Abstract: Erroneous data in the video pulse output string of a CCD imager, caused by defective cells in the imager, is detected by comparison with adjacent data in the string and corrected by replacement with adjacent data. CCD video output is delayed by one clock cycle, then compared to the real time video output while both signals are still on the chip. If the delayed pulse is the same or greater magnitude as the real time pulse, that pulse goes on as part of the video output. If the delayed pulse is less than the real time pulse by a defined amount or more, then the real time pulse is replaced in the output by a copy of the following real time data pulse.
Type:
Grant
Filed:
December 3, 1984
Date of Patent:
March 29, 1988
Assignee:
Texas Instruments Incorporated
Inventors:
Frank L. Skaggs, Stanley W. Holcomb, Benny R. Baker, deceased, Patricia J. Peterson, heir
Abstract: An infrared imager, wherein a transparent gate is separated from a very narrow bandgap semiconductor (such as HgCdTe) by a thin dielectric. The gate is biased to create a depletion well in a semiconductor, and photo-generated carriers are collected in the well. The gate voltage is sensed to measure the accumulated charge. Preferably the accumulated charge is not sensed directly from the gate, but the gate output is repeatedly averaged with another capacitor, so that the output of the imager is sensed as an average over a number of read cycles, which provides a greatly improved signal-to-noise ratio. Preferably an array of the MIS detection devices is formed in a thin layer of HgCdTe, which is bonded to a silicon substrate containing a corresponding array of the averaging capacitors with addressing and output connections, and via holes through the HgCdTe are used to connect each detection device to its corresponding averaging capacitor.
Abstract: Liquid silicon is deposited on a high surface area column of silicon nitride particles, by hydrogen decomposition of trichlorosilane. This is accomplished in an environment heated to a temperature in excess of the melting point of silicon. After deposition, the liquid silicon flows by gravity to a collection point. Preferably a liquid transfer system moves the silicon directly to a crystal pulling operation. The liquid transfer to immediate pulling conserves energy and allows for continual withdrawal of melt from the reactor. The immediate pulling provides additional purification and the crystal thus pulled is preferably used as feedstock for a final crystal pulling operation.
Abstract: A light modulating device such as a liquid crystal display or polarizer is fabricated using optically biaxial plastic material as a substrate. The plastic biaxial material replaces the glass substrate of the LCD, or the cellulose acetate butyrate (CAB) of the polarizer. The biaxial material is a type of stretched plastic, which is more flexible than glass, and much thinner in typical display applications. Typical plastic biaxial materials are chemically stable with liquid crystals and much more stable than isotropic plastics (CAB). The material is optically anistropic, but optical axes of the material are chosen to be outside the field of view over which the device will be observed.
Type:
Grant
Filed:
September 12, 1983
Date of Patent:
August 6, 1985
Assignee:
Texas Instruments Incorporated
Inventors:
Perry A. Penz, Robert J. Petcavich, William P. Stearns, Larry W. Sanders
Abstract: A plasma etch chemistry which allows a near perfectly vertical etch of silicon is disclosed. A Cl-containing compound such as BCl.sub.3 has Br.sub.2 added to it, readily allowing anisotropic etching of silicon. This is due to the low volatility of SiBr.sub.4. The silicon surface facing the discharge is subjected to ion bombardment, allowing the volatilization (etching) of silicon as a Si-Cl-Br compound. The Br which adsorbs on the sidewalls of the etched silicon protects them from the etching. This new plasma etch chemistry yields a very smooth etched surface, and the etch rate is relatively insensitive to the electrical conductivity of the silicon.
Abstract: A liquid crystal display (LCD) capable of automated fabrication facilitated by the use of continuous strips of plastic film on the surface of which corresponding electrode patterns are defined. Liquid crystal material, and spacing means, are sealed between the plastic strips, preferably with the aid of sealing rings formed on one of the film strips; thereby, defining the individual liquid crystal display.