На этой странице Вы можете получить подробный анализ слова или словосочетания, произведенный с помощью лучшей на сегодняшний день технологии искусственного интеллекта:
математика
процедура мажорирования
математика
стандартная процедура
строительное дело
стандартный приём (метод), стандартная методика
Stress majorization is an optimization strategy used in multidimensional scaling (MDS) where, for a set of -dimensional data items, a configuration of points in -dimensional space is sought that minimizes the so-called stress function . Usually is or , i.e. the matrix lists points in or dimensional Euclidean space so that the result may be visualised (i.e. an MDS plot). The function is a cost or loss function that measures the squared differences between ideal (-dimensional) distances and actual distances in r-dimensional space. It is defined as:
where is a weight for the measurement between a pair of points , is the euclidean distance between and and is the ideal distance between the points (their separation) in the -dimensional data space. Note that can be used to specify a degree of confidence in the similarity between points (e.g. 0 can be specified if there is no information for a particular pair).
A configuration which minimizes gives a plot in which points that are close together correspond to points that are also close together in the original -dimensional data space.
There are many ways that could be minimized. For example, Kruskal recommended an iterative steepest descent approach. However, a significantly better (in terms of guarantees on, and rate of, convergence) method for minimizing stress was introduced by Jan de Leeuw. De Leeuw's iterative majorization method at each step minimizes a simple convex function which both bounds from above and touches the surface of at a point , called the supporting point. In convex analysis such a function is called a majorizing function. This iterative majorization process is also referred to as the SMACOF algorithm ("Scaling by MAjorizing a COmplicated Function").