Consider only the coupling and by-pass capacitors in the following circuit. (No parasitic capacitor effects) - +Vcc Rc3.9k2 Rp. 1MQ +V Ce2 RL 6.2 Rg. Vg RE For the BJT, B=200 (Vr=25.9mV) (You will not need value of Vcc) Assume Ic=1.2mA for DC. Magnitude response of A,(s)=Vo/Vg is plotted partly below. 40 9 30 20 10 0- - 10 -20 -30 -40 101 102 frequency 103 104 105 [Hz] Examine the curve to determine important gain, frequency and slope values to answer the following: a) Calculate the value of R, (Hint; Use medium frequency AC gain). b) Determine low-frequency poles and/or zero of A,(s)=vo/Vg to calculate values of Ce1, C2 and CĘ. c) Complete the magnitude response curve of A,(5)=v/vg. Indicate important gain, frequency and slope values on your curve. (Redraw the curve roughly on a paper by showing the missing part as well) IMPORIANT: BELOW you should upload photo(s) of your solution notes for THIS problem (If you upload it somewhere else, it will not be valid). 20 log |Av [dB]

Consider only the coupling and by-pass capacitors in the following circuit. (No parasitic capacitor effects) - +Vcc Rc3.9k2 Rp. 1MQ +V Ce2 RL 6.2 Rg. Vg RE For the BJT, B=200 (Vr=25.9mV) (You will not need value of Vcc) Assume Ic=1.2mA for DC. Magnitude response of A,(s)=Vo/Vg is plotted partly below. 40 9 30 20 10 0- - 10 -20 -30 -40 101 102 frequency 103 104 105 [Hz] Examine the curve to determine important gain, frequency and slope values to answer the following: a) Calculate the value of R, (Hint; Use medium frequency AC gain). b) Determine low-frequency poles and/or zero of A,(s)=vo/Vg to calculate values of Ce1, C2 and CĘ. c) Complete the magnitude response curve of A,(5)=v/vg. Indicate important gain, frequency and slope values on your curve. (Redraw the curve roughly on a paper by showing the missing part as well) IMPORIANT: BELOW you should upload photo(s) of your solution notes for THIS problem (If you upload it somewhere else, it will not be valid). 20 log |Av [dB]

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...

See similar textbooks

Similar questions

In a RC type low pass fitter, the cut- off frequency is 1500 Hz, Assuming the capacitance to be 500 nF. The value of the resistance is - (in Q2)
I want answer (ii)
For circuit shown in the figure with Voc=9 V, Rg=354 kn, Rc=409 0, RE=2.6 kn, B=117, VeE=0.7 V, determine S(lo). Vcc Rc RB Vc |VCE oVE emitter bias configuration Lütfen birini seçin: a.63.38 b.71.86 c.61.96 d.37.75 e.56.97
(please solve by hand)
(7 (6) Find the low frequency response by determining poles due to each coupling and hypass capacitor (CE, Cin & Cont). Ignore to for the BJT. 2/5 + Ps M Cin Vcr R₂ Vcc T R₂ Cont " ERL Vout
For a series RLC circuit with a sinusoidal input voltage, the amplitude of the current passing through the circuit (lo in mA) is plotted as a function of frequency for two cases: Curve 1 with R1, L1, and Curve 2 with R2. L2 as shown in the next figure. The value of the capacitor used in the circuits is C=0.01 micro Farads. The quality factor (Q1) for curve 1 is about: 7.5 5- 2.5 1-10 1-10 1-10 1-10 Frequency (f), Hz O a. 20000 Hz O b. 0.5 O c. 0.23 O d. 2 O e. 1.5
3. A resistive source of 750 with frequency of 0.5GHZ needs to match a 75N resistive load that is in series with a 1.62pF capacitance. Design with the aim of a diagram a matching circuit for this problem.
In a series RLC circuit, the applied voltage is 120V. At resonance, the frequency is 200rad/sec, and the circuit current is 6.26 A. What is the resistance of the circuit (in Ohms)? (Use 2 decimal places. Unit is not required.)
Q3- For the figure shown the initial capacitor voltage V,-300V, capacitance C-1 uF, R-1000 and inductance L-SmH. Drive the expresion for the capacitor voltage (V1). Determine the peak value of resonant current and the conduction time of thyristor T. (Assume the initial voltage across capacitor is zero as also the initial current throngh L) V,(0) R Load
If vsig is a triangle waveform, determine the maximum amplitude that vsig can have? Showyour calculation.
Use the image below to help answers parts a and b.in an LRC type circuit series the inductive reactance is XL=484 ohms. and I=0.8 amps is the measured current amplitude.A) In the inductor determine the amplitude of the voltage.B)If the LRC circuit is at resonance frequency find the capacitive reactance.
Consider the circuit shown below: +Vcc RC SR, BDc RE Solve for VC in Volts given that: RC=0.31kOhms RE=1.08kOhms R1=2.55kOhms R2=4.27kOhms VCC=12.93 V Beta(dc)=131.16