Throws a door at me? Well, it is kinda stupid But, here's a real life example. When am I ever gonna find myself in a gym, and some beefy, bodybuilder I mean, this was a really stupid example. And, you can clean things up if you want. Of the amount I scream times, these two factors. Because the frequency should get increased by this Doppler Shift. And I know that I should be getting a larger total amountįor the frequency I hear. Dividing by a smaller denominator gives me a larger total amount. I wanna subtract because subtracting gives me a smaller denominator. The Doppler Shift should increase the frequency that I hear. So again, speaker, thisĭoor moving toward me. Memorizing is the fact that if things come toward each other, the frequency should be increasing. And on the bottom it's speed of sound plus or minus the speed That factor, if you remember, speed of sound on top. I need to multiply this by another factor that takes into account, the fact that the speaker- this door's not a speaker, but it's acting as a moving This was the frequency right here, f-door. Remember, this was the frequency, the door was receiving. The frequency I hear will be the frequency the speaker What frequency will I actually hear? Alright, we gotta doĪnother Doppler Shift. So I wanna know the frequency that I will actually hear. This door is observing, experiencing a higher frequency. We know what happens with moving speakers. This door is acting like a speaker, and it's acting a like moving speaker, because the door's moving. But no, because this is theįrequency the door hears. And then I should hear that frequency too. That's the way I remember whether I should add or subtract it here. I want the plus sign,īecause a big numerator gives me a larger frequency. So the frequency this door experiences should be bigger than the frequency that's actually emitted by If I'm moving toward the source, or if the source is moving toward me. So I ask myself this- I could never remember this as a student. Speed of sound up top, plus or minus for a moving observer. f-door is gonna equal the frequency that the wave actually has. And if we use the Doppler Effect formula. Because I wanna know what the door hears. Now, doors can't hear anything, but if this door was a person, what frequency would it hear? It wouldn't be f-scream. I wanna know what sound this door would hear if This door is gonna actĪs a moving observer. I'm gonna think of theĭoor as an observer first. So the frequency that I hear- I'm gonna have to do this I wanna know, what frequency would I hear? So I'm gonna have to use What sound would you hear,Īfter this sound wave reflected off the doorĪnd got back to you? Would you hear the same frequency that you're screaming at? Would you hear a higher frequency? Would you hear a lower frequency? Exactly what frequency would you hear? Let's figure it out, it's a This sound is gonna come over to here, it's gonna reflect off the door. And I'm going to call thatįrequency of the scream. I'm like, "Oh, no!" I start screaming at a certain frequency. You're looking at thisĭoor coming towards you. He doesn't know where he's throwing it, but he ends up throwing He's so mad, he takes theĭoor, he rips the door off. Because he's never wiping down his sweat off all the equipment. Because there's thisīig, beefy bodybuilder. Light waves can also be read, examples are:Īn extreme example of the doppler effect is an aeroplane flying at a faster speed than the speed of sound and how the wall of sound is heard on the ground.-Imagine, you are at the gym.
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