估计排序

2010 44th Annual Conference on Information Sciences and Systems (CISS) Pub Date : 2010-03-17 DOI:10.1109/CISS.2010.5464939

Rick S. Blum

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引用次数: 1

摘要

对于从一组分散的传感器节点获得数据的情况，考虑了连续优化问题的离散化版本，并且总体度量是在每个传感器计算的单个度量的总和。这种问题的一个例子是基于统计独立的传感器观测值的最大似然估计。通过对来自传感器节点的传输进行排序，描述了一种用于节省传感器传输的平均数量的方法。虽然传感器传输的平均数量减少了，但该方法总是产生与所有传感器传输的最佳方法相同的解决方案。首先描述了该方法的一般优化问题。随后描述了多节点非相干MIMO雷达系统的最大似然目标定位和速度估计示例。特别是在信号接近理想、监视区域足够小、信噪比足够大的情况下，随着优化问题Q中离散网格点的数量显著增加，平均节省的传输百分比接近100%。在这些相同的情况下，随着网络中传感器数量N的显著增加，传输节省的平均百分比(Q−1)/Q × 100%。对于设计良好的系统的一般优化(或估计)问题，也说明了类似的节省。

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Ordering for estimation

A discretetized version of a continuous optimization problem is considered for the case where data is obtained from a set of dispersed sensor nodes and the overall metric is a sum of individual metrics computed at each sensor. An example of such a problem is maximum likelihood estimation based on statistically independent sensor observations. By ordering transmissions from the sensor nodes, a method for achieving a saving in the average number of sensor transmissions is described. While the average number of sensor transmissions is reduced, the approach always yields the same solution as the optimum approach where all sensors transmit. The approach is described first for a general optimization problem. A maximum likelihood target location and velocity estimation example for a multiple node non-coherent MIMO radar system is later described. In particular, for cases with near ideal signals, sufficiently small surveillance region and sufficiently large signal-to-interference-plus-noise ratio, the average percentage of transmissions saved approaches 100 percent as the number of discrete grid points in the optimization problem Q becomes significantly large. In these same cases, the average percentage of transmissions saved approaches (Q − 1)/Q × 100 percent as the number of sensors N in the network becomes significantly large. Similar savings are illustrated for general optimization (or estimation) problems with well designed systems.

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来源期刊

2010 44th Annual Conference on Information Sciences and Systems (CISS)

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