[Resource Topic] 2013/880: New Constructions of Revocable Identity-Based Encryption from Multilinear Maps

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Title:
New Constructions of Revocable Identity-Based Encryption from Multilinear Maps

Authors: Seunghwan Park, Kwangsu Lee, Dong Hoon Lee

Abstract:

A revocation mechanism in cryptosystems for a large number of users is absolutely necessary for maintaining the security of whole systems. A revocable identity-based encryption (RIBE) provides an efficient revocation method in IBE in which a trusted authority periodically broadcasts an update key for non-revoked users and a user can decrypt a ciphertext if his private key is not revoked in the update key. Boldyreva, Goyal, and Kumar (CCS 2008) defined RIBE and proposed an RIBE scheme that uses a tree-based revocation encryption scheme to revoke users’ private keys. However, this approach has an inherent limitation in that the number of private key elements and update key elements cannot be constant. In this paper, to overcome this limitation, we devise a new technique for RIBE and propose RIBE schemes with a constant number of private key elements. We achieve the following results: - We first devise a new technique for RIBE that combines a hierarchical IBE (HIBE) scheme and a public-key broadcast encryption (PKBE) scheme by using multilinear maps. In contrast to the previous technique for RIBE, our technique uses a PKBE scheme in bilinear maps for revocation to achieve short private keys and update keys. - Following our new technique for RIBE, we propose an RIBE scheme in three-leveled multilinear maps that combines the HIBE scheme of Boneh and Boyen (EUROCRYPT 2004) and the PKBE scheme of Boneh, Gentry, and Waters (CRYPTO 2005). The private key and update key of our scheme possess a constant number of group elements. We introduce a new complexity assumption in multilinear maps and prove the security of our scheme in the selective revocation list model. - Next, we propose another RIBE scheme with reduced public parameters by combining the HIBE scheme of Boneh and Boyen and the PKBE scheme of Boneh, Waters, and Zhandry (CRYPTO 2014), which uses multilinear maps. Compared with our first RIBE scheme, our second RIBE scheme requires high-leveled multilinear maps since the underlying PKBE scheme is based on high-leveled multilinear maps.

ePrint: https://eprint.iacr.org/2013/880

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