Answer:
Step-by-step explanation:
Given two resistor 5.0 Ω and 9.0 Ω connected on parallel
Let R1 = 5Ω, R2 = 9Ω
Equivalent of parallel connection
1/Req = 1/R1 + 1/R2
1/Req = 1/5 + 1/9
1/Req = 14/45
Then, Req(12) = 45/14 = 3.21 Ω
Req(12) = 3.21 Ω
Another 4.0 Ω resistor is connected in series to their equivalent
Let R3 = 4Ω
Total equivalent resistance
Req = R1 + R3
Req = Req(12) + R3
Req = 3.214 + 4
Req = 7.214 Ω
A voltage of 6V is connect across the terminal series connection
Then, since equivalent resistance is 7.214Ω, we can apply ohms law, to know the current that flows in the circuit
V = iR
V = Ieq × Req
6 = Ieq × 7.214
Ieq, = 6/7.214
Ieq = 0.832 A
This is the total current that flows in the circuit, since R3 is in series with the combination of R2 and R1, then, the same current flows in R3 and the combination of R1 and R2
So, R1 and R2, will have to share the currents Ieq,
So, using current divided rule to find currents in R2
I2 = R1/(R1+R2) × Ieq
I2 = 5/(5+9) × 0.832
I2 = 0.296
I2 ≈ 0.3 Amps
Check attachment for circuit diagram and another method