Concetti Chiave
The authors introduce the concept of maximally extendable sheaf codes, demonstrating their significance in linear algebra and coding theory.
Sintesi
The study focuses on sheaf codes, introducing the notion of maximal extendibility within a class of codes on the same coded space. It explores the application of sheaf theoretic approach to classical linear codes and its implications for quantum codes. The paper delves into cohomology groups and expansion properties of sheaf codes, highlighting their relevance in constructing good locally testable quantum low-density parity-check (qLTC) codes. The authors propose a new property called maximal extendibility inspired by recoverable codes, showcasing its importance in code extension globally. They discuss the theoretical framework behind sheaf codes and their potential applications in attacking the qLTC conjecture. The research also presents examples of generic tensor product and flag product codes, illustrating their construction and properties. Furthermore, it outlines operations with sheaf codes such as product, pullback, and pushforward, providing insights into how these operations can be applied effectively.
Statistiche
An infinite family of classical or quantum codes is called (asymptotically) good if both the dimension and distance grow as Θ(n) with length n → ∞.
Originally shown for quantum Tanner codes [3], this holds for all current constructions [6].
Given a set S and a field F, let FS be the vector space of all formal F-linear combinations v = P s∈S v(s) · s.
A poset is a set X equipped with a partial order ⩽.
A chain in X is a subset where all elements are comparable.
The height of a poset X is the size of its largest chain minus 1.
Every classical LDPC code C can be viewed as sheaf code on the poset X.
Sheaves on Posets: Informally, a sheaf is a map F assigning to every open set U of a topological space X some set F(U).
Formally, given a topological space X, a sheaf on X is a function F assigning to each open set U ⊆ X the set F(U) of elements called local sections.
Citazioni
"In every class of sheaf codes defined on the same space... there always exists a maximally extendable sheaf code."
"The recent constructions... are all based on lifting small local (tensor) product code to large global code."
"Given an index set U ⊆ X... can be extended to global codeword ˆc satisfying all constraints."
"A canonical example is the sheaf... assigning to each open set U ⊆ X..."
"Sheaves in Topology: Informally, a sheaf is..."