$\"\"$

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Step 1:

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The resistance $\"\"$ and the capacitor $\"\"$ are in series.

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The voltage across each component is equal to the total circuit voltage.

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$\"\"$

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Solve the equation for current i.

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Substitute $\"\"$ , $\"\"$ and $\"\"$ in $\"\"$ .

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$\"\"$

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Apply laplace transform to find current i.

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$\"\"$

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Laplace transform of constant $\"\"$ .

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Laplace transform of integral function $\"\"$ .

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The initial voltage of the capacitor when $\"\"$ is $\"\"$ .

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$\"\"$

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$\"\"$

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Apply inverse laplace transform.

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$\"\"$

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Laplace transform of constant $\"\"$ .

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$\"\"$

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The current flowing through the circuit at any moment of time is $\"\"$ A.

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Solution :

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The current flowing through the circuit at any moment of time is $\"\"$ A.

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\

\

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Step 1:

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Find the current flowing through the circuit r $\"\"$ .

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The voltage across each component is equal to the total circuit voltage.

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$\"\"$

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So the volatge across capacitor is $\"\"$ .

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Find voltage across resistor : $\"\"$ .

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Substitute $\"\"$ and $\"\"$ .

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$\"\"$

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\ \ Now substitute $\"\"$ and $\"\"$ in $\"\"$ .

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$\"\"$

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Volatge acrossv capacitor is $\"\"$ .

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Solution :

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Volatge acrossv capacitor is $\"\"$ .