12-d4 Verify that energy is conserved in sim- ple harmonic motion.
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- Current Attempt in Progress The function x-(18 m) cosi(Srad/st+ a/4 rad] gives the simple harmonic motion ofa body. Att-7.6s, what are the (a) displacement, (b) velocity, (e) acceleration, and (d) phase of the motion? Aln, what arethe fel treuency and periadtthe (a) Number Units (b) Number Units (c) Number i Units (d) Number Units (e) Number Units () Number Linits eTextbook and Merdia Attemut Oof Jued Save for Lata DELL Clee Inert F10 1otm Lock F7 F6 BAckliDace F4The function x- (18 m) cos((Sarad/st a/4 rad) gives the simple harmonic nibtion of a body. Att-76s what are the (a) displacement, (b) velocity, (c) acceleration, and (d) phase of the motion? Atsa, what are the le) frequency and )oeriod of the motiont (a) Number UnitsA 150 g mass is undergoing simple harmonic motion along the x-axis on an ideal spring with k=100 N/m. At t=0, the mass is at x=-10 cm and is moving with velocity v=-15 m/s. A) What is the total energy of the system? B) What is the position of the mass as a function fo time, x(t)? C) What is the acceleration of the mass at t=3.5 sec? note: Please answer with most steps explained. Thank you!!! :)
- A simple harmonic osccilator has mass 5.00g makes displacement varies as x=(5.60cm)cos((2.50rad/s)t+π/8). Calculate the maximum kinetic energy of the simple harmonic osccilator(b) Determine the equations of motion and frequency characteristics equation for the system shown inFigureQ8b. Take the equivalent mass of cylinder with respect to X2 as m2 + Jo/r. X1 X2 k m1 m2, Jo Figure Q8bPlease Explain thoroughly the formulas and adjustments made to the formulas:A person rides on a mechanical bucking horse (see Figure 13-24) that oscillates up and down withsimple harmonic motion. The period of the bucking is 0.75 s and the amplitude is slowly increasing. At acertain amplitude the rider must hang on to prevent separating from the mechanical horse.(a) What keeps the rider on the horse?. At what point in the motion is the rider most likelythrown?(b) Give a force diagram showing the forces acting on the rider.(c) Find the amplitude at which the rider must hold on or be thrown.