This repository collects our thesis about Riordan arrays, which is our work to graduate at the University of Florence, defended on October 10, 2015.
Candidate: Massimo Nocentini ([email protected])
Supervisor: prof. Donatella Merlini ([email protected])
This work aims to study a subset of objects belonging to the field of analytic
combinatorics, in particular generating functions, formal power series and
infinite lower triangular matrices. Many interesting books by Flajolet and
Sedgewick [1], Knuth [2] and Graham et al. [3] exist on those topics, where
skillful methods to handle sequences of counting numbers, combinatorial sums
and classes of combinatorial discrete objects, such as graphs, words, lattice
paths and trees, are presented. The concept of Riordan array is the core of
the present work. We are interested to show new characterizations to spot some
properties of their structure. One example is the
Although Riordan group theory has been studied intensively in the recent
past, we would like to give an introduction with our words, rethink about the
original and introductory papers of this theory, in particular those by
Shapiro, who introduces the Riordan group and builds a combinatorial
triangle counting non-intersecting paths; by Rogers, who introduces the
concept of renewal arrays and finds the important concept of their
The other topic of this work is the description and formalization of Riordan
arrays under the light of modular arithmetic. We have shown some congruences
about Pascal array
Finally, we have implemented a subset of Riordan group theory using the Python programming language, on top of Sage mathematical framework. Our implementation is written in pure object-oriented style and allows us to do raw matrix expansion, computing inverse arrays, applying modular transformation, using a set of partition functions, and building LaTeX,code for representing such modular arrays as coloured triangles.
[1] Flajolet and Sedgewick, Analytic Combinatorics, Cambridge University Press, 2009
[2] Knuth, The Art of Computer Programming, vol. 1-3, Addison-Wesley, 1973
[3] Graham, Knuth and Patashnik, Concrete Mathematics, Addison-Wesley, 1994
[4] Second International Symposium on Riordan Arrays and Related Topics, RART2015
The content about modular transformations, applied to Pascal and Catalan arrays in particular, was shown in a talk at RART2015; moreover, a paper that collects theorems about the Catalan triangle has been submitted.
Also, we provide an implementation to do matrix expansion of Riordan matrices and computing inverses, symbolically; finally, the code base includes the inductive procedure given in the paper to build the modular Catalan triangle, choosing modulo 2, avoiding the brute force approach; for details and other fractal objects, have a look in this notebook.