In a sinusoidal wave, the time required for a particular point to move from maximum displacement to zero displacement is 0.14 second. The frequency of the wave is

Solve the following example: If the time period of a wave if 0.004s, find the frequency of the wave.

In fundamental mode, the time required for the sound wave to reach upto the closed end of a pipe filled with air is 0.01 s . The frequency of vibration of air column is

Solve the following example: A sound wave passes over a fixed point in space. Ten compression and ten rarefactions pass the point in 0.1 second. Find the frequency and time period of the wave.

If the wavelength of a certain wave of light is 2.0 xx 10^3 cm. What is the frequency of this wave?

A wave travels in a medium according to the equation of displacement given by y(x, t) = 0.03 sin pi where y and x are in metres and t in seconds. The wavelength of the wave is

A wave passes over a fixed point in space. If 20 compressions and 20 rarefaction pass the point in 0.1 s, find the frequency and time period of the wave.

Two sound wave of wavelength 0.80 m and 0.81 m produce 8 beats per second in air. The frequency of the two waves are respectively:

A simple pendulum oscillates in a verticle plane. When it passes through the bottommost point, the tension in the string is 3 times the weight of the pendulum bob. What is the maximum displacement of the pendulum of the string with respect to the vertical

The frequency of a wave of light is 1.0 xx 10^16 sec^-1 . The wave length for this wave is

A progressive wave travels on a stretched string. A particle on this string takes 4.0ms to move from its mean position to one of its extreme positions. The distance between two consecutive points on the string which are at their mena positions (at a certain time instant) is 2.0cm. Find the frequency, wavelength and speed of the wave.