White striping degree assessment using computer vision system and consumer acceptance test

Talita Kato; Saulo Martiello Mastelini; Gabriel Fillipe Centini Campos; Ana Paula Ayub da Costa Barbon; Sandra Helena Prudencio; Massami Shimokomaki; Adriana Lourenço Soares; Sylvio Barbon Jr

doi:10.5713/ajas.18.0504

White striping degree assessment using computer vision system and consumer acceptance test

Asian-Australas J Anim Sci. 2019 Jul;32(7):1015-1026. doi: 10.5713/ajas.18.0504. Epub 2018 Nov 28.

Authors

Talita Kato¹, Saulo Martiello Mastelini², Gabriel Fillipe Centini Campos², Ana Paula Ayub da Costa Barbon³, Sandra Helena Prudencio¹, Massami Shimokomaki³, Adriana Lourenço Soares¹, Sylvio Barbon Jr²

Affiliations

¹ Department of Food Science and Technology, State University of Londrina (UEL), Campus Universitário, Londrina PR 86057-970, Brazil.
² Department of Computer Science, State University of Londrina (UEL), Campus Universitário, Londrina PR 86057-970, Brazil.
³ Department of Animal Science, State University of Londrina (UEL), Campus Universitário, Londrina PR 86057-970, Brazil.

Abstract

Objective: The objective of this study was to evaluate three different degrees of white striping (WS) addressing their automatic assessment and customer acceptance. The WS classification was performed based on a computer vision system (CVS), exploring different machine learning (ML) algorithms and the most important image features. Moreover, it was verified by consumer acceptance and purchase intent.

Methods: The samples for image analysis were classified by trained specialists, according to severity degrees regarding visual and firmness aspects. Samples were obtained with a digital camera, and 25 features were extracted from these images. ML algorithms were applied aiming to induce a model capable of classifying the samples into three severity degrees. In addition, two sensory analyses were performed: 75 samples properly grilled were used for the first sensory test, and 9 photos for the second. All tests were performed using a 10-cm hybrid hedonic scale (acceptance test) and a 5-point scale (purchase intention).

Results: The information gain metric ranked 13 attributes. However, just one type of image feature was not enough to describe the phenomenon. The classification models support vector machine, fuzzy-W, and random forest showed the best results with similar general accuracy (86.4%). The worst performance was obtained by multilayer perceptron (70.9%) with the high error rate in normal (NORM) sample predictions. The sensory analysis of acceptance verified that WS myopathy negatively affects the texture of the broiler breast fillets when grilled and the appearance attribute of the raw samples, which influenced the purchase intention scores of raw samples.

Conclusion: The proposed system has proved to be adequate (fast and accurate) for the classification of WS samples. The sensory analysis of acceptance showed that WS myopathy negatively affects the tenderness of the broiler breast fillets when grilled, while the appearance attribute of the raw samples eventually influenced purchase intentions.

Keywords: Appearance; Broiler Breast Fillet; Classification; Digital Image; Sensory Analysis.