# Is there a way to programmatically find a pattern from just three elements in a given sequence?

## Some Context

I found myself confronting a mathematical meme on Facebook (try not to laugh):

Clearly, this is a simple problem which can be solved by first looking at each number as if they're elements in a 2-dimensional grid, then using subtraction to find changes. Intuitively, I'm sure everyone would start from the top of the imaginary grid in this case, then analyze the problem first evaluating the rows as linear sets.

Change would be the difference between two elements. If there are only two elements, and you had to predict what would come right after those two elements, your best guess would be to add the difference between the numbers you started with to the leftmost element in the sequence (I'm assuming).

## The Questions

The problem I'm having trouble wrapping my head around is the inferring process -- the whole process seems vague and far too innate for me to systematize. How did I come up with the answer? Was my brain doing a special operation? If so, what is the operation? Without looking at every row and column, only choosing one linear set, how am I finding a relationship between the three numbers? Is there a way to make an accurate guess of what the relationship between each element is? If not, is there a minimum number of elements that need to be present in order to make an adequate attempt at concluding a likely pattern?

I understand that computers are being forced to go through this process as they learn in unsupervised fashion, and I know that the field of artificial intelligence is relatively new and underdeveloped, so I'm not expecting absolute answers. I'm moreso asking for a good approach if finding a pattern from three elements of a linear set is possible. Perhaps, by asking this question, I'll gather relevent search queries of considerable specificity.

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then using subtraction to find changes. What subtraction? –  DarkCthulhu Apr 26 '13 at 12:05
I explained shortly after what subtraction you'd need. So you'd take an element prior to one element to find the step between the elements. That's what I meant. –  Mr_Spock Apr 26 '13 at 12:07
There's no subtraction involved. Each middle number is just the product of the numbers next to it. –  Antimony Apr 26 '13 at 12:12
The simplest thing is `x = 42`, always. There are an infinity of possible rules fitting the data, and infinitely many of them will produce 42 as next value. –  Daniel Fischer Apr 26 '13 at 12:19
Three elements is a bit short, but for longer sequences you might be able to write something that does some preprocessing, for example eliminating common factors, before querying OEIS. –  hammar Apr 26 '13 at 14:54

Basically, you're trying to fit numbers into the set of all equations with some number of variables, which is infinite and probably not countable (thus probably not too easy to iterate through). Though I'm sure there has been research on exactly the problem you're trying to solve, but I'll give my take.

While greatly problem dependent, I suspect what sometimes happens in the human brain is some sort of pattern recognition or matching. You see `5 30 6`, you're familiar with `5 * 6 = 30`, so your mind links those 2. Or the brain, when trying to link numbers, tries common operations like adding, subtracting, multiplying or dividing 2 of them and checking if that results in the 3rd.

For such simple problems with such small numbers you can (on a computer) just store all possibilities for `+`, `-`, `*` and `/` (and possibly others) and do a lookup, or just calculate all of those on the fly.

For more difficult problems I suspect the brain just runs through a bunch of possibilities of equations.

For a sequence `4,5,6,x`, you could try some of the below: (note that we're also using the positions of the number with it in an equation, so `1` with `4`, `2` with `5`, `3` with `6`)

``````4a + 5b = 5a + 6b, solve for a and b
4^a * 5^b = 5^a * 6^b, solve for a and b
a.b^(1+c)+d = 4, a.b^(2+c)+d = 5, a.b^(3+c)+d = 6, solve for a, b, c and d
You may want to split the above into a few simpler equations:
b^1 = 4
b^(1+c) = 4
a.b^1 = 4
a.b^1+d = 4
a.b^(1+c) = 4
etc.
``````

You'd (hopefully) get that `4a + 5b = 5a + 6b` would be the equation of choice here, with `b = 1` and `a = -1`.

Once you have the required parameters (`a` and `b`), you could just plug it into the equation to determine the next value.

Looking into Geometric and Arithmetic series may be of some help.

When not dealing with series, how to pick which numbers may be related? Well, just run across rows, columns, diagonals, neighbouring values and whatever else that is applicable or that you can think of.

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The common patterns are arithm./geom. progressions, Fibonacci, something like `a(n) = (n - n1)(n - n2)` (you can see this in 2, 6, 12, 20 succession) etc. So you can define an equations by yourself to check if the succession fits the pattern. For example, in the `a(n) = (n - n1)(n - n2)` case you can use first 2 numbers to find out n1 and n2 and then check the remaining numbers for validity.
It was stated by `Daniel Fischer` in the comments to the question, that any succession of numbers can fit infinite number of rules. By that means you can state that the next number for any succession will be 42.