GA4QCO: Genetic Algorithm for Quantum Circuit Optimization

The design of quantum circuits is often still done manually, for instance by following certain patterns or rule of thumb. While this approach may work well for some problems, it can be a tedious task and present quite the challenge in other situations. Designing the architecture of a circuit for a simple classification problem may be relatively straightforward task, however, creating circuits for more complex problems or that are resilient to certain known problems (e.g. barren plateaus, trainability, etc.) is a different issue. Moreover, efficient state preparation or circuits with low depth are important for virtually most algorithms. In attempts to automate the process of designing circuits, different approaches have been suggested over the years, including genetic algorithms and reinforcement learning. We propose our GA4QCO framework that applies a genetic algorithm to automatically search for quantum circuits that exhibit user-defined properties. With our framework, the user specifies through a fitness function what type of circuit should be created, for instance circuits that prepare a specific target state while keeping depth at a minimum and maximizing fidelity. Our framework is designed in such a way that the user can easily integrate a custom designed fitness function. In this paper, we introduce our framework and run experiments to show the validity of the approach.