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INTELLIGENT TRANSPORTATION SYSTEMS:. Real-Time Vehicle Performance Monitoring Using Wireless Networking. Will Jenkins, Ron Lewis, Georgios Lazarou Joseph Picone, Zach Rowland Human and Systems Engineering. Abstract. Cornerstone of next generation intelligent transportation systems (ITS):
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INTELLIGENT TRANSPORTATION SYSTEMS: Real-Time Vehicle Performance MonitoringUsing Wireless Networking Will Jenkins, Ron Lewis, Georgios Lazarou Joseph Picone, Zach Rowland Human and Systems Engineering
Abstract • Cornerstone of next generation intelligent transportation systems (ITS): • seamless integration of in-vehicle networking with existing wireless telephony infrastructure; • remote access to on-board diagnostics and performance data. Though many systems integrate position tracking and wireless networking to allow for remote position tracking, few systems provide the capability to monitor vehicle performance over the web. Our design is based on: • a popular new standard for wireless communications — GSM/GPRS; • an in-vehicle standard for diagnostic information, OBD-II, is used to gather performance data; • GPS technology to provide vehicle location; • Apache’s Tomcat extensions to provide Internet access via a vehicle tracking web site. The system is being used to track the campus bus system atMississippi State University in Starkville, Mississippi, U.S.A.
NETWORK • Intelligent Transportation Systems (ITS) • Relies heavily on vehicle communication systems including peer-to-peer and peer-to-base station communications • Incorporates seamless integration of in-vehicle networking with existing wireless telephony • Uses networks of collaborative vehicles to optimize traffic flow and provide dynamic routing capability (“intelligent network”)
System Overview Wireless Network Web / Database Server
Provides vehicle performance and position tracking system to users via the Internet • Extensible Vehicle Performance Monitoring System • Incorporates Global Positioning System (GPS) technology for vehicle location • Exploits capabilities of Global System for Mobile Communications (GSM) and General Packet Radio Service (GPRS) • Based on existing in-vehicle automotive standards (e.g., OBD-II, SAE J1850, and SAE J1979)
Global Positioning System (GPS): provides highly accurate position information anywhere in the world • Requires receiver capable of the civilian L1 frequency (1575.42 MHz) • Global Positioning System • 24 geostationary satellites orbiting at an elevation of 11,000 miles • Originally developed for military use only • Triangulates position to an accuracy within 15 meters using at least four satellites
Internet • Global System for Mobile Communication (GSM) is the fastest growing mobile communication standard GSM/GPRS Network • GSM/GPRS Wireless Network • Digitally encodes voice signals using the GSM 06.10 compressor models at 13kbps • Uses time division multiple access (TDMA) • General Packet Radio Service (GPRS) – data communication layer over a GSM wireless transmission link with a theoretical data transfer speed of 171.2 Kbps • Packet format allows for full compatibility with existing Internet services
Provides error codes • SAE J1962 connector provides access to the diagnostic network • In-Vehicle Networking (OBD-II) • Monitors most electrical systems
Garmin GPS 35-PC • Sony Ericsson GC-82 EDGE PC card • BR-3 OBD-II Interface • Generation 1: COTS Prototype • Operates on all OBD-II protocols specified in SAE J1850 • Laptop with two COM ports (RS232) and a 16-bit compatible PCMCIA port
Combines OBD-II data and GPS coordinates into a single data stream • Data Collection Software • OBD-II data is retrieved by continuously polling the system • OBD-II data is identified by generic parameter identifications or PIDs specified in SAE J1979 standard • Speed, Engine RPM, Calculated Throttle Position Sensor (TPS), Engine Load, Engine Coolant Temperature, and Air Intake Pressure
The BR-3 must be initialized. • Data Collection Software • The communication protocol is set based on vehicle protocol. • Specified PIDs are polled continuously • The GPS data is gathered simultaneously. • NMEA GPRMC sentence contains UTC data, longitude, and latitude. • The data is then sent to the server via GSM/GPRS. • The GPS signal is used as the trigger for data transmission.
Apache web server • Tomcat extensions • Five http servlets to maintain data flow from the vehicle to the database to the user interface. • Web and Database Server • Separate database for real-time and stored data are maintained
Displays tracking and performance information to the public via Internet • Map\EOP Interface • Shows vehicle location on a digital map • Route information is available • Engine operating parameters can be viewed in real-time on dashboard-like gauges
A PC104 embedded solution has been developed. • The shuttles operate on a SAE J1708 protocol (heavy-duty vehicle). • Generation 2: Campus Bus Network Pilot • Geographical Information System (GIS) providing faster map rendering based on GPS coordinates. • Deployment for campus shuttles scheduled for Spring 2005.
The final design incorporates a single board including chipsets for various wireless technologies and in-vehicle networking protocols. • A modular architecture supports a variety of sensors and high speed data communications • Summary and Future Work • Prototyped a real-time vehicle performance monitoring system which exploits existing wireless networking technology
References • L. Figueiredo, I. Jesus, J.A.T. Machado, J.R. Ferreira, J.L. Martins de Carvalho, Towards the Development of Intelligent Transportation Systems. IEEE Intelligent Transportation Systems Proceedings, Oakland, CA, 2001, 25-29. • Garmin. “What is GPS.” [online]. Available: http://www.garmin.com/aboutGPS/index.html • T. Yunck, G. Lindal, C. Liu, The role of GPS in precise Earth observation, Position Location and Navigation Symposium, Dec. 1988, 251-258 • GSMWorld. [online]. Available: http://www.gsmworld.com/technology/faq.shtml • J. Cai, D. Goodman, General Packet Radio in GSM, IEEE Communications Magazine, 35(10), 1997, pp 122-131. • S. Godavarty, S. Broyles and M. Parten, Interfacing to the On-board Diagnostic System, Proceedings Vehicular Technology Conference Vol. 4, pp. 2000-2004, 24-28 Sept. 2000. • SAE J 1850 May 2001, Class B Data Communication Network Interface, 2004 SAE Handbook, SAE International, 2004. • SAE J 1979 April 2002, E/E Diagnostic Test Modes Equivalent to ISO/DIS 15031: April 30, 2002, 2004 SAE Handbook, SAE International, 2004. • NMEA 0183 Standard for Interfacing Marine Electronic Devices, Version 2.0, National Marine Electronics Association, Mobile, AL, January 1992. • J. Brittain, I.F. Darwin, Tomcat: the definitive guide (O'Reilly, 2003). • K. English, L. Feaster, Community geography: GIS in action (ESRI Press, 2003). • MARIS. [online]. Available: http://www.maris.state.ms.us/index.html
In-Vehicle Networking (OBD-II) • The 1990 Clean Air Act and the Environmental Protection Agency established strict emission standards and inspection/maintenance (I/M) programs. • The Society for Automotive Engineers (SAE) produced a set of automotive standards and practices that regulated the development of diagnostic systems that would check for emission violations. • These standards were expanded to create the on-board diagnostic system – OBD-II • In 1996, the EPA adopted these standards and practices and mandated their installation in all light-duty vehicles.