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 $\sum_j w_j g(F_j)$, 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.
翻译:我们研究一个单一的处理器的在线日程安排问题,这可以被看作是经过仔细研究的尽量减少总加权流动时间的问题的延伸。特别是,我们提供了一个分析框架,这种框架来自双重性特性,不依赖潜在功能,而且适用于各种时间安排问题。我们的方法中的一个关键因素是绕过“黑箱”四舍五入的分数解决方案的“黑箱”需求,这可以提高竞争比率。我们首先将最高-最高一级(HDF)解释为一种初步的双重算法,并相应地证明HDF对于总分加权流动时间(因此可以伸缩到整体目标)来说是最佳的。我们根据证据的突出想法,展示了如何应用和扩展这一分析的范围,以尽量减少$sum_j w_jg(F_j)g(F_j)$这一更为普遍的问题,因为$w_j$是工作重量, 美元是流动时间,美元是非计算成本的功能。除其他结果外,我们提出改进了在设定“美元”的分数加权流动时间,但将“我们”的计算成本”和“我们的总体成本框架下的总体成本”的计算,作为总成本框架的升级的进度框架。