The quad rotor vehicle is flying to validate research on elements of a futuristic control system that has immediate applications for unmanned aircraft systems and potentially to a future personal air vehicle. (NASA/Tom Tschida) › View Larger Image
When George Jetson was ready to head off to the office he hopped into his bubble-shaped aerocar and zoomed off to work.
Traffic was manageable without cumbersome signals. In addition, he didn't have to worry about parking because his personal air vehicle conveniently converted into a briefcase.
While the realities of the concepts from the 1960s cartoon have not yet come to pass, two Dryden researchers are working on technology that could one day make such a vehicle possible. Fitting them in your suitcase is still a way off.
Dryden cooperative education student Justin McCarthy, from left, and Dryden researchers Matt Redifer and Loyd Hook display the quad-rotor vehicle they are using for their research. (NASA/Tom Tschida) › View Larger Image By using an off-the-shelf, quad-rotor, remotely piloted aircraft with its own piloting system, Matt Redifer and Loyd Hook can do the math to develop algorithms needed for future control systems. They envision these systems to safely and reliably operate a personal air vehicle and make many of those solutions part of the standard hardware for easier certification.
For example, programming the vehicle to avoid accidents with other air traffic is a must. The duo said they also believe such a vehicle would need to have a number of autonomously controlled piloting functions to win certification from the Federal Aviation Administration for this futuristic transportation.
The technology designed to enhance safety and reliability for an eventual personal air vehicle also has broad applications for manned and unmanned aircraft. For example, aircraft required to fly near dense urban or residential areas for work such as delivering packages, law enforcement, or disaster preparation or response could benefit as the FAA continues to look at solutions to best integrate manned and unmanned systems in the National Airspace System. In addition, some uses could be out of this world. A future Mars flying vehicle could use the systems technologies Redifer and Hook are developing.
To begin their research, Redifer and Hook purchased the quad-rotor aircraft and augmented the autopilot system as part of a Dryden Center Innovation Fund grant. Eventually the system for the quad-rotor aircraft could incorporate global positioning satellite information, map and typographical information. For now, three cameras provide location information to navigate the aircraft.
The idea for the project came from a conversation that Hook had with Mark Skoog. Skoog, the NASA project manager for several automatic ground collision avoidance system, or GCAS, projects, thought that the system developed on an F-16 and flown on the Dryden Remotely Operated Integrated Drone, or DROID, could be modified to work with a personal air vehicle. The concept was to make it possible to fly the vehicle in an autonomous mode, like an aircraft, but make it as easy to drive as a car, Hook explained.
FAA certification requirements for analytical systems that learn and predict situations would be complicated. For that reason Hook and Redifer chose a multi-layered system approach, Hook said. A standard flight control system is the first layer with safety critical systems constituting a middle layer that also has a GCAS with the authority to tell the higher level, or "thinking" systems that it can't perform certain maneuvers. For example, "the GCAS would tell the computer it can't fly into the ground," Hook said.
Dryden researcher Loyd Hook flies the quad rotor research vehicle to validate research on elements of a futuristic control system that has immediate applications for unmanned aircraft systems and potentially to a future personal air vehicle. (NASA/Tom Tschida) › View Larger Image
Redifer is interested in the control challenges of the system. The quad-rotor vehicle can validate and verify that the new subsystems work and lay the foundation for the higher level analytical "thinking" for the system.
"Moving the GCAS algorithms to hardware will increase the reliability that will be essential for a future personal air vehicle," Redifer added.
Project goals include demonstration of the multi-level autonomous piloting system.
"We want to have all the systems you would need," Hook said, "and demonstrate the multi-layer approach that will apply to unmanned aerial systems in the short term and one day a personal air vehicle. Such a future vehicle also will have health monitoring systems to indicate if there are troubles prior to takeoff, its destination and where it will land if an emergency develops."
A personal air vehicle is still a futuristic concept. However, the technology to make way for that possibility while making current aircraft systems safer and more reliable is underway today.