A) 4
B) 3
C) 2
D) 1
Correct Answer: A
Solution :
[a] Let resistances be\[{{R}_{1}}\]and\[{{R}_{2}}\], then equivalent of these two is given by, |
\[S={{R}_{1}}+{{R}_{2}}\] |
and \[P=\frac{{{R}_{1}}{{R}_{2}}}{{{R}_{1}}+{{R}_{2}}}\] |
\[\therefore \]\[({{R}_{1}}+{{R}_{2}})=\frac{n\times {{R}_{1}}{{R}_{2}}}{{{R}_{1}}+{{R}_{2}}}\] (from\[S=nP\]) |
\[\Rightarrow \] \[{{({{R}_{1}}+{{R}_{2}})}^{2}}=n{{R}_{1}}{{R}_{2}}\] |
\[\Rightarrow \] \[n=\left[ \frac{R_{1}^{2}+R_{2}^{2}+2{{R}_{1}}{{R}_{2}}}{{{R}_{1}}{{R}_{2}}} \right]\] |
\[=\left[ \frac{{{R}_{1}}}{{{R}_{2}}}+\frac{{{R}_{2}}}{{{R}_{1}}}+2 \right]\] (i) |
We know, |
Arithmetic mean \[\ge \] Geometric mean |
\[\frac{\frac{{{R}_{1}}}{{{R}_{2}}}+\frac{{{R}_{2}}}{{{R}_{1}}}}{2}\ge \sqrt{\frac{{{R}_{1}}}{{{R}_{2}}}\times \frac{{{R}_{2}}}{{{R}_{1}}}}\] |
\[\Rightarrow \] \[\frac{{{R}_{1}}}{{{R}_{2}}}+\frac{{{R}_{2}}}{{{R}_{1}}}\ge 2\] |
So,\[n\](minimum value)\[=2+2=4\] [from Eq. (i)] |
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