Problem 2: The circuit shown is the AC equivalent circuit of a CC amplifier. The parameters...
4. For the amplifier in the figure below use the parameters in the table: +Vcc Re VBE- 0.7V, Ri- 1002, R1-160k2, R2-320k2 R3-200k2, R6-40 k2, Rc-60k2, Vcc- 12V, Ry Do a) Draw the DC equivalent circuit and calculate the Q-point. c) Draw the AC equivalent circuit with the small signal model for the transistor. d) Calculate the voltage gain, Av-Vo/vi. Assume ro infinite. e) Draw the circuit to find the amplifier input resistance (Rin). Calculate Rin f Draw the circuit...
The BJT amplifier circuit in the figure below has β = 90. Use VT = 25 mV a- Draw the DC equivalent circuit and calculate IC. b- Draw the small signal equivalent circuit and calculate the small signal parameters. c- Find the voltage gain +9V 3 kΩ C2 = 1 uF HE C = 1uF + υο 10 kΩ Cz = 50 uF - . υ 9 kΩ Η. 6. ΚΩ -9 V
Q1. For the cascade amplifier circuit shown in Fig (1): a) What are the functions of the capacitors C, C2 and C3? And what are the functions of the capacitors Cs and CE? b) What are the functions of the resistors RD and Rc? c) Draw the DC biasing circuits for each stage. d) Find loa, VGsa, VDs and gm for the JFET stage (you may use either mathematical or graphical methods) e) Calculate l, Ic, le and Ve for...
Quiz-11 Spring 2018 Problem: The circuit shown is the AC equivalent of a Br CB amplifier. The transistor parameters are gm 40 mA/V, r-2 model. B) Find equivalent of a BIT CB amplfieh rornd ovi the voltage gain Av ohms, and ro is very large. A) Find re for the transistor Ka
Problem 2 (10 points) In the amplifier shown in Fig. 2(a), assume Fig. 2(b) that I4 is ideal. Do not ignore the ro of the transistors for this problem, but you can assume that Ri is much smaller than any transistor o I1 and I2 ideal current sources. Also, assume in are (a) Find the small signal differential gain out/vdm of the Fig. 2(a) amplifier in terms of the appropriate small-signal parameters. Then express your answer in terms of appropriate...
1. Consider the Common-Emitter BJT amplifier circuit, shown below. VD VOD BJT Parameters: B=99 A/A i=0 RE Co Circuit Parameters: Ca Cc2 = 0 F Car = OF R = 2022 R = 2002 R1 = 25.8 k22 Ry2 = 51.6 ks V = 15 V VEE=0 V Сct Active Mode: Va >0.2 V Vwx=0.7V Ic=B1, Ic=al, 1 R2 3 SRCA a) Find the open-circuit voltage gain, Ave, of this amplifier circuit. Verify your assumptions. b) Compute the input resistance,...
Problem 2: BJT Small-Signal Voltage Amplifiers in the lectures, we covered in detail the analysis of an npn BJT amplifier that utilizes a single-supply DC biasing. In this problem, you will meet two additional amplifier architectures- one that is based on dual DC supplies combined with a DC current source, and the other that utilizes a pnp BJT with single-supply biasing. In both problems (below) you need to manually find the amplifier's Q-point (that is, the DC values of Ic...
Answer A & B & C as fast as u can 1. The amplifie parameters for each transistor and circuit components are given in the figure, 100 for both Q1 and Q2, and VeEVEe 0.7V. VA 200V for Q1, and VAo for r of the following figure consists of two CE amplifiers connected in cascade. The consider the β and capacitor is very large. (120 pts) RI V. Q2 -4V culate corresponding DC currents (U-) and DC voltages (V-Vs) through...
x=4 Question 3: The parameters of both bjt are as follows: base emitter turn on voltage is VBE,ON = 0.7 V, early voltage VA = 0, ac current gain B = 99. Small signal ac voltage source viis applied to the base of Q1 through a large capacitor. The resistors on the left branch are 63 X and 37xX2 (63 times X and 37 times X, note that these are not k2!!!). The remaining resistors are 4 k 2, 3...
The following ciruits has_ biasing scheme Find lE Find VE and VB . Find Vc and VcE +10 V Find Cb and Cc! Draw an AC equivalent circuit . circuitqent . Find AC input voltage at Find AC voltage gain (A) . Ca 2kQ the base (Vin_b) B-100 10kO . Find the output AC voltage 100 mV @1 KHz 3 kS2 The following ciruits has_ biasing scheme Find lE Find VE and VB . Find Vc and VcE +10 V...