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Dynamic Simulation of Community Crime and Crime-Reporting Behavior. Michael Yonas , Jeffrey Borrebach , Jessica Burke, Shawn Brown, Richard Garland, Katherine Philp , Donald Burke, and John Grefenstette Graduate School of Public Health University of Pittsburgh ISSH 2011 May 26 2011.
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Dynamic Simulation of Community Crime and Crime-Reporting Behavior Michael Yonas, Jeffrey Borrebach, Jessica Burke, Shawn Brown, Richard Garland, Katherine Philp, Donald Burke, and John Grefenstette Graduate School of Public Health University of Pittsburgh ISSH 2011 May 26 2011
Community Crime and Public Health Violence is 2nd leading cause of death for youth ages 15-24 Leading cause of death for African American youth Community interventions include encouraging citizens and victims to report crime However, approximately half of violent crimes go unreported We are developing models to examine and evaluate potential community crime intervention strategies
Background: Collective Efficacy • Collective efficacy refers to the effectiveness of informal mechanisms by which residents achieve public order (Sampson et at, Science 1997) • A key mechanism influencing interpersonal violence in a neighborhood • Contrasts with formally or externally induced actions • e.g. police intervention, administrative programs • Examples • monitoring children's play groups • willingness to intervene against truancy, loitering • Local intervention to control social disorder, such as graffiti
Research Questions Q1: How do these factors operate in a dynamic environment? Q2: Can we capture other theoretical constructs in a spatially explicit model (i.e., dynamics of neighborhood contagion)? Q3: Can we develop metrics to permit comparison and evaluation of possible intervention programs prior to implementation? Q4: Can modeling approach help us develop novel community intervention programs to increase collective efficacy? In addition, can a modeling approach be used as a tool to cultivate community-partnered research (community-based participatory research (CBPR))?
Why Use an Agent-Based Model? • Collective efficacy depends on individual decisions and actions • Capture effects of individual experience • change in attitude of witnesses or victims • change in attitude of offenders due to punishment (or not) • Reflect influence of interpersonal relationships • family, friends, community • Engage respected members of the neighborhood • victims and friends of victims
Agents in the Model • Adults • do not commit offenses in this model • may witness a nearby incident • may report a witnessed incident • Juveniles • may commit an offense • if reported, may receive punishment • assumed to reduce likelihood to offend in future
Community Model • Two-dimensional space (100 x 100 toroid – wraps around) • 1000 Agents • 90% adults • 10% juveniles • similar to Pittsburgh, PA • Community is subdivided into 25 blocks to measure geographic statistics Blocks are different colors to aid visualization Agents are colored to show their current activity
Crime Reporting Behavior for Adults • Have a fixed home location • May witness incidents near their home • each adult i has a probability of witnessing pwitness,i • May report incidents they witness • each adult i has a probability of reporting preport,i • Both probabilities are drawn from uniform random distributions, such that • 50% of incidents are witnessed • 50% of witnessed incidents are reported
Offending Behaviors for Juveniles • Based on Theory of Reasoned Action (Ajzen, 1980): • if perceived reward > perceived risk, then take action • Perceived reward assigned randomly to individuals • and declines with age • Perceived risk depends on experience: • Initial values assigned randomly to individuals • If an offense is committed and is punished, perceived risk increases • If an offense is committed and is not punished, perceived risk decreases • Juveniles may move through the community • attracted toward areas associated with unpunished offenses
Daily Time Step of Simulation • Each juvenile moves a small distance • attracted toward areas of high opportunity • Each juvenile decides whether to commit an offense • based on the individual's current preceived risk and reward • Each adult probabilistically witnesses any nearby offense • based on the individual's current witnessing probability • Witnesses decide whether to report each offense • based on the individual's current reporting probability • If an offender is reported, he/she may received punishment with a global probability of punishment • If an offender is punished, increase perceived risk • If an offender is not punished, decrease perceived risk
Movement of Juvenile Agents • Assumptions: • They share information about detection risks at locations • Offenders prefer locations with low risk of consequences • Mechanisms: • Each location has an associated "opportunity index" • increases if there are unpunished offenses in the nearby surrounding area • decreases otherwise • Each offender moves each time step: • 50% chance of random direction • 50% chance of moving to the highest opportunity location within a few steps of current location
Visualization of current agent activity • Blue = adult, not witnessing • Yellow = witnessing, not reporting • Green = witness and reporting • White = offender not being reported • Red = offender being reported • Orange = offender being reported punished
Calibrating the Offenders Pathways to Desistance Study (Shubert and Mulvey, 2011) • Longitudinal survey of N = 1,354 active juvenile offenders over a three-year period • Collected self-reported frequency of offenses, perceived rewards, perceived risk, at 6 month intervals • Analysis explored differences in risk perception based on prior offending experience • Did perceptions shift as the result of arrest?
Risk, Reward Perception by Offender Frequency Observations(Shubert and Mulvey, 2011) The most frequent offenders perceived significantly less risk and more reward from crime than those with medium frequency of offenses Less frequent offenders perceived significantly more risk and less reward Individuals decrease the level of perceived risk when offending is undetected or avoids punishment Individuals tend to increase the level of perceived risk when they are arrested As individuals age, perceived reward appears to decrease for all levels of offender frequency
Risk, Reward in the Model: Step 1 – Fixed individual levels • Assume each offender has random level of perceived risk and reward • drawn from U(0.25, 0.75) • Assume no changes due to detection or punishment • Result: More frequent offenders perceive less risk and more reward than less frequent offenders • Plots show mean of 5 runs of simulation
Risk, Reward in the Model: Step 2 – Getting away with it • Assume individuals decrease their perceived risk when offense is undetected or avoids punishment: riski = riski + a, where a > 0 For example: a = 0.0002 * riski • Result: More frequent offenders reduce their perceived risk over time more than less frequent offenders • Plots show mean of 5 runs of simulation
Risk, Reward in the Model: Step 3 – Effects of punishment • Assume individuals increase perceived risk when punished: riski = riski – b, where b > 0 for example, b = 0.005 * riski • Result: More frequent offenders increase their perceived risk over time more than less frequent offenders • Plots show mean of 5 runs of simulation
Risk, Reward in the Model: Step 4 – Rewards decline with age • Assume individuals decrease perceived reward over time, for all levels of offenders rewardi = rewardi – c, where c > 0 for example, c = 0.00025 * rewardi • Result: More frequent offenders increase their perceived risk over time more than less frequent offenders • Plots show mean of 5 runs of simulation
Calibrated Model Shubert and Mulvey, 2011 Simulation Data
Community Interventions to Enhance Collective Efficacy • Enhancing Witness Ability • Improved street lighting • Encouraging neighborhood outdoor activity • Enhancing Reporting • Police hotlines • Anonymous reporting systems • Phone trees • Enhancing Offender Intervention • Intervention groups • Parent education
Geographic Heterogeneity • Like real neighborhoods, the blocks within the model community vary in several factors • number of adults • density of houses • individual differences in probability of witnessing and of reporting • These factors lead to block-level differences in incidence rates and punishment rates • As a result, some area are expected to attract offenders who seek low risk areas
Visualization of Patch Incidence Levels Colored irregular regions are associated with high numbers of recent incidents. Offenders follow local gradients of "high opportunity", leading to clustering offenses.
Spatial distributions of incidents (a) (b) (c) Incident Level by Block, showing heterogeneity Histogram of perceived opportunity, splits into high- and low-opportunity areas Histogram of Offense Level per location, results from perceived opportunity distribution
Comparing Community Intervention Programs • Control: no intervention • Global Intervention • Select T% of adults from the entire community, and influence them to always witness and report nearby offenses • Targeted Intervention • Select T% of adults from the area surrounding the blocks with the highest number of offenses, and influence them to always witness and report nearby offenses
Which intervention works best? What is "best"? ....
Which intervention works best? Targeted intervention provides more saturated reporting opportunities, and may be more effective at reduce offenses than global intervention Global intervention may affect more offenders Targeted intervention may encourage offenders to move to other neighborhoods Which methods has the largest effect?
Experimental Design • Three interventions: • Global • Targeted • None (control) • Each intervention activated the same number of adults • Always witness nearby offenses • Always report witness offsenses • Offenders reported by activated witness are always punished • Measurements: • Overall number of offenses post intervention • The distance moved by offenders affected by the intervention • those offenders who are reported by activated adults • 20 runs of 270 days, with intervention starting on day 90
Intervention Effects Conclusions: Global and targeted intervention reduce overall offenses Targeted intervention may have a larger effect on the targeted offenders Targeted intervention leads to offenders moving to surrounding area
Effects of Target Radius and Percent Activated For target radius = 20 or 30, no significant difference in offenses after global or targeted interventions, over activated range of 1% - 5% For activated range > 2%, targeted intervention with radius 20 result in significant movement of offenders to neighboring blocks With larger target radius, targeted intervention approaches global intervention effects on offender movement
Discussion: Future Extensions • More detailed behavior for both witnesses and offenders • Interpersonal offenses and retaliatory behavior • Detailed social networks • e.g., friends and families • Explicit elements of the law enforcement system • e.g., increasing police presence in neighborhoods experiencing high crime rates • Turnover in the population • New offenders become active as others retire • Inter-neighborhood movement of people
Discussion: Conclusions • Models can serve as a useful tool for confirming and generating(?) behavioral theory • Models can provide useful insights into which interventions at the neighborhood level might be most effective in reducing the presence of crime in a community • Models provide a tool for engaging diverse expertise in understanding and preventing crime and violence
Discussion: Lessons Learned Importance of developing a common language Involvement of community partner Finding data against which to validate agent-based model is a challenge!
References 1. Center for Disease Control and Prevention, National Center for Injury Prevention and Control. Web-based Injury Statistics Query and Reporting System (WISQARS) [accessed 2010 June 14]: www.cdc.gov/injury/wisqars/ 2. Center for Disease Control and Prevention, National Center for Injury Prevention and Control. Web-based Injury Statistics Query and Reporting System (WISQARS), Youth Violence Data Sheet [accessed 2010 June 14]:www.cdc.gov/violenceprevention/pdf/YV-DataSheet-a.pdf 3. Kellerman, A.L., Fuqua-Whitley, D.S., Rivara, F.P., Mercy, J.: Preventing Youth Violence: What Works? Annual Review of Public Health 19, 271-292 (1998) 4. National Youth Violence Prevention Resource Center (NYVPRC): www.safeyouth.gov/Resources/Prevention/Pages/PreventionStrategies.aspx 5. Anderson, E.: Code of the Street: Decency, Violence and the Moral Life of the Inner City. Norton, New York (1999) 6. Earls, F. J.: Violence and Todays Youth: Critical Health Issues for Children and Youth. Future of Children 4(3), 4-23 (1994) 7. Sampson, R. J., Raudenbush, S. W., Earls, F.: Neighborhoods and Violent Crime: A Multilevel Study of Collective Efficacy. Science 277, 918-924 (1997) 8. Taylor, R. B., Gottfredson, S. D., Brower, S.: Understanding Block Crime and Fear. Journal of Research in Crime and Delinquency 21, 303-331 (1984) 9. Wilson, J.M., Chermak, S., McGarrell, E.F.: Community-Based Violence Prevention: An Assessment of Pittsburgh's One Vision One Life Program. RAND Corp.,Santa Monica, CA (2010) 10. Bibb, M.: Gang Related Services of Mobilization for Youth. In: Klein, M.W. (ed) Juvenile Gangs in Context: Theory, Research, and Action. Prentice-Hall, Englewood Clis, NJ (1967) 11. Bennett, T.H., Holloway, K.R., Farrington, D.P.: Effectiveness of Neighborhood Watch in Reducing Crime. National Council on Crime Prevention, Stockholm (2008) 12. Reiss, A.J., Roth, J.A.: Measuring Violent Crime and Their Consequences. In: Understanding and Preventing Violence, pp. 404-429. National Research Council, National Academy Press (1993)
Acknowledgments Supported by the National Institute of General Medical Sciences MIDAS grant 1U54GM088491-01 Richard Garland, Executive Director for One Vision One Life (Pittsburgh, PA)
Preliminary Model Dynamics Effects of Witness Rate on Incidence Effects of Reporting Rate on Incidence Effects of Punishment Rate on Incidence Purpose: check the internal consistency and face validity of model
Discussion: Boundaries of the Model • Exogenous Parameters • Proportion of adults, juveniles • Probability of offenses being reporting • Initial decision probabilities for adults and juveniles • unknown, need to test sensitivity • Endogenous Parameters • Change is incident rates over time • Changes in spatial distributions of incidents • Effects of community interventions • Important Excluded Parameters • Social capital • Socio-economic status • Individual prior history • Social networks • Law enforcement policies • Realistic risk-reward assessment by potential offenders
Testing Model Dynamics: Witness Rate Assumes all witnessed offenses are reported
Targeted Intervention: Offenders Move to Adjacent Areas Click to play
Testing Model Dynamics: Report Rate Assumes are offenses are witnessed
Testing Model Dynamics: Punishment Rate Assumes all offenses are witnessed and reported