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Modern technology has changed many things in our lives, including the way we communicate, travel and entertain ourselves. Electronic instruments and computer simulations have revolutionised science. Mathematics, one of the purest forms of human logic and reasoning, has also been changed by computer approaches. Even art has been undergoing a deep upheaval in the way it is created and appreciated, using the fast processing and graphical output of computers. The boundary between artist, computer programmer, and mathematician is becoming ever more blurred. In this article, Lewis Dartnell leads us through some examples of this exciting new wave of digital art.
Art was once restricted to static creations, such as an oil painting, sculpture or photograph, produced by the artist and then passively regarded by the viewer. Nowadays, however, computer-based visual art allows improved dynamic forms — art that develops or evolves before our eyes. The "artist" may have no more idea of what will finally emerge than anyone else. An even more exciting possibility in computer-aided installations is interactivity — digital art that responds to the viewer's actions, for example through input from movements of the computer mouse, or perhaps even by tracking the motion of different parts of the body. The crucial thing here is that dynamic digital art is not so much about the appearance of the finished product, as about the behaviour generated by the art piece through time. The viewer actually helps to modify the work of art, and becomes the artist him or herself.
Early computer art often involved fractals: A detail of the Mandelbrot set created by Wolfgang Beyer.
Mathematics, as the language of form and pattern, has always played an important role in art, but the rise of computer-generated art blurs the boundaries between art and maths even further. The act of programming — finding ways to store data and then creating logic-based algorithms to generate the desired output — is itself intensely mathematical. But the maths of physics is also used to realistically re-create physical processes, and the area of computer music — getting a computer to find those patterns and features that distinguish music from mere noise — poses a whole new range of mathematical challenges.
Consequently, the early days of computer graphics and digital art were dominated by scientists and research technicians — they were the only people with the specialist knowledge and access to operate the rare and expensive computers of the time. Even in 1969, Jasia Reichardt, who was then a curator at the Institute of Contemporary Arts (ICA) in London, said "So far only three artists that I know have actually produced computer graphics, the rest to date having been made by scientists". Since then, the number of artists using computers in their work has dramatically increased, especially with developments like the emergence of the personal computer and easy-to-learn programming languages. One such new computer language, Processing, is making great strides in enabling artists to become programmers, and programmers to become artists, and we'll take a look at this free software a little later.
Computer games such as Doom 3 and Neverwinter nights feature sophisticated graphics.
One obvious example of an area where computer-generated visuals have become crucial is in the games and cinema industries. The graphics in video games and the computer-generated images (CGI) so common nowadays in films and TV documentaries (TV CGI has come a long way since Walking with Dinosaurs!) rely enormously on mathematics. The models used to realistically animate the physics of a lumbering monster and render this model into a photo-realistic animation — particularly with the way light interacts with tricky materials or surface textures such as rippling water or coats of thick animal hair — would be impossible without computers chugging through the maths of Cartesian coordinates, trigonometry, vector geometries, and so on. It is said that the animators working on the film Shrek really struggled to get a glass of milk to look realistic in the gingerbread man scene. By the time Shrek II was under production, the graphic artists had cracked the problem and were able to greatly improve the realism of the rendering by modelling the fact that milk is not in fact an opaque liquid, but is semi-translucent, letting light inside to scatter about before coming out again. They were so proud of their new skill that the second film slipped in great volumes of milk: whole vats of it being sploshed over the sides of a castle! The realism of computer-generated graphics is continually improving, and in the near future the visuals in a computer game or visual art installation will become indistinguishable from the real thing.
Computers have heralded a revolution not only in the way that visual art can be produced, but also in how the piece interacts with its environment, the performance artist or even the viewers. Imagine not just idly looking at a painting in a stuffy gallery, but dancing in front of an installation and having a projection screen come alive with colour and movement, instantly responding to and interpreting your actions. Kinetic art forms can use different input devices and computer processing to allow immediate feed-back and response. These control inputs extend far beyond the standard computer interfaces of keyboard or mouse, and can include your voice captured by a microphone or body gestures watched by a webcam. This form of interactive kinetic artwork, controlled by movements as seen by a computer, can be very difficult to do well, however. Some very sophisticated problem-solving is often needed to enable a computer program to identify features from a webcam. Picking out the brightest or darkest regions in its visual field are easy, but identifying the head or hand of a performer, especially as it moves and so continually appears to change shape and brightness, is very hard for a computer to do accurately.
Obviously the whole point about dynamic digital art is to be there, experiencing the energetic performance and perhaps even directing it yourself. But you can get a feeling for the scope and imagination involved in digital art in the selection of projects show-cased below. These examples are just a taster of the great variety of digital art being explored around the world; on stage, on television, in gallery installations, and so on. We won't go into the mathematical challenges posed by the pieces here — a great deal more information can be gathered by following the links to the artists' websites, and the reading list below has links to Plus articles that explore relevant pieces of mathematics. But for now, just sit back and enjoy the show.
For a relatively simple computer program (using Processing), this digital art piece by LIA generates strikingly beautiful output. Click on the image above to follow a link to WithoutTitle, and use your mouse to interact with the animation. A dense thicket of lines swarm around the current position of your cursor, and moving around the screen affects how the lines expand and contract. See LIA's website for more information.
One recent example of responsive digital art on television was demonstrated within the music video to R.E.M.'s single Animal. A total eclipse of the Sun reveals to the lead singer, Michael Stipe, a whole hidden world of connections and energy lines lying beneath the reality that we are normally restricted to seeing. Figures walking around trail glowing auras, and as Stipe floats in the air singing, his body movements are picked out by the flickering of glowing stars, transiently linking together into constellations.
|The post-production for this music video uses a lot of digital art techniques, such as driving the dynamic star graphics to interact with the singers. The applet on the left, created by Ryan Alexander using Processing, produces the flowing constellation effect. You can interact with it by passing your cursor over the image. Find out more about Star Nursery on the Processing website.|
Shadow Monsters is an interactive installation set up in 2005 that invites viewers to use their hands and arms to project shadow creatures, such as the classic opening-and-closing puppet mouth, onto a white screen. These shadows are monitored in real time by a camera-enabled computer, which then acts to reinterpret the shadow. The silhouettes of monsters are dynamically created from any shadows falling on the screen, complete with rows of teeth, tentacles, and bristling spines along their back. These monstrous creations are then re-projected onto a large viewing screen, just as if the "performers" had actually been casting the shadows themselves. Even better, the computer program generates realistic sound effects of squeaks and roars from the hand gestures as it senses the puppet shadows opening and closing their mouths. It's hard to think of an example of interactive digital art that's more instantly engaging and fun! Check out the video of a shadow monster performance below, or view the still images in the monster zoo on the creator's website.
Messa di Voce
Messa di Voce is an audio-visual performance created by a team of four artists, some sections of which were later recreated as installations for the general public to experience directly. The title, Messa di Voce, is Italian for a vocal technique used by singers, meaning "placing the voice", and is very apt for the unbelievable vocal skills demonstrated by the performance artists here. The speech, singing, and other sound effects created by the two performers are used, along with a video camera following their movements around the stage, as input fed into custom digital art software which generates dynamic visualisations and projects them onto a screen. The stunning effect for the audience is of the artists' voices literally coming alive, the colourful sounds emanating away from their mouths in different magical ways.
The original performances ran in 2003 and 2004, but they have been well-documented in photos and videos that you can view online. Click on the image below to open a video in a new window. This incredible digital art really does need to be seen to be believed!
Much of the digital art show-cased above was created using a new programming language called Processing. This was created at the MIT Media Lab as a collaboration between computer scientists and artists, specifically to make programming as easy and intuitive as possible. This means you'll have absolutely no difficulty in getting hold of this software, learning a little bit about computer programming and getting stuck in creating stunning visual art yourself! Processing can be downloaded for free, and is a very small package to install. It comes with a help file to get you started, but the best source of information for learning the basics, or brushing up on more advanced features if you've programmed before (Processing is based on Java), is to explore the manual and discussion boards on their excellent website. Lots of digital artists have uploaded the computer code from their creations, so you should be able to pick and choose bits to mash up your very own digital art piece in next to no time. There are also a few new books about Processing, aimed at both beginners and more experienced digital artists / computer scientists. You might like to try these two as a first port-of-call.
Further reading on Plus
- The articles Maths goes to the movies and Career interview: Games developer explore some of the maths behind computer generated movies and games;
- The article Matrix: Simulating the world is a hands-on guide on how to create your own computer simulations using Processing;
- The article Perfect buildings: The maths of modern architecture looks at visual modelling in architecture;
- The career interviews Computer music researcher and Audio software engineer explore the mathematical challenges posed by computer music;
- The article Unveiling the Mandelbrot set looks at the maths behind some stunning fractal imagery;
- Look at the Plus archive for more articles on maths in art and music.
About the author
After reading Biological Sciences at Queen's College, Oxford, Lewis Dartnell moved to University College London's new centre for multidisciplinary science, the Centre for Mathematics & Physics in the Life Sciences and Experimental Biology (CoMPLEX). Here he completed his PhD in the field of astrobiology using computer models of the radiation levels on Mars to predict where life could possibly be surviving near the surface. This summer he is organising the Royal Institution Christmas Lectures on Computer Science.
Lewis has won four national communication prizes, including in the Daily Telegraph/BASF Young Science Writer Awards. His popular science book Life in the Universe: A Beginner's Guide has been reviewed in Plus. You can read more of Lewis' work on his website.