63 k12 The Op Amp in the circuit shown in Fig. 1 is ideal, 30 k02...
5.20 The op amp in the circuit shown in Fig, P5.20 is ideal, Calculate v, when v, equals 3 V b) Specify the range of values of vg so that the op amp operates in a linear mode. c) Assume that a's equals 5 V and that the 48n resistor is replaced with a variable resistor. What value of the variable resistor will cause the op amp to saturate? Figure P5.20 48 kΩ 15 kΩ 10 V 30 kΩ 10...
5.4 The op amp in the circuit of Fig. P5.19 is ideal. a) What op amp circuit configuration is this? b) Find in terms of us . c) Find the range of values for e, such that e, does nol saturate and thc op amp remains in its lincar region of operation. Figure P5.19 40 kΩ 10 V 12 kΩ 10 V 1 S1DE
The op amp in the circuit shown below is ideal. The adjustable resistor has a maximum value of 100 k Ohm , and alpha is restricted to the range of 0.2 a 1.0. Calculate the range of v0 if vg = 40mV. If alpha is not restricted, at what value of alpha will the op amp saturate?
solve for part a & b only 13.46 PSPICE MULTISIM The op amp in the circuit shown in Fig. P13.460 is ideal. There is no energy stored in the circuit at the time it is energized. If v, = 20,000tu(t)V, find (a) V., (b) v,, (c) how long it takes to saturate the operational amplifier, and (d) how small the rate of increase in v, must be to prevent saturation. Figure P13.46 100 nF HE C2 1 k12 R2 5V...
Solve by using basic node-voltage or superposition! The op amp in the circuit of Fig. P5.23 is ideal. a) What op amp circuit configuration is this? b) Find vo in terms of vs c) Find the range of values for such that does not saturate and the op amp remains in its linear region of operation. Figure P5.23 96 kΩ 24 kΩ 10 V 16 kΩ 10V 24 kΩ
The op amp in the circuit in Figure below is ideal. a) (3pts) Calculate vo if va=1 V and vh=2.5 V. b) (3pts) Calculate vo if va =2.5 V and v5 = 1V f) (2pts) If Vb = 2.5 V, specify the range of va such that the amplifier does not saturate. 40 k N16V 2k1 totx 16V v.210k
The op amp in the circuit in (Figure 1) is ideal. Suppose R-16 kΩ Part A What op amp circuit configuration is this? O This circuit is an example of the inverting amplifier o This circuit is an example of the non-inverting amplifier Submit Request Answer ▼ Part B Find vo in terms of vs Express your answer in terms of vs 07 Figure 1 of 1 > Submit Request Answer Part C 56 kΩ Find the minimum value of...
Problem 1) [15 marks] The gain of the dual-op-axap instrumentation amplifier shown in Fig. 1 can be adjusted by the variable resistor Ro. The op-amps are ideal. atu Fig. 1 a)Show that v.-2(1 RG )(v2-v.). b Specify suitable components to have a variable gain from 10 to 100 V/V. Problem 2) [15 marks] a) Design an op-amp limiter circuit for amplitude control with the transfer characteristic of Fig. 2(a). Use +-15V DC sources to power the circuit. Assume Vo-0.7 V...
For the circuit shown in Fig. 4.3, the op-amp is ideal and is operating in its linear region. (a) Determine the transfer function H (s) = Vo(s)/Vi(s). (b) Sketch and clearly label the Bode Magnitude-Phase plot of H(jo) (Your provided two graph papers. Use the first for the magnitude plot and the second for the phase plot). (c) What filter is represented by H(s)? Explain. 400 k 2 210 S2 50 nF 160 k92 내 mto 105 2 50 nF...
Assuming an ideal op-amp in the following circuit, find output voltage, Vo if R1= 2 K12, R2=8 KN, R3=3.9 KN, R4=6 KN, R5=18 K2, R6=4.4 KN, RL=12.5 KN, V1=1V, 12=0.5 mA and V3=3.4 V. R6 R1 R5 Vo + + RL R2 V1 R3 R4 + V3 Answer: LOV Using the above circuit, but consider the following component values: R1= 2 KO2 R2=8 K12, R3=3.6 K12, R4=6 K12, R5=16.9 KN, R6=15 KN, RL=10 KO, V1=1V, 12=0.5mA and V3=2V. What is...