Question (26)Two waves travelling in opposite directions along the x-axis have the equationsYı(x, t) = 0.03 sin (2n x + 20n t)Y2(x, t) = 0.03 sin (2n x -20n t)for x and y measured in metres and t in seconds.(a)Use the standard trigonometric relations, sin(01+02) = sin 0zcos 02+ cos e1sin 02 andsin(01-02) = sin 01cos 02-cos 01sin 02, to show that the equation of the standing wave,Y.(x, 1) = y1(x, t) + Y2(x, t), is y(x, t) = 0.06 sin(2n x) cos(201 t)(b) Find the positions of the two nodes with x >0 that are closest to x= 0. How doesthe distance between the nodes compare to the wavelength?(c) Find the positions of the two antinodes with x> 0 that are closest to x= 0. Howdoes the distance between the antinodes compare to the wavelength?

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Question (26) Two waves travelling in opposite directions along the x-axis have the equations Yı(x, t) = 0.03 sin (2n x + 20n t) Y2(x, t) = 0.03 sin (2n x -20n t) for x and y measured in metres and t in seconds. (a)Use the standard trigonometric relations, sin(01+02) = sin 0xcos 02+ cos e1sin 02 and sin(01-02) = sin 01cos 02-cos 01sin 02, to show that the equation of the standing wave, Y(x, t) = y1(x, t) + Y2(x, t), is y(x, t) = 0.06 sin(2n x) cos(201 t) (b) Find the positions of the two nodes with x >0 that are closest to x= 0. How does the distance between the nodes compare to the wavelength? (c) Find the positions of the two antinodes with x> 0 that are closest to x= 0. How does the distance between the antinodes compare to the wavelength?

Question (26) Two waves travelling in opposite directions along the x-axis have the equations Yı(x, t) = 0.03 sin (2n x + 20n t) Y2(x, t) = 0.03 sin (2n x -20n t) for x and y measured in metres and t in seconds. (a)Use the standard trigonometric relations, sin(01+02) = sin 0xcos 02+ cos e1sin 02 and sin(01-02) = sin 01cos 02-cos 01sin 02, to show that the equation of the standing wave, Y(x, t) = y1(x, t) + Y2(x, t), is y(x, t) = 0.06 sin(2n x) cos(201 t) (b) Find the positions of the two nodes with x >0 that are closest to x= 0. How does the distance between the nodes compare to the wavelength? (c) Find the positions of the two antinodes with x> 0 that are closest to x= 0. How does the distance between the antinodes compare to the wavelength?

College Physics

11th Edition

ISBN:9781305952300

Author:Raymond A. Serway, Chris Vuille

Publisher:Raymond A. Serway, Chris Vuille

Chapter1: Units, Trigonometry. And Vectors

Section: Chapter Questions

Problem 1CQ: Estimate the order of magnitude of the length, in meters, of each of the following; (a) a mouse, (b)...

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