Analysis of the Generalization Error: Empirical Risk Minimization over Deep Artificial Neural Networks Overcomes the Curse of Dimensionality in the Numerical Approximation of Black-Scholes Partial Differential Equations

TL;DR

This paper demonstrates that empirical risk minimization over deep neural networks can efficiently approximate solutions to high-dimensional Kolmogorov equations, effectively overcoming the curse of dimensionality in numerical PDE solutions.

Contribution

It provides theoretical conditions under which deep learning-based ERM approximates high-dimensional PDE solutions with polynomial complexity in dimension and accuracy.

Findings

ERM over deep neural networks achieves polynomial scaling in dimension and error.

Deep learning methods overcome the curse of dimensionality for Kolmogorov equations.

High-probability approximation guarantees are established for neural network solutions.

Abstract

The development of new classification and regression algorithms based on empirical risk minimization (ERM) over deep neural network hypothesis classes, coined deep learning, revolutionized the area of artificial intelligence, machine learning, and data analysis. In particular, these methods have been applied to the numerical solution of high-dimensional partial differential equations with great success. Recent simulations indicate that deep learning-based algorithms are capable of overcoming the curse of dimensionality for the numerical solution of Kolmogorov equations, which are widely used in models from engineering, finance, and the natural sciences. The present paper considers under which conditions ERM over a deep neural network hypothesis class approximates the solution of a $d$-dimensional Kolmogorov equation with affine drift and diffusion coefficients and typical initial values arising from problems in computational finance up to error $\varepsilon$. We establish that, with high probability over draws of training samples, such an approximation can be achieved with both the size of the hypothesis class and the number of training samples scaling only polynomially in $d$ and $\varepsilon^{-1}$. It can be concluded that ERM over deep neural network hypothesis classes overcomes the curse of dimensionality for the numerical solution of linear Kolmogorov equations with affine coefficients.