纺织学报 ›› 2023, Vol. 44 ›› Issue (06): 225-231.doi: 10.13475/j.fzxb.20220304802
苑洁1,2, 翟淑娜2, 娄琳1,2,3(), 王其才4, 雷雨田5
YUAN Jie1,2, ZHAI Shu'na2, LOU Lin1,2,3(), WANG Qicai4, LEI Yutian5
摘要:
为实现瞬态捕捉织物刺激下的大脑反应,明确织物舒适度大脑感知机制,从织物舒适度感知过程以及事件相关电位技术的表征原理2个方面阐述事件相关电位技术在织物舒适度表征上的技术优势,并对国内外相关研究进展进行了综述,总结了与织物舒适度相关的诱发电位成分,得到与织物触觉感知存在相关的诱发电位主要为中期和晚期正成分以及刺激450 ms处出现的负电位成分。晚期正成分主要与织物表面粗糙度和接触压力刺激感知相关;中期正成分与刺痒感、接触冷暖感和黏体感相关;刺激450 ms处出现的负电位成分与大脑感知的抗干扰能力相关。与织物视觉舒适度感知相关的诱发电位主要为正电位成分、早期和中期负成分。强烈的织物视觉刺激会引起早期正成分、中期正成分和早期负成分振幅增大,但颜色组合数目增多会导致中期正成分和中期负成分的潜伏期延长,识别速度变慢。晚期正成分才是视觉舒适感知的最终决策成分。
中图分类号:
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