Your search keyword '"Ren, Guo-Peng"' showing total 2 results

1. An automatic method for removing empty camera trap images using ensemble learning.

Author

Yang, Deng‐Qi, Tan, Kun, Huang, Zhi‐Pang, Li, Xiao‐Wei, Chen, Ben‐Hui, Ren, Guo‐Peng, and Xiao, Wen

Subjects

DEEP learning, CONVOLUTIONAL neural networks, ARTIFICIAL intelligence, LABOR costs, CAMERAS, ALGORITHMS

Abstract

Camera traps often produce massive images, and empty images that do not contain animals are usually overwhelming. Deep learning is a machine‐learning algorithm and widely used to identify empty camera trap images automatically. Existing methods with high accuracy are based on millions of training samples (images) and require a lot of time and personnel costs to label the training samples manually. Reducing the number of training samples can save the cost of manually labeling images. However, the deep learning models based on a small dataset produce a large omission error of animal images that many animal images tend to be identified as empty images, which may lead to loss of the opportunities of discovering and observing species. Therefore, it is still a challenge to build the DCNN model with small errors on a small dataset. Using deep convolutional neural networks and a small‐size dataset, we proposed an ensemble learning approach based on conservative strategies to identify and remove empty images automatically. Furthermore, we proposed three automatic identifying schemes of empty images for users who accept different omission errors of animal images. Our experimental results showed that these three schemes automatically identified and removed 50.78%, 58.48%, and 77.51% of the empty images in the dataset when the omission errors were 0.70%, 1.13%, and 2.54%, respectively. The analysis showed that using our scheme to automatically identify empty images did not omit species information. It only slightly changed the frequency of species occurrence. When only a small dataset was available, our approach provided an alternative to users to automatically identify and remove empty images, which can significantly reduce the time and personnel costs required to manually remove empty images. The cost savings were comparable to the percentage of empty images removed by models. [ABSTRACT FROM AUTHOR]

Published

2021

2. An Adaptive Automatic Approach to Filtering Empty Images from Camera Traps Using a Deep Learning Model.

Author

Yang, Deng‐Qi, Ren, Guo‐Peng, Tan, Kun, Huang, Zhi‐Pang, Li, De‐Pin, Li, Xiao‐Wei, Wang, Jian‐Ming, Chen, Ben‐Hui, and Xiao, Wen

Abstract

Camera traps are widely used in wildlife surveys because they are non‐invasive, low‐cost, and highly efficient. Camera traps deployed in the wild often produce large datasets, making it increasingly difficult to manually classify images. Deep learning is a machine learning method that provides a tool to automatically identify images, but it requires labeled training samples and high‐performance servers with multiple Graphics Processing Units (GPUs). However, manually preparing large‐scale training images for training deep learning models is labor intensive, and the high‐performance servers with multiple GPUs are often not available for wildlife management agencies and field researchers. Our study explores an adaptive deep learning method to use small‐scale training sets and a commonly‐available, desktop personal computer (PC) to achieve automatic filtering of empty camera images. Our results showed that by using 29,192 training samples, the overall error, commission error, and omission error of the proposed method on a PC were 2.69%, 6.82%, and 6.45%, respectively. Moreover, the accuracy of our method can be adaptively improved on PCs in actual ecological monitoring projects, which would benefit researchers in field settings when only a PC is available. © 2021 The Wildlife Society. : An adaptive automatic method of empty camera trap images was proposed, which used a small‐scale training set to complete the training of a deep learning model on a common PC. The method will benefit researchers in the field setting when only one PC is available. It can also greatly reduce the workload of manually labeling training samples. [ABSTRACT FROM AUTHOR]

Published

2021