Laser TV — the Death of Plasma?

spoco2 writes, "As reported in major news outlets yesterday in Australia (The Age, the Herald Sun), a new television technology has been developed which is touted (by the developers) as far and away superior to both plasma and LCD. From The Age: 'With a worldwide launch date scheduled for Christmas 2007, under recognisable brands like Mitsubishi and Samsung, Novalux chief executive Jean-Michel Pelaprat is so bold as to predict the death of plasma. "If you look at any screen today, the color content is roughly about 30-35 per cent of what the eye can see," he said. "But for the very first time with a laser TV we'll be able to see 90 per cent of what the eye can see. All of a sudden what you see is a lifelike image on display."' The developing company, Arasor International, is said to be listing on the Australian stock exchange shortly."

Colour gamut

[troon]

The problem with the extended colour gamut of the new system is that existing source material is based on the sRGB colour space, which encompasses roughly 35% of the eye's gamut. Anything shorter wavelength than blue, such as spectral violet; many saturated greens and oranges, and most cyans are not available, and the nearest colour is used.

We're all used to this, so when a violet flower is shown as purple (red + blue) on our displays, we don't question it. But try putting a vase of violets next to your TV and you'll see the difference.

Some proper digital photography setups try to improve on the situation using colour profiles, which is simply a lookup table to transform the RGB colours in the file to absolute colour values.

Digital cameras can record colours outside sRGB, so if you ensure your workflow never enforces that constraint, you can end up with a file that can be printed using colours your monitor can't see.

Typically, the input file (usually a raw camera file) is transformed via a device profile (representing the camera's actual spectral response) into a working space (a device-independent space for editing). Whilst editing, the image is viewed using a transform to sRGB (or your display's output profile, if you've calibrated it), but this restriction is for viewing only and doesn't change the file. Then, when you print, the image is converted via a device profile for your printer to print to the extremes of its capabilities - which may exceed sRGB in some colours (e.g. cyan), and be even worse in others (e.g. pure blue).

To make use of this new TV system, we'd need something similar - wide-gamut source material, and device profiles for each set (or simply assume sRGB as default, for backwards-compatibility). Otherwise, it's like listening to music mixed for cheap portable radios (i.e. most current CDs) on a real hi-fi system.