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Engineers put tens of thousands of artificial brain synapses on a single chip
PhysOrg ^ | Jennifer Chu

Posted on 06/08/2020 7:29:25 PM PDT by LibWhacker

MIT engineers have designed a "brain-on-a-chip," smaller than a piece of confetti, that is made from tens of thousands of artificial brain synapses known as memristors—silicon-based components that mimic the information-transmitting synapses in the human brain.

The researchers borrowed from principles of metallurgy to fabricate each memristor from alloys of silver and copper, along with silicon. When they ran the chip through several visual tasks, the chip was able to "remember" stored images and reproduce them many times over, in versions that were crisper and cleaner compared with existing memristor designs made with unalloyed elements.

Their results, published today in the journal Nature Nanotechnology, demonstrate a promising new memristor design for neuromorphic devices—electronics that are based on a new type of circuit that processes information in a way that mimics the brain's neural architecture. Such brain-inspired circuits could be built into small, portable devices, and would carry out complex computational tasks that only today's supercomputers can handle.

"So far, artificial synapse networks exist as software. We're trying to build real neural network hardware for portable artificial intelligence systems," says Jeehwan Kim, associate professor of mechanical engineering at MIT. "Imagine connecting a neuromorphic device to a camera on your car, and having it recognize lights and objects and make a decision immediately, without having to connect to the internet. We hope to use energy-efficient memristors to do those tasks on-site, in real-time."

Wandering ions

Memristors, or memory transistors, are an essential element in neuromorphic computing. In a neuromorphic device, a memristor would serve as the transistor in a circuit, though its workings would more closely resemble a brain synapse—the junction between two neurons. The synapse receives signals from one neuron, in the form of ions, and sends a corresponding signal to the next neuron.

A transistor in a conventional circuit transmits information by switching between one of only two values, 0 and 1, and doing so only when the signal it receives, in the form of an electric current, is of a particular strength. In contrast, a memristor would work along a gradient, much like a synapse in the brain. The signal it produces would vary depending on the strength of the signal that it receives. This would enable a single memristor to have many values, and therefore carry out a far wider range of operations than binary transistors.

Like a brain synapse, a memristor would also be able to "remember" the value associated with a given current strength, and produce the exact same signal the next time it receives a similar current. This could ensure that the answer to a complex equation, or the visual classification of an object, is reliable—a feat that normally involves multiple transistors and capacitors.

Ultimately, scientists envision that memristors would require far less chip real estate than conventional transistors, enabling powerful, portable computing devices that do not rely on supercomputers, or even connections to the Internet.

Existing memristor designs, however, are limited in their performance. A single memristor is made of a positive and negative electrode, separated by a "switching medium," or space between the electrodes. When a voltage is applied to one electrode, ions from that electrode flow through the medium, forming a "conduction channel" to the other electrode. The received ions make up the electrical signal that the memristor transmits through the circuit. The size of the ion channel (and the signal that the memristor ultimately produces) should be proportional to the strength of the stimulating voltage.

Kim says that existing memristor designs work pretty well in cases where voltage stimulates a large conduction channel, or a heavy flow of ions from one electrode to the other. But these designs are less reliable when memristors need to generate subtler signals, via thinner conduction channels.

The thinner a conduction channel, and the lighter the flow of ions from one electrode to the other, the harder it is for individual ions to stay together. Instead, they tend to wander from the group, disbanding within the medium. As a result, it's difficult for the receiving electrode to reliably capture the same number of ions, and therefore transmit the same signal, when stimulated with a certain low range of current. The new chip (top left) is patterned with tens of thousands of artificial synapses, or “memristors,” made with a silver-copper alloy. When each memristor is stimulated with a specific voltage corresponding to a pixel and shade in a gray-scale image (in this case, a Captain America shield), the new chip reproduced the same crisp image, more reliably than chips fabricated with memristors of different materials. Credit: Image courtesy of the researchers

Borrowing from metallurgy

Kim and his colleagues found a way around this limitation by borrowing a technique from metallurgy, the science of melding metals into alloys and studying their combined properties.

"Traditionally, metallurgists try to add different atoms into a bulk matrix to strengthen materials, and we thought, why not tweak the atomic interactions in our memristor, and add some alloying element to control the movement of ions in our medium," Kim says.

Engineers typically use silver as the material for a memristor's positive electrode. Kim's team looked through the literature to find an element that they could combine with silver to effectively hold silver ions together, while allowing them to flow quickly through to the other electrode.

The team landed on copper as the ideal alloying element, as it is able to bind both with silver, and with silicon.

"It acts as a sort of bridge, and stabilizes the silver-silicon interface," Kim says.

To make memristors using their new alloy, the group first fabricated a negative electrode out of silicon, then made a positive electrode by depositing a slight amount of copper, followed by a layer of silver. They sandwiched the two electrodes around an amorphous silicon medium. In this way, they patterned a millimeter-square silicon chip with tens of thousands of memristors.

As a first test of the chip, they recreated a gray-scale image of the Captain America shield. They equated each pixel in the image to a corresponding memristor in the chip. They then modulated the conductance of each memristor that was relative in strength to the color in the corresponding pixel.

The chip produced the same crisp image of the shield, and was able to "remember" the image and reproduce it many times, compared with chips made of other materials.

The team also ran the chip through an image processing task, programming the memristors to alter an image, in this case of MIT's Killian Court, in several specific ways, including sharpening and blurring the original image. Again, their design produced the reprogrammed images more reliably than existing memristor designs.

"We're using artificial synapses to do real inference tests," Kim says. "We would like to develop this technology further to have larger-scale arrays to do image recognition tasks. And some day, you might be able to carry around artificial brains to do these kinds of tasks, without connecting to supercomputers, the internet, or the cloud."


TOPICS: Computers/Internet; Science
KEYWORDS: artificial; brain; brainonachip; chip; memristor; synapses
Relax, what could go wrong?
1 posted on 06/08/2020 7:29:25 PM PDT by LibWhacker
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To: LibWhacker

Dems could use some more synapses


2 posted on 06/08/2020 7:31:08 PM PDT by goodnesswins (Anyone tired of the Chinese Fire Drill (tm) yet???)
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To: LibWhacker

M5 was still based upon a single person’s engrams — and morals.


3 posted on 06/08/2020 7:31:33 PM PDT by treetopsandroofs
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To: LibWhacker

caprica


4 posted on 06/08/2020 7:37:13 PM PDT by Secret Agent Man (Gone Galt; Not Averse to Going Bronson.)
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To: LibWhacker

5 posted on 06/08/2020 7:38:19 PM PDT by BenLurkin (The above is not a statement of fact. It is either opinion or satire. Or both.)
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To: LibWhacker
Colossus: The Forbin Project
6 posted on 06/08/2020 7:40:52 PM PDT by yesthatjallen
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To: BenLurkin

What could possibly go wrong?


7 posted on 06/08/2020 7:41:21 PM PDT by KC_Lion
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To: LibWhacker
What could go wrong?

They might be smarter than Dems and RINOs...😀

8 posted on 06/08/2020 7:48:15 PM PDT by ConservaTeen (WFLA's Jack Harris: Brooklyn is missing their village idiot. Right you are, Jack.)
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To: Secret Agent Man
Remarkable prequel. Slightly disturbing and thoroughly edgy....

9 posted on 06/08/2020 7:49:42 PM PDT by BenLurkin (The above is not a statement of fact. It is either opinion or satire. Or both.)
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To: LibWhacker
One problem with duplicating the human brains is that biological neurons have 8 positions, and connections to other neurons, while transistors only have two, 0 or 1. By "shading" memory, and remembering it, you can cram more memory onto the chip.

A quantum leap in storage.

We let Democrats wander loose, with less intellect, and no logic. I'm betting that AI will vote Republican.

10 posted on 06/08/2020 7:54:51 PM PDT by jonascord (First rule of the Dunning-Kruger Club is that you do not know you are in the Dunning-Kruger club.)
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To: LibWhacker

I for one welcome our new robot overlords.


11 posted on 06/08/2020 8:02:28 PM PDT by FreedomPoster (Islam delenda est)
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To: goodnesswins

Test models installed with Joe Biden’s hair plugs.


12 posted on 06/08/2020 8:04:08 PM PDT by ptsal (Vote R.E.D. >>>Remove Every Democrat ***)
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To: LibWhacker

Don’t disparage the effort. Do you know how many liberals had to donate their brains just to fill a single chip?


13 posted on 06/08/2020 8:08:13 PM PDT by Viking2002 (Why should I walk into the great unknown, when I can sit here, and throw my bones?)
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To: LibWhacker

Skynet has become self-aware.


14 posted on 06/08/2020 8:22:21 PM PDT by LastDayz (A blunt and brazen Texan. I will not be assimilated.)
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To: LibWhacker

The multi-tronic units one through four were not entirely successful.


15 posted on 06/08/2020 8:31:52 PM PDT by dartuser
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To: KC_Lion

“What could possibly go wrong?”

For example?


16 posted on 06/08/2020 8:36:45 PM PDT by TexasGator (Z1z)
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To: jonascord

Yep! And there’s another problem, “tens of thousands.”

A human brain has well over a hundred trillion synapses. Some estimate over 1,000 trillion.

But AI is now closing the that computational gap with graphic processors and cloud computing.


17 posted on 06/08/2020 8:41:36 PM PDT by MV=PY (The Magic Question: Who's paying for it?)
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To: LibWhacker

Well, there are 100-1000 trillion in the human brain, so I guess they’re making democrats.


18 posted on 06/08/2020 10:09:13 PM PDT by neverevergiveup
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To: LibWhacker
I...VERY-MUCH... APPROVE-OF... THIS-DEVELOPMENT!

END-MESSAGE

19 posted on 06/08/2020 10:14:29 PM PDT by alexander_busek (Extraordinary claims require extraordinary evidence.)
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To: LibWhacker

Daystrum, M5

Star Trek


20 posted on 06/08/2020 10:17:26 PM PDT by Varsity Flight (QE 2020. All Quiet on the Western Front)
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