Single-Period Portfolio Selection via Information Projection
Provides a novel information-theoretic framework for portfolio selection under CRRA utility, offering potential computational advantages for investors.
The paper decomposes CRRA utility portfolio selection into Rényi divergence and entropy terms, showing equivalence to Rényi information projection, and proposes an alternating optimization algorithm that empirically converges faster than existing methods in low risk-aversion regimes.
We study the single-period portfolio selection problem under Constant Relative Risk-Aversion (CRRA) utility through the information-theoretic lens. Assuming only that the market payoff vector has finite support, we show that the Certainty-Equivalent (CE) growth rate under CRRA utility can be exactly decomposed into a portfolio-induced Rényi divergence term, a Rényi entropy term of the risk-tilted market law, and a log-partition term. In this setting, the Rényi order has a clear operational meaning: it exactly coincides with the investor's coefficient of relative risk aversion. We further show that CRRA portfolio selection is equivalent to a Rényi information-projection problem. Using a variational representation of Rényi divergence, we obtain a Blahut-Arimoto-style alternating optimization with a closed-form auxiliary update and a KL-type portfolio step. In the low risk-aversion regime, this method empirically requires fewer iterations than both direct CRRA utility optimization and Cover's method.