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Food systems in archaeology. Examining production and consumption in the past

Published online by Cambridge University Press:  12 May 2021

Kelly Reed*
Affiliation:
Oxford Martin School, University of Oxford, Oxford, UK

Abstract

Research on food has a long history in archaeology and anthropology, with many agreeing that we need to examine the food of complex societies in a more holistic way, through the various stages from production to disposal. Typically, this has occurred through the application of the concept of foodways, although this has a range of definitions and is generally only used in historical archaeological and anthropological research. By building on this important area of research this paper will explore the usefulness of applying a food-systems framework to understanding food in the past. Systems research is already well established in archaeology, sharing elements with approaches such as social-network analysis and complexity science. These theories have been used to address a broad array of questions about the relationships between actors, activities and outcomes for individuals and larger groups at a range of social scales. Thus food systems can help us to explore greater connections between food, human society and the environment via a combination of different archaeological evidence and comparative data.

Type
Articles
Copyright
© The Author(s) 2021. Published by Cambridge University Press

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References

Adams, C.E.P., 1999: Supplying the Roman Army. Bureaucracy in Roman Egypt, in A. Goldsworthy and I. Haynes (eds), The Roman Army as a community, Journal of Roman archaeology 34, 119–126.Google Scholar
Akeret, Ö., Hass, J.N., Leuzinger, U. and Jacomet, S., 1999: Plant macrofossils and pollen in goat/sheep faeces from the Neolithic lake-shore settlement Arbon Bleiche 3, Switzerland, Holocene 9, 175182.CrossRefGoogle Scholar
Antolín, F., Bleicher, N., Brombacher, C., Kühn, M., Steiner, B.L. and Jacomet, S., 2016: Quantitative approximation to large-seeded wild fruit use in a Late Neolithic lake dwelling. New results from the case study of layer 13 of Parkhaus Opéra in Zürich (Central Switzerland), Quaternary international 404(A), 5668.CrossRefGoogle Scholar
Antolín, F. and Schäfer, M., 2020: Insect pests of pulse crops and their management in Neolithic Europe, Environmental archaeology, online first, https://doi.org/10.1080/14614103.2020.1713602, accessed 1 March 2020.CrossRefGoogle Scholar
Armendáriz, V., Armenia, S., Dario, F. and Claudia, V., 2016: Meeting urban food needs. Food supply and distribution systems as complex systems, at www.systemdynamics.org/assets/conferences/2016/proceed/papers/P1341.pdf, accessed 14 August 2019.Google Scholar
Armendáriz, V., Armenia, S. and Stanislao Atzori, S., 2016: Systemic analysis of food supply and distribution systems in city-region systems. An examination of FAO’s policy guidelines towards sustainable agri-food systems, Agriculture 6(4), 65.CrossRefGoogle Scholar
Bailey, G. 2005: Site catchment analysis, in Renfrew, C. and Bahn, P. (eds), Archaeology. The key concepts, London, 230235.Google Scholar
Bakels, C., and Jacomet, S., 2003: Access to luxury foods in Central Europe during the Roman period. The archaeobotanical evidence, World archaeology 34, 542557.CrossRefGoogle Scholar
Banson, K.E., Nguyen, N.C., Sun, D., Asare, D.K., Sowah Kodia, S., Afful, I. and Leigh, J., 2018: Strategic management for systems archetypes in the piggery industry of Ghana. A systems thinking perspective, Systems 6, 35.CrossRefGoogle Scholar
Banson, K.E., Nguyen, N.C. and Bosch, O.J., 2018: A systems thinking approach to the structure, conduct and performance of the agricultural sector in Ghana, Systems research and behavioral science 35(1), 3957.CrossRefGoogle Scholar
Bartosiewicz, L. 2013: Shuffling nags, lame ducks. The archaeology of animal disease, Oxford.CrossRefGoogle Scholar
Becker, D., De Andrés-Herrero, M., Willmes, C., Weniger, G. and Bareth, G., 2017: Investigating the influence of different DEMs on GIS-based cost distance modeling for site catchment analysis of prehistoric sites in Andalusia, ISPRS International journal of geo-information 6, 36.CrossRefGoogle Scholar
Beekman, C.S., and Baden, W.W., 2005: Nonlinear models for archaeology and anthropology. Continuing the revolution, Ashgate.Google Scholar
Bentley, R.A., Bickle, P., Fibiger, L., Nowell, G.M., Dale, C., Hedges, R.E.M., Hamilton, J., Wahl, J., Francken, M., Grupe, G., Lenneis, E., Teschler-Nicola, M., Arbogast, R.M., Hofmann, D. and Whittle, A., 2012: Communty differentiation and kinship among Europe’s first farmers, Proceedings of the National Academy of Sciences 109, 93269330.CrossRefGoogle Scholar
Bentley, R.A., and Maschner, H.D.G. (eds), 2003: Complex systems and archaeology. Empirical and theoretical applications, Salt Lake City.Google Scholar
Bentley, R.A., and Maschner, H.D.G., 2007: Complexity theory, in Bentley, R.A., Maschner, H.D.G. and Chippendale, C. (eds), Handbook of archaeological theories, Lanham, MD, 245270.Google Scholar
Bertalanffy, L. von, 1968: General system theory. Foundations, development, applications, New York.Google Scholar
Bettencourt, L.M.A., Lobo, J., Helbing, D., Kühnert, C. and West, G.B., 2007: Growth, innovation, scaling, and the pace of life in cities, Proceedings of the National Academy of Sciences 104(17), 73017306.CrossRefGoogle ScholarPubMed
Bezeczky, T, 1996: Notes. Amphorae inscription. Legionary supply, Britannia 27, 329336.CrossRefGoogle Scholar
Binford, S.R., and Binford, L., 1968: New perspectives in archaeology, Chicago.Google Scholar
Bödőcs, A., Kovács, G. and Anderkó, K., 2014: The impact of the Roman agriculture on the territory of Savaria, Dissertationes archaelogicae 3(2), 321332.Google Scholar
Bogaard, A., 2004: Neolithic farming in Central Europe. An archaeobotanical study of crop husbandry practices, London.Google Scholar
Bogaard, A., Fraser, R., Heaton, T.H.E., Wallace, M., Vaiglova, P., Charles, M., Jones, G., Evershed, R.P., Styring, A.K., Andersen, N.H., Arbogast, R.-M., Bartosiewicz, L., Gardeisen, A., Kanstrup, M., Maier, U., Marinova, E., Ninov, L., Schäfer, M. and Stephan, E., 2013: Crop manuring and intensive land management by Europe’s first farmers, Proceedings of the National Academy of Sciences 110, 1258912594.CrossRefGoogle ScholarPubMed
Bogaard, A., Strien, H-C. and Krause, R., 2011: Towards a social geography of cultivation and plant use in an early farming community. Vaihingen an der Enz, south-west Germany, Antiquity 85, 395416.CrossRefGoogle Scholar
Bogucki, P., 1993: Animal traction and household economies in Neolithic Europe, Antiquity 67, 492503.CrossRefGoogle Scholar
Borhy, L., 2011: Everyday life on the Pannonian Limes. Houses and their inner decoration in Roman Brigetio (Komárom/Szőny, Hungary), Histria antiqua 20, 3462.Google Scholar
Boserup, E., 1965: The conditions of agricultural growth, Chicago.Google Scholar
Brandes, U., Robins, G., McCranie, A. and Wasserman, S., 2013: What is network science?, Network science 1, 115.CrossRefGoogle Scholar
Breeze, D. J., 2000. Supplying the army, in Alföldy, G., Dobson, B. and Eck, W. (eds), Kaiser, Heer, und Gesellschaft in der Römischen Kaiserzeit, Stuttgart, 5964.Google Scholar
Brughmans, T. 2010: Connecting the dots. Towards archaeological network analysis, Oxford journal of archaeology 29(3), 277303.CrossRefGoogle Scholar
Brughmans, T. 2012: Thinking through networks. A review of formal network methods in archaeology, Journal of archaeological method and theory 20, 623662.CrossRefGoogle Scholar
Brughmans, T., and Peeples, M.A., 2017: Trends in archaeological network research. A bibliometric analysis, Journal of historical network research 1, 124.Google Scholar
Brughmans, T., and Poblome, J., 2015: Pots in space. An exploratory and geographical network analysis of Roman pottery distribution, in Barker, E., Bouzarovski, S., Pelling, C. and Isaksen, L. (eds), New worlds from old texts. Revisiting ancient space and place, Oxford, 255280.CrossRefGoogle Scholar
Brunšmid, J. 1907. Kameni spomenici hrvatskoga narodnoga muzeja u Zagrebu, Vjesnik arheološkog muzeja u Zagrebu 9, 82184.Google Scholar
Burghardt, A.F., 1979: The origins of the road and city network of Roman Pannonia, Journal of historical geography 5 (1), 120.CrossRefGoogle Scholar
Carpenter, S., Walker, B., Anderies, J.M. and Abel, N., 2001: From metaphor to measurement. Resilience of what to what?, Ecosystems 4, 765781.CrossRefGoogle Scholar
Casarotto, A., Pelgrom, J. and Stek, T.D., 2016: Testing settlement models in the early Roman colonial landscapes of Venusia (291 B.C.), Cosa (273 B.C.) and Aesernia (263 B.C.), Journal of field archaeology 41 (5), 568586.CrossRefGoogle Scholar
Cegielski, W.H., and Rogers, J.D., 2016: Rethinking the role of agent-based modeling in archaeology, Journal of anthropological archaeology 41, 283298.CrossRefGoogle Scholar
Chapman, R., 2003: Archaeologies of complexity, London.CrossRefGoogle Scholar
Childe, G.V., 1950: The urban revolution, Town planing review 21, 317.CrossRefGoogle Scholar
Christaller, W., 1933: Die Zentralen Orte in Süddeutschland, Germany.Google Scholar
Clapp, J., 2014: Financialization, distance and global food politics, Journal of peasant studies 41, 797814.CrossRefGoogle Scholar
Clarke, D.L., 1968: Analytical archaeology, London.Google Scholar
Collar, A., 2013: Religious networks in the Roman Empire. The spread of new ideas, Cambridge.CrossRefGoogle Scholar
Collar, A., Coward, F., Brughmans, T. and Mills, B.J., 2015: Networks in archaeology. Phenomena, abstraction, representation, Journal of archaeological method and theory 22(1), 132.CrossRefGoogle Scholar
Comber, M., 2018: Central places in a rural archaeological landscape, Journal of the North Atlantic 36, 112.CrossRefGoogle Scholar
Conolly, J., Manning, K., Colledge, S., Dobney, K. and Shennan, S., 2012: Species distribution modelling of ancient cattle from early Neolithic sites in SW Asia and Europe, Holocene 22, 9971010.CrossRefGoogle Scholar
Cowan, G.A., Pines, D. and Meltzer, D. (eds), 1994: Complexity, metaphors, models, and reality, New York (Santa Fe Institute Studies in the Sciences of Complexity).Google Scholar
Deák, J., Magny, M. and Wüthrich, S., 2017: Late Neolithic to Middle Bronze Age (around 4900–3100 cal. BP) lake-level fluctuations at Lake Neuchâtel (Switzerland) as reflected by the sediment sequence of the site of Colombier/Les Plantées de Rive. Palaeoclimatic and archaeological implications, The Holocene 28, 318.CrossRefGoogle Scholar
Deetz, J., 1977: In small things forgotten. An archaeology of early American life, New York.Google Scholar
Deschler-Erb, S. and Marti-Grädel, E., 2004: Viehhaltung und Jagd. Ergebnisse der Untersuchung der handaufgelesenen Tierknochen, in Jacomet, S., Leuzinger, U. and Schibler, J. (eds), Die jungsteinzeitliche Seeufersiedlung Arbon Bleiche 3. Umwelt und Wirtschaft, Frauenfeld, 158252.Google Scholar
de Soto, P., 2019: Network analysis to model and analyse Roman transport and mobility, in Verhagen, P.., Joyce, J. and Groenhuijzen, M. (eds), Finding the limits of the limes, Cham, 271289.CrossRefGoogle Scholar
Dietre, B., Walser, C., Kofler, W., Kothieringer, K., Hajdas, I., Lambers, K., Reitmaier, T. and Haas, J.N., 2016: Neolithic to Bronze Age (4850–3450 cal. BP) fire management of the Alpine Lower Engadine landscape (Switzerland) to establish pastures and cereal fields, Holocene 27(2), 181196.CrossRefGoogle Scholar
Di Pierro, S., 2003: Ceramic production technology and provenance during the final Neolithic. The portalban settlement, Neuchâtel lake, Switzerland, Revue d’archéométrie 27, 7593.CrossRefGoogle Scholar
Doran, J., 1970: Systems theory, computer simulations and archaeology, World archaeology 1(3), 289298,CrossRefGoogle Scholar
Drack, M., and Apfalter, W., 2007: Is Paul Weiss’ and Ludwig von Bertalanffy’s system thinking still valid today?, Systems research and behavioral science 24(5), 537546.CrossRefGoogle Scholar
Duncan-Jones, R., 2006: Roman customs dues. A comparative view, Latomus 65(1), 316.Google Scholar
Earl, G., and Keay, S., 2006: Urban connectivity of Iberian and Roman towns in southern Spain. A network analysis approach, in J. Clark (ed.), Computer applications and quantitative methods in archaeology. Proceedings of the 34th Conference, Fargo, North Dakota, USA, March 2006, 34th Computer Applications and Quantitative Methods in Archaeology Conference, Oxford (BAR International Series 1230), 89–98.Google Scholar
El Bilali, H., Callenius, C., Strassner, C. and Probst, L., 2019: Food and nutrition security and sustainability transitions in food systems, Food and energy security, 8, e00154.CrossRefGoogle Scholar
Ericksen, P.J., 2008: Conceptualizing food systems for global environmental change research, Global environmental change 18(1), 234245.CrossRefGoogle Scholar
FAO, 1996: The Rome declaration on world food security and the World Food Summit plan of action, http://www.fao.org/docrep/003//w3613e/w3613e00.htm, accessed 27 June 2019.Google Scholar
FAO, 2017: Nutrition-sensitive agriculture and food systems in practice, http://www.fao.org/3/a-i7848e.pdf, accessed 1 June 2019.Google Scholar
Faulseit, R.K., 2015: Beyond collapse. Archaeological perspectives on resilience, revitalization, and transformation in complex society, Carbondale.Google Scholar
Favre, P., and Jacomet, S., 1998: Branch wood from the lake shore settlements of Horgen Scheller, Switzerland. Evidence for economic specialization in the Late Neolithic period, Vegetation history and archaeobotany 7, 167178.CrossRefGoogle Scholar
Flannery, K.V., 1968: Archaeological systems theory and early Mesoamerica, in Meggers, B.J. (ed.), Anthropological archaeology in the Americas, Washington, DC, 6787.Google Scholar
Fodorean, F., 2016: Pannonia, Dacia and Moesia in the ancient geographical sources, Stuttgart.Google Scholar
Folke, C., 2006: Resilience. The emergence of a perspective for social-ecological systems analyses, Global environmental change 16, 253267.CrossRefGoogle Scholar
Folke, C., Carpenter, S.R., Walker, B.H., Scheffer, M., Chapin, F.S. III and Rockström, J., 2010: Resilience thinking. Integrating resilience, adaptability and transformability, Ecology and society 15 (4), 20.CrossRefGoogle Scholar
Fuller, D., and Stevens, C., 2009: Agriculture and the development of complex societies. An archaeobotanical agenda, in Fairbairn, A. and Weiss, E. (eds), From foragers to farmers. Papers in honour of Gordon C. Hillman, Oxford, 3757.Google Scholar
Garnett, T., Appleby, M.C., Balmford, A., Bateman, I.J., Benton, T.G., Bloomer, P. et al., 2013: Sustainable intensification in agriculture. Premises and policies, Science 341, 3334.CrossRefGoogle ScholarPubMed
Gerling, C., Doppler, T., Heyd, V., Knipper, C., Kuhn, T., Lehmann, M.F., Pike, A.W.G. and Schibler, J., 2017: High-resolution isotopic evidence of specialised cattle herding in the European Neolithic, PLoS ONE 12 (7), e0180164.CrossRefGoogle ScholarPubMed
Gillis, R.E., Kovačiková, L., Bréhard, S., Guthmann, E., Vostrovská, I., Nohálová, H., Arbogast, R.-M., Domboróczki, L., Pechtl, J., Anders, A., Marciniak, A., Tresset, A. and Vigne, J.-D., 2017: The evolution of dual meat and milk cattle husbandry in Linearbandkeramik societies, Proceedings of the Royal Society B 284, 20170905.CrossRefGoogle ScholarPubMed
Glicksman, K., 2007: Olive and wine cultivation in the Roman province of Dalmatia, Historia antiqua 15, 4350.Google Scholar
Godfray, H.C.J., Beddington, J.R., Crute, I.R., Haddad, L., Lawrence, D., Muir, J.F., Pretty, J., Robinson, S., Thomas, S.M. and Toulmin, C., 2010: Food security. The challenge of feeding 9 billion people, Science 327(5967), 812818.CrossRefGoogle ScholarPubMed
Gonzalez Carretero, L., Wollstonecroft, M. and Fuller, D.Q., 2017: A methodological approach to the study of archaeological cereal meals. A case study at Çatalhöyük East (Turkey), Vegetation history and archaeobotany 26(4), 415432.CrossRefGoogle Scholar
Goodchild, H., 2013: GIS models of Roman agricultural production, in Bowman, A. and Wilson, A. (eds), The Roman agricultural economy. Organization, investment, and production, Oxford, 5586.CrossRefGoogle Scholar
Gordon, J.M., 2018: Transforming culture on an insula Portunalis. Port cities as central places in early Roman Cyprus, Land 7(4), 155, https://doi.org/10.3390/land7040155.CrossRefGoogle Scholar
Groenhuijzen, M.R., and Verhagen, J.W.H.P., 2016: Testing the robustness of local network metrics in research on archeological local transport networks, Frontiers in digital humanities 3(6), https://doi.org/10.3389/fdigh.(2016).00006.CrossRefGoogle Scholar
Gumerman, G., 1997: Food and complex societies, Journal of archaeological method and theory 4(2), 105139.CrossRefGoogle Scholar
Haas, J.N., Karg, S. and Rasmussen, P., 1998: Beech leaves and twigs used as a winter fodder. Examples from historic and prehistoric times, Environmental archaeology 1, 8186.CrossRefGoogle Scholar
Halstead, P., 1996: Pastoralism or household herding? Problems of scale and specialization in early Greek animal husbandry, World archaeology 28, 2042.CrossRefGoogle Scholar
Halstead, P., 1999: Neighbours from hell. The household in Neolithic Greece, in Halstead, P. (ed.), Neolithic society in Greece, Sheffield, 7795.Google Scholar
Halstead, P., 2004. Farming and feasting in the Neolithic of Greece. The ecological context of fighting with food, Documenta praehistorica 31, 151161.CrossRefGoogle Scholar
Halstead, P., and Jones, G., 1989: Agrarian ecology in the Greek islands. Time stress, scale and risk, Journal of Hellenic studies 109, 4155.CrossRefGoogle Scholar
Halstead, P., and O’Shea, J.M. (eds), 1989: Bad year economics, Cambridge.CrossRefGoogle Scholar
Hamilakis, Y., 2013: Archaeologies and the senses. Human experience, memory, and affect, Cambridge.Google Scholar
Hamilakis, Y., 2015: Food as sensory experience, in Beaudry, M. and Metheny, K. (eds), The archaeology of food. An encyclopedia, Lanham, MD, 205206.Google Scholar
Hammond, R.A., and Dubé, L., 2012: A systems science perspective and transdisciplinary models for food and nutrition security, Proceedings of the National Academy of Science 109(31), 1235612363.CrossRefGoogle ScholarPubMed
Hastorf, C., 2017: The social archaeology of food. Thinking about eating from prehistory to the present, Cambridge.CrossRefGoogle Scholar
Hedges, R.E.M., and Reynard, L.M., 2007: Nitrogen isotopes and the trophic level of humans in archaeology, Journal of archaeological science 34(8), 12401251.CrossRefGoogle Scholar
Heiss, A.G., Antolín, F., Bleicher, N., Harb, C., Jacomet, S., Kühn, M., Marinova, E., Stika, H.-P. and Valamoti, S., 2017: State of the (t)art. Analytical approaches in the investigation of components and production traits of archaeological bread-like objects, applied to two finds from the Neolithic lakeshore settlement Parkhaus Opéra (Zürich, Switzerland), PLoS ONE 12(8), e0182401.CrossRefGoogle Scholar
Hendon, J.A., 2000: Having and holding. Storage, memory, knowledge, and social relations, American anthropologist 102(1), 4253.CrossRefGoogle Scholar
Herbig, C., and Maier, U., 2011: Flax for oil or fibre? Morphometric analysis of flax seeds and new aspects of flax cultivation in Late Neolithic wetland settlements in southwest Germany, Vegetation history and archaeobotany 20, 527533.CrossRefGoogle Scholar
Hillman, G.C., 1981: Reconstructing crop husbandry practices from charred remains of crops, in Mercer, R. (ed.), Farming practice in British prehistory, Edinburgh, 123162.Google Scholar
Hodder, I., and Mol, A., 2016: Network analysis and entanglement, Journal of archaeological method and theory 23, 10661094.CrossRefGoogle Scholar
Holling, C.S., 1996: Engineering resilience versus ecological resilience, in Schulze, P.C. (ed.), Engineering within ecological constraints, Washington, DC, 3144.Google Scholar
Holling, C.S., and Gunderson, L.H., 2002: Resilience and adaptive cycles, in Gunderson, L.H. and Holling, C.S. (eds), Panarchy. Understanding transformations in human and natural systems, Washington, DC, 2562.Google Scholar
Holling, C.S., Gunderson, L.H. and Ludwig, D., 2002: In quest of a theory of adaptive change, in Gunderson, L.H. and Holling, C.S. (eds), Panarchy. Understanding transformations in human and natural systems, Washington, DC, 324.Google Scholar
Iannone, G., 2015: Release and reorganisation in the tropics. A comparative perspective from Southeast Asia, in Faulseit, R.K. (ed.), Beyond collapse. Archaeological perspectives on resilience, revitalization, and transformation in complex society, Carbondale, 179212.Google Scholar
Ingram, J., 2011: A food systems approach to researching food security and its interactions with global environmental change, Food security 3, 417431.CrossRefGoogle Scholar
Ingram, J.S.I., Ericksen, P.J. and Liverman, D. (eds.), 2010: Food security and global environmental change, London and Washington, DC.Google Scholar
Iskra Janošić, I., 2001: Urbanizacija Cibala i Razvoj Keramičarskih Središta, Vinkovci.Google Scholar
Jacomet, S., 2006: Plant economy of the northern Alpine lake dwelling area – 3500–2400 BC cal., Environmental archaeology 11, 6483.CrossRefGoogle Scholar
Jacomet, S., 2007: Neolithic plant economies in the northern Alpine foreland from 5500–3500 BC cal, in Colledge, S. and Conolly, J. (eds), The origins and spread of domestic plants in southwest Asia and Europe, Walnut Creek, CA, 221258.Google Scholar
Jacomet, S., 2009: Plant economy and village life in Neolithic lake dwellings at the time of the Alpine Iceman, Vegetation history and archaeobotany 18, 4759.CrossRefGoogle Scholar
Janowitz, M.F., 1993: Indian corn and Dutch pots. Seventeenth-century foodways in New Amsterdam/New York, Historical archaeology 27, 624.CrossRefGoogle Scholar
Janssen, M.A. (ed.), 2002: Complexity and ecosystem management. The theory and practice of multi-agent systems, Cheltenham.Google Scholar
Jones, G., 1998: Distinguishing food from fodder, Environmental archaeology 1, 9598.CrossRefGoogle Scholar
Jones, J.W., Antle, J.M., Basso, B., Boote, K.J., Conant, R.T., Foster, I., Godfray, H.C., Herrero, M., Howitt, R.E., Janssen, S., Keating, B.A., Munoz-Carpena, R., Porter, C.H., Rosenzweig, C. and Wheeler, T.R., 2017: Brief history of agricultural systems modelling, Agricultural systems 155, 240254.CrossRefGoogle Scholar
Kamash, Z., 2018: ‘Sweet and delicious, he who tastes it will go back to it’. Food, memory and religion in the Roman Middle East, Theoretical Roman archaeology journal 1(1), https://doi.org/10.16995/traj.146.CrossRefGoogle Scholar
Kerdy, M., Chiquet, P. and Schibler, J., 2019: Hunting, husbandry, and human–environment interactions in the Neolithic lakeshore sites of western Switzerland, European journal of archaeology 22 (1), 321.CrossRefGoogle Scholar
Kintigh, K.W., Altschul, J.H., Beaudry, M.C., Drennan, R.D., Kinzig, A.P., Kohler, T.A. et al., 2014: Grand challenges for archaeology, Proceedings of the National Academy of Sciences 111, 879880.CrossRefGoogle ScholarPubMed
Knappett, C., 2011: An archaeology of interaction. Network perspectives on material culture and society, Oxford.CrossRefGoogle Scholar
Knappett, C. (ed.), 2013: Network analysis in archaeology. New approaches to regional interaction, Oxford.CrossRefGoogle Scholar
Knappett, C., Evans, T.R. and Rivers, R., 2011: The Theran eruption and Minoan palatial collapse. New interpretations gained from modelling the maritime network, Antiquity 85, 10081023.CrossRefGoogle Scholar
Kreuz, A., and Schäfer, E., 2011: Weed finds as indicators for the cultivation regime of the early Neolithic Bandkeramik culture?, Vegetation history and archaeobotany 20, 333348.CrossRefGoogle Scholar
Kühn, M., and Hadorn, P., 2004. Pflanzliche Makro- und Mikroreste aus Dung von Wiederkäuern, in Jacomet, S., Leuzinger, U. and Schibler, J. (eds), Die jungsteinzeitliche Seeufersiedlung Arbon Bleiche 3. Umwelt und Wirtschaft, Frauenfeld, 327357.Google Scholar
Kühn, M., Maier, U., Herbig, C., Ismail-Meyer, K., Le Bailly, M. and Wick, L.. 2013: Methods for the examination of cattle, sheep and goat dung in prehistoric wetland settlements with examples of the sites Alleshausen-Täschenwiesen and AlleshausenGrundwiesen (around cal 2900 BC) at Lake Federsee, south-west Germany, Environmental archaeology 18(1), 4357.CrossRefGoogle Scholar
LaBianca, O.S., 1990: Hesban 1, sedentarization and nomadization. Food system cycles at Hesban and vicinity in Transjordan, Berrien Springs.Google Scholar
LaBianca, O.S., 2000: Daily life in the shadow of empire. A food systems approach to the archaeology of the Ottoman Empire, in Baram, U. and Carroll, L. (eds), A historical archaeology of the Ottoman Empire. Breaking new ground, New York, 203217.Google Scholar
Landon, D.B., 2005: Zooarchaeology and historical archaeology. Progress and prospects, Journal of archaeological method and theory 12(l), 136.CrossRefGoogle Scholar
Landon, D.B., 2009: An update on zooarchaeology and historical archaeology. Progress and prospects, in Gaimster, D. and Majewski, T. (eds), International handbook of historical archaeology, New York, 77104.CrossRefGoogle Scholar
Laszlo, A., and Krippner, S., 1998: Systems theories. Their origins, foundations, and development, in Jordan, J.S. (ed.), Systems theories and a priori aspects of perception, Amsterdam, 4774.CrossRefGoogle Scholar
Leidwanger, J., 2014, Maritime networks and economic regionalism in the Roman eastern Mediterranean, Les nouvelles de l’archéologie 135, 3238.CrossRefGoogle Scholar
Leleković, T., 2018: How were imitations of samian formed?, Internet archaeology 50, https://doi.org/10.11141/ia.50.18.Google Scholar
Leleković, T., and Rendić-Miočević, A., 2012: Rural settlements, in Branka, M. (ed.), The archaeology of Roman southern Pannonia, Oxford, 279311.Google Scholar
Leuzinger, U., 2002: Holzartefakte, in De Capitani, A., Deschler-Erb, S., Leuzinger, U., Marti-Grädel, E. and Schibler, J. (eds), Die jungsteinzeitliche Siedlung Arbon Bleiche 3. Funde, Frauenfeld, 76114.Google Scholar
Leuzinger, U., and Rast-Eicher, A., 2011: Flax processing in the Neolithic and Bronze Age pile-dwelling settlements of eastern Switzerland, Vegetation history and archaeobotany 20, 535542.CrossRefGoogle Scholar
Levin, S.A., 1992: The problem of pattern and scale in ecology, Ecology 73, 19431967.CrossRefGoogle Scholar
Liu, J., Dietz, T., Carpenter, S.R., Alberti, M., Folke, C., Moran, E., Pell, A.N., Deadman, P., Kratz, T., Lubchenco, J., Ostrom, E., Ouyang, Z., Provencher, W., Redman, C.L., Schneider, S.H. and Taylor, W.W., 2007a: Complexity of coupled human and natural systems, Science 317 (5844), 15131516.CrossRefGoogle ScholarPubMed
Liu, J., Dietz, T., Carpenter, S.R., Folke, C., Alberti, M., Redman, C.L., Schneider, S.H., Ostrom, E., Pell, A.N., Lubchenco, J., Taylor, W.W., Ouyang, Z., Deadman, P., Kratz, T. and Provencher, W., 2007b: Coupled human and natural systems, Ambio 36 (8), 639649.CrossRefGoogle ScholarPubMed
Livarda, A., 2011: Spicing up life in north-western Europe. Exotic food plant imports in the Roman and medieval world, Vegetation history and archaeobotany 20, 143–64.CrossRefGoogle Scholar
Livarda, A., and Orengo, H., 2015: Reconstructing the Roman London flavourscape. New insights into the exotic plant food trade using network and spatial analyses, Journal of archaeological science 55, 244252.CrossRefGoogle Scholar
McClatchie, M., Schulting, R., McLaughlin, R., Colledge, S., Bogaard, A., Barratt, P. and Whitehouse, N., 2019: Food production, processing and foodways in Neolithic Ireland, Environmental archaeology, DOI: 10.1080/14614103.2019.1615215.CrossRefGoogle Scholar
Magny, M., 2006: Lake level studies, west-central Europe. Holocene fluctuations of lake levels in west-central Europe. Methods of reconstruction, regional pattern, palaeoclimatic significance and forcing factors, in Elias, S. (ed.), Encyclopedia of quaternary geology, Amsterdam, 13891399.Google Scholar
Magny, M., Guiot, J. and Schoellammer, P., 2001: Quantitative reconstruction of Younger Dryas to mid-Holocene paleoclimates at Le Locle, Swiss Jura, using pollen and lake-level data, Quaternary research 56, 170180.CrossRefGoogle Scholar
Maier, U., and Schlichtherle, H., 2011: Flax cultivation and textile production in Neolithic wetland settlements on Lake Constance and in Upper Swabia (south-west Germany), Vegetation history and archaeobotany 20, 567578.CrossRefGoogle Scholar
Maigrot, Y., 2005: Ivory, bone and antler tools production system sar Chalain 4 (Jura, France). Late Neolithic site, 3rd millennium, in Luik, H., Choyke, A.M., Batey, C.E. and Lougas, L. (eds), From hooves to horns, from mollusc to mammoth. Manufacture and use of bone artefacts from prehistoric times to the present, Tallinn, 113126.Google Scholar
Mandich, M.J., 2015: Re-defining the Roman ‘suburbium’ from republic to empire. A theoretical approach, Theoretical Roman archaeology journal 2014, 8199.CrossRefGoogle Scholar
Mandich, M.J., 2016: Urban scaling and the growth of Rome, Theoretical Roman archaeology journal 2015, 188203.CrossRefGoogle Scholar
Meadows, D.H., 2009: Thinking in systems. A primer, London.Google Scholar
Mills, B.J., 2016: Communities of consumption. Cuisines as constellated networks of situated practice, in Roddick, A.P. and Stahl, A.B. (eds), Knowledge in motion. Constellations of learning across time and place, Tucson, 247270.Google Scholar
Mintz, S.W. and Du Bois, C.M., 2002: The anthropology of food and eating, Annual review of anthropology 31, 99119.CrossRefGoogle Scholar
Mócsy, A., 2015: Pannonia and Upper Moesia. A history of the Middle Danube provinces of the Roman Empire, London.Google Scholar
Moragues-Faus, A., Sonnino, R. and Marsden, T., 2017: Exploring European food system vulnerabilities. Towards integrated food security governance, Environmental science and policy 75, 184215.CrossRefGoogle Scholar
Morecroft, J. 2010: Systems dynamics, in Reynolds, M. and Holwell, S. (eds), Systems approaches to managing change. A practical guide, Cham, 2586.CrossRefGoogle Scholar
Morley, N. 1996: Metropolis and hinterland. The city of Rome and the Italian economy, 200 B.C.–A.D. 200, Cambridge.CrossRefGoogle Scholar
O’Brien, M.J., and Bentley, R.A., 2015: The role of food storage in human niche construction. An example from Neolithic Europe, Environmental archaeology 20 (4), 364378.CrossRefGoogle Scholar
Orengo, H., and Livarda, A., 2016: The seeds of commerce. A network analysis-based approach to the Romano-British transport system, Journal of archaeological science 66, 2135.CrossRefGoogle Scholar
Ortega, D., Ibáñez, J.J., Campos, D., Khalidi, L., Méndez, V. and Teira, L., 2016: Systems of interaction between the first sedentary villages in the Near East exposed using agent-based modelling of obsidian exchange, Systems 4(18), 116.CrossRefGoogle Scholar
Ortman, S.G., Cabaniss, A.H.F., Sturm, J.O. and Bettencourt, L.M.A., 2015: Settlement scaling and increasing returns in an ancient society, Science advances 1(1), 18.CrossRefGoogle Scholar
Östborn, P., and Gerding, H., 2014: Network analysis of archaeological data. A systematic approach, Journal of archaeological science 46, 7588.CrossRefGoogle Scholar
Ožanić Roguljić, I. 2016: Tipologija rimske keramike iz Vinkovaca, Zagreb (Monographiae Instituti archaeologici 10).Google Scholar
Ožanić Roguljić, I. 2017. Amophoras from Žuta Lokva, in Lipovac Vrkljan, G., Radić Rossi, I. and Konestra, A. (eds), Amfore kao izvor za rekonstrukciju gospodarskoga razvoja jadranskeregije u antici. Lokalna proizvodnja, Zagreb, 8085.Google Scholar
Pecci, A., Clarke, J., Thomas, M., Muslin, J., van der Graaff, I., Toniolo, L. and Di Pasquale, G., 2017: Use and reuse of amphorae. Wine residues in Dressel 2–4 amphorae from Oplontis Villa B (Torre Annunziata, Italy), Journal of archaeological science. Reports 12, 515521.CrossRefGoogle Scholar
Peeples, M.A., 2018: Connected communities. Networks, identities, and social change in the ancient Cibola world, Tucson.CrossRefGoogle Scholar
Peeples, M.A., and Roberts, J.M., 2013: To binarize or not to binarize. Relational data and the construction of archaeological networks, Journal of archaeological science 40, 30013010.CrossRefGoogle Scholar
Peres, T.M.J., 2017: Foodways archaeology. A decade of research from the southeastern United States, Journal of archaeological research 25, 421460.CrossRefGoogle Scholar
Pimm, S.L., Lawton, J.H. and Cohen, J.E., 1991: Food web patterns and their consequences, Nature 350, 669674.CrossRefGoogle Scholar
Pinterović, D., Mutnjaković, A. and Pehnec, S., 2014: Mursa. Hrvatska akademija znanosti i umjetnosti, Zagreb.Google Scholar
Pitts, M.E.J., 2015: The archaeology of food consumption, in Wilkins, J. and Nadeau, R. (eds), A companion to food in the ancient world, Oxford, 95104.CrossRefGoogle Scholar
Porter, B.W., 2013: Complex communities. The archaeology of Early Iron Age west–central Jordon, Tucson.Google Scholar
Preiser-Kapeller, J., 2017: Networks as proxies. A relational approach towards economic complexity in the Roman period, https://arxiv.org/ftp/arxiv/papers/1703/1703.02865.pdf, accessed 4 July 2019.Google Scholar
Redman, C., 2005: Resilience theory in archaeology, American archaeologist 107, 7077.Google Scholar
Redman, C., and Kinzig, A.P., 2003. Resilience of past landscapes. Resilience theory, society and the longue durée , Conservation ecology 7, 1014.CrossRefGoogle Scholar
Reed, K., 2015: From the field to the hearth. Plant remains from Neolithic Croatia (ca. 6000–4000 cal BC), Vegetation history and archaeobotany 24, 601619.CrossRefGoogle Scholar
Reed, K. and Leleković, T., 2019: First evidence of rice (Oryza cf. sativa L.) and black pepper (Piper nigrum) in Roman Mursa, Croatia, Archaeological and anthropological sciences 11(1), 271278.CrossRefGoogle Scholar
Reed, K., and Ožanić Roguljić, I., 2020: The Roman food system in southern Pannonia (Croatia) from the 1st–4th century A.D., Open archaeology 6 (1), 3862.CrossRefGoogle Scholar
Reed, K., and Ryan, P.., 2019: Lessons from the past and the future of food, World archaeology, at https://doi.org/10.1080/00438243.2019.1610492.CrossRefGoogle Scholar
Renfrew, C. 1987: Problems in the modeling of socio-cultural systems, European journal of operational research 30, 179192.CrossRefGoogle Scholar
Richer, S., Stump, D., and Marchant, R., 2019: Archaeology has no relevance, Internet archaeology 53, https://doi.org/10.11141/ia.53.2.Google Scholar
Rivers, R., and Evans, T.S., 2014: New approaches to archaic Greek settlement structure, Nouvelles de l’archéologie 135, 2128.CrossRefGoogle Scholar
Romanowska, I., Crabtree, S., Harris, K. and Davies, B., 2019: Agent-based modeling for archaeologists, part 1 of 3, Advances in archaeological practice 7(2), 178184.CrossRefGoogle Scholar
Roper, D.C., 1979: The method and theory of site catchment analysis. A review, Advances in archaeological method and theory 2, 119140.Google Scholar
Rowan, E. 2019: Same taste, different place. Looking at the consciousness of food origins in the Roman world, Theoretical Roman archaeology journal 2 (1), http://doi.org/10.16995/traj.378.CrossRefGoogle Scholar
Salmon, M. 1978: What can systems theory do for archaeology?, American antiquity 43(2), 174183.CrossRefGoogle Scholar
Sanader, M.O., 2010. Problemima topografije hrvatskog dijela dunavskog limesa na temelju novijih arheoloških istraživanja, in Radman-Livaja, I. (ed.), The finds of the Roman military equipment in Croatia, Zagreb, 221231.Google Scholar
Scheidel, W., Morris, I. and Saller, R. (eds.). 2007: The Cambridge economic history of the Greco-Roman world, Cambridge.CrossRefGoogle Scholar
Schibler, J., 2006: The economy and environment of the 4th and 3rd millennia BC in the northern Alpine foreland based on studies of animal bones, Environmental archaeology 11(1), 4964.CrossRefGoogle Scholar
Schibler, J., and Jacomet, S., 2010: Short climatic fluctuations and their impact on human economies and societies. The potential of the Neolithic lake shore settlements in the Alpine foreland, Environmental archaeology 15(2), 173182.CrossRefGoogle Scholar
Schibler, J., and Steppan, K., 1999: Human impact on the habitat of large herbivores in eastern Switzerland and southwest Germany in the Neolithic, Archaeofauna 8, 8799.Google Scholar
Schipanski, M.E., MacDonald, G.K., Rosenzweig, S., Chappell, M.J., Bennett, E.M., Bezner Kerr, R., Blesh, J., Crews, T., Drinkwater, L., Lundgren, J.G. and Schnarr, C., 2016: Realizing resilient food systems, BioScience 66 (7), 600610.CrossRefGoogle Scholar
Schwörer, C., Colombaroli, D. and Kaltenrieder, P., 2015: Early human impact (5000–3000 BC) affects mountain forest dynamics in the Alps, Journal of ecology 103(2), 281295.CrossRefGoogle Scholar
Sherratt, A., 1981: Plough and pastoralism. Aspects of the secondary products revolution, in Hodder, I., Isaac, G. and Hammond, N. (eds), Pattern of the past. Studies in honour of David Clarke, Cambridge, 261305.Google Scholar
Sherratt, A., 1983. The secondary exploitation of animals in the Old World, World archaeology 15, 90104.CrossRefGoogle Scholar
Sonnino, R., Tegoni, C.L.S. and Cunto, A. De, 2019: The challenge of systemic food change. Insights from cities, Cities 85, 110116.CrossRefGoogle Scholar
Spangenberg, J.E., Jacomet, S. and Schibler, J., 2006: Chemical analyses of organic residues in archaeological pottery from Arbon Bleiche 3, Switzerland. Evidence for dairying in the late Neolithic, Journal of archaeological science 33(1), 113.CrossRefGoogle Scholar
Spangenberg, J., Matuschik, I., Jacomet, S. and Schibler, J., 2008: Direct evidence for the existence of dairying farms in prehistoric Central Europe (4th millennium BC), Isotopes in environmental and health studies 44(2), 189200.CrossRefGoogle Scholar
Spencer-Wood, S.M., 2013: Nonlinear systems theory, feminism, and postprocessualism, Journal of archaeology, https://doi.org/10.1155/(2013)/540912.CrossRefGoogle Scholar
Springmann, M., Clark, M., Mason-D’Croz, D., Wiebe, K., Leon Bodirsky, B., Lassaletta, L., de Vries, W., Vermeulen, S.J., Herrero, M., Carlson, K.M., Jonell, M., Troell, M., DeClerck, F., Gordon, L.J., Zurayk, R., Scarborough, P., Rayner, M., Loken, B., Fanzo, J., Godfray, H.C.J., Tilman, D., Rockström, J. and Willett, W., 2018: Options for keeping the food system within environmental limits, Nature 562, 519525.CrossRefGoogle ScholarPubMed
Sugiyama, N. and Somerville, A.D., 2016: Feeding Teotihuacan. Integrating approaches to studying food and foodways of the ancient metropolis, Archaeological and anthropological science 9(1), 110.CrossRefGoogle Scholar
Sunseri, J., 2017: Grazing to gravy. Faunal remains and indications of Genízaro foodways on the Spanish colonial frontier of New Mexico, International journal of historical archaeology 21(3), 577597.CrossRefGoogle Scholar
Tainter, J.A., 1988: The collapse of complex societies. New studies in archaeology, Cambridge.Google Scholar
Tendall, D.M., Joerin, J., Kopainsky, B., Edwards, P., Shreck, A., Le, Q.B., Kruetli, P., Grant, M. and Six, J., 2015: Food system resilience. Defining the concept, Global food security 6, 1723.CrossRefGoogle Scholar
Termeer, C.J.A.M., Drimie, S., Ingram, J., Pereira, L. and Whittingham, M.J., 2018: A diagnostic framework for food system governance arrangements. The case of South Africa, NJAS. Wageningen journal of life sciences 84, 8593.CrossRefGoogle Scholar
Thünen, J. von, 1826: Der isolirte Staat in Beziehung auf Landwirthschaft und Nationalökonomie, oder Untersuchungen über den Einfluss, den die Getreidepreise, der Reichtum des Bodens und die Abgaben auf den Ackerbau ausüben, Berlin.Google Scholar
Tourigny, E., 2020: Foodways in historical archaeology, in Smith, C. (ed.), Encyclopedia of global archaeology, New York, at https://doi.org/10.1007/978-3-030-30018-0_3394 Google Scholar
Tripković, B., 2011: Containers and grains. Food storage and symbolism in the central Balkans (Vinča period), Documenta praehistorica 38, 159172.CrossRefGoogle Scholar
Twiss, K.C., 2007: The archaeology of food and identity, Carbondale.Google Scholar
Twiss, K., 2012: The archaeology of food and social diversity, Journal of archaeological research 20(4), 357395.CrossRefGoogle Scholar
Twiss, K.C., 2015: Methodological and definitional issues in the archaeology of food, in Kerner, S., Chou, C. and Warmind, M. (eds), Commensality. From everyday food to feast, London, 8998.CrossRefGoogle Scholar
Van der Leeuw, S., and Redman, C., 2002: Placing archaeology at the center of socio-natural studies, American antiquity 67(4), 597605.CrossRefGoogle Scholar
Van der Veen, M., 2008: Food as embodied material culture. Diversity and change in plant food consumption in Roman Britain, Journal of Roman archaeology 21, 83109.CrossRefGoogle Scholar
Van der Veen, M., 2014: The materiality of plants. Plant–people entanglements, World archaeology 46(5), 799812.CrossRefGoogle Scholar
VanDerwarker, A.M., and Wilson, G.D., 2016: The archaeology of food and warfare, Cham.CrossRefGoogle Scholar
Vita-Finzi, C., and Higgs, E.S., 1970: Prehistoric economy in the Mount Carmel area of Palestine. Site catchment analysis, Proceedings of the Prehistoric Society 36, 137.CrossRefGoogle Scholar
Volkmann, A., 2018: Methods and perspectives of geoarchaelogical site catchment analysis. Identification of palaeoclimate indicators in the Oder region from the Iron to Middle Ages, in Siart, C., Forbriger, M. and Bubenzer, O. (eds), Digital geoarchaeology, Cham, 2744.CrossRefGoogle Scholar
Wallace, M., and Charles, M., 2013: What goes in does not always come out. The impact of the ruminant digestive system of sheep on plant material, and its importance for the interpretation of dung-derived archaeobotanical assemblages, Environmental archaeology 18 (1), 1830.CrossRefGoogle Scholar
Weber, A. 1909: Über den Standort der Industrie, Tübingen (English edn: Alfred Weber’s theory of the location of industries (trans. C.J. Friedrich), Chicago, 1928).Google Scholar
Wesch-Klein, G., 2007: Recruits and veterans, in Erdkamp, P. (ed.), A companion to the Roman Army, London, 435450.CrossRefGoogle Scholar
Willerding, U., 1980: Zum Ackerbau der Bandkeramiker, in Krüger, T. and Stephan, H.G. (eds), Beiträge zur Archäologie Nordwestdeutschlands und Mitteleuropas. Materialhefte zur Ur- und Frühgeschichte Niedersachsens, 16, 421457.Google Scholar
Wilson, A.G., 2009: Approaches to quantifying Roman trade, in Bowman, A. and Wilson, A.G. (eds), Quantifying the Roman economy. Methods and problems, Oxford, 213249.CrossRefGoogle Scholar
Woolf, G. 2016: Only connect? Network analysis and religious change in the Roman world, Hélade. Revista de história antiga 2(2), 4358.Google Scholar
Zeder, M.A., 1991: Feeding cities. Specialized animal economy in the ancient Near East, Washington.Google Scholar
Zurek, M., Hebinck, A., Leip, A., Vervoort, J., Kuiper, M., Garrone, M., Havlík, P., Heckelei, T., Hornborg, S., Ingram, J., Kuijsten, A., Shutes, L., Geleijnse, J.M., Terluin, I., Van ’t Veer, P., Wijnands, J., Zimmermann, A. and Achterbosch, T., 2018: Assessing sustainable food and nutrition security of the EU food system. An integrated approach, Sustainability 10, 4271.CrossRefGoogle Scholar