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If you are moving toward the source of a sound wave and then pass the source and continue moving away the will change.?
As you move toward the source of a sound wave, the frequency of the sound will appear to increase due to the Doppler effect. Once you pass the source and move away from it, the frequency of the sound will appear to decrease. The change in frequency is a result of the relative motion between you and the sound source.
What would be an observable change in sound when the frequency changes?
An observable change in sound when the frequency changes is a difference in pitch. As the frequency increases, the pitch becomes higher, and as the frequency decreases, the pitch becomes lower. This change in pitch is due to the direct relationship between frequency and pitch in sound waves.
Would A sound with a frequency of 12000 Hz be loud or sift?
A sound with a frequency of 12000 Hz would be high-pitched rather than loud or soft. Loudness is determined by the amplitude (intensity) of the sound wave, not its frequency.
The apparent change in the frequency of a sound emitted by a moving object as it passes a stationary abserver?
The apparent change in the frequency of a sound emitted by a moving object as it passes a stationary observer is called the Doppler effect. As the object moves towards the observer, the observer perceives a higher frequency (higher pitch) than what is actually emitted. Conversely, as the object moves away from the observer, the perceived frequency is lower than the actual frequency emitted.
If a sound had a high amplitude and high frequency what would it sound like?
The sound would be like thunder, since thunder also has high amplitudes and frequency also. Usually at the begining of thunder you will listen cracking (krat..kat..krat .........) sound which is high frequency and high pitch. At the time when thundering is almost stop you will listen the heavy /bass sound which is very high amplitude and low frequency (goom.goom....goom...........) sound.
What would be the observable change in the sound when the frequency changes?
what would be an observable change in sound when the frequency changes
If you are moving toward the source of a sound wave and then pass the source and continue moving away the will change.?
As you move toward the source of a sound wave, the frequency of the sound will appear to increase due to the Doppler effect. Once you pass the source and move away from it, the frequency of the sound will appear to decrease. The change in frequency is a result of the relative motion between you and the sound source.
When a sound wave with a frequency of 256 Hz overlaps with a sound wave with a frequency of 250 Hz what would the frequency of the beats be?
The beat frequency would be 6 Hz, which is the difference between the two overlapping frequencies (256 Hz - 250 Hz). This is the rate at which the intensity of the sound will oscillate, creating a pulsating effect.
Find the frequency of a sound wave that has a wavelength of 1.5 meter. Could you hear this sound?
To find the frequency, use the formula: frequency = speed of sound / wavelength. Assuming the speed of sound is 343 m/s, the frequency of the sound wave would be approximately 229 Hz. Yes, this frequency is within the audible range for humans, so you would be able to hear this sound.
If the speed of sound depended on frequency how would distant music sound?
If the speed of sound depended on frequency, distant music would sound distorted. Higher frequency sounds would travel faster than lower frequency sounds, causing a shift in the relative timing of different frequencies and resulting in a jumbled and unintelligible sound.
What would be an observable change in sound when the frequency changes?
An observable change in sound when the frequency changes is a difference in pitch. As the frequency increases, the pitch becomes higher, and as the frequency decreases, the pitch becomes lower. This change in pitch is due to the direct relationship between frequency and pitch in sound waves.
Would A sound with a frequency of 12000 Hz be loud or sift?
A sound with a frequency of 12000 Hz would be high-pitched rather than loud or soft. Loudness is determined by the amplitude (intensity) of the sound wave, not its frequency.
The apparent change in the frequency of a sound emitted by a moving object as it passes a stationary abserver?
The apparent change in the frequency of a sound emitted by a moving object as it passes a stationary observer is called the Doppler effect. As the object moves towards the observer, the observer perceives a higher frequency (higher pitch) than what is actually emitted. Conversely, as the object moves away from the observer, the perceived frequency is lower than the actual frequency emitted.
What happens if a sound wave is compressed?
it is unclear what you mean. One form of 'compression' would be the dopplar effect whereby a object producing sound is moving towards the listener. The sound heard by the listener is of a higher frequency than the sound that is produced.
If a sound had a high amplitude and high frequency what would it sound like?
The sound would be like thunder, since thunder also has high amplitudes and frequency also. Usually at the begining of thunder you will listen cracking (krat..kat..krat .........) sound which is high frequency and high pitch. At the time when thundering is almost stop you will listen the heavy /bass sound which is very high amplitude and low frequency (goom.goom....goom...........) sound.
Would there be a Doppler effect if the source of sound were stationary and the listener in motion?
Yes, there would still be a Doppler effect in this scenario. The observer's motion relative to the medium through which sound travels causes a change in the frequency of the perceived sound, even if the source is stationary.
Occurs when a sound passes an observer?
The Doppler Effect is the change in frequency or wavelength of a wave in relation to an observer who is moving relative to the wave source. This phenomenon can result in variations in pitch or frequency of sound waves as a source and observer move closer or farther apart.
