I609: Complex Systems Seminar I

Spring 2020

Instructor: Luis M. Rocha, Center for Social and Biomedical Complexity, Luddy School of Informatics, Computing and Engineering and Cognitive Science Program, Indiana University

Class Location and Time: Thursdays, 01:10-3:40 PM, Online

Course Description

Description: A complex system is any system featuring a large number of interacting components (agents, processes, etc.) whose aggregate activity is nonlinear (not derivable from the summations of the activity of individual components) and typically exhibits hierarchical self-organization under selective pressures. The networks of interactions that comprise such systems can be studied separately from or together with the multivariate dynamics that define them. In the former case, the focus is the graph structure of networks which is typically pursued in Network Science, whereas dynamical systems theory focuses on the latter. Understanding networked complex systems is key to solving some of the most vexing problems confronting humankind, from discovering how thoughts and behaviors arise from dynamic brain connections, to detecting and preventing the spread of misinformation or unhealthy behaviors across a population. But the study of complex systems requires an understanding of both structure and dynamics which often interact in non-separable multiple levels where information, selection, and collective dynamics operate. Indeed, modeling network interactions among variables operating at multiple scales is an essential capability for effective interventions in complex systems---such as the dynamic web of cellular processes and genetic regulation, the intricate wiring of the brain, patterns of human behavior, as well as the operation of social groups, natural environments, organizations and economies, and science itself. Across all these systems, mapping, analyzing, modeling, and visualizing underlying networks are indispensable steps toward understanding how they work. The sciences of complexity are also necessarily based on interdisciplinary research so that teams of scientists can most effectively approach both the general characteristics of all these systems as well as the specific methodologies required to measure and model them.

Aims: This seminar is designed to present and discuss the history, methodology and impact of complex systems; we cover key literature as well as recent advances in the field.

Course Evaluation

Students are expected to read and annotate the materials presented, as well as present several of the key readings. Students will also work on a term project or paper. Participation and Discussion: 15%; Lead Discussions: 25%; Term Paper/Project: 60%.

Cybernetics and the Information Turn

Borges, Jorge Luis. [1941]. The Library of Babel.
Borges, Jorge Luis. [1941]. The Garden of Forking Paths .
Brenner, Sydney. [2012]. "History of Science. The Revolution in the Life Sciences". Science 338 (6113): 1427-8.
Brenner, Sydney. [2012]. "Turing centenary: Life's code script. Nature 482 (7386) (February 22): 461-461.
Cobb, Matthew. [2013]. "1953: When Genes Became 'Information'." Cell 153 (3): 503-506.
Gleick, J. [2011]. The Information: A History, a Theory, a Flood. Random House. Chapter 8.
Heims, S.G. [1991]. The Cybernetics Group. MIT Press. Chapters: 1,2, 11, and 12.
Optional

McCulloch, W. and W. Pitts [1943], "A Logical Calculus of Ideas Immanent in Nervous Activity". Bulletin of Mathematical Biophysics 5:115-133.
Searls, David B. [2010]. "The Roots of Bioinformatics". PLoS Computational Biology 6(6): e1000809.

Discussion Lectures: Rocha, L.M. [2021] Borges, Turing Computers, Rocha, L.M. [2021] Information, Rocha, L.M. [2021] Cybernetics, Information Turn, Biocomplexity, Evolution, Von Neumann and Genes

Systems Science, Organization, Prediction, and Limits

Ashby, W.R.[1956]. An Introduction to Cybernetics, Chapman & Hall, London, Chapter 1. Full book available electronically. (Alternative Location)
Klir, G.J. [2001]. Facets of systems Science. Springer. Chapters: 1,2,3, 8, and 11.
Rosen, R. [1986]. "Some comments on systems and system theory". Int. J. of General Systems, 13: 1ó3.
Von Foerster, H., P. M. Mora and L. W. Amiot [1960]. "Doomsday: Friday, November 13, AD 2026." Science 132(3436):1291-5.
Weaver, W. [1948]. "Science and Complexity". American Scientist, 36(4): 536-44. (PMID: 18882675)
Wigner, E.P. [1960], "The unreasonable effectiveness of mathematics in the natural sciences". Richard courant lecture in mathematical sciences delivered at New York University, May 11, 1959. Comm. Pure Appl. Math., 13: 1-14.
Discussion Lectures: Rocha, L.M. [2021] Complex Systems Science Modeling.

Self-Organizing Systems

Ashby, W.R.[1962]. "Principles of the self-organizing system". In: Principles of Self-Organization: Transactions of the University of Illinois Symposium. H. Von Foerster and G. W. Zopf, Jr. (eds.), Pergamon Press: London, UK, pp. 255-278.
Kauffman, S.A. [1984]. "Emergent properties in random complex automata". Physica D: Nonlinear Phenomena 10(1–2):145-156.
Prigogine, I. [1985]. "New Perspectives on Complexity". In: The Science and Praxis of Complexity (United Nations University Press: 1985) 107-118
Optional

Cariani, P. [1992]. "Some epistemological implications of devices which construct their own sensors and effectors". In: Towards a Practice of Autonomous Systems.In F. Varela and P. Bourgine (ed.), MIT Press, Cambridge, Massachusetts.
Kauffman, S.A. [1969]. "Metabolic stability and epigenesis in randomly constructed genetic nets". Journal of Theoretical Biology 22(3):437-467.
Rocha, Luis M. [1998]. "Selected Self-Organization and the Semiotics of Evolutionary Systems". In: Evolutionary Systems: The Biological and Epistemological Perspectives on Selection and Self- Organization. S. Salthe, G. Van de Vijver, and M. Delpos (eds.). Kluwer Academic Publishers, pp. 341-358.
Steinbock, O., Renate Wackerbauer, and Dezső Horváth (2019) "Nonlinear Chemical Dynamics and Its Interdisciplinary Impact: Dedicated to Ken Showalter on the Occasion of his 70th Birthday". Chaos: An Interdisciplinary Journal of Nonlinear Science 29:8
Thomas, R. [1973]. "Boolean formalization of genetic control circuits". Journal of Theoretical Biology. 42(3):563-585.

Second-Order Cybernetics

Cariani, P. [1993]. "To evolve an ear. Epistemological implications of Gordon Pask's electrochemical devices". Systems Research, 10(3):19-33.
Varela, Francisco J.; Maturana, Humberto R.; & Uribe, R. [1974]. "Autopoiesis: the organization of living systems, its characterization and a model". Biosystems 5(4): 187-196.
Optional

Cariani P. [2009]. "On the Importance of Being Emergent. Extended Review of Emergence and Embodiment: New Essays on Second-Order Systems Theory edited by Bruce Clark and Mark B. N. Hanson.Duke University Press, Durham, 2009. Constructivist Foundations. 5(2):86-91.
Pask, G. [1992]. "Different kinds of Cybernetics". In: New Perspectives on Cybernetics. G. Van de Vijver (Ed.), Kluwer Academic Publishers. pp. 11-31.
Rocha, Luis M.[1997]. "Obituary for Professor Gordon Pask." International Journal of General Systems. 26(3): 219-222.
Varela, F.J. [1996]. "The early days of autopoiesis". Systems Research, 13(3):407-416.
Varela, F.J. [1997]. "Patterns of Life: Intertwining Identity and Cognition". Brain and Cognition, 34(1):72-87.

Organization of Complex Systems

Pattee, H.H. [1973]. "The Physical Basis and Origin of Hierarchical Control". In: Hierarchy Theory: The Challenge of Complex Systems. H.H. Pattee (ed.) , New York: G. Braziller, pp.73-108.
Rosen, R. [1987]. "On Complex Systems". European Journal of Operational Research, 30: 129-134.
Simon, H.A. [1962]. "The Architecture of Complexity". Proceedings of the American Philosophical Society, 106: pp. 467-482.
Optional

Lazebnik, Y [2002]. "Can a biologist fix a radio?--Or, what I learned while studying apoptosis". Cancer Cell, 2(3):179-182.
Randall, T.S. [2007]. "Robert Rosen in the Age of Systems Biology". Chemistry & Biodiversity, 4(10):2407 - 2414.
Rosen, R. [1986]. "The Physics of Complexity". Systems Research, 2: 171.

Part II: Current Research

Towards a practice of Complex Systems: Interdisciplinarity and Limits

Editorial Board [2015]. "Mind meld". Nature, 525(7569):289–90.
Ledford, H. [2015]. "How to solve the world’s biggest problems". Nature, 525(7569):308–11.
Schuster, P. (2016). The end of Moore’s law: Living without an exponential increase in the efficiency of computational facilities. Complexity. 21(S1): 6-9. DOI 10.1002/cplx.21824
Van Noorden, R. [2015]. "Interdisciplinary research by the numbers". Nature, 525(7569):306–7.
Wu, L., Wang, D., & Evans, J. A. (2019). Large teams develop and small teams disrupt science and technology. Nature, 566, 378–382.
Optional

Arencibia-Jorge, R., García-García, L. , Galbán-Rodríguez, E., Carrillo-Calvet, H. [2020]. The multidisciplinary nature of COVID-19 research. bioRxiv. 11.23.394312
Gallotti, Riccardo, Giulia Bertagnolli, and Manlio De Domenico (2021). "Unraveling the Hidden Organisation of Urban Systems and Their Mobility Flows." EPJ Data Science 10 (1).
Füllsack, Manfred, Simon Plakolb, and Georg Jäger. "Predicting Regime Shifts in Social Systems Modelled with Agent-Based Methods." Journal of Computational Social Science, May 2020.
Hilbert, M., and P. Lopez. [2011]. "The World's Technological Capacity to Store, Communicate, and Compute Information." Science 332 (6025): 6065.
Iwasaki, A. (2019) Why we need to increase diversity in the immunology research community. Nat Immunol 20, 1085–1088.
Kaushal, A., Altman, R. B. (2019). Wiring minds. Nature, 576(7787), S62-S63.
Margolus, Norman, and Lev B. Levitin. "The maximum speed of dynamical evolution." Physica D: Nonlinear Phenomena 120.1-2 (1998): 188-195.

Evolutionary Systems

Conrad, M. [1990]. "The geometry of evolution.". Biosystems 24: 61-81
Hie, Brian, Ellen D. Zhong, Bonnie Berger, and Bryan Bryson [2021]. "Learning the Language of Viral Evolution and Escape." Science 371 (6526).
Kim, Yoo-Ah, and Teresa M. Przytycka [2021]. "The Language of a Virus." Science 371 (6526).
Lenton, Timothy M., Timothy A. Kohler, Pablo A. Marquet, Richard A. Boyle, Michel Crucifix, David M. Wilkinson, and Marten Scheffer. [2021] "Survival of the Systems." Trends in Ecology and Evolution.
Pattee, H. H. (2009). Response to Jon Umerez’s paper: "Where does Pattee’s "How does a Molecule become a Message?" belong in the history of Biosemiotics?". Biosemiotics, 2(3), 291-302.
Prentiss, Anna Marie [2020]. "Theoretical Plurality, the Extended Evolutionary Synthesis, and Archaeology." Proceedings of the National Academy of Sciences 118 (2).
Rocha LM, Hordijk W. [2005]. "Material representations: From the genetic code to the evolution of cellular automata.". Artificial Life. 11(1-2):189-214.
Szathmáry, E. [2015]. "Toward major evolutionary transitions theory 2.0". Proceedings of the National Academy of Sciences of the United States of America, 112(33): 10104–10111.
Vasas, Vera, Eors Szathmary, and Mauro Santos [2010]. " Lack of evolvability in self-sustaining autocatalytic networks: A constraint on the metabolism-first path to the origin of life. ". Proceedings of the National Academy of Sciences of the United States of America: 0912628107.
Optional

Ball, P. (2016). The Strange Inevitability of Evolution. Nautilus 41.
Bakhtin, Yuri, Mikhail I. Katsnelson, Yuri I. Wolf, and Eugene V. Koonin. [2021] "Evolution in the Weak-Mutation Limit: Stasis Periods Punctuated by Fast Transitions between Saddle Points on the Fitness Landscape." Proceedings of the National Academy of Sciences 118(4).
Conrad M. [1993]. "Adaptability theory as a guide for interfacing computers and human society". Systems Research: 10:1-23.
Danger, G., d’Hendecourt, L. L. S., and Pascal, R. (2020). "On the conditions for mimicking natural selection in chemical systems". Nature Reviews Chemistry, 1-8.
Read, Dwight, and Claes Andersson [2020]. "Cultural Complexity and Complexity Evolution." Adaptive Behavior 28, (5): 329–58.
Fields, Chris, and Michael Levin [2020]. "How Do Living Systems Create Meaning?" Philosophies 5 (4): 36.
Pattee, Howard. (2012). "How Does a Molecule Become a Message?". DOI:10.1007/978-94-007-5161-3_3.
Pigliucci M. [2008]. "Is evolvability evolvable?". Nature reviews. Genetics. 9 (1): 75-82
Rocha LM [2015]. "Biologically-inspired computing, Lecture Notes I-485/585". Indiana University
Schuster, P. [2016]. "Major transitions in evolution and in technology: What they have in common and where they differ". Complexity, (21)4:7-13.
Sigmund, Karl, and Robert D. Holt [2021]. "Toward Ecoevolutionary Dynamics." Proceedings of the National Academy of Sciences 118, (9).
Umerez, J. (2009). "Where Does Pattee’s "How Does a Molecule Become a Message?" Belong in the History of Biosemiotics?". Biosemiotics 2, 269.
Wu, N.C., Otwinowski, J., Thompson, A.J. et al. (2020) Major antigenic site B of human influenza H3N2 viruses has an evolving local fitness landscape. Nat Commun 11, 1233.
Wolf, Yuri I, Mikhail I Katsnelson, and Eugene V Koonin (2018). “Physical Foundations of Biological Complexity.” Proceedings of the National Academy of Sciences of the United States of America 115 (37): E8678–87.

Networks, Systems Biology, and Neo-Cybernetics themes

Bagrow, J. P., Liu, X., & Mitchell, L. [2019]. "Information flow reveals prediction limits in online social activity". Nature Human Behaviour, 3:122-128.
Barrat, Alain, Marc Barthelemy, and Alessandro Vespignani. Dynamical processes on complex networks. Cambridge university press, 2008, pp. 756-59.
Broido, A. D., & Clauset, A. (2019). "Scale-free networks are rare" . Nature Communications, 10(1), 1017.
Holme, P. (2019). "Rare and everywhere: Perspectives on scale-free networks". Nature Communications, 10(1), 1016.
James, R., and Crutchfield, J. (2017). Multivariate Dependence beyond Shannon Information. Entropy, 19(10), 531.
Klamt S, Haus U-U, Theis F. [2010]. "Hypergraphs and cellular networks.". PLoS computational biology 5(5): e1000385
Scheffer, Marten, et al. "Early-warning signals for critical transitions." Nature 461.7260 (2009): 53.
G.T. Zañudo, J., Steinway, S. N., & Albert, R. (2018). Discrete dynamic network modeling of oncogenic signaling: Mechanistic insights for personalized treatment of cancer. Current Opinion in Systems Biology, 9, 1–10.
Optional

Arthur, W.B. [2020] "Algorithms and the Shift in Modern Science." Beijer Discussion Paper 269.
Barman,S., Yung-Keun Kwon, [2020]. A neuro-evolution approach to infer a Boolean network from time-series gene expressions, Bioinformatics, 36:i762–i769
Gates, Alexander J., Rion Brattig Correia, Xuan Wang, and Luis M. Rocha (2021) “The Effective Graph Reveals Redundancy, Canalization, and Control Pathways in Biochemical Regulation and Signaling.” Proceedings of the National Academy of Sciences 118(12): e2022598118.
Leemput, Ingrid A van de, Marieke Wichers, Angélique O J Cramer, Denny Borsboom, Francis Tuerlinckx, Peter Kuppens, Egbert H van Nes, et al. "Critical Slowing down as Early Warning for the Onset and Termination of Depression." Proceedings of the National Academy of Sciences of the United States of America 111, no. 1 (January 2014): 87–92.
Netz, R.R. and Eaton, W.A. (2021). Estimating computational limits on theoretical descriptions of biological cells. Proceedings of the National Academy of Sciences 118 (6) e2022753118; DOI: 10.1073/pnas.2022753118
Oka, R. C., Kissel, M., Golitko, M., Sheridan, S. G., Kim, N. C., and Fuentes, A. (2017). Population is the main driver of war group size and conflict casualties. Proceedings of the National Academy of Sciences of the United States of America, 201713972.
Serafino, Matteo, Giulio Cimini, Amos Maritan, Andrea Rinaldo, Samir Suweis, Jayanth R. Banavar, and Guido Caldarelli. [2021] "True Scale-Free Networks Hidden by Finite Size Effects." Proceedings of the National Academy of Sciences 118(2)
Theise, N.D., and M.C. Kafatos. [2013]. "Complementarity in Biological Systems: A Complexity View." Complexity 18 (6): 11-20.
Valverde, J.C., Henning S. Mortveit, Carlos Gershenson, Yongtang Shi, (2020) "Boolean Networks and Their Applications in Science and Engineering", Complexity. 2020: 6183798.

Last Modified: April 15th , 2021

I609: Complex Networks & Systems Seminar I

Course Description

Course Evaluation

Office Hours

Course Materials and Readings

Part I: History of the Field

Part II: Current Research