This paper contains examples of various features from AMS-.

Let $𝐀=\left(a_{ij}\right)$ be the adjacency matrix of graph $G$. The corresponding Kirchhoff matrix $𝐊=\left(k_{ij}\right)$ is obtained from $𝐀$ by replacing in $-𝐀$ each diagonal entry by the degree of its corresponding vertex; i.e., the $i$th diagonal entry is identified with the degree of the $i$th vertex. It is well known that

where $𝐊\left(i\right|i)$ is the $i$th principal submatrix of $𝐊$.

1 \det\mathbf{K}(i|i)=\text{ the number of spanning trees of $G$},

Let $C_{i\left(j\right)}$ be the set of graphs obtained from $G$ by attaching edge $\left(v_i{v}_j\right)$ to each spanning tree of $G$. Denote by $C_i={\bigcup }_j{C}_{i\left(j\right)}$. It is obvious that the collection of Hamiltonian cycles is a subset of $C_i$. Note that the cardinality of $C_i$ is $k_{ii}det𝐊\left(i\right|i)$. Let $\widehat{X}=\{{\widehat{x}}_1,\cdots ,{\widehat{x}}_n\}$.

2 $\wh X=\{\hat x_1,\dots,\hat x_n\}$

Define multiplication for the elements of $\widehat{X}$ by

Let ${\widehat{k}}_{ij}=k_{ij}{\widehat{x}}_j$ and ${\widehat{k}}_{ij}=-{\sum }_{j\ne i}{\widehat{k}}_{ij}$. Then the number of Hamiltonian cycles $H_c$ is given by the relation

The task here is to express () in a form free of any ${\widehat{x}}_i$, $i=1,\cdots ,n$. The result also leads to the resolution of enumeration of Hamiltonian paths in a graph.

It is well known that the enumeration of Hamiltonian cycles and paths in a complete graph $K_n$ and in a complete bipartite graph $K_{n_1{n}_2}$ can only be found from first combinatorial principles . One wonders if there exists a formula which can be used very efficiently to produce $K_n$ and $K_{n_1{n}_2}$. Recently, using Lagrangian methods, Goulden and Jackson have shown that $H_c$ can be expressed in terms of the determinant and permanent of the adjacency matrix . However, the formula of Goulden and Jackson determines neither $K_n$ nor $K_{n_1{n}_2}$ effectively. In this paper, using an algebraic method, we parametrize the adjacency matrix. The resulting formula also involves the determinant and permanent, but it can easily be applied to $K_n$ and $K_{n_1{n}_2}$. In addition, we eliminate the permanent from $H_c$ and show that $H_c$ can be represented by a determinantal function of multivariables, each variable with domain $\{0,1\}$. Furthermore, we show that $H_c$ can be written by number of spanning trees of subgraphs. Finally, we apply the formulas to a complete multigraph $K_{n_1\cdots n_p}$.

The conditions $a_{ij}=a_{ji}$, $i,j=1,\cdots ,n$, are not required in this paper. All formulas can be extended to a digraph simply by multiplying $H_c$ by 2.

Notation For $p,q\in P$ and $n\in \omega$ we write $(q,n)\le (p,n)$ if $q\le p$ and $A_{q,n}=A_{p,n}$.

3 \begin{notation} For $p,q\in P$ and $n\in\omega$
4 ...
5 \end{notation}

Let $𝐁=\left(b_{ij}\right)$ be an $n\times n$ matrix. Let $𝐧=\{1,\cdots ,n\}$. Using the properties of (), it is readily seen that

Lemma 3.1

where $per𝐁$ is the permanent of $𝐁$.

Let $\widehat{Y}=\{{\widehat{y}}_1,\cdots ,{\widehat{y}}_n\}$. Define multiplication for the elements of $\widehat{Y}$ by

Then, it follows that

Lemma 3.4

Note that all basic properties of determinants are direct consequences of Lemma  . Write

where

Let ${𝐁}^{\left(\lambda \right)}=\left(b_{ij}^{\left(\lambda \right)}\right)$. By () and (), it is straightforward to show the following result:

Theorem 3.8

where $I_l=\{i_1,\cdots ,i_l\}$ and ${𝐁}^{\left(\lambda \right)}\left(I_l\right|I_l)$ is the principal submatrix obtained from ${𝐁}^{\left(\lambda \right)}$ by deleting its $i_1,\cdots ,i_l$ rows and columns.

Remark 3.1 Let $𝐌$ be an $n\times n$ matrix. The convention $𝐌\left(𝐧\right|𝐧)=1$ has been used in () and hereafter.

Before proceeding with our discussion, we pause to note that Theorem  yields immediately a fundamental formula which can be used to compute the coefficients of a characteristic polynomial :

Corollary 3.10 Write $det(𝐁-x𝐈)={\sum }_{l=0}^n{(-1)}^l{b}_l{x}^l$. Then

Let

6 \begin{pmatrix} D_1t&-a_{12}t_2&\dots&-a_{1n}t_n\\
7 -a_{21}t_1&D_2t&\dots&-a_{2n}t_n\\
8 \hdotsfor[2]{4}\\
9 -a_{n1}t_1&-a_{n2}t_2&\dots&D_nt\end{pmatrix}

where

Set

Then

where $𝐊(t=1,t_1,\cdots ,t_n;i|i)$ is the $i$th principal submatrix of $𝐊(t=1,t_1,\cdots ,t_n)$.

Theorem   leads to

Note that

Let $t_i={\widehat{x}}_i,i=1,\cdots ,n$. Lemma   yields

10 \begin{multline}
11 \biggl(\sum_{\,i\in\mathbf{n}}a_{l _i}x_i\biggr)
12 \det\mathbf{K}(t=1,x_1,\dots,x_n;l |l )\\
13 =\biggl(\prod_{\,i\in\mathbf{n}}\hat x_i\biggr)
14 \sum_{I\subseteq\mathbf{n}-\{l \}}
15 (-1)^{\envert{I}}\per\mathbf{A}^{(\lambda)}(I|I)
16 \det\mathbf{A}^{(\lambda)}
17 (\overline I\cup\{l \}|\overline I\cup\{l \}).
18 \label{sum-ali}
19 \end{multline}

By (), (), and (), we have

Proposition 3.18

where

We consider here the applications of Theorems  and   to a complete multipartite graph $K_{n_1\cdots n_p}$. It can be shown that the number of spanning trees of $K_{n_1\cdots n_p}$ may be written

where

It follows from Theorems  and   that

20 ... \binom{n_i}{l _i}\\

and

The enumeration of $H_c$ in a $K_{n_1\cdots n_p}$ graph can also be carried out by Theorem   or   together with the algebraic method of (). Some elegant representations may be obtained. For example, $H_c$ in a $K_{n_1{n}_2{n}_3}$ graph may be written

Modern cryptography is fundamentally concerned with the problem of secure private communication. A Secret Key Exchange is a protocol where Alice and Bob, having no secret information in common to start, are able to agree on a common secret key, conversing over a public channel. The notion of a Secret Key Exchange protocol was first introduced in the seminal paper of Diffie and Hellman . presented a concrete implementation of a Secret Key Exchange protocol, dependent on a specific assumption (a variant on the discrete log), specially tailored to yield Secret Key Exchange. Secret Key Exchange is of course trivial if trapdoor permutations exist. However, there is no known implementation based on a weaker general assumption.

The concept of an informationally one-way function was introduced in . We give only an informal definition here:

Definition 5.1 A polynomial time computable function $f=\left\{f_k\right\}$ is informationally one-way if there is no probabilistic polynomial time algorithm which (with probability of the form $1-k^{-e}$ for some $e>0$) returns on input $y\in {\{0,1\}}^k$ a random element of $f^{-1}\left(y\right)$.

In the non-uniform setting show that these are not weaker than one-way functions:

Theorem 5.1 ( (non-uniform)) The existence of informationally one-way functions implies the existence of one-way functions.

We will stick to the convention introduced above of saying “non-uniform” before the theorem statement when the theorem makes use of non-uniformity. It should be understood that if nothing is said then the result holds for both the uniform and the non-uniform models.

It now follows from Theorem  that

Theorem 5.2 (non-uniform) Weak SKE implies the existence of a one-way function.

More recently, the polynomial-time, interior point algorithms for linear programming have been extended to the case of convex quadratic programs , , certain linear complementarity problems , , and the nonlinear complementarity problem . The connection between these algorithms and the classical Newton method for nonlinear equations is well explained in .

We begin our discussion with the following definition:

Definition 6.1

A function $H:{\Re }^n\to {\Re }^n$ is said to be B-differentiable at the point $z$ if (i) $H$ is Lipschitz continuous in a neighborhood of $z$, and (ii)  there exists a positive homogeneous function $BH\left(z\right):{\Re }^n\to {\Re }^n$, called the B-derivative of $H$ at $z$, such that

The function $H$ is B-differentiable in set $S$ if it is B-differentiable at every point in $S$. The B-derivative $BH\left(z\right)$ is said to be strong if

Lemma 6.1 There exists a smooth function ${\psi }_0\left(z\right)$ defined for $\left|z\right|>1-2a$ satisfying the following properties:

Suppose that $\alpha$ is a nonnegative real constant. We apply Proposition  with $\Phi \left(z\right)={\Phi }_0\left(z\right)e^{\alpha {\left|z\right|}^2}$. If $u\in C_0^{\infty }(R^2-{\bigcup }_{\nu }{D}_{\nu }\left(a\right))$, assume that $𝒟$ is a bounded domain containing the support of $u$ and $A\subset 𝒟\subset R^2-{\bigcup }_{\nu }{D}_{\nu }\left(a\right)$. A calculation gives

The boundedness, property () of ${\Phi }_0$, then yields

Let $B\left(X\right)$ be the set of blocks of ${\Lambda }_X$ and let $b\left(X\right)=\left|B\left(X\right)\right|$. If $\varphi \in Q_X$ then $\varphi$ is constant on the blocks of ${\Lambda }_X$.

If ${\Lambda }_{\varphi }\ge {\Lambda }_X$ then ${\Lambda }_{\varphi }={\Lambda }_Y$ for some $Y\ge X$ so that

Thus by Möbius inversion

Thus there is a bijection from $Q_X$ to $W^{B\left(X\right)}$. In particular $\left|Q_X\right|=w^{b\left(X\right)}$.

Next note that $b\left(X\right)=dimX$. We see this by choosing a basis for $X$ consisting of vectors $v^k$ defined by

21 \[v^{k}_{i}=
22 \begin{cases} 1 & \text{if $i \in \Lambda_{k}$},\\
23 0 &\text{otherwise.} \end{cases}
24 \]

Lemma 6.3 Let $𝒜$ be an arrangement. Then

In order to compute $R^{\text{'}\text{'}}$ recall the definition of $S(X,Y)$ from Lemma . Since $H\in ℬ$, ${𝒜}_H\subseteq ℬ$. Thus if $T\left(ℬ\right)=Y$ then $ℬ\in S(H,Y)$. Let $L^{\text{'}\text{'}}=L\left({𝒜}^{\text{'}\text{'}}\right)$. Then

Corollary 6.5 Let $(𝒜,{𝒜}^{\text{'}},{𝒜}^{\text{'}\text{'}})$ be a triple of arrangements. Then

Definition 6.2 Let $(𝒜,{𝒜}^{\text{'}},{𝒜}^{\text{'}\text{'}})$ be a triple with respect to the hyperplane $H\in 𝒜$. Call $H$ a separator if $T\left(𝒜\right)\notin L\left({𝒜}^{\text{'}}\right)$.

Corollary 6.6 Let $(𝒜,{𝒜}^{\text{'}},{𝒜}^{\text{'}\text{'}})$ be a triple with respect to $H\in 𝒜$.

The Poincaré polynomial of an arrangement will appear repeatedly in these notes. It will be shown to equal the Poincaré polynomial of the graded algebras which we are going to associate with $𝒜$. It is also the Poincaré polynomial of the complement $M\left(𝒜\right)$ for a complex arrangement. Here we prove that the Poincaré polynomial is the chamber counting function for a real arrangement. The complement $M\left(𝒜\right)$ is a disjoint union of chambers

The number of chambers is determined by the Poincaré polynomial as follows.

Theorem 6.7 Let ${𝒜}_{𝐑}$ be a real arrangement. Then

Theorem 6.8 Let $\varphi$ be a protocol for a random pair $(X,Y)$. If one of ${\sigma }_{\varphi }(x^{\text{'}},y)$ and ${\sigma }_{\varphi }(x,y^{\text{'}})$ is a prefix of the other and $(x,y)\in S_{X,Y}$, then

If $\varphi$ is a protocol for $(X,Y)$, and $(x,y)$, $(x^{\text{'}},y)$ are distinct inputs in $S_{X,Y}$, then, by the correct-decision property, ${⟨{\sigma }_j(x,y)⟩}_{j=1}^{\infty }\ne {⟨{\sigma }_j(x^{\text{'}},y)⟩}_{j=1}^{\infty }$.

Equation () defined $P_{𝒴}$'s ambiguity set $S_{X|Y}\left(y\right)$ to be the set of possible $X$ values when $Y=y$. The last corollary implies that for all $y\in S_Y$, the multisetA multiset allows multiplicity of elements. Hence, $\{0,01,01\}$ is prefix free as a set, but not as a multiset. of codewords $\{{\sigma }_{\varphi }(x,y):x\in S_{X|Y}\left(y\right)\}$ is prefix free.

${\widehat{C}}_1\left(X\right|Y)$, the one-way complexity of a random pair $(X,Y)$, is the number of bits $P_{𝒳}$ must transmit in the worst case when $P_{𝒴}$ is not permitted to transmit any feedback messages. Starting with $S_{X,Y}$, the support set of $(X,Y)$, we define $G\left(X\right|Y)$, the characteristic hypergraph of $(X,Y)$, and show that

Let $(X,Y)$ be a random pair. For each $y$ in $S_Y$, the support set of $Y$, Equation () defined $S_{X|Y}\left(y\right)$ to be the set of possible $x$ values when $Y=y$. The characteristic hypergraph $G\left(X\right|Y)$ of $(X,Y)$ has $S_X$ as its vertex set and the hyperedge $S_{X|Y}\left(y\right)$ for each $y\in S_Y$.

We can now prove a continuity theorem.

Theorem 7.1 Let $\Omega \subset {𝐑}^n$ be an open set, let $u\in BV(\Omega ;{𝐑}^m)$, and let

for every $x\in \Omega \setminus S_u$. Let $f:{𝐑}^m\to {𝐑}^k$ be a Lipschitz continuous function such that $f\left(0\right)=0$, and let $v=f\left(u\right):\Omega \to {𝐑}^k$. Then $v\in BV(\Omega ;{𝐑}^k)$ and

In addition, for $\left|\tilde{D}u\right|$-almost every $x\in \Omega$ the restriction of the function $f$ to $T_x^u$ is differentiable at $\tilde{u}\left(x\right)$ and

Before proving the theorem, we state without proof three elementary remarks which will be useful in the sequel.

Remark 7.1 Let $\omega :\left]0,+\infty \right[\to \left]0,+\infty \right[$ be a continuous function such that $\omega \left(t\right)\to 0$ as $t\to 0$. Then

for any function $g:\left]0,+\infty \right[\to 𝐑$.

Remark 7.2 Let $g:{𝐑}^n\to 𝐑$ be a Lipschitz continuous function and assume that

exists for every $z\in {𝐐}^n$ and that $L$ is a linear function of $z$. Then $g$ is differentiable at 0.

Remark 7.3 Let $A:{𝐑}^n\to {𝐑}^m$ be a linear function, and let $f:{𝐑}^m\to 𝐑$ be a function. Then the restriction of $f$ to the range of $A$ is differentiable at 0 if and only if $f\left(A\right):{𝐑}^n\to 𝐑$ is differentiable at 0 and

To prove (), it is not restrictive to assume that $k=1$. Moreover, to simplify our notation, from now on we shall assume that $\Omega ={𝐑}^n$. The proof of () is divided into two steps. In the first step we prove the statement in the one-dimensional case $(n=1)$, using Theorem . In the second step we achieve the general result using Theorem .