about
The potential of Internet of m-health Things “m-IoT” for non-invasive glucose level sensingA Comparative Study of Physiological Monitoring with a Wearable Opto-Electronic Patch Sensor (OEPS) for Motion Reduction.A multi-channel opto-electronic sensor to accurately monitor heart rate against motion artefact during exercise.Opto-physiological modeling applied to photoplethysmographic cardiovascular assessment.A Multi-Wavelength Opto-Electronic Patch Sensor to Effectively Detect Physiological Changes against Human Skin Types.A Study of the Dynamic Relation between Physiological Changes and Spontaneous Expressions.BioThreads: a novel VLIW-based chip multiprocessor for accelerating biomedical image processing applications.Insight into the dicrotic notch in photoplethysmographic pulses from the finger tip of young adults.Effect of postural changes on lower limb blood volume, detected with non-invasive photoplethysmography.Recovery of heart rate variability after treadmill exercise analyzed by lagged Poincaré plot and spectral characteristics.The response of the autonomic nervous system to passive lower limb movement and gender differences.Smart Garment Fabrics to Enable Non-Contact Opto-Physiological Monitoring.Analysis of pulse rate variability derived from photoplethysmography with the combination of lagged Poincaré plots and spectral characteristics.Influence of computer work under time pressure on cardiac activity.Assessing blood vessel perfusion and vital signs through retinal imaging photoplethysmography.Breathing Pattern Interpretation as an Alternative and Effective Voice Communication Solution.Frame Registration for Motion Compensation in Imaging PhotoplethysmographyOxygen Saturation Measurements from Green and Orange Illuminations of Multi-Wavelength Optoelectronic Patch SensorsAugmentative and Alternative Communication (AAC) Advances: A Review of Configurations for Individuals with a Speech DisabilityA study of opto-physiological modeling to quantify tissue absorbance in imaging photoplethysmographyDevelopment of effective photoplethysmographic measurement techniques: from contact to non-contact and from point to imagingNoncontact imaging photoplethysmography to effectively access pulse rate variabilityAn Optimization Study of Estimating Blood Pressure Models Based on Pulse Arrival Time for Continuous MonitoringA Revised Point-to-Point Calibration Approach with Adaptive Errors Correction to Weaken Initial Sensitivity of Cuff-Less Blood Pressure Estimation
P50
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P50
description
researcher ORCID ID = 0000-0002-9637-4730
@en
name
Sijung Hu
@ast
Sijung Hu
@en
Sijung Hu
@nl
type
label
Sijung Hu
@ast
Sijung Hu
@en
Sijung Hu
@nl
prefLabel
Sijung Hu
@ast
Sijung Hu
@en
Sijung Hu
@nl
P2456
P31
P496
0000-0002-9637-4730