For the above circuit, E1 = 3.57 V, E2 = 5.79 V.
r1 = 0.591 Ω, r2 = 0.781 Ω, R1 = 41.3 Ω, R2 = 65.1 Ω, R3 = 73.3
Ω.
a)Which equation would describe Kirchhoff's Junction Law at the
right junction?
A I1 - I2 = I3
B I1 + I2 = I3
C I1 + I3 = I2
D I1 = I2 + I3
b)Which equation would describe Kirchhoff's Loop Law for the
lower half-loop?
A E2 - I2*r2 - I3*R3 - I3*R1 = 0
B E2 - I2*r2 - I2*R3 - I3*R1 = 0
C E2 - I2*r2 - I2*R3 - I2*R1 = 0
D E2 - I2*r2 - I2*R3 + I3*R1 = 0
c)Which equation would describe Kirchhoff's Loop Law for the
upper half-loop?
A E1 - I1*r1 + I3*R1 - I1*R2 = 0
B E1 - I1*r1 - I3*R1 - I1*R2 = 0
C E1 - I1*r1 - I1*R1 - I1*R2 = 0
D E1 - I1*r1 - I3*R1 - I3*R2 = 0
d)Calculate I1. I2 and I3
For the above circuit, E1 = 3.57 V, E2 = 5.79 V. r1 = 0.591 Ω, r2 = 0.781 Ω, R1 = 41.3 Ω, R2 = 65...
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