Patents Assigned to Teledyne Scientific & Imaging, LLC
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Patent number: 8482921Abstract: A system and method is disclosed for fabricating a heat spreader system, including providing a plurality of bottom microporous wicks recessed in a bottom substrate, bonding a center substrate to the bottom substrate, and bonding a top substrate having a top chamber portion to the center substrate to establish a first vapor chamber with said plurality of bottom microporous wicks.Type: GrantFiled: November 15, 2010Date of Patent: July 9, 2013Assignee: Teledyne Scientific & Imaging, LLC.Inventors: Qingjun Cai, Chung-Lung Chen, Chialun Tsai
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Publication number: 20130168057Abstract: A modular heat shield and heat spreader (“MHS”) includes top and bottom panels, and a plurality of thermally conductive pillars located between the panels and which support the top panel. A continuous pool of liquid between the panels surrounds some portion of the pillars. Heat to which the top panel is exposed is conducted through the top panel and at least some of the pillars. The heat changes the phase of some of the liquid to a vapor, which spreads the heat to an area larger than that of the heat source and thereby dissipates the heat away from the source at a lower heat flux than that associated with the flux from the source. The MHS preferably includes wicking material on some of the pillars and on the underside of the top panel, such that the wicking material is saturated with the liquid and heated by the conducted heat.Type: ApplicationFiled: November 8, 2012Publication date: July 4, 2013Applicant: Teledyne Scientific & Imaging, LLCInventor: Teledyne Scientific & Imaging, LLC
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Patent number: 8476679Abstract: A dynamic and end-user configurable controlled impedance interconnect line includes a plurality of conductive pixels, a plurality of thin-film transition material interconnects to electrically connect adjacent conductive pixels in the plurality of conductive pixels, and a plurality of addressable pixel interconnect actuators to selectively heat a respective plurality of the thin-film transition material interconnects. The plurality of addressable pixel interconnect actuators is operable to selectively heat a respective plurality of the thin-film transition material interconnects to form an interconnect line.Type: GrantFiled: January 28, 2011Date of Patent: July 2, 2013Assignee: Teledyne Scientific & Imaging, LLCInventors: Jonathan B. Hacker, Christopher E. Hillman
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Patent number: 8472098Abstract: A wafer-level manufacturing method produces stress compensated x-y gimbaled comb-driven MEMS mirror arrays using two SOI wafers and a single carrier wafer. MEMS structures such as comb drives, springs, and optical surfaces are formed by processing front substrate layer surfaces of the SOI wafers, bonding together the processed surfaces, and removing the unprocessed SOI layers to expose second surfaces of the front substrate layers for further wafer-level processing. The bonded SOI wafers are mounted to a surface of the carrier wafer that has been separately processed. Processing wafer surfaces may include formation of a stress compensation layer to counteract physical effects of MEMS mirrors. The method may form multi-layered conductive spring structures for the mirrors, each spring having a first conducting layer for energizing a comb drive, a second conducting layer imparting a restoring force, and an insulating layer between the first and second conducting layers.Type: GrantFiled: September 7, 2010Date of Patent: June 25, 2013Assignee: Teledyne Scientific & Imaging, LLCInventors: Chialun Tsai, Jeffrey F. DeNatale
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Patent number: 8456249Abstract: A microscale apparatus includes a microscale rigidized Parylene strap having a reinforcement structure extending from a first side of the strap, a first silicon substrate suspended by the microscale rigidized Parylene strap, the microscale rigidized Parylene strap conformally coupled to the first substrate, and a second substrate conformally coupled to the microscale rigidized Parylene strap to suspend the first silicon substrate through the microscale rigidized Parylene strap.Type: GrantFiled: May 11, 2011Date of Patent: June 4, 2013Assignee: Teledyne Scientific & Imaging, LLC.Inventors: Jeffrey F. DeNatale, Philip A. Stupar, Yu-Hua Lin, Robert L. Borwick, Alexandros P. Papavasiliou
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Patent number: 8446551Abstract: The present invention relates to a method and apparatus to reduce dielectric discharge in liquid crystal cells driven with high voltage. In one embodiment, the present invention is a liquid crystal cell including a substrate with a surface and a tapered conductive film on top of the surface of the substrate including a first end and a second end. In another embodiment, the present invention is a method for forming a liquid crystal cell including covering a portion of a surface of a substrate with a shadow mask and then depositing conductive film onto the surface of the substrate such that the conductive film is tapered.Type: GrantFiled: December 10, 2007Date of Patent: May 21, 2013Assignee: Teledyne Scientific & Imaging, LLCInventor: Dong Feng Gu
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Patent number: 8440543Abstract: A method of improving thermal cycling reliability for a hybrid circuit structure requires providing at least two circuit layers, aligning two of the circuit layers vertically such that their respective circuit elements have a precise and well-defined spatial relationship, and providing an adhesive material which wicks into a portion of the space between the aligned layers so as to mitigate damage to the structure and/or interconnections that might otherwise occur due to thermal contraction mismatch between the layers. The adhesive material is required to have an associated viscosity such that, when provided under predetermined conditions, the adhesive stops wicking before reaching, and possibly degrading the performance of, the circuit elements.Type: GrantFiled: September 19, 2011Date of Patent: May 14, 2013Assignee: Teledyne Scientific & Imaging, LLCInventors: Donald E. Cooper, William E. Tennant
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Patent number: 8441626Abstract: An OAOA measurement system uses optical elements to converge incoming light from multiple sources onto an FPA as respective crosshair patterns made from lines which are oblique with respect to the FPA's axes, such that each pattern's location indicates the angular position of its corresponding source. The optical elements are arranged such that each crosshair's center point is at least twice as bright as the lines which form the crosshair's arms. The position of each crosshair is interpolated by defining regions around each arm of one of the crosshairs, determining the points of peak intensity in each row or column within each region, and curve-fitting the points to define each arm. Multiple crosshair patterns are accommodated by assigning a small magnitude value to each pixel of a defined arm, and then repeating the interpolation process for another crosshair.Type: GrantFiled: December 17, 2010Date of Patent: May 14, 2013Assignee: Teledyne Scientific & Imaging, LLCInventor: Bing Wen
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Publication number: 20130112376Abstract: A heat pipe apparatus having a sintered lattice wick structure includes a plurality of wicking walls having respective length, width and heights and spaced in parallel to wick liquid in a first direction along the respective lengths, the respective lengths being longer than the respective widths and the respective heights, the plurality of wicking walls being adjacent to one another and spaced apart to form vapor vents between them, a plurality of interconnect wicking walls to wick liquid between adjacent wicking walls in a second direction substantially perpendicular to the first direction, and a vapor chamber encompassing the sintered lattice wick structure, the vapor chamber having an interior condensation surface and interior evaporator surface, wherein the plurality of wicking walls and the plurality of interconnect wicking walls are configured to wick liquid in first and second directions and the vapor vents communicate vapor in a direction orthogonal to the first and second directions.Type: ApplicationFiled: December 24, 2012Publication date: May 9, 2013Applicant: TELEDYNE SCIENTIFIC & IMAGING, LLCInventor: Teledyne Scientific & Imaging, LLC
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Patent number: 8356959Abstract: A biomimetic system for mitigating marine bio-fouling is disclosed which is based upon the sacrificial skin mechanism found in the pilot whale species. The anti-bio-fouling system is characterized by the continuous in-situ underwater formation of a conformal protective skin around a submerged object or structure and employs a circulatory system embedded in a diffuser layer conformably fitted and secured to the structure to controllably deliver a sacrificial skin-forming material to the structural surface. The system advantageously utilizes the unique chemical properties of the skin-forming material to alter the material's viscosity in response to contact with sea water such that the material is uniformly distributed over the structure surface by a self-diffusion process, notwithstanding structural configuration or gravitational orientation, thus forming a stabilized waterproof layer or sacrificial skin.Type: GrantFiled: October 1, 2009Date of Patent: January 22, 2013Assignee: Teledyne Scientific & Imaging LLCInventors: Rahul Ganguli, Vivek Mehrotra
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Patent number: 8354885Abstract: An operational amplifier may include a transimpedance input stage. The operational amplifier is capable of self-biasing its input voltage(s) including a first stage, an input source connected to the first stage, an output stage connected to the first stage via feedback resistors, and feedback current sources connected to the first stage, wherein the feedback current sources are set to generate feedback currents flowing from the output stage back to the input stage via the feedback resistors, so as to self-bias the input voltage(s) at the input stage. A method for allowing for an op-amp to self-bias its input voltage(s), including generating feedback currents flowing from the output stage back to the input stage via feedback resistors, so as to self-bias the input voltage(s) at the input stage.Type: GrantFiled: May 25, 2012Date of Patent: January 15, 2013Assignees: The Regents of the University of California, Teledyne Scientific & Imaging, LLCInventors: Zachary M. Griffith, Miguel E. Urteaga, Mark J. W. Rodwell
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Patent number: 8353334Abstract: A lattice wick system that has a plurality of nano tube wicking walls configured to transport liquid through capillary action in a first direction, each set of the plurality of granular wicking walls forming respective vapor vents between them to transport vapor. A plurality of nano tube interconnect wicks embedded between respective pairs of the plurality of nano tube wicking walls transport liquid through capillary action in a second direction substantially perpendicular to the first direction. The nano tube interconnect wicks have substantially the same height as the nano tube wicking walls so that the plurality of nano tube wicking walls and the plurality of nano tube interconnect wicks enable transport of liquid through capillary action in two directions and the plurality of vapor vents transport vapor in a direction orthogonal to the first and second directions.Type: GrantFiled: June 27, 2008Date of Patent: January 15, 2013Assignee: Teledyne Scientific & Imaging, LLCInventors: Yuan Zhao, Chung-Lung Chen
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Patent number: 8334499Abstract: An optical angle of arrival measurement system uses an optical element to form at least one narrow width line on a focal plane array (FPA) which is oblique with respect to the FPA's row and column axes and which traverses at least two rows or columns along its length; forming two perpendicular narrow width lines in a cross-pattern is preferred. Interpolating the position of the lines on the FPA provides coordinates that can be used to calculate the optical angle of arrival in accordance with ?x=A(x)·tan?1(x/f), and ?y=B(y)·tan?1(y/f), where f is the focal length of the optical element, and A(x) and B(y) are parameters that account for optical distortion and other imperfections of the system. The resolution ?? of the angle of arrival measurement can be improved to at least ??˜(d/n)/f, where d is the FPA pixel width and n is the length in pixels of the imaged line.Type: GrantFiled: March 10, 2009Date of Patent: December 18, 2012Assignee: Teledyne Scientific & Imaging, LLCInventors: Jian Ma, Bruce K. Winker
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Patent number: 8330693Abstract: A two-stage drive waveform switches a DFLC from a high tilt state to a low tilt state quickly and without scattering. A relaxation voltage is applied to delay the onset of the high amplitude high frequency kick voltage when switching from a high tilt state to a low tilt state. The relaxation voltage allows the molecules to ‘relax’ in accordance with their own elasticity towards their low tilt state in the direction of the average azimuth angle of the low tilt state. The kick voltage is then applied to drive the molecules quickly to the low tilt state. Optimal switching time and the desired molecular response is achieved by delaying the onset of the large kick voltage via application of the relaxation voltage. The relaxation voltage may constitute a lower amplitude holding voltage, a small or zero DC voltage or a smooth windowing of the kick voltage.Type: GrantFiled: July 2, 2009Date of Patent: December 11, 2012Assignee: Teledyne Scientific & Imaging, LLCInventors: Bing Wen, Dong-Feng Gu
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Patent number: 8327684Abstract: The present invention relates to a method for adjusting the resonant frequencies of a vibrating microelectromechanical (MEMS) device. In one embodiment, the present invention is a method for adjusting the resonant frequencies of a vibrating mass including the steps of patterning a surface of a device layer of the vibrating mass with a mask, etching the vibrating mass to define a structure of the vibrating mass, determining a first set of resonant frequencies of the vibrating mass, determining a mass removal amount of the vibrating mass and a mass removal location of the vibrating mass to obtain a second set of resonant frequencies of the vibrating mass, removing the mask at the mass removal location, and etching the vibrating mass to remove the mass removal amount of the vibrating mass at the mass removal location of the vibrating mass.Type: GrantFiled: October 21, 2008Date of Patent: December 11, 2012Assignee: Teledyne Scientific & Imaging, LLCInventors: Jeffrey F. DeNatale, Philip A. Stupar
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Patent number: 8313797Abstract: Provided is a method for in-situ coating a substrate or matrix with magnetic metal nanoparticles. A metal salt, which may be organic or inorganic, is introduced into a solution of liquid polyol. In the presence of mechanical stirring and heat, a reduction process occurs wherein the magnetic metal nanoparticles precipitate out of solution and deposit or attach to one or more surfaces of the substrate. The concentration of reaction precursors, combined with the polyol, may be varied to control the size and shape of the magnetic nanoparticles.Type: GrantFiled: April 15, 2009Date of Patent: November 20, 2012Assignee: Teledyne Scientific & Imaging, LLCInventors: Julia J. Mack, Brian N. Cox, Vivek Mehrotra, Ten-Luen T. Liao, Rahul Ganguli
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Patent number: 8309197Abstract: Devices, systems and methods for fabricating improved ceramic composite turbine shrouds with abradable seals are disclosed. A high temperature seal with an abradable coating is provided. The seal comprises a three-dimensional, high-density woven composite base structure recessed below the abradable coating, with loops incorporated in and protruding from the base structure. The abradable coating is integrally attached to the base structure via the loops. Additionally, a graded density seal is provided with a three-dimensional, low-density woven composite structure. The low-density structure is abradable. A three-dimensional, high-density woven composite base structure is recessed below the low-density structure, with the low-density structure integrally attached to the base structure via weaving.Type: GrantFiled: December 17, 2008Date of Patent: November 13, 2012Assignee: Teledyne Scientific & Imaging, LLCInventors: Janet Davis, David Marshall, Olivier Sudre
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Patent number: 8310632Abstract: An adhesion promoter for enhancing the bond between adjacent layers of a multilayer structure to prevent delamination thereof is disclosed. The adhesion promoter comprises an aromatic polyimide-based UV-cured acrylate. Also disclosed are laminated structures including liquid crystal displays and bonded missile domes that utilize an adhesion promoter of the invention, and methods for fabricating such structures.Type: GrantFiled: May 4, 2010Date of Patent: November 13, 2012Assignee: Teledyne Scientific & Imaging, LLCInventor: Young J. Chung
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Patent number: 8292092Abstract: A macrocyclic pore-apertured carbon nanotube apparatus is disclosed. The carbon nanotube apparatus can be used to filter or exclude ions, solutes in solution, as well as particles suspended in a colloidal mixture. The nanotube apparatus includes a carbon nanotube having a carboxylated portion at least one pore entrance and at least one molecular aperture adapted to be bonded to the carboxylated portion of the carbon nanotube. The molecular aperture is further adapted to prevent dissolved ions in a solution from entering the pore entrance. Methods for preparing and using the apparatus are also disclosed. The apparatus can also be incorporated into to filtration media for conducting reverse osmosis filtration.Type: GrantFiled: September 8, 2009Date of Patent: October 23, 2012Assignee: Teledyne Scientific & Imaging, LLCInventors: Dennis R. Strauss, Martin W. Kendig
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Patent number: 8283632Abstract: Embodiments of a read-out integrated circuit (ROIC) include a plurality of unit cells. Each unit cell includes a bias subsystem, a reset switch, at least one integration capacitor, and at least one read switch. A focal plane array includes a plurality of photo detectors disposed in a grid and a ROIC. A column buffer includes a first buffer subsystem, a feedback subsystem, a first and second correlated double sampling subsystem, and a second buffer subsystem. A ROIC includes at least one integration subsystem having a transistor subsection, a poly silicon layer, and a plurality of active layer sections.Type: GrantFiled: September 29, 2006Date of Patent: October 9, 2012Assignee: Teledyne Scientific & Imaging, LLCInventors: Atul Joshi, Angelika Kononenko, David J. Chiaverini, Gananath Wijeratne, John C. Stevens, Selim Eminoglu, William E. Tennant