Chapter 26 Problem 40

Problem

Resistance is futile!

Twelve resistors, each of resistance R, are connected as the edges of a cube. Determine the equivalent resistance

(a) between points a and b, the ends of a side;

(b) between points a and c, the ends of a face diagonal;

(c) between points a and d, the ends of the volume diagonal.

[Hint: Apply an emf and determine currents; use symmetry at junctions.]

solution

(a)

Insert a probe battery between points (a) and (b). Let's label the current drawn from this probe battery as I

This setup has a symmetry plane between abed, so the current split at junction a will be ${\displaystyle I=I_{1}+I_{1}+I_{2}}$

Another symmetry is that the afhe plane is the mirror cdgb (since one has the current I entering, and the other has the current leaving) thus we have the same currents in erverse directions in those planes.

The 6 equations in the symmetry reduced cube is:

1. ${\displaystyle I=2I_{1}+I_{2}}$
2. ${\displaystyle I_{3}+I_{4}=I_{1}}$
3. ${\displaystyle I_{5}=2I_{4}}$
4. ${\displaystyle 0=-2I_{1}R-I_{3}R+I_{2}R}$
5. ${\displaystyle 0=-2I_{4}R-I_{5}R+I_{3}R}$
6. ${\displaystyle 0={\mathcal {E}}-I_{2}R}$

6 equations and 6 unknowns, so we start solving:

1. ${\displaystyle I=2(I_{3}+I_{4})+{\frac {\mathcal {E}}{R}}}$ (2 and 6 in 1)
2. ${\displaystyle 0=-2(I_{3}+I_{4})R-I_{3}R+{\frac {\mathcal {E}}{R}}R=-2I_{4}R-3I_{3}R+{\mathcal {E}}}$ (2 and 6 in 4)
3. ${\displaystyle 0=-2I_{4}R-2I_{4}R+I_{3}R=-4I_{4}R+I_{3}R}$ (3 in 5)

${\displaystyle I_{3}=4I_{4}}$ ( solution of 3)

${\displaystyle 0=-2I_{4}R-3(4I_{4})R+{\mathcal {E}}\rightarrow I_{4}={\frac {\mathcal {E}}{14R}}}$ (previous into 2)

${\displaystyle I=2(4I_{4})+2(I_{4})+{\frac {\mathcal {E}}{R}}=10I_{4}+{\frac {\mathcal {E}}{R}}={\frac {10{\mathcal {E}}}{14R}}+{\frac {\mathcal {E}}{R}}={\frac {12{\mathcal {E}}}{7R}}}$ (previous into 1)

${\displaystyle R_{\textrm {eq}}={\frac {\mathcal {E}}{I}}={\frac {7}{12}}R}$

(b)

Insert a probe battery between points (a) and (c). Let's label the current drawn from this probe battery as I

This ehgb is a symmetry (inversion) plane afcd is a symmmetry plane.

1. ${\displaystyle I=2I_{1}+I_{2}}$ (Junction rule at a)
2. ${\displaystyle 2I_{3}=I_{2}}$ (Junction rule at d)
3. ${\displaystyle 0=-2I_{2}R+{\mathcal {E}}}$ (loop rule around abca)
4. ${\displaystyle 0=-2I_{2}R-2I_{3}R+2I_{1}R}$ (loop rule around afgdcha)

Then

${\displaystyle I_{2}={\frac {\mathcal {E}}{2R}}}$

${\displaystyle I_{3}={\frac {I_{2}}{2}}={\frac {\mathcal {E}}{4R}}}$

${\displaystyle I_{1}=I_{2}+I_{3}={\frac {\mathcal {E}}{2R}}+{\frac {\mathcal {E}}{4R}}={\frac {3{\mathcal {E}}}{4R}}}$

${\displaystyle I=2I_{1}+I_{2}=2\left({\frac {3{\mathcal {E}}}{4R}}\right)+{\frac {\mathcal {E}}{2R}}={\frac {2{\mathcal {E}}}{R}}}$

${\displaystyle R_{\textrm {eq}}={\frac {\mathcal {E}}{I}}={\frac {1}{2}}R}$

(c)

Insert a probe battery between points (a) and (d). Let's label the current drawn from this probe battery as I

1. ${\displaystyle I=3I_{1}}$ (junction rule at a)
2. ${\displaystyle I_{1}=2I_{2}}$ (junction rule at b)
3. ${\displaystyle 0=-2I_{1}R-I_{2}R+{\mathcal {E}}}$ (loop rule abgda)

${\displaystyle 0=-2I_{1}R-{\frac {1}{2}}I_{1}R+{\mathcal {E}}\rightarrow I_{1}={\frac {2{\mathcal {E}}}{5R}}}$

${\displaystyle I=3I_{1}={\frac {6{\mathcal {E}}}{5R}}}$

${\displaystyle R_{\textrm {eq}}={\frac {\mathcal {E}}{I}}={\frac {5}{6}}R}$