Difference between revisions of "Lecture 11"

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Simulated annealing allows a system to be computationally moved out of situations where it is trapped in local minima, and to proceed towards a global minimum on a rough search landscape.
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Revision as of 06:38, 28 November 2006

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Protein Structure Prediction

...

Add:

  • Summary points
  • Exercises
  • Further reading

Lecture Slides

Slide 001
Lecture 11, Slide 001
Slide 002
Lecture 11, Slide 002
Slide 003
Lecture 11, Slide 003
The observation became famously known as "Levinthal's Paradox", that neither random search nor the postulation of folding pathways can explain how a discrete structure can self-organize, given in a combinatorially large search space. But real proteins do just fine, thank you.
Slide 004
Lecture 11, Slide 004
A toy observation on an optimization problem of similar magnitude as the random folding of a protein...
Slide 005
Lecture 11, Slide 005
Slide 006
Lecture 11, Slide 006
Slide 007
Lecture 11, Slide 007
Slide 008
Lecture 11, Slide 008
Slide 009
Lecture 11, Slide 009
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Lecture 11, Slide 010
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Lecture 11, Slide 011
Slide 012
Lecture 11, Slide 012
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Lecture 11, Slide 013
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Lecture 11, Slide 014
Slide 015
Lecture 11, Slide 015
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Lecture 11, Slide 016
Slide 017
Lecture 11, Slide 017
Slide 018
Lecture 11, Slide 018
Non-polynomial time-complexity problems are considered intractable, since even as the problem size 'n' grows only modestly, the time requirements grow beyond all bounds and reasonable resources. A 1,000 element problem of O(2n) complexity takes the age of the universe to compute.
Slide 019
Lecture 11, Slide 019
Slide 020
Lecture 11, Slide 020
Slide 021
Lecture 11, Slide 021
Slide 022
Lecture 11, Slide 022
Slide 023
Lecture 11, Slide 023
Slide 024
Lecture 11, Slide 024
Simulated annealing allows a system to be computationally moved out of situations where it is trapped in local minima, and to proceed towards a global minimum on a rough search landscape.
Slide 025
Lecture 11, Slide 025
Slide 026
Lecture 11, Slide 026
Slide 027
Lecture 11, Slide 027
Slide 028
Lecture 11, Slide 028
Slide 029
Lecture 11, Slide 029
Slide 030
Lecture 11, Slide 030
Slide 031
Lecture 11, Slide 031
Slide 032
Lecture 11, Slide 032
Slide 033
Lecture 11, Slide 033
Slide 034
Lecture 11, Slide 034
Slide 035
Lecture 11, Slide 035
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Lecture 11, Slide 036
Slide 037
Lecture 11, Slide 037
Slide 038
Lecture 11, Slide 038
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