Ceylan Murat, Ceylan Rahime, Ozbay Yüksel, Kara Sadik
Selcuk University, Department of Electrical & Electronics Engineering, Engineering and Architecture Faculty, 42075 Konya, Turkey.
Artif Intell Med. 2008 Sep;44(1):65-76. doi: 10.1016/j.artmed.2008.05.003. Epub 2008 Jul 22.
In biomedical signal classification, due to the huge amount of data, to compress the biomedical waveform data is vital. This paper presents two different structures formed using feature extraction algorithms to decrease size of feature set in training and test data.
The proposed structures, named as wavelet transform-complex-valued artificial neural network (WT-CVANN) and complex wavelet transform-complex-valued artificial neural network (CWT-CVANN), use real and complex discrete wavelet transform for feature extraction. The aim of using wavelet transform is to compress data and to reduce training time of network without decreasing accuracy rate. In this study, the presented structures were applied to the problem of classification in carotid arterial Doppler ultrasound signals. Carotid arterial Doppler ultrasound signals were acquired from left carotid arteries of 38 patients and 40 healthy volunteers. The patient group included 22 males and 16 females with an established diagnosis of the early phase of atherosclerosis through coronary or aortofemoropopliteal (lower extremity) angiographies (mean age, 59 years; range, 48-72 years). Healthy volunteers were young non-smokers who seem to not bear any risk of atherosclerosis, including 28 males and 12 females (mean age, 23 years; range, 19-27 years).
Sensitivity, specificity and average detection rate were calculated for comparison, after training and test phases of all structures finished. These parameters have demonstrated that training times of CVANN and real-valued artificial neural network (RVANN) were reduced using feature extraction algorithms without decreasing accuracy rate in accordance to our aim.
在生物医学信号分类中,由于数据量巨大,压缩生物医学波形数据至关重要。本文提出了两种使用特征提取算法形成的不同结构,以减小训练和测试数据中特征集的大小。
所提出的结构,分别命名为小波变换 - 复值人工神经网络(WT - CVANN)和复小波变换 - 复值人工神经网络(CWT - CVANN),使用实离散小波变换和复离散小波变换进行特征提取。使用小波变换的目的是在不降低准确率的情况下压缩数据并减少网络训练时间。在本研究中,将所提出的结构应用于颈动脉多普勒超声信号的分类问题。从38例患者和40名健康志愿者的左颈动脉采集颈动脉多普勒超声信号。患者组包括22名男性和16名女性,通过冠状动脉或主动脉股腘动脉(下肢)血管造影确诊为动脉粥样硬化早期(平均年龄59岁;范围48 - 72岁)。健康志愿者为年轻不吸烟者,似乎没有任何动脉粥样硬化风险,包括28名男性和12名女性(平均年龄23岁;范围19 - 27岁)。
在所有结构的训练和测试阶段完成后,计算敏感性、特异性和平均检测率进行比较。这些参数表明,根据我们的目标,使用特征提取算法在不降低准确率的情况下减少了CVANN和实值人工神经网络(RVANN)的训练时间。
