Gilad Stern scite author profile

Gilad Stern

5Publications

67Citation Statements Received

189Citation Statements Given

How they've been cited

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139

189

Affiliations

Hebrew University of Jerusalem, Hebrew College, Association for Computing Machinery

Publications

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Reaching Consensus for Asynchronous Distributed Key Generation

Abraham

Jovanovic

Maller³

et al. 2021

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We give a protocol for Asynchronous Distributed Key Generation (A-DKG) that is optimally resilient (can withstand < 3 faulty parties), has a constant expected number of rounds, has˜( 3 ) expected communication complexity, and assumes only the existence of a PKI. Prior to our work, the best A-DKG protocols required Ω( ) expected number of rounds, and Ω( 4 ) expected communication.Our A-DKG protocol relies on several building blocks that are of independent interest. We define and design a Proposal Election (PE) protocol that allows parties to retrospectively agree on a valid proposal after enough proposals have been sent from different parties.With constant probability the elected proposal was proposed by a nonfaulty party. In building our PE protocol, we design a Verifiable Gather protocol which allows parties to communicate which proposals they have and have not seen in a verifiable manner. The final building block to our A-DKG is a Validated Asynchronous Byzantine Agreement (VABA) protocol. We use our PE protocol to construct a VABA protocol that does not require leaders or an asynchronous DKG setup. Our VABA protocol can be used more generally when it is not possible to use threshold signatures. CCS CONCEPTS• Theory of computation → Distributed algorithms; Cryptographic protocols.

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Aggregatable Distributed Key Generation

Gurkan¹,

Jovanovic

Maller³

et al. 2021

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In this paper, we introduce a distributed key generation (DKG) protocol with aggregatable and publicly-verifiable transcripts. Compared with prior publicly-verifiable approaches, our DKG reduces the size of the final transcript and the time to verify it from O(n 2 ) to O(n log n), where n denotes the number of parties. As compared with prior non-publicly-verifiable approaches, our DKG leverages gossip rather than all-to-all communication to reduce verification and communication complexity. We also revisit existing DKG security definitions, which are quite strong, and propose new and natural relaxations. As a result, we can prove the security of our aggregatable DKG as well as that of several existing DKGs, including the popular Pedersen variant. We show that, under these new definitions, these existing DKGs can be used to yield secure threshold variants of popular cryptosystems such as El-Gamal encryption and BLS signatures. We also prove that our DKG can be securely combined with a new efficient verifiable unpredictable function (VUF), whose security we prove in the random oracle model. Finally, we experimentally evaluate our DKG and show that the perparty overheads scale linearly and are practical. For 64 parties, it takes 71 ms to share and 359 ms to verify the overall transcript, while for 8192 parties, it takes 8 s and 42.2 s respectively. cLabs, Ethereum Foundation.

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Revisiting asynchronous fault tolerant computation with optimal resilience

2022

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Reaching Consensus for Asynchronous Distributed Key Generation

Abraham¹,

Jovanovic²,

Maller³

et al. 2021

Preprint

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We give a protocol for Asynchronous Distributed Key Generation (A-DKG) that is optimally resilient (can withstand < 3 faulty parties), has a constant expected number of rounds, has ˜ ( 3 ) expected communication complexity, and assumes only the existence of a PKI. Prior to our work, the best A-DKG protocols required Ω ( ) expected number of rounds, and Ω ( 4 ) expected communication.Our A-DKG protocol relies on several building blocks that are of independent interest. We define and design a Proposal Election (PE) protocol that allows parties to retrospectively agree on a valid proposal after enough proposals have been sent from different parties. With constant probability the elected proposal was proposed by a non-faulty party. In building our PE protocol, we design a Verifiable Gather protocol which allows parties to communicate which proposals they have and have not seen in a verifiable manner.The final building block to our A-DKG is a Validated Asynchronous Byzantine Agreement (VABA) protocol. We use our PE protocol to construct a VABA protocol that does not require leaders or an asynchronous DKG setup. Our VABA protocol can be used more generally when it is not possible to use threshold signatures.

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Revisiting Asynchronous Fault Tolerant Computation with Optimal Resilience

Abraham

Dolev

Stern

2020

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Gilad Stern

Reaching Consensus for Asynchronous Distributed Key Generation

Aggregatable Distributed Key Generation

Revisiting asynchronous fault tolerant computation with optimal resilience

Reaching Consensus for Asynchronous Distributed Key Generation

Revisiting Asynchronous Fault Tolerant Computation with Optimal Resilience

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