$1,000 is the figure to keep in mind to visualise the key role of semiconductor technologies within the automotive industry in 2029.
Yole Group’s analysts announce a $100 billion automotive semiconductor market at that time. Behind those figures, ADAS and safety will experience the highest growth with 14% CAGR between 2023 and 2029. Electrification is not included, as it is the second-largest market driver for semiconductor growth with more than 13% CAGR during the same period. And even though electrification in Europe is slowing down compared to last year, the Chinese market is still highly active in that field.
“The global automotive market is growing slowly, leaving some OEMs and suppliers in more challenging situations during the transformation. However, the mid-term picture still brings a significant 11% growth to the semiconductor device market, which will reach almost $100 billion in 2029,” said Yu Yang, Principal Analyst, Automotive Semiconductor at Yole Group.
Yole Group releases its new Semiconductor Trends in Automotive report, 2024 edition. This new product provides an in-depth understanding of the changing automotive industry ecosystem and supply chain. It delivers a complete overview of the current technological trends and a 2019-2029 forecast of market value, volume, and wafers.
This year, the ‘Triple-C’ model – a specialised tool designed to help OEMs develop their individual semiconductor strategies – has been expanded to include all of the top 20 global OEM groups, along with leading Chinese EV startups such as Nio, XPeng, and Li Auto. The 2024 analysis highlights significant diversity within the ecosystem. On average, OEMs are becoming more deeply engaged in the semiconductor sector. Another notable trend is that Chinese OEMs are making broader investments in various types of chips and are more deeply involved in the upstream supply chain. Power modules, which are critical enablers for EVs, serve as a prime example. Nearly all Chinese OEMs have investments in this segment across various formats. In addition to power modules, high-performance processors and MCUs are also highly favoured by OEMs. Yole Group automotive semiconductor report offers a detailed discussion of each OEM’s strategy.
The semiconductor landscape is evolving rapidly, with emerging players making significant inroads. Who are the key suppliers to keep an eye on, and which cutting-edge technologies are they championing? The Semiconductor Trends in Automotive report from Yole Group takes a comprehensive look at the intersection of automotive innovation and high-tech advancements, offering a deep dive into the latest trends driving the sector forward. As software-defined vehicles are expected to emerge in the coming years, Yole Group analysed their impact on E/E architecture and the increasing demand for domain and zone controllers. In the realm of semiconductors, particularly computing, chiplets are rapidly gaining traction. These could be utilised to integrate multiple functions within ADAS and infotainment systems, making future architectures more cost-effective.
“The market currently represents a semiconductor device value of around $590 per car in 2023. With this figure growing to about $1,000 per car, semiconductor technology and its latest innovations become essential. At Yole Group, we highlight the significant trends linked to ADAS and electrification,” said Pierrick Boulay, Senior Technology & Market Analyst, Automotive Semiconductors.
For example:
Power devices: the growing attractivity of EVs is driving demand for SiC MOSFET modules, crucial for efficient power conversion. While global growth in BEVs is starting to slow, the gap is being filled by a range of hybrid technologies, all of which also rely heavily on advanced power electronics.
MCUs: Advanced 16 and 10nm MCUs are essential for ADAS applications. Yole Group’s analysts include, for example, radars and sensor control. The evolution of E/E architecture toward domain and zonal controllers pushes the need for high-performance MCUs while lowering the total number of MCUs.
Computing power and memory: achieving higher levels of autonomy, beyond Level 3, will require greater memory capacity and enhanced computing power.