An Ensemble-Based AI Approach for Continuous Blood Pressure Estimation in Health Monitoring Applications.
Article
Haque, Rafita, Wang, Chunlei, Pala, Nezih. (2025). An Ensemble-Based AI Approach for Continuous Blood Pressure Estimation in Health Monitoring Applications.
. SENSORS, 25(15), 4574. 10.3390/s25154574
Haque, Rafita, Wang, Chunlei, Pala, Nezih. (2025). An Ensemble-Based AI Approach for Continuous Blood Pressure Estimation in Health Monitoring Applications.
. SENSORS, 25(15), 4574. 10.3390/s25154574
Continuous blood pressure (BP) monitoring provides valuable insight into the body's dynamic cardiovascular regulation across various physiological states such as physical activity, emotional stress, postural changes, and sleep. Continuous BP monitoring captures different variations in systolic and diastolic pressures, reflecting autonomic nervous system activity, vascular compliance, and circadian rhythms. This enables early identification of abnormal BP trends and allows for timely diagnosis and interventions to reduce the risk of cardiovascular diseases (CVDs) such as hypertension, stroke, heart failure, and chronic kidney disease as well as chronic stress or anxiety disorders. To facilitate continuous BP monitoring, we propose an AI-powered estimation framework. The proposed framework first uses an expert-driven feature engineering approach that systematically extracts physiological features from photoplethysmogram (PPG)-based arterial pulse waveforms (APWs). Extracted features include pulse rate, ascending/descending times, pulse width, slopes, intensity variations, and waveform areas. These features are fused with demographic data (age, gender, height, weight, BMI) to enhance model robustness and accuracy across diverse populations. The framework utilizes a Tab-Transformer to learn rich feature embeddings, which are then processed through an ensemble machine learning framework consisting of CatBoost, XGBoost, and LightGBM. Evaluated on a dataset of 1000 subjects, the model achieves Mean Absolute Errors (MAE) of 3.87 mmHg (SBP) and 2.50 mmHg (DBP), meeting British Hypertension Society (BHS) Grade A and Association for the Advancement of Medical Instrumentation (AAMI) standards. The proposed architecture advances non-invasive, AI-driven solutions for dynamic cardiovascular health monitoring.
