From 78199113a6387e67cf0e3b800c81eec73b2e9a68 Mon Sep 17 00:00:00 2001 From: Yu Cong Date: Thu, 1 Jan 2026 21:06:23 +0800 Subject: [PATCH] z --- main.tex | 30 +++++++++++++++--------------- 1 file changed, 15 insertions(+), 15 deletions(-) diff --git a/main.tex b/main.tex index c7751fd..ac24151 100644 --- a/main.tex +++ b/main.tex @@ -43,7 +43,7 @@ \maketitle \section{Connectivity interdiction} \begin{frame}{Connectivity interdiction} -\begin{problem}[connectivity interdiction {[Zenklusen ORL'14]}] +\begin{problem}[connectivity interdiction {[Zenklusen, ORL'14]}] Let $G=(V,E)$ be a graph with edge weights $w:E\to\Z_+$ and edge removal costs $c:E\to\Z_+$ and let $B\in \mathbb Z_+$ be the budget. Find $F\subset E$ with $w(F)\leq B$ s.t. the min-cut in $G-F$ is minimized. @@ -74,10 +74,10 @@ Find the cut with minimum weight $w'$. \toprule unit cost $w(\cdot)=1$ & general case & random? & ref \\ \midrule -$O(m^2n^4\log n)$ & $O(m^{2+1/\e}n^4\log n)$ & $\times$ & [Zenklusen ORL'14] \\ -$O(mn^4\log^2 n)$ & $O(m^{1+1/\e}n^4\log^2 n)$ & $\checkmark$ & [Zenklusen ORL'14] \\ -$\tilde O(m+n^4 B)$ & $O(\frac{m^2n^4}{\e}\log(Bnw_{\max}))$ & $\times$ & [Huang \etal{} IPCO'24]\\ -$\tilde O(mn^3\log w_{\max})$ & - & $\checkmark$ & [Drange \etal{} AAAI'26]\\ +$O(m^2n^4\log n)$ & $O(m^{2+1/\e}n^4\log n)$ & $\times$ & [Zenklusen, ORL'14] \\ +$O(mn^4\log^2 n)$ & $O(m^{1+1/\e}n^4\log^2 n)$ & $\checkmark$ & [Zenklusen, ORL'14] \\ +$\tilde O(m+n^4 B)$ & $O(\frac{m^2n^4}{\e}\log(Bnw_{\max}))$ & $\times$ & [Huang \etal{}, IPCO'24]\\ +$\tilde O(mn^3\log w_{\max})$ & - & $\checkmark$ & [Drange \etal{}, AAAI'26]\\ $\tilde O(m^2+n^3B)$ & $\tilde O(m^2+mn^3+n^3/\e)$ & $\times$ & this work\\ $\tilde O(m+n^3B)$ & $\tilde O(mn^3+n^3/\e)$ & $\checkmark$ & this work\\ \bottomrule @@ -86,18 +86,18 @@ $\tilde O(m+n^3B)$ & $\tilde O(mn^3+n^3/\e)$ & $\checkmark$ & this work\\ \end{table} \end{frame} -\begin{frame}{Method in [Huang \etal{} IPCO'24]} +\begin{frame}{Method in [Huang \etal{}, IPCO'24]} -\begin{problem}[\emph{normalized min-cut} {[Chalermsook \etal{} ICALP'22]}] +\begin{problem}[\emph{normalized min-cut} {[Chalermsook \etal{}, ICALP'22]}] Given the same input as connectivity interdiction, find \[\argmin_{\text{cut $C$}, F\subset C} \frac{w(C-F)}{B-c(F)+1} \quad s.t. \quad 0\leq c(F)\leq B.\] \end{problem} \p -First considered in [Chalermsook \etal{} ICALP'22] as a subproblem in MWU framework when solving minimum $k$-edge connected spanning subgraph (ECSS) problem. +First considered in [Chalermsook \etal{}, ICALP'22] as a subproblem in MWU framework when solving minimum $k$-edge connected spanning subgraph (ECSS) problem. \end{frame} -\begin{frame}{Method in [Huang \etal{} IPCO'24]} +\begin{frame}{Method in [Huang \etal{}, IPCO'24]} Let $\tau$ be a $(1+\e)$-approximation to the normalized min-cut and let $C^*$ be the optimal $B$-free cut. \begin{lemma} $C^*$ is a $(2+2\e)$-approximate min-cut in $(G,w_\tau)$, @@ -171,18 +171,18 @@ P & & P & & P & & \textcolor{BrickRed}{\text{NP-Hard}} \] \p -\begin{conjecture}[{[Geelen \etal{} Ann. Comb. 2015]}] +\begin{conjecture}[{[Geelen \etal{}, Ann. Comb. 2015]}] For any proper minor-closed class $\mathcal M$ of binary matroids, there is a polynomial time algorithm for computing the girth of matroids in $\mathcal M$. \end{conjecture} \end{frame} \begin{frame}{Perturbed graphic matroid} -\begin{theorem}[{[Geelen \etal{} Ann. Comb. 2015]}] +\begin{theorem}[{[Geelen \etal{}, Ann. Comb. 2015]}] For any proper minor-closed class $\mathcal M$ of binary matroids, there exists two constants $k,t\in \Z_+$ such that, for each vertically $k$-connected matroid $M\in \mathcal M$, there exist matrices $A,P\in \F_2^{r\times n}$ such that $A$ is the incidence matrix of a graph, $\mathrm{rank}(P)\leq t$, and either $M$ or $M^*$ is isomorphic to $M(A+P)$. \end{theorem} \p -\begin{theorem}[{[Geelen \& Kapadia Combinatorica'17]}] +\begin{theorem}[{[Geelen \& Kapadia, Combinatorica'17]}] There are polynomial-time randomized algorithms for computing the girth and the cogirth of $M(A+P)$. \end{theorem} @@ -215,13 +215,13 @@ $M(A)$ is a \emph{$(1,t)$-signed graft}. \begin{frame}{Previous works} Results on computing the cogirth of $(1,t)$-signed grafts: \begin{itemize} -\item $O(r^5n)$ random algorithm [Geelen \& Kapadia Combinatorica'17] -\item $n^{O(1)}$ deterministic algorithm when the $\set{s}$-indexed row is all 0 [Nägele \etal{} SODA'18] +\item $O(r^5n)$ random algorithm [Geelen \& Kapadia, Combinatorica'17] +\item $n^{O(1)}$ deterministic algorithm when the $\set{s}$-indexed row is all 0 [Nägele \etal{}, SODA'18] \end{itemize} \end{frame} \begin{frame}{Method} -\begin{theorem}[{[Chekuri \etal{} SOSA'19]}] +\begin{theorem}[{[Chekuri \etal{}, SOSA'19]}] Given a matroid $M$, let $\lambda(M)$ be its cogirth and let $\sigma(M)$ be the fractional base packing number. If there is some constant $c$ that $\frac{\lambda(M)}{\sigma(M)}