A string fixed at both ends is 8 long and has a mass of 0.120 kg. It is subjected to a tension 96 N and set oscillating. The longest possible wavelwngth and frequency of the standing wave are

A string fixed at both ends is 8.40 m long and has a mass of 0.120 kg . It is subjected to a tension of 96.0 N and set oscillating. (a) What is the speed of the waves on the string? (b) What is the longest possible wavelength for a standing wave ? (c) Give the frequency of the wave.

A string fixed at both ends is 7.50 m long and has a mass of 0.120 kg. It is subjected to a tension of 96.0 N and set oscillating (a) What is the speed of the waves on the string? (b) What is thc longest possible wavelength for a standing wave? (c) Give the frequency of that wave.

One end of a 2.4 - m string is held fixed and the other end is attached to a weightless ring that can slide along a frictionless rod as shown in Fig. 7.86. The three longest possible wavelength for standing waves in this string are respectively

A sting of length 1m and linear mass density 0.01 kg//m is stretched to a tension of 100 N. When both ends of the string are fixed, the three lowest frequencies for standing wave are f_1, f_2 and f_3 . When only one end of the string is fixed, the three lowest frequencies for standing wave are n_1, n_2 and n_3 . Then,

A stretched string fixed at both end has n nods, then the lengths of the string is

A string fixed at both ends has consecutive standing wave modes for which the distances between adjacent nodes are 18 cm and 16 cm respectively. The minimum possible length of the string is:

The wave-function for a certain standing wave on a string fixed at both ends is y(x,t) = 0.5 sin (0.025pix) cos500t where x and y are in centimeters and t is seconds. The shortest possible length of the string is :

A string along which waves can travel is 2.70 m long and has a mass of 130 g. The tension in the string is 36.0 N What must be the frequency of traveling waves of amplitude 7.70 mm for the average power to be 170 W?