Mechanisms and robots analysis with MATLAB / by Dan B. Marghitu.
Material type: TextPublisher: New York ; London : Springer, [2009]Copyright date: ©2009Description: xi, 479 pages : illustrations ; 24 cmContent type:- text
- unmediated
- volume
- 1848003900
- 9781848003903
- 1848003919
- 9781848003910
- 629.892 22
- TJ181 .M369 2009
Item type | Current library | Call number | Copy number | Status | Date due | Barcode | |
---|---|---|---|---|---|---|---|
Book | City Campus City Campus Main Collection | 629.892 MAR (Browse shelf(Opens below)) | 1 | Available | A455021B |
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629.892 JAZ Theory of applied robotics : kinematics, dynamics, and control / | 629.892 LAN Nonlinear control of vehicles and robots / | 629.892 MAR Robotic explorations : a hands-on introduction to engineering / | 629.892 MAR Mechanisms and robots analysis with MATLAB / | 629.892 MAS Mechanics of robotic manipulation / | 629.892 MIN Our robots, ourselves : robotics and the myths of autonomy / | 629.892 MOT Motion planning for humanoid robots / |
Includes bibliographical references and index.
1. Introduction -- 1.1. Degrees of Freedom and Motion -- 1.2. Kinematic Pairs -- 1.3. Dyads -- 1.4. Independent Contours -- 1.5. Planar Mechanism Decomposition -- 2. Position Analysis -- 2.1. Absolute Cartesian Method -- 2.2. Slider-Crank (R-RRT) Mechanism -- 2.3. Four-Bar (R-RRR) Mechanism -- 2.4. R-RTR-RTR Mechanism -- 2.5. R-RTR-RTR Mechanism: Complete Rotation -- 2.5.1. Method I: Constraint Conditions -- 2.5.2. Method II: Euclidian Distance Function -- 2.6. Path of a Point on a Link with General Plane Motion -- 2.7. Creating a Movie -- 3. Velocity and Acceleration Analysis -- 3.1. Introduction -- 3.2. Velocity Field for a Rigid Body -- 3.3. Acceleration Field for a Rigid Body -- 3.4. Motion of a Point that Moves Relative to a Rigid Body -- 3.5. Slider-Crank (R-RRT) Mechanism -- 3.6. Four-Bar (R-RRT) Mechanism -- 3.7. Inverted Slider-Crank Mechanism -- 3.8. R-RTR-RTR Mechanism -- 3.9. Derivative Method -- 3.10. Independent Contour Equations -- 4. Dynamic Force Analysis -- 4.1. Equation of Motion for General Planar Motion -- 4.2. D'Alembert's Principle -- 4.3. Free-Body Diagrams -- 4.4. Force Analysis Using Dyads -- 4.4.1. RRR Dyad -- 4.4.2. RRT Dyad -- 4.4.3. RTR Dyad -- 4.5. Force Analysis Using Contour Method -- 4.6. Slider-Crank (R-RRT) Mechanism -- 4.6.1. Inertia Forces and Moments -- 4.6.2. Joint Forces and Drive Moment -- 4.7. R-RTR-RTR Mechanism -- 4.7.1. Inertia Forces and Moments -- 4.7.2. Joint Forces and Drive Moment -- 5. Direct Dynamics: Newton-Euler Equations of Motion -- 5.1. Compound Pendulum -- 5.2. Double Pendulum -- 5.3. One-Link Planar Robot Arm -- 5.4. Two-Link Planar Robot Arm -- 6.1. Generalized Coordinates and Constraints -- 6.2. Laws of Motion -- 6.3. Lagrange's Equations for Two-Link Robot Arm -- 6.4. Rotation Transformation -- 6.5. RRT Robot Arm -- 6.5.1. Direct Dynamics -- 6.5.2. Inverse Dynamics -- 6.5.3. Kane's Dynamical Equations -- 6.6. RRTR Robot Arm -- 7. Problems -- 7.1. Problem Set: Mechanisms -- 7.2. Problem Set: Robots -- A Programs of -- 2. Position Analysis -- A.1 Slider-Crank (R-RRT) Mechanism -- A.2 Four-Bar (R-RRR) Mechanism -- A.3 R-RTR-RTR Mechanism -- A.4 R-RTR-RTR Mechanism: Complete Rotation -- A.5 R-RTR-RTR Mechanism: Complete Rotation Using Euclidian Distance Function -- A.6 Path of a Point on a Link with General Plane Motion: R-RRT Mechanism -- A.7 Path of a Point on a Link with General Plane Motion: R-RRR Mechanism -- B Programs of -- 3. Velocity and Acceleration Analysis -- B.1 Slider-Crank (R-RRT) Mechanism -- B.2 Four-Bar (R-RRR) Mechanism -- B.3 Inverted Slider-Crank Mechanism -- B.4 R-RTR-RTR Mechanism -- B.5 R-RTR-RTR Mechanism: Derivative Method -- B.6 Inverted Slider-Crank Mechanism: Derivative Method -- B.7 R-RTR Mechanism: Derivative Method -- B.8 R-RRR Mechanism: Derivative Method -- B.9 R-RTR-RTR Mechanism: Contour Method -- C Programs of -- 4. Dynamic Force Analysis -- C.1 Slider-Crank (R-RRT) Mechanism: Newton-Euler Method -- C.2 Slider-Crank (R-RRT) Mechanism: D'Alembert's Principle -- C.3 Slider-Crank (R-RRT) Mechanism: Dyad Method -- C.4 Slider-Crank (R-RRT) Mechanism: Contour Method -- C.5 R-RTR-RTR Mechanism: Newton-Euler Method -- C.6 R-RTR-RTR Mechanism: Dyad Method -- C.7 R-RTR-RTR Mechanism: Contour Method -- D Programs of -- 5. Direct Dynamics -- D.1 Compound Pendulum -- D.2 Compound Pendulum Using the Function R (t,x) -- D.3 Double Pendulum -- D.4 Double Pendulum Using the File RR.m -- D.5 One-Link Planar Robot Arm -- D.6 One-Link Planar Robot Arm Using the m-File Function Rrobot.m -- D.7 Two-Link Planar Robot Arm Using the m-File Function RRrobot.m -- E Programs of -- 6. Analytical Dynamics -- E.1 Lagrange's Equations for Two-Link Robot Arm -- E.2 Two-Link Robot Arm: Inverse Dynamics -- E.3 RRT Robot Arm -- E.4 RRT Robot Arm: Inverse Dynamics -- E.5 RRT Robot Arm: Kane's Dynamical Equations -- E.6 RRTR Robot Arm.
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