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E E 2415 Lecture 9 Phasor Circuit Analysis, Effective Value and Complex Power: Watts, VAR’s and Volt-Amperes.

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Presentation on theme: "E E 2415 Lecture 9 Phasor Circuit Analysis, Effective Value and Complex Power: Watts, VAR’s and Volt-Amperes."— Presentation transcript:

1 E E 2415 Lecture 9 Phasor Circuit Analysis, Effective Value and Complex Power: Watts, VAR’s and Volt-Amperes

2 Effective Value of a Sinusoid (1/3)
Average Power:

3 Effective Value of a Sinusoid (2/3)

4 Effective Value of a Sinusoid (3/3)
In our example: Also: The effective value is also called the Root Mean Square value or rms value.

5 R-C Circuit Example (1/6)
Capacitive Reactance

6 R-C Circuit Example (2/6)
Using rms phasor for voltage source.

7 R-C Circuit Example (3/6)
Calculate Real Power: And Reactive Power: Apparent power is the product of voltage and current of the source. Also:

8 R-C Circuit Example (4/6)
Power Factor is the ratio of real power to apparent power: Power Factor is also the Cosine of the angle between the load voltage and the load current: If the load current leads the load voltage, the power factor is leading; if it lags the load voltage, the power factor is lagging.

9 R-C Circuit Example (5/6)
Phasor Diagram of Voltage and Current Current leads voltage.

10 R-C Circuit Example (6/6)
The Power Triangle showing leading power factor.

11 Calculating Complex Power (1/2)

12 Calculating Complex Power (2/2)
From now on, we use the above method to calculate complex power.

13 Lagging Power Factor Example (1/4)

14 Lagging Power Factor Example (2/4)
Calculate complex power directly:

15 Lagging Power Factor Example (3/4)
Power Factor is Lagging Phasor Diagram of Voltage and Current

16 Lagging Power Factor Example (4/4)
Power Triangle for lagging Power Factor

17 Phasor Power Example (1/4)

18 Phasor Power Example (2/4)

19 Phasor Power Example (3/4)
Capacitor VAR’s:

20 Phasor Power Example (4/4)

21 Impedance and Admittance
Conductance Susceptance

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