Scientists have developed a brain-computer control interface for a lower limb exoskeleton by decoding specific signals from within the user’s brain. Using an electroencephalogram (EEG) cap, the system allows users to move forward, turn left and right, sit and stand simply by staring at one of five flickering light emitting diodes (LEDs).
Each of the five LEDs flickers at a different frequency and, when the user focuses their attention on a specific LED, this frequency is reflected within the EEG readout. The signal is identified and used to control the exoskeleton.
A key problem has been separating these precise brain signals from those associated with other brain activity, as well as the highly artificial signals generated by the exoskeleton.
Researchers working at Korea University, Korea, and TU Berlin, Germany have published their results August 18, 2015, in the Journal of Neural Engineering.
“Exoskeletons create lots of electrical ‘noise’” explains Klaus Muller, an author on the paper. “The EEG signal gets buried under all this noise — but our system is able to separate not only the EEG signal, but the frequency of the flickering LED within this signal.”
Although the paper reports tests on healthy individuals, the system has the potential to aid sick or disabled people.
“People with amyotrophic lateral sclerosis (ALS) [motor neuron disease], or high spinal cord injuries face difficulties communicating or using their limbs” continues Muller. “Decoding what they intend from their brain signals could offer means to communicate and walk again.”
The control system could serve as a technically simple and feasible add-on to other devices, with EEG caps and hardware now emerging on the consumer market.
It only took volunteers a few minutes to be trained in how to operate the system. Because of the flickering LEDs, participants were carefully screened for epilepsy prior to taking part in the research. The researchers are now working to reduce the ‘visual fatigue’ associated with longer-term users of such systems.
“We were driven to assist disabled people, and our study shows that this brain control interface can easily and intuitively control an exoskeleton system, despite the highly challenging artefacts from the exoskeleton itself,” concludes Muller.