ALBA | Algebraic Formula Lower Bounds and Applications

Summary
Does efficient verification imply efficient search? Can randomness provide massive speed-ups in computation? These are fundamental questions in theoretical computer science, known as P vs. NP and P vs. BPP respectively. Progress on these questions requires us to to show that certain computational problems are inherently intractable, i.e. do not admit efficient solutions. An important, and concrete, approach to such questions is to understand the complexity of algebraic problems such as the Determinant and the Permanent, in algebraic models of computation. The aim of this project is to tackle these questions head on.

Recent results of the PI and his collaborators have made progress on these problems by resolving a three-decade old open question. These results show intractability for algebraic models of bounded depth, which is a step towards P vs. NP. As a consequence, they also imply the first sub-exponential time deterministic algorithms for the important Polynomial Identity Testing (PIT) problem in these settings, which is progress towards P vs. BPP.

However, this barely scratches the surface of what we want to achieve. The aim of this project is to push beyond these state-of-the-art results in many directions. The principal goal is to prove the first lower bounds for algebraic formulas, which would be a huge breakthrough. Further, we want to improve our recently obtained lower bounds in order to devise faster PIT algorithms. We also want to show lower bounds over finite fields, and to explore the applications of such work in related areas such as algebraic proof complexity and algorithm design.

The recent results point out a new way of exploiting structural and algebraic techniques to prove lower bounds. The aim is to develop and systematically investigate these techniques, incorporating methods from related fields of mathematics such as the theory of symmetric functions and representation theory, to accomplish these goals.
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More information & hyperlinks
Web resources: https://cordis.europa.eu/project/id/101125652
Start date: 01-06-2024
End date: 31-05-2029
Total budget - Public funding: 1 869 055,00 Euro - 1 869 055,00 Euro
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Original description

Does efficient verification imply efficient search? Can randomness provide massive speed-ups in computation? These are fundamental questions in theoretical computer science, known as P vs. NP and P vs. BPP respectively. Progress on these questions requires us to to show that certain computational problems are inherently intractable, i.e. do not admit efficient solutions. An important, and concrete, approach to such questions is to understand the complexity of algebraic problems such as the Determinant and the Permanent, in algebraic models of computation. The aim of this project is to tackle these questions head on.

Recent results of the PI and his collaborators have made progress on these problems by resolving a three-decade old open question. These results show intractability for algebraic models of bounded depth, which is a step towards P vs. NP. As a consequence, they also imply the first sub-exponential time deterministic algorithms for the important Polynomial Identity Testing (PIT) problem in these settings, which is progress towards P vs. BPP.

However, this barely scratches the surface of what we want to achieve. The aim of this project is to push beyond these state-of-the-art results in many directions. The principal goal is to prove the first lower bounds for algebraic formulas, which would be a huge breakthrough. Further, we want to improve our recently obtained lower bounds in order to devise faster PIT algorithms. We also want to show lower bounds over finite fields, and to explore the applications of such work in related areas such as algebraic proof complexity and algorithm design.

The recent results point out a new way of exploiting structural and algebraic techniques to prove lower bounds. The aim is to develop and systematically investigate these techniques, incorporating methods from related fields of mathematics such as the theory of symmetric functions and representation theory, to accomplish these goals.

Status

SIGNED

Call topic

ERC-2023-COG

Update Date

22-11-2024
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Horizon Europe
HORIZON.1 Excellent Science
HORIZON.1.1 European Research Council (ERC)
HORIZON.1.1.0 Cross-cutting call topics
ERC-2023-COG ERC CONSOLIDATOR GRANTS
HORIZON.1.1.1 Frontier science
ERC-2023-COG ERC CONSOLIDATOR GRANTS