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dc.contributor.advisorTobochnik, Jan, 1953-
dc.contributor.advisorMacMillan, Amy
dc.contributor.authorSeid, Bobby
dc.date.accessioned2015-10-17T18:30:12Z
dc.date.available2015-10-17T18:30:12Z
dc.date.issued2011
dc.identifier.urihttp://hdl.handle.net/10920/30004
dc.description75 p.en_US
dc.description.abstractThis paper details the methods, models, and results of this two part project. The premise of this project is that the information flow between two points in a network can be analogous to the current flow between those two points, given the voltage of those two points and the resistance of the link connecting those two points. The first part of the project was computing the critical exponents for the percolation conductance models. Computing these critical exponents would show if our computational methods were precise, building the foundation for the computational methods used for the second part of the project. The second part was calculating current flow distributions for the Small World Network model. The methods we used involved computational relaxation methods based on Kirchhoff's Current Law and Ohm's Law, applied to a large random resistor network for several iterations. The results from the percolation model indicated that our computational methods were correct, since the critical exponents that were calculated coincided with other researchers' results. The current distribution results revealed that the shape of the current distribution was not affected by the parameters of the system. Each current distribution was more or less a normal Gaussian shaped bell curve. This led us to conclude that the Small World Network system exhibits behavior similar to that of the Central Limit Theorem.en_US
dc.format.mimetypeapplication/pdf
dc.language.isoen_USen_US
dc.relation.ispartofKalamazoo College Physics Senior Individualized Projects Collection
dc.rightsU.S. copyright laws protect this material. Commercial use or distribution of this material is not permitted without prior written permission of the copyright holder. All rights reserved.
dc.titleCurrent Distributions of Resistor Networks : An Analogy to Information Flowen_US
dc.typeThesisen_US
KCollege.Access.ContactIf you are not a current Kalamazoo College student, faculty, or staff member, email dspace@kzoo.edu to request access to this thesis.


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  • Physics Senior Individualized Projects [309]
    This collection includes Senior Individualized Projects (SIP's) completed in the Physics Department. Abstracts are generally available to the public, but PDF files are available only to current Kalamazoo College students, faculty, and staff.

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