Monte Carlo on a single sample

Abstract

In this paper, we consider a Monte Carlo simulation method (MinMC) that approximates prices and risk measures for a range of model parameters at once. The simulation method that we study has recently gained popularity [HS20, FPP22, BDG24], and we provide a theoretical framework and convergence rates for it. In particular, we show that sample-based approximations to Eθ[X], where θ denotes the model and Eθ the expectation with respect to the distribution Pθ of the model θ, can be obtained across all θ ∈ by minimizing a map V:H→ R with H a suitable function space. The minimization can be achieved easily by fitting a standard feedforward neural network with stochastic gradient descent. We show that MinMC, which uses only one sample for each model, significantly outperforms a traditional Monte Carlo method performed for multiple values of θ, which are subsequently interpolated. Our case study suggests that MinMC might serve as a new benchmark for parameter-dependent Monte Carlo simulations, which appear not only in quantitative finance but also in many other areas of scientific computing.