Volume 6, Issue 6, December 2018, Page: 142-145
A General n-Port Network’s Equivalent Current Sources Theorem
Runsheng Liang, Department of Electrical Engineering, Wuhan University of Science and Technology, Wuhan, China
Received: Oct. 16, 2018;       Accepted: Nov. 16, 2018;       Published: Dec. 24, 2018
DOI: 10.11648/j.jeee.20180606.11      View  35      Downloads  36
Abstract
In this paper a general n-port network’s equivalent current theorem has been derived out, for n = 1, 2…. the traditional Norton’s Theorem is only a special case of it for n=1. When an n-port passive linear time-invariant network is connected to another n-port linear time-invariant network which contained sinusoidal sources with same frequency, this theorem provides a new way to calculate the port-current of the n-port passive network. But the short-port currents of the n-port network contained sinusoidal sources must be known at first. In sinusoidal networks, currents are vector quantity or complex quantity, including magnitude and phase angle. Ammeter can only be used to measure the magnitude of the current, not including its phase angle. So it is impossible to get the short-port currents by the short-port experiment. Moreover the short-port experiment may cause some dangerous events. So a special method to get the short-port currents is introduced in this paper, First to find out the open-port voltage vector ( including magnitude and phase angle), by measuring the voltages magnitude between some two points of the open-port with a voltmeter and by drawing a series of voltage vector triangles that one side vector is the sum of other two side vectors , if the phase angle of one side vector in a triangle is known, the phase angles of the other side vectors in the same triangle can be decided. In the first triangle, the first open-port voltage vector is contained, its phase angle can be assigned to be zero, then the phase angles of the other two voltage vectors in the first triangle can be decided. In the second triangle, one of the two above voltage vectors is contained, then the phase angles of the other two voltage vectors in the second triangle can be decided. Thus go on step by step, all the open-port voltage vectors can be obtained. And the open-port voltage complex matrix has been obtained. The equation related the short-port current complex matrix and the open-port voltage complex matrix has been derived out in this paper. So the short-port current complex matrix can be obtained.
Keywords
Admittance Matrix, Equivalent Current Sources, Short-port Currents
To cite this article
Runsheng Liang, A General n-Port Network’s Equivalent Current Sources Theorem, Journal of Electrical and Electronic Engineering. Vol. 6, No. 6, 2018, pp. 142-145. doi: 10.11648/j.jeee.20180606.11
Copyright
Copyright © 2018 Authors retain the copyright of this article.
This article is an open access article distributed under the Creative Commons Attribution License (http://creativecommons.org/licenses/by/4.0/) which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
Reference
[1]
RS Liang: A General n-Port Network’s Reciprocity Theorem, Journal of Wuhan Iron and Steel Intitute, VOL.24, NO.3, September 1985.
[2]
W. K. Cheng and RS Liang: A General n-Port Network’s Reciprocity Theorem, IEEE on education, VOL.33, NO.4, November 1990.
[3]
RS Liang: A General n-Port Network’s Equivalent voltage Source Theorem Hans Open Journal of Circuits and Systems. VOL.5, NO.2, June 2016.
[4]
RS Liang: A General n-Port Network’s Maximum Transfer Power Theorem Hans Open Journal of Circuits and Systems, VOL.5, NO.2, June 2016.
Browse journals by subject