Questions -
Q1. Find the equivalent capacitance in the given circuit if all capacitors are 28 μF.
Q2. Find the equivalent capacitance between terminals a and b in the given circuit, where C = 3 μF. All capacitances are in μF.
Q3. Obtain the equivalent capacitance of the network shown in the given figure, where C = 30 μF.
Q4. Consider the given circuit where v(0) = 0 and C= μF.
Find the voltage v(t).
For 0 < t < 1s
For 1s < t < 3s
For 3s < t < 5s
Q5. If the voltage waveform in the given figure is applied across the terminals of a 12-H inductor, calculate the current through the inductor for 4 < t < 5. Assume 1(0) = -1 A.
Q6. Find the equivalent inductance Leq in the given circuit, where L = 5 H and L1 = 25 H.
Q7. The current through a 0.5-F capacitor is 6(1-e-t)A. Assume v(0) = 0 and t = 2.5 s. Determine the power at t = 2.5 s.
Q8. A 4-mF capacitor has the current waveform shown in the given figure. Assume that v(0) = 10 V.
Find the value of voltage for 6s < t < 8s.
Q9. Find the voltage across the capacitors in the given circuit under dc conditions, where R1 = 71 Ω and R2 = 15 Ω.
Q10. Determine the equivalent capacitance for the given circuit, where C = 10 F.
Q11. Obtain the equivalent capacitance of the given circuit, where C = 18 μF.
Q12. In the given circuit, let is = 6.2e-2t mA and the voltage across each capacitor be equal to zero at t= 0.
Determine the voltage v1 and v2.
Q13. Determine the equivalent inductance Leq at terminals a-b of the given circuit, where L = 28 mH.
Consider the given circuit in which v(t) = 12 e-3t mV for t> 0 and i1(0) = -10 mA.
Q14. Find the current i2(0).
Q15. Find the currents i1(t) and i2(t) of the circuit.
Q16. At t = 3 ms, calculate vo due to the cascaded integrators in the given figure. Assume that the integrators are reset to 0 V at t = 0.
Only need answers. Not the work.