Abstract: A display device (200) configured to provide two-dimensional and three dimensional perception. The device comprises a display panel (230), a backlight arrangement (201) and control circuitry (232). The backlight arrangement comprises a first layer (210) in the form of an optically clear lightguide, a birefringent second layer (202) and a third layer (204). At least one interfacing surface between any two of the layers comprises a microstructure (206) in the form of a plurality of essentially parallel structures extending in a direction of extension (x) of the structures. The device further comprises first (218) and second (219) light sources that are configured to emit light into the lightguide in a first (z) and a second direction (-z), respectively. The first and second directions are essentially opposing directions and the first and second directions are essentially perpendicular to the direction of extension of the microstructure.

Abstract: A display device (200) configured to provide two-dimensional and three dimensional perception. The device comprises a display panel (230), a backlight arrangement (201) and control circuitry (232). The backlight arrangement comprises a first layer (210) in the form of an optically clear lightguide, a birefringent second layer (202) and a third layer (204). At least one interfacing surface between any two of the layers comprises a microstructure (206) in the form of a plurality of essentially parallel structures extending in a direction of extension (x) of the structures. The device further comprises first (218) and second (219) light sources that are configured to emit light into the lightguide in a first (z) and a second direction (-z), respectively. The first and second directions are essentially opposing directions and the first and second directions are essentially perpendicular to the direction of extension of the microstructure.

Abstract: A pixel having an upper substrate and a base carrier disposed opposite each other; a dielectric fluid with dispersed electrophoretic particles filled in a gap between the upper substrate and the base carrier; a wall disposed on at least one of the upper substrate and the base carrier between adjacent pixels, preventing migration of the electrophoretic particles between the adjacent pixels; a surrounding electrode disposed in proximity to the wall and extending substantially parallel to an interior surface of the wall; and a facilitating structure positioned along an inner surface of the surrounding electrode, and having a curved inner surface, wherein the facilitating structure is electrically floating relative to the surrounding electrode. The pixels may be used with particles that are colored, black white, and/or reflective. The pixels may incorporate color filters therein.

Abstract: A drive method is provided for a display device using the movement of charged particles with a pixel area, with each pixel having first and second drive electrodes (20,23; 22) and a pixel electrode (26). The method comprises a reset phase to move the particles in each pixel towards the first drive electrode (20,23), a pixel data loading phase, to cause selected particles either to stay in the vicinity of the first drive electrode (20,23) or move towards the pixel electrode (26), and a drive phase to distribute the particles which have moved towards the pixel electrode over the pixel electrode (26). The address phase is line-by-line but can be made short, and the other phases can be carried out in parallel for all pixels, saving time.

Abstract: The invention provides a tool to select reliable organic LED devices, where the risk for failure before the end of its lifetime is low. This tool comprises the steps of: i) subjecting the device to a high electric field over the electroluminescent layer. This leads to a division of the devices into two, clearly separated, populations, namely one population with a low leakage current (current through the electroluminescent layer in reverse voltage operation) and one population with a high leakage current. In this step, the first population is selected in accordance with a current criterion. ii) detecting instabilities in the leakage current, referred to as noise. It has been established that these instabilities arise in particular at reverse driving voltages between 1 and 10 Volts. These instabilities are a measure of the occurrence of early failures during operation. In this step, the devices are selected in accordance with a noise criterion.

Abstract: The invention provides a tool to select reliable organic LED devices, where the risk for failure before the end of its lifetime is low. This tool comprises the steps of: i) subjecting the device to a high electric field over the electroluminescent layer. This leads to a division of the devices into two, clearly separated, populations, namely one population with a low leakage current (current through the electroluminescent layer in reverse voltage operation) and one population with a high leakage current. In this step, the first population is selected in accordance with a current criterion. ii) detecting instabilities in the leakage current, referred to as noise. It has been established that these instabilities arise in particular at reverse driving voltages between 1 and 10 Volts. These instabilities are a measure of the occurrence of early failures during operation. In this step, the devices are selected in accordance with a noise criterion.

Abstract: The invention provides a tool to select reliable organic LED devices, where the risk for failure before the end of its lifetime is low.

Abstract: The invention provides a tool to select reliable organic LED devices, where the risk for failure before the end of its lifetime is low. This tool comprises the steps of: i) subjecting the device to a high electric field over the electroluminescent layer. This leads to a division of the devices into two, clearly separated, populations, namely one population with a low leakage current (current through the electroluminescent layer in reverse voltage operation) and one population with a high leakage current. In this step, the first population is selected in accordance with a current criterion. ii) detecting instabilities in the leakage current, referred to as noise. It has been established that these instabilities arise in particular at reverse driving voltages between 1 and 10 Volts. These instabilities are a measure of the occurrence of early failures during operation. In this step, the devices are selected in accordance with a noise criterion.

Abstract: A magnetic field sensor has a substrate on which a plurality of resistive elements form a double Wheatstone bridge circuit, at least one of the resistive elements in each bridge having a magneto-resistive characteristic. The two bridges are identical except in that, if a given magneto-resistive element in a given branch in one bridge has a positive output polarity, then the corresponding magneto-resistive element in the same branch in the other bridge will have a negative output polarity. By adding the output signals of the two Wheatstone bridges a zero-point offset of the sensor can be determined and eliminated. There is no need to employ the so-called flipping technique employed for that purpose in conventional sensors, which requires increased power consumption.

Abstract: Magnetic heads comprising at least one core portion of polycrystalline MnZn-ferroferrite material exhibit a very low so-called "rubbing noise" level if the average grain size of the material ranges between 0.2 and 3.0 micrometers. The rubbing noise level of these heads is even lower than the electronic noise level if the average grain size of the material ranges between 0.5 and 2.0 micrometers. By virtue thereof, the heads can very suitably be used in the frequency range from 5 to 100 MHz.