RLC circuit and rate of increase of current

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SUMMARY

The discussion centers on the behavior of an RLC circuit at the moment the switch is closed. At t=0+, the inductor current is increasing due to the applied voltage from the DC battery, while the capacitor voltage remains at zero. The key point is that the current through the inductor cannot change instantaneously, leading to a non-zero rate of change of current (v=L di/dt), while the capacitor voltage begins to rise from zero at a positive rate, contradicting the initial assumption of zero voltage change. This highlights the difference in continuity conditions for inductors and capacitors in circuit analysis.

PREREQUISITES
  • Understanding of RLC circuit components: resistor, inductor, capacitor
  • Familiarity with the concepts of voltage and current in electrical circuits
  • Knowledge of differential equations as they apply to circuit analysis
  • Basic principles of DC circuit behavior and steady state conditions
NEXT STEPS
  • Study the transient response of RLC circuits using differential equations
  • Learn about the continuity conditions for current and voltage in circuit elements
  • Explore the concept of time constants in RLC circuits and their implications
  • Investigate the role of initial conditions in circuit analysis and simulation
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Electrical engineering students, circuit designers, and anyone interested in understanding the dynamics of RLC circuits during transient states.

hell-hawk
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Ok, I am having a problem with a RLC circuit and my teacher was unable to offer a satisfactory explanation. Hope that you'll help.
Consider a DC battery, a switch, a resistor, a capacitor and an inductor in series. Before t=0 the switch is open and assume that the circuit has achieved steady state. This means that the capacitor voltage is 0 and so is the inductor current. At t=0 the switch is closed. It follows that at t=0+ (i.e. just after t=0) the capacitor voltage will be 0 and so will the inductor current. It also follows that the voltage across the inductor at t=0+ will be V, i.e. the voltage of the source (the capacitor is acting as short-circuit and the inductor as open circuit). Therefore the rate of change of current in the circuit at t=0+ will be some positive value (from v=L di/dt). But the rate at which the capacitor voltage is increasing is ZERO at t=0+ (from i=C dv/dt; i=0). How could the rate of increase of current in the inductor be non-zero, but the rate of increase of voltage in the capacitor be zero? If one is increasing, shouldn't the other as well?
Please explain in physical terms and not mathematical. I'll be highly grateful.
 
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I will try to explain as best that I can


hell-hawk said:
Ok, I am having a problem with a RLC circuit and my teacher was unable to offer a satisfactory explanation. Hope that you'll help.
Consider a DC battery, a switch, a resistor, a capacitor and an inductor in series. Before t=0 the switch is open and assume that the circuit has achieved steady state. This means that the capacitor voltage is 0 and so is the inductor current. At t=0 the switch is closed. It follows that at t=0+ (i.e. just after t=0) the capacitor voltage will be 0 and so will the inductor current. It also follows that the voltage across the inductor at t=0+ will be V, i.e. the voltage of the source (the capacitor is acting as short-circuit and the inductor as open circuit). Therefore the rate of change of current in the circuit at t=0+ will be some positive value (from v=L di/dt)..

Up till here, you are correct!

hell-hawk said:
But the rate at which the capacitor voltage is increasing is ZERO at t=0+ (from i=C dv/dt; i=0). How could the rate of increase of current in the inductor be non-zero, but the rate of increase of voltage in the capacitor be zero? If one is increasing, shouldn't the other as well?
Please explain in physical terms and not mathematical. I'll be highly grateful.

There is a slight misconception here. You are saying that the current i at time t=0 is zero, using the current continuity of the inductor i(0+)=0, i.e. physically, the current cannot have a discontinuity jump at time t=0. But there is no current continuity at the capacitor, i.e. at time t=0, i(0-)=0 AND
i(0+)=some value. So the rate of increase of capacitor voltage is NOT zero.
Hence the capacitor voltage is increasing at a positive rate together with the inductor current at time t=0+

I may be wrong, because it has been one year ago since I touch on this concept. If I am wrong, can someone please advice. Thanks.
 

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