Question 1

Figure 20-1

-Refer to Figure 20-1 (a). If R₁ = R₂ = 30 k? and the closed loop gain is 450, the value of the external gain-setting resistor R_G is:

A) 13.4 ?.
B) 134 ?.
C) 134 k?.
D) none of the above.

134 ?.

Accepted Answer

134 ?.&#10;

Question 2

The voltage gain of an OTA can be calculated using the formula: A) A_V= g_mR_L. B) A_V= 2 Rf/R_i. C) A_V= R_f/R_i. D) A_V= (R_f/R_i)₊1.

Accepted Answer

The formula for the voltage gain of an Operational Transconductance Amplifier (OTA) typically involves transconductance (g_m) and load resistance (R_L), which is closest to option A, although the formula presented is not standard notation.

Question 3

Figure 19-2&#10;&#10;-If the inputs are 1.2 V, -0.5 V and 2.4 V in Figure 19-2(b), what is the output voltage?&#10;A) -4.1 V&#10;B) -6.2 V&#10;C) 6.2 V&#10;D) 13 V

Accepted Answer

The output voltage of an operational amplifier in a summing configuration can be calculated using the formula Vout = -Rf*(V1/R1 + V2/R2 + V3/R3 + ...), where Rf is the feedback resistor, and V1, V2, V3, etc., are the input voltages with their respective resistors R1, R2, R3, etc. Assuming equal resistances for simplicity, the output voltage for inputs of 1.2 V, -0.5 V, and 2.4 V would be the negative sum of these inputs, resulting in -6.2 V.

Question 4

Figure 19-3 -If V_IN= 70 V_P in Figure 19-3, the output voltage at f_CO equals ________. A) 49.5 V_P B) 0 V_P C) 13 V_P D) 44.2 V_P

Accepted Answer

The output voltage is a percentage of the peak supply voltage (V_P), and given that 70% (from the equation) is the correct operation point, the output voltage at the specified condition would be 49.5% of V_P, which corresponds to choice A.

Question 5

The output of an op-amp differentiator depends on the values of ________ and ________. A) R_IN, C_F B) C_IN, C_F C) C_IN, R_F D) R_IN, R_F

Accepted Answer

The output of an op-amp differentiator depends on the values of the capacitor (C) and the resistor (R).

Question 6

Figure 18-1 -If R_f = 1.2 M? and A_V = 120 in Figure 18-1(c), R_i equals ________. A) 100 k? B) 120 ? C) 1 k? D) 10 k?

Accepted Answer

The voltage gain (A_V) of an inverting amplifier is given by the formula A_V = -R_f/R_i. Given A_V = 120 and R_f = 1.2 MΩ, solving for R_i gives R_i = R_f/A_V = 1.2 MΩ / 120 = 10 kΩ.

Question 7

Figure 18-1 -V_RF equals ________ in Figure 18-1(c). A) V_CC B) V_RI C) V_IN D) V_OUT

Accepted Answer

The answer of Figure 18-1 -V_RF equals ________ in...

Question 8

Figure 18-1 -If R_f = 150 k? and R_i = 2.2 k? in Figure 18-1(c), the voltage gain equals ________. A) -69.2 B) -68.2 C) -1 D) infinite

Accepted Answer

The answer of Figure 18-1 -If R_f = 150...

Question 9

Figure 18-1 -If R_f = 1.2 M? and R_i = 47 k? in Figure 18-1(b), the voltage gain equals ________. A) 25 B) 26 C) 26.5 D) 25.5

Accepted Answer

The answer of Figure 18-1 -If R_f = 1.2...

Question 10

Figure 18-1 -If R_f= 100 k? and A_V = (-833) in Figure 18-1(c), R_i equals ________. A) 10 k? B) 1 k? C) 100 k? D) 120 ?

Accepted Answer

The answer of Figure 18-1 -If R_f= 100 k?...

Question 11

Figure 18-1 -If R_f = 5 k? and R_i = 10 k? in Figure 18-1(c), the voltage gain equals ________. A) -5 B) -2 C) 0 D) -0.5

Accepted Answer

The answer of Figure 18-1 -If R_f = 5...

Question 12

Voltage gain can be found by A_V = V_IN ÷ V_OUT

Accepted Answer

The answer of Voltage gain can be found by A_V...

Question 13

On transistor spec sheet, the key difference between ?_DC and ?_DC is that: A) ?_DC represents I_C/I_B; ?_DC represents I_C/I_E. B) ?_DC represents I_E/I_C; ?_DC represents I_B/I_C. C) ?_DC represents I_E/I_C; ?_DC represents I_C/I_E. D) ?_DC represents I_C/I_B; ?_DC represents I_B/I_c.

Accepted Answer

The answer of On transistor spec sheet, the key difference...

Deck 6: Basic Op-Amp Circuits, Special-Purpose Op-Amp Circuits, the Operational Amplifier, Transistors and Applications