English

Gaussian Cumulative Prospect Theory

Probability 2025-05-06 v1

Abstract

We propose a novel parametrization of Cumulative Prospect Theory (CPT), as developed by Daniel Kahneman and Amos Tversky, that yields an explicit gamble valuation formula for Gaussian reward distributions. Specifically, we define parametric functions vθ v_{\theta} , wθ w^{-}_{\theta} , and wθ+ w^{+}_{\theta} satisfying three key properties. The first, \emph{validity}, ensures that for any parameter θ\theta, the functions conform to the qualitative principles of CPT: vθ v_{\theta} is concave over gains and convex over losses with a steeper slope for losses; wθ w^{-}_{\theta} and wθ+ w^{+}_{\theta} are increasing, exhibit inverse S-shaped curves, and map 0 to 0 and 1 to 1. The second, \emph{richness}, guarantees that the parametrization is expressive enough to capture a wide range of behaviors: vθ v_{\theta} can exhibit arbitrary asymptotic behavior and convergence rates, while wθ w^{-}_{\theta} and wθ+ w^{+}_{\theta} can achieve any specified crossover points and slopes. The third, \emph{explicit valuation}, ensures that for any θ\theta, the CPT valuation of a Gaussian-distributed gamble (with arbitrary mean and variance) can be computed in closed form -- enabling efficient approximations for bell-shaped reward distributions. This framework is designed for scalable and rapid computation, making it particularly suited for applications involving large populations. We demonstrate its practicality through two illustrative examples in population-level CPT modeling.

Keywords

Cite

@article{arxiv.2505.02267,
  title  = {Gaussian Cumulative Prospect Theory},
  author = {Mederic Motte},
  journal= {arXiv preprint arXiv:2505.02267},
  year   = {2025}
}
R2 v1 2026-06-28T23:20:52.407Z