Plot the input/output characteristics of the circuit below,assuming a constant-voltage model D1 R1 2
Plot the output for each circuit, assuming the constant voltage
drop model (CVD) for the diode.
(B) Full-wave rectifier: D2 Di Vi = 5V, sin(2π 103 t) D3 D4
(6) For the circuit below, plot: (a) the transfer characteristics (b) the output, o voltage with 5V peak amplitude. Label the plots clearly 3 V I O (iv) Vi 8V sin( 200πt) 2ΚΩ 2ΚΩ Vi- 9V sin(200nt) -4 V -5 V (4) For each of the clipper circuits below, plot: (a) the transfer characteristics the output. 6i) 3 V 2ΚΩ 2 KS2 VQ Vi- 5V sin(200nt) DI Vi 6V sin( 200πt)
a) Use the constant voltage drop model for the diode and
determine the input / output ratio (Vout x Vin), equations. Vdon =
0.7V, rz = 0Ω, Vz = 3V and R = R1 = R2 = 1000Ω.
b) Draw the Vout x Vin graph. Highlight the slope coefficients
of the lines and the coordinates of the points where the slope
changes occur.
D1 D2 DR3 Vin 7R1 Vout 214 22
For the circuit below, the output is at 15 V and the input voltage is at +2 V if the input voltage is gradually lowered to -2 V, at what input voltage does the output switch from +15 V to-15 V (to 1 % accuracy)? The op-amp has rail-to-rail swing, and a gain-bandwidth product of 3 MHz. The resistors used are r1 -1.5 k ohm and r2 22.8 k ohm r2 Vin 2 +2 V +15 V r1 f 1...
For the circuit below, the output is at-15 V, and the input voltage is at +2 V if the input voltage is gradually lowered to -2 V, at what input voltage does the output switch from-15 V to +15 V (to 1 % accuracy)? The op-amp has rail-to-rail swing, and a gain-bandwidth product of 3 MHz. The resistors used are r1 0.6 k ohm and r2 49.8 k ohm. r2 Vin 2/+2 V +15 V r1 out f-1 kHz 15...
For the circuit below, the output is at -15 V, and the input voltage is at -2 V. if the input voltage is gradually raised to 2 V, at what input voltage does the output switch from-15 V to +15 V (to 1% accuracy)? - The op-amp has rail-to-rail swing, and a gain-bandwidth product of 3 MHz. The resistors used are r1 1.3 k ohm and r2 37.7 k ohm r2 Vin 2/+2 V +15 V r1 o out f...
The output of the following circuit is affected by: R1 Out WYD1 D2 Out D1 v1 2K 1N4148 V2 1N4148 T 1N4148 1N4148 V3 3.6V 4.8V SINE(O 10 1k) Select one: The branch that contains D2. because it has higher DC voltage (4.8V) The branch that contains diode D1 because it has lower DC voltage (3.6V) Both branches (that contain D1 and D2) are parallel with V= 3.6V. Hence both branches are affecting V(out) Both branches (that contain D1 and...
or the following circuit, sketch the output voltage, given an input voltage waveform as shown on the axes below. Assume a constant voltage drop diode model with Vo- 0.7. +15.0V 4 1mA OVout 3009 3 Vo -4 0 0.2 0.4 0.6 0.8 in
or the following circuit, sketch the output voltage, given an input voltage waveform as shown on the axes below. Assume a constant voltage drop diode model with Vo- 0.7. +15.0V 4 1mA OVout 3009 3 Vo -4...
Vx = Vin
2. (60 points) Plot Vout as a function of Vx for the circuit shown below. Assume a constant voltage diode model. Also plot the Vout as a function of Vx in the circuit assuming Vx Vo sin ot D1 VB
1. Find the ratio of the output voltage to the input voltage, Vo/Vin, in the circuit shown. State your assumptions in using the ideal op-amp model. 15 k2 Vin 2. Find the output voltage Vo in the circuit shown assuming an ideal op-amp. State your assumptions in using the ideal op-amp model 15 k12 Vo . Find the voltage Vx and the output voltage Vo in the circuit shown assuming ideal op-amp 3 k2 1 V 6 kn 12 k2