A Fully Analog Pipeline for Portfolio Optimization
Abstract
Portfolio optimization is a ubiquitous problem in financial mathematics that relies on accurate estimates of covariance matrices for asset returns. However, estimates of pairwise covariance are notoriously poor and calculating time-sensitive optimal portfolios is energy-intensive for digital computers. We present an energy-efficient, fast, and fully analog pipeline for solving portfolio optimization problems that overcomes these limitations. The analog paradigm leverages the fundamental principles of physics to recover accurate optimal portfolios in a two-step process. Firstly, we utilize equilibrium propagation, an analog alternative to backpropagation, to train linear autoencoder neural networks to calculate low-rank covariance matrices. Then, analog continuous Hopfield networks output the minimum variance portfolio for a given desired expected return. The entire efficient frontier may then be recovered, and an optimal portfolio selected based on risk appetite.
Cite
Text
Cummins and Berloff. "A Fully Analog Pipeline for Portfolio Optimization." NeurIPS 2024 Workshops: MLNCP, 2024.Markdown
[Cummins and Berloff. "A Fully Analog Pipeline for Portfolio Optimization." NeurIPS 2024 Workshops: MLNCP, 2024.](https://mlanthology.org/neuripsw/2024/cummins2024neuripsw-fully/)BibTeX
@inproceedings{cummins2024neuripsw-fully,
title = {{A Fully Analog Pipeline for Portfolio Optimization}},
author = {Cummins, James S. and Berloff, Natalia},
booktitle = {NeurIPS 2024 Workshops: MLNCP},
year = {2024},
url = {https://mlanthology.org/neuripsw/2024/cummins2024neuripsw-fully/}
}