Quadratic-exponential functionals of Gaussian quantum processes

• URL: http://arxiv.org/abs/2103.09279v1
• Date: Tue, 16 Mar 2021 18:58:39 GMT
• Title: Quadratic-exponential functionals of Gaussian quantum processes
• Authors: Igor G. Vladimirov, Ian R. Petersen, Matthew R. James
• Abstract summary: quadratic-exponential functionals (QEFs) arise as robust performance criteria in control problems. We develop a randomised representation for the QEF using a Karhunen-Loeve expansion of the quantum process. For stationary Gaussian quantum processes, we establish a frequency-domain formula for the QEF rate.
• Score: 1.7360163137925997
• License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
• Abstract: This paper is concerned with exponential moments of integral-of-quadratic functions of quantum processes with canonical commutation relations of position-momentum type. Such quadratic-exponential functionals (QEFs) arise as robust performance criteria in control problems for open quantum harmonic oscillators (OQHOs) driven by bosonic fields. We develop a randomised representation for the QEF using a Karhunen-Loeve expansion of the quantum process on a bounded time interval over the eigenbasis of its two-point commutator kernel, with noncommuting position-momentum pairs as coefficients. This representation holds regardless of a particular quantum state and employs averaging over an auxiliary classical Gaussian random process whose covariance operator is specified by the commutator kernel. This allows the QEF to be related to the moment-generating functional of the quantum process and computed for multipoint Gaussian states. For stationary Gaussian quantum processes, we establish a frequency-domain formula for the QEF rate in terms of the Fourier transform of the quantum covariance kernel in composition with trigonometric functions. A differential equation is obtained for the QEF rate with respect to the risk sensitivity parameter for its approximation and numerical computation. The QEF is also applied to large deviations and worst-case mean square cost bounds for OQHOs in the presence of statistical uncertainty with a quantum relative entropy description.

Related papers

• Utilizing Quantum Processor for the Analysis of Strongly Correlated Materials [34.63047229430798]
  This study introduces a systematic approach for analyzing strongly correlated systems by adapting the conventional quantum cluster method to a quantum circuit model. We have developed a more concise formula for calculating the cluster's Green's function, requiring only real-number computations on the quantum circuit instead of complex ones.
  arXiv  Detail & Related papers  (2024-04-03T06:53:48Z)
• Quantum Circuits for partial differential equations via Schrödingerisation [26.7034263292622]
  We present implementation of a quantum algorithm for general PDEs using Schr"odingerisation techniques. We provide examples of the heat equation, and the advection equation approximated by the upwind scheme.
  arXiv  Detail & Related papers  (2024-03-15T05:42:03Z)
• Quantum error mitigation for Fourier moment computation [49.1574468325115]
  This paper focuses on the computation of Fourier moments within the context of a nuclear effective field theory on superconducting quantum hardware. The study integrates echo verification and noise renormalization into Hadamard tests using control reversal gates. The analysis, conducted using noise models, reveals a significant reduction in noise strength by two orders of magnitude.
  arXiv  Detail & Related papers  (2024-01-23T19:10:24Z)
• Quantum-inspired Hash Function Based on Parity-dependent Quantum Walks with Memory [25.487508611436425]
  We construct a quantum-inspired hash function (called QHFM-P) based on this model. Numerical simulation shows that QHFM-P has near-ideal statistical performance. Stability test illustrates that the statistical properties of the proposed hash function are robust with respect to the coin parameters.
  arXiv  Detail & Related papers  (2023-08-10T05:54:32Z)
• Quantum Chebyshev Transform: Mapping, Embedding, Learning and Sampling Distributions [18.124351208075062]
  We show how to encode data into quantum states with amplitudes growing exponentially in the system size. We propose an embedding circuit for generating the orthonormal Chebyshev basis of exponential capacity. This enables automatic model differentiation, and opens a route to solving differential equations.
  arXiv  Detail & Related papers  (2023-06-29T15:19:32Z)
• Probabilistic bounds with quadratic-exponential moments for quantum stochastic systems [0.0]
  quadratic-exponential moments (QEMs) for dynamic variables of quantum systems with position-momentum type canonical commutation relations. QEMs play an important role for statistical localisation'' of the quantum dynamics in the form of upper bounds on the tail probability distribution for a positive definite function of the system variables.
  arXiv  Detail & Related papers  (2022-11-22T10:40:52Z)
• Gibbs Sampling of Continuous Potentials on a Quantum Computer [0.0]
  We build a quantum algorithm for Gibbs sampling from periodic real-valued functions. Our algorithm makes zeroeth order queries to a quantum oracle of the function.
  arXiv  Detail & Related papers  (2022-10-14T20:56:44Z)
• Field theory approach to eigenstate thermalization in random quantum circuits [0.0]
  We use field-theoretic methods to explore the statistics of eigenfunctions of the Floquet operator for a large family of quantum circuits. The correlation function of the quasienergy eigenstates is calculated and shown to exhibit random matrix circular unitary ensemble statistics.
  arXiv  Detail & Related papers  (2022-10-12T18:00:00Z)
• Infinite-horizon risk-sensitive performance criteria for translation invariant networks of linear quantum stochastic systems [2.0508733018954843]
  This paper is concerned with networks of identical linear quantum systems which interact with each other and external bosonic fields. The systems are associated with sites of a multidimensional lattice and are governed by coupled linear quantum differential equations (QSDEs) A quadratic-exponential functional (QEF) is considered as a risk-sensitive performance criterion for a finite fragment of the network over a bounded time interval.
  arXiv  Detail & Related papers  (2022-02-04T17:44:14Z)
• State-space computation of quadratic-exponential functional rates for linear quantum stochastic systems [2.0508733018954843]
  We use a frequency-domain representation of the QEF growth rate for the invariant Gaussian quantum state of the system. A truncation of this shaping filter allows the QEF rate to be computed with any accuracy.
  arXiv  Detail & Related papers  (2022-01-25T17:36:19Z)
• Quantum Quantile Mechanics: Solving Stochastic Differential Equations for Generating Time-Series [19.830330492689978]
  We propose a quantum algorithm for sampling from a solution of differential equations (SDEs) We represent the quantile function for an underlying probability distribution and extract samples as expectation values. We test the method by simulating the Ornstein-Uhlenbeck process and sampling at times different from the initial point.
  arXiv  Detail & Related papers  (2021-08-06T16:14:24Z)

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.