AbstractWe count the number of lattice paths lying under a cyclically shifting piecewise linear boundary of varying slope. Our main result can be viewed as an extension of well-known enumerative formulae concerning lattice paths dominated by lines of integer slope (e.g. the generalized ballot theorem). Its proof is bijective, involving a classical “reflection” argument. Moreover, a straightforward refinement of our bijection allows for the counting of paths with a specified number of corners. We also show how the result can be applied to give elegant derivations for the number of lattice walks under certain periodic boundaries. In particular, we recover known expressions concerning paths dominated by a line of half-integer slope, and some n...
© 2012 Dr. Paul W. T. FijnThis thesis primarily examines several problems in enumerative combinatori...
AbstractWe provide a direct geometric bijection for the number of lattice paths that never go below ...
AbstractLattice chains and Delannoy paths represent two different ways to progress through a lattice...
We count the number of lattice paths lying under a cyclically shifting piecewise linear boundary of ...
AbstractWe count the number of lattice paths lying under a cyclically shifting piecewise linear boun...
AbstractThere is a strikingly simple classical formula for the number of lattice paths avoiding the ...
AbstractThis paper develops a unified enumerative and asymptotic theory of directed two-dimensional ...
We solve two problems regarding the enumeration of lattice paths in \(\mathbb{Z}^2\) with steps \((1...
International audienceWe analyze some enumerative and asymptotic properties of Dyck paths under a li...
AbstractWe count lattice paths that are confined to the first quadrant by the nature of their step v...
AbstractThis note generalizes André's reflection principle to give a new combinatorial proof of a fo...
We give bijective proofs that, when combined with one of the combinatorial proofs of the general bal...
AbstractA bijective proof of Gessel and Viennot is extended to a proof of an n-dimensional q-analogu...
AbstractA lattice path is a path on lattice points (points with integer coordinates) in the plane in...
AbstractWe deal with non-decreasing paths on the non-negative quadrant of the integral square lattic...
© 2012 Dr. Paul W. T. FijnThis thesis primarily examines several problems in enumerative combinatori...
AbstractWe provide a direct geometric bijection for the number of lattice paths that never go below ...
AbstractLattice chains and Delannoy paths represent two different ways to progress through a lattice...
We count the number of lattice paths lying under a cyclically shifting piecewise linear boundary of ...
AbstractWe count the number of lattice paths lying under a cyclically shifting piecewise linear boun...
AbstractThere is a strikingly simple classical formula for the number of lattice paths avoiding the ...
AbstractThis paper develops a unified enumerative and asymptotic theory of directed two-dimensional ...
We solve two problems regarding the enumeration of lattice paths in \(\mathbb{Z}^2\) with steps \((1...
International audienceWe analyze some enumerative and asymptotic properties of Dyck paths under a li...
AbstractWe count lattice paths that are confined to the first quadrant by the nature of their step v...
AbstractThis note generalizes André's reflection principle to give a new combinatorial proof of a fo...
We give bijective proofs that, when combined with one of the combinatorial proofs of the general bal...
AbstractA bijective proof of Gessel and Viennot is extended to a proof of an n-dimensional q-analogu...
AbstractA lattice path is a path on lattice points (points with integer coordinates) in the plane in...
AbstractWe deal with non-decreasing paths on the non-negative quadrant of the integral square lattic...
© 2012 Dr. Paul W. T. FijnThis thesis primarily examines several problems in enumerative combinatori...
AbstractWe provide a direct geometric bijection for the number of lattice paths that never go below ...
AbstractLattice chains and Delannoy paths represent two different ways to progress through a lattice...