1- In a simple harmonic motion experiment, the period of an oscillator is measured using a...

Confirm that the expression for the period of the simple harmonic motion of an object of...

Confirm that the expression for the period of the simple harmonic motion of an object of mass m attached to a spring of force constant k is dimensionally correct.

A simple harmonic oscillator has a mass of 1.4 kg, a maximum speed of 0.55 m/s,...

A simple harmonic oscillator has a mass of 1.4 kg, a maximum speed of 0.55 m/s, and a spring constant of 20.5 N/m. Use Conservation of Energy to find the amplitude of the system. Assume that there are no frictional losses.

Simple Harmonic Motion: Mass on Spring (Explanation of lab.) [ The intentions of this lab were...

Simple Harmonic Motion: Mass on Spring (Explanation of lab.) [ The intentions of this lab were to further our understanding of spring mass motion by creating a harmonic motion system to find values for spring force and oscillation periods. By the end of the experiment, our group was able to experimentally determine how the measure of spring constant, k, in a harmonic motion system depends upon oscillation periods and ??y. We began our finding of k by running the experiment...

In the simple harmonic experiment, different masses were added to a spring. A graph of Force...

In the simple harmonic experiment, different masses were added to a spring. A graph of Force (weight) versus elongation was plotted. The graph was given by y = 9.4x +3.9. What is the spring constant of the spring in N/m ? In the simple harmonic experiment, different masses were added to a spring. For each mass, the preriod of oscillation was measured. A graph of Period squared versus mass was ploted. The linear graph was given by y = 3.36x...

As you know, a common example of a harmonic oscillator is a mass attached to a...

As you know, a common example of a harmonic oscillator is a mass attached to a spring. In this problem, we will consider a horizontally moving block attached to a spring. Note that, since the gravitational potential energy is not changing in this case, it can be excluded from the calculations. For such a system, the potential energy is stored in the spring and is given by U=12kx2, where k is the force constant of the spring and x is...

Question on Simple Harmonic Motion Since F = -k (Delta X), discuss how you would construct...

Question on Simple Harmonic Motion Since F = -k (Delta X), discuss how you would construct a linear graph using the data yielded from the spring constant K from the graph. What data would be the abscissa and what would be the ordinate. Would the expected slope be positive or negative

1. An object-spring system moving with simple harmonic motion (SHM) has an amplitude A. (a) What...

1. An object-spring system moving with simple harmonic motion (SHM) has an amplitude A. (a) What is the total energy of the system in terms of k and A only? (b) Suppose at a certain instant the kinetic energy is twice the elastic potential energy, KE = 2PE. Re-write this equation by using only the variables for the mass, m, velocity, v, spring constant, k, and position, x. (c) Using the results of (a) and (b) and conservation of energy,...

Problem 1 A simple harmonic oscillator consists of a block (m = 0.50 kg) attached to...

Problem 1 A simple harmonic oscillator consists of a block (m = 0.50 kg) attached to a spring (k = 128 N/m). The block is pulled a certain distance from the equilibrium position and released at t = 0 s. The block slides on a horizontal frictionless surface about the equilibrium point x = 0 m with a total mechanical energy of 16 J. a) What are the amplitude and phase constant of the oscillation? (4 pts.) b) Find the...

Simple harmonic motion of a mass-on-a-vertical-spring is being demonstrated to a physics class. Students are asked...

Simple harmonic motion of a mass-on-a-vertical-spring is being demonstrated to a physics class. Students are asked to find the spring constant, k. After suspending a mass of 335.0 g from the spring, one student notices the spring is displaced 45.5 cm from its previous equilibrium. With this information, calculate the spring constant. In the final section of the class, a student is asked to investigate the energy distribution of the spring system described above. The student pulls the mass down...

.1.) Modelling using second order differential equations a) Find the ODE that models of the motion...

.1.) Modelling using second order differential equations a) Find the ODE that models of the motion of the dumped spring mass system with mass m=1, damping coefficient c=3, and spring constant k=25/4 under the influence of an external force F(t) = cos (2t). b) Find the solution of the initial value problem with x(0)=6, x'(0)=0. c) Sketch the graph of the long term displacement of the mass m.