Geometry, mechanics, and control in action for the falling cat / Toshihiro Iwai.
2021
QA805
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Details
Title
Geometry, mechanics, and control in action for the falling cat / Toshihiro Iwai.
Author
ISBN
9789811606885 (electronic bk.)
9811606889 (electronic bk.)
9789811606878 (print)
9811606870
9811606889 (electronic bk.)
9789811606878 (print)
9811606870
Published
Singapore : Springer, [2021]
Language
English
Description
1 online resource (x, 182 pages) : illustrations (some color)
Item Number
10.1007/978-981-16-0688-5 doi
Call Number
QA805
Dewey Decimal Classification
515/.39
Summary
The falling cat is an interesting theme to pursue, in which geometry, mechanics, and control are in action together. As is well known, cats can almost always land on their feet when tossed into the air in an upside-down attitude. If cats are not given a non-vanishing angular momentum at an initial instant, they cannot rotate during their motion, and the motion they can make in the air is vibration only. However, cats accomplish a half turn without rotation when landing on their feet. In order to solve this apparent mystery, one needs to thoroughly understand rotations and vibrations. The connection theory in differential geometry can provide rigorous definitions of rotation and vibration for many-body systems. Deformable bodies of cats are not easy to treat mechanically. A feasible way to approach the question of the falling cat is to start with many-body systems and then proceed to rigid bodies and, further, to jointed rigid bodies, which can approximate the body of a cat. In this book, the connection theory is applied first to a many-body system to show that vibrational motions of the many-body system can result in rotations without performing rotational motions and then to the cat model consisting of jointed rigid bodies. On the basis of this geometric setting, mechanics of many-body systems and of jointed rigid bodies must be set up. In order to take into account the fact that cats can deform their bodies, three torque inputs which may give a twist to the cat model are applied as control inputs under the condition of the vanishing angular momentum. Then, a control is designed according to the port-controlled Hamiltonian method for the model cat to perform a half turn and to halt the motion upon landing. The book also gives a brief review of control systems through simple examples to explain the role of control inputs.
Bibliography, etc. Note
Includes bibliographical references and index.
Access Note
Access limited to authorized users.
Source of Description
Online resource; title from PDF title page (SpringerLink, viewed April 27, 2021).
Series
Lecture notes in mathematics (Springer-Verlag) ; 2289. 0075-8434
Available in Other Form
Print version: 9789811606878
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Record Appears in
Table of Contents
1 Geometry of many-body systems
2 Mechanics of many-body systems
3 Mechanical control systems
4 The falling cat
5 Appendices.
2 Mechanics of many-body systems
3 Mechanical control systems
4 The falling cat
5 Appendices.