Tag Archives: University of Hong Kong

Synaptic transistor better then memristor when it comes to brainlike learning for computers

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An April 30, 2021 news item on Nanowerk announced research from a joint team at Northwestern University (located in Chicago, Illinois, US) and University of Hong Kong of researchers in the field of neuromorphic (brainlike) computing,

Researchers have developed a brain-like computing device that is capable of learning by association.

Similar to how famed physiologist Ivan Pavlov conditioned dogs to associate a bell with food, researchers at Northwestern University and the University of Hong Kong successfully conditioned their circuit to associate light with pressure.

The device’s secret lies within its novel organic, electrochemical “synaptic transistors,” which simultaneously process and store information just like the human brain. The researchers demonstrated that the transistor can mimic the short-term and long-term plasticity of synapses in the human brain, building on memories to learn over time.

With its brain-like ability, the novel transistor and circuit could potentially overcome the limitations of traditional computing, including their energy-sapping hardware and limited ability to perform multiple tasks at the same time. The brain-like device also has higher fault tolerance, continuing to operate smoothly even when some components fail.

“Although the modern computer is outstanding, the human brain can easily outperform it in some complex and unstructured tasks, such as pattern recognition, motor control and multisensory integration,” said Northwestern’s Jonathan Rivnay, a senior author of the study. “This is thanks to the plasticity of the synapse, which is the basic building block of the brain’s computational power. These synapses enable the brain to work in a highly parallel, fault tolerant and energy-efficient manner. In our work, we demonstrate an organic, plastic transistor that mimics key functions of a biological synapse.”

Rivnay is an assistant professor of biomedical engineering at Northwestern’s McCormick School of Engineering. He co-led the study with Paddy Chan, an associate professor of mechanical engineering at the University of Hong Kong. Xudong Ji, a postdoctoral researcher in Rivnay’s group, is the paper’s first author.

Caption: By connecting single synaptic transistors into a neuromorphic circuit, researchers demonstrated that their device could simulate associative learning. Credit: Northwestern University

An April 30, 2021 Northwestern University news release (also on EurekAlert), which originated the news item, includes a good explanation about brainlike computing and information about how synaptic transistors work along with some suggestions for future applications,

Conventional, digital computing systems have separate processing and storage units, causing data-intensive tasks to consume large amounts of energy. Inspired by the combined computing and storage process in the human brain, researchers, in recent years, have sought to develop computers that operate more like the human brain, with arrays of devices that function like a network of neurons.

“The way our current computer systems work is that memory and logic are physically separated,” Ji said. “You perform computation and send that information to a memory unit. Then every time you want to retrieve that information, you have to recall it. If we can bring those two separate functions together, we can save space and save on energy costs.”

Currently, the memory resistor, or “memristor,” is the most well-developed technology that can perform combined processing and memory function, but memristors suffer from energy-costly switching and less biocompatibility. These drawbacks led researchers to the synaptic transistor — especially the organic electrochemical synaptic transistor, which operates with low voltages, continuously tunable memory and high compatibility for biological applications. Still, challenges exist.

“Even high-performing organic electrochemical synaptic transistors require the write operation to be decoupled from the read operation,” Rivnay said. “So if you want to retain memory, you have to disconnect it from the write process, which can further complicate integration into circuits or systems.”

How the synaptic transistor works

To overcome these challenges, the Northwestern and University of Hong Kong team optimized a conductive, plastic material within the organic, electrochemical transistor that can trap ions. In the brain, a synapse is a structure through which a neuron can transmit signals to another neuron, using small molecules called neurotransmitters. In the synaptic transistor, ions behave similarly to neurotransmitters, sending signals between terminals to form an artificial synapse. By retaining stored data from trapped ions, the transistor remembers previous activities, developing long-term plasticity.

The researchers demonstrated their device’s synaptic behavior by connecting single synaptic transistors into a neuromorphic circuit to simulate associative learning. They integrated pressure and light sensors into the circuit and trained the circuit to associate the two unrelated physical inputs (pressure and light) with one another.

Perhaps the most famous example of associative learning is Pavlov’s dog, which naturally drooled when it encountered food. After conditioning the dog to associate a bell ring with food, the dog also began drooling when it heard the sound of a bell. For the neuromorphic circuit, the researchers activated a voltage by applying pressure with a finger press. To condition the circuit to associate light with pressure, the researchers first applied pulsed light from an LED lightbulb and then immediately applied pressure. In this scenario, the pressure is the food and the light is the bell. The device’s corresponding sensors detected both inputs.

After one training cycle, the circuit made an initial connection between light and pressure. After five training cycles, the circuit significantly associated light with pressure. Light, alone, was able to trigger a signal, or “unconditioned response.”

Future applications

Because the synaptic circuit is made of soft polymers, like a plastic, it can be readily fabricated on flexible sheets and easily integrated into soft, wearable electronics, smart robotics and implantable devices that directly interface with living tissue and even the brain [emphasis mine].

“While our application is a proof of concept, our proposed circuit can be further extended to include more sensory inputs and integrated with other electronics to enable on-site, low-power computation,” Rivnay said. “Because it is compatible with biological environments, the device can directly interface with living tissue, which is critical for next-generation bioelectronics.”

Here’s a link to and a citation for the paper,

Mimicking associative learning using an ion-trapping non-volatile synaptic organic electrochemical transistor by Xudong Ji, Bryan D. Paulsen, Gary K. K. Chik, Ruiheng Wu, Yuyang Yin, Paddy K. L. Chan & Jonathan Rivnay . Nature Communications volume 12, Article number: 2480 (2021) DOI: https://doi.org/10.1038/s41467-021-22680-5 Published: 30 April 2021

This paper is open access.

“… devices that directly interface with living tissue and even the brain,” would I be the only one thinking about cyborgs?

Steering a synthetic nanorobot using light

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This news comes from the University of Hong Kong. A Nov. 8, 2016 news item on Nanowerk throws some light on the matter (Note: A link has been removed),

A team of researchers led by Dr Jinyao Tang of the Department of Chemistry, the University of Hong Kong, has developed the world’s first light-seeking synthetic Nano robot. With size comparable to a blood cell, those tiny robots have the potential to be injected into patients’ bodies, helping surgeons to remove tumors and enabling more precise engineering of targeted medications. The findings have been published in October [2016] earlier in leading scientific journal Nature Nanotechnology (“Programmable artificial phototactic microswimmer”).

An Oct. 24, 2016 University of Hong Kong press release (also on EurekAlert), which originated the news item, expands on the theme,

It has been a dream in science fiction for decades that tiny robots can fundamentally change our daily life. The famous science fiction  movie “Fantastic  Voyage” is a very good example, with a group of scientists driving their miniaturized nano-submarine inside human body to repair a damaged brain. In the film “Terminator  2,” billions of nanorobots were assembled into the amazing shapeshifting body: the T-1000. In the real world, it is quite challenging to make and design a sophisticated nanorobot with advanced functions.

The Nobel Prize in Chemistry 2016 was awarded to three scientists for “the design and synthesis of molecular machines.” They developed a set of mechanical components at molecular scale which may be  assembled into  more complicated nanomachines  to  manipulate single  molecule such as DNA or proteins in the future. The development of tiny nanoscale machines for biomedical applications has been a major trend of scientific research in recent years. Any breakthroughs will potentially open the door to new knowledge and treatments of diseases and development of new drugs.

One difficulty in nanorobot design is to make these nanostructures sense and respond to the environment. Given each nanorobot is only a few micrometer in size which is ~50 times smaller than the diameter of a human hair, it  is very difficult  to  squeeze  normal electronic sensors and circuits into  nanorobots with reasonable price. Currently, the only method to remotely control nanorobots is to  incorporate tiny magnetic inside the nanorobot and guide the motion via external magnetic field.

The  nanorobot developed by Dr Tang’s team use light as the propelling  force, and is the first research team globally to explore the light-guided nanorobots and demonstrated its feasibility and effectiveness. In their paper published in Nature  Nanotechnology, Dr Tang’s team  demonstrated  the  unprecedented ability of these light-controlled nanorobots as they are “dancing”  or even spell a word under light control. With a novel  nanotree structure, the nanorobots can respond to the light shining on it like  moths  being drawn to flames. Dr Tang described the motions as if “they can “see” the light and drive itself towards it”.

The team gained inspiration from natural green algae
for the nanorobot design. In nature, some green algae have evolved  with  the  ability  of  sensing  light  around  it.  Even just a single cell, these green  algae can sense the intensity of light and swim  towards the light source for photosynthesis. Dr  Jinyao  Tang’s team successfully developed the nanorobots after over three years’ efforts. With a novel nanotree structure, they are composed of two  common and low-price semiconductor materials: silicon  and titanium oxide. During  the  synthesis, silicon  and titanium oxide are shaped into nanowire and then further arranged into a tiny nanotree heterostructure.

Dr Tang said: “Although the current nanorobot cannot be used for disease treatment yet, we are working on the next generation nanorobotic system which is more efficient and biocompatible.”

“Light is a more effective option to communicate between microscopic world and macroscopic world. We can conceive that more complicated instructions can be sent to nanorobots which provide scientists with a new tool to further develop more functions into nanorobot and get us one step closer to daily life applications,” he added.

Here’s a link to and a citation for the paper,

Programmable artificial phototactic microswimmer by Baohu Dai, Jizhuang Wang, Ze Xiong, Xiaojun Zhan, Wei Dai, Chien-Cheng Li, Shien-Ping Feng, & Jinyao Tang.  Nature Nanotechnology (2016)  doi:10.1038/nnano.2016.187 Published online 17 October 2016

So, this ‘bot’ seems to be a microbot or microrobot with some nanoscale features. In any event, the paper is behind a paywall.