| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 1 | 用于光传输数字数据的装置 | CN201280045298.7 | 2012-06-21 | CN104040916A | 2014-09-10 | 汉斯·波伊塞尔; 奥拉夫·齐曼; 亚历山大·巴赫曼 |
| 本发明涉及用于光传输数字数据的装置,所述装置包括信号源(1),其用来输出光学信号,所述光学信号的大小是基于要传输的数字数据而调制的。本发明提供荧光光纤(3),将荧光光纤(3)布置为使得通过外围区域接收来自信号源(1)的光学信号,通过荧光光纤(3)输入光学信号,通过发荧光的方法在荧光光纤(3)内将光学信号转换为荧光信号,通过光纤(3)将所述荧光信号路由到光纤末端(5)。 | ||||||
| 2 | 使用智能管理终端升级ODN设备的方法及系统 | CN201310698194.2 | 2013-12-18 | CN103701640B | 2016-09-28 | 肜云; 赵杰; 汪刚; 王欣 |
| 本发明公开了一种使用智能管理终端升级ODN设备的方法及系统,涉及智能光分配网络领域,该方法包括以下步骤:ODN网管服务器通过2G/3G/Wifi连接智能管理终端,智能管理终端通过USB或者蓝牙连接对纤器,对纤器通过USB连接ODN设备,ODN网管服务器以智能管理终端为中转站与ODN设备进行无线通信,ODN设备通过智能管理终端为中装站,从ODN网管服务器下载升级文件。本发明能够实现ODN网管服务器与ODN设备之间的无线通信,凡是有2G/3G/wifi的地方,无需有线网络,就能通过智能管理终端来完成ODN设备的升级。 | ||||||
| 3 | 光学连接到电子装置的连接器模块 | CN201280066072.5 | 2012-01-06 | CN104040395A | 2014-09-10 | K.B.利; G.D.梅加森; D.W.谢罗德; C.C.瓦纳 |
| 模块化连接器基础设施包括装置连接器模块,所述装置连接器模块具有光学地连接到系统中的电子装置的相应子集的光学连接器。装置连接器模块被可移除地连接到电子装置。 | ||||||
| 4 | 光学连接到电子装置的连接器模块 | CN201280066072.5 | 2012-01-06 | CN104040395B | 2016-06-01 | K.B.利; G.D.梅加森; D.W.谢罗德; C.C.瓦纳 |
| 模块化连接器基础设施包括装置连接器模块,所述装置连接器模块具有光学地连接到系统中的电子装置的相应子集的光学连接器。装置连接器模块被可移除地连接到电子装置。 | ||||||
| 5 | 使用智能管理终端升级ODN设备的方法及系统 | CN201310698194.2 | 2013-12-18 | CN103701640A | 2014-04-02 | 肜云; 赵杰; 汪刚; 王欣 |
| 本发明公开了一种使用智能管理终端升级ODN设备的方法及系统,涉及智能光分配网络领域,该方法包括以下步骤:ODN网管服务器通过2G/3G/Wifi连接智能管理终端,智能管理终端通过USB或者蓝牙连接对纤器,对纤器通过USB连接ODN设备,ODN网管服务器以智能管理终端为中转站与ODN设备进行无线通信,ODN设备通过智能管理终端为中装站,从ODN网管服务器下载升级文件。本发明能够实现ODN网管服务器与ODN设备之间的无线通信,凡是有2G/3G/wifi的地方,无需有线网络,就能通过智能管理终端来完成ODN设备的升级。 | ||||||
| 6 | 光纤旋转接头、其应用方法和光纤装置 | CN200980162688.0 | 2009-12-03 | CN102667560A | 2012-09-12 | A·L·鲍曼 |
| 光纤旋转接头、其应用方法和光纤装置。本发明提供一种光纤旋转接头(20),用于使数字光信号的传输能越过转子和定子(21、22)的外表表面(26、29)之间的界面,该光纤旋转接头包括:多个光源(42A、42B、42C、…),被安装在转子和定子之一上,每一光源包含第一光源(43C)和第二光源(43C′),该第一光源被布置成有选择地在第一波长上产生第一光信号,该第二光源被布置成有选择地在第二波长上产生第二光信号;第一多个光发射器(25),沿转子和定子之一的表面的第一弧线距离被间隔开,用于向转子和定子的另一个的外表表面,发送从该光源接收的光信号;第一多个第一光纤,分别地使相应的各个光源与相应的各个光发射器通信,以便从每一相应的光源传送光信号到关联的发射器;第二多个光感受器(31),沿转子和定子的所述另一个的表面上的第二弧线距离被间隔开;以及至少一个光检测器(36、40),被安装在转子和定子的所述另一个上;以及第二多个第二光纤,分别地使相应的各个光感受器与该光检测器通信。 | ||||||
| 7 | 光ファイバ・ロータリージョイント、それによって実施される方法、及び光ファイバデバイス | JP2012541979 | 2009-12-03 | JP5787414B2 | 2015-09-30 | ボウマン、アンソニー、エル |
| 8 | Connector modules to optically connect to electronic devices | US14942415 | 2015-11-16 | US09645337B2 | 2017-05-09 | Kevin B. Leigh; George D. Megason; David W. Sherrod; Christopher C. Wanner |
| A modular connector infrastructure includes device connector modules having optical connectors to optically connect to respective subsets of electronic devices in a system. The device connector modules are removably connected to the electronic devices. | ||||||
| 9 | CONNECTOR MODULES TO OPTICALLY CONNECT TO ELECTRONIC DEVICES | US14942415 | 2015-11-16 | US20160070077A1 | 2016-03-10 | Kevin B. Leigh; George D. Megason; David W. Sherrod; Christopher C. Wanner |
| A modular connector infrastructure includes device connector modules having optical connectors to optically connect to respective subsets of electronic devices in a system. The device connector modules are removably connected to the electronic devices. | ||||||
| 10 | LED based identification and communication systems | US13174028 | 2011-06-30 | US09219544B2 | 2015-12-22 | Peter Gerber; Jodi Lasky |
| In one aspect, identification and communication systems are described herein. In some embodiments, an identification and communication system comprises one or more query units and one or more response units, wherein at least one query unit comprises a query beam source comprising a light emitting diode (LED) operable to emit a query beam. In some embodiments, the query beam is substantially collimated. In some embodiments, an identification and communication system comprises one or more query units and one or more response units, wherein at least one query unit comprises a first query beam source operable to emit a first component beam and a second query beam source operable to emit a second component beam. In some embodiments, the first query beam source comprises an LED and the second query beam source comprises a laser. In some embodiments, the first component beam and the second component beam are substantially concentric. | ||||||
| 11 | Fiber optic rotary joints, methods practiced thereby, and fiber optic devices | US13512450 | 2009-12-03 | US09170378B2 | 2015-10-27 | Anthony L. Bowman |
| This invention provides a fiber optic rotary joint (20) for enabling the transmission of digital optical signals across the interface between facing surfaces (26, 29) of a rotor and a stator (21, 22), comprising: a plurality of light sources (42A, 42B, 42C, . . . ) mounted on one of the rotor and stator, each light source including a first light source (43C) arranged to selectively generate a first optical signal at a first wave length and a second light source (43C) arranged to selectively generate a second optical signal at a second wavelength; a first plurality of light emitters (25) spaced along a first arc distance of the surface of the one of the rotor and stator for transmitting optical signals received from the light sources toward the facing surface of the other of the rotor and stator; a first plurality of first optical fibers severally communicating respective ones of the light sources with respective ones of the light emitters for conveying optical signals from each respective light source to the associated emitter; a second plurality of light receptors (31) spaced along a second arc distance on the surface of the other of the rotor and stator; and at least one light detector (36, 40) mounted on the other of the rotor and stator; and a second plurality of second optical fibers severally communicating respective ones of the light receptors with the light detector(s). | ||||||
| 12 | Handheld identification and communication systems | US13173737 | 2011-06-30 | US08938170B2 | 2015-01-20 | Peter Gerber; Jodi Lasky |
| In one aspect, identification and communication systems are described herein. In some embodiments, an identification and communication system comprises one or more query units and one or more response units, wherein at least one query unit is a handheld device. In some embodiments, the handheld device does not comprise a weapon and is not mounted on a weapon. In some embodiments, the handheld device comprises a flashlight. In some embodiments, the handheld device comprises a stylus. In some embodiments, the handheld device comprises a smart device in communication with the stylus. In some embodiments, the handheld device comprises a display screen. In some embodiments, the handheld device comprises a query controller and the display screen is operable to display data provided by the query controller. | ||||||
| 13 | METHODS OF SIMULATING COMBAT | US13173915 | 2011-06-30 | US20120003612A1 | 2012-01-05 | Peter Gerber; Jodi Lasky |
| In some embodiments, a method of simulating combat described herein comprises emitting a first query beam from a first query unit of a first interoperable identification and communication system, receiving the first query beam with a second response unit of a second interoperable identification and communication system, emitting a second response beam with the second response unit, and receiving the second response beam with the first query unit. In some embodiments, a method of simulating combat comprises emitting a query beam comprising a plurality of packets each comprising a header portion, an information portion, and a footer portion from a query unit; and receiving the query beam with a response unit comprising a plurality of detectors spatially separated from one another, wherein the response unit is operable to independently measure the intensity of each packet of the query beam received at each of the plurality of detectors. | ||||||
| 14 | Apparatus for optical transmission of digital data | JP2014520535 | 2012-06-21 | JP2014522158A | 2014-08-28 | ハンス・ポイゼル; オラフ・ツィーマン; アレクサンダー・バックマン |
| 本発明は、伝送されるデジタルデータに基づいて変調されるレベルで光信号を出力するように設計された信号源(1)を有するデジタルデータの光伝送用の装置に関する。 本発明は、信号源(1)からの信号が周囲領域を介して受信され、蛍光性光ファイバー(3)内に入り、蛍光発光によって蛍性光信号に変換されるように配置された蛍光性光ファイバー(3)を提供し、その蛍光性光信号が光ファイバー(3)を介してファイバー端部(5)に送られる。 | ||||||
| 15 | Fiber optic rotary joint, the method implemented it by, and fiber-optic device | JP2012541979 | 2009-12-03 | JP2013513130A | 2013-04-18 | ボウマン、アンソニー、エル |
| This invention provides a fiber optic rotary joint (20) for enabling the transmission of digital optical signals across the interface between facing surfaces (26, 29) of a rotor and a stator (21, 22), comprising: a plurality of light sources (42A, 42B, 42C, . . . ) mounted on one of the rotor and stator, each light source including a first light source (43C) arranged to selectively generate a first optical signal at a first wave length and a second light source (43C) arranged to selectively generate a second optical signal at a second wavelength; a first plurality of light emitters (25) spaced along a first arc distance of the surface of the one of the rotor and stator for transmitting optical signals received from the light sources toward the facing surface of the other of the rotor and stator; a first plurality of first optical fibers severally communicating respective ones of the light sources with respective ones of the light emitters for conveying optical signals from each respective light source to the associated emitter; a second plurality of light receptors (31) spaced along a second arc distance on the surface of the other of the rotor and stator; and at least one light detector (36, 40) mounted on the other of the rotor and stator; and a second plurality of second optical fibers severally communicating respective ones of the light receptors with the light detector(s). | ||||||
| 16 | Method and system for updating optical distribution network (ODN) device by using intelligent management terminal | US15039213 | 2014-09-18 | US10154324B2 | 2018-12-11 | Yun Rong; Jie Zhao; Gang Wang; Xin Wang |
| A method and system for updating an Optical Distribution Network (ODN) device by using an intelligent management terminal are disclosed. The method includes the following steps: an ODN management server connects to an intelligent management terminal through 2G/3G/Wifi, the intelligent management terminal is connected to an identifier of fiber's both terminations through USB or Bluetooth; the optical fiber connector is connected to an ODN device through USB, the ODN management server communicates wirelessly with the ODN device through the intelligent management terminal as a transfer station, and the ODN device downloads updating file from the ODN management server through the intelligent management terminal as a transfer station. The method and system can realize the wireless communication between the ODN network management server and the ODN device, thereby accomplishing the updating of the ODN device by the intelligent management terminal without cable networks wherever 2G/3G/Wifi. | ||||||
| 17 | METHOD AND SYSTEM FOR UPDATING OPTICAL DISTRIBUTION NETWORK (ODN) DEVICE BY USING INTELLIGENT MANAGEMENT TERMINAL | US15039213 | 2014-09-18 | US20170164075A1 | 2017-06-08 | Yun RONG; Jie ZHAO; Gang WANG; Xin WANG |
| A method and system for updating an Optical Distribution Network (ODN) device by using an intelligent management terminal are disclosed. The method includes the following steps: an ODN management server connects to an intelligent management terminal through 2G/3G/Wifi, the intelligent management terminal is connected to an identifier of fiber's both terminations through USB or Bluetooth; the optical fiber connector is connected to an ODN device through USB, the ODN management server communicates wirelessly with the ODN device through the intelligent management terminal as a transfer station, and the ODN device downloads updating file from the ODN management server through the intelligent management terminal as a transfer station. The method and system can realize the wireless communication between the ODN network management server and the ODN device, thereby accomplishing the updating of the ODN device by the intelligent management terminal without cable networks wherever 2G/3G/Wifi. | ||||||
| 18 | IDENTIFICATION AND COMMUNICATION SYSTEMS USING OPTICAL FIBERS | US15171182 | 2016-06-02 | US20170085320A1 | 2017-03-23 | Peter GERBER; Jodi LASKY |
| In one aspect, identification and communication systems are described herein. An identification and communication system described herein, in some embodiments, comprises one or more query units and one or more response units, wherein at least one response unit comprises one or more detectors comprising one or more optical fibers operable to direct one or more signals received from at least one query unit to the one or more detectors. In some embodiments, at least one optical fiber is operable to receive a signal from at least one query unit through the side of the optical fiber. In some embodiments, at least one optical fiber comprises a fluorescent plastic fiber (FPF). In some embodiments, at least one optical fiber is disposed in a textile. | ||||||
| 19 | Fiber optic rotary joints, methods practiced thereby, and fiber optic devices | US14733553 | 2015-06-08 | US09207406B2 | 2015-12-08 | Anthony L. Bowman |
| This invention provides a fiber optic rotary joint (20) for enabling the transmission of digital optical signals across the interface between facing surfaces (26, 29) of a rotor and a stator (21, 22), comprising: a plurality of light sources (42A, 42B, 42C, . . . ) mounted on one of the rotor and stator, each light source including a first light source (43C) arranged to selectively generate a first optical signal at a first wavelength and a second light source (43C′) arranged to selectively generate a second optical signal at a second wavelength; a first plurality of light emitters (25) spaced along a first arc distance of the surface of the one of the rotor and stator for transmitting optical signals received from the light sources toward the facing surface of the other of the rotor and stator; a first plurality of first optical fibers severally communicating respective ones of the light sources with respective ones of the light emitters for conveying optical signals from each respective light source to the associated emitter; a second plurality of light receptors (31) spaced along a second arc distance on the surface of the other of the rotor and stator; and at least one light detector (36, 40) mounted on the other of the rotor and stator; and a second plurality of second optical fibers severally communicating respective ones of the light receptors with the light detector(s). The light sources, first optical fibers, light emitters, light receptors, second optical fibers and detector(s) are so configured and arranged that the aggregate propagation delay of the optical signal transmitted from the light sources to the detector(s) is less than about one-quarter of the bit width of the optical signal. The fiber optic rotary joint is capable of transmitting the optical signal across the interface with reduced jitter. | ||||||
| 20 | FIBER OPTIC ROTARY JOINTS, METHODS PRACTICED THEREBY, AND FIBER OPTIC DEVICES | US13512450 | 2009-12-03 | US20120237198A1 | 2012-09-20 | Anthony L. Bowman |
| This invention provides a fiber optic rotary joint (20) for enabling the transmission of digital optical signals across the interface between facing surfaces (26, 29) of a rotor and a stator (21, 22), comprising: a plurality of light sources (42A, 42B, 42C, . . . ) mounted on one of the rotor and stator, each light source including a first light source (43C) arranged to selectively generate a first optical signal at a first wave length and a second light source (43C) arranged to selectively generate a second optical signal at a second wavelength; a first plurality of light emitters (25) spaced along a first arc distance of the surface of the one of the rotor and stator for transmitting optical signals received from the light sources toward the facing surface of the other of the rotor and stator; a first plurality of first optical fibers severally communicating respective ones of the light sources with respective ones of the light emitters for conveying optical signals from each respective light source to the associated emitter; a second plurality of light receptors (31) spaced along a second arc distance on the surface of the other of the rotor and stator; and at least one light detector (36, 40) mounted on the other of the rotor and stator; and a second plurality of second optical fibers severally communicating respective ones of the light receptors with the light detector(s). | ||||||
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