Theory of Computation (TOC) studies the fundamental strengths and limits of computation, how these strengths and limits interact with computer science and mathematics, and how they manifest themselves in society, biology, and the physical world.
At its core, TOC investigates tradeoffs among basic computational resources. These resources include computation time, space, communication, parallelization, randomness, quantum entanglement, and more. As computational systems come in many forms and the goals of computation are diverse, TOC studies the limits of computation in its many manifestations. These are determined by what access we have to the computation’s input: do we have access to it as a whole, or does it come as a stream; as samples from a distribution; in encrypted form; or in fragments? Limits are also determined by the environment within which the computation takes place. Beyond the architecture and connectivity of the computational environment determining where the data is produced and stored and where the computation takes place, we are interested in the presence of other forces, such as adversaries who might want to eavesdrop on the computation, or strategic parties who want to influence the computation to their benefit.
Moreover, computation takes place both in systems that are explicitly computational but also systems that are not explicitly computational, such as biological systems, the human brain, social networks, and physical systems. As such, TOC provides a scientific lens with which to study such systems, and the study of these systems motivates new models of computation and computational tradeoffs, to be studied in turn by TOC.
MIT’s TOC faculty research an unusually broad spectrum of both core TOC and interdisciplinary topics, including algorithms, optimization, complexity theory, parallel and distributed computing, cryptography, computational economics and game theory, computational algebra and number theory, computational geometry, quantum computation, computational biology, machine learning, statistics, and numerical computation.
Latest news in theory of computation
MIT CSAIL researchers created an AI-powered method for low-discrepancy sampling, which uniformly distributes data points to boost simulation accuracy.
Associate Professor Julian Shun develops high-performance algorithms and frameworks for large-scale graph processing.
The dedicated teacher and academic leader transformed research in computer architectures, parallel computing, and digital design, enabling faster and more efficient computation.
Ranking at the top for the 13th year in a row, the Institute also places first in 11 subject areas.
Adam Belay, Manya Ghobadi, Stefanie Mueller, and Julian Shun are all being promoted to associate professor with tenure.