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Isomorphism Testing for Graphs Excluding Small Topological Subgraphs: Unifying and Extending Previous Results


核心概念
The author presents a new isomorphism test for graphs excluding small topological subgraphs, unifying and extending previous results in the field.
要約

The content discusses the complexity of graph isomorphism testing, focusing on graphs excluding specific subgraphs. It introduces a novel algorithm that significantly improves previous methods by leveraging group-theoretic techniques and closure operators. The approach involves decomposing input graphs into parts with simple interplay, leading to efficient isomorphism testing. The study provides structural insights into automorphism groups of such graphs, highlighting their unique properties.

The theorem presented in the content establishes a key technical contribution by demonstrating how to compute suitable initial sets for isomorphism testing. By utilizing the 3-dimensional Weisfeiler-Leman algorithm, the author proves that these initial sets satisfy essential properties required for efficient graph analysis. The proof involves intricate analyses of colorings and closure operators to ensure isomorphism-invariance.

Overall, the content delves deep into the theoretical aspects of graph isomorphism testing, offering innovative solutions for challenging problems in computational complexity theory.

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統計
Our result runs in time npolylog(h). Polynomial-time algorithms are known for various restricted classes of graphs. For every X ⊆ V (G), it holds that |NG(Z)| < h for every connected component Z of G−D where D := clGt(X).
引用
"Recall that a graph H is a topological subgraph of a graph G if H can be obtained from G by deleting vertices and edges as well as dissolving degree two vertices." - Content "A common feature of all these algorithms is that the exponent of the running time depends at least linearly on the parameter in question." - Content

抽出されたキーインサイト

by Daniel Neuen 場所 arxiv.org 03-08-2024

https://arxiv.org/pdf/2011.14730.pdf
Isomorphism Testing for Graphs Excluding Small Topological Subgraphs

深掘り質問

How do closure operators impact graph analysis beyond isomorphism testing

Closure operators play a crucial role in graph analysis beyond isomorphism testing. They are used to define topological subgraphs, which can help identify structural properties of graphs such as connectivity, separability, and edge density. By applying closure operators to sets of vertices or edges in a graph, researchers can analyze relationships between different components and study how they interact within the larger graph structure. This allows for a deeper understanding of the graph's topology and can reveal important insights into its overall behavior.

What are potential drawbacks or limitations of using group-theoretic techniques in this context

While group-theoretic techniques have been instrumental in advancing isomorphism testing for graphs, there are potential drawbacks and limitations to consider. One limitation is that these techniques may not always scale well to very large or complex graphs due to computational complexity issues. Group theory algorithms may also be challenging to implement efficiently in practice, requiring specialized knowledge and expertise. Additionally, group-theoretic approaches may not always capture all aspects of graph structure comprehensively. They focus primarily on symmetries and transformations within the graph but may overlook other important characteristics such as local clustering patterns or community structures. As a result, relying solely on group theory for graph analysis could lead to incomplete or biased results.

How might advancements in graph theory influence real-world applications outside theoretical computer science

Advancements in graph theory have significant implications for real-world applications outside theoretical computer science. For example: Social Networks: Graph theory advancements can improve social network analysis by identifying influential nodes, detecting communities within networks, and predicting information flow dynamics. Bioinformatics: Graph algorithms can enhance biological data analysis by modeling protein interactions, genetic pathways, and disease spread patterns. Transportation Planning: Graph theory helps optimize transportation networks by finding efficient routes, minimizing congestion points, and improving overall system performance. Recommendation Systems: Graph-based algorithms power recommendation engines by analyzing user-item interactions to suggest personalized content or products. Overall advancements in graph theory enable more sophisticated problem-solving approaches across various domains leading to improved decision-making processes and innovative solutions.
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