基于机器学习模型的电子纺织品研究进展

doi:10.13475/j.fzxb.20250605302

纺织学报 ›› 2026, Vol. 47 ›› Issue (1): 268-276.doi: 10.13475/j.fzxb.20250605302

基于机器学习模型的电子纺织品研究进展

胡崴琳¹, 白洁², 刘丹², 白濛², 李娟², 李启正³()

1.浙江理工大学纺织科学与工程学院(国际丝绸学院), 浙江杭州 310018
2.中国纺织工程学会, 北京 100025
3.浙江理工大学数智出版研究所, 浙江杭州 310018

收稿日期:2025-06-25 修回日期:2025-11-10 出版日期:2026-01-15 发布日期:2026-01-15
通讯作者: 李启正(1981—),男,特聘研究员,博士。主要研究方向为纺织学术平台建设。Email:liqizheng@zstu.edu.cn。
作者简介:胡崴琳(1998—),男,博士生。主要研究方向为纺织知识图谱与多模态大模型。
基金资助:
中国科协全国学会服务国家战略专项资助项目(202481)

Research progress in e-textiles based on machine learning model

HU Weilin¹, BAI Jie², LIU Dan², BAI Meng², LI Juan², LI Qizheng³()

1. College of Textile Science and Engineering ( International Institute of Silk ), Zhejiang Sci-Tech University, Hangzhou, Zhejiang 310018, China
2. China Textile Engineering Society, Beijing 100025, China
3. Institute of Digital and Intelligent Publishing, Zhejiang Sci-Tech University, Hangzhou, Zhejiang 310018, China

Received:2025-06-25 Revised:2025-11-10 Published:2026-01-15 Online:2026-01-15

摘要/Abstract

摘要：

为了解机器学习模型在不同类型电子纺织品中的适用性及应用趋势,介绍了其在人机交互、运动分析与健康监测三大场景中的应用。通过剖析卷积神经网络(CNN)、长短期记忆网络(LSTM)、支持向量机(SVM)等经典机器学习模型的优缺点,阐述了模型特性与电子纺织品用途、结构之间的内在匹配关系。并从电子纺织品的信号处理,工艺优化,场景应用3个方面对机器学习技术的应用趋势进行梳理。结果表明:复杂模型在嵌入式设备中部署困难、面对用户和环境差异模型泛化能力欠缺、高性能与低成本难以兼顾是当前面临的三大挑战,未来可以向模型轻量化与云端协同推理、大规模多场景数据集构建、多目标优化策略等方向探索,以促进机器学习与电子纺织品的深度融合,推动其智能化升级与产业化落地。

关键词: 电子纺织品, 机器学习, 人机交互, 运动分析, 健康监测, 柔性传感器, 智能纺织品

Abstract:

Significance E-textiles, which integrate sensing, communication, and interactive capabilities into fabrics through embedded flexible electronics, are heralding a transformative shift in the textile industry. These smart textiles have the potential to revolutionize various domains, including human-computer interaction, motion analysis, and health monitoring, by offering versatile applications that go beyond conventional garment functionality. However, the widespread adoption of e-textiles is currently hindered by several challenges. Key barriers include the complexity of adapting machine learning (ML) models to meet the demanding computational constraints of embedded devices, the difficulty of generalizing models across a diverse range of users, and the high costs associated with optimizing both materials and production processes. Despite the significant potential of e-textiles, existing research has yet to systematically explore the inherent relationships between ML models and the various e-textile structures and applications. The matching of specific ML models to the unique characteristics of e-textile structures and their intended use cases remains an unresolved challenge. By addressing this gap, the review seeks to offer valuable insights that will inform the development of intelligent, efficient, and deployable textile systems, facilitating their transition from lab prototypes to practical, real-world applications.

Progress The review examines the evolving role of machine learning in e-textiles along three key dimensions: past developments, current trends, and future directions. Historically, the application of ML models in e-textiles has been shaped by the interplay between model characteristics, the structural properties of e-textiles, and the requirements of different application scenarios. The review discusses how specific ML models have been adapted to address various needs, including human-computer interaction, motion analysis, and health monitoring. For each of these applications, the strengths and weaknesses of the algorithms are critically assessed, providing a comprehensive understanding of their effectiveness in real-world contexts. Additionally, the review highlights a series of documented cases and statistically analyzes the correlations between e-textile structures, the best-performing ML models, and application-specific requirements. These relationships are visually represented through Sankey diagrams, illustrating how the structural characteristics of e-textiles influence the selection of appropriate ML models for different application contexts. The review also identifies key trends currently shaping the field, including the integration of ML in signal processing, process optimization, and scenario-based implementations. By analyzing the temporal evolution of relevant literature, the review offers a snapshot of ongoing advancements and the trajectory of these developments.

Conclusion and Prospect The review concludes that the successful integration of ML models in e-textiles is largely dependent on the specific use case, data characteristics, and the inherent structure of the textile system. ML models like CNNs, LSTMs, and SVMs have demonstrated significant progress in enhancing performance across key application areas, including human-computer interaction, motion analysis, and health monitoring. CNNs, for example, excel in handling spatially rich data, such as pressure distribution images, making them ideal for applications like gesture recognition and handwriting analysis. LSTMs are particularly effective at modeling temporal dependencies, which is crucial for applications involving continuous motion signals. SVMs, on the other hand, offer efficiency and robustness, particularly in scenarios with limited data and well-defined features, making them a popular choice for health monitoring applications. The field is experiencing three major shifts: the movement from simple classification tasks to the decoupling of multi-modal signals in signal processing; the transition from experience-based trial-and-error approaches to model-driven optimization in manufacturing; and the evolution from generalized monitoring to personalized, precision services in application contexts. Despite these advancements, challenges remain, such as the need for lightweight models that can operate within the computational constraints of embedded devices, the difficulty of ensuring model generalization across diverse user populations, and the high cost of optimizing performance. Future research should focus on developing more efficient, lightweight models, enhancing model generalization with diverse and large datasets, and incorporating cost considerations into the design and optimization of ML-driven e-textiles. By addressing these challenges, the review lays a foundational framework for matching ML models with e-textile applications, which will be crucial in driving the intelligent development and industrial scalability of this emerging technology.

Key words: electronic textiles, machine learning, human-computer interaction, motion analysis, health monitoring, flexible sensor, smart textiles

中图分类号:

TP212

胡崴琳, 白洁, 刘丹, 白濛, 李娟, 李启正. 基于机器学习模型的电子纺织品研究进展[J]. 纺织学报, 2026, 47(1): 268-276.

HU Weilin, BAI Jie, LIU Dan, BAI Meng, LI Juan, LI Qizheng. Research progress in e-textiles based on machine learning model[J]. Journal of Textile Research, 2026, 47(1): 268-276.

导出引用管理器 EndNote|Reference Manager|ProCite|BibTeX|RefWorks

链接本文: http://www.fzxb.org.cn/CN/10.13475/j.fzxb.20250605302

http://www.fzxb.org.cn/CN/Y2026/V47/I1/268

图/表 7

图1

表1

表2

表3

图2

图3

图4

参考文献 64

[1]	BERZOWSKA J. Electronic textiles: wearable computers, reactive fashion, and soft computation[J]. TEXTILE, 2005, 3(1): 58-75. doi: 10.2752/147597505778052639
[2]	AHMAD M M, AHUJA K. E-textiles: a revolutionary technology[J]. International Journal of System Assurance Engineering and Management, 2023, 14(6): 2031-2047.
[3]	TIAN Y C, DING R D, YOON S S, et al. Recent advances in next-generation textiles[J]. Advanced Materials, 2025, 37(8): 2417022. doi: 10.1002/adma.v37.8
[4]	MU G R, ZHANG Y, YAN Z H, et al. Recent advancements in wearable sensors: integration with machine learning for human-machine interaction[J]. RSC Advances, 2025, 15(10): 7844-7854. doi: 10.1039/D5RA00167F
[5]	SHEN T C, DI GIULIO I, HOWARD M. Human movement prediction with wearable sensors on loose clothing[C]// 2024 IEEE-RAS 23rd International Conference on Humanoid Robots (Humanoids). New York: IEEE, 2024: 483-490.
[6]	CESARELLI G, DONISI L, COCCIA A, et al. The e-textile for biomedical applications: a systematic review of literature[J]. Diagnostics, 2021, 11(12): 1-28. doi: 10.3390/diagnostics11010001
[7]	LUO Q S. Implementation method of intelligent emotion-aware clothing systembased on nanofibre technology[J]. Industria Textila, 2024, 75(1): 3-14. doi: 10.35530/IT
[8]	BATY F, CVETKOVIC D, BOESCH M, et al. Validation of a textile-based wearable measuring electrocardiogram and breathing frequency for sleep apnea monitoring[J]. Sensors, 2024, 24(19): 1-10. doi: 10.3390/s24010001
[9]	KWON K, LEE Y J, CHUNG S, et al. Full body-worn textile-integrated nanomaterials and soft electronics for real-time continuous motion recognition using cloud computing[J]. ACS Applied Materials & Interfaces, 2025, 17(5): 7977-7988.
[10]	LI J Q, HE X J, KE L, et al. Hierarchically nano-decorated poly(lactic acid) nanofibers for humidity-resistant respiratory healthcare and high-accuracy disease diagnosis[J]. ACS Applied Materials & Interfaces, 2024, 16(39): 52476-52486.
[11]	WEN F, SUN Z D, HE T, et al. Machine learning glove using self-powered conductive superhydrophobic triboelectric textile for gesture recognition in VR/AR applications[J]. Advanced Science, 2020, 7(14): 2000261. doi: 10.1002/advs.v7.14
[12]	GAO Y Y, ZONG R S, FENG J Y, et al. Flexible self-powered and self-sensing shoes based on aeroelastic structure for application in human motion moni-toring[J]. Journal of Power Sources, 2025, 638: 236626. doi: 10.1016/j.jpowsour.2025.236626
[13]	WANG J, ZHANG R, WANG Y F, et al. Highly sensitive, breathable, and superhydrophobic dome structure nonwoven-based flexible pressure sensor utilizing machine learning for handwriting recog-nition[J]. International Journal of Biological Macromolecules, 2025, 300: 139838. doi: 10.1016/j.ijbiomac.2025.139838
[14]	GUO L, LU Z X, YAO L G. Human-machine interaction sensing technology based on hand gesture recognition: a review[J]. IEEE Transactions on Human-Machine Systems, 2021, 51(4): 300-309. doi: 10.1109/THMS.2021.3086003
[15]	CUI L L, HU C Y, WANG W, et al. An adhesive, stretchable, and freeze-resistant conductive hydrogel strain sensor for handwriting recognition and depth motion monitoring[J]. Journal of Colloid and Interface Science, 2025, 677: 273-281. doi: 10.1016/j.jcis.2024.07.214 pmid: 39094488
[16]	KAUR S, KULKARNI N. Recent trends and challenges in human computer interaction using automatic emotion recognition: a review[J]. International Journal of Biometrics, 2024, 16(1): 16-43. doi: 10.1504/IJBM.2024.135160
[17]	WANG D P, WANG M Y, ZHANG Z Q, et al. Wearable electronic glove and multilayer para-LSTM-CNN-based method for sign language recognition[J]. IEEE Internet of Things Journal, 2024, 11(24): 40787-40799. doi: 10.1109/JIOT.2024.3454215
[18]	JIN W Y, PEI J Y, CAO Y T, et al. Intelligent flexible pressure sensors with improved sensing range and sensitivity based on 3D-graphene patterning induced by UV laser[J]. ACS Applied Materials & Interfaces, 2024, 16(48): 66763-66772.
[19]	SHAO Q Y, ZHANG Y L, LIU J, et al. Investigation of flexible graphene hybrid knitted sensor for joint motion recognition based on convolutional neural network fusion long short-term memory network[J]. Journal of Industrial Textiles, 2024, 54: 15280837231225827. doi: 10.1177/15280837231225827
[20]	LIU L, HU T, ZHAO X M, et al. Innovative smart gloves with Phalanges-based triboelectric sensors as a dexterous teaching interface for Embodied Artificial Intelligence[J]. Nano Energy, 2025, 133: 110491. doi: 10.1016/j.nanoen.2024.110491
[21]	KIM D, MIN J, KO S H. Recent developments and future directions of wearable skin biosignal sensors[J]. Advanced Sensor Research, 2024, 3(2): 2300118. doi: 10.1002/adsr.v3.2
[22]	ZENG X H, HU M L, HE P, et al. Highly conductive carbon-based e-textile for gesture recognition[J]. IEEE Electron Device Letters, 2023, 44(5): 825-828. doi: 10.1109/LED.2023.3263170
[23]	WANG N C, YAO Y, WU P G, et al. Soft polymer optical fiber sensors for intelligent recognition of elastomer deformations and wearable applications[J]. Sensors, 2024, 24(7): 1-11. doi: 10.3390/s24010001
[24]	WANG F L, WANG H, WU L, et al. Improved morse code recognition and real-time translation system based on a low-cost, tailorable flexible capacitive sensor[J]. ACS Applied Electronic Materials, 2025, 7(1): 388-399. doi: 10.1021/acsaelm.4c01850
[25]	NA W D, XU C, AN L, et al. Alkali ion-accelerated gelation of MXene-based conductive hydrogel for flexible sensing and machine learning-assisted recog-nition[J]. Gels, 2024, 10(11): 1-15. doi: 10.3390/gels10010001
[26]	WANG J, ZHANG R, WANG Y F, et al. Highly sensitive, breathable, and superhydrophobic dome structure nonwoven-based flexible pressure sensor utilizing machine learning for handwriting recogni-tion[J]. International Journal of Biological Macromolecules, 2025, 300: 139838. doi: 10.1016/j.ijbiomac.2025.139838
[27]	YANG J, WANG R, GUAN X, et al. AI-enabled emotion-aware robot: the fusion of smart clothing, edge clouds and robotics[J]. Future Generation Computer Systems, 2020, 102: 701-709. doi: 10.1016/j.future.2019.09.029
[28]	吴学奎, 任立红, 丁永生, 等. 面向智能服装的多生理信息融合的情绪判别[J]. 计算机工程与应用, 2009, 45(33): 218-221, 235.
	WU Xuekui, REN Lihong, DING Yongsheng, et al. Multi-physiology information fusion for emotion distinction in smart clothing[J]. Computer Engineering and Applications, 2009, 45(33): 218-221, 235. doi: 10.3778/j.issn.1002-8331.2009.33.069
[29]	LONG K X, SU C C, HU C X, et al. Stretchable, conductive Hydrogel-Based triboelectric nanogenerator integrated with deep learning algorithm for character recognition[J]. Chemical Engineering Journal, 2024, 499: 155919. doi: 10.1016/j.cej.2024.155919
[30]	ZHENG Z T, HUANG Z B, ZHANG N, et al. Stretch-tolerant interconnects derived from silanization-assisted capping layer lamination for smart skin-attachable electronics[J]. Materials Today Physics, 2024, 46: 101494. doi: 10.1016/j.mtphys.2024.101494
[31]	MA S Q, WANG X Y, LI P, et al. Optical micro/nano fibers enabled smart textiles for human-machine inter-face[J]. Advanced Fiber Materials, 2022, 4(5): 1108-1117. doi: 10.1007/s42765-022-00163-6
[32]	CHEN K X, ZHANG D L, YAO L N, et al. Deep learning for sensor-based human activity recognition: overview, challenges, and opportunities[J]. ACM Computing Surveys, 2021, 54(4): 1-40.
[34]	LIU J Y, TAN X, JIA X H, et al. A gait phase recognition method for obstacle crossing based on multi-sensor fusion[J]. Sensors and Actuators A: Physical, 2024, 376: 115645. doi: 10.1016/j.sna.2024.115645
[35]	YANG F, ZHENG Q Q, CHEN L Q, et al. Research on human behavior intention perception method based on wearable sensors[J]. IEEE Access, 2024, 12: 70278-70288. doi: 10.1109/ACCESS.2024.3401685
[36]	YI S J, MEI Z Y, IVANOV K, et al. Gait-based identification using wearable multimodal sensing and attention neural networks[J]. Sensors and Actuators A: Physical, 2024, 374: 115478. doi: 10.1016/j.sna.2024.115478
[37]	HASAN S M, D'AURIA B G, PARVEZ MAHMUD M A, et al. AI-aided gait analysis with a wearable device featuring a hydrogel sensor[J]. Sensors, 2024, 24(22): 1-14. doi: 10.3390/s24010001
[38]	XIANG K Y, LIU M J, CHEN J, et al. AI-assisted insole sensing system for multifunctional plantar-healthcare applications[J]. ACS Applied Materials & Interfaces, 2024, 16(25): 32662-32678.
[39]	ZOU H L, CHEN Z J, ZHANG C Y, et al. STFNet: enhanced and lightweight spatiotemporal fusion network for wearable human activity recognition[J]. IEEE Sensors Journal, 2024, 24(8): 13686-13698. doi: 10.1109/JSEN.2024.3373444
[40]	QIU J G, LI Y, LI H, et al. Wearable Sensor-based physical activity intensity recognition using deep learning feature engineering fusion[J]. Measurement, 2025, 241: 115663. doi: 10.1016/j.measurement.2024.115663
[41]	NUNES W A, REUSCH R S, LUZA L, et al. Deploying human activity recognition in embedded RISC-V processors: deploying human activity recognition in embedded RISC-V processors[J]. Design Automation for Embedded Systems, 2024, 28(3): 187-217. doi: 10.1007/s10617-024-09288-w
[42]	MEKRUKSAVANICH S, JITPATTANAKUL A, MEKRUKSAVANICH S, et al. Deep residual network with a CBAM mechanism for the recognition of symmetric and asymmetric human activity using wearable sensors[J]. Symmetry, 2024, 16(5): 1-26. doi: 10.3390/sym16010001
[43]	AISYAH NURMAULIA ENTIFAR S, AQILLA ELLENAHAYA ENTIFAR N, FITRIAN WIBOWO A, et al. Extremely-low electrical-hysteresis hydrogels for multifunctional wearable sensors and osmotic power generators[J]. Chemical Engineering Journal, 2025, 509: 160971. doi: 10.1016/j.cej.2025.160971
[44]	LIN Y K, SUN M Z, LI F M, et al. A triboelectric smart carpet with an optimized braided structure for cruise ship monitoring enabled by deep learning[J]. Materials Today Communications, 2024, 38: 108184. doi: 10.1016/j.mtcomm.2024.108184
[45]	COSTANZO I, SEN D, RHEIN L, et al. Respiratory monitoring: current state of the art and future roads[J]. IEEE Reviews in Biomedical Engineering, 2022, 15: 103-121. doi: 10.1109/RBME.2020.3036330
[46]	Dash P K. Electrocardiogram monitoring[J]. Indian Journal of Anaesthesia, 2002, 46(4): 251-260.
[47]	NIU J Q, LIN S J, CHEN D, et al. A fully elastic wearable electrochemical sweat detection system of tree-bionic microfluidic structure for real-time moni-toring[J]. Small, 2024, 20(11): 2306769. doi: 10.1002/smll.v20.11
[48]	PALUMBO A, VIZZA P, CALABRESE B, et al. Biopotential signal monitoring systems in rehabilitation: a review[J]. Sensors, 2021, 21(21): 1-22. doi: 10.3390/s21010001
[49]	DING T Y, GAGLIANO L, JAHANI A, et al. Epileptic seizure forecasting with wearable-based nocturnal sleep features[J]. Epilepsia Open, 2024, 9(5): 1793-1805. doi: 10.1002/epi4.v9.5
[50]	CARBONARO N, LAURINO M, ARCARISI L, et al. Textile-based pressure sensing matrix for in-bed monitoring of subject sleeping posture and breathing activity[J]. Applied Sciences, 2021, 11(6): 1-14. doi: 10.3390/app11010001
[51]	卢妍, 洪岩, 方剑. 智能背景下机器学习在柔性应变传感器中的应用研究进展[J]. 纺织学报, 2024, 45(5): 228-238.
	LU Yan, HONG Yan, FANG Jian. Research progress on applications of machine learning in flexible strain sensors in context of material intelligence[J]. Journal of Textile Research, 2024, 45(5): 228-238.
[52]	BHONGADE A, GUPTA R, PRATHOSH A P, et al. ResPara-net: respiration parameter estimation using wearable single inertial measurement unit sensor and deep learning[J]. IEEE Sensors Journal, 2024, 24(15): 24931-24944. doi: 10.1109/JSEN.2024.3408464
[53]	BATY F, CVETKOVIC D, BOESCH M, et al. Validation of a textile-based wearable measuring electrocardiogram and breathing frequency for sleep apnea monitoring[J]. Sensors, 2024, 24(19): 1-10. doi: 10.3390/s24010001
[54]	ZHAO Z L, YANG J X, LIU J H, et al. Application of additive manufacturing and deep learning in exercise state discrimination[J]. Sensors, 2025, 25(2): 1-20. doi: 10.3390/s25010001
[55]	CHENANI H, RAZAGHI Z, SAEIDI M, et al. A stretchable, adhesive, and wearable hydrogel-based patches based on a bilayer PVA composite for online monitoring of sweat by artificial intelligence-assisted smartphones[J]. Talanta, 2025, 287: 127640. doi: 10.1016/j.talanta.2025.127640
[56]	EJUPI A, MENON C, EJUPI A, et al. Detection of talking in respiratory signals: a feasibility study using machine learning and wearable textile-based sensors[J]. Sensors, 2018, 18(8): 1-12. doi: 10.3390/s18010001
[57]	CHEN X W, JIANG X, FANG J W, et al. DisPad: flexible on-body displacement of fabric sensors for robust joint-motion tracking[J]. Proceedings of the ACM on Interactive, Mobile, Wearable and Ubiquitous Technologies, 2023, 7(1): 1-27.
[58]	谢浩月, 唐虹, 顾琳燕, 等. 基于温湿度监测功能的智能消防内衣研究[J]. 针织工业, 2019(5): 58-62.
	XIE Haoyue, TANG Hong, GU Linyan, et al. Study on smart fire-fighting underwear based on temperature and humidity monitoring function[J]. Knitting Industries, 2019(5): 58-62.
[59]	KOUCHEHBAGHI N H, YOUSEFZADEH M, GHAREHAGHAJI A, et al. A machine learning-guided design and manufacturing of wearable nanofibrous acoustic energy harvesters[J]. Nano Research, 2024, 17(10): 9181-9192. doi: 10.1007/s12274-024-6613-6
[60]	KE J M, LIU F R, XU G F, et al. Data-driven strain sensor design based on a knowledge graph frame-work[J]. Sensors, 2024, 24(17): 1-16. doi: 10.3390/s24010001
[61]	LIU T, ZHANG M Y, LI Z H, et al. Machine learning-assisted wearable sensing systems for speech recognition and interaction[J]. Nature Communications, 2025, 16: 2363. doi: 10.1038/s41467-025-57629-5
[62]	ZHOU Y, GUO S, ZHOU Y, et al. Ionic composite nanofiber membrane-based ultra-sensitive and anti-interference flexible pressure sensors for intelligent sign language recognition[J]. Advanced Functional Materials, 2025, 35(29): 2425586. doi: 10.1002/adfm.v35.29
[63]	ABU JARAD N, PRASAD A, RAHMANI S, et al. Smart fabrics with integrated pathogen detection, repellency, and antimicrobial properties for healthcare applications[J]. Advanced Functional Materials, 2024, 34(41): 2403157. doi: 10.1002/adfm.v34.41
[64]	ELSHEAKH D N, FAHMY O M, FAROUK M, et al. An early breast cancer detection by using wearable flexible sensors and artificial intelligent[J]. IEEE Access, 2024, 12: 48511-48529. doi: 10.1109/ACCESS.2024.3380453

Metrics

Viewed

Full text

Abstract

Cited

Shared

Discussed

应用场景	机器学习模型	优点	不足
手势识别	LSTM	擅长处理时间序列数据^[17-18];避免梯度消失问题^[17]	捕捉空间特征方面存在局限^[17];对复杂动态信号的特征提取能力有限^[19]
	CNN	自动提取特征,与LSTM结合可较好处理时空任务^[17]	处理时间序列数据表现较差^[17,20]
	SVM	小样本高准确率;参数少易调参;泛化能力强、稳健性好^[21];资源占用低^[22];算法简洁、运行速度快^[23]	难以处理高维时空特征^[17],在复杂或多类手势识别性能较差^[22]
手写识别	CNN	提取局部空间特征^[24]	处理纯时间序列任务时性能欠佳^[24]; 模型复杂度较高^[25]
手写识别	SVM	小数据集上高精度;稳健性强;计算效率高^[26]	依赖手动特征工程^[26]
情感识别	CNN	自动从图像数据中提取空间特征^[27]	存在过拟合倾向; 对数据质量敏感^[27]
情感识别	SVM	小样本场景下表现稳健;泛化性好^[28]	依赖数据质量^[28]

应用场景	机器学习模型	优点	不足
步态分析	LSTM	擅长处理时间序列数据^[34]	存在过拟合的风险^[35]
步态分析	CNN	自动提取特征^[36-37];有效提取压力分布空间特征^[34]	计算成本高^[36];面临梯度消失或爆炸^[38]
活动识别	LSTM	擅长捕捉数据的时间特征^[39-40]	高计算资源需求^[41-42]
	CNN	自动提取特征^[39]	缺乏时间感知能力^[34]
	KNN	区分基本活动性能较好^[43]	复杂动作分类较弱^[43]

应用场景	机器学习模型	优点	不足
呼吸监测	SVM	稳健性好、易训练^[49];多参数处理优异^[50];适合小样本机器学习,避开高维空间的复杂性^[51]	依赖人工特征工程,对图像或原始波形数据的处理能力有限^[49]
呼吸监测	CNN	慢速呼吸率下性能稳定^[52]	受咳嗽、运动等行为影响^[52]
心电监测	SVM	稳健性强;易训练^[49];多生理参数处理优异^[53];适合小样本学习,避开了高维空间的复杂性^[51]	需手动提取特征^[54]
心电监测	LSTM	自动识别相关特征^[54]	模型复杂度较高^[54]
汗液监测	SVM	在预测pH值时表现出高效和非线性处理能力^[55]	图像特征提取能力较弱^[55]
肌电监测	SVM	高效识别生物信号^[54]	需手动提取特征,复杂信号处理效果受限^[54]

基于机器学习模型的电子纺织品研究进展

Research progress in e-textiles based on machine learning model

RichHTML

PDF (PC)

摘要/Abstract

引用本文

使用本文

图/表 7

参考文献 64

相关文章 15

Metrics

本文评价

推荐阅读 0

[1]	刘一鸣, 李琳, 杜鲜晶, 刘攀, 殷霞, 田明伟. 内螺旋结构弹性导电纱线的制备及其应变不敏感性能的调控[J]. 纺织学报, 2026, 47(1): 115-122.
[2]	邵剑波, 岳欣琰, 陈雨, 韩潇, 洪剑寒. 全针织结构多模态柔性电容传感器的构筑及其传感性能[J]. 纺织学报, 2026, 47(1): 123-131.
[3]	张宁讴, 王海龙, 胡星友, 孙彬, 游超瑜. 电致发光纤维的技术创新与研究进展[J]. 纺织学报, 2026, 47(1): 250-258.
[4]	张莹, 郭明靖, 王利君. 针织结构温度传感器设计及其着装传感性能[J]. 纺织学报, 2025, 46(12): 123-132.
[5]	王梁宇, 高晓红, 于彩娇, 张雪婷, 杨旭礼. 还原氧化石墨烯/铜纳米颗粒导电棉织物的制备及其传感性能[J]. 纺织学报, 2025, 46(12): 181-187.
[6]	季巧, 于清源, 周爱晖, 马博谋, 徐进, 袁久刚. 细菌纤维素及其复合材料的应用研究进展[J]. 纺织学报, 2025, 46(12): 243-250.
[7]	周青青, 常硕, 毛志平, 吴伟. 人工智能在纺织印染行业中的应用研究进展[J]. 纺织学报, 2025, 46(12): 260-269.
[8]	邓云涛, 谭艳君, 张洪松, 燕雨, 余秋雨, 林风喜, 王一鑫, 安乐乐. 织物起毛起球等级评定系统[J]. 纺织学报, 2025, 46(11): 102-110.
[9]	张帆, 蔡再生, 刘慧景, 陆少锋, 黄旭明. 高牢固光致变色棉织物的点击化学法制备及其性能[J]. 纺织学报, 2025, 46(11): 196-202.
[10]	刘飞, 刘璐, 郑智超, 刘俊宏, 吴德群, 蒋秋冉. 自黏型玉米醇溶蛋白基超细纤维膜的制备及其性能[J]. 纺织学报, 2025, 46(11): 34-42.
[11]	王莎莎, 李超婧, 李彦, 毛吉富, 王富军, 王璐. 智能可穿戴健康纺织品应用研究进展[J]. 纺织学报, 2025, 46(10): 265-273.
[12]	赵捷清, 王瑧, 秦孝天, 王成成, 张丽平. 模拟绿叶颜色变化的温致变色织物制备及其性能[J]. 纺织学报, 2025, 46(09): 19-26.
[13]	傅林, 钱建华, 单江音, 林灵, 卫梦蓉, 翁可欣, 吴晓睿. 银纳米线/聚氨酯纳米纤维膜柔性传感器制备及其性能[J]. 纺织学报, 2025, 46(09): 74-83.
[14]	权英, 张爱琴, 张曼, 刘淑强, 张钰晶. 基于三维编织结构的柔性应变传感器制备及其性能[J]. 纺织学报, 2025, 46(08): 136-144.
[15]	张清扬, 朱世根, 白云峰, 董威威, 骆祎岚. 基于机器学习的精细薄长零件一致性检测方法[J]. 纺织学报, 2025, 46(08): 226-235.