Chassis and Vehicle Dynamics - P18311969

CONTENT HIGHLIGHTS • Automatic Emergency Braking Overview • History: active safety origins • Key enablers for Automatic Emergency Braking (AEB) • AEB level of automation • AEB features and marketed benefits • Primer: Basic Engineering Fundamentals • Vehicle dynamics; Wheel dynamics • System engineering requirements flow • AEB System Requirements • Basic driving tasks; Basic braking tasks • General & refined system requirements • AEB System Architecture and Decomposition • Functional Architecture – sensing systems, warning systems, actuation systems • AEB operation modes • Physical Architecture – sensors, adaptive cruise control (ACC) ECU, body control module (BCM) ECU, electronic stability control (ESC) ECU • AEB System Design: Safety • ISO-26262 framework • Hazard analysis and risk assessment exercise • AEB safety goals and requirements • Safety of the intended function (SOTIF) considerations • AEB System Design: Performance Objectives • Sensing technology and implementation • Computational objectives: AEB ECU computing platforms • Human Machine Interface (HMI) warnings and considerations • Actuator objectives: braking actuator control design • AEB System Test and Validation • AEB validation objectives • Subsystem testing • Vehicle level testing • Conclusions and Future Direction • Market penetration • Customer acceptance • Incremental steps towards full autonomy INSTRUCTOR Eldon Leaphart Principal Engineer, Carr Engineering, Inc.

I.D.# C1704

SCHEDULE January 14, 2019 Troy, Michigan April 10, 2019 Detroit, Michigan June 25, 2019 Troy, Michigan September 26, 2019 Orlando, Florida

FEES List:

$835 $752

Members:

ONE-DAY/.7 CEUS

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