Near-Optimal Parameter Tuning of Level-1 QAOA for Ising Models
- URL: http://arxiv.org/abs/2501.16419v1
- Date: Mon, 27 Jan 2025 19:00:00 GMT
- Title: Near-Optimal Parameter Tuning of Level-1 QAOA for Ising Models
- Authors: V Vijendran, Dax Enshan Koh, Eunok Bae, Hyukjoon Kwon, Ping Koy Lam, Syed M Assad,
- Abstract summary: We show how to reduce the two-dimensional $(gamma, beta)$ search to a one-dimensional search over $gamma$, with $beta*$ computed analytically.
This approach is validated using Recursive QAOA (RQAOA), where it consistently outperforms both coarsely optimised RQAOA and semidefinite programs.
- Score: 3.390330377512402
- License:
- Abstract: The Quantum Approximate Optimisation Algorithm (QAOA) is a hybrid quantum-classical algorithm for solving combinatorial optimisation problems. QAOA encodes solutions into the ground state of a Hamiltonian, approximated by a $p$-level parameterised quantum circuit composed of problem and mixer Hamiltonians, with parameters optimised classically. While deeper QAOA circuits can offer greater accuracy, practical applications are constrained by complex parameter optimisation and physical limitations such as gate noise, restricted qubit connectivity, and state-preparation-and-measurement errors, limiting implementations to shallow depths. This work focuses on QAOA$_1$ (QAOA at $p=1$) for QUBO problems, represented as Ising models. Despite QAOA$_1$ having only two parameters, $(\gamma, \beta)$, we show that their optimisation is challenging due to a highly oscillatory landscape, with oscillation rates increasing with the problem size, density, and weight. This behaviour necessitates high-resolution grid searches to avoid distortion of cost landscapes that may result in inaccurate minima. We propose an efficient optimisation strategy that reduces the two-dimensional $(\gamma, \beta)$ search to a one-dimensional search over $\gamma$, with $\beta^*$ computed analytically. We establish the maximum permissible sampling period required to accurately map the $\gamma$ landscape and provide an algorithm to estimate the optimal parameters in polynomial time. Furthermore, we rigorously prove that for regular graphs on average, the globally optimal $\gamma^* \in \mathbb{R}^+$ values are concentrated very close to zero and coincide with the first local optimum, enabling gradient descent to replace exhaustive line searches. This approach is validated using Recursive QAOA (RQAOA), where it consistently outperforms both coarsely optimised RQAOA and semidefinite programs across all tested QUBO instances.
Related papers
- Obtaining Lower Query Complexities through Lightweight Zeroth-Order Proximal Gradient Algorithms [65.42376001308064]
We propose two variance reduced ZO estimators for complex gradient problems.
We improve the state-of-the-art function complexities from $mathcalOleft(minfracdn1/2epsilon2, fracdepsilon3right)$ to $tildecalOleft(fracdepsilon2right)$.
arXiv Detail & Related papers (2024-10-03T15:04:01Z) - Improving Quantum Approximate Optimization by Noise-Directed Adaptive Remapping [3.47862118034022]
Noise-Directed Remapping (NDAR) is a algorithm for approximately solving binary optimization problems by leveraging certain types of noise.
We consider access to a noisy quantum processor with dynamics that features a global attractor state.
Our algorithm bootstraps the noise attractor state by iteratively gauge-transforming the cost-function Hamiltonian in a way that transforms the noise attractor into higher-quality solutions.
arXiv Detail & Related papers (2024-04-01T18:28:57Z) - Quantum Approximate Optimization Algorithm Parameter Prediction Using a
Convolutional Neural Network [0.0]
We build a convolutional neural network to predict parameters of depth $p+1$ QAOA by the parameters from the depth $p$ QAOA counterpart.
An average approximation ratio of 92735$ for Max-Cut over $800$ ErdHos-R'enyi is obtained.
arXiv Detail & Related papers (2022-11-17T13:20:58Z) - Twisted hybrid algorithms for combinatorial optimization [68.8204255655161]
Proposed hybrid algorithms encode a cost function into a problem Hamiltonian and optimize its energy by varying over a set of states with low circuit complexity.
We show that for levels $p=2,ldots, 6$, the level $p$ can be reduced by one while roughly maintaining the expected approximation ratio.
arXiv Detail & Related papers (2022-03-01T19:47:16Z) - Unsupervised strategies for identifying optimal parameters in Quantum
Approximate Optimization Algorithm [3.508346077709686]
We study unsupervised Machine Learning approaches for setting parameters without optimization.
We showcase them within Recursive-QAOA up to depth $3$ where the number of QAOA parameters used per iteration is limited to $3$.
We obtain similar performances to the case where we extensively optimize the angles, hence saving numerous circuit calls.
arXiv Detail & Related papers (2022-02-18T19:55:42Z) - STORM+: Fully Adaptive SGD with Momentum for Nonconvex Optimization [74.1615979057429]
We investigate non-batch optimization problems where the objective is an expectation over smooth loss functions.
Our work builds on the STORM algorithm, in conjunction with a novel approach to adaptively set the learning rate and momentum parameters.
arXiv Detail & Related papers (2021-11-01T15:43:36Z) - Parameters Fixing Strategy for Quantum Approximate Optimization
Algorithm [0.0]
We propose a strategy to give high approximation ratio on average, even at large circuit depths, by initializing QAOA with the optimal parameters obtained from the previous depths.
We test our strategy on the Max-cut problem of certain classes of graphs such as the 3-regular graphs and the Erd"os-R'enyi graphs.
arXiv Detail & Related papers (2021-08-11T15:44:16Z) - A Two-Timescale Framework for Bilevel Optimization: Complexity Analysis
and Application to Actor-Critic [142.1492359556374]
Bilevel optimization is a class of problems which exhibit a two-level structure.
We propose a two-timescale approximation (TTSA) algorithm for tackling such a bilevel problem.
We show that a two-timescale natural actor-critic policy optimization algorithm can be viewed as a special case of our TTSA framework.
arXiv Detail & Related papers (2020-07-10T05:20:02Z) - Convergence of adaptive algorithms for weakly convex constrained
optimization [59.36386973876765]
We prove the $mathcaltilde O(t-1/4)$ rate of convergence for the norm of the gradient of Moreau envelope.
Our analysis works with mini-batch size of $1$, constant first and second order moment parameters, and possibly smooth optimization domains.
arXiv Detail & Related papers (2020-06-11T17:43:19Z) - Cross Entropy Hyperparameter Optimization for Constrained Problem
Hamiltonians Applied to QAOA [68.11912614360878]
Hybrid quantum-classical algorithms such as Quantum Approximate Optimization Algorithm (QAOA) are considered as one of the most encouraging approaches for taking advantage of near-term quantum computers in practical applications.
Such algorithms are usually implemented in a variational form, combining a classical optimization method with a quantum machine to find good solutions to an optimization problem.
In this study we apply a Cross-Entropy method to shape this landscape, which allows the classical parameter to find better parameters more easily and hence results in an improved performance.
arXiv Detail & Related papers (2020-03-11T13:52:41Z)
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.