一、核心流程
二、Matlab代码实现
1. 数据预处理(去噪与基线校正)
function clean_ecg = preprocess_ecg(ecg, fs)
% 带通滤波(0.5-40Hz)去除工频干扰和基线漂移
[b,a] = butter(3, [0.5 40]/(fs/2));
filtered = filtfilt(b,a,ecg);
% 小波去噪(db4小波,5层分解)
[c,l] = wavedec(filtered,5,'db4');
denoised = waverec(wthresh(c, 's', 3*std(c)/2), l, 'db4');
% 移动平均平滑(窗口宽度=50ms)
window = round(0.05*fs);
clean_ecg = movmean(denoised, window);
end
2. R波检测(改进Pan-Tompkins算法)
function [r_peaks, locs] = detect_r_peaks(ecg, fs)
N = length(ecg);
window = round(0.15*fs); % 积分窗口
% 平方与积分
squared = ecg.^2;
integrated = filter(ones(1,window)/window, 1, squared);
% 动态阈值
threshold = 0.7*max(integrated(1:1000)) + 0.3*std(integrated(1:1000));
% 峰值检测
[peaks, locs] = findpeaks(ecg, 'MinPeakHeight', threshold, ...
'MinPeakDistance', round(0.2*fs), 'Prominence', 0.5*threshold);
end
3. RR间期提取
function rr_intervals = get_rr_intervals(locs, fs)
rr_samples = diff(locs);
rr_intervals = rr_samples / fs * 1000; % 转换为毫秒
% 异常值处理(3σ原则)
mean_rr = mean(rr_intervals);
std_rr = std(rr_intervals);
rr_intervals(rr_intervals < mean_rr-3*std_rr | rr_intervals > mean_rr+3*std_rr) = [];
end
4. 时域分析
function [sdnn, rmssd, pnn50] = time_domain(rr_intervals)
N = length(rr_intervals);
% 基本指标
sdnn = std(rr_intervals);
% 差分序列
diffs = diff(rr_intervals);
% RMSSD
rmssd = sqrt(mean(diffs.^2));
% pNN50
nn50 = sum(diffs > 50);
pnn50 = nn50 / N;
end
5. 频域分析(Welch方法)
function [lf_power, hf_power, lf_hf_ratio] = freq_domain(rr_intervals, fs)
N = length(rr_intervals);
window = hamming(256);
noverlap = 128;
% 功率谱估计
[Pxx,f] = pwelch(rr_intervals, window, noverlap, [], fs);
% 频段划分
lf_band = [0.04, 0.15];
hf_band = [0.15, 0.4];
% 频段积分
lf_idx = f >= lf_band(1) & f <= lf_band(2);
hf_idx = f > hf_band(1) & f <= hf_band(2);
lf_power = trapz(f(lf_idx), Pxx(lf_idx));
hf_power = trapz(f(hf_idx), Pxx(hf_idx));
% LF/HF比值
lf_hf_ratio = lf_power / hf_power;
end
6. 可视化模块
function plot_hrv_results(ecg, rr_intervals, locs, sdnn, rmssd, lf_hf_ratio)
figure;
% ECG波形与R峰标记
subplot(3,1,1);
plot(ecg);
hold on;
plot(locs, ecg(locs), 'ro');
title('ECG波形与R峰检测');
xlabel('时间 (s)');
ylabel('幅值 (mV)');
% RR间期序列
subplot(3,1,2);
stem(rr_intervals, 'b', 'LineWidth', 1.5);
title('RR间期序列');
xlabel('心跳序号');
ylabel('间隔 (ms)');
% 时频域指标
subplot(3,1,3);
bar([sdnn, rmssd, lf_hf_ratio]);
set(gca, 'XTickLabel', {
'SDNN (ms)', 'RMSSD (ms)', 'LF/HF'});
ylabel('数值');
title('HRV时频域指标');
end
三、完整调用示例
%% 参数设置
fs = 250; % 采样率 (Hz)
ecg = load('ecg_signal.mat'); % 加载ECG数据(列向量)
%% 预处理
clean_ecg = preprocess_ecg(ecg, fs);
%% R波检测
[r_peaks, locs] = detect_r_peaks(clean_ecg, fs);
%% RR间期提取
rr_intervals = get_rr_intervals(locs, fs);
%% 时域分析
[sdnn, rmssd, pnn50] = time_domain(rr_intervals);
%% 频域分析
[lf_power, hf_power, lf_hf_ratio] = freq_domain(rr_intervals, fs);
%% 可视化
plot_hrv_results(clean_ecg, rr_intervals, locs, sdnn, rmssd, lf_hf_ratio);
四、结果示例
| 指标 | 正常范围 | 临床意义 |
|---|---|---|
| SDNN | 50-100 ms | 总体自主神经活性 |
| RMSSD | 20-80 ms | 副交感神经张力 |
| LF/HF | 0.5-2.0 | 交感-副交感平衡 |
参考代码 采用ECG信号进行HRV的时域分析、频域分析的Matlab代码 www.youwenfan.com/contentalh/55064.html
五、扩展功能
呼吸耦合分析
% 呼吸信号同步处理 [resp_rate, phase] = respiratory_analysis(ecg, fs);非线性分析
% Poincaré图 [sd1, sd2] = poincare_plot(rr_intervals);机器学习集成
% 使用HRV特征训练分类模型 features = [sdnn, rmssd, lf_hf_ratio]; model = train_classifier(features, labels);
六、注意事项
数据质量验证:需检查QRS波群形态(使用ECG诊断工具箱)
采样率要求:建议≥250Hz(MIT-BIH标准)
临床验证:需与专业医疗设备(如Holter)对比
参考文献:
ECG信号预处理与R波检测算法优化
HRV时域频域特征计算方法
基于Welch方法的功率谱估计
运动伪影消除技术
