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D’Alembert’s Principle the sum of the work done by

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1 D’Alembert’s Principle the sum of the work done by
MA4248 Weeks 8-9. Topics Generalized Forces, Velocities, and Momenta; Lagrange’s, Lagrange-Euler’s, and Hamilton’s Equations D’Alembert’s Principle the sum of the work done by the applied and inertial forces in a virtual disp. = 0 1

2 GENERALIZED FORCES 2 If the 3N particle coordinates are expressed
in terms of a set of f generalized coordinates then where are called generalized forces. 2

3 GENERALIZED VELOCITIES
Chain-rule gives derivatives of the particle velocities and the kinetic energy with respect to the generalized velocities 3

4 GENERALIZED MOMENTA We define generalized momenta Example (linear momenta) for unconstrained motion of a single particle with generalized coordinates x,y,z and the generalized momenta are components of the linear momentum vector 4

5 GENERALIZED MOMENTA Example (angular momenta) for motion of a particle in a circle with radius with generalized coordinate the generalized momentum is the angular momentum 5

6 TIME DERIVATIVES OF GENERALIZED MOMENTA
Example (linear momenta) Example (angular momentum) These consequences of Newton’s laws motivate us to considerer the quantities 6

7 TIME DERIVATIVES OF GEN. MOMENTA
The Eq. on page 3 and Leibniz’s formula yield 7

8 LAGRANGE’S EQUATIONS Combining these equations yields Therefore 8

9 EULER-LAGRANGE EQUATIONS
If the applied forces are conservative, then where is the potential energy Therefore where is the Lagrangian (it may or may not depend on t) 9

10 EXAMPLE: PLANE PENDULUM
kinetic energy potential energy Lagrangian 10

11 EXAMPLE: SPHERICAL PENDULUM
Lagrangian 11

12 MOMENT OF INERTIA For a particle with mass m and position vector that rotates with angular velocity about a line through the origin hence with respect to orthonormal coordinates x, y, z 12

13 MOMENT OF INERTIA Therefore the kinetic energy of the particle equals where I is the 3 x 3 inertia matrix for the particle 13

14 MOMENT OF INERTIA For a rigid body with density (mass per volume) If then where (see Calkin, page 38) 14

15 CENTER OF MASS The center of mass of a system of N particles with masses and positions is For a rigid body with density (mass per volume) 15

16 HAMILTONIAN A function of is said to be “conserved” if its time derivative is zero satisfies The Hamiltonian hence is conserved iff L does depend explicitly on t 16

17 HAMILTONIAN AND ENERGY
For scleronomic (time independent) holonomic constraints T is a quadratic form in the generalized velocities 17

18 HAMILTONIAN AND ENERGY
Therefore, for scleronomic holonomic constraints and the hamiltonian is the total energy 18

19 HAMILTONIAN AND ENERGY
For a bead with mass m on a horizontal wire rotating with angular speed and distance q from the center therefore and is conserved but This is an example of a rheonomic (time dependent) constraint in which the constraint (wire) can do work 19

20 Then for any smooth and small
EULER’S EQUATION Let F be a function of 3 variables and for any smooth function define Then for any smooth and small 20

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