Planted Random Number Partitioning Problem

Abstract

We consider the random number partitioning problem (NPP): given a list X N(0,In) of numbers, find a partition σ∈\-1,1\n with a small objective value H(σ)=1n| σ,X|. The NPP is widely studied in computer science; it is also closely related to the design of randomized controlled trials. In this paper, we propose a planted version of the NPP: fix a σ* and generate X N(0,In) conditional on H(σ*) 3-n. The NPP and its planted counterpart are statistically distinguishable as the smallest objective value under the former is (n2-n) w.h.p. Our first focus is on the values of H(σ). We show that, perhaps surprisingly, planting does not induce partitions with an objective value substantially smaller than 2-n: σ σ*H(σ) = (2-n) w.h.p. Furthermore, we completely characterize the smallest H(σ) achieved at any fixed distance from σ*. Our second focus is on the algorithmic problem of efficiently finding a partition σ, not necessarily equal to σ*, with a small H(σ). We show that planted NPP exhibits an intricate geometrical property known as the multi Overlap Gap Property (m-OGP) for values 2-(n). We then leverage the m-OGP to show that stable algorithms satisfying a certain anti-concentration property fail to find a σ with H(σ)=2-(n). Our results are the first instance of the m-OGP being established and leveraged to rule out stable algorithms for a planted model. More importantly, they show that the m-OGP framework can also apply to planted models, if the algorithmic goal is to return a solution with a small objective value.