From: 2025-11-21 09:15 to 13:00
Place: Lecture hall M:A, LTH building M, Ole Römers väg 1
Contact: bo [dot] bernhardsson [at] control [dot] lth [dot] se

Title: Real-Time Brain-Computer Interfaces​​
Speaker: Pex Tufvesson
Opponent: Associate Professor Laurent Bougrain, University of Lorraine
Committee: 
Professor Alexander Medvedev, Uppsala University
Associate Professor Oana Geman, Chalmers University of Technology
Associate Professor Foteini Simistira-Liwicki, Luleå Technical
Supervisor: Bo Bernhardsson, Automatic Control Lund University
Assistant supervisors: 
Mikael Johansson, Psykologiinstitutionen på LU
Johan Eker, Automatic Control Lund University
Where: Lecture hall M:A, LTH building M, Ole Römers väg 1
When: November 21^st, 09:15–13

Abstract: 
A brain-computer interface (BCI) is a real-time system that converts a user’s brain activity into commands, enabling control over applications such as moving a cursor on the screen. This conversion is made possible by machine learning techniques and other algorithms. 

Historically, BCI research has focused on the analysis of brain signals offline. However, increasing computational power and algorithmic sophistication now allow real-time interaction, enabling systems to interpret brain activity and translate it into commands instantaneously. This is critical for neuroprosthetic applications where even millisecond-level improvements can produce more natural movement. Even in more playful areas of use, such as brain-controlled computer games, response time is important for creating an experience that can engage the user: "It’s no fun if it lags". A key driver of these advances is machine learning. Unlike earlier BCIs that relied on fixed models, machine learning allows systems to adapt and continuously learn from user signals and behavior, fostering a more intuitive human-machine interface through ongoing feedback and mutual learning.

Despite these promising developments, significant challenges remain: real-time BCI systems demand high-performance hardware and software, require efficient wireless communication, robust processing capabilities, and adaptive algorithms. Furthermore, integrating these systems into real-world applications raises questions about usability and safety.

This thesis addresses some of these challenges, particularly in the context of reducing cognitive load, addressing latency uncertainties and developing a modular BCI research framework. This work presents new insights and pathways toward functional BCI systems. Through experimentation and novel system architecture, this research lays a foundation for the future of BCI technology.