PaDiDom | Packing in Discrete Domains - Geometry and Analysis

Summary
The packing problem associated with a family of sets F seeks a large subfamily of pairwise disjoint members of F. When F comprises the unit balls in d-space, this is the sphere packing problem, which for d = 3 was solved by Hales-Ferguson (Kepler’s conjecture). The cases d = 8, 24 have won Viazovska her Fields Medal. Much of discrete mathematics deals with dense packing problems. The asymptotic rate vs. distance problem, may be the most fundamental open problem about error correcting codes. It seeks the densest Hamming-sphere packing in discrete cubes. A linear code is a linear subspace of F_2n. Such codes are important both in theory and in practice. Here, we seek to maximize dim(C), when every nonzero vector in C has Hamming weight ≥ δn. Despite its mathematical significance and practical importance, the answer remains unknown for all 1/2 > δ > 0, and our best upper bounds on the rate date from the 70’s. Neither do we know if linear codes can be asymptotically as good as general codes. We have made some progress on these key questions of our proposal. The infinite d-regular tree Td is another important metric space where we seek dense sphere packing. It is easy to perfectly pack balls in Td, but not in a periodic manner. Periodic perfect sphere packings in Td coincide with Moore graphs - finite regular graphs of least diameter and largest possible girth (i.e., with no short cycles). Moore graphs were fully characterized in the 70’s, yet we still cannot show that for fixed d ≥ 3 and large r, any periodic packing of r-spheres in Td must have vanishing density. Many important mathematicians, including Erdös, Margulis, and Lubotzky-Phillips-Sarnak sought the largest possible girth of a d-regular n-vertex graph (d fixed, n → ∞). We show how better upper bounds on linear codes yield progress here, whereas bounds on general codes would not do.We use computers as exploratory tools, e.g., to test our new bounds on codes, yet we publish only humanly verifiable proofs.
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Web resources: https://cordis.europa.eu/project/id/101141253
Start date: 01-07-2024
End date: 30-06-2029
Total budget - Public funding: 2 194 125,00 Euro - 2 194 125,00 Euro
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Original description

The packing problem associated with a family of sets F seeks a large subfamily of pairwise disjoint members of F. When F comprises the unit balls in d-space, this is the sphere packing problem, which for d = 3 was solved by Hales-Ferguson (Kepler’s conjecture). The cases d = 8, 24 have won Viazovska her Fields Medal. Much of discrete mathematics deals with dense packing problems. The asymptotic rate vs. distance problem, may be the most fundamental open problem about error correcting codes. It seeks the densest Hamming-sphere packing in discrete cubes. A linear code is a linear subspace of F_2n. Such codes are important both in theory and in practice. Here, we seek to maximize dim(C), when every nonzero vector in C has Hamming weight ≥ δn. Despite its mathematical significance and practical importance, the answer remains unknown for all 1/2 > δ > 0, and our best upper bounds on the rate date from the 70’s. Neither do we know if linear codes can be asymptotically as good as general codes. We have made some progress on these key questions of our proposal. The infinite d-regular tree Td is another important metric space where we seek dense sphere packing. It is easy to perfectly pack balls in Td, but not in a periodic manner. Periodic perfect sphere packings in Td coincide with Moore graphs - finite regular graphs of least diameter and largest possible girth (i.e., with no short cycles). Moore graphs were fully characterized in the 70’s, yet we still cannot show that for fixed d ≥ 3 and large r, any periodic packing of r-spheres in Td must have vanishing density. Many important mathematicians, including Erdös, Margulis, and Lubotzky-Phillips-Sarnak sought the largest possible girth of a d-regular n-vertex graph (d fixed, n → ∞). We show how better upper bounds on linear codes yield progress here, whereas bounds on general codes would not do.We use computers as exploratory tools, e.g., to test our new bounds on codes, yet we publish only humanly verifiable proofs.

Status

SIGNED

Call topic

ERC-2023-ADG

Update Date

24-11-2024
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Horizon Europe
HORIZON.1 Excellent Science
HORIZON.1.1 European Research Council (ERC)
HORIZON.1.1.1 Frontier science
ERC-2023-ADG ERC ADVANCED GRANTS