Kernel space: E-paper support for Linux

While conventional displays use memory-mapped regions to hold the data to be displayed, a new generation of slow but power-efficient display technology requires a new interface.

By Jaya Kumar, LinuxWorld.com, 11/27/07

The familiar CRT monitors or backlit LCD screens on our desks continuously consume power in order to hold an image. Electronic paper (e-paper) is different: power is only needed to change the image. Just like paper, e-paper is able to hold the image permanently without consuming any power. Displays using CRT, backlit LCD, plasma and OLED technologies are all emissive, meaning that they have to produce the photons that reach the eye. This implies that they have to compete in brightness with ambient lighting, which can result in eye strain. E-paper is the opposite: it is reflective, which makes it possible to read the display using ambient light even in the brightness of a hot sunny day.

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E-paper is referred to as a bistable or non-volatile technology because of its ability to hold a specific pixel state without power. There are several variations of e-paper; they differ in terms of which physical mechanism is used to achieve the non-volatility of the display. These mechanisms include interferometric modulation, bi-stable twisted nematic liquid crystal [PDF], cholesteric liquid crystal, and electrophoretic phenomena.

Interferometric modulation uses the same principle of light wave interference that results in the rainbow of colors seen with oil floating on water. Control of wave interference through bi-stable or multi-stable micro-electro-mechanical systems (MEMS) is what enables electronic control of the color of a pixel.

In standard twisted nematic liquid crystal displays (TNLCD), the liquid crystal is sandwiched between two rubbed polymer orthogonal alignment layers. Bi-stable twisted nematic implementations such as Zenithal liquid crystal replace the first or both alignment layers in favour of a sub-micron relief profile that weakens anchoring to the surface and makes it possible to latch various stable orientations of a liquid crystal pixel using electrical pulses.

Cholesteric liquid crystal provides the ability to selectively reflect various ranges of wavelengths of visible light based on the pitch of the liquid crystal. The pitch can then be electronically controlled to set various pixel states.