1 / 18

A Statistical Model of Criminal Behavior

A Statistical Model of Criminal Behavior. M.B. Short, M.R. D’Orsogna, V.B. Pasour, G.E. Tita, P.J. Brantingham, A.L. Bertozzi, L.B. Chayez. Maria Pavlovskaia. Goal. Model the behavior of crime hotspots Focus on house burglaries. Assumptions. Criminals prowl close to home

Download Presentation

A Statistical Model of Criminal Behavior

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. A Statistical Model of Criminal Behavior M.B. Short, M.R. D’Orsogna, V.B. Pasour, G.E. Tita, P.J. Brantingham, A.L. Bertozzi, L.B. Chayez Maria Pavlovskaia

  2. Goal • Model the behavior of crime hotspots • Focus on house burglaries

  3. Assumptions • Criminals prowl close to home • Repeat and near-repeat victimization

  4. The Discrete Model • A neighborhood is a 2d lattice • Houses are vertices • Vertices have attractiveness values Ai • Criminals move around the lattice

  5. Criminal Movement A criminal can: • Rob the house he is at - or - • Move to an adjacent house • Criminals regenerate at each node

  6. Criminal Movement • Modeled as a biased random walk

  7. Attractiveness Values • Rate of burglary when a criminal is at that house • Has a static and a dynamic component • Static (A0) - overall attractiveness of the house • Dynamic (B(t)) - based on repeat and near-repeat victimization

  8. Dynamic Component • When a house s is robbed, Bs(t) increases • When a neighboring house s’ is robbed, Bs(t) increases • Bs(t) decays in time if no robberies occur

  9. Dynamic Component • The importance of neighboring effects:  • The importance of repeat victimization:  • When repeat victimization is most likely to occur:  • Number of burglaries between t and t: Es(t)

  10. Computer Simulations

  11. Computer Simulations Three Behavioral Regimes are Observed: • Spatial Homogeneity • Dynamic Hotspots • Stationary Hotspots

  12. Spatial Homogeneity Dynamic Hotspots Stationary Hotspots

  13. Computer Simulations Three Behavioral Regimes are Observed: • Spatial Homogeneity • Large number of criminals or burglaries • Dynamic Hotspots • Low number of criminals and burglaries • Manifestation of the other two regimes due to finite size effects • Stationary Hotspots • Large number of criminals or burglaries

  14. Continuum Limit In the limit as the time unit and the lattice spacing becomes small: • The dynamic component of attractiveness: • The criminal density:

  15. Continuum Limit • Reaction-diffusion system • Dimensionless version is similar to: • Chemotaxis models in biology (do not contain the time derivative) • Population bioglogy studies of wolfe and coyote territories

  16. Computer Simulations • Dynamic Hotspots are never seen • Spatial Homogeneity or Stationary Hotspots? • Performed linear stability analysis • Found an inequality to distinguish between the cases

  17. Summary • Discrete Model • Computer Simulations • Spatial Homogeneity, Dynamic Hotspots, Stationary Hotspots • Continuum Limit • Dynamic Hotspots are not observed: due to finite size effects • Inequality to distinguish between Homogeneity and Hotspots cases

  18. Applications • House burglaries • Assault with a lethal weapon • Muggings • Terrorist attacks in Iraq • Lootings

More Related