公开(公告)号：US20160307310A1

公开(公告)日：2016-10-20

申请号：US14690700

申请日：2015-04-20

Applicant: General Electric Company

Inventor： Kevin George Harding ,  Christopher Allen Nafis ,  Robert William Tait

IPC: G06T7/00 ,  B29C70/30

CPC classification number: G06T7/0004 ,  B29C70/386 ,  B29L2007/007 ,  G06T2207/30108

Abstract: A device for identifying an end of a fiber tape rolling over a composite structure is presented. The device includes a light source disposed proximate to the composite structure and configured to project a line of light at a first angle on the fiber tape rolling over the composite structure. Also, the device includes an image capturing unit disposed proximate to the composite structure and configured to capture an image of the line of light on the fiber tape at a second angle. Further, the device includes a controller coupled to the image capturing unit and configured to process the captured image to detect a discontinuity in the line of light on the fiber tape and identify the end of the fiber tape based on the detected discontinuity in the line of light on the fiber tape.

Abstract translation: 提出了一种用于识别在复合结构上滚动的纤维带的端部的装置。 该装置包括靠近复合结构设置的光源，并被配置成在卷绕在复合结构上的纤维带上以一定角度投影一条光线。 而且，该装置还包括靠近该复合结构设置的图像捕获单元，并被配置为以第二角度在光纤带上捕获该光线​​的图像。 此外，该设备包括耦合到图像捕获单元并被配置为处理捕获的图像以检测光纤带上的光线中的不连续性并且基于检测到的不连续性来识别光纤带的端部的控制器 光纤上的光纤。

公开(公告)号：US20160134816A1

公开(公告)日：2016-05-12

申请号：US14534837

申请日：2014-11-06

Applicant: General Electric Company

Inventor： Kevin George Harding ,  Thomas James Batzinger

IPC: H04N5/232 ,  G02B13/00

CPC classification number: G02B13/0015 ,  G02B7/38 ,  G02B27/0075 ,  G06T7/571 ,  G06T2207/30164

Abstract: A method for correcting a magnification in image measurements is implemented using a computer device including one or more processors coupled to a user interface and one or more memory devices. The method includes acquiring a plurality of images of a target. Each image is acquired at a different distance from the target. The method also includes determining a distance between a lens used in acquiring the plurality of images and the target and determining a magnification of each acquired image. The method further includes determining a magnification correction with respect to a reference, determining a change in a size of the target, and outputting the determined change in a size of the target.

Abstract translation: 使用包括耦合到用户界面和一个或多个存储器设备的一个或多个处理器的计算机设备来实现用于校正图像测量中的倍率的方法。 该方法包括获取目标的多个图像。 每个图像在与目标不同的距离处获取。 该方法还包括确定在获取多个图像中使用的透镜与目标之间的距离并确定每个获得的图像的放大倍数。 该方法还包括确定相对于参考的放大率校正，确定目标的大小的变化，以及输出所确定的目标大小的变化。

公开(公告)号：US20150178546A1

公开(公告)日：2015-06-25

申请号：US14624639

申请日：2015-02-18

Applicant: General Electric Company

Inventor： Gil Abramovich ,  Kevin George Harding ,  Joseph Czechowski, III ,  Frederick Wilson Wheeler

IPC: G06K9/00

CPC classification number: G06K9/00033 ,  G02B5/3025 ,  G06K9/00026

Abstract: A system and method for contactless handprint capture is disclosed that includes an image capture device to capture handprint images of a subject hand at each of a plurality of different focal distances, with the image capture device including an imaging camera and an electro-optics arrangement having a plurality of light modulating elements and polarization sensitive optical elements having differing optical path lengths based on polarization states. A control system is coupled to the image capture device to cause the device to capture the handprint images at each of the different focal distances, with each handprint image having a depth-of-focus that overlaps with a depth-of-focus of handprint images at adjacent focal distances such that redundant handprint image data is captured. The control system registers each handprint image with positional data and creates a composite handprint image from the handprint images captured at the different focal distances.

Abstract translation: 公开了一种用于非接触式手印捕获的系统和方法，其包括图像捕获装置，用于在多个不同焦距的每一个处拍摄被摄体手的手印图像，所述图像捕获装置包括成像照相机和电光装置， 多个光调制元件和基于极化状态具有不同光程长度的偏振敏感光学元件。 控制系统耦合到图像捕获设备，以使设备在每个不同焦距下捕获手印图像，每个手印图像具有与手印图像的焦点深度重叠的焦点深度 在相邻焦距处，使得捕获冗余的手印图像数据。 控制系统使用位置数据登记每个手印图像，并且从在不同焦距处捕获的手印图像创建复合手印图像。

公开(公告)号：US20140044323A1

公开(公告)日：2014-02-13

申请号：US14056256

申请日：2013-10-17

Applicant: General Electric Company

Inventor： Gil Abramovich ,  Kevin George Harding ,  Christopher Allen Nafis ,  Joseph Czechowski, III ,  Vijay Krishna Paruchuru ,  Daniel Curtis Gray

IPC: G06K9/00

CPC classification number: G06K9/00033

Abstract: A system and method for contactless multi-fingerprint collection is disclosed. The contactless multi-fingerprint collection system includes an imaging volume, a user interface configured to provide feedback to the subject regarding a proximity of a hand to a desired imaging location within the imaging volume, and at least one image capture device to capture images of each of the plurality of fingerprints at each of at least two different depths from the fingerprints. The contactless multi-fingerprint collection system also includes a processor coupled to the at least one image capture device that is programmed to generate a composite image and a contour map of each of the plurality of fingerprints from the images captured at the at least two different depths and generate a two-dimensional rolled equivalent image of each of the plurality of fingerprints from the composite image and the contour map.

Abstract translation: 公开了一种用于非接触式多指纹采集的系统和方法。 非接触式多指纹收集系统包括成像体积，被配置为向被摄体提供关于手到成像体积内的期望成像位置的接近度的反馈的用户界面，以及至少一个图像捕获装置，以捕获每个 在指纹的至少两个不同深度的每一个处的多个指纹中。 非接触式多指纹收集系统还包括耦合到至少一个图像捕获装置的处理器，其被编程为从在至少两个不同深度捕获的图像生成多个指纹中的每一个的合成图像和轮廓图 并且从合成图像和轮廓图生成多个指纹中的每一个的二维滚动等效图像。

公开(公告)号：US12221897B2

公开(公告)日：2025-02-11

申请号：US17277087

申请日：2018-09-28

Applicant: GENERAL ELECTRIC COMPANY

Inventor： Rajesh Ramamurthy ,  Kevin George Harding ,  Jonathan Matthew Lomas ,  Vadim Bromberg

IPC: G06F30/10 ,  F01D5/00 ,  G06F30/20 ,  G06T3/40 ,  G06T7/00 ,  G06T7/536 ,  G06T15/04 ,  G06T15/20 ,  G06V10/44 ,  G06F119/08

Abstract: A method of processing a part includes: identifying (2502) a location of at least one hole (62) disposed in the part using a computer-aided design (CAD) model of the part (36); aligning (2504) the part in a mounting system (56); 3D-scanning (2506) the part (36); detecting (2520) at least one boundary feature of the hole (36) based at least partially on at least one datum from 3D-scanning (2506) the part; and generating (2536) a first toolpath (92) based at least partially on the boundary feature.

公开(公告)号：US10906132B2

公开(公告)日：2021-02-02

申请号：US15476498

申请日：2017-03-31

Applicant: General Electric Company

Inventor： William Thomas Carter ,  Jason Harris Karp ,  Justin John Gambone, Jr. ,  Lang Yuan ,  David Charles Bogdan, Jr. ,  Victor Petrovish Ostroverkhov ,  Marshall Gordon Jones ,  Michael Evans Graham ,  Kevin George Harding

IPC: B23K26/00 ,  B23K26/342 ,  B33Y10/00 ,  B33Y30/00 ,  B33Y50/02 ,  B23K26/082 ,  B23K26/08 ,  B23K26/144 ,  B23K26/12 ,  B23K26/06 ,  B23K103/02 ,  B23K103/10 ,  B23K103/14 ,  B23K103/18

Abstract: An additive manufacturing system configured to manufacture a component including scan strategies for efficient utilization of one or more laser arrays. The additive manufacturing system includes at least one laser device, each configured as a laser array, and a build platform. Each laser device is configured to generate a plurality of laser beams. The component is disposed on the build platform. The at least one laser device is configured to sweep across the component and the build platform in at least one of a radial direction, a circumferential direction or a modified zig-zag pattern and simultaneously operate the one or more of the plurality of individually operable laser beams corresponding to a pattern of the layer of a build to generate successive layers of a melted powdered material on the component and the build platform corresponding to the pattern of the layer of the build. A method of manufacturing a component with the additive manufacturing system is also disclosed.

公开(公告)号：US10583530B2

公开(公告)日：2020-03-10

申请号：US15401643

申请日：2017-01-09

Applicant: General Electric Company

Inventor： Jason Harris Karp ,  Justin John Gambone, Jr. ,  Michael Evans Graham ,  David Charles Bogdan, Jr. ,  Victor Petrovich Ostroverkhov ,  William Thomas Carter ,  Harry Kirk Mathews, Jr. ,  Kevin George Harding ,  Jinjie Shi ,  Marshall Gordon Jones ,  James William Sears

IPC: B23K26/342 ,  B33Y30/00 ,  B22F3/105 ,  B29C64/153 ,  B29C64/282 ,  B23K103/04

Abstract: A component is fabricated in a powder bed by moving a laser array across the powder bed. The laser array includes a plurality of laser devices. The power output of each laser device of the plurality of laser devices is independently controlled. The laser array emits a plurality of energy beams from a plurality of selected laser devices of the plurality of laser devices to generate a melt pool in the powder bed. A non-uniform energy intensity profile is generated by the plurality of selected laser devices. The non-uniform energy intensity profile facilitates generating a melt pool that has a predetermined characteristic.

公开(公告)号：US20190143406A1

公开(公告)日：2019-05-16

申请号：US15810308

申请日：2017-11-13

Applicant: General Electric Company

Inventor： William Thomas Carter ,  David Charles Bogdan, JR. ,  Jason Harris Karp ,  Justin John Gambone, JR. ,  Victor Petrovich Ostroverkhov ,  Marshall Gordon Jones ,  Kevin George Harding ,  Younkoo Jeong ,  Michael Robert Tucker ,  Subhrajit Roychowdhury

IPC: B22F3/00 ,  B22F3/105 ,  B29C64/153 ,  B29C64/245 ,  B29C64/386

Abstract: An additive manufacturing apparatus includes first and second spaced apart side walls defining a build chamber therebetween. The first and second spaced apart side walls are configured to rotate through an angle θ, about a z-axis along a pre-defined path. A build platform is defined within the first and second spaced apart side walls and is configured to rotate through an angle θ about the z-axis and vertically moveable along the z-axis. The apparatus further includes one or more build units mounted for movement along the pre-defined path. An additive manufacturing method is additionally disclosed.

公开(公告)号：US20180045510A1

公开(公告)日：2018-02-15

申请号：US15674920

申请日：2017-08-11

Applicant: General Electric Company

Inventor： Zirong Zahi ,  Kevin George Harding ,  Jie Han ,  Dongmin Yang ,  Clark Alexander Bendall ,  Jijun Gu

IPC: G01B11/25 ,  G02B23/24 ,  G01N21/954

CPC classification number: G01B11/2518 ,  G01B11/25 ,  G01N21/8806 ,  G01N21/954 ,  G01N2021/8829 ,  G02B23/2415

Abstract: A probe system and a method are provided. The probe system includes an emitter unit, a pattern generation system, and an intensity modulator. The emitter unit is for emitting light. The pattern generation system is for projecting at least one reference structured-light pattern onto an object surface to obtain at least one reference projected pattern, and including a mirror scanning unit for reflecting the light to a plurality of directions. The intensity modulator is for modulating intensity of the light according to the at least one reference projected pattern to provide modulated light to the mirror scanning unit to reflect the modulated light to the plurality of directions to project at least one modulated structured-light pattern onto the object surface to obtain at least one modulated projected pattern.

公开(公告)号：US09760986B2

公开(公告)日：2017-09-12

申请号：US14938419

申请日：2015-11-11

Applicant: General Electric Company

Inventor： Rajesh Ramamurthy ,  Kevin George Harding ,  Yi Liao ,  Ratnadeep Paul ,  Tao Jia ,  Xiaoming Du

IPC: G06K9/00 ,  G06T7/00 ,  G06K9/62 ,  G06T7/60 ,  G06K9/52 ,  G06T17/20 ,  G06K9/46 ,  G06T15/10

CPC classification number: G06T7/0004 ,  F01D5/186 ,  F05D2260/202 ,  F05D2260/80 ,  F05D2260/83 ,  G01B11/24 ,  G06K9/4604 ,  G06K9/52 ,  G06K9/6202 ,  G06T7/0006 ,  G06T7/60 ,  G06T15/10 ,  G06T17/20 ,  G06T2200/04 ,  G06T2207/10016 ,  G06T2207/10028 ,  G06T2207/30164 ,  Y02T50/675

Abstract: An automated measurement system includes multi-axis imager configured to receive images of a workpiece wherein the images include visual information about the workpiece at a plurality of focus planes or visual information about the workpiece between at least two focus planes. The multi-axis imager is also configured to determine a point cloud of a plurality of 3 D data points wherein each of the plurality of 3 D data points represents an intersection of one of the plurality of focus planes with a surface of the workpiece or positional information of the workpiece in a de-focused area between the at least two focus planes. The multi-axis imager is further configured to determine a plurality of dimensions of features of the workpiece and compare the determined plurality of dimensions of the features to manufacturing specifications corresponding to at least some of the determined plurality of dimensions of the features.