Efficient Bayesian phase estimation using mixed priors

We describe an efficient implementation of Bayesian quantum phase estimation in the presence of noise and multiple eigenstates. The main contribution of this work is the dynamic switching between different representations of the phase distributions, namely truncated Fourier series and normal distributions. The Fourier-series representation has the advantage of being exact in many cases, but suffers from increasing complexity with each update of the prior. This necessitates truncation of the series, which eventually causes the distribution to become unstable. We derive bounds on the error in representing normal distributions with a truncated Fourier series, and use these to decide when to switch to the normal-distribution representation. This representation is much simpler, and was proposed in conjunction with rejection filtering for approximate Bayesian updates. We show that, in many cases, the update can be done exactly using analytic expressions, thereby greatly reducing the time complexity of the updates. Finally, when dealing with a superposition of several eigenstates, we need to estimate the relative weights. This can be formulated as a convex optimization problem, which we solve using a gradient-projection algorithm. By updating the weights at exponentially scaled iterations we greatly reduce the computational complexity without affecting the overall accuracy.

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Numerical Solvability and Solution of an Inverse Problem Related to the Gibbs Phenomenon

International Journal of Computational Mathematics ◽

10.1155/2015/212860 ◽

2015 ◽

Vol 2015 ◽

pp. 1-13

Author(s):

Nassar H. S. Haidar

Keyword(s):

Inverse Problem ◽

Fourier Series ◽

Series Representation ◽

Gibbs Phenomenon ◽

Theoretic Proof ◽

Truncated Fourier Series ◽

New Distribution

We report on the inverse problem for the truncated Fourier series representation of fx∈BV-L,L in a form with a quadratic degeneracy, revealing the existence of the Gibbs-Wilbraham phenomenon. A new distribution-theoretic proof is proposed for this phenomenon. The paper studies moreover the iterative numerical solvability and solution of this inverse problem near discontinuities of fx.

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Investigation of discontinuous periodic signals using the measuring labview complex

Quality Innovation Education ◽

10.31145/1999-513x-2020-5-72-79 ◽

2020 ◽

pp. 72-79

Author(s):

E.B. Solovyeva ◽

◽

Yu.M. Inshakov ◽

Keyword(s):

Fourier Series ◽

Laboratory Experiment ◽

Gibbs Phenomenon ◽

Electrical Signals ◽

Measuring Complex ◽

Universal Measuring ◽

Depth Study ◽

Periodic Signals ◽

Truncated Fourier Series

General approaches to the analysis of the Gibbs phenomenon for discontinuous periodic signals approximated by the truncated Fourier series are considered. Methods for smoothing the truncated Fourier series and improving its convergence are discussed. The software means for modeling is a universal measuring complex LabVIEW, which possesses a convenient environment for analyzing electrical signals, on the basis of this complex a laboratory experiment is carried out. The advantages of the measuring LabVIEW complex and its capabilities for in-depth study of discontinuous periodic signals are noted.

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Dynamics of Fourier Modes in Torus Generative Adversarial Networks

Mathematics ◽

10.3390/math9040325 ◽

2021 ◽

Vol 9 (4) ◽

pp. 325

Author(s):

Ángel González-Prieto ◽

Alberto Mozo ◽

Edgar Talavera ◽

Sandra Gómez-Canaval

Keyword(s):

Fourier Series ◽

Generative Adversarial Networks ◽

Learning Models ◽

Training Process ◽

Small Perturbations ◽

Adversarial Networks ◽

Novel Method ◽

Truncated Fourier Series ◽

Real Flow ◽

Machine Learning Models

Generative Adversarial Networks (GANs) are powerful machine learning models capable of generating fully synthetic samples of a desired phenomenon with a high resolution. Despite their success, the training process of a GAN is highly unstable, and typically, it is necessary to implement several accessory heuristics to the networks to reach acceptable convergence of the model. In this paper, we introduce a novel method to analyze the convergence and stability in the training of generative adversarial networks. For this purpose, we propose to decompose the objective function of the adversary min–max game defining a periodic GAN into its Fourier series. By studying the dynamics of the truncated Fourier series for the continuous alternating gradient descend algorithm, we are able to approximate the real flow and to identify the main features of the convergence of GAN. This approach is confirmed empirically by studying the training flow in a 2-parametric GAN, aiming to generate an unknown exponential distribution. As a by-product, we show that convergent orbits in GANs are small perturbations of periodic orbits so the Nash equillibria are spiral attractors. This theoretically justifies the slow and unstable training observed in GANs.

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