The equation of a wave of amplitude 0.02 m and period 0.04 s travelling along a stretched string with a velocity of 25m/s will be

Write the equation of a simple harmonic progressive wave of amplitude 0.01 m and frequency 100 Hz travelling along the positive x-axis with a speed of 50 m/s.

Find the displacement of an air particle 3.5 m from the origin of disturbance at t=0.05 s, when a wave of amplitude 0.2 mm and frequency 500 Hz travels along it with a velocity 350 ms^(-1) .

A transverse sinusoidal wave of amplitude A, wavelength lamda and frequency f is travelling along a stretch string. The maximum speed of any point on the string is (v)/(10) , where, V is the velocity of wave propagation. If A=10^(-3)m, and V=10ms^(-1) , then lamda and f are given by

Two sinusoidal waves of the same period, with amplitudes of 5.0 and 7.0 mm, travel in the same direction along a stretched string, they produce a resultant wave with an amplitude of 10.0 mm. The phase constant of the 5.0mm wave is 0. What is the phase constant of the 7.0mm wave?

A wave represented by the given equation Y = A sin (10 pi x + 15 pi t + (pi)/(3)) , where x is in meter and t is in second. The expression represents (1) A wave travelling in the negative X direction with a velocity of 1.5 m/sec (2) A wave travelling in the negative X direction with a wavelength of 0.2 m (3) A wave travelling in the positive X direction with a velocity of 1.5 m/sec. (4) A wave travelling in the positive X direction with a wavelength of 0.2 m

The distance between two points on a stretched string is 20 cm. A pregressive wave of frequency 400 hertz travels on the string with a velocity of 100m//s . Calculate phase differency between the points.

A sinusidal wave with amplitude y_(m)=0.5mm and wavelength lambda=0.4m. is travelling on a string with speed v=12 m/s. At t=0 particle at x=0.1 m is located at y=0.25 mm and going down. (a) Find equation of wave. (b) Plot the sinusoidal wave at t=0.

(i) A sinusoidal wave is travelling along positive x direction and the displacements at two positions x = 0 and x = 1 m are given by y (0, t) = 0.2 cos (3 pi t) and y(1, t)=0.2 cos (3pit+pi/8) Find all possible wavelength of the wave if it is known that wavelength is greater than 0.4 m. (ii) A transverse sine wave of amplitude a = 0.1 cm is travelling along a string laid along the x-axis. The displacement (y) – time (t) graph of the string particle at x = 0.1 m is shown in first figure. The shape of the string at time t = 0.1 s is shown in second figure. At this time the particle at x = 0.11 m is having velocity in positive y direction write the equation of wave.

A string of linear density 0.2kg/m is stretched with a force of 500 N. If a transverse wave of wavelength 4m and amplitude (1//pi) metre is travelling along it, then the speed of the wave will be