Classical and Analytical Mechanics Theory, Applied Examples, and Practice
Auteur : Poznyak Alexander S.
Classical and Analytical Mechanics: Theory, Applied Examples, and Practice provides a bridge between the theory and practice related to mechanical, electrical, and electromechanical systems. It includes rigorous mathematical and physical explanations while maintaining an interdisciplinary engineering focus. Applied problems and exercises in mechanical, mechatronic, aerospace, electrical, and control engineering are included throughout and the book provides detailed techniques for designing models of different robotic, electrical, defense, and aerospace systems. The book starts with multiple chapters covering kinematics before moving onto coverage of dynamics and non-inertial and variable mass systems. Euler?s dynamic equations and dynamic Lagrange equations are covered next with subsequent chapters discussing topics such as equilibrium and stability, oscillation analysis, linear systems, Hamiltonian formalism, and the Hamilton-Jacobi equation. The book concludes with a chapter outlining various electromechanical models that readers can implement and adapt themselves.
1. Kinematics of a point
2. Rigid body kinematics
3. Dynamics
4. Non-inertial and variable-mass systems
5. Euler's dynamic equations
6. Dynamic Lagrange equations
7. Equilibrium and stability
8. Oscillations analysis
9. Linear systems of second order
10. Hamiltonian formalism
11. The Hamilton-Jacobi equation
12. Collection of Electromechanical Models
- Bridges theory and practice by providing readers techniques for solving common problems through mechanical, electrical, and electromechanical models alongside the underlying theoretical foundations
- Describes variable mass, non-inertial systems, dynamic Euler’s equations, gyroscopes, and other related topics
- Includes a broad offering of practical examples, problems, and exercises across an array of engineering disciplines
Date de parution : 04-2021
Ouvrage de 524 p.
15x22.8 cm
Thème de Classical and Analytical Mechanics :
Mots-clés :
Canonical transformations; CD motors; Coefficients of Lamé; Cyclic coordinates; Dynamic reactions; Dynamics; Equilibrium; Euler's dynamic equations; Feynman–Kac formula; First integrals; Force; Generalized coordinates; Geometry of solids; Gyroscope; Hamiltonian canonical form; Hamilton's variables; Integral invariants of Poincaré and Poincaré–Cartan; Kelly problem; Kinetic energy; Lagrange–Dirichlet theorem; Lyapunov's and Chetayev's theorems on instability; Mathematical models; Meshchersky formula; Moment of impulse; Movements in the vicinity of equilibrium points; Newton's laws; Non-inertial systems; Normal and tangential accelerations; Optimal control; Poisson brackets; Power converters; Robot manipulators; S-Canonicity criterion; Stability; Tensor of inertia; The Hamilton–Jacobi method; Tsiolkovsky's rocket formula; Variable-mass systems; Velocity and acceleration in generalized coordinates