Sub-universal variational circuits for combinatorial optimization problems

08/29/2023

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Quantum variational circuits have gained significant attention due to their applications in the quantum approximate optimization algorithm and quantum machine learning research. This work introduces a novel class of classical probabilistic circuits designed for generating approximate solutions to combinatorial optimization problems constructed using two-bit stochastic matrices. Through a numerical study, we investigate the performance of our proposed variational circuits in solving the Max-Cut problem on various graphs of increasing sizes. Our classical algorithm demonstrates improved performance for several graph types to the quantum approximate optimization algorithm. Our findings suggest that evaluating the performance of quantum variational circuits against variational circuits with sub-universal gate sets is a valuable benchmark for identifying areas where quantum variational circuits can excel.

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Sub-universal variational circuits for combinatorial optimization problems

Performance of hybrid quantum/classical variational heuristics for combinatorial optimization

Efficiently Solve the Max-cut Problem via a Quantum Qubit Rotation Algorithm

Predicting parameters for the Quantum Approximate Optimization Algorithm for MAX-CUT from the infinite-size limit

TrojanNet: Detecting Trojans in Quantum Circuits using Machine Learning

Learning to Optimize Variational Quantum Circuits to Solve Combinatorial Problems

On Circuit Depth Scaling For Quantum Approximate Optimization

Benchmarking Adaptative Variational Quantum Algorithms on QUBO Instances

Sub-universal variational circuits for combinatorial optimization problems

Related Research

Performance of hybrid quantum/classical variational heuristics for combinatorial optimization

Efficiently Solve the Max-cut Problem via a Quantum Qubit Rotation Algorithm

Predicting parameters for the Quantum Approximate Optimization Algorithm for MAX-CUT from the infinite-size limit

TrojanNet: Detecting Trojans in Quantum Circuits using Machine Learning

Learning to Optimize Variational Quantum Circuits to Solve Combinatorial Problems

On Circuit Depth Scaling For Quantum Approximate Optimization

Benchmarking Adaptative Variational Quantum Algorithms on QUBO Instances