As a high school teacher, I sometimes wonder about the usefulness of certain topics. Some topics seem to be in the textbook because they have always been there, not because they lead anywhere interesting.

For instance, I am fairly sure that rhombuses and kites are pretty useless. In fact, once you get past alt-int angles, parallelograms are not horribly useful later. I do not recall needing any of this in any math afterwards, at least up to and including calculus.

Since I have been told to cut out some geometry to make way for statistics / probability, it seems to me that rhombuses, kites and a good lot of parallelograms are perfect candidates for the chopping block.

Am I right? Or do rhombuses and kites turn out to be really useful in the conceivable future of any random student? I am not denying their beauty etc.

If proofs could be be put back into the state test, of course, rhombuses etc. would just be more practice in proofs.

A rhombus is a quadrilateral with four congruent sides (which must be a parallelogram), and a kite is a quadrilateral with two pairs of adjacent congruent sides. Useful facts about rhombuses are that their diagonals are perpendicular to each other and also that the diagonals bisect the angles of the rhombus.

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    $\begingroup$ I see the use in helping students understand definitions and quantifiers; many high school students STILL struggle with the classification of quadrilaterals and recognizing that, for example, every square is a rectangle, but not every rectangle is a square. This facility with language (not just mathematical language) is very important for a logical thinker to have, and I have found that quadrilaterals lead to the best opportunity to develop it in geometry. $\endgroup$
    – Opal E
    Commented Jul 11, 2019 at 19:30
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    $\begingroup$ Students who will encounter vectors will also encounter parallelograms in one of the standard definitions of vector addition and in the connection between areas and 2-by-2 determinants. $\endgroup$ Commented Jul 11, 2019 at 20:13
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    $\begingroup$ The same question on math.se math.stackexchange.com/questions/3290170/… $\endgroup$
    – user5402
    Commented Jul 11, 2019 at 22:06
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    $\begingroup$ Related math.stackexchange.com/questions/650161/… $\endgroup$
    – user5402
    Commented Jul 11, 2019 at 22:07
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    $\begingroup$ @OpalE -- Your comment would make a good answer. $\endgroup$
    – Jasper
    Commented Jul 12, 2019 at 22:00

8 Answers 8


Parallelograms are useful for understanding:

  • Paths taken by light, especially through a layer of a medium with a different refractive coefficient
  • Shear, and related deformations
  • Area = height * width (but not necessarily the product of the sides' lengths)
  • Dot products
  • Surface integrals

Paths taken by light are useful for understanding which routes people and other animals will take to minimize their effort.

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    $\begingroup$ I use parallelograms to explain "git rebase." $\endgroup$
    – shoover
    Commented Jul 12, 2019 at 16:45

The following remarks do little more than amplify on a comment made above by Andreas Blass.

A basic use of parallelograms is to represent the sum of vectors in the plane as the diagonal of the parallelogram they determine.

Visualizing the action of a linear transformation of the plane can be achieved by examining the parallelogram determined by the images of the standard basis vectors. This is helpful for understanding the qualitatively different sorts of linear transformations.

Another use of parallelograms is when one formalizes notions such as area and volume, as is typically done in university courses in linear algebra and calculus. The best way to define the determinant of a $2 \times 2$ matrix is as the signed area of the parallelogram generated by the rows (or columns) of the matrix. The basic properties of the determinant - its antisymmetry and linearity in the rows/columns of the matrix and its behavior with respect to elementary row operations can be interpreted in terms of orientations of parallelograms and cutting and pasting parallelograms and their subtriangles. All of this is useful for students who will study things such as the theorems of Green/Stokes, surface integrals, and so forth, and need to assimilate notions such as orientation and signed area. For example, motivating the definition of the integral of a function over a surface by constructing a Riemann sum approximating a parametric form of the integral requires interpreting the summands of the Riemann sum as areas of infinitesimal parallelograms in planes tangent to the surface.


I am just now close to completing my first time teaching geometry (at a community college, a course that parallels the typical high school course) Using the fact that parallelograms (and hence rhombuses) have bisecting diagonals makes a short proof for why the line segment midpoint construction works. Other than that, I don't see rhombuses as a big part of geometry. I would keep some of parallelograms in. Have you looked at the common core standards to see which topics are meant to be kept?

Henri Picciotto, a former high-school teacher and (current) curriculum developer, has written a well-thought out pair of blog posts, In Defense of Geometry, which you might find useful.

  • $\begingroup$ I wish I could upvote, but Henry mentioning NCTM positively and suggesting teaching fractals in public school (a topic that requires university-level education) did not jive with my outlook on school math education. $\endgroup$
    – Rusty Core
    Commented Jul 11, 2019 at 21:09
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    $\begingroup$ @RustyCore I'm not sure why you believe that "teaching fractals" (whatever that phrase means) requires a university-level education. Give me any topic in mathematics (with which I, personally, have sufficient knowledge), and I can prepare a lesson that I can teach to middle schoolers, and I can also prepare a lesson which might give some PhDs a hard time (elementary topics can become research level topics very quickly). I have a 50 minute "Introduction to Dimension Theory" talk that I have given successfully to high school freshman and sophomores in the past which touches on fractal geometry. $\endgroup$
    – Xander Henderson
    Commented Jul 11, 2019 at 21:58
  • $\begingroup$ @XanderHenderson He says that he does not don’t "the underlying mathematics" of statistics, yet he is going to teach high school students topology? Hausdorff dimension? Extended real numbers? I don't think so. It will be an overview with pretty pictures at best, all at the cost of removing either Algebra II or Geometry topics. This is not what public school students need. They need instead a coherent curriculum without repetitions and omissions, not some fancy stuff that school teachers know nothing about. $\endgroup$
    – Rusty Core
    Commented Jul 12, 2019 at 2:46
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    $\begingroup$ You can have your opinions, but his work is stellar, and helped me teach a good course. $\endgroup$
    – Sue VanHattum
    Commented Jul 12, 2019 at 2:49

I am quite surprised by the suggestion (and apparent consensus?) that kites and rhombi are not very important for high school geometry. Here are three entirely different arguments for why they should, in fact, play a central role in the curriculum.

Argument 1: Understanding hierarchical relationships. One of the goals of secondary Geometry is to help students move from a basic conception of "shapes" as individual objects to a more sophisticated notion of "shapes" as generic representatives of categories of objects, and a corresponding focus on the relationships among those categories. (For those who are familiar with the old Van Hiele language for describing geometric understanding, I am talking about the transition from Level 1 to Level 2 and Level 3.).

Students who do not make this transition may fail to understand, for example, that a proof of a property of isosceles trapezoids applies not only to the specific trapezoid represented in a particular diagram, but to any isosceles trapezoid satisfying the hypotheses of the theorem. (See for example Chazan, 1993, particularly at p. 372.)

At a basic level, the goal here is to move students from simpler statements about individual figures ("This is a rectangle because it has four right angles") to claims about nesting of one category of figures inside another category ("All squares are rectangles, but not all rectangles are squares"), with deductive proof making it possible to generalize from a generic case to the category of which it is a representative. At a more advanced level, students are expected to develop an understanding of a hierarchical relationship among types of figures, as shown below. (Image source)

hierarchical model of quadrilaterals

Thus for example students should know (and be able to prove!) conditional statements like the following examples:

  • If $ABCD$ is both a rectangle and a rhombus, then it is a square (and conversely if $ABCD$ is a square then it is both a rectangle and a rhombus)
  • If $ABCD$ is both a parallelogram and a kite, then it is a rhombus (and conversely if it is a rhombus then it is both a parallelogram and a kite).
  • If $ABCD$ is both an isosceles trapezoid and a parallelogram, then it is a rectangle (and conversely...)
  • Every rectangle is a parallelogram (but not every parallelogram is a rectangle); every rhombus is a parallelogram (but not every parallelogram is a rhombus); every parallelogram is a trapezoid (but not every trapezoid is a parallelogram); every trapezoid is a quadrilateral (but not every quadrilateral is a trapezoid).
  • etc.

Note by the way that in the classification scheme shown above, different types of quadrilaterals are defined inclusively, rather than exclusively. Not all curricula follow this convention consistently; for a historical perspective on quadrilateral definitions and classification, see my answer to a related question.

Now if we were to stipulate, for the sake of discussion, that understanding these hierarchical relationships is one of the goals of the curriculum, consider what would happen if the categories of "kite" and "rhombus" were removed or omitted. Roughly 1/3 of the diagram above, and a corresponding number of hierarchical relationships would simply disappear -- there would be no way to even talk about them! We need kites and rhombi in the lexicon so that we can have a fully-developed theory of quadrilaterals.

Argument 2: Analyzing how quadrilaterals are like, and unlike, triangles. In the standard sequence of the Geometry course, students first study triangles, which they learn to classify into types according to two different schemes:

  1. When classifying by side lengths, every triangle is either scalene, isosceles, or equilateral.
  2. When classifying by angle measures, every triangle is either acute, obtuse, or right.

These two different classification schemes interact in complicated ways: a right triangle can be scalene or isosceles; an isosceles triangle can be acute, obtuse, or right; and so on. However, some combinations are impossible. For example, an equilateral triangle cannot be right or obtuse, because of the following theorem:

Theorem. All equilateral triangles are equiangular, and conversely all equiangular triangles are equilateral.

This theorem is a corollary of the Base Angles Theorem and the Triangle Sum Theorem, the proofs of which rely on fundamental properties of parallels and triangle congruence; it is therefore a kind of capstone result for the "triangles unit".

When students move from triangles to quadrilaterals, the situation is suddenly very different. A quadrilateral may be equilateral without being equiangular, or conversely may be equiangular without being equilateral! This is an extremely important idea, one that is very counterintuitive for may students; anecdotally, I can report that many of the high school students I have tutored believe that if you know a quadrilateral has four congruent sides, it must be a square. Informally, the reason this is not true is because quadrilaterals, unlike triangles, are not rigid; there is no "SSSS Congruence" property for quadrilaterals. (See the question, and my answer, at "What is the precise definition of a rigid shape?".)

So we need names for quadrilaterals that are equiangular (but not necessarily equilateral), and for quadrilaterals that are equilateral (but not necessarily equiangular). We call the first type a "rectangle", and we call the second type a "rhombus".

Similarly if we try to generalize the notion of "isosceles triangle" to the quadrilateral case, we might say (as a first attempt) that we are interested in figures in which some, but not all, of the sides are congruent. On further reflection we realize that there are two worthwhile possibilities to consider here:

  • If two pairs of opposite sides are congruent, we have a parallelogram.
  • If two (disjoint) pairs of adjacent sides are congruent, we have a kite.

Argument 3: Transformation-based approaches to Geometry. I'll be briefer about this one, because transformation-based approaches to Geometry, while common internationally, are still somewhat rare in U.S. curricula (see p. 204 of this book for a brief discussion of the history of such approaches in the secondary curriculum), despite the fact that the Common Core State Standards emphasize them as fundamental.

In a transformation-based approach, figures are classified according to the types of symmetry they have. For example, isosceles triangles have exactly one line of symmetry; equilateral triangles have three. With quadrilaterals, again, things are more complicated:

  • A quadrilateral with two lines of symmetry that pass through the midpoints of its sides is a rectangle.
  • A quadrilateral with two lines of symmetry that pass through its vertices is a rhombus.
  • A quadrilateral with one line of symmetry that passes through the midpoints of (two of) its sides is an isosceles trapezoid.
  • A quadrilateral with one line of symmetry that passes through (two of) its vertices is a kite.

There is an important analogy lurking in the above observations: kites and rhombi are, in an important way, dual to isosceles trapezoids and rectangles.

Concluding thoughts:. There is more that could be said on this; for example, one very fruitful avenue of student exploration is to study what kind of figure is produced when one joins together the midpoints of the sides of a quadrilateral. (See here, here, and here for some examples.) This is variously referred to as the "dual" or "midpoint polygon" construction. Some very interesting results can be discovered and proved by students; for example:

  • The dual of any quadrilateral is a parallelogram
  • The dual of any rectangle is a rhombus
  • The dual of any rhombus is a rectangle
  • Therefore the dual of a square is a square
  • The double-dual of a rhombus is another rhombus; the double-dual of a rectangle is another rectangle
  • More generally the double-dual of a parallelogram is another parallelogram similar to the original
  • The dual of an isosceles trapezoid is also a rhombus
  • The dual of a kite is also a rectangle
  • etc.

Without rhombi and kites these kinds of investigations become essentially impossible.

TL;DR: if rhombi and kites did not exist, we would need to invent them in order to answer basic questions about the relationships among the other types of quadrilaterals. Trying to do geometry without them would be like trying to teach algebra without the words "slope" or "quadratic".

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    $\begingroup$ I agree that rhombi and kites should be an important part of the geometry curriculum. I have been bothered by the OP ever since it was posted. The implication is that we must defend on the basis of "usefulness," which is antithetical to all the reasons we want people to learn geometry. Your Argument 1 is important. Removing some figures in the hierarchical diagram is like deciding to play poker without straights and full houses. If you do this, the intellectual connections collapse and it's not interesting. We would end up re-inventing them, or stop playing the game altogether. $\endgroup$
    – user52817
    Commented Jan 6, 2021 at 1:06

I would keep the parallelograms. Too much application in SAT questions--they love the vertical angle theorem.

Agreed on ditching kites and rhombuses. (In the interest of time.) I have never used them in engineering, physics, other math classes that support engineering/science. Actually, I don't even remember covering them much in 1980s geometry. If we did, it was super quick (a day at most).

You could also probably cut solid geometry some (even though this pains me to see this--just give them a handout with the mensuration formulas and don't even test it).

Really, even proofs could be cut. (I'm not saying to cut it all...but if the point is exposure to proofs, do you really need so much for "exposure".) Geometry is such a diversion from the other courses in their headlong build towards calculus.

Anyone saying to keep the topics, ought to suggest other places to cut. Hours are zero sum. And not doing the stats doesn't sound like an option. But it would help if you told us how many days you are trying to free up (how long spending on stats).

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    $\begingroup$ The question for me is, how much time is saved by skipping these couple figures? I graduated HS in ‘80, and don’t recall “kites”, but seeing they were in the curriculum in ‘13 didn’t bother me. ‘Rhombus’? A parallelogram with equal sides. 2 extra seconds to the lecture. (So, +1 for well articulated answer that I sort of agree with) $\endgroup$ Commented Jul 15, 2019 at 0:16
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    $\begingroup$ @JoeTaxpayer More than the definition is taught. Properties of a rhombus are also taught, e.g. the diagonals of a rhombus bisect each other at right angles, to find the area multiply the lengths of a diagonal and divide by 2, etc. There are many problems with these properties. $\endgroup$
    – Amy B
    Commented Jul 25, 2019 at 5:43
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    $\begingroup$ The SAT argument seems to be highly localized to a given culture. An argument related to the content would be better. $\endgroup$
    – Tommi
    Commented Jan 4, 2021 at 10:25

It would be hard to say what you could get rid of without knowing what is on your state test. In my state (NY), they push quads quite a bit. I'll grant you that kites aren't interesting or important, but rhombuses are both.

One of the usual capstone problems is being given the coordinates of four points and demonstrating that the quadrilateral formed from the vertices is a rhombus but not a square. That's a pretty strong review question; it measures skill on the slope and distance formulas, interpreting those results in the context of congruent and parallel/perpendicular line segments, and then interpreting THOSE results in quadrilateral language.

Another sample problem: if a rhombus has diagonals of 10 and 24 inches, what is its perimeter? Again, a lot of facts that you'd need to work that out: the diagonals of any parallelogram bisect each other, all rhombuses are parallelograms, the diagonals of a rhombus are perpendicular, so you can use the Pythagorean theorem to solve for the side length, and then all sides of a rhombus are congruent so you can find the perimeter.

Obviously, as other responses demonstrate, even STEM-based professionals lead fulfilling and successful careers without remembering these facts. But I don't begrudge the Common Core and New York State for expecting my students to master them. Understanding that there are conditions for determining that a quadrilateral is of a special type and there are implications for knowing that a quadrilateral is of a special type is the sort of applied logic that is so often used in the real world and so infrequently nurtured in students.


OP: "I am fairly sure that rhombuses and kites are pretty useless."

Understanding parallelograms and rhombi is quite useful in pop-up card design:


Constructed by Ian Agol. Twitter link; "inspired by @divbyzero's tweet." 19Dec2020.


The observation that a rhombus's diagonals bisect its internal angles gives rise to an efficient method to find an angle bisector.

Here, a British national-exam question hints this method to the candidate:enter image description here

  • $\begingroup$ Ha! When i read this question some time ago, I was thinking that I use parallelograms in describing construction of vectors, but I never posted an answer. And here we are. Interesting observation. $\endgroup$ Commented Jan 3, 2021 at 17:01

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