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    • 22. 发明公开
    • STRUCTURE DISPLACEMENT DETECTION DEVICE, STRUCTURE DISPLACEMENT SHARING SYSTEM, STRUCTURE DISPLACEMENT DETECTION METHOD AND STRUCTURE DISPLACEMENT DETECTION PROGRAM
    • 设备技术检测结构性变化的,系统为检测结构性变化的分流结构的重新定位方法的结构性变化检测和程序
    • EP3109674A1
    • 2016-12-28
    • EP15752902.5
    • 2015-01-20
    • Furuno Electric Co., Ltd.
    • FUJISAWA, NaomiNAKAMURA, HirakuIMASAKA, MasashiSONOMOTO, Tatsuya
    • G01S19/53G01S19/14G01C15/00E01D1/00
    • G01M5/0041B63B39/00E01D19/00E04B1/98E04H9/027G01C15/00G01S19/53
    • A displacement detecting device for a structural object is achieved, which is capable of accurately measuring displacement of the structural object. The displacement detecting device 1 includes first and second attitude data calculators 11 and 21, a data extractor 30, and a displacement calculator 40. The first attitude data calculator 11 is disposed at a first position of the structural object, calculates attitude data of the first position by using received positioning signals, and calculates a calculated time point of the attitude data of the first position based on a time of a positioning system. The second attitude data calculator 21 is disposed at a second position of the structural object, calculates attitude data of the second position by using received positioning signals, and calculates a calculated time point of the attitude data of the second position based on the time of the positioning system. The data extractor 30 extracts the attitude data of the first and second positions calculated at the same time point, based on the time of the positioning system. The displacement calculator 40 calculates a displacement amount and a displacement direction of the structural object by using a difference between the attitude data of the first and second positions calculated at the same time point.
    • 位移用于结构对象检测装置来实现,所有这些都能够在结构物的精确地设定测量位移的。 位移检测装置1包括第一和第二姿态数据计算器11和21,一个数据提取器30,以及一个位移运算部40。第一姿态数据计算器11在结构对象的第一位置被设置,计算第一姿态数据 通过使用接收到的定位信号,并且计算基于一个定位系统的时间的第一位置的姿态数据的一个计算的时间点的位置。第二姿态数据计算器21在结构对象的第二位置被设置,计算姿态数据 30所提取的,通过使用接收到的定位信号,并且计算基于定位系统的第二时间位置的姿态数据的计算的时间点的第二位置。数据提取器的第一和第二位置的姿态数据的计算 的Sametime点的基础上,定位系统的时间。位移计算部40计算的位移量的 第二,通过使用在同一时间点计算出的第一位置和第二位置的姿态数据之间的差的结构物体的位移方向。
    • 24. 发明公开
    • REMOTE CONTROL DEVICE, AND METHOD AND SYSTEM FOR REMOTELY STEERING SHIP
    • FERNSTEUERUNGSVORRICHTUNG SOWIE VERFAHREN UND SYSTEM ZUR FERNSTEUERER EINES SCHIFFS
    • EP3023739A1
    • 2016-05-25
    • EP15190986.8
    • 2015-10-22
    • FURUNO ELECTRIC CO., LTD.
    • OKUDA, Masato
    • G01C21/20B63H25/04G05D1/02
    • B63H25/02B63H25/04B63H25/06B63H2025/028G01C21/203G05D1/0011G05D1/0016G05D1/0206
    • A remote steering system (100) is provided. The remote steering system (100) includes a steering device (17) configured to control a traveling direction of a ship by at least adjusting an angle of a rudder (18), and a remote control device (30) configured to remotely control the steering device (17). The remote control device (30) includes an azimuth sensor (35) configured to detect an oriented azimuth of the remote control device (30), and a controller communication unit (34) configured to transmit, to the steering device (17), at least one of the oriented azimuth detected by the azimuth sensor (35) and a change amount of the oriented azimuth. The steering device (17) receives the at least one of the oriented azimuth and the change amount from the remote control device (30), and controls the traveling direction of the ship based on the at least one of the oriented azimuth and the change amount.
    • 提供远程转向系统(100)。 远程转向系统(100)包括转向装置(17),其被配置成通过至少调节舵(18)的角度来控制船的行进方向;以及远程控制装置(30),远程控制装置 装置(17)。 遥控装置(30)包括被配置为检测远程控制装置(30)的定向方位角的方位传感器(35),以及控制器通信单元(34),被配置为向转向装置(17) 由方位传感器(35)检测到的定向方位角中的至少一个和取向方位角的变化量。 转向装置(17)从远程控制装置(30)接收定向方位角和变化量中的至少一个,并且基于取向方位角和变化量中的至少一个来控​​制船舶的行进方向 。
    • 25. 发明公开
    • CLUTTER SUPPRESSING DEVICE AND RADAR APPARATUS PROVIDED WITH THE SAME
    • 麻醉药物联合国毒品和犯罪问题办公室(DARARTIGEN VORRICHTUNG)
    • EP2990820A1
    • 2016-03-02
    • EP15182037.0
    • 2015-08-21
    • FURUNO ELECTRIC CO., LTD.
    • MINOWA, Masahiro
    • G01S7/41G01S13/95G01S7/02
    • G01S13/524G01S7/023G01S7/414G01S13/89G01S13/95G01S13/951Y02A90/18
    • A clutter suppressing device (20) for suppressing echo data of static clutter components indicating reflection waves caused by radar transmission signals reflecting on a static object is provided. The device (20) includes a static clutter component suppressor (21) configured to receive reception signals containing the static clutter components, and suppress the static clutter components, a reference data memory (23) configured to store, as reference data, echo data of the reception signals obtained in fine weather and in which the static clutter components are suppressed by the static clutter component suppressor (21), and a rain component extracting module (24) configured to extract echo data indicating rain components contained in the reception signals, by removing the reference data stored in the reference data memory (23) from echo data of the reception signals obtained in rainy weather and in which the static clutter components are suppressed by the static clutter component suppressor (21).
    • 提供一种用于抑制指示由在静态物体上反射的雷达传输信号引起的反射波的静态杂波分量的回波数据的杂波抑制装置(20)。 该装置(20)包括:静态杂波分量抑制器(21),被配置为接收包含静态杂波分量的接收信号,并抑制静态杂波分量;参考数据存储器(23),被配置为存储作为参考数据的回波数据 通过静态杂波分量抑制器(21)抑制静态杂波获得的接收信号,以及雨分量提取模块(24),其被配置为提取表示接收信号中包含的雨分量的回波数据,通过 从雨天获得的接收信号的回波数据中去除参考数据存储器(23)中存储的参考数据,其中静态杂波分量抑制器(21)抑制静态杂波分量。
    • 28. 发明公开
    • ANTENNA AND MANUFACTURING METHOD FOR ANTENNA
    • 天E。EN。EN EN。。。。。。
    • EP2835867A1
    • 2015-02-11
    • EP13772217.9
    • 2013-04-01
    • Furuno Electric Co., Ltd.
    • YANO, Kohji
    • H01Q13/20H01P11/00H01Q21/06
    • H01Q13/18G01S13/95H01Q13/22H01Q21/005H01Q21/064Y10T29/49016
    • A slot array antenna where slots are arrayed in two directions is provided, which has a configuration capable of suppressing occurrence of side lobes and suppressed in weight. An antenna 10 includes a radiation waveguide part and probes 18. The radiation waveguide part has two sheets of metal plates facing each other and outwardly radiates a radio wave from a plurality of slots 17 formed in one of the metal plates. Each probe 18 is arranged for every slot 17 to extend inward of the radiation waveguide part from the face where the slots 17 are formed, and changes a transmission mode of the radio wave within the radiation waveguide part. The slots 17 are narrow and arranged at fixed intervals in a longitudinal direction of the slots and in a lateral direction of the slots, respectively. The probe 18 is disposed for every slot 17, on either one of sides of the slot 17 in the lateral direction. Between the adjacent slots 17, the probes are disposed on the opposite sides in the lateral direction.
    • 提供了一种槽阵列天线,其中槽沿两个方向排列,其具有能够抑制旁瓣的发生并且抑制重量的构造。 天线10包括辐射波导部分和探针18.辐射波导部分具有彼此面对的两片金属板,并且从形成在一个金属板中的多个狭槽17向外辐射无线电波。 每个探针18布置成每个槽17从形成有槽17的面向内延伸到辐射波导部分的内侧,并且改变辐射波导部分内的无线电波的传输模式。 狭槽17分别狭窄并且沿狭缝的纵向方向和槽的横向方向上以固定的间隔布置。 探针18在横向方向上在槽17的任一侧上为每个槽17设置。 在相邻的狭槽17之间,探针沿横向设置在相对的两侧。
    • 29. 发明公开
    • GNSS SIGNAL PROCESSING METHOD, POSITIONING METHOD, GNSS SIGNAL PROCESSING PROGRAM, POSITIONING PROGRAM, GNSS SIGNAL PROCESSING DEVICE, POSITIONING DEVICE, AND MOBILE TERMINAL
    • 导航系统信号处理,定位方法,GNSS信号处理程序,定位程序,GNSS信号处理装置,定位装置及移动终端
    • EP2793051A1
    • 2014-10-22
    • EP11877304.3
    • 2011-12-14
    • Furuno Electric Co., Ltd.
    • NAGANO Takeshi
    • G01S19/37G01S19/22G01S19/30H04B1/7085
    • G01S19/30G01S19/22G01S19/24G01S19/37H04B1/7085H04B2201/70715
    • A demodulation unit (13) corresponding to a GNSS signal processing device includes an operator (33). The operator (33) selects an error detecting method based on signs of an early differential value ΔCV E and a late differential value ΔCV L . The operator (33) calculates an error detection value Δτ by using the selected error detecting method. A code phase range where an error detection value is not 0 is wide with a first error detecting method, and the code phase range where an error detection value is not 0 is narrow with a second error detecting method. Immediately after capturing a GNSS signal, a code phase difference between the GNSS signal and a prompt replica signal S RP is large, and signs of the early differential value ΔCV E and the late differential value ΔCV L are different from each other. In this case, the first error detecting method is used. As the code phase is driven, the code phase difference between the GNSS signal and the prompt replica signal S RP becomes smaller, and the signs of the early differential value ΔCV E and the late differential value ΔCV L become the same. In this case, the second error detecting method is used.
    • 的解调单元(13)对应于一个GNSS信号处理装置包括在操作者(33)。 操作者(33)选择错误基于早期差分值“CV E和晚期差分值” CV L.迹象检测方法 操作者(33)计算通过使用所选择的误差检测方法的错误检测值“A。 A码相位范围,其中的错误检测值不为0是宽与第一误差检测方法,以及将码相位范围,其中的错误检测值不为0是窄与第二误差检测方法。 立即捕获GNSS信号之后,GNSS信号和提示副本信号S RP之间的码相位差大,和早期的差分值“CV E和已故差分值” CV升迹象从海誓山盟不同。 在这种情况下,使用第一误差检测方法。 作为码相位被驱动时,GNSS信号和提示副本信号S RP之间的码相位差变小,和早期的差分值“CV E和已故差分值” CV L的迹象变得相同。 在这种情况下,当使用第二误差检测方法。