The Power of Distributed Verifiers in Interactive Proofs

Naor, Moni; Parter, Merav; Yogev, Eylon

doi:10.1137/1.9781611975994.67

Cited by 34 publications

(47 citation statements)

References 28 publications

(90 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…This model provides a better understanding of problems such as symmetric dumbbell graphs in Section 4.3, and follow-up works have shown that powerful tools can be designed for this setting, with trade-offs between the different resources (number of bits exchanged, number of prover-nodes communication rounds etc.) [18,57,55].…”

Section: Distributed Decision: a Complexity Theory Point Of Viewmentioning

confidence: 99%

See 1 more Smart Citation

Introduction to local certification

Feuilloley¹

2021

Discrete Mathematics &Amp; Theoretical Computer Science

View full text Add to dashboard Cite

A distributed graph algorithm is basically an algorithm where every node of a graph can look at its neighborhood at some distance in the graph and chose its output. As distributed environment are subject to faults, an important issue is to be able to check that the output is correct, or in general that the network is in proper configuration with respect to some predicate. One would like this checking to be very local, to avoid using too much resources. Unfortunately most predicates cannot be checked this way, and that is where certification comes into play. Local certification (also known as proof-labeling schemes, locally checkable proofs or distributed verification) consists in assigning labels to the nodes, that certify that the configuration is correct. There are several point of view on this topic: it can be seen as a part of self-stabilizing algorithms, as labeling problem, or as a non-deterministic distributed decision. This paper is an introduction to the domain of local certification, giving an overview of the history, the techniques and the current research directions.

show abstract

Section: Distributed Decision: a Complexity Theory Point Of Viewmentioning

confidence: 99%

“…This is a recent and active area of research. We refer to [57] for a list of nice open questions. Let us just mention that an important question is to establish the best trade-off possible between interaction and communication.…”

Section: Complexity Theorymentioning

confidence: 99%

Introduction to local certification

Feuilloley¹

2021

Discrete Mathematics &Amp; Theoretical Computer Science

View full text Add to dashboard Cite

show abstract

“…It is always important to keep in mind the compiler defined in [40] which turns, automatically, any problem solved in NP in time τ (n) into a dMAM protocol that uses bandwidth τ (n) log n/n. Therefore, any class of sparse graphs that can be recognized in linear time, can also be recognized by a dMAM protocol with logarithmic-sized certificates.…”

Section: Related Workmentioning

confidence: 99%

Distributed Interactive Proofs for the Recognition of Some Geometric Intersection Graph Classes

Jáuregui¹,

Montealegre²,

Rapaport³

2021

Preprint

View full text Add to dashboard Cite

A graph G = (V, E) is a geometric intersection graph if every node v ∈ V is identified with a geometric object of some particular type, and two nodes are adjacent if the corresponding objects intersect. Geometric intersection graph classes have been studied from both the theoretical and practical point of view. On the one hand, many hard problems can be efficiently solved or approximated when the input graph is restricted to a geometric intersection class of graphs. On the other hand, these graphs appear naturally in many applications such as sensor networks, scheduling problems, and others. Recently, in the context of distributed certification and distributed interactive proofs, the recognition of graph classes has started to be intensively studied. Different results related to the recognition of trees, bipartite graphs, bounded diameter graphs, triangle-free graphs, planar graphs, bounded genus graphs, H-minor free graphs, etc., have been obtained. The goal of the present work is to design efficient distributed protocols for the recognition of relevant geometric intersection graph classes, namely permutation graphs, trapezoid graphs, circle graphs and polygon-circle graphs. More precisely, for the two first classes we give proof labeling schemes recognizing them with logarithmic-sized certificates. For the other two classes, we give three-round distributed interactive protocols that use messages and certificates of size O(log n). Finally, we provide logarithmic lower-bounds on the size of the certificates on the proof labeling schemes for the recognition of any of the aforementioned geometric intersection graph classes.

show abstract

“…However, all predicates on labeled graphs can be certified by allowing randomization [23], or by allowing just one alternation of quantifiers (the analog of Π 2 in the polynomial hierarchy) [8]. A recent line of work studies a distributed variant of interactive proofs [15,33,40].…”

Section: Previous Workmentioning

confidence: 99%

Redundancy in distributed proofs

et al. 2020

View full text Add to dashboard Cite

Distributed proofs are mechanisms that enable the nodes of a network to collectively and efficiently check the correctness of Boolean predicates on the structure of the network (e.g., having a specific diameter), or on objects distributed over the nodes (e.g., a spanning tree). We consider well known mechanisms consisting of two components: a prover that assigns a certificate to each node, and a distributed algorithm called a verifier that is in charge of verifying the distributed proof formed by the collection of all certificates. We show that many network predicates have distributed proofs offering a high level of redundancy, explicitly or implicitly. We use this remarkable property of distributed proofs to establish perfect tradeoffs between the size of the certificate stored at every node, and the number of rounds of the verification protocol.

show abstract

The Power of Distributed Verifiers in Interactive Proofs

Cited by 34 publications

References 28 publications

Introduction to local certification

Introduction to local certification

Distributed Interactive Proofs for the Recognition of Some Geometric Intersection Graph Classes

Redundancy in distributed proofs

Contact Info

Product

Resources

About