Abstract
Spatial interaction (SI) is the process whereby entities at different points in physical space make contacts, demand/supply decisions or locational choices. The entities can be individuals or firms and the choices can include housing, jobs, production quantities, exports, imports, face-to-face contacts, schools, retail centres and activity centres. The first SI models can be grouped under the generic heading gravity models. Their main characteristic is that they model the behaviour of demand or supply segments, rather than that of individuals and firms. This article traces the development of these models from their inception in the early part of the twentieth century to the present. The key advances include the replacement of the gravity analogy by the more general concepts of entropy or information theory, a statistical framework commonly used in physics. With the arrival of the regional science paradigm over 50 years ago, a key challenge has been to broaden these models compared to those arising in spatial economics, thus arriving at a more inclusive probabilistic framework. These efforts are discussed here, as well as inclusion of geographical advances, embracing activities as generators of travel, time-geography, recognition of spatial interdependencies, and use of neuro-computing principles.
This is a preview of subscription content, log in via an institution to check access.
Access this chapter
Tax calculation will be finalised at checkout
Purchases are for personal use only
Preview
Unable to display preview. Download preview PDF.
References
Abrahamsson T, Lundqvist L (1999) Formulation and estimation of combined network equilibrium models with applications to Stockholm. Transportation Science 33: 80–100
Alonso W (1978) A theory of movement. In: Hansen NM (ed) Human settlements. Ballinger, Cambridge, MA
Anas A (1983) Discrete choice theory, information theory and the multinomial logit and gravity models. Transportation Research 17B: 13–23
Batten DF, Boyce DE (1986) Spatial interaction: Transportation and interregional commodity flow models. In: Nijkamp P (ed) Handbook of regional and urban economics, vol. I. Regional economics. North-Holland, Amsterdam
Ben-Akiva ME, Lerman SR (1985) Discrete choice analysis: Theory and application to travel demand. MIT Press, Cambridge, MA
Birkin M, Clarke G, Clarke M, Wilson AG (1996) Intelligent GIS. Location decisions and strategic planning. Geolnformation International, Cambridge
Borgers AWJ, Timmermans HJP (1987) Choice model specification, substitution and spatial structure effects: A simulation experiment. Regional Science and Urban Economics 17: 29–41
Borgers AWJ, Timmermans HJP (1988) A context-sensitive model of spatial choice behaviour. In: Golledge RG, Timmermans HJP (1988) (eds) Behavioural modelling in geography and planning. Croom Helm, London
Boyce DE, Bar-Gera H (2003) Validation of multiclass urban travel forecasting models combining origin-destination, mode and route choices. Journal of Regional Science 43: 517–540
Cambridge Systematics (1996) Scan of recent travel surveys. US Department of Transportation, Washington, DC
Boyce DE, Le Blanc LJ, Chon KS, Lee YJ, Lin KT (1983) Implementation and computational issues for combined models of location, destination, mode and route choice. Environment and Planning A 15: 1219–1230
Casetti E (1972) Generating models by the expansion method: Application to geographical research. Geographical Analysis 4: 81–91
Cesario FJ (1973) A note on the entropy model of trip distribution. Transportation Research 27:331–333
Cramer JS (1991) The logit model: An introduction for economists. Edward Arnold, London
Deardorff AV (1998) Determinants of bilateral trade: Does gravity work in a neoclassical world? In: Frankel JA (ed) The regionalization of the world economy. University of Chicago Press, Chicago
Erlander S (1980) Optimal spatial interaction and the gravity model (Lecture Notes in Economics and Mathematical Systems 173). Springer, Berlin Heidelberg New York
Erlander S, Stewart NF (1990) The gravity model in transportation analysis. VSP, Utrecht
Ettema DF, Timmermans HJP (1997) Activity-based approaches to travel analysis. Pergamon, Oxford
Evans SP (1973) A relationship between the gravity model for trip distribution and the transportation problem in linear programming. Transportation Research 7: 39–61
Fischer MM, Gopal S (1994) Artificial neural networks: A new approach to modelling interregional telecommunication flows. Journal of Regional Science 34: 503–527
Fischer MM, Hlavackova-Schindler K, Reismann M (1999) A global search procedure for parameter estimation in neural spatial interaction modelling. Papers in Regional Science 78: 119–134
Fischer MM, Leung Y (1998) A genetic-algorithms based evolutionary computational neural network for modelling spatial interaction data. Annals of Regional Science 32: 437–458
Fischer MM, Reismann M, Hlavackova-Schindler K (2003) Neural network modelling of constrained spatial interaction flows: Design, estimation and performance issues. Journal of Regional Science 43: 35–61
Fisk C, Brown GR (1975) A note on the entropy formulation of distribution models. Operational Research Quarterly 26: 755–758
Fotheringham AS (1983) Some theoretical aspects of destination choice and their relevance to production-constrained gravity models. Environment and Planning A 15: 1121–1132
Fotheringham AS (1986) Modelling hierarchical destination choice. Environment and Planning A 18: 401–418
Fotheringham AS (1988) Consumer store choice and choice set definition. Marketing Science 7:299–310
Fotheringham AS, Dignan T (1984) Further contributions to a general theory of movement. Annals of the Association of American Geographers 74: 620–633
Fotheringham AS, Knudsen DC (1986) Modeling discontinuous change in retailing systems: Extensions of the Harris-Wilson framework with results from a simulated urban retailing system. Geographical Analysis 18: 295–312
Fratar T (1954) Vehicular trip distribution by successive approximation. Traffic Quarterly 8: 53–65
Getis A (1991) Spatial interaction and spatial autocorrelation: A cross-product approach. Environment and Planning A: 1269–1277
Gould P (1991) Dynamic structures of geographic space. In: Brunn SD, Leinbach TR (eds) Collapsing space and time: Geographic aspects of communications and information. HarperCollins Academic, NY
Greenwood MJ, Sweetland D (1972) The determinants of migration between standard metropolitan areas. Demography 9: 665–681
Guldmann JM (1999) Competing destinations and intervening opportunities interaction models of intercity telecommunications flows. Papers in Regional Science 78: 179–194
Harris B, Wilson AG (1978) Equilibrium values and dynamics of attractiveness terms in production-constrained spatial interaction models. Environment and Planning A 10: 371–388
Heckscher E (1919) The effect of foreign trade on the distribution of income. Ekonomisk Tidskrift 21: 497–512
Hensher DA (2001) Travel behaviour research: The leading edge. Pergamon, Oxford
Hua C (1980) An exploration of the nature and rationale of a systemic model. Environment and Planning A 12: 1121–1132
Huff DL (1963) A probabilistic analysis of shopping center trade areas. Land Economics 39: 81–90
Johnston RJ (1973) On frictions of distance and regression coefficients. Area 5: 187–191
Isard W (1960) Methods of regional analysis. MIT Press, Cambridge
Karlqvist A, Marksjö B (1971) Statistical urban models. Environment and Planning 3: 83–98
Kullback S (1959) Information theory and statistics. Wiley, New York
Lakshmanan TR, Hansen WG (1966) A retail market potential model. Journal of the American Institute of Planners 31: 134–143
Linnemann H (1966) An econometric study of international trade flows. North-Holland, Amsterdam
Lesse PF (1982) A phenomenological theory of socio-economic systems with spatial interactions. Environment and Planning A 14: 869–888
Long W, Uris R (1971) Distance, intervening opportunities, city hierarchy, and air travel. Annals of Regional Science 5: 152–161
Mackett R (1994) Land use transportation models for policy analysis. Transportation Research Record 1466:71–78
Marble DF, Gou Z, Liu L (1997) Recent advances in the exploratory analysis of interregional flows in space and time. In: Kemp Z (ed) Innovations in GIS4. Taylor & Francis, London
Martinez F (1996) MUSSA: Land use model for Santiago City. Transportation Research Record 1552: 126–134
Meyer RJ, Eagle TC (1982) Context-induced parameter instability in a disaggregate-stochastic model of store choice. Journal of Marketing Research 19: 62–71
Mozolin M, Thill, JC, Usery EL (2000) Trip distribution forecasting with multilayer perceptron neural networks: A critical evaluation. Transportation Research B 34: 53–73
Ohlin BG (1933) Interregional and international trade. Harvard University Press, Cambridge, MA
Openshaw S (1993) Modelling spatial interaction using a neural net. In: Fischer MM, Nijkamp P (eds) Geographic information systems, spatial modelling and policy evaluation. Springer, Berlin Heidelberg New York
Ortuzar J, Willumsen LG (2001) Modelling transport. Wiley, Chichester New York
Pellegrini PA, Fotheringham AS, Lin G (1997) An empirical evaluation of parameter sensitivity to choice set definition in shopping destination choice models. Papers in Regional Science 76: 257–284
Reggiani A, Tritapepe T (2002) Neural networks and logit models applied to commuters’ mobility in the metropolitan area of Milan. In: Himanen V, Nijkamp P, Reggiani A (eds) Neural networks in transport applications. Ashgate, Aldershot
Roy JR, Lesse PF (1981) On appropriate microstate descriptions in entropy modelling. Transportation Research 5 15:85–96
Roy JR (1983) Estimation of singly-constrained spatial-interaction models. Environment and Planning B 10: 269–274
Roy JR (1985) On forecasting choice among dependent spatial alternatives. Environment and Planning B 12: 479–492
Roy JR, Lesse PF (1985) Entropy models with entropy constraints on aggregated events. Environment and Planning A 17: 1669–1674
Roy JR (1987) An alternative information theory approach for modelling spatial interaction. Environment and Planning A 19: 385–394
Roy JR (1990) Spatial interaction modelling: Some interpretations and challenges. Commentary, Environment and Planning A 22: 712–716
Roy JR (1999) Areas, nodes and networks. Papers in Regional Science 78: 135–155
Roy JR (2004) Spatial interaction modelling: A regional science context. Springer, Berlin Heidelberg New York
Schneider M (1959) Gravity models and trip distribution theory. Papers and Proceedings of the Regional Science Association 5: 51–56
Sen A, Smith TE (1995) Gravity models of spatial interaction behaviour. Springer, Berlin Heidelberg New York
Shannon CE (1948) A mathematical theory of communication. Bell System Technical Journal 27: 379–423; 623–656
Sheppard ES (1976) Entropy, theory construction and spatial analysis. Environment and Planning A 8: 741–752
Sheppard ES (1980) The ideology of spatial choice. Papers of the Regional Science Association 45: 197–213
Smith TE (1978) A cost-efficiency principle of spatial interaction behaviour. Regional Science and Urban Economics 8: 313–337
Smith TE (1989) A simple decision theory of spatial interaction: The Alonso model re-visited. Working Paper 135, Department of Regional Science, University of Pennsylvania
Smith TE (1990) Most-probable-state analysis: A method for testing probabilistic theories of population behaviour. In: Chatterji M, Kuenne RE (eds) New frontiers in regional science. MacMillan, London
Snickars F, Weibull JW (1977) A minimum information principle: Theory and practice. Regional Science and Urban Economics 7: 137–168
Stewart JQ (1941) An inverse distance variation for certain social distances. Science 93: 89–90
Stouffer SA (1940) Intervening opportunities: A theory relating mobility and distance. American Sociological Review 5: 845–867
Theil H (1967) Economics and information theory. North Holland, Amsterdam
Thill JC (1992) Choice set formation for destination choice modelling. Progress in Human Geography 16: 361–382
Thill JC (1995) Modeling store choices with cross-sectional and pooled cross-sectional data: A comparison. Environment and Planning A 27: 1303–1315
Thill JC, Horowitz JL (1997a) Travel-time constraints on destination choice sets. Geographical Analysis 29: 108–123
Thill JC, Horowitz JL (1997b) Modelling non-work destination choices with choice sets defined by travel-time constraints. In: Getis A, Fischer MM (eds) Recent developments in spatial analysis, spatial statistics, behavioural modelling and neurocomputing. Springer, Berlin Heidelberg New York
Thill JC, Mozolin M (2000) Feed-forward neural networks for spatial interaction: Are they trustworthy forecasting tools? In: Reggiani A (ed) Spatial economic science: New frontiers in theory and methodology. Springer, Berlin Heidelberg New York
Tinbergen J (1962) Shaping the world economy: Suggestions for an international economic policy. The Twentieth Century Fund, New York
Tobler W (1975) Spatial interaction: Extracting meaning from masses of data. In: Swain E (ed) The USA project on urban and regional systems. USA, Laxenburg
Wegener M (1994) Operational urban models: State of the art. Journal of the American Planning Association 60: 17–29
Wilson AG (1967) A statistical theory of spatial distribution models. Transportation Research 1:253–269
Wilson AG (1970) Entropy in urban and regional modelling. Pion, London
Zhang J, Kristensen G (1995) A gravity model with variable coefficients: The EEC trade with third countries. Geographical Analysis 27: 307–320
Author information
Authors and Affiliations
Editor information
Editors and Affiliations
Rights and permissions
Copyright information
© 2004 Springer-Verlag Berlin Heidelberg
About this chapter
Cite this chapter
Roy, J.R., Thill, JC. (2004). Spatial interaction modelling. In: Florax, R.J.G.M., Plane, D.A. (eds) Fifty Years of Regional Science. Advances in Spatial Science. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-662-07223-3_15
Download citation
DOI: https://doi.org/10.1007/978-3-662-07223-3_15
Publisher Name: Springer, Berlin, Heidelberg
Print ISBN: 978-3-642-06111-0
Online ISBN: 978-3-662-07223-3
eBook Packages: Springer Book Archive