Timely identification and tracking of abnormal hens in stacked cages are of great significance for precision treatment and the elimination of sick individuals. The head features of the caged-hens are used to overcome observation difficulties caused by the cage and feathers blocking, but it is still hard to identify similar head states. To solve this problem, a fine-grained detection of caged-hens head states was developed using adaptive Brightness Adjustment in combination with Convolutional Neural Networks (FBA-CNN). Grid Region-based CNN (R-CNN), a convolution neural network (CNN), was optimized with the Squeeze-and-Excitation (SE) and Depthwise Over-parameterized Convolutional (DO-Conv) to detect layer heads from cages and to accurately cut them as single-head images. The brightness of each single-head image was adjusted adaptively and classified through the deep convolution neural network based on SE-Resnet50. Finally, we returned to the original image to realize multi-target detection with coordinate mapping. The results showed that the AP@0.5 of layer head detection using the optimized Grid R-CNN was 0.947, the accuracy of classification with SE-Resnet50 was 0.749, the F1 score was 0.637, and the mAP@0.5 of FBA-CNN was 0.846. In summary, this automated method can accurately identify different layer head states in layer cages to provide a basis for follow-up studies of abnormal behavior including dyspnea and cachexia.
Keywords: Grid R-CNN, squeeze-and-excitation, Depthwise Over-parameterized Convolutional, adaptive brightness adjustment, fine-grained detection
DOI: 10.25165/j.ijabe.20231603.7507

Citation: Chen J, Ding Q A, Yao W, Shen M X, Liu L S. Fine-grained detection of caged-hens head states using adaptive Brightness Adjustment in combination with Convolutional Neural Networks. Int J Agric & Biol Eng, 2023; 16(): 16(3): 208–216.

Grid R-CNN, squeeze-and-excitation, Depthwise Over-parameterized Convolutional, adaptive brightness adjustment, fine-grained detection

Neethirajan S, Tuteja S K, Huang S T, Kelton D. Recent advancement in biosensors technology for animal and livestock health management. Biosensors and Bioelectronics, 2017; 98: 398–407.

Okinda C, Nyalala I, Korohou T, Okinda C, Wang J T, Achieng, T, et al. A review on computer vision systems in monitoring of poultry: A welfare perspective. Artificial Intelligence in Agriculture, 2020; 4: 184-208.

Zhong Y F, Xiao H S, Liu N, Gao J K, Lin Z Y, Huang Z B. Breeding chicken temperature measurement system based on ZigBee. Science and Technology Innovation Herald, 2015; 12(8): 48. (in Chinese)

Yang W. Development of wireless wearable sensor equipment for monitoring layers’ body temperature and experiment research. Master dissertation. Hangzhou: Zhejiang University, 2017; 72p. (in Chinese)

McManus C, Tanure C B, Peripolli V, Seixas L, Fischer V, Gabbi A M, et al. Infrared thermography in animal production: An overview. Computers and Electronics in Agriculture, 2016; 123: 10-16.

Shen M X, Lu P Y, Liu L S, Sun Y W, Xu Y, Qin F L. Body temperature detection method of ross broiler based on infrared rhermography. Transactions of the CSAM, 2019; 50(10): 222-229. (in Chinese)

Carpentier L, Vranken E, Berckmans D, Paeshuyse J, Norton T. Development of sound-based poultry health monitoring tool for automated sneeze detection. Computers and Electronics in Agriculture, 2019; 162: 573-581.

Banakar A, Sadeghi M, Shushtari A. An intelligent device for diagnosing avian diseases: Newcastle, infectious bronchitis, avian influenza. Computers and Electronics in Agriculture, 2016; 127: 744-753.

Mahdavian A, Minaei S, Yang C, Almasganj F, Rahimi S, Marchetto P M. Ability evaluation of a voice activity detection algorithm in bioacoustics: A case study on poultry calls. Computers and Electronics in Agriculture, 2020; 168: 105100. doi: c10.1016/j.compag.2019.105100.

Qin F L, Shen M X, Liu L S, Sun Y W, Zheng H H, Lu P Y, et al. Study on recognition algorithm of white feather broiler cough based on audio technology. Journal of Nanjing Agricultural University, 2020; 43(2): 372-378. (in Chinese)

Wang J T, Shen M X, Liu L S, Xu Y, Okinda C. Recognition and classification of broiler droppings based on deep convolutional neural network. Journal of Sensors, 2019; 2019: 3823515. doi: 10.1155/2019/3823515.

Zhuang X L, Bi M N, Guo J L, Wu S Y, Zhang T M. Development of an early warning algorithm to detect sick broilers. Computers and Electronics in Agriculture, 2018; 144: 102-113.

Okinda C, Lu M Z, Liu L S, Nyalala I, Muneri C, Wang J T, et al. A machine vision system for early detection and prediction of sick birds: A broiler chicken model. Biosystems Engineering, 2019; 188: 229-242.

Zhuang X L, Zhang T M. Detection of sick broilers by digital image processing and deep learning. Biosystems Engineering, 2019; 179: 106-116.

Li Y S, Mao W H, Hu X A, Zhang X C. Sick chicken detection with chicken crown color based on machine vision. Robot Technique and Application, 2014; 5: 23-25. (in Chinese)

Bi M N, Zhang T M, Zhuang X L, Zhang X L, Qiao P R. Recognition method of sick yellow feather chicken based on head features. Transactions of the CSAM, 2018; 49(1): 51-57. (in Chinese)

Chen Z B, Hou Y. Research on recognition of fine-grained sick chicken based on DCNN feature fusion. Journal of Lanzhou University of Arts and Science (Natural Sciences), 2020; 34(2): 79-84, 104. (in Chinese)

Hou L Y. Research on small object recognition algorithm based on SE-SSD network. Master dissertation. Dalian: Dalian University of Technology, 2020; 62p. (in Chinese)

Zhang H T, Zhang M. SSD target detection algorithm with channel attention mechanism. Computer Engineering, 2020; 46(8): 264-270. (in Chinese)

Wei L, Wang Y, Yao K M. Small target detection based on improved YOLO v4. Software Guide, 2021; 20(7): 54-58. (in Chinese)

Zhu M C, Feng T, Zhang Y. Remote sensing image multi-target detection method based on FD-SSD. Computer Applications and Software, 2019; 36(1): 232-238. (in Chinese)

Zheng P, Bai H Y, Li W, Guo H W. Small target detection algorithm in complex background. Journal of Zhejiang University (Engeering Science), 2020; 54(9): 1777-1784. (in Chinese)

Wang N, Hu J H, Liu R K, Fan L C. Small target detection algorithm based on Bi-SSD. Computer Systems & Applications, 2020; 29(11): 139-144. (in Chinese)

Yin Z Q, Wang K Y, Jia R Y. Pathomorphological observation on experi-mental Leucocytozoonsis caulleryi. Chinese Journal of Veterinary Science, 2002; 22(6): 597-600. (in Chinese)

Cavanagh D. Severe acute respiratory syndrome vaccine development: experiences of vaccination against avian infectious bronchitis coronavirus. Avian Pathology, 2003; 32(6): 567-582.

Lu X, Li B Y, Yue Y X, Li Q Q, Yan J J. Grid R-CNN. In: 2019 IEEE/CVF Conference on Computer Vision and Pattern Recognition (CVPR), Long Beach: IEEE, 2019; pp.7355-7364. doi: 10.1109/CVPR.2019.00754.

Hu J, Shen L, Sun G. Squeeze-and-excitation networks. In: 2018 IEEE/CVF Conference on Computer Vision and Pattern Recognition, Salt Lake City: IEEE, 2018; pp.7132-7141. doi: 10.1109/CVPR.2018.00745..

Cao J M, Li Y Y, Sun M C, Chen Y, Lischinski D, Clhen-Or D, et al. Do-conv: Depthwise over-parameterized convolutional layer. IEEE Transactions on Image Processing, 2022; 31: 3726-3736.

He T, Zhang Z, Zhang H, Zhang Z Y, Xie J Y, Li M. Bags of tricks for image classification with Convolutional Neural Networks. In: 2019 IEEE/CVF Conference on Computer Vision and Pattern Recognition (CVPR), Long Beach: IEEE, 2019; pp.558-567. doi: 10.1109/CVPR.2019.00065.

David M W. Evaluation: From precision, recall and F-measure to ROC, informedness, markedness and correlation. Journal of Machine Learning Technologies, 2011; 2(1): 37–63.