Revisiting ``scale-free'' networks

Bioessays 27 (10):1060-1068 (2005)
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Abstract

Recent observations of power-law distributions in the connectivity of complex networks came as a big surprise to researchers steeped in the tradition of random networks. Even more surprising was the discovery that power-law distributions also characterize many biological and social networks. Many attributed a deep significance to this fact, inferring a “universal architecture” of complex systems. Closer examination, however, challenges the assumptions that (1) such distributions are special and (2) they signify a common architecture, independent of the system's specifics. The real surprise, if any, is that power-law distributions are easy to generate, and by a variety of mechanisms. The architecture that results is not universal, but particular; it is determined by the actual constraints on the system in question. BioEssays 27:1060–1068, 2005. © 2005 Wiley Periodicals, Inc.

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10.1002/bies.20294

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Citations of this work

Tracing Organizing Principles: Learning from the History of Systems Biology.Sara Green & Olaf Wolkenhauer - 2013 - History and Philosophy of the Life Sciences 35 (4):553-576.
Can biological complexity be reverse engineered?Sara Green - 2015 - Studies in History and Philosophy of Science Part C: Studies in History and Philosophy of Biological and Biomedical Sciences 53:73-83.

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Making Sense of Life.Evelyn Fox Keller - 2002 - Cambridge: Harvard University Press.

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