Flying High

No more intimidating banks of switches and dials. Instead, it’s a few small flight indicators and a computer screen. The airplane is more powerful, but the design for humans is quite simple.

This sort of cockpit will have a computer controlling the action based on inputs from sensors giving flight conditions. The pilot will monitor the plane’s progress and then be ready to jump in if action is necessary – especially if an emergency occurs.

he design requires strong interdisciplinary studies. The people working most closely with this project are not aerospace researchers, but cognitive scientists. Extensive work takes place under Carleton’s Herdman Centre for Applied Cognitive Research, run by psychology professor Chris Herdman.

That’s not all of Carleton’s simulator work, either. The Carleton University Simulator Project, for example, is a simulated cockpit that can be rolled in any direction – just like an airplane – to make sure pilots react safely in controlled conditions. It was built by Carleton students entirely on internal funding, with 10 years of patient work approaching completion in the next little while.

There’s more good stuff to come, too. Carleton’s Rob Langlois received a $1.25 million grant from the Canada Foundation for Innovation to create a wind tunnel that can simulate complex conditions such as helicopters landing on ships. The first phase of this structure is expected to be ready by early 2015.

“We need sophisticated simulator platforms to produce scenarios for proper pilot training,” says Metin Yaras, Carleton’s chair of mechanical and aerospace engineering.
Interdisciplinary thinking is a staple of aerospace research and development, and it’s no different at Carleton. For example, biologist Jeff Dawson’s insect flight group looks at how locusts and other creatures fly to better inform airplane designs.

Or imagine trying to reduce the amount of space junk circling Earth by building a tiny satellite to get rid of this debris littering space in Earth’s orbit. Carleton has a space technology lab where fourth-year students are designing and testing a small “cubesat” that would use compressed air to throw a net around pieces of space junk, effectively corralling them.

Unmanned aerial vehicles, or UAVs, also require thinking outside of the box, such as how to transmit as much data as possible while keeping the onboard computer as lightweight as possible. This is needed to say, assist mining companies find sources of rich resources. Carleton is now developing a centre to get this accomplished.

Other interesting aerospace projects at Carleton include a rover that could be used for lunar or Mars exploration, self-replicating 3-D printing machines that could build structures on the moon, and gas turbine materials science research to figure out how to reduce the number of blades in an airplane engine, which will make the craft lighter and ultimately use less fuel.

Friday, November 21, 2014 in Research
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