Wiki User
∙ 8y agoIf the amplitude of compression waves traveling along the spring increases, the spacing between coils of the spring will decrease. This is because the increased energy from the compression waves causes the coils to compress and come closer together. In essence, the increased amplitude results in a more compacted spring configuration.
As the amplitude of compression waves increases, the spacing between coils of the spring decreases. This is due to the increased compression force causing the coils to be pushed closer together. The closer spacing helps to transmit the increased energy of the compression waves more efficiently along the length of the spring.
No, the distance between one compression and the next compression in a longitudinal wave is its wavelength, not its amplitude. The amplitude of a wave is the maximum displacement of a particle from its rest position as the wave passes through it.
The relationship between amplitude and force is that the force required to maintain a certain amplitude of oscillation in a system is directly proportional to the square of the amplitude. This means that as the amplitude increases, the force required to sustain that motion also increases quadratically.
idk because im doin homework right now and i have no clue what to put down
The energy of a wave is directly proportional to the square of its amplitude. This means that as the amplitude of a wave increases, its energy also increases exponentially. Conversely, decreasing the amplitude of a wave will result in a decrease in its energy.
As the amplitude of compression waves increases, the spacing between coils of the spring decreases. This is due to the increased compression force causing the coils to be pushed closer together. The closer spacing helps to transmit the increased energy of the compression waves more efficiently along the length of the spring.
No, the distance between one compression and the next compression in a longitudinal wave is its wavelength, not its amplitude. The amplitude of a wave is the maximum displacement of a particle from its rest position as the wave passes through it.
The relationship between amplitude and force is that the force required to maintain a certain amplitude of oscillation in a system is directly proportional to the square of the amplitude. This means that as the amplitude increases, the force required to sustain that motion also increases quadratically.
idk because im doin homework right now and i have no clue what to put down
For example, when you have a spring you pull it, and some of it is tight together, and some is spread out. The spread out part is called a Rarefaction and the tight part is compression. The direction it moves is movement of wave, and the opposite side is the movement of coil.
The energy of a wave is directly proportional to the square of its amplitude. This means that as the amplitude of a wave increases, its energy also increases exponentially. Conversely, decreasing the amplitude of a wave will result in a decrease in its energy.
idk because im doin homework right now and i have no clue what to put down
In a spring, squeezing some coils together more tightly causes the nearby coils to be more spread apart. So this is how it increases.
idk because im doin homework right now and i have no clue what to put down
idk because im doin homework right now and i have no clue what to put down
As the frequency increases, the amplitude of a wave remains constant if the system is linear. In non-linear systems, the amplitude may change as the frequency increases due to factors such as resonance or saturation effects.
Wave intensity is directly proportional to the square of the wave amplitude. This means that as the wave amplitude increases, the wave intensity increases by a larger factor. In other words, a small change in wave amplitude can result in a significant change in wave intensity.