Non-metric multidimensional scaling (MDS) in the analysis of consumer behavior in the purchase of dairy products

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Paulina Fernanda Bolaños Logroño
Fernando Ricardo Márquez Sañay
Carmen Elena Mantilla Cabrera

Abstract

Introduction: The study of consumer behavior has made it possible to address various multivariate techniques applied in the area of consumer psychology, economics, marketing, tourism and education, trying to explain the behavior of consumers when choosing a certain product and its influence on decision-making. Objective: In this sense, the present study aims to analyze consumer behavior when buying dairy products in the city of Riobamba, in the middle of a sanitary situation that involves the whole world. Methodology: Through the use of non-metric multidimensional scaling (MDS), starting from a hierarchical matrix related to the importance of the most influential attributes when choosing a dairy product, the multidimensional analysis was optimized through a SMACOF algorithm implemented in the free software RStudio. Results: Consequently, the results obtained allowed to distinguish 2 dimensions, where the relevance of each variable with the consumer behavior at the time of purchase, the brand is definitely far from the rest of variables, being the aspect of less importance for the consumer, Conclusions: it was possible to distinguish a group of factors that associate and confirm that the taste, quality and nutritional value are the most important attributes, the price is a factor that represents a medium importance at the time of purchase of dairy products. It is demonstrated that the Multidimensional Scaling technique can be used in marketing studies on consumer behavior as an alternative to other multivariate techniques.

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Bolaños Logroño, P. F., Márquez Sañay, F. R., & Mantilla Cabrera, C. E. (2021). Non-metric multidimensional scaling (MDS) in the analysis of consumer behavior in the purchase of dairy products. ConcienciaDigital, 4(3), 156-176. https://doi.org/10.33262/concienciadigital.v4i3.1788
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References

Aldana, S., Vereda, F., Hidalgo-Alvarez, R., & de Vicente, J. (2016). Facile synthesis of magnetic agarose microfibers by directed selfassembly. Polymer, 93, 61-64.
Arnau, J. (1996). Métodos y técnicas avanzadas de análisis de datos en ciencias del comportamiento. Barcelona: Universitat de Barcelona.
Bhat, S., Tripathi, A., & Kumar, A. (2010). Supermacroprous chitosan-agarose-gelatin cryogels. in vitro characterization and in vivo assesment for cartilage tissue engineering. Journal of the Royal Society Interface, 1-15.
Borg, I., & Groenen, P. (2005). Modern Multidimensional Scaling. Theory and Applications. Springer.
Bossis, G., Marins, J., Kuzhir, P., Volkova, O., & Zubarev, A. (2015). Functionalized microfibers for field-responsive materials and biological applications. Journal of Intelligent Material Systems and Structures, 1-9.
Cortés, J., Puig, J., Morales , J., & Mendizábal, E. (2011). Hidrogeles nanoestructurados termosensibles sintetizados mediante polimerización en microemulsión inversa. Revista Mexicana de Ingeniería Química., 10(3), 513-520.
Crepaldi, M. (2020). Location regions for Interval Multidimensional Scaling. Granada.
De Lucas Jaramillo, A. B. (2012). UGR. Obtenido de https://masteres.ugr.es/
Dias, A., Hussain, A., Marcos, A., & Roque, A. (2011). A biotechnological perspective on the application of iron oxide magnetic colloids modified with polysaccharides. Biotechnology Advances 29 , 29, 142–155.
Estrada Guerrero, R., Lemus Torres, D., Mendoza Anaya, D., & Rodriguez Lugo, V. (2010). Hidrogeles poliméricos potencialmente aplicables en Agricultura. Revista Iberoamericana de Polímeros, 12(2), 76-87.
García-Cerda, L., Rodríguez-Fernández, O., Betancourt-Galindo, R., Saldívar-Guerrero, R., & Torres-Torres, M. (2003). Síntesis y propiedades de ferrofluidos de magnetita. Superficies y Vacío., 16(1), 28-31.
Ilg, P. (2013). Stimuli-responsive hydrogels cross-linked by magnetic nanoparticles. Soft Matter, 9, 3465-3468.
Leeuw , J., & Mair, P. (2009). Multidimensional scaling using majorization: SMACOF in R. Journal of Statistical Software.
Lewitus, D., Branch, J., Smith, K., Callegari, G., Kohn, J., & Neimark, A. (2011). Biohybrid carbon nanotube/agarose fibers for neural tissue engineering. Advanced Functional Materials, 21, 2624-2632.
Lin, Y.-S., Huang, K.-S., Yang, C.-H., Wang, C.-Y., Yang, Y.-S., Hsu, H.-C., . . . Tsai, C.-W. (2012). Microfluidic synthesis of microfibers for magnetic-responsive controlled drug release and cell culture. PLoS ONE, 7(3), 1-8.
Løland , A., & Høst, G. (2003). Spatial covariance modelling in a complex coastal domain by multidimensional scaling. Environmetrics, pp. 307-321.
López González, E., & Hidalgo Sánchez, R. (2010). Escalamiento Multidimensional No Métrico. Un ejemplo con R empleando el algoritmo SMACOF. Universidad de Navarra.
Macías, R., Rivera, C., & Vera, J. (2007). Dialnet. Obtenido de https://dialnet.unirioja.es/servlet/articulo?codigo=3152246
Mardia , K., Kent , J., & Bibby, J. (1979). Multivariate Analysis. Londres. Gran Bretaña: Academic Press.
Motterlini, M. (2006). Economía Emocional. En qué nos gastamos el dinero y por qué. Milán: Paidós Contextos.
Peñaranda Arenas, I. D. (2016). UGR. Obtenido de https://masteres.ugr.es/moea/pages/curso201516/tfm1516/peaarandaarenas_tfm
Ruiz Estrada, G. (2004). Desarrollo de un Sistema de liberación de fármacos basado en nanopartículas magnéticas recubiertas con Polietilénglicol para el tratamiento de diferentes enfermedades. Madrid: Universidad Autónoma de Madrid. Departamento de Física Aplicada.
Song , J., King, S., Yoon , S., Cho, D., & Jeong, Y. (2014). Enhanced spinnability of narbon nanotube fibers by surfactant addition. Fiberes and Polymers, 15(4), 762-766.
Tartaj, P., Morales, M., González-Carreño, T., Veintemillas-Verdaguer, S., & Serna, C. (2005). Advances in magnetic nanoparticles for biotechnology applications. Journal of Magnetism and Magnetic Materials, 290, 28-34.
Torgerson , W. (1952). Multidimensional scaling: I. Theory and method. Torgerson, W. (1952)., 17, 401-419.: Psychometrika.
Turstone, L. (1927). A law of comparative judgment. Psychological Review.
Vera, J., & Mair, P. (2019). Researchgate. Obtenido de https://www.researchgate.net/publication/331213974_SEMDS_An_R_Package_for_Structural_Equation_Multidimensional_Scaling/download
Wickelmaier, F. (2003). Obtenido de https://homepage.uni-tuebingen.de/florian.wickelmaier/pubs/Wickelmaier2003SQRU.pdf
Wulff-Pérez , M., Martín-Rodriguez, A., Gálvez-Ruiz, M., & de Vicente, J. ( 2013 ). The effect of polymer surfactant on the rheological properties of nanoemulsions. Colloid and Polymer Science, 291, 709–716.
Zamora Mora, V., Soares, P., Echeverria, C., Hernández , R., & Mijangos, C. (2015). Composite chitosan/Agarose ferrogels for potential applications in magnetic hyperethermia. Gels., 1, 69-80.

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