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Physics 536 - Assignment #2 1. A voltage source makes a fast transition at t = 0 between a positive voltage, V and zero volts, which induces a current of the form i(t) = (V /R)e−t/τ in the circuit shown below: R i(t) Vout L (a) Find an expression for the voltage vout (t). (b) A fast digital logic circuit could have V = 5 V, R = 50 Ω and τ = 1 ns. The inductor, L, represents the inductance in the lead that connects the ground on an integrated circuit to the ground on a printed circuit board. Calculate vout at t = 0 when L = 10 nH. (c) What is vout at t = 0 if the ground lead were connected by means of a long wire to the printed circuit board, resulting in L = 100 nH? 2. Consider the circuit below in which a voltage source v(t) = V eiωt , with impedance Rs drives a load RL . What value of RL will maximize the power transferred to the load? Calculate the maximum power when RL has this value. Rs v(t) RL i(t) 3. Consider the source connected to the load by means of a transformer as shown√below. Assuming perfect coupling between the primary and secondary coils, ie. k = 1 in M = k L1 L2 , what ratio of L1 /L2 will maximize the power transferred to a load with impedance RL at high frequencies. What turns ratio, n = N1 /N2 , will maximize the power transfered to RL ? How does the maximum power delivered to RL compare with the maximum power found in question 2? Rs v(t) L1 i1 (t) L2 i2 (t) RL