Asymmetrical Round Trip BasedSynchronization-Free Localization in

Large-Scale Underwater Sensor Networks

Bin Liu, Hongyang Chen, Ziguo Zhong, and H. Vincent Poor

Computer Science Department at the University of Southern California

in Los Angeles, Graduate School of

Information Science and Technology, University of

Tokyo, University of Minnesota, Fellow, IEEE

IEEE Transaction on Wireless Communications 2010

Introduction Related Work The ARTL Scheme Performance Evaluation Conclusion

Outline

Underwater sensor networks(UWSNs) have been proposed for many applications: Scientific exploration Oceanographic data collection Pollution monitoring Coastline protection

Introduction

Accurate node localization

Introduction

(2,4,1)

Typical localization techniques Range-based:

Estimating the distances between beacons and ordinary nodes

Range-free: Multilateration

Introduction

Ranged-based Difficult to synchronize among nodes for ranging

and may introduce additional communication overhead

Introduction

Three different kinds of nodes: Base stations Beacon nodes(s) Ordinary nodes(l)

Related Work

SeaWeb Navigation(SWN)Symmetrical round trip based strategy

Related Work

SDMEClock-offset-compensate based one way localization scheme

Clock-offset compensate(α), ranging(l) Execute time synchronization every

1/αlocalization tasks

Related Work

To reduce the data exchanges as much as possible

Goal

Assume Beacon nodes can receive their own packets Nodes have pressure sensors to determine their

depths Base station can obtain distances from ordinary

nodes to all its corresponding beacon nodes

The ARTL Scheme

Position estimation

The ARTL Scheme

Beacon NodeProject of the Beacon NodeOrdinary Node

:

:

:

A

P

P’

ON

M

L

L’M’

N’O’

Beacon Nodes(s)

The ARTL Scheme

AOrdinary Nodes(l)

packet

:

B

P

L

t1 t2

t3

t4

t5

t6

t7

t8

t9

The ARTL Scheme

A

P

P’

ON

ML

L’ M’

N’O’

Performance Evaluation

Energy consumptions for sending and receiving one packet

Average energy consumption for per node per localization

Performance Evaluation

Expected energy consumption

Energy-error product(EEP)

Performance Evaluation

Expected energy consumption

Performance Evaluation

Energy-error product(EEP)

Performance Evaluation

Localization error

Performance Evaluation

Energy-error product

Performance Evaluation

Localization error in one SDME period

Performance Evaluation

Energy-error product in one SDME period

Performance Evaluation

The authors propose an asymmetrical round trip based localization (ARTL) algorithm that seeks to achieve node localization in large-scale UWSNs in an energy-efficient, easily implemented and accurate manner without time synchronization.

Simulation results show that ARTL can greatly reduce localization energy consumption while maintaining relatively high localization accuracy compared with other localization algorithms.

Conclusion