Abstract: System and method for reducing failures due to hinge memory in a microdisplay display system. A preferred embodiment includes setting the state of each micromirror in a digital micromirror device based on an image being displayed, recording a usage history for the micromirrors, and providing a sequence of states to each micromirror when the display system is in an inactive mode. The sequence of states provided to a micromirror is based on the micromirror's usage history. The operation of the micromirrors while a display system containing the digital micromirror device is not in active use can help to reverse or eliminate hinge memory, thereby extending the lifetime of the digital micromirror device.

Abstract: An optical projection and capture system includes an image sensor integrated with an optical projection device. Additionally, the integrated device may be coupled with a laser pointer to deliver interactive presentations. The laser pointer may be pulsed to improve identifying and tracking a laser light spot on a projected image. These applications may be extended to rear projection systems for gaming and interactive graphics.

Abstract: A digital micromirror device (DMD) modified for use as a temporal light modulator. The DMD is modified so that the mirrors of the DMD have a preferential tilt direction. The inputs and outputs of the DMD are connected to common ground, except for the bias input lines. The latter are connected to a common excitation input, which is used to cyclically reposition the mirrors between tilted and flat states.

Abstract: A digital micromirror device (DMD) modified for use as a temporal light modulator. The DMD is modified so that the mirrors of the DMD have a preferential tilt direction. The inputs and outputs of the DMD are connected to common ground, except for the bias input lines. The latter are connected to a common excitation input, which is used to cyclically reposition the mirrors between tilted and flat states.

Abstract: A method and system for indirectly measuring the tilt angle of micromirrors in a micromirror array. The method and system aims a coherent light beam through an aperture in a screen so that it reflects off of the surface of the micromirror array and creates a pattern of reflected light on the screen. The micromirror array is loaded with a pattern that has a uniform power spectral density (such as a random, aperiodic pattern or a frequency chirped sinusoidal spatial pattern) whereby certain micromirrors will be placed in the “on” position and the other micromirrors will be placed in the “off” position. By loading the micromirror array with a pattern having a uniform power spectral density distribution, the discrete nature of the resulting diffraction pattern is reduced and a pair of [sin(x)/x]2 patterns will be generated on the screen.

Abstract: A digital micromirror device (DMD) modified for use as a temporal light modulator. The DMD is modified so that the mirrors of the DMD have a preferential tilt direction. The inputs and outputs of the DMD are connected to common ground, except for the bias input lines. The latter are connected to a common excitation input, which is used to cyclically reposition the mirrors between tilted and flat states.

Abstract: A digital micromirror device (DMD) modified for use as a temporal light modulator. The DMD is modified so that the mirrors of the DMD have a preferential tilt direction. The inputs and outputs of the DMD are connected to common ground, except for the bias input lines. The latter are connected to a common excitation input, which is used to cyclically reposition the mirrors between tilted and flat states.

Abstract: A method and system for indirectly measuring the tilt angle of micromirrors in a micromirror array. The method and system aims a coherent light beam through an aperture in a screen so that it reflects off of the surface of the micromirror array and creates a pattern of reflected light on the screen. The micromirror array is loaded with a pattern that has a uniform power spectral density (such as a random, aperiodic pattern or a frequency chirped sinusoidal spatial pattern) whereby certain micromirrors will be placed in the “on” position and the other micromirrors will be placed in the “off” position. By loading the micromirror array with a pattern having a uniform power spectral density distribution, the discrete nature of the resulting diffraction pattern is reduced and a pair of [sin(x)/x]2 patterns will be generated on the screen.