The following figure shows the 6 such paths through a ${\displaystyle 2\times 2}$  grid:

A Schröder path of length ${\displaystyle n}$  is a lattice path from ${\displaystyle (0,0)}$  to ${\displaystyle (2n,0)}$  with steps northeast, ${\displaystyle (1,1);}$  east, ${\displaystyle (2,0);}$  and southeast, ${\displaystyle (1,-1),}$  that do not go below the ${\displaystyle x}$ -axis. The ${\displaystyle n}$ th Schröder number is the number of Schröder paths of length ${\displaystyle n}$ .^[2] The following figure shows the 6 Schröder paths of length 2.

Similarly, the Schröder numbers count the number of ways to divide a rectangle into ${\displaystyle n+1}$  smaller rectangles using ${\displaystyle n}$  cuts through ${\displaystyle n}$  points given inside the rectangle in general position, each cut intersecting one of the points and dividing only a single rectangle in two (i.e., the number of structurally-different guillotine partitions). This is similar to the process of triangulation, in which a shape is divided into nonoverlapping triangles instead of rectangles. The following figure shows the 6 such dissections of a rectangle into 3 rectangles using two cuts:

Pictured below are the 22 dissections of a rectangle into 4 rectangles using three cuts:

The Schröder number ${\displaystyle S_{n}}$  also counts the separable permutations of length ${\displaystyle n-1.}$ 

Schröder numbers are sometimes called large or big Schröder numbers because there is another Schröder sequence: the little Schröder numbers, also known as the Schröder-Hipparchus numbers or the super-Catalan numbers. The connections between these paths can be seen in a few ways:

• Consider the paths from ${\displaystyle (0,0)}$  to ${\displaystyle (n,n)}$  with steps ${\displaystyle (1,1),}$  ${\displaystyle (2,0),}$  and ${\displaystyle (1,-1)}$  that do not rise above the main diagonal. There are two types of paths: those that have movements along the main diagonal and those that do not. The (large) Schröder numbers count both types of paths, and the little Schröder numbers count only the paths that only touch the diagonal but have no movements along it.^[3]
• Just as there are (large) Schröder paths, a little Schröder path is a Schröder path that has no horizontal steps on the ${\displaystyle x}$ -axis.^[4]
• If ${\displaystyle S_{n}}$  is the ${\displaystyle n}$ th Schröder number and ${\displaystyle s_{n}}$  is the ${\displaystyle n}$ th little Schröder number, then ${\displaystyle S_{n}=2s_{n}}$  for ${\displaystyle n>0}$  ${\displaystyle (S_{0}=s_{0}=1).}$ ^[4]

Schröder paths are similar to Dyck paths but allow the horizontal step instead of just diagonal steps. Another similar path is the type of path that the Motzkin numbers count; the Motzkin paths allow the same diagonal paths but allow only a single horizontal step, (1,0), and count such paths from ${\displaystyle (0,0)}$  to ${\displaystyle (n,0)}$ .^[5]

There is also a triangular array associated with the Schröder numbers that provides a recurrence relation^[6] (though not just with the Schröder numbers). The first few terms are

1, 1, 2, 1, 4, 6, 1, 6, 16, 22, .... (sequence A033877 in the OEIS).

It is easier to see the connection with the Schröder numbers when the sequence is in its triangular form:

Then the Schröder numbers are the diagonal entries, i.e. ${\displaystyle S_{n}=T(n,n)}$  where ${\displaystyle T(n,k)}$  is the entry in row ${\displaystyle n}$  and column ${\displaystyle k}$ . The recurrence relation given by this arrangement is

${\displaystyle T(n,k)=T(n,k-1)+T(n-1,k-1)+T(n-1,k)}$ 

with ${\displaystyle T(1,k)=1}$  and ${\displaystyle T(n,k)=0}$  for ${\displaystyle k>n}$ .^[6] Another interesting observation to make is that the sum of the ${\displaystyle n}$ th row is the ${\displaystyle (n+1)}$ st little Schröder number; that is,

${\displaystyle \sum _{k=0}^{n}T(n,k)=s_{n+1}}$ .

With ${\displaystyle S_{0}=1}$ , ${\displaystyle S_{1}=2}$ , ^[7]

${\displaystyle S_{n}=3S_{n-1}+\sum _{k=1}^{n-2}S_{k}S_{n-k-1}}$  for ${\displaystyle n\geq 2}$ 

and also

${\displaystyle S_{n}={\frac {6n-3}{n+1}}S_{n-1}-{\frac {n-2}{n+1}}S_{n-2}}$  for ${\displaystyle n\geq 2}$ 

The generating function ${\displaystyle G(x)}$  of ${\displaystyle (S_{n})}$  is

${\displaystyle G(x)={\frac {1-x-{\sqrt {x^{2}-6x+1}}}{2x}}=\sum _{n=0}^{\infty }S_{n}x^{n}}$ .^[7]

One topic of combinatorics is tiling shapes, and one particular instance of this is domino tilings; the question in this instance is, "How many dominoes (that is, ${\displaystyle 1\times 2}$  or ${\displaystyle 2\times 1}$  rectangles) can we arrange on some shape such that none of the dominoes overlap, the entire shape is covered, and none of the dominoes stick out of the shape?" The shape that the Schröder numbers have a connection with is the Aztec diamond. Shown below for reference is an Aztec diamond of order 4 with a possible domino tiling.

It turns out that the determinant of the ${\displaystyle (2n-1)\times (2n-1)}$  Hankel matrix of the Schröder numbers, that is, the square matrix whose ${\displaystyle (i,j)}$ th entry is ${\displaystyle S_{i+j-1},}$  is the number of domino tilings of the order ${\displaystyle n}$  Aztec diamond, which is ${\displaystyle 2^{n(n+1)/2}.}$ ^[8] That is,

${\displaystyle {\begin{vmatrix}S_{1}&S_{2}&\cdots &S_{n}\\S_{2}&S_{3}&\cdots &S_{n+1}\\\vdots &\vdots &\ddots &\vdots \\S_{n}&S_{n+1}&\cdots &S_{2n-1}\end{vmatrix}}=2^{n(n+1)/2}.}$ 

For example:

• ${\displaystyle {\begin{vmatrix}2\end{vmatrix}}=2=2^{1(2)/2}}$ 

• ${\displaystyle {\begin{vmatrix}2&6\\6&22\end{vmatrix}}=8=2^{2(3)/2}}$ 

• ${\displaystyle {\begin{vmatrix}2&6&22\\6&22&90\\22&90&394\end{vmatrix}}=64=2^{3(4)/2}}$ 

• Delannoy number
• Motzkin number
• Narayana number
• Narayana polynomials
• Schröder–Hipparchus number
• Catalan number

• Weisstein, Eric W. "Schröder Number". MathWorld.
• Stanley, Richard P.: Catalan addendum to Enumerative Combinatorics, Volume 2