Textuality in 3D: three-dimensional (re)constructions as digital scholarly editions


RESEARCH ARTICLE

Textuality in 3D: three-dimensional (re)constructions
as digital scholarly editions

Susan Schreibman1 & Costas Papadopoulos1

Published online: 14 May 2019
# The Author(s) 2019

Abstract
3D (re)constructions of heritage sites and Digital Scholarly Editions face similar needs
and challenges and have many concepts in common, although they are expressed
differently. 3D (re)constructions, however, lack a framework for addressing them.
The goal of this article is not to create a single or the lowest common denominator to
which both DSEs and 3D models subscribe, nor is it to reduce 3D to one scholarly
editing tradition. It is rather to problematise the development of a model by borrowing
concepts and values from editorial scholarship in order to enable public-facing 3D
scholarship to be read in the same way that scholarly editions are by providing context,
transmission history, and transparency of the editorial method/decision-making process.

Keywords 3D . (Re)construction . Digital scholalry editions . 3D scholarly editions .

Ambiguity. Transparency. Evidence

1 Introduction

The nature, functionality, and theories informing Digital Scholarly Editions (DSEs)
have flourished over the past three decades, moving beyond how to represent print-
based texts in digital forms into new types of knowledge production and dissemination
informed by the affordances of the medium (Apollon et al. 2014; Sutherland 1997;
Driscoll and Pierazzo 2016; Pierazzo 2015). The creators of the earliest DSEs were
cognizant of these differences in the nomenclature used to describe their scholarship:
The Rosetti Archive, The Blake Archive, The MacGreevy Archive, The Whitman
Archive. The shift from conceiving of their scholarship as an editorial product for print
publication to web-based carried with it a new spatiality in which variants, versions,
and secondary sources did not have to be decomposed into a notational shorthand

International Journal of Digital Humanities (2019) 1:221–233
https://doi.org/10.1007/s42803-019-00024-6

* Susan Schreibman
s.schreibman@maastrichtuniversity.nl

1 Department of Literature & Art, Faculty of Arts and Social Sciences, Maastricht Uiversity,
Maastricht, The Netherlands

http://crossmark.crossref.org/dialog/?doi=10.1007/s42803-019-00024-6&domain=pdf
mailto:s.schreibman@maastrichtuniversity.nl


delivered at the bottom of the page, but rather connoted a shift in thinking of scholarly
editions from sites of textual compression to decentred webs of textuality (after all, this
was the height of hypertext theory). In Derridean terms, the digital archive was a space
for gathering together texts on a specific theme, individual, or topic, expanding the
world of its creation into an archontic space for inscription and investigation (Derrida
and Prenowitz 1995, 10).

These new forms of editions could be also described as assemblages, little machines
of knowledge (Deleuze and Guattari 1987, 4). Thinking of DSEs as machines of
knowledge which represent texts as open objects that can be read and understood
through and by their means of production and reception reelevates long-standing
textual practices such as annotation, apparatus, and commentary as interlinked dis-
courses, ‘not in serially additive arrangements, but in functional interdependence’,
providing a palette for both textual and contextual study (Gabler 2010, 46). This model
of DSEs repositions the editor, not as an objective arbiter of the text, but more like a
hunter-gatherer, a constructor of a dynamic and rhizomatic knowledge site.

These knowledge sites need not privilege the alphanumeric. As early as 1999, when
the first digital archives were being published, McKenzie described the panoply of
objects that could be open to the kinds of intensive bibliographical study (transmission,
production, and reception) that textual scholars had traditionally reserved for print and
manuscript traditions, ‘as verbal, visual, oral and numeric data’ (McKenzie 1999, 13).
Like McKenzie, we believe that the digital provides us with a pan-glossary to abstract
the material medium of the objects of our contemplation to conceptual ones, and that
the text(s) at the centre (or periphery) of the knowledge site we create is worthy of
representing any human activity, not simply the artistic but the anthropologic. In his
definition of digital scholarly editions, Sahle has also advocated that Scholarly Digital
Editions not be restricted to literary texts but rather ‘cover all cultural artefacts from the
past that need critical examination in order to become useful sources for research in the
humanities’ (Sahle 2016, 22). What is key, however, is not simply that the object, or
what we are broadly calling the ‘text’, is digitised and distributed electronically, but that
it exists within a knowledge site, what we are calling a Digital Scholarly Edition; what
Derrida (Derrida and Prenowitz 1995, 10) and the earliest textual editors of web-based
scholarship called the archive, what Deleuze and Guattari (1987, 4) called the
assemblage, and McKenzie (1999, 15) ‘the sociology of texts’, integrating interrogating
and interlinking, the textual and the contextual (Gabler 2010, 46).

At first glance, conceiving of three-dimensional (3D) (re)constructions as Digital
Scholarly Editions might seem anti-intuitive. After all, the technologies, methodol-
ogies, and theories that have informed the creation of DSEs, everything from TEI/
XML, documentary vs critical editions, and relational vs XML-aware databases to
more recent discussions of how the texts created in DSEs can be repurposed,
remodelled, and algorithmically analysed and visualised, share little with the tech-
nologies, methodologies, and theories that have informed scholarship expressed
through 3D reconstructions. 3D reconstructions are computer generated models
produced in computer graphic software packages. They represent in three dimen-
sions geometric data combined with textures and a simulation of how light interacts
with different surfaces.

The 3D(re)constructions we refer to in this article concern cultural heritage
visualisations and simulations. These visualisations range from schematic

222 S. Schreibman, C. Papadopoulos



representations of buildings to photorealistic renderings and predictive simulations of
ancient structures (see Dawson et al. 2007) and from spatial analysis (see Paliou et al.
2011) and physics simulations (see Oetelaar 2016) to interactive virtual worlds utilising
online platforms (see Sequiera and Morgado 2013) and game engines (see the projects
carried out as part of the Humanities Virtual Worlds Consortium – http://virtualworlds.
etc.ucla.edu/). Examples of the types of projects that could be informed by the
principles outlined in this article include the Virtual Rosewood Research project
(http://www.rosewood-heritage.net/), which focuses on Rosewood, Florida, an
African American town destroyed during the 1923 race riot (González-Tennant 2015
), Virtual Williamsburg 1776 (Fischer 2012; http://research.history.org/vw1776/), and
Digital Hadrian’s Villa (Frischer and Stinson 2016), the Unity version of which allows
users to test archaeoastronomical theories (e.g. the alignment of the sun with the tower
of Roccabruna on the summer solstices during Hadrian’s reign to discover celestial
arrangements in the night sky as they would have been seen in the past). It also includes
Contested Memories: The Battle of Mount Street Bridge project
(http://mountstreet1916.ie), which will be discussed at the end of this article.

We will be utilising the term (re)constructions (as opposed to reconstruction) to
signify the theoretical nature of the research being undertaken, reinforcing the hypo-
thetical nature of the models created as described in more detail below. Although three-
dimensional modelling has been seen as an essential research practice in fields such as
archaeology and architecture, with hundreds of applications providing opportunities for
experimentation and new insights, it has never assumed a central role or been
established as scholarship in its own right, and it has been less frequently used by
other fields in the humanities. There is no doubt that these models can have a ‘wow’
factor, and they are commonly used as the last step that takes place at the end of a
project as a means of communicating absence in a visually engaging way (Hermon and
Fabian 2002; Gillings 2005) and attracting publicity and funding. The situation is
changing, however, as the cost of the technologies and equipment needed to create
3D models has become more affordable, and more institutions at third level teach the
skills, methods, and theories involved. Over a decade ago, Gillings (2005, 224) called
for a robust theoretical and conceptual framework that would realise the potential of the
method, providing a means of making visible the underlying decision-making process
while disseminating research findings within a single methodological framework. That
framework still does not exist.

Today 3D (re)constructions are being used as analytical tools within the broad area
of history and heritage studies to explore the impact of light on the experience and
perception of ancient environments, as simulations to investigate how battles unfold, as
a means of providing an embodied and sensorial understanding, and as immersive
experiences of a period, culture, or historical event. In most cases these
(re)constructions have been created for offline use due to the computational power
required to undertake various analyses or even to host the worlds online, making it
difficult for researchers outside project teams to learn from the work of others. It may
be due to these difficulties that those working with these technologies have spent less
time developing a framework within which to convey to a wider public the scholarship
that has gone into the creation of the (re)construction, including the choices used in
creating the model, the methodologies used, the history of the subject under investiga-
tion, and the decisions made during the process of its creation.

Textuality in 3D: three-dimensional (re)constructions as digital scholarly editions 223

http://virtualworlds.etc.ucla.edu/
http://virtualworlds.etc.ucla.edu/
http://www.rosewood-heritage.net/
http://research.history.org/vw1776/
http://mountstreet1916.ie/


Current 3D scholarship primarily exists in a bifurcated information space. The
models exist electronically, but the knowledge generated from them is written about
in journal articles, illustrated by static two-dimensional images, while the models
themselves cannot be accessed beyond the individual or the team who worked on
them. While 15 years ago Earl and Wheatley (2002) ascribed the under-theorisation of
the field to a widespread belief that 3D visualisation had a small role to play as an
interpretive mechanism, there now is a growing body of practitioners in a wide variety
of fields who are looking for a holistic information environment within which to
disseminate their work.

The authors of this article, one with a background that stretches back to scholarly
editing in print and, since the mid-1990s, has included digital forms and the other with
a background in digital archaeology and particularly in the use of 3D modelling for
analytical and documentary purposes, have come to believe that recent scholarship in
digital scholarly editions, as it moves away from the conceptual and medium-specific
frameworks of print traditions into more dynamic knowledge sites, can provide a
productive model of the ways in which 3D (re)constructions can be used to reach
larger audiences and shape intellectual debates. This scholarship can also provide a
model for the ways in which the knowledge gained by the researchers who created it
can be embedded in 3D (re)constructions.

This is a speculative article, the essential intention of which is to propose and test
theories from two domains which at first glance seem to have very little in common.
However, its authors have come to realise after several years of collaboration and
conversation that they share significant concerns and have wrestled with similar
concepts, from expressing transparency and ambiguity to modelling absence from the
extant record. This is an opening salvo to generate discussion about how the current
theories about DSEs could be expanded and applied beyond their dominantly text-
based practice and how 3D (re)constructions can be conceived of as open knowledge
networks which contain, embedded within them, the analytical and archival scholarship
that informed their creation.1

2 Modelling in 3D: an introduction

Three-dimensional computer graphical approaches flourished in the television and film
industry with the first commercial 3D software package, Wavefront Technologies,
released in 1984 to serve the increasing needs of motion pictures. Around the same

1 This article has grown out of present and previous conversations. The authors thank the participants in the
Virtual Worlds as Digital Scholarly Editions Masterclass (Maynooth University, 13–14 June 2017,
http://dhprojects.maynoothuniversity.ie/vwdse/, funded by the Digital Scholarly Editions Initial Training
Network (DiXiT). This Masterclass provided a fruitful dialogue between scholars from the fields of
heritage 3D visualisation and Digital Scholarly Editing, allowing them to explore theoretical and practical
issues pertaining to the creation, annotation, and publication of 3D models with the ultimate aim of marrying
the practices of the two communities. The authors are also part of the Andrew W. Mellon Foundation project
‘Scholarship in 3D: Digital Edition Publishing Cooperative’, which attempts to build a sustainable framework
within which to reconceive 3D works as digital editions and create an infrastructure that will enable its
recognition as scholarship.

224 S. Schreibman, C. Papadopoulos

http://dhprojects.maynoothuniversity.ie/vwdse/


time, 3D modelling was used to (re)construct heritage datasets, with the earliest
reported work being that of the bath building at Caerleon Roman Fort in South Wales
(Smith 1985) and a year later the first animated virtual tour, that of the Old Minster of
Winchester (Reilly et al. 2016).

In this paper, we focus on the type of 3D modelling in which computer graphics are
used to (re)construct ‘what is not there’ as a means of providing a better understanding
of and generating hypotheses concerning and interpretations of different datasets, from
ancient structures to twentieth-century buildings. Like textual scholarship, 3D model-
ling requires evaluations of the reliability of different, often incomplete and ambiguous
sources, and it gathers evidence that leads to a series of decisions regarding the type,
amount, and style of models to be constructed, depending on their intended uses and
audiences.

The 3D scholarship to which we are referring in this paper has been called by many
names, from three-dimensional (solid) modelling to virtual reconstructions and 3D
computer graphic simulations. These terms have emerged from particular schools of
thought, theoretical and methodological traditions, and biases and assumptions. For
example, the term Virtual Reconstruction became popular in the 1990s after Reilly
(1991) coined the term Virtual Archaeology, while in the mid-2000s the term Virtual
Worlds was used to reflect online, multiplayer, avatar-based game approaches (see for
example Bell 2008; Nevelsteen 2017), facilitated by platforms such as Second Life,
Open Simulator, and Unity. In these three decades, no consistency or consensus
emerged concerning the terminology used to describe this type of scholarship; some
consistency has only been seen in the association of these terms with the word
reconstruction.

The fallacy of the term ‘reconstruction’ (Taylor 1948; Clark 2010) is ingrained in the
practice of many disciplines. For example, in archaeology under the influence of the
processual school, emphasis was placed on the objectivity of scientific methods, while
in textual editing, according to the American school, particularly within the Bowers/
Tanselle approach, the goal of the edition is to restore the text to the author’s final
intention (Shillingsburg 1999, 29). Reconstruction implies an attempt to bring some-
thing back to its original state based on available evidence as its starting point.
However, such attempts can never be accurate, as they are interpretations of some past
reality or of the documentary evidence, and as such, they reflect present-day social and
cultural agendas.

Much as editing texts for digital publication has made editors aware of the con-
straints of editing for print publication (McGann 1997, 20) coupled with new theoret-
ical approaches which do not favour (re)construction of the text according to what the
editor believes the author would have intended. Equally, the possibility of photorealistic
rendering of 3D heritage opened up new debates as to the purpose and role of 3D
models in the interpretive process (Gillings 2005). Calling what we model a ‘recon-
struction’ which is indistinguishable from real life (as in the case of 3D) or professing to
know what a long-dead author wanted (in terms of textual editing) leave little room to
question the process according to which the ‘reconstruction’ was made, the authenticity
of the new work that has been created, or the reliability or interpretation of the evidence
used in its construction. Therefore, we use the term (re)construction to emphasise the
decision-making process and the non-absolutist approach in the construction of the
model.

Textuality in 3D: three-dimensional (re)constructions as digital scholarly editions 225



3 3D and textual scholarship: a parallel path

Scholars in both textual editing and 3D (re)constructions have faced similar issues in
modelling the textual/material record, and surprisingly, they have employed either the
same or similar terminology in confronting these challenges. This is what we refer to as
‘a parallel path’. These issues concern the use of evidence, ways of making the decision
making process visible, and ways of dealing with ambiguity. In this section we outline
these parallels, which form the key features of the last section, Towards 3D Digital
Scholarly Editions.

3.1 Evidence

Both fields work to reconstruct the text on the basis of existing, albeit imperfect
evidence (if the evidence were perfect, there would be no need for editors or editions).
In both cases, the researcher is evaluating the evidentiary record, and the further we go
back in this record chronologically, the less evidence remains. In many respects, the 3D
(re)constructions of ancient spaces are more akin to the textual editing tradition of
stemmatics applied to premodern texts, in which the editor reconstructs the original text
by working backwards from extant witnesses through a set of relationships expressed
as a tree structure in an effort to come as close as possible to the original text before it
was corrupted (or indeed thought to be improved) through the copying process.

3D (re)constructions of sites that exist in fragmentary form, e.g. a prehistoric
settlement, also go through a process of evaluation of extant data, resolving, discarding,
and harmonising evidence in an effort to understand what might have existed. This can
be likened to an interpretation of secondary sources documenting remains in the form
of textual records/field notes, photographs, and illustrations, site-specific physical
remains, and information coming from other sites which bear some resemblance
(temporal or spatial) to the subject under investigation. The goal in both fields is the
(re)construction of an artefact (be it a poem or an ancient building) which makes clear
to the user where there are gaps in knowledge of the putative original and what methods
and evidence were used in order to fill these gaps.

On the other hand, 3D (re)constructions based on (nearly) complete evidence, e.g.
(re)constructions of a twentieth-century urban battlefield in which old buildings still
stand, share more with traditions and methods used to edit nineteenth-century and
twentieth-century texts. In both cases, there tends to exist an abundance of evidence,
and the researcher adjudicates among extant sources, each of which carries its own
authority. Just as texts can exist in multiple versions, manuscripts, typescripts, and
printings, some or all of which might have been authorised by the writer, bringing back
in 3D a building or a street or what happened in that space at a specific point in time (or
indeed, over time) may utilise a plethora of evidence, including documentary, oral, and
visual. This evidence may be contradictory and fragmentary, and some items of
evidence may be more ‘authorised’ or credible than others.

The theories underlying the textual tradition of versioning in which the goal is not to
establish a definitive or reading text, but to reconstruct, not only a textual history, but
the underlying view of the nature of the text’s production (Tanselle 1995, 24) might
prove a useful foundation for models of 3D (re)constructions in which what is of
interest is the potential to make visible multiple states over time or alternative

226 S. Schreibman, C. Papadopoulos



possibilities in interpretation. These ‘textual’ moments can be viewed as snapshots,
each providing a unique, equally valid window onto the past (Schreibman 1993, 93).
Textual editors have the ability to model these differences in TEI/XML within one
apparatus or framework explicitly to denote regions of both shared and divergent text.
Once these regions are marked, they can be analysed and visualised, providing the
modeller with a method for recording difference over time and the reader with a
standard notation for the decision making process. While TEI/XML is not a suitable
language for 3D, the theoretical framing may well be, as it offers a way to make
variation visible within a single model.

3.2 Ambiguity

The Oxford English Dictionary defines ambiguity as the ‘quality of being open to more
than one interpretation; inexactness’. It is precisely because of the ambiguous nature of
evidence that textual scholarship exists. Revealing, acknowledging, and/or resolving
this ambiguity is part of the interpretive process. In the transition from print to digital
editing of alphanumeric texts, it has become possible to represent ambiguity more
explicitly in a non-notational manner, providing the reader with the documentary
evidence to mediate between different textual states (Schreibman 2002, 288–89). There
have been lengthy discussions concerning the contention that simply providing the
reader with facsimiles of the various witnesses is a form of unediting (Schreibman
2013), i.e. an abdication of the editorial role. On the other hand, modelling the text
according to a theory such as genetic editing or versioning to make visible the writing
process allows readers to formulate their own sense of the work (or work-in-progress)
situated in both time and place (Machan 1994, 303). In other words, the point of this
type of editing is not to resolve the ambiguity of the textual record, but to expose it
through modelling.

Modelling ambiguity has been the subject of much discussion in 3D (re)construc-
tions. While in both fields there exists the subjective nature of gathering, selecting, and
interpreting evidence, with 3D (re)constructions there are less codified ways to express
ambiguity (or indeed to consider whether or not it should be expressed) and to make the
modelling process as transparent as possible (for a recent discussion see Watterson
2015). Representing ambiguity began to become more pressing in the mid-1990s and
especially in the 2000s, as photorealistic models started dominating heritage represen-
tation. This, in turn, fuelled debates about their misleading nature (Miller and Richards
1995; James 1997; Goodrick and Gillings 2000; Eiteljorg 2000) and the problematic
use of the word ‘reconstruction’ (Clark 2010). These concerns gave rise to a series of
proof-of-concept implementations that demonstrated intellectual rigour in 3D models
and explicated decision-making in the process of their creation as a means of
counteracting their problematic photorealistic nature. These implementations included
alternative reconstructions, annotations, renderings in different colours, textures, and
shadings, as well as ways of activating or deactivating ambiguous features and
alternative models that would in turn affect other elements (Kensek 2007).

Unlike the digital scholarly editing practices in which there exists a core set of
technologies and methods (largely around XML/TEI), to a large extent 3D
visualisations utilise bespoke solutions with no sustainable platforms, methodologies,
or standards which might lead to the wider adoption of such practices (see for example:

Textuality in 3D: three-dimensional (re)constructions as digital scholarly editions 227



Archaeology Data Service Guide to Archiving Virtual Reality Projects (2018):
http://guides.archaeologydataservice.ac.uk/g2gp/Vr_6-1; McDonough et al. 2010).
The World Wide Web currently hosts a wide variety of DSEs, some going back to
the earliest digital archives in the mid-1990s, providing the field with a tradition from
which new theories, models, and editions are developed. However, due to their
intensive computational nature, most 3D visualisation projects are developed for
offline use and in a constantly changing environment in which software and
frameworks become obsolete soon after their release. Also, the Internet itself, with
constant changes to browsers, does not offer a stable environment for such projects
(Ruan and McDonough 2009), providing little opportunity to build a body of knowl-
edge and a practice-based community.

3.3 Transparency

As mentioned above, the creation of 3D models under the influence of photorealism
gave birth to a series of debates regarding transparency, documentation of decision-
making, standards, and intellectual rigour in the process of (re)construction. Earlier,
more schematic work did not carry with it the same calls for transparency, as it did not,
however unintentionally, ‘trick’ the viewer into reading reality into the (re)construction.
Several projects attempted to establish principles to address this new environment. The
best-known is the London Charter (Denard 2009; http://www.londoncharter.org/),
developed in 2006 at a meeting of 3D visualisation specialists who came up with a
series of principles that would ensure a certain level of standardisation in terms of the
creation of documentation, ensuring sustainability and access and articulating the aims
and methods of (re)creation (Denard 2012). For example, principle 4.6, ‘Documenta-
tion of Process (Paradata); states that:

Documentation of the evaluative, analytical, deductive, interpretative and creative
decisions made in the course of computer-based visualisation should be dissem-
inated in such a way that the relationship between research sources, implicit
knowledge, explicit reasoning, and visualisation-based outcomes can be under-
stood (Denard 2009, 8-9).

While a worthy goal, it is impossible not only to document, but, as was found in editing
according to the Greg/Bowers (Bowers 1978) school of copy-text, even to represent
each and every editorial decision and the rationale for that decision. This would amount
to providing a textual record of not only how each accidental (e.g. punctuation,
spelling, word division which was considered less significant and meaning-making
than substantives, e.g. word choice) was handled, but why it was handled that way. In
both traditions, this goal becomes even more unobtainable, as it would involve a full
time amanuenses following the researcher (or team of researchers), recording every
conversation, saving every version of every document, every state of every electronic
file. Even if it were possible to save all this, how could it be presented to the reader so
as to make more transparent the decision-making process? This might be more akin to
an archive or an assemblage, but even if this could be ordered and catalogued, what it
does not necessarily demonstrate is what happens in the space between the evidence,

228 S. Schreibman, C. Papadopoulos

http://guides.archaeologydataservice.ac.uk/g2gp/Vr_6-1
http://www.londoncharter.org/


the ideas that inform the decision-making process, tracing a path from evidence to its
representation.

Despite the fact that several reports and frameworks followed The London Charter,2

none of them tackled the inherent visual illiteracy in reading photorealistic 3D
visualisations as texts. There is no scaffolding within which the 3D model is situated
to provide the reader with access to its conceptual and methodological underpinnings.

4 Towards 3D scholarly editions

We have argued that Digital Scholarly Editions act as mediators and gatherings of
evidence (Gabler 2010, 44), textual, social, and historical, that is read in an increasingly
multimodal infrastructure. As knowledge sites, they encompass within the same com-
putational paradigm both the primary text and the evidence that informed the decisions
in creating the text, thus providing the community which it serves a tool for ‘prying
problems apart and opening up a new space for the extension of learning’ (Apollon
et al. 2014, 5–6). This framework provides the information structures and evidence that
make up the edition so that the audience can understand the process behind the creation
of the edition and adjudicate its authenticity and reliability.

Hence we believe that there exists a case and a rationale for designing a blueprint to
link editorial, epistemological, and technical practices in the development of editions of
3D (re)constructions as scholarship in its own right, as assessable assemblages to
combat the problem of the vacuous nature of most models: empty sites where the
research that went into their creation remains invisible to those outside project teams.
While photorealistic models are ever more beautiful to behold, if their raison d’être is
not to serve as works of art, but as mediators of evidence, the ways in which the chain
of production that informed their creation needs to be made visible in the same
information space as the models. We are not advocating that a DSE of a 3D
(re)construction be thought of as a defined object, but rather as a methodological field
in which a set of codes imposes a prefiguring frame on the reality being created, and not
only the technological codes that govern the creation of this reality, but also the social,
theoretical, and historical codes that its makers adopt in its creation (Barthes 1977).

The construction of such an edition entails building an intertextual network com-
posed of the 3D model along with its accompanying annotation and apparatus, thus
providing a base from which the reader can actively engage in the knowledge creation
process. This approach is being taken in the redevelopment of the Contested Memories:
The Battle of Mount Street Bridge (BMSB) project, a spatiotemporal (re)construction
of one of the most important battles during the 1916 Easter Rising between a small

2 Pletinckx (2007) and the Network of Excellence, Epoch developed the Interpretation Management
KnowHow booklet, which explained different methods, including source assessment and correlation, hypoth-
eses trees, and updating, to ensure scholarly transparency in 3D visualisation. This information and the
comments, decisions, and interpretive processes comprise the paradata of the project (Baker 2012, 163–176),
which allows a clearer interpretation management and understanding of the relationships between primary data
and the outcome. More recently, The Seville Principles (Lopez-Menchero and Grande 2011) used the London
Charter as a theoretical framework to develop a series of principles to increase the applicability of the latter to
3D visualisations of archaeological heritage. Other works have also elaborated on how scientific reasoning can
become visible (Hermon 2012; Niccolucci 2012).

Textuality in 3D: three-dimensional (re)constructions as digital scholarly editions 229



group of Irish Volunteers (17) and a much larger force (1750) of British soldiers
(https://mountstreet1916.ie/ Papadopoulos and Schreibman in press).The apparatus
being explored includes a narrative-driven camera with a voice over providing an
evidence-informed interpretation of how the battle unfolded; audio files that replicate
the types of sounds that accompanied the battle; and a user interface to display in-world
textual annotations about the combatants and other participants (such as the medical
personnel), key buildings and events, the types and makes of guns used, and the
sources for the (re)construction (from the methods used to the primary sources
consulted; see Fig. 1 for a mock up). The project has also experimented (see Fig. 2)
with animated agents to help the reader better visualise troop movements as the battle
unfolded.

Fig. 1 The new user interface of the standalone Unity 3D environment includes an annotation panel that
provides contextual information (text and/or multimedia) activated by hotspots, as well as a timeline for
exploring the battle temporally.

Fig. 2 A total of 252 AI agents (36 for each of the seven companies of British soldiers) have been included in
a WebGL version of the 3D model

230 S. Schreibman, C. Papadopoulos

https://mountstreet1916.ie/


Embedding the iconography of 3D (re)constructions into what we might broadly
describe as scholarly editing practice, opens up new vistas for scholarship and the
communication of the results of that scholarship within spatio-temporal environments
that are immersive and multisensorial. If the goal of the modelled dataset is to create its
own ecosystem to provoke and encourage evolving thought about the materials,
aesthetics, and cultures it simulates (Schreibman 2013), then the scholarly editing
framework we have outlined here, we believe, fulfils that goal.

The real difference between the two domains is not the technologies utilised in
digital production, but the fact that textual editors have a long history of models,
theories, and paradigms of the documentation and display of text and paratext (as well
as models, theories, and paradigms for the fashioning of arguments), and 3D
(re)constructions do not. This article presents a rationale for the development of such
as framework.

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	Textuality in 3D: three-dimensional (re)constructions as digital scholarly editions
	Abstract
	Introduction
	Modelling in 3D: an introduction
	3D and textual scholarship: a parallel path
	Evidence
	Ambiguity
	Transparency

	Towards 3D scholarly editions
	References