Interpolation-based coordinate descent method for parameterized quantum circuits
- URL: http://arxiv.org/abs/2503.04620v2
- Date: Thu, 06 Nov 2025 09:01:52 GMT
- Title: Interpolation-based coordinate descent method for parameterized quantum circuits
- Authors: Zhijian Lai, Jiang Hu, Taehee Ko, Jiayuan Wu, Dong An,
- Abstract summary: We propose an coordinate descent (ICD) method to address the parameter optimization problem in quantum circuits (PQCs)<n>ICD employs to approximate the PQC cost function, effectively recovering its underlying trigonometric structure, and then performs an argmin update on a single parameter in each iteration.<n>In contrast to previous studies on structure optimization, we determine the optimal nodes to mitigate statistical errors from quantum measurements.
- Score: 11.745089977547558
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Parameterized quantum circuits (PQCs) are ubiquitous in the design of hybrid quantum-classical algorithms. In this work, we propose an interpolation-based coordinate descent (ICD) method to address the parameter optimization problem in PQCs. The ICD method provides a unified framework for existing structure optimization techniques such as Rotosolve, sequential minimal optimization, ExcitationSolve, and others. ICD employs interpolation to approximate the PQC cost function, effectively recovering its underlying trigonometric structure, and then performs an argmin update on a single parameter in each iteration. In contrast to previous studies on structure optimization, we determine the optimal interpolation nodes to mitigate statistical errors arising from quantum measurements. Moreover, in the common case of $r$ equidistant frequencies, we show that the optimal interpolation nodes are equidistant nodes with spacing $2\pi/(2r+1)$ (under constant variance assumption), and that our ICD method simultaneously minimizes the mean squared error, the condition number of the interpolation matrix, and the average variance of the approximated cost function. We perform numerical simulations and test on the MaxCut problem, the transverse field Ising model, and the XXZ model. Numerical results imply that our ICD method is more efficient than the commonly used gradient descent and random coordinate descent method.
Related papers
- A Gradient Meta-Learning Joint Optimization for Beamforming and Antenna Position in Pinching-Antenna Systems [63.213207442368294]
We consider a novel optimization design for multi-waveguide pinching-antenna systems.<n>The proposed GML-JO algorithm is robust to different choices and better performance compared with the existing optimization methods.
arXiv Detail & Related papers (2025-06-14T17:35:27Z) - Decentralized Optimization on Compact Submanifolds by Quantized Riemannian Gradient Tracking [45.147301546565316]
This paper considers the problem of decentralized optimization on compact submanifolds.<n>We propose an algorithm where agents update variables using quantized variables.<n>To the best of our knowledge, this is the first algorithm to achieve an $mathcalO (1/K)$ convergence rate in the presence of quantization.
arXiv Detail & Related papers (2025-06-09T01:57:25Z) - Transferring linearly fixed QAOA angles: performance and real device results [0.0]
We investigate a simplified approach that combines linear parameterization with parameter transferring, reducing the parameter space to just 4 dimensions regardless of the number of layers.
We compare this combined approach with standard QAOA and other parameter setting strategies such as INTERP and FOURIER, which require computationally demanding incremental layer-by-layer optimization.
Our experiments extend from classical simulation to actual quantum hardware implementation on IBM's Eagle processor, demonstrating the approach's viability on current NISQ devices.
arXiv Detail & Related papers (2025-04-17T04:17:51Z) - Iterative Interpolation Schedules for Quantum Approximate Optimization Algorithm [1.845978975395919]
We present an iterative method that exploits the smoothness of optimal parameter schedules by expressing them in a basis of functions.<n>We demonstrate our method achieves better performance with fewer optimization steps than current approaches.<n>For the largest LABS instance, we achieve near-optimal merit factors with schedules exceeding 1000 layers, an order of magnitude beyond previous methods.
arXiv Detail & Related papers (2025-04-02T12:53:21Z) - Fast Expectation Value Calculation Speedup of Quantum Approximate Optimization Algorithm: HoLCUs QAOA [55.2480439325792]
We present a new method for calculating expectation values of operators that can be expressed as a linear combination of unitary (LCU) operators.<n>This method is general for any quantum algorithm and is of particular interest in the acceleration of variational quantum algorithms.
arXiv Detail & Related papers (2025-03-03T17:15:23Z) - Near-Optimal Parameter Tuning of Level-1 QAOA for Ising Models [3.390330377512402]
We show how to reduce the two-dimensional $(gamma, beta)$ search to a one-dimensional search over $gamma$, with $beta*$ computed analytically.<n>This approach is validated using Recursive QAOA (RQAOA), where it consistently outperforms both coarsely optimised RQAOA and semidefinite programs.
arXiv Detail & Related papers (2025-01-27T19:00:00Z) - Quantum Natural Stochastic Pairwise Coordinate Descent [13.986982036653632]
Variational quantum algorithms, optimized using gradient-based methods, often exhibit sub-optimal convergence performance.<n>Quantum natural gradient descent (QNGD) is a more efficient method that incorporates the geometry of the state space via a quantum information metric.<n>We formulate a novel quantum information metric and construct an unbiased estimator for this metric using single-shot measurements.
arXiv Detail & Related papers (2024-07-18T18:57:29Z) - 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) - A Near-Optimal Single-Loop Stochastic Algorithm for Convex Finite-Sum Coupled Compositional Optimization [53.14532968909759]
We introduce an efficient single-loop primal-dual block-coordinate algorithm called ALEXR.<n>We establish the convergence rates of ALEXR in both convex and strongly convex cases under smoothness and non-smoothness conditions.<n> Experimental results on GDRO and partial Area Under the ROC Curve for cFCCO demonstrate the promising performance of our algorithm.
arXiv Detail & Related papers (2023-12-04T19:00:07Z) - Stochastic Optimization for Non-convex Problem with Inexact Hessian
Matrix, Gradient, and Function [99.31457740916815]
Trust-region (TR) and adaptive regularization using cubics have proven to have some very appealing theoretical properties.
We show that TR and ARC methods can simultaneously provide inexact computations of the Hessian, gradient, and function values.
arXiv Detail & Related papers (2023-10-18T10:29:58Z) - Probabilistic tensor optimization of quantum circuits for the
max-$k$-cut problem [0.0]
We propose a technique for optimizing parameterized circuits in variational quantum algorithms.
We illustrate our approach on the example of the quantum approximate optimization algorithm (QAOA) applied to the max-$k$-cut problem.
arXiv Detail & Related papers (2023-10-16T12:56:22Z) - Randomized semi-quantum matrix processing [0.0]
We present a hybrid quantum-classical framework for simulating generic matrix functions.
The method is based on randomization over the Chebyshev approximation of the target function.
We prove advantages on average depths, including quadratic speed-ups on costly parameters.
arXiv Detail & Related papers (2023-07-21T18:00:28Z) - Fast Computation of Optimal Transport via Entropy-Regularized Extragradient Methods [75.34939761152587]
Efficient computation of the optimal transport distance between two distributions serves as an algorithm that empowers various applications.
This paper develops a scalable first-order optimization-based method that computes optimal transport to within $varepsilon$ additive accuracy.
arXiv Detail & Related papers (2023-01-30T15:46:39Z) - Automatic and effective discovery of quantum kernels [41.61572387137452]
Quantum computing can empower machine learning models by enabling kernel machines to leverage quantum kernels for representing similarity measures between data.<n>We present an approach to this problem, which employs optimization techniques, similar to those used in neural architecture search and AutoML.<n>The results obtained by testing our approach on a high-energy physics problem demonstrate that, in the best-case scenario, we can either match or improve testing accuracy with respect to the manual design approach.
arXiv Detail & Related papers (2022-09-22T16:42:14Z) - Quantum Goemans-Williamson Algorithm with the Hadamard Test and
Approximate Amplitude Constraints [62.72309460291971]
We introduce a variational quantum algorithm for Goemans-Williamson algorithm that uses only $n+1$ qubits.
Efficient optimization is achieved by encoding the objective matrix as a properly parameterized unitary conditioned on an auxilary qubit.
We demonstrate the effectiveness of our protocol by devising an efficient quantum implementation of the Goemans-Williamson algorithm for various NP-hard problems.
arXiv Detail & Related papers (2022-06-30T03:15:23Z) - 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) - Progress towards analytically optimal angles in quantum approximate
optimisation [0.0]
The Quantum Approximate optimisation algorithm is a $p$ layer, time-variable split operator method executed on a quantum processor.
We prove that optimal parameters for $p=1$ layer reduce to one free variable and in the thermodynamic limit, we recover optimal angles.
We moreover demonstrate that conditions for vanishing gradients of the overlap function share a similar form which leads to a linear relation between circuit parameters, independent on the number of qubits.
arXiv Detail & Related papers (2021-09-23T18:00:13Z) - Sparse Representations of Positive Functions via First and Second-Order
Pseudo-Mirror Descent [15.340540198612823]
We consider expected risk problems when the range of the estimator is required to be nonnegative.
We develop first and second-order variants of approximation mirror descent employing emphpseudo-gradients.
Experiments demonstrate favorable performance on ingeneous Process intensity estimation in practice.
arXiv Detail & Related papers (2020-11-13T21:54:28Z) - Adaptive pruning-based optimization of parameterized quantum circuits [62.997667081978825]
Variisy hybrid quantum-classical algorithms are powerful tools to maximize the use of Noisy Intermediate Scale Quantum devices.
We propose a strategy for such ansatze used in variational quantum algorithms, which we call "Efficient Circuit Training" (PECT)
Instead of optimizing all of the ansatz parameters at once, PECT launches a sequence of variational algorithms.
arXiv Detail & Related papers (2020-10-01T18:14:11Z) - 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) - Large gradients via correlation in random parameterized quantum circuits [0.0]
The presence of exponentially vanishing gradients in cost function landscapes is an obstacle to optimization by gradient descent methods.
We prove that reducing the dimensionality of the parameter space can allow one to circumvent the vanishing gradient phenomenon.
arXiv Detail & Related papers (2020-05-25T16:15:53Z) - 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.