2022-10-23 17:27:30 -07:00
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---
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title: "Search as a Polynomial"
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date: 2022-10-22T14:51:15-07:00
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draft: true
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tags: ["Mathematics"]
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---
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2022-10-26 18:52:24 -07:00
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I read a really neat paper some time ago, and I've been wanting to write about
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it ever since. The paper is called [Algebras for Weighted Search](https://dl.acm.org/doi/pdf/10.1145/3473577),
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and it is a tad too deep to dive into in a blog article -- readers of ICFP are
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rarely the target audience on this site. However, one particular insight I
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gleaned from the paper merits additional discussion and demonstration. I'm
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going to do that here.
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We can with something concrete. Suppose that you're trying to get from city A
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to city B, and then from city B to city C. Also suppose that your trips are
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measured in one-hour intervals, and that trips of equal duration are
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considered equivalent. Given possible routes from A to B, and then given more
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routes from B to C, what are the possible routes from A to C you can build up?
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In many cases, starting with an example helps build intuition. Maybe there
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are two routes from A to B that take two hours each, and one "quick" trip
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that takes only an hour. On top of this, there's one three-hour trip from B
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to C, and one two-hour trip. Given these building blocks, the list of
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possible trips from A to C is as follows.
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1. Two two-hour trips from A to B, followed up by the three-hour trip from B to
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C.
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2. Two two-hour trips from A to B, followed by the shorter two-hour trip from B
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to C.
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3. One one-hour trip from A to B, followed by the three-hour trip from B to C.
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4. One one-hour trip from A to B, followed by the shorter two-hour trip from B to C.
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In the above, to figure out the various ways of getting from A to C, we had to
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examine all pairings of A-to-B routes with B-to-C routes. But then, multiple
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pairings end up having the same total length: the second and third bullet
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points both describe trips that take four hours. Thus, to give
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our final report, we need to "combine like terms" - add up the trips from
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the two matching bullet points, ending up with total of three four-hour trips.
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Does this feel a little bit familiar? To me, this bears a rather striking
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resemblance to an operation we've seen in algebra class: we're multiplying
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two binomials! Here's the corresponding multiplication:
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{{< latex >}}
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\left(2x^2 + x\right)\left(x^3+x^2\right) = 2x^5 + 2x^4 + x^4 + x^3 = \underline{2x^5+3x^4+x^3}
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{{< /latex >}}
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2022-10-26 18:52:24 -07:00
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It's not just binomials that correspond to our combining paths between cities.
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We can represent any combination of trips of various lengths as a polynomial.
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Each term \\(ax^n\\) represents \\(a\\) trips of length \\(n\\). As we just
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saw, multiplying two polynomials corresponds to "sequencing" the trips they
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represent -- matching each trip in one with each of the trips in the other,
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and totaling them up.
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What about adding polynomials, what does that correspond to? The answer there
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is actually quite simple: if two polynomials both represent (distinct) lists of
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trips from A to B, then adding them just combines the list. If I know one trip
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that takes two hours (\\(x^2\\)) and someone else knows a shortcut (\\(x\\\)),
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then we can combine that knowledge (\\(x^2+x\\)).
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2022-10-26 18:52:24 -07:00
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Well, that's a neat little thing. But we can push this observation a bit
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further. To generalize what we've already seen, however, we'll need to
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figure out "the bare minimum" of what we need to make polynomial
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multiplication work as we'd expect.
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### Polynomials over Semirings
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Let's watch what happens when we multiply two binomials, paying really close
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attention to the operations we're performing. The following (concrete)
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example should do.
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{{< latex >}}
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\begin{aligned}
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& (x+1)(1-x)\\
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=\ & (x+1)1+(x+1)(-x)\\
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=\ & x+1-x^2-x \\
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=\ & x-x+1-x^2 \\
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=\ & 1-x^2
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\end{aligned}
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{{< /latex >}}
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The first thing we do is _distribute_ the multiplication over the addition, on
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the left. We then do that again, on the right this time. After this, we finally
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get some terms, but they aren't properly grouped together; an \\(x\\) is at the
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front, and a \\(-x\\) is at the very back. We use the fact that addition is
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_commutative_ (\\(a+b=b+a\\)) and _associative_ (\\(a+(b+c)=(a+b)+c\\)) to
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rearrange the equation, grouping the \\(x\\) and its negation together. This
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gives us \\((1-1)x=0x=0\\). That last step is important: we've used the fact
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that multiplication by zero gives zero. Another important property (though
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we didn't use it here) is that multiplication has to be associative, too.
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2022-10-26 18:52:24 -07:00
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So, what if we didn't use numbers, but rather any _thing_ with two
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operations, one kind of like \\((\\times)\\) and one kind of like \\((+)\\)?
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As long as these operations satisfy the properties we have used so far, we
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should be able to create polynomials using them, and do this same sort of
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"combining paths" we did earlier. Before we get to that, let me just say
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that "things with addition and multiplication that work in the way we
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described" have an established name in math - they're called semirings.
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A __semiring__ is a set equipped with two operations, one called
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"multiplicative" (and thus carrying the symbol \\(\\times)\\) and one
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called "additive" (and thus written as \\(+\\)). Both of these operations
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need to have an "identity element". The identity element for multiplication
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is usually
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{{< sidenote "right" "written-as-note" "written as \(1\)," >}}
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And I do mean "written as": a semiring need not be over numbers. We could
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define one over <a href="https://en.wikipedia.org/wiki/Graph">graphs</a>,
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sets, and many other things! Nevertheless, because most of us learn the
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properties of addition and multiplication much earlier than we learn about
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other more "esoteric" things, using numbers to stand for special elements
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seems to help use intuition.
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{{< /sidenote >}}
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and the identity element for addition is written
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as \\(0\\). Furthermore, a few equations hold. I'll present them in groups.
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First, multiplication is associative and multiplying by \\(1\\) does nothing;
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in mathematical terms, the set forms a [monoid](https://mathworld.wolfram.com/Monoid.html)
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with multiplication and \\(1\\).
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{{< latex >}}
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\begin{array}{cl}
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(a\times b)\times c = a\times(b\times c) & \text{(multiplication associative)}\\
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1\times a = a = a \times 1 & \text{(1 is multiplicative identity)}\\
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\end{array}
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{{< /latex >}}
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Similarly, addition is associative and adding \\(0\\) does nothing.
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Addition must also be commutative; in other words, the set forms a
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commutative monoid with addition and \\(0\\).
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{{< latex >}}
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\begin{array}{cl}
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(a+b)+c = a+(b+c) & \text{(addition associative)}\\
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0+a = a = a+0 & \text{(0 is additive identity)}\\
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a+b = b+a & \text{(addition is commutative)}\\
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\end{array}
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{{< /latex >}}
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Finally, a few equations determine how addition and multiplication interact.
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{{< latex >}}
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\begin{array}{cl}
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0\times a = 0 = a \times 0 & \text{(annihilation)}\\
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a\times(b+c) = a\times b + a\times c & \text{(left distribution)}\\
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(a+b)\times c = a\times c + b\times c & \text{(right distribution)}\\
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\end{array}
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{{< /latex >}}
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That's it, we've defined a semiring. First, notice that numbers do indeed
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form a semiring; all the equations above should be quite familiar from algebra
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class. When using polynomials with numbers to do our city path finding,
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we end up tracking how many different ways there are to get from one place to
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another in a particular number of hours. There are, however, other semirings
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we can use that yield interesting results, even though we continue to add
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and multiply polynomials.
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One last thing before we look at other semirings: given a semiring \\(R\\),
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the polynomials using that \\(R\\), and written in terms of the variable
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\\(x\\), are denoted as \\(R[x]\\).
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#### The Semiring of Booleans, \\(\\mathbb{B}\\)
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Alright, it's time for our first non-number example. It will be a simple one,
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though - booleans (that's right, `true` and `false` from your favorite
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programming language!) form a semiring. In this case, addition is the
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"or" operation (aka `||`), in which the result is true if either operand
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is true, and false otherwise.
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{{< latex >}}
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\begin{array}{c}
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\text{true} + b = \text{true}\\
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b + \text{true} = \text{true}\\
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\text{false} + \text{false} = \text{false}
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\end{array}
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{{< /latex >}}
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For addition, the identity element -- our \\(0\\) -- is \\(\\text{false}\\).
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Correspondingly, multiplication is the "and" operation (aka `&&`), in which the
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result is false if either operand is false, and true otherwise.
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{{< latex >}}
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\begin{array}{c}
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\text{false} \times b = \text{false}\\
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b \times \text{false} = \text{false}\\
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\text{true} \times \text{true} = \text{true}
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\end{array}
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{{< /latex >}}
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For multiplication, the identity element -- the \\(1\\) -- is \\(\\text{true}\\).
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It's not hard to see that _both_ operations are commutative - the first and
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second equations for addition, for instance, can be combined to get
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\\(\\text{true}+b=b+\\text{true}\\), and the third equation clearly shows
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commutativity when both operands are false. The other properties are
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easy enough to verify by simple case analysis (there are 8 cases to consider).
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The set of booleans is usually denoted as \\(\\mathbb{B}\\), which means
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polynomials using booleans are denoted by \\(\\mathbb{B}[x]\\).
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Let's try some examples. We can't count how many ways there are to get from
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A to B in a certain number of hours anymore: booleans aren't numbers!
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Instead, what we _can_ do is track _whether or not_ there is a way to get
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from A to B in a certain number of hours (call it \\(n\\)). If we can,
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we write that as \\(\text{true}\ x^n = 1x^n = x^n\\). If we can't, we write
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that as \\(\\text{false}\ x^n = 0x^n = 0\\). The polynomials corresponding
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to our introductory problem are \\(x^2+x^1\\) and \\(x^3+x^2\\). Multiplying
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them out gives:
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{{< latex >}}
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(x^2+x^1)(x^3+x^2) = x^5 + x^4 + x^4 + x^3 = x^5 + x^4 + x^2
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{{< /latex >}}
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And that's right; if it's possible to get from A to B in either two hours
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or one hour, and then from B to C in either three hours or two hours, then
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it's possible to get from A to C in either five, four, or three hours. In a
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way, polynomials like this give us
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{{< sidenote "right" "homomorphism-note" "less information than our original ones" >}}
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In fact, we can construct a semiring homomorphism (kind of like a
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<a href="https://en.wikipedia.org/wiki/Ring_homomorphism">ring homomorphism</a>,
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but for semirings) from \(\mathbb{N}[x]\) to \(\mathbb{B}[b]\) as follows:
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{{< latex >}}
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\sum_{i=0}^n a_ix^i \mapsto \sum_{i=0}^n \text{clamp}(a_i)x^i
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{{< /latex >}}
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Where the \(\text{clamp}\) function checks if its argument is non-zero.
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In the case of city path search, \(\text{clamp}\) asks the questions
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"are there any routes at all?".
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{{< latex >}}
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\text{clamp}(n) = \begin{cases}
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\text{false} & n = 0 \\
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\text{true} & n > 0
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\end{cases}
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{{< /latex >}}
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We can't construct the inverse of the above homomorphism (a mapping
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that would undo our clamping, and take polynomials in \(\mathbb{B}[x]\) to
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\(\mathbb{N}[x]\)). This fact gives us a more "mathematical" confirmation
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that we lost information, rather than gained it, but switching to
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boolean polynomials: we can always recover a boolean polynomial from the
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natural number one, but not the other way around.
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{{< /sidenote >}}
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(which were \\(\\mathbb{N}[x]\\), polynomials over natural numbers \\(\\mathbb{N} = \\{ 0, 1, 2, ... \\}\\)), so it's unclear why we'd prefer them. However,
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we're just warming up - there are more interesting semirings for us to
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consider!
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2022-10-25 22:46:05 -07:00
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#### The Semiring of Sets of Paths, \\(\\mathcal{P}(\\Pi)\\)
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Until now, we explicitly said that "all paths of the same length are
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equivalent". If we're giving directions, though, we might benefit
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from knowing not just that there _is_ a way, but what roads that
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way is made up of!
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To this end, we define the set of paths, \\(\\Pi\\). This set will consist
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of the empty path (which we will denote \\(\\circ\\), why not?), street
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names (e.g. \\(\\text{Mullholland Dr.}\\) or \\(\\text{Sunset Blvd.}\\)), and
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concatenations of paths, written using \\(\\rightarrow\\). For instance,
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a path that first takes us on \\(\\text{Highway}\\) and then on
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\\(\\text{Exit 4b}\\) will be written as:
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{{< latex >}}
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\text{Highway}\rightarrow\text{Exit 4b}
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{{< /latex >}}
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Furthermore, it's not too much of a stretch to say that adding an empty path
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to the front or the back of another path doesn't change it. If we use
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the letter \\(\\pi\\) to denote a path, this means the following equation:
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{{< latex >}}
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\circ \rightarrow \pi = \pi = \pi \rightarrow \circ
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{{< /latex >}}
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{{< sidenote "right" "paths-monoid-note" "So those are paths." >}}
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Actually, if you clicked through the
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<a href="https://mathworld.wolfram.com/Monoid.html">monoid</a>
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link earlier, you might be interested to know that paths as defined here
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form a monoid with concatenation \(\rightarrow\) and the empty path \(\circ\)
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as a unit.
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{{< /sidenote >}}
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Paths alone, though, aren't enough for our polynomials; we're tracking
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different ways to get from one place to another. This is an excellent
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use case for sets!
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Our next semiring will be that of _sets of paths_. Some example elements
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of this semiring are \\(\\varnothing\\), also known as the empty set,
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\\(\\{\\circ\\}\\), the set containing only the empty path, and the set
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containing a path via the highway, and another path via the suburbs:
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{{< latex >}}
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\{\text{Highway}\rightarrow\text{Exit 4b}, \text{Suburb Rd.}\}
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{{< /latex >}}
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So what are the addition and multiplication on sets of paths? Addition
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is the easier one: it's just the union of sets (the "triangle equal sign"
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symbol means "defined as"):
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{{< latex >}}
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A + B \triangleq A \cup B
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{{< /latex >}}
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It's well known (and not hard to verify) that set union is commutative
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and associative. The additive identity \\(0\\) is simply the empty set
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\\(\\varnothing\\). Intuitively, adding "no paths" to another set of
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paths doesn't add anything, and thus leaves that other set unchanged.
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Multiplication is a little bit more interesting, and uses the path
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concatenation operation we defined earlier. We will use this
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operation to describe path sequencing; given two sets of paths,
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\\(A\\) and \\(B\\), we'll create a new set of paths
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consisting of each path from \\(A\\) concatenated with each
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path from \\(B\\):
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{{< latex >}}
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A \times B \triangleq \{ a \rightarrow b\ |\ a \in A, b \in B \}
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{{< /latex >}}
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The fact that this definition of multiplication on sets is associative
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relies on the associativity of path concatenation; if path concatenation
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weren't associative, the second equality below would not hold.
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{{< latex >}}
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\begin{array}{rcl}
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A \times (B \times C) & = & \{ a \rightarrow (b \rightarrow c)\ |\ a \in A, b \in B, c \in C \} \\
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& \stackrel{?}{=} & \{ (a \rightarrow b) \rightarrow c \ |\ a \in A, b \in B, c \in C \} \\
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& = & (A \times B) \times C
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\end{array}
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{{< /latex >}}
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What's the multiplicative identity? Well, since multiplication concatenates
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all the combinations of paths from two sets, we could try making a set of
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elements that don't do anything when concatenating. Sound familiar? It should,
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that's \\(\\circ\\), the empty path element! We thus define our multiplicative
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identity as \\(\\{\\circ\\}\\), and verify that it is indeed the identity:
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{{< latex >}}
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\begin{gathered}
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\{\circ\} \times A = \{ \circ \rightarrow a\ |\ a \rightarrow A \} = \{ a \ |\ a \in A \} = A \\
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A \times \{\circ\}= \{ a\rightarrow \circ \ |\ a \rightarrow A \} = \{ a \ |\ a \in A \} = A
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\end{gathered}
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{{< /latex >}}
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It's not too difficult to verify the annihilation and distribution laws for
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sets of paths, either; I won't do that here, though. Finally, let's take
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a look at an example. Like before, we'll try make one that corresponds to
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our introductory description of paths from A to B and from B to C. Now we need
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to be a little bit creative, and come up with names for all these different
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roads between our hypothetical cities. Let's say that \\(\\text{Highway A}\\)
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and \\(\\text{Highway B}\\) are the two paths from A to B that take two hours
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each, and then \\(\\text{Shortcut}\\) is the path that takes one hour. As for
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paths from B to C, let's just call them \\(\\text{Long}\\) for the three-hour
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path, and \\(\\text{Short}\\) for the two-hour path. Our two polynomials
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are then:
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{{< latex >}}
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\begin{array}{rcl}
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P_1 & = & \{\text{Highway A}, \text{Highway B}\}x^2 + \{\text{Shortcut}\}x \\
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P_2 & = & \{\text{Long}\}x^3 + \{\text{Short}\}x^2
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\end{array}
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{{< /latex >}}
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Multiplying them gives:
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{{< latex >}}
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\begin{array}{rl}
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& \{\text{Highway A} \rightarrow \text{Long}, \text{Highway B} \rightarrow \text{Long}\}x^5\\
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+ & \{\text{Highway A} \rightarrow \text{Short}, \text{Highway B} \rightarrow \text{Short}, \text{Shortcut} \rightarrow \text{Long}\}x^4\\
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+ & \{\text{Shortcut} \rightarrow \text{Short}\}x^3
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\end{array}
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{{< /latex >}}
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This resulting polynomial gives us all the paths from city A to city C,
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grouped by their length!
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#### The Tropical Semiring, \\(\\mathbb{R}\\)
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I only have one last semiring left to show you before we move on to something
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other than paths between cities. It's a fun semiring though, as even its name
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might suggest: we'll take a look at a _tropical semiring_.
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In this semiring, we go back to numbers; particularly, real numbers (e.g.,
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\\(1.34\\), \\(163\\), \\(e\\), that kind of thing). We even use addition --
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sort of. In the tropical semiring, addition serves as the _multiplicative_
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operation! This is even confusing to write, so I'm going to switch up notation;
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in the rest of this section, I'll use \\(\\otimes\\) to represent the
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multiplicative operation in semirings, and \\(\\oplus\\) to represent the
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additive one. The symbols \\(\\times\\) and \\(+\\) will be used to represent
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the regular operations on real numbers. With that, the operations on our
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tropical semiring over real numbers are defined as follows:
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{{< latex >}}
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\begin{array}{rcl}
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x \otimes y & \triangleq & x + y\\
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x \oplus y & \triangleq & \min(x,y)
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\end{array}
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{{< /latex >}}
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What is this new semiring good for? How about this: suppose that in addition to
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the duration of the trip, you'd like to track the distance you must travel for
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each route (shorter routes do sometimes have more traffic!). Let's watch what
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happens when we add and multiply polynomials over this semiring.
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When we add terms with the same power but different coefficients, like
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\\(ax\oplus bx\\), we end up with a term \\(\min(a,b)x\\). In other words,
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for each trip duration, we pick the shortest length. When we multiply two
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polynomials, like \\(ax\otimes bx\\), we get \\((a+b)x\\); in other words,
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when sequencing two trips, we add up the distances to get the combined
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distance, just like we'd expect.
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We can, of course, come up with a polynomial to match our initial example.
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Say that the trips from A to B are represented by \\(2.0x^2\oplus1.5x\\\) (the
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shortest two-hour trip is \\(2\\) units of distance long, and the one-hour
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trip is \\(1.5\\) units long), and that the trips from B to C are represented
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by \\(4.0x^3\oplus1.0x^2\\). Multiplying the two polynomials out gives:
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{{< latex >}}
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\begin{array}{rcl}
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(2.0x^2\oplus1.5x)(4.0x^3\oplus1.0x^2) & = & 6.0x^5 \oplus \min(2.0+1.0, 1.5+4.0)x^4 \oplus 2.5x^3 \\
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& = & 6.0x^5 \oplus 3.0x^4 \oplus 2.5x^3
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\end{array}
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{{< /latex >}}
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The only time we used the additive operation in this case was to pick between
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two trips of equal druation but different length (two-hour trip from A to B
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followed by a two-hour trip from B to C, or one-hour trip from A to C followed
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by a three-hour trip from B to C). The first trip wins out, since it requires
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only \\(3.0\\) units of distance.
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