School of Electronic and Information Engineering, Jiangsu University, Xuefu Road 301#, Zhenjiang, PR China.
Comput Biol Med. 2012 Jan;42(1):30-8. doi: 10.1016/j.compbiomed.2011.10.004. Epub 2011 Nov 8.
This paper presented a new ant colony optimization (ACO) feature selection method to classify hand motion surface electromyography (sEMG) signals. The multiple channels of sEMG recordings make the dimensionality of sEMG feature grow dramatically. It is known that the informative feature subset with small size is a precondition for the accurate and computationally efficient classification strategy. Therefore, this study proposed an ACO based feature selection scheme using the heuristic information measured by the minimum redundancy maximum relevance criterion (ACO-mRMR). The experiments were conducted on ten subjects with eight upper limb motions. Two feature sets, i.e., time domain features combined with autoregressive model coefficients (TDAR) and wavelet transform (WT) features, were extracted from the recorded sEMG signals. The average classification accuracies of using ACO reduced TDAR and WT features were 95.45±2.2% and 96.08±3.3%, respectively. The principal component analysis (PCA) was also conducted on the same data sets for comparison. The average classification accuracies of using PCA reduced TDAR and WT features were 91.51±4.9% and 89.87±4.4%, respectively. The results demonstrated that the proposed ACO-mRMR based feature selection method can achieve considerably high classification rates in sEMG motion classification task and be applicable to other biomedical signals pattern analysis.
本文提出了一种新的蚁群优化(ACO)特征选择方法,用于对手部运动表面肌电(sEMG)信号进行分类。sEMG 的多通道记录使得 sEMG 特征的维度急剧增加。众所周知,具有小尺寸的信息特征子集是准确和计算高效的分类策略的前提。因此,本研究提出了一种基于蚁群优化的特征选择方案,该方案使用最小冗余最大相关性准则(ACO-mRMR)测量的启发式信息。实验在十位具有八种上肢运动的受试者上进行。从记录的 sEMG 信号中提取了两个特征集,即时域特征与自回归模型系数(TDAR)和小波变换(WT)特征的组合。使用 ACO 减少的 TDAR 和 WT 特征的平均分类准确率分别为 95.45±2.2%和 96.08±3.3%。还对相同的数据集进行了主成分分析(PCA)进行比较。使用 PCA 减少的 TDAR 和 WT 特征的平均分类准确率分别为 91.51±4.9%和 89.87±4.4%。结果表明,所提出的基于 ACO-mRMR 的特征选择方法可以在 sEMG 运动分类任务中实现相当高的分类率,并适用于其他生物医学信号模式分析。
