G. Giorgetti, ACM MSWiM 2008 – Vancouver - October 28, 2008 300 $ 70 $ 115 $ 185 $ Optimal RSS Threshold in Connectivity-Based Localization Schemes Gianni.

Slides:

Advertisements

Similar presentations

Localization for Mobile Sensor Networks ACM MobiCom 2004 Lingxuan HuDavid Evans Department of Computer Science University of Virginia.

Advertisements

Using Cramer-Rao-Lower-Bound to Reduce Complexity of Localization in Wireless Sensor Networks Dominik Lieckfeldt, Dirk Timmermann Department of Computer.

1 ECE 776 Project Information-theoretic Approaches for Sensor Selection and Placement in Sensor Networks for Target Localization and Tracking Renita Machado.

You are here Three Beacon Sensor Network Localization through Self Propagation Mohit Choudhary Under Guidance of: Dr. Bhaskaran Raman.

Yang Yang, Miao Jin, Hongyi Wu Presenter: Buri Ban The Center for Advanced Computer Studies (CACS) University of Louisiana at Lafayette 3D Surface Localization.

Computer Networks Group Universität Paderborn Ad hoc and Sensor Networks Chapter 9: Localization & positioning Holger Karl.

Range-Based and Range-Free Localization Schemes for Sensor Networks

1 Location-Aided Routing (LAR) in Mobile Ad Hoc Networks Young-Bae Ko and Nitin H. Vaidya Yu-Ta Chen 2006 Advanced Wireless Network.

Convex Position Estimation in Wireless Sensor Networks

“Localization in Underwater Sensor Networks” Presented by: Ola Ibrahim EL naggar J presentation.

Digital Data Transmission ECE 457 Spring Information Representation Communication systems convert information into a form suitable for transmission.

Localization from Mere Connectivity Yi Shang (University of Missouri - Columbia); Wheeler Ruml (Palo Alto Research Center ); Ying Zhang; Markus Fromherz.

An Empirical Characterization of Radio Signal Strength Variability in 3-D IEEE Networks Using Monopole Antennas Dimitrios Lymberopoulos, Quentin.

1 University of Freiburg Computer Networks and Telematics Prof. Christian Schindelhauer Wireless Sensor Networks 16th Lecture Christian Schindelhauer.

1 Target Tracking with Sensor Networks Chao Gui Networks Lab. Seminar Oct 3, 2003.

Distributed localization in wireless sensor networks

1 Localization Technologies for Sensor Networks Craig Gotsman, Technion/Harvard Collaboration with: Yehuda Koren, AT&T Labs.

1 University of Freiburg Computer Networks and Telematics Prof. Christian Schindelhauer Wireless Sensor Networks 17th Lecture Christian Schindelhauer.

Range-free Localization Schemes for Large Scale Sensor Networks

1 Spatial Localization Light-Seminar Spring 2005.

Probability Grid: A Location Estimation Scheme for Wireless Sensor Networks Presented by cychen Date ： 3/7 In Secon (Sensor and Ad Hoc Communications and.

Jana van Greunen - 228a1 Analysis of Localization Algorithms for Sensor Networks Jana van Greunen.

Locating Sensors in the Wild: Pursuit of Ranging Quality Wei Xi, Yuan He, Yunhao Liu, Jizhong Zhao, Lufeng Mo, Zheng Yang, Jiliang Wang,

A Distributed Localization Scheme for Wireless Sensor Networks with Improved Grid-Scan and Vector- Based Refinement Jang-Ping Sheu, Pei-Chun Chen, and.

A Location-determination Application in WirelessHART Xiuming Zhu 1, Wei Dong 1,Aloysius K. Mok 1,Song Han 1, Jianping Song 1, Deji Chen 2,Mark Nixon 2.

Wireless Sensor Networking for “Hot” Applications: Effects of Temperature on Signal Strength, Data Collection and Localization.

Localization in Sensor Networking John Quintero. Applications Application-driven, data-centric sensor networks frequently require location information.

Sensor Positioning in Wireless Ad-hoc Sensor Networks Using Multidimensional Scaling Xiang Ji and Hongyuan Zha Dept. of Computer Science and Engineering,

LOCALIZATION in Sensor Networking Hamid Karimi. Wireless sensor networks Wireless sensor node  power supply  sensors  embedded processor  wireless.

Energy Efficient Routing and Self-Configuring Networks Stephen B. Wicker Bart Selman Terrence L. Fine Carla Gomes Bhaskar KrishnamachariDepartment of CS.

Introduction to Sensor Networks Rabie A. Ramadan, PhD Cairo University 3.

Localization With Mobile Anchor Points in Wireless Sensor Networks

Localization in Wireless Sensor Networks Shafagh Alikhani ELG 7178 Fall 2008.

Bayesian Indoor Positioning Systems Presented by: Eiman Elnahrawy Joint work with: David Madigan, Richard P. Martin, Wen-Hua Ju, P. Krishnan, A.S. Krishnakumar.

Architectures and Applications for Wireless Sensor Networks ( ) Localization Chaiporn Jaikaeo Department of Computer Engineering.

June 21, 2007 Minimum Interference Channel Assignment in Multi-Radio Wireless Mesh Networks Anand Prabhu Subramanian, Himanshu Gupta.

Multi-hop-based Monte Carlo Localization for Mobile Sensor Networks

On Distinguishing the Multiple Radio Paths in RSS-based Ranging Dian Zhang, Yunhuai Liu, Xiaonan Guo, Min Gao and Lionel M. Ni College of Software, Shenzhen.

Algorithms for Wireless Sensor Networks Marcela Boboila, George Iordache Computer Science Department Stony Brook University.

1 Robust Statistical Methods for Securing Wireless Localization in Sensor Networks (IPSN ’05) Zang Li, Wade Trappe Yanyong Zhang, Badri Nath Rutgers University.

Localization and Secure Localization. The Problem The determination of the geographical locations of sensor nodes Why do we need Localization? –Manual.

Relative Accuracy based Location Estimation in Wireless Ad Hoc Sensor Networks May Wong 1 Demet Aksoy 2 1 Intel, Inc. 2 University of California, Davis.

A new Ad Hoc Positioning System 컴퓨터 공학과 오영준.

A Distributed Relay-Assignment Algorithm for Cooperative Communications in Wireless Networks ICC 2006 Ahmed K. Sadek, Zhu Han, and K. J. Ray Liu Department.

A Passive Approach to Sensor Network Localization Rahul Biswas and Sebastian Thrun International Conference on Intelligent Robots and Systems 2004 Presented.

0 IEEE SECON 2004 Estimation Bounds for Localization October 7 th, 2004 Cheng Chang EECS Dept,UC Berkeley Joint work with Prof.

Localization and Secure Localization. Learning Objectives Understand why WSNs need localization protocols Understand localization protocols in WSNs Understand.

Positioning in Ad-Hoc Networks - A Problem Statement Jan Beutel Computer Engineering and Networks Lab Swiss Federal Institute of Technology (ETH) Zurich.

1 Value of information – SITEX Data analysis Shubha Kadambe (310) Information Sciences Laboratory HRL Labs 3011 Malibu Canyon.

University “Ss. Cyril and Methodus” SKOPJE Cluster-based MDS Algorithm for Nodes Localization in Wireless Sensor Networks Ass. Biljana Stojkoska.

1 The Effects of Ranging Noise on Multihop Localization: An Empirical Study Kamin Whitehouse Joint With: Chris Karlof, Alec Woo, Fred Jiang, David Culler.

Cooperative Location- Sensing for Wireless Networks Authors ： Haris Fretzagias Maria Papadopouli Presented by cychen IEEE International Conference on Pervasive.

© 2007 Sean A. Williams 1 Ecolocation: A Sequence Based Technique for RF Localization in Wireless Sensor Networks Authors: Kiran Yedavalli, Bhaskar Krishnamachari,

C. Savarese, J. Beutel, J. Rabaey; UC BerkeleyICASSP Locationing in Distributed Ad-hoc Wireless Sensor Networks Chris Savarese, Jan Beutel, Jan Rabaey.

Network/Computer Security Workshop, May 06 The Robustness of Localization Algorithms to Signal Strength Attacks A Comparative Study Yingying Chen, Konstantinos.

Adaptive Tracking in Distributed Wireless Sensor Networks Lizhi Yang, Chuan Feng, Jerzy W. Rozenblit, Haiyan Qiao The University of Arizona Electrical.

1 Localization in Wireless Sensor Networks: Strategies to reduce energy consumption Sadaf Tanvir Benoît Ponsard {sadaf.tanvir,

G. Giorgetti, ACM MELT 2008 – San Francisco – September 19, 2008 Localization using Signal Strength: TO RANGE OR NOT TO RANGE? Gianni Giorgetti Sandeep.

Doc.: a Submission September 2004 Z. Sahinoglu, Mitsubishi Electric research LabsSlide 1 A Hybrid TOA/RSS Based Location Estimation Zafer.

Adaptive Radio Interferometric Positioning System Modeling and Optimizing Positional Accuracy based on Hyperbolic Geometry.

Communications Range Analysis Simulation Set Up –Single Biological Threat placed in Soldier Field –Communication range varied from meters –Sensor.

On Mobile Sink Node for Target Tracking in Wireless Sensor Networks Thanh Hai Trinh and Hee Yong Youn Pervasive Computing and Communications Workshops(PerComW'07)

Wireless Access and Networking Technology (WANT) Lab. An Efficient Data Aggregation Approach for Large Scale Wireless Sensor Networks Globecom 2010 Lutful.

1 A Coordinate-Based Approach for Exploiting Temporal-Spatial Diversity in Wireless Mesh Networks Hyuk Lim Chaegwon Lim Jennifer C. Hou MobiCom 2006 Modified.

Minimum spanning tree diameter estimation in random sensor networks in fractal dimension Students: Arthur Romm Daniel Kozlov Supervisor: Dr.Zvi Lotker.

LEMON: An RSS-Based Indoor Localization Technique Israat T. Haque, Ioanis Nikolaidis, and Pawel Gburzynski Computing Science, University of Alberta, Canada.

Mingze Zhang, Mun Choon Chan and A. L. Ananda School of Computing

Wireless Mesh Networks

Wireless Sensor Networks and Internet of Things

Presentation transcript:

G. Giorgetti, ACM MSWiM 2008 – Vancouver - October 28, $ 70 $ 115 $ 185 $ Optimal RSS Threshold in Connectivity-Based Localization Schemes Gianni Giorgetti Sandeep K.S. Gupta Gianfranco Manes ACM MSWiM - Vancouver October 28, 2008 IMPACT LAB Arizona State University

G. Giorgetti, ACM MSWiM 2008 – Vancouver - October 28, 2008 What is this about? Localization: the problem of locating devices and/or people Localization based on proximity We can reduce the error by optimal selection of one of the parameters Optimal RSS Threshold in Connectivity-Based Localization Schemes

G. Giorgetti, ACM MSWiM 2008 – Vancouver - October 28, 2008 Remote Monitoring Applications Gateway Server Mesh sensor network (x, y) = ?

G. Giorgetti, ACM MSWiM 2008 – Vancouver - October 28, 2008 Why not to use GPS? GPS Board $ x N GPS Receiver - 70 $ x N Wireless Node $ x N Sensor Board $ x N Shopping List: NOT RELIABLE INDOORS Sometimes “good enough” is good enough

G. Giorgetti, ACM MSWiM 2008 – Vancouver - October 28, 2008 Collaborative Localization Inputs: A set of anchor nodes In-network measurements Output: Node Coordinates RF-Based Approaches: Scene analysis (Fingerprinting) Range-Based (RSS, Interferometric) Connectivity d1d1 d2d2 d3d3 d4d4 d5d5

G. Giorgetti, ACM MSWiM 2008 – Vancouver - October 28, 2008 Radio-Based, Range-Free Localization What we like about connectivity: 1.Easy to acquire 2.Easy to communicate (binary value) 3.Easy to process 4.Reasonable accuracy 1 HOP 2 HOPS 3 HOPS

G. Giorgetti, ACM MSWiM 2008 – Vancouver - October 28, 2008 Example – 49 node network Comm. Range = ~ 33 m Connectivity = 9 Avg. Error = 6 – 10 m (0.2 – 0.3 R) Comm. Range = ~ 33 m Connectivity = 9 Avg. Error = 6 – 10 m (0.2 – 0.3 R)

G. Giorgetti, ACM MSWiM 2008 – Vancouver - October 28, 2008 Does it work indoors?

G. Giorgetti, ACM MSWiM 2008 – Vancouver - October 28, 2008 Why it doesn’t work… Every node is in the radio range of every node Nodes at different locations have the same neighbor sets Impossible to distinguish between nodes at different locations IDEA: TO REDUCE CONNECTIVITY BY SETTING A TRESHOLD. WHAT IS THE OPTIMAL VALUE?

G. Giorgetti, ACM MSWiM 2008 – Vancouver - October 28, D Localization RSS 1 RSS 2 RSS 3 RSS 4 … Connectivity-Based Localization = -72 dBm

G. Giorgetti, ACM MSWiM 2008 – Vancouver - October 28, 2008 Log-Normal Shadowing Model Path-Loss Exponent

G. Giorgetti, ACM MSWiM 2008 – Vancouver - October 28, 2008 Measurement Model Connectivity is a random variable Probability of detecting the nodes as “connected” Parameter Estimation Problem: We want to estimate d using observations C={0,1}. Is there a value P th that will reduce the estimation error?

G. Giorgetti, ACM MSWiM 2008 – Vancouver - October 28, 2008 Fisher Information Large value of F  Small Error Small value of F  Large Error Fisher Information: measures the amount of information that a random variable carries about an unknown parameter Cramér-Rao bound: minimum theoretical estimation error

G. Giorgetti, ACM MSWiM 2008 – Vancouver - October 28, 2008 What does F tell us? The available Fisher information: 1.Decreases with the distance 2.Decreases with the noise in the RSS data 3.Depends on how we set the threshold

G. Giorgetti, ACM MSWiM 2008 – Vancouver - October 28, 2008 A toy problem RSS [dBM] pdf There are two nodes (Node 1 and Node 2). You have to decide which one is closer using connectivity information. How do you set the threshold?

G. Giorgetti, ACM MSWiM 2008 – Vancouver - October 28, 2008 Optimal Connectivity Threshold RSS [dBM] pdf 1 1 For a single device the optimal threshold is equal to the expected received power. (p = 0.5)

G. Giorgetti, ACM MSWiM 2008 – Vancouver - October 28, 2008 Network Localization Fisher Information Matrix Cramér-Rao Bound: Anchors Blind Nodes

G. Giorgetti, ACM MSWiM 2008 – Vancouver - October 28, 2008 CRB for 2D Network

G. Giorgetti, ACM MSWiM 2008 – Vancouver - October 28, 2008 CRB for 3D Network Using the CRB we can determine the optimal threshold We cannot compute the CRB at runtime (it requires knowledge of the node positions)

G. Giorgetti, ACM MSWiM 2008 – Vancouver - October 28, 2008 Optimal Connectivity Setting the optimal threshold is equivalent to finding an optimal connectivity value. Easier to deal with (it doesn’t depend on the hardware) We investigated how this optimal connectivity value changes with different network parameters.

G. Giorgetti, ACM MSWiM 2008 – Vancouver - October 28, 2008 Invariance of the optimal conn. GOOD NEWS: The optimal connectivity doesn’t change with network scaling and with the propagation model parameters

G. Giorgetti, ACM MSWiM 2008 – Vancouver - October 28, 2008 Approximation and Simulations The Optimal Connectivity value increases with the network size. We find a formula to approximate the optimal connectivity value 2D

G. Giorgetti, ACM MSWiM 2008 – Vancouver - October 28, 2008 Using the approximate formula we find: Opt. Conn = 9.27 (Pth = dBm) Opt. Conn = 11.1 (Pth = dBm) Case Studies

G. Giorgetti, ACM MSWiM 2008 – Vancouver - October 28, THANKS!