A transistor has these parameters: Vbe(on) = 0.6 V, V ce(Sat) = 0.2 V, and ß = 100.The transistor is biased such that Vcc = 8 V, Rc = 2 kn, Rb = 20 kỵa. Calculate the maximum possible collector current, ic(MAX).b. Suppose ig = 0 such that ic = 0. What is the value of thecollector-emitter voltage VCE?c. Suppose ip = 10 µA. What is the value of the collector-emitter voltage VCE?d. Suppose ig = 2 mA. What is the value of the collector-emitter voltage VCE?RbVBERc+VCEVcc

As per the guidelines of bartleby i need to answer first three subparts only so kindly repost other…

Answered: A transistor has these parameters:…

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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Vec +12V Re 1kS2 Re 470k2 BC107 Vc Ve Figure 3: Practical Fixed Bias Transistor Circuit 2. Measure the DC voltages Vc and VB using digital multi-meters. Determine the quiescent base current, collector current, and collector- emitter voltage.
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%3D = 13 volts, Rg = 500 KN, Rc = 6 KN and ß = 120. Assume Transistor is Silicon, VBE=0.7v. For the given circuit, Vcc +Vcc Rc RB VCE V BE a Compute for the base current Q-point, IBq (in Amperes): b. Compute for the collector current Q-point, Ico (in Amperes): c. Compute for the collector-to-emitter voltage, VCEQ (in Volts): d. Draw the DC load line with the axes and the points labeled.
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Question: 8. With the emitter bias shown, a reasonable assumption for troubleshooting work is that the VcC a. base voltage =+1 V +15 V b. emitter voltage = +5 V RC 3.9 k2 c. emitter voltage =-1 V d. collector voltage = Vcc RB 68 kQ %3D RE 7.5 kQ VEE -15 V
A common- configuration has the input at the base and the output iat the collector. base emitter collector
%3D For the circuit shown in Figure B23, a = 0.97, calculate the following: i. Collector current (Ic) ii. Collector-Base voltage (VCB) iii. Emitter Current (IE) iv. Base Current (IB) IE Ic 2.5 k2 Ouput 2.8V IB 10V VEE Vcc Figure B23
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A certain npn silicon transistor has vBE=0.7 V for iB=0.1 mA at a temperature of 30°C. Sketch the input characteristic to scale at 30°C. What is the approximate value of vBE for iB = 0.1 mA at 180°C? (Use the rule of thumb that vBE is reduced in magnitude by 2 mV per degree increase in temperature.) Sketch the input characteristic to scale at 180°C.
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USE APPROXIMATE ANALYSIS USE 2 decimal places, no commas. Given: Single-stage, voltage-divider biased, common-emitter with 1. VCC = 14V 2. R1 = 37kohms 3. R2 = 10kohms 4. RC = 4kohms 5. RE = 1kohms 6. RS = 6ohms 7. RL = 2kohms 8. BDC = BAC = 144 9. ** 10.C, andcz are coupling capacitors. 11.C3 is bypass capacitor 12. 13.Solve for: a. VB = Blank 1 V: b. VE = Blank 2 V: C. IE = Blank 3 mA ; d. VCE = Blank 4 V; e. VC = Blank 5 V: f. re' = Blank 6 ohms: 8. Rin(base) = Blank 7 kohms ; h. Rin(tot) = Blank 8 kohms : i. Voltage gain (Av) = Blank 9; j. Attenuation (Att) = Blank 10; k. Overall voltage gain (AVT) = Blank 11: %3D

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