China pumps up the hype about A.I. with oddball computer chip Posted on : Aug 03 - 2019

The term "artificial general intelligence," or AGI, doesn't actually refer to anything, at this point, it is merely a placeholder, a kind of Rorschach Test for people to fill the void with whatever notions they have of what it would mean for a machine to "think" like a person. 

Despite that fact, or perhaps because of it, AGI is an ideal marketing term to attach to a lot of efforts in machine learning. Case in point, a research paper featured on the cover of this week's Nature magazine about a new kind of computer chip developed by researchers at China's Tsinghua University that could "accelerate the development of AGI," they claim.

The chip is a strange hybrid of approaches, and is intriguing, but the work leaves unanswered many questions about how it's made, and how it achieves what researchers claim of it. And some longtime chip observers doubt the impact will be as great as suggested.

"This paper is an example of the good work that China is doing in AI," says Linley Gwennap, longtime chip-industry observer and principal analyst with chip analysis firm The Linley Group. "But this particular idea isn't going to take over the world."

The premise of the paper, "Towards artificial general intelligence with hybrid Tianjic chip architecture," is that to achieve AGI, computer chips need to change. That's an idea supported by fervent activity these days in the land of computer chips, with lots of new chip designs being proposed specifically for machine learning.

The Tsinghua authors specifically propose that the mainstream machine learning of today needs to be merged in the same chip with what's called "neuromorphic computing." Neuromorphic computing, first conceived by Caltech professor Carver Mead in the early '80s, has been an obsession for firms including IBM for years, with little practical result.

Neuromorphic chips transform incoming data by "spiking" in electrical potential, whereas today's deep learning performs a "matrix multiplication" operation that transforms incoming data via a set of "weights" or parameters, and then passes them through a non-linear operation called an "activation." The two different paths of the data are incommensurable, which is why they have been pursued as separate technologies to date. View More