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Perspective: Sloppiness and emergent theories in physics, biology, and beyond

Cornell Affiliated Author(s)

Author

M.K. Transtrum
B.B. Machta
K.S. Brown
B.C. Daniels
C.R. Myers
J.P. Sethna

Abstract

Large scale models of physical phenomena demand the development of new statistical and computational tools in order to be effective. Many such models are "sloppy," i.e., exhibit behavior controlled by a relatively small number of parameter combinations. We review an information theoretic framework for analyzing sloppy models. This formalism is based on the Fisher information matrix, which is interpreted as a Riemannian metric on a parameterized space of models. Distance in this space is a measure of how distinguishable two models are based on their predictions. Sloppy model manifolds are bounded with a hierarchy of widths and extrinsic curvatures. The manifold boundary approximation can extract the simple, hidden theory from complicated sloppy models. We attribute the success of simple effective models in physics as likewise emerging from complicated processes exhibiting a low effective dimensionality. We discuss the ramifications and consequences of sloppy models for biochemistry and science more generally. We suggest that the reason our complex world is understandable is due to the same fundamental reason: simple theories of macroscopic behavior are hidden inside complicated microscopic processes. © 2015 Author(s).

Date Published

Journal

Journal of Chemical Physics

Volume

143

Issue

1

URL

https://www.scopus.com/inward/record.uri?eid=2-s2.0-84942866194&doi=10.1063%2f1.4923066&partnerID=40&md5=1f8b9e8279cbf77019fed55c57091c7a

DOI

10.1063/1.4923066

Research Area

Group (Lab)

Christopher Myers
James Sethna Group

Funding Source

DMR 1312160
IOS 1127017

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