Globally Optimizing QAOA Circuit Depth for Constrained Optimization Problems
Rebekah Herrman
Abstract
We develop a global variable substitution method that reduces n-variable monomials in combinatorial optimization problems to equivalent instances with monomials in fewer variables. We apply this technique to 3-SAT and analyze the optimal quantum unitary circuit depth needed to solve the reduced problem using the quantum approximate optimization algorithm. For benchmark 3-SAT problems, we find that the upper bound of the unitary circuit depth is smaller when the problem is formulated as a product and uses the substitution method to decompose gates than when the problem is written in the linear formulation, which requires no decomposition.
Topics & Concepts
MonomialBenchmark (surveying)Unitary stateMathematical optimizationVariable (mathematics)Substitution (logic)Quantum circuitOptimization problemMathematicsDecompositionQuantumUnitary transformationComputer scienceAlgorithmQuantum computerDiscrete mathematicsProgramming languagePolitical scienceQuantum error correctionMathematical analysisPhysicsGeodesyEcologyBiologyLawQuantum mechanicsGeographyQuantum Computing Algorithms and ArchitectureQuantum Information and CryptographyComplexity and Algorithms in Graphs