Most of today’s global challenges, from online misinformation spreading to Ebola outbreaks, involve such a vast number of interacting players that reductionism delivers little insight. Systems are often non-linear, exhibiting complexity in temporal and spatial domains over large scales, which is a challenge to predictability and comprehension. Strategies must be found to look at the problem as a whole, in all its complexity. Representing the associated data as a complex network, in which nodes and connections between them form complicated patterns, is one such strategy. Network science provides novel tools for analyzing, visualizing and modeling this data thanks to the cross-fertilization of fields as diverse as statistical physics, algebraic topology and machine learning, among the others.
This Channel brings together all aspects of complexity research and includes interdisciplinary topics from network theory to applications in neuroscience and the social sciences.
Syndicated copies to:
Announcing the launch of the @PLOS #Complexity Channel https://t.co/RRvsk3O4ok , a home for complexity research and interdisciplinary topics from network theory to applications in neuroscience and the social sciences, feat content from @PLOSONE @PLOSCompBiol @arxiv and more pic.twitter.com/sTRTbRCRu0
— PLOS Channels (@PLOSChannels) June 15, 2018