In the voltage-divider circuit shown in the figure, the no-load value of Vo is 4 V. When the load resistance is attached across the terminals a and b, Vo drops to 3 V. Find the Load Resistance value * E 40 Ω a + 20 V { R2 Vo { RL b
In the voltage-divider circuit shown in the figure, the no-load value of Vo is 4 V. When the load resistance is attached across the terminals a and b, Vo drops to 3 V. Find the Load Resistance value * E 40 Ω a + 20 V { R2 Vo { RL b
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Circuit analysis
![In the voltage-divider circuit shown in the figure, the no-load value of Vo is 4 V. When the load
resistance is attached across the terminals a and b, Vo drops to 3 V. Find the Load Resistance
value * E
40 N
a
+
20 V
R2 Vo
RL
b
O 10 Ohm
O 20 Ohm
80 Ohm
O 24 Ohm
O 12 Ohm
O 240 Ohm
O 100 Ohm
O 1 kilo ohm
O 16 Ohm
180 Ohm](/v2/_next/image?url=https%3A%2F%2Fcontent.bartleby.com%2Fqna-images%2Fquestion%2F609a9d96-6476-4348-a201-12bbfee69916%2F92cb0ece-7d0f-41df-b316-e6cf107f23ac%2Fg2876a8_processed.png&w=3840&q=75)
Transcribed Image Text:In the voltage-divider circuit shown in the figure, the no-load value of Vo is 4 V. When the load
resistance is attached across the terminals a and b, Vo drops to 3 V. Find the Load Resistance
value * E
40 N
a
+
20 V
R2 Vo
RL
b
O 10 Ohm
O 20 Ohm
80 Ohm
O 24 Ohm
O 12 Ohm
O 240 Ohm
O 100 Ohm
O 1 kilo ohm
O 16 Ohm
180 Ohm
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