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FormalConjectures.GreensOpenProblems.«26»

Green's Open Problem 26 #

References:

def Green26.StandardCube {p : } [Fact (Nat.Prime p)] (n : ) :
Set (𝔽 p n)

The standard cube in $\mathbb{F}_p^n$ is the set of points with coordinates in $\{0, 1\}$.

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Instances For
    def Green26.IsCube {p n : } [Fact (Nat.Prime p)] (A : Set (𝔽 p n)) :

    A cube is the image of $\lbrace 0, 1\rbrace^n$ under a linear automorphism.

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    Instances For
      theorem Green26.green_26 (n : ) (A : Fin 100Set (𝔽₃ n)) :
      (∀ (i : Fin 100), IsCube (A i))i : Fin 100, A i = Set.univ

      Let $A_1, \dots, A_{100}$ be "cubes" in $\mathbb{F}^n_3$. Is it true that $A_1 + \dots + A_{100} = \mathbb{F}^n_3$?

      theorem Green26.green_26.variants.yu25 (n : ) (A : Fin 4Set (𝔽₃ n)) :
      (∀ (i : Fin 4), IsCube (A i))i : Fin 4, A i = Set.univ

      [Yu25] has solved the original problem (with 100 replaced by 4)

      theorem Green26.green_26.variants.alm91 (p : ) [Fact (Nat.Prime p)] :
      ∃ (k : ), ((fun (n : ) => (k n)) =O[Filter.atTop] fun (n : ) => Real.log n) ∀ᶠ (n : ) in Filter.atTop, ∀ (A : Fin (k n)Set (𝔽 p n)), (∀ (i : Fin (k n)), IsCube (A i))i : Fin (k n), A i = Set.univ

      [ALM91] showed that if 100 is replaced by $\leq c(p) \log n$ then the result is true for $\mathbb{F}^n_p$.

      theorem Green26.green_26.variants.open :
      sorry ∀ (p : ) [inst : Fact (Nat.Prime p)], ∃ (C : ), ∀ (n : ) (A : Fin CSet (𝔽 p n)), (∀ (i : Fin C), IsCube (A i))i : Fin C, A i = Set.univ

      The analogous problem in $\mathbb{F}^n_p$ remains open. [Gr24]