Surface computing is the use of a specialized computer GUI in which traditional GUI elements are replaced by intuitive, everyday objects. Instead of a keyboard and mouse, the user interacts with a surface. Typically the surface is a touch-sensitive screen, though other surface types like non-flat three-dimensional objects have been implemented as well. It has been said that this more closely replicates the familiar hands-on experience of everyday object manipulation.

Early work in this area was done at the University of Toronto, Alias Research, and MIT. Surface work has included customized solutions from vendors such as LM3LABS or GestureTek, Applied Minds for Northrop Grumman. Major computer vendor platforms are in various stages of release: the iTable by PQLabs, Linux MPX, the Ideum MT-50, interactive bar by spinTOUCH, and Microsoft PixelSense (formerly known as Microsoft Surface).

Surface computing employs the use of two broad categories of surface types, flat and non-flat. The distinction is made not only due to the physical dimensions of the surfaces, but also the methods of interaction.

Flat surface types refer to two-dimensional surfaces such as tabletops. This is the most common form of surface computing in the commercial space as seen by products like Microsoft's PixelSense and iTable. The aforementioned commercial products utilize a multi-touch LCD screen as a display, but other implementations use projectors. Part of the appeal of two-dimensional surface computing is the ease and reliability of interaction. Since the advent of tablet computing, a set of intuitive gestural interactions have been developed to complement two-dimensional surfaces. However, the two-dimensional plane limits the range of interactions a user is able to perform. Furthermore, interactions are only detected when making direct contact with the surface. In order to afford the user a wider range of interaction, research has been done to augment the interaction schemes for two-dimensional surfaces. This research involves using the space above the screen as another dimension for interaction, so, for example, the height of a user's hands above the surface becomes a meaningful distinction for interaction. This particular system would qualify as a hybrid that uses a flat surface, but a three-dimensional space for interaction.

While most work with surface computing has been done with flat surfaces, non-flat surfaces have become an interest with researchers. The eventual goal of surface computing itself is tied to the notion of ubiquitous computing "where everyday surfaces in our environment are made interactive". These everyday surfaces are often non-flat, so researchers have begun exploring curved and three-dimensional modes. Some of these include spherical, cylindrical and parabolic surfaces. Including a third dimension to surface computing presents both benefits and challenges. One of these benefits is an extra dimension of interaction. Unlike flat surfaces, three dimensional surfaces allow for a sense of depth and are thus classified as "depth-aware" surfaces. This allows for more diverse gestural interactions. However, one of the main challenges is designing intuitive gestural actions to facilitate interaction with these non-flat surfaces. Furthermore, three-dimensional shapes such as spheres and cylinders require viewing from all angles, also known as omnidirectional displays. Designing compelling views from every angle is a difficult task, as is designing applications that make sense for these display types.

Displays for surface computing can range from LCD and projection screens to physical object surfaces. Alternatively, an augmented reality headset may be used to display images on real-world objects. Displays can be divided into single-viewpoint and multi-viewpoint displays. Single-viewpoints include any flat screen or surface where viewing is typically done from one angle. A multi-viewpoint display would include any three-dimensional object surface like a sphere or cylinder that allows viewing from any angle.

If a projection screen or a physical object surface is being used, a projector is needed to superimpose the image on the display. A wide range of projectors are used including DLP, LCD, and LED. Front and rear projection techniques are also utilized. The advantage of a projector is that it can project onto any arbitrary surface. However, a user will end up casting shadows onto the display itself, making it harder to identify high detail.

Infrared or thermographic cameras are used to facilitate gestural detection. Unlike digital cameras, infrared cameras operate independently of light, instead relying on the heat signature of an object. This is beneficial because it allows for gesture detection in all lighting conditions. However, cameras are subject to occlusion by other objects that may result in a loss of gesture tracking. Infrared cameras are most common in three-dimensional implementations.