Please draw the picture of the problem and explain why the author picked this initial condition in the solution.

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The body is hanging in its equilibrium position when it receives a sudden blow which projects it upwards with speed u. Find the subsequent motion. Solution When the spring is subjected to a constant force of magnitude mg, the extension is b. Hence a, the strength of the spring, is given by a = mg/b. Let z be the downwards displacement of the body from its equilibrium position. Then the extension of the spring is b + z and the restoring force is a(b + z) g(b+z)/b. The equation of motion for the body is therefore that is m d²z dt² where Ω (g/b)¹/2 = mg d²z + dt² b = This is the SHM equation with ² g/b. It follows that the period of vertical oscillations about the equilibrium position is given by T = b 27 (2) " In the initial value problem, the subsequent motion must have the form 2л 52 mg (b+z) b z = 0. 2π = X = - x = A cost + B sin St, where = (g/b)¹/2. The initial condition x = 0 when t = 0 shows that A = 0 and 0 then gives B = −u, that is, B -u/S2. = the initial condition x =-u whe t = The subsequent motion is therefore И 1/2 = · sin Ωt,

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Example 5.1 An initial value problem for classical SHM A body of mass m is suspended from a fixed point by a light spring and can move under uniform gravity. In equilibrium, the spring is found to be extended by a distance b. Find the period of vertical oscillations of the body about this equilibrium position. [Assume small strains.]