A Crime/S.I.R. optimal control problem

Abstract

This paper presents and discusses a mathematical model inspired by control theory to derive optimal public policies for minimizing costs associated with the reduction and control of criminal activity in a population. Specifically, we analyze the optimal control problem equation* G(u1, u2, u3) = ∫0tF ( I(t) - R(t) + B12 u12(t) + B22 u22(t) + B32 u32(t) ) \, dt. equation* where I=I(t) and R=R(t) satisfies the system of equations equation* \ aligned S &= Λ- (1-u1)SI - μS + ((1+u3)γ2)I + ρΩR,\\ I &= (1-u1)SI - (μ+ δ1)I - ((1+u2)γ1)I - ((1+u3)γ2)I + (1-Ω)ρR,\\ R &= ((1+u2)γ1)I - (μ+ δ2 + ρ)R. aligned . equation* Our approach assumes that the social and economic effects of criminal behavior can be modeled by a dynamic SIR-type system, which serves as a constraint on a cost functional associated with the strategies implemented by government and law enforcement authorities to reduce criminal behavior. Using optimal control theory, the proposed controls, i.e., preventive policies (such as community and social cohesion programs), are expected to have a significant and positive impact on crime reduction, generating opportunities for the most disadvantaged sectors of Cali society and contributing to long-term security. Given that resources to address this problem are limited, this research aims to determine an optimal combination of public interventions and policies that minimize criminality at the lowest possible economic cost, using an SIR model, tools from variational calculus, and optimal control theory.