|
|
|
|
|
|
| Non-Destructive Detection of Pre-Incubation Breeding Duck Egg Fertilization Information Based on Visible/Near Infrared Spectroscopy and Joint Optimization Strategy |
| CHEN Zhuo-ting1, WANG Qiao-hua1, 2*, WANG Dong-qiao1, CHEN Yan-bin1, LI Shi-jun1, 2 |
1. College of Engineering, Huazhong Agricultural University, Wuhan 430070, China
2. Key Laboratory of Agricultural Equipmentin Mid-Lower Yangtze River, Wuhan 430070, China
|
|
|
|
|
Abstract The hatching of duck eggs is an important guarantee for producing duck eggs and duck meat. Eggs without sperm cannot hatch ducklings, and they are prone to spoilage in the incubator, which affects the hatching of fertilized eggs. To solve the problems of high labor intensity and resource waste caused by manually removing -sperm-free eggs through egg photography, this paper takes pre-hatching duck eggs as the research object. It proposes a non-destructive detection method for pre-hatching fertilization information of duck eggs based on visible near-infrared spectroscopy and deep learning. This article uses a visible near-infrared fiber optic spectrometer to collect spectral data from 321 Cherry Valley duck eggs (144 fertilized eggs and 177 azoospermia eggs). The spectral data is divided into training and testing sets in a 3∶1 ratio, and the training set is expanded by adding noise and random offset to the original spectral data, randomly selecting and calculating the average spectrum. This article designs an end-to-end deep learning model: the Autoencoder 1DCNN, which uses convolutional and pooling layers instead of the fully connected layers in the autoencoder to obtain an improved convolutional autoencoder CAE. The CAE-1DCNN model is trained using a joint optimization strategy to enable the autoencoder to extract useful features during the data compression reconstruction process and selectively extract features suitable for classification tasks. This article uses three commonly used feature wavelength selection algorithms, namely Competitive Adaptive Reweighted Sampling (CARS), Continuous Projection (SPA), and Uninformative Variable Elimination (UVE), as well as three machine learning classification models, K-Nearest Neighbor (KNN), Naive Bayes (NB), and Random Forest (RF), to combine and compare with the proposed model. The t-distribution Random Neighborhood Embedding (t-SNE) algorithm is used to visualize the feature extraction effect. Finally, this article used a weighted Class Activation Graph (Grad CAM) to visualize the focus areas of spectral data designed in this paper. It explored the biological interpretability of spectral information. The research results indicate that the CAE-1DCNN model proposed in this paper can effectively extract information from spectral data with a discrimination accuracy of 95.06%. The combination of visible near-infrared spectroscopy technology and deep learning can achieve non-destructive detection of pre-incubation fertilization information in duck eggs. The convolutional autoencoder trained using a joint optimization strategy has good feature extraction ability. The end-to-end CAE-1DCNN model facilitates integration and provides technical support for the development of non-destructive testing equipment.
|
|
Received: 2024-01-16
Accepted: 2025-03-01
|
|
|
|
Corresponding Authors:
WANG Qiao-hua
E-mail: wqh@mail.hzau.edu.cn
|
|
[1] Mbuthia P G, Njagi L W, Nyaga P N, et al. Kenya Veterinarian, 2007, 31(1): 6.
[2] LI Qing-xu, WANG Qiao-hua, GU Wei, et al(李庆旭, 王巧华, 顾 伟,等). Transactions of the Chinese Society for Agricultural Machinery(农业机械学报), 2020, 51(1): 188.
[3] Liu Y, Xiao D, Liu Y, et al. Journal of Thermal Biology, 2022, 110: 103384.
[4] Bain M M, Fagan A J, Mullin J M, et al. Journal of Magnetic Resonance Imaging, 2007, 26(1): 198.
[5] Park E, Lohumi S, Cho B K. Sensors and Actuators B: Chemical, 2019, 281: 204.
[6] ZHAO Juan, SHEN Mao-sheng, PU Yu-ge, et al(赵 娟, 沈懋生, 浦育歌,等). Transactions of the Chinese Society for Agricultural Machinery(农业机械学报), 2023, 54(2): 386.
[7] Dong J, Dong X, Li Y, et al. Computers and Electronics in Agriculture, 2019, 157: 471.
[8] LI Qing-xu, WANG Qiao-hua, GU Wei, et al(李庆旭, 王巧华, 顾 伟, 等). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2020, 40(12): 3847.
[9] Zhao J, Hu L, Dong Y, et al. International Journal of Applied Earth Observation and Geoinformation, 2021, 102: 102459.
[10] ZHENG Jiang-peng, YU Ping, ZHAO Meng, et al(郑江鹏, 余 平, 赵 萌,等). Chinese Optics(中国光学), 2022, 15(3): 443.
[11] Tsakiridis N L, Samarinas N, Kokkas S, et al. Computers and Electronics in Agriculture, 2023, 212: 108098.
[12] Liu Y, Zhou S, Wu H, et al. Computers and Electronics in Agriculture, 2022, 198: 107007.
[13] Syduzzaman M, Rahman A, Alin K, et al. Engineering in Agriculture, Environment and Food, 2019, 12(3): 289.
[14] Syduzzaman M, Khaliduzzaman A, Rahman A, et al. British Poultry Science, 2023, 64(2): 195.
|
| [1] |
WU Nian-yi1, CANG Hao1, GAO Xiu-wen1, LI Yong-quan1, TAN Fei1, DI Ruo-yu1, RUAN Shi-wei1, GAO Pan1*, LÜ Xin2*. Cotton Verticillium Wilt Severity Detection Based on Hyperspectral
Imaging and SSFNet[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2025, 45(05): 1300-1309. |
| [2] |
WANG Ke-ming1, GONG Wei-jia1, WANG Hai-ming2, CAI Yong-jun2, LIU Jia-xing3, SUN Lei4, SONG Li-mei1, LI Jin-yi1*. Hyperspectral Image Detection of Gasoline Pipeline Leakage Using
Improved Unet Network[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2025, 45(05): 1476-1484. |
| [3] |
CHEN Jin-ni, TIAN Gu-feng*, LI Yun-hong, ZHU Yao-lin, CHEN Xin, MEN Yu-le, WEI Xiao-shuang. Near-Infrared Spectral Prediction Model for Cashmere and Wool Based on Two-Way Multiscale Convolution[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2025, 45(03): 678-684. |
| [4] |
LIU Chang-qing, LING Zong-cheng*. LIBS Quantitative Analysis of Martian Analogues Library (MAL)[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2025, 45(03): 717-725. |
| [5] |
LI Wei-qi1, WANG Yi-fan1, YU Yue1, LIU Jie1, 2, 3*. Establishment and Optimization of the Hyperspectral Detection Model for Soluble Solids Content in Fortunella Margarita[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2025, 45(02): 492-500. |
| [6] |
ZHANG Ran1, 2, JIN Wei1, 2, MU Ying1, YU Bing-wen2, BAI Yi-wen2, SHAO Yi-bo1, 2, PING Jin-liang3*, SONG Peng-tao3, HE Xiang-yi3, LIU Fei3, FU Lin-lin3. Transformer-Based Method for Segmentation of Gastric Cancer
Microscopic Hyperspectral Images[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2025, 45(02): 551-557. |
| [7] |
XU Yang1, MAO Yi-lin1, LI He1, WANG Yu1, WANG Shuang-shuang2, QIAN Wen-jun1, DING Zhao-tang2*, FAN Kai1*. Multispectral and Hyperspectral Prediction Models of REC, SPAD and MDA in Overwintered Tea Plant[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2025, 45(01): 256-263. |
| [8] |
XU Zi-yang1, 2, JIANG Xin-hua1, 2*, ZHAI Cheng-jun3, MA Xue-lei1, 2, LI Jing1, 2. Non-Destructive Detection of Multi-Indicator Chilled Mutton Freshness Based on Improved Artificial Neural Network[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2025, 45(01): 291-300. |
| [9] |
WANG Sa1, 2, QU Liang1, 2*, ZHANG Li-fu3, GAO Yu3, LI Guang-hua1, 2, CHANG Jing-jing1, 2. Research on the Inverse Model of Paper Viscosity Based on Hyperspectral Data[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(12): 3524-3533. |
| [10] |
HUANG Lin-feng1, JIANG Xue-song1, 2*, JIA Zhi-cheng1, ZHOU Hong-ping1, 2, ZHOU Lei1, RONG Zi-fan1. Deep Learning-Based Monitoring of Nutrient Content in Pear Trees[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(12): 3543-3552. |
| [11] |
JIA Tong-hua1, CHENG Guang-xu1*, YANG Jia-cong1, CHEN Sheng2, WANG Hai-rong3, HU Hai-jun1. Research of Chlorine Concentration Inversion Method Based on 1D-CNN Using Ultraviolet Spectral[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(11): 3109-3119. |
| [12] |
WANG Hong-en, FENG Guo-hong*, XU Hua-dong, ZHANG Run-ze. Identification of Blueberry Ripeness Based on Visible-Near Infrared
Spectroscopy and Deep Forest[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(11): 3280-3286. |
| [13] |
JIANG Yu-ying1, 2, 4, WEN Xi-xi1, 2, 3, GE Hong-yi1, 2, 3*, CHEN Hao1, 2, 3, JIANG Meng-die1, 2, 3, ZHAO Yang4, WANG Jia-hui4. Research Progress of Terahertz Technology in Defect Detection of
Composite Materials[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(10): 2717-2726. |
| [14] |
YUE Ji-bo1, LENG Meng-die1, TIAN Qing-jiu2, GUO Wei1, LIU Yang3, FENG Hai-kuan4, QIAO Hong-bo1*. Estimation of Leaf Physical and Chemical Parameters Based on Hyperspectral Remote Sensing and Deep Learning Technologies[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(10): 2873-2883. |
| [15] |
WENG Ding-kang1, FAN Zheng-xin1, KONG Ling-fei1, SUN Tong1*, YU Wei-wu2. Rapid Identification of Shelled Bad Torreya Grandis Seeds Based on
Visible-Near Infrared Spectroscopy and Chemometrics[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(09): 2675-2682. |
|
|
|
|
