Wearable hybrid brain-computer interface for daily life application

Nowadays, the event-related potential (ERP)-based spelling device, often referred to as P300-Speller, is the most popular Brain-computer interface (BCI) which can provide a new communication path between patients suffered amyotrophic lateral sclerosis (ALS) with the outside world. At present, there are various P300 paradigms for P300-Speller, but no matter the accuracy or the speed cannot be supplied in our daily life. In this paper, an experiment based the two paradigms was proposed and operated to figure out which paradigm is much better between single display (SD) paradigm and region-based (RB) paradigm. 5 naive subjects participated the experiment and concluded that SD-Speller is superior to RB-Speller when the ISI was set 150ms. This result provides relevant theoretical basis for designing better graphical interface based on BCI.

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A dual-arm mobile robot system performing assistive tasks operated via P300-based brain computer interface

Industrial Robot the international journal of robotics research and application ◽

10.1108/ir-07-2020-0137 ◽

2020 ◽

Vol ahead-of-print (ahead-of-print) ◽

Author(s):

Giuseppe Gillini ◽

Paolo Di Lillo ◽

Filippo Arrichiello ◽

Daniele Di Vito ◽

Alessandro Marino ◽

...

Keyword(s):

Daily Life ◽

Brain Computer Interface ◽

Life Quality ◽

Inverse Kinematic ◽

Robotic System ◽

Assistive Robotics ◽

Computer Interface ◽

Hierarchical Architecture ◽

Content Type ◽

High Level

Purpose In the past decade, more than 700 million people are affected by some kind of disability or handicap. In this context, the research interest in assistive robotics is growing up. For people with mobility impairments, daily life operations, as dressing or feeding, require the assistance of dedicated people; thus, the use of devices providing independent mobility can have a large impact on improving their life quality. The purpose of this paper is to present the development of a robotic system aimed at assisting people with this kind of severe motion disabilities by providing a certain level of autonomy. Design/methodology/approach The system is based on a hierarchical architecture where, at the top level, the user generates simple and high-level commands by resorting to a graphical user interface operated via a P300-based brain computer interface. These commands are ultimately converted into joint and Cartesian space tasks for the robotic system that are then handled by the robot motion control algorithm resorting to a set-based task priority inverse kinematic strategy. The overall architecture is realized by integrating control and perception software modules developed in the robots and systems environment with the BCI2000 framework, used to operate the brain–computer interfaces (BCI) device. Findings The effectiveness of the proposed architecture is validated through experiments where a user generates commands, via an Emotiv Epoc+ BCI, to perform assistive tasks that are executed by a Kinova MOVO robot, i.e. an omnidirectional mobile robotic platform equipped with two lightweight seven degrees of freedoms manipulators. Originality/value The P300 paradigm has been successfully integrated with a control architecture that allows us to command a complex robotic system to perform daily life operations. The user defines high-level commands via the BCI, letting all the low-level tasks, for example, safety-related tasks, to be handled by the system in a completely autonomous manner.

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