With over 45 faculty members solving problems in advanced robotics, autonomous systems, human-robot interaction, and related fields, Waterloo is where the future of robotics is being developed.
Our mission is to make significant advancements in robotics, from fundamental research through design and development to commercial applications including robots that build cars, explore space, deliver coffee, defuse land mines, or perform surgery.
For more details, check out the Robotics @ Waterloo page.
What's the RoboHub?
The Waterloo RoboHub is the home of robotics at the University of Waterloo, bringing together all of the related technical, educational, research, and other services and experience into one central group.
Visit the About the RoboHub section of the website for more details on our team, fleet, facilities, and research themes.
Engineers from the University of Waterloo are harnessing artificial intelligence to help doctors better see and control a non-invasive cancer treatment and, in the process, save lives.
Their imaging system will allow for the safer and more effective use of high-intensity, focused ultrasound to destroy a wide range of cancerous, often deadly, tumours.
“We are addressing a huge challenge for focused ultrasound treatment,” explained project leader Moslem Sadeghi Goughari, a research associate in the university’s Department of Mechanical and Mechatronics Engineering. “Our imaging system can tell doctors exactly how much of a cancerous tissue is destroyed. And it’s the first AI-powered ultrasound technique developed for focused ultrasound treatment.”
A team of University of Waterloo researchers has created smart, advanced materials that will be the building blocks for a future generation of soft medical microrobots.
These tiny robots have the potential to conduct medical procedures, such as biopsy, and cell and tissue transport, in a minimally invasive fashion. They can move through confined and flooded environments, like the human body, and deliver delicate and light cargo, such as cells or tissues, to a target position.
The tiny soft robots are a maximum of one centimetre long and are bio-compatible and non-toxic. The robots are made of advanced hydrogel composites that include sustainable cellulose nanoparticles derived from plants.
This research, led by Hamed Shahsavan, a professor in the Department of Chemical Engineering, portrays a holistic approach to the design, synthesis, fabrication, and manipulation of microrobots. The hydrogel used in this work changes its shape when exposed to external chemical stimulation. The ability to orient cellulose nanoparticles at will enables researchers to program such shape-change, which is crucial for the fabrication of functional soft robots.
Millions of people and vehicles rely on bridge infrastructure to get from point A to point B every day. But the potential for catastrophic failure grows as bridges and other transportation infrastructure age.
According to the 2021 Infrastructure Report Card, there are over 617,000 bridges in the U.S., almost half being at least 50 years old. It is not only age that affects these bridges' reliability and structural integrity. Additional stresses from events such as hurricanes, earthquakes and heat waves are compromising structural durability and longevity too.
Dr. Chul Min Yeum, an assistant professor in the civil and engineering department at the University of Waterloo, leads a team of researchers using technologies like 5G and augmented reality to identify structural issues in bridges, buildings and other infrastructure before disaster strikes.