Discrete Approximation
Ente: ANALYSIS PROGRAM
Scadenza: 2029-07-31
Importo max: 299.999 EUR
Paese: US
Descrizione
Modern data science, quantum computation, and high-dimensional probability rely on mathematical tools for understanding functions of many yes/no variables and their continuous analogues. This project studies such functions on the discrete cube and in Gaussian space, where approximation, learning, randomness, and boundary structure can be analyzed precisely. The work addresses basic questions about how much information is needed to learn a low-complexity function, how well complicated functions can be approximated by simple polynomials, and how the shape of a high-dimensional set controls its boundary. These questions are central to mathematics and also inform learning theory and quantum computing. This project promotes the progress of science and advances national prosperity and welfare by strengthening foundations for reliable computation, high-dimensional data analysis, and artificial intelligence. The project also supports education and workforce development through training of graduate students and postdoctoral researchers, summer schools and research programs for early-career researchers, and dissemination through seminars, webinars, lecture notes, and preprints.
The investigator develops a unified program in analysis on discrete and Gaussian spaces, using semigroup methods, Fourier analysis on the Hamming cube, hypercontractivity, and sharp inequalities. The project seeks sharper Bohnenblust-Hille and hypercontractive inequalities, with applications to PAC learning of low-degree Boolean functions, learning with small spectral support, polynomial threshold functions, and the Aaronson-Ambainis conjecture in quantum query complexity. It develops Jackson- and Poincare-type approximation theorems with dimension-independent bounds and transfers discrete approximation principles to Gaussian weighted approximation. It pursues sharp isoperimetric and influence inequalities, including progress on the Kahn-Park conjecture and the remaining range of Weissler's complex hypercontractivity conjecture. The project also studies discrete additive inequalities, including optimal sumset growth and reverse sharp Young convolution inequalities, and develops a multiversion Hausdorff-Young theory for correlated Gaussian and discrete inputs. Across these themes, the investigator uses heat-flow and Ornstein-Uhlenbeck semigroups, interpolation, invariance and decoupling methods, Bellman-function ideas, and sharp two-point inequalities. Expected outcomes include new constants and exponents, progress on long-standing conjectures, and transferable tools linking harmonic analysis, probability, Banach-space methods, additive combinatorics, learning theory, and quantum computing.
This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.
Istituzione: University of California-Irvine
Sede: IRVINE, CA
PI: Paata Ivanisvili
Settori: Mathematical & Physical Sciences
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