Place a coin on it on its side and set it spinning. Take some butter and spread it over a slice of bread. Pick up an elastic band and stretch it. In each of these cases we do something that affects the shape or orientation of the object in question. The elastic band and butter have been deformed and the coin has been rotated.
When we investigate transformations mathematically we find that there are directions that remain the same after the deformation has occurred. In the case of the stretching of the elastic band, if you had drawn an arrow on the band before you stretched it, would it point in the same direction afterwards ? The answer depends on how you drew the original arrow (see the diagram.) The transformation preserves the direction in which you stretch the band but some other arrows have their direction changed. The preserved direction is called an EIGENVECTOR of the transformation and the associated amount by which it has been stretched is an EIGENVALUE.
Eigenvalues are multipliers. They are numbers that represent how much stretching has taken place or, in other words, how much something has been scaled up by. In the sentence 'I am 3.2 times taller than when I was born' the number 3.2 is acting as an eigenvalue.
To make sense of an eigenvalue it must have an associated 'operation' (the transformation that has occurred) and an associated 'direction' (the eigenvector). It doesn't mean anything by itself to say that 3.2 is an eigenvalue. You need to know the operation 'enlarged' and the direction "up" to say that I am now 3.2 times bigger in the up-direction !
If you rotate a coin by 360 degrees you preserve all directions and so each direction is an eigenvector. Because no stretching has occurred, all of these eigenvectors have eigenvalue 1. Rotating the coin by 60 degrees destroys all directions and this transformation has no eigenvectors or eigenvalues at all. Careful spreading of butter on bread, by moving the knife in one direction only, is a transformation with an eigenvector in the direction of spreading. The associated eigenvalue depends on how far the butter is spread. The elastic band in the picture has an eigenvector in the left-right direction because that arrow still points in that direction after the transformation. The band has been stretched by approximately the same amount that I have grown since I was born - so the eigenvector has eigenvalue 3.2 !
The idea of eigenvalues and eigenvectors can be extended to any operator H. (H might be 'rotate by 360 degrees' or 'stretch in direction of y-axis' or operators in Quantum theory or elsewhere). We write H(x) to mean 'the action of H on x'. (So x might be a particular vector that we are rotating or stretching or it might be a quantum state or some other object). If we can find an object x and a number k so that the following equation is true:
H(x) = k * x
Then we know that x has been preserved by H apart from a scalar multiplier k. It is k times bigger than what it was before H acted upon it. Therefore we call x an eigenvector of H with eigenvalue k.
Answered by:
Sally Riordan, Management Consultant, London
'The strength and weakness of physicists is that we believe in what we can measure. And if we can't measure it, then we say it probably doesn't exist. And that closes us off to an enormous amount of phenomena that we may not be able to measure because they only happened once. For example, the Big Bang. ... That's one reason why they scoffed at higher dimensions for so many years. Now we realize that there's no alternative... '