We propose here a new approach to
the evaluation of two-dimensional
and, more generally, multidimensional separations based on topological
methods. We consider the apex plot as a graph, which could further
be treated using a topological tool: the measure of distances between
the nearest neighbors (NND). Orthogonality can be thus defined as
the quality of peak dispersion in normalized separation space, which
is characterized by two factors describing the population of distances
between nearest neighbors: the lengths (di(o)) of distances
and the degree of similarity of all lengths. Orthogonality grows with
the increase of both factors. The NND values were used to calculate
a number of new descriptors. They inform about the extent of peak
distribution, like the arithmetic mean (A̅(o)) of NNDs, as well as about the homogeneity of peak distribution,
like the geometric mean (G̅(o))
and the harmonic mean (H̅(o)). Our
new, NND-based approach was compared with another recently published
method of orthogonality evaluation: the fractal dimensionality (DF). The comparison shows that the geometric
mean (G̅(o)) is the descriptor behaving
in the most similar way to dimensionality (DF) and the harmonic mean (H̅(o)) displays superior sensitivity to the shortest, critical distances
between peaks. The latter descriptor (H̅(o)) can be considered as sufficient to describe the degree
of orthogonality based on NND. The method developed is precise, simple,
easy to implement, and possible to use for the description of separations
in a true or virtual system of any number of dimensions.