Answer to Question #83101 in Quantum Mechanics for Naima

1. The equation of simple harmonic motion can be written in the form x(t) = A sin (ωt + φ), where A is the amplitude, ω is the angular frequency, and φ is the phase. The angular frequency is related to the ordinary frequency f by the formula ω = 2πf. Now, x(t) is the displacement of object, while its velocity is given by the derivative v(t)=x'(t)=Aωcos(ωt+φ)=±Aω√(1-〖sin〗^2 (ωt+φ) )=±ω√(A^2-x^2 (t) ). The sign here depends on the phase of the motion. The absolute velocity v at a given displacement x is thus given by v=ω√(A^2-x^2 )=2πf√(A^2-x^2 ). Substituting here A = 0.01 m, x = 0.005 m, and f = 12 Hz = 12 s–1, we obtain, approximately, v = 0.653 m/s. The maximum velocity vm is reached at x = 0 and is given by vm = 2πfA = 0.754 m/s. Answer: v = 0.653 m/s, vm = 2πfA = 0.754 m/s.

2 The period of a simple pendulum is given by T=2π√(L⁄g), where L is its length, and g is the acceleration of gravity. If the length is increased by 25.6%, it is thus increased 1.256 times, hence, its period is increased √1.256≈1.12 times, and thus constitutes approximately 1.12 seconds. Answer: approximately 1.12 seconds.

3. The equation of motion of particle executing simple harmonic motion (SHM) is x(t) = A sin (ωt + φ), where A is the amplitude, ω is the angular frequency, and φ is the phase.