184 Transient analysisThe discharge of a capacitor
Once the capacitor in Fig. 8.13 has been charged to V volts, it will remain at that
voltage so long as the input voltage remains at V volts. Even if the supply is
disconnected, as shown in Fig. 8.17(a), the capacitor (provided that it has no
leakage resistance between its plates) will remain charged to V volts. If,
however, the terminals A and B are now short circuited as shown in Fig. 8.17(b)
the capacitor will begin to release its stored energy. The current will now be
leaving its positive plate.R J,,C i C
Ao | I " ~it- ..... ~" +ll- II
VC VCBoFigure 8.17R
A l 1
MRB
(a) (b)Applying KVL to the circuit of Fig. 8.17(b) we see that
Vc - iR = 0 (8.17)
Now i= -(dq/dt), the minus sign indicating that the charge on the plates is
decaying. Since Q - CV then q = Cvc and- (dq/dt) = - C(dvc/dt)
Substituting in Equation (8.17) we get
v c - [-C(dvc/dt)]R = 0
Vc = -CR(dvc/dt)
Separating the variables we have dvc/vc = -dt/CR. Integrating gives
In Vc + C = -t/CR (8.18)
where C is the constant of integration. At t- 0, Vc - V so that In V + C = 0
and C - -ln V. Substituting in Equation (8.18) we obtain
In Vc - In V = -t/CR ~ In (vc/V) = -t/CR
Taking antilogs
vc/V- exp (-(t/CR))Finally
Vc = V exp (-t/CR) (8.19)The current at any instant is given by