All road vehicles require the powertrain to be controlled by an engine management system in order to reduce energy consumption and minimize emissions. Transportation accounts for almost 30% of greenhouse gases (reference) and increasingly tougher emissions regulations are being introduced to help manage the environmental impact.
With almost 100 million vehicles produced each year (reference), multiple dedicated semiconductor devices are needed to address the complex demands of these control systems. The powertrain controller must be highly responsive to meet strict real-time deadlines in the control system. It must be energy-efficient and able to operate safely. For many controllers this means the ISO 26262 functional safety standard must be supported.
Different types and configurations of powertrain systems have evolved as part of the electrification trend. Hybrid powertrain systems combine both conventional ICE engines together with some electrified support:
All of these have a range of control requirements and combine to create a mix of different control systems, from the combustion engine to the electric motor, transmission, battery management and recharging. To account for this, systems are implementing domain controllers where multiple related functions are integrated to enable fewer controllers and the ability to add more software for providing additional functionality. The advent of EVs has freed up some of the past constraints of combustion engines and is one of the enablers of centralized vehicle networking architectures, where controllers communicate with each other. Zonal controllers can be created to integrate multiple functions and offer a more optimized system.