Large and Deep Factor Models
Abstract
We show that a deep neural network (DNN) trained to construct a stochastic discount factor (SDF) admits a sharp additive decomposition that separates nonlinear characteristic discovery from the pricing rule that aggregates them. The economically relevant component of this decomposition is governed by a new object, the Portfolio Tangent Kernel (PTK), which captures the features learned by the network and induces an explicit linear factor pricing representation for the SDF. In population, the PTK-implied SDF converges to a ridge-regularized version of the true SDF, with the effective strength of regularization determined by the spectral complexity of the PTK. Using U.S. equity data, we show that the PTK representation delivers large and statistically significant performance gains, while its spectral complexity has risen sharply-by roughly a factor of six since the early 2000s-imposing increasingly tight limits on finite-sample pricing performance.
Keywords
Cite
@article{arxiv.2402.06635,
title = {Large and Deep Factor Models},
author = {Bryan Kelly and Boris Kuznetsov and Semyon Malamud and Teng Andrea Xu and Yuan Zhang},
journal= {arXiv preprint arXiv:2402.06635},
year = {2026}
}