November 26, 2024

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Former science minister Choi Ki-young delivers a virtual keynote speech at the 29th Korean Conference on Semiconductors held in Jeongseon, Gangwon Province, held on Tuesday. (KCS)

JEONGSEON, Gangwon Province -- New chip technologies could advance to the degree that chips in the future could emulate the human brain in terms of computing speed, density and efficiency, experts said at a semiconductor conference last week.

However, a technology breakthrough is crucial, as achieving large processing capacity and energy efficiency simultaneously is becoming more elusive, for conventional chips to do what a human brain can, former Science Minister Choi Ki-young said.

“A human brain shows high processing speed on a low clock frequency and power density, often outperforming contemporary computers,” Choi said in a keynote speech at the 29th Korean Conference on Semiconductors held in Jeongseon, Gangwon Province.

“Brains are more complex than we think, so it might require much larger memory capacity than what the chip industry has enabled. Increasing the memory capacity of low-energy chips is crucial to getting AI into work.”

With the advent of artificial intelligence, there is growing demand for cutting-edge chips, but new chips have often caused a bottleneck in data processing and are inefficient in energy consumption.

This has raised the need to overcome limitations posed by the conventional von Neumann architecture for chips and adopt next-generational technology to integrate processors with memory cores within a single chip.

According to Choi, Korean memory chip leaders like Samsung Electronics and SK hynix might be facing a “critical opportunity” to beat their rivals, once the companies succeed in integrating processors with memory cores, in the era of artificial intelligence followed by the mobile era, led by Arm’s neural processing unit.

Choi said Samsung’s high bandwidth memory enabled on a processing-in-memory technology reflects the industry’s desire to transition from the mobile era. The solution demonstrated 2.5 times faster processing and a 60 percent cut in power consumption when launched in 2021.

Another keynote speaker, Kang Sung-mo, an electrical and computer engineering professor at University of California, Santa Cruz, echoed Choi’s view. The existing technologies and architectures rather showed that achieving the scale of a human brain -- comprising 100 billion neurons and over 100 trillion synapses across a 2,400 square centimeters of surface space -- is a tall order under the current multilayered convolutional neural network technologies.

A new memristor-based neuromorphic computing model could be a game changer in the chip industry in it’s race for achieving brain scale, Kang said.

The gist of the technology is to use memristor as the building blocks of electronic components, along with resistors, inductors and capacitors for run-of-the-mill circuits. Each of the components will play the role of a neuron in the human brain that sends and receives data.

With memristors allowing chips to regulate the flow of electrical currents in case of the overflowing inputs, the technology, called memristor integrated fire model, has the potential for chip hardware to realize the basics of the neural network, just like a human brain whose neuron transmits signals to another neuron through thousands of synaptic terminals.

“We have a lot to learn from the human brain, consisting of neurons and synapses. The question I pose is: Can you build neurons using memristors and can you build synapses using memristors? The answer is yes,” said Kang, who was formerly president of the Korea Advanced Institute of Science and Technology.

The brain-scale chips can potentially be applied in the field of ultrafast image processing, sound localization and brain repair for dementia patients, according to Kang.

By Son Ji-hyoung (consnow@heraldcorp.com)