CDS 213: Difference between revisions

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| [[ Heat Shock| Heat Shock in cells; Clothing; Legos]]
| [[ Heat Shock| Heat Shock in cells; Clothing; Legos]]
|[[Media: PNASHeatShock.pdf | <i>Surviving Heat Shock: Control strategies for robustness and performance </i>, El-Samad, et al]];[[Media: Cell.pdf |<i> Robustness of Cellular Functions Review</i>, Stelling, et al]];[[Media: ScienceOnlinePDF.pdf | <i>Reverse Engineering of Biological Complexity</i>, Csete, Doyle]]
|[[Media: PNASHeatShock.pdf | <i>Surviving Heat Shock: Control strategies for robustness and performance </i>, El-Samad, et al]];[[Media: Cell.pdf |<i> Robustness of Cellular Functions Review</i>, Stelling, et al]];[[Media: ScienceOnlinePDF.pdf | <i>Reverse Engineering of Biological Complexity</i>, Csete, Doyle]]
|-
| align=center rowspan=3 | 4
| colspan=3 | '''Naming, Addressing and Control in Cell Biology '''
|-
| 2 Feb (T)
| [[Naming, Addressing and Control in Cell Biology | Naming, Addressing and Control in Cell Biology ]]
| [http://www.cds.caltech.edu/~doyle/213/Feb02SlidesReading/Final_IEE_SB.pdf <i>Highly optimised global organisation of metabolic networks</i>, R. Tanaka, M. Csete and J. Doyle];[http://www.cds.caltech.edu/~doyle/213/Feb02SlidesReading/ScaleRichMetabolism.pdf <i>Quantitative evaluation of scale-rich metabolic networks, Tanaka, Doyle]
|-
| 4 Feb (Th)
| [[ Signal Transduction | Signal Transduction]]
|[http://www.cds.caltech.edu/~doyle/213/Feb02SlidesReading/YiEtAlPNAS.pdf Robust perfect adaptation in bacterial chemotaxis through integral feedback control, Yi, Huang, Simon and Doyle]; [http://www.amazon.com/Introduction-Systems-Biology-Mathematical-Computational/dp/1584886420  Chapter 7: Robustness of Protein Circuits: The Example of Bacterial Chemotaxis of "An Introduction to Systems Biology", Uri Alon]
|-
| align=center rowspan=3 | 5
| colspan=3 | '''Architecture and Modeling in Cell Biology '''
|-
| 9 Feb (T)
| [[Modeling Biological Systems | Architecture and Layering in Cell Biology]]
|
|-
| 11 Feb (Th)
| [[ Modeling Biological Systems | Modeling Bio Systems, Speaker: James Faeder]]
|[http://www.cds.caltech.edu/~doyle/213/Feb09weekSlidesReading/Faeder_2009.pdf Rule-Based Modeling of Biochemical Systems with BioNetGen, Faeder, Blinov and Hlavacek]; [http://www.cds.caltech.edu/~doyle/213/Feb09weekSlidesReading/Bioinformatics09a_inpress.pdf Simulation of large-scale rule-based models, Colvin et al.]; [http://www.cds.caltech.edu/~doyle/213/Feb09weekSlidesReading/FaederPerspectives.pdf The Complexity of Cell Signaling and the Need for a New Mechanics, Hlavacek and Faeder];[http://www.cds.caltech.edu/~doyle/213/Feb09weekSlidesReading/STKE2006.pdf Rules for Modeling Signal-Transduction Systems, Hlavacek et al.]; [http://www.cds.caltech.edu/~doyle/213/Feb09weekSlidesReading/nri-published.pdf Mathematical and Computational Models of Immune-Receptor Signalling, Goldstein et al.]
|-
| align=center rowspan=3 | 6
| colspan=3 | '''Complexity and Fragility '''
|-
| 16 Feb (T)
| [[Complexity and Fragility | Complexity and Fragility: Examples with NPP and Mandelbrot sets]]
| [http://www.cds.caltech.edu/~doyle/213/Feb16weekSlidesReading/logFinalCDC2006_X.pdf  Complexity in Automation of SOS Proofs: An Illustrative Example, Gayme et al.];[http://www.cds.caltech.edu/~doyle/213/Feb16weekSlidesReading/mandel2.pdf <i>Optimization Based Methods for Determining Basins of Attraction in the Logistic Map and Set Membership in the Mandelbrot Set</i>, Gayme et al. ]; [http://www.cds.caltech.edu/~doyle/213/Feb16weekSlidesReading/DenniceConnections2006.pdf Studying the Logistic Map and the Mandelbrot Set Using SOS Methods, Gayme, Fazel, Doyle]
|-
| 18 Feb (Th)
| [[Complexity and Fragility | Complexity and Fragility (continued)]]
| [http://www.cds.caltech.edu/~doyle/213/Feb16weekSlidesReading/AldersonDoyle-SMCA.pdf Contrasting Views of Complexity and Their Implications For Network-Centric Infrastructures, Alderson, Doyle ]
|-
| align=center rowspan=3 | 7
| colspan=3 | '''Power Laws/ TCP IP '''
|-
| 23 Feb (T)
| [[Power Laws | Power Laws]]
| [http://www.cds.caltech.edu/~doyle2/wiki/index.php?title=Power_Laws Reading ]
|-
| 25 Feb (Th)
| [[The Internet | Steven Low guest speaker: TCP IP]]
| [http://www.cds.caltech.edu/~doyle2/wiki/index.php?title=The_Internet Reading ]
|-
|-
|-
|-
|}
|}


== Course Projects ==


There will be a course project to be discussed.


== Course Projects ==
* [[Molecular Cell Biology Project | Molecular Cell Biology Project]]

Latest revision as of 17:36, 3 April 2010

The Architecture of Robust, Evolvable Networks
Winter 2010
  • Course mailing list
  • Lectures: TTh 4-5:30 pm, 107 Annenberg, changes emailed to course mailing list

Course Schedule

Week Date Topic Reading
1 Introduction to Network Architectures
12 Jan (T) IST Seminar: The Architecture of Robust, Evolvable Networks
14 Jan (Th) Internet Architecture Network is IPC: Day et al, 2008 (Paper); Matta (Slides); Implications PNA, Day, 2009 (Slides); Multihop/Multiparty influences on Net. Arch., Touch (Slides)
2 Network Architectures: Operating Systems and Cell Biology
19 Jan (T) Internet and Biology Architectures Assessing Security of a Clean Slate Internet Architecture , Boddapati, Day; Linear Control Analysis of the Autocatalytic Glycolysis System , Chandra, Buzi, Doyle
21 Jan (Th) Robustness and Fragility, Hard Limits and Tradeoffs On Lossless Approximations, Fluctuation-Dissipation and Limitations of Measurements , Sandberg, Doyle
3 Case Studies: Cell Biology, Clothing and Legos
26 Jan (T) Network architecture and control of glycolysis; Clothing; Legos Linear Control Analysis of the Autocatalytic Glycolysis System , Chandra, Buzi, Doyle; Assembly and Regulation of a Glycolytic Enzyme Complex on the Human Erythrocyte Membrane , Campanella et al
28 Jan (Th) Heat Shock in cells; Clothing; Legos Surviving Heat Shock: Control strategies for robustness and performance , El-Samad, et al; Robustness of Cellular Functions Review, Stelling, et al; Reverse Engineering of Biological Complexity, Csete, Doyle
4 Naming, Addressing and Control in Cell Biology
2 Feb (T) Naming, Addressing and Control in Cell Biology Highly optimised global organisation of metabolic networks, R. Tanaka, M. Csete and J. Doyle;Quantitative evaluation of scale-rich metabolic networks, Tanaka, Doyle
4 Feb (Th) Signal Transduction Robust perfect adaptation in bacterial chemotaxis through integral feedback control, Yi, Huang, Simon and Doyle; Chapter 7: Robustness of Protein Circuits: The Example of Bacterial Chemotaxis of "An Introduction to Systems Biology", Uri Alon
5 Architecture and Modeling in Cell Biology
9 Feb (T) Architecture and Layering in Cell Biology
11 Feb (Th) Modeling Bio Systems, Speaker: James Faeder Rule-Based Modeling of Biochemical Systems with BioNetGen, Faeder, Blinov and Hlavacek; Simulation of large-scale rule-based models, Colvin et al.; The Complexity of Cell Signaling and the Need for a New Mechanics, Hlavacek and Faeder;Rules for Modeling Signal-Transduction Systems, Hlavacek et al.; Mathematical and Computational Models of Immune-Receptor Signalling, Goldstein et al.
6 Complexity and Fragility
16 Feb (T) Complexity and Fragility: Examples with NPP and Mandelbrot sets Complexity in Automation of SOS Proofs: An Illustrative Example, Gayme et al.;Optimization Based Methods for Determining Basins of Attraction in the Logistic Map and Set Membership in the Mandelbrot Set, Gayme et al. ; Studying the Logistic Map and the Mandelbrot Set Using SOS Methods, Gayme, Fazel, Doyle
18 Feb (Th) Complexity and Fragility (continued) Contrasting Views of Complexity and Their Implications For Network-Centric Infrastructures, Alderson, Doyle
7 Power Laws/ TCP IP
23 Feb (T) Power Laws Reading
25 Feb (Th) Steven Low guest speaker: TCP IP Reading

Course Projects

There will be a course project to be discussed.

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