Your search keyword '"Diquan Moore"' showing total 4 results

1. Walks in phylogenetic treespace.

Author

Alan Joseph J. Caceres, Samantha Daley, John DeJesus, Michael Hintze, Diquan Moore, and Katherine St. John

Published

2011

2. Approaches to Multi-Robot Exploration and Localization.

Author

Arif Tuna Ozgelen, Michael Costantino, Adiba Ishak, Moses Kingston, Diquan Moore, Samuel Sanchez, Juan Pablo Muñoz, Simon Parsons, and Elizabeth Sklar

Published

2011

3. Teaching cardiac electrophysiology modeling to undergraduate students: laboratory exercises and GPU programming for the study of arrhythmias and spiral wave dynamics

Author

James Glimm, Evan Closser, Dana Pardi, Kai Zhao, Nancy Griffeth, Gabriel Deards, Avessie Amedome, Elizabeth M. Cherry, Juan Castillo, Andrew B. Filipski, Joshua Rogers, Alan Joseph J. Caceres, Radu Grosu, Sandeep Sadhu, Terri Grosso-Applewhite, Cem Isbilir, Samuel Sanchez, Diquan Moore, Frederick B. von Stein, Robert F. Gilmour, Rupinder Singh, Joan K. Marc, Anoopa Singh, Pooja Sharma, Ezio Bartocci, Flavio H. Fenton, Andriy Goltsev, Scott A. Smolka, Aron Wolinetz, Edmund M. Clarke, and Roumwelle Sta. Ines

Subjects

Time Factors, Higher education, Physiology, computer.software_genre, Feedback, Education, Heart Conduction System, Surveys and Questionnaires, Computer Graphics, Humans, Learning, Computer Simulation, Electronic Data Processing, Medical education, Multimedia, Cardiac electrophysiology, business.industry, Teaching, Models, Cardiovascular, Arrhythmias, Cardiac, General Medicine, Dynamics (music), Spiral wave, General-purpose computing on graphics processing units, Comprehension, Electrophysiologic Techniques, Cardiac, business, Psychology, computer

Abstract

As part of a 3-wk intersession workshop funded by a National Science Foundation Expeditions in Computing award, 15 undergraduate students from the City University of New York1collaborated on a study aimed at characterizing the voltage dynamics and arrhythmogenic behavior of cardiac cells for a broad range of physiologically relevant conditions using an in silico model. The primary goal of the workshop was to cultivate student interest in computational modeling and analysis of complex systems by introducing them through lectures and laboratory activities to current research in cardiac modeling and by engaging them in a hands-on research experience. The success of the workshop lay in the exposure of the students to active researchers and experts in their fields, the use of hands-on activities to communicate important concepts, active engagement of the students in research, and explanations of the significance of results as the students generated them. The workshop content addressed how spiral waves of electrical activity are initiated in the heart and how different parameter values affect the dynamics of these reentrant waves. Spiral waves are clinically associated with tachycardia, when the waves remain stable, and with fibrillation, when the waves exhibit breakup. All in silico experiments were conducted by simulating a mathematical model of cardiac cells on graphics processing units instead of the standard central processing units of desktop computers. This approach decreased the run time for each simulation to almost real time, thereby allowing the students to quickly analyze and characterize the simulated arrhythmias. Results from these simulations, as well as some of the background and methodology taught during the workshop, is presented in this article along with the programming code and the explanations of simulation results in an effort to allow other teachers and students to perform their own demonstrations, simulations, and studies.

Published

2011

4. Walks in phylogenetic treespace

Author

Samantha Daley, Katherine St. John, Michael Hintze, Diquan Moore, Alan Joseph J. Caceres, and John DeJesus

Subjects

Discrete mathematics, Phylogenetic tree, Computer Science Applications, Theoretical Computer Science, k-nearest neighbors algorithm, Combinatorics, Quantitative Biology::Quantitative Methods, Tree (data structure), Phylogenetics, Signal Processing, Metric (mathematics), Quantitative Biology::Populations and Evolution, Graph algorithms, Information Systems, Mathematics

Abstract

We prove that the spaces of unrooted phylogenetic trees are Hamiltonian for two popular search metrics: Subtree Prune and Regraft (SPR) and Tree Bisection and Reconnection (TBR). Further, we make progress on two conjectures of Bryant on searching phylogenetic treespace: treespace under the Nearest Neighbor Interchange (NNI) metric has a 2-walk, and there exist SPR neighborhoods without complete NNI walks.

Published

2011