Experimental Study of Clothing Tactile Comfort Based on Electro-neurophysiology

Wang, Y.; Wang, Y.; Zhao, M. M.; Yu, M.; Li, J.

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Tytuł artykułu

Experimental Study of Clothing Tactile Comfort Based on Electro-neurophysiology

Autorzy

Wang Y. , Wang Y. , Zhao M. M. , Yu M. , Li J.

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Warianty tytułu

Eksperymentalne badanie komfortu dotykowego odzieży na podstawie elektroneuro fizjologii

Języki publikacji

Abstrakty

Electromyography (EMG) and electroencephalography (EEG) methods were used to evaluate the reaction of human skin to tactile stimuli evoked by textiles. The peak value of the EMG and energy percentage of the weave of the EEG when the subjects came into contact with 9 kinds of fabrics were selected for tests and next clothing was made on their basis. They were utilized as two important evaluating indexes. Statistical analysis was carried out to verify the correlation between the data obtained from objective measurements and the subjective measurements. The results showed that when the subjects came into contact with thicker, heavier and stiffer fabrics, the peak values of the myoelectric potential induced were higher. When clothing with a higher mass density was worn, energy percentages of the weave at both the left and right occipitalia were higher.

Dla oceny reakcji ludzkiej skóry na dotykowe stymulacje materiałami włóknistymi stosowano elektromiografię (EMG) i elektroencefalografie (EEG). Wartość szczytowa przebiegu EMG oraz procent energii fali EEG w czasie kiedy badane osoby znajdowały się w kontakcie z 9 rodzajami materiałów włókienniczych posłużyła do ich selekcji dla stosowanych testów. Na tej podstawie wykonano odzież przeznaczona dla osób testowanych. Przeprowadzono analizę statystyczna dla zweryfikowania korelacji pomiędzy wynikami uzyskanymi z obiektywnych pomiarów oraz subiektywnych testów. Wyniki wykazały, że kiedy osoby badane znajdowały się w kontakcie z grubszymi i cięższymi i sztywniejszymi materiałami to wartość piku EMG była wyższa. Kiedy ubranie wykonane było z udziałem przędz o wyższej masie liniowej procent energii fali lewej i prawej połówki potylicy był wyższy.

Słowa kluczowe

tactile clothing electromyography electroencephalography

dotykowy comfort odzieży elektromiografia elektroencefalografia

Wydawca

Sieć Badawcza Łukasiewicz - Łódzki Instytut Technologiczny

Czasopismo

Fibres & Textiles in Eastern Europe

Rocznik

2014

Tom

Vol. 22, no. 4 (106)

Strony

102--106

Opis fizyczny

Bibliogr. 24 poz., rys., tab.

Twórcy

autor

Wang Y.

P. R. China, Shanghai, Dong Hua University, Fashion Institute, Protective Clothing Research Center
P. R. China, Shanghai, Dong Hua University, Ministry of Education, Key Laboratory of Clothing, Design & Technology

autor

Wang Y.

P. R. China, Shanghai, Dong Hua University, Fashion Institute, Protective Clothing Research Center
P. R. China, Shanghai, Dong Hua University, Ministry of Education, Key Laboratory of Clothing, Design & Technology

autor

Zhao M. M.

P. R. China, Shanghai, Shanghai University of Engineering Science, College of Fashion
P. R. China, Shanghai, Dong Hua University, Fashion Institute, Protective Clothing Research Center

autor

Yu M.

P. R. China, Shanghai, Dong Hua University, Fashion Institute, Protective Clothing Research Center

autor

Li J.

lijun@dhu.edu.cn

P. R. China, Shanghai, Dong Hua University, Ministry of Education, Key Laboratory of Clothing, Design & Technology

Bibliografia

1. Wong ASW, Li Y, Yeung KW. Statistical simulation of psychological perception of clothing sensory comfort. Journal of the Textile Institute 2002; 93, 1: 108-119.
2. Sular, V, Okur, A. Sensory evaluation methods for tactile properties of fabrics. Journal of Sensory Study 2007; 22: 1-16.
3. Ciesielska-Wrobel IL, Langenhove LV. The hand of textiles-definitions, achievements, perspectives-a review. Textile Research Journal 2012; 82, 14: 1457- 1468.
4. Hatch K, Markee N, Maibach H. Skin response to fabric-A review of studies and assessment methods. Textile Research Journal 1992; 10: 54-63.
5. Darden MA, Schwartz CJ. Investigation of skin tribology and its effects on the tactile attributes of polymer fabrics. Wear 2009; 267: 1289-1294.
6. Alimaa D, Matsuo T, Nakajima M, Takahashi M. Sensory measurements of the main mechanical parameters of knitted fabrics. Textile Research Journal 2000; 70, 11: 985-990.
7. Pan N, Chen KC, Zhao SJ, Yang SR. A new approach to the objective evaluation of fabric handle from mechanical properties part I: objective measure for total handle. Textile Research Journal 1988; 58, 8: 438-444.
8. Chollakup R. Tactile sensory analysis applied to silk/cotton knitted fabrics. International Journal of Clothing Science and Technology 2004; 16: 132-140.
9. Bouchard C, Lim D, Aoussat A. Development of a Kansei engineering system for industrial design: identification of input data for KES. In: 6th ADC PROGRAM, 2003.
10. Day S. Important Factors in Surface EMG Measurement, Bortech Biomedical Ltd, 225, 604-1st ST SW, Calgary, AB, T2P 1M7, 2002.
11. Teplan M. Fundamentals of EEG measurement. Measurement Science Review 2002; 2: 1-11.
12. Shizukai A, Seki T, Kato R, Morishita S, Nakamura T, Yokoi H. Walking assistance by functional clothes with highly elastic fabric. In: 2011 IEEE/ASME International Conference on Advanced Intelligent Mechatronics (AIM2011), Budapest, Hungary, July 3-7, 2011: 673-676.
13. Naoyasu H, Akihiro YAG. Measurement method of electromyogram and event related potential in voluntary touching on fabric. The Japanese journal of ergonomics 1996; 32, 6: 327-332.
14. Zimniewska M, Huber J, Krucińska I, Torlinska T, Kozlowski R. The influence of clothes made from natural and synthetic fibres on the activity of the motor units in selected muscles in the forearm- Preliminary studies. Fibres & Textiles in Eastern Europe 2002; 39, 4: 55-59.
15. Park H, Branson D, Kamenidis P, Warren A, Jacobson B, Peksoz S, Petrova A. Exploration of simultaneous mobility assessment for protective clothing. In: 5th ECPC and NOKOBETEF 10, May 2012, Valencia, Spain, p. 29.
16. Choi HY, Lee JS. The physiological response on wear comfort of polyethylene terephthalate irradiated by ultraviolet. Fibers and Polymers 2006; 17, 4: 446-449.
17. Yuki M, Akiko S. Clothing Comfort of the Material (RAFUMA-Mixed Cotton) of Pajamas from the Point of Biological Reactions. Journal of Home Economics of Japan 2005; 56, 4: 233-240.
18. Hiroko S, Kazuya S, Yuniko T, Toshimitsu M. Evaluation of clothing comfort by using emotion spectrum analysis method of electro-encephalogram. Utsunomiya University, Bulletin of the Faculty of Education 1999; 49: 61-70.
19. Herr V, Takashi M, Masahiro N. A Novel Assessment Method of Emotions with Clothes based on Fractal Analyses of EEG. In: IEICE technical report, ME and bio cybernetics 2008; 108: 47-52.
20. Binder MD, Hirokawa N, Windhorst U. (ed). Encyclopedia of Neuroscience. Springer-Verlag GmbH Berlin Heidelberg, 2009. Available at http://www. springer.com/biomed/neuroscience/ book/978-3-540-23735-8.
21. Musha T, Terasaki Y, Haque HA, Ivanitsky GA. Feature extraction from EEGs associated with emotions. Artificial Life and Robotics 1997; 1: 15-19.
22. Hinrichs H, Machleidt W. Basic emotions reflected in EEG coherence. International Journal of Psychophysiology 1992; 13: 225-232.
23. Liu Y, Chen Q. EEG and the Application of EEG in the Sensation Evaluation (in Chinese). Journal of Soochow University Engineering Science Edition 2004;
24, 2: 55-56. 24. Ashdown SP, Delong M. Perception testing of apparel ease variation. Applied Ergonomics 1995; 26, 1: 47-54.

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Bibliografia

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