Vinpeak - peak = 0.75
VinRMS = (0.75/2) / ((2)0.5) = 0.2652 volts
Vin_peak-peak = 0.75 volts
Vin_peak = 0.3726 - 0 = 0.3726
Vin_peak-peak = 0.3726 * 2 = 0.7452 volts
Vout2_peak = 7.943 - 0 = 7.943 volts
Vout2_peak-peak = 7.943 * 2 = 15.886 volts
Gaintotal = 15.886/ 0.7452 = 21.0634 V / V
can you please solve this using a software simulator like multisim or something similar ?? VCC...
can you please solve this using a software simulator like multisim or something similar. just do it by calculation then VCC VCC 15V 15V U2 U1 3 6 + R3 Voutt 741 = Vouth 6 R1 741 2 1.0kg 2.2k VEE -15V VEE Vin= -15V 2 0.75 VIP-P) @ 2 kHz R2 R4 4.7k02 10kΩ Figure A Focus on Op-amp U1 (*Both op-amps have to be completely connected as shown in Figure A) • Use myDAQ's oscilloscope to capture the...
can you please solve this using a software simulator lime multisimbor something similar. just do it by calculations or use a software for circuit simulation Focus on Op-amp U2 ("Both op-amps have to be completely connected as shown in Figure A) • Use myDAQ's oscilloscope to capture the intermediate output waveform Vout1 (on Channel O) and the final output waveform Vout2 (on Channel 1) superimposed. • Set the amplitude scale of the oscilloscope for Channel O to 500 mV/Div, and...
Use the circuit diagram as shown in Figure A below to conduct the experiment and answer the questions 1 to 6. VCC VCC 15V 15V U2 U1 + R3 + 741 Voutt Vouth 6 R1 741 1.0kΩ 2.2k VEE VEE -15V Vin= 0.75 VIP-pl @ 2 kHz -15V R2 R4 TH 4.7ΚΩ 10kΩ Figure A Question 5 3 pts Op-amp U1&U2 • Use myDAQ's oscilloscope to capture the input waveform Vin (on Channel O) and the final output waveform Vout2...
Question 3 3 pts Focus on Op-amp U1 (Both op-amps have to be completely connected as shown in Figure A) Use myDAQ's oscilloscope to capture the input waveform Vin (on Channel 0) and the intermediate output waveform Vout1 (on Channel 1) superimposed. Set the amplitude scale for both channels of the oscilloscope to 500 mV/Div Set the time scale of the oscilloscope to 200 us/Div 1. Take a screenshot of the oscilloscope (both waveform in the same picture) and embed...
Use the circuit diagram as shown in Figure A below to conduct the experiment and answer the questions 1 to 6. VCC VCC 15V 15V U2 U1 + R3 + 741 Voutt Vouth 6 R1 741 1.0kΩ 2.2k VEE VEE -15V Vin= 0.75 VIP-pl @ 2 kHz -15V R2 R4 TH 4.7ΚΩ 10kΩ Figure A Question 3 3 pts Focus on Op-amp U1 ("Both op-amps have to be completely connected as shown in Figure A) • Use myDAQ's oscilloscope to...
Question 6 3 pts 1. Compare your experimental results to the previously-computed theoretical values. 2. Explain your observation from the oscilloscope output waveform. HTML Editor IEE xx E E A B I UA T ECE 12pt Paragraph Use the circuit diagram as shown in Figure A below to conduct the experiment and answer the questions 1 to 6. VCC VCC 15V 15V U2 U1 Voutt R3 1.0k Vout2 741 + 741 R1 2.2kQ VEE 4 VEE -15V Vin 0.75 V(p-p)...
Question 4 3 pts Focus on Op-amp U2 ("Both op-amps have to be completely connected as shown in Figure A) • Use myDAQ's oscilloscope to capture the intermediate output waveform Vouti (on Channel O) and the final output waveform Vout2 (on Channel 1) superimposed. • Set the amplitude scale of the oscilloscope for Channel 0 to 500 mV/Div, and for Channel 1 to 2 V/Div. • Set the time scale of the oscilloscope to 500 us/Div 1. Take a screenshot...
Use the circuit diagram as shown in Figure A below to conduct the experiment and answer the questions 1 to 6. VCC VCC 15V 15V U2 U1 + R3 + 741 Voutt Vouth 6 R1 741 1.0kΩ 2.2k VEE VEE -15V Vin= 0.75 VIP-pl @ 2 kHz -15V R2 R4 TH 4.7ΚΩ 10kΩ Figure A Question 6 3 pts 1. Compare your experimental results to the previously-computed theoretical values. 2. Explain your observation from the oscilloscope output waveform. 12ptv Paragraph...
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...
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...