Title :
Active Motion Artifact Reduction for Wearable Sensors Using Laguerre Expansion and Signal Separation
Author :
Wood, Levi B. ; Asada, H. Harry
Author_Institution :
Dept. of Mechanical Eng., MIT, Cambridge, MA
Abstract :
This paper presents an active noise cancellation technique that utilizes an accelerometry measurement to recover corrupted wearable health monitoring signals. The technique presented here requires no calibration for each patient and is computationally efficient. Also, a method of determining when the desired signal is correlated with the motion reference is presented with a means of partial signal recovery. The Laguerre basis function provides robustness against calibration as well as improvement in computational efficiency, and symmetric decorrelation accommodates the management of correlated signals. Experimentation shows that the system can produce up to an 85% reduction in wearable sensor error for accelerations up to 2G
Keywords :
bio-optics; bioMEMS; medical signal processing; microsensors; patient monitoring; plethysmography; source separation; stochastic processes; Laguerre basis function; Laguerre expansion; MEMS; accelerometry; active motion artifact reduction; active noise cancellation; corrupted wearable health monitoring signals; photoplethysmograph; robustness; signal recovery; signal separation; symmetric decorrelation; wearable sensors; Biomedical monitoring; Calibration; Computational efficiency; Decorrelation; Noise cancellation; Noise measurement; Patient monitoring; Robustness; Source separation; Wearable sensors; Laguerre expansion; MEMS accelerometer; Wearable sensor; active noise cancellation; photoplethysmograph; signal separation; system identification;
Conference_Titel :
Engineering in Medicine and Biology Society, 2005. IEEE-EMBS 2005. 27th Annual International Conference of the
Conference_Location :
Shanghai
Print_ISBN :
0-7803-8741-4
DOI :
10.1109/IEMBS.2005.1617251
