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Your search keyword '"Leyba, Kirtus"' showing total 7 results
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7 results on '"Leyba, Kirtus"'

1. Evolving Collective Behavior in Self-Organizing Particle Systems

Author

Parkar, Devendra, Leyba, Kirtus G., Faerber, Raylene A., and Daymude, Joshua J.

Subjects
Computer Science - Neural and Evolutionary Computing
Abstract

Local interactions drive emergent collective behavior, which pervades biological and social complex systems. But uncovering the interactions that produce a desired behavior remains a core challenge. In this paper, we present EvoSOPS, an evolutionary framework that searches landscapes of stochastic distributed algorithms for those that achieve a mathematically specified target behavior. These algorithms govern self-organizing particle systems (SOPS) comprising individuals with no persistent memory and strictly local sensing and movement. For aggregation, phototaxing, and separation behaviors, EvoSOPS discovers algorithms that achieve 4.2-15.3% higher fitness than those from the existing "stochastic approach to SOPS" based on mathematical theory from statistical physics. EvoSOPS is also flexibly applied to new behaviors such as object coating where the stochastic approach would require bespoke, extensive analysis. Finally, we distill insights from the diverse, best-fitness genomes produced for aggregation across repeated EvoSOPS runs to demonstrate how EvoSOPS can bootstrap future theoretical investigations into SOPS algorithms for new behaviors., Comment: 10 pages, 8 figures, 3 tables; accepted for publication at ALIFE 2024

Published
2024

2. Cutting Through the Noise to Infer Autonomous System Topology

Author

Leyba, Kirtus G., Daymude, Joshua J., Young, Jean-Gabriel, Newman, M. E. J., Rexford, Jennifer, and Forrest, Stephanie

Subjects
Computer Science - Networking and Internet Architecture, Computer Science - Social and Information Networks, Physics - Data Analysis, Statistics and Probability, Physics - Physics and Society
Abstract

The Border Gateway Protocol (BGP) is a distributed protocol that manages interdomain routing without requiring a centralized record of which autonomous systems (ASes) connect to which others. Many methods have been devised to infer the AS topology from publicly available BGP data, but none provide a general way to handle the fact that the data are notoriously incomplete and subject to error. This paper describes a method for reliably inferring AS-level connectivity in the presence of measurement error using Bayesian statistical inference acting on BGP routing tables from multiple vantage points. We employ a novel approach for counting AS adjacency observations in the AS-PATH attribute data from public route collectors, along with a Bayesian algorithm to generate a statistical estimate of the AS-level network. Our approach also gives us a way to evaluate the accuracy of existing reconstruction methods and to identify advantageous locations for new route collectors or vantage points., Comment: 10 pages, 8 figures, 1 table. To appear at IEEE INFOCOM 2022. \copyright\ IEEE 2022

Published
2022

3. Spatially distributed infection increases viral load in a computational model of SARS-CoV-2 lung infection

Author

Moses, Melanie E, Hofmeyr, Steven, Cannon, Judy L, Andrews, Akil, Gridley, Rebekah, Hinga, Monica, Leyba, Kirtus, Pribisova, Abigail, Surjadidjaja, Vanessa, Tasnim, Humayra, and Forrest, Stephanie

Subjects
Medical Microbiology, Biomedical and Clinical Sciences, Immunology, Lung, Pneumonia & Influenza, Prevention, Infectious Diseases, Emerging Infectious Diseases, Biodefense, Pneumonia, Vaccine Related, Aetiology, 2.2 Factors relating to the physical environment, Infection, CD8-Positive T-Lymphocytes, COVID-19, Computer Simulation, Humans, SARS-CoV-2, Viral Load, Mathematical Sciences, Biological Sciences, Information and Computing Sciences, Bioinformatics
Abstract

A key question in SARS-CoV-2 infection is why viral loads and patient outcomes vary dramatically across individuals. Because spatial-temporal dynamics of viral spread and immune response are challenging to study in vivo, we developed Spatial Immune Model of Coronavirus (SIMCoV), a scalable computational model that simulates hundreds of millions of lung cells, including respiratory epithelial cells and T cells. SIMCoV replicates viral growth dynamics observed in patients and shows how spatially dispersed infections can lead to increased viral loads. The model also shows how the timing and strength of the T cell response can affect viral persistence, oscillations, and control. By incorporating spatial interactions, SIMCoV provides a parsimonious explanation for the dramatically different viral load trajectories among patients by varying only the number of initial sites of infection and the magnitude and timing of the T cell immune response. When the branching airway structure of the lung is explicitly represented, we find that virus spreads faster than in a 2D layer of epithelial cells, but much more slowly than in an undifferentiated 3D grid or in a well-mixed differential equation model. These results illustrate how realistic, spatially explicit computational models can improve understanding of within-host dynamics of SARS-CoV-2 infection.

Published
2021

7. Borders and gateways

Author

Leyba, Kirtus G., primary, Edwards, Benjamin, additional, Freeman, Cynthia, additional, Crandall, Jedidiah R., additional, and Forrest, Stephanie, additional

Published
2019
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