基於光體積變化描記圖個人特徵的壓力檢測模型之動態個人化

江健彰; Chien-Chang Chiang

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/101886

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	黃從仁	zh_TW
dc.contributor.advisor	Tsung-Ren Huang	en
dc.contributor.author	江健彰	zh_TW
dc.contributor.author	Chien-Chang Chiang	en
dc.date.accessioned	2026-03-05T16:28:34Z	-
dc.date.available	2026-03-06	-
dc.date.copyright	2026-03-05	-
dc.date.issued	2026	-
dc.date.submitted	2026-02-04	-
dc.identifier.citation	Almadhor, A., Sampedro, G. A., Abisado, M., Abbas, S., Kim, Y.-J., Khan, M. A., Baili, J., & Cha, J.-H. (2023). Wrist-based electrodermal activity monitoring for stress detection using federated learning. Sensors, 23(8), 3984. Can, Y. S., Chalabianloo, N., Ekiz, D., Fernandez-Alvarez, J., Riva, G., & Ersoy, C. (2020). Personal stress-level clustering and decision-level smoothing to enhance the performance of ambulatory stress detection with smartwatches. IEEE Access, 8, 38146-38163. Colligan, T. W., & Higgins, E. M. (2006). Workplace stress: Etiology and consequences. Journal of workplace behavioral health, 21(2), 89-97. Dai, R., Lu, C., Yun, L., Lenze, E., Avidan, M., & Kannampallil, T. (2021). Comparing stress prediction models using smartwatch physiological signals and participant self-reports. Computer Methods and Programs in Biomedicine, 208, 106207. De Vries, S., Smits, R., Tataj, M., Ronckers, M., Van Der Pol, M., Van Oost, F., Adam, E., Smaling, H., & Meinders, E. (2022). Accurate stress detection from novel real-time electrodermal activity signals and multi-task learning models. Cognit Comput Internet Things, 43, 111-117. Elzeiny, S., & Qaraqe, M. (2020). Stress classification using photoplethysmogram-based spatial and frequency domain images. Sensors, 20(18), 5312. Fan, B., Luo, K., Wang, P., & Foroughi, A. (2025). ARIMA‐Based Virtual Data Generation Using Deepfake for Robust Physique Test. International Journal of Intelligent Systems, 2025(1), 5533092. Graves, A. (2012). Long short-term memory. Supervised sequence labelling with recurrent neural networks, 37-45. Hochreiter, S., & Schmidhuber, J. (1997). Long short-term memory. Neural computation, 9(8), 1735-1780. Kim, H.-G., Cheon, E.-J., Bai, D.-S., Lee, Y. H., & Koo, B.-H. (2018). Stress and heart rate variability: a meta-analysis and review of the literature. Psychiatry investigation, 15(3), 235. LeCun, Y., Bottou, L., Bengio, Y., & Haffner, P. (2002). Gradient-based learning applied to document recognition. Proceedings of the IEEE, 86(11), 2278-2324. Liu, Z., Shi, Z., Zhang, G., Jung, J., & Li, M. (2024). Mental Stress Detection Using PPG Signals Based on Transformer-LSTM Model. 2024 IEEE International Conference on Bioinformatics and Biomedicine (BIBM), Makowski, D., Pham, T., Lau, Z. J., Brammer, J. C., Lespinasse, F., Pham, H., Schölzel, C., & Chen, S. A. (2021). NeuroKit2: A Python toolbox for neurophysiological signal processing. Behavior research methods, 53(4), 1689-1696. Miłkowski, M., Hensel, W. M., & Hohol, M. (2018). Replicability or reproducibility? On the replication crisis in computational neuroscience and sharing only relevant detail. Journal of computational neuroscience, 45(3), 163-172. Minakuchi, E., Ohnishi, E., Ohnishi, J., Sakamoto, S., Hori, M., Motomura, M., Hoshino, J., Murakami, K., & Kawaguchi, T. (2013). Evaluation of mental stress by physiological indices derived from finger plethysmography. Journal of physiological anthropology, 32(1), 17. Mukherjee, A., Mazumder, O., & Sinha, A. An Integrated Hidden Markov Model-Van der Pol Oscillator Based Atrial Fibrillation ECG Generator Model. Nkurikiyeyezu, K., Yokokubo, A., & Lopez, G. (2019). The effect of person-specific biometrics in improving generic stress predictive models. arXiv preprint arXiv:1910.01770. Oh, B., Hwang, J., Seo, S., Chun, S., & Lee, K.-H. (2021). Inductive Gaussian representation of user-specific information for personalized stress-level prediction. Expert Systems with Applications, 178, 114912. Oh, K., Park, H., Lee, G. H., & Choi, J. K. (2025). Supervised contrastive learning-based stress detection for wearable sensor-based healthcare applications. Future Generation Computer Systems, 108058. Paromita, P., Mundnich, K., Nadarajan, A., Booth, B. M., Narayanan, S. S., & Chaspari, T. (2023). Modeling inter-individual differences in ambulatory-based multimodal signals via metric learning: a case study of personalized well-being estimation of healthcare workers. Frontiers in Digital Health, 5, 1195795. Peabody, J. E., Ryznar, R., Ziesmann, M. T., Gillman, L., Ryznar, R. J., & Gillman, L. M. (2023). A systematic review of heart rate variability as a measure of stress in medical professionals. Cureus, 15(1). Pereira, T., Almeida, P. R., Cunha, J. P., & Aguiar, A. (2017). Heart rate variability metrics for fine-grained stress level assessment. Computer Methods and Programs in Biomedicine, 148, 71-80. Quick, J. D., Horn, R. S., & Quick, J. C. (2014). Health consequences of stress. In Job Stress (pp. 19-36). Routledge. Rafi, H., Benezeth, Y., Song, F. Y., Reynaud, P., Arnoux, E., & Demonceaux, C. (2024). Tree-based personalized clustered federated learning: A driver stress monitoring through physiological data case study. IEEE Internet of Things Journal. Rajeswari, S., Gomathi, R., & Sujitha, I. (2024). Tree-Based Multiclass Learning Model for Physiological Stress Detection from Students Community. 2024 International Conference on Intelligent Systems for Cybersecurity (ISCS), Rinkevičius, M., Kontaxis, S., Gil, E., Bailón, R., Lázaro, J., Laguna, P., & Marozas, V. (2019). Photoplethysmogram signal morphology-based stress assessment. 2019 Computing in Cardiology (CinC), Salazar-Martínez, E., Naranjo-Orellana, J., & Sarabia-Cachadiña, E. (2024). Heart rate variability: Obtaining the stress score from SDNN values. Isokinetics and Exercise Science, 32(4), 301-307. Sayadi, O., Shamsollahi, M. B., & Clifford, G. D. (2010). Synthetic ECG generation and Bayesian filtering using a Gaussian wave-based dynamical model. Physiological measurement, 31(10), 1309. Slavich, G. M. (2016). Life stress and health: A review of conceptual issues and recent findings. Teaching of Psychology, 43(4), 346-355. Tazarv, A., Labbaf, S., Reich, S. M., Dutt, N., Rahmani, A. M., & Levorato, M. (2021). Personalized stress monitoring using wearable sensors in everyday settings. 2021 43rd Annual International Conference of the IEEE Engineering in Medicine & Biology Society (EMBC), Teredesai, A. (2019). Optuna: A next-generation hyperparameter optimization framework. Applied Data Science Track Paper, 2623. Thayer, J. F., Åhs, F., Fredrikson, M., Sollers III, J. J., & Wager, T. D. (2012). A meta-analysis of heart rate variability and neuroimaging studies: implications for heart rate variability as a marker of stress and health. Neuroscience & Biobehavioral Reviews, 36(2), 747-756. Topalidou, M., Leblois, A., Boraud, T., & Rougier, N. P. (2015). A long journey into reproducible computational neuroscience. Frontiers in computational neuroscience, 9, 30. Tzevelekakis, K., Stefanidi, Z., & Margetis, G. (2021). Real-time stress level feedback from raw ecg signals for personalised, context-aware applications using lightweight convolutional neural network architectures. Sensors, 21(23), 7802. Wan, L., Wang, Q., Papir, A., & Moreno, I. L. (2018). Generalized end-to-end loss for speaker verification. 2018 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), Yang, Y.-Y., Hwang, A. H.-C., Wu, C.-T., & Huang, T.-R. (2022). Person-identifying brainprints are stably embedded in EEG mindprints. Scientific reports, 12(1), 17031. Yu, H., Vaessen, T., Myin-Germeys, I., & Sano, A. (2021). Modality fusion network and personalized attention in momentary stress detection in the wild. 2021 9th International Conference on Affective Computing and Intelligent Interaction (ACII),	-
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/101886	-
dc.description.abstract	近年偵測壓力的研究日益受到重視，然而大多著重於捕捉個體差異，無法泛化到未曾見過的樣本上，缺乏跨受試者的能力，因此，如何有效泛化至新樣本，成為重要的課題。本研究系統性模擬PPG資料，控制個體間變異、狀態內變異、狀態間變異、長度變異、人數變異，生成不同參數下的PPG訊號，並且比較以下三種模型的優劣，三種模型分別是通用模型與嵌入個人化特徵模型以及預訓練編碼器個人化特徵模型，除了比較個體內預測精準與否以外，也加入泛化能力上的測試。模擬結果顯示，不論是在何種參數設置底下，嵌入個人化特徵模型表現最為優異，預訓練編碼器個人化特徵模型稍稍落後於前者，代表從資料中學習並嵌入個人化特徵，有助於模型學習。同時除了在模擬資料上實驗，也將模型放置在真實的資料上，測試泛化能力，研究結果也表明，嵌入個人化特徵模型優異於通用模型。同時為驗證其在真實資料上是否也表現一致，本研究亦將上述的通用模型以及嵌入個人化特徵模型用於真實的資料，也驗證在真實資料上也保持相同的結果。	zh_TW
dc.description.abstract	In recent years, research on stress detection has attracted increasing attention. However, most existing studies primarily focus on capturing individual differences and therefore struggle to generalize to unseen subjects, resulting in limited cross-subject generalization capability. Consequently, how to effectively generalize to new individuals has become a critical research challenge. In this study, we systematically simulate photoplethysmography (PPG) data, controlling between-individual variability, within-state variability, between-state variability, signal length variability, and subject population size. Under different parameter configurations, synthetic PPG signals are generated to evaluate and compare the performance of three modeling approaches: a general model, a model with embedded personalized features, and a personalized-feature model based on a pretrained encoder. In addition to evaluating prediction accuracy at the individual level, we further assess the generalization capability of these models. The simulation results demonstrate that, across all parameter settings, the model with embedded personalized features consistently achieves the best performance, followed by the pretrained encoder–based personalized feature model. These findings suggest that learning and embedding personalized characteristics directly from the data substantially facilitates model learning. Beyond experiments on simulated data, the proposed models are also evaluated on real-world datasets to examine their generalization performance. The results consistently show that the model with embedded personalized features outperforms the general model. Furthermore, to verify the robustness of the findings, both the general model and the embedded personalized feature model are applied to real PPG data, confirming that the observed performance trends remain consistent in real-world scenarios.	en
dc.description.provenance	Submitted by admin ntu (admin@lib.ntu.edu.tw) on 2026-03-05T16:28:34Z No. of bitstreams: 0	en
dc.description.provenance	Made available in DSpace on 2026-03-05T16:28:34Z (GMT). No. of bitstreams: 0	en
dc.description.tableofcontents	致謝 i 摘要 ii Abstract iii 目次 v 圖次 vii 表次 viii 第一章緒論 1 1.1 研究動機 1 1.2 研究目的 2 1.3 研究背景 2 1.4 研究近況限制 3 第二章研究方法 8 2.1 模擬資料生成 8 2.2 模型設計 15 2.3 超參數調校 25 2.4 資料切分方式 28 2.5 評估表現方法 30 2.6 個人化特徵嵌入模型的訓練策略比較 38 2.7 本章總結 42 第三章實驗結果與分析(模擬資料) 43 3.1 個體內資料切分結果分析 43 3.2 個體間資料切分結果分析 48 3.3 比較結論 53 第四章實驗結果與分析(真實資料) 55 4.1 PPG-DaLiA資料集分析 55 4.2 自行實驗蒐集資料集分析 61 第五章綜合討論 68 5.1 研究回顧 68 5.2 研究結果 69 5.3 實際應用可能 70 5.4 研究限制 70 5.5 未來研究方向 71 5.6 最後結論 72 參考文獻 73 附錄A—LSTM模型超參數搜尋空間 77	-
dc.language.iso	zh_TW	-
dc.subject	壓力偵測	-
dc.subject	深度學習	-
dc.subject	個人化特徵	-
dc.subject	光體積變化描記圖	-
dc.subject	Stress Detection	-
dc.subject	Deep Learning	-
dc.subject	Personalized Features	-
dc.subject	Photoplethysmography	-
dc.title	基於光體積變化描記圖個人特徵的壓力檢測模型之動態個人化	zh_TW
dc.title	Dynamic Personalization of a Stress Detection Model using PPG-based Person Features	en
dc.type	Thesis	-
dc.date.schoolyear	114-1	-
dc.description.degree	碩士	-
dc.contributor.oralexamcommittee	黃春融;林書勤	zh_TW
dc.contributor.oralexamcommittee	Chun-Rong Huang;Shu-Chin LIN	en
dc.subject.keyword	壓力偵測,深度學習個人化特徵光體積變化描記圖	zh_TW
dc.subject.keyword	Stress Detection,Deep LearningPersonalized FeaturesPhotoplethysmography	en
dc.relation.page	78	-
dc.identifier.doi	10.6342/NTU202600488	-
dc.rights.note	未授權	-
dc.date.accepted	2026-02-06	-
dc.contributor.author-college	理學院	-
dc.contributor.author-dept	數學系	-
dc.date.embargo-lift	N/A	-
顯示於系所單位：	數學系

文件中的檔案：

檔案	大小	格式
ntu-114-1.pdf 未授權公開取用	2.65 MB	Adobe PDF

顯示文件簡單紀錄

系統中的文件，除了特別指名其著作權條款之外，均受到著作權保護，並且保留所有的權利。