1- Set up the following circuit. Part a) Vdlt) Use values of Vcc, RL and RB...
SIXTH ACTIVITY: Common Emitter Amplifier. Please do the computer simulations before or after the lab (it's recommended that you do them before) 1- Set up the following circuit. Part a) vdt) Use values of Vc, Ru and Rg that will assure that the transistor is in the active region. What's the value of VCE?
Experiment 2: Good biasing Set up the circuit with R2 12 k2, R RE 1 k, and Vcc 15 V 39 k2, Rc = 2 k?. Circuit Analysis: Compute Ic, I, and VCE PSpice Simulation: a) Simulate the circuit with PSpice (bias point details only) and compare values of Ic, IB, VCE, and VBE from PSpice simulations with your analytical calculations. b) Rerun your PSpice simulations for temperatures of 0 and 60°C. Make a table of Ic IB, VCE, and...
The component values for the npn-transistor amplifier circuit are R = 665 Q, Vcc= 20 V, VB= 2.4 V, and RB= 85k a) The graphon the last page shows the characteristics for the transistor in the above circuit Construct the load line for th is transistor circuit and draw it into the IC vs. VCE graph. Briefly state how you determine the load line. b) Determine the base current, assuming that the transistor is made of silicon. c) Determine the...
1. Consider the emitter-stabilized circuit shown below Vcc-15V RB 430kΩ Rc 1.6k2 IB β = 125 RE a) Find b, k, and VCE for the circuit as shown, with β = 125 b) Suppose that β can vary in the range from 100 to 150 due to manufacturing variations. What is the resulting range in Vce? c) What is the requirement on β such that the transistor will not saturate?
Please answer 2,3 and 4 VCC Rb Rs C1 Wwth VS Re Ce RL VO w + Figure 1 For the circuit of Figure 1 the following parameters are given with Vec = 15 volts DC: Rs = 0 ohm ra = 1000 ohm Rb = 1750 ohms CI = 10 microfarads gm = 30ms RL = 50 ohms Ce=0.3 microfarads Re = 145 ohms C2 may be considered very large vs is a sinusoidal voltage source of 1 volt...
1) Consider the following circuit with an assumption that we have the transistor in active mode. The type of circuit below is a transistor commonn-emitter circuit. You must firstly determine i) Is then secondly ii) I and finally ii) Vce. All working must be shown. Rc 1.06.12 RB w @ Bpc = 50 + Vcc 10 V + 10 ΚΩ VBB 3 V
Problem 5 Given the following circuit, assume the following parameters VBB IV, RB 220 k, RC = 2 k, VCC= 10 V, VBE(on)-0.7 V, and B 200 a) Calculate the base, collector, and emitter currents and the C-E voltage, also, calculate the transistor power dissipation b) What transistor configuration does the circuit resemble? Vcc=10V RC=2k Rg=220 kQ VCE VBB= 1V o + VRE IB
design a Voltage Divider Circuit that has the following – VCC= 12 V IC=2.5 mA VCE = 6 V For the design, you will use a 2n3904 npn transistor. Assume a β of 150. Determine values for RC, RE, R1, and R2
This is Part a, I need solution for part B. b) Set up the following circuit VCC R1 100Ω Vin VEE R2 ns Repeat the measurements above 2- Introduction to Transformer a) Set up the following circuit VCC Vin 741 VEE vin(t)- Vm sin (ot), Vm 2 15v, where o 377 rad/s Measure the amplitude of the Vde, Vab, Vbc, Vac, calculate their RMS values. Also, find the turn ratio of iii (d-e): (a-c) b) Set up the following circuit...
It Kind of goes without saying but if you have no knowledge than dont comment or try and answer this question you dope Questions 1-3 below are about the amplifier circuit of Figure 1. Here Vcc is a fixed voltage The base voltage vB(t) is time-varying, and is of the form vB(t) V(t) where VB is a DC offset, and vb(t) is a time-varying purely AC signal. Suppose the amplitude of vb is A. Assume that the capacitor C is...