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\begin{document}

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\epsfxsize=4in
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\begin{center}
\vskip 1cm{\Large\bf Permutations Defining Convex Permutominoes
}
\vskip 1cm
Antonio Bernini\\
Universit\`a di Firenze\\
Dipartimento di Sistemi e Informatica \\
viale Morgagni 65\\
50134 Firenze\\
Italy \\
\href{mailto:bernini@dsi.unifi.it}{\tt bernini@dsi.unifi.it} \\
\ \\
Filippo Disanto\\
Universit\`a di Siena\\
Dipartimento di Scienze Matematiche e Informatiche \\
Pian dei Mantellini 44\\
53100 Siena\\
Italy\\
\ \\
Renzo Pinzani\\
Universit\`a di Firenze\\
Dipartimento di Sistemi e Informatica \\
viale Morgagni 65\\
50134 Firenze\\
Italy \\
\href{mailto:pinzani@dsi.unifi.it}{\tt pinzani@dsi.unifi.it} \\
\ \\
Simone Rinaldi \\
Universit\`a di Siena\\
Dipartimento di Scienze Matematiche e Informatiche \\
Pian dei Mantellini 44\\
53100 Siena\\
Italy\\
\href{mailto:rinaldi@unisi.it}{\tt rinaldi@unisi.it} \\

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\vskip .2 in

\begin{abstract}
A permutomino of size $n$ is a polyomino determined by particular pairs $(\pi_1, \pi_2)$ of permutations of size
$n$, such that $\pi_1(i)\neq \pi_2(i)$, for $1\leq i\leq n$. Here we determine the combinatorial properties and,
in particular, the characterization for the pairs of permutations defining convex permutominoes.

Using such a characterization, these permutations can be uniquely
represented in terms of the so-called square permutations,
introduced by Mansour and Severini. We provide a closed
formula for the number of these permutations with size $n$.

\end{abstract}

\newtheorem{theorem}{Theorem}
\newtheorem{corollary}[theorem]{Corollary}
\newtheorem{lemma}[theorem]{Lemma}
\newtheorem{proposition}[theorem]{Proposition}
\newtheorem{conjecture}[theorem]{Conjecture}


\title{Permutations defining convex permutominoes}

%\newtheorem{definition}{Definition}
%\newtheorem{proposition}{Proposition}
%\newtheorem{corollary}{Corollary}
\newtheorem{example}{Example}
%\newtheorem{theorem}{Theorem}
\setlength{\parindent}{20pt}
%\newcommand{\qed}{\hfill\square\medskip}




\section{Convex polyominoes}

In the plane $\Bbb Z \times \Bbb Z$ a {\em cell} is a unit square,
and a {\em polyomino} is a finite connected union of cells having
no cut point. Polyominoes are defined up to translations (see
Figure~\ref{polyom}~(a)). A {\em column} ({\em row}) of a
polyomino is the intersection between the polyomino and an
infinite strip of cells lying on a vertical (horizontal) line.

Polyominoes were introduced by Golomb~\cite{dbintr39}, and then
they have been studied in several mathematical problems, such as
tilings~\cite{Gi, Go}, or games~\cite{Ga} among many others. The
enumeration problem for general polyominoes is difficult to solve
and still open. The number $a_n$ of polyominoes with $n$ cells is
known up to $n=56$~\cite{jensen-guttmann} and asymptotically,
these numbers satisfy the relation $\smash{\lim_n \left(a_n
\right)^{1/n}=\mu}$, \ $3.96 < \mu <4.64$, where the lower bound
is a recent improvement \cite{bmrr}.

\medskip

In order to simplify enumeration problems of polyominoes, several
subclasses were defined by combining the two simple notions of
{\em convexity} and {\em directed growth}. A polyomino is said to
be {\em column convex} (resp. {\em row convex}) if every its
column (resp. row) is connected (see Figure~\ref{polyom}~$(b)$). A
polyomino is said to be {\em convex}, if it is both row and column
convex (see Figure~\ref{polyom}~$(c)$). The {\em area} of a
polyomino is just the number of cells it contains, while its {\em
semi-perimeter} is half the number of edges of cells in its
boundary. Thus, for any convex polyomino the semi-perimeter is the
sum of the numbers of its rows and columns. Moreover, any convex
polyomino is contained in a rectangle in the square lattice which
has the same semi-perimeter, called {\em minimal bounding
rectangle}.

\medskip

\begin{figure}[htb]
\begin{center}
\epsfig{file=sample.eps}
\end{center}
\caption{(a) a polyomino; (b) a column convex polyomino which is
not row convex; (c) a convex polyomino. \label{polyom}}
\end{figure}

Delest and Viennot \cite{DV} obtained a first significant result
in the enumeration of convex polyominoes. They proved that the
number $\ell_n$ of convex polyominoes with semi-perimeter equal to
$n+2$ is
\begin{equation}\label{eq1}
\ell_{n+2}=(2n+11)4^n \, - \, 4(2n+1) \, {2n \choose n}, \quad n
\geq 2; \quad \ell_{0}=1, \quad \ell_{1}=2.
\end{equation}
\noindent whose first terms (sequence \seqnum{A005436} in \cite{sloane}) are
$$1,2,7,28,120,528,2344,10416, \ldots\quad .$$

%This is sequence $A005436$ in \cite{sloane}, the first few terms
%being:
During the last two decades convex polyominoes, and several
combinatorial objects obtained as a generalizations of this class,
have been studied by various points of view. For the main results
concerning the enumeration and other combinatorial properties of
convex polyominoes we refer to \cite{mbm2, mbm, gutman, chang}.

\medskip

There are two other classes of convex polyominoes which will be
useful in the paper, the {\em directed convex polyominoes} and the
{\em parallelogram polyominoes}. A polyomino is said to be {\em
directed} when each of its cells can be reached from a
distinguished cell, called {\em root}, by a path which is
contained in the polyomino and uses only north and east unitary
steps.

A polyomino is {\em directed convex} if it is both directed and
convex (see Figure~\ref{dirconv}~(a)). It is known that the number
of directed convex polyominoes of semi-perimeter $n+2$ is equal to
the $n$th central binomial coefficient (sequence \seqnum{A000984}
in \cite{sloane}), i.e.,
\begin{equation}\label{bin}
b_n={2n \choose n}.
\end{equation}


\begin{figure}[htb]
\centerline{\hbox{\psfig{figure=parallelogrammi.eps}}}
\caption{(a)  A directed convex polyomino; (b) a parallelogram
polyomino.\label{dirconv}}
\end{figure}
Finally, {\em parallelogram polyominoes} are a special subset of
the directed convex ones, defined by two lattice paths that use
north and east unit steps, and intersect only at their origin and
extremity. These paths are called the {\em upper} and the {\em
lower path} (see Figure~\ref{dirconv}~(b)). It is
known~\cite{stan} that the number of parallelogram polyominoes
having semi-perimeter $n+1$ is the $n$-th {\em Catalan number}
(sequence \seqnum{A000108} in \cite{sloane}),
\begin{equation}\label{cat}
c_n=\frac{1}{n+1} {2n \choose n}.
\end{equation}

%\begin{figure}[htb]
%\centerline{\hbox{\psfig{figure=sc.eps}}} \caption{The seven
%convex polyominoes having semi-perimeter equal to four; the first
%five from the left are parallelogram ones, the sixth one is
%directed convex. \label{sc}}
%\end{figure}

\section{Convex permutominoes}

Let $P$ be a polyomino without holes, having $n$ rows and columns,
$n\geq 1$; we assume without loss of generality that the
south-west corner of its minimal bounding rectangle is placed in
$(1,1)$. Let ${\mathcal A}= \left( A_1, \ldots ,A_{2(r+1)}
\right)$ be the list of its vertices (i.e., corners of its
boundary) ordered in a clockwise sense starting from the lowest
leftmost vertex. We say that $P$ is a {\em permutomino} if
${\mathcal P}_1 = \left( A_1, A_3, \ldots ,A_{2r+1} \right)$ and
${\mathcal P}_2 = \left( A_2, A_4, \ldots ,A_{2r+2} \right)$
represent two permutations of ${\mathcal S}_{n+1}$, where, as
usual, ${\mathcal S}_{n}$ is the symmetric group of size $n$.
Obviously, if $P$ is a permutomino, then $r=n$, and $n+1$ is
called the {\em size} of the permutomino. The two permutations
defined by ${\mathcal P}_1$ and ${\mathcal P}_2$ are indicated by
$\pi _1(P)$ and $\pi _2(P)$, respectively (see Figure
\ref{permu1}).

From the definition any permutomino $P$ has the property that, for
each abscissa (ordinate) there is exactly one vertical
(horizontal) side in the boundary of $P$ with that coordinate. It
is simple to observe that this property is also a sufficient
condition for a polyomino to be a permutomino. By convention we
also consider the empty permutomino of size $1$, associated with
$\pi=(1)$.

\begin{figure}[htb]
\begin{center}
\epsfig{file=permu1.eps} \caption{A permutomino and the two
associated permutations. \label{permu1}}
\end{center}
\end{figure}


Permutominoes were introduced by F.~Incitti \cite{incitti} while
studying the problem of determining the
$\widetilde{R}$-polynomials (related with the Kazhdan-Lusztig
R-polynomials) associated with a pair $(\pi_1,\pi_2)$ of
permutations. Concerning the class of polyominoes without holes,
our definition (though different) turns out to be equivalent to
Incitti's one, which is more general but uses some algebraic
notions not necessary in this paper.

\medskip

Let us recall the main enumerative results concerning convex
permutominoes. Using bijective techniques, it is possible to prove
\cite{fanti} that the number of {\em parallelogram permutominoes}
of size $n+1$ is equal to $c_n$ and that the number of {\em
directed-convex permutominoes} of size $n+1$ is equal to $
\frac{1}{2} \, b_n $, where, throughout all the paper, $c_n$ and
$b_n$ will denote, respectively, the Catalan numbers and the
central binomial coefficients. Finally, Disanto et al.
\cite{rinaldi} proved, by the ECO method, that the number of {\em
convex permutominoes} of size $n+1$ is
\begin{equation}\label{co}
 \, 2 \, (n+3) \, 4^{n-2} \, - \, \frac{n}{2} \, {{2n} \choose {n}} \qquad n\geq 1.
\end{equation}
The first terms of the above sequence (\seqnum{A126020} in \cite{sloane}) are
$$ 1,1,4,18,84,394,1836,8468, \ldots\quad .$$
The same formula has been obtained independently by Boldi et al.
\cite{milanesi}. The main results concerning the enumeration of
classes of convex permutominoes \cite{rinaldi,fanti} are listed in
Table~\ref{tttt}, where the first terms of the sequences are given
starting from $n=1$.

\begin{table}\label{tttt}
\begin{tabular}{l|l|l}
  $Class$ & {\em First terms } & {\em Closed form/rec. relation} \\
      & & \\
  \hline
      & &  \\
  convex &$1,1,4,18,84,394, \ldots $  &$C_{n+1} = 2 \, (n+3) \, 4^{n-2} \, - \,
                                                        \frac{n}{2} \, {{2n} \choose {n}}$ \\
      & & \\
  \hline
      & &  \\
 \hspace{-.35cm} \begin{tabular}{l}
  directed \\
  convex
  \end{tabular}
  &$1,1,3,10,35,126, \ldots $ &$D_{n+1} = \frac{1}{2} \, b_{n}$ \\
      & & \\
  \hline
      & &  \\
  parallelogram &$1,1,2,5,14,42,132, \ldots $ &$P_{n+1} =  c_{n}$ \\
  & & \\
  \hline
  & &  \\
 \hspace{-.35cm} \begin{tabular}{l}
  symmetric \\
  (w.r.t. $x=y$)
  \end{tabular}
  &$1,1,2,4,10,22,54, \ldots $
  &\hspace{-.3cm} $\begin{array}{l} Sym_{n+1} =  (n+3)2^{n-2}-n{{n-1}\choose{\lfloor{\frac{n-1}{2}}\rfloor}} \\
  \\
  \phantom{S_{n+1} = \,} -(n-1){{n-2}\choose{\lfloor{\frac{n-2}{2}}\rfloor}}
  \end{array}$\\
  & & \\
  \hline

 & &  \\
  centered &$1,1,4,16,64,256, \ldots $   &$Q_{n} = 4^{n-2}$ \\
 & &  \\
\hline
 & &  \\
  bi-centered &$1,1,4,14,48,164, \ldots $   &$T_n \, = \, 4 T_{n-1} \, - \, 2 T_{n-2},
                                            \quad n\geq 3$ \\
 & &  \\
\hline
 & &  \\
  stacks &$1,1,2,4,8,16,32, \ldots $   &$St_n \, = \, 2^{n-2}$ \\
 & &  \\
\end{tabular}
\end{table}


\bigskip

\bigskip

\noindent {\bf Notation.} Throughout the whole paper we are going
to use the following notations:\begin{itemize}
    \item $\mathcal C_n$ is the set of convex permutominoes of size $n$;
    \item $C_n$ is the cardinality of $\mathcal C_n$;
    \item $C(x)$ is the generating function of the sequence $\{C_n\}_{n\geq 2}$.
\end{itemize}
Moreover, if $\pi$ is a permutation of size $n$, then we define
its \emph{reversal} $\pi^R$ and its \emph{complement} $\pi^C$ as
follows: $\pi^R(i)=\pi(n+1-i)$ and $\pi^C(i)=n+1-\pi(i)$, for each
$i=1,\ldots,n$.




%Before ending this section, just a few words of explanation concerning some notations used in the
%work. If $\mathcal L$ is a generic class of permutominoes, then the set of permutominoes of
%$\mathcal L$ of dimension $n$ will be denoted by ${\mathcal L}_n$, its cardinality by $L_n$, and
%its generating function $L(x)=\sum _{n\geq 0} L_n x^n$. Moreover, the set of permutations
%associated with ${\mathcal L}_n$ will be denoted by $\widetilde{{\mathcal L}}_n=\{ \, \pi_1(P) \,
%: \, P \in {{\mathcal L}}_n \,\}$, its cardinality by $\widetilde{{L}}_n$, and its generating
%function by $\widetilde{L}(x)=\sum _{n\geq 0} \widetilde{{L}}_n x^n$.

\section{Permutations associated with convex permutominoes}

Given a permutomino $P$, the two permutations associated with $P$
are denoted by $\pi _1$ and $\pi _2$ (see Figure \ref{permu1}).
While it is clear that any permutomino of size $n\geq 2$ uniquely
determines two permutations $\pi _1$ and $\pi _2$ of ${\mathcal
S}_{n}$, with
\begin{description}
    \item[1] $\pi_1 (i) \neq \pi_2 (i)$, $1 \leq i \leq n$,
    \item[2] $\pi_1(1)<\pi_2(1)$, and $\pi_1(n)>\pi_2(n)$,
\end{description}
there are pairs of permutations $\left ( \pi _1 , \pi _2 \right )$
of $n$ satisfying 1  and 2 and not defining a permutomino: Figure
\ref{permuz} depicts the two problems which may occur.

\begin{figure}[htb]
\begin{center}
\epsfig{file=cases.eps} \caption{Two permutations $\pi _1$ and
$\pi _2$ of ${\mathcal S}_{n}$, satisfying 1 and 2, do not
necessarily define a permutomino, since two problems may occur:
(a) two disconnected sets of cells; (b) the boundary crosses
itself. \label{permuz}}
\end{center}
\end{figure}
Frosini et al. \cite{fanti} give a simple constructive proof that
every permutation of ${\mathcal S}_n$ is associated with at least
one column convex permutomino.

\begin{proposition}\label{ovo}
If $\pi \in {\mathcal S}_n$ then there is at least one column
convex permutomino $P$ such that $\pi = \pi_1(P)$ or $\pi = \pi_2
(P)$.
\end{proposition}

For instance, Figure \ref{casesb} (a) depicts a column convex
permutomino associated with the permutation $\pi_1$ in Figure
\ref{permuz} (b).

\begin{figure}[htb]
\begin{center}
\epsfig{file=casesbis.eps} \caption{(a) a column convex
permutomino associated with the permutation $\pi_1$ in Figure
\ref{permuz} (b); (b) the symmetric permutomino associated with
the involution $\pi_1=(3,2,1,7,6,5,4)$. \label{casesb}}
\end{center}
\end{figure}


The statement of Proposition~\ref{ovo} does not hold for convex
permutominoes. Therefore, in this paper we consider the class
${\mathcal C}_n$ of convex permutominoes of size $n$, and study
the problem of giving a characterization for the set of
permutations defining convex permutominoes,
$$ \left \{ \, (\pi_1(P),\pi_2(P)) \, : \, P \in {\mathcal C}_n \, \right \}.$$
 Moreover, let us consider the following
subsets of $S_n$:
$$ \widetilde{\mathcal C}_n=\{ \, \pi_1 (P) \, : \, P \in {\mathcal C}_n \,
    \}, \qquad  \widetilde{\mathcal C}'_n=\{ \, \pi_2 (P) \, : \, P \in {\mathcal C}_n \,
    \}. $$
It is easy to prove the following properties:
\begin{enumerate}
    \item $\left | \widetilde{\mathcal C}_n \right | = \left |  \widetilde{\mathcal C}'_n \right
    |$,
    \item $\pi \in \widetilde{\mathcal C}_n$ if and only if $\pi^R \in \widetilde{\mathcal
    C}'_n$.
    \item If $P$ is symmetric according to the diagonal $x=y$, then $\pi _1(P)$ and
    $\pi _2(P)$ are both {\em involutions} of ${\mathcal S}_n$. We recall that an involution
    is a permutation where all the cycles have length at most $2$ (see for instance Figure \ref{casesb} (b)).
    Figures \ref{pippe} and \ref{classi} show permutominoes where only $\pi_1$ is an involution, and this
    condition is not sufficient for the permutomino to be symmetric.
\end{enumerate}

Given a permutation $\pi \in {\mathcal S}_n$, we say that $\pi$ is
{\em $\pi_1$-associated} (briefly {\em associated}) with a
permutomino $P$, if $\pi = \pi _1(P)$. With no loss of generality,
we will study the combinatorial properties of the permutations of
$\widetilde{\mathcal C}_n$, and we will give a simple way to
recognize if a permutation $\pi$ is in $\widetilde{\mathcal C}_n$
or not. Moreover, we will study the cardinality of this set. In
particular, we will exploit the relations between the
cardinalities of ${\mathcal C}_n$ and of $\widetilde{\mathcal
C}_n$.

\medskip
\noindent For small values of $n$ we have that:
\begin{eqnarray*}
  \widetilde{\mathcal C}_1 &=& \{ 1 \}, \\
  \widetilde{\mathcal C}_2 &=& \{ 12 \}, \\
  \widetilde{\mathcal C}_3 &=& \{ 123, 132, 213 \}, \\
  \widetilde{\mathcal C}_4 &=& \{ 1234, 1243, 1324 , 1342, 1423,1432, 2143,   \\
   & &  \, \, \, 2314, 2134, 2413, 3124, 3142, 3214  \}.\\
\end{eqnarray*}
As a main result we will prove that the cardinality of $\widetilde{\mathcal C}_{n+1}$ is
\begin{equation}\label{cnv}
 \, 2 \, (n+2) \, 4^{n-2} \, - \, \frac{n}{4} \, \left ( {\frac{3-4n}{1-2n}}
\right ) \, {{2n} \choose {n}}, \qquad n \geq 1,
\end{equation}
(sequence \seqnum{A122122} in \cite{sloane}) the first terms being
$$1,1,3,13,62,301,1450, \ldots\quad .$$
For any $\pi \in \widetilde{\mathcal C}_n$, let us consider also
$$[\pi]= \{ P\in {\mathcal C}_n : \pi _1 (P)=\pi \},$$
i.e., the set of convex permutominoes associated with $\pi$. For
instance, there are $4$ convex permutominoes associated with $\pi
= (2,1,3,4,5)$, as depicted in Figure~\ref{pippe}. In this paper
we will also give a simple way of computing $[\pi ]$, for any
given $\pi \in \widetilde{\mathcal C}_n$.
\begin{figure}[htb]
\begin{center}
\epsfig{file=pippe.eps,width=4.2in,clip=} \caption{The four convex
permutominoes associated with $(2,1,3,4,5)$. \label{pippe}}
\end{center}
\end{figure}


\subsection{A matrix representation of convex permutominoes}\label{rif}

Before going on with the study of convex permutominoes, we would like to point out a simple property of their
boundary, related to {\em reentrant} and {\em salient points}. Let us briefly recall the definition of these
objects.

Let $P$ be a polyomino; starting from the leftmost point having minimal ordinate, and moving in a clockwise
sense, the boundary of $P$ can be encoded as a word in a four letter alphabet, $\{ N, E, S, W \}$, where $N$
(resp., $E$, $S$, $W$) represents a {\em north} (resp., {\em east}, {\em south}, {\em west}) unit step. Any
occurrence of a sequence $NE$, $ES$, $SW$, or $WN$ in the word encoding $P$ defines a {\em salient point} of $P$,
while any occurrence of a sequence $EN$, $SE$, $WS$, or $NW$ defines a {\em reentrant point} of $P$ (see for
instance, Figure \ref{reentrant}).

It i spossible to prove \cite{daurat,brlek} that, in a more
generale context, the difference between the number of salient and
reentrant points of any polyomino is equal to $4$.

\begin{figure}[htb]
\begin{center}
\epsfig{file=salient.eps} \caption{The coding of the boundary of a
polyomino, starting from $A$ and moving in a clockwise sense; its
salient (resp. reentrant) points are indicated by black (resp.
white) squares. \label{reentrant}}
\end{center}
\end{figure}

In a convex permutomino of size $n+1$ the length of the word
coding the boundary is $4n$, and we have $n+3$ salient points and
$n-1$ reentrant points; moreover, we observe that a reentrant
point cannot lie on the minimal bounding rectangle. This leads to
the following remarkable property:

\begin{proposition}\label{spigoli}
The set of reentrant points of a convex permutomino of size $n+1$
defines a permutation matrix of dimension $n-1$, $n\geq 1$.
\end{proposition}

For simplicity of notation, we agree to group the reentrant points
of a convex permutomino in four classes; in practice we choose to
represent the reentrant point determined by a sequence $EN$ (resp.
$SE$, $WS$, $NW$) with the symbol $\alpha$ (resp. $\beta$,
$\gamma$, $\delta$).
\begin{figure}[htb]
\begin{center}
\epsfig{file=permu2.eps} \caption{The reentrant points of a convex
permutomino uniquely define a permutation matrix in the symbols
$\alpha$, $\beta$, $\gamma$ and $\delta$. \label{permu2}}
\end{center}
\end{figure}

Using this notation we can state the following simple
characterization for convex permutominoes:
\begin{proposition}\label{car_mat}
A convex permutomino of size $n\geq 2$ is uniquely represented by
the permutation matrix defined by its reentrant points, which has
dimension $n-2$, and uses the symbols $\alpha , \, \beta , \,
\gamma , \, \delta $, and such that for all points $A,B,C,D$, of
type $\alpha$, $\beta$, $\gamma$ and $\delta$, respectively, we
have:
\begin{enumerate}
    \item $x_A < x_B$, $x_D < x_C$, $y_A > y_D$, $y_B > y_C$;
    \item $\neg (x_A > x_C \, \wedge \, y_A < y_C )$ and
    $\neg (x_B < x_D \, \wedge \, y_B < y_D )$,
    \item the ordinates of the $\alpha$ and of $\gamma$ points
    are strictly increasing, from left to right;
    the ordinates of the $\beta$ and of $\delta$ points are
    strictly decreasing, from left to right.
\end{enumerate}
where $x$ and $y$ denote the abscissa and the ordinate of the
considered point.
\end{proposition}
\begin{figure}[htb]
\begin{center}
\epsfig{file=d.eps,width=2.5in,clip=} \caption{A sketched
representation of the $\alpha$, $\beta$, $\gamma$ and $\delta$
paths in a convex permutomino. \label{d}}
\end{center}
\end{figure}
Just to give a more informal explanation, on a convex permutomino,
let us consider the special points
$$A=(1,\pi_1(1)), \quad B=(\pi_1^{-1}(n),n), \quad C=(n,\pi_1(n)),
\quad D=(\pi_1^{-1}(1),1).$$ The path that goes from $A$ to $B$
(resp. from $B$ to $C$, from $C$ to $D$, and from $D$ to $A$) in a
clockwise sense is made only of $\alpha$ (resp. $\beta$, $\gamma$,
$\delta$) points, thus it is called the $\alpha$-path (resp.
$\beta$-path, $\gamma$-path, $\delta$-path) of the permutomino.
The situation is schematically sketched in Figure~\ref{d}.

\medskip

\noindent From the characterization given in Proposition
\ref{car_mat} we have the following two properties:

\begin{description}
    \item[(z1)] the $\alpha $ points are never below the diagonal $x=y$, and the $\gamma$ points
    are never above the diagonal $x=y$.
    %(in particular this yields that all the points in the $\alpha$-path
%    are never below the diagonal $x=y$, and that all the points in the $\gamma$-path are never
%    above this diagonal).
    \item[(z2)] the $\beta $ points are never below the diagonal $x+y=n+1$, and the $\delta$ points
    are never above the diagonal $x+y=n+1$.
    %(and then all the points in the $\beta$-path
%    are never below the diagonal $x+y=n+1$, and all the points in the $\delta$-path are never above
%    this diagonal).
\end{description}

\subsection{Characterization and combinatorial properties of $\widetilde{\mathcal C}_n$}

Let us consider the problem of establishing, for a given
permutation $\pi \in {\mathcal S}_n$, if there is at least a
convex permutomino $P$ of size $n$ such that $\pi_1 (P)=\pi$.

\noindent Let $\pi$ be a permutation of ${\mathcal S}_n$, we
define $\mu(\pi)$ (briefly $\mu$) as the maximal upper unimodal
sublist of $\pi$ ($\mu$ retains the indexing of $\pi$).

\medskip

\noindent Specifically, if $\mu$ is denoted by $\left ( \mu (i_1 )
, \ldots , n , \ldots , \mu (i_m) \right ),$ then we have the
following:
\begin{enumerate}
    \item $\mu (i_1)=\mu(1)=\pi(1)$;
    \item if $n\notin \{ \mu (i_1), \ldots , \mu (i_k) \}$, then $\mu (i_{k+1})=\pi (i_{k+1})$ such that
    \begin{description}
        \item[i] $i_k < i < i_{k+1}$ implies $\pi(i)<\mu (i_k)$, and
        \item[ii] $\pi (i_{k+1}) > \mu (i_k)$;
    \end{description}
    \item if $n\in \{ \mu (i_1), \ldots , \mu (i_k) \}$, then $\mu (i_{k+1})=\pi (i_{k+1})$ such that
    \begin{description}
        \item[i] $i_k < i < i_{k+1}$ implies $\pi(i)<\pi (i_{k+1})$, and
        \item[ii] $\pi (i_{k+1}) < \mu (i_k)$.
    \end{description}
\end{enumerate}

\noindent Summarizing we have:
$$ \mu(i_1)=\mu(1)=\pi(1) < \mu (i_2) < \ldots < n > \ldots \mu (i_m)=\mu(n)=\pi(n). $$

\begin{figure}[htb]
\begin{center}
\centerline{\hbox{\includegraphics[width=0.75\textwidth]{conv_ini.eps}}}
\caption{A convex permutomino and the associated
permutations.}\label{conv_new}
\end{center}
\end{figure}

\noindent Moreover, let $\sigma (\pi)$ (briefly $\sigma$) denote
$\left(\sigma (j_1) , \ldots , \sigma (j_r) \right )$ where:
\begin{enumerate}
    \item $\sigma (j_1)=\sigma(1)=\pi(1)$, $\sigma (j_r)=\sigma (n)=\pi (n)$, and
    \item if $1<j_k<j_r$, then $\sigma(j_k)=\pi(j_k)$ if and only if \\
    $\pi(j_k) \notin \{ \mu(i_1), \ldots , \mu (i_m) \}$.
\end{enumerate}

\medskip

We note that the sequence $\mu$ can be defined in terms of
left-right and right left-maxima. A \emph{left-right maximum}
(resp. \emph{right-left maximum}) of a given permutation $\tau$ is
an entry $\tau(j)$ such that $\tau(j)>\tau(i)$ for each $i<j$ (for
each $i>j$). Let $u=(u_{i_1},u_{i_2},\ldots ,u_{i_s})$ be the
sequence of the left-right maxima of $\pi$ with
$u_{i_1}=\pi(1)<u_{i_2}<\ldots<u_{i_s}=n$, and let
$v=(v_{j_1},v_{j_2},\ldots,v_{j_t})$ be the sequence of the
right-left maxima (read from the left) with
$v_{j_1}=n>v_{j_2}>\ldots>v_{j_t}=\pi(n)$. The sequence $\mu$
coincides with the sequence obtained by connecting $u$ with $v$,
observing that, clearly, $u_{i_s}=v_{j_1}=n$. In other words it is
$\mu=(u_{i_1},u_{i_2},\ldots
,u_{i_s}(=v_{j_1}),v_{j_1},v_{j_2},\ldots,v_{j_t})$.


\begin{example}
{\em Consider the convex permutomino of size $16$ represented in
Figure ~\ref{conv_new}. We have
$$ \pi_1 = (8,6,1,9,11,14,2,16,15,13,12,10,7,3,5,4), $$
\noindent and we can determine the decomposition of $\pi$ into the
two subsequences $\mu$ and~$\sigma$:

\bigskip

\begin{center}
\begin{tabular}{c|cccccccccccccccc}
   &$1$ &$2$ &$3$ &$4$ &$5$ &$6$ &$7$ &$8$ &$9$ &$10$ &$11$ &$12$ &$13$ &$14$ &$15$ &$16$ \\
  \hline
  $\mu$ & $8$ & - & - & $9$ & $11$ &$14$ &- &$16$ &$15$ &$13$ &$12$ &$10$ &$7$ &- & $5$ & $4$ \\
  $\sigma$ &$8$ & $6$ & $1$ & - & - & - & 2 & - & - & - & - & - & - &$3$ & - &$4$ \\
\end{tabular}
\end{center}

\bigskip

\noindent For the sake of brevity, when there is no possibility of
misunderstanding, we use to represent the two sequences omitting
the empty spaces, as
$$\mu = (8,9,11,14,16,15,13,12,10,7,5,4), \quad
\sigma=(8,6,1,2,3,4).$$}
\end{example}
While $\mu$ is upper unimodal by definition, here $\sigma$ turns
out to be lower unimodal. In fact, from the characterization given
in Proposition \ref{car_mat} we have that
\begin{proposition}\label{und}
If $\pi$ is associated with a convex permutomino then the sequence
$\sigma$ is lower unimodal.
\end{proposition}

In this case, similarly to the sequence $\mu$, also the sequence
$\sigma$ can be defined in terms of left-right and right-left
minima. A \emph{left-right minimum} (resp. \emph{right-left
minimum}) of a given permutation $\tau$ is an entry $\tau(j)$ such
that $\tau(j)<\tau(i)$ for each $i<j$ (for each $i>j$). If
$\sigma$ is lower unimodal, then it is easily seen to be the
sequence of the left-right minima followed by the sequence of the
right-left minima (read from the left), recalling that the entry
$1$ is both a left-right minimum and a right-left minimum.

\medskip

The conclusion of Proposition \ref{und} is a necessary condition
for a permutation $\pi$ to be associated with a convex
permutomino, but it is not sufficient. For instance, if we
consider the permutation $\pi=(5,9,8,7,6,3,1,2,4)$, then $\mu =
(5,9,8,7,6,4)$, and $\sigma=(5,3,1,2,4)$ is lower unimodal, but as
shown in Figure \ref{conv_news} (a) there is no convex permutomino
associated with $\pi$. In fact, any convex permutomino associated
with such a permutation has a $\beta$ point below the diagonal
$x+y=10$ and, correspondingly, a $\delta$ point above this
diagonal. Thus the $\beta$ and the $\delta$ paths cross
themselves.
\begin{figure}[htb]
\begin{center}
\centerline{\hbox{\includegraphics[width=0.90\textwidth]{non_con.eps}}}
\caption{ (a) there is no convex permutomino associated with $\pi
=(5,9,8,7,6,3,1,2,4)$, since $\sigma$ is lower unimodal but the
$\beta$ path passes below the diagonal $x+y=10$. The $\beta$ point
below the diagonal and the corresponding $\delta$ point above the
diagonal are encircled. (b) The permutation $\pi
=(5,9,8,7,6,3,1,2,4)$ is the direct difference $\pi = (1,5,4,3,2)
\ominus (3,2,1,4)$.}\label{conv_news}
\end{center}
\end{figure}

\medskip

In order to give a necessary and sufficient condition for a
permutation $\pi$ to be in $\widetilde{\mathcal C}_n$, let us
recall that, given two permutations $\theta=(\theta_1, \ldots
,\theta_m) \in {\mathcal S}_m$ and $\theta'=(\theta'_1, \ldots
,\theta'_{m'})\in {\mathcal S}_{m'}$, their {\em direct
difference} $\theta \ominus \theta '$ is a permutation of
${\mathcal S}_{m+m'}$ defined as
$$ (\theta_1+m', \ldots ,\theta_m+m',\theta'_1, \ldots ,\theta'_{m'} ). $$
A pictorial description is given in Figure~\ref{conv_news}~(b),
where $\theta = (1,5,4,3,2)$, $\theta'= (3,2,1,4)$, and their
direct difference is $\theta \ominus \theta' =(5,9,8,7,6,3,1,2,4)$
.

\medskip

Finally the following characterization holds.
\begin{theorem}\label{caratt_conv}
Let $\pi \in {\mathcal S}_n$ be a permutation. Then $\pi \in
\widetilde{\mathcal C}_n$ if and only if:

\begin{enumerate}
    \item $\sigma$ is lower unimodal, and
    \item there are no two permutations, $\theta \in\theta_m $,
    and $\theta' \in \theta_m'$, such that
    $m+m'=n$, and $\pi = \theta \ominus \theta'$.
\end{enumerate}
\end{theorem}

\begin{proof}
Before starting, we need to observe that
in a convex permutomino all the $\alpha$ and $\gamma$ points
belong to the permutation $\pi_1$, thus by  {\bf (z1)} they can
also lie on the diagonal $x=y$; on the contrary, the $\beta$ and
$\delta$ points belong to $\pi_2$, then by  {\bf (z2)} all the
$\beta$ (resp. $\delta$) points must remain strictly above (resp.
below) the diagonal $x+y=n+1$.

\medskip

\noindent $(\Longrightarrow)$ By Proposition \ref{und} we have
that $\sigma$ is lower unimodal. Then, we have to prove that $\pi$
may not be decomposed into the direct difference of two
permutations, $\pi = \theta \ominus \theta'$.

If $\pi(1)<\pi(n)$ the property is straightforward. Let us
consider the case $\pi(1)>\pi(n)$, and assume that $\pi = \theta
\ominus \theta'$ for some permutations $\theta$ and $\theta'$. We
will prove that if the vertices of polygon $P$ define the
permutation $\pi$, then the boundary of $P$ crosses itself, hence
$P$ is not a permutomino.

\smallskip

Let us assume that $P$ is a convex permutomino associated with
$\pi = \theta \ominus \theta'$. We start by observing that the
$\beta$ and the $\delta$ paths of $P$ may not be empty. In fact,
if the $\beta$ path is empty, then $\pi (n)=n>\pi(1)$, against the
hypothesis. Similarly, if the $\delta$ path is empty, then $\pi
(1)=1<\pi(n)$. Essentially for the same reason, both $\theta$ and
$\theta'$ must have more than one element.


\begin{figure}[htb]
\begin{center}
\centerline{\hbox{\includegraphics[width=0.50\textwidth]{th1.eps}}}
\caption{ If $\pi = \theta \ominus \theta'$ then the boundary of
every polygon associated with $\pi$ crosses itself.}\label{th1}
\end{center}
\end{figure}


As we observed, the points of $\theta$ (resp. $\theta'$) in the
$\beta$ path of $P$, are placed strictly above the diagonal
$x+y=n+1$. Let $F$ (resp. $F'$) be the rightmost (resp. leftmost)
of these points. Similarly, there must be at least one point of
$\theta$ (resp. $\theta'$) in the $\delta$ path of $P$, placed
strictly below the diagonal $x+y=n+1$. Let $G$ (resp. $G'$) be the
rightmost (resp. leftmost) of these points. The situation is
schematically sketched in Figure \ref{th1}.

Since $F$ and $F'$ are consecutive points in the $\beta$ path of
$P$, they must be connected by means of a path that goes down and
then right, and, similarly, since $G'$ and $G$ are two consecutive
points in the $\delta$ path, they must be connected by means of a
path that goes up and then left. These two paths necessarily cross
in at least two points, and their intersections must be on the
diagonal $x+y=n+1$.

\medskip

\noindent \noindent $(\Longleftarrow)$ Clearly condition 2.
implies that $\pi (1) < n$ and $\pi (n)>1$, which are necessary
conditions for $\pi \in \widetilde{\mathcal C}_n$. We start
building up a polygon $P$ such that $\pi_1(P)=P$, and then prove
that $P$ is a permutomino. As usual, let us consider the points
$$A=(1,\pi(1)), \quad B=(\pi^{-1}(n),n), \quad C=(n,\pi(n)),
\quad D=(\pi^{-1}(1),1).$$ The $\alpha$ path of $P$ goes from $A$
to $B$, and it is constructed connecting the points of $\mu$
increasing sequence; more formally, if $\mu (i_l)$ and $\mu
(i_{l+1})$ are two consecutive points of $\mu$, with $\mu
(i_l)<\mu (i_{l+1})\leq n$, we connect them by means of a path $$
1^{\mu (i_{l+1}) - \mu (i_l)} \, 0^{i_{l+1} -i_l} ,$$ (where $1$
denotes the vertical, and $0$ the horizontal unit step). Similarly
we construct the $\beta$ path, from $B$ to $C$, the $\gamma$ path
from $C$ to $D$, and the $\delta$ path from $D$ to $A$. Since the
subsequence $\sigma$ is lower unimodal the obtained polygon is
convex (see Figure \ref{th2}).


\begin{figure}[htb]
\begin{center}
\centerline{\hbox{\includegraphics[width=0.8\textwidth]{th2.eps}}}
\caption{Given the permutation $\pi = (3,1,6,8,2,4,7,5)$
satisfying conditions 1. and 2., we construct the $\alpha$,
$\beta$, $\gamma$, and $\delta$ paths.}\label{th2}
\end{center}
\end{figure}

\begin{figure}[htb]
\begin{center}
\centerline{\hbox{\includegraphics[width=.8\textwidth]{th3.eps}}}
\caption{(a) The $\alpha$ path and the $\gamma$ path may not
cross; (b) The $\beta$ path and the $\delta$ path may not
cross.}\label{th3}
\end{center}
\end{figure}

Now we must prove that the four paths we have defined may not
cross themselves. First we show that the $\alpha$ path and the
$\gamma$ path may not cross. In fact, if this happened, there
would be a point $(r,\pi(r))$ in the path $\gamma$, and two points
$(i,\pi(i))$ and $(j,\pi(j))$ in the path $\alpha$, such that
$i<r<j$, and $\pi(i)<\pi(r)>\pi(j)$ (see Figure \ref{th3} (a)). In
this case, according to the definition, $\pi(r)$ should belong to
$\mu$, and then $(r,\pi(r))$ should be in the path $\alpha$, and
not in $\gamma$.


Finally we prove that the paths $\beta$ and $\delta$ may not
cross. In fact, if they cross, their intersection should
necessarily be on the diagonal $x+y=n+1$; if $(r,s)$ is the
intersection point having minimum abscissa, then the reader can
easily check, by considering the various possibilities, that the
points $(i,\pi(i))$ of $\pi$ satisfy:
$$i\leq r \; \; \mbox{ if and only if } \; \; \pi(i)\geq s $$
(see Figure \ref{th3} (b)). Therefore, setting
$$\theta =\left \{ (i,\pi(i)-s+1) : i\leq r \right \} $$
we have that $\theta$ is a permutation of ${\mathcal S}_r$, and letting
$$ \theta ' = \{ \, (i,\pi(i) \, : \, i>r \, \}$$
we see that $\pi  = \theta \ominus \theta '$, against the hypothesis. 
\end{proof}

\smallskip

There is an interesting refinement of the previous general
theorem, which applies to a particular subset of the permutations
of ${\mathcal S}_n$.

\begin{corollary}\label{caratt_conv1}
{\em Let $\pi \in {\mathcal S}_n$, such that $\pi(1)<\pi(n)$. Then
$\pi \in \widetilde{\mathcal C}_n$ if and only if $\sigma$ is
lower unimodal.}
\end{corollary}

\medskip


\begin{figure}[htb]
\begin{center}
\centerline{\hbox{\includegraphics[width=.9\textwidth]{cnv.eps}}}
\caption{(a) a square permutation and the associated $4$-face
polygon; (b) a $4$ face polygon defined by a non square
permutation.}\label{square}
\end{center}
\end{figure}
At the end of this section we would like to point out an
interesting connection between the permutations associated with
convex permutominoes and another kind of combinatorial objects
treated in some recent works. We are referring to the so called
{\em  $k$-faces permutation polygons} defined by T. Mansour and S.
Severini \cite{toufik}. In order to construct a polygon from a
given permutation $\pi$ in an unambiguous way, they find the set
of left-right minima and the set of right-left minima. An entry
which is neither a left-right minimum nor a right-left minimum is
said to be a \emph{source}, together with the first and the last
entry (which are also a left-right minimum and a right-left
minimum, respectively). Finally, two entries of $\pi$ are
connected with an edge if they are two consecutive left-right
minima or right-left minima or sources. A maximal path of
increasing or decreasing edges defines a \emph{face}. If the
obtained polygon has $k$ faces, than it is said to be a
$k$-$faces$ polygon. A permutation is said to be $square$ if the
sequence of the sources lies in at most two faces. The set of the
square permutations of length $n$ is denoted by ${\mathcal Q}_n$.
We note that a square permutation has at most four faces, but the
inverse statement does not hold: the permutation
$(1,5,8,2,7,3,9,10,6,4)$ has four faces and it is not square.
Figure \ref{square} depicts an example.

Connecting all pairs of consecutive points of the sequences $\mu$
and $\sigma$ we obtain a polygon which may not coincide with the
polygon obtained from the definition of Mansour and Severini, as
the reader can easily check with the permutation $(1,2,4,3)$. It
is however simple to state the following

\begin{proposition}\label{stopponi}
Given a permutation $\pi \in {\mathcal S}_n$, then $\pi \in
{\mathcal Q}_n$ if and only if $\sigma(\pi)$ is lower unimodal.
\end{proposition}

We point out that the square permutations coincide with the of the
\emph{convex permutations}, introduced by Waton \cite{waton}. In
his PhD thesis the author characterizes the convex permutations in
terms of forbidden patterns. More precisely, he proves that the
convex permutations are all the permutations avoiding the
following sixteen patterns of length five:
$$
\{52341, 52314, 51342, 51324, 42351, 42315, 41352, 41325$$ $$
25341, 25314, 15342, 15324, 24351, 24315, 14352, 14325\}.
$$

\bigskip\noindent
All the relations between ${\mathcal Q}_n$, ${\mathcal C}_n$ and
${\mathcal C}'_n$ are exploited in the next section, where, in
particular, we prove that, given a permutation $\pi$, then $\pi\in
{\mathcal Q}_n$ if and only if $\pi\in {\mathcal C}_n\cup{\mathcal
C'}_n$.

Mansour and Severini \cite{toufik} (and independently Waton
\cite{waton}) prove that the number $Q_{n+1}$ of square
permutation of size $n+1$ is
\begin{equation}
Q_{n+1}=2(n+3)4^{n-2}-4(2n-3){{2(n-2)}\choose {n-2}}, \label{squar}
\end{equation}
defining the sequence (\seqnum{A128652} in \cite{sloane})
$$1,2,6,24,104,464,2088, \ldots\quad.$$

\subsection{The relation between the number of permutations and the number convex permutominoes}

Let $\pi \in \widetilde{\mathcal C}_n$, and $\mu$ and $\sigma$
defined as above. Let ${\mathcal F}(\pi)$ (briefly ${\mathcal F}$)
denote the set of fixed points of $\pi$ lying in the increasing
part of the sequence $\mu$ and which are different from $1$ and
$n$. We call the points in $\mathcal F$ the {\em free fixed
points} of $\pi$.

For instance, concerning the permutation $\pi = (2,1,3,4,7,6,5)$
we have $\mu = ( 2,3,4,7,6,5)$, $\sigma = (2,1,5)$, and ${\mathcal
F}(\pi)=\{ 3,4 \}$; here $6$ is a fixed point of $\pi$ but it is
not on the increasing sequence of $\mu$, then it is not free. By
definition, a permutation in $\widetilde{\mathcal C}_n$ can have
no free fixed points (e.g., the permutation associated with the
permutomino in Figure~\ref{conv_new}), and at most $n-2$ free
fixed points (as the identity $(1, \ldots , n)$).

\begin{theorem}\label{car_2}
Let $\pi\in \widetilde{\mathcal C}_n$, and let ${\mathcal F}(\pi)$
be the set of free fixed points of $\pi$. Then we have:
$$ \left | \; \left [ \; \pi \; \right ] \; \right | \; = \; 2^{\left | {\mathcal F}(\pi) \right |}.$$
\end{theorem}

\begin{proof}
Since $\pi\in \widetilde{\mathcal C}_n$ there exists a permutomino $P$ associated with
$\pi$. If we look at the permutation matrix defined by the reentrant points of $P$, we see that all the free
fixed points of $\pi$ can be only of type $\alpha$ or $\gamma$, while the type of all the other reentrant points
of $\pi$ is established. It is easy to check that in any way we set the typology of the free fixed points in
$\alpha$ or $\gamma$ we obtain, starting from the matrix of $P$, a permutation matrix which defines a convex
permutomino associated with $\pi$, and in this way we get all the convex permutominoes associated with ~$\pi$.
\end{proof}

%Let $P\in {\mathcal C}_n$, and let us consider the usual points $A$,
%$B$, $C$, and $D$ on the boundary of $P$. We observe that each
%fixed point of ${\mathcal F}(\pi_1)$ can belong to the ``upper path''
%from $B$ to $C$ or to the ``lower path'' from $A$ to $D$; instead,
%due to the convexity constrain, the paths from $A$ to $B$, and
%from $C$ to $D$ are uniquely determined, and are equal for all the
%permutominoes of $\left [ \; P \; \right ]_\sim $. Hence there are
%$2^{\left | {\mathcal F}(P) \right |}$ possible convex permutominoes
%which can be obtained from~$\pi_1$. \qed


\medskip

\noindent Applying Theorem \ref{car_2} we have that the number of
convex permutominoes associated with $\pi = (2,1,3,4,7,6,5)$  is
$2^2=4$, as shown in Figure \ref{classi}. Moreover, Theorem
\ref{car_2} leads to an interesting property.

\begin{figure}[htb]
\begin{center}
\centerline{\hbox{\includegraphics[width=1\textwidth]{classi.eps}}}
\caption{The four convex permutominoes associated with the
permutation $\pi = (2,1,3,4,7,6,5)$. The two free fixed points are
encircled.}\label{classi}
\end{center}
\end{figure}

\begin{proposition}\label{caratt_conv2}
Let $\pi \in \widetilde{\mathcal C}_n$, with $\pi(1)>\pi(n)$. Then
there is only one convex permutomino associated with $\pi$, i.e.,
$\left | \, \left [ \, \pi \, \right ] \, \right | \, = \, 1$.
\end{proposition}

\smallskip

\begin{proof}
If $\pi(1)>\pi(n)$ then all the points in
the increasing part of $\mu$ are strictly above the diagonal
$x=y$, then $\pi$ cannot have free fixed points. The thesis is
then straightforward. 
\end{proof}

\medskip

Let us now introduce the sets $\widetilde{\mathcal C}_{n,k}$ of
permutations having exactly $k$ free fixed points, with $0\leq k
\leq n-2$. We easily derive the following relations:
\begin{equation}\label{xx}
\widetilde{C}_{n} = \sum _{k=0}^{n-2} \; \left |
\widetilde{\mathcal C}_{n,k} \right | \qquad \qquad \qquad {C}_{n}
= \sum _{k=0}^{n-2} \; 2^k \; \left | \widetilde{\mathcal C}_{n,k}
\right |.
\end{equation}

\section{The cardinality of $\widetilde{\mathcal C}_{n}$}

In order to find a formula to express $\widetilde{C}_n$, it is now
sufficient to count how many permutations of ${\mathcal Q}_n$ can
be decomposed into the direct difference of other permutations. We
say that a square permutation is {\em indecomposable} if it is not
the direct difference of two permutations. For any $k\geq 2$, let
$${\mathcal B}_{n,k}=\left \{ \, \pi \in {\mathcal Q}_n: \pi =
\theta_1 \ominus \ldots \ominus \theta_k , \, \theta_i \mbox{
indecomposable}, \, 1\leq i \leq k \, \right \}$$ be the set of
square permutations which are direct difference of exactly $k$
indecomposable permutations, and $$ {\mathcal B}_n = \bigcup
_{k\geq 2} {\mathcal B}_{n,k}.$$ For any $n,k\geq 2$, let
${\mathcal T}_{n,k}$ be the class of the sequences
$(P_1,\dots,P_k)$ such that:
\begin{description}
    \item[i] $P_1$ and $P_k$ are (possibly empty) directed convex permutominoes,
    \item[ii] $P_2, \dots, P_{k-1}$ are (possibly empty) parallelogram
    permutominoes,
\end{description}
 and such that the sum of the dimensions of $P_1,\dots,P_k$ is equal to
 $n$.

\begin{proposition}\label{filippo}
There is a bijective correspondence between the elements of
${\mathcal B}_{n,k}$ and the elements of ${\mathcal T}_{n,k}$, so
that the two classes have the same cardinality.
\end{proposition}

\begin{proof}
Let us consider $(P_1,\dots,P_k)\in
{\mathcal T}_{n,k}$, we construct the corresponding permutation
$\pi=\delta_1 \ominus \dots \ominus \delta_k$ as follows. For any
$1\leq i \leq k$, if $P_i$ is the empty permutomino, then
$\delta_i=(1)$, otherwise:

\begin{description}
    \item[i] for all $i$ with $1\leq i\leq k-1$, $\delta_i$ is the reversal
     of $\pi_2(P_i)$ (i.e., the permutation $\pi_1$ associated with the symmetric
    permutomino of $P_i$ with respect to the $y$- axis).
    \item[ii] $\delta_k$ is the complement of $\pi_2(P_k)$ (i.e., it is the
    permutation $\pi_1$ associated with the symmetric permutomino of $P_k$ with
    respect to the $x$-axis).
%    $\delta_k$ is defined by $\delta_k(j) = dim(P_k)-\pi_2(P_k)(j)$ (i.e., it is the
%    permutation $\pi_1$ associated with the permutomino symmetric of $P_k$ with
%    respect to the $x$-axis).
\end{description}


\begin{figure}[htb]
\begin{center}
\centerline{\hbox{\includegraphics[width=1.1\textwidth]{4faces00.eps}}}
\caption{An element of
 ${\mathcal T}_{19,5}$, constituted of a sequence of five permutominoes,
 and the associated permutations.}\label{squaredd}
\end{center}
\end{figure}


For example, starting from the sequence of permutominoes in Figure
\ref{squaredd} we obtain the following permutations:
$\delta_1=(2,1,4,5,3)$ is obtained from the permutomino $P_1$ such
that $\pi_2(P_1)=(3,5,4,1,2)$; $\delta_2=(1)$ is obtained from the
empty permutomino $P_2$; $\delta_3=(1,2)$ is obtained from $P_3$;
$\delta_4=(3,1,5,4,2)$ is obtained from the permutomino $P4$ such
that $\pi_2(P_4)=(2,4,5,1,3)$. Moreover, $\delta_5=(3,1,6,5,2,4)$
is the complement of $\tau=(4,6,1,2,5,3)$ which is such that
$\pi_2(P_5)=\tau$. Then, as showed in Figure \ref{squared}, we
obtain the permutation
$\pi=\delta_1\ominus\delta_2\ominus\delta_4\ominus\delta_4\ominus\delta_5$,
$$\pi=(16,15,18,19,17,14,12,13,9,7,11,10,8,3,1,6,5,2,4)$$
We note that the points in the increasing part of $\mu(\pi)$ are
precisely the points of the increasing part of $\mu(\delta_1)$;
the points in the increasing part of $\sigma(\pi)$ are the points
of the increasing part of $\sigma(\delta_k)$; the points in the
decreasing part of $\mu(\pi)$ are given by the sequence of points
of the decreasing parts of $\mu(\delta_1),\dots,\mu(\delta_k)$;
finally, the points in the decreasing part of $\sigma(\pi)$ are
given by the sequence of the points of the decreasing parts of
$\sigma(\delta_1),\dots,\sigma(\delta_k)$. Then, we have that
$\pi\in\mathcal Q_n$ and then $\pi\in {\mathcal B}_{n,k}$.

\medskip

Conversely, let $\pi\in {\mathcal B}_{n,k}$, with $\pi=\delta_1
\ominus \dots \ominus \delta_k$. By the previous considerations we
have that $\pi\in {\mathcal Q}_n$, and then it is clear that, for
each component $\delta _i$, the sequence $\mu(\delta_i)$ is upper
unimodal, and $\sigma(\delta_i)$ is lower unimodal.

If $\delta _i$ is the one element permutation, then it is
associated with the empty permutomino. Otherwise, if a permutation
$\delta_i$ is indecomposable and has dimension greater than $1$ it
is clearly associated with a polygon with exactly one side for
every abscissa and ordinate and with the border which does not
intersect itself. These two conditions are sufficient to state
that $\delta_i$ is associated with a convex permutomino, and in
particular the reader can easily observe the following properties,
due to its the indecomposability:

\begin{enumerate}
    \item there is exactly one directed convex permutomino $P_1$
corresponding to $\delta_1$, and it is the reflection according to
the $y$-axis of a permutomino associated with $\delta _1$;
    \item for any $2\leq i\leq k-1$, there is exactly one parallelogram
permutomino $P_i$ corresponding to $\delta_i$, and it is the
reflection according to the $y$-axis of a permutomino associated
with $\delta _i$;
    \item there is exactly one directed convex permutomino $P_k$
corresponding to $\delta_k$, and it is the reflection according to
the $x$-axis of a permutomino associated with $\delta _k$.
\end{enumerate}
We have thus the sequence $(P_1,\dots,P_k)\in {\mathcal T}_{n,k}$. 
\end{proof}


\begin{figure}[htb]
\begin{center}
\centerline{\hbox{\includegraphics[width=1.1\textwidth]{4faces1.eps}}}
\caption{(a) a square permutation which can be decomposed into the
direct difference of five indecomposable permutations; (b) the
five permutominoes associated with them. For each permutomino
$P_i$, we denote by $\bar{P}_i$ the corresponding reflected
permutomino.} \label{squared}
\end{center}
\end{figure}

\bigskip

If we denote by $B_n$ (resp. $B_{n,k}$) the cardinality of
${\mathcal B}_n$ (resp. ${\mathcal B}_{n,k}$), by Proposition
\ref{stopponi} we have
$$ \widetilde{C}_n = Q_n - B_n.$$


\noindent Let us pass to generating functions, denoting by:

\begin{enumerate}
    \item $P(x)$ (resp. $D(x)$) the generating function of
    parallelogram permutominoes (resp. $P(x)$), hence
    \begin{eqnarray*}
     P(x) = \frac{1-\sqrt{1-4x}}{2} &=& x+x^2+2x^3+5x^4+14x^5+
    \ldots  \\
     D(x) = \frac{x}{2} \left( \frac{1}{\sqrt{1-4x}} +1 \right ) &=& x+x^2+3x^3+10x^4+35x^5+
    \ldots ;
    \end{eqnarray*}
    \item $B_k(x)$ (resp. $B(x)$) the generating function of the
    numbers $\{ B_{k,n} \}_{n\geq 0}$, $k\geq 2$ (resp. $\{ B_{n} \}_{n\geq
    0}$).
\end{enumerate}

\noindent Due to Proposition  \ref{filippo}, for any $k\geq 2$, we
have that $B_k(x)=D^2(x)P^{k-2}(x)$ and then
$$ B(x)=\sum_{k\geq 0} D^2(x) P^{k-2}(x)
=\frac{D^2(x)}{1-P(x)}=\frac{1}{2}\left ( \frac{x^2}{1-4x} +
\frac{x^2}{\sqrt{1-4x}} \right ).$$ Therefore
$$B_{n+2}=\frac{1}{2}\left ( 4^{n} +
{{2n}\choose n} \right )=\sum_{i=0}^n {{2n}\choose i}. $$ Now it
is easy to determine the cardinality of $\widetilde{\mathcal
C}_{n}$. For simplicity of notation we will express most of the
following formulas in terms of $n+1$ instead of~$n$.
\begin{proposition}\label{wwww}
{\em The number of permutations of $\widetilde{\mathcal C}_{n+1}$ is
\begin{equation}\label{solution}
 \, 2 \, (n+2) \, 4^{n-2} \, - \, \frac{n}{4} \, \left ( {\frac{3-4n}{1-2n}}
\right ) \, {{2n} \choose {n}}, \qquad n \geq 1.
\end{equation}}
\end{proposition}

\begin{proof}
In fact, for any $n\geq 2$, we have
$\widetilde{C}_{n}=Q_{n}-B_{n}$, then the result is
straightforward. 
\end{proof}

\bigskip\noindent
For the sake of completeness, in Table \ref{tab} we list the first
terms of the sequences involved in the preceding formulas.

\begin{table}[htb]
\begin{center}
\begin{tabular}{l|ccccccccc}
  sequence &$1$ &$2$ &$3$ &$4$ &$5$ &$6$ &$7$ &$8$ &$\ldots$ \\
  \hline
    \\
  $Q_n$ &$1$ &$2$ &$6$ &$24$ &$104$ &$464$ &$2088$ &$9392$ &$\ldots$ \\
    \\
  $B_n$ & &$1$ &$3$ &$11$ &$42$ &$163$ &$638$ &$2510$ &$\ldots$ \\
    \\
  $\widetilde{C}_n $ &$1$ &$1$ &$3$ &$13$ &$62$ &$301$ &$1450$ &$6882$
&$\ldots$ \\
\end{tabular}
\caption{The first terms of the sequences $Q_n$, $B_n$,
$\widetilde{C}_n $, starting with $n=1$.}\label{tab}
\end{center}
\end{table}


\medskip

In ending the paper we would like to point out some other results that directly come out from the one stated in
Proposition \ref{wwww}. First we observe that:
\begin{description}
    \item[i]  the number of permutations $\pi \in \widetilde{\mathcal C}_{n}$
for which $\pi (1) < \pi(n)$ is equal to $\frac{1}{2} Q_n$,
    \item[ii] the number of of permutations for which $\pi (1)
> \pi(n)$ is equal to
$$ \frac{1}{2}Q_n - B_n = \widetilde{C}_{n} - \frac{1}{2}Q_n ,$$
and the $(n+1)$th term of this difference is equal to
\begin{equation}\label{exp}
(n+1)4^{n-2}-\frac{n}{2}{{2n+1}\choose {n-1}},
\end{equation}
whose first terms are $1,10,69,406, 2186, 11124,\ldots$, (sequence \seqnum{A038806} in \cite{sloane}).
\end{description}

\medskip

\noindent Moreover,
%recalling that $$\widetilde{\mathcal C}'_{n}= \left \{ \, \pi_2(P): P \mbox{ is
%a convex permutomino }\right \},$$
it is also possible to consider the set $\widetilde{\mathcal
C}_{n} \cap \widetilde{\mathcal C}'_{n}$, i.e., the set of the
permutations $\pi$ for which there is at least one convex
permutomino $P$ such that $\pi_1(P)=\pi$ and one convex
permutomino $P'$ such that $\pi_2(P')=\pi$. For instance, we have:
$$
\begin{array}{ll}
\widetilde{\mathcal C}_{3} \cap \widetilde{\mathcal C}'_{3}=\emptyset, \\
\\
\widetilde{\mathcal C}_{4} \cap \widetilde{\mathcal C}'_{4}=\{ (2,4,1,3), (3,1,4,2) \}.
\end{array}
$$
We start by recalling that $\pi \in \widetilde{\mathcal C}_{n}$ if
and only if $\pi^R \in \widetilde{\mathcal C}'_{n}$
%, where, as usual, $\pi^M=(\pi(n),\ldots ,\pi(1)$ denotes the {\em
%mirror image} of $\pi = (\pi(1), \ldots ,\pi(n))$
.

\begin{proposition}\label{opo}
{\em A permutation $\pi \in {\mathcal Q}_n$ if and only if $\pi
\in \widetilde{\mathcal C}_{n} \cup \widetilde{\mathcal C}'_{n}$.}
\end{proposition}

\begin{proof}
($\Leftarrow$) If $\pi$ is a square permutation but it is not in $\widetilde{\mathcal
C}_{n}$, then necessarily $\pi (1) > \pi (n)$. Hence, if we consider $\pi^R$, we have $\pi^R(1)<\pi^R(n)$, and
$\pi^R\in \widetilde{\mathcal C}_{n}$, then $\pi\in \widetilde{\mathcal C}'_{n}$.

\smallskip

\noindent ($\Rightarrow$) Trivial. 
\end{proof}

\medskip

Finally, since $\left | \widetilde{\mathcal C}'_n \right |= \left
| \widetilde{\mathcal C}_n \right |$, and $ Q_{n} =
2\widetilde{C}_n - \left | \, \widetilde{{\mathcal C}}_n \cap
\widetilde{{{\mathcal C}'}}_n \right |$, we can state the
following.


\begin{proposition}\label{opoz}
{\em For any $n \geq 2$, we have
\begin{equation}\label{ds} \left |
\, \, \widetilde{{\mathcal C}}_{n} \cap \widetilde{{{\mathcal
C}'}}_{n} \right | = \widetilde{{C}}_{n} - B_{n}=Q_n-2B_n.
\end{equation}}
\end{proposition}

The reader can easily recognize that the numbers defined by
(\ref{ds}) are the double of the ones expressed by the formula in
(\ref{exp}), so that

\begin{equation}\label{gek}
\left | \, \widetilde{{\mathcal C}}_{n+1} \cap
\widetilde{{{\mathcal C}'}}_{n+1} \right | =
2(n+1)4^{n-2}-{{2n-1}\choose {n-1}}.
\end{equation}


\section{Further work}
Here we outline the main open problems and research lines on the
class of permutominoes.
\begin{enumerate}
    \item It would be natural to look for a combinatorial proof of
    the formula (\ref{co}) for the number of convex permutominoes
    and (\ref{solution}) for the number of permutations associated
    with convex permutominoes. These proofs could be
    obtained using the matrix characterization for convex
    permutominoes provided in Section \ref{rif}.

    \item The main results of the paper have been obtained in an analytical
    way. In particular from (\ref{co}) and (\ref{solution}) we
    have a direct relation between convex permutominoes and
    permutations, obtaining
    \begin{equation}\label{inter}
    C_{n+2} = \widetilde{C}_{n+2} + \frac{1}{2} \left ( 4^n - {{2n} \choose n} \right
    ),
    \end{equation}
    which requires a combinatorial explanation. In particular,
    recalling that
    $$ C_n = \sum _{\pi \in \widetilde{\mathcal C}_{n}} \left | [  \pi ]\right
    |, $$
    the right term of (\ref{inter}) is the number of convex
    permutominoes which are determined by the permutations having
    at least one free fixed point.

    \medskip

    Moreover, from (\ref{wwww}) and (\ref{inter}) we get that
    $$ Q_{n+2} = C_{n+2} + {{2n} \choose n}, $$
    and also this identity cannot be clearly explained using the
    combinatorial arguments used in the paper.

    \medskip

    From (\ref{gek}) we have that the generating function of the
    permutations in $\widetilde{{\mathcal C}}_{n} \cap \widetilde{{{\mathcal
    C}'}}_{n}$ is
    $$ 2\left ( \frac{x^2 c(x)}{1-4x} \right ) ^2, $$
    where $c(x)$ denotes the generating function of Catalan
    numbers. While the factor $2$ can be easily explained,
    since for any $\pi \in \widetilde{{\mathcal C}}_{n} \cap \widetilde{{{\mathcal
    C}'}}_{n}$, also $\pi^R \in \widetilde{{\mathcal C}}_{n} \cap \widetilde{{{\mathcal
    C}'}}_{n}$, and clearly $\pi \neq \pi '$, the convolution of
    Catalan numbers and the powers of four begs for a
    combinatorial interpretation.

    \item
    We would like to consider the characterization and
     the enumeration of the permutations associated with other
    classes of permutominoes, possibly including the class of
    convex permutominoes. For instance, if we take the
    class of column convex permutominoes, we observe
    that Proposition \ref{spigoli} does not hold.
    In particular, one can see that, if the permutomino is not convex,
    then the set of reentrant points does not form
    a permutation matrix (see Figure~\ref{ccc}).

    \begin{figure}[htb]
    \begin{center}
    \centerline{\hbox{\includegraphics[width=1\textwidth]{ccc.eps}}}
    \caption{The four column convex permutominoes associated
    with the permutation $(1,6,2,5,3,4)$; only the
    leftmost is convex}\label{ccc}
    \end{center}
    \end{figure}

    Moreover, it might be interesting to determine
    an extension of Theorem~\ref{car_2} for the class of
    column convex permutominoes, i.e., to
    characterize the set of column convex permutominoes
    associated with a given permutation.
    For instance, we observe that while there is one convex
    permutomino associated with $\pi=(1,6,2,5,3,4)$,
    there are four column convex permutominoes
    associated with $\pi$ (see Figure \ref{ccc}).

\end{enumerate}
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\end{thebibliography}

\bigskip
\hrule
\bigskip

\noindent 2000 {\it Mathematics Subject Classification}: Primary
05A15; Secondary 05A05.

\noindent \emph{Keywords: } permutominoes, polyominoes.

\bigskip
\hrule
\bigskip

\noindent (Concerned with sequences 
\seqnum{A000108},
\seqnum{A000984},
\seqnum{A005436},
\seqnum{A038806},
\seqnum{A122122},
\seqnum{A126020}, and
\seqnum{A128652}.)

\bigskip
\hrule
\bigskip


\vspace*{+.1in}
\noindent
Received July 28 2007;
revised version received November 20 2007.
Published in {\it Journal of Integer Sequences}, November 20 2007.

\bigskip
\hrule
\bigskip

\noindent
Return to
\htmladdnormallink{Journal of Integer Sequences home page}{http://www.cs.uwaterloo.ca/journals/JIS/}.
\vskip .1in


\end{document}

                                                                                


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