MQV
MQV (Menezes–Qu–Vanstone) is an authenticated protocol for key agreement based on the Diffie–Hellman scheme. Like other authenticated Diffie-Hellman schemes, MQV provides protection against an active attacker. The protocol can be modified to work in an arbitrary finite group, and, in particular, elliptic curve groups, where it is known as elliptic curve MQV (ECMQV).
MQV was initially proposed by Menezes, Qu and Vanstone in 1995. It was modified with Law and Solinas in 1998. There are one-, two- and three-pass variants.
MQV is incorporated in the public-key standard IEEE P1363.
Some variants of MQV are claimed in patents assigned to Certicom.
MQV has some weaknesses that were fixed by HMQV in 2005.[1] A few articles[2][3] offered alternative viewpoint.
ECMQV has been dropped from the National Security Agency's Suite B set of cryptographic standards.
Description
Alice has a key pair (A,a) with A her public key and a her private key and Bob has the key pair (B,b) with B his public key and b his private key.
In the following has the following meaning. Let be a point on an elliptic curve. Then where and n is the order of the used generator point P. So are the first L bits of the x coordinate of R.
Step | Operation |
---|---|
1 | Alice generates a key pair (X,x) by generating randomly x and calculating X=xP with P a point on an elliptic curve. |
2 | Bob generates a key pair (Y,y) in the same way as Alice. |
3 | Now, Alice calculates and sends X to Bob. |
4 | Bob calculates and sends Y to Alice. |
5 | Alice calculates and Bob calculates where h is the cofactor (see Elliptic curve cryptography: domain parameters). |
6 | The communication of secret was successful. A key for a symmetric-key algorithm can be derived from K. |
Note: for the algorithm to be secure some checks have to be performed. See Hankerson et al.
Correctness
Bob calculates: .
Alice calculates: .
So the keys K are indeed the same with
See also
References
- ↑ Krawczyk, H. (2005). "HMQV: A High-Performance Secure Diffie-Hellman Protocol". Advances in Cryptology – CRYPTO 2005. Lecture Notes in Computer Science 3621. pp. 546–566. doi:10.1007/11535218_33. ISBN 978-3-540-28114-6.
- ↑ Koblitz, Neal (2007). "The Uneasy Relationship Between Mathematics and Cryptography" (PDF). Notices of the AMS 54 (8): 972–979.
- ↑ "Letters to the Editor" (PDF). Notices of the AMS 54 (11): 1454–1456. 2007.
Bibliography
- Kaliski, B. S., Jr (2001). "An unknown key-share attack on the MQV key agreement protocol". ACM Trans. Inf. Syst. Secur. 4 (3): 275–288. doi:10.1145/501978.501981.
- Law, L.; Menezes, A.; Qu, M.; Solinas, J.; Vanstone, S. (2003). "An Efficient Protocol for Authenticated Key Agreement". Des. Codes Cryptography 28 (2): 119–134. doi:10.1023/A:1022595222606.
- Leadbitter, P. J.; Smart, N. P. (2003). "Analysis of the Insecurity of ECMQV with Partially Known Nonces". Information Security. 6th International Conference, ISC 2003, Bristol, UK, October 1–3, 2003. Proceedings. Lecture Notes in Computer Science. pp. 240–251. doi:10.1007/10958513_19. ISBN 978-3-540-20176-2.
- Menezes, Alfred J.; Qu, Minghua; Vanstone, Scott A. (2005). Some new key agreement protocols providing implicit authentication (PDF). 2nd Workshop on Selected Areas in Cryptography (SAC '95). Ottawa, Canada. pp. 22–32.
- Hankerson, D.; Vanstone, S.; Menezes, A. (2004). Guide to Elliptic Curve Cryptography. Springer Professional Computing. New York: Springer. doi:10.1007/b97644. ISBN 0-387-95273-X.
External links
- A Secure and Efficient Authenticated Diffie–Hellman Protocol by Sarr, Elbaz-Vincent, and Bajard
- HMQV: A High-Performance Secure Diffie–Hellman Protocol by Hugo Krawczyk
- Another look at HMQV
- An Efficient Protocol for Authenticated Key Agreement
- MQV and HMQV in IEEE P1363 (power point)
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