系统工程与电子技术
繫統工程與電子技術
계통공정여전자기술
SYSTEMS ENGINEERING AND ELECTRONICS
2014年
11期
2143-2148
,共6页
混合矩阵估计%Davies-Bouldin 指标%密度参数%改进 K-均值聚类
混閤矩陣估計%Davies-Bouldin 指標%密度參數%改進 K-均值聚類
혼합구진고계%Davies-Bouldin 지표%밀도삼수%개진 K-균치취류
mixing matrix estimation%Davies-Bouldin (DB)index%density parameter%improved K-means clustering
在源信号个数未知条件下,提出一种基于改进 K-均值聚类的欠定混合矩阵盲估计方法。该方法首先计算观测信号在单位半超球面上投影点的密度参数,然后去掉低密度投影点,并从高密度投影点中选取初始聚类中心,最后对剩余投影点进行聚类,根据 Davies-Bouldin 指标估计源信号个数,并估计出混合矩阵。仿真结果表明,该方法的复杂度低,其运行时间仅为拉普拉斯势函数法的1%~3%;该方法的源信号个数估计正确率远高于鲁棒竞争聚类算法,当信噪比高于13 dB 时,该方法源信号个数估计正确率大于96.6%,且混合矩阵估计误差较小。该方法在信噪比较高时,可降低对源信号稀疏度的要求。
在源信號箇數未知條件下,提齣一種基于改進 K-均值聚類的欠定混閤矩陣盲估計方法。該方法首先計算觀測信號在單位半超毬麵上投影點的密度參數,然後去掉低密度投影點,併從高密度投影點中選取初始聚類中心,最後對剩餘投影點進行聚類,根據 Davies-Bouldin 指標估計源信號箇數,併估計齣混閤矩陣。倣真結果錶明,該方法的複雜度低,其運行時間僅為拉普拉斯勢函數法的1%~3%;該方法的源信號箇數估計正確率遠高于魯棒競爭聚類算法,噹信譟比高于13 dB 時,該方法源信號箇數估計正確率大于96.6%,且混閤矩陣估計誤差較小。該方法在信譟比較高時,可降低對源信號稀疏度的要求。
재원신호개수미지조건하,제출일충기우개진 K-균치취류적흠정혼합구진맹고계방법。해방법수선계산관측신호재단위반초구면상투영점적밀도삼수,연후거도저밀도투영점,병종고밀도투영점중선취초시취류중심,최후대잉여투영점진행취류,근거 Davies-Bouldin 지표고계원신호개수,병고계출혼합구진。방진결과표명,해방법적복잡도저,기운행시간부위랍보랍사세함수법적1%~3%;해방법적원신호개수고계정학솔원고우로봉경쟁취류산법,당신조비고우13 dB 시,해방법원신호개수고계정학솔대우96.6%,차혼합구진고계오차교소。해방법재신조비교고시,가강저대원신호희소도적요구。
A method for blind estimation of underdetermined mixing matrix based on improved K-means clustering is proposed when the source number is unknown.First,the density parameter of the projection points of the mixing signals on half of the unit ultra sphere is calculated.Then,the projection points with low density are removed and the initial clustering centers are chosen from the projection points with high density.Finally, cluster the remaining points,use the Davies-Boudin index to estimate the source number,and estimate the mix-ing matrix.The simulation results show that the proposed algorithm’s complexity is lower and its running time is only about 1% to 3% of that of the Laplace mixed model potential function algorithm;its source number esti-mation accuracy is much higher than that of the robust competitive agglomeration algorithm;when the signal to noise ratio is greater than 13 dB,its accuracy is higher than 96.6% and its estimated mixing matrix error is small.When SNR is higher,it can relax the sparsity requirement of the sources.