A novel family of geometric signal detectors are proposed through medians of the total Bregman divergence (TBD), which are shown advantageous over the conventional methods and their mean counterparts. By interpreting the observation data as Hermitian positive-definite (HPD) matrices, their mean or median play an essential role in signal detection. As is difficult to be solved analytically, we propose numerical solutions through Riemannian gradient descent algorithms or fixed-point algorithms. Beside detection performance, robustness of a detector to outliers is also of vital importance, which can often be analyzed via the influence functions. Introducing an orthogonal basis for Hermitian matrices, we are able to compute the corresponding influence functions analytically and exactly by solving a linear system, which is transformed from the governing matrix equation. Numerical simulations show that the TBD medians are more robust than their mean counterparts.
翻译:通过显示优于传统方法及其平均对等方的布雷格曼总差异的中位数,提出了几何信号探测器的新体系。通过将观测数据解释为赫米西亚正无限制矩阵,其平均值或中位值在信号探测中起着不可或缺的作用。由于难以通过分析解决,我们通过里格曼梯度下行算法或定点算法提出了数字解决方案。在检测之外,探测器对外部线的稳健性也至关重要,这往往可以通过影响功能加以分析。在赫米提亚矩阵引入一个正方位基时,我们能够通过分析来计算相应的影响函数,并准确地通过从管理矩阵方程式中转换出来的线性系统来计算。数字模拟表明TBD中位值比其平均对等方更强大。