03732oam 2200481 450 99641820120331620210610154936.03-030-60307-510.1007/978-3-030-60307-6(CKB)5460000000008750(DE-He213)978-3-030-60307-6(MiAaPQ)EBC6450978(PPN)253252725(EXLCZ)99546000000000875020210610d2020 uy 0engurnn|008mamaatxtrdacontentcrdamediacrrdacarrierTurnpike theory for the Robinson-Solow-Srinivasan model /Alexander J. Zaslavski1st ed. 2020.Cham, Switzerland :Springer,[2020]©20201 online resource (X, 442 p.) Springer Optimization and Its Applications ;Volume 1663-030-60306-7 1. Introduction -- 2 The RSS model and its basic properties -- 3. Infinite horizon optimization. 4. Turnpike results for the RSS model -- 5.The RSS model with a nonconcave utility function. - 6.Infinite horizon nonautonomous optimization problems -- 7. One-dimensional RSS model -- 8. Optimal Programs -- 9. Turnpike for the RSS model with nonconcave utility functions. 10. An autonomous one-dimensional model -- 11. The continuous-time Robinson–Solow–Srinivasan model -- References -- Index.This book is devoted to the study of a class of optimal control problems arising in mathematical economics, related to the Robinson–Solow–Srinivasan (RSS) model. It will be useful for researches interested in the turnpike theory, infinite horizon optimal control and their applications, and mathematical economists. The RSS is a well-known model of economic dynamics that was introduced in the 1960s and as many other models of economic dynamics, the RSS model is determined by an objective function (a utility function) and a set-valued mapping (a technology map). The set-valued map generates a dynamical system whose trajectories are under consideration and the objective function determines an optimality criterion. The goal is to find optimal trajectories of the dynamical system, using the optimality criterion. Chapter 1 discusses turnpike properties for some classes of discrete time optimal control problems. Chapter 2 present the description of the RSS model and discuss its basic properties. Infinite horizon optimal control problems, related to the RSS model are studied in Chapter 3. Turnpike properties for the RSS model are analyzed in Chapter 4. Chapter 5 studies infinite horizon optimal control problems related to the RSS model with a nonconcave utility function. Chapter 6 focuses on infinite horizon optimal control problems with nonautonomous optimality criterions. Chapter 7 contains turnpike results for a class of discrete-time optimal control problems. Chapter 8 discusses the RSS model and compares different optimality criterions. Chapter 9 is devoted to the study of the turnpike properties for the RSS model. In Chapter 10 the one-dimensional autonomous RSS model is considered and the continuous time RSS model is studied in Chapter 11.Springer optimization and its applications ;Volume 166.Mathematical abilityTurnpike theory (Economics)Mathematical ability.Turnpike theory (Economics)153.9Zaslavski Alexander J.721713MiAaPQMiAaPQUtOrBLWBOOK996418201203316Turnpike theory for the Robinson-Solow-Srinivasan model2113488UNISA03868nam 2200589 450 991042705170332120210302141842.01-4842-5884-310.1007/978-1-4842-5884-2(CKB)4100000011491014(DE-He213)978-1-4842-5884-2(MiAaPQ)EBC6363155(OCoLC)1203981374(OCoLC-P)1203981374(PPN)253257085(CaSebORM)9781484258842(EXLCZ)99410000001149101420210302d2020 uy 0engurnn#008mamaatxtrdacontentcrdamediacrrdacarrierBeginning C++20 from novice to professional. /Ivor Horton, Peter Van Weert6th ed. 2020.New York, New York :APress,[2020]©20201 online resource (XXVIII, 825 p. 80 illus.)Includes index.1-4842-5883-5 1. Basic Ideas -- 2. Introducing Fundamental Types of Data -- 3. Working Fundamental Types -- 4. Making Decisions -- 5. Arrays and Loops -- 6. Pointers and References -- 7. Working with Strings -- 8. Defining Functions -- 9. Vocabulary Types -- 10. Function Templates -- 11. Modules and Namespaces -- 12. Defining your own Data Types -- 13. Operator Overloading -- 14. Inheritance -- 15. Polymorphism -- 16. Runtime Errors and Exceptions -- 17. Class Templates -- 18. Move Semantics -- 19. First-Class Functions -- 20. Containers and Algorithms -- 21. Constrained Templates and Concepts.Begin your programming journey with C++ , starting with the basics and progressing through step-by-step examples that will help you become a proficient C++ programmer. This book includes new features from the C++20 standard like modules, concepts, ranges, and the spaceship operator. All you need are Beginning C++20 and any recent C++ compiler and you'll soon be writing real C++ programs. There is no assumption of prior programming knowledge. All language concepts that are explained in the book are illustrated with working program examples, and all chapters include exercises for you to test and practice your knowledge. Free source code downloads are provided for all examples from the text and solutions to the exercises. This latest edition has been fully updated to the latest version of the language, C++20, and to all conventions and best practices of modern C++. Beginning C++20 also introduces the elements of the C++ Standard Library that provide essential support for the C++20 language. You will: Begin programming with the C++20 standard Carry out modular programming in C++ Work with arrays and loops, pointers and references, strings, and more Write your own functions, types, and operators Discover the essentials of object-oriented programming Use overloading, inheritance, virtual functions, and polymorphism Write generic function and class templates, and make them safer using concepts Learn the ins and outs of containers, algorithms, and ranges Use auto type declarations, exceptions, move semantics, lambda expressions, and much more.C++ (Computer program language)Programming languages (Electronic computers)Computer softwareComputer scienceSoftware engineeringC++ (Computer program language)Programming languages (Electronic computers)Computer software.Computer science.Software engineering.005.133Horton Ivor855937Weert Peter vanMiAaPQMiAaPQMiAaPQBOOK9910427051703321Beginning C++201911030UNINA