SVP$_p$ is NP-Hard for all $p > 2$, Even to Approximate Within a Factor of $2^{\log^{1-\epsilon} n}$

Isaac M Hair; Amit Sahai

Electronic Colloquium on Computational Complexity

Under the auspices of the Computational Complexity Foundation (CCF)

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Paper:

TR25-153 | 21st October 2025 23:37

SVP$_p$ is NP-Hard for all $p > 2$, Even to Approximate Within a Factor of $2^{\log^{1-\epsilon} n}$

TR25-153 Authors: Isaac M Hair, Amit Sahai
Publication: 22nd October 2025 00:52
Downloads: 175

Keywords:

hardness of approximation, NP hard problems, shortest vector problem

Abstract:

We prove that SVP$_p$ is NP-hard to approximate within a factor of $2^{\log^{1 - \varepsilon} n}$, for all constants $\varepsilon > 0$ and $p > 2$, under standard deterministic Karp reductions. This result is also the first proof that \emph{exact} SVP$_p$ is NP-hard in a finite $\ell_p$ norm. Hardness for SVP$_p$ with $p$ finite was previously only known if NP~$\not \subseteq$~RP, and under that assumption, hardness of approximation was only known for all constant factors. As a corollary to our main theorem, we show that under the Sliding Scale Conjecture, SVP$_p$ is NP-hard to approximate within a small polynomial factor, for all constants $p > 2$.

Our proof techniques are surprisingly elementary; we reduce from a \emph{regularized} PCP instance directly to the shortest vector problem by using simple gadgets related to Vandermonde matrices and Hadamard matrices.

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