It is often desirable to summarise a probability measure on a space $X$ in terms of a mode, or MAP estimator, i.e. a point of maximum probability. Such points can be rigorously defined using masses of metric balls in the small-radius limit. However, the theory is not entirely straightforward: the literature contains multiple notions of mode and various examples of pathological measures that have no mode in any sense. Since the masses of balls induce natural orderings on the points of $X$, this article aims to shed light on some of the problems in non-parametric MAP estimation by taking an order-theoretic perspective, which appears to be a new one in the inverse problems community. This point of view opens up attractive proof strategies based upon the Cantor and Kuratowski intersection theorems; it also reveals that many of the pathologies arise from the distinction between greatest and maximal elements of an order, and from the existence of incomparable elements of $X$, which we show can be dense in $X$, even for an absolutely continuous measure on $X = \mathbb{R}$.
翻译:通常有必要用一种模式或MAP测算器来概括对一个空间的X美元概率测量值,即最大概率点。这些点可以用小半径限制的多球量来严格定义。然而,理论并不完全直截了当:文献中包含多种模式概念和各种没有任何模式的病理计量实例。由于球团在X美元点上诱导自然定序,本文章的目的是通过采用定序理论角度来说明非参数的MAP估算的某些问题,这似乎是反向问题界中的一种新观点。这个观点开启了基于Cantor和Kuratowski交叉理论的有吸引力的证据战略;它还表明,许多病理来自一个顺序的最大和最大要素之间的区别,以及我们所显示的无法比较的美元($X美元)的存在,即使对于美元=\mathbb{R}的绝对连续测量值也是如此。