Inside Arm’s vision for the ‘software-defined vehicle’ of the future

Technology


The digitisation of cars has made comparisons to “data centres on wheels” so common that they’ve become clichéd. It’s also built a booming market for tech firms — few of which have capitalised as adeptly as Arm. 

Often described as the UK’s leading IT company, SoftBank-owned Arm designs energy-efficient computer chips. The company’s architectures are found in endless applications, from smart cities to laptops, but they’re best-known for powering mobile devices. Around 95% of the world’s smartphones use Arm’s technology.

In recent years, however, the company’s fastest-growing division has been the automotive unit. Arm has reportedly more than doubled its revenues from the sector since 2020. 

Dennis Laudick, Arm’s vice president of automotive go-to-market, attributes the growth to a convergence of three trends: electrification, automation, and in-vehicle user experience (UX).

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“All of those are driving more compute into the vehicle,” he says — and more compute means more business for Arm.

As the company prepares for a long-awaited public listing, Laudick gave TNW a glimpse into his automotive strategy.

Electric avenues

Gradually, EVs are engulfing the car market. Last year, fully-electric vehicles comprised over 10% of car sales in Europe for the first time. Globally, their total sales hit around 7.8 million units — as much as 68% more than in 2022. To serve this growing market, automakers have to integrate a complex new collection of electronics.

“When you do that, it becomes a lot more complicated system,” says Laudick. “You need to look at even more electronics to manage it, and that causes people to rethink their architectures.”

The result is firmer foundations for more digital features. Take the all-electric Nissan Leaf, which runs Arm’s Cortex-R4 processor alongside an electric powertrain.

To control the power inverter, a microcomputer core has to accurately repeat a series of processes — such as sensing, calculation, and control output — for events that occur in 1/10,000-second cycles. In this tiny computation window, the system has to deliver efficient, responsive, and precise control. 

By placing the battery and other heavy items close to the center of gravity, the yaw moment of inertia has been reduced compared to front-engine vehicles for improved stability and smoother cornering.