A simple electric circuit consisting of a resistor, a capacitor, and an inductor is depicted as shown below. The charge on the capacitor q(t) as a function of time can be computed as ... R q(t) = qoe -Rt/(2L) cos LC where t = time, q0 = the initial charge, R = the resistance, L = inductance, and C= capacitance. Use MATLAB to generate a plot of this function from t=0 to 0.8 with an increment of 0.001, given that q0= 10, R = 60, L = 9, and C = 0.00005. What is the maximum value of q=. Blank 1? Express your answer to the nearest whole number. Blank 1 Add your answer

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A simple electric circuit consisting of a resistor, a capacitor, and an inductor is depicted as shown below. The charge on the capacitor q(t) as a function of time can be computed as 9(1) = goe-Rt/(2L) Cos LC 2L where t = time, q0 = the initial charge, R = the resistance, L = inductance, and C = capacitance. Use MATLAB to generate a plot of this function from t= 0 to 0.8 with an increment of 0.001, given that q0= 10, R = 60, L = 9, and C = 0.00005. What is the maximum value of q= Blank 1? Express your answer to the nearest whole number. Blank 1 Add your answer

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A simple electric circuit consisting of a resistor, a capacitor, and an inductor is depicted as shown below. The charge on the capacitor g(t) as a function of time can be computed as 1 R 9(1) = goe-Rt/(2L) Cos where t = time, q0 = the initial charge, R = the resistance, L = inductance, and C = capacitance. Use MATLAB to generate a plot of this function from t= 0 to 0.8 with an increment of 0.001, given that q0= 10, R = 60, L = 9, and C = 0.00005. What is the minimum value of q=. Blank 1? Express your answer with four decimal digits after the decimal point. Blank 1 Add your answer