On Two Families of Generalizations of Pascal’s Triangle

On Two Families of Generalizations of Pascal’s Triangle

We consider two families of Pascal-like triangles that have all ones on the left side and ones separated by m − 1 zeros on the right side. The m = 1 cases are Pascal’s triangle and the two families also coincide when m = 2. Members of the first family obey Pascal’s recurrence everywhere inside the t...

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Main Author: Allen M.A.
Other Authors: Mahidol University
Format: Article
Published: 2023
Subjects:
Mathematics
Online Access:https://repository.li.mahidol.ac.th/handle/123456789/85121
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spelling th-mahidol.851212023-06-19T00:28:23Z On Two Families of Generalizations of Pascal’s Triangle Allen M.A. Mahidol University Mathematics We consider two families of Pascal-like triangles that have all ones on the left side and ones separated by m − 1 zeros on the right side. The m = 1 cases are Pascal’s triangle and the two families also coincide when m = 2. Members of the first family obey Pascal’s recurrence everywhere inside the triangle. We show that the m-th triangle can also be obtained by reversing the elements up to and including the main diagonal in each row of the (1/(1 − xm), x/(1 − x)) Riordan array. Properties of this family of triangles can be obtained quickly as a result. The (n, k)-th entry in the m-th member of the second family of triangles is the number of tilings of an (n + k) × 1 board that use k (1, m − 1)-fences and n − k unit squares. A (1, g)-fence is composed of two unit square sub-tiles separated by a gap of width g. We show that the entries in the antidiagonals of these triangles are coefficients of products of powers of two consecutive Fibonacci polynomials and give a bijective proof that these coefficients give the number of k-subsets of {1, 2, …, n −m} such that no two elements of a subset differ by m. Other properties of the second family of triangles are also obtained via a combinatorial approach. Finally, we give necessary and sufficient conditions for any Pascal-like triangle (or its row-reversed version) derived from tiling (n × 1)-boards to be a Riordan array. 2023-06-18T17:28:23Z 2023-06-18T17:28:23Z 2022-01-01 Article Journal of Integer Sequences Vol.25 No.7 (2022) 15307638 2-s2.0-85135198542 https://repository.li.mahidol.ac.th/handle/123456789/85121 SCOPUS
institution Mahidol University
building Mahidol University Library
continent Asia
country Thailand
Thailand
content_provider Mahidol University Library
collection Mahidol University Institutional Repository
topic Mathematics
spellingShingle Mathematics
Allen M.A.
On Two Families of Generalizations of Pascal’s Triangle
description We consider two families of Pascal-like triangles that have all ones on the left side and ones separated by m − 1 zeros on the right side. The m = 1 cases are Pascal’s triangle and the two families also coincide when m = 2. Members of the first family obey Pascal’s recurrence everywhere inside the triangle. We show that the m-th triangle can also be obtained by reversing the elements up to and including the main diagonal in each row of the (1/(1 − xm), x/(1 − x)) Riordan array. Properties of this family of triangles can be obtained quickly as a result. The (n, k)-th entry in the m-th member of the second family of triangles is the number of tilings of an (n + k) × 1 board that use k (1, m − 1)-fences and n − k unit squares. A (1, g)-fence is composed of two unit square sub-tiles separated by a gap of width g. We show that the entries in the antidiagonals of these triangles are coefficients of products of powers of two consecutive Fibonacci polynomials and give a bijective proof that these coefficients give the number of k-subsets of {1, 2, …, n −m} such that no two elements of a subset differ by m. Other properties of the second family of triangles are also obtained via a combinatorial approach. Finally, we give necessary and sufficient conditions for any Pascal-like triangle (or its row-reversed version) derived from tiling (n × 1)-boards to be a Riordan array.
author2 Mahidol University
author_facet Mahidol University
Allen M.A.
format Article
author Allen M.A.
author_sort Allen M.A.
title On Two Families of Generalizations of Pascal’s Triangle
title_short On Two Families of Generalizations of Pascal’s Triangle
title_full On Two Families of Generalizations of Pascal’s Triangle
title_fullStr On Two Families of Generalizations of Pascal’s Triangle
title_full_unstemmed On Two Families of Generalizations of Pascal’s Triangle
title_sort on two families of generalizations of pascal’s triangle
publishDate 2023
url https://repository.li.mahidol.ac.th/handle/123456789/85121
_version_ 1781415108806705152

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