What are some examples of notation that really improved mathematics? [closed]

I've always felt that the concise, suggestive nature of the written language of mathematics is one of the reasons it can be so powerful. Off the top of my head I can think of a few notational conventions that simplify problem statements and ideas, (these are all almost ubiquitous today):

• $\binom{n}{k}$
• $\left \lfloor x \right \rfloor$ and $\left \lceil x \right \rceil$
• $\sum f(n)$
• $\int f(x) dx$
• $[P] = \begin{cases} 1 & \text{if } P \text{ is true;} \\ 0 & \text{otherwise} \end{cases}$

The last one being the Iverson Bracket. A motivating example for the use of this notation can be found here.

What are some other examples of notation that really improved mathematics over the years? Maybe also it is appropriate to ask what notational issues exist in mathematics today?

EDIT (11/7/13 4:35 PM): Just thought of this now, but the introduction of the Cartesian Coordinate System for plotting functions was a HUGE improvement! I don't think this is outside the bounds of my original question and note that I am considering the actual graphical object here and not the use of $(x,y)$ to denote a point in the plane.

closed as too broad by user642796May 4 '15 at 9:00

Please edit the question to limit it to a specific problem with enough detail to identify an adequate answer. Avoid asking multiple distinct questions at once. See the How to Ask page for help clarifying this question. If this question can be reworded to fit the rules in the help center, please edit the question.

• Positional notation to write numbers. – OR. Nov 7 '13 at 18:21
• As this doesn't seem like it would have a right answer, I am flagging to make the question community wiki – Stahl Nov 7 '13 at 18:28
• $x^2+ax+b$ or, in general, using letters to denote numbers. – egreg Nov 7 '13 at 18:47
• @voromax Hmm, you're not from here, you come from Stack Overflow like me ;) I've noticed that here at Math.SE, these types of questions are encouraged. It's not the same as SO here – Doorknob Nov 8 '13 at 1:21
• I have to agree with ABC . . . positional notation is without a doubt the most significant advance in notation. Try simple addition with Roman numerals. Try ANYTHING with Roman Numerals, tally marks, or any other system of numeration. – Marc Nov 8 '13 at 2:17

Vector notation! The fact that you can write: $$\vec{a}\cdot\vec{b}$$ Instead of: $$a_1 b_1 + a_2 b_2 + \ldots$$ Or that you can use vector operators such as $\vec\nabla$, really helped develop linear algebra and its use in applied fields. To point out one famous example, Maxwell's original equations take up an entire page!

$\quad\quad\quad\quad\quad$ And here's the same using vector notation for comparison:

\boxed{\begin{align}\\\,\\\qquad&\qquad\nabla\cdot\mathbf D=\rho&&\text{(1)} \qquad\qquad\text{Gauss' law}&\\\,\\ \qquad&\qquad\nabla\cdot\mathbf B=0&&\text{(2)}\quad\text{Gauss' law for magnetism}&\\\,\\ \qquad&\,\,\,\nabla\times\mathbf E=-\dfrac{\partial\mathbf B}{\partial t}&&\text{(3)}\qquad\quad\,\text{Faraday's law}&\\\,\\ \qquad&\,\nabla\times\mathbf H=\dfrac{\partial\mathbf D}{\partial t}+\mathbf J&&\text{(4)}\qquad\text{Ampère-Maxwell law}\qquad\\\,\\ \end{align}}\\\,\\\textit{Maxwell's equations in vector form}

(Image from IEEE's history page)

• I would argue that "vector notation" isn't really special notation, just a useful definition of operators like the scalar product. In a programming language, we'd say it's just a custom-defined operator but all in the language's default syntax. – leftaroundabout Nov 8 '13 at 15:05
• vector notation also obviates the need to refer to spatial coordinates/parametrization. – Jonathan Nov 9 '13 at 2:55
• Maxwell actually wrote twenty equations, of which (4) is actually two equations. There are actually eight equations in vector form, (4) breaks into [math]\nabla\times H = C \quad C = J + \dot D[\math]. Maxwell actually invented something like Nabla, by writing these as the scalar and vector parts of a quarterion. – wendy.krieger May 3 '15 at 10:23
• @wendy.krieger We use a $stuff$ tag here, not a [math]stuff[\math] tag. That's $\nabla\times H = C \quad C = J + \dot D$. – Akiva Weinberger May 3 '15 at 12:49
• Late comment but lets not forget that when tensor notation was introduced Maxwell’s equations were simplified into just two! See here: en.m.wikipedia.org/wiki/… – aidangallagher4 Apr 2 '18 at 17:18

Algebraic notation with letters instead of verbal descriptions for quantities that are not explicitly known. The transition from rhetorical mathematics to syncopated and then symbolic had a tremendous impact on mathematics, making it possible to state rules and algorithms in greater generality.

• I think that consistency in the choice of some letters for some mathematical objects has proven particularly helpful. I'm thinking about $n,\,m$ for integers, $i,\,j$ for indices, $z,\,x,\,y$ when talking about complex numbers, $p,\,q$ for prime numbers, $k$ for the base field, $\phi_i : U_i \rightarrow V_i$ for charts, and so on. – Luca Bressan Nov 7 '13 at 20:37
• For me this is by far the most important notational advance in mathematical history, whose impact on mathematics is so fundamental that it hard to express properly. Without it mathematics just couldn't have advanced much beyond its medieval state. I'll take the freedom to replace "numbers" in the first sentence though, as this is improper; apart from some rare cases like$~\pi$, letters are almost never used in place of (explicit) numbers. – Marc van Leeuwen Nov 8 '13 at 8:42
• Agreed; this seems to me the single most important answer by far. It’s hard to conceive that modern mathematics could have developed if we were still writing out “that number, which when squared and added to five times itself yields 3” and the like. – Peter LeFanu Lumsdaine Nov 8 '13 at 15:58
• Just think how Indian mathematicians stated all of their theorems! Paragraphs! Implicit reference unrolled through winding sentences! – bright-star Nov 11 '13 at 9:38

I would suggest Gauss's invention of the notation for congruences in modular arithmetic:

"The invention of [congruence notation] by Gauss affords a striking example of the advantage which may be derived from an appropriate notation, and marks an epoch in the development of the science of arithmetic."

G. B. Matthews (1861-1922)

Edit:

For anyone who is not sure what the notation actually is:

$$a \equiv b \pmod{k}$$ means that $a$ and $b$ give the same remainder on division by $k$, or equivalently, that $a-b$ is divisible by $k$.

• Absolutely. ${}{}{}{}$ – Pedro Tamaroff Nov 7 '13 at 18:58
• It is hard to believe how they managed without it before then, I reckon. – Old John Nov 7 '13 at 18:59
• And yet I read somewhere that Gauss said something like, “We need new notions, not new notations.” – Lubin Nov 8 '13 at 1:39
• @Lubin: "But in our opinion truths of this kind should be drawn from notions rather than from notations." - Gauss, Disquisitiones Arithmeticae, Article 76. (Of course, the original quote was in Latin.) This was a remark towards Edward Waring's Meditationes Algebraicae, another Latin work, wherein Waring states that a proof of Wilson's theorem (and other theorems of 'that sort') would be difficult because of a lack of notation to represent prime numbers. – Reid Nov 8 '13 at 7:03
• I agree fully that having a notation for congruences is invaluable, but I must admit that I've always found the $\equiv \pmod k$ notation itself to be cumbersome. I wish it were written $a=_k b$ or $a\equiv_k b$ or something like that. – Alexander Gruber Nov 10 '13 at 1:43

Landau notation for describing the asymptotic behavior of a function:

$$O(n)\quad o(\log n)\quad \Omega(n!)\quad \Theta(2^n) \quad \dots$$

• I actually think the notation for this is not very good. For example, we say $2x^2 = O(x^2)$, but also that $2x^2 = O(x^3)$, even though $O(x^3) \neq O(x^2)$ (and whether we can say $O(x^2) = O(x^3)$ depends on what book you read). It would have been better to use =, <, and > to convey a partial-ordering, so that we could say $O(2x^2) = O(x^2) < O(x^3)$ – BlueRaja - Danny Pflughoeft Nov 7 '13 at 21:47
• @BlueRaja-DannyPflughoeft Maybe we should say, for instance, $2x^2 \in O(x^2)$ instead, interpreting $O(x^2)$ as a set of functions. – Lily Chung Nov 7 '13 at 21:50
• @BlueRaja-DannyPflughoeft: I think the most powerful way to use Landau notation is as shorthand for a generic function in the set, and combining it with other functions. E.g. $f(n) = n! + o(n^2)$. If you insist on treating $o(n^2)$ formally as a set, you'll have to replace this with something much more clunky. – Nate Eldredge Nov 7 '13 at 21:58
• @BlueRaja-DannyPflughoeft I don't get what you mean. $2x^2 = O(x^2)$ is a notation abuse. The correct notation is $2x^2 \in O(x^2)$ since $O$ is a set. Hence there is absolutely nothing strange in having $2x^2 \in O(x^2) \wedge 2x^2 \in O(x^3) \wedge O(x^2) \neq O(x^3)$. Also you must use three different notations to describe the relationship between functions because we want to be able to express $f$ is at most as big as $g$, but also $f$ is at least as big as $g$ and even $f$ is "close" to $g$. Making these three cases distinct is clearer (explicit is better than implicit) – Bakuriu Nov 7 '13 at 22:03
• @NateEldredge: $f(n) \in n! + o(n^2)$ isn't that clunky – Max Nov 10 '13 at 15:59

Commutative diagrams! Their use revolutionized whole areas of mathematics and probably paved the way to the discovery-invention of category theory.

Writing matrices with double subindices $$\begin{pmatrix}a_{11}&a_{12}&a_{13}&\dots\\a_{21}&a_{22}&a_{23}&\cdots\\\vdots&\vdots&\vdots&\ddots\end{pmatrix}$$

Here's a little information and images of how things were done before. It is thought Leibniz was the pioneer. In fact, you can find this in A Source Book in Mathematics: • +1 for your invaluable link. I was just discussing the extraordinary creativity of Leibni(t)z with a friend this afternoon and that was before you taught me that the double index notation is also due to him. Voltaire was very, very wrong to mock Leibniz in Candide :-) [but the book is so well-written that one can't help forgiving him ...] – Georges Elencwajg Nov 7 '13 at 20:25
• Not to mention he originated the $\int$ notation for integrals ... – Kyle Hale Nov 7 '13 at 20:58
• @GeorgesElencwajg Thanks for the comment. Agreed! =) – Pedro Tamaroff Nov 7 '13 at 21:11

Einstein summation notation really helped simplify things in areas of linear algebra applied to physics and differential geometry.

For example:

$$y = \sum_{i=1}^3 c_i x^i = c_1 x^1 +c_2 x^2 + c_3 x^3$$

could be written as

$$y = c_i x^i$$

where the lower and upper indices imply "sum over $i$".

• "Really hate" would be a bit strong, but I seriously dislike it. Unlikely that I will ever win an Abel Prize though, and my chance for a Fields medal is gone, so take it just as my personal preference. – Daniel Fischer Nov 7 '13 at 20:05
• A caveat: many mathematicians really hate this notation and it is actually not common at all in pure mathematics. Bourbaki, Serre, Henri Cartan certainly haven't used it and I would guess that very few Fields medalists and no Abel Prize winner ever used it. I don't know however about Henri Cartan's Daddy Elie ... (Just for clarification: I don't use that convention but it doesn't disturb me in the least to read documents which do use it) – Georges Elencwajg Nov 7 '13 at 20:11
• Pg 122 of "Michael Atiyah Collected Works Volume 5: Gauge Theories" The foot note reads "The Einstein summation convention is employed...". Sir Michael Atiyah (British) also collaborated with and inspired Edward Witten (American) who also wrote on Gauge theories and used the convention in countless papers. Michael Atiyah won the Abel prize in 2004, Edward Witten won the Fields medal in 1990. – Graham Hesketh Nov 9 '13 at 17:59
• This is a great example of an advance in notation. Reducing clutter like the summation symbol is not trivial. A less cluttered notation allows one to think more clearly about mathematical ideas. It also saves chalk. Mathematicians avoid going to components but for some calculations it is preferable or even necessary. That is when Einstein's notation shows its power. (+1) – user26872 Nov 10 '13 at 23:21
• @oen: You might find this answer interesting. – Nikolaj-K Jan 2 '14 at 17:47

$$Y^X$$

This is some of the most suggestive notation I can think of (and the best notation for some object should be suggestive of the structure of that object). If $X$ and $Y$ are numbers, then we have the familiar rule $(Y^X)^Z = Y^{X\times Z}$, and this holds in more generality as well: if $X$, $Y$, and $Z$ are topological spaces, then $Y^X = \{f : X\to Y\mid f\textrm{ continuous}\}$, and $(Y^X)^Z \cong Y^{X\times Z}$. Moreover, if we are only thinking of $X$, $Y$, and $Z$ as sets, and of $Y^X$ as set-theoretic functions, we have $\left|Y^X\right| = \left|Y\right|^{\left|X\right|}$ (assuming the expressions make sense). It even works in some cases where one of the expressions doesn't make sense; we obtain the correct combinatorial interpretation of $0^0$ via this rule: $1 = \left|\emptyset^{\emptyset}\right| =" 0^0$ (one could take this as the reason that $0^0 = 1$ for discrete types of things, although there are others as well).

$$\frac{d}{dx}$$ Another piece of notation that is useful/suggestive is the Leibniz $\frac{d}{dx}$ notation. There's the chain rule $\frac{d f}{dx} = \frac{df}{dg}\cdot\frac{dg}{dx}$ (while we're not actually cancelling $dg$'s, it at least makes it easier to remember) and the rule $\frac{dy}{dx} = \frac{1}{dx/dy}$, for example. The $\frac{d}{dx}$ (and $\int$) notation can also be seen as an operator, and this also lends itself to some interesting formal calculations that turn out to give the right answer!

Of course, the suggestiveness of these notations is not their only benefit - they also are convenient/useful/space saving!

Another to add to this: functions as arrows from one space to another $$X\xrightarrow{f} Y$$ or $$f : X\to Y$$

• I think you could improve this by – Dylan Yott Nov 7 '13 at 20:25
• Another piece of notation that is useful/suggestive is the Leibniz $\frac{d}{dx}$ notation Leibniz! Him again! – Georges Elencwajg Nov 7 '13 at 20:29
• Haha the formal calculations document is pretty cool. Do you know if such techniques work in the general case? – fiftyeight Nov 8 '13 at 1:22
• @fiftyeight: The arguments presented in the link actually can be made rigorous by interpreting the derivative and integral as operators and observing that they have operator norm less than $1$, so that it does make sense to use the infinite geometric series identity. However, I don't know all the details required to make the arguments precise. – Stahl Nov 8 '13 at 4:13
• nice post and very cool article – Jonathan Nov 9 '13 at 2:44

Perhaps $\forall , \exists , \vee , \wedge , \neg , \Rightarrow , \Leftarrow , \Leftrightarrow , =$ belong in this list, together with $\in$.

• I'm not sure how to feel about sets $X$ with $\in \in X$. – Mike F Nov 7 '13 at 19:05
• I've changed it; it bugged me :) – Shaun Nov 7 '13 at 19:16
• That's why I write $\varepsilon \in X$ in my delta-epsilon arguments :) – Caleb Jares Nov 7 '13 at 19:30
• I enjoy the comment that these "belong in this list"... ∈ – Ray Nov 8 '13 at 15:31
• @MikeF I think there aren't enough sets with ${\in}\in X$. :-P – Akiva Weinberger Aug 18 '15 at 1:06

The use of decimal notations for tenths, hundredths ...

When dealing with noninteger number early European mathematicians used sexagesimal fractions

for example Fibonacci gave the solution to the equation $x^3 + 2x^2 + 10x = 20$ as
$1^{\circ}22'07''42'''33^{IV}04^{V}40^{VI}$

From chapter 4.1 of The art of computer programming .

And in fact, this sexagesimal system is still used for minuts and seconds.

Try calculating eg a compound index using such a system!

• Fibonacci's notation nearly just gave me a seizure. – Bruno Joyal Nov 7 '13 at 23:22
• Sexagesimal has the advantage of 60 being highly-composite, with 10 non-trivial divisors, compared to only 7 for 100 and only 2 for 10 itself. Fibonacci's notation is horrible, though. Something like 01;22:07:42:33:04:40 would give the same information with less clutter. – Dan Nov 8 '13 at 0:58
• @Dan: good points about divisors. However for your last point: Fibonnacci's notation straight-away tells it's a sexagesimal number [even many years later], whereas your alternative doesn't – Olivier Dulac Nov 8 '13 at 11:18
• @OlivierDulac But if his had been used, we would know right away. I'd prefer (1.22 07 42 33 04 40)_{60}, though. (Don't know how you get spaces in mathjax, that last bit is meant to be a subscript) – Random832 Nov 8 '13 at 17:42
• Fibonacci also used 'added fractions', or 'continued numerators'. For example, the amount of half a guinea (as shown on the mad hatter's hat) is \frac{10}{20}\frac{6}{12}, the pound being 20 shillings, the hat costs 10 of the same, and the shilling gives twelve pence, the hat needs six of these. So the first fraction is (10 6/12)/20. This, with a string of 10's as the denominator. – wendy.krieger May 3 '15 at 10:28

The equal sign.

The earliest known printed occurrence is Recorde's Whetstone of witte, England, 1557. It was a significant step in the direction of symbolic logic.

Recorde described it as two parallel lines of equal length; according to him nothing could be more equal than that.

• That and also $+$. – John Nov 8 '13 at 15:43
• How is equality expressed before that then? – Heisenberg Nov 9 '13 at 3:55
• ...........Prose. – DanielV Nov 9 '13 at 8:28

One huge innovation that flies so far under the radar that multiple other answers to this question (as well as the question itself!) have used it in one way or another without note: the notation $f(n)$ for (take your pick) expressing the value of the function $f$ at the parameter-value $n$, or applying the function/operator $f$ to the argument $n$. It's probably the single most-used notation in mathematics beyond the basic operations themselves, and I've always found it absolutely amazing that the calculus itself was invented before the standard notation for functions existed.

How about the basics: the notation of basic arithmetic expressions: $+$, $-$, $\times$, $\div$, and their precedence rules and parentheses. And of course "Arabic" numerals (including zero), as @ABC already noted in a comment.

Of course positional notation of numbers with zero.

$\langle \phi | \psi \rangle$

$\langle \phi | A | \psi \rangle$

$| \phi \rangle \langle\psi |$

• Physicists may like this, but I'm not sure that most mathematicians find it an improvement over our usual notation for vectors and operators in Hilbert space. – Nate Eldredge Nov 7 '13 at 19:59
• It's a matter of taste, of course. But for me, when I see $\sum \langle \phi | x \rangle |\phi\rangle$, my first thought is not "matrix multiplication" but rather "parse error, unbalanced delimiters". – Nate Eldredge Nov 7 '13 at 20:28
• @NateEldredge Which version are you running? – Bruno Joyal Nov 8 '13 at 1:58
• I love bra-ket notation. It really adds nothing conceptually to write it as $\langle \phi \mid \psi \rangle$ instead of $\langle \psi , \phi \rangle$, but dang, do I feel cool when I'm doing it. – Alexander Gruber Nov 10 '13 at 1:48
• @swish, you forgot to mention the main reason to use bra-ket notation: all the great identities you get! For instance, $\langle \phi \mid (\mid \psi \rangle) = \langle \phi, \psi \rangle$, and $(\mid \phi \rangle \langle \psi \mid)^* = \mid \psi \rangle \langle \phi \mid$, and the fact that $\mid \phi \rangle \mapsto \langle \phi\mid$ is an isomorphism from $H$ to $H'$, etc. – Julien Clancy Aug 7 '14 at 3:12

The use of $\lambda$ for abstraction, as in Church's $\lambda$-calculus. It may not have improved mathematics generally speaking, but it beautifully complements the notation for application, and it simplified reasoning about currying. It certainly proved useful for computer science, at least.

• Lambda notation does make it clearer that functions are objects independent of their arguments. Syntactically $f=\lambda x. y$ is just solving for $f$ in $f(x)=y$. – Jon Purdy Nov 8 '13 at 3:14
• Related to this would the notation $\mapsto$. – Baby Dragon Nov 8 '13 at 6:43
• Actually the choice of using the symbol $\lambda$ for this is a pretty lousy one, since it is already used as a variable name (and often one of preference: eigenvalues, partitions,...) in many areas. I would argue that this choice, while harmless in the subfield where the notation emerged, has greatly hampered the spread of anonymous function notation throughout mathematics. For what it's worth, I use a notation like $v\mapsto(\alpha\mapsto \alpha(v))$ for the map $V\to V^{**}$ in linear algebra, without feeling much need to explain the notation. – Marc van Leeuwen Nov 8 '13 at 8:33
• Originally it was not supposed to be $\lambda x. x$, but $\hat{x}.x$, as in Russell and Whitehead's Principia Mathematica. Typewriters printed this as $\hat{} x. x$, and $\hat{}$ was mistaken as a $\Lambda$, which then became $\lambda$. – Luca Bressan Nov 8 '13 at 9:20

The only one that comes to mind is the representation of zero.

Going from having to write ML or 1    5      and hoping the omission would allow the number to be understood, to 1050 as an unambiguous representation

Leibniz notation has been immensely useful in the improvement of applied mathematics. The notion of $dx$ denoting infinitesimal increments of a quantity $x$ (while not strictly consistent Newton's limit interpretation) has helped many a scientist arrive at a better intuitive understanding of the relationship between various physical quantities and facilitated modelling of physical processes and objects.

I find Euler and Bernoulli's work in applied math (which prefers Leibniz's notation) speaks for how intuitive Leibniz calculus is compared to the alternative.

How about complex and imaginary number notation: $$a + bi$$

Includes the phase plane representation of vectors $$z = a + bi = |z|\space(\cos( \theta) + i\space \sin (\theta)) = |z| \space e^{i \space \theta}$$

based on one of the more elegant statements in all mathematics, Euler's formula:

$$e^{ix} = \cos(x) + i \space \sin(x)$$

or in a more limited application, a beautiful equation relating the fundamental constants: $\pi,i,e,1,$ and $0$.

$$e^{i\pi} + 1 = 0$$

• If we are talking about improvement, we must replace $2\pi \rightarrow \tau$. It is outrageous that we are stuck with $2\pi$, especially in the context of notation-induced improvements. – Val Nov 8 '13 at 13:07
• Tau is used for a LOT of symbols, it's already stretched extremely thin even in the context of frequency analysis. They should just come up with a new symbol altogether. – DanielV Dec 29 '13 at 5:57
• @Val I'm not an enthusiast of changing $\pi$ to anything else, the pros of switching to a new symbol aren't that great to be honest. – Santiago Aug 25 '16 at 16:32

So - what about fraction notation? Using this:

$$\frac{a+b}{c+d}$$

$$(a+b)\div(c+d)$$

And to some extent anything else that trades vertical space for horizontal compactness, e.g.:

$$\sum^{10}_{x=1}x^2$$

instead of (for example) $\mathrm{sum}(x,1,10,x\uparrow 2)$

The arrow notation invented by Knuth for representing large numbers (i.e. so large that scientific notation isn't practical).

• When'd one use those, though? The universe is estimated to contain only 1e82 particles. – Cees Timmerman Nov 12 '13 at 14:11
• In pure mathematics, analyses and proofs will often require far larger numbers than are tied to any physical reality. See this article about Graham's Number. – JDM Jun 17 '15 at 18:41

The mutli-index notation is used to write tuples and express sums, powers and products of these tuples. The $n$ dimensional multi-index is a $n$-tuple $$\alpha = (\alpha_1, \alpha_2, \alpha_3, \ldots, \alpha_n)$$ with each $\alpha_i > 0$

For multi-indices $\alpha, \beta$ we have

• Component wise summation $$\alpha \pm \beta = (\alpha_1 \pm \beta_1, \alpha_2 \pm \beta_2, \ldots, \alpha_n \pm \beta_n)$$
• For $x = (x_1, x_2, \ldots, x_n) \in \mathbb{R}$, we have $$x^\alpha = x_1^{\alpha_1}x_2^{\alpha_2}\ldots x_n^{\alpha_n}$$
• Partial derivatives $$\partial^\alpha = \partial_1^{\alpha_1}\partial_2^{\alpha_2}\ldots \partial_n^{\alpha_n}$$ where each $\partial_i^{\alpha_i} = \partial^{\alpha_i}/\partial x_i ^{\alpha_i}$.

This notation helps in topics such as functional analysis and pseudo differential operators. Look at the Wikipedia article for more examples

• I've edited my answer. – Tyler Hilton Nov 8 '13 at 6:38
• Actually, the idea of using indices for a whole bunch of different values instead of letters of some alphabet is a groundbreaking revolution in my opinion. – rwols Nov 9 '13 at 0:02

The switch from Roman to Arabic numerals has to be a fundamental improvement.

Try to calculate IL divided by VII !!

I like the French invention ∃! to designate unicity. It is nicely useful in mathematics but is not universally used. There are a lot of illustrations of this ("∃x such that f(x) is something and this x is unique" changes by "∃!x such that f(x) is something" or "Prove that ∃!x such that something". A professor of University of Toledo (Ohio) adopted this notation after I mentioned it).

Matrix notation: Ax=mx, A*=(P^-1)BP etc.., block matrices. Without it it will be very hard to express these operations.

Conspicuous by its absence among the above answers is any celebration of the usual notation for multiplication.

I love the exclamation mark for factorial

x! = 1 * 2 * .. * x

because of the way that bang indicates intensity in natural language. Seems quite fitting to its fast growth.

Coxeter co-joined Stott's operator and Schläfli's description of regular polytopes into a combined notation that is used to this day.

Stott wrote the truncated icosahedron as e_1 I. Wythoff wrote it as t_0,1 I. Coxeter writes it as t_0,1 {3,5}. Krieger writes it as x3x5o. If one wants to write the figure where the inter-hexagon edge is phi, then only Krieger's notation works: f3x5o.

I greatly revamped the notation in terms of vectors and phase-space the effect is similar from going from roman notation to digital forms, and with the new notation, we describe figures well past the scope of Coxeter's Stott-Schläfli construction.