Nowadays, in the fast-paced digital age, few industries remain untouched by the winds of transformation and the automotive industry is no exception. Now, at the forefront of its electrification evolution (or revolution), stands the concept of autonomous driving (AD) and electric vehicles (EVs), heralding an era where vehicles no longer rely on human intervention. But why has autonomous driving become the ultimate goal of this industry’s digital transformation? Let’s delve deeper.
AD is crucial for EVs, and vice versa
The symbiotic relationship between autonomous driving and electric vehicles (EVs) is profound. Due to the need of integrating state-of-the-art sensors and computing hardwares on vehicle, AD systems demand high power consumption and power efficiency. Traditional internal combustion engines, with their myriad of moving parts, don’t quite match the sleek electric powertrains in this domain. EVs, being inherently more efficient, responsive and predictable, cater to the exacting demands of AD systems.
Conversely, the proliferation of AD can accelerate the adoption of EVs. As AD technology becomes a mainstream choice, there will be a shift in the perception of vehicles from being purely utility- driven purchases to experience-focused ones. In such a scenario, the tangible benefits of EVs – like lower operating costs and reduced emissions – will make them the preferred choice for autonomous systems. Moreover, AD will make EVs not just a means of transportation, but more of a living space with enjoyable experiences.
AD is more than software and requires full-stack specialties
Many mistakenly believe that making a car autonomous is simply about layering sophisticated software over existing vehicle systems. In reality, achieving true autonomy requires deep integration across the full vehicle stack, from hardware to software.
The sensors that allow AD to perceive its environment, the algorithms that process this data, and the actuators that execute driving actions all need to work in perfect harmony. This mandates a seamless melding of various disciplines – mechanical engineering, computer science, electrical engineering, and more.
Moreover, ensuring safety in AD is paramount. Redundancies need to be considered into every sub- system, and these redundancies must be rigorously designed, validated and verified. The vehicle should be able to react appropriately even in the event of unforeseen failures, ensuring the safety of its occupants and other road users.
Automotive semiconductors are critical enablers for AD & EVs
The heart of the digital revolution in vehicles beats thanks to automotive semiconductors. As the driving force behind sensors, computation units, and electrical architectures, semiconductors play a pivotal role in making autonomous driving a reality.
Advanced sensors, from lidars to radars to cameras, rely on semiconductor components to function accurately and reliably. The data these sensors generate is immense. Processing this data in real- time requires powerful computation units, again enabled by advanced semiconductor technology.
Furthermore, the entire electrical and electronic (EE) architecture of a modern vehicle, which supports everything from infotainment to advanced driver assistance systems, is built upon semiconductors. As demands grow, with higher data rates and lower latencies, the role of automotive semiconductors will only become more significant.
In Conclusion
Autonomous driving, though still in its nascent stages, represents the pinnacle of what the automotive industry can achieve with digital transformation. It’s a testament to human ingenuity, showcasing how cutting-edge technology can redefine age-old industries. As we stand on the cusp of this revolution, it’s essential to recognize and appreciate the myriad of components and specialties that converge to make it possible. The road ahead is exciting, and the journey promises to be transformative.