PHY 3003 SPRING 2015: WEEKS OF MARCH 9 AND 16 Reading
Transcription
PHY 3003 SPRING 2015: WEEKS OF MARCH 9 AND 16 Reading
PHY 3003 SPRING 2015: WEEKS OF MARCH 9 AND 16 Reading: Taylor, Chapter 6, all and 7.1-7.3 Homework: Due in class March 23. All problems count equally towards your grade. (Numbers refer to problems in Classical Mechanics, J. R. Talyor, 2005 Edition). This counts as two problem sets. (1) Consider an oscillator described by a coordinate x obeying the equation dx d2 x +4 + x = cos (t) 2 dt dt The general solution is the sum of a particular solution xp and the general solution of the associated homogeneous equation, xh . To construct the particular solution we note that the oscillator frequency Ω = 1 and the drive frequency ω = 1. The damping coefficient τ1 = 2. This implies the phase angle is π/2 while the q 2 amplitude factor R = 1/ (ω 2 − Ω2 )2 + 4 ωτ 2 = 1/4 so cos t − π2 xp = 4 For the homogeneous solution we note that we are in the overdamped case with the two decay constants given as r √ 1 1 1 2 =2± 3 = ± − Ω τ± τ τ2 Thus the general solution is π 2 sin t − A+ − τt+ A− − τt− v(t) = − e − e − τ+ τ− 4 π 2 − τt x(t) = A+ e + + A− e − τt − cos t − + 4 implying (a) Find x(t > 0) and v(t > 0) assuming that both x and v = dx/dt equal 0 at t = 0. x(t = 0) = 0 and v(t = 0) = 0 means A+ + A− = 0 − 1 A+ A− 1 − + =0 τ+ τ− 4 2 PHY 3003 SPRING 2015: WEEKS OF MARCH 9 AND 16 The first equation implies A− = −A+ ; using this in the second gives 1 A+ = √ 8 3 so t cos t − π2 1 −τ − τt e + −e − + x(t) = √ 4 8 3 (b) Find x(t > 0 and v(t > 0) assuming that at t = 0, x = 0 but v = 0.5 We still have A+ = −A− but now A+ A− 1 1 − + = − τ+ τ− 4 2 so 1 A+ = − √ 8 3 and so t cos t − π2 1 −τ − τt e + −e − + x(t) = − √ 4 8 3 (c) Sketch (on one graph) the phase plane portraits showing the evolution of these two solutions for t > 0. 0.4 0.2 0.0 -0.2 -0.4 -0.4 -0.2 0.0 0.2 0.4 Figure 1. Phase plane portraits: Solid line: solution to (a); dashed line, solution to (b). Notice how the solution converges to the circle that is the particular solution. PHY 3003 SPRING 2015: WEEKS OF MARCH 9 AND 16 3 (2) Consider a general harmonically driven oscillator obeying the equation d2 x 2m dx + + kx = Fd cos (Ωd t) dt2 τ dt We saw in class that the steady state solution (at long times, after the transients have died away) is of the form m x(t) = RFd cos (Ωd t − φ) with R and φ determined by m, τ and k. Over one quarter period, x changes from −RFd to 0. Compare the energy put in to the oscillator over this time by the driving force to the energy taken out of the oscillator by friction. The velocity is v(t) = −RFd Ωd sin (Ωd t − φ) A time at which x = −RF is t = (π + φ)/ΩD . One quarter period later t = t = ( 3π 2 + φ)/ΩD . Energy put into oscillator is Z Ein = dtF v = −RFD2 ΩD Z 3π +φ 2 2ΩD π+φ ΩD dt cos (ΩD t) sin (ΩD t − φ) Using cosAsinB = (Sin(A + B) − Sin(A − B))/2 we get Ein RFD2 ΩD =− 2 Z 3π +φ 2 ΩD π+φ Ωd dt (sin (2ΩD t − φ) − sin (φ)) or Ein = RFD2 RFD2 (Cos (3π + φ) − Cos(2π + φ)) + sinφ 4 4 or RFD2 RFD2 Cos (φ) + sinφ 2 4 Energy taken out of oscillator is Ein = − Z Eout = 2m 2 2 2 dtF v = R FD ΩD τ Z 3π +φ 2 2ΩD π+φ ΩD dt sin2 (ΩD t − φ) = mR2 FD2 ΩD 2τ (3) 5.43 (variant): answer this question but instead of using the data in the book assume that the car sinks by 2 cm if one 80kG passenger climbs in and that the axle assembly has total mass 10kG. Here we need to estimate the spring constant for the wheel assembly and then note that the spring constant, plus the mass of the wheel assembly, implies an oscillation frequency for the car. 4 PHY 3003 SPRING 2015: WEEKS OF MARCH 9 AND 16 (a) Car without passenger has mass M and is supported by the 2 axle assemblies. Each axle assembly has 2 springs, each of spring constant K. Thus the extension of the springs H is given by 4KH = gM We add a person, mass 80kG and H → H + 0.02m. Thus approximating g = 10m/sec2 4K × 0.02m = g(80kG) so 80 × 10 = 104 N/m2 4 × 0.02 (b) Because each axle has 2 wheels the total spring constant for the axle is 2K = 2 × 104 N/m2 . The mass of the axle assembly is 10kG so the oscillation frequency ω0 is r r 2K 2 × 104 = ≈ 45/sec ω0 = maxle 10 K= This implies that the period 2π/ω0 ≈ 0.13 sec. If the car is driven over a road with bumps spaced 0.8m apart then then the velocity at which these bumps will resonate with the suspension of the car is 0.8/0.13 ≈ 6m/sec (4) 6.1 and 6.16 The infinitesimal path length is p dl = dx2 + dy 2 + dz 2 Expressing x, y, z in polar coordinates and taking the differential gives dz = −Rsinθdθ dx = Rcosθcosφdθ − Rsinθsinφdφ dy = Rcosθsinφdθ + Rsinθcosφdφ so dx2 + dy 2 + dz 2 = R2 dθ2 + sin2 θdφ2 = R2 1 + sin2 θ so s dl = R 1+ dφ dθ s 2 dθ and Z θstop L=R 1+ θstart dφ(θ) dθ 2 dθ dφ dθ 2 ! dθ2 PHY 3003 SPRING 2015: WEEKS OF MARCH 9 AND 16 5 Because the “Lagrangian” (argument of the integral) has no explicit dependence on θ we may construct the conserved “energy” as 2 s dφ dθ 1 dφ(θ) 2 = −r H=r 2 − 1 + 2 dθ dφ(θ) 1 + dφ(θ) 1 + dθ dθ This implies that dφ dθ is constant, which is the equation for a great circle path, in other words a path traced out by drawing the circle that is centered at the origin of the sphere and connects the two points. (5) 6.22 Noting that ds2 = dx2 + dy 2 we have s 1− dx = dy ds 2 ds so that Z s Z A= ydx = 1− y dy ds 2 ds Again the absence of explicit dependence on s gives us a conserved “energy” which is 2 s 2 y dy ds dy y H = −r = −r 2 − y 1 − ds 2 dy 1 − dy 1 − ds ds in terms of dy/dx gives y2 1− 2 = H dy ds 2 whose solution is y = Hsin(s) which is the equation of a circle of radius H, related to length by l = 2πH. (6) 6.24 We want to minimize Z T = Z nds = a 1 ds = a r2 s Z dr Thus the Euler-Lagrange equation is d δL d = dr δ dφ dr dr dφ dr r2 dφ dr r r2 1 + r2 1 + r2 dφ dr 2 = 0 2 1 r2 6 PHY 3003 SPRING 2015: WEEKS OF MARCH 9 AND 16 implying dφ dr r 2 = c dφ dr dφ dr 1 + r2 or 2 d −r 2 2 =1 with d = 1/c. We can rearrange this equation to dr d2 − r2 writing r = dsinψ we conclude dψ = dφ so dφ = √ r = dsinφ Thus d d sin2φ y = rsinψ = dsin2 φ = (1 − cos2φ) 2 2 so 2 d d2 2 x + −y = 2 4 which is the equation of a circle centered at 0, d2 and touching the origin on one side. As light approaches the origin (moving along the circle, it is progressively slowed down and its angle changes more. x = rcosφ = dcosφsinφ = (7) 7.8 In the general case L= 1 2 k 1 2 x˙ 1 + x˙ − (x1 − x2 − l)2 2m1 2m2 2 2 We have 1 x1 = X + x 2 1 x2 = X − x 2 Specializing to m1 = m2 = m we find 1 1 2 k L = X˙ 12 + x˙ − (x − l)2 m 4m 2 Thus because L does not depend on X the equations of motion are ¨ = 0 X x ¨ = k (x − l) PHY 3003 SPRING 2015: WEEKS OF MARCH 9 AND 16 7 so that X simply moves at a velocity determined by the initial conditions while the relative coordinate executes simple harmonic motion around the value x = l. (8) 7.14 The angular velocity is Rω = x˙ so m m m 2 mR2 2 x˙ + ω˙ − mgx = x˙ 2 + x˙ 2 − mgx 2 4 2 4 The Euler-Lagrange equation is thus d m mx˙ + x˙ = −mg dt 2 implying 2g x ¨=− 3 L= (9) 7.22 Here the velocity of the pendulum bob is the sum of the velocity relative to the suspension point |v| = Lφ˙ plus the velocity due to the upward acceleration vaccel = at; the position is −Lcosφ + at2 /2; thus 2 2 m ˙ at Lφ + at − mg − Lcosφ L= 2 2 so the Euler-Lagrange equation is (note the factor of L which comes from the chain rule) d ˙ Lφ + at = −mgLsin(φ) mL dt or g+a φ¨ = − sinφ L For small oscillations we may replace sinφp→ φ, obtaining a harmonic oscillator equation. The mass is 1 so the frequency is (g + a)/L