Channel-Aware Random Access Control for Distributed Estimation in Sensor Networks

A cross-layered slotted ALOHA protocol is proposed and analyzed for distributed estimation in sensor networks. Suppose that the sensors in the network record local measurements of a common event and report the data back to the fusion center through direct transmission links. We employ a channel-awar...

Full description

Saved in:
Bibliographic Details
Published in:IEEE transactions on signal processing 2008-07, Vol.56 (7), p.2967-2980
Main Authors: Hong, Y.-W.P., Keng-U Lei, Chong-Yung Chi
Format: Article
Language:English
Subjects:
Access control
Access protocols
Active control
Applied sciences
Channels
Control systems
Cooperative communications
Design optimization
distributed estimation
diversity combining
Diversity reception
Exact sciences and technology
Feedback
Information, signal and communications theory
medium access control
Miscellaneous
Networks
Policies
Sensor fusion
sensor networks
Sensors
Signal processing
statistical inference
Switches
Switching theory
Telecommunications and information theory
Television networks
Throughput
Time measurement
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:A cross-layered slotted ALOHA protocol is proposed and analyzed for distributed estimation in sensor networks. Suppose that the sensors in the network record local measurements of a common event and report the data back to the fusion center through direct transmission links. We employ a channel-aware transmission control where the transmission probability of each sensor is chosen according to the quality of its local observation and transmission channels. As opposed to maximizing the system throughput, our goal is to design transmission control policies that optimize the estimation performance. Two transmission control strategies are proposed: the maximum mean-square-error (MSE) reduction (MMR) scheme and the suboptimal two-mode MSE-reduction (TMMR) scheme. The MMR maximizes the MSE-reduction of the estimate after each time slot. However, this method requires knowledge of the number of active sensors and the accumulated estimation performance in each time slot, which must be provided through feedback from the fusion center. In TMMR, the sensors switch between two predetermined transmission control functions without explicit knowledge of the estimation performance and the number of active sensors in each time slot. Moreover, we notice that, if new observations are made by the sensors in each time slot, diversity combining techniques can be employed to fully exploit the data that the sensors measure over their idle time slots. Specifically, we perform selective combining on the observations that are made in between transmissions. As a result, we are able to exploit both the spatial and temporal diversity gains inherent in the multisensor system.
ISSN:1053-587X
1941-0476
DOI:10.1109/TSP.2008.917382