Difference between revisions of "Erik Winfree"
From Thermodynamics of Computation
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|Biography=Erik Winfree (born September 26, 1969) is an American computer scientist, bioengineer, and professor at California Institute of Technology. He is a leading researcher into DNA computing and DNA nanotechnology. (Wikipedia) | |Biography=Erik Winfree (born September 26, 1969) is an American computer scientist, bioengineer, and professor at California Institute of Technology. He is a leading researcher into DNA computing and DNA nanotechnology. (Wikipedia) | ||
− | |Fields of Research=Chemical Reaction Networks; | + | |Fields of Research=Chemical Reaction Networks; Artificial Biological Computation |
|Related links={{Related link | |Related links={{Related link | ||
|Related link title=Erik Winfree's Caltech website. | |Related link title=Erik Winfree's Caltech website. | ||
|Related link URL=http://www.dna.caltech.edu/~winfree/ | |Related link URL=http://www.dna.caltech.edu/~winfree/ | ||
}} | }} | ||
+ | |Thematic area=Thermodynamics of Computation | ||
}} | }} |
Latest revision as of 21:18, April 16, 2018
Biography: Erik Winfree (born September 26, 1969) is an American computer scientist, bioengineer, and professor at California Institute of Technology. He is a leading researcher into DNA computing and DNA nanotechnology. (Wikipedia)
Field(s) of Research: Chemical Reaction Networks, Artificial Biological Computation
Related links
Reference Materials
- Computation with finite stochastic chemical reaction networks
- Construction of an in vitro bistable circuit from synthetic transcriptional switches
- Control of DNA strand displacement kinetics using toehold exchange
- DNA as a universal substrate for chemical kinetics (Extended Abstract)
- Diversity in the dynamical behaviour of a compartmentalized programmable biochemical oscillator
- Efficient turing-universal computation with DNA polymers
- Enzyme-free nucleic acid dynamical systems
- Enzyme-free nucleic acid logic circuits
- Neural network computation with DNA strand displacement cascades
- Synthetic in vitro transcriptional oscillators
- Verifying chemical reaction network implementations: A pathway decomposition approach