Navigation – Plan du site

AccueilNuméros135Dossier: Analyse des réseaux soci...On Connecting Stamps – Network An...

Dossier: Analyse des réseaux sociaux en archéologie

On Connecting Stamps – Network Analysis and Epigraphy

Shawn Graham
p. 39-44


L’analyse des réseaux, qui est à la fois une méthode et une théorie, vise à explorer les relations inhérentes aux données archéologiques. Dans cet article, je m'intéresse aux sources épigraphiques qui sont porteuses de liens sociaux manifestes et qui permettent, si on les envisage du point de vue archéologique, de discerner de nouvelles relations. J'en donne l'exemple à travers deux courtes études de cas traitant de briques romaines estampillées découvertes dans la vallée du Tibre. L'analyse des réseaux ne cherche pas à prouver une théorie particulière à partir de ces données mais à les considérer d'une nouvelle manière pour produire de nouvelles connaissances. Quand d'autres ensembles, archéologiques plutôt qu'épigraphiques, seront étudiés, elle intègrera sans mal la boîte à outils de l'archéologue.

Haut de page

Entrées d’index

Index de mots-clés :

briques estampillées, épigraphie

Index by keyword:

epigraphy, Italy, stamped bricks

Index géographique :

Haut de page

Texte intégral


1Network analysis in archaeology is a growing method for rigorously examining the interplay of relationships across space and time, within a formal theoretical framework (Brughmans 2010, 2012, 2013). Most archaeological network analyses operate on local or regional scales, creating nodes from sites and links (or edges) based on some measure of similarity of artefact assemblages (as for instance Mills et al. 2013). Alternatively, some archaeological network analyses draw the connections between sites based on measures of geographic proximity, as in for instance proximal point analysis (e.g. Collar 2013; Blake 2013). In this paper, I suggest that one of the richest skeins to unpick for network analysis in archaeology should naturally be that branch of archaeology wherein social relationships are at their most clear: epigraphy. Epigraphic materials, especially in the Roman world, are dense with multi-dimensional data that can be examined through space and time. A network analysis framework is one way of visualizing and analyzing those patterns. I first demonstrate how one could begin to reconstruct some aspects of social experience from the dominiusofficinator relationships recorded in Roman stamped bricks. I then explore another aspect of the multi-dimensionality of stamped bricks through a consideration of the relationship of the figurative devices, the signa, to the texts of the stamps, to explore something of the logistics of the industry.

2Neither brief case study is meant to be exhaustive or definitive; rather my purpose is to illustrate what can be achieved quite quickly by network analysis on what ought to be low-hanging fruit for archaeological network analysis, and to encourage other scholars to begin to explore the method.

Named individuals in stamped bricks

3Stamps on bricks in the city of Rome and its hinterland are, especially by the second century, extremely dense with information. There can often be an indication of the brick maker, the land owner, the estate, and the year. There are a range of standard shapes and internal arrangement of the epigraphic data (semi-circular or circular shape, with a small or large orbiculus on the edge of the stamp, with text in one, two, or three rows). There can often be a figurative device (the signum) in the centre. Consider also the physicality of the brick itself. Its fabric may be studied for provenance. The findspot of the brick may be compared with the findspots of other bricks carrying the same stamp, or having been made from the same clay source. All of these elements can be combined into a network where a single node exists in a multiplicity of dimensions – networks of exploitation, of production, of power, of construction (Graham 2006). While it is computationally possible to deal with such multigraphs, it may be more tractable and comprehensible to deal with one dimension of the information present in stamped bricks at a time (cf. Weingart 2011).

4Let us begin by considering the relationship between domini and officinatores. Steinby (1974), Helen (1975), and Setälä (1977) used this relationship to work out the organization, evolution, and prosopography of the brick industry. The tools did not exist at that point however to analyze the resulting connections on formal network grounds. They were however able to point to the obvious importance of figures such as Domitia Lucilla, or C. Fulvius Plautianus by the simple fact that these names occurred over and over again. What might we also see if we revisit this data through a formal network lens?

5Getting started is simplicity itself. One simply lists pairs of individuals on a spreadsheet as one encounters them in a catalogue (as for instance, in the CIL). One can even consider the directionality of this relationship, that is, the power imbalance. The relationship officinator – dominus is not one between equals. The network analysis programme Gephi (Bastian et al. 2009) can import such a list by labeling the first column ‘source’ and the second column ‘target’. We might then list every pair of individuals so that the dominus is listed in the first column, and the officinator in the second. Other columns or attributes could be listed, such as dates, estate information, or any of the other multiple dimensions of data described above. It is important to note however that these attributes are not nodes in themselves (and thus avoiding the problems created by multigraphs).

6There is a problem, however. Do we imagine that officinatores and domini are the same kind of node? If we do (they are both humans, for instance) then we can proceed with the analysis since Gephi and most other network analysis programmes run various statistics under the assumption that we are computing them for a one-mode network (ie, relationships tying one kind of thing together). If, however, we think that officinatores and domini really are two different kinds of things, then we have to transform this two-mode network into two separate one-mode networks. Otherwise the resulting metrics are entirely misleading. The key to unraveling this conundrum lies in our research question. If we are interested in the connections among the land-owning elites in the hinterland of Rome, and how they manage their land resources (as evidenced by ceramic building materials), then we really perhaps ought to look at a one-mode network of domini connected to other domini by virtue of the officinatores who worked for both. That is, we turn the officinatores into the ties that bind.

7Conversely, if our research question is centred on the social world of the officinatores, we might wish to have a network of officinatores tied to other officinatores by virtue of exploiting the clay of the same domini. Making this transformation by hand is extremely tedious and prone to error; fortunately, Gephi has a plugin (the ‘multimode transformation’) that can do this quite quickly.

8The visualization of this network of domini to domini via shared officinatores (drawn from Setälä 1977) is not, in itself, of much analytic use. We can however recast it to visualize also various kinds of metrics. We could search for sub-groups within this network. We could ask, which domini are in a position to influence the industry by virtue of their connections? This is a question of centrality. Is Domitia Lucilla as important as other scholars have long surmised? We could then arrange the network so that the nodes are scaled in size according to a centrality metric (in this case, PageRank, as it ranks nodes based on how often a user will reach that node following the links. Clearly, this is the language of the internet, but here it translates into the language of power). The PageRank metric agrees that Domitia Lucilla is indeed the most central individual. What about subgroups? Gephi can compute modularity, or the degree to which nodes have similar (though not identical) patterns of connections. The network could then be re-coloured to show subgroups. Now the visualization is becoming more useful.

9We can do one final transformation to make the relative positioning of the nodes on the page carry information concerning the overall structure of the network. We can lay out the network so that nodes are arranged in concentric steps or orbits from some central node. Let us put Domitia Lucilla in the centre, and every dominus who is one step away in the first orbit. Every dominus who is two steps can be arranged in the next circle, and so on until we come to the furthest domini away. This layout where graph-distance or number of steps are arranged in progressive orbits, allows us to quite quickly see the social world of Domitia Lucilla, Figure 1. One could then re-visualize to the social world of this industry from others’ perspectives. In Figure 2 the network is from the perspective of L Publilius Celsus (consul under Trajan). The action, so to speak, is about four steps removed from him. Can we read in this distance some of the factors in his eventual downfall under Hadrian? That is perhaps a step too far, but the idea is seductive.

10Far more complicated and sophisticated analyses could be done. One could generate random networks with the same number of nodes and proportions of ties, to act as a kind of null hypothesis. In what ways does the observed network differ from the random network? Or one could generate small-world networks (which are assumed to have particular social implications) to ask, to what degree does the observed network resemble the small world? Or one could look for holes in the network, patterns of non-connections, and compare those against the observed or generated networks. One could use the network as a substrate for modeling various kinds of social interaction in an agent-based simulation (Graham 2009). It all begins though with listing relationships.

Fig. 1

Fig. 1

Network of domini to domini via shared officinatores. Concentric-circle layout based on link distance from Domitia Lucilla. Node size is scaled to reflect pageRank centrality scores. Nodes and edges are coloured according to modularity (subgroupings)

Fig. 2

Fig. 2

Network of domini to domini via shared officinatores. Concentric-circle layout based on link distance from L Publilius Celsus. Node size is scaled to reflect pageRank centrality scores. Nodes and edges are colouredaccording to modularity (subgroupings).

Networking the language of stamps

11We can begin to examine more abstract relationships in our material, for instance, to consider the relationship in stamped brick between the text of the brick (the indication of figlinae or the property from which the brick was made) and the signa that often appear in association with it. The data used in this section comes with a caveat: the database from which it draws is problematic and incomplete (see below; Graham 2012), but this brief consideration (or proof-of-concept, if you will) represents an example of what a more rigorous and thorough examination might accomplish.

12Understanding the organization of the Roman brick industry outside of Rome has long relied on making connections between various stamps on the basis of shared language, or shared signa. The obvious connection for example between ‘Rutilius Lupus’ and the signum of his brick stamps—the wolf—make that a logical inference. That said, certain of the signa do not seem to fit into this pattern. The pine nut for instance appears on stamps from a wide variety of figlinae and domini (Graham 2006: 14). Portus Licini stamps all carry the same text, but with different signa. Elsewhere I have mused on the possibility of signa being tied into the exigencies of the infrastructure along the Tiber for loading and unloading bricks (Graham 2005). Navigation within the Roman city used among other things the symbols emblazoned on fountains, or major landmarks. Mocchegiani Carpano (1984: 39) argued for docks on the Tiber being reserved for the trade in specific goods, while Steinby argued for specific warehouses for brick (Steinby 1974: 74). Contracts for the specific warehousing of goods in particular spaces are known (Rickman 1980: 236-8). I have argued in the past, by analogy to the docks of Georgian and Victorian London, that the owners of warehouses might also have owned the specific docks where the goods were unloaded. The docks could also have been tied to the warehouse owners through bonds of patronage (Graham 2006: 82). In Rome there exists the ‘Tor di Nona’, a breakwater along the Tiber some 96m long with a temple to Hercules on its end (Quilici 1986: 202). Hercules appears as a signum in brick stamps CIL XV.1 156, 214-6, 241, 324-5, 686, 715, 768, 772, 1247, 1497 Figlinae: Domitianae, Favorianae, Genianae, Marcianae, Voconianae.

13As a graduate student, I copied out the transcription for every stamped brick listed in the CIL XV.1. It was a rough-and-ready copy, meant to help me with a question concerning the numbers of stamped bricks recorded. While not without errors, there might be enough data within that copy that could enable us to look at the patterns of figlinae and their use of signa. I imported this data into Gephi as a two-mode network, where there are two kinds of nodes, the figlina and the signa, connected when they both appear in the same stamp. Clearly this is a messy process, as the compilers of the CIL sometimes were not entirely sure what the signum might mean. Is it a dog? Is it a wolf? I cleaned this table up by merging such cases together. Within Gephi I recast this two mode table into two one-mode tables, where the nodes are either figlinae or signa, thus a network graph of figlinae tied to other figlinae by virtue of shared signa, and a network graph of signa tied to other signa by virtue of appearing in stamps marked with the same figlinae.

14Once we have done this, we can begin to ask the computer to identify groups of nodes that fall into ‘natural’ communities, based on the similarity of the pattern of their connections (using Gephi’s community detection algorithm, ‘modularity’). We can re-colour the graph to show these communities and their interconnections, and filter the network so that we only show one community at a time. Moreover, we can also ask Gephi to identify those nodes that are important in terms of their connectivity. Which particular metric we use depends on what we imagine to ‘flow’ over these connections. I have argued before that networks derived from brick stamp data represent fossilized flows of power and patronage (Graham 2006). If we accept that argument, then one metric worth calculating might be ‘PageRank’, which we can imagine as the likelihood that someone who ‘reads’ the stamp would be able to quickly follow the thread back to a central figlina.

15We can begin to analyze this network of figlinae connected by use of common signa (476 stamp types tied by 47 816 edges). Looking for communities, I find 18 communities, where the top five capture 94% of the nodes. I visualize this network using Gephi’s radial layout, which orders groups of nodes along spars of a wheel to show both the internal structure of the group and the group’s ties to other groups. The sequence along the spar is determined by each node’s individual PageRank. If we look at the nodes with highest PageRank in the largest group, we find some familiar names: domitianae veteres; domitianae; favorianae; ab isis; domitianae maiores; viccianae; septimianae; oceanae maiores. Hercules is a signum in many of the stamps of these figlinae, but not all of them. If signa were either heraldic devices or tied to transport exigencies, we would expect to find much tighter groupings (i.e., we would perhaps expect to find a group tied solely together via the Hercules signum).

16While family connections or the evolution of figlinae over time (domitianae maiores and veteres split from the main domitianae, for instance) was not explicitly incorporated in the data for this network, that patterning still emerges viewed through this lens. Oceanae Maiores and Oceanae Minores presumably are remnants of an earlier single contiguous unit of land; they appear here in different groupings (and the minores is strongly tied to caninianae). In this instance, the signa are functioning not as heraldic devices but perhaps are tied to the transport and infrastructure idea mooted above. The situation is complex, but a network visualization allows us to start teasing apart the different strands.

17What is perhaps more interesting is the ways these subgroups (modules; communities) interconnect across groupings. The edges connecting the nodes have weight, which was extracted from the original two-mode network. If terentianae is connected to caepionianae via the shared use of three different signum, then when the two mode figlinae to signa network is transformed into figlinae tied to other figlinae via shared signa, that number of instances is transferred to a single instance as its weight: 3. If we then filter that network so only the strongest connections are shown, we get a sense of not just the internal connections within the groups, but also across groups. Figure 3 visualizes figlinae to figlinae by common signa filtered to show ties with a weight of 2 or more.

18It becomes evident at this point that our largest group (the domitianae veteres group) forms a group not so much out of internal cohesion but through patterns of ties to the other groups. That is, it is a group precisely because of its internal disunity but external cohesion. On the contrary view, the group headed by the figlinae terentianae seems to have much greater internal cohesion as each figlinae ties tightly to the others within the same group, and lesser external cohesion. DeLaine (1997: 90-1) argued that the figlinae ponticulanae was tied to a locality along the Farfa river near Castello Tribucum, and that this area was a locality for domitianae maiores, bucconianae, oceanae, and genianae as well. One of the smaller groups in our network graph is composed of genianae, dom min, ponticulanae, and publilianae. It is important to note that the figlinae that obviously ‘go’ together, like the various parts of the domitianae, still are connected to each other in this graph; it is just that the overall patterning of connections is sufficient that they can be partitioned into different groups. Considering the nature of the different groups may help tease apart the question of what, precisely, signa do in stamps.

Fig. 3

Fig. 3

Detail of network of figlinae connected by use of common signa, filtered to show only ties of weight 2 or above.Forced-atlas layout.Node size is scaled to reflect pageRank centrality scores. Nodes and edges are coloured according to modularity (subgroupings).

19We can take the inverse of this network, and look at the signa themselves as nodes (and where the connections between them are appearance in stamps of the same figlinae). When modularity is computed, I find four groups that account for 63 of the 72 signa appearing in the graph. Hercules appears in a group with ‘equus’, ‘capricorn’, ‘minerva’, ‘castores’. Since these signa are connected by similar patterns of appearing with various figlinae, can we assume that this particular grouping would have made sense to the Roman worker who saw them? Might we see in this assemblage of icons a reference to the Circus Flaminius with its adjacent temples to Hercules, Minerva, and the Dioscuri (Petruccioli 2013, entry 37)?

20There are clear problems with the data that are used in this current exploration, the most obvious being that the source database is not rigorous enough in its categorizations. Ideally, one would create a list with the following headings: unique stamp id; officinator; dominus; praedia; figlina; signum; consular date; shape. The data entered into this list would be what was explicitly written on the stamp rather than our suppositions that, for instance, signa of type abc always indicate figlinae xyz. Then, one could generate networks using any permutation of those data. A two-mode network of officinatores to domini could be transformed into a one-mode network of domini to other domini by virtue of the individuals who moved around between figlinae (and servile/freed status) over time. What this brief foray into a network visualization of the relationship between signa and text on the stamps is meant to do is to demonstrate the possibilities of this kind of approach for the study of stamped brick, and epigraphy more generally.

Moving forward

21The hardest part about analyzing epigraphic materials in the Roman world from a network analysis perspective is making our catalogues and databases available in formats that allow easy import or export into the various analytical packages that exist. Recent initiatives such as the ‘Linked Ancient World Data Institute’ which focuses on creating ‘digital resources that emphasizes connections between diverse information on the basis of published and stable web addresses (URIs) that identify common concepts and individual items’ [​Linked_Ancient_World_Data_Institute], are to be applauded, as these will open more of our data to the kind of analyses envisioned here. In this way, network analysis would become not just a means of understanding the past, but also for organizing our knowledge of it in the present.

22Bastian M., Heymann S. & Jacomy M. 2009. ‘Gephi: An open source software for exploring and manipulating networks’. Third International AAAI Conference on Weblogs and Social Media (ICWSM 2009), San Jose, Ca. 2009 [​ocs/​index.php/​ICWSM/​09/​paper/​view/​154 and].

23Blake E. 2013. ‘Social networks, path dependence, and the rise of ethnic groups in pre-Roman Italy’, in C. Knappett (ed.), Network Analysis in Archaeology. New Approaches to Regional Interaction. Oxford, Oxford University Press: 203-222.

24Brughmans T. 2010. ‘Connecting the dots: towards archaeological network analysis’, Oxford Journal of Archaeology, 29, 3: 277-303.

25Brughmans T. 2012. ‘Thinking through networks: a review of formal network methods in archaeology’, Journal of Archaeological Method and Theory, 19, 2: doi:10.1007/s10816-012-9133-8.

26Brughmans T. 2013. ‘Networks of networks: a citation network analysis of the adoption, use, and adaptation of formal network techniques in archaeology’, LLC. The Journal of Digital Scholarship in the Humanities,28, 4: 538-562.

27Collar A. 2013. ‘Re-thinking Jewish ethnicity through social network analysis’, in C. Knappett (ed.), Network Analysis in Archaeology. New Approaches to Regional Interaction. Oxford, Oxford University Press: 223-246.

28DeLaine J. 1997. The Baths of Caracalla: A Study in the Design, Construction, and Economics of Large-Scale Building Projects in Imperial Rome. Portsmouth, Rhode Island (Journal of Roman Archaeology Supplementary Series, 25).

29Graham S. 2005. ‘Of lumberjacks and brick stamps: working with the Tiber as infrastructure’, in A. MacMahon & J. Price (eds), Roman Urban Living. Oxford, Oxbow: 106-124.

30Graham S. 2006. Ex Figlinis: The Network Dynamics of the Tiber Valley Brick Industry in the Hinterland of Rome. Oxford, John Hedges (BAR International Series, 1468).

31Graham S. 2009. ‘Behaviour space: Simulating Roman social life and civil violence’, Digital Studies / Le Champ Numérique, 1, 2. [​ojs/​index.php/​digital_studies/​article/​view/​172/​214. Accessed 18 September 2013].

32Graham S. 2012. CIL XV.1 ‘Instrumentum Domesticum (a working copy).’ figshare. [​10.6084/​m9.figshare.92031] Accessed Nov 20 2013.

33Helen T. 1975. ‘Organization of Roman brick production in the first and second centuries AD – an interpretation of Roman brick stamps’, Annales Academiae Scientiarum Fennicae – Dissertationes Humanarum Litterarum 5. Helsinki, Suomalainen Tiedeakatemia.

34Mills B., Roberts J.M. Jr., Clark J., Haas W.R. Jr., Huntley D., Peeples M., Borck L., Ryan S.C., Trowbridge M. & Breiger R.L. 2013. ‘The dynamics of social networks in the Late Prehispanic US Southwest’, in C. Knappett (ed.), Network Analysis in Archaeology. New Approaches to Regional Interaction. Oxford, Oxford University Press: 181-202.

35Mocchegiani Carpano C. 1984. ‘Il Tevere, archeologia e commercio’, Bollettino di Numismatica, 2-3: 21-83.

36Petruccioli G. 2013. ‘37. Circus Flaminius. Digital Augustan Rome. [​map/​#/​rome/​filter:0/​records/​read/​ 4b498a26-02b2-a65b-ceda-5adc557d86bd/] Accessed November 30 2013.

37Quilici L. 1986. ‘Il Tevere e l’aniene come vie d’acqua a monte di Roma in età imperial’, Archeologia laziale, 7, 2: 198-217.

38Rickman G. 1980. The Corn Supply of Ancient Rome. Oxford, Clarendon Press.

39Setälä P. 1977. ‘Private domini in Roman brick stamps of the empire: a historical and prosopographical study of landowners in the district of Rome’, Annales Academiae Scientiarum Fennicae – Dissertationes Humanarum Litterarum 10. Helsinki, Suomalainen Tiedeakatemia.

40Steinby E.M. 1974. ‘La cronologia della ‘figlinae’ doliari urbane dalla fine dell’età repubblicana fino all’inizio dell III secolo’, Bullettino della Commissione Archeologica Comunale di Roma,84: 7-132.

41Weingart S. 2011. ‘Demystifying networks, parts I & II’, Journal of Digital Humanities 1, 1 [​1-1/​demystifying-networks-by-scott-weingart/​] Accessed November 20 2013.

Haut de page

Table des illustrations

Titre Fig. 1
Légende Network of domini to domini via shared officinatores. Concentric-circle layout based on link distance from Domitia Lucilla. Node size is scaled to reflect pageRank centrality scores. Nodes and edges are coloured according to modularity (subgroupings)
Fichier image/jpeg, 156k
Titre Fig. 2
Légende Network of domini to domini via shared officinatores. Concentric-circle layout based on link distance from L Publilius Celsus. Node size is scaled to reflect pageRank centrality scores. Nodes and edges are colouredaccording to modularity (subgroupings).
Fichier image/jpeg, 348k
Titre Fig. 3
Légende Detail of network of figlinae connected by use of common signa, filtered to show only ties of weight 2 or above.Forced-atlas layout.Node size is scaled to reflect pageRank centrality scores. Nodes and edges are coloured according to modularity (subgroupings).
Fichier image/jpeg, 164k
Haut de page

Pour citer cet article

Référence papier

Shawn Graham, « On Connecting Stamps – Network Analysis and Epigraphy »Les nouvelles de l'archéologie, 135 | 2014, 39-44.

Référence électronique

Shawn Graham, « On Connecting Stamps – Network Analysis and Epigraphy »Les nouvelles de l'archéologie [En ligne], 135 | 2014, mis en ligne le 01 janvier 2016, consulté le 17 juin 2024. URL : ; DOI :

Haut de page


Shawn Graham

Carleton University, Ottawa, Ontario, Canada,

Haut de page

Droits d’auteur

Le texte et les autres éléments (illustrations, fichiers annexes importés), sont « Tous droits réservés », sauf mention contraire.

Haut de page
Rechercher dans OpenEdition Search

Vous allez être redirigé vers OpenEdition Search