Assessing the suitability of convolutional auto encoder as an unsupervised tool for image classification in artisanal small-scale gold mining environment

International Journal of Computing and Artificial Intelligence Pub Date : 2022-01-01 DOI:10.33545/27076571.2022.v3.i1a.43

S. Akpah, Y. Ziggah, D. Mireku-Gyimah

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Abstract

Efforts to control or stop illegal Artisanal Small-Scale Gold Mining (ASGM) in Ghana, which is causing significant environmental degradation, have faced numerous challenges because these illegal activities are carried out in remote areas, inaccessible by the current practice of using 4WD vehicles or trekking by foot. This paper sought to assess the suitability of using an Unmanned Aerial Vehicle (UAV) to capture the locations and features of all ASGM sites and use a Convolutional Autoencoder (CAE) to classify the defined sites into legal and illegal ASGM sites. The classification process used by the CAE involved three main stages, namely encoding, latent space learning, and decoding. The encoder accepts the UAV captured images as input, processes the input images to extract salient features and the decoder decodes the salient features to reconstruct the input image and define a site as an ASGM site. To classify a defined ASGM site as legal or illegal, a python program was integrated into the CAE which makes use of known point coordinates of all legal ASGM sites. A site is flagged as illegal if its point coordinates do not match those in the legal ASGM sites database, otherwise, it is a legal site. The performance of the CAE was measured using the following performance metrics: accuracy, precision, recall, and FI-score. The results of the CAE proved superior giving a classification accuracy of 97.52% when compared with the results obtained from other classification algorithms, namely Random Forest (RF) and Support Vector Machine (SVM) with 93.23% and 95.66% respectively. In this paper, it has been demonstrated that UAVs can be used to capture the locations and features of all ASGM sites, which otherwise would have been inaccessible by the use of 4WD vehicles or trekking, and classify the captured location into legal and illegal ASGM sites using a CAE, to facilitate the control and prevention of illegal ASGM in Ghana.

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评估卷积自编码器在手工小规模金矿环境下作为无监督图像分类工具的适用性

加纳的非法手工小规模金矿开采(ASGM)正在造成严重的环境退化，由于这些非法活动是在偏远地区进行的，目前使用四轮驱动车辆或徒步旅行的做法无法进入，因此控制或制止非法手工小规模金矿开采(ASGM)的努力面临着许多挑战。本文试图评估使用无人机(UAV)捕获所有ASGM站点的位置和特征的适用性，并使用卷积自动编码器(CAE)将定义的站点分类为合法和非法ASGM站点。CAE使用的分类过程包括三个主要阶段，即编码、潜在空间学习和解码。编码器接受无人机捕获的图像作为输入，对输入图像进行处理以提取显著特征，解码器对显著特征进行解码以重建输入图像并将站点定义为ASGM站点。为了将已定义的ASGM站点划分为合法或非法，CAE中集成了一个python程序，该程序使用所有合法ASGM站点的已知点坐标。如果一个站点的点坐标与合法ASGM站点数据库中的点坐标不匹配，则该站点被标记为非法站点，否则为合法站点。CAE的性能使用以下性能指标进行测量:准确性、精密度、召回率和fi评分。与随机森林(Random Forest, RF)和支持向量机(Support Vector Machine, SVM)的分类准确率分别为93.23%和95.66%相比，CAE的分类准确率为97.52%。在本文中，已经证明了无人机可以用来捕获所有ASGM站点的位置和特征，否则使用四轮驱动车辆或徒步旅行将无法进入这些站点，并使用CAE将捕获的位置分为合法和非法ASGM站点，以促进加纳非法ASGM的控制和预防。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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International Journal of Computing and Artificial Intelligence

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