Coloring Graphs with Minimal Edge Load

Nitin Ahuja; Andreas Baltz; Benjamin Doerr; Anand Srivastav

doi:10.1016/j.endm.2004.03.005

Coloring Graphs with Minimal Edge Load

Nitin Ahuja
, Andreas Baltz
, Benjamin Doerr
, Anand Srivastav

Christian-Albrechts-University Kiel

Research output: Contribution to journal › Article › peer-review

Abstract

The load of a coloring φ : V → {red, blue} for a given graph G = (V, E) is a pair L_φ = (r_φ, b_φ), where r_φ is the number of edges with at least one red end-vertex and b_φ is the number of edges with at least one blue end-vertex. Our aim is to find a coloring φ such that l_φ : = max {r_φ, b_φ} is minimized. We show that this problem is NP-complete. For trees, we give a polynomial time algorithm computing an optimal solution. This has load at most m / 2 + Δ log₂ n, where m and n denote the number of edges and vertices respectively. For arbitrary graphs, a coloring with load at most frac(3, 4) m + O (sqrt(Δ m)) of Azuma's martingale inequality. This bound cannot be improved in general: almost all graphs have to be colored with load at least frac(3, 4) m - sqrt(3 m n).

Original language	English
Pages (from-to)	9-13
Number of pages	5
Journal	Electronic Notes in Discrete Mathematics
Volume	17
DOIs	https://doi.org/10.1016/j.endm.2004.03.005
Publication status	Published - 20 Oct 2004
Externally published	Yes

Keywords

graph coloring
graph partitioning

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10.1016/j.endm.2004.03.005

Cite this

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title = "Coloring Graphs with Minimal Edge Load",

abstract = "The load of a coloring φ : V → \{red, blue\} for a given graph G = (V, E) is a pair Lφ = (rφ, bφ), where rφ is the number of edges with at least one red end-vertex and bφ is the number of edges with at least one blue end-vertex. Our aim is to find a coloring φ such that lφ : = max \{rφ, bφ\} is minimized. We show that this problem is NP-complete. For trees, we give a polynomial time algorithm computing an optimal solution. This has load at most m / 2 + Δ log2 n, where m and n denote the number of edges and vertices respectively. For arbitrary graphs, a coloring with load at most frac(3, 4) m + O (sqrt(Δ m)) of Azuma's martingale inequality. This bound cannot be improved in general: almost all graphs have to be colored with load at least frac(3, 4) m - sqrt(3 m n).",

keywords = "graph coloring, graph partitioning",

author = "Nitin Ahuja and Andreas Baltz and Benjamin Doerr and Anand Srivastav",

year = "2004",

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doi = "10.1016/j.endm.2004.03.005",

language = "English",

volume = "17",

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journal = "Electronic Notes in Discrete Mathematics",

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TY - JOUR

T1 - Coloring Graphs with Minimal Edge Load

AU - Ahuja, Nitin

AU - Baltz, Andreas

AU - Doerr, Benjamin

AU - Srivastav, Anand

PY - 2004/10/20

Y1 - 2004/10/20

N2 - The load of a coloring φ : V → {red, blue} for a given graph G = (V, E) is a pair Lφ = (rφ, bφ), where rφ is the number of edges with at least one red end-vertex and bφ is the number of edges with at least one blue end-vertex. Our aim is to find a coloring φ such that lφ : = max {rφ, bφ} is minimized. We show that this problem is NP-complete. For trees, we give a polynomial time algorithm computing an optimal solution. This has load at most m / 2 + Δ log2 n, where m and n denote the number of edges and vertices respectively. For arbitrary graphs, a coloring with load at most frac(3, 4) m + O (sqrt(Δ m)) of Azuma's martingale inequality. This bound cannot be improved in general: almost all graphs have to be colored with load at least frac(3, 4) m - sqrt(3 m n).

AB - The load of a coloring φ : V → {red, blue} for a given graph G = (V, E) is a pair Lφ = (rφ, bφ), where rφ is the number of edges with at least one red end-vertex and bφ is the number of edges with at least one blue end-vertex. Our aim is to find a coloring φ such that lφ : = max {rφ, bφ} is minimized. We show that this problem is NP-complete. For trees, we give a polynomial time algorithm computing an optimal solution. This has load at most m / 2 + Δ log2 n, where m and n denote the number of edges and vertices respectively. For arbitrary graphs, a coloring with load at most frac(3, 4) m + O (sqrt(Δ m)) of Azuma's martingale inequality. This bound cannot be improved in general: almost all graphs have to be colored with load at least frac(3, 4) m - sqrt(3 m n).

KW - graph coloring

KW - graph partitioning

U2 - 10.1016/j.endm.2004.03.005

DO - 10.1016/j.endm.2004.03.005

M3 - Article

AN - SCOPUS:34247370226

SN - 1571-0653

VL - 17

SP - 9

EP - 13

JO - Electronic Notes in Discrete Mathematics

JF - Electronic Notes in Discrete Mathematics

ER -

Coloring Graphs with Minimal Edge Load

Abstract

Keywords

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