Presentation is loading. Please wait.

Presentation is loading. Please wait.

Spencer/Ghausi, Introduction to Electronic Circuit Design, 1e, ©2003, Pearson Education, Inc. Chapter 9, slide 1 Introduction to Electronic Circuit Design.

Published byKerry Powell Modified over 8 years ago

Similar presentations

Presentation on theme: "Spencer/Ghausi, Introduction to Electronic Circuit Design, 1e, ©2003, Pearson Education, Inc. Chapter 9, slide 1 Introduction to Electronic Circuit Design."— Presentation transcript:

1 Spencer/Ghausi, Introduction to Electronic Circuit Design, 1e, ©2003, Pearson Education, Inc. Chapter 9, slide 1 Introduction to Electronic Circuit Design Richard R. Spencer Mohammed S. Ghausi

2 Spencer/Ghausi, Introduction to Electronic Circuit Design, 1e, ©2003, Pearson Education, Inc. Chapter 9, slide 2 Figure 9-1 One possible model for (a) a real resistor, (b) a real inductor, and (c) a real capacitor. The elements used in the models are ideal resistance, capacitance, and inductance. R s is the series parasitic resistance (caused by the leads), R p is the parallel parasitic resistance, and L s and C p are the parasitic series inductance and parallel capacitance, respectively.

3 Spencer/Ghausi, Introduction to Electronic Circuit Design, 1e, ©2003, Pearson Education, Inc. Chapter 9, slide 3 Figure 9-2 A small-signal model for a diode that is valid for high frequencies. r d is present only in forward bias. The value of C depends on the type of diode and whether it is forward or reverse biased; see text for details.

4 Spencer/Ghausi, Introduction to Electronic Circuit Design, 1e, ©2003, Pearson Education, Inc. Chapter 9, slide 4 Figure 9-3 (a) The high-frequency hybrid-  model and (b) the high- frequency T model for the generic transistor.

5 Spencer/Ghausi, Introduction to Electronic Circuit Design, 1e, ©2003, Pearson Education, Inc. Chapter 9, slide 5 Figure 9-4 The high-frequency hybrid-  model for a BJT. Figure 9-5 The high-frequency T model of a BJT with r b omitted. Figure 9-6 The current-controlled version of the high-frequency hybrid-  BJT model.

6 Spencer/Ghausi, Introduction to Electronic Circuit Design, 1e, ©2003, Pearson Education, Inc. Chapter 9, slide 6 Figure 9-7 The high-frequency small-signal models for a MOSFET: (a) in the linear region, (b) the hybrid-  model for forward-active operation (i.e., saturation), and (c) the T model for forward-active operation.

7 Spencer/Ghausi, Introduction to Electronic Circuit Design, 1e, ©2003, Pearson Education, Inc. Chapter 9, slide 7 Figure A9-5 An ideal voltage amplifier with a feedback impedance. Figure A9-6 An equivalent circuit.

8 Spencer/Ghausi, Introduction to Electronic Circuit Design, 1e, ©2003, Pearson Education, Inc. Chapter 9, slide 8 Figure 9-25 A common-emitter amplifier. (This is the same circuit as in Figure 8-33.)

9 Spencer/Ghausi, Introduction to Electronic Circuit Design, 1e, ©2003, Pearson Education, Inc. Chapter 9, slide 9 Figure 9-26 The small-signal low-frequency AC equivalent circuit for the common-emitter amplifier of Figure 9-25. Figure 9-27 The circuit of Figure 9-26 with the emitter impedance reflected into the base.

10 Spencer/Ghausi, Introduction to Electronic Circuit Design, 1e, ©2003, Pearson Education, Inc. Chapter 9, slide 10 Figure 9-29 The small-signal high-frequency AC equivalent circuit for the amplifier of Figure 9-25.

11 Spencer/Ghausi, Introduction to Electronic Circuit Design, 1e, ©2003, Pearson Education, Inc. Chapter 9, slide 11 Figure 9-30 The equivalent circuit from Figure 9-29 after application of Miller’s theorem.

12 Spencer/Ghausi, Introduction to Electronic Circuit Design, 1e, ©2003, Pearson Education, Inc. Chapter 9, slide 12 Figure 9-32 (a) The small-signal low-frequency AC equivalent for the common-emitter amplifier of Figure 9-25 and (b) the circuit for finding the short-circuit driving-point resistance seen by C E.

13 Spencer/Ghausi, Introduction to Electronic Circuit Design, 1e, ©2003, Pearson Education, Inc. Chapter 9, slide 13 Figure 9-34 The circuit for finding the open- circuit driving-point resistance seen by C .

14 Spencer/Ghausi, Introduction to Electronic Circuit Design, 1e, ©2003, Pearson Education, Inc. Chapter 9, slide 14 Figure 9-35 A common-source amplifier.

15 Spencer/Ghausi, Introduction to Electronic Circuit Design, 1e, ©2003, Pearson Education, Inc. Chapter 9, slide 15 Figure 9-36 The small-signal low-frequency AC equivalent circuit for the common-source amplifier of Figure 9-35.

16 Spencer/Ghausi, Introduction to Electronic Circuit Design, 1e, ©2003, Pearson Education, Inc. Chapter 9, slide 16 Figure 9-37 Finding R Ss for the circuit in Figure 9-36.

17 Spencer/Ghausi, Introduction to Electronic Circuit Design, 1e, ©2003, Pearson Education, Inc. Chapter 9, slide 17 Figure 9-40 The equivalent circuit from Figure 9-39 after application of Miller’s theorem.

18 Spencer/Ghausi, Introduction to Electronic Circuit Design, 1e, ©2003, Pearson Education, Inc. Chapter 9, slide 18 Figure 9-43 The circuit for finding the open-circuit driving-point resistance seen by C gd.

19 Spencer/Ghausi, Introduction to Electronic Circuit Design, 1e, ©2003, Pearson Education, Inc. Chapter 9, slide 19 Figure 9-46 (a) The small-signal high-frequency AC equivalent for the buffer in Figure 9-44. (b) After applying Miller’s approximation.

20 Spencer/Ghausi, Introduction to Electronic Circuit Design, 1e, ©2003, Pearson Education, Inc. Chapter 9, slide 20 Figure 9-47 Finding the open-circuit driving-point resistance seen by C cm.

21 Spencer/Ghausi, Introduction to Electronic Circuit Design, 1e, ©2003, Pearson Education, Inc. Chapter 9, slide 21 Figure 9-59 The small-signal high-frequency AC equivalent circuit for a common-control amplifier stage.

22 Spencer/Ghausi, Introduction to Electronic Circuit Design, 1e, ©2003, Pearson Education, Inc. Chapter 9, slide 22 Figure 9-61 The small-signal high-frequency AC equivalent circuit for the amplifier in Figure 9-60. Figure 9-60 A common-base amplifier.

23 Spencer/Ghausi, Introduction to Electronic Circuit Design, 1e, ©2003, Pearson Education, Inc. Chapter 9, slide 23 Figure 9-63 The small-signal high-frequency AC equivalent circuit for the amplifier in Figure 9-62. Figure 9-62 A common-gate amplifier.

24 Spencer/Ghausi, Introduction to Electronic Circuit Design, 1e, ©2003, Pearson Education, Inc. Chapter 9, slide 24 Figure 9-64 A general bipolar single-transistor amplifier.

25 Spencer/Ghausi, Introduction to Electronic Circuit Design, 1e, ©2003, Pearson Education, Inc. Chapter 9, slide 25

26 Spencer/Ghausi, Introduction to Electronic Circuit Design, 1e, ©2003, Pearson Education, Inc. Chapter 9, slide 26 Figure 9-65 A general FET single-transistor amplifier.

27 Spencer/Ghausi, Introduction to Electronic Circuit Design, 1e, ©2003, Pearson Education, Inc. Chapter 9, slide 27

28 Spencer/Ghausi, Introduction to Electronic Circuit Design, 1e, ©2003, Pearson Education, Inc. Chapter 9, slide 28

29 Spencer/Ghausi, Introduction to Electronic Circuit Design, 1e, ©2003, Pearson Education, Inc. Chapter 9, slide 29 Figure 9-83 A bipolar cascode amplifier.

30 Spencer/Ghausi, Introduction to Electronic Circuit Design, 1e, ©2003, Pearson Education, Inc. Chapter 9, slide 30 Figure 9-84 The high-frequency small-signal AC equivalent circuit of the cascode amplifier in Figure 9-83.

31 Spencer/Ghausi, Introduction to Electronic Circuit Design, 1e, ©2003, Pearson Education, Inc. Chapter 9, slide 31 Figure 9-86 A MOSFET cascode amplifier.

32 Spencer/Ghausi, Introduction to Electronic Circuit Design, 1e, ©2003, Pearson Education, Inc. Chapter 9, slide 32 Figure 9-87 The high-frequency small-signal AC equivalent circuit for the amplifier in Figure 9-86.

Download ppt "Spencer/Ghausi, Introduction to Electronic Circuit Design, 1e, ©2003, Pearson Education, Inc. Chapter 9, slide 1 Introduction to Electronic Circuit Design."

Similar presentations

Chapter 5: BJT AC Analysis. Copyright ©2009 by Pearson Education, Inc. Upper Saddle River, New Jersey 07458 All rights reserved. Electronic Devices and.

Chapter 5: BJT AC Analysis. Copyright ©2009 by Pearson Education, Inc. Upper Saddle River, New Jersey All rights reserved. Electronic Devices and.
Transistor Amplifiers

Transistor Amplifiers
Electronic Devices Ninth Edition Floyd Chapter 10.

Electronic Devices Ninth Edition Floyd Chapter 10.
Lecture 21 REMINDERS OUTLINE Frequency Response Reading: Chapter 11

Lecture 21 REMINDERS OUTLINE Frequency Response Reading: Chapter 11
Using the Hybrid-  Model.  r bb and r o are omitted (insignificant)  R B represents parallel combination of R B1 and R B2  At high frequencies C.

Using the Hybrid-  Model.  r bb and r o are omitted (insignificant)  R B represents parallel combination of R B1 and R B2  At high frequencies C.
Voltage-Series Feedback

Voltage-Series Feedback
Cascode Stage. OUTLINE Review of BJT Amplifiers Cascode Stage Reading: Chapter 9.1.

Cascode Stage. OUTLINE Review of BJT Amplifiers Cascode Stage Reading: Chapter 9.1.
COMSATS Institute of Information Technology Virtual campus Islamabad

COMSATS Institute of Information Technology Virtual campus Islamabad
EE105 Fall 2007Lecture 8, Slide 1Prof. Liu, UC Berkeley Lecture 8 OUTLINE BJT Amplifiers (cont’d) – Common-emitter topology – CE stage with emitter degeneration.

EE105 Fall 2007Lecture 8, Slide 1Prof. Liu, UC Berkeley Lecture 8 OUTLINE BJT Amplifiers (cont’d) – Common-emitter topology – CE stage with emitter degeneration.
Single Stage IC Amplifiers

Single Stage IC Amplifiers
Common-Base vs. Common-Emitter

Common-Base vs. Common-Emitter
Module 2: Part 2 Basic BJT Amplifiers. Learning Objectives After studying this module, the reader should have the ability to: n Explain graphically the.

Module 2: Part 2 Basic BJT Amplifiers. Learning Objectives After studying this module, the reader should have the ability to: n Explain graphically the.
Fig. 7.1 Bode plot for the typical magnitude term. The curve shown applies for the case of a zero. For a pole, the high-frequency asymptote should be drawn.

Fig. 7.1 Bode plot for the typical magnitude term. The curve shown applies for the case of a zero. For a pole, the high-frequency asymptote should be drawn.
Differential and Multistage Amplifiers

Differential and Multistage Amplifiers
Chapter 4 – Bipolar Junction Transistors (BJTs)

Chapter 4 – Bipolar Junction Transistors (BJTs)
Chapter 2 Small-Signal Amplifiers

Chapter 2 Small-Signal Amplifiers
© Electronics ECE 1312  Nor Farahidah Za’bah  Room number : E2-2-13.12  Phone number : 03-6196 4562  address : 

© Electronics ECE 1312  Nor Farahidah Za’bah  Room number : E  Phone number :  address : 
Chapter 7: BJT Transistor Modeling

Chapter 7: BJT Transistor Modeling
Chapter Five The Field-Effect Transistor. Figure 6—2 A three-terminal nonlinear device that can be controlled by the voltage at the third terminal v.

Chapter Five The Field-Effect Transistor. Figure 6—2 A three-terminal nonlinear device that can be controlled by the voltage at the third terminal v.
Single-Stage Integrated- Circuit Amplifiers

Single-Stage Integrated- Circuit Amplifiers

Similar presentations

Ads by Google