Online Unbounded Knapsack
July 02, 2024 Β· Declared Dead Β· π Theory of Computing Systems
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Authors
Hans-Joachim BΓΆckenhauer, Matthias Gehnen, Juraj HromkoviΔ, Ralf Klasing, Dennis Komm, Henri Lotze, Daniel Mock, Peter Rossmanith, Moritz Stocker
arXiv ID
2407.02045
Category
cs.DS: Data Structures & Algorithms
Citations
2
Venue
Theory of Computing Systems
Last Checked
4 months ago
Abstract
We analyze the competitive ratio and the advice complexity of the online unbounded knapsack problem. An instance is given as a sequence of n items with a size and a value each, and an algorithm has to decide how often to pack each item into a knapsack of bounded capacity. The items are given online and the total size of the packed items must not exceed the knapsack's capacity, while the objective is to maximize the total value of the packed items. While each item can only be packed once in the classical 0-1 knapsack problem, the unbounded version allows for items to be packed multiple times. We show that the simple unbounded knapsack problem, where the size of each item is equal to its value, allows for a competitive ratio of 2. We also analyze randomized algorithms and show that, in contrast to the 0-1 knapsack problem, one uniformly random bit cannot improve an algorithm's performance. More randomness lowers the competitive ratio to less than 1.736, but it can never be below 1.693. In the advice complexity setting, we measure how many bits of information the algorithm has to know to achieve some desired solution quality. For the simple unbounded knapsack problem, one advice bit lowers the competitive ratio to 3/2. While this cannot be improved with fewer than log(n) advice bits for instances of length n, a competitive ratio of 1+epsilon can be achieved with O(log(n/epsilon)/epsilon) advice bits for any epsilon>0. We further show that no amount of advice bounded by a function f(n) allows an algorithm to be optimal. We also study the online general unbounded knapsack problem and show that it does not allow for any bounded competitive ratio for deterministic and randomized algorithms, as well as for algorithms using fewer than log(n) advice bits. We also provide an algorithm that uses O(log(n/epsilon)/epsilon) advice bits to achieve a competitive ratio of 1+epsilon for any epsilon>0.
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