Question

3. For the circuit below, obtain the differential equation that governs $v_2(t)$. This can be obtained relatively easily by thinking in terms of KCL applied to the $v_1$ node. Express all the currents in terms of the voltages. Then, consider the current $i_2$. There are two ways to express this current. One way involves Ohm's law. The other way employs the $i-v$ relationship for the capacitor $C_2$. Equating these two expressions for $i_2$ allows you to obtain an expression for $v_1$ in terms of $v_2$. Using that (and returning to the KCL expression) allows you to obtain a differential equation that only involves $v_2$. You should obtain a second-order differential equation with constant coefficients. We could, if we so desired, write the equation in the form: $$\frac{d^2v_2(t)}{dt^2} + 2\alpha \frac{dv_2(t)}{dt} + \omega_0^2 v_2(t) = 0.$$ The $\alpha$ and $\omega_0$ depend on $R_1$, $R_2$, $C_1$, and $C_2$ (in a way that is distinct from what we have with parallel or serial $RLC$ circuits), but the way in which $v_2(t)$ behaves would be no dif- ferent from what we've seen before. It would be either underdamped, critically damped, or underdamped (depending on the relative sizes of $\alpha$ and $\omega_0$). Finally, you can be fairly confident that you have the right differential equation if, when you set $R_2$ to zero, you get a first-order differential equation with an equivalent capacitance of $C_1+C_2$ (i.e., the time constant is $R_1(C_1+C_2)$ if $R_2$ goes to zero). $i_0$ $v_1$ $i_2$ $R_2$ $v_2$ $i_1$ + + $R_1$ $C_1$ $v_1$ $C_2$ $v_2$

          3. For the circuit below, obtain the differential equation that governs $v_2(t)$.
This can be obtained relatively easily by thinking in terms of KCL applied to the $v_1$ node.
Express all the currents in terms of the voltages. Then, consider the current $i_2$. There are two
ways to express this current. One way involves Ohm's law. The other way employs the $i-v$
relationship for the capacitor $C_2$. Equating these two expressions for $i_2$ allows you to obtain
an expression for $v_1$ in terms of $v_2$. Using that (and returning to the KCL expression) allows
you to obtain a differential equation that only involves $v_2$.
You should obtain a second-order differential equation with constant coefficients. We could,
if we so desired, write the equation in the form:
$$\frac{d^2v_2(t)}{dt^2} + 2\alpha \frac{dv_2(t)}{dt} + \omega_0^2 v_2(t) = 0.$$
The $\alpha$ and $\omega_0$ depend on $R_1$, $R_2$, $C_1$, and $C_2$ (in a way that is distinct from what we have
with parallel or serial $RLC$ circuits), but the way in which $v_2(t)$ behaves would be no dif-
ferent from what we've seen before. It would be either underdamped, critically damped, or
underdamped (depending on the relative sizes of $\alpha$ and $\omega_0$).
Finally, you can be fairly confident that you have the right differential equation if, when you
set $R_2$ to zero, you get a first-order differential equation with an equivalent capacitance of
$C_1+C_2$ (i.e., the time constant is $R_1(C_1+C_2)$ if $R_2$ goes to zero).
$i_0$
$v_1$ $i_2$
$R_2$
$v_2$
$i_1$
+
+
$R_1$
$C_1$
$v_1$
$C_2$
$v_2$

3 for the circuit below obtain the differential equation that governs v2t this can be obtained relatively easily by thinking in terms of kcl applied to the v1 node express all the currents 56936

Added by Richard L.

Question

Please give Ace some feedback