Schoof's algorithm

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  1. The algorithm is an extension of Schoof's algorithm by Noam Elkies and A. O. L. Atkin to significantly improve its efficiency (under heuristic assumptions).[1]
  2. The Elkies-Atkin extension to Schoof's algorithm works by restricting the set of primes S = { l 1 , … , l s } {\displaystyle S=\{l_{1},\ldots ,l_{s}\}} considered to primes of a certain kind.[1]
  3. For Elkies primes, this allows one to compute the number of points on E {\displaystyle E} modulo l {\displaystyle l} more efficiently than in Schoof's algorithm.[1]
  4. This is an implementation of Schoof's algorithm for counting the points on elliptic curves over finite fields (Schoof, René.[2]
  5. René Schoof's algorithm for counting the points on an elliptic curve over a finite field is the foundation for the (asymptotically) fastest Schoof–Elkies–Atkin counting algorithm.[2]
  6. Schoof's algorithm uses arithmetic on elliptic curves, finite fields, rings of polynomials, and quotient rings.[2]
  7. Before Schoof's algorithm, approaches to counting points on elliptic curves such as the naive and baby-step giant-step algorithms were, for the most part, tedious and had an exponential running time.[3]
  8. In any case Schoof's algorithm is most frequently used in addressing the case since there are more efficient, so called adic algorithms for small characteristic fields.[3]
  9. Schoof's algorithm stores the values of in a variable for each prime considered.[3]
  10. Given that this computation needs to be carried out for each of the primes, the total complexity of Schoof's algorithm turns out to be .[3]
  11. Schoof's algorithm is an efficient algorithm to count points on elliptic curves over finite fields.[4]
  12. We define the curve, and compute the order, just to know which is the number we try to exhibit using Schoof's algorithm.[5]
  13. We also present an implementation of Schoof's algorithm as a collection of Mathematica functions.[6]
  14. Chapter 4 describes some methods for computing the elliptic curve group order, and includes an introduction to Schoof's algorithm.[7]
  15. We present the details of Schoof's algorithm in chapter 5.[7]
  16. I know Schoof's algorithm is mostly used over large prime fields.[8]
  17. Schoof's algorithm, first described by R. Schoof in 1985 , allows one to calculate the number of points on an elliptic curve over a finite field and is used mostly in elliptic curve cryptography .[9]
  18. mid-90s: lots of speed-ups, characteristic-2 algorithms note: basic Schoof algorithm also applicable for hyperelliptic curves; see Eric Schosts talk next week at ECC p.3 1.[10]
  19. In todays lecture, we study Schoof algorithm to compute the number of rational points of an elliptic curve E/Fq over a nite eld.[11]

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  • [{'LOWER': 'schoof'}, {'LOWER': "'s"}, {'LEMMA': 'algorithm'}]
  • [{'LOWER': 'schoof'}, {'LEMMA': 'algorithm'}]