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Dimensional Expressivity Analysis of Parametric Quantum Circuits

Lena Funcke, Tobias Hartung, Karl Jansen, Stefan Kühn, Paolo Stornati

2021Quantum51 citationsDOIOpen Access PDF

Abstract

Parametric quantum circuits play a crucial role in the performance of many variational quantum algorithms. To successfully implement such algorithms, one must design efficient quantum circuits that sufficiently approximate the solution space while maintaining a low parameter count and circuit depth. In this paper, develop a method to analyze the dimensional expressivity of parametric quantum circuits. Our technique allows for identifying superfluous parameters in the circuit layout and for obtaining a maximally expressive ansatz with a minimum number of parameters. Using a hybrid quantum-classical approach, we show how to efficiently implement the expressivity analysis using quantum hardware, and we provide a proof of principle demonstration of this procedure on IBM's quantum hardware. We also discuss the effect of symmetries and demonstrate how to incorporate or remove symmetries from the parametrized ansatz.

Topics & Concepts

Quantum circuitQuantumElectronic circuitParametric statisticsAnsatzHomogeneous spaceComputer scienceQuantum algorithmTopology (electrical circuits)Space (punctuation)AlgorithmMathematicsQuantum error correctionQuantum computerExpressivityQuantum gateTheoretical computer scienceQuantum operationQuantum networkAlgebra over a fieldQuantum processElectronic engineeringQuantum Computing Algorithms and ArchitectureQuantum many-body systemsQuantum-Dot Cellular Automata