New bounds for double covers of the discrete box 0,1,2d
Abstract
A proper sub-box of A=\0,1,2\d is a product S1×…× Sd with each ≠ Si⊂neq\0,1,2\. A double cover is a finite multiset of proper sub-boxes covering every point of A exactly twice; write f(d) for the minimum size of a double cover. Leader, Milicevic and Tan asked whether f(d) 2d for all d (Question 4.1 of the PatternBoost paper of Charton-Ellenberg-Wagner-Williamson), analogous to the Alon-Bohman-Holzman-Kleitman partition bound 2d. No better than the trivial volume bound was previously known, for any d 2. We prove the first nontrivial lower bounds. A modular refinement of the parity argument gives f(d) 2d+1/(d+1); a slicing argument gives f(4) 19, f(5) 33, both above 2d, resolving the question for d=4,5 -- the first cases beyond the trivially known d 3. A finer "line rigidity" argument yields f(6) 60, breaking the profile-statistic barrier (capped at 57, shown here). This is formally verified in Lean 4: f(6) 60 is machine-checked on the three standard Mathlib axioms alone. On the upper-bound side, a dimension-lifting construction f(r+3) 6· 2r+3f(r) gives f(6) 81 (improving the known 82) and f(d)(65+o(1))2d asymptotically; a refinement improves the constant to 87. This makes partial progress on PatternBoost's problem of reducing their constant 1.28, and refutes the closed-form guess f(d)=5· 2d-2+1 from d=7 on. Together, 60 f(6) 81. Finally we isolate the construction-side obstruction -- an "S+c=2j+1" phenomenon, every skeleton sitting exactly one box past the partition bound -- and show it is of a piece with the Leader-Milicevic-Tan question itself.
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