Dheyaa Alhelal, K. Aboalayon, M. Daneshzand, M. Faezipour
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引用次数: 20
摘要
在这项工作中,利用硬件设计了一个高效的数字系统来过滤心电图(ECG)信号并检测QRS复合体(心跳)。系统采用现场可编程门阵列(FPGA)实现。在硬件系统实现的第一阶段,设计了有限脉冲响应(FIR)滤波器对心电信号进行预处理和去噪。然后将滤波后的信号用作硬件实现第二阶段的输入,以检测和分类心电拍。通过设计可合成有限状态机,在ALTERA DE II FPGA上实现了整个系统。利用Quartus II工具对系统进行了仿真和测试。设计的系统已在MIT-BIH心律失常数据库的心电波上进行了测试,通过对信号进行窗口处理,并在每个处理窗口中应用自适应信号和噪声阈值。硬件系统在心跳检测阶段的总体准确率达到98%,同时实时提供检测到的心跳和不规则心率的分类。
FPGA-based denoising and beat detection of the ECG signal
In this work, an efficient digital system is designed using hardware to filter the Electrocardiogram (ECG) signal and to detect the QRS complex (beats). The system implementation has been done by using a Field Programmable Gate Array (FPGA). In the first phase of the hardware system implementation, Finite Impulse Response (FIR) filters are designed for preprocessing and denoising the ECG signal. The filtered signal is then used as the input of the second phase of the hardware implementation to detect and classify the ECG beats. The entire system has been implemented on ALTERA DE II FPGA by designing synthesizable finite state machines. Quartus II tool has been used to simulate and test the system. The designed system has been tested on ECG waves from the MIT-BIH Arrhythmia database by windowing the signal and applying adaptive signal and noise thresholds in each window of processing. The hardware system has achieved an overall accuracy of 98% in the beat detection phase, while providing the detected beats and the classification of irregular heart beat rates in real time.
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