子分类:
| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 181 | LOCATION SYSTEM FOR DETERMINING THE POSITION OF AN OBJECT | EP12704243.0 | 2012-01-26 | EP2673653A1 | 2013-12-18 | WALLGREN, Carl JOHAN Erik |
| A location system for determining the position of a movable object (12) like a power wrench in a three dimensional space and comprising a number of stationary signal communication modules (15, 16 and 17) and a movable signal communication module (18) carried by the movable object (12), wherein the stationary signal communication modules (15, 16 and 17) are connected to an evaluation and calculation unit (24) which is arranged to determine the position of the movable object (12) in response to the signals delivered by the stationary signal communication modules (15, 16 and 17) and based on signals communicated between the movable signal communication module (18) and the stationary signal communication modules (15, 16 and 17). At least one (16) of the stationary signal communicating modules (15, 16 and 17) is displaceable between two or more positions (A,B) to enable signal communication contact with the movable signal communicating module (18) in normally screened off positions. | ||||||
| 182 | METHOD AND DEVICE FOR LOCATING TERMINAL BY USING BASE STATION | EP10805978 | 2010-05-26 | EP2464181A4 | 2013-11-06 | GAO YIN; WU HAO |
| The present invention provides a method for locating a terminal by using a base station, and the method includes steps as follows: constructing a locating message by expanding a location report message or via an independent message; sending the locating message to a locating judgment center; and locating the terminal by using the locating message. The present invention is helpful to reduce the power consumption of the User Equipment (UE). | ||||||
| 183 | SYSTEM AND METHOD FOR TRACKING | EP11820968.3 | 2011-08-30 | EP2612163A2 | 2013-07-10 | DENSHAM, Gilray; EICHEL, Justin |
| Systems and methods are provided for tracking at least position and angular orientation. The system comprises a computing device in communication with at least two cameras, wherein each of the cameras are able to capture images of one or more light sources attached to an object. A receiver is in communication with the computing device, wherein the receiver is able to receive at least angular orientation data associated with the object. The computing device determines the object's position by comparing images of the light sources and generates an output comprising the position and angular orientation of the object. | ||||||
| 184 | MOVING PLATFORM INS RANGE CORRECTOR (MPIRC) | EP11797424.6 | 2011-06-27 | EP2585852A1 | 2013-05-01 | GEORGY, Jacques; SYED, Zainab; GOODALL, Chris; EL-SHEIMY, Naser; NOURLEDIN, Aboelmagd |
| A moving platform INS range corrector ("MPIRC") module and its method of operation are disclosed for providing navigation and positioning information. The module comprises: means, such as a receiver, for receiving a first set of absolute navigational information from an external source (such as satellites in case of GNSS); an inertial sensor unit for generating a second set of navigational information at the module; and a transceiver, for receiving and/or transmitting signals and estimating distance measurement from a known position and receiving position coordinates. The navigational information is used by a processor programmed with a core algorithm, to produce a navigation solution (which comprises position, velocity and attitude). The system has the following attributes: the solution is produced seamlessly, even if one source of navigational information is temporarily out of service; the accuracy of the solution is assisted by use of distance and position coordinate measurement from a known position. | ||||||
| 185 | VERWENDUNG VON PHASOR MEASUREMENT UNITS FÜR DIFFERENTIELLE GLOBALE SATELLITENNAVIGATIONSSYSTEME (GNSS) | EP09718019.4 | 2009-02-18 | EP2245480B1 | 2012-10-17 | OLPP, Dieter |
| 186 | INFORMATION MANAGEMENT DEVICE, DATA PROCESSING METHOD THEREOF, AND COMPUTER PROGRAM | EP10822099.7 | 2010-10-07 | EP2487640A1 | 2012-08-15 | MIYAKAWA Shinya |
An information management apparatus includes: a data receiving section, a collected data storage section, an aggregating section, a feature extracting section, a determining section, and an evaluation data storage section. The data receiving section periodically receives action data showing an action of a user. The collected data storage section stores the action data received by the data receiving section every user. The aggregating section generates a data set every user by aggregating action data containing an approximate content, of the action data stored in the collected data storage section. The feature extracting section extracts an index and a reference showing privacy confidentiality of the data set as a feature to incorporate in the data set. The determining section determines whether or not the privacy confidentiality of the feature of the data set is equal to or higher than a predetermined level. The evaluation data storage section stores the data set which passed the determining section. |
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| 187 | ENHANCED LOCATION BASED SERVICE FOR POSITIONING INTERSECTING OBJECTS IN THE MEASURED RADIO COVERAGE | EP07826215.1 | 2007-08-30 | EP2080036A1 | 2009-07-22 | LEHTINEN, Joni |
| A method, apparatus or tangible computer medium (which stores computer executable code or program code) performs or facilitates obtaining information concerning one or more characteristics of one or more monitored wireless signals or links, such as radio frequency (RF) signals, transmitted across a geographic area; and detecting a presence of an object in the geographic area according to a variation of a characteristic of one or more of the RF signals reflecting interference of the RF signal(s) by the object. | ||||||
| 188 | 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. | ||||||
| 189 | A TRACKING AND MONITORING APPARATUS AND SYSTEM | EP04711657.9 | 2004-02-17 | EP1599847B1 | 2007-08-15 | DOUGLAS, Raymond |
| A programmable mobile unit for a portable host, such as a person, comprising a microcontroller in communication with each of a detachable freespace communication module for communication with a control centre, a GPS unit for communication with at least a GPS satellite system and a biometric sensor for monitoring and identifying the host. | ||||||
| 190 | IMPROVEMENTS IN AND RELATING TO INVESTIGATIONS | EP05790789.1 | 2005-09-30 | EP1795031A1 | 2007-06-13 | GOODE, Amanda, c/o The Forensic Science Service |
| A method of investigating the location of a portable telecommunications device used in making a call, the method including: obtaining information on the position of the receiver involved in the call; surveying a location by visiting the location and establishing the receiver a portable telecommunications device would use from that location; comparing the receiver involved in the call with the receiver that would be used from the surveyed location. | ||||||
| 191 | 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). | ||||||
| 192 | 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). | ||||||
| 193 | 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. | ||||||
| 194 | INDOOR POSITIONING SYSTEMS AND MEETING ROOM OCCUPANCY | PCT/CA2016050835 | 2016-07-15 | WO2017011902A8 | 2017-03-02 | JAMPANI KRISHNAM RAJU; MARTIN DARYL JOSEPH; TSAI I-MING; BECKETT JASON CHRISTOPHER |
| A method of determining room occupancy of a room in a facility having an indoor positioning system with wireless access point fingerprints each correlated to a location in the facility. The method may include receiving a request from a computing device for a room occupancy assessment associated with the room. It may further include obtaining location data that correlates to the location of one or more people from the indoor positioning system and determining from the location data associated with the room whether the room is occupied. The determination of whether the room is occupied is then sent to the computing device. | ||||||
| 195 | SECONDARY CELL SELECTION BASED ON GEOGRAPHIC SIGNATURES | PCT/IB2015050739 | 2015-01-30 | WO2015114594A3 | 2015-12-10 | LU GUOQIANG; MANN KARL D; BOSTRÖM LISA; PARSONS ERIC W; LIU RICHARD; BUJOLD IRIS; BEUERMAN JAMIE; LIU QINQCHAO; RANAWEERA DAMITHA; MAH EDWARD |
| Systems and methods for Secondary Cell (sCell) selection for wireless devices (22) operating according to a carrier aggregation scheme in a cellular communications network (14) are disclosed. In one embodiment, a network node (16) in the cellular communications network (14) obtains geographic 5 signatures for a number of candidate sCells (24). The geographic signatures include a geographic signature for each candidate sCell (24) that approximates a coverage area of the candidate sCell (24). The network node (16) obtains position information for a wireless device (22) and then selects one or more sCells (24) for the wireless device (22) from the candidate sCells (24) based on 10 the geographic signatures for the candidate sCells (24) and the position information for the wireless device (22). The network node (16) then configures the selected sCell(s) (24) for use by the wireless device (22) according to a carrier aggregation scheme. Using this process, sCell selection is performed, in some examples, without measurement gaps and without disabling an s-Measure 15 parameter. | ||||||
| 196 | PORTABLE WIRELESS MESH DEVICE | PCT/US2014055399 | 2014-09-12 | WO2015038894A3 | 2015-06-04 | MACKIE DAVID |
| A wireless mesh network (24) comprising a plurality of mobile mesh devices (22) coupled as nodes in a mesh network topology is provided herein. Generally speaking, each mobile mesh device may be a portable, self-contained unit, which does not require network or power wiring to communicate network traffic between the nodes. According to one embodiment, the mobile mesh device may include a plurality of dipole antennas (66), which are enclosed within the mobile mesh device and configured to forward network traffic. At least one of the dipole antennas may be a frequency adjustable end-fed dipole antenna (64) comprising a channel selection pin (80), which can be adjusted up or down along the dipole axis to change a resonant frequency of the dipole antenna. | ||||||
| 197 | SUPPORTING AND ENHANCING IMAGE-BASED POSITIONING | PCT/SE2013051621 | 2013-12-27 | WO2014109694A3 | 2014-09-18 | SIOMINA IANA |
| A method in a radio communications network is described of using image data for positioning a first wireless device. The method comprises obtaining image data comprising at least two image objects and an angle between lines formed between each of the objects and a reference point. The method further comprises extracting the at least two image objects from the obtained image data, determining, from the obtained image data, the angle between the lines formed between each of the objects and the reference point, and using the at least two image objects and/or the image data for positioning the first wireless device based on the determined angle. The method is performed by at least one of: a network node, the first wireless device, a camera device, a second wireless device, an image processing node and a server, each operating in the radio communications network. | ||||||
| 198 | RFID-BASED SYSTEM FOR LINKING ELECTRONIC MEDICAL RECORD | PCT/KR2009003054 | 2009-06-08 | WO2010018923A3 | 2010-04-08 | SUNG MYUNG-WHUN; PARK KWANG-SUK; KIM CHUNG-HYEON |
| The present invention relates to an RFID-based system for linking an EMR. According to the invention, the RFID-based system detects the location of a patient who has a tag by using an RTLS (Real-Time Locating System) and links the detected location to the EMR. Therefore, the RFID-based system is able to manage the movement or location of the patient by detecting the location of the patient in real time. | ||||||
| 199 | PRACH 기반 근접도 검출 | KR20187014286 | 2014-01-28 | KR20180056810A | 2018-05-29 | BARBIERI ALAN; XU HAO; JAIN VIKAS; MALLADI DURGA PRASAD; KHAN AWAIZ AHMAD; KOTLA SAMATHA; SACHDEV BALWINDERPAL |
| 물리적랜덤액세스채널(PRACH) 기반근접도검출에사용하기위한시그널링프로시저들에대한개선들이개시된다. 서빙기지국으로부터의시그널링및 시그널링프로세스들은관련사용자장비(UE)로부터의 PRACH의보다효율적이고신뢰성있는송신을트리거할수 있다. 이러한 PRACH 기반근접도에대해모니터링하는동적전력노드(DPN)들에서, 검출및 근접도활성화의보다효율적인관리를위해이웃리스트들을설정하는특징들이개시된다. | ||||||
| 200 | 무선 통신 시스템에서 위치 결정을 위한 측정 결과 보고 방법 및 이를 위한 장치 | KR1020167035922 | 2016-03-22 | KR1020170129595A | 2017-11-27 | 이현호; 박한준; 김봉회 |
| 본발명의일 실시예에따른무선통신시스템에서위치결정을위한측정결과를보고하기위한방법에있어서, 상기방법은단말에의해수행되며, 복수의기지국들각각의위치식별자를포함하는 PRS(positioning reference signal) 관련정보를수신하는단계, 상기복수의기지국들각각이전송한 PRS들에대한측정을수행하는단계, 상기복수의기지국들각각의위치식별자가서로동일한경우, 상기 PRS들에대한측정결과들중 적어도하나의측정결과를선택하는단계및 상기선택된측정결과를서빙기지국으로보고하는단계를포함할수 있다. | ||||||
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