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Difference between revisions of "Complex Systems Summer School 2011-Faculty"

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{{Complex Systems Summer School 2011}}
 
{{Complex Systems Summer School 2011}}
  
[[Image:Krakauer.jpg|left]]My research is concerned with the evolutionary history of information processing mechanisms in biology and culture, with an emphasis on robust information transmission, signaling dynamics and their role in constructing novel, higher level features. The research spans several levels of organization finding analogous processes in genetics, cell biology, microbiology and in organismal behavior and society. At the cellular level I have been interested in molecular processes, which rely on volatile, error-prone, asynchronous, mechanisms, which can be used as a basis for decision making and patterning. I also investigate how signaling interactions at higher levels, including microbial and organismal, are used to coordinate complex life cycles and social systems, and under what conditions we observe the emergence of proto-grammars. Much of this work is motivated by the search for 'noisy-design' principles in biology and culture emerging through evolution that span hierarchical structures. In addition to general principles there is a need to provide an explicit theory of evolutionary history, a theory accounting for those incompressible regularities revealed once the regular components have been subtracted.
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[[Image:Krakauer.jpg|left]]'''David Krakauer''' Evolution Module Leader and Program Director. My research is concerned with the evolutionary history of information processing mechanisms in biology and culture, with an emphasis on robust information transmission, signaling dynamics and their role in constructing novel, higher level features. The research spans several levels of organization finding analogous processes in genetics, cell biology, microbiology and in organismal behavior and society. At the cellular level I have been interested in molecular processes, which rely on volatile, error-prone, asynchronous, mechanisms, which can be used as a basis for decision making and patterning. I also investigate how signaling interactions at higher levels, including microbial and organismal, are used to coordinate complex life cycles and social systems, and under what conditions we observe the emergence of proto-grammars. Much of this work is motivated by the search for 'noisy-design' principles in biology and culture emerging through evolution that span hierarchical structures. In addition to general principles there is a need to provide an explicit theory of evolutionary history, a theory accounting for those incompressible regularities revealed once the regular components have been subtracted.
  
 
Research projects includes work on the molecular logic of signaling pathways, the evolution of genome organization (redundancy, multiple encoding, quantization and compression), robust communication over networks, the evolution of distributed forms of biological information processing, dynamical memory systems, the logic of transmissible regulatory networks (such as virus life cycles) and the many ways in which organisms construct their environments (niche construction). Thinking about niche constructing niches provides us with a new perspective on the major evolutionary transitions.
 
Research projects includes work on the molecular logic of signaling pathways, the evolution of genome organization (redundancy, multiple encoding, quantization and compression), robust communication over networks, the evolution of distributed forms of biological information processing, dynamical memory systems, the logic of transmissible regulatory networks (such as virus life cycles) and the many ways in which organisms construct their environments (niche construction). Thinking about niche constructing niches provides us with a new perspective on the major evolutionary transitions.
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[[Image:Flack.jpg|left]] '''Jessica Flack''' Robustness Module Leader. Jessica Flack is Professor at the Santa Fe Institute and Co-Director (with David Krakauer) of the Collective Social Computation Group. Her research program combines dynamical systems and computational perspectives in order to build a theory of how aggregate structure and hierarchy arise in social evolution. Primary goals are to understand the conditions and mechanisms supporting the emergence of slowly changing collective features that feed-down to influence component behavior, the role that conflict plays in this process, and the implications of multiple timescales and overlapping networks for robustness and adaptability in social evolution. Research foci include design principles for robust systems, conflict dynamics and control, the role of uncertainty reduction in the evolution of signaling systems, the implications of higher-order structures for social complexity and innovation, behavioral grammars and adaptive circuit construction. Flack approaches these issues using data on social process collected from animal society model systems, and through comparison of social dynamics with neural, immune, and developmental dynamics.  
 
[[Image:Flack.jpg|left]] '''Jessica Flack''' Robustness Module Leader. Jessica Flack is Professor at the Santa Fe Institute and Co-Director (with David Krakauer) of the Collective Social Computation Group. Her research program combines dynamical systems and computational perspectives in order to build a theory of how aggregate structure and hierarchy arise in social evolution. Primary goals are to understand the conditions and mechanisms supporting the emergence of slowly changing collective features that feed-down to influence component behavior, the role that conflict plays in this process, and the implications of multiple timescales and overlapping networks for robustness and adaptability in social evolution. Research foci include design principles for robust systems, conflict dynamics and control, the role of uncertainty reduction in the evolution of signaling systems, the implications of higher-order structures for social complexity and innovation, behavioral grammars and adaptive circuit construction. Flack approaches these issues using data on social process collected from animal society model systems, and through comparison of social dynamics with neural, immune, and developmental dynamics.  
 
'''David Krakauer''' Evolution Module Leader and Program Director
 
  
 
'''Jim Cruthfield''' Complexity Module Leader
 
'''Jim Cruthfield''' Complexity Module Leader

Revision as of 16:40, 5 April 2011

Complex Systems Summer School 2011
Krakauer.jpg

David Krakauer Evolution Module Leader and Program Director. My research is concerned with the evolutionary history of information processing mechanisms in biology and culture, with an emphasis on robust information transmission, signaling dynamics and their role in constructing novel, higher level features. The research spans several levels of organization finding analogous processes in genetics, cell biology, microbiology and in organismal behavior and society. At the cellular level I have been interested in molecular processes, which rely on volatile, error-prone, asynchronous, mechanisms, which can be used as a basis for decision making and patterning. I also investigate how signaling interactions at higher levels, including microbial and organismal, are used to coordinate complex life cycles and social systems, and under what conditions we observe the emergence of proto-grammars. Much of this work is motivated by the search for 'noisy-design' principles in biology and culture emerging through evolution that span hierarchical structures. In addition to general principles there is a need to provide an explicit theory of evolutionary history, a theory accounting for those incompressible regularities revealed once the regular components have been subtracted.

Research projects includes work on the molecular logic of signaling pathways, the evolution of genome organization (redundancy, multiple encoding, quantization and compression), robust communication over networks, the evolution of distributed forms of biological information processing, dynamical memory systems, the logic of transmissible regulatory networks (such as virus life cycles) and the many ways in which organisms construct their environments (niche construction). Thinking about niche constructing niches provides us with a new perspective on the major evolutionary transitions.

Many of these areas are characterized by the need to encode heritable information (genetic, epigenetic, auto-catalytic or linguistic) at distinct levels of biological organization, where selection pressures are often independent or in conflict. Furthermore, components are noisy and degrade and interactions are typically diffusively coupled. At each level I ask how information is acquired, stored, transmitted, replicated, transformed and robustly encoded. With collaborators I am engaged in projects applying insights from biological information processing to electronic, engineered systems.

The big question that many of us are asking is what will evolutionary theory look like once it has become integrated with the sciences of information, and of course, what will these sciences then look like?

Elizabeth Bradley Concepts: Nonlinearity Module Leader

Mark Newman Networks Module Leader

Dan Rockmore Machine Learning Module Leader

Flack.jpg

Jessica Flack Robustness Module Leader. Jessica Flack is Professor at the Santa Fe Institute and Co-Director (with David Krakauer) of the Collective Social Computation Group. Her research program combines dynamical systems and computational perspectives in order to build a theory of how aggregate structure and hierarchy arise in social evolution. Primary goals are to understand the conditions and mechanisms supporting the emergence of slowly changing collective features that feed-down to influence component behavior, the role that conflict plays in this process, and the implications of multiple timescales and overlapping networks for robustness and adaptability in social evolution. Research foci include design principles for robust systems, conflict dynamics and control, the role of uncertainty reduction in the evolution of signaling systems, the implications of higher-order structures for social complexity and innovation, behavioral grammars and adaptive circuit construction. Flack approaches these issues using data on social process collected from animal society model systems, and through comparison of social dynamics with neural, immune, and developmental dynamics.

Jim Cruthfield Complexity Module Leader

Simon DeDeo Emergence Module Leader

James O'Dwyer Emergence Module Leader

Cris Moore Computation Module Leader