Cameron–Liebler k-sets in subspaces and non-existence conditions

Beule, Jan De; Mannaert, Jonathan; Storme, Leo

doi:10.1007/s10623-021-00995-0

Cited by 4 publications

(3 citation statements)

References 15 publications

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“…Nowadays many counterexamples to the Conjecture of Cameron and Liebler are known if (n, k) = (4, 2) and q 3; see [8,14,22,23,31,33]. The general case of k > 2 has been investigated more recently, for instance see [4,15,16,26,35,41]. Indeed, it has been shown in [26] that Conjecture 5 holds for k 2 and q ∈ {2, 3, 4, 5} if we exclude the case (n, k) = (4, 2).…”

Section: Cameron-liebler Line Classes and Boolean Functions On The Gr...mentioning

confidence: 99%

Degree 2 Boolean Functions on Grassmann Graphs

Beule

D'haeseleer²,

Ihringer³

et al. 2023

Electron. J. Combin.

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We investigate the existence of Boolean degree $d$ functions on the Grassmann graph of $k$-spaces in the vector space $\mathbb{F}_q^n$. For $d=1$ several non-existence and classification results are known, and no non-trivial examples are known for $n \geq 5$. This paper focusses on providing a list of examples on the case $d=2$ in general dimension and in particular for $(n, k)=(6,3)$ and $(n,k) = (8, 4)$.We also discuss connections to the analysis of Boolean functions, regular sets/equitable bipartitions/perfect 2-colorings in graphs, $q$-analogs of designs, and permutation groups. In particular, this represents a natural generalization of Cameron-Liebler line classes.

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Section: Cameron-liebler Line Classes and Boolean Functions On The Gr...mentioning

confidence: 99%

Degree 2 Boolean Functions on Grassmann Graphs

Beule

D'haeseleer²,

Ihringer³

et al. 2023

Electron. J. Combin.

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“…Over the years, there have been many interesting extensions of this result. See [2, 9, 20, 23, 29, 31] for Cameron–Liebler sets of

k

‐spaces in PG

(n,q)

, [12] for Cameron–Liebler classes in finite sets, and [19] for Cameron–Liebler sets in several classical distance‐regular graphs.…”

Section: Introductionmentioning

confidence: 99%

Cameron–Liebler sets for maximal totally isotropic flats in classical affine spaces

Ji-dong

Wan

2023

J of Combinatorial Designs

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“…The many equivalent ways to describe a Cameron-Liebler set, both algebraically and combinatorially, sparked the interest of many researchers, and allowed for generalisations. Cameron-Liebler sets of k-spaces in PG(n, q) were studied in [3,4,16,42,47], and Cameron-Liebler sets of subsets of finite sets were discussed in [19,29,43]. In [18] Cameron-Liebler sets of generators in finite classical polar spaces were introduced, and those were further investigated in [17].…”

Section: Introductionmentioning

confidence: 99%

Equivalent definitions for (degree one) Cameron–Liebler classes of generators in finite classical polar spaces

Boeck

D'haeseleer

2020

Discrete Mathematics

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In this article, we study degree one Cameron-Liebler sets of generators in all finite classical polar spaces, which is a particular type of a Cameron-Liebler set of generators in this polar space, [9]. These degree one Cameron-Liebler sets are defined similar to the Boolean degree one functions, [15]. We summarize the equivalent definitions for these sets and give a classification result for the degree one Cameron-Liebler sets in the polar spaces W (5, q) and Q(6, q).

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Cameron–Liebler k-sets in subspaces and non-existence conditions

Cited by 4 publications

References 15 publications

Degree 2 Boolean Functions on Grassmann Graphs

Degree 2 Boolean Functions on Grassmann Graphs

Cameron–Liebler sets for maximal totally isotropic flats in classical affine spaces

Equivalent definitions for (degree one) Cameron–Liebler classes of generators in finite classical polar spaces

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