基于自适应Loess的纱线张力信号处理方法

doi:10.13475/j.fzxb.20231006201

纺织学报 ›› 2024, Vol. 45 ›› Issue (02): 246-254.doi: 10.13475/j.fzxb.20231006201

基于自适应Loess的纱线张力信号处理方法

彭来湖¹^,², 侯良美¹^,², 齐育宝¹^,²(), 汝欣¹, 刘建廷²

1.浙江理工大学浙江省现代纺织装备技术重点实验室, 浙江杭州 310018
2.浙江理工大学龙港研究院有限公司, 浙江温州 325802

收稿日期:2023-10-18 修回日期:2023-11-13 出版日期:2024-02-15 发布日期:2024-03-29
通讯作者: 齐育宝(1998—),男,硕士。主要研究方向为纺织智能制造。E-mail:202020601042@mails.zstu.edu.cn。
作者简介:彭来湖(1980—),男,教授,博士。主要研究方向为针织装备技术。
基金资助:
浙江省“尖兵”“领雁”研发攻关计划项目(2022C01065)

Yarn tension signal processing method based on adaptive Loess principle

PENG Laihu¹^,², HOU Liangmei¹^,², QI Yubao¹^,²(), RU Xin¹, LIU Jianting²

1. Zhejiang Key Laboratory of Modern Textile Equipment Technology, Zhejiang Sci-Tech University, Hangzhou, Zhejiang 310018, China
2. Zhejiang Sci-Tech University, Longgang Research Institute Co., Ltd., Wenzhou, Zhejiang 325802, China

Received:2023-10-18 Revised:2023-11-13 Published:2024-02-15 Online:2024-03-29

摘要/Abstract

摘要：

为保持针织系统中纱线张力的稳定并解决纱线张力检测过程中的噪声干扰问题,提出了一种基于自适应Loess的纱线张力信号优化方法。通过信号特征分析,将纱线张力结果划分为周期性信号、奇异点信号、高频干扰信号和低频耦合干扰信号。为消除这些干扰信号,提出了相应的数据处理方法:限幅滤波去除奇异点信号、低通滤波消除高频干扰信号以及改进的Loess方法去除低频耦合干扰信号。在3种不同情况的张力信号上验证了该方法的可靠性。实验结果显示,自适应Loess算法能有效平滑张力波动,提升信噪比分别达25.014%、27.661%、25.276%,证明了该方法在不同情况下的有效性和稳定性,为针织系统中纱线张力的稳定性和生产效率的提升提供了可行的解决方案。

关键词: 纱线张力检测, 自适应, 张力波动, 信号优化, 干扰信号处理

Abstract:

Objective The objective of this research is to develop an adaptive Loess based data processing algorithm for mitigating noise interference in dynamic yarn tension signals. The study aims to address three types of noise, which are Singularity signal, low frequency coupling signals below 2.6 kHz, and high frequency interference signals above 2.6 kHz. By combining limit filtering, low pass filtering, and Loess smoothing techniques, the proposed algorithm seeks to achieve stability and accurate smoothing of yarn tension signals. The importance of this work lies in enhancing yarn tension stability, improving production efficiency, and preventing yarn defects, so as to provide a feasible solution for optimizing text systems and processes.

Method The research method employs an adaptive Loess data processing algorithm to address the noise interference in dynamic yarn tension signals. Three types of noise (abnormal hidden changes, low frequency coupling, and high frequency interference) are identified based on noise type, tension signal characteristics, and filtering methods. The proposed algorithm combined limit filtering, low pass filtering, and loess smoothing to achieve noise suppression and signal smoothing. An experimental platform was set up to validate the yarn tension measurement method, by comparing a yarn package, yarn feeder, tension sensor, hooks, and groove cylinder. Crochet hook mimics the work of a high-speed seamless lingerie machine with sensors for experimental data collection on yarns.

Results The method proposed in this article has achieved significant results in yarn tension measurement. The data was analyzed and the effectiveness of three different algorithms (SG, Adj, and Loess) was evaluated. The Loess algorithm was found most effective in achieving the smoothing of tension signals and the impact of response time. The effect of window width on tension signals was investigated experimentally, with a focus on the tension response time during signal processing. Window width appeared to be an important parameter in smoothing algorithms because it affects the trade-off between signal smoothness and response time. The response time of the loess algorithm increased with the increase of window width, and it was demonstrated that a wider window would lead to smoother signal, but with slower response to tension changes. By analyzing the inflection points, the optimal window width of the Loess algorithm was determined to be 120, where the signals achieved the highest smoothness while maintaining an acceptable response time.

In order to further evaluate the effectiveness of the Loess algorithm, the processed tension signal was compared with the original tension waveform. The Loess algorithm successfully filtered out noise interference while accurately representing the original tension waveform. The signal processing results were compared with the original data, and the signal to noise ratio (SNR) was calculated to evaluate the filtering effect. The adaptive Loess algorithm was proven to effectively smooth tension fluctuations, and in all three cases under consideration, the signal-to-noise ratio of yarn tension signals was improved by 25.014%, 27.661%, and 25.276%, respectively. The results showed that the Loess algorithm achieves the highest signal-to-noise ratio for all three types of tension signals, and it effectively reduces noise interference while maintaining the characteristics of the signal, providing a smoother tension waveform. Overall, the research results confirmed the practical feasibility of the proposed adaptive Loess weighted regression yarn tension optimization method. The Loess algorithm is believed to be the best choice for smoothing tension signals due to its excellent noise reduction performance and minimal impact on response time.

Conclusion Through this study, we have successfully explored the impact of yarn tension variation on textile quality and proposed a yarn tension signal optimization method based on Loess weighted regression. Experimental results demonstrate that the yarn tension signal after Loess processing outperforms other algorithms, achieving a higher signal-to-noise ratio (32.186 dB). This validates the feasibility of the method for real-time yarn tension measurement and control in practical working environments. This research holds significant practical implications for the textile industry. Accurate real-time yarn tension measurement contributes to improving textile quality stability and production efficiency. Moreover, by optimizing yarn tension signals, the negative impact of yarn tension on knitted fabric quality can be minimized, reducing the possibility of producing defective products. Future research can further apply this method to industrial knitting machines and integrate it with other advanced technologies to enhance the accuracy and stability of yarn tension measurement. Additionally, exploring deeper relationships between yarn tension signals and textile quality will help optimize production processes and elevate textile quality. In summary, this study provides an effective solution for yarn tension measurement, fostering quality control and technological advancements in the textile sector. Continuous improvement and application of this method will lead the textile industry towards higher quality and greater efficiency.

Key words: yarn tension detection, odaptive, tension fluctuation, signal optimization, interference signal processing

中图分类号:

TS181.9

彭来湖, 侯良美, 齐育宝, 汝欣, 刘建廷. 基于自适应Loess的纱线张力信号处理方法[J]. 纺织学报, 2024, 45(02): 246-254.

PENG Laihu, HOU Liangmei, QI Yubao, RU Xin, LIU Jianting. Yarn tension signal processing method based on adaptive Loess principle[J]. Journal of Textile Research, 2024, 45(02): 246-254.

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信号种类	信噪比
信号种类	原始数据	Loess	SG	Adj
数据1	25.185	31.485	29.937	30.485
数据2	24.999	31.914	29.501	30.671
数据3	25.692	32.186	30.257	31.902

基于自适应Loess的纱线张力信号处理方法

Yarn tension signal processing method based on adaptive Loess principle

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