354749 Consider two sound sources \(S_{1}\) and \(S_{2}\) having same frequency \(100\;Hz\) and the observer \(O\) located between them. All the three are moving with same velocity in same direction. The beat frequency as heard by the observer is

354750 The observer is moving with velocity ' \(v_{0}\) ' towards the stationary source of sound and then after crossing moves away from the source with velocity \(v_{0}\). Assume that the medium through which the sound wave travel is at rest. If \(v\) is velocity of sound and \(n\) is the frequency emitted by the source, then the difference between apparent frequencies heard by the observer is

354751 An observer is moving away from a source at rest. The pitch of the note heard by the observer is less because

354752 With what velocity should an observer approach a stationary sound source so that the apparent frequency of sound should appear double the actual frequency? (\(v\) is velocity of sound).

354749 Consider two sound sources \(S_{1}\) and \(S_{2}\) having same frequency \(100\;Hz\) and the observer \(O\) located between them. All the three are moving with same velocity in same direction. The beat frequency as heard by the observer is

354750 The observer is moving with velocity ' \(v_{0}\) ' towards the stationary source of sound and then after crossing moves away from the source with velocity \(v_{0}\). Assume that the medium through which the sound wave travel is at rest. If \(v\) is velocity of sound and \(n\) is the frequency emitted by the source, then the difference between apparent frequencies heard by the observer is

354751 An observer is moving away from a source at rest. The pitch of the note heard by the observer is less because

354752 With what velocity should an observer approach a stationary sound source so that the apparent frequency of sound should appear double the actual frequency? (\(v\) is velocity of sound).

354749 Consider two sound sources \(S_{1}\) and \(S_{2}\) having same frequency \(100\;Hz\) and the observer \(O\) located between them. All the three are moving with same velocity in same direction. The beat frequency as heard by the observer is

354750 The observer is moving with velocity ' \(v_{0}\) ' towards the stationary source of sound and then after crossing moves away from the source with velocity \(v_{0}\). Assume that the medium through which the sound wave travel is at rest. If \(v\) is velocity of sound and \(n\) is the frequency emitted by the source, then the difference between apparent frequencies heard by the observer is

354751 An observer is moving away from a source at rest. The pitch of the note heard by the observer is less because

354752 With what velocity should an observer approach a stationary sound source so that the apparent frequency of sound should appear double the actual frequency? (\(v\) is velocity of sound).

354749 Consider two sound sources \(S_{1}\) and \(S_{2}\) having same frequency \(100\;Hz\) and the observer \(O\) located between them. All the three are moving with same velocity in same direction. The beat frequency as heard by the observer is

354750 The observer is moving with velocity ' \(v_{0}\) ' towards the stationary source of sound and then after crossing moves away from the source with velocity \(v_{0}\). Assume that the medium through which the sound wave travel is at rest. If \(v\) is velocity of sound and \(n\) is the frequency emitted by the source, then the difference between apparent frequencies heard by the observer is

354751 An observer is moving away from a source at rest. The pitch of the note heard by the observer is less because

354752 With what velocity should an observer approach a stationary sound source so that the apparent frequency of sound should appear double the actual frequency? (\(v\) is velocity of sound).