2. The University of Iowa. Copyright© 2005 A. Kruger 1 Introduction to Wireless Sensor Networks Wireless Terms, FAQ & Glossary 27 January 2005

3. The University of Iowa. Copyright© 2005 A. Kruger 2 Organizational Monday 4:30-5:20Room 4511 SC Thursday12:30-1:20Room 3220 SC Please note that the room numbers are different for Mondays and Thursdays. Monday5:20-6:20Room 1126 SC Thursday1:30-2:30Room 1126 SC OtherBy appointmentRoom 523C SHL Class Website www.engineering.uiowa.edu/~ece195/2005/ Class Time Office Hours

4. The University of Iowa. Copyright© 2005 A. Kruger 3 Organizational No Class on Monday January 31

5. The University of Iowa. Copyright© 2005 A. Kruger 4 Review Questions Name and explain the differences and similarities between the concept of a WSN and traditional telemetry Explain what the Argos system is Explain what the acronym SCADA stands for True or false – wireless fleet management is an example of WSNs Explain what the term “ISM” means

6. The University of Iowa. Copyright© 2005 A. Kruger 5 Wireless Terms –Decibel (dB). Ratio of two powers –dBm. The reference power is in mW –SNR. Signal-to-Noise Ratio. Power, expressed in dB –Attenuation. Power loss (dB) –CDMA. Code Division Multiple Access –Simplex communication. One direction at a time –Duplex communication. Transmit and receive simultaneously –FCC. Federal Communications Commission –Antenna gain. How much more power the antenna received compared to reference (half wave). Expressed in dB –MAC. Medium/Media Access Control

7. The University of Iowa. Copyright© 2005 A. Kruger 6 Wireless Terms –Circuit Switched. Dedicated (virtual) link between parties. Connection held even when no data transmitted. –Packet Data. Split information into packets and route independently through network. Use of spectrum only when data are transmitted. –Spread Spectrum. A wideband modulation which imparts noise-like characteristics to an RF signal. –Frequency-hopping and Direct Sequence Examples of Spread Spectrum –TDMA. Time-Division Multiple Access –FDMA. Frequency Division Multiplex Access

8. The University of Iowa. Copyright© 2005 A. Kruger 7 BER and Effective Channel Capacity Analog vs. Digital links BER – Bit Error Rate increases as SNR decreases –Error detection and correction mechanisms –Repeated transmission –Reduce channel capacity

9. The University of Iowa. Copyright© 2005 A. Kruger 8 Radio Propagation Mechanisms Free Space Reflection –Wave impinges on large (compared to wavelength) objects. Diffraction –Waves bends around obstacle (no LOS) Scattering –Objects much smaller that wavelength

10. The University of Iowa. Copyright© 2005 A. Kruger 9 Radio Propagation Simple (but useful) models exist for –Free Space –Common geometries (flat, curved earth, wall) Radio propagation in many real environments is complex –Multipath propagation –Shadowing –Attenuation Environment changes => fluctuations in received power

11. The University of Iowa. Copyright© 2005 A. Kruger 10 Radio Propagation Free space model Receiver Transmitter htht hrhr R P t, G t P r, G r

12. The University of Iowa. Copyright© 2005 A. Kruger 11 Radio Propagation Two-beam/ray ground reflection model, large R The “breakpoint” distance R at which the model changes from 1/ R 2 to 1/ R 4 is  4  h t h r / Receiver Transmitter htht hrhr Phase shift R P t, G t P r, G r

13. The University of Iowa. Copyright© 2005 A. Kruger 12 Fresnel Zone and LOS Consistent Units 60% rule-of-thumb Diffraction

14. The University of Iowa. Copyright© 2005 A. Kruger 13 Example A 1-km 2.4 GHz link has two antennas that are 2 m above the ground. Do we have LOS? 60% of this is 3.3 m, so we don’t have clearance. Answer is “NO”

15. The University of Iowa. Copyright© 2005 A. Kruger 14 Loss Models This graph does not reflect temporal changes Why need model? Hybrid models (physics and empirical)

16. The University of Iowa. Copyright© 2005 A. Kruger 15 Indoor Propagation Signal decays much faster Coverage contained by walls (waveguides) Very complicated dynamic (people move) attenuation and multipath Path Loss = Unit Loss + 10nlog(R) = kF+lW Unit Loss = power loss @ 1 m (say 30 dB) n = power delay index R k = # of floors, F = # of floors l = # of walls, W = loss per wall

17. The University of Iowa. Copyright© 2005 A. Kruger 16 Indoor Propagation BuildingFreq (MHz) n Sigma (dB) Retail Store9142.28.7 Grocery Store9141.85.2 Office15003.07.0 Textile Factory13002.03.0 Home9003.07.0 Path Loss = Unit Loss + 10nlog(R) = kF+lW

18. The University of Iowa. Copyright© 2005 A. Kruger 17 Received Signal Strength Indicator (RSSI) Measure of received signal strength of radio Indicator of link quality Radio can be interrogated for RSSI On-board Software use RSSI Typically a number 23, 19, etc. Consult manufacturer for mapping to power level dBm

19. The University of Iowa. Copyright© 2005 A. Kruger 18 RSSI OS determines RSSI is too small for reliable link

20. The University of Iowa. Copyright© 2005 A. Kruger 19 RSSI Radio with serial interface Controller +++ ATRS ATCN 40 Small!

21. The University of Iowa. Copyright© 2005 A. Kruger 20 No Class on Monday January 31

22. The University of Iowa. Copyright© 2005 A. Kruger 21 Introduction to Wireless Sensor Networks Energy Considerations in Wireless Sensor Networks 2 February 2005