JTF-SqueezeNet: A SqueezeNet network based on joint time-frequency data representation for egg-laying detection in individually caged ducks

IF 3.8 1区农林科学 Q1 AGRICULTURE, DAIRY & ANIMAL SCIENCE

Poultry Science Pub Date : 2025-02-01 DOI:10.1016/j.psj.2025.104782

Siting Lv , Yuanyang Mao , Youfu Liu , Yigui Huang , Dakang Guo , Lei Cheng , Zhuoheng Tang , Shaohai Peng , Deqin Xiao

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引用次数: 0

Abstract

Accurate individual egg-laying detection is crucial for eliminating low-yielding breeder ducks and improving production efficiency. However, existing methods are often expensive and require strict environmental conditions. This study proposes a data processing method based on wearable sensors and joint time-frequency representation (TFR), aimed at accurately identifying egg-laying in ducks. First, the sensors continuously monitor the ducks' activity and collect corresponding X-axis acceleration data. Next, a sliding window combined with Short-Time Fourier Transform (STFT) is applied to convert the continuous data into spectrograms within consecutive windows. SqueezeNet is then used to detect spectrograms containing key features of the egg-laying process, marking these as egg-laying state windows. Finally, Kalman filtering was used to continuously predict the detected egg-laying status, allowing for the precise determination of the egg-laying period. The best detection performance was achieved by applying the 10-fold cross-validation to a dataset of 59,135 spectrograms, using a window size of 50 min and a step size of 3 min. This configuration yielded an accuracy of 95.73 % for detecting egg-laying status, with an inference time of only 2.1511 milliseconds per window. The accuracy for identifying the egg-laying period reached 92.19 %, with a precision of 93.57 % and a recall rate of 91.95 %. Additionally, we explored the scalability of the joint time-frequency representation to reduce the computational complexity of the model.

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JTF-SqueezeNet：一种基于联合时频数据表示的SqueezeNet网络，用于单独笼鸭的产蛋检测。

精确的个体产蛋检测对于淘汰低产种鸭和提高生产效率至关重要。然而，现有方法往往成本高昂，且对环境条件要求严格。本研究提出了一种基于可穿戴传感器和联合时频表示（TFR）的数据处理方法，旨在准确识别鸭子的产蛋情况。首先，传感器持续监测鸭子的活动并收集相应的 X 轴加速度数据。然后，应用滑动窗口结合短时傅里叶变换（STFT）将连续数据转换为连续窗口内的频谱图。然后使用 SqueezeNet 检测包含产蛋过程关键特征的频谱图，并将其标记为产蛋状态窗口。最后，使用卡尔曼滤波连续预测检测到的产蛋状态，从而精确确定产蛋期。通过对 59,135 个频谱图数据集进行 10 倍交叉验证，使用 50 分钟的窗口大小和 3 分钟的步长，实现了最佳检测性能。这种配置检测产卵状态的准确率为 95.73%，每个窗口的推理时间仅为 2.1511 毫秒。识别产卵期的准确率达到 92.19%，精确率为 93.57%，召回率为 91.95%。此外，我们还探索了时频联合表示法的可扩展性，以降低模型的计算复杂度。

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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来源期刊

Poultry Science 农林科学-奶制品与动物科学

CiteScore

7.60

自引率

15.90%

发文量

审稿时长

94 days

期刊介绍： First self-published in 1921, Poultry Science is an internationally renowned monthly journal, known as the authoritative source for a broad range of poultry information and high-caliber research. The journal plays a pivotal role in the dissemination of preeminent poultry-related knowledge across all disciplines. As of January 2020, Poultry Science will become an Open Access journal with no subscription charges, meaning authors who publish here can make their research immediately, permanently, and freely accessible worldwide while retaining copyright to their work. Papers submitted for publication after October 1, 2019 will be published as Open Access papers. An international journal, Poultry Science publishes original papers, research notes, symposium papers, and reviews of basic science as applied to poultry. This authoritative source of poultry information is consistently ranked by ISI Impact Factor as one of the top 10 agriculture, dairy and animal science journals to deliver high-caliber research. Currently it is the highest-ranked (by Impact Factor and Eigenfactor) journal dedicated to publishing poultry research. Subject areas include breeding, genetics, education, production, management, environment, health, behavior, welfare, immunology, molecular biology, metabolism, nutrition, physiology, reproduction, processing, and products.