Detection of Mitral Valve Diseases by Bicoherence Analysis of Heart Sound Signals

The analysis of 10 normal and 51 mitral valve pathology making a total of 61 heart sound signals that were obtained with Littmann 4100 Digital Stethoscope were conducted in this study.Following the recorded sound signals were denoised by using wavelet filters,the signals were applied bicoherence analysis that is an high order spectral analysis method.It has been demonstrated that varieties of mitral valve pathology could be determined by three-dimensional surfaces of bicoherence and maximum bicoherence values.

Study on Real-Time Heart Rate Detection Based on Multi-People

Heart rate is an important vital characteristic which indicates physical and mental health status.Typically heart rate measurement instruments require direct contact with the skin which is time-consuming and costly.Therefore,the study of non-contact heart rate measurement methods is of great importance.Based on the principles of photoelectric volumetric tracing,we use a computer device and camera to capture facial images,accurately detect face regions,and to detect multiple facial images using a multi-target tracking algorithm.Then after the regional segmentation of the facial image,the signal acquisition of the region of interest is further resolved.Finally,frequency detection of the collected Photo-plethysmography(PPG)and Electrocardiography(ECG)signals is completed with peak detection,Fourier analysis,and a Waveletfilter.The experimental results show that the subject’s heart rate can be detected quickly and accurately even when monitoring multiple facial targets simultaneously.

Emotions States Recognition Based on Physiological Parameters by Employing of Fuzzy-Adaptive Resonance Theory

This paper is an investigation on negative emotions states recognition by employing of Fuzzy Adaptive Resonance Theory (Fuzzy-ART) considering the changes in activities of autonomic nervous system (ANS). Specific psychological experiments were designed to induce appropriate physiological responses on individuals in order to acquire a suitable database for training, validating and testing the proposed procedure. In this research, the three physiological applied signals are Galvanic Skin Response (GSR), Heart Rate (HR) and Respiration Rate (RR). The first experiment which is named Shock was designed to determine a criterion for the change of physiological signals of each individual. In the second one, a combination of two sets of questions has been asked from the subjects to induce their emotions. Finally, Physiological responses were analyzed by Fuzzy-ART to recognize which question excites the negative emotions. Detecting negative emotions from neutral is obtained with total accuracy of 94%.

Underwater Noise Target Recognition Based on Sparse Adversarial Co-Training Model with Vertical Line Array

The automatic identification of underwater noncooperative targets without label records remains an arduous task considering the marine noise interference and the shortage of labeled samples.In particular,the data-driven mechanism of deep learning cannot identify false samples,aggravating the difficulty in noncooperative underwater target recognition.A semi-supervised ensemble framework based on vertical line array fusion and the sparse adversarial co-training algorithm is proposed to identify noncooperative targets effectively.The sound field cross-correlation compression(SCC)feature is developed to reduce noise and computational redundancy.Starting from an incomplete dataset,a joint adversarial autoencoder is constructed to extract the sparse features with source depth sensitivity,aiming to discover the unknown underwater targets.The adversarial prediction label is converted to initialize the joint co-forest,whose evaluation function is optimized by introducing adaptive confidence.The experiments prove the strong denoising performance,low mean square error,and high separability of SCC features.Compared with several state-of-the-art approaches,the numerical results illustrate the superiorities of the proposed method due to feature compression,secondary recognition,and decision fusion.

基于活动性检测动态估计噪声的心音降噪算法

针对基于小波分解和最优改进对数幅度谱估计的心音降噪算法存在噪声残留和心音失真的问题,提出一种基于心音活动性检测(HSAD)动态估计噪声的心音降噪算法。通过设计的HSAD判断当前心音帧是否为基础心音帧(FHS),根据判断结果分别采用改进最小值控制递归平均(IMCRA)算法和递归平滑算法对噪声功率进行动态估计与更新,采用非因果先验信噪比,实现心音信号的降噪。实验结果表明,提出算法能更好在提升降噪性能的同时,降低FHS的失真。

MEMS心音传感器及检测电路优化设计

对基于微电子机械系统(MEMS)技术的心音传感器声敏结构进行了优化且设计了其检测电路。首先,针对心音信号的特点,设计了二次集成的扁平状仿生纤毛结构,对该结构进行仿真,确定了纤毛的尺寸参数和梁上最大应力1.2×10^(5) N/m^(2),对纤毛进行特征频率仿真,在硅油域中结果为711 Hz;其次由扁平状纤毛结构X轴接收噪声时梁上的应力仿真结果可知该结构具有抗干扰能力;最后设计了后端的放大电路和滤波电路并对传感器封装后进行测试。测试结果表明,该结构的信噪比达到了27 dB,较传统的圆柱形纤毛提高了35%,且其抗干扰能力也优于传统的圆柱形纤毛。优化过后的MEMS心音传感器具有抗干扰、低噪声、低成本、采集的信号不失真等优势,可为临床心音信号的采集提供关键核心部件。

心肺音分离方法研究进展

听诊是诊断心血管和呼吸系统疾病最有效的方法。为了达到准确诊断的目的,设备必须能够识别各种临床情况下的心肺音。然而,记录的胸腔声音通常为心肺音混合信号。因此,将心肺音混合信号分离对于医生听诊至关重要。本文介绍了心音信号和肺音信号的频率范围和信号特征,综述了目前心肺音分离方法的研究进展,阐述了现有各种心肺音分离方法的优缺点,指出了选取一种合适的心肺音分离算法来分离心肺音对辅助医疗的重要意义。

心音特征智能分析在心血管功能评估和疾病诊断中的应用

数字化心音与人工智能技术的结合可实现对心音进行精确地连续、定量分析和分类识别,使心音特征提取与融合分析在心脏血流动力学监测、心力衰竭分型诊断、先天性或风湿性心脏病分类、冠状动脉疾病检测等领域成为研究热点。本文综述心音特征智能分析在心血管功能评估和疾病诊断中的应用。

OFDM信号的新型自动识别与解调技术研究

近年来,通信领域越来越多地使用OFDM信号,有关OFDM的识别和解调也成为业界的热点问题之一。在对OFDM信号特性进行分析的基础上,设计了用于OFDM信号识别的新型四阶累量特征提取方法;研究和讨论了OFDM子载波间隔、频率及数目自动测量等调制规格分析技术;定义了频带边界虚音的概念,提出了新颖的基于频带边界虚音能量检测的符号速率估计算法;讨论分析了频偏与载波间干扰的关系,提出了基于迭代运算的载波频率精确估计算法。实际应用结果表明了此种OFDM信号自动识别与解调技术的有效性。

基于CEEMDAN和小波熵的心音信号去噪算法研究

针对传统心音去噪算法可能丢失部分重要心音信息问题,提出了一种自适应噪声完备经验模态分解(CEEMDAN)和小波熵结合的心音信号去噪算法。算法通过CEEMDAN将心音信号自适应分解成多个本征模态函数(IMFs),基于各阶本征模态的能量分析判别信噪分界点,对含噪IMF分量采用小波熵自适应阈值去噪后,与信号IMF分量重构,得到去噪后的心音信号。仿真结果显示,在不同信噪比条件下,上述算法均能明显提高心音信号的信噪比,降低均方根误差,优于其它传统去噪算法,具有良好地抑制噪声能力。

Heart Rate Detection Based on Facial Video

Heart rate is an important data reflecting human vital characteristics and an important reference index to describe human physical and mental state.Currently,widely used heart rate measurement devices require direct contact with a person’s skin,which is not suitable for people with burns,delicate skin,newborns and the elderly.Therefore,the research of non-contact heart rate measurement method is of great significance.Based on the basic principle of Photoplethysmography,we use the camera of computer equipment to capture the face image,detect the face region accurately,and detect multiple faces in the image based on multi-target tracking algorithm.Then the region segmentation of the face image is carried out to further realize the signal acquisition of the region of interest.Finally,peak detection,Fourier analysis and wavelet analysis were used to detect the frequency of PPG and ECG signals.The experimental results show that the heart rate information can be quickly and accurately detected even in the case of monitoring multiple face targets.

基于DnCNN声音增强的高坝泄流微弱空化声音信号识别与提取

空化空蚀是水工建筑物泄洪安全监测的重要内容,但是高坝泄流期间产生的强泄流噪声会大幅减弱空化空蚀音频监测方法的效果甚至致其失效。针对该问题提出了基于降噪卷积神经网络(denoising convolutional neural network,DnCNN)声音增强的空化声信号增强方法,该方法依据语音增强思想,通过DnCNN实现带噪音频监测信号中空化声信号的增强。首先对该方法的实现原理和DnCNN网络结构进行了阐述,然后使用采集自空蚀和泄流试验的空化声信号和泄流噪声对该方法的效果进行验证,最后通过支持向量机信号多分类识别试验和单分类支持向量机空化声信号单分类识别试验对该方法的泛化性能和工程实用性进行评价。研究结果表明该方法能够有效提升带噪空化声信号的信噪比,极大地还原空化声信号的频谱结构特征,实现强泄流噪声中微弱空化声信号的识别与提取,同时该方法具有较强的泛化性能和较好的工程实用性。

动液面深度检测中两个关键问题的研究进展

为了确保油田安全生产,满足提产增效的需求,实时检测井下动液面深度具有重要的意义。当采用声波法测量动液面深度时,需要解决套管内声速的计算和声波旅行时间的获取这两个关键问题。围绕该问题,归纳总结了近年来该领域取得的进展和成果,梳理了众多文献间的区别和联系。在此基础上,利用油田现场采集的声波信号对一些方法进行了复现。结果表明:对于不同环境的油井,上述方法存在明显的适应性差异。最后分析了当前研究的不足,并对两个关键问题的未来研究方向做出了展望。研究成果为特定环境下的井下声波信号处理提供了详细的解决方案,对于快速检索井下声波信号的处理方法有积极作用,具有一定的理论价值和重要的现实意义。

中厚板V型坡口GMAW电弧声信号焊缝偏差识别方法研究

针对中厚板V型坡口GMAW(熔化极气体保护焊)焊缝偏差识别问题,提出一种新型基于电弧声信号的中厚板GMAW摆动焊焊缝偏差识别方法。在V型坡口摆动焊接中,发现当摆动中心与焊缝中心出现偏差,电弧声信号呈现明显非对称性。为此,针对电弧声信号的时域和频域特征开展了进一步研究,明确了与焊缝偏差信号存在密切关联的电弧声摆动极限位置能量差、标准差、小波包第7频带和第8频带能量等特征参量。构建基于上述4类参量的GS-SVR非线性回归方程,通过电弧声特征信号检测,可实现焊接过程中焊接偏差信息的在线识别,通过左右偏差试验表明该模型具有良好精度,可满足工程实际生产需要。

基于随机森林的电机异音故障诊断方法

针对电机异音故障检测技术存在准确率低、模型复杂等问题,提出一种基于随机森林的电机异音故障诊断方法。通过自行研制的汽车智能座椅靠背电机振动测试平台,分析电机故障产生过程及异音的特征,并从时域中提取11个特征表征异音信号的变化;通过主成分分析法对所提取的特征进行降维,在训练基于随机森林和概率神经网络的电机故障智能识别方法基础上,通过自行研制的汽车智能座椅靠背电机振动测试平台采集数据,得到随机森林的平均识别准确率为95.11%±2.17%,概率神经网络的平均识别准确率为93.90%±2.16%。

基于IAFSA-SVM的心音信号识别研究

为提高心音信号识别的准确率,针对传统的支持向量机(SVM)在寻找最优核函数参数和惩罚因子时存在的优化问题,提出一种改进的人工鱼群算法(IAFSA)优化SVM的心音信号分类算法(IAFSA-SVM)。首先将采集到的含噪心音信号利用改进的小波阈值进行降噪处理,并进行时频域分析提取出特征值;然后采用改进的人工鱼群算法寻找最优SVM参数,并输入到SVM识别模型中进行心音信号的识别。通过仿真证实IAFSA-SVM算法相对于传统的SVM模型和粒子群优化的SVM模型提高了心音信号识别的准确率,为心脏病的诊断提供了新方法。

基于DE-VRF的猪声音分类识别

为了监测识别生猪健康状况以及情绪状态,提出一种基于差分进化优化加权随机森林(DE-VRF)猪只声音分类模型,以猪只咳嗽、尖叫和进食声作为研究对象,经预处理后提取改进的梅尔倒谱系数(MFCC_F)、短时能量和短时过零率进行特征融合。采用主成分分析法(PCA)将特征参数降至13维,利用差分进化算法优化加权随机森林模型参数,将融合特征参数输入DE-VRF进行训练与识别。实验结果表明,基于DE-VRF模型的猪只声音平均识别率达96.34%,较DNN、1D-CNN模型相比提高了系统识别的性能。

基于树莓派的心音诊断系统

当今社会,心脏疾病已成为威胁人类健康的“头号杀手”。心血管类疾病一直伴随着我们人类,成为人们生活中最大的隐患,对人们的生命健康造成了严重的威胁。因此,为了提取反映心脏健康状况的定量的全方位的心音信息,利用先进的数字信号处理技术和计算机技术,以树莓派为中央处理器,通过被誉为“数学显微镜”的小波变换分析心音的各种成份时间,设计一套便捷的、高质量的心音采集系统,并与互联网信息连接,能够对心音信号波形进行显示。实验测试结果表明,该系统所提取的波形平滑,系统运行稳定,可以准确地判断出所采集的心音信号类型,这对于心血管疾病的预防有重大意义。

心音采集电子综合实验项目设计与实现

面对目前高等教育中实验教学跨课程综合环节教学缺失的问题,提出了建设跨课程、跨学期的综合性实验课程的思想。采用心音采集作为示范项目,综合应用了信号传感、电路技术、微处理器技术以及简单的数字信号处理和控制原理等相关知识,以MSP430F6638微处理器为控制核心实现了对微弱心音信号的采集、存储、显示和传输。实验结果表明采集的心音信号能够清晰的显示出第一心音和第二心音。

小波包与混沌集成的心音特征提取及分类识别

针对心脏疾病诊断过程中心音识别的难点,提出了一种结合小波包分析及混沌的特征提取的心音识别方法。首先分析统计了心音信号的小波包能量特征,然后选取小波包分解中能表征心音信号特征的分量进行混沌分析,计算了最大Lyapunov指数和关联维数;最后以这些参数构成特征矢量作为支持向量机的输入,对临床采集到的65例正常及有心脏疾病的心音信号进行识别分类。结果表明,结合小波包分析和混沌的特征参量,较传统的分类识别方法具有更高的识别精度,说明非线性混沌特征能够较有效地表征心音信号的特征,为下一步临床心脏疾病的更准确诊断奠定了基础。