Microelectronics: Circuit Analysis and Design
Microelectronics: Circuit Analysis and Design
4th Edition
ISBN: 9780073380643
Author: Donald A. Neamen
Publisher: McGraw-Hill Companies, The
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Chapter 5, Problem 5.55P

a.

To determine

The RTH and the VTH for the given circuit.

a.

Expert Solution
Check Mark

Answer to Problem 5.55P

Explanation of Solution

Given:

The circuit is given as:

  Microelectronics: Circuit Analysis and Design, Chapter 5, Problem 5.55P , additional homework tip  1

Assume β=100 .

Redrawing the given circuit by replacing voltage sources by the short circuit:

  Microelectronics: Circuit Analysis and Design, Chapter 5, Problem 5.55P , additional homework tip  2

Hence, the equivalent Thevenin resistance is:

  RTH=R1R2RTH=R1×R2R1+R2........(1)RTH=12× 103×2× 10312× 103+2× 103RTH=24× 10314RTH=1.714KΩ

The current through the resistors R1 and R2:

  I=5+5R1+R2...........(2)I=5+5( 12+2)× 103I=10× 10 314I=0.714mA

Hence, the Thevenin voltage is

  VTH=IR2VEE..........(3)VTH=(0.714× 10 3)(2× 103)5VTH=1.4285VTH=3.572V

b.

To determine

The range of the ICQ and VCEQ.

b.

Expert Solution
Check Mark

Answer to Problem 5.55P

The range of the given values are:

  ICQ=1.4mAVCEQ=2.3V

Explanation of Solution

Given:

The circuit is given as:

  Microelectronics: Circuit Analysis and Design, Chapter 5, Problem 5.55P , additional homework tip  3

Assume, β=100 .

Redrawing the Thevenin equivalent circuit for the given circuit as:

  Microelectronics: Circuit Analysis and Design, Chapter 5, Problem 5.55P , additional homework tip  4

Apply Kirchhoff s voltage law to the above circuit we get

  VTH+IBQRTH+VBE( on)+IEQRE5=0IBQRTH+(1+β)IBQRE=5VTHVBE( on)IBQ=5V THV BE(on)R TH+( 1+β)RE............(4)

Substitute the values in the above expression , we get

  IBQ=53.5720.71.714× 103+( 1+100)0.5× 103IBQ=0.72852.214× 103IBQ=13.94μA

The common emitter mode current gain is:

  ICQ=βIBQ..........(5)ICQ=(100)(13.94× 10 6)ICQ=1.4mA

The quiescent collector emitter voltage is

  VCEQ=5+5(RC+RE)ICQ..........(6)VCEQ=10(5+0.5)×103×1.4×103VCEQ=107.7VCEQ=2.3V

c.

To determine

To draw: The load line and the plot Q-point.

c.

Expert Solution
Check Mark

Explanation of Solution

Given:

The circuit is given as:

  Microelectronics: Circuit Analysis and Design, Chapter 5, Problem 5.55P , additional homework tip  5

Assume, β=100 .

The equation for the load line is :

  VCE=5+5(RC+RE)IC..........(7)VCE=10(5+0.5)×103ICVCE=105.5×103IC

Hence, the coordinates of the end points of the load line are :

Let VCE=0V In the above expression is

  0=105.5×103ICIC=105.5× 103IC=1.818mA

Let IC=0A In the Above expression is

  VCE=105.5×103(0)VCE=100VCE=10V

Hence, the co-ordinates of the two extremities of the load line is

  (0V,1.818mA)and(10V,0mA) .

Therefore, the plot for load line is drawn is:

  Microelectronics: Circuit Analysis and Design, Chapter 5, Problem 5.55P , additional homework tip  6

d.

To determine

The range of ICQ and VCEQ and the load line corresponding to the minimum and the maximum resistor value and the plot Q-points.

d.

Expert Solution
Check Mark

Answer to Problem 5.55P

The range of the data:

  1.33mAICQ1.473mA1.915VVCEQ2.685V

Explanation of Solution

Given:

The circuit is given as:

  Microelectronics: Circuit Analysis and Design, Chapter 5, Problem 5.55P , additional homework tip  7

Assume, β=100 .

The resistors RC and RE vary by ±5 percent .

The values of the resistor are given as:

  RE=(0.5+5%of0.5)RE=(0.5+0.025)RE=0.525KΩRE=(0.55%of0.5)RE=(50.025)RE=0.475

Using the equation (7) when RC=5.25,RE=0.525andVCEQ=2.3V :

  VCEQ=10(RC+RE)ICQICQ=10V CEQRC+REICQ=102.3( 4.75+0.475)× 103ICQ=7.75.225× 103ICQ=1.473mA

Thus, the range of ICQ is

  1.33mAICQ1.473mA

Load line equation for maximum resistor values using

  VCE=10(RC+RE)ICVCE=10(5.25+0.525)×103ICVCE=105.775×103IC

Put VCE=0V In the above expression:

  0=105.775×103ICIC=105.775× 103IC=1.731mA

Put IC=0mA in the above expression, we get

  VCE=10(5.25+0.525)×103(0)VCE=100VCE=10V

Hence, the co-ordinates of the two extremities of the load line is

  (0V,1.731mA)and(10V,0mA) and the plot for land line for the ,maximum resistance and Q point is :

  Microelectronics: Circuit Analysis and Design, Chapter 5, Problem 5.55P , additional homework tip  8

From equation (7) when RE=5.25,RE=0.525andICQ=1.4mA

  VCEQ=10(RC+RE)ICQVCEQ=10(5.25+0.525)×103×1.4×103VCEQ=108.085VCEQ=1.915V

From equation (7) when RC=4.75,RE=0.475andICQ=1.4mA :

  VCEQ=10(RC+RE)ICQVCEQ=10(4.75+0.475)×103×1.4×103VCEQ=107.315VCEQ=2.685V

Hence , the range of VCEQ is

  1.915VVCEQ2.685V

Load line equation for maximum resistor values using

  VCE=10(RC+RE)ICVCE=10(4.75+0.475)×103ICVCE=105.225×103IC

Put VCE=0V in the above expression , we get

  0=105.225×103ICIC=105.225× 103IC=1.914mA

Put IC=0mA In the above expression :

  VCE=10(4.75+0.475)×103(0)VCE=100VCE=10V

Thus the co-ordinates of the two extremities of the load line is :

  (0V,1.914mA)and(10V,0mA) and the plot for load line for the minimum resistance and Q point is:

  Microelectronics: Circuit Analysis and Design, Chapter 5, Problem 5.55P , additional homework tip  9

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Chapter 5 Solutions

Microelectronics: Circuit Analysis and Design

Ch. 5 - (a) Verify the results of Example 5.3 with a...Ch. 5 - Consider the pnp circuit in Figure 5.22(a). Assume...Ch. 5 - In the following exercise problems, assume...Ch. 5 - In the following exercise problems, assume...Ch. 5 - The circuit elements in Figure 5.27(a) are changed...Ch. 5 - Using a PSpice simulation, plot the voltage...Ch. 5 - The parameters of the circuit shown in Figure...Ch. 5 - Design the commonbase circuit shown in Figure 5.33...Ch. 5 - The bias voltages in the circuit shown in Figure...Ch. 5 - The bias voltages in the circuit shown in Figure...Ch. 5 - The circuit elements in Figure 5.36(a) are V+=5V ,...Ch. 5 - For the transistor shown in the circuit of Figure...Ch. 5 - For the circuit shown in Figure 5.41, determine...Ch. 5 - Assume =120 for the transistor in Figure 5.42....Ch. 5 - For the transistor in Figure 5.43, assume =90 ....Ch. 5 - (a) Redesign the LED circuit in Figure 5.45(a)...Ch. 5 - The transistor parameters in the circuit in Figure...Ch. 5 - Redesign the inverter amplifier circuit shown in...Ch. 5 - For the circuit shown in Figure 5.44, assume...Ch. 5 - Consider the circuit shown in Figure 5.51(b)....Ch. 5 - [Note: In the following exercises, assume the BE...Ch. 5 - [Note: In the following exercises, assume the B—E...Ch. 5 - Consider the circuit in Figure 5.54(a), let...Ch. 5 - Prob. 5.16EPCh. 5 - The parameters of the circuit shown in Figure...Ch. 5 - Consider the circuit in Figure 5.54(a). The...Ch. 5 - Consider the circuit shown in Figure 5.58. The...Ch. 5 - In the circuit shown in Figure 5.60, the...Ch. 5 - The parameters of the circuit shown in Figure...Ch. 5 - For Figure 5.59, the circuit parameters are...Ch. 5 - In the circuit shown in Figure 5.61, determine new...Ch. 5 - For the circuit shown in Figure 5.63, the circuit...Ch. 5 - (a) Verily the cascode circuit design in Example...Ch. 5 - Prob. 1RQCh. 5 - Prob. 2RQCh. 5 - Prob. 3RQCh. 5 - Define commonbase current gain and commonemitter...Ch. 5 - Discuss the difference between the ac and dc...Ch. 5 - State the relationships between collector,...Ch. 5 - Define Early voltage and collector output...Ch. 5 - Describe a simple commonemitter circuit with an...Ch. 5 - Prob. 9RQCh. 5 - Prob. 10RQCh. 5 - Prob. 11RQCh. 5 - Describe a bipolar transistor NOR logic circuit.Ch. 5 - Describe how a transistor can be used to amplify a...Ch. 5 - Discuss the advantages of using resistor voltage...Ch. 5 - Prob. 15RQCh. 5 - Prob. 16RQCh. 5 - (a) In a bipolar transistor biased in the...Ch. 5 - (a) A bipolar transistor is biased in the...Ch. 5 - (a) The range of ( for a particular type of...Ch. 5 - (a) A bipolar transistor is biased in the...Ch. 5 - Prob. 5.5PCh. 5 - An npn transistor with =80 is connected in a...Ch. 5 - Prob. 5.7PCh. 5 - A pnp transistor with =60 is connected in a...Ch. 5 - (a) The pnp transistor shown in Figure P5.8 has a...Ch. 5 - An npn transistor has a reverse-saturation current...Ch. 5 - Two pnp transistors, fabricated with the same...Ch. 5 - The collector currents in two transistors, A and...Ch. 5 - Prob. 5.13PCh. 5 - Prob. 5.14PCh. 5 - In a particular circuit application, the minimum...Ch. 5 - A particular transistor circuit design requires a...Ch. 5 - For all the transistors in Figure P5.17, =75 . The...Ch. 5 - The emitter resistor values in the circuits show...Ch. 5 - Consider the two circuits in Figure P5.19. The...Ch. 5 - The current gain for each transistor in the...Ch. 5 - Consider the circuits in Figure P5.21. For each...Ch. 5 - (a) The circuit and transistor parameters for the...Ch. 5 - In the circuits shown in Figure P5.23, the values...Ch. 5 - (a) For the circuit in Figure P5.24, determine VB...Ch. 5 - (a) The bias voltages in the circuit shown in...Ch. 5 - The transistor shown in Figure P5.26 has =120 ....Ch. 5 - The transistor in the circuit shown in Figure...Ch. 5 - In the circuit in Figure P5.27, the constant...Ch. 5 - For the circuit shown in Figure P5.29, if =200 for...Ch. 5 - The circuit shown in Figure P5.30 is to be...Ch. 5 - (a) The bias voltage in the circuit in Figure P5.3...Ch. 5 - The current gain of the transistor in the circuit...Ch. 5 - (a) The current gain of the transistor in Figure...Ch. 5 - (a) The transistor shown in Figure P5.34 has =100...Ch. 5 - Assume =120 for the transistor in the circuit...Ch. 5 - For the circuit shown in Figure P5.27, calculate...Ch. 5 - Consider the commonbase circuit shown in Figure...Ch. 5 - (a) For the transistor in Figure P5.38, =80 ....Ch. 5 - Let =25 for the transistor in the circuit shown in...Ch. 5 - (a) The circuit shown in Figure P5.40 is to be...Ch. 5 - The circuit shown in Figure P5.41 is sometimes...Ch. 5 - The transistor in Figure P5.42 has =120 . (a)...Ch. 5 - The commonemitter current gain of the transistor...Ch. 5 - For the circuit shown in Figure P5.44, plot the...Ch. 5 - The transistor in the circuit shown in Figure...Ch. 5 - Consider the circuit in Figure P5.46. For the...Ch. 5 - The current gain for the transistor in the circuit...Ch. 5 - Consider the amplifier circuit shown in Figure...Ch. 5 - For the transistor in the circuit shown in Figure...Ch. 5 - Reconsider Figure P5.49. The transistor current...Ch. 5 - The current gain of the transistor shown in the...Ch. 5 - For the circuit shown in Figure P5.52, let =125 ....Ch. 5 - Consider the circuit shown in Figure P5.53. (a)...Ch. 5 - (a) Redesign the circuit shown in Figure P5.49...Ch. 5 - Prob. 5.55PCh. 5 - Consider the circuit shown in Figure P5.56. (a)...Ch. 5 - (a) Determine the Q-point values for the circuit...Ch. 5 - (a) Determine the Q-point values for the circuit...Ch. 5 - (a) For the circuit shown in Figure P5.59, design...Ch. 5 - Design a bias-stable circuit in the form of Figure...Ch. 5 - Using the circuit in Figure P5.61, design a...Ch. 5 - For the circuit shown in Figure P5.61, the bias...Ch. 5 - (a) A bias-stable circuit with the configuration...Ch. 5 - (a) For the circuit shown in Figure P5.64, assume...Ch. 5 - The dc load line and Q-point of the circuit in...Ch. 5 - The range of ß for the transistor in the circuit...Ch. 5 - The nominal Q-point of the circuit in Figure P5.67...Ch. 5 - (a) For the circuit in Figure P5.67, the value of...Ch. 5 - For the circuit in Figure P5.69, let =100 and...Ch. 5 - Prob. 5.70PCh. 5 - Design the circuit in Figure P5.70 to be bias...Ch. 5 - Consider the circuit shown in Figure P5.72. (a)...Ch. 5 - For the circuit in Figure P5.73, let =100 . (a)...Ch. 5 - Prob. D5.74PCh. 5 - (a) Design a fourresistor bias network with the...Ch. 5 - (a) Design a four-resistor bias network with the...Ch. 5 - (a) A fourresistor bias network is to be designed...Ch. 5 - (a) Design a fourresistor bias network with the...Ch. 5 - For each transistor in the circuit in Figure...Ch. 5 - The parameters for each transistor in the circuit...Ch. 5 - The bias voltage in the circuit shown in Figure...Ch. 5 - Consider the circuit shown in Figure P5.82. The...Ch. 5 - (a) For the transistors in the circuit shown in...Ch. 5 - Using a computer simulation, plot VCE versus V1...Ch. 5 - Using a computer simulation, verify the results of...Ch. 5 - Using a computer simulation, verify the results of...Ch. 5 - Consider a commonemitter circuit with the...Ch. 5 - The emitterfollower circuit shown in Figure P5.89...Ch. 5 - The bias voltages for the circuit in Figure...Ch. 5 - The multitransistor circuit in Figure 5.61 is to...
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