![]() ![]() ![]() Jason: “It looks like if the boat is moving through the water, it affects the frequency of the waves measured by someone on the boat.” Ibrahim and Jason have just completed the above text and activity, and have the following discussion: Student discussion about a moving source. What happens if the boat moves directly toward the top or bottom of the screen?ī. What happens to the frequency as the boat moves away from the source? As the boat moves toward the source?ģ. When do you get the greatest difference between the observed and the emitted frequencies?Ģ. The second is the frequency of the waves as measured by the observer.ġ. The first is the frequency emitted by the source. In the bottom right corner, the frequency of the waves is displayed. The observer (the person in the boat) is able to move around the water. In this case, the source of waves is far to the right of the screen, so far in fact that the waves arrive parallel to each other. Source of waves is stationary, observer moves. Next, you will find a set of activities, each depicting a person in a boat and waves, but in different configurations.Ī. In that case, the boat does not go up and down at all, and the sailor measures zero frequency for the waves. Of course, in the case where the boat moves at precisely the same speed as the waves, the waves can never catch the boat. The faster the boat moves, the slower the frequency of the waves the sailor perceives. Similar to the previous case, the faster the boat moves, the bigger the effect. A person on the boat would therefore measure a lower frequency for the waves. This causes the boat to go up and down more slowly than it otherwise would. Each successive wave must catch the receding boat, and so it takes a little bit longer for the waves to reach the boat than it would if the boat were stationary. Now consider the case where the boat moves in the same direction as the waves (but still slower than they move through the water). The faster the boat moves toward the waves, the higher the frequency will be when measured on the boat. That is, as perceived by a person on the moving boat, the waves have a higher frequency than when the boat is stationary. Thus, they reach the boat a bit sooner than they would, and the boat is forced up and down more often than when it was stationary. Since the boat is moving toward the waves, successive waves do not have to travel quite as far to reach the boat as they would if the boat were stationary the boat rushes to meet them as they travel toward it. If you examine the situation, you can probably convince yourself that the frequency will change. Will the frequency at which the boat rises and falls remain the same, or will it change? Now imagine that the boat begins to sail directly into the oncoming waves. In that case, the boat will rise and fall with the frequency of the waves. ![]() Now, further imagine that the boat is in a harbor that is sheltered such that only waves from a certain direction and with a constant wavelength (or frequency) are allowed to enter. The boat will rise and fall periodically because waves in the water lift it as they pass. Imagine you are sitting in a boat on the ocean. We will explore how these very different things are related in the following section. Mika: “Well, I agree that light is different from sound, but I think that we can’t see the Doppler shift because light waves travel so much faster than sound waves.”Įver wonder how scientists are able to measure the masses of stars or galaxies? Or how they detect planets around other stars, or how it is possible to determine the distance to a galaxy across the Universe? It turns out that these measurements have something in common with everyday experiences like the apparent change in pitch of a car horn honking as it passes you.Light doesn’t need air to travel in, so it works in a different way than sound.” Nancy: “That’s because the Doppler shift really doesn’t apply to light.I mean, stop lights don’t shift colors, right?” Luke: “Okay, but light’s a wave, too, and we don’t see different colors of light as we drive toward or away from things.Once they pass, the frequency decreases.” Mika: “The sound waves from the cars have their frequency increased as the cars move toward us.Luke: “What did you say that was called, where the sound of the engines goes from high pitch to low pitch as they pass by us?”.After the cars pass by, Jason turns to Mika and Nancy. Mika, Nancy, and Luke are watching a Formula One race from the stands.
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