Optimal Allocation of Police Patrol Resources Using a Continuous-Time Crime Model

Police departments worldwide are eager to develop better patrolling methods to manage the complex and evolving crime landscape. Surprisingly, the problem of spatial police patrol allocation to optimize expected crime response time has not been systematically addressed in prior research. We develop a bi-level optimization framework to address this problem. Our framework includes novel linear programming patrol response formulations. Bender's decomposition is then utilized to solve the underlying optimization problem. A key challenge we encounter is that criminals may respond to police patrols, thereby shifting the distribution of crime in space and time. To address this, we develop a novel iterative Bender's decomposition approach. Our validation involves a novel spatio-temporal continuous-time model of crime based on survival analysis, which we learn using real crime and police patrol data for Nashville, TN. We demonstrate that our model is more accurate, and much faster, than state-of-the-art alternatives. Using this model in the bi-level optimization framework, we demonstrate that our decision theoretic approach outperforms alternatives, including actual police patrol policies.

[1]  Nicole White,et al.  Seasonal Patterns in Criminal Victimization Trends , 2014 .

[2]  Christopher S. Koper,et al.  Just enough police presence: Reducing crime and disorderly behavior by optimizing patrol time in crime hot spots , 1995 .

[3]  R. Kay The Analysis of Survival Data , 2012 .

[4]  Marek Chrobak,et al.  New results on server problems , 1991, SODA '90.

[5]  Milind Tambe,et al.  Keeping Pace with Criminals: Designing Patrol Allocation Against Adaptive Opportunistic Criminals , 2015, AAMAS.

[6]  Wilpen L. Gorr,et al.  Leading Indicators and Spatial Interactions: A Crime‐Forecasting Model for Proactive Police Deployment , 2007 .

[7]  Tim Hope,et al.  PROBLEM-ORIENTED POLICING AND DRUG-MARKET LOCATIONS: THREE CASE STUDIES , 2006 .

[8]  Patricia L. Brantingham,et al.  Patterns in Crime , 1984 .

[9]  Alan T. Murray,et al.  Exploratory Spatial Data Analysis Techniques for Examining Urban Crime , 2001 .

[10]  George E. Tita,et al.  Self-Exciting Point Process Modeling of Crime , 2011 .

[11]  Gary Higgs,et al.  The Dynamic Spatial Disaggregation Approach: A Spatio-Temporal Modelling of Crime , 2007, World Congress on Engineering.

[12]  P. Speer,et al.  Violent Crime and Alcohol Availability: Relationships in an Urban Community , 1998, Journal of public health policy.

[13]  Darin J Erickson,et al.  Is the density of alcohol establishments related to nonviolent crime? , 2012, Journal of studies on alcohol and drugs.

[14]  Daniel Fridman,et al.  The Seasonality of Violent Crime: The Case of Robbery and Homicide in Israel , 1993 .

[15]  Andrea L. Bertozzi,et al.  c ○ World Scientific Publishing Company A STATISTICAL MODEL OF CRIMINAL BEHAVIOR , 2008 .

[16]  Marcus Felson,et al.  Simple indicators of crime by time of day , 2003 .

[17]  BRIT. J. Criminol WEATHER AND CRIME , 2005 .

[18]  Marcin Kaminski,et al.  Linear Optimization , 2017, Encyclopedia of GIS.

[19]  Milind Tambe,et al.  Using Abstractions to Solve Opportunistic Crime Security Games at Scale , 2016, AAMAS.

[20]  Eric L. Piza,et al.  Risk Clusters, Hotspots, and Spatial Intelligence: Risk Terrain Modeling as an Algorithm for Police Resource Allocation Strategies , 2011 .

[21]  Edward R. Kleemans,et al.  Repeat Burglary Victimization. Results of Empirical Research in the Netherlands , 2001 .