' sin AOB 
 
 ^ ^ sm nOB sm A OH 
 
 but the angles HOO', D.OB, AOD.' are all constant since 
 
 the circular lines make the same angle with every line in 
 
 the plane, and ZAOB is. constant by hypothesis. 
 
 .'. 0(ilD,'AB) is constant. 
 
 131. Prop. All conies passing through the circular 
 points are circles. 
 
 Let G be the centre of a conic S passing through the 
 circular points, which we will denote by fl and 12'. 
 
 Then 012, 0X2' are the asymptotes of S. 
 
 But the asymptotes are the double lines of the 
 involution formed by pairs of conjugate diameters. 
 
 And the double lines completely determine an involu- 
 tion, that is to say there can be only one involution with 
 the same double lines. 
 
 Thus the conjugate diameters of S are all orthogonal. 
 
 Hence >Si is a circle. 
 
 The circular points may he utilised for establishing 
 properties of conies passing through two or more fixed 
 points. 
 
 For a system of conies all passing through the same 
 two points can all be projected into circles simultaneously. 
 
160 CIRCULAR POINTS. FOCI OF CONICS. 
 
 This is effected by projecting the two points into the 
 circular points on the plane of projection. The projec- 
 tions of the conies will now go through the circular points 
 in the new plane and so they are all circles. 
 
 The student of course understands that such a projec- 
 tion is an imaginary one. 
 
 132. We will now proceed to an illustration of the 
 use of the circular points. 
 
 It can be seen at once that any transversal is cut by 
 a system of coaxal circles in pairs of points in involution 
 (the centre of this involution being the point of intersec- 
 tion of the line with the axis of the system). 
 
 From this follows at once Desargues' theorem (§ 122), 
 namely that conies through four points cut any transversal 
 in pairs of points in involution. 
 
 For if we project two of the points into the circular 
 points the conies all become circles. Moreover the circles 
 form a coaxal system, for they have two other points in 
 common. 
 
 Hence Desargues' theorem is seen to follow from the 
 involution property of coaxal circles. 
 
 The involution property of coaxal circles again is a 
 particular case of Desargues' theorem, for coaxal circles 
 have four points in common, two being the circular 
 points, and two the points in which all the circles are cut 
 by the axis of the system. 
 
 133. We will now make use of the circular points to 
 prove the theorem : If a triangle he self -conjugate to a 
 rectangular hyperbola its circumcircle passes through the 
 centre of the hyperbola. 
 
 Let be the centre of the rectangular hyperbola, 
 ABC the self-conjugate triangle, H, 11' the circular points. 
 
CIRCULAR POINTS. FOCI OF CONICS. 161 
 
 Now observe first that Oflfi' is a self-conjugate 
 triangle for the rectangular hyperbola. For OH, OH' are 
 the double lines of the orthogonal involution at to 
 which the asymptotes, being- at right angles, belong. 
 Therefore 0X1, Oil' belong to the involution whose 
 double lines are the asymptotes (§ 118), that is the 
 involution formed by pairs of conjugate lines through 0. 
 
 .'. OD., OH' are conjugate lines, and is the pole of 
 no', which is the line at infinity. 
 
 .*. OXlfl' is a self-conjugate triangle. 
 
 Also ABC is a self-conjugate triangle. 
 
 .*. the six points A, B, G, 0, fl, fi' all lie on a conic 
 (§ 111); and this conic must be a circle as it passes 
 through O and H'. 
 
 .'. A, B, G, are coney clic. 
 
 Cor. If a rectangular hyperbola circumscribe a 
 triangle, its centre lies on the nine-points circle. 
 
 This well-known theorem is a particular case of the 
 above proposition, for the pedal triangle is self-conjugate 
 for the rectangular hyperbola. (Ex. 20, Chapter VII.) 
 
 134. Prop. Goncentric circles have doable contact at 
 infinity. 
 
 For if be the centre of the circles, H, H' the circular 
 points at infinity, all the circles touch OH and OVl' at the 
 points n and O'. 
 
 That is, all the circles touch one another at the points 
 ft and ft'. 
 
 135. Foci of Conies. 
 
 Defining a conic by its focus and directrix property 
 {viz. that the distance of a point on the conic from the 
 
 A. G. 11 
 
162 CIRCULAR POINTS. FOCI OF CONICS. 
 
 focus varies as its distance from the directrix), we obtain 
 the various properties of conies. 
 
 Among these properties we have this one, that every 
 pair of conjugate lines through a focus is at right angles. 
 In other words, conjugate lines through a focus form an 
 orthogonal involution. 
 
 Let us now extend our notion of a focus. Let us 
 define a focus of a conic as a point in the plane of the 
 conic at which all the pairs of conjugate lines are ortho- 
 gonal. In this way we include those points which we 
 have hitherto known as foci, but we have opened the door 
 for others. 
 
 As we have extended the term 'focus,' so must we 
 extend the correlative term 'directrix.' Each focus, 
 according to the extended meaning of the term, has 
 associated with it its polar with respect to the conic, 
 and this polar we call the corresponding directrix. 
 
 The question now is : What other foci and directrices 
 are there in addition to those we know, and what are 
 their properties ? 
 
 136. Prop. Every conic has four foci, two of which 
 lie on one axis of the conic and are real, and two on the 
 other axis and are imaginary. 
 
 Since conjugate lines at a focus form an orthogonal 
 involution, and since the tangents from any point are the 
 double lines of the involution formed by the conjugate 
 lines there, it follows that the circular lines through a 
 focus are the tangents to the conic from that point. 
 
 But the circular lines at any point go through O and 
 n', the circular points. 
 
 Thus the foci of the conic will be obtained by drawing 
 tangents from Vt and 12' to the conic, and taking their 
 four points of intersection. 
 
CIRCULAR POINTS. FOCI OF CONICS. 163 
 
 Hence there are four foci. 
 
 We will here follow Mr Russell's method in his 
 Elementary Treatise on Pure Geometry ^ p. 255. 
 
 To help the imagination, construct a figure as if II 
 and H' were real points. 
 
 Draw tangents from these points to the conic and let 
 S, S\ F, F' be their points of intersection as in the figure ; 
 S, S' being opposite vertices as also F and F'. 
 
 Let FF' and SS' intersect in 0. 
 
 Now the triaugle formed by the diagonals FF\ SS' 
 and no' is self-conjugate for the conic, because it touches 
 the sides of the quadrilateral. 
 
 .'. is the pole of fl£l\ i.e. of the line at infinity. 
 
 .*. is the centre of the conic. 
 
 Further OUft' is the diagonal, or harmonic, triangle of 
 the qimdrangle SS'FF\ 
 
 .-. 0(nn\FS) = -l. 
 
 11—2 
 
164 CIRCULAR POINTS. FOCI OF CONICS. 
 
 .*. O^and OS are conjugate lines in the involution of 
 which on and OH' are the double lines. 
 
 .'. OF and 08 are at right angles. 
 
 And OF and OS are conjugate lines for the conic since 
 the triangle formed by the diagonals FF', 8S\ HIl' is 
 self-conjugate for the conic ; and is, as we have seen, 
 the centre. 
 
 .'. Oi^ and OS, being orthogonal conjugate diameters, 
 are the axes. 
 
 Thus we have two pairs of foci, one on one axis and 
 the other on the other axis. 
 
 Now we know that two of the foci, say >Si and S', are 
 real. 
 
 It follows that the other two, F and F', are imaginary. 
 For if F were real, the line FS would meet the line at 
 infinity in a real point, which is not the case. 
 
 .'. i^and F' must be imaginary. 
 
 Cor. The lines joining non-corresponding foci are 
 tangents to the conic and the points of contact of these 
 tangents are concyclic. 
 
 137. Prop. The distance of any point on a conic 
 from a focus varies as its distance from the corresponding 
 directrix. 
 
 We know, of course, that this property is true of the 
 two real foci, but we have yet to shew that it is true for 
 all the foci. 
 
 Let F he a focus and KM the corresponding directrix. 
 
 Let the chord PP' of the conic cut this directrix in K. 
 
 Let the tangents at P and P' meet in T. Let FT cut 
 PP' in L. 
 
 Now the polar of T goes through K,.'. the polar of K 
 goes through T 
 
CIRCULAR POINTS. FOCI OF CONICS. 
 
 165 
 
 Also the polar of K, a point on the directrix, goes 
 through F, the pole of the directrix. 
 
 .-. Ti^ is the polar of iiT. 
 .-. {KL,PF) = -1. 
 
 Also FT and FK being conjugate lines through a 
 focus are at right angles. 
 
 .*. -PTand FK are the internal and external bisectors 
 of the ^PFF. 
 
 .-. FP:FP' = PK:P'K 
 = PM'.P'M\ 
 where PM, P'M' are perpendicular to the directrix. 
 
 Hence FP : PM is constant for all positions of P on 
 the conic. 
 
 138. Prop. A system of conies touching the sides of 
 a quadrilateral can he projected into confocal conies. 
 
 Let A BCD be the quadrilateral, the pairs of opposite 
 vertices being A, G ; B, D , E, F. 
 
166 CIRCULAR POINTS. FOCI OF CONICS. 
 
 Project E and F into the circular points at infinity on 
 the plane of projection. 
 
 .*. A, C and B, D project into the foci of the conies in 
 the projection, by § 136. 
 
 CoR. Confocal conies form a system of conies touching 
 four lines. 
 
 139. We will now make use of the notions of this 
 chapter to prove the following theorem, which is not 
 unimportant. 
 
 If the sides of two triangles all touch the same conic, 
 the six vertices of the triangles all lie on a conic. 
 
 Let ABC, A'B'C be the two triangles the sides of 
 which all touch the same conic 8. 
 
 Denote the circular points on the tt plane or plane of 
 projection by «, w. 
 
 Project B and G into o) and o)'; .', S projects into a 
 parabola, since the projection of S touches the line at 
 infinity. 
 
CIRCULAR POINTS. FOCI OF CONICS. 167 
 
 Further A will project into the focus of the parabola, 
 since the tangents from the focus go through the circular 
 points. 
 
 Using corresponding small letters in the projection, 
 we get, since the circumcircle of a triangle whose sides 
 touch a parabola goes through the focus, that a, a, h', c 
 are concyclic. 
 
 .*. a, a', h', c\ (o, w lie on a circle. 
 .*. A, B, C, A\ B', C lie on a conic. 
 
 The converse of the above proposition follows at once 
 by reciprocation. 
 
 140. We have in the preceding article obtained a 
 proof of the general proposition that if the sides of two 
 triangles touch a conic, their six vertices lie on another 
 conic by the projection of what is a particular case of this 
 proposition, viz. that the circumcircle of a triangle whose 
 sides touch a parabola passes through the focus. 
 
 This process is known as generalising hy projection. 
 We will proceed to give further illustrations of it. 
 
 Let us denote the circular points in the p plane by 12, 
 II', and their projections on the tt plane by o), (o'. Then 
 of course co and w are not the circular points in the tt 
 plane. But by a proper choice of the tt plane and the 
 vertex of projection w and w may be any two points we 
 choose, real or imaginary. For if we wish to project ft 
 and ft' into the points (o and w' in space, we have only to 
 take as our vertex of projection the point of intersection 
 of the lines wft and w'ft', and as the plane tt some plane 
 passing through &> and o)'. 
 
 The following are the principal properties connecting 
 
168 CIRCULAR POINTS. FOCI OF CONICS. 
 
 figures in the p and it planes when H and Vl' are projected 
 into ft) and &>' : 
 
 1. Circles in the p plane project into conies through 
 the points w and w' in the tt plane. 
 
 2. Parabolas in the p plane project into conies 
 touching the line ww in the ir plane. 
 
 3. Rectangular hyperbolas in the p plane, for which, 
 as we have seen, H and 12' are conjugate points, project 
 into conies having w and a for conjugate points. 
 
 4. The centre of a conic in the p plane, since it is 
 the pole of 12 O', projects into the pole of the line coay'. 
 
 5. Concentric circles in the p plane project into conies 
 having double contact at &> and ay' in the ir plane. 
 
 6. A pair of lines OA, OB at right angles in the 
 p plane project into a pair of lines oa, oh harmonically 
 conjugate with ow, ow. This follows from the fact that 
 012, 012' are the double lines of the involution to which 
 OA, OB belong, and therefore 0(^5, 1212') = - 1 (§ 118); 
 from which it follows that o {ah, cow) = — 1. 
 
 7. A conic with >S^ as focus in the p plane will project 
 into a conic touching' the lines sco, sw in the tt plane. 
 
 And the two foci S and S' of a conic in the p plane 
 will project into the vertices of the quadrilateral formed 
 by drawing tangents from o) and w' to the projection of 
 the conic in the tt plane. 
 
 It is of importance that the student should realise 
 that ft) and w are not the circular points in the tt plane 
 when they are the projections of 12 and 12'. 
 
 In § 139 we have denoted the circular points in the tt 
 plane by w and w, but they are not there the projections 
 of the circular points in the p plane. 
 
CIRCULAR POINTS. FOCI OF CONICS. 
 
 169 
 
 Our practice has been to use small letters to represent 
 the projections of the corresponding capitals. So then we 
 use CO and co' for the projection of O and fl' respectively. 
 If n and il' are the circular points in the _p plane, co and 
 m are not the circular points in the tt plane ; and if co 
 and w are the circular points in the tt plane, D, and fl' are 
 not the circular points in the p plane. That is to say, only 
 one of the pairs can be circular points at the same time. 
 
 141. We will now proceed to some examples of 
 generalisation by projection. 
 
 Consider the theorem that the radius of a circle to any 
 point A is perpendicular to the tangent at A. 
 
 Project the circle into a conic through co and co' ; the 
 centre G of the circle projects into the pole of coco'. 
 
 The generalised theorem is that if the tangents at two 
 points CO, co' of a conic meet in c, and a he any point on the 
 conic and at the tangent there 
 
 a {tc, coco') = — 1. 
 
 142. Next consider the theorem that angles in the 
 same segment of a circle are equal. Let AQB be an 
 angle in the segment of which AB is the base. Project 
 the circle into a conic through co and co' and we get the 
 
170 
 
 CIRCULAR POINTS. FOCI OF CONICS. 
 
 theorem that if q be any point on a fixed conic through 
 the four points a, h, o, w, q {ahaxo') is constant (§ 130). 
 
 Thus the property of the equality of angles in. the same 
 segment of a circle generalises into the constant cross-ratio 
 property of conies. 
 
 143. Again we have the property of the rectangular 
 hyperbola that if PQR be a triangle inscribed in it and 
 
 having a right angle at P the tangent at P is at right 
 angles to QR, 
 
CIRCULAR POINTS. FOCI OF CONICS. 
 
 171 
 
 Project the rectangular hyperbola into a conic having 
 0) and 0)' for conjugate points and we get the following 
 property. 
 
 If p be any point on a conic for which w and w! are 
 conjugate points and q, r two other points on the conic such 
 that p (qr, cow) = — 1 and if the tangent at p meet qr in k 
 then k (pq, coco') = — 1. 
 
 144. Lastly we will generalise by projection the 
 theorem that chords of a circle which touch a concentric 
 circle subtend a constant angle at the centre. 
 
 Let PQ be a chord of the outer circle touching the 
 inner and subtending a constant angle at G the centre. 
 
 The concentric circles have double contact at the 
 circular points fl and XI' and so project into two conies 
 having double contact at co and &)'. 
 
 The centre C is the pole of 120" and so c, the projection 
 of C, is the pole of (oco\ 
 
 The property we obtain by projection is then : 
 If two conies have double contact at two points co and 
 (o' and if the tangents at these points meet in c, and if pq 
 he any chord of the outer conic touching the inner conic, 
 then c(pq(oco') is constant. 
 
172 CIRCULAR POINTS. FOCI OF CONICS. 
 
 EXERCISES. 
 
 1. If be the centre of a conic, O, 12' the circular points 
 at infinity, and if OQil' be a self -conjugate triangle for the 
 conic, the conic must be a rectangular hyperbola. 
 
 2. If a variable conic pass through two given points F 
 and P', and touch two given straight lines, shew that the 
 chord which joins the points of contact of these two straight 
 lines will always meet FF in a fixed point. 
 
 3. If three conies have two points in common, the 
 opposite common chords of the conies taken in pairs are 
 concurrent. 
 
 4. Two conies Sj^ and S.2 circumscribe the quadrangle 
 ABCI). Through A and B lines AEF, BGH are drawn 
 cutting S^ in E and G, and S^ in F and H. Prove that 
 CD, EG, FH are concurrent. 
 
 5. If a conic pass through two given points, and touch a 
 given conic at a given point, its chord of intersection with the 
 given conic passes through a fixed point. 
 
 6. If i\ Q,' be the circular points at infinity, the two 
 imaginary foci of a parabola coincide with Q and O', and the 
 centre and second real focus of the parabola coincide with the 
 point of contact of OO' with the parabola. 
 
 7. If a conic be drawn through the four points of inter- 
 section of two given conies, and through the intersection of 
 one pair of common tangents, it also passes through the 
 intersection of the other pair of common tangents. 
 
 8. Prove that, if three conies pass through the same four 
 points, a common tangent to any two of the conies is cut 
 harmonically by the third. 
 
 9. Reciprocate the theorem of Ex. 8. 
 
CIRCULAR POINTS. FOCI OF CONICS. 173 
 
 10. If from two points P, P' tangents be drawn to a 
 conic, the four points of contact of the tangents with the conic, 
 and the points P and P' all lie on a conic. 
 
 [Project P and F into the circular points.] 
 
 11. If out of four pairs of points every combination of 
 three pairs gives six points on a conic, either the four conies 
 thus determined coincide or the four lines determined by the 
 four pairs of points are concurrent. 
 
 12. Generalise by projection the theorem that the locus 
 of the centre of a rectangular hyperbola circumscribing a 
 triangle is the nine-points circle of the triangle. 
 
 13. Generalise by projection the theorem that the locus 
 of the centre of a rectangular hyperbola with respect to which 
 a given triangle is self-conjugate is the circumcircle. 
 
 14. Given that two lines at right angles and the lines to 
 the circular points form a harmonic pencil, find the reciprocals 
 of the circular points with regard to any circle. 
 
 Deduce that the polar reciprocal of any circle with regard 
 to any point has the lines from to the circular points as 
 tangents, and the reciprocal of the centre of the circle for the 
 corresponding cliord of contact. 
 
 15. Prove and generalise by projection the following 
 theorem : The centre of the circle circumscribing a triangle 
 which is self-conjugate with regard to a parabola lies on the 
 directrix. 
 
 16. P and P' are two points in the plane of a triangle 
 ABC. D is taken in BG such that BC and DA are harmonic- 
 ally conjugate with DP and DP' ; E and F are similarly taken 
 in CA and AB respectively. Prove that AD^ BE, CF are 
 concurrent. 
 
 17. Generalise by projection the following theorem : The 
 lines perpendicular to the sides of a triangle through the 
 middle points of the sides are concurrent in the circumcentre 
 of the triangle. 
 
174 CIRCULAR POINTS. FOCI OF CONICS. 
 
 18. Generalise: The feet of the perpendiculars on to the 
 sides of a tiiangle from any point on the circumcircle are 
 collinear. 
 
 19. If two conies have double contact at A and B, and if 
 FQ a chord of one of them touch the other in B and meet AB 
 in T, then 
 
 {PQ,BT)^-1. 
 
 20. Generalise by projection the theorem that confocal 
 conies cut at right angles. 
 
 21. Prove and generalise tliat the envelope of the polar 
 of a given point for a system of confocals is a parabola 
 touching the axes of the confocals and having the given 
 point on its directrix. 
 
 22. If a system of conies pass through the four points 
 A, B, C, D, the poles of the line AB with respect to them will 
 lie on a line I. Moreover if this line I meet CD in P, FA and 
 FB are harmonic conjugates of CD and I. 
 
 23. A pair of tangents from a fixed point 7^ to a conic 
 meet a third fixed tangent to the conic in L and L'. F is any 
 point on the conic, and on the tangent at P a point X is taken 
 such that X{F1\ LL') — — 1 ; prove that the locus of X is a 
 straight line. 
 
 24. Defining a focus of a conic as a point at which each 
 pair of conjugate lines is orthogonal, prove that the polar 
 reciprocal of a circle with respect to another circle is a conic 
 having the centre of the second circle for a focus. 
 
CHAPTEK XII. 
 
 INVERSION. 
 
 145. We have already in § 13 explained what is 
 meant by two 'inverse points' with respect to a circle. 
 being the centre of a circle, P and F' are inverse points 
 if they lie on the same radius and OP . OP' = the square 
 of the radius. P and P' are on the same side of the 
 centre, unless the circle have an imaginary radius, = ik, 
 where k is real. 
 
 As P describes a curve S, the point P' will describe 
 another curve S\ S and >S' are called inverse curves. is 
 called the centre of inversion, and the radius of the circle 
 is called the radius of inversion. 
 
 If P describe a curve in space, not necessarily a plane 
 curve, then we must consider P' as the inverse of P with 
 respect to a sphere round 0. That is, whether P be 
 confined to a plane or not, if be a fixed point in space 
 and P' be taken on OP such that OP . OP' = a constant A;', 
 P' is called the inverse of P, and the curve or surface 
 described by P is called the inverse of that described by 
 P\ and vice versa. 
 
 It is convenient sometimes to speak of a point P' as 
 inverse to another point P with respect to a point 0. By 
 this is meant that is the centre of the circle.'^r sphere 
 with respect to which the points are inverse. 
 
176 
 
 INVERSION. 
 
 146. Prop. The inverse of a circle with respect to a 
 point in its plane is a circle or straight line. 
 
 First let 0, the centre of inversion, lie on the circle. 
 Let k be the radius of inversion. 
 
 Draw the diameter OA, let A' be the inverse of A. 
 
 Let P be any point on the circle, P' its inverse. 
 
 Then OP . OP' = k' = OA, 0A\ 
 
 .'.PAA'F is cyclic. 
 
 .'. the angle AA'P' is the supplement of ^PP', which 
 is a right angle. 
 
 .'. A'P' is at right angles to AA\ 
 
 .'. the locus of P' is a straight line perpendicular to 
 the diameter OA, and passing through the inverse of ^. 
 
 Next let not be on the circumference of the circle. 
 Let P be any point on the circle, P' its inverse. 
 Let OP cut the circle again in Q. 
 Let A be the centre of the circle. 
 
INVERSION. 177 
 
 Then OP . OP' = k\ 
 and OP . OQ = sq. of tangent from to the circle = t^ (say). 
 
 OP' ^ k^ 
 
 OB k^ 
 Take -B on OA such that ^ 7-= — • •*• B is a fixed 
 
 UA t^ 
 
 point and i?P' is parallel to ^Q. 
 
 , , BP' OB k^ 
 
 ^^^ AQ=-OA = ¥^''''''^^'''' 
 
 .'. P' describes a circle round B. 
 
 Thus the inverse of the circle is another circle. 
 
 Cor. 1. The inverse of a straight line is a circle 
 passing through the centre of inversion. 
 
 Cor. 2. If two circles be inverse each to the other, 
 the centre of inversion is a centre of similitude (§ 25) ; 
 and the radii of the circles are to one anothei* in the ratio 
 of the distances of their centres from 0. 
 
 The student should observe that, if we call the two 
 circles S and S\ and if OPQ meet S' again in Q\ Q' will 
 be the inverse of Q. 
 
 Note. The part of the circle S which is convex to 
 corresponds to the part of the circle S' which is concave 
 to 0, and vice versa. 
 
 Two of the common tangents of S and S' go through 
 
 A. G. 12 
 
178 INVERSION. 
 
 0, and the points of contact with the circles of each of 
 these tangents will be inverse points. 
 
 147. Prop. The inverse of a sphere with respect to 
 any point is a sphere or a plane. 
 
 This proposition follows at once from the last by 
 rotating the figures round OA as axis ; in the first figure 
 the circle and line will generate a sphere and plane each 
 of which is the inverse of the other ; and in the second 
 figure the two circles will generate spheres each of which 
 will be the inverse of the other. 
 
 148. Prop. The inverse of a circle with respect to a 
 poirit 0, not in its plane^ is a circle. 
 
 For the circle may be regarded as the intersection 
 of two spheres, neither of which need pass through 0. 
 
 These spheres will invert into spheres, and their inter- 
 section, which is the inverse of the intersection of the other 
 two spheres, that is of the original circle, will be a circle. 
 
 149. Prop. A circle will invert into itself with 
 respect to a point in its plane if the radius of inversion 
 
 he the length of the tangent to the circle from the centre of 
 inversion. 
 
INVERSION. 179 
 
 This is obvious at once, for if OThe the tangent from 
 and OPQ cut the circle in P and Q, since OP.OQ= OT^ 
 it follows that P and Q are inverse points. 
 
 That is, the part of the circle concave to inverts into 
 the part which is convex and vice versa. 
 
 Cor. 1. Any system of coaxal circles can be simul- 
 taneously inverted into themselves if the centre of 
 inversion be any point on the axis of the system. 
 
 Cor. 2. Any three coplanar circles can be simul- 
 taneously inverted into themselves. 
 
 For we have only to take the radical centre of the 
 three circles as the centre of inversion, and the tangent 
 from it as the radius. 
 
 150. Prop. Two coplanar curves cat at the same 
 angle as their inverses with respect to any point in their 
 plane. 
 
 Let P and Q be two near points on a curve >S, P' and 
 Q their inverses with respect to 0. 
 
 Then since OP . OP' = k'=OQ. OQ'. 
 .'. QPP'Q' is cyclic. 
 .-. /.OPQ = zOQT\ 
 Now let Q move up to P so that PQ becomes the 
 tangent to /Sf at P ; then Q' moves up at the same time to 
 
 12—2 
 
180 
 
 INVERSION. 
 
 P' and P'Q' becomes the tangent at P' to the inverse 
 curve B\ 
 
 .'. the tangents at P and P' make equal angles with 
 OPP\ 
 
 The tangents however are antiparallel, not parallel. 
 
 Now if we have two curves S^ and 8.2 intersecting at 
 
 P, and PTi, PT^ be their tangents there, and if the 
 inverse curves be S^, S^' intersecting at P\ the inverse of 
 P, and P'Ti, P'T^ be their tangents, it follows at once 
 from the above reasoning that Z T^PT^ = Z T^P'T^. 
 
 Thus 8i and 82 intersect at the same angle as their 
 inverses. 
 
 Cob. If two curves touch at a point P their inverses 
 touch at the inverse of P. 
 
 151. Prop. If a circle 8 he inverted into a circle 8\ 
 and P, Q he inverse points with respect to 8, then P' and 
 Q', the inverses of P and Q respectively, will he inverse 
 points with respect to 8\ 
 
INVERSION. 
 Let be the centre of inversion. 
 
 181 
 
 Since P and Q are inverse points for S, therefore S 
 cuts orthogonally every circle through P and Q, and in 
 particular the circle through 0, P, Q. 
 
 Therefore the inverse of the circle OPQ will cut S' 
 orthogonally. 
 
 But the inverse of the circle OPQ is a line ; since 0, 
 the centre of inversion, lies on the circumference. 
 
 Therefore P'Q' is the inverse of the circle OPQ. 
 
 Therefore P'Q' cuts S' orthogonally, that is, passes 
 through the centre of S'. 
 
 Again, since every circle through P and Q cuts S 
 orthogonally, it follows that every circle through P' and 
 Q' cuts S' orthogonally (§ 150). 
 
 Therefore, if A^ be the centre of S\ 
 
 AiP' . AiQ' = square of radius of S\ 
 
 Hence P' and Q' are inverse points for the circle S'. 
 
 152. Prop. A system of non-intersecting coaxal 
 circles can he inverted iyito concentric circles. 
 
 The system being no n -intersecting, the limiting points 
 L and L' are real. 
 
182 INVERSION. 
 
 Invert the system with respect to L. 
 
 Now L and L' being inverse points with respect to 
 each circle of the system, their inverses will be inverse 
 points for each circle in the inversion. 
 
 But L being the centre of the circle of inversion, its 
 inverse is at infinity. Therefore L' must invert into the 
 centre of each of the circles. 
 
 153. Feuerbach's Theorem. 
 
 The principles of inversion may be illustrated by their 
 application to prove Feuerbach's famous theorem, viz. that 
 the nine-points circle of a triangle touches the inscribed 
 and the three escribed circles. 
 
 Let ABC be a triangle, / its incentre and I^ its 
 ecentre opposite to A. 
 
 Let M and M^ be the points of contact of the incircle 
 and this ecircle with BG. 
 
 Let the line AII^ which bisects the angle A cut BG 
 in R. 
 
 Draw AL perpendicular to BG. Let 0, P, U be 
 the circumcentre, orthocentre and nine-points centre 
 respectively. 
 
 Draw OD perpendicular to BG and let it meet the 
 circumcircle in K. 
 
 Now since BI and BI^ are the internal and external 
 bisectors of angle B, 
 
 .•.(.4ii,//0 = -l, 
 .'.L{AR,II,)^-l. 
 
 .'. since RLA is a right angle, LI and LIi are equally 
 inclined to BG (§ 27, Cor. 2). 
 
 .-. the polars of L with regard to the incircle and 
 the ecircle will be equally inclined to BG. 
 
INVERSION. 183 
 
 Now the polar of L for the in circle goes through M 
 and that for the ecircle through M^. 
 
 Let MX be the polar of L for the incircle cutting OD 
 in X. 
 
 Then since D is the middle point of MM^ (§ 12, Cor.) 
 
 .'. M^X is the polar of Jj for the ecircle, i.e. L and X 
 are conjugate points for both circles. 
 
184 INVERSION. 
 
 Let N be the middle point of XL, then the square of 
 the tangent from N to both circles = NX^ = ND\ 
 
 .'. X is on the radical axis of the two circles ; but so 
 also is D since DM^DM^, 
 
 .'. ND is the radical axis, and this is perpendicular 
 to //i. 
 
 Now the pedal line of K goes through D, and clearly 
 also, since K is on the bisector of the angle A, the pedal 
 line must be perpendicular to AK. 
 
 .'. DN is the pedal line of K. 
 
 But the pedal line of K bisects KP. 
 
 .'. KNP is a straight line and X its middle point. 
 
 And since U is the middle point of OP, UX = ^OK. 
 
 .*. iVis a point on the nine-points circle. 
 
 Now invert the nine-points circle, the incircle and 
 ecircle with respect to the circle whose centre is X and 
 radius XD or XL. 
 
 The two latter circles will invert into themselves ; and 
 the nine-points circle will invert into the line BG\ for 
 X being on the nine-points circle the inverse of that 
 circle must be a line, and D and L, points on the circle, 
 invert into themselves, .'. DL is the inverse of the nine- 
 points circle. 
 
 But this line touches both the incircle and ecircle. 
 
 .*. the nine-points circle touches both the incircle and 
 ecircle. 
 
 Similar 1}^ it touches the other two ecircles. 
 
 Cor. The point of contact of the nine-points circle 
 with the incircle will be the inverse of M, and with the 
 ecircle the inverse of ifj. 
 
INVERSION. 185 
 
 EXERCISES. 
 
 1. Prove that a system of intersecting coaxal circles can 
 be inverted into concurrent straight lines. 
 
 2. A sphere is inverted from a point on its surface ; shew 
 that to a system of meridians and parallels on the surface will 
 correspond two systems of coaxal circles in the inverse figure. 
 
 [See Ex. 18 of Chap. II.] 
 
 3. li A, B, C, D be four collinear points, and A', B\ C", 
 D' the four points inverse to them, then 
 
 AC.BD A'C .B'D' 
 AB.CD ~ A'B' .CD' ' 
 
 4. If P be a point in the plane of a system of coaxal 
 circles, and P^, P.2, P^ &c. be its inverses with respect to the 
 different circles of the system, P^, P^, P^ &c. are coney clic. 
 
 5. If P be a fixed point in the plane of a system of 
 coaxal circles, P' the inverse of P with respect to a circle of 
 the system, P" the inverse of P' with respect to another circle, 
 P'" of P" with respect to another and so on, then P', P", F" 
 &c. are concyclic. 
 
 6. POP', QOQ' are two chords of a circle and is a fixed 
 point. Prove that the locus of the other intersection of the 
 circles POQ, P'OQ' lies on a second fixed circle. 
 
 7. Shew that the result of inverting at any odd number 
 of circles of a coaxal system is equivalent to a single inversion 
 at one circle of the system ; and determine the circle which is 
 so equivalent to three given ones in a given order. 
 
 8. Shew that if the circles inverse to two given circles 
 ACD, BCD with respect to a given point P be equal, the 
 circle PCD bisects (internally and externally) the angles of 
 intersection of the two given circles. 
 
186 INVERSION. 
 
 9. Three circles cut one another orthogonally at the three 
 pairs of points AA\ BB', GC; prove that the circles through 
 ABC\ AB'C touch at A. 
 
 10. Prove that if the nine-points circle of a triangle and 
 one of the angular points of a triangle be given, the locus of 
 the orthocentre is a circle. 
 
 11. Prove that the nine-points circle of a triangle touches 
 the inscribed and escribed circles of the three triangles formed 
 by joining the orthocentre to the vertices of the triangle. 
 
 12. The figures inverse to a given figure with regard to 
 two circles C-^ and G^ are denoted by *S'i and S.2 respectively ; 
 shew that if G-^ and G^ cut orthogonally, the inverse of S^ with 
 regard to Cg is also the inverse of S^ with regard to Cj. 
 
 13. li A, B, G he three collinear points and any other 
 point, shew that the centres P, Q, R of the three circles 
 circumscribing the triangles OBG, OGA, GAB are concyclic 
 with 0. 
 
 Also that if three other circles are drawn through G, A ; 
 G, B ; G, G to cut the circles GBG, OGA, GAB, respectively, 
 at right angles, then these circles will meet in a point which 
 lies on the circumcircle of the quadrilateral GPQR. 
 
 14. Shew that if the circle PAB cut orthogonally the 
 circle PGD -, and the circle PAG cut orthogonally the circle 
 PBD ; then the circle PAD must cut the circle PBG ortho- 
 gonally. 
 
 15. Prove the following construction for obtaining the 
 point of contact of the nine-points circle of a triangle ABG 
 with the incircle. 
 
 The bisector of the angle A meets BG in H. From H the 
 other tangent HY i^ drawn to the incircle. The line joining 
 the point of contact Y of this tangent and D the middle point 
 of BG cuts the incircle again in the point required. 
 
 16. Given the circumcircle and incircle of a triangle, 
 shew that the locus of the centroid is a circle. 
 
INVERSION. 187 
 
 17. A, B, C are three circles and a, h, c their inverses 
 with respect to any other circle. Shew that if A and B are 
 inverses with respect to C, then a and b are inverses with 
 respect to c. 
 
 18. A circle S is inverted into a line, prove that this line 
 is the radical axis of S and the circle of inversion. 
 
 19. Shew that the angle between a circle and its inverse 
 is bisected by the circle of inversion. 
 
 20. The perpendiculars ALj BM, CN to the sides of a 
 triangle ABC meet in the orthocentre K. Prove that each 
 of the four circles which can be described to touch the three 
 circles about KMAN^ KNBL, KLGM touches the circumcircle 
 of the triangle ABC. 
 
 [Invert the three circles into the sides of the triangle by 
 means of centre if, and the circumcircle into the nine-points 
 circle.] 
 
 21. Invert two spheres, one of which lies wholly within 
 the other, into concentric spheres. 
 
 22. Examine the particular case of the proposition of 
 § 151, where the centre of inversion lies on S. 
 
 23. li A, P, Q be three collinear points, and if F', Q' be 
 the inverses of F, Q with respect to 0, and if F'Q' meet OA in 
 Aj^, then 
 
 AF.AQ OA^ 
 
 A,F'.A,Q'~ OA,'' 
 
CHAPTEE XIII. 
 
 SIMILARITY OF FIGURES. 
 
 154. Homothetic Figures. 
 
 If jP be a plane figure, which we may regard as an 
 assemblage of points typified by P, and if be a fixed 
 point in the plane, and if on each radius vector OP, 
 produced if necessary, a point P' be taken on the same 
 side of as P such that OP : OP' is constant (= k), then 
 P' will determine another figure F' which is said to be 
 similar and similarly situated to F. 
 
 Two such figures are conveniently called, in one word, 
 homothetic, and the point is called their homothetic 
 centre. 
 
 We see that two homothetic figures are in perspective, 
 the centre of perspective being the homothetic centre. 
 
 155. Prop. The line joining two points in the figure 
 F is parallel to the line joining the corresponding points in 
 the figure F' which is homothetic with it, and these lines 
 are in a constant ratio. 
 
 For if P and Q be two points in F, and P\ Q' the 
 corresponding points in F', since OP : OP' = OQ : OQ' 
 it follows that PQ and P'Q' are parallel, and that 
 PQ : P'Q = OP : OP' the constant ratio. 
 
SIMILARITY OF FIGURES. J 89 
 
 In the case where Q is in the line OP it is still true that 
 PQ:P'Q' = the constant ratio, for since OP:OQ=OP':OQ' 
 
 ,'.oP:OQ-op= OP' : oq - OF. 
 
 .-. OP:PQ=OR:P'Q\ 
 .'.PQ:P'Q=OP:OP'. 
 
 Cor. If the figures F and F' be curves S and S' the 
 tangents to them at corresponding points P and P' will 
 be parallel. For the tangent at P is the limiting position 
 of the line through P and a near point Q on aSi, and the 
 tangent at P' the limiting position of the line through 
 the corresponding points P' and Q'. 
 
 156. Prop. The homothetic centre of two homothetic 
 figures is determined by two pairs of corresponding points. 
 
 For if two pairs of corresponding points P, P'\ Q, Q' 
 be given is the intersection of PP' and QQ'. 
 
 Or in the case where Q is in the line PP\ is deter- 
 mined in this line by the equation OP : OP' = PQ : P'Q'. 
 
 The point is thus uniquely determined, for OP and 
 OP' have to have the same sign, that is, have to be in the 
 same direction. 
 
190 
 
 SIMILARITY OF FIGURES. 
 
 157. Figures directly similar. 
 
 If now two figures F and F' be homothetic, centre 0, 
 and the figure F' be turned in its plane round through 
 any angle, we shall have a new figure F^ which is similar 
 to F but not now similarly situated. 
 
 Two such figures F and F^ are said to be directly 
 similar and is called their centre of similitude. 
 
 Two directly similar figures possess the property that 
 the zPOPi between the lines joining to two corre- 
 sponding points P and Pj is constant. Also OP : OP^ 
 is constant, and PQ : P^Q^ = the same constant, and the 
 triangles OPQ, OP^Q^ are similar. 
 
 158. Prop. If P, P^; Q, Q^ be two pairs of corre- 
 sponding points of two figures directly similar, and if PQ, 
 PiQi intersect in R, is the other intersection of the circles 
 PRP„ QEQ,. 
 
 For since Z OPQ = Z OP,Q^ 
 
SIMILARITY OF FIGURES. 
 
 Z OPR and Z OP^R are supplementary. 
 
 191 
 
 .-.POPijR is cyclic. 
 Similarly Q^OQR is cyclic. 
 Thus the proposition is proved. 
 
 Cor. The centre of similitude of two directly similar 
 figures is determined by two pairs of corresponding points. 
 
 It has been assumed thus far that P does not coincide 
 with Pj nor with Q^. 
 
192 SIMILARITY OF FIGURES. 
 
 If P coincide with Pj, then this point is itself the 
 centre of similitude. 
 
 If P coincide with Q^ we can draw QT and Q^T^ 
 through Q and Q^ such that 
 
 Z P,Q,T, = Z PQT and Q,T, : QT=P,Q, : PQ ; 
 then T and 2\ are corresponding points in the two figures. 
 
 159. When two figures are directly similar, and the 
 two members of each pair of corresponding points are on 
 opposite sides of 0, and coUinear with it, the figures may 
 be called antihomothetic, and the centre of similitude is 
 called the antihomothetic centime. 
 
 When two figures are antihomothetic the line joining 
 any two points P and Q of the one is parallel to the line 
 joining the corresponding points P' and Q' of the other ; 
 hut PQ and P'Q' are in opposite directions. 
 
 160. Case of two coplanar circles. 
 
 If we divide the line joining the centres of two given 
 circles externally at 0, and internally at 0' in the ratio 
 of the radii, it is clear from § 25 that is the homothetic 
 centre and 0' the antihomothetic centre for the two circles. 
 
 We spoke of these points as ' centres of similitude ' 
 before, but we now see that they are only particular 
 centres of similitude, and it is clear that there are other 
 
SIMILARITY OB^ FIGURES. 
 
 193 
 
 centres of similitude not lying in the line of these. For 
 taking the centre A of one circle to correspond with the 
 centre A-^ of the other, we may then take any point P of 
 the one to correspond with any point Pi of the other. 
 
 Let >Si be the centre of similitude for this corre- 
 spondence. 
 
 The triangles P>Si-4, P^SA^ are similar, and 
 8 A : ^^1 = ^P : .^iPi = ratio of the radii. 
 
 Thus S lies on the circle on 00' as diameter (§ 27). 
 
 Thus the locus of centres of similitude for two coplanar 
 circles is the circle on the line joining the homothetic and 
 antihomothetic centres. 
 
 This circle we have already called the circle of simili- 
 tude and the student now understands the reason of the 
 name. 
 
 161. Figures inversely similar. 
 
 If P be a figure in a plane, a fixed point in the 
 plane, and if another figure F' be obtained by taking 
 A. G. 13 
 
194 
 
 SIMILARITY OF FIGURES. 
 
 points P' in the plane to correspond with the points P 
 of F in such a way that OP : OP' is constant, and all the 
 angles POP' have the same bisecting line OX, the two 
 figures F and F' are said to be inversely similar ; is 
 then called the centre and OX the axis of inverse similitude. 
 
 Q' 
 
 X 
 
 K ^ 
 
 /i 
 
 P\ \ L 
 
 //P, 
 
 Q 
 
 Draw P'X perpendicular to the axis OX and let it 
 meet OP in Pj. 
 
 Then plainly, since OX bisects Z POP' 
 AOLP'=AOLP„ 
 and OPi = OP'. 
 
 .'. OPi : OP is constant. 
 
 Thus the figure formed by the points Pi will be 
 homothetic with F. 
 
 Indeed the figure F' may be regarded as formed from 
 a figure Pj homothetic with F by turning Pj round the 
 axis OX through two right angles. 
 
SIMILARITY OF FIGURES. 
 
 195 
 
 The student will have no difficulty in proving for 
 himself that if any line OF be taken through in the 
 plane of F and F\ and if P'K be drawn perpendicular to 
 OY and produced to P^ so that P'K^KP^ then the 
 figure formed with the points typified by P^ will be 
 similar to F ; but the two will not be similarly situated 
 except in the case where OF coincides with OX. 
 
 162. If P and Q be two points in the figure jP, and 
 P\ Q' the corresponding points in the figure F', in- 
 versely similar to it, we easily obtain that P'Q : PQ = the 
 constant ratio of OP : OP' , and we see that the angle 
 POQ = angle Q'OF {not PVQ), In regard to this last 
 point we see the distinction between figures directly 
 similar and figures inversely similar. 
 
 163. Given two pairs of corresponding points in two 
 inversely similar figures, to find the centre and acds of 
 similitude. 
 
 To solve this problem we observe that if PP' cut the 
 
 13—2 
 
196 SIMILARITY OF FIGURES. 
 
 axis OX in F, then PF :FF =0P -.OP' since the axis 
 bisects the angle POP'. 
 
 .\PF:FP' = PQ:P'Q'. 
 
 Hence if P, P' ; Q, Q' be given, join PP' and QQ' and 
 divide these lines at F and G in the ratio PQ : P'Q', then 
 the line FG is the axis. 
 
 Take the point Pj symmetrical with P on the other 
 side of the axis, then is determined by the intersection 
 of P'Py with the axis. 
 
 Note. The student who wishes for a fuller discussion 
 on the subject of similar figures than seems necessary or 
 desirable here, should consult Lachlan's Modern Pure 
 Geometry, Chapter IX. 
 
 EXERCISES. 
 
 1. Prove that homothetic figures will, if ortliogonally 
 projected, be projected into homothetic figures. 
 
 2. If P, P' ; Q, Q' ; R, R' be three corresponding pairs of 
 points in two figures either directly or inversely similar, tlie 
 triangles PQE^ FQ'R' are similar in the Euclidean sense. 
 
 3. If S and aS" be two curves directly similar, prove 
 that if S be turned in the plane about any point, the locus of 
 the centre of similitude of S and *S" in the different positions 
 of S will be a circle. 
 
 4. If two triangles, directly similar, be inscribed in the 
 same circle, shew that the centre of the circle is their centre 
 of similitude. 
 
 Shew also that the pairs of corresponding sides of the 
 triangles intersect in points forming a triangle directly similar 
 to them. 
 
SIMILARITY OF FIGURES. 197 
 
 5. If two triangles be inscribed in the same circle so as to 
 be inversely similar, shew that they are in perspective, and 
 that the axis of perspective passes through the centre of the 
 circle. 
 
 6. If on the sides BC, CA, AB oi a, triangle ABC points 
 X, r, Z be taken such that the triangle XYZ is of constant 
 shape, construct the centre of similitude of the system of 
 triangles so formed ; and prove that the locus of the ortho- 
 centre of the triangle XYZ is a straight line. 
 
 7. If three points X, Y, Z be taken on the sides of a 
 triangle ABC opposite to A^ B, C respectively, and if three 
 similar and similarly situated ellipses be described round 
 AYZy BZX and CXY^ they will have a common point. 
 
 8. The circle of similitude of two given circles belongs to 
 the coaxal system whose limiting points are the centres of the 
 two given circles. 
 
 9. If two coplanar circles be regarded as inversely similar 
 the locus of the centre of similitude is still the 'circle of 
 similitude,' and the axis of similitude passes through a fixed 
 point. 
 
 10. P and P' are corresponding points on two coplanar 
 circles regarded as inversely similar and >S' is the centre of 
 similitude in this case. Q is the other extremity of the 
 diameter through P, and when Q and P' are corresponding 
 points in the two circles for inverse similarity, S' is the centre 
 of similitude. Prove that SS' is a diameter of the circle of 
 similitude. 
 
 11. ABCD is a cyclic quadrilateral ; AC and BD intersect 
 in ^, ^i> and BC in F ', prove that EF is a diameter of the 
 circle of similitude for the circles on AB^ CD as diameters. 
 
 12. Generalise by projection the theorem that the circle 
 of similitude of two circles is coaxal with them. 
 
MISCELLANEOUS EXAMPLES. 
 
 1. Prove that when four points A, B, C, D lie on a 
 circle, the orthocentres of the triangles BCD, GDA^ DAB, 
 ABC lie on an equal circle, and that the line which joins the 
 centres of these circles is divided in the ratio of three to one 
 by the centre of mean position of the points A, B, C, D. 
 
 2. ABC is a triangle, the centre of its inscribed circle, 
 and ^1, B^, C^ the centres of the circles escribed to the sides 
 BC, CAf AB respectively; Z, M, N the points where these 
 sides are cut by the bisectors of the angles A, B, C. Shew 
 that the orthocentres of the three triangles LB^C^, MCiA^, 
 NA^B^ form a triangle similar and similarly situated to 
 A^B^Cii and having its orthocentre at 0. 
 
 3. ABC is a triangle, L^, M^, iV^j are the points of contact 
 of the incircle with the sides opposite to A, B, C respectively ; 
 L2 is taken as the harmonic conjugate of L^ with respect to 
 B and C ; M^ and iVg ^^^ similarly taken; P, Q, R are the 
 middle points of L^Lc^, M-^M]^, N^N^. Again AA^ is the bisector 
 of the angle A cutting BG in A-^y and A^, is the harmonic 
 conjugate of A-^ with respect to B and G ; B^ and C2 are 
 similarly taken. Prove that the line A^B^G^ is parallel to the 
 line PQR. 
 
 4. ABC is a triangle the centres of whose inscribed and 
 circumscribed circles are 0, 0' \ 0^ 0^, 0^ are the centres of 
 its escribed circles, and OjOg, O2O3 meet AB, BG respectively 
 in L and M ; shew that 00' is perpendicular to LM. 
 
MISCELLANEOUS EXAMPLES. 199 
 
 5. If circles be described on the sides of a given triangle 
 as diameters, and quadrilaterals be inscribed in them having 
 the intersections of their diagonals at the orthocentre, and one 
 side of each passing through the middle point of the upper 
 segment of the corresponding perpendicular, prove that the 
 sides of the quadrilaterals opposite, to these form a triangle 
 equiangular with the given one. 
 
 6. Two circles are such that a quadrilateral can be 
 inscribed in one so that its sides touch the other. Shew 
 that if the points of contact of the sides be P, Q, i?, S, then 
 the diagonals of FQES are at right angles; and prove that 
 PQ, BS and QE, SP have their points of intersection on the 
 same fixed line. 
 
 7. A straight line drawn through the vertex A of the 
 triangle ABC meets the lines BB, BF which join the middle 
 point of the base to the middle points E and F of the sides 
 CA, AB in Z, 7; shew that BY is parallel to GX. 
 
 8. Four intersecting straight lines are drawn in a plane. 
 Reciprocate with regard to any point in this plane the 
 theorem that the circumcircles of the triangles formed by 
 the four lines are concurrent at a point which is concyclic 
 with their four centres. 
 
 9. E and F are two fixed points, P a moving point, on a 
 hyperbola, and PE meets an asymptote in Q. Prove that the 
 line through E parallel to the other asymptote meets in a 
 fixed point the line through Q parallel to PF. 
 
 10. Any parabola is described to touch two fixed straight 
 lines and with its directrix passing through a fixed point P. 
 Prove that the envelope of the polar of P with respect to the 
 parabola is a conic. 
 
 11. Shew how to construct a triangle of given shape 
 whose sides shall pass through three given points. 
 
 12. Construct a hyperbola having two sides of a given 
 triangle as asymptotes and having the base of the triangle as 
 a normal. 
 
200 MISCELLANEOUS EXAMPLES. 
 
 13. A tangent is drawn to an ellipse so that the portion 
 intercepted by the equiconjugate diameters is a minimum ; 
 shew that it is bisected at the point of contact. 
 
 14. A parallelogram, a point and a straight line in the 
 same plane being given, obtain a construction depending on 
 the ruler only for a straight line through the point parallel to 
 the given line. 
 
 15. Prove that the problem of constructing a triangle 
 whose sides each pass through one of three fixed points and 
 whose vertices lie one on each of three fixed straight lines is 
 poristic, when the three given points are collinear and the 
 three given lines are concurrent. 
 
 16. A, B, Cf D are four points in a plane no three of 
 which are collinear, and a projective transformation inter- 
 changes A and B, and also G and D. Give a pencil and ruler 
 construction for the point into which any arbitrary point 
 F is changed ; and shew that any conic through A, B, C, D is 
 transformed into itself. 
 
 17. Three hyperbolas are described with B, C ; G, A; 
 and A, B for foci passing respectively through A, Bj G. Shew 
 that they have two common points P and Q ; and that there 
 is a conic circumscribing ABG with P and Q for foci. 
 
 18. Three triangles have their bases on one given line 
 and their vertices on another given line. Six lines are formed 
 by joining the point of intersection of two sides, one from 
 each of a pair of the triangles, with a point of intersection of 
 the other two sides of those triangles, choosing the pairs of 
 triangles and the pairs of sides in every possible way. Prove 
 that the six lines form a complete quadrangle. 
 
 19. Shew that in general there are four distinct solutions 
 of the problem : To draw two conies which have a given point 
 as focus and intersect at right angles at two other given 
 points. Determine in each case the tangents at the two 
 given points. 
 
MISCELLANEOUS EXAMPLES. 201 
 
 20. An equilateral triangle ABC is inscribed in a circle 
 of which is the centre : two hyperbolas are drawn, the first 
 has C as a focus, OA as directrix and passes through B ; the 
 second has C as focus, OB as directrix and passes through A. 
 Shew that these hyperbolas meet the circle in eight points, 
 which with C form the angular points of a regular polygon of 
 nine sides. 
 
 21. An ellipse, centre 0, touches the sides of a triangle 
 ABC, and the diameters conjugate to OA, OB, 00 meet any 
 tangent in D, E, F respectively ; prove that AD, BE, OF meet 
 in a point. 
 
 22. A parabola touches a fixed straight line at a given 
 point, and its axis passes through a second given point. Shew 
 that the envelope of the tangent at the vertex is a parabola 
 and determine its focus and directrix. 
 
 23. Three parabolas have a given common tangent and 
 touch one another at P, Q, R. Shew that the points P, Q, R 
 are collinear. Prove also that the parabola which touches the 
 given line and the tangents at P, Q, R has its axis parallel 
 to PQR. 
 
 24. Prove that the locus of the middle point of the 
 common chord of a parabola and its circle of curvature is 
 another parabola whose latus rectum is one-fifth that of the 
 given parabola. 
 
 25. Three circles pass through a given point and their 
 other intersections are A, B, C. A point D is taken on the 
 circle OBO, E on the circle OCA, F on the circle OAB. Prove 
 that 0, D, E, F are concyclic ii AF.BD. CE = -FB.DC .EA, 
 where ^i^ stands for the chord AF, and so on. Also explain 
 the convention of signs which must be taken. 
 
 26. Shew that a common tangent to two confocal 
 parabolas subtends an angle at the focus equal to the angle 
 between the axes of the parabolas. 
 
 27. The vertices A, B oi &> triangle ABC are fixed, and 
 the foot of the bisector of the angle A lies on a fixed straight 
 line ; determine the locus of C. 
 
202 MISCELLANEOUS EXAMPLES. 
 
 28. A straight line A BCD cuts two fixed circles X and 
 Y, so that the chord AB of X is equal to the chord CD of F. 
 The tangents to X at ^ and B meet the tangents to F at C 
 and D in four points P, Q, R, S. Shew that P, Q, E, S lie on 
 a fixed circle. 
 
 29. On a fixed straight line AB, two points F and Q are 
 taken such that FQ is of constant length. X and Y are two 
 fixed points and XF, YQ meet in a point F. Shew that as F 
 moves along the line AB, the locus of P is a hyperbola of 
 which AB is an asymptote. 
 
 30. A parabola touches the sides BC, CA, AB of a 
 triangle ABC in I), E, F respectively. Prove that the straight 
 lines AD, BE, OF meet in a point which lies on the polar of 
 the centre of gravity of the triangle ABC. 
 
 31. If two conies be inscribed in the same quadrilateral, 
 the two tangents at any of their points of intersection cut 
 any diagonal of the quadrilateral harmonically. 
 
 32. A circle, centre 0, is inscribed in a triangle ABC. 
 The tangent at any point F on the circle meets BC in D. 
 The line through perpendicular to OD meets FD in D' . 
 The corresponding points E', F' are constructed. Shew that 
 AD', BE', CF' are parallel. 
 
 33. Two points are taken on a circle in such a manner 
 that the sum of the squares of their distances from a fixed 
 point is constant. Shew that the envelope of the chord joining 
 them is a parabola. 
 
 34. A variable line FQ intersects two fixed lines in 
 points F and Q such that the orthogonal projection of FQ 
 on a third fixed line is of constant length. Shew that the 
 envelope of FQ is a parabola, and find the direction of its axis. 
 
 35. With a focus of a given ellipse {A) as focus, and the 
 tangent at any point F as directrix, a second ellipse {B) is 
 described similar to (A). Shew that {B) touches the minor 
 axis of {A) at the point where the normal at F meets it. 
 
MISCELLANEOUS EXAMPLES. 203 
 
 36. A parabola touches two fixed lines which intersect in 
 T, and its axis passes through a fixed point D. Prove that, if 
 S be the focus, the bisector of the angle TSD is fixed in 
 direction. Shew further that the locus of >S' is a rectangular 
 hyperbola of which D and T are ends of a diameter. What 
 are the directions of its asymptotes 1 
 
 37. If an ellipse has a given focus and touches two fixed 
 straight lines, then the director circle passes through two fixed 
 points. 
 
 38. is any point in the plane of a triangle ABC, and 
 X, Y, Z are points in the sides BC, CA, AB respectively, such 
 that AOX, BOY, COZ are right angles. If the points of 
 intersection of GZ and AX, ilX and ^F be respectively Q and 
 i?, shew that OQ and OR are equally inclined to OA. 
 
 39. The line of collinearity of the middle points of the 
 diagonals of a quadrilateral is drawn, and the middle point of 
 the intercept on it between any two sides is joined to the 
 point in which they intersect. Shew that the six lines so 
 constructed together with the line of collinearity and the 
 three diagonals themselves touch a parabola. 
 
 40. The triangles A^B^Ci, A2B2C2 are reciprocal with 
 respect to a given circle ; B.2C2, C^A-^ intersect in I\, and B^C^, 
 C.2A2 in P^. Shew that the radical axis of the circles which 
 circumscribe the triangles P^A^B^, P^A^B^ passes through the 
 centre of the given circle. 
 
 41. A transversal cuts the three sides BC, CA, AB oi a, 
 triangle in P, Q, R; and also cuts three concurrent lines 
 through A, B and G respectively in P', Q', R'. Prove that 
 
 PQ' . QR' . RP' = -P'Q. Q'R . R'P. 
 
 42. Through any point in the plane of a triangle ABG 
 is drawn a transversal cutting the sides in P, Q, R. The 
 lines OA, OB, OG are bisected in A', B', G' ; and the segments 
 QR, RP, PQ of the transversal are bisected in P', Q', R'. 
 Shew that the three lines A'P', B'Q', G'E are concurrent; 
 
204 MISCELLANEOUS EXAMPLES. 
 
 43. From any point P on a given circle tangents PQ, 
 PQ' are drawn to a given circle whose centre is on the 
 circumference of the first : shew that the chord joining the 
 points where these tangents cut the first circle is fixed in 
 direction and intersects QQ' on the line of centres. 
 
 44. If any parabola be described touching the sides of 
 a fixed triangle, the chords of contact will pass each through 
 a fixed point. 
 
 45. From D, the middle point of AB^ a tangent DP is 
 drawn to a conic. Shew that if CQ, GR are the semi- 
 diameters parallel to AB and DP, 
 
 AB : CQ=='2DP : CR. 
 
 46. The side BC of a triangle ABC is trisected at M, N. 
 Circles are described within the triangle, one to touch BG at 
 M and AB at ZT, the other to touch BG at JSf and AG a,t K. 
 If the circles touch one another at L, prove that GH, BK pass 
 through L. 
 
 47. ABG is a triangle and the perpendiculars from A, B, 
 G on the opposite sides meet them in Z, M, N respectively. 
 Three conies are described ; one touching BM, GN at J/, N 
 and passing through A ; a second touching GN, AL at iV, L 
 and passing through B ; a third touching AL, BM at L, M 
 and passing through G. Prove that at J, ^, G they all touch 
 the same conic. 
 
 48. A parabola touches two fixed lines meeting in T and 
 the chord of contact passes through a fixed point A ; shew 
 that the directrix passes through a fixed point 0, and that the 
 ratio TO to OA is the same for all positions of A. Also that 
 if A move on a circle whose centre is T, then AO is always 
 normal to an ellipse the sum of whose semi-axes is the radius 
 of this circle. 
 
 49. Triangles which have a given centroid are inscribed 
 in a given circle, and conies are inscribed in the triangles so 
 as to have the common centroid for centre, prove that they 
 all have the same fixed director circle. 
 
MISCELLANEOUS EXAMPLES. 205 
 
 50. A circle is inscribed in a right-angled triangle and 
 another is escribed to one of the sides containing the right 
 angle ; prove that the lines joining the points of contact of 
 each circle with the hypothenuse and that side intersect one 
 another at right angles, and being produced pass each through 
 the point of contact of the other circle with the remaining 
 side. Also shew that the polars of any point on either of 
 these lines with respect to the two circles meet on the other, 
 and deduce that the four tangents drawn from any point on 
 either of these lines to the circles form a harmonic pencil. 
 
 51. If a triangle PQR circumscribe a conic, centre C, 
 and ordinates be drawn from Q, R to the diameters CR, CQ 
 respectively, the line joining the feet of the ordinates will pass 
 through the points of contact of PQ, PR. 
 
 52. Prove that the common chord of a conic and its circle 
 of curvature at any point and their common tangent at this 
 point divide their own common tangent harmonically. 
 
 53. Shew that the point of intersection of the two 
 common tangents of a conic and an osculating circle lies 
 on the confocal conic which passes through the point of 
 osculation. 
 
 54. In a triangle ABC, AL, RM, ON are the perpen- 
 diculars on the sides and MN^ NL, LM when produced meet 
 BG, CA, AB in P, Q, R. Shew that P, Q, R lie on the 
 radical axis of the nine-points circle and the circumcircle of 
 ABC, and that the centres of the circumcircles of ALP, BMQ, 
 CNR lie on one straight line. 
 
 55. A circle through the foci of a rectangular hyperbola 
 is reciprocated with respect to the hyperbola ; shew that the 
 reciprocal is an ellipse with a focus at the centre of the 
 hyperbola; and its minor axis is equal to the distance 
 between the directrices of the hyperbola. 
 
 56. A circle can be drawn to cut three given circles 
 orthogonally. If any point be taken on this circle its polars 
 with regard to the three circles are concurrent. 
 
206 MISCELLANEOUS EXAMPLES. 
 
 57. From any point tangents OP, OF, OQ, OQ' are 
 drawn to two confocal conies ; OP, OP' touch one conic, OQ, 
 OQ' the other. Prove that the four lines PQ, P'Q', PQ', P'Q 
 all touch a third confocal. 
 
 58. P, F and Q, Q' are four collinear points on two 
 conies U and V respectively. Prove that the corners of the 
 quadrangle whose pairs of opposite sides are the tangents iat 
 P, P' and Q, Q' lie on a conic which passes through the four 
 points of intersection of U and F. 
 
 59. If two parabolas have a real common self -conjugate 
 triangle they cannot have a common focus. 
 
 60. The tangents to a conic at two points A and B meet 
 in T, those at A', B in T' ; prove that 
 
 i\a'abb)^t'{a:ab'B). 
 
 61. A circle moving in a plane always touches a fixed 
 circle, and the tangent to the moving circle from a fixed point 
 is always of constant length. Prove that the moving circle 
 always touches another fixed circle. 
 
 62. A system of triangles is formed by the radical axis 
 and each pair of tangents from a fixed point P to a coaxal 
 system of circles. Shew that if P lies on the polar of a 
 limiting point with respect to the coaxal system, then the 
 circumcircles of the triangles form another coaxal system. 
 
 63. Two given circles S, S' intersect in ^, ^ ; through A 
 any straight line is drawn cutting the circles again in P, F 
 respectively. Shew that the locus of the other point of inter- 
 section of the circles, one of which passes through B, P and 
 cuts S orthogonally, and the other of which passes through 
 B, F and cuts S' orthogonally, is the straight line through B 
 perpendicular to AB. 
 
 64. All conies with respect to which a given triangle 
 EFG is self-conjugate and which pass through a given point A 
 pass also through three other fixed points. 
 
 65. A, B, C, D are four points on a conic ; EF cuts the 
 lines BC, GA, AB in a, b, c respectively and the conic in JS 
 
MISCELLANEOUS EXAMPLES. 207 
 
 and F \ a\ h', c are harmonically conjugate to a, h, c with 
 respect to E, F. The lines Da\ Dh\ Dc meet BC, CA, AB 
 in a, ^, y respectively. Shew that a, /8, y are collinear. 
 
 66. Three circles intersect at so that their respective 
 diameters DO, EO, FO pass through their other points of 
 intersection A, B, C ; and the circle passing through D, E, F 
 intersects the circles again in G, II, I respectively. Prove 
 that the circles AOG, BOH, COI are coaxal. 
 
 67. A conic passes through four fixed points on a circle, 
 prove that the polar of the centre of the circle with regard to 
 the conic is parallel to a fixed straight line. 
 
 68. The triangles PQE, FQ'R are such that PQ, PR, 
 FQ', FR' are tangents at Q, R, Q', R' respectively to a conic. 
 Prove that 
 
 P{QR'Q'R) = P'{QRQ'R) 
 and P, Q, R, F, Q', R' lie on a conic. 
 
 69. If ^', B', C, D' be the points conjugate to A, B, C, D 
 in an involution, and P, Q, R, S be the middle points of A A', 
 BB', CC, DD', 
 
 (PQRS) = (ABGD) . {AB'GD'). 
 
 70. ABC is a triangle. If BDCX, CEAY, AFBZ be 
 three ranges such that {XBCD) .{AYGE) .{ABZF) = \, and 
 AD, BE, CF be concurrent, then X, Y, Z will be collinear. 
 
 71. If ABC be a triangle and D any point on BC, then 
 (i) the line joining the circumcentres of ABD, ACD touches a 
 parabola : (ii) the line joining the incentres touches a conic 
 touching the bisectors of the angles ABC, ACB. 
 
 Find the envelope of the line joining the centres of the 
 circles escribed to the sides BD, CD respectively. 
 
 72. Two variable circles S and S' touch two fixed circles, 
 find the locus of the points which have the same polars with 
 regard to S and S'. 
 
 73. QP, QP' are tangents to an ellipse, QM is the per- 
 pendicular on the chord of contact PP' and K is the pole of 
 QM. If H is the orthocentre of the triangle PQP', prove that 
 HK is perpendicular to QC. 
 
208 MISCELLANEOUS EXAMPLES. 
 
 74. Two circles touch one anotlier at 0. Prove that the 
 locus of the points inverse to with respect to circles which 
 touch the two given circles is another circle touching the 
 given circles in 0, and find its radius in terms of the radii 
 of the given circles. 
 
 75. Prove that the tangents at A and C to a parabola 
 and the chord AG meet the diameter through B, a third point 
 on the parabola in a, c, 6, such that aB : Bb = Ab :bC = Bb : cB. 
 Hence draw through a given point a chord of a parabola 
 that shall be divided in a given ratio at that point. How 
 many different solutions are there of this problem, % 
 
 76. If A, B, C be three points on a hyperbola and the' 
 directions of both asymptotes be given, then the tangent at B 
 may be constructed by drawing through B a parallel to the 
 line joining the intersection of BC and the parallel through A 
 to one asymptote with the intersection of ^-5 and the parallel 
 through C to the other. 
 
 77. A circle cuts three given circles at right angles; calling 
 these circles A, B, C, fi, shew that the points where C cuts O 
 are the points where circles coaxal with A and B touch O. 
 
 78. If ABG^ DEF be two coplanar triangles, and aS' be 
 a point such that SD, SB, SF cut the sides BC, CA, AB 
 respectively in three collinear points, then aS'^, SB, SC cut 
 the sides FF, FD, DE in three collinear points. 
 
 79. ABC is a triangle, Z) is a point of contact with BC 
 of the circle escribed to BC \ E and F are found on CA, AB 
 in the same way. Lines are drawn through the middle points 
 of BC, CA, AB parallel to AB, BE, CF respectively; shew 
 that these lines meet at the incentre. 
 
 80. Four points lie on a circle; the pedal line of each 
 of these with respect to the triangle formed by the other three 
 is drawn ; shew that the four lines so drawn meet in a point. 
 
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208 
 
 MISCELLANEOUS EXAMPLES. 
 
 74. Two circles touch one anotlier at 0. Prove that 
 locus of the points inverse to with respect to circles whi 
 touch the two given circles is another circle touching 
 given circles in 0, and find its radius in terms of the r 
 of the given circles. 
 
 75. Prove that the tangents at A and (7 to a par 
 and the chord AG meet the diameter through B, a thir 
 on the parabola in a, c, 6, such that aB:Bb=^Ab:bC 
 Hence draw through a given point a chord of 
 
 that shall be divided in a given ratio at that 
 many different solutions are there of this pro^ 
 
 76. If A, B, C be three points on ^ 
 directions of both asymptotes be gi^' 
 
 may be constructed by drawi^ 
 line joining the intersect!^ 
 to one asymptote with 
 through C to t> 
 
 77. * 
 
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