Your search keyword '"Ming-Chung Tang"' showing total 2 results

1. Q-bridge: a QoS enabled bridging model for 802.11 access point

Author

Li-Ping Tung, Wei-Kuan Shih, and Ming-Chung Tang

Subjects

Mobile radio, Wireless network, Computer science, business.industry, Network packet, Quality of service, Distributed computing, ComputerSystemsOrganization_COMPUTER-COMMUNICATIONNETWORKS, law.invention, Scheduling (computing), law, GSM, Wireless lan, Wireless, Wi-Fi, Data as a service, business, Computer network

Abstract

The rapid growth of wireless LAN-enabled devices over recent years has generated a successful framework for wireless data accessing. It seems viable to expand the framework as part of the last mile solution for mobile users to access data services. Therefore, in this paper, we further focus on quality of service (QoS) and timeliness issues for supporting advanced multimedia applications in such environments. A bridging model, named Q-bridge, is proposed in the paper for layer-2 access points to exhibiting QoS and real-time packet scheduling capabilities in the last mile configuration. The model explicitly applies the imprecise computation technique. That is, each bridged packet can be logically divided into two portions: a mandatory portion and an optimal portion. The mandatory portions must be scheduled to transmit by their deadlines while the optional portions can be chopped to meet their deadlines or QoS requirements. By taking advantage of this model and the scheduling algorithms we devised, wireless data services can benefit from QoS and timeliness guarantees provided by access points supporting Q-bridge at the last mile.

Published

2004

2. Imprecise Computations with Deferred Optional Tasks.

Author

JIA-MING CHEN, WAN-CHEN LU, WEI-KUAN SHIH, and MING-CHUNG TANG

Subjects

COMPUTER scheduling, TASKS, REAL-time control, ALGORITHMS, QUALITY of service

Abstract

The imprecise computation model is an extension of the traditional real-time processing model. In this model, each imprecise task is logically divided into two portions: a mandatory portion and an optional portion. Since the optional portions of imprecise tasks can be traded for their deadlines and/or the required quality of service (QoS), the resulting quality of executing tasks in this model can be controlled by different strategies of the scheduling algorithms. In this paper, we present two significant results pertaining to on-line scheduling problems in the model of imprecise computation obeying Deferred Optional Tasks (DOT) scheduling discipline. The first significant result presented is, to the best of our knowledge, the very first proof of NP-hardness property for the problem of on-line, imprecise DOT scheduling without preemption (DOTwoP). And the second one is that we propose an O(n log²n) algorithm to solve the problem of on-line, imprecise DOT scheduling with preemption (DOTwP) when tasks are ready upon arrival. [ABSTRACT FROM AUTHOR]

Published

2009