@ARTICLE{ iet:/content/journals/10.1049/htl.2017.0027, author = {Mohammad Tariqul Islam}, author = {Sk. Tanvir Ahmed}, author = {Ishmam Zabir}, author = {Celia Shahnaz}, author = {Shaikh Anowarul Fattah}, keywords = {photoplethysmographic signal;noise reduction;algorithmic approach;three-channel accelerometer signals;intensive physical exercise;wearable devices;motion artefacts;adaptive filters;parallel combination;adaptive noise cancelers;heart rate monitoring;}, language = {English}, abstract = {Photoplethysmographic (PPG) signal is getting popularity for monitoring heart rate in wearable devices because of simplicity of construction and low cost of the sensor. The task becomes very difficult due to the presence of various motion artefacts. In this study, an algorithm based on cascade and parallel combination (CPC) of adaptive filters is proposed in order to reduce the effect of motion artefacts. First, preliminary noise reduction is performed by averaging two channel PPG signals. Next in order to reduce the effect of motion artefacts, a cascaded filter structure consisting of three cascaded adaptive filter blocks is developed where three-channel accelerometer signals are used as references to motion artefacts. To further reduce the affect of noise, a scheme based on convex combination of two such cascaded adaptive noise cancelers is introduced, where two widely used adaptive filters namely recursive least squares and least mean squares filters are employed. Heart rates are estimated from the noise reduced PPG signal in spectral domain. Finally, an efficient heart rate tracking algorithm is designed based on the nature of the heart rate variability. The performance of the proposed CPC method is tested on a widely used public database. It is found that the proposed method offers very low estimation error and a smooth heart rate tracking with simple algorithmic approach.}, title = {Cascade and parallel combination (CPC) of adaptive filters for estimating heart rate during intensive physical exercise from photoplethysmographic signal}, journal = {Healthcare Technology Letters}, issue = {1}, volume = {5}, year = {2018}, month = {February}, pages = {18-24(6)}, publisher ={Institution of Engineering and Technology}, copyright = {This is an open access article published by the IET under the Creative Commons Attribution -NonCommercial License (http://creativecommons.org/licenses/by-nc/3.0/)}, url = {https://digital-library.theiet.org/;jsessionid=64pba732dt9mj.x-iet-live-01content/journals/10.1049/htl.2017.0027} }