Wikipedia:Reference desk/Archives/Mathematics/2008 October 19
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October 19
[edit]The number of arithmetic progressions possible
[edit]Hello. The question is: How many finite k-term Arithmetic Progressions's are possible in the set {1,2,3,...m}. Thanks--Shahab (talk) 05:05, 19 October 2008 (UTC)
- Well, assuming m >= k, the set will be non-empty, and less than mCk, but I can't see an obvious way to count them. -mattbuck (Talk) 05:58, 19 October 2008 (UTC)
- SAy that each of such arithmetic progressions is determined by its first term, and by the increment h. If h=1 there are m+k-1 of them, if this number is positive, because you can start with 1,..,m-k+1, and from m-k on there is no room left: so with h=1 they are (here denotes the positive part of ). Similarly you can count how many of them are there with h=2,3,.., and you end up with your answer in form of a sum over all natural , where however only finitely many terms are nonzero. Enjoy it! The next step could be: find an asymptotic for , say with , approximating the sum with an integral. (e.g. ~) --PMajer (talk) 08:02, 19 October 2008 (UTC)
- I think I have got it by your approach. h however also must be bounded: (k-1)h < m, so I guess the sum (m-hk+h)should be from 1 to . Thanks--Shahab (talk) 08:18, 19 October 2008 (UTC)
- Right, but that's automatically included writing , which is 0 for larger h --PMajer (talk) 08:46, 19 October 2008 (UTC)
- Pardon me, but can you explain how to find the asymptotic. I actually need to show that the number is at least . A closed form expression by your technique is . Now how can I show this quantity to be at least . Thanks a lot.--Shahab (talk) 13:47, 19 October 2008 (UTC)
- Right, but that's automatically included writing , which is 0 for larger h --PMajer (talk) 08:46, 19 October 2008 (UTC)
- I think I have got it by your approach. h however also must be bounded: (k-1)h < m, so I guess the sum (m-hk+h)should be from 1 to . Thanks--Shahab (talk) 08:18, 19 October 2008 (UTC)
- For bounds and asymptotics one possibility is: factor out from the sum of m-h(k-1) (for 0<h<m/(k-1), then look at the resulting sum as a Riemann sum of a suitable function. But since you have that nice closed formula, maybe you can factor out the term , then bound the floor terms in it from below and above using (taking into account the sign) and see what happens...--PMajer (talk) 15:08, 19 October 2008 (UTC)
- I presume you mean . That approach doesn't work. I get . This is short of what I need.--Shahab (talk) 15:17, 19 October 2008 (UTC)
- Yes sorry I meant with floor inside :)
Otherwise you can think your closed formula like a second degree polynomial computed in . We are in the half-line where has a definite sign so you can have bounds of the form . Can you obtain this way? But by the way first check your formula. Seems OK, but maybe you get a better form using the (equivalent) bounds for h in the sum: , so . --PMajer (talk) 15:31, 19 October 2008 (UTC)
- Isn't as would make whatever initial term a we choose? --Shahab (talk) 16:26, 19 October 2008 (UTC)
I just mean that the term in the sum corresponding to is 0.
Summarizing: your number N of arithmetic progressions is the value of computed
in a point (i.e. the integer one), between and .
Observe that has a maximum exactly at the midpoint between a and b. This gives you
, that is I guess , or something similar, in any case sharp bounds, in that may well fall in an endpoint or in the midpoint of the interval . In particular, the inequality cannot be always true, even if is true for large , e.g. for . It also means that a more precise approximation needs non-algebraic terms. I did not check everything so don't take it for sure. PMajer (talk) 17:45, 19 October 2008 (UTC)
Gourami, genetic mutation?
[edit]- Duplicate question removed - see Wikipedia:Reference_desk/Science#Genetic_mutation-_Double_tail_gourami. Gandalf61 (talk)
Countable metacompactness of the Sorgenfrey plane.
[edit]Does anyone know whether the conjecture that the Sorgenfrey plane is countably metacompact, is solved? It is not metacompact (I am pretty sure) but determining countable metacompactness is a lot less trivial. I would appreciate any references.
Thanks in advance.
Topology Expert (talk) 14:04, 19 October 2008 (UTC)
- According to the excellent table at the end of Counterexamples in Topology, it is countably metacompact. Algebraist 15:45, 19 October 2008 (UTC)
- Thanks very much for that reference, sounds good. I'm glad I looked at this question. Dmcq (talk) 21:34, 19 October 2008 (UTC)