A transverse sinusoidal wave is generated at one end of a long, horizontal string by an oscillator moving up and down through a total distance of 1.00 cm. The motion is continuous at a frequency of 120 Hz. The string has a linear density of 120 g m 1 and is kept at a tension of F = 90.0 N. a. Calculate the maximum value of the transverse speed u b. Calculate the maximum value of the transverse component of tension f c. I Show that the two maximum values found in (a) and (b) occur at the same phase values for the wave, and determine the transverse displacement y at this point.

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10) A transverse sinusoidal wave is generated at one end of a long, horizontal string by an
oscillator moving up and down through a total distance of 1.00 cm. The motion is continuous
at a frequency of 120 Hz. The string has a linear density of 120 g m1 and is kept at a tension
of F = 90.0 N.
a. Calculate the maximum value of the transverse speed u
b. Calculate the maximum value of the transverse component of tension f
c. I Show that the two maximum values found in (a) and (b) occur at the same phase
values for the wave, and determine the transverse displacement y at this point.
Transcribed Image Text:10) A transverse sinusoidal wave is generated at one end of a long, horizontal string by an oscillator moving up and down through a total distance of 1.00 cm. The motion is continuous at a frequency of 120 Hz. The string has a linear density of 120 g m1 and is kept at a tension of F = 90.0 N. a. Calculate the maximum value of the transverse speed u b. Calculate the maximum value of the transverse component of tension f c. I Show that the two maximum values found in (a) and (b) occur at the same phase values for the wave, and determine the transverse displacement y at this point.
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