The concepts underlying these kinds of transformations are more easily seen by first looking at a one dimensional case. The image here shows a square wave along with several of the first terms of an infinite series. Looking at it, note that if the functions for the terms are added together, they begin to approximate the shape of the square wave. The more terms you add up, the better the approximation. But, to get from an approximation to the exact signal, you have to sum an infinite number of terms. The reason for this is that the square wave is discontinuous. If you think of a square wave as a function of time, it goes from -1 to 1 in zero time. To represent such a thing requires an infinite series. Take another look at the plot of the series terms. The first is red, the second yellow. Successive terms have more "up and down" transitions. These are from the increasing frequency of each term. Sticking with the square wave as a function of time, and each series term a function of frequency there are two equivalent representations: a function of time and a function of frequency (1/time).

In the real world, there are no square waves. Nothing happens in zero time. Audio signals, for example occupy the range 20Hz to 20KHz, where Hz is 1/time. Such things can be represented with finite series'.

For images, the mathematics are the same, but two things are different. First, it's two dimensional. Second the notion of time makes no sense. In the 1D sense, the square wave is merely a function that gives some numerical value for for an argument that we said was time. An (static) image is a function that gives a numerical value for for every pair of row, column indeces. In other words, the image is a function of a 2D space, that being a rectangular region. A function like that can be represented in terms of its spatial frequency. To understand what spatial frequency is, consider an 8 bit grey level image and a pair of adjacent pixels. The most abrupt transistion that can occur in the image is going from 0 (say black) to 255 (say white) over the distance of 1 pixel. This corresponds directly with the highest frequency (last) term of a series representation.

A two dimensional Fourier (or Cosine) transformation of the image results in an array of values the same size as the image, representing the same information not as a function of space, but a function of 1/space. The information is ordered from lowest to highest frequency along the diagonal from the origin highest row and column indeces. An example is here.

For image compression, you can transform an image, discard some number of higher frequency terms and inverse transform the remaining ones back to an image, which has less detail than the original. Although it transforms back to an image of the same size (with the removed terms replaced by zero), in the frequency domain, it occupies less space.

Another way to look at it is reducing an image to a smaller size. If, for example you try to reduce the size of an image by throwing away three of every four pixels in a row, and three of every four rows, you'll have an array 1/4 the size but the image will look terrible. In most cases, this is accomplished with a 2D interpolator, which produces new pixels by averaging rectangular groups of the larger image's pixels. In so doing, the interpolation has an effect similar throwing away series terms in the frequency domain, only it's much faster to compute.

To do more things, I'm going to refer to a Fourier transformation as an example. Any good discussion of the topic will illustrate how the Fourier and Cosine transformation are related. The Fourier transformation of an image can't be viewed directly as such, because it's made of complex numbers. It's already segregated into two kinds of information, the Real and Imaginary parts of the numbers. Typically, you'll see images or plots of these. But it's more meaningful (usually) to separate the complex numbers into their magnitude and phase angle. This is simply taking a complex number on the complex plane and switching to polar coordinates.

For the audio signal, think of the combined sin and cosine functions taking an attitional quantity in their arguments to shift the function back and forth (as a part of the signal representation). For an image, the phase information describes how each term of the series is shifted with respect to the other terms in frequency space. In images, edges are (hopefully) so distinct that they are well characterized by lowest frequency terms in the frequency domain. This happens not because they are abrupt transitions, but because they have e.g. a lot of black area adjacent to a lot of lighter area. Consider a one dimensional slice of an edge. The grey level is zero then transitions up and stays there. Visualize the sine wave that woud be the first approximation term where it crosses the signal transition's midpoint at sin(0). The phase angle of this term corresponds to a displacement in the image space. A great illustraion of this is available here. If you are trying to find shapes and can make a reference shape, this is one way to recognize them.