Laplace transforms: Simple Electrical Network: Difference between revisions

Problem Statement

Using the formulas

${\displaystyle E(t)=L{\displaystyle \frac{d{i}_R}{dt}}+R{i}_C}$
${\displaystyle RC{\displaystyle \frac{d{i}_R}{dt}}+i_R-i_C=0}$

Solve the system when V0 = 50 V, L = 4 h, R = 20 Ω, C = 10^-4 f, and the currents are initially zero.

Solution

Solve the system when V0 = 50 V, L = 4 h, R = 20 Ω, C = 10^-4 f, and the currents are initially zero.

${\displaystyle 4\frac{d{i}_1}{dt}+20i_2=50}$

${\displaystyle 20(10^{-4})\frac{d{i}_2}{dt}+i_2-i_1=0}$

Applying the Laplace transform to each equation gives

${\displaystyle 4(s{ℒ}\left\{i_1\right\}-i_1(0))+20{ℒ}\left\{i_2\right\}=50}$

${\displaystyle \Rightarrow 4s{I}_1(s)+20I_2(s)=\frac{50}{s}}$

${\displaystyle 0.005(s{ℒ}{i}_2-i_2(0))+{ℒ}\left\{i_2\right\}-{ℒ}\left\{i_1\right\}=0}$

${\displaystyle \Rightarrow -500I_1(s)+[s+500]I_2(s)=0}$

Solving for ${\displaystyle I_2(s)}$

${\displaystyle I_2(s)=\frac{6250}{s(s^2+500s+2500)}}$

We find the partial decomposition

Let ${\displaystyle I_2(s)=\frac{6250}{s(s^2+500s+2500)}=\frac{A}{s}+\frac{Bs+C}{s^2+500s+2500}}$

${\displaystyle \Rightarrow 6250=A(s^2+500s+2500)+(Bs+C)s}$

${\displaystyle \Rightarrow 62500=A{s}^2+500As+2500A+B{s}^2+Cs}$

Comparing the coefficients we get

${\displaystyle A=\frac{5}{2},B=-5,C=-1250}$

Thus ${\displaystyle I_2(s)=\frac{5}{2s}-\frac{5s+1250}{s^2+500s+2500}}$

Now we do the same for ${\displaystyle I_1}$ where we solve the function in terms of ${\displaystyle I_1}$ and decomposing the partial fraction resulting in

${\displaystyle I_1(s)=\frac{25s+12500}{s(s^2+500s+2500)}=\frac{5}{2s}-\frac{5s+2475}{s^2+125s+20000}}$

In order to make it nicer on us we need to complete the square Taking the Inverse Laplace transform yields

${\displaystyle {{ℒ}}^{-1}\{I_1(s)\}=\frac{5}{8}+\frac{39\sqrt{103}}{824}sin*(\frac{25}{2}\sqrt{103}*t)}$

${\displaystyle {{ℒ}}^{-1}\{I_2(s)\}=}$