Presentation is loading. Please wait.

Presentation is loading. Please wait.

1 ECE 221 Electric Circuit Analysis I Chapter 14 Maximum Power Transmission (From [1] chapter 4.12, p. 120-122) Herbert G. Mayer, PSU Status 11/30/2014.

Published byBailey Phenix Modified over 9 years ago

Similar presentations

Presentation on theme: "1 ECE 221 Electric Circuit Analysis I Chapter 14 Maximum Power Transmission (From [1] chapter 4.12, p. 120-122) Herbert G. Mayer, PSU Status 11/30/2014."— Presentation transcript:

1 1 ECE 221 Electric Circuit Analysis I Chapter 14 Maximum Power Transmission (From [1] chapter 4.12, p. 120-122) Herbert G. Mayer, PSU Status 11/30/2014 For use at Changchun University of Technology CCUT

2 2 Syllabus Motivation Motivation Thévenin Equivalent Thévenin Equivalent First Derivative Formulae First Derivative Formulae Identify Maximum Identify Maximum Derivative p’ Derivative p’ Maximum Power Maximum Power Sample Sample

3 3 Motivation When utility systems transmit electrical energy across power lines, this must be done with utmost efficiency, lest the universe gets heated up When electric signals of typically low voltage get transmitted, ultimate goal is sending the signal as strongly as possible, even it that means losing a great % of power, i.e. even if inefficiently! Here we discuss efficient power transmission from a source, with unknown dependent and independent sources and resistive networks How do we find the load R L at terminals a and b such that the least % of power is wasted?

4 4 Motivation Given such a network, we can always determine the Thévenin equivalent CVS, with V Th and R Th in series to the CVS For ease of computation, we then replace the actual circuit by the Thévenin equivalent network, and compute:   The maximum power delivered in the load resistor R L   And the efficiency: dissipated over delivered power, in % of the original delivered

5 5 Thévenin Equivalent R Th + V Th - Equivalent CVS at terminals a, b with computable V Th and R Th RLRL iL a b RLRL Green box: resistive network containing independent and dependent sources a b

6 6 First Derivative Formulae f(x) f’(x), with u(x) and v(x) functions of x f(x) = some variable f’(x) = 0 f(x) = constant f’(x) = 0 f(x) = x f’(x) = 1 f(x) = u + v f’(x) = u’ + v’ f(x) = u - v f’(x) = u’ - v’ f(x) = u * v f’(x) = u’*v + u*v’ f(x) = u / v f’(x)= (u’*v -u*v’) / v 2 f(x) = ln(u) f’(x) = u’ / u f(x) = u ^ v f’(x) = u' * v * u^(v - 1) + ln(u) * v' * u ^ v Example: f(x) = x ^ x f’(x) = 1 * x * x^(x - 1) + ln(x) * 1 * x^x = x^x + ln(x) * x^x = x^x + ln(x) * x^x = (ln(x) + 1) * x^x = (ln(x) + 1) * x^x

7 7 Identify Maximum Given a function y = f(x), with x occurring to the n th power, there will be n-1 maxima To find the points of maximal values, compute the derivative f’(x) Set the derivative f’(x) to zero, this is the incline of the tangent Compute values of x, where in fact f’(x) = 0 At those values for x, f(x) has highest −or lowest− values Since the tangent will be horizontal

8 8 Identify Maximum

9 9 Function (a) above is a 3 rd power of x, there will be 2 maxima There are 2 values for x, where f’(x) is 0, or the tangent is horizontal Function (b) above is a 2 nd power of x, there will be 1 maximum Again, this is where the derivative f’(x) is 0, or the tangent is horizontal We see that the power function p = u*i is a second order function of the resistor R L, hence we have 1 solution for the maximum

10 10 Derivative p’ = f(R L ) p=i * v =i * i * R L (Eq 1) p=i 2 * R L p=(V Th /(R Th + R L )) 2 * R L p = R L * V Th 2 /(R Th + R L ) 2 Power p is max, when the second-order function p = f( R L ) has a tangent with 0 incline, i.e. when the derivative dp/dR L is = 0, so we form first derivative! Use product rule and quotient rule! Note that V Th and R Th are not functions of R L so they are constant, and are 0 when derived toward R L Use product rule, quotient rule, and set : dp / dR L = 0

11 11 Derivative p’ = f(R L ) dp/dR L = p’ P’ = (V Th 2 *(R Th +R L ) 2 -V Th 2 *R L *2*(R Th +R L ))/(R Th +R L ) 4 P’ = V Th 2 *((R Th +R L ) 2 -R L *2*(R Th +R L ))/(R Th +R L ) 4 P’ = 0 0 = (R Th +R L ) 2 - R L * 2 * (R Th + R L ) 0 = (R Th +R L ) - R L * 2 0 = R Th + R L - R L * 2 R Th = R L

12 12 Maximum Power é Maximum Power transmission occurs, when the load resistance R L equals the Thévenin resistance R Th How large is that P max ? With R L = R Th and Eq 1: P max = V Th 2 * R L / (2 * R L ) 2 P max = V Th 2 / (4 * R L )

13 13 Sample Maximum Power Transfer é (a) Given the circuit on the next page, find the Thévenin equivalent with V Th and R Th (b) What is the maximum power delivered to R L ? (c) What is the percentage of power delivered?

14 14 Sample Maximum Power Transfer 30 Ω + 360 V - Sample CVS with 30 and 150 Ω Resistors RLRL iL a b 150 Ω

15 15 (a) Find Thévenin Equivalent V Th is voltage at open plugs a and b i Th is short-circuit current at plugs a and b R Th = V Th / i Th V Th =360 * 150 / 180=300 V i Th =360 / 30= 12 A R Th =300 / 12= 25 Ω

16 16 Sample Maximum Power Transfer 25 Ω + 300 V - Thevenin Equivalent of Sample CVS RLRL iL a b 30 Ω + 360 V - Sample CVS with 30 and 150 Ω Resistors RLRL iL a b 150 Ω

17 17 (b) Maximum Power Delivered to R L Maximum power is delivered with R L = R Th p Th = i * v Voltage at R L is half of V Th = 300 V, V L = 150 V p Th =150 * 300/50=900 W

18 18 (c) Percent of Power Delivered R L in original circuit is = R Th = 25 Ω R L parallel to 150 Ω in series with 30 Ω is 360/7 Percent = p Th / p 360 p 360 =v * i i=v / (360 / 7)=360*7 / 360=7 A P 360 =360 * 7=2520 W=2.52 kW Percent=2,520 / 900=0.357129=35.71 %

Download ppt "1 ECE 221 Electric Circuit Analysis I Chapter 14 Maximum Power Transmission (From [1] chapter 4.12, p. 120-122) Herbert G. Mayer, PSU Status 11/30/2014."

Similar presentations

1 ECE 221 Electric Circuit Analysis I Chapter 12 Superposition Herbert G. Mayer, PSU Status 2/26/2015.

1 ECE 221 Electric Circuit Analysis I Chapter 12 Superposition Herbert G. Mayer, PSU Status 2/26/2015.
1 ECE 221 Electric Circuit Analysis I Chapter 12 Superposition Herbert G. Mayer, PSU Status 11/26/2014 For use at Changchun University of Technology CCUT.

1 ECE 221 Electric Circuit Analysis I Chapter 12 Superposition Herbert G. Mayer, PSU Status 11/26/2014 For use at Changchun University of Technology CCUT.
1 ECE 221 Electric Circuit Analysis I Chapter 8 Example 4.3, Problem 4.11 Node-Voltage Method Herbert G. Mayer, PSU Status 1/19/2015.

1 ECE 221 Electric Circuit Analysis I Chapter 8 Example 4.3, Problem 4.11 Node-Voltage Method Herbert G. Mayer, PSU Status 1/19/2015.
THEVENIN’S THEOREM Thevenin’s theorem permits the reduction of a two-terminal dc network with any number of resistors and sources (Complex Circuit) to.

THEVENIN’S THEOREM Thevenin’s theorem permits the reduction of a two-terminal dc network with any number of resistors and sources (Complex Circuit) to.
Discussion D2.5 Sections 2-9, 2-11

Discussion D2.5 Sections 2-9, 2-11
Lecture 11 Thévenin’s Theorem Norton’s Theorem and examples

Lecture 11 Thévenin’s Theorem Norton’s Theorem and examples
1 ECE 221 Electric Circuit Analysis I Chapter 13 Thévenin & Norton Equivalent Herbert G. Mayer, PSU Status 3/5/2015.

1 ECE 221 Electric Circuit Analysis I Chapter 13 Thévenin & Norton Equivalent Herbert G. Mayer, PSU Status 3/5/2015.
Lecture 131 Maximum Power Transfer (4.4) Prof. Phillips February 28, 2003.

Lecture 131 Maximum Power Transfer (4.4) Prof. Phillips February 28, 2003.
ECE 201 Circuit Theory I1 Maximum Power Transfer Maximize the power delivered to a resistive load.

ECE 201 Circuit Theory I1 Maximum Power Transfer Maximize the power delivered to a resistive load.
Lecture 4 Overview More circuit analysis –Thevenin’s Theorem –Norton’s Theorem.

Lecture 4 Overview More circuit analysis –Thevenin’s Theorem –Norton’s Theorem.
Announcements First Assignment posted: –Due in class in one week (Thursday Sept 15 th )

Announcements First Assignment posted: –Due in class in one week (Thursday Sept 15 th )
Source Transformation

Source Transformation
Circuits Series and Parallel. Series Circuits Example: A 6.00 Ω resistor and a 3.00 Ω resistor are connected in series with a 12.0 V battery. Determine.

Circuits Series and Parallel. Series Circuits Example: A 6.00 Ω resistor and a 3.00 Ω resistor are connected in series with a 12.0 V battery. Determine.
Announcements Master of Exam I is available in E-learning. The scores will be posted soon. Class average of 12.46 and standard deviation 3.42 QUESTIONS?

Announcements Master of Exam I is available in E-learning. The scores will be posted soon. Class average of and standard deviation 3.42 QUESTIONS?
Electrical Systems 100 Lecture 3 (Network Theorems) Dr Kelvin.

Electrical Systems 100 Lecture 3 (Network Theorems) Dr Kelvin.
L14 § 4.5 Thevenin’s Theorem A common situation: Most part of the circuit is fixed, only one element is variable, e.g., a load: i0i0 +  +  The fixed.

L14 § 4.5 Thevenin’s Theorem A common situation: Most part of the circuit is fixed, only one element is variable, e.g., a load: i0i0 +  +  The fixed.
ELECTRICAL ENGINEERING: PRINCIPLES AND APPLICATIONS, Fourth Edition, by Allan R. Hambley, ©2008 Pearson Education, Inc. Lecture 16 Phasor Circuits, AC.

ELECTRICAL ENGINEERING: PRINCIPLES AND APPLICATIONS, Fourth Edition, by Allan R. Hambley, ©2008 Pearson Education, Inc. Lecture 16 Phasor Circuits, AC.
Chapter 8.

Chapter 8.
ELECTRICAL TECHNOLOGY EET 103/4

ELECTRICAL TECHNOLOGY EET 103/4
Basic Electrical Circuits & Machines (EE-107) Course Teacher Shaheena Noor Assistant Professor Computer Engineering Department Sir Syed University of Engineering.

Basic Electrical Circuits & Machines (EE-107) Course Teacher Shaheena Noor Assistant Professor Computer Engineering Department Sir Syed University of Engineering.

Similar presentations

Ads by Google