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Building spatial symmetries into parameterized quantum circuits for faster training

Frédéric Sauvage, Martín Larocca, Patrick J. Coles, M. Cerezo

2023Quantum Science and Technology49 citationsDOIOpen Access PDF

Abstract

Abstract Practical success of quantum learning models hinges on having a suitable structure for the parameterized quantum circuit. Such structure is defined both by the types of gates employed and by the correlations of their parameters. While much research has been devoted to devising adequate gate-sets, typically respecting some symmetries of the problem, very little is known about how their parameters should be structured. In this work, we show that an ideal parameter structure naturally emerges when carefully considering spatial symmetries (i.e. the symmetries that are permutations of parts of the system under study). Namely, we consider the automorphism group of the problem Hamiltonian, leading us to develop a circuit construction that is equivariant under this symmetry group. The benefits of our novel circuitstructure, called ORB, are numerically probed in several ground-state problems. We find a consistent improvement (in terms of circuit depth, number of parameters required, and gradient magnitudes) compared to literature circuit constructions.

Topics & Concepts

Parameterized complexityHomogeneous spaceQuantum circuitElectronic circuitHamiltonian (control theory)Equivariant mapQuantumTopology (electrical circuits)Computer scienceAutomorphismMathematicsPure mathematicsPhysicsAlgorithmQuantum mechanicsQuantum computerGeometryQuantum error correctionCombinatoricsMathematical optimizationQuantum Computing Algorithms and ArchitectureQuantum and electron transport phenomenaQuantum Information and Cryptography
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