As dimension increases, the ratio of volume between a unit ball and a unit cube goes to zero. Said another way, if you have a high-dimensional ball inside a high-dimensional box, nearly all the volume is in the corners. This is a surprising result when you first see it, but it’s well known among people who work with such things.

In terms of L^p (Lebesgue) norms, this says that the ratio of the volume of the 2-norm ball to that of the ∞-norm ball goes to zero. More generally, you could prove, using the volume formula in the previous post, that if p < q, then the ratio of the volume of a p-norm ball to that of a q-norm ball goes to zero as the dimension n goes to infinity.

Proof sketch: Write down the volume ratio, take logs, use the asymptotic series for log gamma, slug it out.

Here’s a plot comparing p = 2 and q = 3.

Related posts

• Corners stick out more in high dimensions
• The cross polytope

Architect Peter Panholzer coined the term “squircle” in the summer of 1966 while working for Gerald Robinson. Robinson had seen a Scientific American article on the superellipse shape popularized by Piet Hein and suggested Panholzer use the shape in a project.

Piet Hein used the term superellipse for a compromise between an ellipse and a rectangle, and the term “supercircle” for the special case of axes of equal length. While Piet Hein popularized the superellipse shape, the discovery of the shape goes back to Gabriel Lamé in 1818.

You can find more on the superellipse and squircle by following these links, but essentially the idea is to take the equation for an ellipse or circle and replace the exponent 2 with a larger exponent. The larger the exponent is, the closer the superellipse is to being a rectangle, and the closer the supercircle/squircle is to being a square.

Panholzer contacted me in response to my article on squircles. He gives several pieces of evidence to support his claim to have been the first to use the term. One is a letter from his employer at the time, Gerald Robinson. He also cites these links. [However, see Andrew Dalke’s comment below.]

Optimal exponent

As mentioned above, squircles and more generally superellipses, involve an exponent p. The case p = 2 gives a circle. As p goes to infinity, the squircle converges to a square. As p goes to 0, you get a star-shape as shown here. As noted in that same post, Apple uses p = 4 in some designs. The Sergels Torg fountain in Stockholm is a superellipse with p = 2.5. Gerald Robinson designed a parking garage using a superellipse with p = e = 2.71828.

Panholzer experimented with various exponents [1] and decided that the optimal value of p would be the one for which the squircle has an area half way between the circle and corresponding square. This would create visual interest, leaving the viewer undecided whether the shape is closer to a circle or square.

The area of the portion of the unit circle contained in the first quadrant is π/4, and so we want to find the exponent p such that the area of the squircle in the first quadrant is (1 + π/4)/2. This means we need to solve

We can solve this numerically [2] to find p = 3.1620. It would be a nice coincidence if the solution were π, but it’s not quite.

Sometime around 1966 Panholzer had a conference table made in the shape of a squircle with this exponent.

Computing

I asked Panholzer how he created his squircles, and whether he had access to a computer in 1966. He did use a computer to find the optimal value of p; his brother in law, Hans Thurow, had access to a computer at McPhar Geophysics in Toronto. But he drew the plots by hand.

There was no plotter around at that time, but I used transparent vellum over graph paper and my architectural drawing skills with “French curves” to draw 15 squircles from p=2.6 (obviously “circlish”) to p=4.0 (obviously “squarish”).

Related posts

• Swedish superellipse
• Squircle curvature

[1] The 15 plots mentioned in the quote at the end came first. A survey found that people preferred the curve corresponding to p around 3.1. Later the solution to the equation for the area to be half way between that of a circle and a square produced a similar value.

[2] Here are a couple lines of Mathematica code to find p.

    f[p_] := Gamma[1 + 1/p]^2/Gamma[1 + 2/p]
    FindRoot[f[p] - (1 + Pi/4)/2, {p, 4}]

The 4 in the final argument to FindRoot is just a suggested starting point for the search.

It occurred to me recently that I rarely hear about finite rings. I did a Google Ngram search to make sure this isn’t just my experience.

Source

Why are finite groups and finite fields common while finite rings are not?

Finite groups have relatively weak algebraic structure, and demonstrate a lot of variety. Finite fields have very strong algebraic structure. Their complete classification has been known for a long time and is easy to state.

I imagine that most of the references to finite groups above have to do with classifying finite groups, and that most of the references to finite fields have to do with applications of finite fields, which are many.

You can see that references to finite groups hit their peak around the time of the Feit-Thompson theorem in 1962, and drop sharply after the classification of finite simple groups was essentially done in 1994. There’s a timeline of the progress toward the classification theorem on Wikipedia.

Rings have more structure than groups, but less structure than fields. Finite rings in particular are in a kind of delicate position: they easily become fields. Wedderburn’s little theorem says every finite domain is a field.

The classification of finite rings is much simpler than that of finite groups. And in applications you often want a finite field. Even if a finite ring (not necessarily a field) would do, you’d often use a finite field anyway.

In summary, my speculation as to why you don’t hear much about finite rings is that they’re not as interesting to classify as finite groups, and not as useful in application as finite fields.

Posts on finite simple groups

• A 3,000 page proof
• Orders of finite simple groups
• PSL(q)

Posts on finite fields

• Brief introduction to finite fields
• Sum-product theorem for finite fields
• Encryption posts, many using finite fields

Many times on this blog I’ve argued that the difference between pure and applied math is motivation. As my graduate advisor used to say, “Applied mathematics is not a subject classification. It’s an attitude.”

Traditionally there was general agreement regarding what is pure math and what is applied. Number theory and topology, for example, are pure, while differential equations and numerical analysis are applied.

But then public key cryptography and topological data analysis brought number theory and topology over into the applied column, at least for some people. And there are people working in differential equations and numerical analysis that aren’t actually interested in applications. It would be more accurate to say that some areas of math are more directly and more commonly applied than others. Also, some areas of math are predominantly filled with people interested in applications and some are not.

The US Army is interested in applying some areas of math that you would normally think of as very pure, including homotopy type theory (HoTT).

From an Army announcement:

Modeling frameworks are desired that are able to eschew the usual computational simplification assumptions and realistically capture … complexities of real world environments and phenomena, while still maintaining some degree of computational tractability. Of specific interest are causal and predictive modeling frameworks, hybrid model frameworks that capture both causal and predictive features, statistical modeling frameworks, and abstract categorical models (cf. Homotopy Type Theory).

And later in the same announcement

Homotopy Type Theory and its applications are such an area that is of significant interest in military applications.

HoTT isn’t the only area of math the Army announcement mentions. There are the usual suspects, such as (stochastic) PDEs, but also more ostensibly pure areas of math such as topology; the word “topological” appears 23 times in the document.

This would be fascinating. It can be interesting when a statistical model works well in application, but it’s no surprise: that’s what statistics was developed for. It’s more interesting when something finds an unexpected application, such as when number theory entered cryptography. The applications the Army has in mind are even more interesting because the math involved is more abstract and, one would have thought, less likely to be applied.

Related posts

• Next areas of math to be applied
• Homotopy groups of spheres
• (Categorical (data analysis)) and ((Categorical data) analysis)

I wrote a while back about Base32 and Base64 encoding, and yesterday I wrote about Bitcoin’s Base58 encoding. For completeness I wanted to mention Base85 encoding, also known as Ascii85. Adobe uses it in PostScript and PDF files, and git uses it for encoding patches.

Like Base64, the goal of Base85 encoding is to encode binary data printable ASCII characters. But it uses a larger set of characters, and so it can be a little more efficient. Specifically, it can encode 4 bytes (32 bits) in 5 characters.

Why 85?

There are 95 printable ASCII characters, and

log₉₅(2³²) = 4.87

and so it would take 5 characters encode 4 bytes if you use all possible printable ASCII characters. Given that you have to use 5 characters, what’s the smallest base that will still work? It’s 85 because

log₈₅(2³²) = 4.993

and

log₈₄(2³²) = 5.006.

(If you’re not comfortable with logarithms, see an alternate explanation in the footnote [1].)

Now Base85 is different from the other bases I’ve written about because it only works on 4 bytes at a time. That is, if you have a number larger than 4 bytes, you break it into words of 4 bytes and convert each word to Base 85.

Character set

The 95 printable ASCII characters are 32 through 126. Base 85 uses characters 33 (“!”) through 117 (‘u’). ASCII character 32 is a space, so it makes sense you’d want to avoid that one. Since Base85 uses a consecutive range of characters, you can first convert a number to a pure mathematical radix 85 form, then add 33 to each number to find its Base85 character.

Example

Suppose we start with the word 0x89255d9, equal to 143807961 in decimal.

143807961 = 2×85⁴ + 64×85³ + 14×85² + 18×85 + 31

and so the radix 85 representation is (2, 64, 14, 18, 31). Adding 33 to each we find that the ASCII values of the characters in the Base85 representation are (35, 97, 47, 51, 64), or (‘#’, ‘a’, ‘/’, ‘3’, ‘@’) and so #a/3@ is the Base85 encoding of 0x89255d9.

Z85

The Z85 encoding method is also based on a radix 85 representation, but it chose to use a different subset of the 95 printable characters. Compared to Base85, Z85 adds seven characters

 v w x y z { }

and removes seven characters

 ` \ " ' _ , ;

to make the encoding work more easily with programming languages. For example, you can quote Z85 strings with single or double quotes because neither kind of quote is a valid Z85 character. And you don’t have to worry about escape sequences since the backslash character is not part of a Z85 representation.

Gotchas

There are a couple things that could trip someone up with Base85. First of all, Base 85 only works on 32-bit words, as noted above. For larger numbers it’s not a base conversion in the usual mathematical sense.

Second, the letter z can be used to denote a word consisting of all zeros. Since such words come up disproportionately often, this is a handy shortcut, though it means you can’t just divide characters into groups of 5 when converting back to binary.

Related posts

• Base32 and Base64
• Base58

[1] 95⁴ = 81450625 < 2³² = 4294967296, so four characters from an alphabet of 95 elements is not enough to represent 2³² possibilities. So we need at least five characters.

85⁵ = 4437053125 > 2³², so five characters is enough, and in fact it’s enough for them to come from an alphabet of size 85. But 84⁵ = 4182119424 < 2³², so an alphabet of 84 characters isn’t enough to represent 32 bits with five characters.