Deep Learning Empowered Water Quality Assessment: Leveraging IoT Sensor Data with LSTM Models and Interpretability Techniques

Authors

  • Sindhu Achuthankutty Faculty of Engineering (ISE),Chulalongkorn University, Bangkok, Thailand
  • Padma M University College of Engineering Tiruchirapalli BIT campus
  • Deiwakumari K Department of Mathematics, Sona College of Technology, Salem
  • Kavipriya P KPR College of Arts Science and Research
  • prathipa R Panimalar Engineering College, Chennai

DOI:

https://doi.org/10.22399/ijcesen.512

Keywords:

Fine-tuning Parameters, Water quality, Deep Learning Techniques, IoT Sensor Datasets, LSTM Models

Abstract

Addressing the imperative demand for accurate water quality assessment, this paper delves into the application of deep learning techniques, specifically leveraging IoT sensor datasets for the classification and prediction of water quality parameters. The utilization of LSTM (Long Short-Term Memory) models navigates the intricacies inherent in environmental data, emphasizing the balance between model accuracy and interpretability. This equilibrium is achieved through the deployment of interpretability methods such as LIME, SHAP, Anchor, and LORE. Additionally, the incorporation of advanced parameter optimization techniques focuses on fine-tuning essential parameters like learning rates, batch sizes, and epochs to optimize model performance. This comprehensive approach ensures not only precise predictions but also enhances the transparency and interpretability of the model, addressing the critical need for actionable information in water quality management. The research significantly contributes to the convergence of deep learning, IoT, and environmental science, offering valuable tools for informed decision-making while highlighting the importance of fine-tuning parameters for optimal model performance

References

Essamlali, I., Nhaila, H., & El Khaili, M. (2024). Advances in machine learning and IoT for water quality monitoring: A comprehensive review. Heliyon, 10(6), e27920.

Wang, Q., Lin, J., Guo, W., Liu, S., Zeng, X., & Xu, Y. (2020). A CNN-LSTM hybrid model for real-time water quality prediction based on limited historical data. Environmental Science and Pollution Research, 27(23), 32883-32893.

Niu, J., Zhang, H., Wang, X., & Sheng, Y. (2021). Attention-based LSTM for water quality prediction using IoT sensors. Sensors (Switzerland), 21(12), 4254.

Zhang, Y., Li, X., Wang, Z., & Peng, J. (2019). Deep learning for real-time water quality parameter prediction based on IoT devices. Journal of Sensors,

Kaur, P., Saini, V., & Singh, H. (2022, September). Explainable LSTM with SHAP for water quality prediction using IoT sensors. In 2022 International Conference on Machine Learning, Big Data, Cloud and Parallel Computing (COMLBCP) (pp. 1-6). IEEE.

Al-Barakati, A., Al-Saggaf, A., Ali, M., & Shahabi, M. (2020). A Long Short-Term Memory (LSTM) based deep learning model for water quality prediction. Sensors (Switzerland), 20(23), 6790.

JongCheol Pyo, Yakov Pachepsky, Soobin Kim, Ather Abbas, Minjeong Kim, Yong Sung Kwon, Mayzonee Ligaray, Kyung Hwa Cho, (2023). Long short-term memory models of water quality in inland water environments, Water Research X, 21;100207. https://doi.org/10.1016/j.wroa.2023.100207

Chen, H.; Yang, J.; Fu, X.; Zheng, Q.; Song, X.; Fu, Z.; Wang, J.; Liang, Y.; Yin, H.; Liu, Z.; et al. (2022). Water Quality Prediction Based on LSTM and Attention Mechanism: A Case Study of the Burnett River, Australia. Sustainability, 14, 13231. https://doi.org/10.3390/su142013231

Khokhar, F.A., Shah, J.H., Saleem, R. et al. (2024). Harnessing deep learning for faster water quality assessment: identifying bacterial contaminants in real time. Vis Comput (2024). DOI:10.1007/s00371-024-03382-7

Wang, H.; Xiao, N. (2023). Underwater Object Detection Method Based on Improved Faster RCNN. Appl. Sci., 13(4), 2746; https://doi.org/10.3390/app13042746

Zhou, J.; Wang, J.; Chen, Y.; Li, X.; Xie, Y. (2021). Water Quality Prediction Method Based on Multi-Source Transfer Learning for Water Environmental IoT System. Sensors 21, 7271.

N. Radhakrishnan and A. S. Pillai, (2020). Comparison of Water Quality Classification Models using Machine Learning. 2020 5th International Conference on Communication and Electronics Systems (ICCES), Coimbatore, India, pp. 1183-1188.

N. Abulail, A. Y. Owda and M. Owda, (2023). Water Quality Classification Decision Support System. 2023 International Conference on Information Technology (ICIT), Amman, Jordan, pp. 73-78.

Shehab, S.A., Darwish, A., Hassanien, A.E. et al. (2023) Water quality classification model with small features and class imbalance based on fuzzy rough sets. Environ Dev Sustain. DOI:10.1007/s10668-023-03916-4

Kaur, A., Khurana, M., Kaur, P., Kaur, M. (2021). Classification and Analysis of Water Quality Using Machine Learning Algorithms. In: Sabut, S.K., Ray, A.K., Pati, B., Acharya, U.R. (eds) Proceedings of International Conference on Communication, Circuits, and Systems. Lecture Notes in Electrical Engineering, vol 728. Springer, Singapore.

Maheshwari, R.U., Kumarganesh, S., K V M, S. et al. (2024). Advanced Plasmonic Resonance-enhanced Biosensor for Comprehensive Real-time Detection and Analysis of Deepfake Content. Plasmonics. https://doi.org/10.1007/s11468-024-02407-0

Maheshwari, R. U., Paulchamy, B., Arun, M., Selvaraj, V., & Saranya, N. N. (2024). Deepfake Detection using Integrate-backward-integrate Logic Optimization Algorithm with CNN. International Journal of Electrical and Electronics Research, 12(2), 696-710.

Maheshwari, R. U., & Paulchamy, B. (2024). Securing online integrity: a hybrid approach to deepfake detection and removal using Explainable AI and Adversarial Robustness Training. Automatika, 65(4), 1517-1532. DOI:10.1080/00051144.2024.2400640

Sood, K., Dhanaraj, R. K., Balusamy, B., Grima, S., & Uma Maheshwari, R. (Eds.). (2022). Big Data: A game changer for insurance industry. Emerald Publishing Limited.

Janarthanan, R., Maheshwari, R. U., Shukla, P. K., Shukla, P. K., Mirjalili, S., & Kumar, M. (2021). Intelligent detection of the PV faults based on artificial neural network and type 2 fuzzy systems. Energies, 14(20), 6584. DOI:10.3390/en14206584

Appalaraju, M., Sivaraman, A. K., Vincent, R., Ilakiyaselvan, N., Rajesh, M., & Maheshwari, U. (2021). Machine learning-based categorization of brain tumor using image processing. In Artificial Intelligence and Technologies: Select Proceedings of ICRTAC-AIT 2020 (pp. 233-242). Singapore: Springer Singapore.

Sasikala, S., Sasipriya, S., & Maheshwari, U. (2022, March). Soft Computing based Brain Tumor Categorization with Machine Learning Techniques. In 2022 International Conference on Advanced Computing Technologies and Applications (ICACTA) (pp. 1-9). IEEE.

Rajendran, U. M., & Paulchamy, J. (2021). Analysis and classification of gait characteristics. Iconic Research and Engineering Journals, 4(12).

Maheshwari, R. U., Paulchamy, B., Pandey, B. K., & Pandey, D. (2024). Enhancing Sensing and Imaging Capabilities Through Surface Plasmon Resonance for Deepfake Image Detection. Plasmonics, 1-20. DOI:10.1007/s11468-024-02492-1

Maheshwari, R. U., Jayasutha, D., Senthilraja, R., & Thanappan, S. (2024). Development of Digital Twin Technology in Hydraulics Based on Simulating and Enhancing System Performance. Journal of Cybersecurity & Information Management, 13(2);50-65 DOI:10.54216/JCIM.130204

ÇELİK, M. E. (2023). A Novel Deep Learning Model for Pain Intensity Evaluation. International Journal of Computational and Experimental Science and Engineering, 9(4), 325–330. Retrieved from https://ijcesen.com/index.php/ijcesen/article/view/274

AYKAT, Şükrü, & SENAN, S. (2023). Using Machine Learning to Detect Different Eye Diseases from OCT Images. International Journal of Computational and Experimental Science and Engineering, 9(2), 62–67. Retrieved from https://ijcesen.com/index.php/ijcesen/article/view/191

KIRELLİ, Y., & AYDIN, G. (2023). Classification of Histopathological Images in Automatic Detection of Breast Cancer with Deep Learning Approach. International Journal of Computational and Experimental Science and Engineering, 9(4), 359–367. Retrieved from https://ijcesen.com/index.php/ijcesen/article/view/279

Priti Parag Gaikwad, & Mithra Venkatesan. (2024). KWHO-CNN: A Hybrid Metaheuristic Algorithm Based Optimzed Attention-Driven CNN for Automatic Clinical Depression Recognition . International Journal of Computational and Experimental Science and Engineering, 10(3);491-506. https://doi.org/10.22399/ijcesen.359

Jha, K., Sumit Srivastava, & Aruna Jain. (2024). A Novel Texture based Approach for Facial Liveness Detection and Authentication using Deep Learning Classifier. International Journal of Computational and Experimental Science and Engineering, 10(3);323-331. https://doi.org/10.22399/ijcesen.369

Varone G, Ieracitano C, Çiftçioğlu AÖ, Hussain T, Gogate M, Dashtipour K, Al-Tamimi BN, Almoamari H, Akkurt I, Hussain A. A Novel Hierarchical Extreme Machine-Learning-Based Approach for Linear Attenuation Coefficient Forecasting. Entropy. 2023; 25(2):253. https://doi.org/10.3390/e25020253

Downloads

Published

2024-10-20

How to Cite

Achuthankutty, S., M, P., K, D., P, K., & R, prathipa. (2024). Deep Learning Empowered Water Quality Assessment: Leveraging IoT Sensor Data with LSTM Models and Interpretability Techniques. International Journal of Computational and Experimental Science and Engineering, 10(4). https://doi.org/10.22399/ijcesen.512

Issue

Vol. 10 No. 4 (2024): IJCESEN

Section

Research Article

License

Copyright (c) 2024 International Journal of Computational and Experimental Science and Engineering

Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 International License.