Problem 4 (20 %) For the circuit shown in Figure 4 determine IB,
IC, and VC. Data VCC=9 V VBB=4 V R2= 165 k R1= 2.5 k Transistor
Assume VBE ≈ 0.7 V and =150
Derive all the results. Give the answers with the preestablished
prefix.
FAVOR DIBUJAR LOS CIRCUITOS
Problem 4 (20 %) For the circuit shown in Figure 4 determine IB, IC, and VC....
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
4. Determine the terminal voltages of each transistor with respect to ground for each circuit in the Figure shown. Also determine VcE. VBe, and VcB- Ans: Vc=-12 V Vy--4V VBE =-0.7 V ½ =-3.3 V Va. =-8.7 V 4 V RE 2.2 kΩ CE 4. Determine the terminal voltages of each transistor with respect to ground for each circuit in the Figure shown. Also determine VcE. VBe, and VcB- Ans: Vc=-12 V Vy--4V VBE =-0.7 V ½ =-3.3 V Va....
Vcc 10 V #2. Calculate the values of VBE, VCE, IB, Ic, and IE assuming B = 150 for the Transistor Biasing Circuit in Figure 5 - 5. Simulate the circuit in Figure 5 - 5. Include the procedure and results of calculation / simulation in related section. 370k SR2 2370K BROD 2N3904 ŽR3 330 Figure 5 -5: Transistor Biasing
5 نقاط For the circuit shown, If there is an added 1 K. Ohm resistor at the emitter terminal connected between Emitter and Ground, then calculate IB, IC, VCE, VB, and VC knowing that Vcc = 12 Volts, RB = 220 K. Ohm, RC = 4 K. Ohm, VBE = 0.7 volts, and Beta of transistor = 50 VCC Fig. 1 Rc im Ic RB ac HE output signal C2 IB + ac VCE input I signal G B +...
Design a transistor biasing circuit as shown below. Assume ß = 100, Ice = 10 mA, VE = Vcc/3, VCEQ = Vcc/3 and VBE = 0.7 V. RTH = 0.1 (1 + BRE. Also find the power rating of all resistors. +15V R2 Rc V 10 R1 RE
Q. 3. Design a transistor biasing circuit as shown below. Assume B = 100, Ica = 10 mA, VE = Vcc/3, VceQ = Vcc /3 and VBE = 0.7 V. RTH = 0.1 (1 + B)RE . Also find the power rating of all resistors. (25) > +15V R2 Rc Vio R1 RE
Q. 3. Design a transistor biasing circuit as shown below. Assume ß = 100, lco = 10 mA, VE = Vcc/3, VCEQ = Vcc/3 and VBE = 0.7 V. RTH = 0.1 (1 + B)RE . Also find the power rating of all resistors. +15V R2 Rc V10 R1 RE
Please only use PSpice as stated in the directions. Any other software will not be accepted. Thanks No multisim or LTSpice. Part I: Transistor Output Characteristic Procedure: 1. Build the circuit model in PSpice as shown in Fig. 1 with Vbb = 10V, R2 = 330 k92 and R3 = 0.22 k22. R3 0.22 Vec vbь R2 Q1 10V 330k or 147k Figure 1. Circuit configuration for Transistor output characteristic testing 2. Use Ohm's Law to calculate Ib. You may...
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...
4. Lab VIII: Experiment VII The Bipolar Junction Transistor (BJT) Characteristics The bipolar junction transistor (BJT) is a three-terminal solid state device widely used as an amplifier (or switching) device. It consists of two n-type materials sandwiched by p-type material (npn) or two p-type and n-type. The terminals (sections) are known as emitter E, base B and collector C. Two currents and two voltages uniquely describe the behavior of the device. The third current/voltage can be determined through KCL/KVL. See...