How to detect a salami slicer: a stochastic controller-stopper game with unknown competition

Abstract

We consider a stochastic game of control and stopping specified in terms of a process Xt=-θ t+Wt, representing the holdings of Player 1, where W is a Brownian motion, θ is a Bernoulli random variable indicating whether Player 2 is active or not, and is a non-decreasing process representing the accumulated "theft" or "fraud" performed by Player 2 (if active) against Player 1. Player 1 cannot observe θ or directly, but can merely observe the path of the process X and may choose a stopping rule τ to deactivate Player 2 at a cost M. Player 1 thus does not know if she is the victim of fraud and operates in this sense under unknown competition. Player 2 can observe both θ and W and seeks to choose the fraud strategy that maximizes the expected discounted amount \[ E [θ∫ 0τ e-rs ds ],\] whereas Player 1 seeks to choose the stopping strategy τ so as to minimize the expected discounted cost \[ E [θ∫ 0τ e-rs ds + e-rτM I\τ<∞\ ].\] This non-zero-sum game appears to be novel and is motivated by applications in fraud detection; it combines filtering (detection), non-singular control, stopping, strategic features (games) and asymmetric information. We derive Nash equilibria for this game; for some parameter values we find an equilibrium in pure strategies, and for other parameter values we find an equilibrium by allowing for randomized stopping strategies.