Multi-Objective Optimization and Network Routing with Near-Term Quantum
Computers
- URL: http://arxiv.org/abs/2308.08245v1
- Date: Wed, 16 Aug 2023 09:22:01 GMT
- Title: Multi-Objective Optimization and Network Routing with Near-Term Quantum
Computers
- Authors: Shao-Hen Chiew, Kilian Poirier, Rajesh Mishra, Ulrike Bornheimer, Ewan
Munro, Si Han Foon, Christopher Wanru Chen, Wei Sheng Lim, Chee Wei Nga
- Abstract summary: We develop a scheme with which near-term quantum computers can be applied to solve multi-objective optimization problems.
We focus on an implementation based on the quantum approximate optimization algorithm (QAOA)
- Score: 0.2150989251218736
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Multi-objective optimization is a ubiquitous problem that arises naturally in
many scientific and industrial areas. Network routing optimization with
multi-objective performance demands falls into this problem class, and finding
good quality solutions at large scales is generally challenging. In this work,
we develop a scheme with which near-term quantum computers can be applied to
solve multi-objective combinatorial optimization problems. We study the
application of this scheme to the network routing problem in detail, by first
mapping it to the multi-objective shortest path problem. Focusing on an
implementation based on the quantum approximate optimization algorithm (QAOA)
-- the go-to approach for tackling optimization problems on near-term quantum
computers -- we examine the Pareto plot that results from the scheme, and
qualitatively analyze its ability to produce Pareto-optimal solutions. We
further provide theoretical and numerical scaling analyses of the resource
requirements and performance of QAOA, and identify key challenges associated
with this approach. Finally, through Amazon Braket we execute small-scale
implementations of our scheme on the IonQ Harmony 11-qubit quantum computer.
Related papers
- Distributed Quantum Approximate Optimization Algorithm on Integrated High-Performance Computing and Quantum Computing Systems for Large-Scale Optimization [1.7099366779394252]
Quantum approximated optimization algorithm (QAOA) has shown promise for solving optimization problems by providing quantum speedup on gate-based quantum computing systems.
We propose a distributed QAOA (DQAOA), which leverages a high-performance computing-quantum computing integrated system.
We successfully optimize photonic structures using AL-DQAOA, indicating that solving real-world optimization problems using gate-based quantum computing is feasible with our strategies.
arXiv Detail & Related papers (2024-07-29T17:42:25Z) - Bayesian Parameterized Quantum Circuit Optimization (BPQCO): A task and hardware-dependent approach [49.89480853499917]
Variational quantum algorithms (VQA) have emerged as a promising quantum alternative for solving optimization and machine learning problems.
In this paper, we experimentally demonstrate the influence of the circuit design on the performance obtained for two classification problems.
We also study the degradation of the obtained circuits in the presence of noise when simulating real quantum computers.
arXiv Detail & Related papers (2024-04-17T11:00:12Z) - Variational Quantum Multi-Objective Optimization [6.04831065589027]
We present a variational quantum multiple-objective optimization (QMOO) algorithm.
At the core of the algorithm is a variational quantum circuit (VQC) tuned to produce a quantum state.
We show the effectiveness of the proposed algorithm on several benchmark problems with up to five objectives.
arXiv Detail & Related papers (2023-12-21T18:59:21Z) - Federated Multi-Level Optimization over Decentralized Networks [55.776919718214224]
We study the problem of distributed multi-level optimization over a network, where agents can only communicate with their immediate neighbors.
We propose a novel gossip-based distributed multi-level optimization algorithm that enables networked agents to solve optimization problems at different levels in a single timescale.
Our algorithm achieves optimal sample complexity, scaling linearly with the network size, and demonstrates state-of-the-art performance on various applications.
arXiv Detail & Related papers (2023-10-10T00:21:10Z) - Optimizing Solution-Samplers for Combinatorial Problems: The Landscape
of Policy-Gradient Methods [52.0617030129699]
We introduce a novel theoretical framework for analyzing the effectiveness of DeepMatching Networks and Reinforcement Learning methods.
Our main contribution holds for a broad class of problems including Max-and Min-Cut, Max-$k$-Bipartite-Bi, Maximum-Weight-Bipartite-Bi, and Traveling Salesman Problem.
As a byproduct of our analysis we introduce a novel regularization process over vanilla descent and provide theoretical and experimental evidence that it helps address vanishing-gradient issues and escape bad stationary points.
arXiv Detail & Related papers (2023-10-08T23:39:38Z) - A Review on Quantum Approximate Optimization Algorithm and its Variants [47.89542334125886]
The Quantum Approximate Optimization Algorithm (QAOA) is a highly promising variational quantum algorithm that aims to solve intractable optimization problems.
This comprehensive review offers an overview of the current state of QAOA, encompassing its performance analysis in diverse scenarios.
We conduct a comparative study of selected QAOA extensions and variants, while exploring future prospects and directions for the algorithm.
arXiv Detail & Related papers (2023-06-15T15:28:12Z) - Recommending Solution Paths for Solving Optimization Problems with
Quantum Computing [4.306566710489809]
We propose a framework designed to identify and recommend the best-suited solution paths.
State-of-the-art hybrid algorithms, encoding and decomposition techniques can be integrated in a modular manner.
We demonstrate and validate our approach on a selected set of options and illustrate its application on the capacitated vehicle routing problem.
arXiv Detail & Related papers (2022-12-21T15:55:43Z) - A Study of Scalarisation Techniques for Multi-Objective QUBO Solving [0.0]
Quantum and quantum-inspired optimisation algorithms have shown promising performance when applied to academic benchmarks as well as real-world problems.
However, QUBO solvers are single objective solvers. To make them more efficient at solving problems with multiple objectives, a decision on how to convert such multi-objective problems to single-objective problems need to be made.
arXiv Detail & Related papers (2022-10-20T14:54:37Z) - Adiabatic Quantum Computing for Multi Object Tracking [170.8716555363907]
Multi-Object Tracking (MOT) is most often approached in the tracking-by-detection paradigm, where object detections are associated through time.
As these optimization problems are often NP-hard, they can only be solved exactly for small instances on current hardware.
We show that our approach is competitive compared with state-of-the-art optimization-based approaches, even when using of-the-shelf integer programming solvers.
arXiv Detail & Related papers (2022-02-17T18:59:20Z) - 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) - Analysis of Vehicle Routing Problem in Presence of Noisy Channels [0.0]
Vehicle routing problem (VRP) is an NP-hard optimization problem.
This work builds a basic VRP solution for 3 and 4 cities using variational quantum eigensolver on a variable ANSATZ.
arXiv Detail & Related papers (2021-12-28T10:20:42Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.