throbber
VWGoA - Ex. 1004
`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
`
`I2]-2
`
`10
`
`
`
`10
`
`

`
`*
`
`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
`e-mail
`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
`
`I21-3
`
`
`
`11
`
`

`
`
`
`IIflQ‘$0.1'!
`
`XI-I 1|!)
`
`I|Ifi...\
`
`[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
`
`I
`
`.
`
`l
`
`Radiatingftioupiing Stub
`
`[coupimfl E_F§eM
`
`_
`
`s.\.§T.§is
`
`_’
`
`Propagating -I
`
`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.
`
`121-4
`
`s
`
`12
`
`12
`
`

`
`'"—.r.....;"
`
`' *
`
`2
`
`
`
`
`
`"V'-?~'-'.'-"-4’i’_-',’-1'*'\"7.r.-.9/"
`
`
`
`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_|,[
`
`
`,,_,,,§
`__
`lLiu.i.f,_{x.-'2» aitil .-.l=iil.i:9l.=im
`?HA'tl:L
`
`
`
`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
`
`I21-5
`
`13
`
`.In‘.
`
`.
`
`13
`
`

`
`
`
`
`
`rlrrtorrrotive Computer Soflwflff
`
`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..
`
`0-7803-5086-3 !'98I'$l0.0f} ©1998 IEEE.
`
`121-6
`
`14
`
`
`
`14
`
`

`
`
`
`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

This document is available on Docket Alarm but you must sign up to view it.


Or .

Accessing this document will incur an additional charge of $.

After purchase, you can access this document again without charge.

Accept $ Charge
throbber

Still Working On It

This document is taking longer than usual to download. This can happen if we need to contact the court directly to obtain the document and their servers are running slowly.

Give it another minute or two to complete, and then try the refresh button.

throbber

A few More Minutes ... Still Working

It can take up to 5 minutes for us to download a document if the court servers are running slowly.

Thank you for your continued patience.

This document could not be displayed.

We could not find this document within its docket. Please go back to the docket page and check the link. If that does not work, go back to the docket and refresh it to pull the newest information.

Your account does not support viewing this document.

You need a Paid Account to view this document. Click here to change your account type.

Your account does not support viewing this document.

Set your membership status to view this document.

With a Docket Alarm membership, you'll get a whole lot more, including:

  • Up-to-date information for this case.
  • Email alerts whenever there is an update.
  • Full text search for other cases.
  • Get email alerts whenever a new case matches your search.

Become a Member

One Moment Please

The filing “” is large (MB) and is being downloaded.

Please refresh this page in a few minutes to see if the filing has been downloaded. The filing will also be emailed to you when the download completes.

Your document is on its way!

If you do not receive the document in five minutes, contact support at support@docketalarm.com.

Sealed Document

We are unable to display this document, it may be under a court ordered seal.

If you have proper credentials to access the file, you may proceed directly to the court's system using your government issued username and password.


Access Government Site

We are redirecting you
to a mobile optimized page.





Document Unreadable or Corrupt

Refresh this Document
Go to the Docket

We are unable to display this document.

Refresh this Document
Go to the Docket