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Itiner-e: A high-resolution dataset of roads of the Roman Empire
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  * Published: 06 November 2025

Itiner-e: A high-resolution dataset of roads of the Roman Empire

  * Pau de Soto  ORCID: orcid.org/0000-0002-7068-786X^1^ na1,
  * Adam Pazout  ORCID: orcid.org/0000-0001-7745-5634^2^ na1,
  * Tom Brughmans  ORCID: orcid.org/0000-0002-1589-7768^2^ na1,
  * Peter Bjerregaard Vahlstrup^3,
  * Alvaro Auir^4,
  * Toon Bongers  ORCID: orcid.org/0000-0002-4249-5086^5,
  * Jens Emil Bodstrup Christoffersen^6,
  * Mael Crepy  ORCID: orcid.org/0000-0002-9901-1820^7,
  * Mathias Holland Johansen  ORCID: orcid.org/0009-0008-9361-6838^8,
  * Joseph Lewis  ORCID: orcid.org/0000-0002-0477-1756^9,
  * Louis Maniere  ORCID: orcid.org/0000-0003-0426-2975^7,
  * Michele Ruzgar Massa  ORCID: orcid.org/0000-0003-4992-9016^10,
  * Louise Matilde Harreby Moller  ORCID: orcid.org/
    0009-0005-8048-5072^6,
  * Berangere Redon  ORCID: orcid.org/0000-0003-4834-0269^7,
  * Giuseppina Renda  ORCID: orcid.org/0009-0001-5045-5236^11,
  * Hamdi Sahin  ORCID: orcid.org/0000-0002-2812-4246^12,
  * Adela Sobotkova  ORCID: orcid.org/0000-0002-4541-3963^13,
  * Amanda Leighton Spatzek^6,
  * Philip Verhagen  ORCID: orcid.org/0000-0001-8166-122X^14 &
  * ...
  * Barbora Weissova^15 

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Scientific Data volume 12, Article number: 1731 (2025) Cite this
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  * Archaeology
  * History

Abstract

The Roman Empire's road system was critical for structuring the
movement of people, goods and ideas, and sustaining imperial control.
Yet, it remains incompletely mapped and poorly integrated across
sources despite centuries of research. We present Itiner-e, the most
detailed and comprehensive open digital dataset of roads in the
entire Roman Empire. It was created by identifying roads from
archaeological and historical sources, locating them using modern and
historical topographic maps and remote sensing, and digitising them
with road segment-level metadata and certainty categories. The
dataset nearly doubles the known length of Roman roads through
increased coverage and spatial precision, and reveals that the
location of only 2.737% are known with certainty. This resource is
transformative for understanding how mobility shaped connectivity,
administration, and even disease transmission in the ancient world,
and for studies of the millennia-long development of terrestrial
mobility in the region.

Background & Summary

The study of roads of the Roman Empire is a centuries-old pursuit^1,2
. There is a wealth of information about roads that were physically
identified in archaeological excavations and surveys, about
milestones which were placed at regular intervals along Roman roads,
and historical sources like the Antonine Itinerary^3,4 or the Tabula
Peutingeriana^5, describing major connections between settlements, as
well as detailed regional summaries on Roman roads^6,7. However,
finding and locating this diversity of research and the spatially
precise locations of the roads themselves is inhibited by a lack of
an Empire-wide synthesis and digitisation.

There have previously been very few other open digital
representations of our knowledge of roads over the entire Roman
Empire. The Barrington Atlas of the Greek and Roman World^8 is the
main reference atlas for the ancient world, and the roads recorded in
it are openly digitally available from the Ancient World Mapping
Center (https://awmc.unc.edu) and Mapping Past Societies (formerly
the Digital Atlas of Roman and Medieval Civilizations, https://
darmc.harvard.edu/). These two digitisations are highly similar and
differ only in a few areas where the latter also includes roads from
the Tabula Imperii Byzantini for Greece and Asia Minor^9,10,11,12,13,
14,15,16. They have proven invaluable resources for spatially
explicit computational studies of ancient trade and mobility, and as
references for the overall structure of the Roman transport system^17
,18. However, both are of limited spatial detail as they reflect the
spatial resolution of the Barrington Atlas (ranging from 1:500,000 to
1:1,000,000), which results in disregarding natural corridors and
barriers. Moreover, the sources used to create the roads included in
the Barrington Atlas are only available as a short list of references
for all information in an atlas map sheet, and not on a road-by-road
basis. The sources and methods used to include roads in the
Barrington Atlas and trace their particular paths are not documented,
and a quantitative assessment of how representative and reliable this
resource is is not possible.

Itiner-e (dataset: https://doi.org/10.5281/zenodo.17122148, online
platform: https://itiner-e.org/) addresses this gap in resources for
studying the ancient world. It presents an open, spatially high
resolution digitisation of Roman roads, drawing on published
historical and archaeological information, topographic maps, and
remote sensing data, citing the sources used to create each road
segment, and making each road segment uniquely citable through a URI
(Uniform Resource Identifier) that is linked to URIs of nearby
ancient places in the Pleiades gazetteer of ancient places (http://
pleiades.stoa.org/). Itiner-e covers the area of the Roman Empire at
its maximum extent, ca. 150 CE, and includes any terrestrial route
with an evidenced, conjectured, or hypothesised location in the
sources used for the study. This includes any road predating Roman
conquest that continued to be in use during Roman times.

The resulting map includes, in total, 299,171.31 km of roads in an
area of nearly 4,000,000 km^2, which is nearly double the length of
other resources (the Digital Atlas of Roman and Medieval
Civilizations road dataset is 188,555 km). This increase is due to a
higher coverage of roads (Figs. 1b, 2a; e.g., the Iberian Peninsula,
Greece, North Africa), but also by the decision to make a spatially
explicit dataset that adapts routes to the geographical reality
(i.e., to cross a mountain, our roads follow a winding pass rather
than a direct line), resulting in a higher number of vertices for the
road lines and higher total length (Figs. 1c; 2b). The dataset
includes 14,769 road segments and consists of 14 connected
components, reflecting the contiguous landmasses (including
continental Europe, Britain, Asia-North Africa, and various
Mediterranean islands). The core of the Roman terrestrial transport
network were those roads classified as main roads (see Main/Secondary
Roads) documented via milestones or historical sources. Our dataset
reveals these covered 103,477.9 km (34.58%), and this number is
unlikely to increase significantly, since these are the most
documented and studied Roman roads. The dataset enables studies of
how these main roads structured and enabled phenomena including Roman
conquest and administration. Our dataset further includes
195,693.3 km (65.42%) of secondary roads which can be studied to
understand the structure of more local mobility, and future data
collection focusing on understudied areas could significantly
increase this number. The dataset reveals for the first time that
only 2.737% of the spatial location of the total road length is
certain, whilst 89.818% is conjectured and 7.445% hypothesised (see
Certainty categories). This shows a discrepancy between our knowledge
of the existence and location of Roman roads: we know all of the
included roads were used at some point during the Roman period, but
their precise locations are not certain. Our confidence maps (see
Technical validation) visualise this uncertainty and elaborate on it
by expressing differences across the dataset in road density, spatial
accuracy of road digitisation, and source reliability.

Fig. 1
figure 1

(a) The Itiner-e road dataset, and two comparisons with the DARMC
dataset: (b) difference in coverage, and (c) difference in spatial
resolution as expressed by the number of vertices contained in the
datasets. Itiner-e increases the coverage in selected areas
throughout the Empire, most notably in the Iberian Peninsula, the
Aegean and Egypt, and increases spatial detail throughout with a few
exceptions marked in blue in c).

Full size image
Fig. 2
figure 2

Comparison of DARMC (in orange) and Itiner-e (in black) datasets, (a)
showing an example from France of a region with increased coverage of
roads, and (b) an example of increased spatial detail.

Full size image

A major challenge is the absence of chronological evidence of the
creation and change of roads, that is comparable at an Empire-wide
scale. This means the current dataset cannot show the growth and
change over time of Roman roads and the degree to which they built on
and reused previously existing roads. Historical and archaeological
sources teach us that transport networks grow organically, new roads
are constructed on top of old ones, they change function and physical
characteristics, and become disused. Detailed temporal evidence for
road construction, use and change is only available for a handful of
cases, making an evidence-based reconstruction of how the road system
changed throughout the Roman period at an Empire-wide scale currently
impossible. This should be the subject of dedicated large-scale
efforts in future research.

Itiner-e makes such gaps in our current knowledge of Roman roads
explicit for the first time, allowing this information to inform
robustness tests and uncertainty quantifications of future studies,
and specifying how and where future data collection efforts can
improve our knowledge.

Methods

Road digitisation followed three steps (Fig. 3), with regional
variation depending on the availability of sources and intensity of
research activity, as well as collaborators (see Regional overviews):
(1) identifying roads through relevant literature, historical and
archaeological sources, gazetteers and milestones; (2) locating roads
using modern and historical aerial photographs, modern and historical
topographic maps, and modern and historical satellite imagery; (3)
digitising roads using GIS, cross-checking with sources, and adding
attribute information.

Fig. 3
figure 3

Workflow summarizing the data collection and digitisation process.

Full size image

The first step consisted of identifying roads in sources and those
revealed in prior studies within the research area, based on
previously published atlases, regional summaries, surveys, milestones
and excavations. Previous studies identified roads through a set of
historical and archaeological parameters^19,20, often based on a
combination of historical and archaeological sources, diachronic
studies of the landscape and the geographical characteristics of
possible paths. A key factor in all prior research was the inclusion
of roads on ancient itineraries such as the Antonine Itinerary or the
Tabula Peutingeriana. The location of milestones, and the location of
cities or settlements close to each other also allowed researchers to
assume the existence of roads that connected them, since all ancient
places must have been reachable by a terrestrial route. But only
rarely have long stretches of Roman roads been excavated or survived
to the present day. Key overviews of roads of the entire Roman Empire
include the Barrington Atlas^8, and its digital representation by the
Ancient World Mapping Centre and by Mapping Past Societies, as well
as the Tabula Imperii Romani (https://tir-for.iec.cat/), and
summaries of the Roman road network in specific regions, provinces,
countries or extensively surveyed areas (discussed per region in
Regional overviews). This phase further included collecting and
summarizing relevant archaeological and historical sources and
publications for each region. Milestones were used as an important
source to determine points where roads passed through, and for
chronology, as they were placed along the roads to indicate the
distance to ancient places and sometimes named infrastructure
investments by emperors. Milestone data were collected primarily
using the geocoded database LIRE (Latin Inscriptions of the Roman
Empire)^21, which includes 8,388 milestones with Latin inscriptions.
While milestones with Greek inscriptions are also included in LIRE,
they are not fully represented. The drawbacks of the sources used by
LIRE include the absence of anepigraphic milestones, the imprecise or
incorrect location of some milestones and missing or unknown
chronological data. This necessitated case-by-case corrections by
consulting additional region-specific sources of the milestone data
(see per region in Regional overviews). Furthermore, milestones were
not evenly distributed throughout the Roman Empire and their
explanatory potential is limited mainly to the major public roads (
viae publicae)^22. Additional data about ancient places, sites and
settlements was consulted from Pleiades, which is the gazetteer of
ancient places, and Vici.org, the archaeological atlas of antiquity (
https://vici.org/). The archaeological, milestone, and site data were
used to identify the existence of individual roads and the general
layout of the road network in each region.

In step two, we proceeded to spatially locate identified roads. The
specific information obtained for each road in the previous step
(location of settlements, location of extant remains from survey or
excavations, location of bridges, milestones, road stations, etc.)
was subsequently compared to different planimetric sources such as
modern and historical aerial photographs (USAF 1950s photogrammetric
flights^23), modern satellite imagery (ESRI World Imagery^24, Google
Satellite^25) and historical satellite imagery (Corona mission^26),
and modern and historical (19th-early 20th century) topographic maps
(see a detailed overview of the sources for each region in Regional
overviews). Available topographic maps were scanned and georeferenced
as needed. This enabled locating the roads in the real world.

In step three, each road section was manually digitised with a target
spatial resolution of 5-200 m on a Geographic Information Systems
(GIS) platform and stored as a single data record in a vector layer
with an associated attribute table. A number of general principles or
observations were followed to guide the digitisation work. In ideal
cases, ancient roads can be visually identified on satellite imagery,
aerial imagery, or are marked as such on topographic maps (Fig. 4a-g
). These usually appear as straight linear features in flat areas
(Fig. 4b), or as sharp switchback roads on slopes (Fig. 4c). Roman
land divisions (centuriation), which include the construction of
roads in an orthogonal layout, are often preserved in modern networks
of roads and agricultural fields, especially in northern Italy^27
(Fig. 4d), but also elsewhere (e.g., Tunisia^28 and Syria^29). All
such identified features were cross-checked against the primary
publications and additional datasets (milestones and site data) where
applicable. However, in other cases where roads were not visible in
imagery, the digitised road sections follow a line connecting known
archaeological road remains, milestones, and ancient sites. The
digitised paths of such segments are refined by comparing them to
existing contemporary and historical roads on georeferenced
topographic maps and satellite imagery. It is then possible to
approximate the layout of a Roman road to one of the existing roads
to achieve a more realistic road layout that takes into account local
topography, especially in areas where more formidable obstacles are
present (wetlands, rugged terrain, mountain passes, etc.). In many of
these cases then, the conjectured line of a Roman road follows the
line of a modern road, which is often corroborated by additional
archaeological and historical evidence. The only modern roads which
were excluded from consideration for corroboration with Roman roads
were modern highways/expressways, which in most cases do not conform
to any previous historical roads. This process results in a plausible
digitised road course recorded as 'conjectured' or 'hypothetical'
(see Certainty categories), which is informed by Roman remains and
prior research whilst conforming to the geographical context. A
consistent issue across all study areas was the presence of modern
water reservoirs and dams. In these cases, we relied on historical
topographic maps or historical satellite imagery (especially Corona
satellite photography for the Near East, from ca. 1967-1972) taken
before construction of any dams to digitise the road segments (Fig. 
4h-i).

Fig. 4
figure 4

Examples of the road locating process. (a) A Roman road indicated as
'Voie Romaine' on a topographic map (Levant 1:50,000) leaving ancient
Bostra (Bosra esh-Sham, Syria) due west; (b) Via Hadriana in the
Eastern Desert of Egypt appears as a wide light linear feature on a
darker soil on satellite imagery; (c) the Klimax pass between Argos
and Mantinea (Greece) can be identified as a sharp switchback track
on the mountain, partially overlaid by a modern wider track; (d)
orthogonal Roman land divisions are retained by modern roads north of
Padua, Italy; (e) a road drawn on the Tabula Imperii Romani Iudaea/
Palaestina sheet; (f) the same area on the modern 1:50,000
topographic map of Israel, indicating 'remains of the Roman road' (in
Hebrew), and (g) the same area on a modern orthophoto, where the
Roman road appears as a straight line with sharp turns running
roughly southwest to northeast across the picture. (h) An example of
employing Corona satellite imagery for locating roads around the
ancient city of Samosata (Samsat, Turkey) before flooding (Corona
mission image DS1107-2138DA061-62), and (i) its current state.

Full size image

Several parameters were calculated for each road segment and added to
the attribute table. Geodesic length in metres of each segment was
calculated in GIS using the WGS 1984 World Mercator projected
coordinate system (EPSG:3395). Average slope in degrees along the
length of each segment was calculated over SRTM^30 Global Digital
Elevation Model with a resolution of 3-arc seconds. The dataset was
finally cleaned to ensure consistency in terminology and topological
continuity between line segments.

The work was performed as a collaborative effort between the
co-authors of this paper undertaken between 2020 and 2024. The
MINERVA (https://pure.au.dk/portal/en/projects/
minerva-understanding-the-centuries-long-functioning-of-the-roman)
project led the digitisation of the Roman road system in North
Africa, the Near East, Asia Minor, and Southeastern Europe. The
Viator-e (https://viatore.icac.cat/) project led the digitisation of
the roads in the Western Roman Empire, excluding North Africa. The
Viator-e project is a continuation of an earlier Mercator-e project,
that focused on the Iberian peninsula (https://
fabricadesites.fcsh.unl.pt/mercator-e/). These two projects' efforts
were supplemented with road datasets for the Eastern Desert of Egypt
(ERC Desert Networks, https://desertnetworks.huma-num.fr/), Bithynia
(Weissova), Rough Cilicia (Sahin), Pamphylia (Massa), Campania
(Renda), the Dutch part of the Roman frontier (Verhagen), the Meuse
and Scheldt basins (Bongers), and Britannia and Sardinia (Lewis). The
data collection per region is described in Regional overviews.

Research area

The geographical limits of the data collection are broadly defined by
the extent of the Roman Empire during the Antonine dynasty, ca. 150
CE, when the Empire reached its largest extent (Fig. 1a). The
inclusion of some regions does not strictly follow this chronological
framework and is rather founded on available source material and
natural connections of these regions to the Roman provinces in the
2nd century CE. Therefore, the road system on the left bank of the
Euphrates between Samosata and Edessa (modern Samsat and Sanliurfa,
Turkey) is included, since the exact boundary between the Roman
Empire and the Edessan kingdom is impossible to define exactly.
Dura-Europos in Syria is included, although it was permanently
annexed around the year 165 CE. Further regions to the east (Armenia,
Mesopotamia) are not included as they were annexed by the Romans only
for a short time in the early 2nd c. CE. A string of north Saharan
oases (Jaghbub, al-Wahat, Marada, Zillah, Waddan and Fezzan in Libya,
and Touggourt in Algeria) are included - even though they were not
part of the Roman Empire they were part of the Roman trade network in
North Africa. The region between Hadrian's Wall and the Antonine Wall
in Britain is also included, even though Roman control there was only
ephemeral (ca. 142-182 CE).

Chronological boundaries

CE (Common Era) and BCE (Before Common Era) are used throughout this
paper and in the dataset. The lower chronological limit of the data
collection is broadly defined by the first incorporation of each
territory into the Roman dominion as a province (be it under the
Republic or the Empire). Thus, the earliest dated road in the dataset
is the Via Appia between Rome and Capua, built in 312 BCE. The lower
boundary then varies on a regional basis (Table 1).

Table 1 Chronological period marking regions' incorporation into the
Roman dominion.
Full size table

However, the Romans usually incorporated older roads into their road
system, which they then improved, paved, or equipped with bridges and
milestones^20. Therefore, evidence for the pre-Roman road network in
each region was taken into account during data collection, based on
available published data. Only in rare specific cases is it possible
to establish a precise date for the construction of a completely new
road. For this reason, the start date of most roads in the dataset is
not fixed, and in such cases the date fields are filled with the
value 9999, to indicate missing data (see the next section, Data
field description). The upper chronological boundary for the data
collection was set at 400 CE, as there were minor changes in the
Roman road system until the early part of 4th century CE. That means
we also only used milestones dated up to ca. 400 CE.

Data field description

Each data record represents a road section between two ancient places
or road crossings, and additional information associated with it
(Table 2). Due to limited sources about many roads and limits to the
scope of data collection, it was not always possible to assign all
values to every data record. As a minimum, each data record contains
ID, Name, Type, Citation, Bibliography, and Segment Certainty, in
addition to Shape Length and Average Slope.

Table 2 Fields in the Itiner-e dataset.
Full size table

Each record is identified by a unique numerical identifier and a
descriptive name. The name is constructed from the two
origin-destination place names of the digitised section, connected by
a hyphen '-'. The ancient place name is used when known. The
present-day toponym was used instead in cases where the name of the
ancient settlement was unknown or did not exist. A characteristic
geographical element was chosen as a place name in cases where the
road ended without the existence of a settlement.

Further attributes are included for each road section related to the
chronology of its creation and abandonment and, if known, the name of
an emperor or a magistrate under whose mandate the road was built.
Few roads can be dated with certainty, and it was outside of the
scope of our data collection to obtain chronological information for
all roads. These fields will be especially relevant to capture future
new findings about road chronology, when the attributes will enable
us to visualise the evolution of the Roman road system, or to compare
the infrastructure investment of each Roman emperor.

Additional fields describe the type of road in the road system
hierarchy ('Main Road' or 'Secondary Road'), the creator of each data
record, bibliography, field identifying the ancient name of the road
or itinerary it is part of, and segment certainty ('Certain',
'Conjectured', and 'Hypothetical'). Additional fields describe
physical properties of the road segments - length (in metres), and
average slope (in degrees). Each entry also has a URI on the live
itiner-e.org version of the dataset, which enables linking to other
online resources.

Definition of road section/record

For the purposes of the data collection, a road was defined as any
line of terrestrial communication connecting sites existing within
the defined geographical and chronological boundaries. This
definition includes both formal (built, engineered) and informal
(non-built) roads, i.e., both paved and unpaved roads which are in
regular use as an accepted line of communication (e.g., desert camel
tracks). Every inhabited place in the Roman world must have been
reachable within its continental or island terrestrial context by a
path of some sort, but road digitisation was not attempted in cases
where no information was available for tracks and pathways leading to
an inhabited place.

In the dataset, all roads are represented as line (vector) segments,
where each segment corresponds to a single data record. A road
segment spans from an intersection with another segment to the next
intersection with a different segment, or from a starting point to
the nearest intersection. This means that a single named road (e.g.,
Rome-Capua) will be split into multiple segments as the road is
intersected by other roads along its course. These multiple segments
will share many attributes (name, type, author, etc.) but not all of
them - Shape Length and Average Slope are almost always unique, and
the FID is a unique identifier for each record.

Main/Secondary Roads

A basic road hierarchy is provided by designating each road segment
as either a 'Main Road' or 'Secondary Road'. The assignment of these
categories to the road segments is for the most part based on prior
designations by archaeological and historical publications used in
the digitisation process (see further below). We used the following
principle in cases where prior designations were lacking. A road
segment is defined as a 'Main Road' if it has more than one of these
characteristics: (a) the presence of milestones, (b) is part of an
ancient Itinerary (chiefly the Antonine Itinerary and Tabula
Peutingeriana), (c) it shares (a large part of) its course with a
historically known major road indicated on 19th/early 20th century
maps. The remaining roads were classified as a 'Secondary Road'. This
two-tier hierarchy is satisfactory for most of the study area,
although in several regions with detailed road data an additional
third tier could have been used (e.g., the region of Sicyon in
Greece, Sagalassos in Turkey, Durocortorum-Reims in France, etc.),
but due to the limited extent of these regions this was not
implemented.

Certainty categories

The segment certainty specifies the spatial accuracy and confidence
in the digitised location of the road segment. Three values are
defined: 'Certain', 'Conjectured', and 'Hypothetical'. 'Certain'
designates well-documented segments in our sources that were
digitised with high spatial accuracy (less than 50 m deviation in the
mountainous terrain, less than 200 m in the plains). Most roads fall
into the 'Conjectured' category, i.e., identified road segments with
lower spatial accuracy due to lower level of documentation in our
sources. 'Hypothetical' is reserved for identified but not located
roads, or identified roads where the physical infrastructure of the
roads was less fixed or where multiple parallel tracks might have
existed (e.g., desert areas, flood plains). In addition,
'Hypothetical' is used for roads which are speculated to have existed
in antiquity but insufficient evidence exists to classify them as
either 'Certain' or 'Conjectured'.

Regional overviews

The following section provides an overview summarised by region of
the main sources used in the processes of identifying and locating
roads and in specific cases methods used in the process of digitising
roads.

North Africa

For Morocco, the main source was the Barrington Atlas^31,
supplemented by a few other studies^32,33. Except for a road
intersection at the site of ancient Volubilis (Fertassa) which is
visible on the satellite imagery, all roads are only conjectured,
following existing roads. The primary topographic map used for
digitisation was a 1:200,000 map from the Army Map Service^34. In
comparison to previous datasets, this work resulted in improving the
spatial accuracy of the road data.

Algeria, Libya, and western Libya (Tripolitania) is covered by a map
by Pierre Salama^6. This source was supplemented by a study on the
region of Sitifis (Setif)^35. Data on ancient sites from Pleiades and
Vici were corroborated with the Atlas Archeologique d'Algerie^36.
Milestone data in LIRE were cross-checked against the Corpus
Inscriptionum Latinarum^37, but their interpretation and the
assignment of construction dates to roads was found to be beyond the
scope of the present research and only a few roads were unambiguously
dated. The data for Tunisia is more detailed, with up-to-date
research on several roads (Carthage-Theveste, Capsa-Tacape, etc.)^38.
Further roads could be digitised using an atlas of Roman land
divisions (centuriation), which marks several Roman roads on modern
1:50,000 topographic maps^28. A number of these roads could have been
digitised with high accuracy as it was possible to visually identify
them on modern satellite imagery. The majority of roads tend to
follow a variety of modern roads, field roads, and tracks marked on
topographic maps and corroborated on modern satellite imagery.
Primary topographic maps used for Algeria were 1:50,000, and
1:200,000 Army Map Service maps, and for Tunisia, 1:50,000,
1:100,000, and 1:200,000 Army Map Service maps^39,40,41,42,43. In
comparison to previous datasets, this work resulted in improving
spatial accuracy across the region, and increased coverage in
northern Tunisia, the desert region, and Algeria.

The primary source for Libya was Mattingly^44 and two sheets of the
Tabula Imperii Romani^45,46, and the outlines of the main Roman roads
and their milestones are provided in Inscriptions of Roman
Tripolitania^47 and Inscriptions of Roman Cyrenaica^48. A study of
roads in the hinterland of Lepcis Magna (el-Khoms)^49 and Cyrene^50
provided detailed data that could be corroborated with modern
satellite imagery and topographic maps, resulting in high accuracy of
digitisation for the two cities. The road network for the Fezzan
region was reconstructed based on the Archaeology of Fazzan^51. Roads
around Bani Walid, Misrata District, mostly follow wadi beds, along
which settlements and water sources are concentrated, occasionally
crossing rocky plateaus where indicated on modern topographic maps.
However, their exact course, as with other desert roads, is
hypothetical. Coastal roads in both Libya and Tunisia avoided sabkhas
- seasonally inundated coastal salt pans not suitable for travel.
Principal topographic maps used for coastal Tripolitania and
Cyrenaica were 1:100,000 maps produced by the Army Map Service^52,53.
The desert area was covered by 1:250,000 maps by the Army Map Service
^54. In comparison to previous datasets, this work resulted in
increased spatial accuracy and increased coverage in Tripolitania and
the city of Cyrene.

In Egypt, many desert routes were identified on both modern
topographic maps and satellite imagery, following the approach to the
identification of caravan routes outlined by Bubenzer and Bolten^55.
A specific problem is presented by the Nile Valley and its delta,
which traditionally relied primarily on water transport. Both the
Barrington Atlas^56,57 and the Tabula Imperii Romani^58 suggest a
land route along the Nile and the delta, based on ancient sources
(the Tabula Peutingeriana and the Antonine Itinerary); therefore,
these roads were included. However, due to the regular flooding of
the Nile and numerous waterworks in the valley (irrigation channels,
dykes), the location of these roads is very uncertain and they were
likely located closer to the edges of the Nile Valley (such as modern
roads). The main reference work used for the Western Desert and Sinai
was Paprocki^59. Primary topographic maps used for Egypt were
1:250,000 maps by the Army Map Service^54. In comparison to previous
datasets, this work resulted in increased spatial accuracy and
increased coverage in the Eastern Desert, Western Desert and the Nile
Valley.

The road system in the Eastern Desert included in our dataset was
developed by the ERC Desert Networks project (https://
desertnetworks.huma-num.fr/). Our knowledge about these routes came
from the Tabula Imperii Romani (sheet 36 Coptos)^58, supplemented by
regional surveys^60,61 and archaeological work on the stations of the
Coptos-Myos Hormos road^62 and the Coptos-Berenike road^63. However,
the roads themselves and their exact routes were not well known as
there are, e.g., no milestones. To overcome this lack of data, the
Desert Networks project has adopted an original, semi-empirical
approach, combining 1:50,000 scale maps from the Egyptian Survey
Authorities, a DEM with a spatial resolution of 11 m, a corpus of 288
archaeological sites with precise locations, and 60 reconstructed
itineraries by modern travellers (18th-19th centuries) who travelled
through the desert in conditions comparable to Roman ones
(environment, transport means and logistics)^64. These data were used
to calibrate various factors involved in camel caravan travel and to
validate the least-cost routes calculated between sites. The modelled
network was then used to generate routes, taking into account
transport infrastructure, navigation conditions, difficulties of the
terrain and the topographical constraints specific to camels. The
Roman roads were reconstructed by calculating the least-cost paths^65
,66 between the known Roman road stations according to ancient
sources (the Tabula Peutingeriana and the Antonine Itinerary, and
ostraca found at the stations^67). The occupation of most of them is
well-dated thanks to recent excavations. It was thus possible to
refine the route and propose an itinerary for each 50-year period
between 1 CE and 300 CE, allowing us to consider the evolution of the
network over time. The ERC Desert Networks project data were adapted
to our data structure (removal of multiple overlapping segments,
merging of segments diverging less than 200 m from each other,
adjustment of start and end point vertices to archaeological sites).

The Near East

The principal source for the southern Levant (Israel, Jordan,
Palestinian Territories, southern Syria) is the Tabula Imperii Romani
^68, supplemented by numerous detailed studies on individual roads
(Legio-Scythopolis^69, Jerusalem-Jaffa^70, Via Nova^71,72,73,
Gaza-Petra^74), cities (Caesarea^75, Jerusalem^76, Petra^77), and
regions (Galilee^78, southern Syria^79, Negev^80, north-east Jordan^
81). Many of the Roman roads were in continual use until the 20th
century and are clearly marked on 19th/early 20th century maps, such
as the Survey of Western Palestine^82, or the 1:50,000 Levant map
series by the French Army^83. Many are still used to this day as
modern paved roads or local field roads and tracks. In the case of
Israel and the Palestinian Territories, high-resolution orthophotos
and detailed 1:50,000 modern topographic maps were available on the
Israeli government portal GovMap (https://www.govmap.gov.il/), which
enabled digitisation with high spatial accuracy and resolution.
Jordan was mostly covered by the French Army 1:50,000 Levant series
and 1:250,000 topographic maps by the Army Map Service^83,84. In
comparison to previous datasets, this work resulted in increased
spatial accuracy and better coverage in the desert and mountainous
regions.

A key overview of Lebanon and Syria is the study by Thomsen^85 and by
Bauzou^86. The Syrian desert was covered by research by Antoine
Poidebard and Rene Mouterde^87,88. Northern Syria and southeastern
Turkey was covered in the Tabula Imperii Byzantini project^89 and
Comfort^90. Limited detailed studies were dedicated to only a few
areas, mainly the city of Apamea^91 and Antioch^92. As in the
southern Levant, many Roman roads have been used continually,
corresponding to modern paved and unpaved roads marked on topographic
maps (1:50,000 French Army series^83) and visible on modern satellite
imagery. The road system in flooded areas of the Ataturk and Assad
dams was digitised over Corona satellite imagery and historical
topographic maps recording the situation before the construction of
the dams. The maps produced by Poidebard and Mouterde were
corroborated with historical topographic maps (1:200,000 by the
French Army^93) and modern satellite imagery. The area between the
Euphrates and the Taurus Mountains was covered by 1:100,000 military
maps by the USSR General Staff^94. In comparison to previous
datasets, this work resulted in increased spatial accuracy and better
coverage in the Euphrates valley, and desert and pre-desert areas.

The roads of ancient Cyprus were described in detail by
Bekker-Nielsen^95, and a detailed survey was conducted on the Akamas
Peninsula^96. Most roads could be corroborated with historical roads
recorded in Kitchener's survey of Cyprus (1:63,360)^97 and modern
topographic maps (1:50,000) by the Army Map Service^98,99. Several
roads not recorded on these maps (mainly on the Akamas Peninsula)
could be identified on modern satellite imagery. In comparison to
previous datasets, this work resulted in increased spatial accuracy
and increased coverage across the island.

Asia Minor

The principal source for the main Roman roads and their milestones in
Asia Minor was the work by David French^100,101,102,103,104,105,106,
107 and the Tabula Imperii Byzantini^10,12,13,14,15,16,108. This
general survey is supplemented by various regional studies for the
Euphrates frontier^109, Cappadocia^110,111, Pontus^112, Lycia^113,
Caria^114, and the Kucukmenderes valley^115; and by further studies
focusing on individual roads (Pilgrim's road^116,117) and cities
(Tavium^118,119, Neoclaudiopolis^120, Pergamum^121, Aphrodisias^122,
and Sagalassos^123).

Many Roman roads were in continual use until the 20th century and
thus could be corroborated with Kiepert's Karte von Kleinasien
(1:400,000)^124 and the Deutsches Heereskarte (1:200,000)^125 and
with modern satellite imagery. The remainder of the roads mostly
follow modern paved and unpaved roads as recorded on 1:100,000 USSR
General Staff topographic maps^94. A group of abandoned historical
roads likely corresponding to Roman roads were identified on modern
satellite imagery principally along the Euphrates frontier (the
Melitene-Satala road) and in Lycia (the Patara-Phellos road above
Kalkan, etc.). They were digitised in places where these could be
corroborated with additional archaeological and historical data. In
places where both historical and modern topographic maps lacked roads
that could guide digitisation, a preference was given either to
valley bottoms or ridges as suitable places for unobstructed travel.
Particular problems occurred in digitising roads in dynamic fluvial
environments where coastal progression and silting occurs. It
necessitated using georeferenced maps published by geoarchaeological
research in the Buyuk Menderes^126,127, Kucukmenderes^128, and Dalyan
^129 river valleys. Detailed archaeological reports and visible
remains identifiable on modern satellite imagery permitted the road
network to be digitised in the vicinity of several cities with very
high accuracy and detail (Ephesus, Magnesia^130, Pergamum, Milet,
Laodicea, Sagalassos, Tavium).

Mountain roads in Pisidia and Pamphylia (Termessus, Selge and Etenna,
Antalya Province) were supplied as GPS tracks by Michele Massa and
adapted to our data structure. These roads were digitised as part of
a project aimed at creating a new archaeological trail in the region,
and for the most part have not been published before with the
exception of the 'Doseme Bogazi' (Via Sebasteia)^131. In comparison
to previous datasets, this work resulted in increased spatial
accuracy and increased coverage, especially in western and
north-eastern Asia Minor.

Bithynia

The road data for Bithynia were directly supplied by Barbora Weissova
^132 and adapted to our data structure. The first descriptions of
Roman roads in Bithynia were published in the 19th century^133,134,
135,136. A fundamental contribution to the study of the road system
represents W. M. Ramsay's The Historical Geography of Asia Minor^137.

Bithynia was explored in the last two decades of the 19th century by
von Diest, von der Goltz and Anton^138,139,140,141,142. Results of
their travels are particularly helpful for the present study as they
brought to light 28 remains of pavements of roads and nine bridges
with meticulous descriptions of their geographic positions, allowing
for the rectification of the courses of ancient roads.

Researchers in the 20th century focused mainly on the reconstructions
of the courses of the supra-regional Pilgrim's Road^116,143,144 and
the regional 'Northern Road'^145,146, leaving the course of the
Pilgrim's Road in Nicomedia and following the eastern direction
through Prusias ad Hypium-Claudiopolis-Cretia
Flaviopolis-Hadrianopolis. The development of the roads from the
Early Byzantine period onwards was examined by Belke^108,147,148 and
Avramea^149.

Reconstructions in the present study were furthermore based on nodal
points and roads compiled in the Barrington Atlas^150, French's^103
compendium of milestones in Pontus and Bithynia, and information
about remains of roads and bridges scattered among regional
archaeological and epigraphic studies and reports^151,152,153,154,155
,156,157,158,159. In comparison to previous datasets, this work
resulted in increased spatial accuracy and increased coverage in the
Marmara region.

Rough Cilicia

The milestones from Cilicia were first compiled by Theodor Mommsen in
1873 as part of CIL III^160, in 1902 expanded together with
Hirschfeld and Domaszewski, with milestones from Pamphylia and
Cilicia. Additional milestone inscriptions in Cilicia were collected
by Keil and Wilhelm^161, and by Mitford and Bean^162,163. French
published several studies on local finds^164,165,166,167,168 and a
new catalogue of milestones^169. In 2014, French provided a revised
monograph, which includes new milestones from Cilicia^106.

Sayar's essay published in 2002 on the ancient road connections of
Cilicia in the Roman imperial period provided a repetition that was
enriched with some milestone inscriptions, listed in Tabula Imperii
Byzantini 5, of the road connections of Cilicia^170.

Information from this prior research was combined with new surveys in
Rough Cilicia (the regions of Anemurium-Anamur and Diocaesarea/
Olba-Uzuncaburc), which began in 2011, to collect and publish
milestone inscriptions from the area. During the fieldwork, several
new Roman roads, showing connections between ancient cities, as well
as new milestones, were discovered^171,172,173,174, and previously
published inscriptions were re-analysed and re-interpreted in some
cases. The identified roads were recorded with GPS and entered into a
topographic map (MapSource TOPO). To compile the milestone
inscriptions, a database was developed using FileMaker Pro database
software, in which the inscriptions were already entered. GPS tracks
were adapted to our data structure and incorporated into the dataset.
In comparison with previous datasets, this work resulted in increased
spatial accuracy and increased coverage in the region.

Southeastern Europe

Most of Greece, European Turkey, and parts of Bulgaria were covered
by the Tabula Imperii Byzantini^9,11,175,176. The Tabula Imperii
Romani covered parts of Greece, Albania, North Macedonia, Kosovo, and
southern Serbia^177,178,179. Several maps from the Barrington Atlas
were used as a basis to digitise especially secondary roads in Dacia
(Romania), Moesia Superior and Moesia Inferior (Serbia and Bulgaria)^
180,181.

Detailed studies for Greece covered mainly the western Peloponnese^
182,183, including individual city territories (Corinth^184 and
Sicyon^185), Attica^186,187,188, Thessaly^189, southern Euboea^190,
and lower Macedonia^191. Pritchet described several individual roads^
192,193,194. The Via Egnatia, spanning from the Adriatic to the
Bosporus, attracted most scholarly attention^195,196,197,198,199. It
was possible to corroborate most of the roads with the known
historical roads presented on the Carte der Europaeischen Tuerkey
(1:575,000)^200, Carte de la Moree (1:200,000)^201, Carte de la Grece
(1:900,000)^202, Karten von Attika (1:25,000)^203, and modern
topographic maps (1:50,000 USSR General Staff)^204, since many of
these were used until the 20th century or they survive as local roads
and tracks. In several cases, it was possible to identify the ancient
roads on modern satellite imagery. Pikoulas^182,183 provided precise
GPS coordinates of the remains of roads which were used for
digitisation. In other cases, the roads follow modern paved and
unpaved roads and tracks, marked on modern topographic maps and
visible satellite imagery. Several roads in the central Peloponnese
(Arcadia) connecting Pheneos, Orchomenos, and Mantinea were added as
hypothetical (based on the Carte de la Moree), since they must have
existed in the Roman period. Coastal progression re-shaped the
landscape in the deltas of several rivers, and georeferenced maps
stemming from geoarchaeological research were used in these cases:
the Vardar river^205,206, the Sperchios river^207,208, the Acheron
river^209 and the Kalamas river^210. The road network of Crete should
be treated as preliminary, since only limited studies were done on
the cities of Aptera and Hierapytna^211,212. The rest of the road
network was reconstructed by connecting identified sites from the
Tabula Peutingeriana with known and still existing historical roads
identified by Pendelbury^213 and corroborated on 1:50,000 British
Army topographic maps. In comparison to previous datasets, this work
resulted in increased spatial accuracy and increased coverage in
Attica, the Peloponnese, Acarnania, and Epirus.

The Roman and ancient road network in Albania was investigated mainly
in its southern part^214, along the Via Egnatia^198, and in the city
of Butrint^215,216. For the remainder of the roads, the main
reference was the Barrington Atlas^180. Most of the digitised roads
follow modern paved and unpaved roads and tracks found on the
1:50,000 topographic maps (USSR General Staff)^217 and corroborated
with modern satellite imagery. In comparison to previous datasets,
this work resulted mainly in increased spatial accuracy and increased
coverage in the region of Butrint.

A principal overview for Roman roads in Serbia and Kosovo was
Petrovic^7, more detailed albeit limited surveys were conducted
around Viminacium (Kostolac, Serbia)^218, Ulpiana (Gracanica/
Gracanice, Kosovo)^219, and on the road Naissus (Nis, Serbia)
-Ratiaria (Arcar, Bulgaria)^220,221. For a variety of secondary
roads, the main source was the Barrington Atlas^180 and the Tabula
Imperii Romani^177, which were also principal sources for Northern
Macedonia. All of the roads could be corroborated with historical and
modern roads found on both historical and modern topographic maps (
Yugoslavia 1:100,000 by the War Office, 1:575,000 Carte der
Europaeischen Tuerkey, and 1:864,000 General-Karte der Europaeischen
Turkei und des Konigreiches Griechenland)^200,222,223 and identified
on modern satellite imagery. In comparison to previous datasets, this
work resulted in increased spatial accuracy and increased coverage in
several areas along the Danube (e.g., Viminacium).

An overview of Roman roads in Bulgaria was provided by Madzarov^224,
which was supplemented by a number of studies focusing on Via
Militaris^225, and the region of the middle Strymon river^226. The
lower Danube was treated by Panaite^227 and Tentea et al.^228, and
the geoarchaeological reconstruction of the landscape surrounding
ancient Histria (Istria, Romania) was used to reconstruct the roads
approaching the city^229. The only additional source for European
Turkey, besides the Tabula Imperii Byzantini, was a study of a 'North
Road' by Karaca^230. Many of the Roman roads remained in continual
use until the 20th century and it was possible to corroborate them
with historical topographic maps (Bulgaria 1:126,000, 1:575,000 Carte
der Europaeischen Tuerkey, and 1:864,000 General-Karte der
Europaeischen Turkei und des Konigreiches Griechenland)^200,222,231
and modern topographic maps (1:100,000 USSR General Staff)^232. Some
roads that do not appear on these maps (mainly along the lower Danube
and the Danube delta) were digitised using modern paved and unpaved
roads and tracks that connect the ancient sites obtained from modern
satellite imagery. In comparison to previous datasets, this work
resulted in increased spatial accuracy and increased coverage in all
areas south of the Danube.

The Roman roads of Dacia (Romania) were treated by Fodorean^233,234.
The data on Roman sites was improved by consulting the dataset of
archaeological sites from the National Archaeological Repertory (RAN)
of Romania (http://ran.cimec.ro/). Most of these roads were
corroborated with historical topographic maps (1:200,000 by
Austria-Hungary military mapping), modern topographic maps (1:100,000
USSR General Staff)^235,236, and modern satellite imagery. The roads
typically follow the course of modern paved and unpaved roads, and
tracks. In comparison to previous datasets, this work resulted in
increased spatial accuracy and increased coverage in the
Transylvanian plateau.

Italy

The roads in central Italy have Rome as a focal point, they are
numerous, many are named and are well known^237. The roads published
in the Barrington Atlas synthesised the previously published
information and were used as a starting point. It was supplemented by
the works of Crainz and Giuliani^238 and Valenti^239. The digital
documentation offered by the Appia Regina Viarum (http://
appia.beniculturali.it/appia/) project has been used to reconstruct
the course of the Via Appia. Works used to identify possible road
layouts in Northern Italy include, Bosio^240 and Mateazzi^27 for the
Venice area, Page^241 and Luccardini^242 for the Po valley and
Liguria, and Nouvel and Cramate^243 for Alpine routes, in addition to
the Barrington Atlas^244,245. Finally, most of the Roman roads of
Puglia, Basilicata and Calabria have been digitised following the
Barrington Atlas^246,247 and using sources such as Zocco^248 and
Ceraudo^249. In comparison to previous datasets, this work resulted
in increased spatial accuracy and increased coverage in the Alpine
piedmont.

Northern Campania and the middle Volturno valley

The road data is based on the work by Prof. Giuseppina Renda^250,251,
252,253, which in turn is based on a diversity of sources:
archaeological documentation, fieldwalking and direct knowledge of
the territory, combined with literary and ancient itineraria,
epigraphic, ancient and contemporary cartographic sources, and
supported by remote sensing and spatial analysis. The dataset
originates from field surveys of the tracks, combined with the
digitisation of ancient cartography and the results of photo
interpretation and archaeological excavation. In comparison to
previous datasets, this work resulted in increased spatial accuracy
and increased coverage in Campania.

Sardinia

The location of Roman roads in Sardinia was digitised using the Roman
road system as presented by Attilio Mastino^254 and digitised by
Lewis^255. Roman roads were predominantly identified from excavation
and survey data. Where possible, in-situ milestones were also
utilised. In comparison to previous datasets, this work resulted
mainly in increased spatial accuracy.

Gallia

In Narbonensis (southern France), one of the most important roads was
the Via Domitia, which has been studied by Laforgue et al.^256. The
territory and the roads from this region have been studied by Leveau^
257. The eastern part of this region was published by Leveau and
Segard^258 (after Benoit^259), while Passelac^260 has been working on
the route of the Via Aquitania. In the region of Aquitania, we relied
on data from the Aquitaviae research group, who conducted a field
survey of Roman roads (https://aquitaviae.hypotheses.org/). Some of
the most recent sources used to digitise Roman roads in this region
have been Baret^261 and Cribeller^262. For completing the Lugdunensis
province (northern and central France), the work of Bayard and
Lemaire^263, Cloppet^264, Cribellier^265, Ferdiere, Monnier and
Cassard were used^266. Nouvel and Venault^267 studied the Roman roads
of the Alps. Provost^268 and Taboue^269 were primary sources for
north-east of France. For the region of Bretagne, we also have used
the information provided by the Voies Romaines de Bretagne (https://
voies-romaines-bretagne.com/index.html). In comparison to previous
datasets, this work resulted in increased spatial accuracy and
increased coverage in northern France and Belgium.

The Iberian Peninsula

As general sources, we have used Arias' publication about all Roman
roads of the Iberian peninsula^270, completing certain areas with
information from the Barrington Atlas^271,272,273,274. The
northeastern territories have been studied in detail by de Soto^275.
Magallon^276 published all the Roman roads of the central and western
Pyrenees and Pre-Pyrenees regions. Arasa and Rossello^277 published a
book about the Roman roads of the western coast of the peninsula. The
Roman roads of the Baetican province have been studied by Corso^278
and Sillieres^279. Lusitania and the Portuguese territories were
studied by Mantas and Alvarez Martinez^280. For the territory of
Castilla y Leon, the principal source was Moreno Gallo (https://
www.viasromanas.net/). Finally, to complete the Northwestern part of
the Iberian peninsula, we used the work done by Arguelles-Alvarez^281
, Guimill-Farina and Parcero-Oubina^282, Losada Perez^283 and
Rodriguez Colmenero^284. In comparison to previous datasets, this
work resulted in increased spatial accuracy and increased coverage
across the whole of the Iberian peninsula.

Germaniae, Raetia and Noricum

The principal reference source for the digitisation of roads in the
upper Germanian and upper Danubian provinces (Raetia, Noricum) and
the Alps was the Barrington Atlas^244,285 and Corpus Inscriptionum
Latinarum^286, which also provided data on the milestones and the
itineraries. The communication and exchange networks in the Alps were
examined by Flugel et al.^287. The routes starting in the Po valley
and leading up to the Alpine passes were examined by Bosio^240. In
comparison to previous datasets, this work resulted mainly in
increased spatial accuracy.

Pannonia

The principal reference source for the digitisation of roads in
Pannonia (roughly modern day Hungary, on the left bank of the Danube
and eastern Austria) was the Barrington Atlas^288. A comprehensive
description of the Limes road and associated sites was provided by
the Danube Limes project, conducted in the context of inscribing the
Danubian Limes as a UNESCO World Heritage Site^289,290. Recent
research concentrated on the site of Brigetio (Komarom, Hungary)^291.
The local road network in the hinterland of Savaria (Szombathely,
Hungary) was briefly examined by Borhy et al.^292 and around nearby
Arrabona (Gyor, Hungary) by Teichner^293. The road network around the
legionary camp and the civil settlement at Carnuntum (Petronell and
Bad Deutsch-Altenburg, Austria) was based on the published maps by
Gugl et al.^294. In comparison to previous datasets, this work
resulted in increased spatial accuracy and increased coverage in the
region of Carnuntum.

Lower Germania, the Dutch part of the Roman frontier

The reconstructions of the Dutch Roman road system south of the Rhine
are based primarily on registered observations in the Dutch national
archaeological database system, ARCHIS (https://
archis.cultureelerfgoed.nl/), and are supplemented with information
from the Dutch national repository for archaeological research data,
DANS DataverseNL (https://dataverse.nl/dataverse/dans/). While
usually quite accurate in terms of location, many observations have
low degrees of accuracy when it comes to dating, simply being
referred to as 'Roman'. Establishing an end date for the observed
segments is often especially problematic. Coverage is best for the
western part of the Rhine frontier (from Utrecht to the North Sea)
and in the province of Limburg (the valley of the Maas and the
so-called Via Belgica). Conjectured and hypothesised road sections
are mostly based on maps and descriptions in the secondary literature
^295,296,297,298. These mostly rely on archaeological, historical and
topographical analysis, and their accuracy can often not be assessed.
Notably, reconstructions for the southwestern part of the Netherlands
(Zeeland, parts of Zuid-Holland and most of Noord-Brabant) are either
absent or have no underlying evidence, due to the major changes of
the landscape since the Roman period. No additional modelling or
reconstruction was attempted. In comparison to previous datasets,
this work resulted in increased spatial accuracy and increased
coverage along the Rhine.

Lower and Upper Germania, Gallia Belgica, and the Meuse and Scheldt
basins

For the Scheldt and Meuse basins, the project used the detailed
reconstructions by M.-H. Corbiau^299,300,301,302,303, supplemented by
various regional studies^297,304,305,306,307,308,309. Despite a large
amount of data, several regions remain underrepresented, such as the
(Campine) Meuse-Demer-Scheldt area. Notably, the dataset exclusively
relies on digitisation of published sources and does not represent
additional analyses. The data was compiled as part of the project
Inland Waterways in the Roman Transport Network of the Gallic and
Germanic Provinces (c. 50 BC-c. AD 400, https://research.flw.ugent.be
/en/projects/
inland-waterways-roman-transport-network-gallic-and-germanic-provinces
). In comparison to previous datasets, this work resulted in
increased spatial accuracy and increased coverage in north-eastern
France and Belgium.

Britannia

The reconstruction of the Roman road system in Britain is primarily
based on recorded observations by Margary^310. Additional roads in
the south-east midlands of Britain are conjectured by the Viatores
group^311. These two sources were digitised by Bishop^312. To create
an interconnected network, a number of road sections were connected
using straight lines^313. In comparison to previous datasets, this
work resulted mainly in increased spatial accuracy.

Data cleaning

A data cleaning phase was designed for this collaborative data
collection effort, which included three steps: 1) ensuring consistent
use of standardised terminology across data records; 2) proofreading
and corrections of all textual fields; 3) checking for topological
continuity and identifying topological errors in the vector polyline
layer containing road segments. First, standardised terminology was
applied to all fields following Table 2 (e.g., 'Main Road'/'Secondary
Road', 'CE'/'BCE', etc.). Second, all ancient place names were
corrected to conform to the Latin and Greek versions as recorded in
the Barrington Atlas of the Greek and Roman World^8 and the Pleiades
dataset. Modern place names were derived from modern topographic
maps, but omitting diacritic marks and other grammatical markings.
Diacritics were retained only for personal names in the 'Citation'
and 'Bibliography' fields. Third, the vector geometry of all road
segments was checked, so that all are cut to intersections with other
roads and are connected with (i.e., snapped to) vertices at the
intersections. Continuity of road names and itineraries was checked,
so they do not contain gaps or are not otherwise disconnected (e.g.,
the 'Via Appia' will be presented as a continuous line of vector
segments, same as all roads belonging to the 'Tabula Peutingeriana'
itinerary). The data cleaning was performed manually in GIS by a
small team of three people over the course of four months.

Data Records

The dataset is available in an open Zenodo repository^314 with a
canonical citation^315. It contains 14,769 data records (road
segments) and is stored as a polyline vector layer in the shapefile
format (itinere_roads.shp), as a geopackage (itinere_roads.gpkg), and
as a geojson database (itinere_roads.geojson). The shapefile and
geopackage is projected onto the WGS 1984 World Mercator (EPSG:3395)
coordinate system, while the geojson database is in the WGS 1984
(EPSG:4326) coordinate system. The Zenodo repository was chosen over
a subject-specific repository to encourage findability and reuse
beyond the field of archaeology, given the cross-disciplinary value
of the dataset. The total size of the shapefile and associated files
is 144 MB; the geopackage is 33.62 MB; the geojson database is 78.05
MB. The files can be opened in any GIS software or spatial database.
Each data record contains only a shortened bibliographical reference
(name and year), and all full references are stored in an openly
accessible Zotero bibliography (https://www.zotero.org/groups/5141113
/itiner-e) and attached to the Zenodo repository in bibtex format
(.bib). The unchanging version of the dataset as described in this
article is stored on Zenodo^314 with a canonical citation (https://
itiner-e.org/).

Technical Validation

The available sources differ significantly between regions of the
former Roman Empire due to preservation and research biases (see
Methods). Some areas have good preservation of traces of roads in the
landscape, while in others it is more obscured due to land use and
building activity; some areas received vast amounts of research
attention in the form of surveys and excavations, and others have
not. The accessibility to the authors of sources and local knowledge
from the roughly 40 countries in Europe, Africa and Asia that lie
inside the boundaries of the former Roman Empire has also put
practical limits on completeness. Some areas concern a significant
increase in the number and accuracy of roads (e.g., the Iberian
Peninsula, Egypt, Greece), others a significant increase in accuracy
(e.g., the southern Levant), and yet others remained more similar to
previous digitisations but with added metadata (e.g., some Central
European regions). This has resulted in heterogeneities across the
dataset in road density, spatial accuracy of road digitisation, and
source reliability.

We evaluate and visualise this incompleteness and heterogeneity of
the data by using the terminology and methodology proposed by Ostir
et al.^316 and Nuninger et al.^317 to create a set of maps: road
density (Fig. 5a) and number of vertices (Fig. 5b) are combined in a
representativity map (Fig. 5c), which is in turn combined with source
reliability (Fig. 6b), into a final confidence map (Fig. 6c). By
establishing these maps as the basis for current knowledge about
Roman roads, it will be possible to address some of these gaps
through future projects that will further improve the digitised
routes on our map through collaborative efforts.

Fig. 5
figure 5

The representativity map (c) is created by numerically reclassifying
and summarizing the (a) road density map and (b) vertex count map.

Full size image
Fig. 6
figure 6

The confidence map is created by numerically reclassifying and
summing the (a) representativity and (b) reliability maps. (c) Roman
road data overlaid on the confidence map.

Full size image

Units of analysis

The research area was divided into polygons measuring 0.5deg x 0.5deg
(latitude and longitude). Polygons overlapping the ocean and seas
were clipped to follow the coastlines. Polygons were only included in
the confidence maps if they met two criteria: 1) intersecting with at
least one road segment; 2) within the boundaries of the Roman Empire.
This means polygons containing no road data in our dataset were
excluded from the confidence analysis, including desert areas and
small islands (e.g., Malta). The results for polygons at the borders
of the analysis region (Fig. 5) suffer from edge effects: they
receive lower values than would be expected, due either to the
polygon that extends beyond the borders of the Empire not covered in
this research (Lower Rhine, Upper and Middle Danube) or to small
seacoast polygons with few road segments.

Representativity map

The aim of the representativity map (Fig. 5c) is to visualise and
quantify the spatial heterogeneity, resolution, and accuracy of the
collected data. Representativity in the current context of the road
dataset means two things: a) whether a region contains many roads
that likely represent a complete road network (coverage), and b)
whether roads are digitised in high detail (spatial resolution). To
describe the dataset regarding coverage and resolution we use road
density (m/km^2, Fig. 5a) and vertices (number of vertices/km, Fig. 
5b). Vertices represent edit points of each road segment in our
dataset and in this way directly reflect the level of spatial
resolution with which each road segment was digitised (roads
digitised in higher resolution will have more vertices than roads
digitised in lower resolution). The data were standardised within the
polygons (units of analysis) in relation to the global (theoretical)
mean value. In this way, we can compare the differences across
regions to find areas where the data conforms to the average, is
overrepresented, or is underrepresented compared to the global mean
value. On the one hand it will be possible to identify areas of high
road density and high resolution, which are therefore highly
representative of the potentially complete Roman road network. On the
other hand it will be possible to identify areas of low road density
and low resolution, i.e., areas where the road network is
underrepresented in the dataset. We employ these two metrics (road
density and vertices) to analyse representativity for several
reasons. Taking into account only road density would underrepresent
areas where lower road density is expected (such as mountains,
deserts, etc.). On the other hand, considering only vertices would
overrepresent areas with complicated road profiles - such as
mountains where roads tend to be more sinuous than on plains. By
combining these two metrics it is possible to better capture overall
representativity of the dataset and to mitigate effects caused by its
heterogeneity.

Road density

The mean value used is the global road density computed as the
fraction of total road length over the total area of the polygons.

Global road density = 299,171,310.141 m / 4,819,775 km^2  = 62.07 m/
km^2

The road density for each polygon is then calculated and the mean
expected value (global road density) is subtracted from the values in
the polygons.

Difference in road density = Road density in a polygon - Global road
density

The resulting difference values are then classified into four
categories representing the difference of the local road density
compared to the global road density calculated in multiples of the
global road density 62.07 (Table 3). The cut-off values were adapted
and modified from the original methodology used by Ostir and Nuninger
^316,317. A value of '0' represents no difference from the global
road density, so the value between 0-1 times the global road density
are considered as 'Average' representativity. Below '0' signifies
lower representativity than the global road density. The values for
'Above Average' and 'Exceptional' represent a difference of 1-4
times, and more than 4 times higher than the difference from the
global road density respectively.

Table 3 Representativity categories based on differences in road
density.
Full size table

Vertices

The values of vertices per road length are normalised in a similar
fashion as with the road density, first a global value is calculated:

Global vertices per road length = 1,031,791 vertices / 299,171.31 km 
= 3.448 vertices/km

The values are aggregated for each polygon of analysis and the global
value is subtracted from the value of each polygon. This difference
is divided into four categories (Table 4), based on the same rule as
was done previously with the road density categories above.

Table 4 Representativity categories based on differences in vertices/
road length.
Full size table

Representativity map results

To compose the final representativity map, the reclassified values of
both road density and vertex count (Tables 3 and 4) are added
together and divided by two (both categories are given equal weight).
The resulting number is rounded down to arrive at the final
representativity value used in the representativity map (Fig. 5c,
Table 5). E.g., if the road density value is 'Average' (30) and
vertex count 'Above Average' (20), the resulting value is calculated
as 30 + 20 = 50, 50/2 = 25, and 25 is rounded to 20 ('Above
Average'). We chose to round the values to the 'better' category in
order to reflect that at least one of the used metrics is more
representative for the description of the data in the affected unit
of analysis.

Table 5 Representativity values used in the final representativity
map.
Full size table

The representativity map (Figs. 5c; 6a) visualises and quantifies the
spatial heterogeneity, resolution, and accuracy of the collected data
^316,317. Of the 38.93% of the study area that has low
representativity, 20.63% concerns deserts and 6.48% mountainous
areas. Future data collection efforts should focus in particular on
the remaining 11.82% of low representativity in areas including
Northern England, Cornwall, the Upper and Middle Danube, Tuscany and
Marche in Italy, Corsica, Sardinia, and central Anatolia.

Reliability map

The aim of the reliability map (Fig. 6b; Table 6) is to assess the
quality of the sources used for the road data collection. This
represents a value judgement about the sources used by the
researchers responsible for the data collection on a region-by-region
basis. Three categories of reliability are defined: high, medium, and
low. High reliability represents areas with ample and detailed
academic publications, often composed of large national projects
(e.g., the Carte archeologique de la Gaule in France) or regional
surveys and syntheses providing data in high-resolution spatial
accuracy. Medium reliability is reserved for less detailed and
lower-resolution sources, which in our case include some of the
previous efforts mapping the Roman world (the Barrington Atlas of the
Greek and Roman World, Tabula Imperii Romani, and Tabula Imperii
Byzantini) whose data were re-digitised and upscaled using additional
sources and our methodology described above. Low reliability
represents regions with little coverage in past scholarship or with
very low resolution of data and therefore low reliability of the
digitised geometry of the roads. In other instances, it represents
areas where our own digitisation efforts only used previous
large-scale and low-resolution resources (the Barrington Atlas). The
reliability categories are reclassified into a numeric code using the
following key:

Table 6 Reliability categories.
Full size table

The high reliability areas in North Africa, the Near East, Asia
Minor, and Greece represent some of the more recent detailed
regional-focused research projects (e.g., the Desert Networks project
in the Eastern Desert of Egypt). The high reliability of Spain is
thanks to the previous efforts of the Mercator-e project (https://
fabricadesites.fcsh.unl.pt/mercator-e/). The high reliability of
France and the Benelux countries is thanks to research carried out by
project collaborators (Philip Verhagen and Toon Bongers). The
moderate reliability of Portugal, Britain, Italy and the eastern
Balkans is due to employing lower resolution sources, mostly
region-based overviews. Most low reliability desert areas represent
regions with only 'Hypothetical' road segments, i.e., segments with
very low reliability in the digitised geometry and outdated
scholarship. The two large Mediterranean islands - Corsica and Crete
- together with the western Balkans and the Upper and Middle Danube
region are covered only using the low-resolution maps published in
the Barrington Atlas.

Confidence map

The representativity and reliability maps were subsequently combined
to create the confidence map (Fig. 6c). It is meant as a tool to
evaluate confidence and reliability in spatial analysis results that
use the data^316,317. The representativity and reliability maps are
reclassified into numerical values, rasterized, and using map algebra
added up to create a simple matrix of summed representativity and
reliability.

The confidence map (Fig. 6c) reveals areas for which open digital
data collection should be prioritised: categories 33, 42 and 43
(39.51%). Among the more significant missing data gaps in this
category are several areas of northern Italy (Tuscany, Marche, and
northern Po valley), the western Danube, western Balkans, and
Corsica. Other areas in these categories concern deserts or suffer
from edge effects (see Units of analysis). Curious is the case of
high reliability and low representativity areas mainly in Western
Europe (category 41, 7.73%) - some (especially upland) areas exhibit
lower digitisation resolution, while in other areas the environmental
factors influencing human settlement and movement potential might
lower representativity (such as floodplains of the lower Rhine and
Landes de Gascogne).

While developing the methodology, we consulted with area experts to
better understand local historical and environmental conditions that
shaped the Roman road network. This expert knowledge helped to
improve our methodological workflow and our understanding of the
Roman road network in its complexity. There is inherent bias in all
archaeological and historical data, stemming from human and
geomorphological transformation processes, accidents of survival, and
research biases. Throughout this process we attempted to minimise the
potential for errors and omissions that would negatively impact the
resulting dataset. The resulting dataset reflects these biases as
shown on the confidence map, whilst representing the most
comprehensive open digital dataset of Roman roads.

Usage Notes

Itiner-e is valuable for future research on ancient mobility and
trade, and the long-term development of transport infrastructure in
Europe, the Near East and North Africa. Its spatial resolution means
it can be used for both regional and Empire-wide studies. Our
confidence map can be used to support future data collection work
that can focus on areas of particularly low reliability and
representativity to continue to fill in the gaps. Such focused work
can expect particular growth in the knowledge about the existence and
location of secondary roads. We also present an online platform (
https://itiner-e.org) that allows Itiner-e to grow, and to address
the incompleteness and heterogeneity revealed by our confidence maps
(Fig. 7). The Itiner-e platform allows a scholarly community to add
new road data as it becomes available, or to recommend corrections
and alternative interpretations of existing road data.

Fig. 7
figure 7

Screenshot of Itiner-e.org, a linked open data gazetteer for
managing, querying, editing and expanding data about ancient roads,
including a routing tool for recreating ancient journeys over roads
and an immersive 3D landscape representation.

Full size image

Data availability

The dataset is available in an open Zenodo^314 repository (https://
doi.org/10.5281/zenodo.17122148) and with a canonical citation on the
Itiner-e platform (https://itiner-e.org). The Zenodo repository
contains the data stored in shapefile format (itinere_roads.shp and
associated files), as a geopackage (itinere_roads.gpkg), and as a
geojson database (itinere_roads.geojson). In addition, it contains a
data field description file (Data field description.docx) and
bibliography file (Itiner-e bibliography.bib).

Code availability

No customised code was produced to create or analyse this dataset.
Specifically, the data was manually digitised with a target spatial
resolution of 5-200 m on a GIS platform and stored as a single data
record in a vector layer with an associated attribute table. The
dataset is available on Zenodo at: https://doi.org/10.5281/
zenodo.17122148.

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Acknowledgements

We thank all Itiner-e and Viabundus workshop participants for helpful
feedback on the data and its analysis. For support and feedback we
thank Aarhus University's Past Networks team, Social Resilience Lab,
Mie Egelund Lind, CORE, Antikmuseet and students in Classical
Archaeology. We thank Cory Stade for language editing. This work was
supported by Danmarks Frie Forskningsfond (DFF) Sapere Aude research
leadership grant (0163-00060B) awarded to T.B. for project MINERVA;
the Carlsberg Foundation's Young Researcher Fellowship (CF21-0382)
awarded to T.B. for The Past Social Networks Project; Danish National
Research Foundation (DNRF) Centre of Excellence for Urban Network
Evolutions (UrbNet) (DNRF119); and the Viator-e project
RTI2018-098905-J-I00 funded by MCIN/AEI/10.13039/501100011033/ and by
FEDER, una manera de hacer Europa awarded to P.S. We would also like
to sincerely thank the many other non-author contributors who have
accompanied us during the difficult (but rewarding) process of Roman
road digitisation.

Author information

Author notes

 1. These authors contributed equally: Pau de Soto, Adam Pazout, Tom
    Brughmans.

Authors and Affiliations

 1. Grup de Recerca en Arqueologia (GRAC_UAB), Universitat Autonoma
    de Barcelona, Barcelona, Catalonia, Spain

    Pau de Soto

 2. Department of History and Classical Studies, Social Resilience
    Lab, and Centre for Urban Network Evolutions (UrbNet), Aarhus
    University, Aarhus, Denmark

    Adam Pazout & Tom Brughmans

 3. Center for Humanities Computing, Aarhus University, Aarhus,
    Denmark

    Peter Bjerregaard Vahlstrup

 4. University of Barcelona, Barcelona, Spain

    Alvaro Auir

 5. Department of History, Ghent University, Ghent, Belgium

    Toon Bongers

 6. Aarhus University, Aarhus, Denmark

    Jens Emil Bodstrup Christoffersen, Louise Matilde Harreby Moller 
    & Amanda Leighton Spatzek

 7. French National Centre for Scientific Research, HiSoMA Research
    Center (UMR 5189), Lyon, France

    Mael Crepy, Louis Maniere & Berangere Redon

 8. Gothenburg university, Department of history, Gothenburg, Sweden

    Mathias Holland Johansen

 9. Department of Archaeology, University of Cambridge, Cambridge,
    United Kingdom

    Joseph Lewis

10. Bilkent University, Ankara, Turkey

    Michele Ruzgar Massa

11. Department of Humanities and Cultural Heritage, University of
    Campania Luigi Vanvitelli, Santa Maria Capua Vetere, Italy

    Giuseppina Renda

12. Istanbul University, Istanbul, Turkey

    Hamdi Sahin

13. Department of History and Classical Studies, Aarhus University,
    Aarhus, Denmark

    Adela Sobotkova

14. Faculty of Social Sciences and Humanities, Vrije Universiteit
    Amsterdam, Amsterdam, Netherlands

    Philip Verhagen

15. Institute of Classical Archaeology, Faculty of Arts, Charles
    University, Prague, Czechia

    Barbora Weissova

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Contributions

Pau de Soto: conception and design of work; data collection for the
Roman West; drafting article. Adam Pazout: design of work; data
collection for the Roman East and North Africa; data analysis and
interpretation; drafting article. Tom Brughmans: conception and
design of work; drafting article. Alvaro Auir: data collection for
the Roman West. Toon Bongers: data collection for the Meuse and
Scheldt basins; critical revision of article. Jens Emil Bodstrup
Christoffersen: data collection for the Balkans; critical revision of
article. Mael Crepy: the Eastern Desert compilation of traveller
itineraries, model calibration. Mathias Holland Johansen: data
collection for Morocco, Algeria and Tunisia; critical revision of
article. Joseph Lewis: data collection for Britannia and Sardinia;
critical revision of article. Louis Maniere: Eastern Desert creation
and calibration of the network model. Michele Massa: data collection
for Pamphylia; critical revision of article. Louise Matilde Harreby
Moller: data collection for Tunisia; critical revision of article.
Berangere Redon: data collection for the Eastern Desert of Egypt in
the context of the ERC desert networks; critical revision of article.
Giuseppina Renda: data collection for Campania; critical revision of
article. Hamdi Sahin: data collection for Rough Cilicia; critical
revision of article. Adela Sobotkova: design of work; critical
revision of article. Amanda Leighton Spatzek: data cleaning; critical
revision of article. Philip Verhagen: data collection for the Dutch
part of the Roman frontier; critical revision of article. Barbora
Weissova: data collection for Bithynia; critical revision of article.

Corresponding author

Correspondence to Tom Brughmans.

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Competing interests

The authors declare no competing interests.

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Cite this article

de Soto, P., Pazout, A., Brughmans, T. et al. Itiner-e: A
high-resolution dataset of roads of the Roman Empire. Sci Data 12,
1731 (2025). https://doi.org/10.1038/s41597-025-06140-z

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  * Received: 03 July 2025

  * Accepted: 16 October 2025

  * Published: 06 November 2025

  * Version of record: 06 November 2025

  * DOI: https://doi.org/10.1038/s41597-025-06140-z

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