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In Multisim, rewire your opamp circuit so that it matches the circuit in Figure 2 U1-....
A. B. 1.Choosing the appropriate one of the two circuits above, design an amplifier that has...
A.
B.
1.Choosing the appropriate one of the two circuits above, design
an amplifier that has a voltage amplification factor of +10 (i.e.,
the output signal should be 10 times larger than the input signal,
and also be in-phase with the input signal). You may use any values
for your resistors, but avoid values greater than 100 kΩ.
2. construct the circuit using multisim, and perform a transient
analysis
U1 .V43 0.707 Vrms: 60 Hz O° 0PAMP 3T BASIC 2.R1...
1) For the bridge opamp circuit in the figure, find the total voltage gain expression Vo/Vin...
1) For the bridge opamp circuit in the figure, find the total voltage gain expression Vo/Vin when the opamps are not saturated. (20p) When Vin (4th) (2001Tt) signal is applied to the input and R1 = R4 = 10K, R2 = R3 = 20K resistance values are selected, draw a single period of the Vo output signal by specifying its time and amplitude values. R2 +12V R1 Vin 1-12V RL Vo +12V -12V WW R3 R4
nde) Figare 18 Circuit for Problem 15 Analysis 1. Plot the input and output vollage wavefoems nlt) and lt) as wel as the capacitor current iclt) for the input wavelorm shown in Fig ure 1....
nde) Figare 18 Circuit for Problem 15 Analysis 1. Plot the input and output vollage wavefoems nlt) and lt) as wel as the capacitor current iclt) for the input wavelorm shown in Fig ure 1.10 on the next page, Assume the capacitoris initially discharged 2 Determine the following numerical descriptors for lf) and iclf (a) Voltage values of t) at times-250, 650, and 960ms. (b) Peak capacitor current t Discass the relationship between the plots of the capacitor current ic(t)...
PART B: OPAMP as a non-inverting amplifier a) Implement the following circuit using the LM741 and...
PART B: OPAMP as a non-inverting
amplifier
a) Implement the following circuit using the LM741
and energize the integrated circuit 741 with + 15v and -15v. In
addition, feed the circuit with a 1 Vpp and 1KHz sinusoidal signal.
Values: R2 = 10kΩ, R1 = 1KΩ
b) Obtain the graph of the output voltage and the input voltage.
Explain the differences between the graphs and determine
the circuit gain.
c) Change the R2 resistor with a 5.1k Ω resistor. Obtain...
02 +Vo D3 Rgare 18 Circuit for Problem 1 Analysis 1. Copy the circuit of Figure 1.8 and sketch the ow of pesitive curment throughout the entire circuit for o>0. Repeat for n ce 2....
02 +Vo D3 Rgare 18 Circuit for Problem 1 Analysis 1. Copy the circuit of Figure 1.8 and sketch the ow of pesitive curment throughout the entire circuit for o>0. Repeat for n ce 2. Plot two periods of nlt) and s) for each of the thee input wave shown in Figune 17 on page 37 fom output t (a) Feak value, and b) Eflective DC value, also known as RMS value NotTE These and are therefore optional 4. Determine...
1. Find the transfer function Voda)/Vin(a) for the circuit shown in Figure 1 of the lab (where co...
Please answer number 1
1. Find the transfer function Voda)/Vin(a) for the circuit shown in Figure 1 of the lab (where complex frequency variable s jo can be substituted for ease of analysis.) Calculate values for R and C such that the phase shift between the output and input is zero for an input frequency of 10kHz. What is the amplitude ratio (gain) of the output to the input at this frequency. 2. The RC network in figure 3 of...
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 toolba...
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 &...
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...
Laboratory 2: Transistor circuit characteristics A. Objectives: 1. To study the basic characteris...
Laboratory 2: Transistor circuit characteristics A. Objectives: 1. To study the basic characteristics of a transistor circuit. 2. To study the bias circuit of a transistor circuit. B. Apparatus: 1. DC Power supply 2. Experimental boards and corresponding components 3. Electronic calculator (prepared by students) 4. Digital camera (prepared by students for photo taking of the experimental results) 5. Laptop computer with the software PicoScope 6 and Microsoft Word installed. 6. PicoScope PC Oscilloscope and its accessories. 7. Digital multi-meter....
IV, Laboratory Procedure 1. Construct the circuit of Figure 6.1, measure the current value 2. Con...
IV, Laboratory Procedure 1. Construct the circuit of Figure 6.1, measure the current value 2. Construct the circuit of Figure 6.2; measure Vn and v., using the oscilloscope. 3. Construct the circuit of Figure 6.3, measure the value of Io and V 4. Construct the clipper design circuit, Capture the input and output waveforms. 5. Construct your clamper design circuit. Capture the input and output waveforms Figure 6.3 Design a clipper circuit which limits input signals to +3V and -2V....
A.
B.
1.Choosing the appropriate one of the two circuits above, design
an amplifier that has a voltage amplification factor of +10 (i.e.,
the output signal should be 10 times larger than the input signal,
and also be in-phase with the input signal). You may use any values
for your resistors, but avoid values greater than 100 kΩ.
2. construct the circuit using multisim, and perform a transient
analysis
U1 .V43 0.707 Vrms: 60 Hz O° 0PAMP 3T BASIC 2.R1...
1) For the bridge opamp circuit in the figure, find the total voltage gain expression Vo/Vin when the opamps are not saturated. (20p) When Vin (4th) (2001Tt) signal is applied to the input and R1 = R4 = 10K, R2 = R3 = 20K resistance values are selected, draw a single period of the Vo output signal by specifying its time and amplitude values. R2 +12V R1 Vin 1-12V RL Vo +12V -12V WW R3 R4
nde) Figare 18 Circuit for Problem 15 Analysis 1. Plot the input and output vollage wavefoems nlt) and lt) as wel as the capacitor current iclt) for the input wavelorm shown in Fig ure 1.10 on the next page, Assume the capacitoris initially discharged 2 Determine the following numerical descriptors for lf) and iclf (a) Voltage values of t) at times-250, 650, and 960ms. (b) Peak capacitor current t Discass the relationship between the plots of the capacitor current ic(t)...
PART B: OPAMP as a non-inverting
amplifier
a) Implement the following circuit using the LM741
and energize the integrated circuit 741 with + 15v and -15v. In
addition, feed the circuit with a 1 Vpp and 1KHz sinusoidal signal.
Values: R2 = 10kΩ, R1 = 1KΩ
b) Obtain the graph of the output voltage and the input voltage.
Explain the differences between the graphs and determine
the circuit gain.
c) Change the R2 resistor with a 5.1k Ω resistor. Obtain...
02 +Vo D3 Rgare 18 Circuit for Problem 1 Analysis 1. Copy the circuit of Figure 1.8 and sketch the ow of pesitive curment throughout the entire circuit for o>0. Repeat for n ce 2. Plot two periods of nlt) and s) for each of the thee input wave shown in Figune 17 on page 37 fom output t (a) Feak value, and b) Eflective DC value, also known as RMS value NotTE These and are therefore optional 4. Determine...
Please answer number 1
1. Find the transfer function Voda)/Vin(a) for the circuit shown in Figure 1 of the lab (where complex frequency variable s jo can be substituted for ease of analysis.) Calculate values for R and C such that the phase shift between the output and input is zero for an input frequency of 10kHz. What is the amplitude ratio (gain) of the output to the input at this frequency. 2. The RC network in figure 3 of...
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...
Laboratory 2: Transistor circuit characteristics A. Objectives: 1. To study the basic characteristics of a transistor circuit. 2. To study the bias circuit of a transistor circuit. B. Apparatus: 1. DC Power supply 2. Experimental boards and corresponding components 3. Electronic calculator (prepared by students) 4. Digital camera (prepared by students for photo taking of the experimental results) 5. Laptop computer with the software PicoScope 6 and Microsoft Word installed. 6. PicoScope PC Oscilloscope and its accessories. 7. Digital multi-meter....
IV, Laboratory Procedure 1. Construct the circuit of Figure 6.1, measure the current value 2. Construct the circuit of Figure 6.2; measure Vn and v., using the oscilloscope. 3. Construct the circuit of Figure 6.3, measure the value of Io and V 4. Construct the clipper design circuit, Capture the input and output waveforms. 5. Construct your clamper design circuit. Capture the input and output waveforms Figure 6.3 Design a clipper circuit which limits input signals to +3V and -2V....
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