Figure shows a wave pulse at t=0. The pulse moves to the right with a speed of 10cms^-1. Sketch the shape of the string at t=s, 2s and 3s.

Figure shows a wave pulse at t=0. The pulse moves to the right with a speed of 10cms^-1. Sketch the shape of the string at t=1s, 2s and 3s.

Figure shows a wave pulse at t=0. The pulse moves to the right with a speed of 10cms^-1. Sketch the shape of the string at t=1s, 2s and 3s.

Two pulses on a string approach each other at speeds of 1m//s what is the shape of the string at t=6s?

Following figure shows two wave pulses at t = 0 travelling on a string in opposite directions with the same wave speed 50 cm s1. Sketch the shape of the string at t = 4 ms, 6 ms, 8 ms, and 12 ms.

A pulse travelling on a string is represented by the function y=a^3/((x-vt)^2+a^2) where a=5 mm and v=20 cms^-1. Sketch the shape of the string at t=0, 1 s and 2s. Take x=0 in the middle of the string.

Two triangular wave pulses are travelling toward each other on a stretched string as shown in Fig . 7.25. Both pulses are identical to each other and travels at 2.00 cm//s . The leading edges of the pulses are 1.00 cm apart at t = 0 . Sketch the shape of the string at t = 0.250 s, t = 0.500 s , t = 0.750 s, t = 1.000 s and t = 1.250 s .

Two triangular wave pulses are travelling toward each other on a stretched string as shown in Fig . 7.25. Both pulses are identical to each other and travels at 2.00 cm//s . The leading edges of the pulses are 1.00 cm apart at t = 0 . Sketch the shape of the string at t = 0.250 s, t = 0.500 s , t = 0.750 s, t = 1.000 s and t = 1.250 s .