Fix even $n$ and consider the boolean function $f : \{0, 1\}^n \rightarrow \{0, 1\}$, $f : (x_0, \ldots , x_{n - 1}) \mapsto (x_0 \vee x_1) \wedge (x_2 \vee x_3) \wedge \cdots \wedge (x_{n - 2} \vee x_{n - 1})$. Fix a field $K$ and any affine hyperplane $H \subset K^n$.

**Conjecture.** If $H \cap \{0, 1\}^n \subset f^{-1}(1)$, then  $\left| H \cap \{0, 1\}^n \right| \leq 2^{\frac{n}{2}}$.

**Notes.**
- Because $\left| f^{-1}(1) \right| = 3^{\frac{n}{2}}$, the claimed bound on $\left| H \cap \{0, 1\}^n \right|$ is exponentially smaller than the _a priori_ maximum.
- The claimed upper bound can easily be attained: indeed, set $K := \mathbb{F}_p$ for $p > n$ (e.g.) and set $H$ as the kernel of the functional $H : (x_0, \ldots , x_{n - 1}) \mapsto x_1 + x_3 + \cdots + x_{n - 1}$. It's easy to check that $H \cap \{0, 1\}^n \subset f^{-1}(1)$ and $\left| H \cap \{0, 1\}^n \right| = 2^{\frac{n}{2}}$. Thus the claim is that this is the best you can do.
- Viewed as a poset with the natural ordering inherited from $\{0, 1\}^n$, $f^{-1}(1)$ is exactly the $\frac{n}{2}$-dimensional "cubical lattice" of e.g. [Metropolis and Rota, 1978][1] (i.e., the facets of the $\frac{n}{2}$-cube, ordered by inclusion). $2^{\frac{n}{2}}$ is exactly the number of _vertices_ (minimal elements) of this lattice.
- The problem can also be phrased "dually" in terms of subset sums. It says that if an array of field elements $a_0, \ldots , a_{n - 1}, a$'s subset sums "lacks adjacent elements", in the sense that every $\{i_0, \ldots , i_{k - 1}\} \subset \{0, \ldots , n -1 \}$ such that $\sum_{j = 0}^{k - 1} a_{i_j} = a$ also satisfies $\{2 j, 2 j + 1 \} \cap \{i_0, \ldots , i_{k - 1}\} \neq \emptyset$ for each $j \in \{0, \ldots , \frac{n}{2} - 1\}$, then there can be at most $2^{\frac{n}{2}}$ subsets $\{i_0, \ldots , i_{k - 1}\} \subset \{0, \ldots , n - 1\}$ such that $\sum_{j = 0}^{k - 1} a_{i_j} = a$.
- The problem is related to certain Littlewood–Offord-type problems. Indeed, a [1993 paper of Griggs][2] shows that any $H$ with nonzero coefficients satisfies $H \cap \{0, 1\}^n \leq {n \choose \frac{n}{2}}$. Thus the goal is to instead assume that $H \cap \{0, 1\}^n \subset f^{-1}(1)$, and then again try to upper-bound the size of $H \cap \{0, 1\}^n$.
- The problem seems possibly related to the "Eventown" problem (see [Babai and Frankl][3], Ex. 2.3.11). That theorem states that if a family $\mathcal{F} = \{F_0, \ldots , F_{m - 1}\}$ of subsets of the powerset $\mathcal{P}(\{0, \ldots , n - 1\})$ satisfies $\left| F_i \cap F_j \right| \equiv 0 \pmod{2}$ for each $i, j \in \{0, \ldots , m - 1\}$, then $m \leq 2^{\frac{n}{2}}$. I have been unable to reduce the problem at hand to the Eventown problem.

**EDIT:** Thanks @Antoine Labelle for the nice answer in characteristic 2. I think the general case is much harder, so I will ideally wait for that before accepting.

I care most about the case $\mathbb{F}_p$, for $p$ a "large" prime (say, in $p \in \{2^{n-1}, \ldots , 2^n - 1\}$), and that's what I have in mind for the bounty. **I believe** this should be true for any field!


  [1]: https://www.jstor.org/stable/2100984
  [2]: https://citeseerx.ist.psu.edu/viewdoc/download?doi=10.1.1.104.5579&rep=rep1&type=pdf
  [3]: https://people.cs.uchicago.edu/~laci/CLASS/HANDOUTS-COMB/BaFrNew.pdf