Give initial stabs at Arthur's suggestions
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@ -12,7 +12,7 @@ _"Pick a number"_, he said, _"And I'll teach you how to draw a pattern from it."
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The procedure was rather simple:
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1. Pick a number between 2 and 8 (inclusive).
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2. Start generating multiples of this number. If you picked 8,
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2. Start generating positive multiples of this number. If you picked 8,
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your multiples would be 8, 16, 24, and so on.
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3. If a multiple is more than one digit long, sum its digits. For instance, for 16, write 1+6=7.
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If the digits add up to a number that's still more than 1 digit long, add up the digits of _that_
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@ -37,7 +37,7 @@ characters (`"17"` becomes `["1", "7"]`), turning each of these character back i
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We may now encode the "drawing" logic. At any point, there's a "direction" we're going - which
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I'll denote by the Ruby symbols `:top`, `:bottom`, `:left`, and `:right`. Each step, we take
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the current `x`/`y` coordinates (our position on the grid), and shift them by `n` in a particular
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the current `x`,`y` coordinates (our position on the grid), and shift them by `n` in a particular
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direction `dir`. We also return the new direction alongside the new coordinates.
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{{< codelines "Ruby" "patterns/patterns.rb" 10 21 >}}
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@ -109,7 +109,7 @@ larger than \(k\).
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\end{aligned}
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{{< /latex >}}
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We only _really_ care about the remainder here, not the quotient, since it's the remainder
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We only really care about the remainder here, not the quotient, since it's the remainder
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that determines if something is divisible or not. From the form of the second equation, we can
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deduce that \\(b-r\\) is divisible by \\(a\\) (it's literally equal to \\(a\\) times \\(k\\),
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so it must be divisible). Thus, we can write:
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@ -138,6 +138,9 @@ Multiplying both sides by the same number (call it \\(n\\)) also works:
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\textbf{if}\ a \equiv b\ (\text{mod}\ k),\ \textbf{then}\ na \equiv nb\ (\text{mod}\ k).
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{{< /latex >}}
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To see why this works, try rewriting the equivalences back into statements of divisibility,
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then into actual equations (just like our very first \\(b-r=ka\\)).
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Ok, that's a lot of notation and other _stuff_. Let's talk specifics. Of particular interest
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is the number 10, since our number system is _base ten_ (the value of a digit is multiplied by 10
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for every place it moves to the left). The remainder of 10 when dividing by 3 is 1. Thus,
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@ -248,8 +251,16 @@ and since turning four times leaves us facing "up" again, we'll end up getting _
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From this, we can devise a simple condition to prevent spiraling -- the _length_ of the sequence before
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it repeats _cannot be a multiple of 4_. This way, whenever the cycle restarts, it will do so in a
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different direction: backwards, turned once to the left, or turned once to the right. Clearly repeating
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the sequence backwards is guaranteed to take us back to the start. The same is true for the left and right-turn sequences,
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since after two iterations they will _also_ leave us facing backwards.
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the sequence backwards is guaranteed to take us back to the start. The same is true for the left and right-turn sequences, though it's less obvious. If drawing our sequence once left us turned to the right,
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drawing our sequence twice will leave us turned more to the right. On a grid, two right turns are
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the same as turning around. The third repetition will then undo the effects of the first one
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(since we're facing backwards now), and the fourth will undo the effects of the second.
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There is an exception to this
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multiple-of-4 rule: a sequence makes it back to the origin right before it starts over.
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In that case, even if it's facing the very same direction it started with, all is well -- things
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are just like when it first started, and the cycle repeats. I haven't found a sequence that does this,
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so for our purposes, we'll stick with multiples of 4.
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Okay, so we want to avoid cycles with lengths divisible by four. What does it mean for a cycle to be of length _k_? It effectively means the following:
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@ -303,10 +314,10 @@ is not ruled out as a valid cycle by our previous condition, we don't find any c
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So what is it that _really_ determines if there can be cycles or not?
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Let's do some more playing around. What _are_ the actual cycle lengths when we divide by 9?
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Let's do some more playing around. What are the actual cycle lengths when we divide by 9?
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For all but two numbers, the cycle lengths are 9. The two special numbers are 6 and 3, and they end up
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with a cycle length of 3. From this, we can say that the cycle length seems to depend on whether or
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nor our \\(n\\) has any common factors with the divisor.
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not our \\(n\\) has any common factors with the divisor.
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Let's explore this some more with a different divisor, say 12. We fill find that 8 has a cycle length
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of 3, 7 has a cycle length of 12, 9 has a cycle length of 4. What's
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@ -321,8 +332,8 @@ k = \frac{d}{\text{gcd}(d,n)}
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{{< /latex >}}
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Where \\(d\\) is our divisor, which has been 9 until just recently. Indeed, this equation is in agreement
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with our experiment for \\(d = 9\\), too. Why might this be? Let's start once again with
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our equation for paths of length \\(k\\):
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with our experiment for \\(d = 9\\), too. Why might this be? Recall that sequences with
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period \\(k\\) imply the following congruence:
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{{< latex >}}
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kn \equiv 0\ (\text{mod}\ d)
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@ -337,7 +348,7 @@ since this number divides \\(n\\) and \\(d\\), we can write \\(n=fm\\) for some
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kfm \equiv 0\ (\text{mod}\ fg)
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{{< /latex >}}
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We can simplify this a little bit. Recall that what this equation _really_ means is that the
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We can simplify this a little bit. Recall that what this equation really means is that the
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difference of \\(kfm\\) and \\(0\\), which is just \\(kfm\\) is divisible by \\(fg\\):
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{{< latex >}}
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@ -351,14 +362,21 @@ we can write:
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g|km
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{{< /latex >}}
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We also know that \\(g\\) and \\(m\\) have no common factors -- they were all divided out from \\(d\\)
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and \\(n\\) when we divided by \\(f\\)! We can thus further simplify our claim:
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Can we distill this statement even further? It turns out that we can. Remember that we got \\(g\\)
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and \\(m\\) by dividing \\(d\\) and \\(n\\) by their greatest common factor, \\(f\\). This, in
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turn, means that \\(g\\) and \\(m\\) have no more common factors (that aren't equal to 1). If they
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did have such a common factor, say \\(h\\), we would be able to write \\(m=hi\\) and \\(g=hj\\).
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Then, we would _also_ be able to write \\(n=fhi\\) and \\(d=fhj\\). But now, \\(fh\\) is a common
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factor of both \\(n\\) and \\(d\\), and it's bigger than \\(f\\) (since \\(h\\) is not 1)! This
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violates our assumption that \\(f\\) is the greatest common factor. So there can't be another shared
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fadctor between \\(g\\) and \\(m\\). From this, in turn, we can deduce that \\(m\\) is not
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relevant to \\(g\\) dividing \\(km\\), and we get:
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{{< latex >}}
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g|k
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{{< /latex >}}
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This says that \\(k\\) must be divisible by \\(g\\). Recall that we got \\(g\\) by dividing
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That is, we get that \\(k\\) must be divisible by \\(g\\). Recall that we got \\(g\\) by dividing
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\\(d\\) by \\(f\\), which is our largest common factor -- aka \\(\\text{gcd}(d,n)\\). We can thus
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write:
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@ -366,12 +384,23 @@ write:
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\frac{d}{\text{gcd}(d,n)}|k
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{{< /latex >}}
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All that's left is to pick the smallest \\(k\\) that fits this description (that would be the first
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point at which our sequence of multiples of \\(n\\) will loop). Zero is divisible by anything, but
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alas, our sequence numbers start at 1 -- zero's out. The next best thing is \\(d/\\text{gcd}(d,n)\\).
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And there we have it: the first point at which our sequence loops, just like we guessed.
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Let's stop and appreciate this result. We have found a condition that is required for a sequnce
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of remainders from dividing by \\(d\\) (which was 9 in the original problem) to repeat after \\(k\\)
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numbers. Furthermore, all of our steps can be performed in reverse, which means that if a \\(k\\)
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matches this conditon, we can work backwards and determine that a sequence of numbers has
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to repeat after \\(k\\) steps.
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Lastly, recall that a cycle occurs whenever a \\(k\\) is a multiple of 4. Now that we know what
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Multiple \\(k\\)s will this condition, and that's not surprising. If a sequence repeats after 5 steps,
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it also repeats after 10, 15, and so on. We're interested in the first time our sequences repeat after
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taking any steps, which means we have to pick the smallest possible non-zero value of \\(k\\). The smallest
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number divisible by \\(d/\\text{gcd}(d,n)\\) is \\(d/\\text{gcd}(d,n)\\) itself. We thus confirm
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our hypothesis:
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{{< latex >}}
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k = \frac{d}{\text{gcd}(d,n)}
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{{< /latex >}}
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Lastly, recall that our patterns would spiral away from the center whenever a \\(k\\) is a multiple of 4. Now that we know what
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\\(k\\) is, we can restate this as "\\(d/\\text{gcd}(d,n)\\) is divisible by 4". But if we pick
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\\(n=d-1\\), the
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{{< sidenote "right" "coprime-note" "greatest common factor has to be \(1\)," >}}
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