Related papers: Modified Recursive QAOA for Exact Max-Cut Solutions on Bipartite Graphs: Closing the Gap Beyond QAOA Limit

Modified Recursive QAOA for Exact Max-Cut Solutions on Bipartite Graphs: Closing the Gap Beyond QAOA Limit

URL: http://arxiv.org/abs/2408.13207v2
Date: Tue, 26 Nov 2024 04:35:19 GMT
Title: Modified Recursive QAOA for Exact Max-Cut Solutions on Bipartite Graphs: Closing the Gap Beyond QAOA Limit
Authors: Eunok Bae, Hyukjoon Kwon, V Vijendran, Soojoon Lee,
Abstract summary: Quantum Approximate Optimization Algorithm (QAOA) is a quantum-classical hybrid algorithm proposed with the goal of approximately solving optimization problems such as the MAX-CUT problem. We first analytically prove the performance limitations of level-1 QAOA in solving the MAX-CUT problem on bipartite graphs. Second, we demonstrate that Recursive QAOA (RQAOA), which reduces graph size using QAOA as a subroutine, outperforms the level-1 QAOA. Finally, we show that RQAOA with a restricted parameter regime can fully address these limitations.
Score: 4.364124102844566
License:
Abstract: Quantum Approximate Optimization Algorithm (QAOA) is a quantum-classical hybrid algorithm proposed with the goal of approximately solving combinatorial optimization problems such as the MAX-CUT problem. It has been considered a potential candidate for achieving quantum advantage in the Noisy Intermediate-Scale Quantum era and has been extensively studied. However, the performance limitations of low-level QAOA have also been demonstrated across various instances. In this work, we first analytically prove the performance limitations of level-1 QAOA in solving the MAX-CUT problem on bipartite graphs. To this end, we derive an upper bound for the approximation ratio based on the average degree of bipartite graphs. Second, we demonstrate that Recursive QAOA (RQAOA), which recursively reduces graph size using QAOA as a subroutine, outperforms the level-1 QAOA. However, the performance of RQAOA exhibits limitations as the graph size increases. Finally, we show that RQAOA with a restricted parameter regime can fully address these limitations. Surprisingly, this modified RQAOA always finds the exact maximum cut for any bipartite graphs and even for a more general graph with parity-signed weights.

Related papers

Phantom Edges in the Problem Hamiltonian: A Method for Increasing Performance and Graph Visibility for QAOA [0.0]
We present a new QAOA ansatz that introduces only one additional parameter to the standard ansatz. We derive a general formula for our new ansatz at $p=1$ and analytically show an improvement in the approximation ratio for cycle graphs.
arXiv Detail & Related papers (2024-11-07T22:20:01Z)
Hybrid Classical-Quantum Simulation of MaxCut using QAOA-in-QAOA [0.0]
In this work, an implementation of the QAOA2 method for the scalable solution of the MaxCut problem is presented. The limits of the Goemans-Williamson (GW) algorithm as a purely classical alternative to QAOA are investigated. Results from large-scale simulations of up to 33 qubits are presented, showing the advantage of QAOA in certain cases and the efficiency of the implementation.
arXiv Detail & Related papers (2024-06-25T09:02:31Z)
Missing Puzzle Pieces in the Performance Landscape of the Quantum Approximate Optimization Algorithm [0.0]
We consider the maximum cut and maximum independent set problems on random regular graphs. We calculate the energy densities achieved by QAOA for high regularities up to $d=100$. We combine the QAOA analysis with state-of-the-art upper bounds on optimality for both problems.
arXiv Detail & Related papers (2024-06-20T18:00:02Z)
An Analysis of Quantum Annealing Algorithms for Solving the Maximum Clique Problem [49.1574468325115]
We analyse the ability of quantum D-Wave annealers to find the maximum clique on a graph, expressed as a QUBO problem. We propose a decomposition algorithm for the complementary maximum independent set problem, and a graph generation algorithm to control the number of nodes, the number of cliques, the density, the connectivity indices and the ratio of the solution size to the number of other nodes.
arXiv Detail & Related papers (2024-06-11T04:40:05Z)
An Expressive Ansatz for Low-Depth Quantum Approximate Optimisation [0.23999111269325263]
The quantum approximate optimisation algorithm (QAOA) is a hybrid quantum-classical algorithm used to approximately solve optimisation problems. While QAOA can be implemented on NISQ devices, physical limitations can limit circuit depth and decrease performance. This work introduces the eXpressive QAOA (XQAOA) that assigns more classical parameters to the ansatz to improve its performance at low depths.
arXiv Detail & Related papers (2023-02-09T07:47:06Z)
QAOA-in-QAOA: solving large-scale MaxCut problems on small quantum machines [81.4597482536073]
Quantum approximate optimization algorithms (QAOAs) utilize the power of quantum machines and inherit the spirit of adiabatic evolution. We propose QAOA-in-QAOA ($textQAOA2$) to solve arbitrary large-scale MaxCut problems using quantum machines. Our method can be seamlessly embedded into other advanced strategies to enhance the capability of QAOAs in large-scale optimization problems.
arXiv Detail & Related papers (2022-05-24T03:49:10Z)
Scaling Quantum Approximate Optimization on Near-term Hardware [49.94954584453379]
We quantify scaling of the expected resource requirements by optimized circuits for hardware architectures with varying levels of connectivity. We show the number of measurements, and hence total time to synthesizing solution, grows exponentially in problem size and problem graph degree. These problems may be alleviated by increasing hardware connectivity or by recently proposed modifications to the QAOA that achieve higher performance with fewer circuit layers.
arXiv Detail & Related papers (2022-01-06T21:02:30Z)
Solving correlation clustering with QAOA and a Rydberg qudit system: a full-stack approach [94.37521840642141]
We study the correlation clustering problem using the quantum approximate optimization algorithm (QAOA) and qudits. Specifically, we consider a neutral atom quantum computer and propose a full stack approach for correlation clustering. We show the qudit implementation is superior to the qubit encoding as quantified by the gate count.
arXiv Detail & Related papers (2021-06-22T11:07:38Z)
Empirical performance bounds for quantum approximate optimization [0.27998963147546135]
Quantifying performance bounds provides insight into when QAOA may be viable for solving real-world applications. We find QAOA exceeds the Goemans-Williamson approximation ratio bound for most graphs. The resulting data set is presented as a benchmark for establishing empirical bounds on QAOA performance.
arXiv Detail & Related papers (2021-02-12T23:12:09Z)
Hybrid quantum-classical algorithms for approximate graph coloring [65.62256987706128]
We show how to apply the quantum approximate optimization algorithm (RQAOA) to MAX-$k$-CUT, the problem of finding an approximate $k$-vertex coloring of a graph. We construct an efficient classical simulation algorithm which simulates level-$1$ QAOA and level-$1$ RQAOA for arbitrary graphs.
arXiv Detail & Related papers (2020-11-26T18:22:21Z)
ROOT-SGD: Sharp Nonasymptotics and Near-Optimal Asymptotics in a Single Algorithm [71.13558000599839]
We study the problem of solving strongly convex and smooth unconstrained optimization problems using first-order algorithms. We devise a novel, referred to as Recursive One-Over-T SGD, based on an easily implementable, averaging of past gradients. We prove that it simultaneously achieves state-of-the-art performance in both a finite-sample, nonasymptotic sense and an sense.
arXiv Detail & Related papers (2020-08-28T14:46:56Z)

This list is automatically generated from the titles and abstracts of the papers in this site.