MinT - Best Known (115−101, 115, s)-Nets in Base 5

Best Known (115−101, 115, s)-Nets in Base 5

(115−101, 115, 35)-Net over F₅ — Constructive and digital

Digital (14, 115, 35)-net over F₅, using

net from sequence [i] based on digital (14, 34)-sequence over F₅, using
- Niederreiterâ€“Xing sequence constructionÂ III based on the algebraic function field F/F₅ with g(F)Â =Â 11, N(F)Â =Â 32, and 3 places with degree 2 [i] based on function field F/F₅ with g(F) = 11 and N(F) ≥ 32, using an explicitly constructive algebraic function field [i]

(115−101, 115, 39)-Net over F₅ — Digital

Digital (14, 115, 39)-net over F₅, using

net from sequence [i] based on digital (14, 38)-sequence over F₅, using
- Niederreiterâ€“Xing sequence constructionÂ II/III [i] based on function field F/F₅ with g(F) = 14 and N(F) ≥ 39, using
  - algebraic function fields over â„¤₅ by Niederreiter/Xing [i]

(115−101, 115, 77)-Net over F₅ — Upper bound on s (digital)

There is no digital (14, 115, 78)-net over F₅, because

41 times m-reduction [i] would yield digital (14, 74, 78)-net over F₅, but
- extracting embedded orthogonal array [i] would yield linear OA(5⁷⁴, 78, F₅, 60) (dual of [78, 4, 61]-code), but
  - residual code [i] would yield linear OA(5¹⁴, 17, F₅, 12) (dual of [17, 3, 13]-code), but
    - a result by Hill [i]

(115−101, 115, 78)-Net in Base 5 — Upper bound on s

There is no (14, 115, 79)-net in base 5, because

45 times m-reduction [i] would yield (14, 70, 79)-net in base 5, but
- extracting embedded orthogonal array [i] would yield OA(5⁷⁰, 79, S₅, 56), but
  - the linear programming bound shows that MÂ â‰¥ 5 918642 718939 423619 239903 473498 998209 834098 815917 968750 / 578151 > 5⁷⁰ [i]