Internet Engineering Task Force (IETF) D. Fu
Request for Comments: 5903 J. Solinas
Obsoletes: 4753 NSA
Category: Informational June 2010
ISSN: 2070-1721
Elliptic Curve Groups modulo a Prime (ECP Groups) for IKE and IKEv2
Abstract
This document describes three Elliptic Curve Cryptography (ECC)
groups for use in the Internet Key Exchange (IKE) and Internet Key
Exchange version 2 (IKEv2) protocols in addition to previously
defined groups. These groups are based on modular arithmetic rather
than binary arithmetic. These groups are defined to align IKE and
IKEv2 with other ECC implementations and standards, particularly NIST
standards. In addition, the curves defined here can provide more
efficient implementation than previously defined ECC groups. This
document obsoletes RFC 4753.
Status of This Memo
This document is not an Internet Standards Track specification; it is
published for informational purposes.
This document is a product of the Internet Engineering Task Force
(IETF). It represents the consensus of the IETF community. It has
received public review and has been approved for publication by the
Internet Engineering Steering Group (IESG). Not all documents
approved by the IESG are a candidate for any level of Internet
Standard; see Section 2 of RFC 5741.
Information about the current status of this document, any errata,
and how to provide feedback on it may be obtained at
http://www.rfc-editor.org/info/rfc5903.
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Copyright Notice
Copyright (c) 2010 IETF Trust and the persons identified as the
document authors. All rights reserved.
This document is subject to BCP 78 and the IETF Trust's Legal
Provisions Relating to IETF Documents
(http://trustee.ietf.org/license-info) in effect on the date of
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to this document. Code Components extracted from this document must
include Simplified BSD License text as described in Section 4.e of
the Trust Legal Provisions and are provided without warranty as
described in the Simplified BSD License.
Table of Contents
1. Introduction ....................................................3
2. Requirements Terminology ........................................4
3. Additional ECC Groups ...........................................4
3.1. 256-Bit Random ECP Group ...................................4
3.2. 384-Bit Random ECP Group ...................................5
3.3. 521-Bit Random ECP Group ...................................6
4. Security Considerations .........................................7
5. Alignment with Other Standards ..................................7
6. IANA Considerations .............................................7
7. ECP Key Exchange Data Formats ...................................8
8. Test Vectors ....................................................9
8.1. 256-Bit Random ECP Group ...................................9
8.2. 384-Bit Random ECP Group ..................................10
8.3. 521-Bit Random ECP Group ..................................11
9. Changes from RFC 4753 ..........................................13
10. References ....................................................13
10.1. Normative References .....................................13
10.2. Informative References ...................................14
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1. Introduction
This document describes default Diffie-Hellman groups for use in IKE
and IKEv2 in addition to the Oakley Groups included in [IKE] and the
additional groups defined since [IANA-IKE]. This document assumes
that the reader is familiar with the IKE protocol and the concept of
Oakley Groups, as defined in RFC 2409 [IKE].
RFC 2409 [IKE] defines five standard Oakley Groups: three modular
exponentiation groups and two elliptic curve groups over GF[2^N].
One modular exponentiation group (768 bits - Oakley Group 1) is
mandatory for all implementations to support, while the other four
are optional. Nineteen additional groups subsequently have been
defined and assigned values by IANA. All of these additional groups
are optional.
The purpose of this document is to expand the options available to
implementers of elliptic curve groups by adding three ECP groups
(elliptic curve groups modulo a prime). The reasons for adding such
groups include the following.
- The groups proposed afford efficiency advantages in software
applications since the underlying arithmetic is integer arithmetic
modulo a prime rather than binary field arithmetic. (Additional
computational advantages for these groups are presented in [GMN].)
- The groups proposed encourage alignment with other elliptic curve
standards. The proposed groups are among those standardized by
NIST, the Standards for Efficient Cryptography Group (SECG), ISO,
and ANSI. (See Section 5 for details.)
- The groups proposed are capable of providing security consistent
with the Advanced Encryption Standard [AES].
In summary, due to the performance advantages of elliptic curve
groups in IKE implementations and the need for further alignment with
other standards, this document defines three elliptic curve groups
based on modular arithmetic.
These groups were originally proposed in [RFC4753]. This document
changes the format of the shared key produced by a Diffie-Hellman
exchange using these groups. The shared key format used in this
specification appeared earlier as an erratum to RFC 4753 [Err9], but
some implementors of RFC 4753 were unaware of the erratum and did not
implement the correction. Implementations of RFC 4753 that
incorporate the correction are interoperable with implementations of
this specification. However, there is a potential for
interoperability problems between implementations of this
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specification and implementations of RFC 4753 that did not implement
the correction from the erratum. These problems could be difficult
to detect and analyze since both use the same code point but the
secret value (which is probably not available to the trouble desk) is
computed differently. Where peers are not interoperable, the
initiator will never receive a response and eventually times out.
Section 9 provides more details of the changes from [RFC4753]. This
document obsoletes RFC 4753 and addresses the erratum.
2. Requirements Terminology
The key words "MUST" and "SHOULD" that appear in this document are to
be interpreted as described in [RFC2119].
3. Additional ECC Groups
The notation adopted in RFC 2409 [IKE] is used below to describe the
groups proposed.
3.1. 256-Bit Random ECP Group
IKE and IKEv2 implementations SHOULD support an ECP group with the
following characteristics. The curve is based on the integers modulo
the generalized Mersenne prime p given by:
p = 2^(256)-2^(224)+2^(192)+2^(96)-1
The equation for the elliptic curve is:
y^2 = x^3 - 3 x + b
Field Size:
256
Group Prime/Irreducible Polynomial:
FFFFFFFF 00000001 00000000 00000000 00000000 FFFFFFFF FFFFFFFF FFFFFFFF
Group Curve b:
5AC635D8 AA3A93E7 B3EBBD55 769886BC 651D06B0 CC53B0F6 3BCE3C3E 27D2604B
Group Order:
FFFFFFFF 00000000 FFFFFFFF FFFFFFFF BCE6FAAD A7179E84 F3B9CAC2 FC632551
The group was chosen verifiably at random using SHA-1 as specified
in [IEEE-1363] from the seed:
C49D3608 86E70493 6A6678E1 139D26B7 819F7E90
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The generator for this group is given by g=(gx,gy) where:
gx:
6B17D1F2 E12C4247 F8BCE6E5 63A440F2 77037D81 2DEB33A0 F4A13945 D898C296
gy:
4FE342E2 FE1A7F9B 8EE7EB4A 7C0F9E16 2BCE3357 6B315ECE CBB64068 37BF51F5
3.2. 384-Bit Random ECP Group
IKE and IKEv2 implementations SHOULD support an ECP group with the
following characteristics. The curve is based on the integers modulo
the generalized Mersenne prime p given by:
p = 2^(384)-2^(128)-2^(96)+2^(32)-1
The equation for the elliptic curve is:
y^2 = x^3 - 3 x + b
Field Size:
384
Group Prime/Irreducible Polynomial:
FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFE
FFFFFFFF 00000000 00000000 FFFFFFFF
Group Curve b:
B3312FA7 E23EE7E4 988E056B E3F82D19 181D9C6E FE814112 0314088F 5013875A
C656398D 8A2ED19D 2A85C8ED D3EC2AEF
Group Order:
FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF C7634D81 F4372DDF
581A0DB2 48B0A77A ECEC196A CCC52973
The group was chosen verifiably at random using SHA-1 as specified
in [IEEE-1363] from the seed:
A335926A A319A27A 1D00896A 6773A482 7ACDAC73
The generator for this group is given by g=(gx,gy) where:
gx:
AA87CA22 BE8B0537 8EB1C71E F320AD74 6E1D3B62 8BA79B98 59F741E0 82542A38
5502F25D BF55296C 3A545E38 72760AB7
gy:
3617DE4A 96262C6F 5D9E98BF 9292DC29 F8F41DBD 289A147C E9DA3113 B5F0B8C0
0A60B1CE 1D7E819D 7A431D7C 90EA0E5F
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3.3. 521-Bit Random ECP Group
IKE and IKEv2 implementations SHOULD support an ECP group with the
following characteristics. The curve is based on the integers modulo
the Mersenne prime p given by:
p = 2^(521)-1
The equation for the elliptic curve is:
y^2 = x^3 - 3 x + b
Field Size:
521
Group Prime/Irreducible Polynomial:
01FFFFFF FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF
FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF
FFFF
Group Curve b:
0051953E B9618E1C 9A1F929A 21A0B685 40EEA2DA 725B99B3 15F3B8B4 89918EF1
09E15619 3951EC7E 937B1652 C0BD3BB1 BF073573 DF883D2C 34F1EF45 1FD46B50
3F00
Group Order:
01FFFFFF FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF
FFFA5186 8783BF2F 966B7FCC 0148F709 A5D03BB5 C9B8899C 47AEBB6F B71E9138
6409
The group was chosen verifiably at random using SHA-1 as specified
in [IEEE-1363] from the seed:
D09E8800 291CB853 96CC6717 393284AA A0DA64BA
The generator for this group is given by g=(gx,gy) where:
gx:
00C6858E 06B70404 E9CD9E3E CB662395 B4429C64 8139053F B521F828 AF606B4D
3DBAA14B 5E77EFE7 5928FE1D C127A2FF A8DE3348 B3C1856A 429BF97E 7E31C2E5
BD66
gy:
01183929 6A789A3B C0045C8A 5FB42C7D 1BD998F5 4449579B 446817AF BD17273E
662C97EE 72995EF4 2640C550 B9013FAD 0761353C 7086A272 C24088BE 94769FD1
6650
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4. Security Considerations
Since this document proposes groups for use within IKE and IKEv2,
many of the security considerations contained within [IKE] and
[IKEv2] apply here as well.
The groups proposed in this document correspond to the symmetric key
sizes 128 bits, 192 bits, and 256 bits. This allows the IKE key
exchange to offer security comparable with the AES algorithms [AES].
5. Alignment with Other Standards
The following table summarizes the appearance of these three elliptic
curve groups in other standards.
256-Bit 384-Bit 521-Bit
Random Random Random
Standard ECP Group ECP Group ECP Group
----------- ------------ ------------ ------------
NIST [DSS] P-256 P-384 P-521
ISO/IEC [ISO-15946-1] P-256
ISO/IEC [ISO-18031] P-256 P-384 P-521
ANSI [X9.62-1998] Sect. J.5.3,
Example 1
ANSI [X9.62-2005] Sect. L.6.4.3 Sect. L.6.5.2 Sect. L.6.6.2
ANSI [X9.63] Sect. J.5.4, Sect. J.5.5 Sect. J.5.6
Example 2
SECG [SEC2] secp256r1 secp384r1 secp521r1
See also [NIST], [ISO-14888-3], [ISO-15946-2], [ISO-15946-3], and
[ISO-15946-4].
6. IANA Considerations
IANA has updated its registries of Diffie-Hellman groups for IKE in
[IANA-IKE] and for IKEv2 in [IANA-IKEv2] to include the groups
defined above.
In [IANA-IKE], the groups appear as entries in the list of Diffie-
Hellman groups given by Group Description (attribute class 4).
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The descriptions are "256-bit random ECP group", "384-bit random ECP
group", and "521-bit random ECP group". In each case, the group type
(attribute class 5) has the value 2 (ECP, elliptic curve group over
GF[P]).
In [IANA-IKEv2], the groups appear as entries in the list of IKEv2
transform type values for Transform Type 4 (Diffie-Hellman groups).
These entries in both [IANA-IKE] and [IANA-IKEv2] have been updated.
The update consisted of changing the reference from [RFC4753] to this
document.
7. ECP Key Exchange Data Formats
In an ECP key exchange, the Diffie-Hellman public value passed in a
KE payload consists of two components, x and y, corresponding to the
coordinates of an elliptic curve point. Each component MUST have bit
length as given in the following table.
Diffie-Hellman group component bit length
------------------------ --------------------
256-bit Random ECP Group 256
384-bit Random ECP Group 384
521-bit Random ECP Group 528
This length is enforced, if necessary, by prepending the value with
zeros.
The Diffie-Hellman public value is obtained by concatenating the x
and y values.
The Diffie-Hellman shared secret value consists of the x value of the
Diffie-Hellman common value.
These formats should be regarded as specific to ECP curves and may
not be applicable to EC2N (elliptic curve group over GF[2^N]) curves.
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8. Test Vectors
The following are examples of the IKEv2 key exchange payload for each
of the three groups specified in this document.
We denote by g^n the scalar multiple of the point g by the integer n;
it is another point on the curve. In the literature, the scalar
multiple is typically denoted ng; the notation g^n is used in order
to conform to the notation used in [IKE] and [IKEv2].
8.1. 256-Bit Random ECP Group
IANA assigned the ID value 19 to this Diffie-Hellman group.
We suppose that the initiator's Diffie-Hellman private key is:
i:
C88F01F5 10D9AC3F 70A292DA A2316DE5 44E9AAB8 AFE84049 C62A9C57 862D1433
Then the public key is given by g^i=(gix,giy) where:
gix:
DAD0B653 94221CF9 B051E1FE CA5787D0 98DFE637 FC90B9EF 945D0C37 72581180
giy:
5271A046 1CDB8252 D61F1C45 6FA3E59A B1F45B33 ACCF5F58 389E0577 B8990BB3
The KEi payload is as follows.
00000048 00130000 DAD0B653 94221CF9 B051E1FE CA5787D0 98DFE637 FC90B9EF
945D0C37 72581180 5271A046 1CDB8252 D61F1C45 6FA3E59A B1F45B33 ACCF5F58
389E0577 B8990BB3
We suppose that the response Diffie-Hellman private key is:
r:
C6EF9C5D 78AE012A 011164AC B397CE20 88685D8F 06BF9BE0 B283AB46 476BEE53
Then the public key is given by g^r=(grx,gry) where:
grx:
D12DFB52 89C8D4F8 1208B702 70398C34 2296970A 0BCCB74C 736FC755 4494BF63
gry:
56FBF3CA 366CC23E 8157854C 13C58D6A AC23F046 ADA30F83 53E74F33 039872AB
The KEr payload is as follows.
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00000048 00130000 D12DFB52 89C8D4F8 1208B702 70398C34 2296970A 0BCCB74C
736FC755 4494BF63 56FBF3CA 366CC23E 8157854C 13C58D6A AC23F046 ADA30F83
53E74F33 039872AB
The Diffie-Hellman common value (girx,giry) is:
girx:
D6840F6B 42F6EDAF D13116E0 E1256520 2FEF8E9E CE7DCE03 812464D0 4B9442DE
giry:
522BDE0A F0D8585B 8DEF9C18 3B5AE38F 50235206 A8674ECB 5D98EDB2 0EB153A2
The Diffie-Hellman shared secret value is girx.
8.2. 384-Bit Random ECP Group
IANA assigned the ID value 20 to this Diffie-Hellman group.
We suppose that the initiator's Diffie-Hellman private key is:
i:
099F3C70 34D4A2C6 99884D73 A375A67F 7624EF7C 6B3C0F16 0647B674 14DCE655
E35B5380 41E649EE 3FAEF896 783AB194
Then the public key is given by g^i=(gix,giy) where:
gix:
667842D7 D180AC2C DE6F74F3 7551F557 55C7645C 20EF73E3 1634FE72 B4C55EE6
DE3AC808 ACB4BDB4 C88732AE E95F41AA
giy:
9482ED1F C0EEB9CA FC498462 5CCFC23F 65032149 E0E144AD A0241815 35A0F38E
EB9FCFF3 C2C947DA E69B4C63 4573A81C
The KEi payload is as follows.
00000068 00140000 667842D7 D180AC2C DE6F74F3 7551F557 55C7645C 20EF73E3
1634FE72 B4C55EE6 DE3AC808 ACB4BDB4 C88732AE E95F41AA 9482ED1F C0EEB9CA
FC498462 5CCFC23F 65032149 E0E144AD A0241815 35A0F38E EB9FCFF3 C2C947DA
E69B4C63 4573A81C
We suppose that the response Diffie-Hellman private key is:
r:
41CB0779 B4BDB85D 47846725 FBEC3C94 30FAB46C C8DC5060 855CC9BD A0AA2942
E0308312 916B8ED2 960E4BD5 5A7448FC
Then the public key is given by g^r=(grx,gry) where:
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grx:
E558DBEF 53EECDE3 D3FCCFC1 AEA08A89 A987475D 12FD950D 83CFA417 32BC509D
0D1AC43A 0336DEF9 6FDA41D0 774A3571
gry:
DCFBEC7A ACF31964 72169E83 8430367F 66EEBE3C 6E70C416 DD5F0C68 759DD1FF
F83FA401 42209DFF 5EAAD96D B9E6386C
The KEr payload is as follows.
00000068 00140000 E558DBEF 53EECDE3 D3FCCFC1 AEA08A89 A987475D 12FD950D
83CFA417 32BC509D 0D1AC43A 0336DEF9 6FDA41D0 774A3571 DCFBEC7A ACF31964
72169E83 8430367F 66EEBE3C 6E70C416 DD5F0C68 759DD1FF F83FA401 42209DFF
5EAAD96D B9E6386C
The Diffie-Hellman common value (girx,giry) is:
girx:
11187331 C279962D 93D60424 3FD592CB 9D0A926F 422E4718 7521287E 7156C5C4
D6031355 69B9E9D0 9CF5D4A2 70F59746
giry:
A2A9F38E F5CAFBE2 347CF7EC 24BDD5E6 24BC93BF A82771F4 0D1B65D0 6256A852
C983135D 4669F879 2F2C1D55 718AFBB4
The Diffie-Hellman shared secret value is girx.
8.3. 521-Bit Random ECP Group
IANA assigned the ID value 21 to this Diffie-Hellman group.
We suppose that the initiator's Diffie-Hellman private key is:
i:
0037ADE9 319A89F4 DABDB3EF 411AACCC A5123C61 ACAB57B5 393DCE47 608172A0
95AA85A3 0FE1C295 2C6771D9 37BA9777 F5957B26 39BAB072 462F68C2 7A57382D
4A52
Then the public key is given by g^i=(gix,giy) where:
gix:
0015417E 84DBF28C 0AD3C278 713349DC 7DF153C8 97A1891B D98BAB43 57C9ECBE
E1E3BF42 E00B8E38 0AEAE57C 2D107564 94188594 2AF5A7F4 601723C4 195D176C
ED3E
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giy:
017CAE20 B6641D2E EB695786 D8C94614 6239D099 E18E1D5A 514C739D 7CB4A10A
D8A78801 5AC405D7 799DC75E 7B7D5B6C F2261A6A 7F150743 8BF01BEB 6CA3926F
9582
The KEi payload is as follows.
0000008C 00150000 0015417E 84DBF28C 0AD3C278 713349DC 7DF153C8 97A1891B
D98BAB43 57C9ECBE E1E3BF42 E00B8E38 0AEAE57C 2D107564 94188594 2AF5A7F4
601723C4 195D176C ED3E017C AE20B664 1D2EEB69 5786D8C9 46146239 D099E18E
1D5A514C 739D7CB4 A10AD8A7 88015AC4 05D7799D C75E7B7D 5B6CF226 1A6A7F15
07438BF0 1BEB6CA3 926F9582
We suppose that the response Diffie-Hellman private key is:
r:
0145BA99 A847AF43 793FDD0E 872E7CDF A16BE30F DC780F97 BCCC3F07 8380201E
9C677D60 0B343757 A3BDBF2A 3163E4C2 F869CCA7 458AA4A4 EFFC311F 5CB15168
5EB9
Then the public key is given by g^r=(grx,gry) where:
grx:
00D0B397 5AC4B799 F5BEA16D 5E13E9AF 971D5E9B 984C9F39 728B5E57 39735A21
9B97C356 436ADC6E 95BB0352 F6BE64A6 C2912D4E F2D0433C ED2B6171 640012D9
460F
gry:
015C6822 6383956E 3BD066E7 97B623C2 7CE0EAC2 F551A10C 2C724D98 52077B87
220B6536 C5C408A1 D2AEBB8E 86D678AE 49CB5709 1F473229 6579AB44 FCD17F0F
C56A
The KEr payload is as follows.
0000008c 00150000 00D0B397 5AC4B799 F5BEA16D 5E13E9AF 971D5E9B 984C9F39
728B5E57 39735A21 9B97C356 436ADC6E 95BB0352 F6BE64A6 C2912D4E F2D0433C
ED2B6171 640012D9 460F015C 68226383 956E3BD0 66E797B6 23C27CE0 EAC2F551
A10C2C72 4D985207 7B87220B 6536C5C4 08A1D2AE BB8E86D6 78AE49CB 57091F47
32296579 AB44FCD1 7F0FC56A
The Diffie-Hellman common value (girx,giry) is:
girx:
01144C7D 79AE6956 BC8EDB8E 7C787C45 21CB086F A64407F9 7894E5E6 B2D79B04
D1427E73 CA4BAA24 0A347868 59810C06 B3C715A3 A8CC3151 F2BEE417 996D19F3
DDEA
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giry:
01B901E6 B17DB294 7AC017D8 53EF1C16 74E5CFE5 9CDA18D0 78E05D1B 5242ADAA
9FFC3C63 EA05EDB1 E13CE5B3 A8E50C3E B622E8DA 1B38E0BD D1F88569 D6C99BAF
FA43
The Diffie-Hellman shared secret value is girx.
9. Changes from RFC 4753
Section 7 (ECP Key Exchange Data Formats) of [RFC4753] states that
The Diffie-Hellman public value is obtained by concatenating the x
and y values.
The format of the Diffie-Hellman shared secret value is the same
as that of the Diffie-Hellman public value.
This document replaces the second of these two paragraphs with the
following:
The Diffie-Hellman shared secret value consists of the x value of
the Diffie-Hellman common value.
This change aligns the ECP key exchange format with that used in
other standards.
This change appeared earlier as an erratum to RFC 4753 [Err9]. This
document obsoletes RFC 4753 and addresses the erratum.
Section 8 (Test Vectors) of [RFC4753] provides three examples of
Diffie-Hellman key agreement using the ECP groups. This document
changes the last paragraph of each subsection of Section 8 to reflect
the new format.
10. References
10.1. Normative References
[IANA-IKE] Internet Assigned Numbers Authority, "Internet Key
Exchange (IKE) Attributes", .
[IANA-IKEv2] Internet Assigned Numbers Authority, "Internet Key
Exchange Version 2 (IKEv2) Parameters",
.
[IKE] Harkins, D. and D. Carrel, "The Internet Key Exchange
(IKE)", RFC 2409, November 1998.
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[IKEv2] Kaufman, C., Ed., "Internet Key Exchange (IKEv2)
Protocol", RFC 4306, December 2005.
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119, March 1997.
[RFC4753] Fu, D. and J. Solinas, "ECP Groups For IKE and IKEv2",
RFC 4753, January 2007.
10.2. Informative References
[AES] U.S. Department of Commerce/National Institute of
Standards and Technology, Advanced Encryption Standard
(AES), FIPS PUB 197, November 2001,
.
[DSS] U.S. Department of Commerce/National Institute of
Standards and Technology, Digital Signature Standard
(DSS), FIPS PUB 186-2, January 2000.
.
[Err9] RFC Errata, Errata ID 9, RFC 4753,
.
[GMN] J. Solinas, Generalized Mersenne Numbers,
Combinatorics and Optimization Research Report 99-39,
1999, .
[IEEE-1363] Institute of Electrical and Electronics Engineers.
IEEE 1363-2000, Standard for Public Key Cryptography,
.
[ISO-14888-3] International Organization for Standardization and
International Electrotechnical Commission, ISO/IEC
14888-3:2006, Information Technology: Security
Techniques: Digital Signatures with Appendix: Part 3
- Discrete Logarithm Based Mechanisms.
[ISO-15946-1] International Organization for Standardization and
International Electrotechnical Commission, ISO/IEC
15946-1: 2002-12-01, Information Technology: Security
Techniques: Cryptographic Techniques based on Elliptic
Curves: Part 1 - General.
Fu & Solinas Informational [Page 14]
RFC 5903 ECP Groups for IKE and IKEv2 June 2010
[ISO-15946-2] International Organization for Standardization and
International Electrotechnical Commission, ISO/IEC
15946-2: 2002-12-01, Information Technology: Security
Techniques: Cryptographic Techniques based on Elliptic
Curves: Part 2 - Digital Signatures.
[ISO-15946-3] International Organization for Standardization and
International Electrotechnical Commission, ISO/IEC
15946-3: 2002-12-01, Information Technology: Security
Techniques: Cryptographic Techniques based on Elliptic
Curves: Part 3 - Key Establishment.
[ISO-15946-4] International Organization for Standardization and
International Electrotechnical Commission, ISO/IEC
15946-4: 2004-10-01, Information Technology: Security
Techniques: Cryptographic Techniques based on Elliptic
Curves: Part 4 - Digital Signatures giving Message
Recovery.
[ISO-18031] International Organization for Standardization and
International Electrotechnical Commission, ISO/IEC
18031:2005, Information Technology: Security
Techniques: Random Bit Generation.
[NIST] U.S. Department of Commerce/National Institute of
Standards and Technology. Recommendation for Pair-
Wise Key Establishment Schemes Using Discrete
Logarithm Cryptography, NIST Special Publication
800-56A, March 2006,
.
[SEC2] Standards for Efficient Cryptography Group. SEC 2 -
Recommended Elliptic Curve Domain Parameters, v. 1.0,
2000, .
[X9.62-1998] American National Standards Institute, X9.62-1998:
Public Key Cryptography for the Financial Services
Industry: The Elliptic Curve Digital Signature
Algorithm. January 1999.
[X9.62-2005] American National Standards Institute, X9.62:2005:
Public Key Cryptography for the Financial Services
Industry: The Elliptic Curve Digital Signature
Algorithm (ECDSA).
Fu & Solinas Informational [Page 15]
RFC 5903 ECP Groups for IKE and IKEv2 June 2010
[X9.63] American National Standards Institute. X9.63-2001,
Public Key Cryptography for the Financial Services
Industry: Key Agreement and Key Transport using
Elliptic Curve Cryptography. November 2001.
Authors' Addresses
David E. Fu
National Information Assurance Research Laboratory
National Security Agency
EMail: defu@orion.ncsc.mil
Jerome A. Solinas
National Information Assurance Research Laboratory
National Security Agency
EMail: jasolin@orion.ncsc.mil
Fu & Solinas Informational [Page 16]