University
Mind and Machine: Flying Drones with Your Brain
By Aaron Hilf
A state-of-the-art competition at USF will bridge the gap between mind and machine. The 2019 USF Brain-Drone Race, scheduled Feb. 9 at the Yuengling Center, will feature teams from around the world as they race drones using brain power.
USF assistant professor Marvin Andujar, department of computer science and engineering in the College of Engineering, is organizing the event. He led the University of 51在线 group that first started the competition in 2016. Andujar says this year鈥檚 event will be the world鈥檚 first international competition of brain-drone racers, featuring teams from the United Kingdom, Japan, and Brazil, as well as several teams from USF and from across the United States.
鈥淚t鈥檚 been amazing to see how much interest there鈥檚 been in the field since our first Brain-Drone Race,鈥 Andujar says. 鈥淔or us, the racing is a way to introduce young people, students and others to this technology and hopefully spur more research into neuro-technologies.鈥
While the idea of piloting a drone with your mind may sound like science-fiction, it鈥檚 really a combination of neuroscience and computer science. The underlying technology is part of a much larger field of study into brain-computer interfaces (BCI) 鈥 a term first coined in the 1970s. BCIs are devices that create a pathway between the brain and an external device, such as a drone, computer or prosthetic limb.
BCI technology reads the brain鈥檚 electrical signals to function. Every time we think about something or move a muscle, the neurons in our brain send electrical signals to one another. Through technological advances and the development of wearable electroencephalography (EEG) systems, scientists are able to detect and interpret these signals. By doing so, they can then translate the electrical signals into commands for external devices.
When applied to brain-drone racing, researchers link a specific brainwave pattern to forward movement in the drone. So, when the pilot, who is outfitted with an EEG headband, produces that pattern, the drone is signaled to move.
鈥淲hen you imagine a movement, your brain produces the same electrical activity as if you were performing the movement with your muscles,鈥 Andujar says. 鈥淔or drone-racing, we have our pilots imagine they鈥檙e pushing an object forward. Then, we capture that signal, classify it and send the information to the drone, which has already been programmed to move when it receives that data.鈥
While brain-drone racing represents a piece of the innovative potential of BCIs, the technology is also being utilized in life-changing ways. BCIs have been in development for medical applications for decades. They can be used by patients to control prosthetic limbs and have even helped return partial sight to vision-impaired individuals. In people with Lou Gehrig's disease, a neurodegenerative disease that destroys nerve cells and causes disability, the technology is also being refined to provide communication and mobility assistance.
For Andujar and his research team, these medical advances act as motivation, pushing them to find new and unique ways of utilizing the technology within the medical field and beyond.
鈥淔rom a computer science perspective, there is really an endless number of ways you can apply these systems,鈥 he says. 鈥淵ou can use BCIs in a smart home to open and close doors with your brain. Or, have the environment adapt to you based on your brain activity. It鈥檚 pretty incredible to think about what鈥檚 possible when you combine biology and neuroscience with technology.鈥
The 2019 USF Brain-Drone Race at the Yuengling Center is free and open to public. For more information and updates visit braindronerace.com.
Learn more about Brain-powered drones and view video of the drones in action.