Circuit Theory/1Source Excitement/Example 10

Have already found the steady state/particular solution:

${\displaystyle V_{s}(t)=I_{m}{\frac {\sqrt {(\omega ^{2}L^{2}R)^{2}+(\omega LR^{2})^{2}}}{R^{2}+\omega ^{2}L^{2}}}\cos(\phi +\arctan({\frac {R}{\omega L}}))}$ 

Or numerically:

${\displaystyle V_{s_{P}}(t)=599\cos(377t+3.30)}$ 

Need to find the transient/homogeneous solution to:

${\displaystyle I_{s}=I_{R}+I_{L}}$ 

${\displaystyle I_{s}={\frac {Vs}{R}}+I_{L}}$ 

${\displaystyle {dI_{s} \over dt}={d{\frac {V_{s}}{R}} \over dt}+{dI_{L} \over dt}}$ 

${\displaystyle {dI_{s} \over dt}={d{\frac {V_{s}}{R}} \over dt}+{\frac {V_{s}}{L}}}$ 

${\displaystyle 0={\frac {1}{R}}{dV_{sH} \over dt}+{\frac {V_{sH}}{L}}}$ 

There is no I_S .. this makes the homogeneous solution easy!

Guess:

${\displaystyle V(t)_{s_{H}}=A*e^{\frac {-t}{\tau }}}$ 

Finding the time constant:

${\displaystyle {\frac {-Ae^{\frac {-t}{\tau }}}{\tau R}}+{\frac {A}{L}}e^{\frac {-t}{\tau }}=0}$ 

Dividing out A and the exponential:

${\displaystyle -{\frac {1}{\tau R}}+{\frac {1}{L}}=0}$ 

Solving for the time constant:

${\displaystyle \tau =L/R=.001}$ 

Now see if it works:

${\displaystyle {\frac {Ae^{\frac {-t}{L/R}}}{R}}+{\frac {A(-{\frac {R}{L}})*e^{\frac {-t}{L/R}}}{L}}{\overset {\underset {\mathrm {???} }{}}{=}}0}$ 

Divide through by A, cancel L's

${\displaystyle Re^{\frac {-t}{L/R}}-Re^{\frac {-t}{L/R}}{\overset {\underset {\mathrm {???} }{}}{=}}0}$ 

It works, therefore it must be the solution:

${\displaystyle v(t)_{s_{H}}=Ae^{\frac {-t}{0.0001}}}$ 

There are two constants. ${\displaystyle A}$  and ${\displaystyle C}$  come from any homogeneous solution to a non-homogeneous differential equation equation. These were not ignored in the steady state phasor solutions earlier, the fact that they were not being computed was pointed out.

${\displaystyle V(t)_{s}=V(t)_{s_{P}}+V(t)_{s_{H}}}$ 

${\displaystyle V(t)_{s}=599\cos(377t+3.30)+Ae^{\frac {-t}{0.0001}}+C}$ 

There are two initial conditions that have to be true:

1. The inductor terminal relationship has to be true at t=0
2. initial current through the inductor is zero, thus is an open, thus all the current is going through the resistor

Two equations are necessary to find A and C:

The inductor's terminal relationship has to be true:

${\displaystyle V_{s}(t)=L*{di_{L}(t) \over dt}}$ 

We don't know what the inductor's current is, but we know it is 0 at t=0. So we have to solve the equation for i_L and then set that equation equal to zero.

${\displaystyle \int V_{s}(t)=L*i_{L}(t)}$ 

${\displaystyle \int (599\cos(377x+3.30)+Ae^{\frac {-t}{0.0001}}+C)dt=L*i_{L}(t)}$ 

${\displaystyle 1.59*sin(377.0*t+3.3)-0.001*Ae^{\frac {-t}{0.0001}}+C*t=L*i_{L}(t)}$ 

${\displaystyle -0.001*A-0.258=0}$ 

${\displaystyle A=-258}$ 

The other equation comes from the fact that all the source current is going through the resistor. The initial voltage across the resistor and inductor is determined only by the resistor. The inductor doesn't care about or influence the voltage. The inductor is only worried about maintaining it's energy level (which is assumed to be 0.) So the second equation is:

${\displaystyle v_{s}(0)=i_{s}(0)*R}$ 

${\displaystyle 599\cos(3.30)+A+C=120{\sqrt {2}}cos(120^{\circ })*10}$ 

${\displaystyle 258+A+C=0}$ 

So

${\displaystyle C=0}$ 

${\displaystyle v_{s}(t)=599\cos(377t+3.30)-258*e^{\frac {-t}{0.0001}}}$