Customer mobility and congestion in supermarkets

The analysis and characterization of human mobility using population-level mobility models is important for numerous applications, ranging from the estimation of commuter flows in cities to modeling trade flows between countries. However, almost all of these applications have focused on large spatial scales, which typically range between intracity scales and intercountry scales. In this paper, we investigate population-level human mobility models on a much smaller spatial scale by using them to estimate customer mobility flow between supermarket zones. We use anonymized, ordered customer-basket data to infer empirical mobility flow in supermarkets, and we apply variants of the gravity and intervening-opportunities models to fit this mobility flow and estimate the flow on unseen data. We find that a doubly-constrained gravity model and an extended radiation model (which is a type of intervening-opportunities model) can successfully estimate 65%-70% of the flow inside supermarkets. Using a gravity model as a case study, we then investigate how to reduce congestion in supermarkets using mobility models. We model each supermarket zone as a queue, and we use a gravity model to identify store layouts with low congestion, which we measure either by the maximum number of visits to a zone or by the total mean queue size. We then use a simulated-annealing algorithm to find store layouts with lower congestion than a supermarket's original layout. In these optimized store layouts, we find that popular zones are often in the perimeter of a store. Our research gives insight both into how customers move in supermarkets and into how retailers can arrange stores to reduce congestion. It also provides a case study of human mobility on small spatial scales.

[1]  Iain Borden,et al.  Environment and Planning b: Planning and Design , 1998 .

[2]  Peter S. Fader,et al.  Path Data in Marketing: An Integrative Framework and Prospectus for Model-Building , 2007, Mark. Sci..

[3]  P. Moran,et al.  Reversibility and Stochastic Networks , 1980 .

[4]  Alexandre Arenas,et al.  Optimal network topologies for local search with congestion , 2002, Physical review letters.

[5]  M. Batty,et al.  Gravity versus radiation models: on the importance of scale and heterogeneity in commuting flows. , 2012, Physical review. E, Statistical, nonlinear, and soft matter physics.

[6]  N. F. Stewart,et al.  The Gravity Model in Transportation Analysis - Theory and Extensions , 1990 .

[7]  Maxime Lenormand,et al.  Systematic comparison of trip distribution laws and models , 2015, 1506.04889.

[8]  S. S. Manna,et al.  Phase transition in a directed traffic flow network. , 2005, Physical review. E, Statistical, nonlinear, and soft matter physics.

[9]  James A. Pooler,et al.  The development of an intervening opportunities model with spatial dominance effects , 2001, J. Geogr. Syst..

[10]  Earl R. Ruiter,et al.  Toward a better understanding of the intervening opportunities model , 1967 .

[11]  Kenneth Dixon,et al.  Introduction to Stochastic Modeling , 2011 .

[12]  T. R. Anderson Intermetropolitan Migration: A Comparison of the Hypotheses of Zipf and Stouffer , 1955 .

[13]  C. D. Gelatt,et al.  Optimization by Simulated Annealing , 1983, Science.

[14]  Steven R. Bishop,et al.  A mathematical model of the London riots and their policing , 2013, Scientific Reports.

[15]  Sang Hoon Lee,et al.  Matchmaker, Matchmaker, Make Me a Match: Migration of Populations via Marriages in the Past , 2013, bioRxiv.

[16]  James E. Anderson A Theoretical Foundation for the Gravity Equation , 1979 .

[17]  A Díaz-Guilera,et al.  Communication in networks with hierarchical branching. , 2001, Physical review letters.

[18]  U. Brandes A faster algorithm for betweenness centrality , 2001 .

[19]  J. Bergstrand The Gravity Equation in International Trade: Some Microeconomic Foundations and Empirical Evidence , 1985 .

[20]  Nathan Eagle,et al.  Limits of Predictability in Commuting Flows in the Absence of Data for Calibration , 2014, Scientific Reports.

[21]  J. Perelló,et al.  Active and reactive behaviour in human mobility: the influence of attraction points on pedestrians , 2015, Royal Society Open Science.

[22]  T. Wassmer 6 , 1900, EXILE.

[23]  Fahui Wang,et al.  Measures of Spatial Accessibility to Health Care in a GIS Environment: Synthesis and a Case Study in the Chicago Region , 2003, Environment and planning. B, Planning & design.

[24]  Toru Ohira,et al.  PHASE TRANSITION IN A COMPUTER NETWORK TRAFFIC MODEL , 1998 .

[25]  T. S. Evans,et al.  Predictive limitations of spatial interaction models: a non-Gaussian analysis , 2019, Scientific Reports.

[26]  Mason A. Porter,et al.  Random walks and diffusion on networks , 2016, ArXiv.

[27]  Marta C. González,et al.  A universal model for mobility and migration patterns , 2011, Nature.

[28]  Henry Charles Carey,et al.  Principles of social science , 1888 .

[29]  F. Calabrese,et al.  Urban gravity: a model for inter-city telecommunication flows , 2009, 0905.0692.

[30]  Guillaume Deffuant,et al.  A Universal Model of Commuting Networks , 2012, PloS one.

[31]  Peter S. Fader,et al.  Research Note - The Traveling Salesman Goes Shopping: The Systematic Deviations of Grocery Paths from TSP Optimality , 2009, Mark. Sci..

[32]  Michael Batty,et al.  Measuring accessibility using gravity and radiation models , 2018, Royal Society Open Science.

[33]  Mauricio Barahona,et al.  Great cities look small , 2015, Journal of The Royal Society Interface.

[34]  M. Barthelemy,et al.  Human mobility: Models and applications , 2017, 1710.00004.

[35]  W. Deming,et al.  On a Least Squares Adjustment of a Sampled Frequency Table When the Expected Marginal Totals are Known , 1940 .

[36]  Helbing,et al.  Social force model for pedestrian dynamics. , 1995, Physical review. E, Statistical physics, plasmas, fluids, and related interdisciplinary topics.

[37]  Ericka Stricklin-Parker,et al.  Ann , 2005 .

[38]  John U. Farley,et al.  A Stochastic Model of Supermarket Traffic Flow , 1966, Oper. Res..

[39]  Alan Wilson,et al.  Entropy in urban and regional modelling , 1972, Handbook on Entropy, Complexity and Spatial Dynamics.

[40]  Scott A. Hale,et al.  Estimating local commuting patterns from geolocated Twitter data , 2017, EPJ Data Science.

[41]  Morton Schneider,et al.  GRAVITY MODELS AND TRIP DISTRIBUTION THEORY , 2005 .

[42]  G. Zipf The P 1 P 2 D Hypothesis: On the Intercity Movement of Persons , 1946 .

[43]  J. Pooler,et al.  An Intervening Opportunities Model of U.S. Interstate Migration Flows , 2016 .

[44]  Nong Ye,et al.  Onset of traffic congestion in complex networks. , 2005, Physical review. E, Statistical, nonlinear, and soft matter physics.

[45]  Z. Néda,et al.  Human Mobility in a Continuum Approach , 2012, PloS one.

[46]  Margaret Nichols Trans , 2015, De-centering queer theory.

[47]  B. M. Fulk MATH , 1992 .

[48]  J. Little A Proof for the Queuing Formula: L = λW , 1961 .

[49]  Universiṭat Ben-Guryon ba-Negev. Maḥlaḳah le-geʾografyah,et al.  Geography research forum , 1984 .

[50]  Shengyong Chen,et al.  Traffic Dynamics on Complex Networks: A Survey , 2012 .

[51]  M. Mézard,et al.  Journal of Statistical Mechanics: Theory and Experiment , 2011 .

[52]  S. Stouffer Intervening opportunities: a theory relating mobility and distance , 1940 .

[53]  Michael T. Gastner,et al.  The complex network of global cargo ship movements , 2010, Journal of The Royal Society Interface.

[54]  E. Todeva Networks , 2007 .

[55]  H. Stanley,et al.  Gravity model in the Korean highway , 2007, 0710.1274.