| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 101 | System, method and program product for automatically matching new members of a population with analogous members | US13711616 | 2012-12-12 | US09417256B2 | 2016-08-16 | Mohamed Ahmed Hegazy; Sonia Mariette Embid Droz; Hilario Martin Rodriguez; Bruno Da Costa Flach; Davi Michel Valladao; Bianca Zadrozny |
| A population comparison system, method and a computer program product therefor. A stored list of population members, e.g., hydrocarbon reservoirs, characteristics and analogous members is partitioned into lists for each member. A weighting system automatically uses the partitions to determine a weight set (w*) for population member characteristic and a similarity function. The weighting system may include an objective model that iteratively, blindly identifies analogous members for each population member until the identified analogous members match the listed analogous members. An analogous member selector uses the weights set (w*) and similarity function to automatically select analogous listed members for each new population member. | ||||||
| 102 | Uninhabited test city | US13436531 | 2012-03-30 | US09361810B2 | 2016-06-07 | Robert H. Brumley; Robert H. Brumley, III; Michael J. Reedy; Fletcher W. Brumley; Charles Warner |
| A full scale uninhabited test facility is configured for building modular man made structures, evaluating modular man made structures, evaluating use of modular man made structures, and/or for other purposes. The structures may be located in a user configurable simulated environment. One or more structures may be configured to simulate use by inhabitants in a simulated environment. After testing, the constructed structure(s) may remain where built in the simulated environment(s) until such time as another user may reconfigure the environments or structures. As additional structures are built and/or modified, new and old structures may operate side by side, generating opportunity, for example, to test new and/or different technology on the same structures. | ||||||
| 103 | METHOD FOR PRODUCING MICROCHANNEL, AND MICROCHANNEL | US14655239 | 2013-12-18 | US20150329354A1 | 2015-11-19 | Seiko KATO; Masafumi IDE; Takaaki NOZAKI; Takaaki TAKEISHI; Takaaki ISHIGURE; Kazutomo SOMA |
| Provided is a method for producing a microchannel including an approximately circular cross section with neither a joined surface nor an inlet in a smaller number of steps than has been conventional. The method for producing a microchannel includes the steps of forming a layer of an uncured curable resin (2) on a substrate (1), inserting into the curable resin a needle body (3) that can inject a liquid (4), injecting a liquid in a tubular shape into the curable resin via the needle body while moving the needle body, extracting the needle body from the curable resin, and curing the curable resin to form a channel (4A) in a tubular region injected with the liquid. | ||||||
| 104 | Method and System For Overlay Control | US14733300 | 2015-06-08 | US20150268564A1 | 2015-09-24 | Yang-Hung Chang; Chih-Ming Ke; Kai-Hsiung Chen |
| A method for overlay monitoring and control is introduced in the present disclosure. The method includes selecting a group of patterned wafers from a lot using a wafer selection model; selecting a group of fields for each of the selected group of patterned wafers using a field selection model; selecting at least one point in each of the selected group of fields using a point selection model; measuring overlay errors of the selected at least one point on a selected wafer; forming an overlay correction map using the measured overlay errors on the selected wafer; and generating a combined overlay correction map using the overlay correction map of each selected wafer in the lot. | ||||||
| 105 | Method and system for overlay control | US14017793 | 2013-09-04 | US09053284B2 | 2015-06-09 | Yang-Hung Chang; Kai-Hsiung Chen; Chih-Ming Ke |
| A method for overlay monitoring and control is introduced in the present disclosure. The method comprises forming resist patterns on one or more wafers in a lot by an exposing tool; selecting a group of patterned wafers in the lot using a wafer selection model; selecting a group of fields for each of the selected group of patterned wafers using a field selection model; selecting at least one point in each of the selected group of fields using a point selection model; measuring overlay errors of the selected at least one point on a selected wafer; forming an overlay correction map using the measured overlay errors on the selected wafer; and generating a combined overlay correction map using the overlay correction map of each selected wafer in the lot. | ||||||
| 106 | Method for fabricating a microarray of soft materials | US13814588 | 2012-03-27 | US08999443B2 | 2015-04-07 | Satoshi Hiyama; Kaori Kuribayashi; Hiroaki Onoe; Shoji Takeuchi |
| A method for fabricating a microarray of plural soft materials includes: vapor-depositing a first layer poly(para-xylylene) resin on a substrate, forming a first micro pattern in the poly(para-xylylene) resin; obtaining a substrate including a first microarray formed by pouring a first soft material solution, freeze-drying the first soft material to obtain a micro-arrayed substrate of the freeze-dried first soft material; vapor-depositing a second layer poly(para-xylylene) resin on the micro-arrayed substrate of the freeze-dried first soft material, forming a second micro pattern placed differently from the first micro pattern by penetrating the poly(para-xylylene) resin of the first and second layers, forming a second microarray on the substrate by pouring a second soft material solution; and forming a microarray of the first and second soft materials on the substrate by peeling off the poly(para-xylylene) resin of the first and second layers. | ||||||
| 107 | Gravitational attenuating material | US13506975 | 2012-05-29 | US08901943B1 | 2014-12-02 | Ronald J. Kita |
| A gravitational attenuating material that utilizes an organic based material that has the electrons of the dielectric reconfigured through the use of electrostatic fields, magnetic fields, or photonic or actinic radiation as to render the dielectric less interactive with gravitational forces. The dielectric material is a solid, homo-charged, bipolar binary material having aligned dipoles and made of a polymer and hydrocarbon molecules. Each of the hydrocarbon molecules has at least one aromatic ring and cyclic electron ring current therein. The hydrocarbon molecules are benzene-series molecules, substituted-benzene-series molecules, chloronapthalene molecules, 1,4-dichloronapthalene molecules, chlorobenzene molecules, or 1,2,3-trichlorobenzene molecules. | ||||||
| 108 | SYSTEM, METHOD AND PROGRAM PRODUCT FOR AUTOMATICALLY MATCHING NEW MEMBERS OF A POPULATION WITH ANALOGOUS MEMBERS | US13711616 | 2012-12-12 | US20140163901A1 | 2014-06-12 | Mohamed Ahmed Hegazy; Sonia Mariette Embid Droz; HILARIO Martin RODRIGUEZ; Bruno Da Costa Flach; Davi Michel Valladao; Bianca Zadrozny |
| A population comparison system, method and a computer program product therefor. A stored list of population members, e.g., hydrocarbon reservoirs, characteristics and analogous members is partitioned into lists for each member. A weighting system automatically uses the partitions to determine a weight set (w*) for population member characteristic and a similarity function. The weighting system may include an objective model that iteratively, blindly identifies analogous members for each population member until the identified analogous members match the listed analogous members. An analogous member selector uses the weights set (w*) and similarity function to automatically select analogous listed members for each new population member. | ||||||
| 109 | CIRCUITS AND METHODS FOR ARTIFACT ELIMINATION | US14133834 | 2013-12-19 | US20140107981A1 | 2014-04-17 | Edgar A. Brown; James D. Ross; Richard A. Blum; Stephen P. Deweerth |
| Disclosed are apparatus and methods that provide the ability to electrical stimulate a physical system, and actively eliminate interference with signal acquisition (artifacts) that arises from the stimulation. The technique implemented in the circuits and methods for eliminating interference connects a discharge path to a physical interface to the system to remove charge that is built-up during stimulation. By placing the discharge path in a feedback loop that includes a recording preamplifier and AC-coupling circuitry, the physical interface is brought back to its pre-stimulation offset voltage. The disclosed apparatus and methods may be used with piezoelectric transducers, ultrasound devices, optical diodes, and polarizable and non-polarizable electrodes. The disclosed apparatus can be employed in implantable devices, in vitro or in vivo setups with vertebrate and invertebrate neural tissue, muscle fibers, pancreatic islet cells, osteoblasts, osteoclasts, bacteria, algae, fungi, protists, and plants. | ||||||
| 110 | Method and apparatus for approximating effects of transcranial magnetic stimulation to a brain | US13823114 | 2012-10-15 | US20140107931A1 | 2014-04-17 | Katja Pesola; Ilkka Autio |
| The present invention relates generally to a method and apparatus for determining one or more cumulative effects of an application of transcranial magnetic stimulation to the brain of a subject, as well as a method and apparatus of representing same. According to an aspect of certain embodiments of the invention there is provided a method for determining one or more cumulative effects of an application of transcranial stimulation to one or more locations in a brain of a subject comprising the steps of applying multiple transcranial magnetic stimulation pulses to the brain, determining a dose of each of said stimulation pulses, measuring a physical response of the user and determining or approximating an accumulation of said response of said brain for each of said one or more locations in the brain of said subject. | ||||||
| 111 | Data storage device tester | US12749243 | 2010-03-29 | US08626463B2 | 2014-01-07 | Curtis E. Stevens; Lawrence J. Dalphy |
| A data storage device (DSD) tester is disclosed for testing a DSD. The DSD tester comprises control circuitry operable to receive production line data through an interface, wherein the production line data is related to the DSD. The control circuitry executes a DSD test on the DSD, and transmits failure data generated by the DSD test and the production line data to a failure information database. | ||||||
| 112 | GAS-MEASURING PROBE FOR DETERMINING THE PHYSICAL CHARACTERISTIC OF A MEASURING GAS | US13788190 | 2013-03-07 | US20130186176A1 | 2013-07-25 | Bernhard WILD; Rainer MAIER; Gregor JAEHNIG; Peter DETTLING; Stefan HEINZELMANN; Bernd RATTAY; Bastian BUCHHOLZ; Juergen MORATZ |
| A gas-measuring probe for determining a physical characteristic of a measuring gas, in particular the concentration of a gas component or the temperature or pressure of the measuring gas, which includes a sensor element accommodated in a housing, at least one connection cable for the sensor element having an electrical conductor, which is enclosed by an insulation sheath and contacts the sensor element, and a cable channel sealing the housing end, which has at least one axial cable feedthrough through which the connection cable is guided out of the housing. To achieve long-lasting sealing at the cable-exit end of the housing even at higher temperatures, the insulation sheath of the connection cable is at least regionally welded to the cable wall of the cable feedthrough. To this end, a tube made of a material that fuses with the insulation sheath and the cable channel when heated is slipped over the cable section of the connection cable lying inside the cable channel. | ||||||
| 113 | METHOD FOR FABRICATING A MICROARRAY OF SOFT MATERIALS | US13814588 | 2012-03-27 | US20130136863A1 | 2013-05-30 | Satoshi Hiyama; Kaori Kuribayashi; Hiroaki Onoe; Shoji Takeuchi |
| A method for fabricating a microarray of plural soft materials includes: vapor-depositing a first layer poly(para-xylylene) resin on a substrate, forming a first micro pattern in the poly(para-xylylene) resin; obtaining a substrate including a first microarray formed by pouring a first soft material solution, freeze-drying the first soft material to obtain a micro-arrayed substrate of the freeze-dried first soft material; vapor-depositing a second layer poly(para-xylylene) resin on the micro-arrayed substrate of the freeze-dried first soft material, forming a second micro pattern placed differently from the first micro pattern by penetrating the poly(para-xylylene) resin of the first and second layers, forming a second microarray on the substrate by pouring a second soft material solution; and forming a microarray of the first and second soft materials on the substrate by peeling off the poly(para-xylylene) resin of the first and second layers. | ||||||
| 114 | AirFromThere - Exotic air system | US12558633 | 2009-09-14 | US20110061342A1 | 2011-03-17 | Edward HELBLING |
| According to the invention air is trapped at an origin location in a container, and the container is sealed to hermetically confine the trapped air therein. The container is then provided with literature identifying the origin location at which the air was trapped and giving other information regarding this origin location. Then the container with the literature is shipped to a destination location distant from the origin location. Finally the container is opened and the trapped air is consumed. | ||||||
| 115 | NUCLEOTIDE ANALOGS WITH SIX-MEMBERED RINGS | US11846555 | 2007-08-29 | US20080038745A1 | 2008-02-14 | Frank Bergmann; Horst Donner; Herbert Von Der Eltz; Dieter Heindl; Piet Herdewijn |
| The present invention is related to compounds comprising six-membered rings capable of being incorporated into nucleic acids. Particularly, the six-membered ring is a derivative of cyclohexane, cyclohexene, tetrahydropyran, tetrahydrothiopyran or piperidine. These compounds may be used to build up oligomeric compounds. The invention is further related to uses of these oligomeric compounds for hybridization and as probes. In addition, methods for the detection of nucleic acids are provided wherein the oligomeric compounds are used. | ||||||
| 116 | PRÜFGERÄT UND VERFAHREN ZUR KALIBRIERUNG EINES PRÜFGERÄTS | EP12740480.4 | 2012-07-03 | EP2729797B1 | 2018-12-05 | BLOSS, Michael; DECKENBACH, Wolfgang; HEIMANN, Werner; EHRL, Hans-Peter; KERST, Erich |
| 117 | METHOD FOR REMOVING LIQUID, AND LIQUID OPERATION DEVICE | EP16864098.5 | 2016-11-02 | EP3376234A1 | 2018-09-19 | IWASHITA, Atsuo; AOKI, Youichi; MIYAZAKI, Koji |
The present invention provides a method for removing liquid from the interior of a flow channel tip, which enables both to reduce the amount of liquid remaining and prevent the time spent removing the liquid from being longer than necessary. The method comprises: suctioning a liquid within a flow channel, the liquid being suctioned into the interior of a liquid suction implement inserted into a first through-hole of a flow channel tip; and removing the liquid within the flow channel. This method comprises: a first suction step for suctioning some of the liquid within the flow channel at a first suction speed; and a second suction step for suctioning the liquid remaining within the flow channel at a second suction speed that is less than the first suction speed, the second suction step being performed in continuation from the first suction step. |
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| 118 | ANALYSIS DEVICE AND ANALYSIS METHOD | EP16850704.4 | 2016-03-18 | EP3358349A1 | 2018-08-08 | IWAMA, Shigehiko; ITONAGA, Makoto; HASEGAWA, Yuichi; TSUJITA, Koji; ONO, Masayuki; IGARASHI, Makoto |
An analysis device (1) includes a turntable (10) holding a substrate (60), an optical pickup (20) driven in a direction perpendicular to a rotation axis (C10) of the turntable (10) and configured to emit laser light (20a) to reaction regions (65) and to receive reflected light from the respective reaction regions (65), an optical pickup drive circuit (8), and a controller (9). The reaction regions (65) are formed at positions different from the center (Ca) of the substrate (60) . The center (Ca) of the substrate (60) is located on the rotation axis (C10) of the turntable (10). The optical pickup (20) detects a reception level of the reflected light to generate a light reception level signal (KS) . The controller (9) controls a turntable drive circuit (4) to rotate the substrate (60), controls the optical pickup drive circuit (8) to drive the optical pickup (20), and specifies the respective reaction regions (65) in accordance with a positional information signal (PS) and the light reception level signal (KS). |
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| 119 | FLUID HANDLING DEVICE AND METHOD FOR MANUFACTURING FLUID HANDLING DEVICE | EP15866983 | 2015-10-29 | EP3231507A4 | 2018-06-20 | SUNAGA NOBUYA; MURAKI KOJI |
| In the present invention, a fluid handling device has: a first substrate made of resin whereon a channel is formed in a first surface; a first film made of resin and joined to the first surface of the first substrate; a second film made of resin a first surface of which is joined to a second surface of the first substrate; and a second substrate made of resin and joined to a second surface of the second film. A recessed part overlapping the channel in a plane view is formed on the surface of the second substrate joined to the second film. The glass transition temperature Tg 1s of the first substrate, the glass transition temperature Tg 1f of the first film, the glass transition temperature Tg 2s of the second substrate, and the glass transition temperature Tg 2f of the second film satisfy Tg 1s , Tg 2s > Tg 1f , Tg 2f . | ||||||
| 120 | MICRO LIQUID TRANSFER STRUCTURE AND ANALYSIS DEVICE | EP15863839 | 2015-11-27 | EP3226003A4 | 2018-06-20 | OONUKI RYUUJI; KUNINORI MASAHIRO; IWASAKI TSUTOMU |
| Unit rows are periodically arranged in which a plurality of micro projections 60 are arranged in one row and spaces between the adjacent micro projections 60 are formed as liquid transfer paths 61, the micro projections 60 are arranged so that an interval between the respective micro projections 60 becomes an interval to cause a capillary action, and the micro projections 60 are arranged so that in each of the unit rows, at least one of the liquid transfer paths 61 is formed as a low flow resistance liquid transfer path 61 a in which a flow resistance is relatively lowered than in other liquid transfer paths 61 b, and the low flow resistance liquid transfer paths 61 a are disposed along a predetermined liquid transfer direction. Consequently, the liquid transfer direction is optionally controllable with good reproducibility and without causing any deviation in the liquid transfer direction. | ||||||
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