johnsonc007 said:
Still doesn't help. Trying to teach myself via text this due to lack of interaction from professor. Ended up buying the solution online. Would have never seen the setup, still don't follow how it becomes that.
Is 3.5A the correct answer?
For a), by adding a voltage source across the terminals AB, you have a voltage source in parallel with the resistor.
The other two resistors are in series with another, i.e. all current entering BC must exit through CA (and vice versa).
Because the two resistors are in series, you can add up their resistances to get the equivalent resistance (that is, you can replace the 10 and 20 ohm resistors by a single resistor of 30 ohms).
You're then left with the voltage source in parallel with the 15 ohm resistor, in parallel with the 30 ohm resistor. To find the equivalent resistance of two parallels resistors, you use:
\frac{1}{R_{eq}} = \frac{1}{R_{1}} + \frac{1}{R_{2}}
which simplifies to:
R_{eq} = \frac{R_{1}*R_{2}}{R_{1}+R_{2}}
So, R
eq = 15*30 / (30+15) = 10 ohms.
Then, to find the current, you simply apply Ohm's Law: i = V/R = 35/10 = 3.5A.
Does that clear it up for you? If not, which of the above steps don't you follow? It might be easier for you to visualise it as a rectangle (i.e. the AB resistor on the left, BC resistor on the top, AC resistor on the bottom, with nothing on the right line).
