Patents Represented by Attorney Amy Ressing
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Patent number: 8189560Abstract: An apparatus for use with a first data device, a second data device, and a third data device operable to generate one of directly and indirectly an interrupt signal and to disable one of directly and indirectly the interrupt signal. The apparatus includes a switch connectable to the first data device, the second data device, and the third data device, the switch in a first state connecting the first data device and the second data device, the switch in a second state being operable, upon detection by the switch of the interrupt signal, to disconnect automatically the first data device from the second data device and to connect automatically thereafter the first data device to said the data device.Type: GrantFiled: May 30, 2008Date of Patent: May 29, 2012Assignee: The United States of America as represented by the Secretary of the NavyInventors: Daniel Taibi, Robert Roberts, Eric Vandersall
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Patent number: 8175827Abstract: An rf probe is placed within a plasma and an rf signal from a network analyzer for a given dc bias voltage Vp is applied The frequency applied by the network analyzer, ?, is less than the plasma frequency, ?pe, and therefore is not in the resonant absorption range (?=?pe) used to determine electron density in typical rf impedance probe operation. Bias voltages at the applied frequency are applied to the probe in a series of voltage steps in a range which includes the plasma potential. At each bias step, a value of Re(Zac), the real part of the plasma's complex impedance, is returned by the analyzer. A local minimum in the real part of the impedance Re(Zac) occurs where the applied bias voltage Vp equals the plasma potential ?p. The plasma potential ?p can be found by taking the first derivative of Re(Zac) with respect to Vp, ? ( Re ? ( Z a ? ? c ) ? V p , and finding the value of Vp at which ? ( Re ? ( Z a ? ? c ) ? V p = 0 within error tolerances.Type: GrantFiled: July 13, 2011Date of Patent: May 8, 2012Assignee: The United States of America as represented by the Secretary of the NavyInventors: David N. Walker, Richard F. Fernsler, David D. Blackwell, William E. Amatucci
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Patent number: 8173084Abstract: A high purity nano-sized Yb3+ doped Y2O3 (Yb:Y2O3) ceramic powder with a narrow size distribution and without hard agglomerates is provided. Also provided is a process for manufacturing the same wherein water in the reaction bath is replaced by a non-water washing agent having little or no hydrogen bonding capability to inhibit the formation of hard agglomerates in the ceramic powder.Type: GrantFiled: November 18, 2009Date of Patent: May 8, 2012Assignee: The United States of America as represented by the Secretary of the NavyInventors: Woohong Kim, Jasbinder S. Sanghera, Guillermo R Villalobos, Shyam S Bayya, Ishwar D. Aggarwal
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Patent number: 8163874Abstract: Disclosed is a method of making peptide structures that are stable in aqueous and non-aqueous media where a first linear peptide chain comprising alternating D,L- or L,D-amino acids having an N and C termini is joined by at least one turn region to a second linear peptide chain comprising alternating D,L- or L,D-amino acids having an N and C termini. The peptide chains can be joined at the C terminus of one of the linear peptide chains with an N terminus of the other linear peptide chain, a C terminus of one of the linear peptide chains with a C terminus of the other linear peptide chain, or an N terminus of one of the linear peptide chains with an N terminus of the other linear peptide chain.Type: GrantFiled: August 6, 2008Date of Patent: April 24, 2012Assignee: The United States of America, as represented by the Secretary of the NavyInventors: John L Kulp, Thomas D Clark
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Patent number: 8144392Abstract: A waveguide amplifier, disposed on a substrate, composed of sputtered film of chalcogenide glass doped with Erbium is disclosed. The amplifier includes a substrate, a thick film of chalcogenide glass disposed on the substrate, a pumping device, and an optical combining device, wherein the waveguide is operable to amplify the optically combined signal. This type of amplifier has been shown to be compact and cost-effective, in addition to being transparent in the mid-IR range as a result of the low phonon energy of chalcogenide glass.Type: GrantFiled: February 12, 2007Date of Patent: March 27, 2012Assignee: The United States of America as represented by the Secretary of the NavyInventors: Jasbinder S Sanghera, Ishwar D Aggarwal, Jesse A. Frantz, Leslie Brandon Shaw
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Patent number: 8137624Abstract: Provided is a method and apparatus for attaching a fluid cell to a planar substrate. The planar substrate may have on it sensors or devices for detecting components within the fluid, and/or be treated to selectively bind or react with components within the fluid. Substrates might include solid-state IC integrated circuit sensor microchips, glass slides, genomic and proteomic arrays, and or other suitable substrates that can make conformal contact with the fluid cell. The fluid cell can be mounted directly on top of the substrate to easily create a fluidic system in a wide variety of implementations. The assembly does not require modification of the substrate; all the fluidic connections are inherent in the apparatus. The present device can be made using low-cost materials and simple methods.Type: GrantFiled: August 15, 2007Date of Patent: March 20, 2012Assignee: The United States of America as represented by the Secretary of the NavyInventors: Michael P. Malito, Cy R. Tamanaha, Lloyd J Whitman
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Patent number: 8137988Abstract: This invention describes a method of using controlled fluidic forces to improve the performance of a biochemical binding assay where a target molecule is captured by specific molecular recognition onto a substrate surface with an affinity coating, and then labeled with a detectable micrometer-scale particle using a second specific molecular recognition reaction with the target. By using specific ranges of label sizes and laminar flow conditions, controlled fluidic forces can be applied to the label particles in order to selectively remove molecules bound to a surface according to their binding strength, and thereby increase the ratio of specifically bound labels to more weakly attached non-specifically bound labels. This method can be used with a wide variety of label types and associated detection methods, improving the sensitivity and selectivity of a broad range of binding assays.Type: GrantFiled: September 22, 2009Date of Patent: March 20, 2012Assignee: The United States of America as represented by the Secretary of the NavyInventors: Jack C Rife, Lloyd J Whitman
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Patent number: 8125706Abstract: A gain medium and an interband cascade laser, an interband cascade amplifier, and an external cavity laser having the gain medium are presented.Type: GrantFiled: March 12, 2009Date of Patent: February 28, 2012Assignee: The United States of America as represented by the Secretary of the NavyInventors: Igor Vurgaftman, Jerry R Meyer, Chadwick L. Canedy, William W. Bewley, James R. Lindle, Chul-soo Kim, Mijin Kim
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Patent number: 8105509Abstract: A transparent polycrystalline ceramic having scattering and absorption loss less than 0.2/cm over a region comprising more than 95% of the originally densified shape and further provides a process for fabricating the same by hot pressing. The ceramic can be any suitable ceramic such as yttria (Y2O3) or scandia (Sc2O3) and can have a doping level of from 0 to 20% and a grain size of greater than 30 ?m, although the grains can also be smaller than 30 ?m. In a process for making a transparent polycrystalline ceramic in accordance with the present invention, ceramic nanoparticles can be coated with a sintering aid to minimize direct contact of adjacent ceramic powder particles and then baked at high temperatures to remove impurities from the coated particles. The thus-coated particles can then be densified by hot pressing into the final ceramic product. The invention further provides a transparent polycrystalline ceramic solid-state laser material and a laser using the hot pressed polycrystalline ceramic.Type: GrantFiled: November 18, 2009Date of Patent: January 31, 2012Assignee: The United States of America as represented by the Secretary of the NavyInventors: Jasbinder S. Sanghera, Guillermo R Villalobos, Woohong Kim, Shyam S Bayya, Ishwar D. Aggarwal, Bryan Sadowski
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Patent number: 8094519Abstract: A fiber optic hydrophone has a reflective diaphragm having an exposed face and a reflective protected face, at least one transmitting multimode optical fiber having an end spaced apart from the protected face of the diaphragm positioned to emit light toward the diaphragm housing, and a reservoir. A cavity is defined by the diaphragm and the interior surface of the housing. Silicone oil and a compliant elastomeric material with embedded air bubbles are located in the cavity. Ports between the cavity and the reservoir and the reservoir and the exterior of the hydrophone allow static pressure communication between the cavity and the exterior of the hydrophone. The fiber optic probe can have one transmitting multimode optical fiber and six receiving multimode optical fibers, or more or fewer optical fibers. A grating can protect the diaphragm from environmental damage.Type: GrantFiled: August 16, 2011Date of Patent: January 10, 2012Assignee: The United States of America as represented by the Secretary of the NavyInventors: Nicholas Lagakos, Joseph A. Bucaro, Jacek Jarzynski, Barbara Jarzynski, legal representative
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Patent number: 8056222Abstract: A laser direct write method used to transfer entire single components such as semiconductor bare dies or surface mount passive and active components on a substrate or inside recess in a substrate for making embedded microelectronics is disclosed. This method laser-machine the pockets, laser-transfer the individual components inside those pockets, and then laser-print the interconnects required to “wire” the components, thus resulting in a fully assembled embedded circuit required to make a fully functional microelectronic system.Type: GrantFiled: February 20, 2009Date of Patent: November 15, 2011Assignee: The United States of America, as represented by the Secretary of the NavyInventors: Alberto Pique, Scott A Mathews, Raymond C Y Auyeung, Bhanu Pratrap Sood
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Patent number: 8058869Abstract: The device includes two supports and a primary conductive strip. The primary conductive strip includes a neutral surface, a first side, and a second side. The primary conductive strip is connected one of directly and indirectly on the first side to the two supports such that the primary conductive strip is constrained in two dimensions and movable in one dimension. The device also includes a primary distributed feedback fiber laser. The primary distributed feedback fiber laser includes a fiber axis. The primary distributed feedback fiber laser is connected to the primary conductive strip along one of the first side and the second side such that there is a positive distance between the neutral surface of the primary conductive strip and the fiber axis of the primary distributed feedback fiber laser.Type: GrantFiled: October 21, 2008Date of Patent: November 15, 2011Assignee: The United States of America as represented by the Secretary of the NavyInventors: Geoff A Cranch, Gordon M. A. Flockhart
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Patent number: 8048547Abstract: A fuel cell comprising an anode chamber, a cathode chamber, and a nanoporous membrane between the anode chamber and the cathode chamber, wherein the nanoporous membrane sequesters and isolates a microbe in the anode chamber. The nanoporous membrane allows nutrients to flow actively or passively from the cathode chamber to the anode chamber and can be modified by a thin film composite (TFC) to create a TFC nanofiltration membrane. The nanoporous membrane can have a pore size from about 100 nm to about 1000 nm. A method of making a fuel cell comprising configuring a nanoporous membrane between an anode chamber and a cathode chamber wherein the nanoporous membrane sequesters and isolates a microbe in the anode chamber and can be used to protect the cathode chamber.Type: GrantFiled: October 30, 2007Date of Patent: November 1, 2011Assignee: The United States of America, as represented by the Secretary of the NavyInventors: Bradley R. Ringeisen, Justin C. Biffinger
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Patent number: 8050141Abstract: A system and method is provided for estimating a trajectory of an incoming bullet based on the acoustics of the shock wave created as the bullet travels through the air. A first auditory signal representing a direct sound from the shock wave is recorded and its azimuthal direction is determined. Based on this azimuthal direction and other assumptions two possible bullet directions that can cause that shock wave are estimated. A second auditory signal representing a reflection of the shock wave as it travels through the air also is recorded and its azimuthal direction determined. The azimuthal direction of the ground reflection will lie between the azimuthal direction of the first auditory signal and the more correct of the two estimated trajectories, and thus can resolve the ambiguity in the estimated direction of the bullet source.Type: GrantFiled: November 21, 2008Date of Patent: November 1, 2011Assignee: The United States of America as represented by the Secretary of the NavyInventors: Thomas L. Carroll, Graham K. Hubler
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Patent number: 8029921Abstract: A semiconductor device including a ferrite layer, a widebandgap semiconductor material layer, and a buffer layer. The buffer layer comprises an interweaving of MgO and BaM. In addition the buffer layer allows a gradual reduction of the interfacial stress, and mediates the strain between a silicon substrate and a ferrite layer of the device. In addition, the buffer layer allows for high crystal alignment resulting in high crystal quality and thereby producing a low microwave loss semiconductor device. The buffer layer also minimizes chemical interdiffusion of atoms between the substrate and the ferrite layer.Type: GrantFiled: October 4, 2006Date of Patent: October 4, 2011Assignee: The United States of America as represented by the Secretary of the NavyInventors: Vincent G Harris, Zhaohui Chen
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Patent number: 8022006Abstract: A catalyst nanoparticle covalently bonded to a surface ligand wherein the surface ligand has a peripheral functional group having a property suitable to ensure solubility in a fluid such as a hydroxylic solvent, water, lower molecular weight alcohol, methanol, ethanol, iso-propanol, or and mixtures thereof. The peripheral functional group can have an ability to couple the catalyst nanoparticle to a second catalyst nanoparticle or to a bridging material. The peripheral functional group can be capable of interacting with a surface functional group on a conductive electrode substrate. The covalently-bound ligand bearing a peripheral functional group can have a charge opposite to or chemical reactivity amenable with that of the surface functional group. A method of making a catalyst nanoparticle comprising bonding a surface ligand to a catalyst nanoparticle wherein the bonding is via a covalent bond and the surface ligand has a peripheral functional group.Type: GrantFiled: August 25, 2006Date of Patent: September 20, 2011Assignee: The United States of America as represented by the Secretary of the NavyInventors: Walter J. Dressick, Cynthia N. Kostelansky, Terence L. Schull
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Patent number: 8021991Abstract: Oxide films are deposited under conditions generating a silicon-rich oxide in which silicon nanoclusters form either during deposition or during subsequent annealing. Such deposition conditions include those producing films with optical indices (n) greater than 1.46. The method of the present invention reduces the TID radiation-induced shifts for the oxides.Type: GrantFiled: February 28, 2006Date of Patent: September 20, 2011Assignee: The United States of America as represented by the Secretary of the NavyInventors: Harold L Hughes, Bernard J Mrstik, Reed K Lawrence, Patrick J McMarr
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Patent number: 8012616Abstract: An improved benthic microbial fuel cell for generating energy at the interface of aquatic sediment and seawater includes an anode electrode embedded within the aquatic sediment, a cathode electrode positioned within the seawater and above the aquatic sediment, a rig for maintaining the relative positions of the anode and cathode electrodes, electrical leads extending from the anode and cathode electrodes to a load, wherein the anode electrode comprises a bottlebrush electrode residing within a permeable tube. The apparatus is easier to deploy than previously-described fuel cells, while being lighter, more durable, and generating greater power density. Also disclosed are methods of generating power from such an apparatus.Type: GrantFiled: December 15, 2010Date of Patent: September 6, 2011Assignee: The United States of America as represented by the Secretary of the NavyInventor: Leonard M. Tender
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Patent number: 8009995Abstract: A method and apparatus for receiving a digital signal having a plurality of significant bits of resolution. The apparatus includes a mode locked laser comprising a single output. The apparatus also includes a beam divider operable to receive the single output. The apparatus also includes a plurality of optical modulators operable to communicate with said beam divider and operable to receive a respective plurality of signals corresponding to a plurality of significant bits of resolution. Optionally, the apparatus also includes a source operable to output a digital waveform with the plurality of signals corresponding to the plurality of significant bits of resolution of the digital waveform, the plurality of signals operable to drive the plurality of optical modulators.Type: GrantFiled: September 27, 2006Date of Patent: August 30, 2011Assignee: The United States of America as represented by the Secretary of the NavyInventors: Currie Marc, Lou W. Janet
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Patent number: 8005767Abstract: The present invention enables identification of events such as target. From training target event data the present a very large number of clusters are formed for each class based on Euclidean distance using a repetitive k-means clustering process. Features from each cluster are identified by extracting out their dominant eigenvectors. Once all of the dominant eigenvectors have been identified, they define the relevant space of the cluster. New target event data is compared to each cluster by projecting it onto the relevant and noise spaces. The more the data lies within the relevant space and the less it lies within the noise space the more similar the data is to a cluster. The new target event data is then classified based on the training target event data.Type: GrantFiled: June 1, 2007Date of Patent: August 23, 2011Assignee: The United States of America as represented by the Secretary of the NavyInventor: Vincent A. Cassella