| Advanced Driver Assistance Systems |
High-voltage battery management systems for electric vehicles |
Driver State and Intent Recognition |
Power Electronics and Motor Drives |
| Advances in battery technologies for electric vehicles |
Human Factors and Human Machine Interaction |
Dynamics and Controls |
Powertrain: Design, Thermal Management, Packaging, and Optimization |
| Advantages and disadvantages of electric vehicles |
Image, Radar, Lidar Signal Processing |
Eco-driving and Energy-efficient Vehicles |
Proton battery |
| All-solid-state batteries |
Impact on Traffic Flows |
Electric and Hybrid Technologies |
Proximity Awareness Technology |
| Autonomous and Intelligent Robotic Vehicles |
Intelligent Ground, Air and Space Vehicles |
Electric road vehicle battery charging systems and infrastructure |
Redox-flow batteries |
| Battery Chargers: Onboard, Wireless, Fast and Ultra-Fast |
Intelligent Vehicle Software Infrastructure |
Electric vehicle |
Renewable and Non-Renewable Energies |
| Battery design and performance |
Internal Combustion Engines |
Electric, Hybrid Electric, Plug-in Hybrid Electric Vehicle System Architectures and Control |
Robotics |
| Battery electric vehicles, and off-road electric vehicles |
Lead-acid batteries for hybrid electric vehicles and battery electric vehicles |
Electrical Systems and Components for Sea, Undersea, Air, and Space Vehicles |
Safety aspects of battery management systems |
| Battery pack design |
Licensing regulations for electric vehicles |
Electrification of Heavy-Duty and Off-Road Vehicles |
Safety requirements |
| Battery parameters for HEV applications |
Life-cycle energy consumption and CO2 emissions compared |
Energy consumption and CO2 emissions of vehicle production |
Smart and Micro Grids, EV-Interacting Smart Grid and Electrical Infrastructure |
| Battery parameters for hybrid electric vehicles |
Limits to and potential future developments of lithium-ion batteries and supercapacitors |
Energy consumption of electric vehicles |
Smart Mobility |
