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Fractal Image Compression: What's it all About?Seven things you should know about Fractal Image Compression (assuming that you want to know about it).
That's the scoop in condensed form. Now to elaborate, beginning with a little background. A Brief History of Fractal Image CompressionThe birth of fractal geometry (or rebirth, rather) is usually traced to IBM mathematician Benoit B. Mandelbrot and the 1977 publication of his seminal book The Fractal Geometry of Nature. The book put forth a power ful thesis: traditional geometry with its straight lines and smooth surfaces does not resemble the geometry of trees and clouds and moun tains. Fractal geometry, with its convoluted coastlines and detail ad infinitum, does. This insight opened vast possibilities. Computer scientists, for one, found a mathematics capable of generating artificial and yet realistic looking landscapes, and the trees that sprout from the soil. And mathe maticians had at their disposal a new world of geometric entities. It was not long before mathematicians asked if there was a unity among this diversity. There is, as John Hutchinson demonstrated in 1981, it is the branch of mathematics now known as Iterated Function Theory. Later in the decade Michael Barnsley, a leading researcher from Georgia Tech, wrote the popular book Fractals Everywhere. The book presents the mathematics of Iterated Functions Systems (IFS), and proves a result known as the Collage Theorem. The Collage Theorem states what an Iterated Function System must be like in order to represent an image. This presented an intriguing possibility. If, in the forward direction, fractal mathematics is good for generating natural looking images, then, in the reverse direction, could it not serve to compress images? Going from a given image to an Iterated Function System that can generate the original (or at least closely resemble it), is known as the inverse problem. This problem remains unsolved. Barnsley, however, armed with his Collage Theorem, thought he had it solved. He applied for and was granted a software patent and left academia to found Iterated Systems Incorporated (US patent 4,941,193. Alan Sloan is the co-grantee of the patent and co-founder of Iterated Systems.) Barnsley announced his success to the world in the January 1988 issue of BYTE magazine. This article did not address the inverse problem but it did exhibit several images purportedly compressed in excess of 10,000:1. Alas, it was a slight of hand. The images were given suggestive names such as "Black Forest" and "Monterey Coast" and "Bolivian Girl" but they were all manually constructed. Barnsley's patent has come to be derisively referred to as the "graduate student algorithm." Graduate Student Algorithm o Acquire a graduate student. o Give the student a picture. o And a room with a graphics workstation. o Lock the door. o Wait until the student has reverse engineered the picture. o Open the door. Attempts to automate this process have continued to this day, but the situation remains bleak. As Barnsley admitted in 1988: "Complex color images require about 100 hours each to encode and 30 minutes to decode on the Masscomp [dual processor workstation]." That's 100 hours with a _person_ guiding the process. Ironically, it was one of Barnsley's PhD students that made the graduate student algorithm obsolete. In March 1988, according to Barnsley, he arrived at a modified scheme for representing images called Partitioned Iterated Function Systems (PIFS). Barnsley applied for and was granted a second patent on an algorithm that can automatically convert an image into a Partitioned Iterated Function System, compressing the image in the process. (US patent 5,065,447. Granted on Nov. 12 1991.) For his PhD thesis, Arnaud Jacquin implemented the algorithm in software, a description of which appears in his landmark paper "Image Coding Based on a Fractal Theory of Iterated Contractive Image Transformations." The algorithm was not sophisticated, and not speedy, but it was fully automatic. This came at price: gone was the promise of 10,000:1 compression. A 24-bit color image could typically be compressed from 8:1 to 50:1 while still looking "pretty good." Nonetheless, all contemporary fractal image compression programs are based upon Jacquin's paper. That is not to say there are many fractal compression programs available. There are not. Iterated Systems sell the only commercial compressor/decompressor, an MS-Windows program called "Images Incorporated." There are also an increasing number of academic programs being made freely available. Unfortunately, these programs are - how should I put it? - of merely academic quality. This scarcity has much to do with Iterated Systems' tight lipped policy about their compression technology. They do, however, sell a Windows DLL for programming. In conjunction with independent development by researchers elsewhere, therefore, fractal compression will gradually become more pervasive. Whether it becomes all-pervasive remains to be seen. Historical Highlights: On the InsideThe fractals that lurk within fractal image compression are not those of the complex plane (Mandelbrot Set, Julia sets), but of Iterated Function Theory. When lecturing to lay audiences, the mathematician Heinz-Otto Peitgen introduces the notion of Iterated Function Systems with the alluring metaphor of a Multiple Reduction Copying Machine. A MRCM is imagined to be a regular copying machine except that:
The first point is what makes an IFS a system. The third is what makes it iterative. As for the second, it is implicitly understood that the functions of an Iterated Function Systems are contractive. An IFS, then, is a set of contractive transformations that map from a defined rectangle of the real plane to smaller portions of that rectangle. Almost invariably, affine transformations are used. Affine transformations act to translate, scale, shear, and rotate points in the plane. Here is a simple example: |---------------| |-----| |x | |1 | | | | | | | |---------------| | | |2 |3 | | | | | | |---------------| |---------------| Before After Figure 1. IFS for generating Sierpinski's Triangle. This IFS contains three component transformations (three separate lens arrangements in the MRCM metaphor). Each one shrinks the original by a factor of 2, and then translates the result to a new location. It may optionally scale and shift the luminance values of the rectangle, in a manner similar to the contrast and brightness knobs on a TV. The amazing property of an IFS is that when the set is evaluated by iteration, (i.e. when the copy machine is run), a unique image emerges. This latent image is called the fixed point or attractor of the IFS. As guaranteed by a result known as the Contraction Theorem, it is completely independent of the initial image. Two famous examples are Sierpinski's Triangle and Barnsley's Fern. Because these IFSs are contractive, self-similar detail is created at every resolution down to the infinitesimal. That is why the images are fractal. The promise of using fractals for image encoding rests on two suppositions:1. many natural scenes possess this detail within detail structure (e.g. clouds), and 2. an IFS can be found that generates a close approximation of a scene using only a few transformations. Barnsley's fern, for example, needs but four. Because only a few numbers are required to describe each transformation, an image can be represented very compactly. Given an image to encode, finding the optimal IFS from all those possible is known as the inverse problem. The inverse problem - as mentioned above - remains unsolved. Even if it were, it may be to no avail. Everyday scenes are very diverse in subject matter; on whole, they do not obey fractal geometry. Real ferns do not branch down to infinity. They are distorted, discolored, perforated and torn. And the ground on which they grow looks very much different. To capture the diversity of real images, then, Partitioned IFSs are employed. In a PIFS, the transformations do not map from the whole image to the parts, but from larger parts to smaller parts. An image may vary qualitatively from one area to the next (e.g. clouds then sky then clouds again). A PIFS relates those areas of the original image that are similar in appearance. In the literature, the big areas are called domain blocks and the small areas are called range blocks. It is necessary that every pixel of the original image belong to (at least) one range block. The pattern of range blocks is called the partitioning of an image. Because this system of mappings is still contractive, when iterated it will quickly converge to its latent fixed point image. Constructing a PIFS amounts to pairing each range block to the domain block that it most closely resembles under some to-be-determined affine transformation. Done properly, the PIFS encoding of an image will be much smaller than the original, while still resembling it closely. Therefore, a fractal compressed image is an encoding that describes:
The decompression process begins with a flat gray background. Then the set of transformations is repeatedly applied. After about four iterations the attractor stabilizes. The result will not (usually) be an exact replica of the original, but reasonably close. Scalelessnes and Resolution EnhancementWhen an image is captured by an acquisition device, such as a camera or scanner, it has an inherent scale determined by the sampling resolution of that device - 300 dots per inch is common for scanners. If software is used to zoom in on the image, you don't see additional detail, just bigger pixels. A fractal image is different. Because the individual transformations of a PIFS are spatially contractive, detail is created at finer and finer resolutions with each iteration. In the limit, self-similar detail is created at all levels of resolution, down the infinitesimal. Because there is no level that 'bottoms out' fractal images are considered to be scaleless. What this means in practice is that as you zoom in on a fractal image, it will still look 'as it should.' In particular, there won't be the staircase effect of pixel replication. The significance of this is cause of some misconception, so here is the right spot for a public service announcement. /--- READER BEWARE ---\Iterated Systems is fond of the following argument. Take a portrait that is, let us say, a grayscale image 250x250 pixels in size, 1 byte per pixel. You run it through their software and get a 2500 byte file. A compression ration of 25:1, wonderful. Now zoom in on the person's hair at 4x magnification. What do you see? A texture that still looks like hair. Well then, it's as if you had an image 1000x1000 pixels in size. So your _effective_ compression ratio is 25 x 16 = 400. Amazing! Buy our software today! The sleight of hand is apparent. The detail has not been retained, but generated. With a little luck it will look as it should, but don't count on it. Zooming in on a person's face will not reveal the pores. Objectively, what fractal image compression offers is an advanced form of interpolation. This is a useful and attractive property. Useful to graphic artists, for example, or for printing on a high resolution device. But you can't use it to claim fantastically high compression ratios. \--- READER BEWARE ---/That said, what is resolution enhancement? It is the process of compressing an image, expanding it to a higher resolution, saving it, then discarding the iterated function system. In other words, the compressed fractal image is the means to an end, not the end itself. The Speed ProblemThe essence of the compression process is the pairing of each range block to a domain block such that the difference between the two, under an affine transformation, is minimal. This involves a lot of searching. As a matter of fact, there is nothing that says the blocks have to be squares or even rectangles. That is just an imposition made to keep the problem tractable. More generally, the method of finding a good PIFS for any given image involves five main issues:
Many possibilities exist for each of these. The choices that Jacquin offered in his paper are:
The importance of categorization can be seen by calculating the size of the total domain pool. Suppose the image is partitioned into 4x4 range blocks. A 256x256 image contains a total of (256-8+1)^2 = 62,001 different 8x8 domain blocks. Including the 8 isometric symmetries increases this total to 496,008. There are (256-4+1)^2 = 64,009 4x4 range blocks, which makes for a maximum of 31,748,976,072 possible pairings to test. Even on a fast workstation an exhaustive search is prohibitively slow. You can start the program before departing work Friday afternoon; Monday morning, it will still be churning away. Increasing the search speed is the main challenge facing fractal image compression. Similarity to Vector QuantizationTo the VQ community, a "vector" is a small rectangular block of pixels. The premise of vector quantization is that some patterns occur much more frequently than others. So the clever idea is to store only a few of these common patterns in a separate file called the codebook. Some codebook vectors are flat, some are sloping, some contain tight texture, some sharp edges, and so on - there is a whole corpus on how to construct a codebook. Each codebook entry (each domain block) is assigned an index number. A given image, then, is partitioned into a regular grid array. Each grid element (each range block) is represented by an index into the codebook. Decompressing a VQ file involves assembling an image out of the codebook entries. Brick by brick, so to speak. The similarity to fractal image compression is apparent, with some notable differences:
There is a more refined version of VQ called gain-shape vector quantization in which a luminance scaling and offset is also allowed. This makes the similarity to fractal image compression as close as can be. Compression RatiosExaggerated claims not withstanding, compression ratios typically range from 4:1 to 100:1. All other things equal, color images can be compressed to a better extent that grayscale images. The size of a fractal image file is largely determined by the number of transformations of the IFS. For the sake of simplicity, and for the sake of comparison to JPEG, assume that a 256x256x8 image is partitioned into a regular partitioning of 8x8 blocks. There are 1024 range blocks and thus 1024 transformations to store. How many bits are required per transformation? In most implementations the domain blocks are twice the size of the range blocks. So the spatial contraction is constant and can be hard coded into the decompression program. What needs to be stored are: x position of domain block 8 6 y position of domain block 8 6 luminance scaling 8 5 luminance offset 8 6 symmetry indicator 3 3 - 35 26 bits In the first scheme, a byte is allocated to each number except for the symmetry indicator. The upper bound on the compression ratio is thus (8x8x8)/35 = 14.63. In the second scheme, domain blocks are restricted to coordinates modulo 4. And experiments have revealed that 5 bits per scale factor and 6 bits per offset still give good visual results. So the compression ratio limit is now 19.69. Respectable but not outstanding. There are other, more complicated, schemes to reduce the bit rate further. The most common is to use a three or four level quadtree structure for the range partitioning. That way, smooth areas can be represented with large range blocks (high compression), while smaller blocks are used as necessary to capture the details. In addition, entropy coding can be applied as a back-end step to gain an extra 20% or so. Quality: Fractal vs. JPEGThe greatest irony of the coding community is that great pains are taken to precisely measure and quantify the error present in a compressed image, and great effort is expended toward minimizing an error measure that most often is - let us be gentle - of dubious value. These measure include signal-to-noise ratio, root mean square error, and (less often) mean absolute error. A simple counter example is systematic error: add a value of 10 to every pixel. Standard error measures indicate a large distortion, but the image has merely been brightened. With respect to those dubious error measures, the results of tests reveal the following: for low compression ratios JPEG is better, for high compression ratios fractal encoding is better. The crossover point varies but is often around 40:1 to 50:1. This figure bodes well for JPEG since beyond the crossover point images so severely distorted that they are seldom worth using. Proponents of fractal compression counter that signal-to-noise is not a good error measure and that the distortions present are much more 'natural looking' than the blockiness of JPEG, at both low and high bit rates. This is a valid point but is by no means universally accepted. What the coding community desperately needs is an easy to compute error measure that accurately captures subjective impression of human viewers. Until then, your eyes are the best judge.
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