Comparing Performance of Iterative and Non-Iterative Algorithms on Various Feature Schemes for Arrhythmia Analysis

Many popular iterative algorithms have been used to approximate fixed point of contractive type operators. We define the concept of generalized ?-weakly contractive random operator T on a separable Banach space and establish Bochner integrability of random fixed point and almost sure stability of T with respect to several random Kirk type algorithms. Examples are included to support new results and show their validity. Our work generalizes, improves and provides stochastic version of several earlier results by a number of researchers.

Download Full-text

Convergence analysis of gradient-based iterative algorithms for a class of rectangular Sylvester matrix equations based on Banach contraction principle

Advances in Difference Equations ◽

10.1186/s13662-020-03185-9 ◽

2021 ◽

Vol 2021 (1) ◽

Author(s):

Adisorn Kittisopaporn ◽

Pattrawut Chansangiam ◽

Wicharn Lewkeeratiyutkul

Keyword(s):

Spectral Radius ◽

Matrix Equation ◽

Iterative Algorithms ◽

Banach Contraction Principle ◽

Contraction Principle ◽

Convergence Factor ◽

Sylvester Matrix ◽

Iteration Matrix ◽

Banach Contraction ◽

The Matrix

AbstractWe derive an iterative procedure for solving a generalized Sylvester matrix equation $AXB+CXD = E$ A X B + C X D = E , where $A,B,C,D,E$ A , B , C , D , E are conforming rectangular matrices. Our algorithm is based on gradients and hierarchical identification principle. We convert the matrix iteration process to a first-order linear difference vector equation with matrix coefficient. The Banach contraction principle reveals that the sequence of approximated solutions converges to the exact solution for any initial matrix if and only if the convergence factor belongs to an open interval. The contraction principle also gives the convergence rate and the error analysis, governed by the spectral radius of the associated iteration matrix. We obtain the fastest convergence factor so that the spectral radius of the iteration matrix is minimized. In particular, we obtain iterative algorithms for the matrix equation $AXB=C$ A X B = C , the Sylvester equation, and the Kalman–Yakubovich equation. We give numerical experiments of the proposed algorithm to illustrate its applicability, effectiveness, and efficiency.

Download Full-text

A Neural Network-Based Approach for Approximating Arbitrary Roots of Polynomials

Mathematics ◽

10.3390/math9040317 ◽

2021 ◽

Vol 9 (4) ◽

pp. 317

Author(s):

Diogo Freitas ◽

Luiz Guerreiro Lopes ◽

Fernando Morgado-Dias

Keyword(s):

Iterative Methods ◽

Fundamental Problem ◽

Iterative Algorithms ◽

Rounding Errors ◽

Suggested Approach ◽

Simultaneous Iterative Methods ◽

Complex Roots ◽

Roots Of Polynomials ◽

Comparative Results ◽

The One

Finding arbitrary roots of polynomials is a fundamental problem in various areas of science and engineering. A myriad of methods was suggested to address this problem, such as the sequential Newton’s method and the Durand–Kerner (D–K) simultaneous iterative method. The sequential iterative methods, on the one hand, need to use a deflation procedure in order to compute approximations to all the roots of a given polynomial, which can produce inaccurate results due to the accumulation of rounding errors. On the other hand, the simultaneous iterative methods require good initial guesses to converge. However, Artificial Neural Networks (ANNs) are widely known by their capacity to find complex mappings between the dependent and independent variables. In view of this, this paper aims to determine, based on comparative results, whether ANNs can be used to compute approximations to the real and complex roots of a given polynomial, as an alternative to simultaneous iterative algorithms like the D–K method. Although the results are very encouraging and demonstrate the viability and potentiality of the suggested approach, the ANNs were not able to surpass the accuracy of the D–K method. The results indicated, however, that the use of the approximations computed by the ANNs as the initial guesses for the D–K method can be beneficial to the accuracy of this method.

Download Full-text

How to Select the Number of Active Pumps during the Operation of a Pumping Station: The Convex Hyperbola Charts

Water ◽

10.3390/w13111474 ◽

2021 ◽

Vol 13 (11) ◽

pp. 1474

Author(s):

Araceli Martin-Candilejo ◽

Francisco Javier Martin-Carrasco ◽

David Santillán

Keyword(s):

Specific Energy ◽

Analytic Solution ◽

Iterative Algorithms ◽

Computational Effort ◽

Control Technique ◽

Pumping Station ◽

Operation Control

This research aims to identify the number of pumps that should be working at any moment during the operation of a pumping station in order to provide the desired volume of water whilst consuming the least amount of energy. This is typically done by complex iterative algorithms that require much computational effort. The pumping station should pump the desired volume of water V* using the least specific energy e* (energy per volume). In the methodology of this article, the shape of the curves e*–V* was analyzed. The result is that such curves present a convex hyperbola shape. This is a straightforward analytic solution that does not require any iterations. The representation of the Convex Hyperbolas Charts will indicate the best pump combination during the operation of a pumping station. Therefore, this is a straightforward resource for practitioners: the curves immediately tell engineers the number of pumps that should be turned on, depending on the desired volume of water to pump. The elaboration of such charts only requires the use of any calculation sheet, only once, and it is a permanent resource that can be used at any time during the operation. In addition, the Convex Hyperbolas Charts are completely compatible and complementary with any other operation control technique.

Download Full-text

Preconditioner Auto-Tuning Using Deep Learning for Sparse Iterative Algorithms

2018 Sixth International Symposium on Computing and Networking Workshops (CANDARW) ◽

10.1109/candarw.2018.00055 ◽

2018 ◽

Cited By ~ 2

Author(s):

Kenya Yamada ◽

Takahiro Katagiri ◽

Hiroyuki Takizawa ◽

Kazuo Minami ◽

Mitsuo Yokokawa ◽

...

Keyword(s):

Deep Learning ◽

Iterative Algorithms ◽

Auto Tuning

Download Full-text