05071nam 22008055 450 991068255450332120240313114930.0981-19-6553-610.1007/978-981-19-6553-1(CKB)5580000000525715(DE-He213)978-981-19-6553-1(EXLCZ)99558000000052571520230318d2023 u| 0engurnn#008mamaatxtrdacontentcrdamediacrrdacarrierLearning with Fractional Orthogonal Kernel Classifiers in Support Vector Machines[electronic resource] Theory, Algorithms and Applications /edited by Jamal Amani Rad, Kourosh Parand, Snehashish Chakraverty1st ed. 2023.Singapore :Springer Nature Singapore :Imprint: Springer,2023.1 online resource (XIV, 305 p. 83 illus., 58 illus. in color.)Industrial and Applied Mathematics,2364-6845981-19-6552-8 Introduction to SVM -- Basics of SVM Method and Least Squares SVM -- Fractional Chebyshev Kernel Functions: Theory and Application -- Fractional Legendre Kernel Functions: Theory and Application -- Fractional Gegenbauer Kernel Functions: Theory and Application -- Fractional Jacobi Kernel Functions: Theory and Application -- Solving Ordinary Differential Equations by LS-SVM -- Solving Partial Differential Equations by LS-SVM -- Solving Integral Equations by LS-SVR -- Solving Distributed-Order Fractional Equations by LS-SVR -- GPU Acceleration of LS-SVM, Based on Fractional Orthogonal Functions -- Classification Using Orthogonal Kernel Functions: Tutorial on ORSVM Package.This book contains select chapters on support vector algorithms from different perspectives, including mathematical background, properties of various kernel functions, and several applications. The main focus of this book is on orthogonal kernel functions, and the properties of the classical kernel functions—Chebyshev, Legendre, Gegenbauer, and Jacobi—are reviewed in some chapters. Moreover, the fractional form of these kernel functions is introduced in the same chapters, and for ease of use for these kernel functions, a tutorial on a Python package named ORSVM is presented. The book also exhibits a variety of applications for support vector algorithms, and in addition to the classification, these algorithms along with the introduced kernel functions are utilized for solving ordinary, partial, integro, and fractional differential equations. On the other hand, nowadays, the real-time and big data applications of support vector algorithms are growing. Consequently, the Compute Unified Device Architecture (CUDA) parallelizing the procedure of support vector algorithms based on orthogonal kernel functions is presented. The book sheds light on how to use support vector algorithms based on orthogonal kernel functions in different situations and gives a significant perspective to all machine learning and scientific machine learning researchers all around the world to utilize fractional orthogonal kernel functions in their pattern recognition or scientific computing problems.Industrial and Applied Mathematics,2364-6845Algebraic fieldsPolynomialsMathematical optimizationQuantitative researchMachine learningPattern recognition systemsPython (Computer program language)Field Theory and PolynomialsOptimizationData Analysis and Big DataMachine LearningAutomated Pattern RecognitionPythonAprenentatge automàticthubAlgorismesthubFuncions de KernelthubPython (Llenguatge de programació)Llibres electrònicsthubAlgebraic fields.Polynomials.Mathematical optimization.Quantitative research.Machine learning.Pattern recognition systems.Python (Computer program language).Field Theory and Polynomials.Optimization.Data Analysis and Big Data.Machine Learning.Automated Pattern Recognition.Python.Aprenentatge automàticAlgorismesFuncions de KernelPython (Llenguatge de programació)512.3Rad Jamal Amaniedthttp://id.loc.gov/vocabulary/relators/edtParand Kouroshedthttp://id.loc.gov/vocabulary/relators/edtChakraverty Snehashishedthttp://id.loc.gov/vocabulary/relators/edtBOOK9910682554503321Learning with Fractional Orthogonal Kernel Classifiers in Support Vector Machines3272695UNINA