Laplace transforms: Simple Electrical Network: Difference between revisions

Revision as of 17:52, 30 November 2009

Problem Statement

Using the formulas

 $E (t) = L \frac{d i_{R}}{d t} + R i_{C}$ 
 $R C \frac{d i_{R}}{d t} + i_{R} - i_{C} = 0$

Solve the system when V0 = 50 V, L = 0.5 h, R = 60 Ω, C = 10^-4 f, and the currents are initially zero.

Solution

Solve the system when V0 = 50 V, L = 0.5 h, R = 60 Ω, C = 10^{-4} f, and the currents are initially zero. Substituting numbers into the equations, we have

$0.5 \frac{d i_{1}}{d t} + 60 i_{2} = 0$

$60 (1 0^{- 4}) \frac{d i_{2}}{d t} + i_{2} - i_{1} = 0$

Applying the Laplace transform to each equation gives

$\frac{1}{2} (s^{2} ℒ I_{1} (s) - i_{1} (0)) + 60 ℒ {i_{2}}$

@@ Line 7: / Line 7: @@
 ==Solution==
+Solve the system when V0 = 50 V, L = 0.5 h, R = 60 Ω, C = 10^{-4} f, and the currents are initially zero.
+Substituting numbers into the equations, we have
+<math>0.5\frac{di_1}{dt}+60i_2=0</math>
+<math>60(10^{-4})\frac{di_2}{dt}+i_2-i_1=0</math>
+Applying the Laplace transform to each equation gives
+<math>\frac{1}{2}(s^2\mathcal{L}{I_1}(s)-i_1(0))+60\mathcal{L}\left\{i_2\right\}</math>
+<math></math>

Laplace transforms: Simple Electrical Network: Difference between revisions

Revision as of 17:52, 30 November 2009

Problem Statement

Solution

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