> Can a natural number be *nontrivially* [palindromic](https://en.wikipedia.org/wiki/Palindromic_number) in **more than** $3$  consecutive number bases? 
> 
> *Nontrivially* means that I'm not counting one-digit palindromes.

Was asked on [MSE](https://math.stackexchange.com/questions/2234587/can-a-number-be-palindrome-in-4-consecutive-number-bases) - but wasn't solved and went inactive, even after a [bounty](https://math.stackexchange.com/help/bounty).



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<br>

$$\text{Looking at consecutive palindromes in three bases}$$

I believe it can be proved that a solution for $4$ or more consecutive bases does not exist (if this is the case), if all patterns for $3$ consecutive bases are found, since at that point, it would be possible to show if the patters will or never will extend to a fourth consecutive base. 

(*Like it was [shown](https://math.stackexchange.com/q/2244067) on MSE for the 3 digit pattern*) - This still does not exclude the 3 digit palindromes, since it is not proven if this is the only pattern. See more under $d=1$ below.

> $(0)$ Even length palindromes ($2p$ digits, $p\in\mathbb N$) seem to
> not form consecutive palindromes in three or more bases - still don't
> know how to prove this observation.
> 
> Following that, then we choose to observe odd digit length palindromes
> of $2d+1$ digits, $d\in\mathbb N$, which are palindromic in $3$ consecutive number bases $b\in\mathbb N \ge 2$, and we have so far:

<br>
$$\text{ 3 digit examples } (d=1)$$

Pick ($n=2k+3, k\in\mathbb N$), then all examples for this case are of form: ? 

$$\frac{1}{2}(n^3 + 6n^2 + 14n + 11)$$

And palindromic in bases $n+1, n+2, n+3$; Except number $300 = 606_7 = 454_8 = 363_9$

> $(1)$ How to show (prove) that all 3 digit examples other than $300$ are in
> this pattern?  <br> 
> 
> (No new exceptions or patterns exist for [$b\lt2333$](), so far.
> [Verified here](https://drive.google.com/open?id=19U-fsbBUsvrYw5MQpzRVVDeXrDlz6NEF) using [python code](https://drive.google.com/open?id=1gPLJZwXWT-OYZC07amwd1qmshPa9w9De))


<br>
$$\text{ 5 digit examples } (d=2)$$

Pick ($n=4k+40, k\in\mathbb N$), then all examples for this case are of form:

$$\frac{1}{4}(3n^5 + 30n^4 + 125n^3 + 270n^2 + 307n + 148)$$

And palindromic in bases $n+1, n+2, n+3$; No Exceptions found.

> $(2)$ How to show (prove) that all 5 digit examples are in
> this pattern?  <br> 
> 
> (No exceptions or new patterns exist for [$b\le333$](), so far.
> [Verified here](https://drive.google.com/open?id=140sHBRImwLRWJxg00LelVyJLYuFGBN6z) using [python code](https://drive.google.com/open?id=1gPLJZwXWT-OYZC07amwd1qmshPa9w9De))

<br>
$$\text{ 7 digit examples } (d=3)$$

**Update:** Based on computed examples and observations so far, multiple patterns and exceptions seem to exist for this case. First pattern that occurs:

Pick ($n=2k+79, k\in\mathbb N\cup \{-3,-2,-1\}$), then there are infinitely many examples of form:

$$\frac{1}{2}(n^7+14n^6+88n^5 + 320n^4 + 718n^3 + 980n^2 + 748n + 247)$$

And are palindromic in number bases $n+1, n+2, n+3$.

Numbers that seem to form the second pattern: (And are palindromic in $(b), (b+1), (b+2)$)

    326217315210 (56), 
    657158314249 (62), 
    2226313335987 (74), 
    3815123088334 (80), 
    6290902501325 (86), 
    10032985497864 (92), 
    15540762075415 (98), 
    23460181868882 (104), 
    ... (106), etc.


Numbers that seem to form the third pattern: (And are palindromic in $(b), (b+1), (b+2)$)

    19987816 (13), 
    19683596522 (37), 
    133256051308 (49), 
    597702412638 (61), 
    2055729074336 (73), 
    5872897399570 (85), 
    14629218708372 (97),
    ... (109), etc.

Numbers that seem to be exceptions, and the only exceptions (not belonging to any patterns):

    9 3360633 
    15 43443858 
    22 532083314 
    26 1778140759 
    28 2721194733 
    28 11325719295 
    36 47622367425 
    40 97638433343 
    42 224678540182 
    43 265282702996 
    48 561091062285 
    68 1242101453540 
   
These are palindromic in column given base $b$ and bases $b+1,b+2$.

> (3) I believe the second and third patterns belong to a similar
> polynomial formula as the first pattern. I will find and post them,
> but first I need to compute more terms. I also believe no more
> exceptions than these listed, exist. These findings of course, also
> need to be proven.
> 
> (Exceptions and patterns verified for all [$b\lt110$](), so far.
> [Computed here](https://drive.google.com/open?id=1gqUXWMdOUcvDA8ayNoGmtdkJymPyjeoO) using [python code](https://drive.google.com/open?id=1gPLJZwXWT-OYZC07amwd1qmshPa9w9De))

<br>
$$\text{ 9 digit examples } (d=4)$$

No examples have been found so far. I've checked number bases $b\lt50$ so far, [here](https://drive.google.com/open?id=1uiCmF6afB3Jeq-72iYCcch1174xrovUd).

<br>
$$\text{ 11 or more digit examples } (d\ge5)$$

Haven't searched for examples yet, as $d=4$ is already taking a long time per number base. 

<br>
<br>

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Some of these examples and patterns are also mentioned in an [OEIS sequence](http://oeis.org/A279093). <br>(Should I update it with my patterns for 7 digit examples?; as 3 and 5 digit ones are mentioned)

*I will keep updating the post as new examples are computed.*

> Can the python code I'm using be more optimized? (Is there a faster way to compute this?)
> 
> How can one find these polynomial pattern expressions algebraically? Is there anything out there that can actually attack this problem?