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ISRN Robotics  2013 

Classification of Clothing Using Midlevel Layers

DOI: 10.5402/2013/630579

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Abstract:

We present a multilayer approach to classify articles of clothing within a pile of laundry. The classification features are composed of color, texture, shape, and edge information from 2D and 3D data within a local and global perspective. The contribution of this paper is a novel approach of classification termed L-M-H, more specifically LC-S-H for clothing classification. The multilayer approach compartmentalizes the problem into a high (H) layer, multiple midlevel (characteristics (C), selection masks (S)) layers, and a low (L) layer. This approach produces “local” solutions to solve the global classification problem. Experiments demonstrate the ability of the system to efficiently classify each article of clothing into one of seven categories (pants, shorts, shirts, socks, dresses, cloths, or jackets). The results presented in this paper show that, on average, the classification rates improve by +27.47% for three categories (Willimon et al., 2011), +17.90% for four categories, and +10.35% for seven categories over the baseline system, using SVMs (Chang and Lin, 2001). 1. Introduction Sorting laundry is a common routine that involves classifying and labeling each piece of clothing. This particular task is not close to becoming an automated procedure. The laundry process consists of several steps: handling, washing, drying, separating/isolating, classifying, unfolding/flattening, folding, and putting it away into a predetermined drawer or storage unit. Figure 1 gives a high-level flow chart of these various steps. In the past, several bodies of work have attempted at solving the tasks of handling [1–8], separating/isolating [8–12], classifying [6, 9, 11–15], unfolding/flattening [14, 16], and folding [17] clothes. Figure 1 gives a flow chart of the various areas. Figure 1: Overview of the laundry process, adapted from [ 10]. Green areas represent parts of the process that have already been explored in previous work, while the Red area represents the part of the process that is the focus of this paper. A robotic classification system is designed to accurately sort a pile of clothes in predefined categories, before and after the washing/drying process. Laundry is normally sorted by individual, then by category. Our procedure allows for clothing to be classified/sorted by category, age, gender, color (i.e., whites, colors, darks), or season of use. The problem that we address in this paper is grouping isolated articles of clothing into a specified category (e.g., shirts, pants, shorts, cloths, socks, dresses, jackets) using midlevel layers (i.e., physical

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