ARCHIVED - Wireless sensors for smart buildings

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February 09, 2009— Ottawa, Ontario

NRC has launched an ambitious multidisciplinary project to develop and link arrays of indoor environment sensors in order to help improve a building's environmental health, energy efficiency and maintenance, as well as the general comfort of its occupants.

Today, building sensors can be used to detect a wide variety of environmental conditions such as carbon dioxide, temperature, light levels, noise levels and occupancy rates. Such data could then be collated centrally where "some intelligence is applied" to decide whether it's necessary to change operational settings, says Dr. Guy Newsham, who leads the lighting group at the NRC Institute for Research in Construction (NRC-IRC) in Ottawa. "Signals would then be sent to actuators within the building systems to adjust an airflow rate, temperature or light level in ways that are better for office workers and management, and increase energy efficiency," he explains.

Under this three year project, led by the NRC Information and Communication Technologies (NRC-ICT) key sector, researchers from several NRC labs will integrate both existing and new sensing hardware, a wireless communication interface, and software-based analysis and feedback systems into several demonstration systems.

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The project has three main thrusts. One is to develop a network of indoor air quality sensors to measure pollutants, such as formaldehyde or toluene, for which no practical monitoring method now exists. "If the levels of a pollutant are too high, a sensor might tell a building system to increase the ventilation rate or automatically open a window," says Dr. Newsham. "Or you may retrofit a new kind of filter based on that information."

The second thrust will involve "mining" the data from existing sensors to improve decision-making processes. "Historical sensor data could tell you whether maintenance is needed now to avoid equipment breaking down later, which would significantly increase the cost of building maintenance," explains Ruth Rayman, the NRC-ICT key sector coordinator.

The third thrust, led by Dr. Newsham's group, will focus on the general environment within buildings. "This is about exploring what we can do if we know not only how many people are in the building, but also where and who they are," he says. Currently, a conventional occupancy sensor can control lighting by determining whether a room is occupied, and then automatically increasing or dimming the lights, or changing the position of window blinds. But the sensor can't tell how many people are in the room or who is there.

"But if a sensor — such as one located on an employee's security badge — knows a person's identity and preferences, it could say, 'Oh, its Guy. He prefers the office lights at half of normal output,'" suggests Dr. Newsham. "Or if it knows that both Guy and Ruth are here, it could set the lights at our average preferred level. And if I need to work in my neighbour's office, it could set the lights to my own rather than my neighbour's preferences." Valuable health monitoring, such as fall detection, could also be added to such a "smart badge."

The same approach could be used to adjust ventilation and temperature, he adds. "If a sensor knows there are two or more people in the room, it could instantly increase the ventilation rate or adjust the temperature to an appropriate level for this group."

In collaboration with Simon Fraser University, Dr. Newsham's team is currently setting up a demonstration network at NRC-IRC's existing indoor environment lab, which features a mock up office space with six cubicles. "The idea is to bring in potential clients from industry and ask them to help us explore directions that such technology could take," he says.

Enquiries: Media relations
National Research Council of Canada
613-991-1431
media@nrc-cnrc.gc.ca

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