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Let $A$ be a given $n$-by-$n$ complex matrix with eigenvalues $lambda ,lambda _{2},ldots ,lambda _{n}$. Suppose there are nonzero vectors $% x,yin mathbb{C}^{n}$ such that $Ax=lambda x$, $y^{ast }A=lambda y^{ast }$, and $y^{ast }x=1$. Let $vin mathbb{C}^{n}$ be such that $v^{ast }x=1$% , let $cin mathbb{C}$, and assume that $lambda eq clambda _{j}$ for each $j=2,ldots ,n$. Define $A(c):=cA+(1-c)lambda xv^{ast }$. The eigenvalues of $% A(c)$ are $lambda ,clambda _{2},ldots ,clambda _{n}$. Every left eigenvector of $A(c)$ corresponding to $lambda $ is a scalar multiple of $% y-z(c)$, in which the vector $z(c)$ is an explicit rational function of $c$. If a standard form such as the Jordan canonical form or the Schur triangular form is known for $A$, we show how to obtain the corresponding standard form of $A(c)$. The web hyper-link matrix $G(c)$ used by Google for computing the PageRank is a special case in which $A$ is real, nonnegative, and row stochastic (taking into consideration the dangling nodes), $cin (0,1)$, $x$ is the vector of all ones, and $v$ is a positive probability vector. The PageRank vector (the normalized dominant left eigenvector of $G(c)$) is therefore an explicit rational function of $c$. Extrapolation procedures on the complex field may give a practical and efficient way to compute the PageRank vector when $c$ is close to $1$. A discussion on the model, on its adherence to reality, and on possible variations is also considered.