Interdisciplinary Mathematics: Cartanian geometry, nonlinear waves, and control theory, pt. A-B
Author: Robert Hermann
Publisher:
Published: 1973
Total Pages: 526
ISBN-13:
DOWNLOAD EBOOKPosts
Cartanian Geometry, Nonlinear Waves, and
Author: Robert Hermann
Publisher:
Published: 1980
Total Pages: 585
ISBN-13:
DOWNLOAD EBOOKCartanian Geometry, Nonlinear Waves, and Control
Author: Robert Hermann
Publisher:
Published: 1979
Total Pages: 501
ISBN-13:
DOWNLOAD EBOOKInterdisciplinary Mathematics: Cartanian geometry, nonlinear waves, and control theory, pt. A-B
Author: Robert Hermann
Publisher:
Published: 1973
Total Pages: 616
ISBN-13:
DOWNLOAD EBOOKContemporary Trends in Nonlinear Geometric Control Theory and Its Applications
Author: A. Anzaldo-Meneses
Publisher: World Scientific
Published: 2002
Total Pages: 495
ISBN-13: 9810248415
DOWNLOAD EBOOKConcerns contemporary trends in nonlinear geometric control theory and its applications.
Algebraic and Differential Methods for Nonlinear Control Theory
Author: Rafael Martínez-Guerra
Publisher: Springer
Published: 2019-01-30
Total Pages: 196
ISBN-13: 3030120252
DOWNLOAD EBOOKThis book is a short primer in engineering mathematics with a view on applications in nonlinear control theory. In particular, it introduces some elementary concepts of commutative algebra and algebraic geometry which offer a set of tools quite different from the traditional approaches to the subject matter. This text begins with the study of elementary set and map theory. Chapters 2 and 3 on group theory and rings, respectively, are included because of their important relation to linear algebra, the group of invertible linear maps (or matrices) and the ring of linear maps of a vector space. Homomorphisms and Ideals are dealt with as well at this stage. Chapter 4 is devoted to the theory of matrices and systems of linear equations. Chapter 5 gives some information on permutations, determinants and the inverse of a matrix. Chapter 6 tackles vector spaces over a field, Chapter 7 treats linear maps resp. linear transformations, and in addition the application in linear control theory of some abstract theorems such as the concept of a kernel, the image and dimension of vector spaces are illustrated. Chapter 8 considers the diagonalization of a matrix and their canonical forms. Chapter 9 provides a brief introduction to elementary methods for solving differential equations and, finally, in Chapter 10, nonlinear control theory is introduced from the point of view of differential algebra.
Nonlinear Waves and Solitons on Contours and Closed Surfaces
Author: Andrei Ludu
Publisher: Springer Science & Business Media
Published: 2012-01-14
Total Pages: 498
ISBN-13: 364222895X
DOWNLOAD EBOOKThis volume is an introduction to nonlinear waves and soliton theory in the special environment of compact spaces such a closed curves and surfaces and other domain contours. It assumes familiarity with basic soliton theory and nonlinear dynamical systems. The first part of the book introduces the mathematical concept required for treating the manifolds considered, providing relevant notions from topology and differential geometry. An introduction to the theory of motion of curves and surfaces - as part of the emerging field of contour dynamics - is given. The second and third parts discuss the modeling of various physical solitons on compact systems, such as filaments, loops and drops made of almost incompressible materials thereby intersecting with a large number of physical disciplines from hydrodynamics to compact object astrophysics. This book is intended for graduate students and researchers in mathematics, physics and engineering. This new edition has been thoroughly revised, expanded and updated.
Reduction of Nonlinear Control Systems
Author: V.I. Elkin
Publisher: Springer Science & Business Media
Published: 2012-12-06
Total Pages: 259
ISBN-13: 9401146179
DOWNLOAD EBOOKAdvances in science and technology necessitate the use of increasingly-complicated dynamic control processes. Undoubtedly, sophisticated mathematical models are also concurrently elaborated for these processes. In particular, linear dynamic control systems iJ = Ay + Bu, y E M C ]Rn, U E ]RT, (1) where A and B are constants, are often abandoned in favor of nonlinear dynamic control systems (2) which, in addition, contain a large number of equations. The solution of problems for multidimensional nonlinear control systems en counters serious difficulties, which are both mathematical and technical in nature. Therefore it is imperative to develop methods of reduction of nonlinear systems to a simpler form, for example, decomposition into systems of lesser dimension. Approaches to reduction are diverse, in particular, techniques based on approxi mation methods. In this monograph, we elaborate the most natural and obvious (in our opinion) approach, which is essentially inherent in any theory of math ematical entities, for instance, in the theory of linear spaces, theory of groups, etc. Reduction in our interpretation is based on assigning to the initial object an isomorphic object, a quotient object, and a subobject. In the theory of linear spaces, for instance, reduction consists in reducing to an isomorphic linear space, quotient space, and subspace. Strictly speaking, the exposition of any mathemat ical theory essentially begins with the introduction of these reduced objects and determination of their basic properties in relation to the initial object.
Introduction to Geometric Control
Author: Yuri Sachkov
Publisher: Springer Nature
Published: 2022-07-02
Total Pages: 176
ISBN-13: 3031020707
DOWNLOAD EBOOKThis text is an enhanced, English version of the Russian edition, published in early 2021 and is appropriate for an introductory course in geometric control theory. The concise presentation provides an accessible treatment of the subject for advanced undergraduate and graduate students in theoretical and applied mathematics, as well as to experts in classic control theory for whom geometric methods may be introduced. Theory is accompanied by characteristic examples such as stopping a train, motion of mobile robot, Euler elasticae, Dido's problem, and rolling of the sphere on the plane. Quick foundations to some recent topics of interest like control on Lie groups and sub-Riemannian geometry are included. Prerequisites include only a basic knowledge of calculus, linear algebra, and ODEs; preliminary knowledge of control theory is not assumed. The applications problems-oriented approach discusses core subjects and encourages the reader to solve related challenges independently. Highly-motivated readers can acquire working knowledge of geometric control techniques and progress to studying control problems and more comprehensive books on their own. Selected sections provide exercises to assist in deeper understanding of the material. Controllability and optimal control problems are considered for nonlinear nonholonomic systems on smooth manifolds, in particular, on Lie groups. For the controllability problem, the following questions are considered: controllability of linear systems, local controllability of nonlinear systems, Nagano–Sussmann Orbit theorem, Rashevskii–Chow theorem, Krener's theorem. For the optimal control problem, Filippov's theorem is stated, invariant formulation of Pontryagin maximum principle on manifolds is given, second-order optimality conditions are discussed, and the sub-Riemannian problem is studied in detail. Pontryagin maximum principle is proved for sub-Riemannian problems, solution to the sub-Riemannian problems on the Heisenberg group, the group of motions of the plane, and the Engel group is described.
