A Novel Method for Design and Implementation of Systolic Associative Cascaded Variable Leaky Least Mean Square Adaptive Filter for Denoising of ECG Signals
Authors: 
Chitra Manickam, Murugesan Govindasamy, Suresh Muthusamy, Muneeshwari ParamasivamAuthors Info & Claims
Pages 1029 - 1043
Abstract
Electrocardiogram is the most essential diagnostic test for heart disease detection in this era, where it has low frequency and small amplitude, making it vulnerable to a variety of stimuli, including high/low-frequency noises resulting in diagnostic quality suffers. Implementation of adaptive filter removes noise from the signal in a better way. Adaptive filters in signal processing plays a major role in biomedical applications for denoising different types of noises such as Power Line Interference noise which is generated by the power line electromagnetic field and it exhibits its peak from 50 to 60 Hz, Baseline Wander noise which occurs due to the variation of electrode skin impedance, Motion Artifacts which is generated by the electrode motions away from the contact zone on the skins and Muscle Noise, this is due to the Electromyographic signals, originating from the skeletal muscle contractions. In order to eliminate the above-mentioned noises, the most common adaptive filters such as Least Mean Square (LMS) and Recursive Least Squares (RLS) are used. In existing method, they used Cascaded Least Mean Square adaptive filters to reduce noises at a much higher rate than the Least Mean Square Adaptive filter and to achieve the higher Signal to Noise Ratio (SNR). The Cascaded RLS filter can be used to obtain faster range of convergence than the Cascaded LMS. The filter is designed with adaptive variable step size which calculates the step size according to the input signal of the filter, this is used to increase the stability of the filter. The systolic architecture and associativity of the VLLMS filter is implemented to reduce the number of adders and multipliers along the critical path of the filter. This work comprises of designing the 4 tap, 8 tap and 16 tap cascaded systolic associative variable leaky least mean square adaptive filters using Simulink and the SNR comparisons have been made between normal LMS cascaded filter and cascaded VLLMS filter. The area and delay between normal filter and systolic associative filter are compared by converting the Simulink design into Verilog and by implementing in Xilinx.
References
[1]
Velayudhan, A., & Peter, S. (2016). Noise analysis and different denoising techniques of ECG signal survey. In International organization of scientific research journal of electronics and communication engineering, (vol. 12, p. 7).
[2]
Maurya AK Cascade-cascade least mean square (LMS) adaptive noise cancellation Circuits system and Signal Processing 2017 37 9 3785-3826
[3]
Devendra Goyal and Manish Singhal Area-efficient FPGA model of LMS filtering algorithm Journal of recent cognizance in Wireless Communication & Image Processing 2016 23 943-952
[4]
Tokunbo Ogunfunmi and Thomas Paul Analysis of convergence of a frequency-domain LMS adaptive filter implemented as a multi-stage adaptive filter Journal of Signal Processing Systems 2008 56 341-350
[5]
Mohd. Tasleem Khan and Rafi Ahamed Shaik Optimal complexity architectures for pipelined distributed arithmetic-based lms adaptive filter’ IEEE Transactions on Circuits and Systems 2019 66 630-642
[6]
Hannah Pauline S and Samiappan D Variable-stage cascaded adaptive filter technique for signal de-noising application Journal of Circuits Systems and Signal Processing 2021 37 1-35
[7]
Wan C, Chen D, Yang J, and Huang M Combining parallel adaptive filtering and wavelet threshold denoising for PPG for monitoring during exercises IEICE Transactions on Information and Systems 2020 103 3 612-620
[8]
Kose M, Ramaji MK, Ahirwal, and Rekh Ram Janghel Descendant adaptive filter to remove different noises from ECG signals International Journal of Biomedical Engineering and Technology 2020 33 258-273
[9]
Singh A and Mehra R Adaptive filter for ECG noise Reduction using RLS Algorithm’ International Journal of Engineering Research and Applications 2013 3 1304-1308
[10]
Mugdha, A., Chowdhury, F. S., Rawnaque, & Uddin Ahmed, M. (2015). A study of recursive least squares (RLS) adaptive filter algorithm in noise removal from ECG signals. In 2015 International conference on informatics, electronics & vision (ICIEV) (pp. 1–6). IEEE
[11]
Gupta, D. K., Gupta, V. K., Chandra, M., Mishra, A. N., & Praween Kumar, S. (2019). Hardware co-simulation of adaptive noise cancellation system using LMS and Leaky LMS algorithms. In 2019 4th International Conference on Internet of Things: Smart Innovation and Usages (IoT-SIU) (pp. 1–6). IEEE
[12]
Kalkar, P., & Sahaya Rani Alex. J. (2017). Field programmable gate array implementation of variable leaky least mean square algorithm. Asian Journal of Pharmaceutical and Clinical Research, 69, 13.
[13]
Tajuddeen R, Gwadabe MS, Salman, and Abuhilal H A modified leaky-LMS algorithm International Journal of Computer and Electrical Engineering 2014 6 222
[14]
Dongyuan Shi, W. S., Gan, B., Lam, X., & Shen (2022). Optimal penalty factor for the MOV-Fx LMS algorithm in active noise control system. International Journal on IEEE Signal Processing and Letters 29, 85–89.
[15]
Priya, P. K., Shanmugaraja, T., & Sugapriyaa, T. (2018). LUT optimization of LMS adaptive filter architecture using high level transformation for clamor cancellation. Current Trends In Biomedical Communication And Tele–Medicine 14.
[16]
Chaudhary, A., Barnawal, A., Gupta, A., & Chaudhary, D. (2014). Analysis of noise signal cancellation using adaptive algorithms. International Journal of Engineering Research and General Science, 2(6), 2091–2730.
[17]
Thenua R, Kumar, and Agarwal SK Simulation and performance analysis of adaptive filter in noise cancellation International Journal of Engineering Science and Technology 2010 4 73-78
[18]
Gu, Y., Chen, Y., & Hero, A. O. (2009). Sparse LMS for system identification. In 2009 IEEE international conference on acoustics, speech and signal processing, (Vol. 43, pp. 35–52).
[19]
Velayudhan A and Peter S Noise analysis and different denoising techniques of ECG signal-a survey IOSR Journal of Electronics and Communication Engineering 2016 3 641-644
[20]
Krishnamoorthy, M., Muthusamy, S., Balakrishnan, B., Sridevi, S., Panneerselvam, M., Rameshkumar, M., Abualigah, L., Saber, A., & Salama, D. (2024). A novel multi class disease detection of chest x-ray images using deep learning with pre trained transfer learning models for medical imaging applications.
[21]
Mann S, Yadav D, Muthusamy S, Rathee D, and Om Prava M A novel method for prediction and analysis of COVID 19 transmission using machine learning based time series models Wireless Personal Communications 2024 133 1-27
[22]
Ramasamy M, Devi K, Periasamy S, Muthusamy S, Ramamoorthi P, Thangavel G, Sekaran S, Sadasivuni KK, and Geetha M A novel adaptive neural network-based Laplacian of Gaussian (AnLoG) classification algorithm for detecting diabetic retinopathy with colour retinal fundus images Neural Computing and Applications 2024 36 7 3513-3524
[23]
Kozakijevic S, Salb M, Elsadai A, Mani J, Devi K, Sharko AD, and Muthusamy S Seizure detection via time series classification using modified metaheuristic optimized recurrent networks Theoretical and Applied Computational Intelligence 2023 1 82-94
[24]
Raghavendran PS, Ragul S, Asokan R, Loganathan AK, Muthusamy S, Mishra OP, Ramamoorthi P, and Sundararajan SC A new method for chest X-ray images categorization using transfer learning and CovidNet_2020 employing convolution neural network Soft Computing 2023 27 19 14241-14251
[25]
Sinnaswamy R, Ammapalayam N, Palanisamy K, Subramaniam S, Muthusamy R, Lamba, and Sekaran S An extensive review on deep learning and machine learning intervention in prediction and classification of types of aneurysms Wireless Personal Communications 2023 131 3 2055-2080
[26]
Subramaniam K, Palanisamy N, Sinnaswamy RA, Muthusamy S, Mishra OP, Loganathan AK, Ramamoorthi P, Gnanakkan CA, Thangavel G, and Sundararajan SC A comprehensive review of analyzing the chest X-ray images to detect COVID-19 infections using deep learning techniques Soft Computing 2023 27 19 14219-14240
[27]
Thangavel K, Palanisamy N, Muthusamy S, Mishra OP, Sundararajan SC, Panchal H, Loganathan AK, and Ramamoorthi P A novel method for image captioning using multimodal feature fusion employing mask RNN and LSTM models Soft Computing 2023 27 19 14205-14218
[28]
Gnanadesigan NS, Dhanasegar N, Ramasamy MD, Muthusamy S, Mishra OP, Pugalendhi GK, Sundararajan SC, and Ravindaran A An integrated network topology and deep learning model for prediction of Alzheimer disease candidate genes Soft Computing 2023 27 19 14189-14203
[29]
Krishnasamy K, Gobichettipalayam S, Periasamy K, Moorthy VP, Thangavel G, Lamba R, and Muthusamy S A pair-task heuristic for scheduling tasks in heterogeneous multi-cloud environment Wireless Personal Communications 2023 131 2 773-804
[30]
Jagadeesan V, Venkatachalam D, Vinod VM, Loganathan AK, Muthusamy S, Krishnamoorthy M, Sadasivuni KK, and Geetha M Design and development of a new metamaterial sensor-based Minkowski fractal antenna for medical imaging Applied Physics A 2023 129 5 391
[31]
Periyasamy K, Rathinam V, Ganesan K, Ramachandran M, Muthusamy S, Lamba R, Panchal H, Shanmugam M, Jalajakumari SP, and Kottapalli R A novel method for analyzing the performance of free space optical communication in WDM using EDFA Wireless Personal Communications 2023 131 1 679-707
[32]
Batcha BB, Singaravelu R, Ramachandran M, Muthusamy S, Panchal H, Thangaraj K, and Ravindaran A A novel security algorithm RPBB31 for securing the social media analyzed data using machine learning algorithms Wireless Personal Communications 2023 131 1 581-608
[33]
Rakkiannan T, Ekambaram G, Palanisamy N, Ramasamy RR, Muthusamy S, Loganathan AK, Panchal H, Thangaraj K, and Ravindaran A An automated network slicing at edge with software defined networking and network function virtualization: A federated learning approach Wireless Personal Communications 2023 131 1 639-658
[34]
Bennet, M., Anto, O. P., Mishra, & Muthusamy, S. (2023). Modeling of upper limb and prediction of various yoga postures using artificial neural networks. In 2023 international conference on sustainable computing and data communication systems (ICSCDS), (pp. 503–508). IEEE.
[35]
Jude MJ, Diniesh VC, Shivaranjani M, Muthusamy S, Panchal H, Sundararajan SC, and Sadasivuni KK On minimizing TCP traffic congestion in vehicular internet of things (VIoT) Wireless Personal Communications 2023 128 3 1873-1893
[36]
Kathamuthu ND, Subramaniam S, Le QH, Muthusamy S, Panchal H, Sundararajan SC, Alrubaie AJ, and Zahra MM A deep transfer learning-based convolution neural network model for COVID-19 detection using computed tomography scan images for medical applications Advances in Engineering Software 2023 175 103317
[37]
Manojkumar P, Suresh M, Ahmed AAA, Panchal H, Rajan CA, Dheepanchakkravarthy A, Geetha A, Gunapriya B, Mann S, and Sadasivuni KK A novel home automation distributed server management system using internet of things International Journal of Ambient Energy 2022 43 1 5478-5483
Recommendations
Cascade---Cascade Least Mean Square (LMS) Adaptive Noise Cancellation
The paper presents a new model of noise cancellation using cascading of cascaded LMS adaptive filters. The model has a combination of `$$2N+1$$2N+1' LMS filters for N-stage of adaptive noise cancellation. First LMS filter works as a basic noise ...
Gaussian Noise Filtering from ECG by Wiener Filter and Ensemble Empirical Mode Decomposition
Empirical mode decomposition (EMD) is a powerful algorithm that decomposes signals as a set of intrinsic mode function (IMF) based on the signal complexity. In this study, partial reconstruction of IMF acting as a filter was used for noise reduction in ...
ECG Denoising by using FIR and IIR Filtering Techniques: An Experimental Study
ICBBT '19: Proceedings of the 2019 11th International Conference on Bioinformatics and Biomedical TechnologyIn this work an experimental study is presented by verifying the performance of the FIR and IIR filters. These techniques have been used to eliminate the different types of intrinsic noise of the ECG signal. In order to measure the quality of the filters ...
Comments
Please enable JavaScript to view thecomments powered by Disqus.Information & Contributors
Information
Published In
© The Author(s), under exclusive licence to Springer Science+Business Media, LLC, part of Springer Nature 2024. Springer Nature or its licensor (e.g. a society or other partner) holds exclusive rights to this article under a publishing agreement with the author(s) or other rightsholder(s); author self-archiving of the accepted manuscript version of this article is solely governed by the terms of such publishing agreement and applicable law.
Publisher
Kluwer Academic Publishers
United States
Publication History
Published: 11 July 2024
Accepted: 30 June 2024
Author Tags
Qualifiers
- Research-article
Contributors
Other Metrics
Bibliometrics & Citations
Bibliometrics
Article Metrics
- 0Total Citations
- 0Total Downloads
- Downloads (Last 12 months)0
- Downloads (Last 6 weeks)0
Reflects downloads up to 16 Nov 2024
Other Metrics
Citations
View Options
View options
Login options
Check if you have access through your login credentials or your institution to get full access on this article.
Sign in