Abstract
It is interesting to find the equivalent resistance between two nodes of an infinite electrical network. In this paper, we consider an infinite electrical network that can be described as a series of squares whose edges are resistors with resistance $R$ and whose corresponding vertices are joined successively by resistors with resistance $R$ as well. Our major work is to find the equivalent resistance between the diagonal vertices of the base square of this infinite network. First, we apply the techniques of balanced bridges and symmetry of voltages to convert each iteration of the network to a parallel circuit that includes the previous iteration. Then, we evaluate the equivalent resistance of each iteration of the network and derive a recursive sequence of equivalent resistances with iterations. After that, we prove that the recursive sequence is convergent using the contraction theorem in real analysis. Finally, we claim that the limit of the recursive sequence is the equivalent resistance of the infinite network.
Highlights
The first thorough mathematical description of electrical circuits goes back to Gustav Kirchhoff [5]
We attempt to find the equivalent resistance between nodes a and b using this planar network
By adding an additional square with resistors of resistance R for each edge, and connecting the vertices of that square, via a resistor of resistance R as well, to the corresponding vertices of the nth network, we have constructed the (n + 1)th network as depicted in Figure 5 and Rn+1 is the resistance between the nodes a and b in the (n + 1)th network
Summary
The first thorough mathematical description of electrical circuits goes back to Gustav Kirchhoff [5]. Important question is determining the equivalent resistance between two nodes of finite or infinite electrical networks. Many work has been done on finding equivalent resistance of different infinite electrical networks; see [1, 2, 3, 4, 9].
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