(1-ε)-Approximation of Knapsack in Nearly Quadratic Time

Abstract

Knapsack is one of the most fundamental problems in theoretical computer science. In the (1 - ε)-approximation setting, although there is a fine-grained lower bound of (n + 1 / ε) 2 - o(1) based on the (, +)-convolution hypothesis ([K\"unnemann, Paturi and Stefan Schneider, ICALP 2017] and [Cygan, Mucha, Wegrzycki and Wlodarczyk, 2017]), the best algorithm is randomized and runs in O(n + (1ε)11/5/2((1/ε))) time [Deng, Jin and Mao, SODA 2023], and it remains an important open problem whether an algorithm with a running time that matches the lower bound (up to a sub-polynomial factor) exists. We answer the question positively by showing a deterministic (1 - ε)-approximation scheme for knapsack that runs in O(n + (1 / ε) 2) time. We first extend a known lemma in a recursive way to reduce the problem to n ε-additive approximation for n items with profits in [1, 2). Then we give a simple efficient geometry-based algorithm for the reduced problem.