Information-based complexity, feedback and dynamics in convex programming

TL;DR

This paper investigates the fundamental limits of sequential convex optimization using information theory, showing how information constraints affect the speed and efficiency of optimization algorithms.

Contribution

It introduces a novel information-theoretic framework for analyzing optimization limits, linking feedback, information gain, and convergence in convex programming.

Findings

Optimization speed is limited by information acquisition constraints.

Algorithms experience diminishing returns as they approach the optimum.

The framework applies to active learning and estimation problems.

Abstract

We study the intrinsic limitations of sequential convex optimization through the lens of feedback information theory. In the oracle model of optimization, an algorithm queries an {\em oracle} for noisy information about the unknown objective function, and the goal is to (approximately) minimize every function in a given class using as few queries as possible. We show that, in order for a function to be optimized, the algorithm must be able to accumulate enough information about the objective. This, in turn, puts limits on the speed of optimization under specific assumptions on the oracle and the type of feedback. Our techniques are akin to the ones used in statistical literature to obtain minimax lower bounds on the risks of estimation procedures; the notable difference is that, unlike in the case of i.i.d. data, a sequential optimization algorithm can gather observations in a {\em controlled} manner, so that the amount of information at each step is allowed to change in time. In particular, we show that optimization algorithms often obey the law of diminishing returns: the signal-to-noise ratio drops as the optimization algorithm approaches the optimum. To underscore the generality of the tools, we use our approach to derive fundamental lower bounds for a certain active learning problem. Overall, the present work connects the intuitive notions of information in optimization, experimental design, estimation, and active learning to the quantitative notion of Shannon information.