# Why use the word Quadratic?

While talking about different types of equations, a student in my class asked: Why we use the word quadratic to refer to second-degree equations?

Here is some context:

1) Linear ($x^1$) equations make sense, because the graph of a linear equation is a straight line.

2) Exponential ($a^x$) equations make sense, because $x$ is in the exponent, and my students will soon learn to recognize graphs of exponential equations.

3) Cubic ($x^3$) equations make sense, because $x$ is being cubed, and my students will soon learn to recognize graphs of cubic equations.

... so why do we use the word "quadratic" to refer to second degree equations? My students already know that the graph of a quadratic equation can be called a "parabola," and the word QUADratic sounds like it has something to do with the number four, rather than squaring.

Follow up question: Would it be better to call $x^2$ equations "parabolic" referring to the shape they make when graphed? Or why not call them "squared" equations in the same way we use for higher-degree equations?

• To expand on @MichaelE2: For "biquadratic" one needs to be careful what is meant. It can mean quartic (degree 4), yet this is now very rare. More frequently it means an equation of the form $a x^4 + b c^2 + c =0$, in this sense it is somewhat common in some contexts such as field extensions/Galois theory.
– quid
Apr 28 '14 at 14:30
• Possibly duplicate: english.stackexchange.com/questions/151217/… Apr 28 '14 at 15:09
• I suggest that you use the word coined by Robert Recorde in his ground-breaking work The Whetstone of Witte, which is also famous for having introduced the $=$ sign. The word Recorde used deserves to be revived. It is “zenzic”. Apr 28 '14 at 17:24
• I would not use "parabolic equation" as that already has a meaning in higher mathematics. The linear heat equation, for example, is a parabolic equation. Apr 28 '14 at 18:20
• A similar issue: we know from linear algebra that a linear function from $\mathbb{R}$ to $\mathbb{R}$ is actually a function of the form $x\mapsto ax$ for some $a\in\mathbb{R}$; a function of the form $x\mapsto ax+b$ for some $a,b\in\mathbb{R}$ is an affine function. Now try to go and change all the elementary math textbooks... There are more things like that. Part of mathematical maturity is getting used to such ambiguities. Apr 29 '14 at 10:26

The situation for quadratic equations is in one sense exactly analogous to the one for cubic equations, except that for reasons of the development of the language some discrepancy between square, squaring and related and quadratic arose.

I am not well placed to discuss this in English but see on the English.SE site for the etymology of "quadratic": Why does “quadratic” describe second power while “quad” usually describes “four”?

Also, note that in other languages this split did not happen. In German a square is a "Quadrat," and to square is "quadrieren," and quadratic is "quadratisch." In fact from the link above it seems to quadrate was used in English too (long ago).

Thus the naming linear, quadratic, cubic follows the logic line, square, cube (as said by Joe Taxpayer) only that the development of language took one of the terms slightly apart.

I would rather advise against using the terminology parabolic equation, because this in fact breaks the logic of the naming. To add the "s" and to call them something like squared equations, as you propose, would seem relatively better to me, though also not good.

If you want to avoid any naming issues I suggest to call them first degree, second degree, third degree equations.

To sum this up: Either explain the origin of the terminology to make the (hidden) logic clear or use a simple systematic naming. But avoid introducing the term parabolic in this context.

• Indeed, "parabolic equations" have a completely different meaning in theory of PDEs. Apr 28 '14 at 11:12
• I much prefer the terminology of first/second/third degree. Apr 28 '14 at 11:25
• Not to mention, a 'quadrangle' is still an English word for a square (with some tolerance for rectangles that are close to being square in practice). Many large older buildings in the UK have quadrangles (usually shortened to 'quad'), which are square(ish) internal courtyards, usually with a pristine lawn. Apr 28 '14 at 20:20
• Another connection in (mathematical) English between "quadrat..." and "square" is that "quadrature" means finding areas (or, more generally, integrals), so that "quadrature of the circle" is the same problem as "squaring the circle". May 3 '14 at 18:20

It may be as simple as the fact that the word quadratic derives from the Latin quadratus which means square. A square has 4 sides, but the word squared is used to mean "to the power of 2".

To answer the follow on - No. Changing anything means re-writing the complete body of text to use the new designation, and un-learning the old definitions for all existing students. See discussion of tau vs pi.

• "un-learning the old definitions for all existing students" That's only required if there's ambiguity. Oct 6 '19 at 19:21

When something has a standard name, use the standard name, especially when it's something so fundamental. Calling quadratic equations anything other than quadratic equations just means you end up with a class of students who become confused when they discuss quadratic equations with anyone who wasn't taught by you (i.e., almost everybody else on the planet).

As mentioned in the other answers, explaining to your students why the term "quadratic" is used, should help them to remember and understand it.

Quoting Wikipedia:

Summarizing succinctly: Consider objects of side-length $a \in \mathbb{R}^{+}$.

$a^1$ gives the size ("length") of a line segment, hence linear.

$a^2$ gives the size ("area") of a square, hence squared.

$a^3$ gives the size ("volume") of a cube, hence cubed.

• Valuable in its brevity. Apr 28 '14 at 23:10

I don't have any scholarly justification for this suggestion, but it seems very plausible that quadratic equations are so called because they split the rectangle up into quadrants as so Obviously not all quadratics can be expressed in the form $(x+a)(x+b),$ but the ones that were considered solvable when the word quadratic was first being used (i.e. before the invention/acceptance of imaginary numbers) all could.

Edit:

Here's an idea. Cubes are bounded by $6$ faces, so let's call $x^{3}$ a hexic. No, wait. That should be $x^{6},$ surely. In which case $x^{3}$ should be called... triadic? Or even better, $x^{4}$ could be called a tesseractic!

I'm only half joking here. The point is that trying to create too profound a link between the language used to describe things and the things themselves can result in linguistic or logical hiccups. Squares have a lot to do with the number four, it being the number of vertices, edges, lines of symmetry and number of rotational symmetries, but this breaks down for cubes, and so the language instead settled on extending the verb 'cubed' into the adjective 'cubic'. Poor language, it tries so hard to be non-arbitrary, but it was seduced by the 'fourness' of squares when, really, two is the more important number.

• This is what I always thought the answer was ... The standard form of a parabola is just a quadratic that simplifies into three monomials ... But if you expand it into its geometric representations, it represents four sides and I believe the name stems from this representation. It always seemed obvious to me ... now it seems less so Apr 29 '14 at 0:11
• "I disclaim that I don't have..." Does this mean that you "have"? :)
– user386
May 2 '14 at 12:50
• It looks that way, doesn't it? I'll change it because it's not clear what I'm trying to say there; 'exclaim' would be more sensible, but then it just sounds pretentious! Thanks. And :P
– Shai
May 3 '14 at 14:01