## Polynomial Division

Polynomials generally form a ring, and not a field. However, the integers also form a ring, and we have a notion of division from arithmetic. For polynomials we have a similar form of division we’ll discuss now. Instead of using the absolute value of an integer to measure its size, we’ll use the degree of a polynomial to measure its size.

Given two polynomials and , we can find two more polynomials — the quotient and the remainder — so that , and . These polynomials are unique. The fact that we can find them is called the “division algorithm”, even though it’s a theorem. There are various algorithms we can use to establish this fact, but one of the most straightforward is polynomial long division, which we were all taught in high school algebra.

We start by writing . If the degree of is less than that of , we’re done. Otherwise let’s write and . The polynomials lead off with terms and . If we multiply by its leading term becomes exactly the same as that of , so when we subtract the top degree terms cancel out. That is, we write , and we see that has degree less than that of .

Now if the degree of is still greater than or equal to that of we can keep going. Multiply by a term so that when we subtract the product from we’ll kill off the highest remaining term and drop its degree. Since the degree of the remainder keeps going down, it must eventually drop below that of . Even if the degree of is zero, we can get the remainder down to the polynomial , which we decided to give the degree . This gives us our and

Now for uniqueness. Let’s say we have and , and both and have degrees less than that of . We can subtract to find . Now the degree on the right must be less than that of , since adding and subtracting polynomials can’t increase the degree beyond the larger of the two. On the left, on the other hand, the degree is at *least* that of , with one exception: if . In this case the left hand side vanishes. Since this is the only way to drop the degree of the left-hand side we must have . And then on the right we find .

[…] Algorithm for Polynomials Consider the division algorithm. It looks a lot like division for integers, as it should. Specifically, it’s got all the […]

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[…] we know from the fact that is a root that is a factor of . Our division algorithm shows us that we can write . The factor that gives us the root shows up twice! But since […]

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