(2 intermediate revisions by one other user not shown) | |||
Line 3: | Line 3: | ||
GF(p^n) are the only fields we need to worry about, so we just need to find the smallest field of this form that has exactly 6 subfields. Since GF(p^n) has exactly one subfield per divisor of n, we are looking at the smallest field GF(p^n) such that n has exactly 6 divisors. Just enumerate the divisors of n's and you should find the smallest n that has 6 divisors. See Theorem 22.3. -Josh | GF(p^n) are the only fields we need to worry about, so we just need to find the smallest field of this form that has exactly 6 subfields. Since GF(p^n) has exactly one subfield per divisor of n, we are looking at the smallest field GF(p^n) such that n has exactly 6 divisors. Just enumerate the divisors of n's and you should find the smallest n that has 6 divisors. See Theorem 22.3. -Josh | ||
− | = | + | So what did you get as an answer? if 1 and 12 count as divisors then I got n=12. |
− | + | ||
+ | Do 1 and 12 count? |
Latest revision as of 05:45, 11 December 2008
Do any of you have any helpful hints? That would be lovely.
GF(p^n) are the only fields we need to worry about, so we just need to find the smallest field of this form that has exactly 6 subfields. Since GF(p^n) has exactly one subfield per divisor of n, we are looking at the smallest field GF(p^n) such that n has exactly 6 divisors. Just enumerate the divisors of n's and you should find the smallest n that has 6 divisors. See Theorem 22.3. -Josh
So what did you get as an answer? if 1 and 12 count as divisors then I got n=12.
Do 1 and 12 count?