Smart Autolube: Optimized machine learning-based  pressure prediction for AIoT lubrication systems

Ali KHUMAIDI; Risanto DARMAWAN; Lukman ADITYA; Wardhana Halking HAMKA; Hudzaifah Al JIHAD

doi:10.35784/acs_7947

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Published: Mar 31, 2026

DOI: https://doi.org/10.35784/acs_7947

Issue Vol. 22 No. 1 (2026)

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Smart Autolube: Optimized machine learning-based pressure prediction for AIoT lubrication systems
Ali KHUMAIDI, Risanto DARMAWAN; Lukman ADITYA; Wardhana Halking HAMKA, Hudzaifah Al JIHAD

171-183
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DOI

https://doi.org/10.35784/acs_7947

Authors

Ali KHUMAIDI

alikhumaidi@binainsani.ac.id

Universitas Nusa Mandiri, Indonesia

https://orcid.org/0000-0002-4319-5018

Risanto DARMAWAN

risantodarmawan@unkris.ac.id

Krisnadwipayana University, Indonesia

https://orcid.org/0009-0009-9332-5368

Lukman ADITYA

lukmanaditya@unkris.ac.id

Krisnadwipayana University, Indonesia

https://orcid.org/0009-0000-2416-1413

Wardhana Halking HAMKA

wardhana.hamka@multindo-technology.com

PT. Multindo Technology Utama, Indonesia

https://orcid.org/0000-0002-4319-5018

Hudzaifah Al JIHAD

hudzaifah@multindo-technology.com

PT. Multindo Technology Utama, Indonesia

https://orcid.org/0000-0002-4319-5018

Abstract

Autolube systems have been widely adopted in the mining industry to improve equipment reliability, but most still operate at fixed time intervals without adapting to real conditions in the field, and monitoring systems use LED lights, making it difficult to diagnose failures due to the minimal system interface. To overcome these issues, this study developed Smart Autolube based on Artificial Intelligence of Things (AIoT), which integrates sensor-based monitoring with machine learning models for adaptive lubrication pressure prediction. With industry support from PT. Multindo Technology Utama, the system was tested under mining simulation conditions using pressure, temperature, and stress sensor data. After preprocessing, which includes winsorization, feature engineering (lag, rolling statistics, and trends), two ensemble algorithms, Random Forest Regressor (RFR) and Gradient Boosting Regressor (GBR), are used to build a prediction model. The base model showed low accuracy (R² < 0.1), but after feature engineering and extreme hyperparameter tuning, the performance improved significantly with an R² of 0.9816 for GBR and 0.9711 for RFR. Explanability analysis using SHAP (SHapley Additive exPlanations) shows that engineering features such as trends, lag_2, and rolling_mean_3 contribute the most to the predictions compared to native features such as temperature and voltage. This study proves that Smart Autolube can provide accurate and explainable lubrication pressure predictions. Further research is suggested to expand the scope of the data, add other mechanical parameters, and test the generalization of the model in different industrial environments.

Keywords:

extreme fine tuning, feature engineering, gradient boosting, random forest, smart autolube

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KHUMAIDI, A., DARMAWAN, R., ADITYA, L., HAMKA, W. H., & JIHAD, H. A. (2026). Smart Autolube: Optimized machine learning-based pressure prediction for AIoT lubrication systems. Applied Computer Science, 22(1), 171–183. https://doi.org/10.35784/acs_7947

Smart Autolube: Optimized machine learning-based pressure prediction for AIoT lubrication systems

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