Assuming the speed of sound in air equal to 340 m`s^(-1)` and in water equal to 1360 m `s^(-1)`, find the time taken to travel a distance 1700 m by sound in air .

Assuming the speed of sound in air equal to 340 m s^(-1) and in water equal to 1360 m s^(-1) , find the time taken to travel a distance 1700 m by sound in water.

The speed of sound in air is 330 m s^(-1) and in water is 1650 m s^(-1) . It takes 2 s for sound to reach a certain distance from the source placed in air. Find the distance.

The speed of sound in air is 330 m s^(-1) and in water is 1650 m s^(-1) . It takes 2 s for sound to reach a certain distance from the source placed in air. How much time will it take for sound to reach the same distance when the source is in water ?

Ultrasonic waves of frequency 4.5 MHz are used to detect tumour in soft tissues. The speed of sound in tissue is 1.5 km s^-1 and that in air is 340 m s^-1 . Find the wavelength of this ultrasonic wave in air and in tissue.

The speed of sound in air is 332 in ms^-1. Is it advisable to define the length 1 m as the distance travelled by sound in 1/332 s ?

If speed of sound in air is 340 m//s and in water is 1480 m//s .If frequency of sound is 1000 kHz, then find wavelength in water

A train approaching a railway platform with a speed of 20 m s^(-1) starts blowing the whistle. Speed of sound in air is 340 m s^(-1) . If the frequency of the emitted sound from the whistle is 640 Hz, the frequency of sound as heard by person standing on the platform

The distance of a galaxy from the earth is 5.6 xx 10^(25) m. Assuming the speed of light to be 3 xx 10^8 m s^(-1) find the time taken by light to travel this distance.

The speed of sound waves in air at 300K is 332 m/s. At what temperature will the speed be 574 m/s

A source of sound of frequency 1000 Hz moves to the right with a speed of 32(m)/(s) relative to the ground. To its right there is a reflecting surface moving to the left with a speed of 64(m)/(s) relative to the ground. Take the speed of 64(m)/(s) . Relative to the ground. Take the speed of sound in air to be 332(m)/(s) and find (a) The wavelength of the sound emitted in air by the source, (b) the number of waves per second arriving at the reflecting surface, (c ) The speed of the reflected waves and (d) The wavelength of the reflected waves.