![]() The observer moving toward the source receives them at a higher frequency (and therefore shorter wavelength), and the person moving away from the source receives them at a lower frequency (and therefore longer wavelength).įigure 14.16 The same effect is produced when the observers move relative to the source. Therefore, the wavelength is shorter in the direction the source is moving (on the right in Figure 14.15), and longer in the opposite direction (on the left in Figure 14.15).įinally, if the observers move, as in Figure 14.16, the frequency at which they receive the compressions changes. But if the source is moving and continues to emit sound as it travels, then the air compressions (crests) become closer together in the direction in which it’s traveling and farther apart in the direction it’s traveling away from. If the source and observers are stationary, then observers on either side see the same wavelength and frequency as emitted by the source. ![]() In each case, the sound spreads out from the point where it was emitted. What causes the Doppler effect? Let’s compare three different scenarios: Sound waves emitted by a stationary source ( Figure 14.14), sound waves emitted by a moving source ( Figure 14.15), and sound waves emitted by a stationary source but heard by moving observers ( Figure 14.16). Safety warning: Make sure the buzzer is secured tightly to the string before swinging. What could be the reason for the changing pitch? Ask students how they think this happens. However, when you swing it around your head, its pitch appears to change. If so, when did it appear to be higher? And when was it lower? You can do a demonstration of the Doppler effect in class using a buzzer and a string. ![]() ![]() Ask students if they have ever experienced the phenomenon where a car horn or siren appears to change its pitch as the vehicle passes them by. ![]()
0 Comments
Leave a Reply. |