Proof without words

In mathematics, a proof without words (or visual proof) is an illustration of an identity or mathematical statement which can be demonstrated as self-evident by a diagram without any accompanying explanatory text. Such proofs can be considered more elegant than formal or mathematically rigorous proofs due to their self-evident nature.^[1] When the diagram demonstrates a particular case of a general statement, to be a proof, it must be generalisable.^[2]

A proof without words is not the same as a mathematical proof, because it omits the details of the logical argument it illustrates. However, it can provide valuable intuitions to the viewer that can help them formulate or better understand a true proof.

Examples

Sum of odd numbers

The statement that the sum of all positive odd numbers up to 2n − 1 is a perfect square—more specifically, the perfect square n²—can be demonstrated by a proof without words.^[3]

In one corner of a grid, a single block represents 1, the first square. That can be wrapped on two sides by a strip of three blocks (the next odd number) to make a 2 × 2 block: 4, the second square. Adding a further five blocks makes a 3 × 3 block: 9, the third square. This process can be continued indefinitely.

Pythagorean theorem

The Pythagorean theorem that $a^{2}+b^{2}=c^{2}$ can be proven without words.^[4]

One method of doing so is to visualise a larger square of sides $a+b$ , with four right-angled triangles of sides $a$ , $b$ and $c$ in its corners, such that the space in the middle is a diagonal square with an area of $c^{2}$ . The four triangles can be rearranged within the larger square to split its unused space into two squares of $a^{2}$ and $b^{2}$ .^[5]

Jensen's inequality

Jensen's inequality can also be proven graphically. A dashed curve along the X axis is the hypothetical distribution of X, while a dashed curve along the Y axis is the corresponding distribution of Y values. The convex mapping Y(X) increasingly "stretches" the distribution for increasing values of X.^[6]

Usage

Mathematics Magazine and the College Mathematics Journal run a regular feature titled "Proof without words" containing, as the title suggests, proofs without words.^[3] The Art of Problem Solving and USAMTS websites run Java applets illustrating proofs without words.^[7]^[8]

Compared to formal proofs

For a proof to be accepted by the mathematical community, it must logically show how the statement it aims to prove follows totally and inevitably from a set of assumptions.^[9] A proof without words might imply such an argument, but it does not make one directly, so it cannot take the place of a formal proof where one is required.^[10]^[11] Rather, mathematicians use proofs without words as illustrations and teaching aids for ideas that have already been proven formally.^[12]^[13]

Notes

References

Dunham, William (1994), The Mathematical Universe, John Wiley and Sons, ISBN 0-471-53656-3
Nelsen, Roger B. (1997), Proofs without Words: Exercises in Visual Thinking, Mathematical Association of America, p. 160, ISBN 978-0-88385-700-7
Nelsen, Roger B. (2000), Proofs without Words II: More Exercises in Visual Thinking, Mathematical Association of America, pp. 142, ISBN 0-88385-721-9
Gulley, Ned (March 4, 2010), Shure, Loren (ed.), Nicomachus's Theorem, Matlab Central.

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