Primal–Dual and Dual-Fitting Analysis of Online Scheduling Algorithms for Generalized Flow-Time Problems

We study online scheduling problems on a single processor that can be viewed as extensions of the well-studied problem of minimizing total weighted flow time. In particular, we provide a framework of analysis that is derived by duality properties, does not rely on potential functions and is applicab...

Full description

Saved in:
Bibliographic Details
Published in:Algorithmica 2019-09, Vol.81 (9), p.3391-3421
Main Authors: Angelopoulos, Spyros, Lucarelli, Giorgio, Nguyen Kim, Thang
Format: Article
Language:English
Subjects:
Algorithm Analysis and Problem Complexity
Algorithms
Completion time
Computer Science
Computer Systems Organization and Communication Networks
Cost analysis
Cost function
Data Structures and Algorithms
Data Structures and Information Theory
Density
Job shops
Mathematics of Computing
Microprocessors
Production scheduling
Rounding
Scheduling
Theory of Computation
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:We study online scheduling problems on a single processor that can be viewed as extensions of the well-studied problem of minimizing total weighted flow time. In particular, we provide a framework of analysis that is derived by duality properties, does not rely on potential functions and is applicable to a variety of scheduling problems. A key ingredient in our approach is bypassing the need for “black-box” rounding of fractional solutions, which yields improved competitive ratios. We begin with an interpretation of Highest-Density-First (HDF) as a primal–dual algorithm, and a corresponding proof that HDF is optimal for total fractional weighted flow time (and thus scalable for the integral objective). Building upon the salient ideas of the proof, we show how to apply and extend this analysis to the more general problem of minimizing ∑ j w j g ( F j ) , where w j is the job weight, F j is the flow time and g is a non-decreasing cost function. Among other results, we present improved competitive ratios for the setting in which g is a concave function, and the setting of same-density jobs but general cost functions. We further apply our framework of analysis to online weighted completion time with general cost functions as well as scheduling under polyhedral constraints.
ISSN:0178-4617
1432-0541
DOI:10.1007/s00453-019-00583-8