Understanding and Managing Propagation on Large Networks - Theory, Algorithms, and Models

Abstract

How do contagions spread in population networks? What happens if the networks change with time? Which hospitals should we give vaccines to, for maximum effect? How to detect sources of rumors on Twitter/Facebook? These questions and many others such as which group should we market to, for maximizing product penetration, how quickly news travels in online media and how the relative frequencies of competing tasks evolve are all related to propagation/cascade-like phenomena on networks. In this thesis, we present novel theory, algorithms and models for propagation processes on large static and dynamic networks, focusing on 1. Theory: We tackle several fundamental questions like determining if there will be an epidemic, given the underlying networks and virus propagation models and predicting who-wins when viruses (or memes or products etc.) compete. We give a unifying answer for the threshold based on eigenvalues, and prove the surprising winner-takes-all? result and other subtle phase-transitions for competition among viruses. 2. Algorithms: Based on our analysis, we give dramatically better algorithms for important tasks like effective immunization and reliably detecting culprits of epidemics. Thanks to our carefully designed algorithms we achieve 6x fewer infections on real hospital patient-transfer graphs while also being significantly faster than other competitors (upto 30,000x). 3. Models: Finally using our insights, we study numerous datasets to develop powerful general models for information diffusion and competing species in a variety of situations. Our models unify earlier patterns and results, yet being succinct and enable challenging tasks like trend forecasting, spotting outliers and answering ?what-if? questions. Our inter-disciplinary approach has led to many discoveries in this thesis with broad applications spanning areas like public health, social media product marketing and networking. We are arguably the first to present a systematic study of propag

Open PDF

Document Details

Document Type
Technical Report
Publication Date
Sep 01, 2012
Accession Number
ADA569956

Entities

People

  • B. A. Prakash

Organizations

  • Carnegie Mellon University

Tags

Communities of Interest

  • Cyber
  • Energy and Power Technologies
  • Materials and Manufacturing Processes

DTIC Thesaurus Topics

  • Anomaly Detection
  • Change Detection
  • Computational Science
  • Computer Networks
  • Computers
  • Data Mining
  • Differential Equations
  • Electronic Mail
  • Health Services
  • Information Systems
  • Internet
  • Mobile Phones
  • Network Science
  • Online Communications
  • Public Health
  • Social Media
  • Web Browsers

Readers

  • Neural Network Machine Learning.
  • Systems Analysis and Design
  • Theoretical Analysis.

Technology Areas

  • AI & ML
  • AI & ML - Machine Learning Algorithms
  • AI & ML - Neural Networks
  • Biotechnology