Microelectronics: Circuit Analysis and Design
4th Edition
ISBN: 9780073380643
Author: Donald A. Neamen
Publisher: McGraw-Hill Companies, The
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Textbook Question
Chapter 2, Problem 2.11EP
Repeat Example 2.11 for the case when
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The circuit of Figure.1 is to pass a 10KHz current with minimum impedance and to block a 20KHz current as effectively as possible. Here, R0 =2*R Ω, R1=R Ω, C2=0.03 µF are fixed. (Here, R= 62).
1. After finding the desired value of L1 and L0 or C0 for the circuit given in Figure.1 at terminal ab if, Vin=100sin (100πt+60˚) V,
Compute Zeq seen from a-b terminal.
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S2.2 Which of the following Common Source Amplifier's generalone of its features.A) The voltage gain of the circuit is always less than 1.B) There is no phase difference between the output signal and the input signal of the circuit.C) There is a phase difference of 1800 between the output signal and the input signal of the circuit.D) The voltage gain of the circuit is always less than 1.
1. Which of the following statements is true?a. Terminal A is negative with respect to terminal D.b. Terminal D is negative with respect to terminal A.c. A voltmeter connected between terminals A and C would measure 40Vdc.d. Terminal A is positive with respect to terminal D.2. Which of the following statements is true?a. ES = ER1 – ER2 – ER3b. ER1 – ER2 – ER3 = 100Vdcc. ES = ER1 + ER2 + 30 Vdcd. ER1 + ER2 + ER3 = ES3. What is the value of resistor R1?a. 5000 Ωb. 1500 Ωc. 3000 Ωd. 10 000 Ω
4. What is the voltage drop between points A and B?a. 45 Vdcb. 15 Vdcc. 10 Vdcd. 60 Vdc
5. What is the voltage drop between points B and C?a. 5 Vdcb. 15 Vdcc. 10 Vdcd. 7.5 Vdc6. What is the value of resistor R2?a. 500 Ωb. 1000 Ωc. 1500 Ωd. 3000 Ω7. Refer to TLO 4, Fig. 4-3 and Exercise Procedure 4. What is the approximatedresistance of DS1 when lighted?a. 35 Ωb. 75 Ωc. 42 Ωd. 100 Ω
5. What is the voltage drop between points B and C?a. 5 Vdcb. 15 Vdcc. 10 Vdcd. 7.5 Vdc6. What is the value of resistor…
Chapter 2 Solutions
Microelectronics: Circuit Analysis and Design
Ch. 2 - Repeat Example 2.1 if the input voltage is...Ch. 2 - Consider the bridge circuit shown in Figure 2.6(a)...Ch. 2 - Assume the input signal to a rectifier circuit has...Ch. 2 - The input voltage to the halfwave rectifier in...Ch. 2 - Consider the circuit in Figure 2.4. The input...Ch. 2 - The circuit in Figure 2.5(a) is used to rectify a...Ch. 2 - The secondary transformer voltage of the rectifier...Ch. 2 - Determine the fraction (percent) of the cycle that...Ch. 2 - The Zener diode regulator circuit shown in Figure...Ch. 2 - Repeat Example 2.6 for rz=4 . Assume all other...
Ch. 2 - Consider the circuit shown in Figure 2.19. Let...Ch. 2 - Suppose the currentlimiting resistor in Example...Ch. 2 - Suppose the power supply voltage in the circuit...Ch. 2 - Design a parallelbased clipper that will yield the...Ch. 2 - Sketch the steadystate output voltage for the...Ch. 2 - Consider the circuit in Figure 2.23(a). Let R1=5k...Ch. 2 - Determine the steadystate output voltage O for the...Ch. 2 - Design a parallelbased clipper circuit that will...Ch. 2 - Consider the circuit shown in Figure 2.38, in...Ch. 2 - Consider the circuit shown in Figure 2.39. The...Ch. 2 - Repeat Example 2.11 for the case when R1=8k ,...Ch. 2 - The cutin voltage of each diode in the circuit...Ch. 2 - Prob. 2.12TYUCh. 2 - Consider the OR logic circuit shown in Figure...Ch. 2 - Consider the AND logic circuit shown in Figure...Ch. 2 - (a) Photons with an energy of hv=2eV are incident...Ch. 2 - Determine the value of resistance R required to...Ch. 2 - What characteristic of a diode is used in the...Ch. 2 - Prob. 2RQCh. 2 - Describe a simple fullwave diode rectifier circuit...Ch. 2 - Prob. 4RQCh. 2 - Prob. 5RQCh. 2 - Describe a simple Zener diode voltage reference...Ch. 2 - What effect does the Zener diode resistance have...Ch. 2 - What are the general characteristics of diode...Ch. 2 - Describe a simple diode clipper circuit that...Ch. 2 - Prob. 10RQCh. 2 - What one circuit element, besides a diode, is...Ch. 2 - Prob. 12RQCh. 2 - Describe a diode OR logic circuit. Compare a logic...Ch. 2 - Describe a diode AND logic circuit. Compare a...Ch. 2 - Describe a simple circuit that can be used to turn...Ch. 2 - Consider the circuit shown in Figure P2.1. Let...Ch. 2 - For the circuit shown in Figure P2.1, show that...Ch. 2 - A halfwave rectifier such as shown in Figure...Ch. 2 - Consider the battery charging circuit shown in...Ch. 2 - Figure P2.5 shows a simple fullwave battery...Ch. 2 - The fullwave rectifier circuit shown in Figure...Ch. 2 - The input signal voltage to the fullwave rectifier...Ch. 2 - The output resistance of the fullwave rectifier in...Ch. 2 - Repeat Problem 2.8 for the halfwave rectifier in...Ch. 2 - Consider the halfwave rectifier circuit shown in...Ch. 2 - The parameters of the halfwave rectifier circuit...Ch. 2 - The fullwave rectifier circuit shown in Figure...Ch. 2 - Consider the fullwave rectifier circuit in Figure...Ch. 2 - The circuit in Figure P2.14 is a complementary...Ch. 2 - Prob. 2.15PCh. 2 - A fullwave rectifier is to be designed using the...Ch. 2 - Prob. 2.17PCh. 2 - (a) Sketch o versus time for the circuit in Figure...Ch. 2 - Consider the circuit shown in Figure P2.19. The...Ch. 2 - Consider the Zener diode circuit shown in Figure...Ch. 2 - Consider the Zener diode circuit shown in Figure...Ch. 2 - In the voltage regulator circuit in Figure P2.21,...Ch. 2 - A Zener diode is connected in a voltage regulator...Ch. 2 - Consider the Zener diode circuit in Figure 2.19 in...Ch. 2 - Design a voltage regulator circuit such as shown...Ch. 2 - The percent regulation of the Zener diode...Ch. 2 - A voltage regulator is to have a nominal output...Ch. 2 - Consider the circuit in Figure P2.28. Let V=0 ....Ch. 2 - The secondary voltage in the circuit in Figure...Ch. 2 - The parameters in the circuit shown in Figure...Ch. 2 - Consider the circuit in Figure P2.31. Let V=0 (a)...Ch. 2 - Prob. 2.32PCh. 2 - Each diode cutin voltage is 0.7 V for the circuits...Ch. 2 - The diode in the circuit of Figure P2.34(a) has...Ch. 2 - Consider the circuits shown in Figure P2.35. Each...Ch. 2 - Plot O for each circuit in Figure P2.36 for the...Ch. 2 - Consider the parallel clipper circuit in Figure...Ch. 2 - A car’s radio may be subjected to voltage spikes...Ch. 2 - Sketch the steadystate output voltage O versus...Ch. 2 - Prob. D2.40PCh. 2 - Design a diode clamper to generate a steadystate...Ch. 2 - For the circuit in Figure P2.39(b), let V=0 and...Ch. 2 - Repeat Problem 2.42 for the circuit in Figure...Ch. 2 - The diodes in the circuit in Figure P2.44 have...Ch. 2 - In the circuit in Figure P2.45 the diodes have the...Ch. 2 - The diodes in the circuit in Figure P2.46 have the...Ch. 2 - Consider the circuit shown in Figure P2.47. Assume...Ch. 2 - The diode cutin voltage for each diode in the...Ch. 2 - Consider the circuit in Figure P2.49. Each diode...Ch. 2 - Assume V=0.7V for each diode in the circuit in...Ch. 2 - The cutin voltage of each diode in the circuit...Ch. 2 - Let V=0.7V for each diode in the circuit in Figure...Ch. 2 - For the circuit shown in Figure P2.54, let V=0.7V...Ch. 2 - Assume each diode cutin voltage is V=0.7V for the...Ch. 2 - If V=0.7V for the diode in the circuit in Figure...Ch. 2 - Let V=0.7V for the diode in the circuit in Figure...Ch. 2 - Each diode cutin voltage in the circuit in Figure...Ch. 2 - Let V=0.7V for each diode in the circuit shown in...Ch. 2 - Consider the circuit in Figure P2.61. The output...Ch. 2 - Consider the circuit in Figure P2.62. The output...Ch. 2 - Prob. 2.63PCh. 2 - Consider the circuit shown in Figure P2.64. The...Ch. 2 - The lightemitting diode in the circuit shown in...Ch. 2 - The parameters of D1 and D2 in the circuit shown...Ch. 2 - If the resistor in Example 2.12 is R=2 and the...Ch. 2 - Consider the photodiode circuit shown in Figure...Ch. 2 - Consider the fullwave bridge rectifier circuit....Ch. 2 - Design a simple dc voltage source using a...Ch. 2 - A clipper is to be designed such that O=2.5V for...Ch. 2 - Design a circuit to provide the voltage transfer...
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- 1. Which of the following statements is true?a. Terminal A is negative with respect to terminal D.b. Terminal D is negative with respect to terminal A.c. A voltmeter connected between terminals A and C would measure 40Vdc.d. Terminal A is positive with respect to terminal D.2. Which of the following statements is true?a. ES = ER1 – ER2 – ER3b. ER1 – ER2 – ER3 = 100Vdcc. ES = ER1 + ER2 + 30 Vdcd. ER1 + ER2 + ER3 = ES3. What is the value of resistor R1?a. 5000 Ωb. 1500 Ωc. 3000 Ωd. 10 000 Ω 4. What is the voltage drop between points A and B?a. 45 Vdcb. 15 Vdcc. 10 Vdcd. 60 Vdc 5. What is the voltage drop between points B and C?a. 5 Vdcb. 15 Vdcc. 10 Vdcd. 7.5 Vdc6. What is the value of resistor R2?a. 500 Ωb. 1000 Ωc. 1500 Ωd. 3000 Ω7. Refer to TLO 4, Fig. 4-3 and Exercise Procedure 4. What is the approximatedresistance of DS1 when lighted?a. 35 Ωb. 75 Ωc. 42 Ωd. 100 Ω 5. What is the voltage drop between points B and C?a. 5 Vdcb. 15 Vdcc. 10 Vdcd. 7.5 Vdc6. What is the value of resistor…arrow_forward1. Which of the following statements is true?a. Terminal A is negative with respect to terminal D.b. Terminal D is negative with respect to terminal A.c. A voltmeter connected between terminals A and C would measure 40Vdc.d. Terminal A is positive with respect to terminal D.2. Which of the following statements is true?a. ES = ER1 – ER2 – ER3b. ER1 – ER2 – ER3 = 100Vdcc. ES = ER1 + ER2 + 30 Vdcd. ER1 + ER2 + ER3 = ES3. What is the value of resistor R1?a. 5000 Ωb. 1500 Ωc. 3000 Ωd. 10 000 Ω 4. What is the voltage drop between points A and B?a. 45 Vdcb. 15 Vdcc. 10 Vdcd. 60 Vdc 5. What is the voltage drop between points B and C?a. 5 Vdcb. 15 Vdcc. 10 Vdcd. 7.5 Vdc6. What is the value of resistor R2?a. 500 Ωb. 1000 Ωc. 1500 Ωd. 3000 Ω7. Refer to TLO 4, Fig. 4-3 and Exercise Procedure 4. What is the approximatedresistance of DS1 when lighted?a. 35 Ωb. 75 Ωc. 42 Ωd. 100 Ω 5. What is the voltage drop between points B and C?a. 5 Vdcb. 15 Vdcc. 10 Vdcd. 7.5 Vdc6. What is the value of resistor…arrow_forwardCalculate the output voltage using the circuit shown. For the resistor components value Rf= 470k ohms, R1 = 4.3k ohms, R2 = 33k ohms, R3 = 33k ohms. For an imput of 80 microV.arrow_forward
- By using DFT method, compute the convolution process of y(n)=x(n)*h(n). The value of x(n) and h(n)are as follows.h(n)=[ 2,4,6,8]x(n)=[5,1,8,1]Show your calculation in details. dont skip/simplify any methodarrow_forwardConsider the circuit shown in Figure 1. Vcc= +12 V (DC), R1 = 100KΩ, R2 = 10 KΩ, RE = 1KΩ and RL = 2.2 KΩ. Assume β = 100 Calculate IE, IC, IB, VE, VC, VBarrow_forwardTHE CHOICES: 52 500 VA 62 500 VA 72 500 VA 42 500 VAarrow_forward
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- MESH ANALYSIS ( NEED NEAT HANDWRITTEN SOLUTION AND EXPLANATION OTHERWISE DOWNVOTE).arrow_forwardPerform the following steps for the given circuit in below.RD = RS = 1kΩ, R1 = 300kΩ, R2 = 100kΩ, VDD = +12V, IDSS = 12mA, VP = -4Va) Calculate the ID current, VDS and VGS voltage and determine the region of operationfor the JFET. (Hint: Use Thevenin’s Theorem)arrow_forwardThe AC Bridge shown below is used to measure an unknown inductance, Lx and its internal resistance, Rx. The Bridge parameters are R1 = 20,000 ohms, R2 = 50,000 ohms, C2 = 0.003 µf, w = 105 radians per sec. C1 is adjustable from 10 pf to 150 pf, and R3 is adjustable from 0 to 10,000 ohms. At Balance, I. Derive expressions for Rx and Lx in terms of w, R1, R2, R3, C1, and C2. II. Determine the largest values of Rx and Lx that are measurable with the given parameters.arrow_forward
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