![]() ![]() It is important to note that the effect does not result because of an actual change in the frequency of the source. The Doppler effect can be described as the effect produced by a moving source of waves in which there is an apparent upward shift in frequency for observers towards whom the source is approaching and an apparent downward shift in frequency for observers from whom the source is receding. The Doppler effect is observed whenever the source of waves is moving with respect to an observer. This effect is known as the Doppler effect. The net effect of the motion of the bug (the source of waves) is that the observer towards whom the bug is moving observes a frequency that is higher than 2 disturbances/second and the observer away from whom the bug is moving observes a frequency that is less than 2 disturbances/second. For this reason, observer A observes a frequency of arrival that is less than the frequency at which the disturbances are produced. On the other hand, each consecutive disturbance has a further distance to travel before reaching observer A. Thus, observer B observes that the frequency of arrival of the disturbances is higher than the frequency at which disturbances are produced. Subsequently, each consecutive disturbance has a shorter distance to travel before reaching observer B and thus takes less time to reach observer B. ![]() Since the bug is moving towards the right, each consecutive disturbance originates from a position that is closer to observer B and farther from observer A. Now suppose that our bug is moving to the right across the puddle of water and producing disturbances at the same frequency of 2 disturbances per second. If the bug produces disturbances at a frequency of 2 per second, then each observer would observe them approaching at a frequency of 2 per second. In fact, the frequency at which disturbances reach the edge of the puddle would be the same as the frequency at which the bug produces the disturbances. ![]() An observer at point A (the left edge of the puddle) would observe the disturbances to strike the puddle's edge at the same frequency that would be observed by an observer at point B (at the right edge of the puddle). These circles would reach the edges of the water puddle at the same frequency. The pattern produced by the bug's shaking would be a series of concentric circles as shown in the diagram at the right. Since each disturbance is traveling in the same medium, they would all travel in every direction at the same speed. If these disturbances originate at a point, then they would travel outward from that point in all directions. The bug is periodically shaking its legs in order to produce disturbances that travel through the water. Suppose that there is a happy bug in the center of a circular water puddle. ![]()
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