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    • 3. 发明授权
    • Remote control system
    • 遥控系统
    • US09158305B2
    • 2015-10-13
    • US13565153
    • 2012-08-02
    • Fumio OhtomoKazuki OsaragiTetsuji Anai
    • Fumio OhtomoKazuki OsaragiTetsuji Anai
    • H04N13/02G05D1/00
    • G05D1/0038G05D1/0016
    • A remote control system comprises a mobile object, a remote controller for remotely controlling the mobile object, and a storage unit where background images to simulate a driving room or an operation room of the mobile object are stored. The mobile object has a stereo camera, a camera control unit for controlling image pickup direction of the stereo camera, and a first communication unit for communicating information including at least images photographed by the stereo camera. The remote controller has a second communication unit for communicating to and from the first communication unit, a control unit for controlling the mobile object, and a display unit for synthesizing at least a part of the images photographed by the stereo camera and the background images and for displaying the images so that a stereoscopic view can be displayed.
    • 远程控制系统包括移动对象,用于远程控制移动对象的遥控器,以及存储用于模拟移动对象的驾驶室或操作室的背景图像的存储单元。 移动体具有立体摄像机,摄像机控制单元,用于控制立体摄像机的摄像方向,以及第一通信单元,用于传送至少包含由立体摄像机拍摄的图像的信息。 遥控器具有用于与第一通信单元进行通信的第二通信单元,用于控制移动体的控制单元和用于合成由立体摄像机和背景图像拍摄的图像的至少一部分的显示单元,以及 用于显示图像,使得可以显示立体视图。
    • 4. 发明授权
    • Electro-optical distance measuring device
    • 电光测距装置
    • US08908156B2
    • 2014-12-09
    • US12984975
    • 2011-01-05
    • Fumio OhtomoKaoru Kumagai
    • Fumio OhtomoKaoru Kumagai
    • G01S17/66G01S17/36G01S17/32G01S17/46G01S17/88G01S17/89
    • G01S17/36G01S17/32G01S17/325G01S17/89
    • An electro-optical distance measuring device having a photodetection unit comprising a plurality of pixels arranged in a predetermined arrangement is disclosed. A signal processing unit has a storage unit for storing the detection result in correspondence with each of the pixels, wherein the signal processing control unit sequentially changes a position of the division for every cycle wave at which the photodetection amount is detected and continues detections until a detected range becomes at least one cycle or more. The arithmetic processing unit calculates a waveform for at least one cycle stored in the storage unit for each pixel, obtains a phase difference of the waveform with respect to the irradiated distance measuring light, and calculates the distance based on the phase difference.
    • 公开了一种具有以预定布置布置的多个像素的光检测单元的电光测距装置。 信号处理单元具有用于存储与每个像素相对应的检测结果的存储单元,其中信号处理控制单元对于检测到光检测量的每个周期波顺序改变除法的位置,并继续检测,直到 检测范围变为至少一个周期以上。 算术处理单元针对每个像素计算存储在存储单元中的至少一个周期的波形,获得相对于照射的距离测量光的波形的相位差,并且基于相位差来计算距离。
    • 7. 发明授权
    • Time difference measuring device, measuring method, distance measuring device, and distance measuring method
    • 时差测量装置,测量方法,距离测量装置和距离测量方法
    • US07777865B2
    • 2010-08-17
    • US11664666
    • 2005-09-30
    • Masahiro OhishiFumio Ohtomo
    • Masahiro OhishiFumio Ohtomo
    • G01C3/08
    • G01S17/105G01S7/497G04F10/06
    • A time difference measuring device can accurately measure a time difference between two pulse signals generated with a predetermined time difference by measuring the two pulse signals by one measurement. The time difference measuring device measures a time difference between a start signal (M1) and a stop signal (M2). The device has a reference signal generation unit (41) for generating two reference signals (S1, S2) having a π/2 phase difference. According to corresponding amplitude values (A11, A12) and (A21, A22) of the reference signals (S1, S2) at each generation timing of the start signal (M1) and the stop signal (M2), a phase difference detection unit (42) calculates a phase difference Δθ (=θstop−θstart) between the generation timings of the pulse signals (M1, M2). According to the detected phase difference Δθ and the cycle (Ts) of the reference signals (S1; S2), a time difference calculation unit (44) calculates the generation time difference Δt between the pulse signals (m1, M2).
    • 时差测量装置可以通过一次测量来测量两个脉冲信号来精确地测量以预定时间差产生的两个脉冲信号之间的时间差。 时差测量装置测量起始信号(M1)和停止信号(M2)之间的时间差。 该装置具有用于产生具有&pgr / 2相位差的两个参考信号(S1,S2)的参考信号产生单元(41)。 根据开始信号(M1)和停止信号(M2)的各生成定时的参考信号(S1,S2)的相应振幅值(A11,A12)和(A21,A22),相位差检测单元 42)计算相位差&Dgr;&Thetas; (M1,M2)的发生定时之间(=& t;停止 - 开始)。 根据检测到的相位差&Dgr;&Thetas; 参考信号(S1; S2)的周期(Ts),时间差计算单元(44)计算脉冲信号(m1,M2)之间的生成时间差Dgr; t。
    • 9. 发明申请
    • Multi-Point Measuring Method and Surveying Device
    • 多点测量方法和测量装置
    • US20090241358A1
    • 2009-10-01
    • US12309060
    • 2008-04-18
    • Fumio OhtomoHitoshi OtaniJunki KanekoTetsuji AnaiTerukazu Nagashima
    • Fumio OhtomoHitoshi OtaniJunki KanekoTetsuji AnaiTerukazu Nagashima
    • G01C3/04G06K9/00H04N7/00
    • G01C15/002
    • There are provided a telescope unit (5) having a first image pickup unit for acquiring a wide-angle image and a second image pickup unit for acquiring a telescopic image with higher magnification than the wide-angle image, a distance measuring unit for performing distance measurement by projecting a distance measuring light and by receiving a light reflected from an object to be measured, an angle measuring unit for detecting a horizontal angle and a vertical angle of the telescope unit, a drive unit for rotating and driving the telescope unit in a horizontal direction and in a vertical direction, and a control device for controlling image pickup of the first image pickup unit and the second image pickup unit and for controlling the drive unit based on the results of detection from the angle measuring unit, wherein the control device synthesizes a panoramic image by connecting the wide-angle image obtained by the first image pickup unit, sets up a scheduled measuring point by edge processing of the wide-angle image, and extracts the measuring point corresponding to the scheduled measuring points in the telescopic image by scanning the scheduled measuring point and acquiring the telescopic image by the second image pickup unit with respect to scheduled measuring points, and distance measurement is performed on the measuring point.
    • 提供了具有用于获取广角图像的第一图像拾取单元和用于获取具有比广角图像更高放大率的望远图像的第二图像拾取单元的望远镜单元(5),用于执行距离的距离测量单元 通过投射距离测量光并且接收从被测量物体反射的光的测量,用于检测望远镜单元的水平角度和垂直角度的角度测量单元,用于在望远镜单元中旋转和驱动望远镜单元的驱动单元 水平方向和垂直方向的控制装置,以及用于控制第一图像拾取单元和第二图像拾取单元的图像拾取并基于来自角度测量单元的检测结果来控制驱动单元的控制装置,其中控制装置 通过连接由第一图像拾取单元获得的广角图像来合成全景图像,通过边缘处理设置预定的测量点 并且通过扫描预定测量点并且通过第二图像拾取单元相对于计划的测量点获取与伸缩图像中的预定测量点相对应的测量点并获取伸缩图像,以及距离测量 在测量点进行。
    • 10. 发明授权
    • Position measuring instrument
    • 位置测量仪
    • US07515256B2
    • 2009-04-07
    • US10686858
    • 2003-10-16
    • Fumio OhtomoKazuki OsaragiKunihiro Hayashi
    • Fumio OhtomoKazuki OsaragiKunihiro Hayashi
    • G01C3/08
    • G01S7/4817G01C15/002G01S7/006G01S7/4813G01S7/497G01S17/023G01S17/42G01S17/89
    • The present invention relates to a position measuring instrument for, for example, scanning a photoreceiver as a target to be measured, and more particularly to an automatic position detection instrument capable of emitting distance measuring light and tracking light while turning directions of the distance measuring light and the tracking light so that three-dimensional measurement of a light receiving position is performed, and further capable of transmitting measured data to a photoreceiver provided on a target. A light source unit emits measuring light, and then a light receiving unit receives its reflected light. A scanning means emits measuring light in a scanning direction, and leads its reflected light to the light receiving unit. An angle detector detects a rotational position of the scanning means. The measuring light includes distance measuring light expanding in a fan-shaped manner. Its reflected light can be used to measure a distance to a reflector.
    • 本发明涉及一种用于例如扫描作为待测对象的光接收器的位置测量仪器,更具体地说,涉及一种能够在转动距离测量光的方向的同时发射距离测量光和跟踪光的自动位置检测仪器 和跟踪光,从而执行光接收位置的三维测量,并且还能够将测量数据发送到设置在目标上的光接收器。 光源单元发射测量光,然后光接收单元接收其反射光。 扫描装置沿扫描方向发射测量光,并将其反射光引导到光接收单元。 角度检测器检测扫描装置的旋转位置。 测量光包括以扇形方式扩展的距离测量光。 其反射光可用于测量到反射器的距离。