Question 1.8: Given three resistors in parallel, where R1 = 3 Ω, R2 = 6 Ω,...

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Given three resistors in parallel, where $R_{1} = 3 Ω , R_{2} = 6 Ω , \text{ and } R_{3} = 2 Ω$ , calculate the parallel equivalent resistor.

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Using Equation (1.43), we obtain

$1 / R_{\text {parallel-equiv }}=1 / R_1+1 / R_2+1 / R_3+\ldots+1 / R_n \text {. }$ (1.43)

$\frac{1}{R_{\text {parallel-equiv }}}=\frac{1}{R_1}+\frac{1}{R_2}+\frac{1}{R_3} \text {, }$ (1.44)

and using the corresponding values for $R_{1} , R_{2} , \text{ and } R_{3}$ , we get that

$1 / R_{\text {parallel-equiv }}=1 / 3+1 / 6+1 / 2 \text {, }$ (1.45)

from where

$R_{\text {equiv }}= 1 \Omega \text {. }$ (1.46)

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