约束力学系统动力学-英文版 |
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2020-07-24 00:00:00 |
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约束力学系统动力学-英文版 目录
Ⅰ Fundamental Concepts in Constrained Mechanical Systems 1 Constraints and Their Classification 1.1 Constraints 1.2 Equations of Constraint 1.3 Classification of Constraints 1.3.1 Holonomic Constraints and Nonholonomic Constraints 1.3.2 Stationary Constraints and Non-stationary Constraints 1.3.3 Unilateral Constraints and Bilateral Constraints 1.3.4 Passive Constraints and Active Constraints 1.4 Integrability Theorem of Differential Constraints 1.5 Generalization of the Concept of Constraints 1.5.1 First Integral as Nonholonomic Constraints 1.5.2 Controllable System as Holonomic or Nonholonomic System 1.5.3 Nonholonomic Constraints of Higher Order 1.5.4 Restriction on Change of Dynamical Properties as Constraint 1.6 Remarks 2 Generalized Coordinates 2.1 Generalized Coordinates 2.2 Generalized Velocities 2.3 Generalized Accelerations 2.4 Expression of Equations of Nonholonomic Constraints in Terms of Generalized Coordinates and Generalized Velocities 2.5 Remarks 3 Quasi-Velocities and Quasi-Coordinates 3.1 Quasi-Velocities 3.2 Quasi-Coordinates 3.3 Quasi-Accelerations 3.4 Remarks 4 Virtual Displacements 4.1 Virtual Displacements 4.1.1 Concept of Virtual Displacements 4.1.2 Condition of Constraints Exerted on Virtual Displacements 4.1.3 Degree of Freedom 4.2 Necessary and Sufficient Condition Under Which Actual Displacement Is One of Virtual Displacements 4.3 Generalization of the Concept of Virtual Displacement 4.4 Remarks 5 Ideal Constraints 5.1 Constraint Reactions 5.2 Examples of Ideal Constraints 5.3 Importance and Possibility of Hypothesis of Ideal Constraints 5.4 Remarks 6 Transpositional Relations of Differential and Variational Operations 6.1 Transpositional Relations for First Order Nonholonomic Systems 6.1.1 Transpositional Relations in Terms of Generalized Coordinates 6.1.2 Transpositional Relations in Terms of Quasi-Coordinates 6.2 Transpositional Relations of Higher Order Nonholonomic Systems 6.2.1 Transpositional Relations in Terms of Generalized Coordinates 6.2.2 Transpositional Relations in Terms of Quasi-Coordinates 6.3 Vujanovic Transpositional Relations 6.3.1 Transpositional Relations for Holonomic Nonconservative Systems 6.3.2 Transpositional Relations for Nonholonomic Systems 6.4 Remarks
Ⅱ Variational Principles in Constrained Mechanical Systems 7 Differential Variational Principles 7.1 D'Alembert-Lagrange Principle 7.1.1 D'Alembert Principle 7.1.2 Principle of Virtual Displacements 7.1.3 D'Alembert-Lagrange Principle 7.1.4 D'Alembert-Lagrange Principle in Terms of Generalized Coordinates 7.2 Jourdain Principle 7.2.1 Jourdain Principle 7.2.2 Jourdain Principle in Terms of Generalized Coordinates 7.3 Gauss Principle 7.3.1 Gauss Principle 7.3.2 Gauss Principle in Terms of Generalized Coordinates 7.4 Universal D'Alerabert Principle 7.4.1 Universal D'Alembert Principle 7.4.2 Universal D'Alembert Principle in Terms of Generalized Coordinates 7.5 Applications of Gauss Principle 7.5.1 Simple Applications 7.5.2 Application of Gauss Principle in Robot Dynamics 7.5.3 Application of Gauss Principle in Study Approximate Solution of Equations of Nonlinear Vibration 7.6 Remarks
8 Integral Variational Principles in Terms of Generalized Coordinates for Holonomic Systems 8.1 Hamilton's Principle 8.1.1 Hamilton's Principle 8.1.2 Deduction of Lagrange Equations by Means of Hamilton's Principle 8.1.3 Character of Extreme of Hamilton's Principle 8.1.4 Applications in Finding Approximate Solution 8.1.5 Hamilton's Principle for General Holonomic Systems 8.2 Lagrange's Principle 8.2.1 Non-contemporaneous Variation 8.2.2 Lagrange's Principle 8.2.3 Other Forms of Lagrange's Principle 8.2.4 Deduction of Lagrangc's Equations by Means of Lagrange's Principle 8.2.5 Generalization of Lagrange's Principle to Non-conservative Systems and Its Application 8.3 Remarks
9 Integral Variational Principles in Terms of Quasi-Coordinates for Holonomic Systems 9.1 Hamilton's Principle in Terms of Quasi-Coordinates 9.1.1 Hamilton's Principle 9.1.2 Transpositional Relations 9.1.3 Deduction of Equations of Motion in Terms of Quasi-Coordinates by Means of Hamilton's Principle 9.1.4 Hamilton's Principle for General Holonomic Systems 9.2 Lagrange's Principle in Terms of Quasi-Coordinates 9.2.1 Lagrange's Principle 9.2.2 Deduction of Equations of Motion in Terms of Quasi-Coordinates by Means of Lagrange's Principle 9.3 Remarks
l0 Integral Variational Principles for Nonholonomic Systems 10.1 Definitions of Variation 10.1.1 Necessity of Definition of Variation of Generalized Velocities for Nonholonomic Systems 10.1.2 Suslov's Definition 10.1.3 HSlder's Definition 10.2 Integral Variational Principles in Terms of Generalized Coordinates for Nonholonomic Systems 10.2.1 Hamilton's Principle for Nonholonomic Systems 10.2.2 Necessary and Sufficient Condition Under Which Hamilton's Principle for Nonholonomic Systems Is Principle of Stationary Action 10.2.3 Deduction of Equations of Motion for Nonholonomie Systems by Means of Hamilton's Principle 10.2.4 General Form of Hamilton's Principle for Nonhononomic Systems 10.2.5 Lagranges Principle in Terms of Generalized Coordinates for Nonholonomic Systems 10.3 Integral Variational Principle in Terms of QuasiCoordinates for Nonholonomic Systems 10.3.1 Hamilton's Principle in Terms of Quasi-Coordinates 10.3.2 Lagrange's Principle in Terms of Quasi-Coordinates 10.4 Remarks
11 Pfaff-Birkhoff Principle 11.1 Statement of Pfaff-Birkhoff Principle 11.2 Hamilton's Principle as a Particular Case of Pfaff-Birkhoff Principle 11.3 Birkhoff's Equations 11.4 Pfaff-Birkhoff-d'Alembert Principle 11.5 Remarks
III Differential Equations of Motion of Constrained Mechanical Systems
12 Lagrange Equations of Holonomic Systems 12.1 Lagrange Equations of Second Kind 12.2 Lagrange Equations of Systems with Redundant Coordinates 12.3 Lagrange Equations in Terms of Quasi-Coordinates 12.4 Lagrange Equations with Dissipative Function 12.5 Remarks
13 Lagrange Equations with Multiplier for Nonholonomic Systems 13.1 Deduction of Lagrange Equations with Multiplier 13.2 Determination of Nonholonomic Constraint Forces 13.3 Remarks
14 Mac Millan Equations for Nonholonomie Systems 14.1 Deduction of Mac Millan Equations 14.2 Application of Mac MiUan Equations 14.3 Remarks
15 Volterra Equations for Nonholonomic Systems 15.1 Deduction of Generalized Volterra Equations 15.2 Volterra Equations and Their Equivalent Forms 15.2.1 Volterra Equations of First Form 15.2.2 Volterra Equations of Second Form 15.2.3 Volterra Equations of Third Form 15.2.4 Volterra Equations of Fourth Form 15.3 Application of Volterra Equations 15.4 Remarks
16 Chaplygin Equations for Nonholonomic Systems 16.1 Generalized Chaplygin Equations 16.2 Voronetz Equations 16.3 Chaplygin Equations 16.4 Chaplygin Equations in Terms of Quasi-Coordinates 16.5 Application of Chaplygin Equations 16.6 Remarks ……
Ⅳ Special Problems in Constrained Mechanical Systems Ⅴ Integration Methods in Constrained Mechanical Systems Ⅵ Symmetries and Conserved Quantities in Constrained Mechanical Systems
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