Presentation is loading. Please wait.

Presentation is loading. Please wait.

Chapter 4(c) DC Biasing – Bipolar Junction Transistors (BJTs)

Published byIsabel Little Modified over 5 years ago

Similar presentations

Presentation on theme: "Chapter 4(c) DC Biasing – Bipolar Junction Transistors (BJTs)"— Presentation transcript:

1 Chapter 4(c) DC Biasing – Bipolar Junction Transistors (BJTs)
DMT 121 – ELECTRONIC 1 Chapter 4(c) DC Biasing – Bipolar Junction Transistors (BJTs)

2 Collector Feedback Bias
An improved level of stability can also be obtained by introducing a feedback path from collector to base. If IC tries to increase, it drops more voltage across RC, thereby causing VC to decrease. When VC decrease, there is a decrease voltage across RB, which decrease IB. The decrease in IB produce less IC which in turn, drops less voltage across RC and thus offsets the decrease in VC. These feedbacks keep the Q-point stable. VC IC  VRC   VC  VRB   IB   IC  VRC   offset the decrease in VC

3 Collector Feedback Bias
Base – Emitter Loop VCC – IC'RC – IBRB – VBE – IERE = 0 Actual case IC' = IC + IB Approximation can be employed : IC'  IC = IB and IE  IC VCC – VBE - IB (RC + RE) – IBRB = 0 Solving for IB, yields

4 Collector Feedback Bias
Collector – Emitter Loop VCC – IC'RC – VCE – IERE = 0 Approximation can be employed : IC'  IC and IE  IC VCC – VCE - IC (RC + RE) = 0 VCE = VCC – IC (RC + RE)

5 Collector Feedback Bias - Summary
Circuit recognition The base resistor is connected between the base and the collector terminals of the transistor. Q-Point Stability IC is dependent to βDC and VBE, IB is dependent to VBE -ve feedback effect the Q-point for stability. Advantage: A simple circuit with relatively stable Q-point. Disadvantage: Relatively poor ac characteristics. Applications: Used primarily to bias linear amplifiers.

6 Collector Feedback Bias - Summary
Q-point relationships:

7 EXAMPLE Determine the values of ICQ and VCEQ for the amplifier shown in figure below. VCC = 10 V, RB = 180 kΩ, RC = 1.5kΩ and β =100 VC

8 TROUBLESHOOTING Shown is a typical voltage divider circuit with correct voltage readings. Knowing these voltages are required before logical troubleshooting can be applied. We will discuss some of the faults and symptoms.

9 TROUBLESHOOTING R1 Open With no bias the transistor is in cutoff.
Base voltage goes down to 0V. Collector voltage goes up to 10 V (VCC). Emitter voltage goes down to 0V.

10 TROUBLESHOOTING Resistor RE Open: Transistor is in cutoff.
Base reading voltage will stay approximately the same. Collector voltage goes up to 10V(VCC). Emitter voltage will be approximately the base voltage + 0.7V.

11 TROUBLESHOOTING Base Open Internally: Transistor is in cutoff.
Base voltage stays approximately the same. Collector voltage goes up to 10V(VCC). Emitter voltage goes down to 0V.

12 TROUBLESHOOTING Open BE Junction: Transistor is in cutoff.
Base voltage stays approximately the same. Collector voltage goes up to 10V(VCC) Emitter voltage goes down to 0V.

13 TROUBLESHOOTING Open BC Junction:
Base voltage goes down to 1.11V because of more base current flow through emitter. Collector voltage goes up to 10V (VCC). Emitter voltage will drop to 0.41V because of small current flow from forward biased base-emitter junction.

14 TROUBLESHOOTING RC Open:
Base voltage goes down to 1.11V because of more current flow through the emitter. Collector voltage will drop to 0.41V because of current flow from forward biased collector-base junction. Emitter voltage will drop to 0.41V because of small current flow from forward biased base-emitter junction.

15 TROUBLESHOOTING R2 Open:
Transistor pushed close to or into saturation. Base voltage goes up slightly to 3.83V because of increased bias. Emitter voltage goes up to 3.13V because of increased current. Collector voltage goes down because of increased conduction of transistor.

16 SUMMARY The purpose of biasing is to establish a stable operating point (Q-point). The Q-point is the best point for operation of a transistor for a given collector current. The dc load line helps to establish the Q-point for a given collector current. The linear region of a transistor is the region of operation within saturation and cutoff.

17 SUMMARY Voltage-divider bias is most widely used because it is stable and uses only one voltage supply Base bias is very unstable because it is  dependant. Emitter bias is stable but require two voltage supplies. Collector-back is relatively stable when compared to base bias, but not as stable as voltage-divider bias.

Download ppt "Chapter 4(c) DC Biasing – Bipolar Junction Transistors (BJTs)"

Similar presentations

Chapter 7 DC Biasing Circuits

Chapter 7 DC Biasing Circuits
Chapter 4 DC Biasing – Bipolar Junction Transistors (BJTs)

Chapter 4 DC Biasing – Bipolar Junction Transistors (BJTs)
Chapter 5 Transistor Bias Circuits

Chapter 5 Transistor Bias Circuits
Dr. Nasim Zafar Electronics 1 - EEE 231 Fall Semester – 2012 COMSATS Institute of Information Technology Virtual campus Islamabad.

Dr. Nasim Zafar Electronics 1 - EEE 231 Fall Semester – 2012 COMSATS Institute of Information Technology Virtual campus Islamabad.
Chapter 5 Transistor Bias Circuits. Objectives  Discuss the concept of dc biasing of a transistor for linear operation  Analyze voltage-divider bias,

Chapter 5 Transistor Bias Circuits. Objectives  Discuss the concept of dc biasing of a transistor for linear operation  Analyze voltage-divider bias,
Chapter 5 Transistor Bias Circuits

Chapter 5 Transistor Bias Circuits
Chapter 5 Transistor Bias Circuits. Objectives  Discuss the concept of dc biasing of a transistor for linear operation  Analyze voltage-divider bias,

Chapter 5 Transistor Bias Circuits. Objectives  Discuss the concept of dc biasing of a transistor for linear operation  Analyze voltage-divider bias,
ITM UNIVERSE,VADODARA ELECTRONIC DEVICES & CIRCUITS TOPIC NAME TRANSISTOR BIASING (DC ANALYSIS) PREPARED BY: NAME: Dilsha Dharmajan Electronics & communication.

ITM UNIVERSE,VADODARA ELECTRONIC DEVICES & CIRCUITS TOPIC NAME TRANSISTOR BIASING (DC ANALYSIS) PREPARED BY: NAME: Dilsha Dharmajan Electronics & communication.
Chapter 4 DC Biasing–BJTs. Copyright ©2009 by Pearson Education, Inc. Upper Saddle River, New Jersey 07458 All rights reserved. Electronic Devices and.

Chapter 4 DC Biasing–BJTs. Copyright ©2009 by Pearson Education, Inc. Upper Saddle River, New Jersey All rights reserved. Electronic Devices and.
DC Biasing - BJTs Chapter 4 Boylestad Electronic Devices and Circuit Theory.

DC Biasing - BJTs Chapter 4 Boylestad Electronic Devices and Circuit Theory.
Chapter 5 Transistor bias circuits Ir. Dr. Rosemizi Abd Rahim 1 Ref: Electronic Devices and Circuit Theory, 10/e, Robert L. Boylestad and Louis Nashelsky.

Chapter 5 Transistor bias circuits Ir. Dr. Rosemizi Abd Rahim 1 Ref: Electronic Devices and Circuit Theory, 10/e, Robert L. Boylestad and Louis Nashelsky.
Chapter 4 DC Biasing–BJTs

Chapter 4 DC Biasing–BJTs
LECTURE 1: BASIC BJT AMPLIFIER -AC ANALYSIS-

LECTURE 1: BASIC BJT AMPLIFIER -AC ANALYSIS-
Recall Lecture 10 Introduction to BJT 3 modes of operation

Recall Lecture 10 Introduction to BJT 3 modes of operation
Voltage Divider Bias Voltage-divider bias is the most widely used type of bias circuit. Only one power supply is needed and voltage-divider bias is more.

Voltage Divider Bias Voltage-divider bias is the most widely used type of bias circuit. Only one power supply is needed and voltage-divider bias is more.
Recall Last Lecture Biasing of BJT Applications of BJT

Recall Last Lecture Biasing of BJT Applications of BJT
Recall Last Lecture Biasing of BJT Three types of biasing

Recall Last Lecture Biasing of BJT Three types of biasing
Recall Last Lecture Biasing of BJT Three types of biasing

Recall Last Lecture Biasing of BJT Three types of biasing
Bipolar Junction Transistor Circuit Analysis

Bipolar Junction Transistor Circuit Analysis
Lecture 07 DC and AC Load Line

Lecture 07 DC and AC Load Line

Similar presentations

Ads by Google