Conditionally-perfect secrecy and a provably-secure randomized cipher
Journal of Cryptology - Eurocrypt '90
Randomness-optimal oblivious sampling
Proceedings of the workshop on Randomized algorithms and computation
Tight security proofs for the bounded-storage model
STOC '02 Proceedings of the thiry-fourth annual ACM symposium on Theory of computing
Hyper-Encryption and Everlasting Security
STACS '02 Proceedings of the 19th Annual Symposium on Theoretical Aspects of Computer Science
Unconditional Security Against Memory-Bounded Adversaries
CRYPTO '97 Proceedings of the 17th Annual International Cryptology Conference on Advances in Cryptology
Encryption against Storage-Bounded Adversaries from On-Line Strong Extractors
Journal of Cryptology
On everlasting security in the hybrid bounded storage model
ICALP'06 Proceedings of the 33rd international conference on Automata, Languages and Programming - Volume Part II
Everlasting security in the bounded storage model
IEEE Transactions on Information Theory
Towards efficient private distributed computation on unbounded input streams
ACNS'13 Proceedings of the 11th international conference on Applied Cryptography and Network Security
| Hi-index | 0.00 |
We propose efficient schemes for information-theoretically secure key exchange in the Bounded Storage Model (BSM), where the adversary is assumed to have limited storage. Our schemes generate a secret One Time Pad (OTP) shared by the sender and the receiver, from a large number of public random bits produced by the sender or by an external source. Our schemes initially generate a small number of shared secret bits, using known techniques. We introduce a new method to expand a small number of shared bits to a much longer, shared key. Our schemes are tailored to the requirements of sensor nodes and wireless networks. They are simple, efficient to implement and take advantage of the fact that practical wireless protocols transmit data in frames, unlike previous protocols, which assume access to specific bits in a stream of data. Indeed, our main contribution is twofold. On the one hand, we construct schemes that are attractive in terms of simplicity, computational complexity, number of bits read from the shared random source and expansion factor of the initial key to the final shared key. On the other hand, we show how to transform any existing scheme for key exchange in BSM into a more efficient scheme in the number of bits it reads from the shared source, given that the source is transmitted in frames.