Related papers: Semidefinite Programming for Quantum Channel Learning

Semidefinite Programming for Quantum Channel Learning

URL: http://arxiv.org/abs/2601.12502v1
Date: Sun, 18 Jan 2026 17:26:45 GMT
Title: Semidefinite Programming for Quantum Channel Learning
Authors: Mikhail Gennadievich Belov, Victor Victorovich Dubov, Vadim Konstantinovich Ivanov, Alexander Yurievich Maslov, Olga Vladimirovna Proshina, Vladislav Gennadievich Malyshkin,
Abstract summary: Semidefinite Programming (SDP) can be applied to solve the fidelity optimization problem with respect to the Choi matrix.<n>We have tested several commercially available SDP solvers, all of which allowed for the reconstruction of quantum channels of different forms.<n>This suggests that a relatively small Kraus rank quantum channel is typically sufficient to describe experimentally observed classical data.
Score: 35.18016233072556
License: http://creativecommons.org/licenses/by/4.0/
Abstract: The problem of reconstructing a quantum channel from a sample of classical data is considered. When the total fidelity can be represented as a ratio of two quadratic forms (e.g., in the case of mapping a mixed state to a pure state, projective operators, unitary learning, and others), Semidefinite Programming (SDP) can be applied to solve the fidelity optimization problem with respect to the Choi matrix. A remarkable feature of SDP is that the optimization is convex, which allows the problem to be efficiently solved by a variety of numerical algorithms. We have tested several commercially available SDP solvers, all of which allowed for the reconstruction of quantum channels of different forms. A notable feature is that the Kraus rank of the obtained quantum channel typically comprises less than a few percent of its maximal possible value. This suggests that a relatively small Kraus rank quantum channel is typically sufficient to describe experimentally observed classical data. The theory was also applied to the problem of reconstructing projective operators from data. Finally, we discuss a classical computational model based on quantum channel transformation, performed and calculated on a classical computer, possibly hardware-optimized.

Related papers

Quantum-Channel Matrix Optimization for Holevo Bound Enhancement [87.57725685513088]
We propose a unified projected gradient ascent algorithm to optimize the quantum channel given a fixed input ensemble.<n> Simulation results demonstrate that the proposed quantum channel optimization yields higher Holevo bounds than input ensemble optimization.
arXiv Detail & Related papers (2026-02-19T04:15:03Z)
Quantum Approximate Optimization Algorithm for MIMO with Quantized b-bit Beamforming [47.98440449939344]
Multiple-input multiple-output (MIMO) is critical for 6G communication, offering improved spectral efficiency and reliability.<n>This paper explores the use of the Quantum Approximate Optimization Algorithm (QAOA) and alternating optimization to address the problem of b-bit quantized phase shifters both at the transmitter and the receiver.<n>We demonstrate that the structure of this quantized beamforming problem aligns naturally with hybrid-classical methods like QAOA, as the phase shifts used in beamforming can be directly mapped to rotation gates in a quantum circuit.
arXiv Detail & Related papers (2025-10-07T17:53:02Z)
Efficient Learning for Linear Properties of Bounded-Gate Quantum Circuits [62.46800898243033]
Recent progress in quantum learning theory prompts a question: can linear properties of a large-qubit circuit be efficiently learned from measurement data generated by varying classical inputs?<n>We prove that the sample complexity scaling linearly in $d$ is required to achieve a small prediction error, while the corresponding computational complexity may scale exponentially in d.<n>We propose a kernel-based method leveraging classical shadows and truncated trigonometric expansions, enabling a controllable trade-off between prediction accuracy and computational overhead.
arXiv Detail & Related papers (2024-08-22T08:21:28Z)
Recursive Quantum Relaxation for Combinatorial Optimization Problems [3.3053321430025258]
We show that some existing quantum optimization methods can be unified into a solver to find the binary solution.<n>Experiments on standard benchmark graphs with several hundred nodes in the MAX-CUT problem, conducted in a fully classical manner.
arXiv Detail & Related papers (2024-03-04T13:48:21Z)
Quantum Semidefinite Programming with Thermal Pure Quantum States [0.5639904484784125]
We show that a quantization'' of the matrix multiplicative-weight algorithm can provide approximate solutions to SDPs quadratically faster than the best classical algorithms. We propose a modification of this quantum algorithm and show that a similar speedup can be obtained by replacing the Gibbs-state sampler with the preparation of thermal pure quantum (TPQ) states.
arXiv Detail & Related papers (2023-10-11T18:00:53Z)
A Universal Quantum Algorithm for Weighted Maximum Cut and Ising Problems [0.0]
We propose a hybrid quantum-classical algorithm to compute approximate solutions of binary problems. We employ a shallow-depth quantum circuit to implement a unitary and Hermitian operator that block-encodes the weighted maximum cut or the Ising Hamiltonian. Measuring the expectation of this operator on a variational quantum state yields the variational energy of the quantum system.
arXiv Detail & Related papers (2023-06-10T23:28:13Z)
Efficient information recovery from Pauli noise via classical shadow [6.689075863602204]
We introduce an efficient algorithm that can recover information from quantum states under Pauli noise. For a local and bounded-degree observable, only partial knowledge of the channel is required to recover the ideal information. As a notable application, our method can be severed as a sample-efficient error mitigation scheme for Clifford circuits.
arXiv Detail & Related papers (2023-05-06T23:34:13Z)
Quantum Worst-Case to Average-Case Reductions for All Linear Problems [66.65497337069792]
We study the problem of designing worst-case to average-case reductions for quantum algorithms. We provide an explicit and efficient transformation of quantum algorithms that are only correct on a small fraction of their inputs into ones that are correct on all inputs.
arXiv Detail & Related papers (2022-12-06T22:01:49Z)
Quantum-inspired optimization for wavelength assignment [51.55491037321065]
We propose and develop a quantum-inspired algorithm for solving the wavelength assignment problem. Our results pave the way to the use of quantum-inspired algorithms for practical problems in telecommunications.
arXiv Detail & Related papers (2022-11-01T07:52:47Z)
Analyzing Prospects for Quantum Advantage in Topological Data Analysis [35.423446067065576]
We analyze and optimize an improved quantum algorithm for topological data analysis. We show that super-quadratic quantum speedups are only possible when targeting a multiplicative error approximation. We argue that quantum circuits with tens of billions of Toffoli can solve seemingly classically intractable instances.
arXiv Detail & Related papers (2022-09-27T17:56:15Z)
Provably efficient variational generative modeling of quantum many-body systems via quantum-probabilistic information geometry [3.5097082077065003]
We introduce a generalization of quantum natural gradient descent to parameterized mixed states. We also provide a robust first-order approximating algorithm, Quantum-Probabilistic Mirror Descent. Our approaches extend previously sample-efficient techniques to allow for flexibility in model choice.
arXiv Detail & Related papers (2022-06-09T17:58:15Z)
Quantum Speedup for Higher-Order Unconstrained Binary Optimization and MIMO Maximum Likelihood Detection [2.5272389610447856]
We propose a quantum algorithm that supports a real-valued higher-order unconstrained binary optimization problem. The proposed algorithm is capable of reducing the query complexity in the classical domain and providing a quadratic speedup in the quantum domain.
arXiv Detail & Related papers (2022-05-31T00:14:49Z)
A Hybrid Quantum-Classical Algorithm for Robust Fitting [47.42391857319388]
We propose a hybrid quantum-classical algorithm for robust fitting. Our core contribution is a novel robust fitting formulation that solves a sequence of integer programs. We present results obtained using an actual quantum computer.
arXiv Detail & Related papers (2022-01-25T05:59:24Z)

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