(1)

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Step 1:

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Millmans theorem:

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Millman states that the voltage at the ends of the circuit is $\"\"$ .

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Where $\"\"$ ,

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$\"\"$ is the resistance at the voltage sources and

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$\"\"$ is the resistance on the branch with no source or generators.

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Find the Thevinins equivalent resistance of the circuit.

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1.Open the load resistor.

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2.Open Current Sources and Short Voltage Sources.

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3.Calculate the Open Circuit Resistance. This is the Thevenin Resistance (R_TH).

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Redraw the circuit :

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$\"\"$

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Step 2:

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Observe the circuit:

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$\"\"$ can be written in complex form as $\"\"$ $\ \$

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$\"\"$

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$\"\"$ can be written in complex form as $\"\"$ . \ \

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Three impedances are in parallel.

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$\"\"$

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$\"\"$ .

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Step 3:

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Observe the circuit:

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$\"\"$

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$\"\"$ can be written in complex form as $\"\"$ . \ \

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$\"\"$

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$\"\"$ can be written in complex form as $\"\"$ .

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$\"\"$ can be written in complex form as $\"\"$ . \ \

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Substitute corresponding values in the $\"\"$ .

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$\"\"$

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$\"\"$ .

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$\"\"$ can be written in polar form as $\"\"$ .