3. Let Vi is AC input signal which has following properties: Voffset: 1 Volt Vpp: 0.5 Volt Wavefo...
Question 4 The input signal to the circuit below is a Triangle wave with a peak to peak Vin of 10 V Determine the ideal peak to peak output voltage signal. The Frequency is 1 kHz Note: At 0.5 Tp Amplifier Parameters Vin R1 10 Ypg R1 10 K2 0.01 uF C1 Veu Ereg 1 1H2 Vout Note 4 Vpp, Triangle Wave 4 Vpp, Square Wave 2 Vpp, Square Wave 2 Vpp, Triangle Wave
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...
URGENT!! PLEASE HELP! be clear and answer all questions clearly!! Lab ll: Voltage Follower ECE 210: 1. For the following circuit, Theoretically calculate the peak voltage across R3 (Vo) an ved R1-2.2k0 2.17362(Actual) R2 = 3.3kN-3.Z44KAL (Actual) R3-10kΩ 9.873M. (Actual) Vin- 1kHz Triangle wave, 2V peak, NO DC offset e) R Draw the output waveform Vo: UI R1 R2 X-Axis 0.1 msec/div 2. Remove the resistor R2 to create the following circuit Draw the output waveform Vo: U1 R1 R3...
1. You want a gain of -8/5 V/V-1.6 VN on the input ac signal labeled Vi. (I know it's a strange value for gain, but just go with it.) (By the way, Vi has a zero DC offset.) Find R1 and R2 if the smaller of the two should be 500 k-ohms. (HINT: Use superposition by grounding VDC to figure this out. You can probably do this in your head.) 2. Now, you also want the output to have a...
The alternating signal with an amplitude of 0.9 V, a frequency of 1 KHz, and a phase of -22.5° is o.TV dc b.as. Try connecting this signal to a load resistance of 50 Q to test the waveform 1.Express circuit as CAD drawing 2.Show output graph through Transient analysis in PSPICE 3.Calculate the instantaneous value at 0.1 second and compare it with the result of 2 4.When connecting the signal to the A and B terminals of the voltage distribution...
1. As a reference, observe the full amplitude range of the AC voltage, without limiting. R1 330 0 f=1.0 kHz 3.0 k2 out Vap = 15.0 V Figure 1. AC Circuit without limiter Construct the circuit of Figure 1. Set the function generator for a sine wave with a frequency of about 1 kHz. Begin with the AC input voltage adjusted to its minimum value, approximately 0 V. Connect Channel 1 of the oscilloscope to observe the AC input voltag...
1. Set up the following circuit. (20pts) 5 Vp-p R2 Vo Use the function generator to set up signal (5 Vpp sinusoidal with a 5 V DC offset) as the input voltage (Vin) and take the output voltage (Vo) across R Sketch and label the input voltage (Vin) and actual output voltage (Vo) displayed on the Oscilloscope and compare actual Vo to your calculated output Vo. (Show your all work for your calculation to get a full credit.) You should...
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...
a)Which LED will be turned on when vi = 1V? Which LED will be turned on when vi=-1V? b) Write an equation for v1 as a function of the pot setting ?. Assume ? = 0 corresponds to the slider being all the way up. c) What do you expect the LEDs to do for a pot setting of ? = 0.4? How about ? = 0.5? How about ? = 0.6? d) What is the threshold ? for the Schmitt trigger...
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...