The application of finite-differenceequations in the solution of repetitive multiloop resistive circuits in one-and two-dimensional configurations is discussed in both finite and infinite cases. The technique of solution involves only ordinary algebra and trigonometry. Yet one can see the emergence of simple orthogonal functions and the finite-difference approximations of the Cauchy-Riemann equations and Laplace's equation.Boundary-value problems can be presented and understood at a simple level of physics and mathematics. Such repetitive structures can serve as discrete approximative models for various physical properties of continuous media. The implications for the teaching of boundary-value problems in electricity are brought out.
%0 Journal Article
%1 lavatelli72
%A Lavatelli, Leo
%D 1972
%J American Journal of Physics
%K circuit effective.resistance network physics resistor
%N 9
%P 1246--1257
%R 10.1119/1.1986809
%T The Resistive Net and Finite-Difference Equations
%V 40
%X The application of finite-differenceequations in the solution of repetitive multiloop resistive circuits in one-and two-dimensional configurations is discussed in both finite and infinite cases. The technique of solution involves only ordinary algebra and trigonometry. Yet one can see the emergence of simple orthogonal functions and the finite-difference approximations of the Cauchy-Riemann equations and Laplace's equation.Boundary-value problems can be presented and understood at a simple level of physics and mathematics. Such repetitive structures can serve as discrete approximative models for various physical properties of continuous media. The implications for the teaching of boundary-value problems in electricity are brought out.
@article{lavatelli72,
abstract = {The application of finite-differenceequations in the solution of repetitive multiloop resistive circuits in one-and two-dimensional configurations is discussed in both finite and infinite cases. The technique of solution involves only ordinary algebra and trigonometry. Yet one can see the emergence of simple orthogonal functions and the finite-difference approximations of the Cauchy-Riemann equations and Laplace's equation.Boundary-value problems can be presented and understood at a simple level of physics and mathematics. Such repetitive structures can serve as discrete approximative models for various physical properties of continuous media. The implications for the teaching of boundary-value problems in electricity are brought out.},
added-at = {2016-04-24T14:50:00.000+0200},
author = {Lavatelli, Leo},
biburl = {https://www.bibsonomy.org/bibtex/2bb35b872427781b07632ba3bb7ab2623/ytyoun},
doi = {10.1119/1.1986809},
eid = {1246},
interhash = {71d82ef1447ae733893dce368342f39a},
intrahash = {bb35b872427781b07632ba3bb7ab2623},
journal = {American Journal of Physics},
keywords = {circuit effective.resistance network physics resistor},
number = 9,
pages = {1246--1257},
timestamp = {2016-04-25T14:53:56.000+0200},
title = {The Resistive Net and Finite-Difference Equations},
volume = 40,
year = 1972
}