Difference between revisions of "Secp256k1"

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[[File:Secp256k1.png|thumb |This is a graph of secp256k1's elliptic curve ''y<sup>2</sup> = x<sup>3</sup> + 7'' over the real numbers. Note that because secp256k1 is actually defined over the field Z<sub>p</sub>, its graph will look like random scattered points, not anything like this.]]
 
[[File:Secp256k1.png|thumb |This is a graph of secp256k1's elliptic curve ''y<sup>2</sup> = x<sup>3</sup> + 7'' over the real numbers. Note that because secp256k1 is actually defined over the field Z<sub>p</sub>, its graph will look like random scattered points, not anything like this.]]
  
'''secp256k1''' refers to the parameters of the elliptic curve used in Bitcoin's public-key cryptography, and is defined in ''Standards for Efficient Cryptography (SEC)'' (Certicom Research, http://www.secg.org/sec2-v2.pdf). Bitcoin SV uses secp256k1 with the [[Digital Signatures (ECDSA)|ECDSA]] algorithm.  
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'''secp256k1''' refers to the parameters of the elliptic curve used in Bitcoin's public-key cryptography, and is defined in ''Standards for Efficient Cryptography (SEC)'' (Certicom Research, [http://www.secg.org/sec2-v2.pdf]). Bitcoin SV uses secp256k1 with the [[Digital Signatures (ECDSA)|ECDSA]] algorithm.  
  
 
secp256k1 was almost never used before Bitcoin became popular, but it is now gaining in popularity due to its several advantageous properties. Most commonly-used curves have a random structure, but secp256k1 was constructed in a special non-random way which allows for especially efficient computation. As a result, it is often more than 30% faster than other curves if the implementation is sufficiently optimized. Also, unlike the popular NIST curves, secp256k1's constants were selected in a predictable way, which significantly reduces the possibility that the curve's creator inserted any sort of backdoor into the curve.
 
secp256k1 was almost never used before Bitcoin became popular, but it is now gaining in popularity due to its several advantageous properties. Most commonly-used curves have a random structure, but secp256k1 was constructed in a special non-random way which allows for especially efficient computation. As a result, it is often more than 30% faster than other curves if the implementation is sufficiently optimized. Also, unlike the popular NIST curves, secp256k1's constants were selected in a predictable way, which significantly reduces the possibility that the curve's creator inserted any sort of backdoor into the curve.

Revision as of 12:32, 13 December 2019

This is a graph of secp256k1's elliptic curve y2 = x3 + 7 over the real numbers. Note that because secp256k1 is actually defined over the field Zp, its graph will look like random scattered points, not anything like this.

secp256k1 refers to the parameters of the elliptic curve used in Bitcoin's public-key cryptography, and is defined in Standards for Efficient Cryptography (SEC) (Certicom Research, [1]). Bitcoin SV uses secp256k1 with the ECDSA algorithm.

secp256k1 was almost never used before Bitcoin became popular, but it is now gaining in popularity due to its several advantageous properties. Most commonly-used curves have a random structure, but secp256k1 was constructed in a special non-random way which allows for especially efficient computation. As a result, it is often more than 30% faster than other curves if the implementation is sufficiently optimized. Also, unlike the popular NIST curves, secp256k1's constants were selected in a predictable way, which significantly reduces the possibility that the curve's creator inserted any sort of backdoor into the curve.

Technical details

As excerpted from Standards:

The elliptic curve domain parameters over Fp associated with a Koblitz curve secp256k1 are specified by the sextuple T = (p,a,b,G,n,h) where the finite field Fp is defined by:

  • p = FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFE FFFFFC2F
  • = 2256 - 232 - 29 - 28 - 27 - 26 - 24 - 1

The curve E: y2 = x3+ax+b over Fp is defined by:

  • a = 00000000 00000000 00000000 00000000 00000000 00000000 00000000 00000000
  • b = 00000000 00000000 00000000 00000000 00000000 00000000 00000000 00000007

The base point G in compressed form is:

  • G = 02 79BE667E F9DCBBAC 55A06295 CE870B07 029BFCDB 2DCE28D9 59F2815B 16F81798

and in uncompressed form is:

  • G = 04 79BE667E F9DCBBAC 55A06295 CE870B07 029BFCDB 2DCE28D9 59F2815B 16F81798 483ADA77 26A3C465 5DA4FBFC 0E1108A8 FD17B448 A6855419 9C47D08F FB10D4B8

Finally the order n of G and the cofactor are:

  • n = FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFE BAAEDCE6 AF48A03B BFD25E8C D0364141
  • h = 01

Properties

  • secp256k1 has characteristic p, it is defined over the prime field ℤp. Some other curves in common use have characteristic 2, and are defined over a binary Galois field GF(2n), but secp256k1 is not one of them.
  • As the a constant is zero, the ax term in the curve equation is always zero, hence the curve equation becomes y2 = x3 + 7.

See also

  • [2] (libsecp256k1 implementation in Bitcoin SV)

es:Secp256k1