Revealing structure in large graphs: Szemerédi’s regularity lemma and its use in pattern recognition

Pelillo, Marcello; Elezi, Ismail; Fiorucci, Marco

doi:10.1016/j.patrec.2016.09.007

Cited by 9 publications

(9 citation statements)

References 41 publications

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“…In particular, the higher is the value of the M AP ∈ [0, 1], the higher is the quality of the proposed graph search algorithm. Figures 7,8,9,10 show that the proposed summarization based approach improved the query quality. Figure 8: The MAP@k of the top-k graphs given as output in a database of 180 graphs.…”

Section: Graph Searchmentioning

confidence: 91%

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Separating Structure from Noise in Large Graphs Using the Regularity Lemma

Fiorucci

Pelosin

Pelillo

2020

Pattern Recognition

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How can we separate structural information from noise in large graphs? To address this fundamental question, we propose a graph summarization approach based on Szemerédi's Regularity Lemma, a well-known result in graph theory, which roughly states that every graph can be approximated by the union of a small number of random-like bipartite graphs called "regular pairs". Hence, the Regularity Lemma provides us with a principled way to describe the essential structure of large graphs using a small amount of data. Our paper has several contributions: (i) We present our summarization algorithm which is able to reveal the main structural patterns in large graphs. (ii) We discuss how to use our summarization framework to efficiently retrieve from a database the top-k graphs that are most similar to a query graph. (iii) Finally, we evaluate the noise robustness of our approach in terms of the reconstruction error and the usefulness of the summaries in addressing the graph search task.

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Section: Graph Searchmentioning

confidence: 91%

“…However, despite being polynomial in the size of the underlying graph, all these algorithms have a hidden tower-type dependence on an accuracy parameter. To overcome this limitation, in the last years we have proposed some simple heuristics that, most of the times, allowed us to construct a regular partition [7,8,9].…”

Section: Introductionmentioning

confidence: 99%

Separating Structure from Noise in Large Graphs Using the Regularity Lemma

Fiorucci

Pelosin

Pelillo

2020

Pattern Recognition

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“…In the first step we apply the algorithm implemented by Fiorucci et al (2019) 2 . This extends the previous algorithm of Fiorucci et al (2017) by proposing a novel heuristic procedure where the node set is first partitioned into two groups of nodes and then these are recursively split into smaller groups until a desired cardinality is met and certain conditions that measure quality of the ε-regularity of the partition are satisfied (Pelillo et al, 2017). In particular Fiorucci et al propose two different heuristics to split the groups, one called degree based, which groups together nodes with similar degrees (Fiorucci et al, 2017), and a second one called indeg guided, which splits a sparse (dense) partition into two sparse (dense) partitions.…”

Section: Anonymization Frameworkmentioning

confidence: 99%

You Can't See Me: Anonymizing Graphs Using the Szemerédi Regularity Lemma

2019

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Complex networks gathered from our online interactions provide a rich source of information that can be used to try to model and predict our behavior. While this has very tangible benefits that we have all grown accustomed to, there is a concrete privacy risk in sharing potentially sensitive data about ourselves and the people we interact with, especially when this data is publicly available online and unprotected from malicious attacks. k-anonymity is a technique aimed at reducing this risk by obfuscating the topological information of a graph that can be used to infer the nodes' identity. In this paper we propose a novel algorithm to enforce k-anonymity based on a well-known result in extremal graph theory, the Szemerédi regularity lemma. Given a graph, we start by computing a regular partition of its nodes. The Szemerédi regularity lemma ensures that such a partition exists and that the edges between the sets of nodes behave almost randomly. With this partition, we anonymize the graph by randomizing the edges within each set, obtaining a graph that is structurally similar to the original one yet the nodes within each set are structurally indistinguishable. We test the proposed approach on real-world networks extracted from Facebook. Our experimental results show that the proposed approach is able to anonymize a graph while retaining most of its structural information.

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“…Their approach is based on the Szemerédi regularity lemma [7], a well-known result of extremal graph theory. The Szemerédi regularity lemma has been successfully applied to several problems, from graph theory [18] to computer vision and pattern recognition [25], [34]. The lemma roughly states that every sufficiently large and dense graph can be approximated by the union of Fig.…”

Section: Introductionmentioning

confidence: 99%

k-Anonymity on Graphs Using the Szemerédi Regularity Lemma

Minello

Rossi

Torsello

2021

IEEE Trans. Netw. Sci. Eng.

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Graph anonymization aims at reducing the ability of an attacker to identify the nodes of a graph by obfuscating its structural information. In k-anonymity, this means making each node indistinguishable from at least other k − 1 nodes. Simply stripping the nodes of a graph of their identifying label is insufficient, as with enough structural knowledge an attacker can still recover the nodes identities. We propose an algorithm to enforce k-anonymity based on the Szemerédi regularity lemma. Given a graph, we start by computing a regular partition of its nodes. The Szemerédi regularity lemma ensures that such a partition exists and that the edges between the sets of nodes behave quasi-randomly. With this partition to hand, we anonymize the graph by randomizing the edges within each set, obtaining a graph that is structurally similar to the original one yet the nodes within each set are structurally indistinguishable. Unlike other k-anonymization methods, our approach does not consider a single type of attack, but instead it aims to prevent any structure-based de-anonymization attempt. We test our framework on a wide range of real-world networks and we compare it against another simple yet widely used k-anonymization technique demonstrating the effectiveness of our approach.

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Revealing structure in large graphs: Szemerédi’s regularity lemma and its use in pattern recognition

Cited by 9 publications

References 41 publications

Separating Structure from Noise in Large Graphs Using the Regularity Lemma

Separating Structure from Noise in Large Graphs Using the Regularity Lemma

You Can't See Me: Anonymizing Graphs Using the Szemerédi Regularity Lemma

k-Anonymity on Graphs Using the Szemerédi Regularity Lemma

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