Complexity Explorer Santa Few Institute

NetLogo:

• Download NetLogo
• Hints for downloading NetLogo (if you're having problems)
• Getting started with NetLogo (pdf)
• Netlogo Users Manual
• NetLogo Behavior Space Tutorial

Unit 1 Models:

• Ant1.nlogo
• Ant2.nlogo
• AntsNew.nlogo
• OneAnt.nlogo
• MultipleAnts.nlogo

Unit 2 Models:

• SimplePopulationGrowth.nlogo
• LogisticModel.nlogo
• LogisticMap.nlogo
• SensitiveDependence.nlogo
• LogisticMapBifurcationDiagramExplorer.nlogo
• SineMap.nlogo

Unit 3 Models:

• KochCurve.nlogo
• ExamplesOfFractals.nlogo
• BoxCountingDimension.nlogo
• BoxCountingApplied.zip
• LSystems.nlogo

Unit 4 Models:

• SlotMachine.nlogo
• CoinFlipInformationContent.nlogo
• TextInformationContent.nlogo
• LogisticMapInformationContent.nlogo

Unit 5 Models:

• RobbyGA.nlogo
• CommonSelectionMethods.pdf (for Advanced-Level Homework)

Unit 6 Models:

• Mini-Life.nlogo (note that this version does not show the "green" updates shown in the vidoes)
• GameOfLife.nlogo
• ElementaryCAs.nlogo
• Link to Edge of Chaos Applet

Unit 7 Models:

• Note that the Flocking, Fireflies, and Ants NetLogo models are in the Models Library:  go to the Biology section. 
• FirefliesWithEntropy.nlogo
• FlockingWithEntropy.nlogo

Unit 8 Models:

• PD-Two-Person-Iterated.nlogo

• PD-N-Person-Iterated.nlogo
• El-Farol.nlogo

Unit 9 Models:

• SmallWorldNetworks.nlogo
• preferential-attachment.nlogo (from the NetLogo Models Library)
• ZipfsLaw.nlogo

Unit 10

• PowerLawCalculator.nlogo

Optional Readings:

General:

• M. Mitchell, Complexity:  A Guided Tour.  Parts of the course will roughly follow this book.  The book is a useful companion to the course, but is not required for taking this course.

Unit 1: What is Complexity?

• W. Weaver, Science and complexity. American Scientist, 36: 536-544, 1948.   A classic article by an influential 20th century scientists/mathematician, on why science should focus on complex systems. 
• S. Lloyd, Measures of complexity: A non-exhaustive list. IEEE Control Systems Magazine, 7-8, August, 2001.   A list of some mathematical measures of complexity, though without much explanation of what they mean.

Unit 2: Dynamics and Chaos

• L. Kadanoff, Chaos: A view of complexity in the physical sciences. In From Order to Chaos: Essays: Critical, Chaotic, and Otherwise, 1993.   A relatively non-technical discussion of the logistic map, and other issues in the study of chaos.
• M. Feigenbaum, Universal behavior in nonlinear systems. Los Alamos Science, 1, 1980, pp. 4-27.  A more thorough and technical, though very readable, discussion of the logistic map and related systems by the scientist who made many of the discoveries described here. 
• J. Garland and L. Bradley, On the importance of nonlinear modeling in computer performance prediction

Unit 3: Fractals

• Fractal Explorer. An on-line book and other resources for learning about fractals.
• B. Mandelbrot, The Fractal Geometry of Nature, W.H. Freeman and Co. New York (1983).
• N. Lesmoir-Gordon and R. Edney, et al. Introducing Fractal Geometry, Icon Books Ltd. (2000).
• M. Schroeder, Fractals, Chaos, Power Laws. W. H. Freeman and Co. (1991)
• C. Brown and L. Liebovitch, Fractal Analysis, Series: Quantitative Applications in the Social Sciences, Sage Publications Inc. (2010).

Unit 4: Information, Order, and Randomness

• Shannon, C.E. (1948), A Mathematical Theory of Communication, Bell System Technical Journal, 27, pp. 379–423 & 623–656, July & October, 1948.  Shannon's original article is tough going in places but is available online here.
• R.V.L. Hartley, Transmission of Information, Bell System Technical Journal, July 1928
• J. L. Lebowitz, Boltzmann's entropy and time's arrow. A semi-popular article for people who want to read further about the issues in Unit 4.
• S. Carroll, From Eternity to Here: The Quest for the Ultimate Theory of Time. A fascinating (if long) book that will bring you up-to-date on current views in physics about the nature of time.
• T. D. Schneider, Information Theory Primer. A nice, brief primer on Shannon information; readable if you are comfortable with exponents, logarithms, summation signs, and such. Geared towards biologists, so uses genetics as an example.
• James Gleick, The Information: A History, a Theory, a Flood, New York: Pantheon, 2011.  For general audiences.
• Thomas M. Cover, Joy A. Thomas. Elements of information theory. New York: Wiley-Interscience, 1991.  A more advanced textbook on information theory.

Unit 5: Genetic Algorithms

• There are many excellent online tutorials on genetic algorithms, and several good free software packages.
• Chapter 9 in Complexity:  A Guided Tour, covers some of the same material covered in the lectures for this unit.
• Robby the Robot code in C.
• Link to Karl Sims' papers on evolving computer graphics and virtual creatures.
• J. H. Holland.  Adaptation in Natural and Artificial Systems.   MIT Press, 1992.  John Holland's classic book, originally published in 1975, that sets out the theoretical basis for genetic algorithms. 
• K. De Jong, Evolutionary Computation.  MIT Press, 2002.  Somewhat technical textbook on genetic algorithms and other evolutionary computation techniques.
• M. Mitchell, An Introduction to Genetic Algorithms.  MIT Press, 1996.  Older, fairly short textbook on genetic algorithms

Unit 6: Cellular Automata

• J. Conway, "What is Life?" Chapter 25 in Berlekamp, E. R.; Conway, J. H.; and Guy, R. K., Winning Ways for Your Mathematical Plays, Vol. 2: Games in Particular 
• W. Poundstone, The Recursive Universe:  Cosmic Complexity and the Limits of Scientific Knowledge.  An entertaining and enlightening popular science book that tackles big questions about the universe by looking at Conway's Game of Life.
• Elementary Cellular Automaton from mathworld.wolfram.com
• Website for A New Kind of Science

• M. Mitchell, Review of A New Kind of Science
• M. Mitchell, Computation in Cellular Automata: A Selected Review
• Mitchell, M., Crutchfield, J. P., and Das, R. Evolving cellular automata to perform computations: A review of recent work

Unit 7: Models of Self-Organization

• S. Camazine et al., Self-Organization in Biological Systems.  Princeton University Press, 2001.
• S. Strogatz, Sync: How Order Emerges From Chaos In the Universe, Nature, and Daily Life.  Hyperion, 2003.
• E. Yong, How the science of swarms can help us fight cancer and predict the future. Wired, 03.19.13.
• C. W. Reynolds, Flocks, herds, and schools:  A distributed behavioral model.  ACM SIGGRAPH Computer Graphics, 1987.
• D. M. Gordon, The regulation of foraging activity in Red Harvester ant colonies. 
• D. M. Gordon, Interaction patterns and task allocation in ant colonies.

Unit 8: Models of Self-Organization and Cooperation in Social Systems

• R. Axlerod, The Evolution of Cooperation. New York: Basic Books, 1984.
• R. Axelrod, The Complexity of Cooperation. Princeton University Press, 1997. 
• M. Nowak, Five rules for the evolution of cooperation. 
• B. Hayes, New dilemmas for the prisoner. American Scientist
• T. C. Schelling, Dynamic models of segregation.
• B. Hayes, The math of segregation.
• W. B. Arthur, Inductive reasoning and bounded rationality (the El Farol problem).
• W. B. Arthur, Complexity economics:  A different framework for economic thought.
• J. D. Farmer, Economics needs to treat the economy as a complex system.

Unit 9: Networks

• D. J. Watts and S. H. Strogatz,  Collective dynamics of 'small-world' networks.
• A. L. Barabasi and R. Albert, Emergence of scaling in random networks.
• M. E. J. Newman, Networks: An Introduction.
• M. E. J. Newman, Structure and function of complex networks.
• D. Easley and J. Kleinberg, Networks, Crowds, and Markets.
• D. J. Watts, Six degrees:  The science of a connected age.
• A. L Barabasi, Linked:  The new science of networks.
• D. J. Watts, "Too complex to exist", Boston Globe, June 14, 2009.

Unit 10: Scaling in Biology and Society

• M. E. J. Newman, Power laws, Pareto distributions, and Zipf's law.
• G. B. West and J. H. Brown, The origin of allometric scaling laws in biology from genomes to ecosystems: Towards a quantitative unifying theory of biological structure and organization.
• G. B. West et al., The fourth dimension of life:  Fractal geometry and allometric scaling of organisms.
• P. S. Agutter and D. N. Wheatley, Metabolic scaling:  Consensus or controversy?
• Mathbench, The 3/4 Law  (Very nice, relatively nontechnical overview)
• L. M. A. Bettencourt et al., Growth, innovation, scaling, and the pace of life in cities. 
• L. M. A. Bettencourt, The origins of scaling in cities.