Set up the following BVP wave problem and solve it. Suppose there is a string of...

Solve the following inhomogeneous wave problem for a vibrating string of length 1 (0 ≤ x...

Solve the following inhomogeneous wave problem for a vibrating string of length 1 (0 ≤ x ≤ 1): ∂^2u/ ∂t^2 = 1/2 * ∂^2u/∂x^2 − x. The initial conditions are u(x, 0) = cos(πx/2) + 1/3x^3 & ∂u/∂t (x, 0) = 0 boundary conditions are ∂u/∂x(0, t) = 0  & u(1, t) = 1/3.

A standing wave is set up in a L=2.00m long string fixed at both ends. The...

A standing wave is set up in a L=2.00m long string fixed at both ends. The string vibrates in its 5th harmonic when driven by a frequency f=120Hz source. The mass of the string is m=3.5grams. Recall that 1kg = 1000grams. A. Find the linear mass density of the string B. What is the wavelength of the standing wave C. What is the wave speed D. What is the tension in the string E. what is the first harmonic frequency...

A transverse sinusoidal wave is moving along a string in the positive direction of an x...

A transverse sinusoidal wave is moving along a string in the positive direction of an x axis with a speed of 93 m/s. At t = 0, the string particle at x = 0 has a transverse displacement of 4.0 cm from its equilibrium position and is not moving. The maximum transverse speed of the string particle at x = 0 is 16 m/s. (a) What is the frequency of the wave? (b) What is the wavelength of the wave?...

A transverse sinusoidal wave is moving along a string in the positive direction of an x-axis...

A transverse sinusoidal wave is moving along a string in the positive direction of an x-axis with a speed of 89 m/s. At t = 0, the string particle at x = 0 has a transverse displacement of 4.0 cm from its equilibrium position and is not moving. The maximum transverse speed of the string particle at x = 0 is 18 m/s. (a) What is the frequency of the wave? (b) What is the wavelength of the wave? If...

Oscillation of a 230 Hz tuning fork sets up standing waves in a string clamped at...

Oscillation of a 230 Hz tuning fork sets up standing waves in a string clamped at both ends. The wave speed for the string is 750 m/s. The standing wave has four loops and an amplitude of 1.6 mm. (a) What is the length of the string? (b) Write an equation for the displacement of the string as a function of position and time. Round numeric coefficients to three significant digits.

1a. Derive a formula for the wavelength of a standing wave on a fixed string at...

1a. Derive a formula for the wavelength of a standing wave on a fixed string at both ends in terms of the number of antinodes, n, and the length of the string. 1b. For an aluminum rod, when a wave is set up in the rod, do you expect the ends of the rod to allow vibrations or not? Are they considered open or closed for displacement? 1c. Draw schematic pictures of the two longest wavelengths that could fit on...

Solve the BVP for the wave equation ∂^2u/∂t^2(x,t)=∂^2u/∂x^2(x,t),  0 < x < pi, t > 0 u(0,t)=0,...

Solve the BVP for the wave equation ∂^2u/∂t^2(x,t)=∂^2u/∂x^2(x,t),  0 < x < pi, t > 0 u(0,t)=0, u(pi,t)=0,  ? > 0, u(0,t)=0,  u(pi,t)=0,  t>0, u(x,0)= sin(x)cos(x), ut(x,0)=sin(x), 0 < x < pi

A guitar string lies along the x-axis when in equilibrium. The end of the string at...

A guitar string lies along the x-axis when in equilibrium. The end of the string at x = 0 is fixed. A sinusoidal wave with amplitude 0.75mm and frequency 440Hz, travels along the string in x-direction at 143m/s. It is reflected from the fixed end, and the superposition of the incident and reflected waves forms a standing wave. (a) Find the equation giving the displacement of a point on the string as a function of position and time. (b) Locate...

A stretched string of length L is plucked at a position L/3 by producing an initial...

A stretched string of length L is plucked at a position L/3 by producing an initial displacement h and then releasing the string. Determine the resulting amplitudes for the fundamental and the first three harmonic overtones. Sketch the wave shapes of these individual waves and the shape of the string resulting from the linear combination of these waves at t = 0. Repeat for t = L/c, where c is the transverse wave speed on the string.

Please show all steps, thanks!! a) Solve the BVP: y" + 2y' + y = 0,...

Please show all steps, thanks!! a) Solve the BVP: y" + 2y' + y = 0, y(0) = 1, y(1) =3 b) Prove the superposition principle: suppose that the functions y1(x) and y2(x) satisfy the homogenous equation of order two: ay'' + by' + cy = 0. Show that the following combinations also satisfy it: constant multiple m(x) = k*y1(x) sum s(x) = y1(x) + y2(x)