| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 61 | Systems and Methods of Tracking Moving Hands and Recognizing Gestural Interactions | US15989090 | 2018-05-24 | US20190033975A1 | 2019-01-31 | Kevin A. HOROWITZ; Matias PEREZ; Raffi BEDIKIAN; David S. HOLZ; Gabriel A. HARE |
| The technology disclosed relates to relates to providing command input to a machine under control. It further relates to gesturally interacting with the machine. The technology disclosed also relates to providing monitoring information about a process under control. The technology disclosed further relates to providing biometric information about an individual. The technology disclosed yet further relates to providing abstract features information (pose, grab strength, pinch strength, confidence, and so forth) about an individual. | ||||||
| 62 | METHOD FOR LOCATING ELECTROMAGNETIC PULSE EMISSION SOURCES IN AN ENVIRONMENT INCLUDING REFLECTORS | US16102611 | 2018-08-13 | US20180348336A1 | 2018-12-06 | Daniel JAHAN; Romain Giacometti; Cedric Cornu |
| Methods for locating electromagnetic pulse emission sources in an environment including reflectors is disclosed. In one aspect, the method includes receiving, by a detector, for each source to be located, at least one same emitted pulse, received directly from said source and received by reflection on one of the reflectors. The method also includes identifying direct subsets and reflected subsets, regrouping by pairs of direct subsets with reflected subsets, calculating, for each pair, differences in dates of arrival between the pulses of the reflected subset and the pulses of the direct subset of the pair, and determining the distance of each source from the detector from calculated differences in dates of arrival of the pulses of each pair. | ||||||
| 63 | Ship handling device | US15519939 | 2015-08-20 | US10078332B2 | 2018-09-18 | Gakuji Tamura; Jun Watanabe; Hiroaki Wakahara; Naohiro Hara |
| A ship handling device may be provided with which a ship moves and turns in a target orientation toward target coordinates without monitoring the behavior of the ship against disturbance or the characteristics of the ship. The ship handling device moves the ship toward the target coordinates and in the target orientation from a GPS device and a signal from an orientation sensor, wherein the target coordinates and the target orientation are calculated from operation of a joystick lever, and a thrust is generated by a propulsion device so as to move the ship to the target coordinates and the target orientation after a signal finalizing the target coordinates and the target orientation has been acquired. | ||||||
| 64 | POLARIZATION ILLUMINATION USING ACOUSTO-OPTIC STRUCTURED LIGHT IN 3D DEPTH SENSING | US15428780 | 2017-02-09 | US20180227567A1 | 2018-08-09 | Qing Chao; Michael Hall |
| A depth camera assembly (DCA) includes a polarized structured light generator, an imaging device and a controller. The structured light generator illuminates a local area with one or more polarized structured light patterns in accordance with emission instructions from the controller. The structured light generator comprises an illumination source, an acousto-optic device, and a polarizing element. The acousto-optic device generates a structured light pattern from an optical beam emitted from the illumination source. The polarizing element generates the one or more polarized structured light patterns using the structured light pattern. The imaging device captures portions of the one or more polarized structured light patterns scattered or reflected from the local area. The controller determines depth information, degree of polarization and index of refraction map for the local area based at least in part on the captured portions of the one or more scattered or reflected polarized structured light patterns. | ||||||
| 65 | Systems and methods of tracking moving hands and recognizing gestural interactions | US15728242 | 2017-10-09 | US09983686B2 | 2018-05-29 | Kevin A. Horowitz; Matias Perez; Raffi Bedikian; David S. Holz; Gabriel A. Hare |
| The technology disclosed relates to relates to providing command input to a machine under control. It further relates to gesturally interacting with the machine. The technology disclosed also relates to providing monitoring information about a process under control. The technology disclosed further relates to providing biometric information about an individual. The technology disclosed yet further relates to providing abstract features information (pose, grab strength, pinch strength, confidence, and so forth) about an individual. | ||||||
| 66 | MOBILE PHOTOGRAPHING APPARATUS, MOBILE PHOTOGRAPHING CONTROL APPARATUS, PHOTOGRAPHING DEVICE, PHOTOGRAPHING METHOD, CONTROL METHOD OF MOBILE PHOTOGRAPHING APPARATUS, AND RECORDING MEDIUM FOR RECORDING PHOTOGRAPHING PROGRAM | US15805341 | 2017-11-07 | US20180131856A1 | 2018-05-10 | Akinobu SATO; Koichi Shintani; Kenji Homma; Yoshihisa Ogata; Manabu Tajima |
| A mobile photographing apparatus includes an image sensor provided in a mobile body, a storage section configured to store map information within a moving range of the mobile body, and a control section configured to receive target identification information including information on a moving photographing target generated in accordance with a user's operation, acquire information on a photographing position based on the target identification information, perform movement control to cause the mobile body to move in order for the image sensor to pick up an image of the photographing target based on the information on the photographing position and the map information, and cause the image sensor to pick up an image of the photographing target. | ||||||
| 67 | Gimbaled camera object tracking system | US14830023 | 2015-08-19 | US09936133B2 | 2018-04-03 | Paul M. Bosscher; Matthew D. Summer; William S. Bowman; Jeffrey M. Pollard |
| A system for automatically controlling a gimbaled camera system of a vehicle. The system includes a camera positioned relative to a body of the vehicle and one or more sensors configured to sense the pointing direction of the camera. One or more sensors are configured to monitor movement of the vehicle relative to a surface. A processor is configured to receive the sensed camera pointing direction data and vehicle movement data. The processor establishes and stores a target position representative of the position of a target object relative to the vehicle body based on an object independent association and automatically adjusts the camera pointing direction in response to the vehicle movement data such that the camera remains aimed on the target position. A method for automatically controlling the gimbaled camera system is also provided. | ||||||
| 68 | SYSTEMS AND METHODS OF TRACKING MOVING HANDS AND RECOGNIZING GESTURAL INTERACTIONS | US15728242 | 2017-10-09 | US20180032144A1 | 2018-02-01 | Kevin A. HOROWITZ; Matias PEREZ; Raffi BEDIKIAN; David S. HOLZ; Gabriel A. HARE |
| The technology disclosed relates to relates to providing command input to a machine under control. It further relates to gesturally interacting with the machine. The technology disclosed also relates to providing monitoring information about a process under control. The technology disclosed further relates to providing biometric information about an individual. The technology disclosed yet further relates to providing abstract features information (pose, grab strength, pinch strength, confidence, and so forth) about an individual. | ||||||
| 69 | ESTIMATING POSE IN 3D SPACE | US15597694 | 2017-05-17 | US20180005034A1 | 2018-01-04 | Adrian Kaehler; Gary Bradski |
| Methods and devices for estimating position of a device within a 3D environment are described. Embodiments of the methods include sequentially receiving multiple image segments forming an image representing a field of view (FOV) comprising a portion of the environment. The image includes multiple sparse points that are identifiable based in part on a corresponding subset of image segments of the multiple image segments. The method also includes sequentially identifying one or more sparse points of the multiple sparse points when each subset of image segments corresponding to the one or more sparse points is received and estimating a position of the device in the environment based on the identified the one or more sparse points. | ||||||
| 70 | SHIP HANDLING DEVICE | US15519939 | 2015-08-20 | US20170351259A1 | 2017-12-07 | Gakuji TAMURA; Jun WATANABE; Hiroaki WAKAHARA; Naohiro HARA |
| A ship handling device may be provided with which a ship moves and turns in a target orientation toward target coordinates without monitoring the behavior of the ship against disturbance or the characteristics of the ship. The ship handling device moves the ship toward the target coordinates and in the target orientation from a GPS device and a signal from an orientation sensor, wherein the target coordinates and the target orientation are calculated from operation of a joystick lever, and a thrust is generated by a propulsion device so as to move the ship to the target coordinates and the target orientation after a signal finalizing the target coordinates and the target orientation has been acquired. | ||||||
| 71 | Camera for Locating Hidden Objects | US15645545 | 2017-07-10 | US20170323458A1 | 2017-11-09 | Peter Lablans |
| A distance substantially between a camera and an object is measured preferably with a rangefinder. Positional coordinates including an altitude of the camera are determined. A pose including pitch and azimuth of the camera directed at the object is determined from sensors. Positional coordinates of the object are determined using at least the positional coordinates of the camera, the pose of the camera and the distance substantially between the camera and the object which are used to determine a location volume. A database is searched for objects located at least partially inside the location volume. The camera is part of a computing device with a screen. Search results are listed on the screen and an outline of a hidden object in the location volume is drawn on the screen. | ||||||
| 72 | TRANSMISSION APPARATUS, WIRELESS COMMUNICATION APPARATUS, AND WIRELESS COMMUNICATION SYSTEM | US15377006 | 2016-12-13 | US20170187098A1 | 2017-06-29 | Hiroshi ASHIDA |
| A transmission apparatus includes a first metal plate including a first surface, a second surface opposite to the first surface, and a first through hole penetrating from the first surface to the second surface, the first metal plate; a first board being disposed on the first surface side of the first metal plate, the first board including a first patch antenna positioned inside the first through hole; and a second board being disposed on the second surface side of the first metal plate, the second board including a second patch antenna positioned inside the first through hole and opposed to the first patch antenna, wherein an interval between the first patch antenna and the second patch antenna is set in accordance with a distance for wireless communicating between the first patch antenna and the second patch antenna in a near field. | ||||||
| 73 | SYSTEMS AND METHODS FOR PERFORMING AUTOMATIC ZOOM | US14991698 | 2016-01-08 | US20170094184A1 | 2017-03-30 | Jinglun Gao; Dashan Gao; Xin Zhong; Yingyong Qi |
| An electronic device is described. The electronic device includes a processor. The processor is configured to obtain a plurality of images. The processor is also configured to obtain global motion information indicating global motion between at least two of the plurality of images. The processor is further configured to obtain object tracking information indicating motion of a tracked object between the at least two of the plurality of images. The processor is additionally configured to perform automatic zoom based on the global motion information and the object tracking information. Performing automatic zoom produces a zoom region including the tracked object. The processor is configured to determine a motion response speed for the zoom region based on a location of the tracked object within the zoom region. | ||||||
| 74 | GIMBALED CAMERA OBJECT TRACKING SYSTEM | US14830023 | 2015-08-19 | US20170050563A1 | 2017-02-23 | Paul M. Bosscher; Matthew D. Summer; William S. Bowman; Jeffrey M. Pollard |
| A system for automatically controlling a gimbaled camera system of a vehicle. The system includes a camera positioned relative to a body of the vehicle and one or more sensors configured to sense the pointing direction of the camera. One or more sensors are configured to monitor movement of the vehicle relative to a surface. A processor is configured to receive the sensed camera pointing direction data and vehicle movement data. The processor establishes and stores a target position representative of the position of a target object relative to the vehicle body based on an object independent association and automatically adjusts the camera pointing direction in response to the vehicle movement data such that the camera remains aimed on the target position. A method for automatically controlling the gimbaled camera system is also provided. | ||||||
| 75 | METHOD OF IMAGING MOVING OBJECT AND IMAGING DEVICE | US14941971 | 2015-11-16 | US20170034403A1 | 2017-02-02 | Chang-woo SEO; Jae-ho LEE; Do-han KIM |
| An imaging device configured to image a moving object includes a sensing unit configured to obtain location information of the imaging device; a processor configured to determine a moving trajectory of the moving object using the location information; an interface configured to output a first image representing the moving trajectory; and an image processor configured to generate the first image and a second image representing the moving object based on the moving trajectory. | ||||||
| 76 | Visual and audio recognition for scene change events | US14307090 | 2014-06-17 | US09536161B1 | 2017-01-03 | Christopher John Lish; Oleg Rybakov; Sonjeev Jahagirdar; Junxiong Jia; Neil David Cooper; Avnish Sikka |
| Various embodiments describe systems and methods for utilizing a reduced amount of processing capacity for incoming data over time, and, in response to detecting a scene-change-event, notify one or more data processors that a scene-change-event has occurred, and cause incoming data to be processed as new data. In some embodiments, an incoming frame can be compared with a reference frame to determine a difference between the reference frame and the incoming frame. The reference frame may be correlated to a latest scene-change-event. In response to a determination that the difference does not meet one or more difference criteria, a user interface or at least one processor of the computing device can be notified to reduce processing of incoming data over time. In response to a determination that the difference meets the one or more difference criteria, the user interface or the at least one processor can be notified that a scene-change-event has occurred. Incoming data to the computing device is then treated as new and processed as those under an active condition. The current incoming frame can be selected as a new reference frame for detecting next scene-change-event. | ||||||
| 77 | Acoustic ranging system using atmospheric dispersion | US13480192 | 2012-05-24 | US09146295B2 | 2015-09-29 | Qin Jiang; Michael J. Daily; Richard Michael Kremer |
| A method and apparatus for processing sound from a sound source. The sound from the sound source is detected. Harmonics in the sound from the sound source are identified. A distance to the sound source is identified using the harmonics and a number of atmospheric conditions. | ||||||
| 78 | System and method for relative localization | US13771909 | 2013-02-20 | US09134403B1 | 2015-09-15 | Roger J. Anderson |
| Localization systems and methods for unambiguously determining the range, bearing, and relative heading of a neighboring object relative to a reference point are provided. The systems and methods utilize a triangulation-based approach, wherein the range and heading information is based on measurements of angles between a reference coordinate system superposed on the reference point to a minimum of three target points on the neighboring object. The target points can include a minimum of three uniquely discernible beacons mounted to the neighboring object. A sensor capable of detecting the beacons is mounted at the reference point. The range and heading of the neighboring object can be calculated by an analysis of the geometries of the beacons and the reference point. | ||||||
| 79 | Methods and systems for use in indicating directions finding systems | US13473997 | 2012-05-17 | US08970355B1 | 2015-03-03 | Benjamin Alan Stensland; David Mark McClelland; Kevin Luke Mace |
| An article is worn by a user. A plurality of indicating devices are coupled to the article. A processing unit is communicatively coupled to the plurality of indicating devices. The processing unit selectively actuates at least one indicating device of the plurality of indicating devices based on positional data. | ||||||
| 80 | Electromagnetic spectrum aerial surveying | US13267564 | 2011-10-06 | US08942938B2 | 2015-01-27 | Donald M. Bishop |
| Disclosed is an aerial surveying system for collecting electromagnetic spectrum data. Spectrally tuned antennas are used on an airplane to prefilter the data in accordance with spectral frequency bands. The data is sequentially sampled using an antenna switching device, band pass filtered and downconverted to an intermediate frequency. High speed vector signal analyzers and digitizers create frequency spectral data and I and Q temporal data. The collected data is recorded and compressed using any desirable compression technique, including video compression. Data analyzers analyze the data and display the data on a GIS map. | ||||||
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