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1. Set up the following circuit. (20pts) 5 Vp-p R2 Vo Use the function generator to set up signal (5 Vpp sinusoidal...
k solve CET 3615L Practical Final Exam Name Spring 2019 1. Set up the following circuit. (20pts) Vin: 5 Vp-p Vo Use the function generator to set up signal (5 Vep sinusoidal with a 5 V DC offset) as the input voltage (Vn) and take the output voltage (Vo) across R Sketch and label the input voltage (Vi) and actual output voltage (Ve) displayed on the Oscilloscope and compare actual Vo to your calculated output Vo. (Show your all work...
can anyone please write an explanation as well when answering? thank you for your assistance R Vin nwww Vot) Take a square wave signal from Function Generator for Vin through AO 0 port. Then set Vn and Vas to Al 0 and Al 1 respectively in order to observe the input and output waveform using oscilloscope. Vary the frequency of the square wave input according to the values shown in the table below. Then, observe the amplitude of the output...
The circuit 3-The circuit of problem # 2 is subjected to a small ac input by the signal generator. By neglecting the voltage drop across the coupling and bypass capacitors, determine the small signal voltage gain Vo/ Vì = Avi , input resistance Ri-vi / ii and the output resistance Ro external to R Avi= Ri= , Ro The accompanying circuit shows a 4-resistor biased JFET transistor Determine the values of Rp and Rs so that the Q-point is equal...
Inverting Amplifier Figure 4.2 shows the fundamental configuration of Op-Amp in which it is used as an inverting amplifier. In this configuration the ratio, R2/R1 completely controls the effective gain of the amplifier and it can be verified that the output voltage is equal to Vo = - (R2/R1)Vin R2 100K Q-10V R1 Vinow 20K 1 2 7 V Vo 3 -10v Figure 4.2 Part 1 - Inverting Amp: Procedure 1. Construct the circuit of figure 4.2 using Op-Amp IC...
Analog Oscilloscope Setup: 1. Turn on the power to the oscilloscope. 2. Connect the function generator to the Channel 1 input on the oscilloscope 3. In the Vertical Control Group, set the Channel 1 AC/GND/DC switch to AC. 4. Set the Volts-per-Division knob 5. Intensity knob: adjust the signal intensity and focus to a comfortable level by using the intensity and focus knobs, respectively Set the seconds-per-division knob 6. Assignment Procedures: 1. Using the settings completed above, answer the following...
LAB TEST 1 (set 1) PMENT REQUIRED 2 Power Supply 3. Function Generator PROCEDURE 1. Connect a circuit as shown in Figure 1 2. Measure the output voltage at Ri. Ra for the given frequency range oscilloscope. Ri 1.6 kW 10 Vpp, 5 kHz 100 nF R 24 KW Figure 1 RESULTS Vpp Vpo at R Freq (kHz) Vou (Vop at Ra) 10 10 03.5t 20 10 30 10 10 50 10 60 70 10 80 10 100 10 ....
For each filter mentioned in the following cases, first simulate the circuit using Multisim. You can get a plot of the transfer function that is called the Bode plot. From the right toolbar, select "Bode Plotter". Change initial (I) and final (F frequencies to 1Hz and 200 KHz, respectively. Use a Voltage AC source as the input signal. You do not need to change any parameter from voltage AC source Connect "Bode Plotter" to input and output of your circuit...
Design a diode waveform shaping circuit that would have the above transfer function. You can use PN junction diodes with VD0 = 0.7 V, DC voltage sources, and resistors in your design. You should indicate the resistor values and the DC voltage sources’ values in your design if you used any resistors or DC voltage sources. You can use Zener diodes with different Vz values if you want, but you do not have to. Write the possible cases of the...
4. Construct the following circuit: V1 5 V 1MHz ODeg Set up your function generator to provide v = 5 sin (6.28 x 10 t). Calculate Vrı from the schematic. Measure Vri with your oscilloscope (be careful - think!). They should be the same. If they are not the same explain why not.
Simulation For each filter mentioned in the following cases, first simulate the circuit using Multisim. You can get a plot of the transfer function that is called the Bode plot. From the right toolbar, select "Bode Plotter". Change initial (I) and final (F) frequencies to 1Hz and 200 KHz, respectively. Use a Voltage AC source as the input signal. You do not need to change any parameter from voltage AC source. Connect "Bode Plotter" to input and output of your...