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    • 3. 发明申请
    • DIGITAL SIGNAL PROCESSING IN OPTICAL SYSTEMS USED FOR RANGING APPLICATIONS
    • 用于范围应用的光学系统中的数字信号处理
    • WO2009059391A1
    • 2009-05-14
    • PCT/CA2007/002001
    • 2007-11-07
    • INSTITUT NATIONAL D'OPTIQUE
    • LEVESQUE, MarcBABIN, FrançoisCANTIN, Daniel
    • G01S7/487G01S17/10G01S17/50G01S17/58
    • G01S7/487G01S17/10G01S17/58
    • Methods and apparatuses for reducing the response time along with increasing the probability of ranging of optical rangefinders that digitize the signal waveforms obtained from the pulse echoes returned from various types of objects to be ranged, the pulse echoes being too weak to allow successful ranging from a single waveform or the objects being possibly in motion during the capture of the pulse echoes. In a first embodiment of the invention, the response time at close range of a digital optical rangefinder is reduced by using a signal averaging process wherein the number of data to be averaged varies with the distance according to a predetermined function. In a second embodiment of the invention, the probability of ranging objects in motion along the line of sight of a digital optical rangefinder is increased and the object velocity measured by performing a range shift of each acquired signal waveform prior to averaging. In a third embodiment of the invention, the signal waveforms acquired in the line of sight of a digital optical rangefinder are scanned over a predetermined zone and range shifted and averaged to allow for early detection and ranging of objects that enter in the zone.
    • 减少响应时间的方法和装置以及随着光学测距仪测距的可能性的增加,数字化从从不同类型的物体返回的脉冲回波获得的信号波形,脉冲回波太弱,不能从 在捕获脉冲回波期间,单个波形或物体可能运动。 在本发明的第一实施例中,通过使用信号平均处理来减少数字光学测距仪的近距离处的响应时间,其中要平均的数据数量根据预定功能的距离而变化。 在本发明的第二实施例中,沿着数字光学测距仪的视线测量对象的运动概率增加,并且通过在平均之前执行每个获取的信号波形的范围偏移来测量对象速度。 在本发明的第三实施例中,在数字光学测距仪的视线中获取的信号波形在预定的区域上被扫描,并且移动和平均的范围以允许早期检测和进入该区域的物体的测距。
    • 5. 发明申请
    • SYSTEM AND METHOD FOR INDIVIDUAL PARTICLE SIZING USING LIGHT SCATTERING TECHNIQUES
    • 使用光散射技术的个体粒子尺寸的系统和方法
    • WO2017054070A1
    • 2017-04-06
    • PCT/CA2015/050995
    • 2015-10-02
    • INSTITUT NATIONAL D'OPTIQUE
    • CANTIN, Daniel
    • G01N15/10
    • G01N15/1459G01N15/0211G01N2015/0046G01N2015/1486
    • A particle sizing system is provided that includes an optical source generating a light beam for illuminating particles in a monitored volume, a plurality of light deflectors, each positioned to receive and deflect light scattered by the particles, and an image capture device collecting scattered light deflected by each light deflector. The image capture device outputs an image including a plurality of sub-images, each generated from the collected light deflected from a respective one of the light deflectors. Each particle is imaged as a spot in each sub-image, the plurality of spots associated with each particle corresponding to a plurality of scattering angles. The system also includes a processing unit configured to identify the spots associated with the each particle in the sub-images, compute a spot parameter associated with each spot, and determine the size of each particle from its related spot parameters. A particle sizing method is also provided.
    • 提供了一种粒子尺寸系统,其包括产生用于照射监测体积中的颗粒的光束的光源,多个光偏转器,每个光偏转器定位成接收和偏转由颗粒散射的光,以及收集散射光的图像捕获装置 由每个导光板。 图像捕获装置输出包括多个子图像的图像,每个子图像从从相应的一个光偏转器偏转的收集的光产生。 每个粒子被成像为每个子图像中的斑点,与每个粒子相关联的多个斑点对应于多个散射角。 该系统还包括处理单元,其被配置为识别与子图像中的每个粒子相关联的斑点,计算与每个斑点相关联的斑点参数,以及根据其相关斑点参数确定每个粒子的大小。 还提供了颗粒尺寸测定方法。
    • 6. 发明申请
    • LIGHT-INTEGRATING RANGEFINDING DEVICE AND METHOD
    • 光集成测量装置和方法
    • WO2009105857A1
    • 2009-09-03
    • PCT/CA2008/000408
    • 2008-02-29
    • INSTITUT NATIONAL D'OPTIQUEBABIN, FrançoisCANTIN, Daniel
    • BABIN, FrançoisCANTIN, Daniel
    • G01S17/10
    • G01S17/107G01S7/4865G01S7/4876G01S17/89
    • A rangefinding device and a method for determining the range of an object from a rangefinding device are provided. A train of light pulses each having an emission time and a pulse duration is generated. The pulse duration is set to twice the round-trip time to a maximum range of the device. The light pulses are reflected back toward the device by the object and detected according to three time intervals, respectively determined by a background gate, a ranging gate and a pulse energy gate. The light energy received during each interval is integrated and the integrated light value corresponding to the ranging gate is normalized using the values from the other two intervals. The range of the object is determined from the normalized ranging measurement and calibration data.
    • 提供了一种测距装置和用于确定来自测距装置的物体的距离的方法。 产生具有发射时间和脉冲持续时间的一串光脉冲。 脉冲持续时间设置为设备最大范围的往返时间的两倍。 光脉冲被对象反射回设备,并根据三个时间间隔进行检测,分别由背景门,测距门和脉冲能量门决定。 在每个间隔期间接收的光能被积分,并且使用来自其它两个间隔的值来对应于测距门的积分光值被归一化。 对象的范围由归一化的测距和校准数据确定。