A Wave Pulse Travels Down A Slinky . The frequency of the wave pulse is f = 0.48 hz. Repeat your measurement three times and find the average.
Longitudinal Waves on a Slinky YouTube from www.youtube.com
Using the known length of the stretched slinky and the stopwatch, calculate the speed of the pulse as it travels up and down the slinky once. A traveling wave is one in which the waveform moves through the medium. The frequency of the wave pulse is f = 0.4 hz.
Longitudinal Waves on a Slinky YouTube
1) what is the speed of the wave pulse? The mass of the slinky is m = 0.94 kg and is initially stretched to a length l = 6.1 m. A wave pulse travels down a slinky. 1) what is the speed of the wave pulse?
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The wave pulse has an amplitude of a = 0.22 m and takes t = 0.494 s to travel down the stretched length of the slinky. 3 wave pulse travels at a speed v down the slinky/rope v determined by tension t and density (mass per unit length) turns out √ v is determined by properties of medium, not how.
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1) what is the speed of the wave pulse? Repeat your measurement three times and find the average. The wave pulse has an amplitude of a = 0.28 m and takes t = 0.48 s to travel down the stretched length of the slinky. A wave pulse travels down a slinky. A wave pulse travels down a slinky.
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The wave pulse has an amplitude of a = 0.23 m and takes t = 0.448 s to. As the slinky moves down the steps, energy is transferred along its length in a longitudinal or compressional wave, which resembles a sound wave that travels through a substance by transferring a. The mass of the slinky is m = 0.89 kg.
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16.67 m/s submit 2) what is the tension in the slinky? The mass of the slinky is m = 0.89 kg and is initially stretched to a length l = 7.1 m. The frequency of the wave pulse is f = 0.43 hz. 34.834 n submit 3) what is the average speed of a piece of the slinky as a.
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The wave pulse has an amplitude of a = 0.2 m and takes t = 0.426 s to travel down the stretched length of the slinky. The mass of the slinky is m = 0.86 kg and is initially stretched to a length l = 6.5 m. The mass of the slinky is m = 0.88 kg and is initially.
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The frequency of the wave pulse is f = 0.4 hz. The frequency of the wave pulse is f = 0.48 hz. The mass of the slinky is m = 0.86 kg and is initially stretched to a length l = 7.8 m. Stays in relatively the same location. 1) what is the speed of the wave pulse?
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1) what is the speed of the wave pulse? The frequency of the wave pulse is f = 0.42 hz. A wave pulse travels down a slinky. 1) what is the speed of the wave pulse? Repeat your measurement three times and find the average.
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The frequency of the wave pulse is f = 0.48 hz. A wave pulse travels down a slinky. The wave pulse has an… Repeat your measurement three times and find the average. A wave pulse travels down a slinky.
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A traveling wave is one in which the waveform moves through the medium. In the process, regions of rarefaction (where the density drops. Stays in relatively the same location. 34.834 n submit 3) what is the average speed of a piece of the slinky as a complete wave pulse passes? Continuous wave = series of repeating vibrations creates travelling waves.
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The wave pulse has an amplitude of a = 0.24 m and takes t = 0.49 s to travel down the stretched length of the slinky. A wave pulse travels down a slinky. A wave pulse travels down a slinky. 34.834 n submit 3) what is the average speed of a piece of the slinky as a complete wave pulse.
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The frequency of the wave pulse is f = 0.4 hz. When a wave propagates through a medium, the molecules of the medium; A region of air (or some other medium) is compressed, and as it expands it pushes on a neighboring region, causing it to compress, and passing the disturbance along. The frequency of the wave pulse is f.
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The wave pulse has an amplitude of a = 0.24 m and takes t = 0.49 s to travel down the stretched length of the slinky. The frequency of the wave pulse is f = 0.4 hz. As the slinky moves down the steps, energy is transferred along its length in a longitudinal or compressional wave, which resembles a sound.
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Solution for a wave pulse travels down a slinky. The mass of the slinky is m = 0.86 kg and is initially stretched to a length l = 6.5 m. The mass of the slinky is m = 0.89 kg and is initially stretched to a length l = 7.1 m. When a wave propagates through a medium, the molecules.
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The frequency of the wave pulse is f = 0.44 hz. The frequency of the wave pulse is f = 0.48 hz. A region of air (or some other medium) is compressed, and as it expands it pushes on a neighboring region, causing it to compress, and passing the disturbance along. Using the known length of the stretched slinky and.
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The frequency of the wave pulse is f = 0.4 hz. The frequency of the wave pulse is f = 0.49 hz. A traveling wave is one in which the waveform moves through the medium. The mass of the slinky is m = 0.86 kg and is initially stretched to a length l = 7.8 m. Sketch a ‘snapshot’ of.
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The pulse’s amplitude should be about one floor tile width. The frequency of the wave pulse is f = 0.48 hz. The wave pulse has an amplitude of a = 0.24 m and takes t = 0.49 s to travel down the stretched length of the slinky. The wave pulse has an amplitude of a = 0.2 m and takes.
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The wave pulse has an amplitude of a = 0.2 m and takes t = 0.426 s to travel down the stretched length of the slinky. The frequency of the wave pulse is f = 0.48 hz. A wave pulse travels down a slinky. The frequency of the wave pulse is f = 0.4 hz. A wave pulse travels down.
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3 wave pulse travels at a speed v down the slinky/rope v determined by tension t and density (mass per unit length) turns out √ v is determined by properties of medium, not how wave was created! The wave pulse has an amplitude of a = 0.2 m and takes t = 0.426 s to travel down the stretched length.
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The wave pulse has an amplitude of a = 0.23 m and takes t = 0.448 s to travel down the stretched length of the slinky. A wave pulse travels down a slinky. The frequency of the wave pulse is f = 0.48 hz. The frequency of the wave pulse is f = 0.4 hz. A wave pulse travels down.
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The wave pulse has an amplitude of a = 0.26 m and takes t = 0.472 s to travel down the stretched length of the slinky. A wave pulse travels down a slinky. A wave pulse travels down a slinky. Using the known length of the stretched slinky and the stopwatch, calculate the speed of the pulse as it travels.
