| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 161 | ロボットによるスマートサインシステムおよび方法 | JP2016518417 | 2014-06-03 | JP2016527537A | 2016-09-08 | リプトン,マイケル,ウイリアム; グネラス,マティアス,ハンズ; ゾルティー,アンドリュー,ステフィン |
| ロボットサインが記載され、該ロボットサインは、サインポスト;サインポストに可動的に取り付けられたアームであって、該アームが、サインポストのまわりで独立して及び隣接して回転することができるように構成された測位装置を有し、ディスプレイ項目を提示するように構成された電子ディスプレイを含む少なくとも1つの面を有している、アーム;およびリモート管理アプリケーションからディスプレイ項目情報を受信するように構成された通信要素であって、該ディスプレイ項目情報が、方向および記述を含む、通信要素;を含み、ここで、ディスプレイ項目の提示後、アームは、方向を示すために回転し、記述を表示する。また、ロボットサインを構成するためのソフトウェアアプリケーション、ロボットサインのネットワーク、およびロボットサインを利用する広告システムが記載される。【選択図】図1 | ||||||
| 162 | 制御装置、制御方法およびプログラム | JP2012104887 | 2012-05-01 | JP5979960B2 | 2016-08-31 | 立和 航 |
| 163 | ロボットシステム | JP2013156184 | 2013-07-26 | JP5942938B2 | 2016-06-29 | 橋口 幸男; 村井 真二; 白木 知行 |
| 164 | 比較した設定データの相違点の反映機能を備えるロボット制御装置 | JP2014119654 | 2014-06-10 | JP2015231656A | 2015-12-24 | 延原 敦史; 西 浩次 |
| 【課題】特定のロボット制御装置から他のロボット制御装置に、選択した設定データを反映させることが可能なロボット制御装置を提供する。 【解決手段】複数のロボット制御装置の間と、ロボット制御装置の設定データを格納した記録媒体との間でデータ交換が可能なロボット制御装置であって、特定のロボット制御装置に設定されている設定データと、他のロボット制御装置に設定されている設定データ及び記録媒体に格納された設定データの、少なくとも2つを、項目毎に比較し、比較した設定データ間に相違があった項目を表示し、設定をコピーした項目に対しては、項目毎に設定データをコピーできるようにしたロボット制御装置である。 【選択図】図9 |
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| 165 | 生産装置 | JP2013140328 | 2013-07-04 | JP2015013329A | 2015-01-22 | MIMURA TOSHIHIKO; DAN KEITA; EGUCHI TADASHI; TAKADA SATOYUKI |
| 【課題】他の生産装置との通信の干渉を回避しつつ、安定した無線通信を確保すること。【解決手段】ロボットアームに支持されたアンテナ部310は、複数の送信アンテナ321〜328を有する送信アンテナ部311と、複数の受信アンテナ331〜338を有する受信アンテナ部312とを有する。送信側スイッチャ回路361は、ロボットアームの姿勢情報に対応して、複数の送信アンテナ321〜328の中から送信機351に接続する送信アンテナを切り替えることで、送信アンテナ部311の指向方向を変更する。受信側スイッチャ回路362は、ロボットアームの姿勢情報に対応して、複数の受信アンテナ331〜338の中から受信機352に接続する受信アンテナを切り替えることで、受信アンテナ部312の指向方向を変更する。【選択図】図5 | ||||||
| 166 | Autonomous coverage robot navigation system | JP2013017419 | 2013-01-31 | JP2013144112A | 2013-07-25 | OZICK DANIEL N; OKERHOLM ANDREA M; MAMMEN JEFFRY W; HALLORAN MICHAEL J; SANDIN PAUL E; WON CHIKYUNG |
| PROBLEM TO BE SOLVED: To provide autonomous coverage robots and associated navigation systems.SOLUTION: A cleaning system comprising an autonomous mobile robot 100 and a base station is provided. The autonomous mobile robot 100 comprises a central receiver and two side receivers located at a front portion of a chassis 102 and a controller located within the chassis 102 and configured to direct the mobile robot 100 toward a docked position using the receiver signals received by the receivers 104. The base station comprises three emitters, the three emitters comprising at least two side emitters spaced in opposite directions from a central location of the base station, at least two of the emitters being detectable by the mobile robot from a position proximate the base station when the mobile robot 100 is aligning itself for docking. | ||||||
| 167 | Autonomous coverage robot navigation system | JP2012083706 | 2012-04-02 | JP2012178162A | 2012-09-13 | DANIEL N OZIK; ANDREA M OKERHOLM; JEFFRY W MAMMEN; MICHAEL J HALLORAN; SANDIN PAUL E; WON CHIKYUNG |
| PROBLEM TO BE SOLVED: To allow an autonomous mobile robot to move to an adjacent bounded spatial region by a navigation beacon.SOLUTION: The navigation beacon has a gateway beacon emitter comprised so as to transmit gateway marking emission by a navigation beacon placed inside a gateway between a first bounded spatial region and an adjacent second bounded spatial region. An autonomous coverage robot includes beacon emission sensors (104, 106) for responding to the beacon emission and a drive system comprised so as to move the robot around the first bounded spatial region in a cleaning mode in which to change the direction of the robot in response to detection of the gateway marking emission. The drive system moves the robot to the second bounded spatial region through the gateway in a migration mode. | ||||||
| 168 | Autonomous cleaning robot | JP2012087445 | 2012-04-06 | JP2012130781A | 2012-07-12 | SVENDSEN SELMA; OZICK DANIEL N; CASEY CHRISTOPHER M; KAPOOR DEEPAK RAMESH; CAMPBELL TONY L; WON CHIKYUNG; MORSE CHRISTOPHER; BURNETT SCOTT THOMAS |
| PROBLEM TO BE SOLVED: To provide an autonomous cleaning robot which suitably detects existence of a cliff, such as a set of stairs in a floor surface to prevent the robot from falling down the cliff when the robot meeting with the cliff while moving.SOLUTION: The autonomous cleaning robot includes: a chassis; a drive system mounted on the chassis and having a plurality of wheels configured to maneuver the autonomous cleaning robot; a floor proximity sensor carried by the chassis and configured to detect the cliff in the floor surface; a run off sensor disposed in the proximity of the wheel and detecting a downward displacement of the wheel relative to the chassis; and a verification system for verifying whether the floor proximity sensor is blocked, based on the detection result of the floor proximity sensor, when the run off sensor detects that all the wheels of the drive system run off. | ||||||
| 169 | Autonomous cleaning robot | JP2011088402 | 2011-04-12 | JP2011161242A | 2011-08-25 | WON CHIKYUNG; SVENDSEN SELMA; SANDIN PAUL E; BURNETT SCOTT THOMAS; KAPOOR DEEPAK RAMESH; HICKEY STEPHEN; RIZZARI ROBERT; DUBROVSKY ZIVTHAN A C |
| <P>PROBLEM TO BE SOLVED: To provide an autonomous cleaning device that can respond when one of components is breakdown without shipping a whole robot for a repair or without purchasing a new robot. <P>SOLUTION: There is provide an autonomous cleaning robot includes: a chassis; a driving wheel module for running the autonomous cleaning robot; a cleaning module for removing debris from a floor surface. The chassis has a formed receptacle with which the driving wheel module is detachably engaged. <P>COPYRIGHT: (C)2011,JPO&INPIT | ||||||
| 170 | REMOTE CONTROL ROBOT SYSTEM | EP16838719.9 | 2016-05-27 | EP3342564A1 | 2018-07-04 | HASHIMOTO, Yasuhiko; KAMON, Masayuki |
A robot main body (1) having a robotic arm (10), a remote control device (2) which includes a robotic arm operational instruction input part (70) installed outside of a working area and by which an operational instruction for the robotic arm is inputted, and a contactless action detecting part (71) configured to detect a contactless action including at least one given operating condition parameter change instructing action by an operator, a control device (3) communicably connected to the remote control device and configured to control operation of the robot main body. The control device includes a memory part (32) configured to store change instruction content data defining a change mode of an operating condition parameter related to an operating condition of the robot main body corresponding to the at least one operating condition parameter change instructing action, a change instruction content identifying module (34) configured to identify the change mode of the operating condition parameter corresponding to one of the operating condition parameter change instructing action detected by the contactless action detecting part based on the change instruction content data, and a motion controlling module (33) configured to control operation of the robot main body by changing the operating condition of the robot main body based on the change mode of the operating condition parameter identified by the change instruction content identifying module. |
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| 171 | INFORMATION SHARING SYSTEM AND INFORMATION SHARING METHOD FOR SHARING INFORMATION BETWEEN MULTIPLE ROBOT SYSTEMS | EP16838710.8 | 2016-05-27 | EP3342553A1 | 2018-07-04 | HASHIMOTO, Yasuhiko; KAMON, Masayuki |
An information sharing system between a plurality of robot systems includes a plurality of robot systems, communicatably connected with each other through a network, and configured to be capable of presetting a given operation of a robot and repeating a correction of the operation, and a storage device, connected with the network and configured to store corrected information containing corrected operating information that is operating information for causing the robot to execute a given operation corrected in at least one of the robot systems. Each of the plurality of robot systems shares the corrected information stored in the storage device and operates the robot based on the sharing corrected information. |
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| 172 | ROBOT SYSTEM | EP16838708.2 | 2016-05-27 | EP3342551A1 | 2018-07-04 | HASHIMOTO, Yasuhiko; SHIMOMURA, Nobuyasu; MAEHARA, Tsuyoshi; KAMON, Masayuki; KUROSAWA, Yasushi; TANAKA, Shigetsugu |
A robot system includes a robot main body, a memory part configured to store information for causing the robot main body to perform a given operation, as saved operational information, a motion controller configured to control the operation of the robot main body by using the saved operational information as automatic operational information for causing the robot main body to operate, and an operation correcting device configured to generate, by being operated, manipulating information for correcting the operation of the robot main body during operation. The motion controller controls the robot main body to perform an operation corrected from the operation related to the automatic operational information in response to a reception of the manipulating information while the robot main body is operating by using the automatic operational information. The memory part is configured to be storable of corrected operational information for causing the robot main body to perform the corrected operation as saved operational information, when the robot main body performs the corrected operation. |
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| 173 | ROBOT SYSTEM | EP16838732.2 | 2016-06-24 | EP3342545A1 | 2018-07-04 | HASHIMOTO, Yasuhiko; KAMON, Masayuki |
A robot system (100) includes a robot (1) including a tactile sensor (5) and a hand (1c) having the tactile sensor, a robot controller (6) configured to control operation of the hand of the robot according to robot manipulating information, a manipulator (2), a tactile information processor (7) configured to generate tactile information defined by a pressure distribution based on pressures detected by at least the plurality of pressure sensors and spatial positions of the plurality of pressure sensors, convert the tactile information into sensible tactile information that is sensible by the operator, and output the sensible tactile information, a sensible tactile information presenting part (10) configured to present to the operator the sensible tactile information outputted from the tactile information processor. |
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| 174 | INDUSTRIAL REMOTE CONTROL ROBOT SYSTEM | EP16838704.1 | 2016-05-27 | EP3342542A1 | 2018-07-04 | HASHIMOTO, Yasuhiko; KAMON, Masayuki |
A remote control robot system includes a master device, a slave arm having a plurality of control modes including an automatic mode and a manual mode, a control device configured to operate the slave arm, an entering-person sensing device configured to detect an entering person into an operational area of the slave arm, an entering-person identifying information acquisition device configured to acquire entering-person identifying information for identifying whether the entering person is the operator who carries the master device, and an operation regulating device configured to regulate the operation of the slave arm based on the information acquired from the entering-person sensing device and the entering-person identifying information acquisition device. In the automatic mode, the operation regulating device regulates the operation of the slave arm when the entering person is detected. In the manual mode, the operation regulating device allows the operation of the slave arm to continue when the entering person is detected and the entering person is the operator, and regulates the operation of the slave arm when the entering person is other than the operator. |
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| 175 | REMOTE CONTROL MANIPULATOR SYSTEM AND OPERATION METHOD THEREOF | EP16838712.4 | 2016-05-27 | EP3321044A1 | 2018-05-16 | HASHIMOTO, Yasuhiko; KAMON, Masayuki |
A remote-control manipulator system according to the present disclosure includes a manipulator (2) configured to receive a manipulating instruction from an operator, a slave arm (1) configured to perform a series of works comprised of a plurality of processes, a camera (3) configured to image operation of the slave arm (1), a display device (6) configured to display an image captured by the camera (3), a storage device (5) configured to store information related to environment in a workspace as an environment model (52), and a control device (4). The control device (4) is configured, while operating the slave arm (1) manually or hybridly, to acquire circumference information that is information related to a circumference area of an area imaged by the camera (3) based on the environment model (52) stored in the storage device (5), and display on the display device (6) so that the image captured by the camera (3) and the circumference information are interlocked. |
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| 176 | ROBOTERGESTÜTZTES TRANSPORTIEREN EINES VERFAHRBAREN GEGENSTANDS | EP16738666.3 | 2016-06-03 | EP3302894A2 | 2018-04-11 | Buck, Thomas |
| The present invention relates to a robot system (1) for transporting a mobile object (2), in particular a hospital bed, wherein the robot system (1) comprises at least two robots (3) and each of the two robots (3) can be coupled to the mobile object (2), in particular to a coupling device (9) of the mobile object (2), such that a force of at least one of the robots (3) can be transmitted to the mobile object (2) so that the robots (3) can transport the mobile object (2) together. The present invention further relates to: a robot (3) for transporting a mobile object (2), in particular a hospital bed; a coupling device (9) for coupling a mobile object (2), in particular a hospital bed; a hospital bed (2); a central control system (49) for a robot (3) and/or a robot system (1); and a method for transporting a mobile object (2), in particular a hospital bed. | ||||||
| 177 | CLEANING ROBOT AND METHOD FOR CONTROLLING CLEANING ROBOT | EP15843361 | 2015-09-24 | EP3199083A4 | 2018-04-04 | HAN SEONG JOO; HONG JUN PYO |
| A cleaning robot is provided. The cleaning robot includes a sensor configured to sense obstacle information, and a controller configured to generate a map based on sensed values obtained by the sensor, analyze a structure of the generated map by detecting a region segmentation point from the map, and generate a map image based on an analysis result. | ||||||
| 178 | REMOTELY OPERATING A MOBILE ROBOT | EP14877905 | 2014-11-10 | EP3094452A4 | 2018-03-14 | HOFFMAN ORIN P F; KEEFE PETER; SMITH ERIC; WANG JOHN; LABRECQUE ANDREW; PONSLER BRETT |
| A method of operating a robot includes electronically receiving images and augmenting the images by overlaying a representation of the robot on the images. The robot representation includes user-selectable portions. The method includes electronically displaying the augmented images and receiving an indication of a selection of at least one user-selectable portion of the robot representation. The method also includes electronically displaying an intent to command the selected at least one user-selectable portion of the robot representation, receiving an input representative of a user interaction with at least one user-selectable portion, and issuing a command to the robot based on the user interaction. | ||||||
| 179 | MIXED ENVIRONMENT DISPLAY OF ATTACHED DATA | EP16720944.4 | 2016-04-06 | EP3289428A1 | 2018-03-07 | HILL, David M.; CHARBONNEAU, Emiko V.; JEAN, Andrew William; EVERTT, Jeffrey J.; JONES, Alan M.; ROESLER, Richard C. |
| Concepts and technologies are described herein for providing enhanced configuration and control of robots. Configurations disclosed herein augment a mobile computing device, such as a robot, with resources for understanding and navigation of an environment surrounding the computing device. The resources can include sensors of a separate computing device, which may be in the form of a head-mounted display. Data produced by the resources can be used to generate instructions for the mobile computing device. The sensors of the separate computing device can also detect a change in an environment or a conflict in the actions of the mobile computing device, and dynamically modify the generated instructions. By the use of the techniques disclosed herein, a simple, low-cost robot can understand and navigate through a complex environment and appropriately interact with obstacles and other objects. | ||||||
| 180 | DISPOSITIF PORTATIF D'AMPLIFICATION D'UN EFFORT AXIAL | EP15808150.5 | 2015-12-09 | EP3240657A1 | 2017-11-08 | GARREC, Philippe |
| The invention relates to a portable device (1) for amplifying an axial force applied to a tool, which includes: means (100) for linking the device to a user; means (2) for guiding the tool (4) in translation along a longitudinal axis (X); means for actuating the tool, including a drum (5) provided with a motor (6) and a rope (7) rigidly connected to the tool (4) and forming at least one turn (8) around the drum (5); and means for controlling the actuating means in order to apply a force to the tool in response to a force provided by the user via a control member. The means (100) for linking the device to the user and the means (2) for guiding the tool (4) in translation allow the tool (4) to rotate freely about the longitudinal axis (X) and about at least one axis (Z, Y) extending in a plane (P) which is normal to the longitudinal axis (X). | ||||||
