`Volkswagen Group of America, Inc., Petitioner
`
`1
`
`
`
`. write to {BEE
`.anc. PO Box 1331.
`Cop_v1'igI1[
`if} 1998 by the
`
`FM:-oress Produciaorz By:
`
`ISOGEN International Corp.
`E750 N Academy Blvd. SUIIE 301
`_
`oforado Snnngs. CO 3091?
`?19 572-1706
`5gm!@_f-Sogencom
`
`Prmfed rn USA by:
`
`Lucent Technorcgies
`
`Customer Information Center
`2833 N. Frankhn Road
`lndlanapohs. IN 80917
`
`2
`
`
`
`17"‘ DASC
`
`Presentations
`
`Track F - Air Traffic Mgmt Systems
`Si-ssiiin Fl: Air Trai'fit' .\-‘Iaiiagenienl
`I-tin‘. G'eiie.i'-"it.-i-ii ATM
`yer-.i.'.eil 1-‘nth T'i'.'1i-.-:."ti..ii y Prei'li.:_rii_..-i
`ft.-i
`A:l\«'aiii7i_*<;
`iii Flii'_i_Ii'i D:-ST.-I Au.:ti_iii.~.iti='iii
`.-‘ii-itl T-'|.'1|‘i:1i_'_]t-_|11_r_*|'iI_
`g,ir.,—,i-._.-_.,-He
`
`CNS,IATM Aii'C.i'a1'1 t'jiistt;iii'ii.-tsititiii Trisl-<
`USAF l:-iiliauves for Cilolual Air “l'i'.-viii:
`
`{H-,_'iT pLJl1||\1.l'1t"l_']:i
`l'1Cl1‘-E!f_'}('_‘lT1Ei"l":l airirjl
`
`lilaii.-rifiaiti-ciii S:.~';eiy
`
`A Siimilifieiil At-)i'<iitautlc.al T~:—3let:-::uiiiii"ii1.Iilczatitxis Netwi_'ii'k {ATN} Avi-zniiitzs,
`Roiiler
`Avioiiics Arcliilectiire For Air Force l-1c-t;-ility Qt"-.ii'iriiai':r_1 Aircraft To l-leer.
`Ciisi’!-'itrii Aiicl GATM Re-i.]Li~:i'i:i1ieii:s
`A PSt?l:|[|[i Ramp [‘-1Fll1F-1L_It-_‘r' Wt:i:"i<statio.u roi tiie L_a['itj:-|'a[Qr'\.- [)L-.WgiL-H-_i.m-s_,.i
`Airline-ATC Colleilscwatiyc Arrival P'»cii'iiiiiir__; Tools
`
`"
`
`'. £\rit':ii"iriy WI-iri-'-\‘i
`'. T-'iil‘i
`I'—1=‘.De1if!-:
`'. Ai'l-.i"ilrl CIic.=c'i~.'i
`
`l..er.'a La Fr..:rr_ie
`
`. T. Sioni:ii'e
`
`. D[J|'1£l|Cl H.-T-lfillel
`
`‘. Siisazi DDi's"i<y
`
`. Deii.=s-F: R. Juries
`
`. Ricliarcl Huestzlieii
`
`v
`
`.A.-1t'hoi‘iy D. Aritlre Pl:.D.
`
`. Steve Koczo
`.Jaii1es Raiikiii
`
`'.
`
`\-'int'.ei‘.I Capezzttti‘;
`
`. Rick Ca ssell
`
`. Carl Evers
`
`1 Dan I-liccik
`
`. Steven Yourig
`
`. Wayrie H. Bryant
`
`Di‘
`. Michael Geyer
`Prof. Chin Lin
`
`M l‘
`
`. Juan Besada Portas
`
`Mr
`
`. Alex Smith
`
`Mr
`
`. Vern Edwards
`
`Ro
`
`bert Strain
`
`Session F2: Surface Movement 1: Display & Datalink
`Airport Surface l\‘lr.iyei'nent Te<:l'ii'ioiogies - Atlanta DE?|'1'IE')|'1SlTi"11|Ori Overview
`
`Descnption and Flight Test of a Roilotit and Tiiriiolf {ROTC} Head-Uii Display
`{HUD} Gu-.r_laiice System
`Fieltl EVallI'rl[IOl‘i Of T-NASA: Tax-.
`System
`Airport Surface Operations Data Link Comn-iziiiirzatioiis and DGPS
`Controller Pilot Data Link Statistics froiii NASAS 199? Ataanta Flight Test
`
`l"Javiga'lioi'i And Sittiatioii Awarei'ies~_;
`
`1 2
`
`Session F3: Surface Movement 2: Surveillance
`1
`Runway Incursion Rerluction Prograiri (RIRP‘_: Surveillance System - NASA .r'
`FAA Atlanta Deirionstratioii
`Development of Airport Stirface Surveillance Performance Reguire,riiei'its
`
`Analysis of ADS-B, ASDE—3 and Multilateration Surveillance Performance
`NASA Atlanta Denionstration
`
`6
`
`Application oi ADS-B for Airport Surface Surveillance
`Cornparisoii or" A-SMGCS Requirements with Observed Perforrnaiice of an
`Integrated Airport CNS System
`What's Next for LVLASO: Status of Plaiis for a Year 2L)[)L'l Flight Test and
`Deinonsti'atioi'i
`(Not Putilished}
`Session F4: Communication, Navigation, Surveillance
`Baiicroft's Algorithm for Solving Passive Multilateration Equations
`An Integral Flight Director and Surveillance System for Helicopters in
`Metropolitan Service
`Data Processing Methods For Aiitonomous On Board Surveillance And
`Collision Avoidance:
`
`Implementation of a Low—Cost SSRIADS-B Aircraft Receiver Decoder
`
`Loop Technology (LOT) as an Alternative Surface SUWEIIIBHCE System
`
`Broadcast Data Link Range Performance as a Function of Aircraft Size
`Experirnentai Results (Not Published)
`
`1 2 3 4 5 6
`
`Session F5: CNS/ATM Human Factors
`1
`How Data Link Communication Might Affect Controller Workload in a
`Terminal Option
`Slrnulation Study of Vocoder Communication In Air Traffic Control
`Survey of In—Flight Replariiiing Peiformed on the Flight Deck
`Introducing New Technology to the Air Traffic Controller: Implications for
`Skill Acquisition and Training
`Human Factors Issues in a Future Air Traffic |"|€lIT69el‘l1€Fl'(
`
`5Y5t€'l“
`
`Man—ln-The-Loop Part Of A Study Looking At A Free Flight Concept
`
`Dr
`
`.0. Veronika Prinzo PhD
`
`Dr
`Mr
`Mr
`
`. Earl S. Stein
`. James K. Kuchar
`. Alfred L. Smith Jr.
`
`Mr
`
`. Philip J. Smith
`Jacco l-loekstra
`
`3
`
`
`
`1r“oAsc
`
`Presentations
`
`Track G Aircraft S_ysten1S
`Session G1: II1Flighl Entertainment
`1
`Total liitegiated Managemem (TIM) ‘Not Published)
`va
`.
`r
`1:.
`ilability Reliability and Maintainabilitv PFBGICEION M095”
`Reality In Certification of IFE and TeleD|10ll9 E(il"D'“9”[
`A New Approach to para Communications Utilizing the North American
`‘]'erre5tr[a[ system (“Of PUb|I5hEd]
`Reapworid Implementations of Intra—Aircrai‘t infrared Data Comnmnicai.ion.s
`Networks
`
`In-Flight Entertainment — Gettlfig Fm“ W‘5h"5t To Ream’
`
`High Speed Networking of Multimedia Data for Passenger Entertaiiiment
`Published}
`PacI<et~oased Networks
`
`(Not
`
`Session G2: Aircraft 8: Satellite Avionics
`1
`Airoorne Reception of Data and Direct Broadcast TV using a Phased Array
`Antenna {Not Published)
`Guidance Characteristics of GNSS Landing Systems
`Managing Aircraft Ainiiortniness Through Information Technology [Not
`Published}
`Pro Line 21 Advanced Avionics System Architecture
`Techniques for Improved Reception of 1090 MHz ADS—B Signals.
`Enhanced Ground Proximity warning System {Not Published)
`Session G3: Commercial-Off—The-Shelf 8: Open Systems
`COTS Based Open Systems for Military Avionics
`
`1
`
`Session G4: Unma
`nned Airborne Vehicles
`Redundant Control 5
`ystems for UAV's
`(Not Published)
`2'9” Testing i>erseiis—B (Not Published}
`lght Testing a La
`t A
`.
`to soar) (Not puniiiignidlumnomom Unmanmd ’°“’C’aft (Or Global Hawk Begins
`Flight Tasting Darkstar (Not Published)
`
`'
`
`-'
`
`Jen’-vF'i R- wmsior.
`JrJlTl(—_’$ M_ Hansefi
`.
`. Ritcli L. Tripletl
`1. Niki? 0'Meara
`
`. Patrick Pmega
`
`Mr. Dcihalcl B. Lee
`Mr‘. Greg Henrikgon
`
`Mr. Stt3,\.-‘Gil W. Russ:-._ir[
`
`Mr. David C. Vacanti
`
`Di‘. Alex Stratton
`
`Ml‘. Williarn E. Larsen
`
`Mr. Timothy Rayl
`Mr. William Harman
`Mr. Barry C. Breen
`
`Mi’. John Paul
`
`Mr. David Sharp
`
`Mr. Sergio Navarro
`
`Dr. George Mitschaiig
`Mr. Hugh 5. Perry
`
`Brian Gratier
`
`Graham Gyattt
`
`Mr. Tom Clancy
`Robert Ettinger
`
`Mr. John Straub
`Willard J Harris
`Mr. Bill Harris
`
`Christopher Nagy‘
`
`Mr. Peter Lemme
`Mr. Richard H. Palm?
`Joe Cecchini
`
`Randy Black
`Dr. Daniel Nouoseller
`Mr. Dave Barnett
`
`4
`
`
`
` 1r"DAsc
`
`Presentations
`
`
`
`Track H - Spacecraft Systems (Continued)
`Session H2: Space Exploration
`Deep Space One lntegratioii arid Test Challenges: Getting to the Launch Pad Ms. Paula J. Pingree
`in the Faster, Better, Cheaper World
`The Mars Microprobe Mission Advanced Micro-Avionics for Exploration of the Mr Randel Blue
`Martiaii Surface (Not Published)
`From the Sun to Pluto
`
`Ms. Karla 3. Clark
`Mr. Robert L. Bunker
`
`Mr. Charles E. Bell
`
`1 2 3 4 5
`
`NASAIJPL Mars Surveyor Program: New Challenges in a New Era
`("Not Published)
`Iiiteiferorrieter Real Time Control for the Space Interferometry Mission
`(Not Published)
`Session H3: Microelectronics for Space
`Uitra Low Power Rad Hard 12 Bit A/D Converter for Space-Based E0 Sensors Sven Nvstrom
`
`1 2 3 4 5
`
`Integrating PWA Design and Analysis Using a Unix—Based Durability Toolset
`(Not Published}
`Amecom Direct Chip Attach Project
`
`Mr. Mostafa Rassaian
`
`Tracev Clay
`
`Digital Control of the MIDEX Spacecraft Power System (Not Published)
`Issues To Address in Use of Composite Materials for Electronic Packaging
`
`Ms. Karen Casteli
`Mr. Gaw Trembley
`
`Session H4: Space System Elements
`X2000: Avionics for A Multi—Mission Spacecraft
`
`
`
`
`
`O‘JU"I-l"-‘-DiJl\J—|
`
`Applications For A Spacecraft Avionics Functional Model
`A TaD|e—Driven Control Method To Meet Continuous, Near—Real-Time
`Observation Requirernents For The Solar x—Ray lmager
`The TRWIS III Hyperspectral Imager: Instrument Performance and Remote
`Sensing Applications
`Fault Protection Design of the Quil-cscat and Seawinds Instruments
`Development of a Low Cost Data Acquisition System for the Space Shuttle
`Solid Rocket Booster Program
`
`Mr. Savio Chau
`
`Mr. Joseph F. Smith
`Mr. Kevin Shawn Wallace
`
`Dr. Stephanie Sandor—Leahy
`
`Mr. Matthew 8. Bennett
`Mr. Kevin Crawford
`
`
`
`
`
`"*~JO')U"!-F3C.iJ|\1-F
`
`Track I — Automotive Systems
`Session 11: Ground Vehicle Electronics
`Mr. Gregory McHugI'i
`Software Process Improvement in an Automotive Eiectronics Organization
`Dr. Peter Hofrriarin
`Automotive System Design: Toclav and Tomorrow
`Specification and Testing of Automotive Powertrain Control System Software Mr. Steve ToeiJD9
`Using CACSD Tools
`Active Control of Vehicle Dynamics
`The Next Generation Automotive Electrical Power System Architecture:
`Issues and Challenges.
`Automotive 8i Aerospace Circuit Fault Analysis
`Requirements For A Real—Time Local Area Network Architecture In Land
`Combat Vehicles
`Session 12: Intelligent Transportation System (1)-
`Vehicle Electronics
`The Network Vehicle — A Glimpse into the Future of Mobile MuIti—Media
`
`W1 Mike F000?
`Dr. John P. Miller PE, PhD
`_
`Mr. Craig Siege‘
`Mr. Paul Richardson
`
`Huan—wun Yen
`
`A Demonstration Project for the ITS Data Bus Prototype
`Signal Processing and Waveform Generation in the Side Zone Automotive
`Radar
`Adapting Radar and Tracking Technology to an On-Board Automotive
`Collision Warning System
`Use of Map Data Information in an Ori—board Intersection Violation Detection Mr. John Pierowicz
`System
`SWIFT Project Results
`
`Mr. Philip Slllelt Ph-D.
`Mr. John C. Reed
`
`Dr. Edward Jocoy
`
`Mr‘ I-"”rV 56”"
`
`O')U‘|-F‘hDiJ|\}
`
`
`
`xiv
`
`5
`
`
`
`17"‘ DASC
`
`Presentations
`
`Track I - Automotive Systems (Continued)
`session I3: Intelligent Transportation System (2) -
`Info Management
`
`1
`2
`3
`
`4
`
`5
`
`5
`
`The In-vehicle Information System Developlfiem Center at ORNL. An ln-
`Vehicle Information System for ITS Information i'-laiiiaQl':‘m9l‘3
`Decision Making for Road Departure Warning Systems
`(NO! PLil,)li5-'.heij}
`Human Factors in Intel!
`igent Transportation Systems in the Vehicle
`Environment {Not Published)
`Reconfigurable Field Research Vehicle For Human Factors Experiments
`The Carnegie Mellon Trucksirn, The Advanc
`DI'i\.lEl’ Training Research Facility
`The Drowsev Driver R
`
`Mr. Piiilri.» Spelt Pii,o_
`
`Di‘
`
`. Tlioinns Piliim
`Mi". Gt?'lT(:' Farmer
`
`'t."ii'ayrir_'- Deverem.
`Hi‘. R.
`ed Human Factors Research and Mr. Rirhard Grace
`
`Session I4: Hybrid Vehicles
`Energy Power
`
`Mr‘. William MCIFCHJI1
`Ml". Henry Oman
`Mr. Henry Oman
`
`Mr. Tim Grewe
`Ilya KOfn1al’l(JVSk\.-'
`
`Mr. Jefl‘ Armfield
`Mr. Herman L. N. Wiegrnan
`
`.1855 M. Irwiri
`
`Mr. Brian Reynolds
`etrv Svsrem {RAFT} Mr. Sy Levine
`T_
`vionics Sygtem
`
`6
`
`
`
`F.
`
`System Design Track - Air Traffic Management Systems
`The ATM track is designed to cover recent developments in technologies
`and procedures for new air traffic managenieni systems as we move into the
`21st Century. The 5 sessions are designed to cover ATC provider plans for
`research. development. and the introduction of new tools and systems to
`improve aircraft safety and efficiency in the current ATC system and in it
`free flight environment.
`
`Track Chair: Alex Smith, Rannoch Corp
`
`Track F — Air Traffic Management Systems
`Session F1: Air Traffic Management
`Chairs: Steve Hill. Hanscomb AFB; Vu Duorig. Eurocontrol Experimental
`Center
`
`1
`
`Vertical Path Trajectory Prediction for Next Generation ATM
`Advances in Fiight Data Acquisition and Management Systems
`CNS/ATM Aircraft Customization Task {Not Published)
`
`. Anthony warren
`. Tom McDacle
`. Arnold Oldach
`
`USAF Initiatives for Global Air Traffic Management and Navigation Safety
`
`. Leo La Forge
`
`A Simplified Aeronautical Telecommunications Network (ATN) Avionics
`Router
`
`. T. Signore
`
`Avionics Architecture For Air Force Mobility Command Aircraft To Meet
`Cns,:’Atm And GATM Requirements
`A Pseudo Rarnp Manager workstation for the Laboratory Development of
`Airline—ATC Collaborative Arrival Planning Tools
`
`. Donald Happei
`
`. Susan Dorskv
`
`Session F2: Surface Movement 1: Display &
`Datalink
`
`Chair: Denise Jones. NASA Langley Research Center
`I
`Airport Surface Movement Technologies - Atlanta Demonstration Overview
`
`. Denise R. Jones
`
`. Richard Hueschen
`
`. Anthony D. Andre Ph.D.
`
`. Steve Koczo
`
`Description and Flight Test of a Rollout and Turnoff (ROTC) Head—Up Display
`(HUD) Guidance System
`Field Evaluation Of T-NASA: Taxi Navigation And Situation Awareness
`System
`Airport Surface Operations Data Link Communications and DGPS
`
`2 3 4
`
`5
`
`Controller-Pilot Data Link Statistics from NASA‘s 1997 Atlanta Flight Test
`
`. James Rankin
`
`Track F — Air Traffic Management Systems
`
`7
`
`
`
`Session F3: Surface Hovement 2: Surveillance
`-' ~_\ Rc:'-earth Center
`cu...-— S:.=m~;
`K.»-_<.
`'-
`
`
`
`._ _
`
`‘
`Z. q‘_'_
`
`1-. __
`
`_
`
`__
`
`_
`:'
`
`-
`
`P
`
`iv
`
`{""...l.-’_‘s
`
`-
`3
`
`.'
`
`Session F4: Communication, Navigation,
`
`. ~'
`
`; F"
`
`_ '
`
`—
`
`‘ 5- _ _=, 3 5.
`
`
`
`H
`_
`,.
`— ; ;-_,
`‘
`'
`T " ‘
`
`d
`
`“c'C_‘.C'."-ii?'_"_
`3?-3 ‘“-—.="=~"-
`I:r1I5cI' 4.-,
`
`1'-as-5-a-3*r:-.:.;r rr 2 _~-....:;._: 5._::_ ;_:5_5 _-__....=_;, R3;
`
`;_ ..g__ _ M
`
`8
`
`
`
` T
`
`THE NETWORK VEHICLE — A GLIMPSE INTO THE FUTURE or
`MOBILE MULTI-MEDIA
`
`R.
`
`t'.imil, R. Schttniur_'t'ici'. R. Roger, R_ 0,lm:\~_ H_ ym mm: M Lam.
`
`Dd.-’7}“ D€’=’€’f»‘
`
`f5lr:'r't.t'rJriir's .S'_'.‘.s'Iem.s‘. Krikrmm. frtdirtrtu
`
`R. Hecinrrrt
`
`IBM C(n‘p()!'{Hf(Jft. White Plains. Nev.‘ l’ork
`
`ABSTRACT
`
`the Delphi
`The Network Vehicle is
`the future
`Automotive Systems" vision for
`convergence of computers. the communications
`infrastructure. and the automobile.
`It features
`many advanced functions
`such as:
`satellite
`video.
`Internet
`access.
`virtual
`navigation,
`remote vehicle diagnostics and control. games.
`mobile office.
`automotive web
`site.
`and
`customized real-time stock quotes and sports
`scores.
`These features are enabled by an
`integrated planar antenna that
`is capable of
`multiple
`satellite
`reception.
`a client-server
`network
`architecture.
`and
`unique
`hurnan-
`vehicle-interfaces such as color reconfigurable
`head up and head down displays.
`steering
`wheel
`controls.
`voice
`recognition.
`text-to-
`speech. and large touch screen active matrix
`liquid crystal displays (LCD's']. The software
`applications
`are written
`in
`Java.
`using
`Application Programming Interfaces t'APl's) to
`reduce the complexity and cost of the source
`code.
`
`entertainment
`
`to millions of commuters who
`
`spend hours each day cruising the roads or
`stuck in traffic.
`It
`is designed to demonstrate
`what technoiogies and software can do for the
`vehicle of the future. The Network Vehicle,
`
`at
`its debut
`1. made
`pictured in Figure
`COMDEX ’9?' and has since been all over the
`world appearing in demos. conferences. and
`technology shows.
`including SAE Congress
`'98. and CeBit '98.
`
`
`
`INTRODUCTION
`
`a
`
`new
`Vehicle.
`Network
`The
`De1C0
`by
`initiative
`technology
`Delphi
`Electronics Systems and its partners (IBM.
`Neiscape
`Communications,
`and
`Still
`Microsystems)
`is
`aimed at offering more
`Productivity tools. convenience.
`safety. and
`03803-5086-3 .-’98J'$l0.00 ©1998 [EEE
`
`SYSTEM OVERVIEW
`The Network Vehicle is created by
`integrating existing hardware and software
`technologies
`including
`voice
`recognition,
`wireless communications. global positioning
`via
`satellite.
`head~up
`d1spla}’5«
`-la""“m
`technology. microprocessors. Web access. and
`121-!
`
`9
`
`
`
`
`
`
`
`-+::-
`
`r---.
`__e,_
`gm
`
`functionalit_v. gateways are used to translate the
`messages from one sub-network to anothgrm
`as to ensure harmonious operations,
`l
`n
`Iclu
`'— I
`l:~«_v:_
`.::..,!i..::1_I
`s::.
`.:::..!
`__,.H__r__.- ~~ — -
`Cf-IIIZHI-1
`C-lflu2EuI I:
`E
`l GI!-ivy
`l
`959“? I
`if‘ '
`
`'
`
`DIUII1
`
`WWW
`
`_'
`
`other
`lntcrnetfintranet
`features.
`The voice
`recognition technology allows drivers
`imd
`passengers to verbally request and listen to e-
`mail messages. locate a restaurant or hotel. ask
`for navigation help or
`for specific music or
`sports scores. and use voice-activated telephone
`services. all done safely without
`interfering
`with driving. Drivers can use a head-up displflbl
`projected through the windshield to navigate to
`their destination or check vehicle functions
`
`without taking their eyes off the road.
`
`terminals
`Passengers using individual
`next to their seats can do even more, including
`interacting with
`the
`Internet. watching
`television or playing games. Existing services
`such
`as
`theft
`deterrent
`technologies
`and
`emergency services could also be integrated.
`These "smart"
`features are enabled mainly
`because
`of
`the
`real-time
`data-streaming
`capabilities over a wireless network using Java-
`based technology. The Network Vehicle also
`has an integrated cellular phone, Netscape
`Communicator software for Web browsing and
`e-mail, a removable personal digital assistant
`{PDA') and docking station. There is also a
`vehicle web site that provides driver support for
`a wide array of customized capabilities such as
`enabling remote monitoring and control of
`vehicle systems in emergency situations.
`
`Outboard And Off-Board Communications
`Networks
`
`The key to the functions of the Network
`Vehicle is its ability to communicate efficiently
`both onboard and off-board of the vehicle.
`Figure
`2
`depicts
`the
`onboard
`network
`architecture of the vehicle.
`
`At the heart of the onboard system is a
`network computer that
`links up a number of
`sub-networks.
`including a Class II bus (for
`engine, head-up and head-down displays, door
`lock and door actuator, RFID, and cell phone.
`etc.), an Ethernet (for passenger computers and
`displays),
`and a mobile media
`link (for
`speakers
`and CD players}.
`Since
`the
`subnetworks all have different clock speed and
`
`
`E232
`-
`i
`.
`.
`. 1
`Network '- Canter
`
`
`
`
`ll d3=>3Dil'C!3>JD§lmau'|t!ts2:»L
`lmnlnttorvspuliug
`
`Figure 2. Onboard Network Architecture
`
`shown in
`The off-board network is
`Figure 3. The high bandwidth requirements for
`on-demand audio and video functions
`are
`fulfilled with DirecPC and DirecTV satellite
`broadcasts. A wireless modem provides the
`uplink out of the vehicle directly to lntemet
`service providers. The downlink retum path
`from the Internet to the Network Vehicle can
`come through either the satellite (400 kbps]. or
`through the wireless modem.
`The downlink
`satellite video and data signals are collected by
`the Network Vehicle's roof-mounted antenna
`and processed by their respective receivers.
`
`Figure 3. Off-Board Network Architecture
`Galnly-I.|'
`GE‘
`
`
`
`In order to take full advantages Bl ll"
`resources and services available to the Cll’l\’8i'5
`
`the vehicle must have robust
`and passengers.
`external communications paths.
`11
`i5 3_l-‘‘’
`vitally important that the vehicle configuration
`includes a firewall to ensure the integrlll’ “me
`
`0-7803-5086-3 ;’982'$l 0.00 ©1998 IEEE
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`vehicle operation. This means that regardless
`GI-what happens to the multimedia applications
`that are running in the vehicle. the powertrain
`system control,
`the chassis control. brakes,
`airbags.
`and other critical
`functions must
`maintain
`their
`integrity.
`In
`the Network
`Vehicle. this isolation is implemented through
`multiple gateways as shown in Figure 2.
`
`KEY TECHNOLOGIES AND SYSTEM
`COMPONENTS
`
`system
`and
`technologies
`key
`The
`components behind the Network Vehicle are
`advanced speech recognition software. mobile
`media link (high-speed fiber optic data bus),
`reconfigurable
`head-up
`display,
`high-
`bandwidth communications that connect
`the
`vehicle with the outside world. and a suite of
`automotive computer software. These elements
`aredescribed below.
`
`Speech Recognition and Text-to-Speech
`System
`
`IBM has modified its advanced speech
`
`system.
`text-to—speech
`and
`recognition
`Viavoicem. for the automotive environment.
`Vial/oice allows the driver to access virtually
`all
`the
`vehicle's
`features
`through
`voice
`commands and enables the vehicle to talk back
`using synthesized speech.
`For example,
`the
`driver can: execute vehicle system commands
`such as lock doors, play CD, and change radio
`station.
`request
`travel directions and traffic
`updates from the Web or other sources, check
`e-mail and voicemail. request news, sports, and
`stock information.
`The speech recognition
`system can understand most drivers instantly,
`with no system training required, and it has
`been tuned to offer optimal performance even
`in a potentially noisy vehicle environment.
`
`Driver and Center Console Displays
`The Network Vehicle is equipped with
`three displays for the driver:
`the head-down
`
`the head~up display (HUD),
`display (HDD).
`and the center console display.
`
`standard
`Th‘? HDD System displays
`graphics for an instrument panel: road speed.
`engine speed. engine status. door lockfajar, and
`fuel level.
`It also displays the functions for the
`steering wheel buttons since these functions
`vary with the entertainment mode that
`is
`selected. The HUD projects a virtual
`image
`through the windshield that gives infonnation
`to drivers without requiring them to take their
`eyes off the road.
`It displays road speed.
`engine
`status, waiting
`indication.
`navigation information, microphone onfoff. and
`a text message area for giving feedback to the
`driver.
`
`The center console's touch-screen LCD
`
`serves as a user interface for controlling nearly
`all of
`the Network Vehicle's multimedia
`
`(office, navigation, entertainment,
`functions.
`and information). When in entertainment
`mode, the display is configured as a radio- or
`CD-style faceplate whose buttons and controls
`are activated by touch (see Figure 4).
`It
`is
`reconfigured to display e-rnail, navigation
`maps, Web browser. cellular phone faceplate
`(shown in Figure 5),
`and more.
`Voice-
`activated commands can be used with all of the
`center console functions and, in some cases, is
`
`
`
`text-to-speech
`combined with
`minimize driver distraction.
`
`input
`
`to
`
`Figure 4. Audio on Demand Faceplate
`
`0-7803-5086-3 !'98t'$10.00 ©1998 IEEE
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`[cnnmnl
`a one—dirncnsiona]
`"extrusion" of
`cross—scction) geometry. This has the effector
`replacing a conventional "N_rN:N3" elemcm
`structure {of discrete radiators. couplers, em,
`with
`a
`less
`complex
`“n1onolithic"
`am...
`comprised of "N" integrated ctiuplerfradjam}
`features. The simple “tee“ cross-section Dflhf
`integrated CTS
`couplerlradiator
`form an
`inherently
`low—"Q"
`(non-resonant)
`clemcm
`which
`exhibits
`significant
`advantages
`[3,
`compared to slot or patch radiators} in terms oi
`wide—-angle
`scanning capability.
`polarization
`purity.
`bandwidth.
`and
`dlmcngjgna]
`insensitivity.
`
`...'_z'J.4
`
`Figure 5. Cellular Phone Faceplate Display
`
`Passenger Displays
`The Network Vehicle has color LCD
`
`touch panels for the back-seat and front-seat
`passengers. As with the center console display.
`the passenger displays serve. as user interfaces
`for controlling nearly all of the functions on the
`Network Vehicle. Unlike the center console
`display. however.
`the passenger displays can
`show video from DirecTV or DVD players, and
`they allow touch-screen access to all functions.
`
`Planar Satellite Antenna
`
`The antenna technology used in the
`Network Vehicle is the Continuous Transverse
`Stub {CTS) array.
`It
`is chosen because of its
`simplicity. planar construction. and potential
`for being an inexpensive product.
`Figure 6
`shows the cross sectional view of a typical CTS
`antenna.
`realized
`as
`an
`array of broad
`continuous transverse radiating stubs, finite in
`height, extending from the upper conductive
`plate of an open parallel-plate transmission-line
`structure.
`
`the induced
`As a receiving antenna.
`longitudinal current components in the parallel
`plate structure are interrupted by the transverse—
`oriented stubs and excite propagating waves in
`the
`parallel-plate
`structure.
`This
`simple
`architecture
`allows
`for
`a
`complex
`two-
`dimensional planar array to be realized as an
`0-7803-5086-3 .f98:’$l0.00 @1998 {FEB
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`Propagating -I
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`Piane-Wave
`
`Parallel-Plate Region
`
`Figure 6. (ITS Antenna Cross Section
`
`Customer /tppiicatiori Web Site
`
`the
`passengers of
`and
`The. driver
`Network Vehicle can take advantage of Internet
`services provided by automotive—oriented [SP5
`[Internet Service Providers}.
`The customer
`service site developed for the Network Vehicle
`showcases the types of features that could be
`offered when intelligent vehicle systems are
`connected to the Internet.
`
`Because the Network Vehicle's systcmfi
`are accessible via its command and control
`
`application. which also has secure access to the
`Internet. many
`scenarios
`are
`possible.
`Functions like parking lights and door loclcson
`the Network Vehicle
`can
`be
`controlled
`remotely. providing safety and convenience.
`An example of such a web page is shown lfi
`Figure 7.
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`Figure 7. Monitor and Control of Vehicle
`Status via Internet
`
`Under voice control of the driver,
`
`the
`
`Network Vehicle can upload vehicle status
`according to a profile set up in advance. An
`application monitors the diagnostic information
`iwailable
`from components
`in
`the
`engine
`compartment. Should the diagnostics indicate
`that the latest reading from engine sensors falls
`outside a normal
`range,
`the application can
`notify the customer service Web site, where the
`severity of
`the reading can be determined.
`According to this determination, the control on
`the Network Vehicle could be used by the
`service representative to alert
`the driver;
`the
`alert could be done using text-to-speech and
`head-up display,
`and then features of
`the
`application, e—mail, and office could be used to
`arrange
`a
`service
`appointment. Figure
`8
`illustrates
`the
`sensor data that
`are being
`
`monitored through the vehicle web site.
`
`'ill'Hir_|,[
`
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`lLiu.i.f,_{x.-'2» aitil .-.l=iil.i:9l.=im
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`Flgllre 8. Remote Monitoring of Vehicle
`Gauges via a Web Site
`
`take
`demonstrated
`features
`Other
`"dV3“l3t‘%€ Of Internet service providers‘ ability
`locommunicate with the Network Vehicle.
`T”P_ Plans created by vehicle owners or
`Concierge services can be stored at the Internet
`“e“f“_~'e ‘ Provider.
`By
`accessing
`global
`positioning satellite {GPS} data directly from
`the ‘vehicle.
`the driver and passengers can
`obtain maps. route guidance. fuel. lodging, and
`restaurant information while traveling. Owners
`of the Networlt Vehicle can also use their Web
`
`including
`profile.
`a
`up
`set
`to
`browser
`like radio stations. personalized
`preferences
`audio content. service records. and emergency
`service numbers.
`
`Personal Digilal Assistant Dockirtg
`
`the Network
`role of
`An important
`Vehicle is providing office functions to mobile
`users. using the same data the users have in
`their 0lT1C6 desktop computers. This function
`is
`mainly
`provided
`through
`vehicle
`applications,
`Internet
`connectivity.
`and
`advanced, voice—based user interfaces.
`It
`is
`
`important for the Network Vehicle to access
`and synchronize personal and business data
`with PDAs, which is becoming increasingly
`important in our mobile, connected world.
`
`A slot built into the center console of
`the Network Vehicle
`accepts
`the
`IBM
`WorltPad“" and uses the Network Vehicle's
`computer to add speech recognition and text-to-
`speech functions. This enables the driver to
`listen to schedules and to update files and other
`office data stored in the Worl<Pad.
`So the
`driver could,
`for example,
`issue
`a voice
`command to read calendar entries from the
`Worl<Pad or dictate a to-do list while driving.
`As PDA and smart card technology advances,
`the Network Vehicle's PDA integration could
`support
`the use of PDA-type devices for the
`secure
`transport
`and
`access of personal.
`financial, and business information as people
`move
`from one network access point
`to
`another.
`
`0-7803-5086-3 !98f$10.00 ©1998 IEEE
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`rlrrtorrrotive Computer Soflwflff
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`Virtual machine-based. ob,l‘»‘Cl'0"l‘~'m‘3'*l
`technologies were
`applied to the Nctvt-'0!'i~'
`Vehicle's development because they SU]TtPUTl
`the special requirements posed by the Vcllli-‘lC‘v
`Smalltalk.
`a well
`proven
`object-oriented
`environment and the latest Ja\-'tt"'“ technologies
`were chosen to develop the Network VehiL‘lC'5
`software.
`
`A command and control application.
`written in Smalltalk and running on
`the
`vehicle's main processor. monitors
`vehicle
`status. controls devices such as cell phone and
`microphone. supplies driver
`information via
`he-ad—up
`displa_y_
`manages
`off-vehicle
`information
`flow.
`and
`controls
`vehicle
`
`software. such as the voice recognition and
`various convenience passenger applications.
`This application coordinates with the voice
`recognition. the head-up display. and the touch
`screen to provide feedback and control of the
`various systems. helping to keep the driver's
`eyes on the road. For driver convenience and
`safety.
`this application also interfaces via the
`Internet
`to a customer service provider, who
`can remotely monitor the vehicle status. unlock
`doors. turn on exterior lighting. etc.
`
`Graphical user interfaces for Network
`Vehicle's center console and passenger displays
`are developed with Java to provide access to
`various in-vehicle and off—vehicle applications,
`such as navigation, audiolvideo entertainment,
`and office. An Internet server application was
`developed with VisualAge® for Java to provide
`communication
`between
`Internet-based
`customer applications and the vehicle systems.
`These applications support a message-based
`protocol communicating through the Internet to
`the
`in-vehicle
`command
`and
`control
`application, which in turn interfaces to the
`vehicle
`systems
`and
`the
`user
`interface
`application.
`Java applets were also developed
`for
`the customer
`site in order
`to provide
`animated vehicle status and control graphics.
`
`Media BI.-'3‘ and Jn- l/'e}u'cJe Electrorrics
`The Network Vehicle
`cnnluim
`ii
`number of audio and video components that am
`coniigured and controlled via a high-spam
`tlt)(} Mhps) digital
`l"ihcr~optic mobile ntcdla
`link (MML). Audio and video devices like CD
`players can send their output sigttals via the
`multiplexed.
`lihcr—optic bus
`to drive om
`L.pmponents like amplifiers and displays.
`_,-,1
`control signal
`is also carried on the MML l'l|.J§
`to configure and control the devices - C0l'll_lgu[e
`the components.
`switch signals.
`and adjw
`variables such as volume.
`fade, and balance.
`The MML gives the application full use ofthg
`vehicle's multimedia
`systems
`to
`develop
`functions and user interfaces tailored to drive;
`and passenger use.
`
`Combining a command and control
`application with the MML in the Network
`Vehicle made possible features such as context-
`sensitive volume reduction during the use oi
`the phone and the text-to-speech feature.
`ll
`also allows "faceplatc—style" user interface to
`integrate Internet radio with the sound system.
`and common and consistent user interfaces to
`define, review. and play the audio and video
`content preferred by the driver and passengers.
`The vehicle also features a satellite receiver
`
`system. which provides DirecTV and DirecPC
`access. DirecPC offers high—speed (440 kbps':
`Internet data access while DirecTV offers over
`US
`channels
`of
`digital
`entertainment
`programming.
`
`FEATURES AND FUNCTIONS OF THE
`NETWORK VEHICLE
`
`The main features of
`
`the Netwflrli
`
`Vehicle are manifested in the following lhft’-5
`areas: (1) Driving Aids. {2} Business Toolszttltl
`(3) News and Entertainment.
`The Network
`Vehicle is designed such that. through softwttrf
`upgrades the customer can be provided will?
`new features and functions as they becomf
`available.
`
`..'..3..
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`0-7803-5086-3 !'98I'$l0.0f} ©1998 IEEE.
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`D,-fpmg Aids - Get Where You '11: Going
`Eflicientfy
`The Network Vchiclc can access a simulated
`imggrated global positioning system and hence
`flat-anced navigation capabilities via Internet,
`Therefore.
`it
`literally knows where it
`is and
`where it's going.
`It can display the appropriate
`maps or simply provide route (.lll”CCIlt‘.tns on the
`head-up display.
`command console or
`as
`spoken instructions. Drivers could control the
`navigation
`system using
`commands
`like
`"destination" to select
`a new destination or
`"route
`guidance"
`to
`get
`turn-by-turn
`instructions. An example of such a display is
`shown in Figure 9.
`
`
`
`Figure 9. Example of a Navigation Function
`Display
`
`The ability to monitor key vehicle systems
`means that the Network Vehicle can detect and
`avoid problems before they happen.
`If key
`vehicle
`systems
`show signs of
`failino.
`a
`warning light appears on the head-up display.
`Or the vehicle tells the driver what the problem
`is.
`In the future. a technician or a vehicle
`manufacturer could take a look under the hood
`remotely to identify and diagnose problems,
`determine whether you can keep driving. or
`recommend obtaining service.
`
`the Network
`left
`you
`think
`If you
`Vehicle-‘s doors unlocked or the lights on, just
`Visit the vehicle web site from your home or
`Office computer to check, then fix the problem
`
`0-T803-S086-3 .4'98f$l0.0O ©1998 IEEE
`
`are
`
`just
`
`trol
`
`ttrlt
`~ st-
`
`of
`
`It
`In
`
`to
`.
`to
`
`\’El'
`
`PC
`
`ps I
`
`nt
`
`rlt
`
`ad
`
`1'}:
`
`Tcmfllely.
`
`The Network Vehicle's
`
`future
`
`remote control capabilities not only could allow
`youto actually start the vehicle in the parking
`lot irom the office. but also to set the heater or
`air conditioner from your office computer. so
`tha