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Installation and Evaluation of RFID Readers on Moving Vehicles. VANET 2009 Eun Kyu Lee, Young Min Yoo, Chan Gook Park, Minsoo Kim, and Mario Gerla. Agenda. RFID applications RFID-enabled vehicular applications RFID system RFID read performance Installation of RFID system on vehicle
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Installation and Evaluation of RFID Readers on Moving Vehicles VANET 2009 Eun Kyu Lee, Young Min Yoo, Chan Gook Park, Minsoo Kim, and Mario Gerla
Agenda • RFID applications • RFID-enabled vehicular applications • RFID system • RFID read performance • Installation of RFID system on vehicle • Road test • Conclusion
RFID Applications Supply Chain & Warehouse ePassport www.infoworld.com
Human implant RFID Applications www.wikipedia.org Automatic toll collection www.ezpass.com Smart payment www.ti.com
2. Radio Frequency Identification (RFID) • RFID system review • RFID communication
Radio Frequency Identification (RFID) • What is RFID? • Identify physical objects • through a radio interface • Identification? • Assign ID to each object • Bar code, license plate, student ID • How does RFID work? • RFID tag + RFID reader + antenna • Backscattering coupling (UHF) Antenna Chip 02.3DFEX4.78AF51 EasyToll card #816
Radio Frequency Identification (RFID) • Tag type • Radio frequency range www.hitachi.com & www.vicariousconversations.com
RFID Communication • Framed slotted Aloha (FSA) A response from one RFID tag Slot .. .. . CW Query Cycle Power down CW Query Cycle Power down .. .. ..
3. RFID in Vehicular Applications • RFID-enabled Vehicular Applications • On-board RFID reader system
RFID-enabled Vehicular Applications • Methodology of data producer/consumer • RFID tag • Stores data in memory, which is provided to RFID readers • A data producer • RFID reader • Obtains RFID data from tags and utilizes it for further programs • A data consumer Each vehicle is a data producer !!
RFID-enabled Vehicular Applications cs.rutgers.edu • Tag on vehicle (data producer) • Readers are on the roadside • Automatic toll collection • Intelligent traffic signal system • Electronic license plate • Priority lane management • Lane reservation and enforcement Reservation/ Enforcement System www.ti.com Enforce Enforce Reserve Reserve RFID Reader/ Camera Low-Priority Lanes Lane Entrance Assistance System High-Priority Lane
RFID-enabled Vehicular Applications • Reader on vehicle (data consumer) • Tags on the roadside units (road surface, sign post, direction sign) • RFID positioning and Road beacon system (RBS) • Lane-level GPS (Donath’06) • RFID tags along each lane contains useful data (e.g., position) • Intersection collision avoidance, • Enhancement of driver’s situation awareness, • Lane by lane incident management RFID reader RFID tag
RFID-enabled Vehicular Applications • Tag/reader on vehicle (data prosumer) • Intelligent priority lane management • Peer localization RFID tag RFID reader
On-board RFID Reader System • Challenges • High vehicle speed • Faster than 100Km/h on a freeway • Short communication distance • Much less chance of RFID communication • Random mobility of reader • Reader position affects performance significantly than tag placement • Random fading effects 0.3m RFID tag 3m~4m RFID reader
On-board RFID Reader System • Motivation • Initial deployment of RFID reader/tag is important for better performance • Necessary to measure performance in a real test road • In this work, we • Install RFID reader on a vehicle and tags on a road surface • Evaluate RFID read performance in a laboratory environment • Propose antenna diversity and tag multiplicity for improvement • Conduct a road test to study feasibility of the system
4. Understand RFID Read Rate • Specification of the RFID system • RFID performance • RFID read area • Read latency • RFID read rate
RFID Performance • RFID read area • Size and moving speed Moving speed of RFID area RFID read area For instance, if h=37.5cm and θ=45°, then X1=58.58cm and X2=185.63cm Measured X2≒100cm (1m) RFID communication should occur in 1m read area within 36m
RFID Performance • Read latency • Time period when one RFID communication occurs • Measured 38.39ms on average • Mostly due to the maximum pause time of the tag: 62.5ms • However, • RFID read area moves at 36ms > 38.39ms • Even 60ms at 60km/h < 62.5ms • RFID read rate High possibility of RFID communication failure <- 36ms 38.39ms # of tags successfully read = ----------------------- total # of tags deployed
Laboratory Experiment • Experiment setup • RFID reader antenna • Height • Pitch angle • Antenna diversity • RFID tag • Yaw angle • Pitch angle • Tag multiplicity • Result
Laboratory Experiment • Target performance • 0.5m of read area and 18m of read latency • Height of RFID reader antenna h=30cm • Similar performance in h=20~40cm • Height of the test vehicle is 30cm • Installation • RFID reader antenna & RFID tag 18ms of read latency RFID reader antenna RFID tag 30°of tag yaw angle and 30°of antenna pitch angle 0.5m
RFID Reader Antenna • Pitch angle • Varying pitch angle of the antennas • Measure the read area given 18ms of read latency • 30° of pitch angle RFID tags are attached on the floor with 0°
RFID Reader Antenna RFID Tag 80 cm 78 cm • Antenna diversity • Install one and dual antenna(s) • Measure the read area given 18ms of read latency 43 cm 65 cm RFID Reader Antenna RFID Reader Antenna 2 RFID Reader Antenna 1 1.5m 3m 1 Antenna 2m 0.86m 2 Antennas 1.3m RFID Tag
RFID Tag • Yaw angle and pitch angle • Measure the read latency given 0.5m of the read area • Both are set 0° 30° of reader antenna
RFID Tag • Tag multiplicity • To mitigate effect of the random pause time • Measure the read latency given 0.5m of the read area • Cluster model 3 having 3 or 4 member tags Cluster 2 Cluster 4 Cluster 3 Cluster 1
Results • RFID communication successfully occurs within 0.8m of RFID read area and 18ms of read latency • Antenna diversity and tag multiplicity • Showed improved performance • Estimation of the maximum vehicle speed • At which RFID communication can occur • 161.7km/h • Equivalent to previous researches
Road Test • Test road configuration • Effect of antenna diversity • Effect of tag multiplicity
Server Test Road RFID Reader RFID Tag RFID Reader Antenna Test scenarios with variables Deployment parameters
Road Test • Effect of antenna diversity • Proof of concept in terms of width • Reduced length does not affect performance much Average duplication read 1 Antenna 1.5m 3m 2m 0.86m Average read rate 1.3m RFID Tag 2 Antennas
1 Tag, 2m Interval (Test 2) 1 Tag, 2m Interval (Test 2) Road Test 3 Tags, 2m Interval (Test 3) 3 Tags, 2m Interval (Test 3) 4 Tags, 2m Interval (Test 4) 4 Tags, 2m Interval (Test 4) 3 Tags, 5m Interval (Test 5) 3 Tags, 5m Interval (Test 5) 4 Tags, 5m Interval (Test 6) 4 Tags, 5m Interval (Test 6) 100 30 Average Duplication Read [number] • Effect of tag multiplicity • Tag cluster outperforms single tag (Test 2, 3, and 4) • Tag interval influences performance (Test 3 and 5) • In particular, at high speed • Duplication read dramatically decreases at high speed 90 25 80 70 20 60 50 15 40 10 30 Vehicle Speed [km/h] Average duplication read 20 5 10 0 0 10 20 30 40 50 60 70 80 90 100 10 20 30 40 50 60 70 80 90 100 Average Read Rate [%] Vehicle Speed [km/h] Average read rate
Conclusion • Summary • RFID-enabled vehicular applications • On-board RFID reader system • Experiment • In a laboratory • RFID reader antenna and RFID tag • On a test road • Contribution • A different approach to RFID-enabled vehicular system • Address antenna diversity and tag multiplicity • The newest topics for performance improvement • Experiment data from a real test bed
Thank you VANET 2009