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Chapter 11 AC Power Analysis

Chapter 11 AC Power Analysis. Chapter Objectives: Know the difference between instantaneous power and average power Learn the AC version of maximum power transfer theorem Learn about the concepts of effective or rms value Learn about the complex power, apparent power and power factor

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Chapter 11 AC Power Analysis

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  1. Chapter 11AC Power Analysis Chapter Objectives: • Know the difference between instantaneous power and average power • Learn the AC version of maximum power transfer theorem • Learn about the concepts of effective or rms value • Learn about the complex power, apparent power and power factor • Understand the principle of conservation of AC power • Learn about power factor correction Huseyin Bilgekul Eeng224 Circuit Theory II Department of Electrical and Electronic Engineering Eastern Mediterranean University

  2. Instantenous AC Power • Instantenous Powerp(t) is the power at any instant of time.

  3. Instantenous AC Power • Instantenous Powerp(t) is the power at any instant of time. • The instantaneous power is composed of two parts. • A constant part. • The part which is a function of time.

  4. Instantenous and Average Power • The instantaneous power p(t) is composed of a constant part (DC) and a time dependent part having frequency 2ω. Instantenous Power p(t)

  5. Instantenous and Average Power

  6. Average Power • The average power P is the average of the instantaneous power over one period .

  7. Average Power • The average power P, is the average of the instantaneous power over one period . • A resistor has (θv-θi)=0º so the average power becomes: • P is not time dependent. • When θv = θi , it is a purely resistive load case. • When θv– θi = ±90o, it is a purely reactive load case. • P = 0 means that the circuit absorbs no average power.

  8. Example 1Calculate the instantaneous power and average power absorbed by a passive linear network if: Instantenous and Average Power

  9. Average Power Problem • Practice Problem 11.4: Calculate the average power absorbed by each of the five elements in the circuit given.

  10. Average Power Problem

  11. Maximum Average Power Transfer • Finding the maximum average power which can be transferred from a linear circuit to a Load connected. a) Circuit with a load b) Thevenin Equivalent circuit • Represent the circuit to the left of the load by its Thevenin equiv. • Load ZLrepresents any element that is absorbing the power generated by the circuit. • Find the load ZL that will absorb the Maximum Average Powerfrom the circuit to which it is connected.

  12. Maximum Average Power Transfer Condition • Write the expression for average power associated with ZL: P(ZL). • ZTh= RTh+ jXThZL= RL+ jXL

  13. Maximum Average Power Transfer Condition • Therefore: ZL= RTh - XTh = ZThwill generate the maximum power transfer. • Maximum power Pmax • For Maximum average power transfer to a load impedance ZL we must choose ZL as the complex conjugate of the Thevenin impedance ZTh.

  14. Maximum Average Power Transfer • Practice Problem 11.5: Calculate the load impedance for maximum power transfer and the maximum average power.

  15. Maximum Average Power Transfer

  16. Maximum Average Power for Resistive Load • When the load is PURELY RESISTIVE, the condition for maximum power transfer is: • Now the maximum power can not be obtained from the Pmax formula given before. • Maximum power can be calculated by finding the power of RL when XL=0. ● RESISTIVE LOAD ●

  17. Maximum Average Power for Resistive Load • Practice Problem 11.6: Calculate the resistive load needed for maximum power transfer and the maximum average power.

  18. Maximum Average Power for Resistive Load RL • Notice the way that the maximum power is calculated using the Thevenin Equivalent circuit.

  19. Effective or RMS Value • The EFFECTIVE Value or the Root Mean Square (RMS) value of a periodic current is the DC value that delivers the same average power to a resistor as the periodic current. a) AC circuit b) DC circuit

  20. Effective or RMS Value of a Sinusoidal • The Root Mean Square (RMS) value of a sinusoidal voltage or current is equal to the maximum value divided by square root of 2. • The average power for resistive loads using the (RMS) value is:

  21. Effective or RMS Value • Practice Problem 11.7: Find the RMS value of the current waveform. Calculate the average power if the current is applied to a 9  resistor. 4t 8-4t

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