This paper focuses on kernelization algorithms for the fundamental Knapsack problem. A kernelization algorithm (or kernel) is a polynomial-time reduction from a problem onto itself, where the output size is bounded by a function of some problem-specific parameter. Such algorithms provide a theoretical model for data reduction and preprocessing and are central in the area of parameterized complexity. In this way, a kernel for Knapsack for some parameter $k$ reduces any instance of Knapsack to an equivalent instance of size at most $f(k)$ in polynomial time, for some computable function $f(\cdot)$. When $f(k)=k^{O(1)}$ then we call such a reduction a polynomial kernel. Our study focuses on two natural parameters for Knapsack: The number of ...
We consider the special case of the bounded knapsack problem with divisible item sizes, and present ...
none4siWe analyze the computational complexity of three fundamental variants of the bilevel knapsack...
In this paper, we present the first average-case analysis proving an expected polynomial running tim...
Kernelization is a formalization of efficient preprocessing for \mathsf {np}\mathsf {np}-hard proble...
Kernelization is a formalization of efficient preprocessing for NP-hard problems using the framework...
AbstractKernelization is a strong and widely-applied technique in parameterized complexity. A kernel...
Makespan minimization (on parallel identical or unrelated machines) is arguably the most natural and...
A fundamental technique in the design of parameterized algorithms is kerneliza-tion: Given a problem...
Kernelization is a notion from parameterized complexity that captures the concept of efficient prepr...
We analyze the computational complexity of three fundamental variants of the bilevel knapsack proble...
In parameterized algorithmics the process of kernelization is defined as a polynomial time algorithm...
We introduce a new technique for proving kernelization lower bounds, called cross-composition. A cla...
We study pseudo-polynomial time algorithms for the fundamental \emph{0-1 Knapsack} problem. Recent r...
In this paper we propose a new framework for analyzing the performance of preprocessing algorithms. ...
A polynomial algorithm for the multiple bounded knapsack problem with divisible item sizes is prese...
We consider the special case of the bounded knapsack problem with divisible item sizes, and present ...
none4siWe analyze the computational complexity of three fundamental variants of the bilevel knapsack...
In this paper, we present the first average-case analysis proving an expected polynomial running tim...
Kernelization is a formalization of efficient preprocessing for \mathsf {np}\mathsf {np}-hard proble...
Kernelization is a formalization of efficient preprocessing for NP-hard problems using the framework...
AbstractKernelization is a strong and widely-applied technique in parameterized complexity. A kernel...
Makespan minimization (on parallel identical or unrelated machines) is arguably the most natural and...
A fundamental technique in the design of parameterized algorithms is kerneliza-tion: Given a problem...
Kernelization is a notion from parameterized complexity that captures the concept of efficient prepr...
We analyze the computational complexity of three fundamental variants of the bilevel knapsack proble...
In parameterized algorithmics the process of kernelization is defined as a polynomial time algorithm...
We introduce a new technique for proving kernelization lower bounds, called cross-composition. A cla...
We study pseudo-polynomial time algorithms for the fundamental \emph{0-1 Knapsack} problem. Recent r...
In this paper we propose a new framework for analyzing the performance of preprocessing algorithms. ...
A polynomial algorithm for the multiple bounded knapsack problem with divisible item sizes is prese...
We consider the special case of the bounded knapsack problem with divisible item sizes, and present ...
none4siWe analyze the computational complexity of three fundamental variants of the bilevel knapsack...
In this paper, we present the first average-case analysis proving an expected polynomial running tim...