NO AI PLEASE 2. Determine the 3 dB frequency of the current gain for the BJT circuit shown below, bothwith and without the effect of CM. The circuit parameters are: Rc = R₁ = 4 kQ, r = 2.6 kQ,RB = 200 kQ, C₁ =0.8pF, C₁ =0.05pF, and gm =38.5mA/V.[Hint: To find 3-dB frequency concentrate on RC time constant.Also given, CM = Cμ [1+gm(Rc||RL)]1, RBC:CMRCRL8mVx

Answered: 2. Determine the 3 dB frequency of the…

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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Full the following blanks:
Q1. Clearly draw the small signal low-frequency model (with the Hybrid-π) and derive an equation for the break frequency (Hint: Find the Thevenin resistance seen by the capacitor
Q1. For the MOSFET circuit below, input is sinusoidal signal of amplitude IV and frequency 50Hz. Find, the DC operating point, Plot the frequency response and Plot the input, output and transfer characteristics and find out the small signal equivalent. Assume an overdrive voltage of 0.2V Use MOSFET 500nm Library file provided. F Vdd=5V -=80 K R1 (1 1.20F
3. gain to 70.7% of its midrange value. --- Frequencies are values of frequency at which the RC circuits reduce the voltage 4. In low frequency response of an amplifier if the critical frequencies of the three RC circuits are not all equal, the dominant RC circuit is - ----- 5. fa is the abbreviation of - 6. In the coupling and bypass capacitors can be neglected. 7. 8. frequency. 9. When the negative feedback is applied to an amplifier, its voltage gain is 10. Negative feedback is employed in is used in special areas of tuned circuits, such as radio or communications. is the formula that shows the capacitive reactance varies inversely with
Problem #1. The parameters for the circuit below are V₁=00, and VBE (on)= 0.7 V. www-H R$ Rc RL STEF RE V+=5 V V = -5 V Low-Frequency Analysis: Clearly draw the small signal low-frequency model (with the Hybrid-) and derive an equation for the break frequency (Hint: Find the Thevenin resistance seen by the capacitor).
Electrical Engineering PROBLEM SET QI. For the MOSFET circuit below, input is sinusoidal signal of amplitude 1V and frequency 50HZ. Find, the DC operating point, Plot the frequency response and Plot the input, output and transfer characteristics and find out the small signal equivalent. Assume an overdrive voltage of 0.2V Use MOSFET 500nm Library file provided. AG-PPA <80 K 1-2nF Q1 Vin
Is=20*10-16 B=100 question A&B
Please solve with steps
3) VDD=VSS=1.5 V, μpCox=250 μA/V2, µn=2.5-µp, Vthn=0.5 V, Vthp=-0.5 V, λn=λp=0.1 V-¹ is given for the circuit below. The differential amplifier biased using current mirrors will be designed to meet the following requirements: Adm=-70, IREF=150mA, Vov3-Vov4=Vov5-Vov6-Vov7-150 mV. a) Calculate the value of resistor R and the W/L values of the transistors. b) Calculate the value of CMRR M6 REFR M7 VDD I D HM3 Vi1-M₁ M2V12 Vo1 HM4 -Vss Vo2 M5
For the circuit as shown, find R3 to set ID3 = 0.8 mA with VDD = VSS = 10 V, and ID4 = 4 mA. Calculate a new R4 to maintain Vo = 0 V. Calculate the poles of the amplifier and calculate RZ to cancel the right-half plane zero. Find the unitygain frequency such that the phase margin is set to 70◦. For the phase margin calculation, assume the dominant pole contributes 90◦ of phase shift at the unity-gain frequency. Calculate the CC required to achieve the desired unity-gain frequency and phase margin.
Answer the following with illustration and solutions. 1. Determine the frequency of oscillation of a three-stage ladder network oscillator in which C= 30 nF and R= 47kilo-ohms. See the example below..
QUESTION: Draw small signal equivalent circuit of the amplifier in high frequency band.

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