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This prototype UV lamp, designed by a team including undergraduate student Bipasha Goyal (Year 3 EngSci), is part of a smart robotic assembly that is designed to sterilize surfaces in hospitals, schools and even residential buildings. (Image: Junho (Dave) Jeong)

Bipasha Goyal (Year 3 EngSci) is creating what she hopes will be the newest line of defence against the global COVID-19 pandemic: a smart UV lamp.

“Hospitals already use a similar method called ultraviolet germicidal irradiation (UVGI) to sterilize operating theatres and other spaces,” says Goyal. “The challenge is that these systems are very expensive, and it’s hard to ensure a sufficient UV dosage has been applied to a surface.”

Goyal is part of Team LumineSence, which also includes her supervisor, Professor Joyce Poon (ECE), and several other U of T Engineering students. Together, they are designing a new UVGI system that would be more effective and less costly than currently available machines.

One of their insights is to focus on both the light emission and light sensing aspects of the device.

“Much of the innovation in existing systems has been the autonomous mobile robot supporting the lamps,” says Goyal. “But then it comes to the lamps themselves, the emission pattern is usually not shaped or purposefully directed. The lamps have not been integrated with any sensors to monitor their efficacy.”

Team LumineSense is creating an integrated system that would do both of these things, and could be mounted on mobile racks, or on static surfaces such as ceilings and table tops. The team and its flagship product sprung from CDL Recovery, a program from U of T’s Creative Destruction Lab that focuses on smart solutions to accelerate the world’s recovery from the COVID-19 crisis.

Using smart sensors and carefully designed algorithms, the device would adapt its output to provide optimal UV light exposure to sterilize surfaces. The sensors would also enable it to automatically shut down if human presence is detected, minimizing the risk of exposure to harmful UV radiation.

Currently, Goyal’s contribution to the project is being supported by a Mitacs Research Training Award (RTA), which is matched 1:1 by U of T Engineering. She is among 87 U of T Engineering undergraduate and graduate students whose research projects have earned Mitacs RTAs, with topics ranging from data science and artificial intelligence to advanced materials and manufacturing.

Many of the projects also involve partner organizations. In Goyal’s case, it’s the Max Planck Institute (MPI) of Microstructure Physics in Germany, where Poon serves as Director. Early in the project, MPI researchers brought new ideas, advice and insight to LumineSense.

“Communicating with a large team across multiple time zones was a difficult task,” says Goyal. “It taught me the importance of being in regular communication and seamlessly distributing roles and responsibilities.”

“As engineers, we contribute to solutions to better the world,” says Poon. “I am very proud of Bipasha and all of the students and postdocs who have come together for this team project.”

In addition to enhancing her technical understanding of light sensing and autonomous robotics, Goyal says the project is also teaching her about the challenges of translating research from the lab to the marketplace.

“The overall features and use cases of the design required us to identify potential stakeholders, which include schools, research labs and even residential buildings, and create an adaptable modular design to better suit their needs” she says.

“COVID-19 affected everyone professionally and personally. I consider myself very lucky to have found this opportunity to be involved in such a meaningful project.”

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