788.11J Presentation “Flock Control: Using Information Energy” Presented by Mukundan Sridharan.

Slides:

Advertisements

Similar presentations

Kinetic Molecular Theory

Advertisements

On the Coverage Problem in Video- based Wireless Sensor Networks Stanislava Soro Wendi Heinzelman University of Rochester.

P4 – Explaining Motion. Average Speed Average Speed = Total Distance/Total Time.

Explaining motion P4. Big picture How forces arise How forces arise Friction and normal reaction Friction and normal reaction Adding forces Adding forces.

Queuing Network Models for Delay Analysis of Multihop Wireless Ad Hoc Networks Nabhendra Bisnik and Alhussein Abouzeid Rensselaer Polytechnic Institute.

Dalton’s Law of Partial Pressure In mixtures of gases each component gas behaves independently of the other(s). John Dalton (remember him from.

Minimum Energy Mobile Wireless Networks IEEE JSAC 2001/10/18.

Integrated Coverage and Connectivity Configuration in Wireless Sensor Networks Xiaorui Wang, Guoliang Xing, Yuanfang Zhang*, Chenyang Lu, Robert Pless,

Guang Tan, Stephen A. Jarvis, and Anne-Marie Kermarrec IEEE Transactions on Mobile Computing, VOL. 8, NO.6, JUNE Yun-Jung Lu.

CSLI 5350G - Pervasive and Mobile Computing Week 3 - Paper Presentation “RPB-MD: Providing robust message dissemination for vehicular ad hoc networks”

1 A Novel Topology-blind Fair Medium Access Control for Wireless LAN and Ad Hoc Networks Z. Y. Fang and B. Bensaou Computer Science Department Hong Kong.

Better Group Behaviors in Complex Environments using Global Roadmaps O. Burchan Bayazit, Jyh-Ming Lien and Nancy M. Amato Presented by Mohammad Irfan Rafiq.

“Sensor Flock” An Airborne Wireless Sensor Network of Micro-Air Vehicles Presented by: Ahmed ezz-eldin.

COORDINATION and NETWORKING of GROUPS OF MOBILE AUTONOMOUS AGENTS.

788.11J Presentation “Sensor Flock” Presented by Ahmed Saber.

1 Next Century Challenges: Scalable Coordination in sensor Networks MOBICOMM (1999) Deborah Estrin, Ramesh Govindan, John Heidemann, Satish Kumar Presented.

Differentiated Surveillance for Sensor Networks Ting Yan, Tian He, John A. Stankovic CS294-1 Jonathan Hui November 20, 2003.

Diffusion. Atomic Collision  Molecules in a gas make collisions with each other as well as the wall.  There is an average time and average distance.

1 Prediction-based Strategies for Energy Saving in Object Tracking Sensor Networks Tzu-Hsuan Shan 2006/11/06 J. Winter, Y. Xu, and W.-C. Lee, “Prediction.

On the Construction of Energy- Efficient Broadcast Tree with Hitch-hiking in Wireless Networks Source: 2004 International Performance Computing and Communications.

Globecom 2004 Energy-Efficient Self-Organization for Wireless Sensor Networks: A Fully Distributed approach Liang Zhao, Xiang Hong, Qilian Liang Department.

Distributed Sensing and Data Collection Via Broken Ad Hoc Wireless Connected Networks Mobile Robots By Alan FT Winfield Presented By Navpreet Bawa.

IEEE TSMCA 2005 IEEE TRANSACTIONS ON SYSTEMS, MAN, AND CYBERNETICS Presented by 황재호.

8/22/20061 Maintaining a Linked Network Chain Utilizing Decentralized Mobility Control AIAA GNC Conference & Exhibit Aug. 21, 2006 Cory Dixon and Eric.

Pursuit Evasion Games (PEGs) Using a Sensor Network Luca Schenato, Bruno Sinopoli Robotics and Intelligent Machines Laboratory UC Berkeley

Dr. Shankar Sastry, Chair Electrical Engineering & Computer Sciences University of California, Berkeley.

Interference Minimization and Uplink Relaying For a 3G/WLAN Network Ju Wang Virginia Commonwealth University May, 2005.

High Throughput Route Selection in Multi-Rate Ad Hoc Wireless Networks Dr. Baruch Awerbuch, David Holmer, and Herbert Rubens Johns Hopkins University Department.

A Vehicular Ad Hoc Networks Intrusion Detection System Based on BUSNet.

RTS/CTS-Induced Congestion in Ad Hoc Wireless LANs Saikat Ray, Jeffrey B. Carruthers, and David Starobinski Department of Electrical and Computer Engineering.

Tuning the Carrier Sensing Range of IEEE MAC Jing Deng,Ben Liang and Pramod K. Varshney Univ. of New Orleans Globecom 2004.

Query Driven Data Collection and Data Forwarding in Intermittently Connected Mobile Sensor Networks Wei WU 1, Hock Beng LIM 2, Kian-Lee TAN 1 1 National.

Nuttapon Boonpinon Advisor Dr. Attawith Sudsang Department of Computer Engineering,Chulalongkorn University Pattern Formation for Heterogeneous.

M-GEAR: Gateway-Based Energy-Aware Multi-Hop Routing Protocol

Built in Collision Avoidance for Unmanned Aircraft Systems (UAS)

UCAN: A Unified Cellular and Ad Hoc Network Architecture Presenter: Tripp Parker Authors: Haiyun Luo Ramachandran Ramjee Prasun Sinha, Li Erran Li, Songwu.

EPL 476 Fundamental Concepts in Wireless Networks

DARP: Distance-Aware Relay Placement in WiMAX Mesh Networks Weiyi Zhang *, Shi Bai *, Guoliang Xue §, Jian Tang †, Chonggang Wang ‡ * Department of Computer.

Using Pattern of Social Dynamics in the Design of Social Networks of Sensors - Marello Tomasini, Franco Zambonelli, Ronaldo Menezes 한국기술교육대학교 전기전자통신 공학부.

Coordinated Sensor Deployment for Improving Secure Communications and Sensing Coverage Yinian Mao, Min Wu Security of ad hoc and Sensor Networks, Proceedings.

Symbiotic Simulation of Unmanned Aircraft Systems (UAS)

Connectivity-Aware Routing (CAR) in Vehicular Ad Hoc Networks Valery Naumov & Thomas R. Gross ETH Zurich, Switzerland IEEE INFOCOM 2007.

Rushing Attacks and Defense in Wireless Ad Hoc Network Routing Protocols ► Acts as denial of service by disrupting the flow of data between a source and.

Selection and Navigation of Mobile sensor Nodes Using a Sensor Network Atul Verma, Hemjit Sawant and Jindong Tan Department of Electrical and Computer.

Probabilistic Coverage in Wireless Sensor Networks Authors : Nadeem Ahmed, Salil S. Kanhere, Sanjay Jha Presenter : Hyeon, Seung-Il.

Network UAV C3 Stage 1 Final Briefing Timothy X Brown University of Colorado at Boulder Interdisciplinary Telecommunications Program Electrical and Computer.

Trade-offs Between Mobility and Density for Coverage in Wireless Sensor Networks Wei Wang, Vikram Srinivasan and Kee-Chaing Chua National University of.

1 Probabilistic Coverage in Wireless Sensor Networks Nadeem Ahmed, Salil S. Kanhere and Sanjay Jha Computer Science and Engineering, University of New.

Issues and Challenges for Co-operative UAV Missions Chris Halliday and Tony Dodd.

By Fernando Martincic, Loren Schwiebert.  Sensors periodically send data to BS.  Sensors send data to BS when threshold is exceeded. (reactive method)

MMAC: A Mobility- Adaptive, Collision-Free MAC Protocol for Wireless Sensor Networks Muneeb Ali, Tashfeen Suleman, and Zartash Afzal Uzmi IEEE Performance,

Computer Network Lab. Integrated Coverage and Connectivity Configuration in Wireless Sensor Networks SenSys ’ 03 Xiaorui Wang, Guoliang Xing, Yuanfang.

Performance of Adaptive Beam Nulling in Multihop Ad Hoc Networks Under Jamming Suman Bhunia, Vahid Behzadan, Paulo Alexandre Regis, Shamik Sengupta.

Richard Patrick Samples Ph.D. Candidate, ECE Department 1.

Honeywell Navigation, Communication and Control SAE G&C Committee Meeting Oct 19, 2005

Load Balanced Link Reversal Routing in Mobile Wireless Ad Hoc Networks Nabhendra Bisnik, Alhussein Abouzeid ECSE Department RPI Costas Busch CSCI Department.

Saran Jenjaturong, Chalermek Intanagonwiwat Department of Computer Engineering Chulalongkorn University Bangkok, Thailand IEEE CROWNCOM 2008 acceptance.

A Protocol for Tracking Mobile Targets using Sensor Networks H. Yang and B. Sikdar Department of Electrical, Computer and Systems Engineering Rensselaer.

Mobility Increases the Connectivity of K-hop Clustered Wireless Networks Qingsi Wang, Xinbing Wang and Xiaojun Lin.

I-Hsin Liu1 Event-to-Sink Directed Clustering in Wireless Sensor Networks Alper Bereketli and Ozgur B. Akan Department of Electrical and Electronics Engineering.

Distributed Algorithms for Dynamic Coverage in Sensor Networks Lan Lin and Hyunyoung Lee Department of Computer Science University of Denver.

VORONOI DIAGRAM AND CONVEX HULL BASED GEOCASTING AND ROUTING IN WIRELESS NETWORKS 指導教授：許子衡報告學生：翁偉傑 1 Copyright # 2006 John Wiley & Sons, Ltd. Wirel. Commun.

KAIS T Sensor Deployment Based on Virtual Forces Reference: Yi Zou and Krishnendu Chakarabarty, “Sensor Deployment and Target Localization Based on Virtual.

1 On Improving Data Accessibility in Storage Based Sensor Networks Tan Apaydin, Serdar Vural and Prasun Sinha IEEE International Conference on Mobile Adhoc.

I owa S tate U niversity Laboratory for Advanced Networks (LAN) Coverage and Connectivity Control of Wireless Sensor Networks under Mobility Qiang QiuAhmed.

Students: Yossi Turgeman Avi Deri Self-Stabilizing and Efficient Robust Uncertainty Management Instructor: Prof Michel Segal.

788.11J Presentation “Atmospheric Observatory”

Outline 1. INTRODUCTION 2. PRELIMINARIES 3.THE PROPOSED PROTOCOL

Spectrum Sharing in Cognitive Radio Networks

Do Now Give 1 example of potential energy.

Presentation transcript:

788.11J Presentation “Flock Control: Using Information Energy” Presented by Mukundan Sridharan

The Main Idea Use a Flock of Bat-sized Micro Aerial Vehicles (MAV) to sense the air of a medium sized city (20 km radius and 2 Km height), for toxic material. The MAVs form a Ad hoc network and relays the data back to a ground control centre. We want more sensing nodes in areas of higher toxic plumes As the MAVs move the communication with the base station should not be interrupted.

The Main Achievements Information Energy gradient for command and control: –How important is a certain region –Based on: Quality of data sensed by the node and its neighbors Amount of data relayed to BS by the node and its neighbors –More important a region, less is the repelling potential for the nodes in the region

The Challenges 1.Avoiding Collision between MAVs 2.Dispersing MAVs to search for contaminated areas 3.Bounding vehicle movement to a limited coverage volume (preventing MAVs from hitting buildings) –Based on the first three conditions each node calculates a repelling potential –This achieves uniform distribution in the coverage volume, in the absence of any toxic plumes 4.Encouraging some MAVs to cluster in the vicinity of toxic plumes –As the quality of data sensed increases, the repelling potential of the node is decreased, attracting other nodes to the area. 5.Maintaining network connectivity between the MAVs in plumes to the ground control centre –A weighted average of unit vectors pointing from BS to each MAV, is computed –Vectors are weighted based on the data quality of the nodes –The weighted average vector points in the direction of the plume from BS –MAVs closer to this vector decrease their repelling potential

Picture of MAV under development at University of Colorado

Results Only Simulation Results A 147 node flock is simulated, which form a ad hoc network, to cover a volume of 40 X 40 X 1(km) The communication range of nodes, assumed to be >5km (?)

Simulation of flock behavior for rules 1,2 and 3

MAV motions using information energy with data clustering effects

MAV motions using information energy with both data and communication clustering effects

References 1.Information Energy for Sensor-Reactive UAV Flock ControlInformation Energy for Sensor-Reactive UAV Flock Control

Comments and Questions