| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 41 | A method for a wireless communication system planning | JP53645296 | 1996-04-12 | JPH10503915A | 1998-04-07 | タン・ユキアン; ダグラス リード・ジョン |
| (57)【要約】 無線通信システム計画のための方法は、第1の実施形態では、あるカバレージ領域内の送信位置(401)および反射(415)および回折(425)面に基づき、イメージツリーを決定する段階(500)、および該イメージツリーを制限して所定の数の反射および/または回折を必要とする高次のイメージ、または親のイメージの範囲内にない面に対応する可能性ある子供のイメージに対する分岐を排除する段階(530,560)を含む。 前記イメージツリーおよび伝搬経路のバックトレーシング(620)に基づき、受信信号品質尺度(例えば、電力)が各々の送信位置に対して決定される。 異なる受信信号電力を比較することにより、最適の受信機ユニットの位置が決定される。 さらに、他のアンテナ位置/組合わせに対しバックトレーシングを行ない、かつダイバシティ効果を比較することにより(864,865)、総合的なカバレージ品質が各々のアンテナの組合わせに対して決定することができかつ比較されて最適のベースダイバシティアンテナ位置を生成する(867)。 | ||||||
| 42 | METHOD OF IMAGING MOVING OBJECT AND IMAGING DEVICE | EP15899757.7 | 2015-11-25 | EP3329665A1 | 2018-06-06 | SEO, Chang-woo; LEE, Jae-ho; KIM, Do-han |
| An imaging device configured to image a moving object includes a sensing unit configured to obtain location information of the imaging device; a processor configured to determine a moving trajectory of the moving object using the location information; an interface configured to output a first image representing the moving trajectory; and an image processor configured to generate the first image and a second image representing the moving object based on the moving trajectory. | ||||||
| 43 | CORRECTING AND VERIFYING METHOD, AND CORRECTING AND VERIFYING DEVICE | EP15829298 | 2015-07-14 | EP3179443A4 | 2017-08-02 | UEDA JUNKO |
| A correcting and verifying method and a correcting and verifying device cause a processor to display a specific frame image as a frame image to be confirmed based on a tracking result of a moving body in each of a plurality of frame images which configure a video, and to correct a position of the moving body in the frame image to be confirmed in a case where a correction instruction of a user is received. | ||||||
| 44 | Passive acoustic ranging system using atmospheric dispersion | EP13167920.1 | 2013-05-15 | EP2667216B1 | 2017-07-12 | Jiang, Qin; Daily, Michael J; Kremer, Richard Michael |
| 45 | A SYSTEM A METHOD AND AN APPARATUS FOR PERFORMING WIRELESS MEASUREMENTS, POSITIONING AND SURFACE MAPPING BY MEANS OF A PORTABLE COORDINATE SYSTEM | EP05709119.1 | 2005-02-23 | EP1743137A2 | 2007-01-17 | Ash, Chaim; Volodine, Yuri G.; Novikov, Lenny M.; Kovtun, Michael |
| The present invention is a new multifunctional low-cost solution for performing measurements and positioning in construction sites and automatically extracting a three-dimensional virtual model, plans, elevations and sections drawings based on these measurements. The preferred embodiment of the present invention consists of a field beacon FB3 or a set of field beacons FB1-FB14, spread around the measured area, communicating by omnidirectional signals with at least one central signal collector 100, which communicates with a computer. Dedicated computer software performs the spatial calculations and other applicable functions. The disclosed system is used for laying out axes and columns at the beginning stage of construction while ensuring the exact match of each mark to its planned position, and for quality and exactitude control of constructions or assembling. In addition the system may be used for locating and tracking objects in a predefined area and automatic directing of machinery to target points. | ||||||
| 46 | Apparatus and method for determining geographical location relative to a designated geographical location | EP04009613.3 | 2004-04-22 | EP1482322A3 | 2005-11-09 | Cheon, Mun-Ki |
The present invention provides an apparatus and method that allows the geographical location of a user with respect to a designated geographical location to be determined in a manner that cost-efficient, the user given several options regarding the way in which his or her present location is determined as well as the format in which the user's relative position to the designated geographical location is represented and the apparatus being easy to operate and relatively lightweight. |
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| 47 | DUAL-FREQUENCY MILLIMETER WAVE AND LASER RADIATION RECEIVER | EP00981527.5 | 2000-12-05 | EP1322903A1 | 2003-07-02 | SANDERS, Ross, J.; SHMOLDAS, John, Dusan; WICKS, Dean, Arthur |
| A tandem dual-frequency sensor for a missile that uses a steerable dichroic primary millimeter wave reflector to reflect millimeter wave energy to a secondary reflector while passing laser light in the infra-red region through a dichroic region of the reflector to multiple staring laser detectors mounted behind the primary reflector. | ||||||
| 48 | METHOD FOR WIRELESS COMMUNICATION SYSTEM PLANNING | EP96906193 | 1996-01-29 | EP0763313A4 | 1999-05-19 | TANG YUQIANG; REED JOHN DOUGLAS |
| A method for wireless communication system planning includes, in a first embodiment, determining an image tree (500), based on a transmitter location (401) and the reflective (415) and diffractive (425) surfaces within a coverage region, and limiting the image tree to exclude branching for higher order images requiring more than a predetermined number of reflections and/or diffractions, or potential child images corresponding to surfaces not within the scope of the parent image (530, 560). Based on the image tree and propagation path back-tracing (620), a received signal quality measure (e.g., power) is determined for each receive location. By comparing the different received signal powers, an optimal receiver unit location is determined. Further, by building further image trees for further transmitter locations, an overall coverage quality can be determined for each transmitter and compared to yield an optimal transmitter location. | ||||||
| 49 | 오토매틱 줌을 수행하기 위한 시스템들 및 방법들 | KR20187012039 | 2016-08-05 | KR20180051643A | 2018-05-16 | GAO JINGLUN; GAO DASHAN; ZHONG XIN; QI YINGYONG |
| 전자디바이스가또한기술된다. 전자디바이스는프로세서를포함한다. 프로세서는복수의이미지들을획득하도록구성된다. 프로세서는또한, 복수의이미지들중 적어도 2 개사이에서글로벌모션을표시하는글로벌모션정보를획득하도록구성된다. 프로세서는추가로, 복수의이미지들중 적어도 2 개사이에서트래킹된오브젝트의모션을표시하는오브젝트트래킹정보를획득하도록구성된다. 프로세서는추가로, 글로벌모션정보및 오브젝트트래킹정보에기초하여오토매틱줌을수행하도록구성된다. 오토매틱줌을수행하는것은트래킹된오브젝트를포함하는줌 영역을생성한다. 프로세서는줌 영역내의트래킹된오브젝트의위치에기초하여줌 영역에대한모션응답속도를결정하도록구성된다. | ||||||
| 50 | Apparatus for informing location of vehicle and method of informing location of vehicle | KR20100082125 | 2010-08-24 | KR20120019040A | 2012-03-06 | KIM SIN GU; KIM HYUNG SEOK; KIM SUNG MIN; KO SEUNG RI |
| PURPOSE: Apparatus for informing location of a vehicle and a method of informing a location of a vehicle are provided to estimate the location of a vehicle by relative direction and distance by using reception signal of a multi antenna and a terrestrial magnetism sensor, thereby reducing the error even in indoor or underground. CONSTITUTION: Apparatus for informing location of a vehicle comprises a main body part(100), a plurality of vehicle antennas(142a-142d), and a remote control device. The main body part comprises a first terrestrial magnetism sensor and a main control unit. The first terrestrial magnetism sensor measures an angle of azimuth of the reference direction of a vehicle. The main control unit calculates the relative direction of the remote control device through the angle of azimuth and the intensity of signals of the remote control device. The main control unit transmits data including directions through the vehicle antennas to the remote control device. The remote control unit comprises a second terrestrial magnetism sensor, a remote antenna, a remote main control part, and a display part. The second terrestrial magnetism sensor measures an angle of azimuth of the reference direction of the remote control unit. The remote main control unit calculates location information including relative direction against the remote control unit through the angle of azimuth measured by the second terrestrial magnetism and the data received from the main body part. The display part indicates the location information calculated in the remote control device. | ||||||
| 51 | RICHTFUNKSYSTEM UND VERFAHREN ZUR AUTOMATISCHEN ANTENNENAUSRICHTUNG | EP16202240.4 | 2016-12-05 | EP3176966B1 | 2018-01-17 | Petri, Markus; Ehrig, Marcus |
| 52 | RICHTFUNKSYSTEM UND VERFAHREN ZUR AUTOMATISCHEN ANTENNENAUSRICHTUNG | EP16202240.4 | 2016-12-05 | EP3176966A1 | 2017-06-07 | Petri, Markus; Ehrig, Marcus |
Verfahren zur automatischen Ausrichtung von Antennen von Stationen einer Richtfunkstrecke, wobei eine Station als Master und mindestens eine andere Station als Slave konfiguriert ist. In einer ersten Phase bestimmen der Master und der Slave eine Erstausrichtung zum Signalaustausch. Liegt noch keine Sichtverbindung vor, wird in einer zweiten Phase über eine Anzahl von Iterationen jeweils der Master eine neue Slave-Strahlrichtung und eine Verweilzeit für den Slave vorgeben. Der Master sendet anschließend Suchsignale in eine vorbestimmte Anzahl seiner Master-Strahlrichtungen, der Slave führt während der Verweilzeit eine Signalqualitätsparameterbestimmung für jedes empfangene Signal durch und speichert deren Ergebnisse. Nach dem Ablauf der Verweilzeit übermittelt der Slave Signalqualitätsparameterbestimmungsergebnisse. Sofern eine Sichtverbindung gefunden wurde, wird diese in einer dritten Phase optimiert und eine optimale Ausrichtung der Antennen von Master und Slave bestimmt.
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| 53 | TRIGGER SIGNAL GENERATION DEVICE AND DYNAMICS MANAGEMENT SYSTEM | EP12885985.7 | 2012-10-01 | EP2905751A1 | 2015-08-12 | KAWAHARA, Takeshi |
A trigger signal generating device outputs a trigger signal activating an IC tag. The trigger signal generating device includes first and second trigger coils placed at a predetermined separation distance and each having predetermined magnetic field intensity distribution. Each of the first and second trigger coils includes attenuating means for attenuating intensity of a magnetic field generated by the first and second trigger coils to a predetermined level that allows the ID tag to detect trigger IDs of the first and second trigger coils on a side on which the first and second trigger coils are provided, and that does not allow the ID tag to detect the trigger ID of the first trigger coil on an opposite side to the side on which the first and second trigger coils are provided. |
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| 54 | Passive acoustic ranging system using atmospheric dispersion | EP13167920.1 | 2013-05-15 | EP2667216A1 | 2013-11-27 | Jiang, Qin; Daily, Michael J; Kremer, Richard Michael |
A method and apparatus for processing sound (218) from a sound source (210). The sound (218) from the sound source (210) is detected. Harmonics (224) in the sound (218) from the sound source (210) are identified. A distance (222) to the sound source (210) is identified using the harmonics (224) and a number of atmospheric conditions (226).
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| 55 | Acoustic localization of a speaker | EP07007817.5 | 2007-04-17 | EP1983799B1 | 2010-07-07 | Buck, Markus; Haulick, Tim; Schmidt, Gerhard; Wolff, Tobias |
| 56 | A SYSTEM A METHOD AND AN APPARATUS FOR PERFORMING WIRELESS MEASUREMENTS, POSITIONING AND SURFACE MAPPING BY MEANS OF A PORTABLE COORDINATE SYSTEM | EP05709119 | 2005-02-23 | EP1743137A4 | 2008-06-25 | ASH CHAIM; VOLODINE YURI G; NOVIKOV LENNY M; KOVTUN MICHAEL |
| The present invention is a new multifunctional low-cost solution for performing measurements and positioning in construction sites and automatically extracting a three-dimensional virtual model, plans, elevations and sections drawings based on these measurements. The preferred embodiment of the present invention consists of a field beacon FB3 or a set of field beacons FB1-FB14, spread around the measured area, communicating by omnidirectional signals with at least one central signal collector 100, which communicates with a computer. Dedicated computer software performs the spatial calculations and other applicable functions. The disclosed system is used for laying out axes and columns at the beginning stage of construction while ensuring the exact match of each mark to its planned position, and for quality and exactitude control of constructions or assembling. In addition the system may be used for locating and tracking objects in a predefined area and automatic directing of machinery to target points. | ||||||
| 57 | METHOD FOR WIRELESS COMMUNICATION SYSTEM PLANNING | EP96913788 | 1996-04-12 | EP0772893A4 | 1998-06-10 | REED JOHN DOUGLAS; TANG YUQIANG |
| A method for wireless communication system planning includes, in a first embodiment, determining an image tree (500), based on a transmitter location (401) and the reflective (415) and diffractive (425) surfaces within a coverage region, and limiting the image tree to exclude branching for higher order images requiring more than a predetermined number of reflections and/or diffractions, or potential child images corresponding to surfaces not within the scope of the parent image (530, 560). Based on the image tree and propagation path back-tracing (620) a received signal quality measure (e.g., power) is determined for each transmit location. By comparing the different received signal powers, an optimal receiver unit location is determined. Further, by back-tracing for further antenna locations/combinations, and comparing for diversity effects (864, 865), overall coverage qualities can be determined for each antenna combination and compared to yield optimal base diversity antenna locations (867). | ||||||
| 58 | METHOD FOR WIRELESS COMMUNICATION SYSTEM PLANNING | EP96913788.0 | 1996-04-12 | EP0772893A1 | 1997-05-14 | REED, John, Douglas; TANG, Yuqiang |
| A method for wireless communication system planning includes, in a first embodiment, determining an image tree (500), based on a transmitter location (401) and the reflective (415) and diffractive (425) surfaces within a coverage region, and limiting the image tree to exclude branching for higher order images requiring more than a predetermined number of reflections and/or diffractions, or potential child images corresponding to surfaces not within the scope of the parent image (530, 560). Based on the image tree and propagation path back-tracing (620) a received signal quality measure (e.g., power) is determined for each transmit location. By comparing the different received signal powers, an optimal receiver unit location is determined. Further, by back-tracing for further antenna locations/combinations, and comparing for diversity effects (864, 865), overall coverage qualities can be determined for each antenna combination and compared to yield optimal base diversity antenna locations (867). | ||||||
| 59 | METHOD FOR WIRELESS COMMUNICATION SYSTEM PLANNING | EP96906193.0 | 1996-01-29 | EP0763313A1 | 1997-03-19 | TANG, Yuqiang; REED, John, Douglas |
| A method for wireless communication system planning includes, in a first embodiment, determining an image tree (500), based on a transmitter location (401) and the reflective (415) and diffractive (425) surfaces within a coverage region, and limiting the image tree to exclude branching for higher order images requiring more than a predetermined number of reflections and/or diffractions, or potential child images corresponding to surfaces not within the scope of the parent image (530, 560). Based on the image tree and propagation path back-tracing (620), a received signal quality measure (e.g., power) is determined for each receive location. By comparing the different received signal powers, an optimal receiver unit location is determined. Further, by building further image trees for further transmitter locations, an overall coverage quality can be determined for each transmitter and compared to yield an optimal transmitter location. | ||||||
| 60 | INERTIAL MEASUREMENT UNIT PROGRESS ESTIMATION | US16225242 | 2018-12-19 | US20190149806A1 | 2019-05-16 | Alexander Jay Bruen Trevor; Chris Beall; Stefan Johannes Josef Holzer; Radu Bogdan Rusu |
| Various embodiments of the present invention relate generally to systems and methods for analyzing and manipulating images and video. In particular, a multi-view interactive digital media representation can be generated from live images captured from a camera. The live images can include an object. An angular view of the object captured in the live images can be estimated using sensor data from an inertial measurement unit. The multi-view interactive digital media representation can include a plurality of images where each of the plurality of images includes the object from a different camera view. When the plurality of images is output to a display, the object can appear to undergo a 3-D rotation through the determined angular view where the 3-D rotation of the object is generated without a 3-D polygon model of the object. | ||||||
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