We pull the rod down so that the springs are extended by 10 cm with respect to its equilibrium point. At time t=0 s, the rod is released. (a) Find the expression for the electromotive force as a function of time Ɛ(t). (b) What is the maximal value of the electromotive force and when (t =?) would it be achieved for the first time? (c) Overlay the vertical position y(t) of the rod and the electromotive force (t) graph for one cycle of the oscillation.

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attempt if you have done Waves) In the figure below, all components are conducting hence force a conducting loop. The vertical sides of the loop are made of springs with k = 2 N/m and the conducting rod on the bottom has length = 30 cm and mass m = 20 g. A uniform magnetic field of strength 0.4 T is perpendicular to the plane of loop and into the page. X X X e x X X

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We pull the rod down so that the springs are extended by 10 cm with respect to its equilibrium point. At time t = 0 s, the rod is released. (a) Find the expression for the electromotive force as a function of time (t). (b) What is the maximal value of the electromotive force and when (t =?) would it be achieved for the first time? (c) Overlay the vertical position y(t) of the rod and the electromotive force E (t) graph for one cycle of the oscillation.