Fall 2007: CLASSICAL MECHANICS HOMEWORK ASSIGNMENT

PHY6426/Fall 2007: CLASSICAL MECHANICS HOMEWORK ASSIGNMENT #5: SOLUTIONS due by 9:35 a.m. Mon 10/01 Instructor: D. L. Maslov ... Goldstein, Problem 5...

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PHY6426/Fall 2007: CLASSICAL MECHANICS HOMEWORK ASSIGNMENT #5: SOLUTIONS due by 9:35 a.m. Mon 10/01 Instructor: D. L. Maslov [email protected] 392-0513 Rm. 2114 Please help your instructor by doing your work neatly.

1. Goldstein, Problem 5.3 (30 points) T =

1X mi~vi2 , 2 i

sum is over all particles in the system. dT 1 X d~vi = mi ·~vi dt 2 i dt For rotation, ~vi = ω ~ ×~ri so that dT 1 X d~vi mi = · (~ ω ×~ri ) . dt 2 i dt Using the cyclic property of the mixed product, µ ¶ d~vi d~vi · (~ ω ×~ri ) = ω ~ · ~ri × , dt dt and summing over the particles, we find dT ~, =ω ~ ·N dt where ~ = N

X i

µ ¶ X d~vi ~ri × mi = ~ri × F~i dt i

vi th and F~ = mi d~ particle. dt is the force on the i

2. Goldstein, Problem 5.16 (30 points) Tensor of inertia 

 5 0 0 Iˆ = 2ma2  0 3 −2  . 0 −2 3 ˆv = λ~v reduces to finding the roots of the equation The eigenvalue problem I~ ³ ´ Det Iˆ − λˆ1 = 0,

2 where ˆ1 is the unity matrix. The roots are λ = 2ma2 (5, 5, 1) . The double degenerate eigenvalue λ1 = λ2 = 10ma2 corresponds to the following equation for the components of the eigenvalue vector       0 0 0 v1 0 0  0 −2 −2   v2  =  −2(v2 + v3 )   0  . 0 −2 −2 v3 −2(v2 + v3 ) 0 Hence, v1 can be arbitrary, whereas v2 and v3 must satisfy v2 + v3 = 0. One of the eigenvectors satisfying these conditions is   0 ~v (1) =  1  . −1 The other eigenvector, orthogonal to the first one can be chosen as   1 ~v (2) =  0  0 The non-degenerate eigenvalue λ3 = 2ma2 corresponds to       v1 4v1 0 4 0 0  0 2 −2   v2  =  2(v2 − v3 )   0  → 0 −2 2 v3 −2(v2 − v3 ) 0 

~v (3)

 0 =  1 . 1

The principal axes can be chosen as the x− axis, and lines z = y and z = −y. 3. Goldstein, Problem 5.17 (40 points) See Ch. 32 in Landau & Lifshits, ”Mechanics”, problem 7, p. 104.