AUTONOMOUS VEHICLE SYSTEMS AND A CONNECTED FUTURE IoT Summit RWW 2018 SERGIO PACHECO SYSTEMS AND APPLICATIONS INFOTAINMENT AND DRIVER ASSISTANCE PUBLIC USE
LEVELS OF AUTONOMATION IN CARS Level 0-2 Human driver performs part of the dynamic driving task Level 3-5 Automated driving system performs the entire dynamic driving task HUMAN DRIVER MONITORS DRIVING ENVIRONMENT AUTOMATED DRIVING SYSTEM MONITORS DRIVING ENVIRONMENT 0 1 2 3 4 5 No Automation Driver Assistance Partial Automation Conditional Automation High Automation Full Automation SAE standard J3016 PUBLIC USE 2 2
MEGATRENDS IN THE AUTOMOTIVE ARENA Seamlessly Connected Mobility Experience ADAS Towards Self-Driving Energy Efficiency One hour per day in the vehicle Enjoying Life 1.3M global road fatalities every year Saving Lives US mandates 163 grams / mile and 54.5 MPG by 2025 Reducing CO 2 PUBLIC USE 3
REDUCING ROAD FATALITIES 5 US Fatality Rate per 100-Million Vehicle Miles Traveled Safety crucial for self-driving car Safety, quality & reliability at the heart of automotive engineering Trusted technology and functional safety track-record essential 0 1971 1981 1991 2001 2011 2015 2021E Safety system adoption accelerated by mandates & NCAP ratings ADAS needed to reverse recent increase in fatality rate (texting) Reactive (Airbag) Predictive (ADAS) Active (Anti-Lock Braking & Stability) Preventive (Tire Pressure Monitoring System) Self Driving Car PUBLIC USE 4 4
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DRONE APPLICATIONS PUBLIC USE 6
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Market Drivers: NCAP and Automation Towards a 360 view by Sensor Fusion NCAP Roadmap NCAP L1: Partial Assistance L2: Partial Automation ACC LCA AEB Junction Assist Emergency Steer Assist 2010 2016 2018 2020 >2025 Parking (Autonomous parallel parking) Co-operative cruise control Platooning Smart Navigation (Vehicle deciding on routes) Traffic Jam Assist (Semi Autonomous steering) Automated vehicle (taking complete control of navigation, transmission, steering, braking & parking) Level 4/5 Autonomous Driving Autonomous Driving L3: Conditional Automation L4: Highly Autonomous Adapted from Frost & Sullivan analysis. PUBLIC USE 8
Proliferation of Radarbased Safety: SRR Radar for "Entry-level" NCAP for low-end models and corner radar for NCAP 2020 Emergence of L3/L4 Autonomous Support: Need for "surround-sense" USRR/SRR radar satellite modules Small module size for flexible deployment new deployment scenarios in doors, etc driving small size requirements Small Size for New Deployment Scenarios "Stand-Alone" NCAP Functions "Satellite" Sensors for L3/L4 Autonomous PUBLIC USE 9
Advanced Radar High Resolution Radar Sometimes called Imaging Radar Some techniques use Synthetic Aperture Radar Integrate information as the vehicle moves to improve overall view of the environment Use many transmit antennas and many receive antennas Create large amounts of complimentary data Perform calculations to effectively increase the resolution of the radar Claims as low as 1.2 of angular resolution Lidar High Resolution Radar PUBLIC USE 10 10
Application Context for Radar Systems MULTI-MODE MRR/SRR Junction Assist, Cross Traffic, Evasive Steering MULTI-MODE MRR/SRR NCAP Lateral Assist, Evasive Steering, Highway Pilot PUBLIC USE 11 LONG RANGE HIGH RESOLUTION RADAR Adaptive Cruise Control Automatic Emergency Braking Forward Collision Warning
V2X extends sensing beyond own vehicle & beyond line of sight Motorcycle approaching / do not pass! Platooning / cooperative driving 5m gap @ 80km/h based on 802.11p low latency Roadworks beyond line-of-sight 802.11p required for Safety-critical V2X features: Emergency vehicle around corner Low Latency, Secure & Beyond-line-of-sight Providing additional safety data earlier than any other sensor can see PUBLIC USE 12
WAVE/G5 Dedicated Short Range Communications (DSRC*) Ad-hoc, 2-way network ITS-G5 (Europe) WAVE/DSRC (USA) Regulated spectrum for ITS 7 free channels Low latency (<50ms) 360, Range up to 2km Data rates from 6-27Mbps Cooperative Assist Messages Decentralized Environmental Notification Message Basic Transport Protocol GeoNet Non-Safety Apps TCP/UDP IPv6 BSM Message Formats Min. Perf. Requirements (SAE J2735, J2945-1) DSRC Wave Short Message Protocol (WSMP) with Safety Sub- Layer (IEEE 1609.3) L5-7 L3-4 Signed messages using Public Key Infrastructure Decentralized Congestion Control 802.11p MAC DSRC Channel Switching (IEEE 1609.4) L2 * EU: DSRC describes road-tolling at 5.8 GHz, and not 802.11p 802.11p OFDM PHY (5.850 to 5.925 GHz) WAVE: Wireless Access in Vehicular Environment PUBLIC USE 13 L1
Security for V2X communications Message authentication via digital signatures Digital signature: For authentication (sender identity, content integrity) And non-repudiation (no plausible deniability) Based on: Public-key crypto: two keys, one is private (secret), other public (non-secret) Hash function unique identifier for message ETSI (EU) and IEEE (US) standards mandate ECDSA RSA signatures too long (bandwidth limitation) Comparable security strength: RSA 3072b ~ ECC 256b ~ AES 128b MSG SIGN MSG MSG VERIFY MSG SXF1800 Public key exchange (certificate can be part of message) SAF5400 PUBLIC USE 14 14
Security Pseudonym identity Privacy for V2X communication Pseudo-identities A vehicle can be tracked if it always uses the same unique identifiers A vehicle therefore uses multiple pseudoidentities each with limited lifetime Pseudo-identities are switched regularly (engine start, every X minutes,...) All identifiers are derived from the pseudoidentity and changed simultaneously Application ID Network & transport IPv6 address Data-link MAC address Physical...AID....IPv6........MAC.......key PUBLIC USE 15 15
Rinspeed Etos Concept Car https://www.youtube.com/watch?v=mienynrwzgw PUBLIC USE 16
NXP and the NXP logo are trademarks of NXP B.V. All other product or service names are the property of their respective owners. 2017 NXP B.V. PUBLIC USE 17 PUBLIC USE