Adaptive Triangular Deployment Algorithm for Unattended Mobile Sensor Networks Ming Ma and Yuanyuan Yang Department of Electrical & Computer Engineering.

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Adaptive Triangular Deployment Algorithm for Unattended Mobile Sensor Networks Ming Ma and Yuanyuan Yang Department of Electrical & Computer Engineering The State University of New York at Stony Brook IEEE Transactions on Computers 2007

Outline Introduction Basic Triangular Deployment Algorithm Adaptive Triangular Deployment Algorithm Performance Evaluations Conclusions

Introduction The resource-limited sensor nodes are usually thrown into an unknown environment without a pre-configured infrastructure Without the control from the human being, sensor nodes must be “smart” enough to learn the working area by themselves and deploy themselves to the expected working targets

Introduction - Goals We expect that our algorithm Maximize node coverage Minimize coverage overlap and gap Minimize the total moving distance Adjust the node density based on different task requirements for different regions

Assumptions Each sensor can estimate the relative location information to nearby nodes by detecting the relative distances and angles Each node has a unique reference direction, which can be easily obtained from the electronic compass

Ideal Node Layout for Maximum Coverage rsrs AB C rsrs rsrs

Basic Triangular Deployment Algorithm

N0N0 N1N1 Y1Y1 Y0Y0 X1X1 X0X0 X-axis

Basic Triangular Deployment Algorithm After the movement vectors in all six sectors are obtained, they need to be transferred into uniform coordinates and added in order to obtain the total movement vector for the current round

Basic Triangular Deployment Algorithm

Minimizing Oscillation However, since the global location information of the network is difficult to obtain in the deployment process, it is impossible for each node to move to its desired target directly Threshold strategy Movement state strategy

Minimizing Oscillation -Threshold strategy When two far away nodes move toward each other and the distance between them decreased to T 1, two nodes stop moving When two close nodes move apart and the distance between them increases to T 2, they will stop and keep the current distance between them

Minimizing Oscillation -movement state strategy

Adaptive Triangular Deployment Algorithm We have discussed how to deploy nodes with equal or almost equal density in an open area where the entire area needs to be sensed uniformly However, in many real-world applications, the working area is partially or entirely bounded

Adaptive Triangular Deployment Algorithm

Thus, the distance between a real node and a virtual node needs to be adjusted to instead of

Adaptive Triangular Deployment Algorithm

When nodes move into a highly concerned region and find that they need to be deployed more densely they set a new shorter deployment radius, say, r d, instead of the sensing radius r

Performance Evaluations The ideal flat open area and practical environment where irregularly-shaped obstacles may block the movement of nodes Transmission range: 50 meters Sense range: 3 meters

Performance Evaluations

Conclusions Adaptive triangular deployment (ATRI) algorithm maximum no-gap coverage area limit the oscillation and reduce the total movement distance of nodes avoid obstacles and adjust the density dynamically based upon different requirements