User talk:Franz Scheerer (Olbers)

Hello, Franz Scheerer (Olbers), and welcome to Wikipedia! Thank you for your contributions, especially what you did for Magnetic field. I hope you like the place and decide to stay. Here are a few links to pages you might find helpful:

• Introduction to Wikipedia
• The five pillars of Wikipedia
• How to edit a page and How to develop articles
• How to create your first article
• Simplified Manual of Style

Please remember to sign your messages on talk pages by typing four tildes (~~~~); this will automatically insert your username and the date. If you need help, check out Wikipedia:Questions, ask me on my talk page, or ask your question on this page and then place {{help me}} before the question. Again, welcome! RockMagnetist (talk) 17:31, 29 October 2013 (UTC)[reply]

Welcome to Wikipedia. We welcome and appreciate your contributions, including your edits to Magnetic field, but we cannot accept original research. Original research also encompasses combining published sources in a way to imply something that none of them explicitly say. Please be prepared to cite a reliable source for all of your contributions. Thank you. RockMagnetist (talk) 17:32, 29 October 2013 (UTC)[reply]

Your edits here, so far, might possibly be suitable for Wikibooks or Wikiversity; they are not suitable here, because there is no source outside of your edits for the material. The (3/2)^k analysis, as I said on the article talk page, might be suitable here if a reputable mathematician stated it. Unfortunately, some of your posts and websites clearly indicate that mathematician is not anyone named "Franz Scheerer". — Arthur Rubin (talk) 14:41, 8 January 2014 (UTC)[reply]

Good morning Arthur Rubin, I tried something new. If one start the some number s the numbers n alway can be written as

${\displaystyle n=a\cdot s+b}$

with a,b fractional numbers. If known which operations (3n+1)/2 or n/2 is performed the new a,b can be calculated as follows.

${\displaystyle a'=(3/2)a\,or\,(1/2)a}$

Finally a gets the value

${\displaystyle a_{final}=(3^{c}/2^{l})}$

and as well b

${\displaystyle b'=(3/2)b+1/2\,\,or\,(1/2)b}$

Now we can ask wether a cycle occurs

${\displaystyle a_{final}\,s+b_{final}=s}$

or

${\displaystyle s={\frac {b_{final}}{a_{final}-1}}}$

Using ${\displaystyle a_{final}=(3^{c}/2^{l})}$ we obtain

${\displaystyle s={\frac {2^{l}\cdot b_{final}}{2^{l}-3^{c}}}}$

If the first operation is (3n+1)/2 and the other (3n+1)/2 operations follow directly, we can derive

${\displaystyle b_{final}={\frac {3^{c}-2^{c}}{2^{l}}}}$

and final get

${\displaystyle s={\frac {3^{c}-2^{c}}{2^{l}-3^{c}}}}$

For c=1, l=2 we get s=1.

If the (3n+1)/2 don't follow directly on each other or we don't start with the minimum still

${\displaystyle s>={\frac {3^{c}-2^{c}}{2^{l}-3^{c}}}={\frac {1-2^{c}/3^{c}}{2^{l}/3^{c}-1}}={\frac {1-(2/3)^{c}}{2^{l-c}(2/3)^{c}-1}}}$.

A minimum is, starting with (n/2) divisions

${\displaystyle s<=2^{l-c}{\frac {3^{c}-2^{c}}{2^{l}-3^{c}}}=2^{l-c}{\frac {1-2^{c}/3^{c}}{2^{l}/3^{c}-1}}=2^{l-c}{\frac {1-(2/3)^{c}}{2^{l-c}(2/3)^{c}-1}}}$.

Franz Scheerer (Olbers) (talk) 21:40, 22 January 2014 (UTC)[reply]