Smallest Domination Number and Largest Independence Number of Graphs and Forests with given Degree Sequence

For a sequence $d$ of non-negative integers, let ${\cal G}(d)$ and ${\cal F}(d)$ be the sets of all graphs and forests with degree sequence $d$, respectively. Let $\gamma_{\min}(d)=\min\{ \gamma(G):G\in {\cal G}(d)\}$, $\alpha_{\max}(d)=\max\{ \alpha(G):G\in {\cal G}(d)\}$, $\gamma_{\min}^{\cal F}(d)=\min\{ \gamma(F):F\in {\cal F}(d)\}$, and $\alpha_{\max}^{\cal F}(d)=\max\{ \alpha(F):F\in {\cal F}(d)\}$ where $\gamma(G)$ is the domination number and $\alpha(G)$ is the independence number of a graph $G$. Adapting results of Havel and Hakimi, Rao showed in 1979 that $\alpha_{\max}(d)$ can be determined in polynomial time. We establish the existence of realizations $G\in {\cal G}(d)$ with $\gamma_{\min}(d)=\gamma(G)$, and $F_{\gamma},F_{\alpha}\in {\cal F}(d)$ with $\gamma_{\min}^{\cal F}(d)=\gamma(F_{\gamma})$ and $\alpha_{\max}^{\cal F}(d)=\alpha(F_{\alpha})$ that have strong structural properties. This leads to an efficient algorithm to determine $\gamma_{\min}(d)$ for every given degree sequence $d$ with bounded entries as well as closed formulas for $\gamma_{\min}^{\cal F}(d)$ and $\alpha_{\max}^{\cal F}(d)$.