How many fingers do the inhabitants of this planet have?

Question

Actual Puzzle

After crash-landing your spaceship on an uncharted planet, you run across the following drawing:

$\begin{matrix} ⊙ & × & × & ⊓ & ⊓ & ⊙ & & \\ ⊙ & ∿ & × & ⊓ & × & ⊳ & & \\\hline ∿ & ⊓ & ⊓ & ⊳ & ⊙ & × & × & \\ \end{matrix}$

How many fingers do the inhabitants of the planet have?

Sidenotes

• The above is produced with MathJaX. Starting with a copy of its source may ease the technical part of writing an answer.

• Provenance: I remember encountering a similar puzzle in a popular-science or riddle book (I don’t remember which). I wanted to pose it to somebody else, but could not find such a puzzle on the web. Thus I designed one on my own.

• There is some overlap with this puzzle, but other aspects are crucially different.

Answer 1

It seems likely that they have

Three 'fingers' on each of two 'hands' (or some other features providing six digits)

Reasoning:

Replacing the glyphs with our familiar digits: \begin{matrix}3&1&1&2&2&3&\\3&0&1&2&1&4&\\\hline0&2&2&4&3&1&1\end{matrix} Then rewriting it with our usual positional numbering system: \begin{matrix}&3&2&2&1&1&3\\&4&1&2&1&0&3\\\hline1&1&3&4&2&2&0\end{matrix} Results in a simple base-6 addition problem with solution.

Edit for detailed reasoning:

Working with the assumption that the glyphs represent distinct digits in a basic addition problem, we can first reverse the order of the glyphs to use our familiar system of writing numbers. \begin{matrix}&⊙&⊓&⊓&×&×&⊙\\&⊳&×&⊓&×&∿&⊙\\\hline×&×&⊙&⊳&⊓&⊓&∿\\\end{matrix} Then note that the $×$ must be $1$ as it is the carry value. \begin{matrix}&⊙&⊓&⊓&1&1&⊙\\&⊳&1&⊓&1&∿&⊙\\\hline1&1&⊙&⊳&⊓&⊓&∿\\\end{matrix} Now we see that $⊓$ must be $1+1=2$ because there cannot be a carry-over from $1+∿$ unless $⊓=0$ \begin{matrix}&⊙&2&2&1&1&⊙\\&⊳&1&2&1&∿&⊙\\\hline1&1&⊙&⊳&2&2&∿\\\end{matrix} We can then determine that $2+2=⊳\implies ⊳=4$ and $2+1=⊙\implies ⊙=3$ as there are no carries involved. \begin{matrix}&3&2&2&1&1&3\\&4&1&2&1&∿&3\\\hline1&1&3&4&2&2&∿\\\end{matrix} Finally $1+∿=2$ must include a carry with $∿=0$ \begin{matrix}&3&2&2&1&1&3\\&4&1&2&1&0&3\\\hline1&1&3&4&2&2&0\\\end{matrix} With $3_b+3_b=10_b$, we must be working in base $b=6$. Confirming that the end result is valid in base 6 verifies the solution.

Answer 2

I just want to point out that

the number of fingers could be completely unrelated to the number of mathematical digits they use. Furthemore, even if they are related, then they could either have 6 fingers on each hand or 6 fingers in total (3 on each hand, assuming there are two hands). So the most accurate answer is "we don't know for sure, but most likely 6 or 12 fingers in total".

Answer 3

Answer (spoiler, I was wrong):

I'd say they have 5 fingers on each hand.

Reasoning:

There are 5 distinct glyphs, ⊙, ×, ⊓, ∿, ⊳. If we wildly extrapolate from human counting methods, there would be one number, and therefore one glyph, for each finger on each hand. They could also have 10 fingers and the puzzle only uses 5 of the values.

The aliens could also do something weird, like order their digits from the middle to the outsides, alternating left and right. This could be a haiku with zero mathematical intent. Etc. But I assumed on looking at it that it was intended to be a basic addition problem with glyph substitution.

Getting the correct answer:

Cheating a bit, I looked at Daniel's answer. He decided to try solving in base 6. I'm not that smart, so I wrote a program to brute force everything to base 12 (anything higher takes too much time).

It assumes addition (multiplication would probably add a lot more digits to the product, subtraction and division couldn't add any unless one glyph is a negative sign or decimal point). It tests both forward (treating the leftmost digits as most significant) and reverse (treating leftmost digits as least significant). The minimum possible base is 5, since there are 5 glyphs.

The only valid answer is if we reverse the digits left-to-right, and use base 6. Precisely the answer Daniel gave in a much more clever manner. I suspect that if base 12 has no solutions, higher bases won't either, because of something related to carrying in the left column, but I don't think I can prove that mathematically.