Development of a system for creating and recommending combination collections in the e-commerce clothing industry
Abstract
In the clothing sector, matching the right demand with the appropriate user is of great significance. Combination suggestions emerge as an innovative strategy for e-commerce platforms operating in the clothing sector. By providing suitable combination suggestions tailored to the right user, the profit margin of sales increased, and the brand image strengthened. The aim of this study is to develop a recommendation system based on image processing and machine learning that generates combinations from products that may interest users and recommends these combinations to them. 90 million possible combinations have been obtained using a dataset consisting of products detected from images of items sold in the clothing category on Trendyol. These combinations have been trained using the Prod2Vec algorithm to create new pairings. Subsequently, collections have been developed for purchasing looks using image processing methods. In this context, the You Only Look Once (YOLO) model has been selected for clothing classification, while the Convolutional Network Next (ConvNext) model has been employed for calculating image similarity. Models have also been developed for estimating click performance using Random Forest (RF), Extreme Gradient Boosting (XGBoost), and Linear Regression (LR). The prediction performances of the developed models have been evaluated using Coefficient of Determination (R2), Mean Squared Error (MSE), and Mean Absolute Error (MAE) metrics. When the developed models have been examined, it has been observed that RF had superior performance. The developed system provided a 5% increase in the time spent on the Trendyol mobile application.
References
[1]Singh S, & Vijay TS. Technology road mapping for the e-commerce sector: A text-mining approach. Journal of Retailing and Consumer Services. 2024; 81: 103977.
[2]Jaradat S, Dokoohaki N, & Matskin M. Outfit2vec: Incorporating clothing hierarchical metadata into outfits’ recommendation. In: Dokoohaki N (editor). Fashion Recommender Systems. Springer International Publishing; 2020. pp. 87–107.
[3]Laenen K, & Moens MF. A comparative study of outfit recommendation methods with a focus on attention-based fusion. Information Processing & Management. 2020; 57(6): 102316.
[4]Patil P, Kadam SU, Aruna ER, et al. Recommendation System for E-Commerce Using Collaborative Filtering. European Journal of Automated Systems. 2024; 57(04): 1145–1153. doi: 10.18280/jesa.570421
[5]Kachbal I, El Abdellaoui S, Arhid K. Revolutionizing Fashion Recommendations: A Deep Dive into Deep Learning-based Recommender Systems. In: Proceedings of the 7th International Conference on Networking, Intelligent Systems and Security; 18–19 April 2024; Meknes, Morocco. pp. 1–8.
[6]Zhou B, Suleiman B, & Yaqub W. Aesthetic-aware recommender system for online fashion products. In: Proceedings of Neural Information Processing: 28th International Conference, ICONIP 2021; 8–12 December 2021; Bali, Indonesia. pp. 292–304.
[7]Robbi E, Bronzini M, Viappiani P, & Passerini A. Personalized bundle recommendation using preference elicitation and the Choquet integral. Frontiers in Artificial Intelligence. 2024; 7: 1346684. doi: 10.3389/frai.2024.1346684
[8]Gao C, Zheng Y, Li N, et al. A survey of graph neural networks for recommender systems: Challenges, methods, and directions. ACM Transactions on Recommender Systems. 2023; 1(1): 1–51.
[9]Ke H, Li L, Wang P, et al. Hyperbolic Mutual Learning for Bundle Recommendation. In: Database Systems for Advanced Applications. Cham: Springer Nature Switzerland; 2023. Volume 13944. pp. 417–433.
[10]Pereira AM, de Barros Costa E, Vieira T, et al. Helping Online Fashion Customers Help Themselves: Personalised Recommender Systems. In: Reinventing Fashion Retailing: Digitalising, Gamifying, Entrepreneuring. Cham: Springer International Publishing; 2023. pp. 17–33.
[11]Yıldız E, Güngör Şen C, & Işık EE. A hyper-personalized product recommendation system focused on customer segmentation: An application in the fashion retail industry. Journal of Theoretical and Applied Electronic Commerce Research. 2023; 18(1): 571–596.
[12]Chang J, Gao C, He X, et al. Bundle recommendation and generation with graph neural networks. IEEE Transactions on Knowledge and Data Engineering. 2021; 35(3): 2326–2340.
[13]Kim H, Jeong J, Kim KM, et al. Intent-based product collections for e-commerce using pretrained language models. In: Proceedings of 2021 International Conference on Data Mining Workshops (ICDMW); Auckland, New Zealand. pp. 228–237.
[14]Moghtader B. A collaborative filtering-based recommendation system for an online high-end retailer [PhD thesis]. Sabancı University; 2021.
[15]Tunalı O, & Bayrak AT. Targeted personalized product bundle generation. In: Proceedings of 2021 6th International Conference on Computer Science and Engineering (UBMK); 15–17 September 2021; Ankara, Turkey. pp. 1–5.
[16]Hao J, Zhao T, Li J, et al. P-companion: A principled framework for diversified complementary product recommendation. In: Proceedings of the 29th ACM International Conference on Information & Knowledge Management; 19–23 October 2020. pp. 2517–2524.
[17]Chen L, Liu Y, He X, et al. Matching user with item set: Collaborative bundle recommendation with deep attention network. In: Proceedings of the Twenty-Eighth International Joint Conference on Artificial Intelligence (IJCAI-19). pp. 2095–2101.
[18]Papush A. Data-driven methods for personalized product recommendation systems [PhD thesis]. Massachusetts Institute of Technology; 2018.
[19]Tercan H, Bitter C, Bodnar T, et al. Evaluating a Session-based Recommender System using Prod2vec in a Commercial Application. In: Proceedings of the 23rd International Conference on Enterprise Information Systems (ICEIS). pp. 610–617.
[20]Redmon J. You only look once: Unified, real-time object detection. In: Proceedings of the 2016 IEEE Conference on Computer Vision and Pattern Recognition (CVPR); 27–30 June 2016; Las Vegas, USA. pp: 779–788
[21]Zhang X, Wang H, Mao L, et al. Bone Stick Image Matching Algorithm Based on Improved ConvNeXt and Siamese Network. IEEE Access. 2024; 12: 60028–60038. doi: 10.1109/ACCESS.2024.3394048
[22]Park S, & Kim J. Landslide susceptibility mapping based on random forest and boosted regression tree models, and a comparison of their performance. Applied Sciences. 2019; 9(5): 942.
[23]Gökçe MM, & Duman E. Performance comparison of simple regression, random forest and XGBoost algorithms for forecasting electricity demand. In: Proceedings of 2022 3rd International Informatics and Software Engineering Conference (IISEC); 15–16 December 2022; Ankara, Turkey. pp. 1–6.
[24]Petruseva S, Zileska-Pancovska V, Žujo V, & Brkan-Vejzović A. Construction costs forecasting: comparison of the accuracy of linear regression and support vector machine models. Technical gazette. 2017; 24(5): 1431–1438.
[25]Trendyol. Trendyol. Available online: https://www.trendyol.com/en (accessed on 1 November 2024).
Copyright (c) 2024 Erdem Çetin, Murat Berker Özbek, Sezin Biner, Ceren Ulus, M. Fatih Akay
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