Tag Archives: University of Hong Kong (HKU)

Year of Quantum Across Canada Conference October 6 – 9, 2025, Waterloo, Ontario (call for submissions deadline: Sept. 19, 2025)

Leave a reply

A September 9, 2025 Perimeter Institute for Theoretical Physics (PI) notice (received via email) announces a quantum conference and call for posters,

Join leading quantum researchers at the Year of Quantum Across Canada Conference that will highlight advances in quantum information theory and applications. The conference is co-hosted by the Institute for Quantum Computing (IQC) and Perimeter Institute of Theoretical Physics from October 6 to 9, 2025.

  • Learn about and share the latest advances in quantum information theory and applications.
  • Find opportunities to collaborate with local, Canadian and international quantum researchers.
  • Celebrate 100 years since the initial development of quantum mechanics this International Year of Quantum.

IQC and Perimeter Institute invite all scientists who are interested in:

  • Quantum metrology
  • Quantum simulation and quantum advantage
  • Quantum error-correction and fault tolerance
  • Quantum complexity and algorithms
  • Quantum communication and networks
  • Quantum cryptography
  • Quantum information in quantum matter and quantum gravity

Register Today

Registration Deadlines: 

  • In-Person: September 22 [2025] at 23:59 ET
  • Virtual: October 6 [2025] at 23:59 ET

We are hosting a poster session on Tuesday, October 7 [2025]. Abstract submission deadline is September 19 [2025] at 23:59 ET.

Please forward this email to your colleagues who would be interested in attending. Questions can be directed to mail to: iqc.events@uwaterloo.ca

I have more information about the call for poster submissions, from the Year of Quantum Across Canada’s Call for Abstracts webpage,

Submission deadline: Sep[t] 19, 2025, 11:59 PM [ET]

The Year of Quantum Across Canada Symposium will be hosting a poster session on Tuesday, Oct 7th [2025] at IQC. Poster submissions are welcome and will be reviewed by the program committee. Some posters may be selected to present as a contributed talk. If you are interested in your poster being considered for a talk, please indicate this on the submission form.

NOTE: You must be in attendance at the Symposium in Waterloo to present a poster and/or contributed talk. We encourage you to register for the Symposium as soon as possible as space is limited. You will be advised if your poster has been accepted before the registration fee payment deadline.

If you have questions about the Call for Abstracts with respect to your research, please contact Alex May (amay@perimeterinstitute.ca).

Any logistical questions about the application process, the website or decision timelines should be directed to conferences@perimeterinstitute.ca

Then, there’s this from the Year of Quantum Across Canada’s Speaker List webpage, Note: Two confirmed speakers from Canada to “celebrate and aim to strengthen the quantum information science community in Canada and beyond, by bringing together leading Canadian researchers as well as members of the broader quantum community” as per the conference homepage. Maybe they’ll get a few more before October 2025?,

Speaker List

Confirmed Speakers:

Christian Bauer (Lawrence Berkeley National Laboratory)
Alexandre Blais (Université de Sherbrooke)
Sergey Bravyi (IBM Research – Thomas J. Watson Research Center)
Nikolas Breuckmann (University of Bristol)
Soonwon Choi (MIT [Massachusetts Institute of Technology])
Zohreh Davoudi (University of Maryland)
Matthew Fisher (University of California, Santa Barbara)
Dakshita Khurana (University of Illinois Urbana-Champaign)
Aleksander Kubica (Yale University)
Hank Lamm (Fermilab)
Laura Mancinska (University of Copenhagen)
Antonio Mezzacapo (IBM)
John Preskill (Caltech)
Martin Savage (University of Washington)
Brian Swingle (Brandeis University)
Nathan Wiebe (University of Toronto)
Yu-Xiang Yang (The University of Hong Kong)

Moving on, UNESCO (United Nations Educational, Scientific and Cultural Organization) took a slightly more celebratory approach to their launch of the International Year of Quantum Science and Technology 2025 (IYQ 2025) in February 2025 (see my January 31, 2025 posting).

You can find the International Year of Quantum Science and Technology 2025 (IYQ 2025) website here. It provides information about a plethora of quantum events in countries around the world along with this video embedded here too,

Happy International Year of Quantum Science and Technology 2025 (YQ 2025)!

Memristor-based brain-computer interfaces (BCIs)

Leave a reply

Brief digression: For anyone unfamiliar with memristors, they are, for want of better terms, devices or elements that have memory in addition to their resistive properties. (For more see: R Jagan Mohan Rao’s undated article ‘What is a Memristor? Principle, Advantages, Applications” on InsstrumentalTools.com)

A March 27,2025 news item on ScienceDaily announces a memristor-enhanced brain-computer interface (BCI),

Summary: Researchers have conducted groundbreaking research on memristor-based brain-computer interfaces (BCIs). This research presents an innovative approach for implementing energy-efficient adaptive neuromorphic decoders in BCIs that can effectively co-evolve [emphasis mine] with changing brain signals.

So, the decoder in the BCI will ‘co-evolve’ with your brain? hmmm Also, where is this ‘memristor chip’? The video demo (https://assets-eu.researchsquare.com/files/rs-3966063/v1/7a84dc7037b11bad96ae0378.mp4) shows a volunteer wearing cap attached by cable to an intermediary device (an enlarged chip with a brain on it?) which is in turn attached to a screen. I believe some artistic licence has been taken with regard to the brain on the chip..

Caption: Researchers propose an adaptive neuromorphic decoder supporting brain-machine co-evolution. Credit: The University of Hong Kong

A March 25, 2025 University of Hong Kong (HKU) press release (also on EurekAlert but published on March 26, 2025), which originated the news item, explains more about memristors, BCIs, and co-evolution,

Professor Ngai Wong and Dr Zhengwu Liu from the Department of Electrical and Electronic Engineering at the Faculty of Engineering at the University of Hong Kong (HKU), in collaboration with research teams at Tsinghua University and Tianjin University, have conducted groundbreaking research on memristor-based brain-computer interfaces (BCIs). Published in Nature Electronics, this research presents an innovative approach for implementing energy-efficient adaptive neuromorphic decoders in BCIs that can effectively co-evolve with changing brain signals.

A brain-computer interface (BCI) is a computer-based system that creates a direct communication pathway between the brain and external devices, such as computers, allowing individuals to control these devices or applications purely through brain activity, bypassing the need for traditional muscle movements or the nervous system. This technology holds immense potential across a wide range of fields, from assistive technologies to neurological rehabilitation. However, traditional BCIs still face challenges.

“The brain is a complex dynamic system with signals that constantly evolve and fluctuate. This poses significant challenges for BCIs to maintain stable performance over time,” said Professor Wong and Dr Liu. “Additionally, as brain-machine links grow in complexity, traditional computing architectures struggle with real-time processing demands.”

The collaborative research addressed these challenges by developing a 128K-cell memristor chip that serves as an adaptive brain signal decoder. The team introduced a hardware-efficient one-step memristor decoding strategy that significantly reduces computational complexity while maintaining high accuracy. Dr Liu, a Research Assistant Professor in the Department of Electrical and Electronic Engineering at HKU, contributed as a co-first author to this groundbreaking work.

In real-world testing, the system demonstrated impressive capabilities in a four-degree-of-freedom drone flight control task, achieving 85.17% decoding accuracy—equivalent to software-based methods—while consuming 1,643 times less energy and offering 216 times higher normalised speed than conventional CPU-based systems.

Most significantly, the researchers developed an interactive update framework that enables the memristor decoder and brain signals to adapt to each other naturally. This co-evolution, demonstrated in experiments involving ten participants over six-hour sessions, resulted in approximately 20% higher accuracy compared to systems without co-evolution capability.

“Our work on optimising the computational models and error mitigation techniques was crucial to ensure that the theoretical advantages of memristor technology could be realised in practical BCI applications,” explained Dr Liu. “The one-step decoding approach we developed together significantly reduces both computational complexity and hardware costs, making the technology more accessible for a wide range of practical scenarios.”

Professor Wong further emphasised, “More importantly, our interactive updating framework enables co-evolution between the memristor decoder and brain signals, addressing the long-term stability issues faced by traditional BCIs. This co-evolution mechanism allows the system to adapt to natural changes in brain signals over time, greatly enhancing decoding stability and accuracy during prolonged use.”

Building on the success of this research, the team is now expanding their work through a new collaboration with HKU Li Ka Shing Faculty of Medicine and Queen Mary Hospital to develop a multimodal large language model for epilepsy data analysis.

“This new collaboration aims to extend our work on brain signal processing to the critical area of epilepsy diagnosis and treatment,” said Professor Wong and Dr Liu. “By combining our expertise in advanced algorithms and neuromorphic computing with clinical data and expertise, we hope to develop more accurate and efficient models to assist epilepsy patients.”

The research represents a significant step forward in human-centred hybrid intelligence, which combines biological brains with neuromorphic computing systems, opening new possibilities for medical applications, rehabilitation technologies, and human-machine interaction.

The project received support from the RGC Theme-based Research Scheme (TRS) project T45-701/22-R, the STI 2030-Major Projects, the National Natural Science Foundation of China, and the XPLORER Prize.

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

A memristor-based adaptive neuromorphic decoder for brain–computer interfaces by Zhengwu Liu, Jie Mei, Jianshi Tang, Minpeng Xu, Bin Gao, Kun Wang, Sanchuang Ding, Qi Liu, Qi Qin, Weize Chen, Yue Xi, Yijun Li, Peng Yao, Han Zhao, Ngai Wong, He Qian, Bo Hong, Tzyy-Ping Jung, Dong Ming & Huaqiang Wu. Nature Electronics volume 8, pages 362–372 (2025) DOI: https://doi.org/10.1038/s41928-025-01340-2 Published online: 17 February 2025 Issue Date: April 2025

This paper is behind a paywall.

Words from the press release like “… human-centred hybrid intelligence, which combines biological brains with neuromorphic computing systems …” put me in mind of cyborgs.