Question 18.2: Three Resistors in Parallel GOAL Analyze a circuit having re...

(a) Find the current in each resistor.
Apply Ohm’s law, solved for the current I delivered by the battery to find the current in each resistor:

I_{1}={\frac{\Delta V}{R_{1}}}={\frac{18\,\mathrm{V}}{3.0\,\Omega}}=\,{{6.0\,{\mathrm{A}}}}

I_{2}={\frac{\Delta V}{R_{2}}}={\frac{18\;\mathrm{V}}{6.0\,\Omega}}=\ {3.0\,\mathrm{A}}

I_{\mathrm{3}}={\frac{\Delta V}{R_{\mathrm{3}}}}={\frac{18\,\mathrm{V}}{9.0\,\Omega}}=2.0~A

(b) Calculate the power delivered to each resistor and the total power.
Apply P = I²R to each resistor, substituting the results from part (a):

3\Omega\colon P_{1}=I_{1}^{2}R_{1}=(6.0\mathrm{~A})^{2}(3.0\Omega)=\mathrm{~110~W}

6\Omega\colon P_{2}=I_{2}^{\ 2}R_{2}=(3.0\mathrm{~A})^{2}(6.0\Omega)\,=\,54\mathrm{~W}

9\ \Omega:P_{3}=I_{3}{}^{2}R_{3}=(2.0\ \mathrm{A})^{2}(9.0\ \Omega)\,=\,36\ \mathrm{W}

Sum to get the total power:

P_{\mathrm{tot}}=110~{\mathrm{W}}+54~{\mathrm{W}}+36~{\mathrm{W}}=\textstyle{{2.0}}\times10^{2}~{\mathrm{W}}

(c) Find the equivalent resistance of the circuit.
Apply the reciprocal-sum rule, Equation 18.6:

{\frac{1}{R_{\mathrm{eq}}}}={\frac{1}{R_{1}}}+{\frac{1}{R_{2}}}+{\frac{1}{R_{3}}}

{\frac{1}{R_{\mathrm{eq}}}}={\cfrac{1}{3.0~\Omega}}+{\cfrac{1}{6.0~\Omega}}+{\cfrac{1}{9.0~\Omega}}={\cfrac{11}{18~\Omega}}

R_{\mathrm{eq}}={\frac{18}{11}}~\Omega={1.6}~\Omega

{\frac{1}{R_{\mathrm{eq}}}}={\frac{1}{R_{1}}}+{\frac{1}{R_{2}}}+{\frac{1}{R_{3}}}+…     [18.6]

(d) Compute the power dissipated by the equivalent resistance.
Use the alternate power equation:

P={\frac{(\Delta V)^{2}}{R_{\mathrm{eq}}}}={\frac{(18\,\mathrm{V})^{2}}{1.6\,\Omega}}=\ {{2.0\times10^{2}\,{\mathrm{W}}}}

REMARKS There’s something important to notice in part (a): the smallest 3.0 Ω resistor carries the largest current, whereas the other, larger resistors of 6.0 Ω and 9.0 Ω carry smaller currents. The largest current is always found in the path of least resistance. In part (b) the power could also be found with P = (ΔV)²/R. Note that P_{1} = 108 W, but is rounded to 110 W because there are only two significant figures. Finally, notice that the total power dissipated in the equivalent resistor is the same as the sum of the power dissipated in the individual resistors, as it should be.