Diameter Spanners, Eccentricity Spanners, and Approximating Extremal Distances
The diameter of a graph is one if its most important parameters, being used in many real-word applications. In particular, the diameter dictates how fast information can spread throughout data and communication networks. Thus, it is a natural question to ask how much can we sparsify a graph and stil...
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| creator | Choudhary, Keerti Gold, Omer |
| description | The diameter of a graph is one if its most important parameters, being used
in many real-word applications. In particular, the diameter dictates how fast
information can spread throughout data and communication networks. Thus, it is
a natural question to ask how much can we sparsify a graph and still guarantee
that its diameter remains preserved within an approximation $t$. This property
is captured by the notion of extremal-distance spanners. Given a graph
$G=(V,E)$, a subgraph $H=(V,E_H)$ is defined to be a $t$-diameter spanner if
the diameter of $H$ is at most $t$ times the diameter of $G$.
We show that for any $n$-vertex and $m$-edges directed graph $G$, we can
compute a sparse subgraph $H$ that is a $(1.5)$-diameter spanner of $G$, such
that $H$ contains at most $\tilde O(n^{1.5})$ edges. We also show that the
stretch factor cannot be improved to $(1.5-\epsilon)$. For a graph whose
diameter is bounded by some constant, we show the existence of
$\frac{5}{3}$-diameter spanner that contains at most $\tilde O(n^\frac{4}{3})$
edges. We also show that this bound is tight.
Additionally, we present other types of extremal-distance spanners, such as
$2$-eccentricity spanners and $2$-radius spanners, both contain only $\tilde
O(n)$ edges and are computable in $\tilde O(m)$ time.
Finally, we study extremal-distance spanners in the dynamic and
fault-tolerant settings. An interesting implication of our work is the first
$\tilde O(m)$-time algorithm for computing $2$-approximation of vertex
eccentricities in general directed weighted graphs. Backurs et al. [STOC 2018]
gave an $\tilde O(m\sqrt{n})$ time algorithm for this problem, and also showed
that no $O(n^{2-o(1)})$ time algorithm can achieve an approximation factor
better than $2$ for graph eccentricities, unless SETH fails; this shows that
our approximation factor is essentially tight. |
| doi_str_mv | 10.48550/arxiv.1812.01602 |
| format | Article |
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in many real-word applications. In particular, the diameter dictates how fast
information can spread throughout data and communication networks. Thus, it is
a natural question to ask how much can we sparsify a graph and still guarantee
that its diameter remains preserved within an approximation $t$. This property
is captured by the notion of extremal-distance spanners. Given a graph
$G=(V,E)$, a subgraph $H=(V,E_H)$ is defined to be a $t$-diameter spanner if
the diameter of $H$ is at most $t$ times the diameter of $G$.
We show that for any $n$-vertex and $m$-edges directed graph $G$, we can
compute a sparse subgraph $H$ that is a $(1.5)$-diameter spanner of $G$, such
that $H$ contains at most $\tilde O(n^{1.5})$ edges. We also show that the
stretch factor cannot be improved to $(1.5-\epsilon)$. For a graph whose
diameter is bounded by some constant, we show the existence of
$\frac{5}{3}$-diameter spanner that contains at most $\tilde O(n^\frac{4}{3})$
edges. We also show that this bound is tight.
Additionally, we present other types of extremal-distance spanners, such as
$2$-eccentricity spanners and $2$-radius spanners, both contain only $\tilde
O(n)$ edges and are computable in $\tilde O(m)$ time.
Finally, we study extremal-distance spanners in the dynamic and
fault-tolerant settings. An interesting implication of our work is the first
$\tilde O(m)$-time algorithm for computing $2$-approximation of vertex
eccentricities in general directed weighted graphs. Backurs et al. [STOC 2018]
gave an $\tilde O(m\sqrt{n})$ time algorithm for this problem, and also showed
that no $O(n^{2-o(1)})$ time algorithm can achieve an approximation factor
better than $2$ for graph eccentricities, unless SETH fails; this shows that
our approximation factor is essentially tight.</description><identifier>DOI: 10.48550/arxiv.1812.01602</identifier><language>eng</language><subject>Computer Science - Data Structures and Algorithms</subject><creationdate>2018-12</creationdate><rights>http://arxiv.org/licenses/nonexclusive-distrib/1.0</rights><oa>free_for_read</oa><woscitedreferencessubscribed>false</woscitedreferencessubscribed></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><link.rule.ids>228,230,780,885</link.rule.ids><linktorsrc>$$Uhttps://arxiv.org/abs/1812.01602$$EView_record_in_Cornell_University$$FView_record_in_$$GCornell_University$$Hfree_for_read</linktorsrc><backlink>$$Uhttps://doi.org/10.48550/arXiv.1812.01602$$DView paper in arXiv$$Hfree_for_read</backlink></links><search><creatorcontrib>Choudhary, Keerti</creatorcontrib><creatorcontrib>Gold, Omer</creatorcontrib><title>Diameter Spanners, Eccentricity Spanners, and Approximating Extremal Distances</title><description>The diameter of a graph is one if its most important parameters, being used
in many real-word applications. In particular, the diameter dictates how fast
information can spread throughout data and communication networks. Thus, it is
a natural question to ask how much can we sparsify a graph and still guarantee
that its diameter remains preserved within an approximation $t$. This property
is captured by the notion of extremal-distance spanners. Given a graph
$G=(V,E)$, a subgraph $H=(V,E_H)$ is defined to be a $t$-diameter spanner if
the diameter of $H$ is at most $t$ times the diameter of $G$.
We show that for any $n$-vertex and $m$-edges directed graph $G$, we can
compute a sparse subgraph $H$ that is a $(1.5)$-diameter spanner of $G$, such
that $H$ contains at most $\tilde O(n^{1.5})$ edges. We also show that the
stretch factor cannot be improved to $(1.5-\epsilon)$. For a graph whose
diameter is bounded by some constant, we show the existence of
$\frac{5}{3}$-diameter spanner that contains at most $\tilde O(n^\frac{4}{3})$
edges. We also show that this bound is tight.
Additionally, we present other types of extremal-distance spanners, such as
$2$-eccentricity spanners and $2$-radius spanners, both contain only $\tilde
O(n)$ edges and are computable in $\tilde O(m)$ time.
Finally, we study extremal-distance spanners in the dynamic and
fault-tolerant settings. An interesting implication of our work is the first
$\tilde O(m)$-time algorithm for computing $2$-approximation of vertex
eccentricities in general directed weighted graphs. Backurs et al. [STOC 2018]
gave an $\tilde O(m\sqrt{n})$ time algorithm for this problem, and also showed
that no $O(n^{2-o(1)})$ time algorithm can achieve an approximation factor
better than $2$ for graph eccentricities, unless SETH fails; this shows that
our approximation factor is essentially tight.</description><subject>Computer Science - Data Structures and Algorithms</subject><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2018</creationdate><recordtype>article</recordtype><sourceid>GOX</sourceid><recordid>eNpNj8tqwzAURLXJoqT9gK6qD6hdvSzZy5C4DwjJItmba0m3CGLFyKI4f9807aKrgRk4zCHkkbNS1VXFXiDN4avkNRcl45qJO7LbBBh89okeRojRp-mZttb6mFOwIV_-1RAdXY1jOs9hgBziJ23nnPwAJ7oJU4Zo_XRPFginyT_85ZIcX9vj-r3Y7t8-1qttAdqIotdOycY22onKabROYc2VQ5TGYi_9dauZsaIxXDUaei28MUL2FRqNDplckqdf7E2oG9P1Ubp0P2LdTUx-A-t_SZY</recordid><startdate>20181204</startdate><enddate>20181204</enddate><creator>Choudhary, Keerti</creator><creator>Gold, Omer</creator><scope>AKY</scope><scope>GOX</scope></search><sort><creationdate>20181204</creationdate><title>Diameter Spanners, Eccentricity Spanners, and Approximating Extremal Distances</title><author>Choudhary, Keerti ; Gold, Omer</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-a672-b6d439c96d25d6fcd4f814dff37cfb3e39c807c2971496ab62e7723b5f76fdf03</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2018</creationdate><topic>Computer Science - Data Structures and Algorithms</topic><toplevel>online_resources</toplevel><creatorcontrib>Choudhary, Keerti</creatorcontrib><creatorcontrib>Gold, Omer</creatorcontrib><collection>arXiv Computer Science</collection><collection>arXiv.org</collection></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext_linktorsrc</fulltext></delivery><addata><au>Choudhary, Keerti</au><au>Gold, Omer</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Diameter Spanners, Eccentricity Spanners, and Approximating Extremal Distances</atitle><date>2018-12-04</date><risdate>2018</risdate><abstract>The diameter of a graph is one if its most important parameters, being used
in many real-word applications. In particular, the diameter dictates how fast
information can spread throughout data and communication networks. Thus, it is
a natural question to ask how much can we sparsify a graph and still guarantee
that its diameter remains preserved within an approximation $t$. This property
is captured by the notion of extremal-distance spanners. Given a graph
$G=(V,E)$, a subgraph $H=(V,E_H)$ is defined to be a $t$-diameter spanner if
the diameter of $H$ is at most $t$ times the diameter of $G$.
We show that for any $n$-vertex and $m$-edges directed graph $G$, we can
compute a sparse subgraph $H$ that is a $(1.5)$-diameter spanner of $G$, such
that $H$ contains at most $\tilde O(n^{1.5})$ edges. We also show that the
stretch factor cannot be improved to $(1.5-\epsilon)$. For a graph whose
diameter is bounded by some constant, we show the existence of
$\frac{5}{3}$-diameter spanner that contains at most $\tilde O(n^\frac{4}{3})$
edges. We also show that this bound is tight.
Additionally, we present other types of extremal-distance spanners, such as
$2$-eccentricity spanners and $2$-radius spanners, both contain only $\tilde
O(n)$ edges and are computable in $\tilde O(m)$ time.
Finally, we study extremal-distance spanners in the dynamic and
fault-tolerant settings. An interesting implication of our work is the first
$\tilde O(m)$-time algorithm for computing $2$-approximation of vertex
eccentricities in general directed weighted graphs. Backurs et al. [STOC 2018]
gave an $\tilde O(m\sqrt{n})$ time algorithm for this problem, and also showed
that no $O(n^{2-o(1)})$ time algorithm can achieve an approximation factor
better than $2$ for graph eccentricities, unless SETH fails; this shows that
our approximation factor is essentially tight.</abstract><doi>10.48550/arxiv.1812.01602</doi><oa>free_for_read</oa></addata></record> |
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| title | Diameter Spanners, Eccentricity Spanners, and Approximating Extremal Distances |
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