|
| Effective Streaming of Clustered Sensor Data in Harsh Environment
|
|
Full
text: |
 PDF(220.7KB) |
|
|
Source |
International Journal of Computer Networks (IJCN) |
|
Table of Contents |
|
|
Download
Complete Issue PDF(912.87KB) |
|
Volume: 3 Issue: 3 |
| |
Pages: NULL |
|
Publication
Date: July / August 2011 |
|
ISSN
(Online): 1985-4129 |
|
|
|
|
|
Pages |
178 - 195 |
|
Author(s) |
|
|
|
Published
Date |
05-08-2011 |
|
Publisher |
CSC
Journals, Kuala Lumpur,
Malaysia |
|
ADDITIONAL
INFORMATION |
| Keywords Abstract References Cited by Related Articles Collaborative
Colleague |
| |
|
| |
KEYWORDS: Ad-hoc Network, Sensor Network, QoS |
|
|
| |
|
|
| This Manuscript is indexed in the following databases/websites:- |
|
| 1. Google Scholar |
| 2. Scribd |
| 3. Docstoc |
| |
|
| |
|
|
| A milestone of success for any sensor network establishment is successful data streaming over point-to-point communications (P2P). Typical P2P services would present the descriptive best-effort (BE) or other Quality of Service (QoS) streams. In this research, we present the Stateless Wireless Ad-hoc Network model (SWAN), an integrated model that is known to work in typical ad-hoc configurations like the classical wireless ad-hoc sensor networks. SWAN is a lightweight QoS model that enables operations over any routing protocol or Media Access Control (MAC) layers while exhibiting some advantages over competing models. Nevertheless, SWAN is vulnerable to troubles related to mobility and false admission. The SWAN model design relies on picking a candidate (victim) data flow to manipulate as a congestion control measure. We extend SWAN by adding the destination-based regulation and also show the reasons why the destination-based regulation chooses real-time data victim streams in an accurate mode.
Thus, we propose the use of destination-based regulation to resolve the dynamic congestion issues. This confines SWANs pertinence for streaming scenarios such as the instance of essential continuous broadcast (CB-streaming). We consider, it is possible to transport CB communications over substitute MAC layer such as the 802.11 or other wireless technology. To perform that, we introduce the purpose of SWAN in addition to the suggested enhanced destination based algorithm to transport the trusted CB-streaming applying P2P communications, but by rendering it with dissimilar QoS parameters. We believe that the SWAN approach in this regard is more in line with the nature of sensor networking with the awareness that sensors normally form and vanish quickly giving small opportunity to reconfigure or reposition the profiles of dynamically formed networks. Hence, sensing devices maintain low computational, storage capacities, processing, and battery life.
|
| |
|
| |
|
| |
| |
|
| |
|
| |
| |
|
| |
|
| |
| |
|
| |
|
| |
|
| Y. Morgan : Colleagues
|
|
| T. Kunz : Colleagues
|
|
| M. El-Gindy : Colleagues
|
|
