Detection of abnormal rhythm morphologies is more difficult than normal beat, therefore, we need to collect abnormal rhythm signals in clinical practice to improve the detection of QRS-complex.
This project is for Electrocardiogram(ECG) signal algorithms design and validation, include preprocessing, QRS-Complex detection, embedded system validation, ECG segmentation, label your machine learning dataset, and clinical trial...etc.
For algorithm performance, in ANSI/AAMI EC38,it is required that the detected QRS shall in the 150ms range of the signed point from annotation by human exper.
目前僅用MIT-BIH等標準心律不整資料庫或是生理訊號挑戰賽提供的標註資料,理論上很難得到超越其標注的學習模型,實務上還是需要配合其他臨床實驗搜集更多案例強化模型,下個To-Do會用標準資料庫訓練分類模型增加基本的自動化標註,目前僅針對臨床實時運行的特殊案例配合人工選擇QRS-Complex演算法自動切片。
- Win10
- wxWidgets 3.1.2
- VS2017 - MSVC 10.0.17763-SDK
- Mac High Sierra
- wxWidgets 3.x
- g++
- Clinical trial
- 1.Setup your ECG device to clinical trial.
- 2.Connect VCP to wxECGAnalyzer. (Tools -> VCP, select cu or COM devices,bouadrate is UART only)
- 3.Monitor target.
- 4.Segmentation and save target morphology of the ECG.(you can modify the windows-size, tihs project is 700ms)
- 5.Select ECG-Codes to labeling.
Snapshot.csv: example file.
-
Validation of Algorithm for Real-time Embedded Systems(Holter)
- 1.Add *.cpp and .h file, and create new wxRadioBox item to apply.
- 2.Design algorithm with C/C++.
- 3.Clinical trial and validation.
- 4.Port code file to your embedded project.
- Filter
- Finite Impulse Response(FIR)
- QRS-Complex Detect Algorithm
- Adaptive Threshold Algorithm
- HC_Chen Algorithm
- Enhanced So & Chen
- Pan-Tompkins
- Deep-ECG(1D-CNN)
- Heart Rate Variability
- Heart Rate
- SDNN
- NN50
- pNN50
- Labeling
- Segmentation
- Automatic segmentation
- MIT-BIH ECG-Codes
- Automatic labeling(SVM+CNN Feature)
- MIT-BIH Database Operate
- WFDB
- Quantitative
- Sensitivity
- Specificity
- Accuracy
- Confusion Matrix
- Other Operate
- Record RAW data(60s)
- Save four plot(.png)
- Fast Furious Transform(FFT) amplitude spectrum
- Connect serial port
This project with FIR to filter ECG signal, coefficients generate parameter is 360hz, 32taps, band-pass 0.51Hz~8.9Hz and kaiser window.
Coefficients Generator : https://github.com/GCY/Finite-Impulse-Response-FIR-Filter-
This algorithm purpose for this project, involving two parts, first is adaptive threshold update, and second find the local maxima and minima.
Define threshold update period: (Sampling Rate / Target Low-Frequency), for example, target is ECG HR, normal people Heart Rate is 45-150 BPM, that is equally 0.75Hz-2.5Hz, 360SR/0.75Hz = 480 signal point, decrease update period the algorithm be sensitive.
Determinate the local maxima and minima we need to know gradient, calculate below equation to find the gradient, Threshold_Factor for 12Bit ADC is 3.0f, increase Threshold_Factor, the local maximum and minimum are determinated by the algorithm which need more gradient.
Gradient = RMS * CV(%) * Threshold_Factor
Design more rules for the local maximum and minimum, your project will be able to recognize ECG PQRST.
This project modified LPF and HPF window size, hp_buffer = 150ms(QRS-Complex size), forgetting factor alpha is used to avoid threshold keeping high-level.
The threshold_parameter and filter_parameter are 4 and 16 in the implementation , enhanced point is 123(350ms for 360Hz sampling rate), if last QRS-Complex point is over triple sampling rate, we will decrease threshold until zero, slope square process could detect abnormal heart rhythms.
The Pan-Tompkins filter of classical version is design for 200Hz and band-pass 5Hz-15Hz, if ECG signal is over 200Hz it needs to downsample to 200Hz, this project with FIR to clean 360Hz ECG signal, and modified Search Back period must be more than sampling_rate * 1.66(600 point, but this project is 550 point) .
Running on STM32F407 clock 168MHz and enable FPU, y-axix time uint is nanoseconds, x-axix is signal point.
Charts below show runtime environment time complexity, Adative Threshold Algorithm complexity is follow gradient threshold(step edge), the QRS-complex detection of the classical Pan-Tompkins algorithm mainly complexity is Search Back, HC Chen and So&Chen relatively stable.
Heart Rate and HRV are move-average in the implementation, N = BEAT_SIZE = 16.
-
ARM Cortex-M4
- STM32F407-Discovery
- AD8232
-
cNIBP: Use the ECG part.(without Right Leg Drive)
Connect ECG signal output to STM32F4 PC0 pin, next load *.elf and run.
The setup ADC sampling rate is 360Hz with ADC + DMA + Timer-Trigger same as MIT-BIT arrhythmia database record.
For VCP mode just define
#define VCP_MODE
For Holter
#define SINGLE_MODE
And define QRS-Complex detect algorithm flag
#define ATA
//#define HC
//#define SO
//#define PT
- Find the local maxima and minima : http://billauer.co.il/peakdet.html
- Heart rate variability : https://en.wikipedia.org/wiki/Heart_rate_variability
- HC_Chen Algorithm
- HC Chen, SW Chen, "A Moving Average based Filtering System with its Application to Real-time QRS Detection", Computers in Cardiology, 2003.
- https://github.com/blakeMilner/real_time_QRS_detection (modified)
- Enhanced So & Chen Algorithm
- So, H. H., & Chan, K. L. (1997, October). Development of QRS detection method for real-time ambulatory cardiac monitor. In Proceedings of the 19th Annual International Conference of the IEEE Engineering in Medicine and Biology Society.'Magnificent Milestones and Emerging Opportunities in Medical Engineering'(Cat. No. 97CH36136) (Vol. 1, pp. 289-292). IEEE.
- Lee, R. G., Chou, I. C., Lai, C. C., Liu, M. H., & Chiu, M. J. (2005). A novel QRS detection algorithm applied to the analysis for heart rate variability of patients with sleep apnea. Biomedical Engineering: Applications, Basis and Communications, 17(05), 258-262.
- Wang, C. Y., Chang, R. C. H., Lin, C. H., & Su, S. H. (2018, May). Fatigue Detection System Using Enhanced So and Chan Method. In 2018 IEEE International Conference on Consumer Electronics-Taiwan (ICCE-TW) (pp. 1-2). IEEE.
- Pan-Tompkins Algorithm
- Pan, J., & Tompkins, W. J. (1985). A real-time QRS detection algorithm. IEEE transactions on biomedical engineering, (3), 230-236.
- Afonso, V. X. (1993). Ecg qrs detection. Biomedical digital signal processing, 237-264.
- https://github.com/rafaelmmoreira/PanTompkinsQRS (modified)
MIT License
Copyright (c) 2019 Tony Guo
Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions:
The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software.
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.