Amr Elsayed said:Hi,
Does Doppler effect differs in reason from sound to light ? I mean is the Doppler effect of sound just because changing velocity ? In the case of light it's because of merely time dilation
Okay I know that time dilation applies in both cases, but because the speed of sound is changing unlike C, the change in frequency of sound will not be just about time dilation ?? I mean increasing speed of sound would necessarily associate a change in the frequency ?Nugatory said:Time dilation applies in both cases, but the effect is generally insignificant when we're working with sound.
Amr Elsayed said:Okay I know that time dilation applies in both cases, but because the speed of sound is changing unlike C, the change in frequency of sound will not be just about time dilation ?? I mean increasing speed of sound would necessarily associate a change in the frequency ?
Amr Elsayed said:In the case of light it's because of merely time dilation
Okay I now get how relative velocity affects rate of receiving light according to the moving body. But we think that time dilation will increase the rate of receiving light by the moving body when we relate the receiving of pulses to a specific time on the clock with the moving body which appears to be slow for me. But on the other hand if we relate the shooting of pulses to specific times on the fixed clock on the source, shouldn't I see the rate of emission smaller ? I know it's not, but why not ? I discussed this question in the other thread by the waybcrowell said:No, this is not true. We discussed this in the other thread you started: https://www.physicsforums.com/threads/rate-of-emission.821970/ .
The Doppler Effect is the change in frequency or wavelength of a wave in relation to an observer who is moving relative to the source of the wave. It is commonly observed in sound waves, such as the change in pitch of a siren as it passes by, and in light waves, such as the shift in color of a star as it moves away from us.
The main difference between the Doppler Effect in sound and light is the medium in which the waves travel. Sound waves require a medium, such as air or water, to travel through, while light waves can travel through a vacuum. This difference in medium affects the speed at which the waves travel, resulting in different observed effects.
The Doppler Effect is caused by the relative motion between the source of the wave and the observer. If the source is moving towards the observer, the waves will be compressed, resulting in a higher frequency (shorter wavelength) and a higher pitch (in sound waves). If the source is moving away from the observer, the waves will be stretched, resulting in a lower frequency (longer wavelength) and a lower pitch.
The Doppler Effect is used in various fields of science, including astronomy, meteorology, and seismology. In astronomy, it is used to determine the movement and distance of celestial objects. In meteorology, it is used to track the movement of storms. In seismology, it is used to analyze seismic waves and determine the location and magnitude of earthquakes.
Some common examples of the Doppler Effect in everyday life include the change in pitch of a car horn or ambulance siren as it passes by, the shift in sound of a train as it approaches and then moves away, and the change in frequency of a police car siren as it moves towards and then away from us. In astronomy, the redshift of distant galaxies is a result of the Doppler Effect, as the light waves are stretched due to the expansion of the universe.