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The circuit shown in figure (2) utilizes an ideal transformer and it operates in the steady-state condition at 100 Hz. The circuit operates such that the impedance Zs dissipates the maximum possible power. Answer the following: a) Define the characteristics of the ideal transformer b) Calculate the currents I1 and I2 and voltage Vo all in phasor and sinusoidal forms. c) Calculate the complex power supplied by the voltage source and its operating power factor. Then drew the complex power triangle.

The circuit shown in figure (2) utilizes an ideal transformer and it operates in the steady-state condition at 100 Hz. The circuit operates such that the impedance Zs dissipates the maximum possible power. Answer the following: a) Define the characteristics of the ideal transformer b) Calculate the currents I1 and I2 and voltage Vo all in phasor and sinusoidal forms. c) Calculate the complex power supplied by the voltage source and its operating power factor. Then drew the complex power triangle.

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The circuit shown in figure (2) utilizes an ideal transformer and it operates in the steady-state condition at 100 Hz. The circuit operates such that the impedance Zs dissipates the maximum possible power. Answer the following: a) Define the characteristics of the ideal transformer b) Calculate the currents I1 and I2 and voltage Vo all in phasor and sinusoidal forms. c) Calculate the complex power supplied by the voltage source and its operating power factor. Then drew the complex power triangle.

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