Image Segmentation Based Determination of Elastane Core Yarn Diameter

Hladnik, A.; Pavko-Čuden, A.; Farajikhah, S.

doi:10.5604/12303666.1191424

Artykuł - szczegóły

Tytuł artykułu

Image Segmentation Based Determination of Elastane Core Yarn Diameter

Autorzy

Hladnik A. , Pavko-Čuden A. , Farajikhah S.

Treść / Zawartość

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Identyfikatory

DOI

10.5604/12303666.1191424

Warianty tytułu

Określenie średnic elastomerowych przędz rdzeniowych poprzez segmentacyjną analizę obrazu

Języki publikacji

Abstrakty

Yarn diameter is one of the key knitted fabric parameters, whose accurate determination, however, continues to be a difficult task. The goal of the study presented was to calculate the diameter of dry and wet relaxed yarns with and without incorporated elastane using imageprocessing and -analysis tools implemented in MATLAB. Compared to the images of wet relaxed samples, a much more sophisticated segmentation approach had to be implemented for dry relaxed yarn images due to their weaker yarn-background contrast. The values calculated were compared with those obtained with the conventional yarn thickness determination method developed by Sadikov. Linear correlation between the two techniques was found to be substantial – coefficients of determination for the yarn diameters of the wet and dry relaxed samples were 0.87 and 0.72, respectively. Unlike Sadikov’s method, our newly developed technique calculates yarn core diameter without hairiness.

Średnica przędz jest jednym z podstawowych parametrów dzianin, którego dokładna ocena jest jednak bardzo trudna. Celem przedstawionych badań było obliczenie średnicy suchych i mokrych przędz relaksowanych zawierających i niezawierających włókna elastomerowe. Zastosowano analizę obrazów i narzędzia programu MATLAB. W porównaniu do przędz wilgotnych znacznie trudniejsze było określenie średnic relaksowanych przędz suchych ze względu na znacznie słabszy kontrast w stosunku do tła. Wartości obliczone były porównywane z wartościami uzyskanymi za pomocą konwencjonalnych metod określenia grubości przędz opracowanymi przez Sadikova. Stwierdzono, że korelacje liniowe pomiędzy obydwoma technikami pomiarowymi były satysfakcjonujące. Uzyskano współczynniki korelacji 0.87 dla przędz mokrych i 0.72 dla przędz suchych. W przeciwieństwie do metody Sadikova nasza nowoopracowana technika pozwala na obliczenie średnicy rdzenia przędzy bez włochatości.

Słowa kluczowe

elastane core yarn image analysis image segmentation yarn diameter

rdzeń przędzy analiza obrazu segmentacja obrazu średnica przędzy

Wydawca

Sieć Badawcza Łukasiewicz - Łódzki Instytut Technologiczny

Czasopismo

Fibres & Textiles in Eastern Europe

Rocznik

2016

Tom

Vol. 24, no. 2 (116)

Strony

29--36

Opis fizyczny

Bibliogr. 28 poz., rys., tab.

Twórcy

autor

Hladnik A.

ales.hladnik@ntf.uni-lj.si

Department of Textiles, Graphic Arts and Design, Faculty of Natural Science and Engineering, University of Ljubljana, Ljubljana, Slovenia

autor

Pavko-Čuden A.

alenka.cuden@ntf.uni-lj.si

Department of Textiles, Graphic Arts and Design, Faculty of Natural Science and Engineering, University of Ljubljana, Ljubljana, Slovenia

autor

Farajikhah S.

farajikhah@aut.ac.ir

Department of Textile Engineering, Amirkabir University of Technology, Tehran, Iran
ARC Centre of Excellence in Electromaterials Science (ACES), University of Wollongong Australia, Wollongong NSW, Australia

Bibliografia

1. Grosberg P. Shape and structure in textiles. Journal of the Textile Institute 1966; 57: T383–T394.
2. Skenderi Z, Perić P, Orešković V. Influence of the tensile force on the change of cotton yarn diameter. Tekstil 1991; 11: 515–521.
3. Barella A, Manich AM. Revista de la Industria Textil 1981; 38: 37–46.
4. Mahmoudi MR, Oxenham W. A new electro-mechanical method for measuring yarn thickness. Autex Research Journal 2002; 1: 28–37.
5. Kobljakov A (ed). Laboratory practice in the study of textile materials. Moscow: Mir Publishers, 1989.
6. Gonzalez RC, Woods RE, Eddins SL. Image Segmentation. In: Digital Image Processing using Matlab. Upper Saddle River, NJ: Prentice Hall, 2004.
7. Fisher R, Perkins S, Walker A, Wolfart E. Thresholding. In: Hypermedia Image Processing Reference. 2003-2013. Web: http://homepages.inf.ed.ac.uk/rbf/HIPR2/hipr_top.htm. Accessed on 15. 3. 2014.
8. Fletcher HM, Roberts SH. The geometry of plain and rib knit cotton fabrics and its relation to shrinkage in laundering. Textile Research Journal 1952; 22: 84–88.
9. Fletcher HM, Roberts SH. Elastic properties of plain and double knit cotton fabrics. Textile Research Journal 1965; 35: 497–503.
10. Sirang Y, Dinfon G, Begery HM. A study of hairiness and diameter of open-end yarn processed through single- and double-cylinder carding machines and its comparison with ring yarn. Textile Research Journal 1982; 52: 274–279.
11. Cybulska M. Assessing yarn structure with image analysis methods. Textile Research Journal 1999; 69: 369–373.
12. Basu A, Doraiswamy I, Gotipamul RL. Measurement of yarn diameter and twist by image analysis. Journal of the Textile Institute 2003; 94, 1–2: 37–48.
13. Kilic M, Okur A. Relationships between Yarn Diameter / Diameter Variation and Strength. Fibres & Textiles in Eastern Europe 2006; 14, 5: 84–87.
14. Zhang X, Gao W, Liu J. Automatic Recognition of Yarn Count in Fabric Based on Digital Image Processing. In: Image and Signal Processing conference 2008 - CISP ‚08. Sania, Haynan, China, 27-30 May 2008, Vol 3, p. 100-103. DOI: 10.1109/CISP.2008.435.
15. Jaouadi M, Msehli S, Sakli F. Contribution to measurement of real yarn diameter. Journal of the Textile Institute 2009; 100, 2: 158–164.
16. Rameshkumar C, Regasamy RS, Anbumani N. Studies on polyester/waste silk core-spun yarns and fabrics. Journal of Industrial Textiles 2009; 38: 191–203.
17. Carvalho V, Vasconcelos RM, Soares FM, Belsley M. Yarn diameter and linear mass correlation. Journal of Nondestructive Evaluation 2009; 28: 49–54.
18. Caravalho V, Cardoso P, Belsley M, Vasconcelos RM, Soares FO. Yarn Irregularity Parameterisation Using Optical Sensors. Fibres & Textiles in Eastern Europe 2009, 17, 1: 26–32.
19. Unal PG, Arikan C, Ozdil N, Taskin C. The effect of fibre properties on the characteristics of spliced yarns: Part II: Prediction of retained spliced diameter. Textile Research Journal 2010; 80: 1751–1758.
20. Behtaj S, Sadri S, Tavanai H. Objective yarn bulk measurement through image analysis. Journal of the Textile Institute 2011; 12: 1094–1100.
21. Majumdar A, Mukhopadhyay S, Yadav R, Mondal AK. Properties of ring-spun yarns made from cotton and regenerated bamboo fibres. Indian Journal of Fibre & Textile Research 2011; 36: 18–23.
22. Yuvaraj D, Nayar RC. A simple yarn hairiness measurement setup using image processing technique. Indian Journal of Fibre & Textile Research 2012; 37: 331–336.
23. Shady E, Qashqary K, Hassan M, Militky J. Image Processing Based Method Evaluating Fabric Structure Characteristics. Fibres & Textiles in Eastern Europe 2012; 20, 6A: 86–90.
24. Rukuižiene Ž, Kumpikaite E. Investigation of Initial Warp Tension and Weave Influence on Warp Yarn Diameter Projections. Fibres & Textiles in Eastern Europe 2013; 21, 5: 43–48.
25. Krupincova G, Drašarova J, Mertova I. Evaluation of yarn lateral deformation. AUTEX Research Journal 2013; 13, 1: 17–21.
26. Zhong P, Kang Z, Han, S, Hu R, Pang J, Zhang X and Huang F. Evaluation method for yarn diameter uneveness based on image sequence processing. Textile Research Journal 2015; 85: 369–379.
27. Pavko-Čuden A, Stanković Elesini U. Yarn diameter in elasticized knitted structures. Industria Textila 2013; 64, 6: 313–320.
28. Pavko-Čuden A. Parameters of compact single weft knitted structure. Part 3, Fabric thickness and Knapton constant. Tekstilec 2010; 54, 1/3: 5–15.

Uwagi

Opracowanie ze środków MNiSW w ramach umowy 812/P-DUN/2016 na działalność upowszechniającą naukę.

Typ dokumentu

Bibliografia

Identyfikator YADDA

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