Abstract: A shadow mask deposition system includes a plurality of identical shadow masks arranged in a number of stacks to form a like number of compound shadow masks, each of which is disposed in a deposition vacuum vessel along with a material deposition source. Materials from the material deposition sources are deposited on the substrate via openings in corresponding compound shadow masks, each opening being formed by the whole or partial alignment of apertures in the shadow masks forming the compound shadow mask, to form an array of electronic elements on the substrate.

Abstract: The present invention is a multi-layer shadow mask and method of use thereof. The multi-layer shadow mask includes a sacrificial mask bonded to a deposition mask. The sacrificial mask provides protection against an accumulation of evaporant on the deposition mask which would cause the deposition mask to deform.

Abstract: A shadow mask deposition system includes a plurality of identical shadow masks arranged in a number of stacks to form a like number of compound shadow masks, each of which is disposed in a deposition vacuum vessel along with a material deposition source. Materials from the material deposition sources are deposited on the substrate via openings in corresponding compound shadow masks, each opening being formed by the whole or partial alignment of apertures in the shadow masks forming the compound shadow mask, to form an array of electronic elements on the substrate.

Abstract: In a shadow mask vapor deposition system, a first conductor is vapor deposited on a substrate and an insulator is vapor deposited on the first conductor. A second conductor is then vapor deposited on at least the insulator. The insulator layer is plasma etched either before or after the vapor deposition of the second conductor to define in the insulator layer a via hole through which at least a portion of the first conductor is exposed. An electrical connection is established between the first and second conductors by way of the via hole.

Abstract: A system and method for active array temperature sensing and cooling. The system includes an active temperature sensing layer, a thermoelectric cooling layer and a heatsink layer. The temperature sensing layer is formed of temperature sensing elements that sense the temperature gradient across an unevenly heated region of the active array substrate. The thermoelectric cooling layer controls the temperature gradient sensed by the temperature sensing layer. The heatsink layer includes a plurality of cooling channels for absorbing thermal energy from the unevenly heated region. The system is under the control of a process control computer.

Abstract: Via holes are formed in a continuous inline shadow mask production system by depositing a first conductor layer and subsequently depositing a first insulator layer over a portion of the first conductor layer. The first insulator layer is deposited in a manner to define at least one notch along its edge. The second insulator layer is then deposited on another portion of the first conductor layer in a manner whereupon the second insulator layer slightly overlaps each notch of the first insulator layer, thereby forming the one or more via holes. A conductive filler can optionally be deposited in each via hole. Lastly, a second conductive layer can be deposited over the first insulator layer, the second insulator layer and, if provided, the conductive filler.

Abstract: A shadow mask deposition system includes a plurality of identical shadow masks arranged in a number of stacks to form a like number of compound shadow masks, each of which is disposed in a deposition vacuum vessel along with a material deposition source. Materials from the material deposition sources are deposited on the substrate via openings in corresponding compound shadow masks, each opening being formed by the whole or partial alignment of apertures in the shadow masks forming the compound shadow mask, to form an array of electronic elements on the substrate.

Abstract: A vapor deposition shadow mask system includes a number of series connected vacuum vessels each having a material deposition source and shadow mask positioned therein. A substrate is translated along a path that has a longitudinal axis that extends through the vacuum vessels. Centers of shadow masks in first and second vacuum vessels are offset laterally on opposite sides of the longitudinal axis. The system is operative for depositing material on a second area of the substrate via the material deposition source and shadow mask in the second vacuum vessel in a manner that overlaps a portion of the material deposited on a first, adjacent area of the substrate via the material deposition source and shadow mask in the first vacuum vessel.

Abstract: Via holes are formed in a continuous inline shadow mask production system by depositing a first conductor layer and subsequently depositing a first insulator layer over a portion of the first conductor layer. The first insulator layer is deposited in a manner to define at least one notch along its edge. The second insulator layer is then deposited on another portion of the first conductor layer in a manner whereupon the second insulator layer slightly overlaps each notch of the first insulator layer, thereby forming the one or more via holes. A conductive filler can optionally be deposited in each via hole. Lastly, a second conductive layer can be deposited over the first insulator layer, the second insulator layer and, if provided, the conductive filler.

Abstract: A brightness compensation system and method of providing brightness uniformity in an active-matrix organic light-emitting diode (OLED) flat-panel display. The brightness compensation system of the present invention includes a system controller, a timing generator, a test brightness generator, a pixel address generator, a video formatter, a first and second multiplexer, a memory device, a pixel adjust device, a level shifter and driver, a current sensor, an analog-to-digital converter, a DC power supply, and an active-matrix OLED display under test. The brightness compensation system and method of the present invention subjects an active-matrix OLED display to a testing operation that alternately tests every pixel, detects its output current, which is an indicator of light output level, for a given input voltage, saves the output current value in memory, then applies a corrective voltage to each pixel, so that each pixel has the same light output (output current) as its neighboring pixel.

Abstract: An LCD pixel includes a first conductive segment connected to a first bus, a first insulator segment on the first conductive segment, a second conductive segment on the first insulator segment, a liquid crystal material on the second conductive segment, a third conductive segment on the liquid crystal material, and a thin film transistor having a control terminal, a first power terminal and second power terminal connected to a second bus, a third bus and the second conductive segment, respectively. In response to application of a suitable signal on the second bus when reference voltages are present on the first bus and on the third conductive segment, and a voltage is applied to the third bus, the thin film transistor is operative for charging a capacitor formed by the first conductive segment, the first insulator segment and the second conductive segment and for activating the liquid crystal material.

Abstract: In a shadow mask vapor deposition system, a first conductor is vapor deposited on a substrate and an insulator is vapor deposited on the first conductor. A second conductor is then vapor deposited on at least the insulator. The insulator layer is plasma etched either before or after the vapor deposition of the second conductor to define in the insulator layer a via hole through which at least a portion of the first conductor is exposed. An electrical connection is established between the first and second conductors by way of the via hole.

Abstract: Via holes are formed in a continuous inline shadow mask production system by depositing a first conductor layer and subsequently depositing a first insulator layer over a portion of the first conductor layer. The first insulator layer is deposited in a manner to define at least one notch along its edge. The second insulator layer is then deposited on another portion of the first conductor layer in a manner whereupon the second insulator layer slightly overlaps each notch of the first insulator layer, thereby forming the one or more via holes. A conductive filler can optionally be deposited in each via hole. Lastly, a second conductive layer can be deposited over the first insulator layer, the second insulator layer and, if provided, the conductive filler.

Abstract: A multi-layer electronic device can be formed to include an insulative substrate (212), a first vapor deposited conductor layer (312) on the insulative substrate (212), a first vapor deposited insulator layer (314) on the first conductor layer (312), the first insulator layer (314) having at least one via hole (316) therein, and a vapor deposited conductive filler (320) in the via hole (316) of the first insulator layer (314). Desirably, the conductive filler (320) is deposited in the via hole (316) of the first insulator layer (314) such that the surface of the conductive filler (320) opposite the first conductor layer (312) is substantially planar with the surface of the first insulator layer (314) opposite the first conductor layer (312).

Abstract: A method of improved patterning of indium-tin oxide (ITO) for precision-cutting and aligning a liquid crystal display (LCD) panel includes depositing a transparent ITO layer upon a transparent substrate, depositing a non-transparent plating layer upon the transparent ITO layer and depositing a photoresist layer upon the non-transparent plating layer. The photoresist layer is patterned, exposed and developed to form a plurality of photoresist lines. The photoresist lines are exposed again in an active area only and the plating layer is etched to form a plurality of non-transparent plated lines. The ITO layer is then etched to form a plurality of ITO lines. The photoresist lines are then developed and the non-transparent plated lines are etched away in the active area only. The photoresist that is outside the active area is then removed.

Abstract: The present invention is a multi-layer shadow mask and method of use thereof. The multi-layer shadow mask includes a sacrificial mask bonded to a deposition mask. The sacrificial mask provides protection against an accumulation of evaporant on the deposition mask which would cause the deposition mask to deform.

Abstract: The present invention is a substrate holder system for and method of providing a substrate-to-mask alignment mechanism, securing mechanism and temperature control mechanism. The substrate holder system is suitable for use in an automated shadow mask vacuum deposition process. The substrate holder system includes a system controller, and a substrate arranged between a magnetic chuck assembly and a mask holder assembly. The magnetic chuck assembly includes a magnetic chuck, a thermoelectric device, a plurality of thermal sensors and a plurality of light sources. The mask holder assembly includes a shadow mask, a mask holder, a motion control system and a plurality of cameras. The substrate holder system of the present invention provides close contact between the substrate and the shadow mask thereby avoiding the possibility of evaporant material entering into a gap therebetween.

Abstract: The present invention is a two-layer shadow mask with small dimension apertures and method of making and using same. The two-layer shadow mask of the present invention is suitable for use for manufacturing an electronic device via deposition in a production system. The two-layer shadow mask of the present invention is formed by a first thick mask, which includes a plurality of apertures that has been formed, for example, by etching, bonded to a second, comparatively thin mask, that has been formed by an electrolytic process, and which includes a plurality of apertures that has been patterned by a photoresist. The second mask is aligned and bonded atop the first mask, with their respective apertures desirably offset one to another. The offset amount of the respective apertures of the two-layer shadow mask determines the resulting final aperture dimension, which may approach 0 microns, through which material is deposited upon a substrate in a deposition production system.

Abstract: A deposition system uses the same low coefficient of thermal expansion (CTE) material, for example, a CTE of below 10 ppm/° C. in the temperature range of 0-200° C., for forming both a shadow mask and a substrate upon which depositions occur in order to overcome the heating effects of a high-temperature deposition process, thereby ensuring a uniform expansion and contraction rate of the shadow mask and the substrate.

Abstract: An electronic device is formed from electronic elements deposited on a substrate. The electronic elements are deposited on the substrate by advancing the substrate through a plurality of deposition vacuum vessels, with each deposition vacuum vessel having at least one material deposition source and a shadowmask positioned therein. The material from at least one material deposition source positioned in each deposition vacuum vessel is deposited on the substrate through the shadowmask positioned in the deposition vacuum vessel to form on the substrate a circuit comprised of an array of electronic elements. The circuit is formed solely by the successive deposition of materials on the substrate.