- #1
zenterix
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- Homework Statement
- Initially, the capacitor in a series LC circuit is charged. A switch is closed, allowing the capacitor to discharge. After a time ##t_1##, the energy stored in the capacitor is one fourth of its initial value.
- Relevant Equations
- Calculate the value of the self-inductance ##L## in terms of ##t_1## and ##C##.
We seem to have the following circuit
and the differential equation ##\ddot{q}+\omega^2q=0## where ##\omega=\frac{1}{\sqrt{LC}}##.
The solution is
$$q(t)=A\cos{(\omega t+\phi)}$$
Since ##I(t)=-\dot{q}(t)## we have
$$I(t)=-\dot{q}(t)=A\omega\sin{(\omega t+\phi)}$$
At ##t=0## we have
$$q(0)=A\cos{\phi}$$
$$I(0)=A\omega\sin{\phi}=0\implies \phi=0$$
Thus,
$$q(0)=A$$
There is no battery in the circuit and no resistance in the wires. The total energy in inductor and capacitor is constant.
The energy in the capacitor is
$$U_E(t)=\frac{q(t)^2}{2C}=\frac{A^2}{2C}\cos^2{(\omega t)}$$
and the energy in the inductor is
$$U_B(t)=\frac{LI^2(t)}{2}=\frac{L}{2}A^2\omega^2\sin^2{(\omega t)}$$
$$=\frac{A^2}{2C}\sin^2{(\omega t)}$$
I am stuck trying to find an expression for ##L## in terms of ##t_1##.
and the differential equation ##\ddot{q}+\omega^2q=0## where ##\omega=\frac{1}{\sqrt{LC}}##.
The solution is
$$q(t)=A\cos{(\omega t+\phi)}$$
Since ##I(t)=-\dot{q}(t)## we have
$$I(t)=-\dot{q}(t)=A\omega\sin{(\omega t+\phi)}$$
At ##t=0## we have
$$q(0)=A\cos{\phi}$$
$$I(0)=A\omega\sin{\phi}=0\implies \phi=0$$
Thus,
$$q(0)=A$$
There is no battery in the circuit and no resistance in the wires. The total energy in inductor and capacitor is constant.
The energy in the capacitor is
$$U_E(t)=\frac{q(t)^2}{2C}=\frac{A^2}{2C}\cos^2{(\omega t)}$$
and the energy in the inductor is
$$U_B(t)=\frac{LI^2(t)}{2}=\frac{L}{2}A^2\omega^2\sin^2{(\omega t)}$$
$$=\frac{A^2}{2C}\sin^2{(\omega t)}$$
I am stuck trying to find an expression for ##L## in terms of ##t_1##.