MICROELECT. CIRCUIT ANALYSIS&DESIGN (LL)4th EditionNEAMEN Publisher: MCGISBN: 9781266368622
MICROELECT. CIRCUIT ANALYSIS&DESIGN (LL)
Solutions for MICROELECT. CIRCUIT ANALYSIS&DESIGN (LL)
Problem 5.1EP:
An npn transistor is biased in the forwardactive mode. The base current is IB=8.50A and the emitter...Problem 5.1TYU:
(a) The common-emitter current gains of two transistors are =60 and =150 . Determine the...Problem 5.2TYU:
An npn transistor is biased in the forwardactive mode. The base current is IB=5.0A and the collector...Problem 5.3TYU:
The emitter current in a pnp transistor biased in the forwardactive mode is IE=1.20mA . The...Problem 5.4TYU:
The output resistance of a bipolar transistor is ro=225k at IC=0.8mA . (a) Determine the Early...Problem 5.5TYU:
Assume that IC=1mA at VCE=1V , and that VBE is held constant. Determine IC at VCE=10V if: (a) VA=75V...Problem 5.2EP:
The openemitter breakdown voltage is BVCBO=200V , the current gain is =120 , and the empirical...Problem 5.6TYU:
A particular transistor circuit requires a minimum openbase breakdown voltage of BVCEO=30V . If =100...Problem 5.3EP:
The circuit elements in Figure 5.20(a) are changed to VCC=3.3V , VBB=2V , RC=3.2k , and RB=430k ....Problem 5.4EP:
The circuit elements in Figure 5.22(a) are V+=3.3V , VBB=1.2V , RB=400k , and RC=5.25k . The...Problem 5.1CAE:
(a) Verify the results of Example 5.3 with a PSpice analysis. Use a standard transistor. (b) Repeat...Problem 5.5EP:
Consider the pnp circuit in Figure 5.22(a). Assume transistor parameters of VEB(on)=0.7V ,...Problem 5.7TYU:
In the following exercise problems, assume VBE(on)=0.7V and VCE(sat)=0.2V . Figure 5.26 Figure for...Problem 5.8TYU:
In the following exercise problems, assume VBE(on)=0.7V and VCE(sat)=0.2V . Figure 5.26 Figure for...Problem 5.6EP:
The circuit elements in Figure 5.27(a) are changed to RB=200k , RC=4k , and V+=9V . The transistor...Problem 5.2CAE:
Using a PSpice simulation, plot the voltage transfer characteristics of the circuit shown in Figure...Problem 5.7EP:
The parameters of the circuit shown in Figure 5.30(a) are changed to V+=3.3V , V=3.3V , VBB=0 ,...Problem 5.8EP:
Design the commonbase circuit shown in Figure 5.33 such that IEQ=0.125mA and VECQ=2.2V . The...Problem 5.9TYU:
The bias voltages in the circuit shown in Figure 5.34 are V+=3.3V and V=3.3V . The measured value of...Problem 5.10TYU:
The bias voltages in the circuit shown in Figure 5.35 are V+=5V and V=5V . Assume that =85 ....Problem 5.9EP:
The circuit elements in Figure 5.36(a) are V+=5V , VBB=2V , RE=2k , and RB=180k . Assume...Problem 5.10EP:
For the transistor shown in the circuit of Figure 540, the common-base current gain is =0.9920 ....Problem 5.11TYU:
For the circuit shown in Figure 5.41, determine IE,IB,IC , and VCE , if =75 . (Ans. IB=15.1A ,...Problem 5.12TYU:
Assume =120 for the transistor in Figure 5.42. Determine RE such that VCE=2.2V . (Ans. RE=154 )...Problem 5.13TYU:
For the transistor in Figure 5.43, assume =90 . (a) Determine VBB such that IE=1.2mA . (b) Find IC...Problem 5.11EP:
(a) Redesign the LED circuit in Figure 5.45(a) such that IC1=15mA and IC1/IB1=50 for 1=5V . Use the...Problem 5.12EP:
The transistor parameters in the circuit in Figure 5.46(b) are: =40 , VBE(on)=0.7V , and...Problem 5.13EP:
Redesign the inverter amplifier circuit shown in Figure 5.48(a) such that the voltage amplification...Problem 5.14TYU:
For the circuit shown in Figure 5.44, assume circuit and transistor parameters of RB=240 , VCC=12V ,...Problem 5.14EP:
Consider the circuit shown in Figure 5.51(b). Assume VCC=2.8V , =150 , and VBE(on)=0.7V . Design the...Problem 5.15TYU:
[Note: In the following exercises, assume the BE cutin voltage is 0.7 V. Also assume the CE...Problem 5.16TYU:
[Note: In the following exercises, assume the B—E cutin voltage is 0.7V. Also assume the CE...Problem 5.15EP:
Consider the circuit in Figure 5.54(a), let VCC=3.3V , RE=500k , RC=4k , R1=85k , R2=35k , and =150...Problem 5.17TYU:
The parameters of the circuit shown in Figure 5.54(a) are VCC=5V , RE=1k , RC=4k , R1=440k and...Problem 5.18TYU:
Consider the circuit in Figure 5.54(a). The circuit parameters are VCC=5V and RE=1k . The transistor...Problem 5.17EP:
Consider the circuit shown in Figure 5.58. The transistor parameters are =150 and VBE(on)=0.7V . The...Problem 5.18EP:
In the circuit shown in Figure 5.60, the parameters are V+=3.3V , V=3.3V , and RB=0 . The transistor...Problem 5.19TYU:
The parameters of the circuit shown in Figure 5.57(a) are V+=5V , V=5V , RE=0.5k , and RC=4.5k . The...Problem 5.20TYU:
For Figure 5.59, the circuit parameters are IQ=0.25mA , V+=2.5V , V=2.5V , RB=75k , and RC=4k . The...Problem 5.19EP:
In the circuit shown in Figure 5.61, determine new values of RC1 and RC2 such that VCEQ1=3.25V and...Problem 5.20EP:
For the circuit shown in Figure 5.63, the circuit parameters are V+=12V and RE=2k , and the...Problem 5.4CAE:
(a) Verily the cascode circuit design in Example 5.20 using a PSpice simulation. Use standard...Problem 6RQ:
State the relationships between collector, emitter, and base currents in a bipolar transistor biased...Problem 8RQ:
Describe a simple commonemitter circuit with an npn bipolar transistor and discuss the relation...Problem 12RQ:
Describe a bipolar transistor NOR logic circuit.Problem 14RQ:
Discuss the advantages of using resistor voltage divider biasing compared to a single base resistor.Problem 5.1P:
(a) In a bipolar transistor biased in the forwardactive region, the base current is iB=2.8A and the...Problem 5.2P:
(a) A bipolar transistor is biased in the forwardactive mode. The collector current is iC=726A and...Problem 5.3P:
(a) The range of ( for a particular type of transistor is 110180 . Determine the corresponding range...Problem 5.4P:
(a) A bipolar transistor is biased in the forwardactive mode. The measured parameters are iE=1.25mA...Problem 5.6P:
An npn transistor with =80 is connected in a commonbase configuration as shown in Figure P5.6. (a)...Problem 5.8P:
A pnp transistor with =60 is connected in a commonbase configuration as shown in Figure P5.8. (a)...Problem 5.9P:
(a) The pnp transistor shown in Figure P5.8 has a common-base current gain =0.9860 . Determine the...Problem 5.10P:
An npn transistor has a reverse-saturation current of IS=51015A and a current gain of =125 . The...Problem 5.11P:
Two pnp transistors, fabricated with the same technology, have different junction areas. Both...Problem 5.12P:
The collector currents in two transistors, A and B, are both iC=275A . For transistor A, ISA=81016A...Problem 5.15P:
In a particular circuit application, the minimum required breakdown voltages are BVCBO=220V and...Problem 5.16P:
A particular transistor circuit design requires a minimum openbase breakdown voltage of BVCEO=50V ....Problem 5.17P:
For all the transistors in Figure P5.17, =75 . The results of some measurements are indicated on the...Problem 5.18P:
The emitter resistor values in the circuits show in Figures P5.17(a) and (c) may vary by 5 percent...Problem 5.19P:
Consider the two circuits in Figure P5.19. The parameters of each transistor are IS=51016A and =90 ....Problem 5.20P:
The current gain for each transistor in the circuits shown in Figure P5.20 is =120 . For each...Problem 5.21P:
Consider the circuits in Figure P5.21. For each transistor, =120 . Determine IC and VEC for each...Problem 5.22P:
(a) The circuit and transistor parameters for the circuit shown in Figure 5.20(a) are VCC=3V ,...Problem 5.23P:
In the circuits shown in Figure P5.23, the values of measured parameters are shown. Determine , ,...Problem 5.24P:
(a) For the circuit in Figure P5.24, determine VB and IE such that VB=VC . Assume =90 . (b) What...Problem 5.25P:
(a) The bias voltages in the circuit shown in Figure P5.25 are changed to V+=3.3V and V=3.3V . The...Problem 5.26P:
The transistor shown in Figure P5.26 has =120 . Determine IC and VEC . Plot the load line and the...Problem 5.27P:
The transistor in the circuit shown in Figure P5.27 is biased with a constant current in the...Problem 5.28P:
In the circuit in Figure P5.27, the constant current is I=0.5mA .If =50 , determine the power...Problem 5.29P:
For the circuit shown in Figure P5.29, if =200 for each transistor, determine: (a) IE1 , (b) IE2 ,...Problem 5.30P:
The circuit shown in Figure P5.30 is to be designed such that ICQ=0.8mA and VCEQ=2V for the case...Problem D5.31P:
(a) The bias voltage in the circuit in Figure P5.3 1 is changed to VCC=9V . The transistor current...Problem 5.32P:
The current gain of the transistor in the circuit shown in Figure P5.32 is =150 . Determine IC,IE ,...Problem 5.33P:
(a) The current gain of the transistor in Figure P5.33 is =75 . Determine VO for: (i) VBB=0 , (ii)...Problem 5.34P:
(a) The transistor shown in Figure P5.34 has =100 . Determine VO for (i) IQ=0.1mA , (ii) IQ=0.5mA ,...Problem 5.35P:
Assume =120 for the transistor in the circuit shown in Figure P5.34. Determine IQ such that (a)...Problem 5.36P:
For the circuit shown in Figure P5.27, calculate and plot the power dissipated in the transistor for...Problem 5.37P:
Consider the commonbase circuit shown in Figure P5.37. Assume the transistor alpha is =0.9920 ....Problem 5.38P:
(a) For the transistor in Figure P5.38, =80 . Determine V1 such that VCEQ=6V . (b) Determine the...Problem 5.39P:
Let =25 for the transistor in the circuit shown in Figure P5.39. Determine the range of V1 such that...Problem D5.40P:
(a) The circuit shown in Figure P5.40 is to be designed such that ICQ=0.5mA and VCEQ=2.5V . Assume...Problem 5.41P:
The circuit shown in Figure P5.41 is sometimes used as a thermometer. Assume the transistors Q1 and...Problem 5.42P:
The transistor in Figure P5.42 has =120 . (a) Determine VI that produces VO=4V for (i) RE=0k and...Problem 5.43P:
The commonemitter current gain of the transistor in Figure P5.43 is =80 . Plot the voltage transfer...Problem 5.44P:
For the circuit shown in Figure P5.44, plot the voltage transfer characteristics over the range...Problem 5.45P:
The transistor in the circuit shown in Figure P5.45 has a current gain of =40 . Determine RB such...Problem 5.46P:
Consider the circuit in Figure P5.46. For the transistor, =50 . Find IB,IC,IE , and VO for (a) VI=0...Problem 5.47P:
The current gain for the transistor in the circuit in Figure P5.47 is =60 . Determine RB such that...Problem 5.48P:
Consider the amplifier circuit shown in Figure P5.48. Assume a transistor current gain of =120 . The...Problem D5.49P:
For the transistor in the circuit shown in Figure P5.49, assume =120 . Design the circuit such that...Problem 5.50P:
Reconsider Figure P5.49. The transistor current gain is =150 . The circuit parameters are changed to...Problem 5.51P:
The current gain of the transistor shown in the circuit of Figure P5.51 is =100 . Determine VB and...Problem 5.52P:
For the circuit shown in Figure P5.52, let =125 . (a) Find ICQ and VCEQ . Sketch the load line and...Problem 5.53P:
Consider the circuit shown in Figure P5.53. (a) Determine IBQ,ICQ , and VCEQ for =80 . (b) What is...Problem 5.54P:
(a) Redesign the circuit shown in Figure P5.49 using VCC=9V such that the voltage drop across RC is...Problem 5.56P:
Consider the circuit shown in Figure P5.56. (a) Determine RTH,VTH,IBQ,ICQ , and VECQ for =90 . (b)...Problem 5.57P:
(a) Determine the Q-point values for the circuit in Figure P5.57. Assume =50 . (b) Repeat part (a)...Problem 5.58P:
(a) Determine the Q-point values for the circuit in Figure P5.58. Assume =50 . (b) Repeat part (a)...Problem D5.59P:
(a) For the circuit shown in Figure P5.59, design a biasstable circuit such that ICQ=0.8mA and...Problem D5.60P:
Design a bias-stable circuit in the form of Figure P5.59 with =120 such that ICQ=0.8mA , VCEQ=5V ,...Problem D5.61P:
Using the circuit in Figure P5.61, design a bias-stable amplifier such that the Q-point is in the...Problem D5.62P:
For the circuit shown in Figure P5.61, the bias voltages are changed to V+=3V and V=3V . (a) Design...Problem 5.63P:
(a) A bias-stable circuit with the configuration shown in Figure P5.6 1 is to be designed such that...Problem D5.64P:
(a) For the circuit shown in Figure P5.64, assume that the transistor current gain is =90 and that...Problem 5.65P:
The dc load line and Q-point of the circuit in Figure P5.65(a) are shown in Figure P5.65(b). For the...Problem D5.66P:
The range of ß for the transistor in the circuit in Figure P5.66 is 80120 . Design a biasstable...Problem D5.67P:
The nominal Q-point of the circuit in Figure P5.67 is ICQ=1mA and VCEQ=5V , for =60 . The current...Problem D5.68P:
(a) For the circuit in Figure P5.67, the value of VCC is changed to 3 V. Let RC=5RE and =120 ....Problem D5.69P:
For the circuit in Figure P5.69, let =100 and RE=3k . Design a biasstable circuit such that VE=0 ....Problem D5.71P:
Design the circuit in Figure P5.70 to be bias stable and to provide nominal Q-point values of...Problem D5.72P:
Consider the circuit shown in Figure P5.72. (a) The nominal transistor current gain is =80 . Design...Problem 5.73P:
For the circuit in Figure P5.73, let =100 . (a) Find VTH and RTH for the base circuit. (b) Determine...Problem D5.75P:
(a) Design a fourresistor bias network with the configuration shown in Figure P5.6 1 to yield Qpoint...Problem D5.76P:
(a) Design a four-resistor bias network with the configuration shown in FigureP5.61 to yield Q-point...Problem D5.77P:
(a) A fourresistor bias network is to be designed with the configuration shown in Figure P5.77. The...Problem D5.78P:
(a) Design a fourresistor bias network with the configuration shown in Figure P5.77 such that the...Problem 5.79P:
For each transistor in the circuit in Figure P5.79, =120 and the BE turn on voltage is 0.7 V....Problem 5.80P:
The parameters for each transistor in the circuit in Figure P5.80 are =80 and VBE(on)=0.7V ....Problem D5.81P:
The bias voltage in the circuit shown in Figure 5.63 is changed to V+=5V . Design the circuit to...Problem 5.82P:
Consider the circuit shown in Figure P5.82. The current gain for the npn transistor is n=120 and for...Problem 5.83P:
(a) For the transistors in the circuit shown in Figure P5.83, the parameters are: =100 and...Problem 5.84CSP:
Using a computer simulation, plot VCE versus V1 over the range 0VI8V for the circuit in Figure...Problem 5.85CSP:
Using a computer simulation, verify the results of Example 5.7.Problem 5.87CSP:
Using a computer simulation, verify the results of Example 5.19.Problem D5.88DP:
Consider a commonemitter circuit with the configuration shown in Figure 5.54(a). Assume a bias...Problem D5.89DP:
The emitterfollower circuit shown in Figure P5.89 is biased at V+=2.5V and V=2.5V . Design a...Browse All Chapters of This Textbook
Chapter 1 - Semiconductor Materials And DiodesChapter 2 - Diode CircuitsChapter 3 - The Fields-effect TransistorChapter 4 - Basic Fet AmplifiersChapter 5 - Thebipolar Junction TransistorChapter 6 - Basic Bjt AmplifiersChapter 7 - Frequency ResponseChapter 8 - Output Stages And Power AmplifiersChapter 9 - Ideal Operational Amplifiers And Op-amp CircuitsChapter 10 - Integrated Circuit Biasinh And Active Loads
Chapter 11 - Differential And Multisatge AmplifiersChapter 12 - Feedback And StabilityChapter 13 - Operational Amplifier CircuitsChapter 14 - Nonideal Effects In Operational Amplifier CircuitsChapter 15 - Applications And Design Of Integrated CircuitsChapter 16 - Mosfet Digital CircuitsChapter 17 - Bipolar Digital Circuits
Sample Solutions for this Textbook
We offer sample solutions for MICROELECT. CIRCUIT ANALYSIS&DESIGN (LL) homework problems. See examples below:
Chapter 1, Problem 1.1EPChapter 1, Problem 1.2EPChapter 1, Problem 1.1TYUChapter 1, Problem 1.7TYUChapter 1, Problem 1.3PChapter 1, Problem 1.17PChapter 1, Problem 1.27PChapter 1, Problem 1.30PChapter 1, Problem 1.35P
Given: The value of current is, IS1=IS2=10−13 A IS1=5×10−14 A, IS2=5×10−13A The given circuit is...Chapter 1, Problem 1.47PChapter 1, Problem 1.48PChapter 2, Problem 2.1EPChapter 2, Problem 2.1TYUChapter 2, Problem 2.3PChapter 2, Problem 2.24PChapter 2, Problem D2.25PChapter 2, Problem 2.45PChapter 2, Problem 2.47PChapter 2, Problem 2.51PChapter 2, Problem 2.52PChapter 2, Problem 2.57PChapter 2, Problem 2.59PChapter 2, Problem 2.62PChapter 3, Problem 3.1EPChapter 3, Problem 3.2TYUChapter 3, Problem 3.5EPChapter 3, Problem 3.8EPChapter 3, Problem 3.1PChapter 3, Problem 3.4PChapter 3, Problem 3.3CAEChapter 3, Problem 3.4CAEChapter 3, Problem 3.17PChapter 3, Problem 3.27PChapter 3, Problem 3.29PGiven Information: The given values are: VTN=1.4 V, Kn=0.25 mA/V2, IDQ=0.5 mA, VD=1 V The given...Given Information: The given circuit is shown below. VTN=0.4 V, kn'=120 μAV2( W L)1=( W L)2=30...Given Information: The given values are: VTN=0.6 V, kn'=120 μA/V2, IDQ=0.8 mA, V1=2.5 V, V2=6 V The...Given information: The given values are IDQ=0.8mAVTN=0.6Vkn'=100μA/V2=0.1mA/V2gm=1.8mA/V...Chapter 4, Problem 4.2EPChapter 4, Problem 4.3EPChapter 4, Problem 4.4EPChapter 4, Problem 4.8EPChapter 4, Problem 4.9EPChapter 4, Problem 4.12TYUChapter 4, Problem 4.40PChapter 4, Problem 4.66PChapter 4, Problem 4.67PChapter 4, Problem 4.70PChapter 4, Problem 4.71PChapter 4, Problem 4.78PChapter 5, Problem 5.1EPChapter 5, Problem 5.9EPChapter 5, Problem D5.31PChapter 5, Problem 5.32PChapter 5, Problem 5.42PChapter 5, Problem 5.52PGiven: The circuit is given as: Assume β=100 . Redrawing the given circuit by replacing voltage...Chapter 5, Problem 5.57PChapter 5, Problem 5.58PChapter 5, Problem D5.59PChapter 5, Problem D5.62PChapter 5, Problem 5.79PChapter 5, Problem 5.82PChapter 5, Problem D5.89DPChapter 5, Problem D5.91DPChapter 6, Problem 6.1EPGiven: Given circuit: Given Data: β=120VA=∞VBE(on)=0.7V Calculation: Considering the BJT (Bipolar...Given Information: The circuit diagram is shown below. β=120, VBE(on)=0.7 V, VA=∞VCC=VEE=3.3 V,...Chapter 6, Problem 6.16TYUChapter 6, Problem 6.19PChapter 6, Problem 6.26PChapter 6, Problem 6.45PChapter 6, Problem 6.51PChapter 6, Problem 6.52PChapter 6, Problem 6.54PChapter 6, Problem 6.83PChapter 7, Problem 7.1EPChapter 7, Problem 7.10EPChapter 7, Problem 7.21PChapter 7, Problem 7.23PChapter 7, Problem 7.32PChapter 7, Problem 7.40PChapter 7, Problem 7.41PChapter 7, Problem 7.49PChapter 7, Problem 7.50PChapter 7, Problem 7.69PChapter 7, Problem 7.70PCalculation: The expression for the collector to the emitter load line is given by, VCE=VCC−ICRC The...Calculation: The given diagram is shown in Figure 1 The conversion from 1 mA into A is given by, 1...Calculation: The sketch for the safe operating area of the transistor is shown below. The required...Calculation: The given diagram is shown in Figure 1 The expression for the maximum value of the...Calculation: The given diagram is shown in Figure 1 The conversion from 1 mA into A is given by, 1...Calculation: The given diagram is shown in Figure 1 The diagram for the class AB output stage using...Calculation: The given diagram is shown in Figure 1. The expression for the value of base current of...Chapter 8, Problem 8.48PChapter 8, Problem 8.49PChapter 9, Problem 9.1EPChapter 9, Problem 9.9EPChapter 9, Problem 9.6PChapter 9, Problem 9.13PChapter 9, Problem 9.14PChapter 9, Problem D9.18PChapter 9, Problem 9.51PChapter 9, Problem 9.62PChapter 9, Problem 9.63PChapter 9, Problem 9.65PChapter 9, Problem 9.67PChapter 9, Problem 9.72PChapter 9, Problem 9.81PChapter 10, Problem 10.1EPChapter 10, Problem 10.6TYUGiven: The circuit parameters are V+=+5VV−=0 The transistor parameters are...Chapter 10, Problem 10.56PGiven: VTN=0.4VVTP=−0.4VK'n=100μA/V2K'p=60μA/V2λn=λp=0 (W/L) 1 = (W/L) 2 =20 (W/L) 3 =5 (W/L) 4 =10...Chapter 10, Problem 10.63PGiven: VTN=0.5VVTP=−0.5V(1/2)μnCox=50μA/V2(1/2)μpCox=20μA/V2λn=λp=0 (W/L) 1 = (W/L) 3 = (W/L) 4 =5/1...Chapter 10, Problem 10.68PGiven: VTN=0.8VVTP=−0.8VK'n=100μA/V2K'P=60μA/V2λn=λp=0R=100kΩ Calculation: The given circuit is,...Chapter 10, Problem 10.76PGiven: R1=47kΩVAN=120VVAP=90VV+=3VVEB(on)=0.6V Calculation: The given circuit is, The transistor Q1...Chapter 10, Problem 10.83PChapter 10, Problem 10.89PChapter 10, Problem D10.90PChapter 11, Problem 11.1EPGiven: The given circuit is, V+=+5V ,V−=−5V,RD=1kΩ ,RS=2kΩ,VTP=−0.6V,Kp=1.2mA/V2,λ=0 v1=v2=0...Given: The given circuit is, V+=+5V ,V−=−5V,RD=25kΩ...Given: The given circuit is shown in Figure 1 Figure 1 Calculation: The expression for the current...Chapter 11, Problem 11.62PChapter 11, Problem 11.68PGiven: The given diagram is shown in Figure 1 Figure 1 Calculation: The expression for the input...Given: The given circuit is shown in Figure 1 Figure 1 Calculation: The expression for the input...Given: The given diagram is shown in Figure 1 Figure 1 Calculation: The expression to determine the...Chapter 11, Problem 11.82PGiven: The given circuit is, IQ=25μA,β=100 VA=50V,VTN=0.8V,Kn=0.25mA/V2,λ=0.02V−1 The two amplifying...Given: The circuit is given as: The circuit parameters:...Chapter 11, Problem 11.90PGiven: The given circuit is, β=200,VBE(on)=0.7V,VA=80V Calculation: Consider the given figure,...Chapter 11, Problem 11.93PChapter 11, Problem D11.105DPChapter 12, Problem 12.1EPGiven: The given diagram is shown in Figure 1 Figure 1 Calculation: Mark the nodes and redraw the...Given: The given diagram is shown in Figure 1 Figure 1 Feedback resistor value is varied between 5...Chapter 12, Problem 12.11TYUGiven: The give circuit is shown in Figure 1 Calculation: The value of the collector current of the...Chapter 12, Problem 12.37PChapter 12, Problem 12.38PGiven: The given values are: V+=5 VVGG=2.5 VRD1=5 kΩRE2=1.6 kΩRL=1.2 kΩKn=1.5(mAV2)VTN=0.5...Given: The given circuit is shown in Figure 1. Calculation: The Thevenin resistance of the above...Given: The given diagram is shown in Figure 1 Calculation: The expression to determine the value of...Chapter 12, Problem 12.49PChapter 12, Problem 12.50PChapter 12, Problem 12.53PGiven: The given circuit is shown in Figure 1 Figure 1 Calculation: The small signal equivalent...Chapter 12, Problem 12.77PChapter 12, Problem 12.80PGiven: The bias circuit and input stage portion of 741 op-amp circuit is shown below. Figure 1...Given: Following is given circuit of the MC14573 op-amp equivalent circuit Given data, The...Given: The circuit diagram of the BJT op-amp is Given that The transistor parameters are, β(npn)=120...Given: Circuit is given as; V+=3 V,V−=−3 V,R1=80 kΩ,RE=3.5 kΩ Current for transistors Q1,Q2 and Q3...Given: Consider the 741 op-amp having bias voltage ±5 V Calculation: The reference current is....Given: Consider the 741 op-amp having bias voltage ±5 V Calculation: The early voltage given as...Given: Consider the 741 op-amp having bias voltage ±5 V Calculation: The resistance at Q14 can be...Chapter 14, Problem 14.1TYUGiven: Given bipolar active load diff-amp is, Given parameters are: V+=5V V−=−5V The transistor...Chapter 14, Problem 14.38PGiven: Bipolar diff-amp with active load and a pair of offset-null terminal is shown below. Given...Given: The given circuit is: IB1=IB2=1 μA and vI=0 As vI=0 , the modified circuit is; For first...Given: The given circuit is: Input bias current IB=0.8 μA Input offset current IOS=0.2 μA R1=R2=50...Given: The given circuit is shown below. Input offset voltage is VOS=3 mV Average input bias current...Given: The given circuit is shown below. Input offset voltage V0S=2 mV at T=25°C Average input bias...Chapter 14, Problem 14.60PGiven: The given difference amplifier circuit is, Tolerance of each resistor is ±x% . Minimum CMRRdB...Chapter 15, Problem 15.1EPGiven: Circuit diagram for voltage regulator is shown below. The voltage of Zener diode Vz=5.6 V...Given: Calculation: Redraw the given circuit in s -domain as From the circuit,...Given: The circuit is given as: The circuit is redrawn by labeling the voltages as shown below:...Given: Consider the circuit shown below. Calculation: The non-inverting terminal of op-amp is...Given: The circuit is given for the phase shift oscillator: Redrawing the given circuit Nodal...Given: The circuit for the Hartley oscillator is given as: Transconductance, gm=30mA/VForward biased...Given: The circuit is given as: For the ideal operation amplifier, the inverting and non-inverting...Chapter 15, Problem 15.46PChapter 15, Problem 15.47PChapter 15, Problem 15.49PGiven: The circuit is given as: For the ideal operational amplifier, the currents in the inverting...Given: Given LM380 power amplifier circuit as V+=22Vβn=100βp=20 Calculation: Assuming matched input...Chapter 16, Problem 16.1EPGiven: Power supply voltage, VDD=3V Intrinsic trans conductance parameter, kn'=100×10−6A/V2 Device...Chapter 16, Problem 16.9EPGiven: The given circuit is shown below. The parameters are: VDD=3.3 VKn=50 μA/V2RD=100 kΩvI=3.3...Calculation: The given diagram is shown in Figure 1. The expression for the voltage VOH is given by,...Calculation: The given diagram is shown in Figure 1 The expression to determine the power dissipated...Calculation: The given diagram is shown in Figure 1 The expression to determine the...Calculation: The given diagram is shown in Figure 1 The expression to determine the...Calculation: The given diagram is shown in Figure 1. Consider the case when the input voltage is...Calculation: The expression to determine the value of the KN is given by, KN=k′n2(WL)n Substitute 80...Calculation: The expression to determine the value of the KN is given by, KN=k′n2(WL)n Substitute...Calculation: Consider the case when the input voltage is, vI=VDD The expression for the conduction...Calculation: The expression to determine the value of the KN is given by, KN=k′n2(WL)n Substitute...Calculation: The given diagram is shown in Figure 1 The given table is shown in Table 1 Table 1...Given: The given diagram is shown in Figure 1. Calculation: The expression to determine the...Calculation: The given diagram is shown in Figure 1 The expression to determine the analog output...Chapter 17, Problem 17.1EPCalculation: The given diagram is shown in Figure 1 The redesign circuit is shown below. The...Chapter 17, Problem 17.9EPCalculation: The given diagram is shown in Figure 1 Apply KVL in the above circuit. 5 V=iC(2.25...Calculation: The given diagram is shown in Figure 1 The expression to determine the value of the...Calculation: The given diagram is shown in Figure 1 Mark the currents and redraw the circuit. The...Calculation: The given diagram is shown in Figure 1. The expression for the current i1 is given by,...Calculation: The given diagram is shown in Figure 1 The expression for the voltage vB1 is given by,...
More Editions of This Book
Corresponding editions of this textbook are also available below:
Microelectronics: Circuit Analysis And Design
3rd Edition
ISBN: 9780071254434
Microelectronics Circuit Analysis and Design
4th Edition
ISBN: 9780071289474
MICROELECTRONICS CIRCUIT PACKAGE
4th Edition
ISBN: 9780078007972
Microelectronics Circuit Analysis and Design
4th Edition
ISBN: 9780077387815
Microelectronics: Circuit Analysis and Design
4th Edition
ISBN: 9780073380643
Related Electrical Engineering Textbooks with Solutions
Still sussing out bartleby
Check out a sample textbook solution.
