Interdisciplinary Program for Bioengineering, Seoul National University, Seoul, Republic of Korea.
DMC R&D Center, Samsung Electronics Co. Ltd., Suwon, Republic of Korea.
Clin Neurophysiol. 2014 Jul;125(7):1380-91. doi: 10.1016/j.clinph.2013.11.016. Epub 2013 Dec 1.
A high-frequency steady-state visual evoked potential (SSVEP) has been suggested for the reduction of eye fatigue for SSVEP-based brain-computer interfaces (BCIs). However, the poor performance of high-frequency SSVEP requires a novel stimulus of better performance even with low eye fatigue. As an alternative to the high-frequency SSVEP, we explore the SSVEP response to an amplitude-modulated stimulus (AM-SSVEP) to verify its availability for brain-computer interfaces (BCIs).
An amplitude-modulated stimulus was generated as the product of two sine waves at a carrier frequency (fc) and a modulating frequency (fm). The carrier frequency was higher than 40 Hz to reduce eye fatigue, and the modulating frequency ranged around the α-band (9-12 Hz) to utilize low-frequency harmonic information. Four targets were used in combinations of three different modulating frequencies and two different carrier frequencies in the offline experiment, and two additional targets were added with one additional modulating and one carrier frequency in online experiments.
In the AM-SSVEP spectra, seven harmonic components were identified at 2fc, 2fm, fc±fm, fc±3fm, and 2fc-4fm. Using an optimized combination of the harmonic frequencies, online experiments demonstrated that the accuracy of the AM-SSVEP was equivalent to that of the low-frequency SSVEP. Furthermore, subject evaluation indicated that an AM stimulus caused lower eye fatigue and less sensing of flickering than a low-frequency stimulus, in a manner similar to a high-frequency stimulus.
The actual stimulus frequencies of AM-SSVEPs are in the high-frequency band, resulting in reduced eye fatigue. Furthermore, AM-SSVEPs can utilize both fundamental stimulus frequencies and non-integer harmonic frequencies including low frequencies for SSVEP recognition. The feasibility of AM-SSVEP with high BCI performance and low eye fatigue was confirmed through offline and online experiments.
AM-SSVEPs combine the advantages of both low- and high-frequency SSVEPs--high power and low eye fatigue, respectively. AM-SSVEP-based BCI systems exploit these advantages, making them promising for application in practical BCI systems.
高频率稳态视觉诱发电位(SSVEP)已被提出用于减少基于 SSVEP 的脑机接口(BCI)的眼疲劳。然而,高频率 SSVEP 的性能较差,即使眼疲劳较低,也需要一种性能更好的新型刺激。作为高频 SSVEP 的替代方案,我们探索了对调幅刺激(AM-SSVEP)的 SSVEP 响应,以验证其在脑机接口(BCI)中的可用性。
调幅刺激是由载波频率(fc)和调制频率(fm)的两个正弦波的乘积产生的。载波频率高于 40 Hz 以减少眼疲劳,调制频率在 α 波段(9-12 Hz)附近变化,以利用低频谐波信息。离线实验中,使用四个目标组合了三种不同的调制频率和两种不同的载波频率,在线实验中,增加了一个调制频率和一个载波频率,总共增加了两个目标。
在 AM-SSVEP 谱中,在 2fc、2fm、fc±fm、fc±3fm 和 2fc-4fm 处识别出七个谐波分量。使用谐波频率的优化组合,在线实验表明 AM-SSVEP 的准确性与低频 SSVEP 相当。此外,通过主观评价表明,与低频刺激相比,AM 刺激引起的眼疲劳更低,闪烁感更小,与高频刺激类似。
AM-SSVEP 的实际刺激频率处于高频带,从而减少了眼疲劳。此外,AM-SSVEP 可以利用基本刺激频率和包括低频在内的非整数谐波频率进行 SSVEP 识别。通过离线和在线实验证实了具有高 BCI 性能和低眼疲劳的 AM-SSVEP 的可行性。
AM-SSVEP 结合了低频率和高频率 SSVEP 的优点-高功率和低眼疲劳,分别。基于 AM-SSVEP 的 BCI 系统利用了这些优势,使其在实际 BCI 系统中具有应用前景。
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