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In a world increasingly reliant on digital technologies, the quest for energy-efficient solutions has become paramount. Nowhere is this more evident than in the realm of artificial intelligence (AI), where the demand for intelligent devices that can operate efficiently on limited power sources has soared.
Recognising this need, researchers from the National University of Singapore (NUS), in collaboration with industry leaders, have unveiled a groundbreaking suite of silicon systems poised to revolutionise the landscape of AI-connected devices.
At the forefront of this technological breakthrough lies fully-depleted silicon-on-insulator (FD-SOI) technology, a cutting-edge approach to semiconductor design that promises unparalleled energy efficiency. Demonstrated at an industry showcase, these chips represent a significant leap forward in semiconductor innovation, offering transformative capabilities that extend far beyond traditional applications.
The potential impact of this innovation is profound. With the ability to significantly enhance energy efficiency, these chips hold the key to unlocking a new era of AI-connected devices, from wearables to smart cities. By optimising battery life, supporting intensive computational workloads, and reducing power consumption associated with wireless communications, these chips are poised to redefine the boundaries of what is possible in the realm of AI technology.
Leading the charge in this groundbreaking research is Professor Massimo Alioto, Director of the FD-fAbrICS joint lab at NUS. Speaking at the industry showcase, Professor Alioto emphasised the transformative potential of FD-SOI technology in powering the next generation of AI devices. By simultaneously reducing average power consumption while enhancing peak performance, these chips enable a wide range of applications previously thought unattainable.
But the impact of this research extends far beyond the confines of academia. Recognising the importance of collaboration between academia and industry, the researchers have formed partnerships with industry leaders to accelerate the adoption of FD-SOI technology on a larger scale. Through collaborative efforts, these partnerships aim to lower the design barrier to entry, making energy-efficient chip technologies more accessible to a wider range of applications.
Central to this collaborative effort is the establishment of the FD-SOI & IoT Industry Consortium, a platform aimed at amplifying the impact of FD-SOI technology on Singapore’s semiconductor ecosystem. Through this consortium, industry players gain access to innovative design IP and methodologies, accelerating the prototyping and development cycle of next-generation AI-connected chips. By fostering collaboration and knowledge-sharing, the consortium aims to drive rapid adoption of energy-efficient chip technologies, positioning Singapore as a global leader in semiconductor innovation.
Looking ahead, the potential for these chips to reshape the landscape of AI technology is immense. With their ability to power a wide range of intelligent devices, from wearables to smart cities, these chips hold the key to unlocking new possibilities in AI-driven innovation. By leveraging the capabilities of FD-SOI technology, researchers and industry partners are poised to usher in a new era of energy-efficient computing, transforming the way we interact with technology and shaping the future of AI-connected devices.
The collaboration between NUS researchers and industry partners represents a significant milestone in the field of semiconductor innovation. By harnessing the power of FD-SOI technology, these chips have the potential to revolutionise the way we think about energy efficiency in AI-connected devices. With their transformative capabilities, these chips are poised to drive innovation and propel Singapore to the forefront of semiconductor technology on the global stage.