Difference between revisions of "RITworkshop2017"

From CHAOS wiki
Jump to: navigation, search
Line 62: Line 62:
  
 
[http://wiki.chaos.gatech.edu/images/a/aa/20160112_RIT.pdf Visualizing Electrical Activity in the Heart]
 
[http://wiki.chaos.gatech.edu/images/a/aa/20160112_RIT.pdf Visualizing Electrical Activity in the Heart]
 +
 +
== Videos ==
 +
[https://www.youtube.com/watch?v=TJR2AfxVHsM Arrhythmias in motion]
 +
 +
[https://www.youtube.com/watch?v=bQnFzTT7Ioc Us!]
  
 
== Existential Crisis material ==
 
== Existential Crisis material ==

Revision as of 12:49, 20 January 2017

What makes your heart beat regularly or go out of control? Can chemical reactions change colors continuously? What happens when you burn a candle at both ends? Why can't we predict the weather more than a few days in advance?

Excitable systems are found throughout nature and have three main properties that can be illustrated through a canonical example, a forest fire.

  • Behavior threshold (no fire occurs without a sufficiently large stimulus like a lightning strike or initial blaze set by a camper).
  • Wave propagation without damping (the fire continues to spread to any nearby unburned trees).
  • Recovery period (the forest must regrow before another fire can occur).

Numerous biological and physical systems are excitable, with perhaps the most famous examples being cardiac and neural cells. Related oscillatory systems exhibit similar properties but produce their own stimuli without the need for an external perturbation

This workshop focuses on understanding the electrical properties of the heart. Individual cardiac cells are excitable and support propagation of electrical signals, which trigger contraction. Disruptions of this signaling can lead to serious health issues but also demonstrate interesting dynamics, including period-doubling bifurcations and formation of interesting patterns like spiral waves. Along the way, we will study simpler physical systems that show similar behavior and use these systems as a gateway to building understanding of the physics and mathematics that can describe such systems.

The workshop will alternate lectures with laboratory and collaborative exercises involving discussion, group work, experiments with physical systems, and computational modeling. In addition, participants will work in teams on a project. The teams will bring together students from multiple disciplines to assemble a diversity of backgrounds and expertise.

Instructors: Elizabeth M. Cherry (Rochester Institute of Technology) and Flavio H. Fenton (Georgia Institute of Technology)

Schedule

Sunday (01/08)

  • 12:45pm: Hotel shuttle transport to RIT campus
  • 5:15pm: Shuttle transport to hotel

Monday (01/09) - Friday (01/13)

  • 8:45am: Hotel shuttle transport to RIT campus
  • 9am - 5pm: Science
  • 5:15pm: Shuttle transport to hotel

Saturday (01/14)

  • 8:45am: Hotel shuttle transport to RIT campus
  • 9am - 2:45pm: Science

Final Presentations

Alison, Renee, Tony

Bella, Nora, Sean

Brenda, Jennifer, Leo

Daniel, Joel, Pat

Ian, Nathan, Zach

Jamie, Jenny, Rachel

Resources

Workshop Notes

Stability Analysis

Sunday

Monday

Tuesday

Wednesday

Thursday

Slides

Cardiac Electrophysiology Overview

Visualizing Electrical Activity in the Heart

Videos

Arrhythmias in motion

Us!

Existential Crisis material

Are we a simulation? (Nick Bostrom)

Are we living in a computer simulation? (Scientific American)

Numerical Simulation

The Virtual Heart

Numerical Integration (pdf)

Opportunities

Membership Opportunities (pdf)