Wireless Sensornetworks - IHP Microelectronics

Wireless Sensornetworks Concepts, Protocolls and Applications Chapter 1 Introduction, Applications and Challenges

Hon.-Prof. Dr. rer. nat. Peter Langendörfer leader of the research group of sensor nets telefon: 0335 5625 350 fax: 0335 5625 671

e-mail: langendoerfer [ at ] ihp-microelectronics.com web: www.tu-cottbus.de/systeme

general information • lecture dates – exercise each time after lecture (starts on demand)

• exam at the beginning of the vacations by exam or orally • certificate by proof of their participation in lecture (list of participants: at least 5 participated) • documents for lecture and exercise on chair website • for rescheduling information or other announcements will be publish on chair website and/or by email (please register in LEHVIS system) • www.tu-cottbus.de/systeme

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Literatur und Quellen • • • • • • •

Protocols and Architectures for Wireless Sensor Networks Prof. Holger Karl; Andreas Willig, Wiley, ISBN 0-470-09510-5 Distributed Sensor Networks S. Sitharama Iyengar and Richard. R. Brooks, Chapman & Hall/CRC, ISBN 1-58488-383-9 Wireless Sensor Networks, Architectures and Protocols Edgar H. Callaway, Jr, Auerbach Publications ISBN 0-8493-1823-8 Sensor Technology Handbook John S. Wilson, Newnes ISBN 0-7506-7729-5 Ad Hoc Wireless Networks Mohamed Ilyas, CRC Press, ISBN 0-8493-1332-5 Präsentationen aus dem WWRF Folien des Kollegen Karl aus Paderborn

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lecture overview

• • • • • • • • •

Introduction, Applications and Challenges Single Node Architectures Physical Layer MAC Protocols LLC Protocols Routing Protocols Network Architectures DSN Architectures Power Management

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infrastructure-based wireless networks •

Typical wireless network: Based on infrastructure – – – –

e.g., GSM, UMTS, … base stations connected to a wired backbone network mobile entities communicate wirelessly to these base stations traffic between different mobile entities is relayed by base stations and wired backbone – mobility is supported by switching from one base station to another – backbone infrastructure required for administrative tasks Gateways

Server

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IP backbone

Router Chapter 1 – Page 5

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infrastructure-based wireless networks (2)

• Which are the limits ? • What if … – … no infrastructure is available ? • e.g., in disaster areas

– … it is too expensive/inconvenient to set up ? • e.g., in remote, large construction sites

– … there is no time to set it up ? • e.g., in military operations

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possible applications for infrastructure-free networks • factory floor automation

• disaster recovery

• car-to-car communication

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• military networking: tanks, soldiers, … • finding out empty parking lots in a city, without asking a server • search-and-rescue in an avalanche • personal area networking (watch, glasses, PDA, medical appliance, …) winter term 2010 – Wireless Sensor Networks

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sensor equipment

tiny 1cm³ Particle includes sensors, battery, CPU, communication

source: www.teco.edu winter term 2010 – Wireless Sensor Networks

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sensor nodes

UC Berkeley: COTS Dust UC Berkeley: COTS Dust

UC Berkeley: Smart Dust

Rockwell: WINS UCLA: WINS

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JPL: Sensor Webs

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Sensor Node Antenna Processor

Radio Frontend

Sensor Interface

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Sensorknoten Antenne Processor

Radio Frontend

Sensor Internface

Power Mgmt.

Power Supply

Microcontroller

I/O

HardwareAccelerator

Memory

Baseband Base band

Analogue Frontend

Sensor Communication Interface

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IHP Sensor nodes Tandem Node Power Mgmt.

Power Supply

Microcontroller

Speicher Memory 250KB

Ein-/Ausgabe

Basisband Baseband

IPMS430

SPI

HardwareHW Acc Beschleuniger ECC, AES

Baseband

Analoges

868MHz Frontend

Sensor Kommunikationsschnittstelle On board comm.

FeuerWhere Node designed by IHP

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First Tandem node, security flavour for BSI

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sensors and local infrastructure • location aware mall – Metro FutureStore – location aware shopping system – finds location of products

• ubiquitous mall – mobile communication + sensors/RFID tags Sensor node • tiny 1cm³ • sensors, • battery, • CPU, • communication Source: www.teco.edu

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telecom and internet world

• most modern cell phones combine features of former PDAs plus: – internet access – NFC – payment functionality

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sensors and internet

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applications

• bird observation on Great Duck Island – interest: breeding behavior: usage of burrows, environment, breeding sites – nodes located in burrows and on surface – measurement: humidity, pressure, temperature, ambient light (every minute) – infrared sensors detect presence of birds – ad-hoc clusters with dedicated node for long-range communication

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applications (2)

• ZebraNet – interest: behavior of individual animals, interactions, human impact – hundreds of square kilometers, years of observation, every 3 minutes – animals carry nodes with GPS and sensors (now light, more coming) – data transferred whenever nodes come close together – mobile base station (car or plane) collects data from time to time

• related: cattle herding using “virtual fences” winter term 2010 – Wireless Sensor Networks

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applications (3)

• disaster relief operations – drop sensor nodes from an aircraft over a wildfire – each node measures temperature – derive a “temperature map”

• biodiversity mapping – use sensor nodes to observe wildlife

• intelligent buildings (or bridges) – reduce energy wastage by proper humidity, ventilation, air conditioning (HVAC) control – needs measurements about room occupancy, temperature, air flow, … winter term 2010 – Wireless Sensor Networks

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sensors and local infrastructure

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Tunnel Monitoring

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application (3)

• glacier monitoring – interest: monitor glacier dynamics to understand climate – nodes in drill holes measure pressure, temperature, tilt – base station on glacier uses differential GPS, transmits data via GSM – major problem: radio communication through ice and water

• ocean water monitoring – – – –

interest: global, long-term coverage of ocean and climate measure temperature, salinity, ocean profile continuously nodes cycle to 2000m depth every ten days data transmitted to satellite when on surface

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application (4)

• vital sign monitoring – Interest: monitor vital signs of patients in hospital using WSN – Better accuracy and patient comfort compared to conventional approaches – Components: patient identifier, medical sensors, display device, setup pen – Staff uses setup pen to set up associations between body area nodes

• parts assembly – Interest: assist assembly of do-it-yourself furniture – Parts and tools equipped with sensor nodes – Use force sensors (joints), gyroscope (screwdriver), accelerometer (hammer) – Ad-hoc network detects activities, feedback via LEDs in furniture parts winter term 2010 – Wireless Sensor Networks

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application (5)

• power monitoring – interest: save power in large office building – sensor node connected to each power outlet – transceiver nodes form multihop network to central unit, gateway to internet

• other applications – – – – – –

grape monitoring: conditions which influence plant growth cold chain management: monitor food temperature compliance avalanche rescue: assist rescue of avalanche victims military vehicle tracking: find and track e.g. tanks self-healing mine field: Intact mines hop into a breach sniper localization: locate snipers and bullet trajectories

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application scenarios

• facility management – intrusion detection into industrial sites – control of leakages in chemical plants, …

• machine surveillance and preventive maintenance – embed sensing/control functions into places no cable has gone before – e.g., tire pressure monitoring

• precision agriculture – bring out fertilizer/pesticides/irrigation only where needed

• medicine and health care – post-operative or intensive care winter term 2010 – Wireless Sensor Networks

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application scenarios (2)

• logistics – equip goods (parcels, containers) with a sensor node – track their whereabouts – total asset management – note: passive readout might suffice – compare RFIDs

• telematics – provide better traffic control by obtaining finer-grained information about traffic conditions – intelligent roadside – cars as the sensor nodes winter term 2010 – Wireless Sensor Networks

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Application Areas

Homeland Security

Industrial Automation

Telemedicine winter term 2010 – Wireless Sensor Networks

Context aware systems Chapter 1 – Page 26

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Geographical setting and system req. Demonstration side • 65 Ground water measurement points • 12,6km² area • 250m to 2000m distance • Rural/forest area • No power supply Requirements • Automatic measurement (min. once a day) • Radio transmission • Local buffering of measurement results • 10 year maintenance free operation • Temperature range -30°Cto +40°C • Protection against vandalism and animals winter term 2010 – Wireless Sensor Networks

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IQlevel System Centralised server • GPRS/GSM connection node • Local Internet-Server • Solar module Low Power Wireless Sensor Network • 868MHz Long Distance Radio • Ultra Low Power Micro controller • Low Duty Cycle Protocol • Crypto-based security • 10 years life time • Mesh-Network incl. adaptive routing Digital probe • Ultra Low Power Micro controller • Modular probe • Pressure-, ph-value-, sulphate- and elect. conductivity measurements • Buffering of measurement results winter term 2010 – Wireless Sensor Networks

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Protecting First Responders Vital parameters: • Body core temperature • Pulse • Blood oxygen saturation Environmental data: • Remaining air in the breathing apparatus • Temperature inside protective clothing • Temperature at surface of protective clothing • Environmental temperature appr. 2 m above the head of fire fighters • Relative humidity inside protective clothing • Relative humidity around the fire fighters • Explosive gas and/or explosive pyrolysis products winter term 2010 – Wireless Sensor Networks

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Data handling •

Buffering of all measurement data in the BAN

•

In network processing (local evaluation)

•

Timely transmission according a red-yellow-green model – Red: acute life threatening situation, immediate data transmission (continuously) – Yellow: situation might become life threatening in a short time scale, data transmission latest 10 sec. after measurement – Green: no threat at all, transmission of data every 60 seconds as self-test

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Harsh Environmental Conditions • • • • • • •

Temperature up to 1000°C Saturated steam atmosphere No sight due to smoke Extremely noisy Aggressive liquids and gas Ionizing radiation Blast e.g. after explosion

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Protecting Critical Infrastructure (Drinking Water Pipeline)

Flow rate, pressure, quantity…

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Measurement parameters Measurements are done every 30 seconds Location Waterworks Briesen

Distance to next substation ~1800 m

Briesen