6. Build the circuit shown in Figure 2 below in PSpice. Note that the power supply V1 is aVSIN power supply in the SOURCE library. Vcc is a VDC supply found in the SOURCElibrary. Model this circuit using the Time Domain (Transient) Analysis Type with a Run ToTime of 2 ms.A. Paste your output graph showing the voltage at the base terminal, collector terminaland at the load.B. What is the voltage gain of the circuit? (Compare the voltage amplitude at the baseterminal input (across Rb2) to that at the collector terminal.C. What happens to the output voltage at the collector terminal if the value of Rb1 isreduced by a factor of 10 (to 14.7 kn)? Simulate this situation and explain the result.D. What happens to the output voltage at the collector terminal if the value of Rb1 isincreased by a factor of 3 (to 441 k)? Simulate this situation and explain the result.Rb1RC147k1kC2C1Q1Vcc1uVOFF = 0Q2N390410VdcVAMPL = 0.1V11uFREQ = 2kR_loadRb2ReAC = 025040k20Figure 2. A single BJT amplifier.

Answered: Image /qna-images/answer/cdb17ac0-c1bf-4cdc-9b04-0fa16d832049.jpg

Answered: 6. Build the circuit shown in Figure 2…

Introductory Circuit Analysis (13th Edition)

13th Edition

ISBN:9780133923605

Author:Robert L. Boylestad

Publisher:Robert L. Boylestad

Chapter1: Introduction

Section: Chapter Questions

Problem 1P: Visit your local library (at school or home) and describe the extent to which it provides literature...

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Set up a midpoint bias for a JFET with IDSS = 14 mA and VGS(off) = -10 V. Use a 24 V dc source as the supply voltage. Show the circuit and resistor values. Indicate the value of ID. Indicate the value of VGS. Indicate the value of VDS.
1. The DC-DC converter has several circuit configurations. a) (Draw a simple connection of IGBT switch, diode and inductor that can discriminate between Buck, Boost and Buck-Boost converter circuits respectively.) b) ('A Boost converter produces an output voltage, Vo that is more than or equal to the input voltage, Vi. Based on this statement develop the equation for the relationship between Vo Viand D. where D represents the duty ratio. You can use any suitable diagram to illustrate your answer.)
The small-signal model is said to be valid for voltage variations of about 5 mV. To what percentage current change does this correspond? (Consider both positive and negative signals.) What is the maximum allowable voltage signal (positive or negative) if the current change is to be limited to 10%?
(a) What is the output current IO in the circuitshown if −VEE = −10 V andR = 20 ohm? Assume that the MOSFET is saturated.(b) What is the minimum voltage VDDneeded to saturate the MOSFET if VTN = 2.5 Vand K'n = 0.25 A/V2. (c) What must be the powerdissipation ratings of resistor R and the FET.
4) Consider the clamping circuit below, assume Vref=3 V and Vin=5sin(wt) ..Draw the output voltage waveform. Clearly mark the max and min of the voltage.. Vref
Determine VB, VE, VC, VCE, IB, IE, and IC in Figure. The 2N3904 is a general purpose transistor with a typical BDC 200 Vcc +30 V WWII VCE VB R₁ • 22 ΚΩ IC(mA) Chọn... * Chọn... * IB(UA) Chọn... * IE(MA) Chọn... ◆ Chọn... * Chọn... * Chọn... * VE VC R₂ ´ 10 ΚΩ www Rc 1.0 ΚΩ 2N3904 PDC=200 RE 1.0 ΚΩ
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5, a) Determine Vdsat when ID=.5 mA. b) Determine Kn when ID = 0.5 Amps. (Show your work!) c) Determine VTN. (Show your work!) d) Vgs Consider the circuit and corresponding graph, shown below. ID (mA) 0.60 0.50 0.40 0.30 0.20 0.10 0.00 0 0.5 Vds 1 1.5 2 2.5 Vds 3 3.5 4 4.5 5 -Vgs = 1V - Vgs = 1.1V - Vgs = 1.2V - Vgs = 1.3V
IDSS=8mA , VP =-4VTo help plot the DC load line VGS=VG-IDRSa)Attach a Plot of JFET Characteristic Curve as shown in Figureb)What is the approximate VGSQ?c)What is the approximate IDQ in mA?d)Determine source voltage VS.e)Calculate the drain voltage VD.f)Calculate the drain-to-source voltage VDS.
Open with v Consider class-A emitter follower circuit shown in the figure below. The circuit parameters are V+ = 24 V, V- = -24 V, and RL = 2000. The transistor parameters are B = 50, VBElon) = 0.7 V, and VCElsat) = 0.2 V. The output voltage is to vary between +20 V and -20 V. The minimum current in Q1 is to be ie1 = 20 mA. For vo = 0, find the power dissipated in the first transistor Q1- V+
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