Color display projection method and apparatus

What is claimed is: 1. A multi-DMD projection system, comprising: a light source; three digital micromirror device (DMD) spatial light modulators having bottom-illuminated tilt-and-roll pixels, each pixel having a respective mirror supported by a hinge that allows the mirror to rotate between: a first stable landed state in which the mirror rests upon a first contact point and upon a second contact point, but not upon a third contact point; and a second stable landed state in which the mirror rests upon the second contact point and upon the third contact point, but not upon the first contact point; three total internal reflection (TIR) prisms; three light directing elements; a projection lens; and an X-cube color splitting/recombining prism having upper and lower sections, and front, rear, left and right side faces; the light source, the DMD spatial light modulators, the TIR prisms, the light directing elements, the projection lens and the X-cube prism being relatively positioned and configured so that: light from the light source is: directed into the front side face at a first one of the upper and lower sections of the X-cube prism (“first section”); and split by the X-cube prism into three colors that are respectively directed out of the left, rear and right side faces at the first section (“illumination light”); outside of the X-cube prism, the light directing elements respectively direct the three colors to corresponding respective ones of the three DMD spatial light modulators for modulation; the TIR prisms respectively direct the three colors after modulation from the bottom-illuminated tilt-and-roll pixels of the three DMD spatial light modulators (“projection light”) into corresponding respective ones of the left, rear and right side faces at a second one of the upper and lower sections of the X-cube prism (“second section”); and the modulated colors from the TIR prisms are recombined at the second section, and the combined light is directed out of the front side face at the second section and projected by the projection lens; wherein the illumination light and the projection light traverse different paths from one another within the X-cube prism to avoid polarization induced leakage and color desaturation. 2. A projection method, comprising: directing light from a light source into a front side face at a first one of upper and lower sections of an X-cube prism (“first section”), the light being split by the X-cube prism into three colors that are respectively directed out of left, rear and right side faces of the X-cube prism at the first section (“illumination light”); outside of the X-cube prism, respectively directing the three colors to corresponding respective ones of three digital micromirror device (DMD) spatial light modulators for modulation; using three total internal reflection (TIR) prisms to respectively direct the three colors after modulation from bottom-illuminated tilt-and-roll pixels of the three DMD spatial light modulators (“projection light”) into corresponding respective ones of the left, rear and right side faces at a second one of the upper and lower sections of the X-cube prism (“second section”), each pixel having a respective mirror supported by a hinge that allows the mirror to rotate between: a first stable landed state in which the mirror rests upon a first contact point and upon a second contact point, but not upon a third contact point; and a second stable landed state in which the mirror rests upon the second contact point and upon the third contact point, but not upon the first contact point; at the second section, recombining the modulated colors from the TIR prisms; directing the combined light out of the front side face at the second section; and projecting the combined light from the second section by a projection lens; wherein the illumination light and the projection light traverse different paths from one another within the X-cube prism to avoid polarization induced leakage and color desaturation. 3. The system of claim 1 , wherein the TIR prisms are reverse TIR prisms. 4. The method of claim 2 , wherein the TIR prisms are reverse TIR prisms.