It’s hard to understand anything from just one example. One of the reason for studying other planets is that it helps us understand Earth. It can even be helpful to have more examples when the examples are purely speculative, such as xenobiology, or even known to be false, i.e. counterfactuals, though here be dragons.

The fundamental theorem of arithmetic seems trivial until you see examples of similar contexts where it isn’t true. The theorem says that integers have a unique factorization into primes, up to the order of the factors. For example, 12 = 2² × 3. You could re-order the right hand side as 3 × 2², but you can’t change the list of prime factors and their exponents.

I was unimpressed when I first heard of fundamental theorem of arithmetic. It seemed obvious, and hardly worth distinguishing as the fundamental theorem of arithmetic. (If not this, what would the fundamental theorem of arithmetic be? Any candidates? I didn’t have one, and still don’t.)

In order to appreciate the unique factorization property of the integers, mathematicians created algebraic structures analogous to the integers, i.e. rings, in which unique factorization may or may not hold. In the language of ring theory, the integers are a “unique factorization domain” but not all rings are.

An easy way to create new rings is to extend the integers by adding new elements, analogous to the way the complex numbers are created by adding i to the reals.

If you extend the integers by appending √-5, i.e. using the set of all numbers of the form a + b√-5 where a and b are integers, you get a ring that is not a unique factorization domain. In this ring, 6 can be factored as 2 × 3 but also as (1 + √-5)(1 – √-5).

However, you can extend the integers by other elements and you may get a unique factorization domain. For example, the Eisenstein [1] integers append (-1 + i√ 3)/2 to the ordinary integers, and the result is a unique factorization domain.

More fundamental theorem posts

• Fundamental theorem of algebra
• Fundamental theorem of calculus

[1] That’s Eisenstein, not Einstein. Gotthold Eisenstein was a 19th century mathematician who worked in analysis and number theory.

This post will take a familiar theorem in a few less familiar directions.

The Fundamental Theorem of Algebra (FTA) says that an nth degree polynomial over the complex numbers has n roots. The theorem is commonly presented in high school algebra, but it’s not proved in high school and it’s not proved using algebra! A math major might see a proof midway through college.

You’re most likely to see a proof of the Fundamental Theorem of Algebra in a course in complex analysis. That is because the FTA depends on analytical properties of the complex numbers, not just their algebraic properties. It is an existence theorem that depends on the topological completeness of the complex numbers, and so it cannot be proved from the algebraic properties of the complex numbers alone.

(The dividing lines between areas of math, such as between algebra and analysis, are not always objective or even useful. And for some odd reason, some people get touchy about what belongs where. But the categorization of math subjects implicit in the creation of course catalogs puts the proof of the FTA on the syllabus of complex analysis courses, sometimes topology courses, but not algebra courses.)

Gauss offered a proof of the FTA in 1799, but his proof was flawed because he implicitly assumed the Jordan curve theorem, a seemingly obvious theorem that wasn’t rigorously proven until 1911. In keeping with our the theme above, the hole was due to overlooking a topological subtlety, not due to an algebraic mistake.

The proof of the FTA using complex analysis is a quick corollary of Liouville’s theorem: If a function is analytic everywhere in the complex plane and bounded, then it must be constant. Assume a non-constant polynomial p(z) is nowhere zero. Then 1/p(z) is analytic everywhere in the complex plane. And it must be bounded because p(z) → ∞ as |z| → ∞. We have a contradiction, so p(z) must be zero for some z.

The usual statement of the FTA says that an nth degree polynomial has n roots, but the proof above only says it must have one root. But you can bootstrap your way to the full result from there. The analyst tells the algebraist “I’ve done the hard part for you. You can take it from there.”

In some sense the rest of the theorem properly belongs to algebra, because the bookkeeping of how to count zeros is more of an algebraic matter. In order for every nth degree polynomial to have exactly n roots, some roots must be counted more than once. For example, (z – 42)² has a double root at 42. From a strictly analytical view point, there is one point where (z – 42)² is zero, namely at z = 42, but it is useful, even to analysts, to count this as a double root.

It may seem pedantic, or even Orwellian, so say that some roots count more than others. But a great deal of theorems are simpler to state if we agree to count roots according to multiplicity. This idea is taken further in algebraic geometry. For example, Bézout’s theorem says that if X is an mth degree curve and Y is an nth degree curve, then X and Y intersect in mn points. It takes a lot of prep work for this theorem to have such a simple statement. You have to count intersections with multiplicity, and you have to add points at infinity.

Liouville’s theorem’s is useful for more than proving the FTA. It is also useful in studying elliptic functions. (I believe Liouville proved his theorem for this purpose. Someone into math history can check me on that.) If an analytic function is periodic in two distinct directions in the complex plane (more on that here), it must have a singularity because otherwise it would be bounded.

The FTA may seem less profound than it is. You might object that of course every nth degree polynomial has n roots: you’ve cheated by adding in the roots you need. But that’s not true. The complex numbers are created by adding in one root to one particular polynomial, namely z² = -1. The impressive part is that adding one root of one particular quadratic polynomial is enough to force all quadratic polynomials and even all higher degree polynomials also to also have roots.

This does not happen in finite fields. A finite field cannot be algebraically complete. If you extend a finite field so that every quadratic equation has a root, then only quadratic equations have roots. It does not follow that cubic polynomials, for example, have roots. You could extend it further so that all cubic equations have roots, but then 4th degree polynomials will not all have roots. If you stop the extension process after any finite number of steps, there will be some polynomials without roots.

Related posts

• Fundamental theorem of calculus
• Doubly and triply periodic functions
• Solving systems of polynomial equations

Several people have told me they can’t understand most of my math posts, but they subscribe because they enjoy the occasional math post that they do understand. If you’re in that boat, thanks for following, and I wanted to let you know there have been a few posts lately that are more accessible than you might think.

The posts I refer to don’t require any advanced math to follow, though they may require some advanced math to fully appreciate.

For example, my latest post on means and sums only requires pre-calculus math to understand, though it introduces ideas that usually aren’t introduced until they’re needed in more advanced courses.

A few days ago I started what turned into a series of four blog posts, all consequences of combining the binomial theorem and Euler’s theorem. Here are the four posts:

1. Building high frequencies out of low frequencies
2. Manipulating sums
3. More juice in the lemon
4. Chebyshev’s other polynomials

These posts do not require calculus, and should be mostly accessible with high school math.

Chebyshev polynomials come up several times in these posts. High school math will not prepare you to appreciate the significance of these particular polynomials, but you can follow along by ignoring the name and just thinking “OK, they’re polynomials. I know what a polynomial is.”

It would seem that sums and means are trivially related; the mean is just the sum divided by the number of items. But when you generalize things a bit, means and sums act differently.

Let x be a list of n non-negative numbers,

and let r > 0 [*]. Then the r-mean is defined to be

and the r-sum is define to be

These definitions come from the classic book Inequalities by Hardy, Littlewood, and Pólya, except the authors use the Fraktur forms of M and S. If r = 1 we have the elementary mean and sum.

Here’s the theorem alluded to in the title of this post:

As r increases, M_r(x) increases and S_r(x) decreases.

If x has at least two non-zero components then M_r(x) is a strictly increasing function of r and S_r(x) is a strictly decreasing function of r. Otherwise M_r(x) and S_r(x) are constant.

The theorem holds under more general definitions of M and S, such letting the sums be infinite and inserting weights. And indeed much of Hardy, Littlewood, and Pólya is devoted to studying variations on M and S in fine detail.

Here are log-log plots of M_r(x) and S_r(x) for x = (1, 2).

Note that both curves asymptotically approach max(x), M from below and S from above.

Related posts

• Volume of L^p norm balls
• Swedish superellipse
• Squircles

[*] Note that r is only required to be greater than 0; analysis books typically focus on r ≥ 1.