Trainability maximization using estimation of distribution algorithms assisted by surrogate modelling for quantum architecture search

TL;DR

This paper introduces a novel approach to quantum architecture search that uses surrogate models and gradient magnitude metrics to reduce measurements and avoid trainability issues like barren plateaus, improving efficiency and performance.

Contribution

It proposes an online surrogate modeling method combined with gradient-based metrics to enhance quantum architecture search by reducing measurements and bypassing barren plateaus.

Findings

Successfully reduces measurement costs in QAS

Avoids training in barren plateau regions

Outperforms existing methods in finding optimal architectures

Abstract

Quantum architecture search (QAS) involves optimizing both the quantum parametric circuit configuration but also its parameters for a variational quantum algorithm. Thus, the problem is known to be multi-level as the performance of a given architecture is unknown until its parameters are tuned using classical routines. Moreover, the task becomes even more complicated since well-known trainability issues, e.g., barren plateaus (BPs), can occur. In this paper, we aim to achieve two improvements in QAS: (1) to reduce the number of measurements by an online surrogate model of the evaluation process that aggressively discards architectures of poor performance; (2) to avoid training the circuits when BPs are present. To detect the presence of the BPs, we employed a recently developed metric, information content, which only requires measuring the energy values of a small set of parameters to estimate the magnitude of cost function's gradient. The main idea of this proposal is to leverage a recently developed metric which can be used to detect the onset of vanishing gradients to ensure the overall search avoids such unfavorable regions. We experimentally validate our proposal for the variational quantum eigensolver and showcase that our algorithm is able to find solutions that have been previously proposed in the literature for the Hamiltonians; but also to outperform the state of the art when initializing the method from the set of architectures proposed in the literature. The results suggest that the proposed methodology could be used in environments where it is desired to improve the trainability of known architectures while maintaining good performance.