Timeline for Special linear Diophantine system - is it solvable in general?
Current License: CC BY-SA 4.0
8 events
| when toggle format | what | by | license | comment | |
|---|---|---|---|---|---|
| Oct 28, 2019 at 23:28 | comment | added | Max Alekseyev | @Vepir: Yes, fixed now. Thanks! | |
| Oct 28, 2019 at 23:27 | history | edited | Max Alekseyev | CC BY-SA 4.0 |
typo corrected
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| Oct 28, 2019 at 21:15 | comment | added | Vepir | You say at the start $b,b+1$ but in the post you work with $b,b-1$? (Typo?) | |
| Oct 3, 2019 at 20:35 | comment | added | Vepir | I see you also extracted the $3$-palindromes from $d=7$ as well. That part of your answer then confirms (computationally proves) all the proposed solutions for $d=7$ 3-palindromes: last part of claim $(3^*)$ from $3$-palindrome system. (where we only consider "equally long" 3-palindromes, since it is not known if any of the finite 2-palindromes extend to a "not-equally-long" 3-palindrome or not.) | |
| Oct 3, 2019 at 20:06 | comment | added | Max Alekseyev | @Vepir: I've updated my answer with the $d=7$ results. | |
| Oct 3, 2019 at 20:05 | history | edited | Max Alekseyev | CC BY-SA 4.0 |
added 771 characters in body
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| Oct 3, 2019 at 16:39 | comment | added | Vepir | This looks very nice, I'll take a closer look and try to play with this once I find time. The $k_i$'s remind me of $o_i$'s, but $k_i$'s being more useful to work with now. (Mentioned $d=5$ typos in OP are corrected as of this comment, thank you for noticing.) | |
| Oct 2, 2019 at 13:27 | history | answered | Max Alekseyev | CC BY-SA 4.0 |