| 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 | 在对通信信道进行共享的通信网络之间的信道重用 | CN201380050442.0 | 2013-09-26 | CN104662804A | 2015-05-27 | J·卡里米; E·塔希尔; B·J·朗格莱; J·F·查普尔; S·B·甘; R·D·罗泽; G·A·梅金; C·A·科拉尔; S·A·侯赛因; K·赖利 |
| 第一网络设备确定在通信信道上的至少第一传输中所包括的第一参考码是否与所述第一网络设备中配置的码相关联。所述通信信道是在多个通信网络之间共享的,并且所述第一参考码与多个通信网络中的第一通信网络相关联。所述第一网络设备响应于确定所述第一参考码与所述第一网络设备中配置的所述码相关联,加入与所述第一参考码相关联的所述第一通信网络。所述第一网络设备使用所述第一网络设备中配置的所述码来与所述第一通信网络中的第二网络设备通信。 | ||||||
| 2 | 在控制单元和测位设备之间传输能量和数据的设备和方法 | CN201310122448.6 | 2013-04-10 | CN103365226A | 2013-10-23 | B.博伊里; H.霍夫鲍尔; M.莫沙默; E.施特拉泽; E.蒂利克; S.唐多夫 |
| 本发明描述了用于在控制单元(100)和位置测量设备(10)之间经由一个线路对(110)传输能量和数据的设备和方法,其中能量的传输在充电模式中进行,以及数据的传输在通信模式中进行,其中在位置测量设备(10)中配备储能器(15),该储能器能够在充电模式中经由所述线路对(110)充电,并且利用该储能器能够在通信模式中向位置测量设备(10)提供能量,以及在控制单元(100)中配备充电单元(130),以及开关装置(120.1,120.2;200.1,200.2,200.3,200.4),在充电模式中经由该开关装置能够将充电单元(130)与所述线路对(110)双极连接。 | ||||||
| 3 | Device and method for transmitting energy and data between control unit and position-measuring device | JP2013078375 | 2013-04-04 | JP2013220015A | 2013-10-24 | BERNHARD BEAURY; HOFBAUER HERMANN; MARKUS MOOSHAMMER; STRASSER ERICH; ERNST THIELICKE; TONDORF SEBASTIAN |
| PROBLEM TO BE SOLVED: To provide a device and method for transmitting energy and data between a control unit (100) and a position-measuring device (10) via a line pair (110).SOLUTION: Energy is transmitted in a charge mode, and data is transmitted in a communication mode. In the position-measuring device (10), an energy storage device (15) is arranged which is chargeable via the line pair (110) in the charge mode. The energy storage device can be used to supply energy to the position-measuring device (10) in the communication mode. In the control unit (100), a charge unit (130) and switching means (120.1, 120.2; 200.1, 200.2, 200.3, 200.4) are arranged. The switching means makes it possible to connect the charge unit (130) to the line pair (110) in a two-pole manner in the charge mode. | ||||||
| 4 | 電力グリッドを介して信号を送信する及び/又は受信するための方法、装置及びコンピュータプログラム | JP2015562004 | 2014-02-21 | JP6436493B2 | 2018-12-12 | ウォモ, ヘイッキ |
| 5 | Coupling Circuit for Power Line Communications | US16269324 | 2019-02-06 | US20190173526A1 | 2019-06-06 | Riccardo Fiorelli |
| A coupling circuit for power line communications includes a coupling transformer having first and second mutually coupled windings, with the first winding connectable to a power line. The second winding includes a pair of intermediate taps with one or more tuning inductor therebetween. The inductor or inductors are set between a first portion and a second portion of the second winding of the coupling transformer. A switch member is provided coupled with the inductor. The switch member is selectively actuatable to short-circuit the inductor. | ||||||
| 6 | CHANNEL REUSE AMONG COMMUNICATION NETWORKS SHARING A COMMUNICATION CHANNEL | US13838678 | 2013-03-15 | US20140092774A1 | 2014-04-03 | Joubin Karimi; Ehab Tahir; Brian James Langlais; John Fraser Chappel; Son Binh Cam; Richard David Roze; Gregory Allen Magin; Celestino A. Corral; Syed Adil Hussain; Keith Riley |
| A first network device determines whether a first reference code included in at least a first transmission on a communication channel is associated with a code configured in the first network device. The communication channel is shared among a plurality of communication networks and the first reference code is associated with a first communication network of the plurality of communication networks. The first network device joins the first communication network associated with the first reference code in response to determining the first reference code is associated with the code configured in the first network device. The first network device communicates with a second network device in the first communication network using the code configured in the first network device. | ||||||
| 7 | Device and Method for Transmitting Energy and Data Between a Control Unit and a Position-Measuring Device | US13859926 | 2013-04-10 | US20130265000A1 | 2013-10-10 | Bernhard Beaury; Hermann Hofbauer; Markus Mooshammer; Erich Strasser; Ernst Thielicke; Sebastian Tondorf |
| In a device and a method for transmitting energy and data between a control unit and a position-measuring device via a line pair, the energy transmission takes place in a charge mode and the data transmission takes place in a communication mode, and an energy storage device is provided in the position-measuring device, which is able to be charged in the charge mode via the line pair, and which is able to supply energy to the position-measuring device in the communication mode, and a charge unit and a switching device are provided in the control unit. The switching unit is adapted to the charge unit to the line pair in two-pole manner. | ||||||
| 8 | NETWORK COMMUNICATION NODE AND DATA TRANSMISSION METHOD THEREOF FOR USE IN POWER LINE COMMUNICATION NETWORK | US12977636 | 2010-12-23 | US20120140628A1 | 2012-06-07 | Chi-Wen TENG |
| A network communication node and a data transmission method thereof for use in a power line communication network are provided. The network communication node receives a broadcast message from a gateway, and determines whether the load of the power line communication network changes or not. The network communication node is capable of changing a route for transmitting the data dynamically according to the change of the load. | ||||||
| 9 | Method and System to Validate Physical and Logical System Connectivity of Components in a Data Processing System | US11862593 | 2007-09-27 | US20090089594A1 | 2009-04-02 | Brian James Cagno; John Charles Elliott; Kenny Nian Gan Qiu; Donald Scott Smith |
| A method, system, and computer program product are provided for validating a connection of powered elements within a data processing system. A request for data is issued to a set of powered elements using a set of communication channels. The set of communication channels comprises one or more alternating current power lines. The request is sent as a set of instructions injected onto the communication channels to the set of powered elements. Data received from the set of powered elements using the set of communication channels includes physical connection information for the set of powered elements. A determination is made as to whether each powered element in the set of powered elements is connected in a predetermined configuration. A notification is presented to a user identifying each powered element in the set of powered elements that is not connected in the predetermined configuration. | ||||||
| 10 | COUPLING CIRCUIT FOR POWER LINE COMMUNICATIONS | US15607256 | 2017-05-26 | US20180109290A1 | 2018-04-19 | Riccardo Fiorelli |
| A coupling circuit for power line communications includes a coupling transformer having first and second mutually coupled windings, with the first winding connectable to a power line. The second winding includes a pair of intermediate taps with one or more tuning inductor therebetween. The inductor or inductors are set between a first portion and a second portion of the second winding of the coupling transformer. A switch member is provided coupled with the inductor. The switch member is selectively actuatable to short-circuit the inductor. | ||||||
| 11 | Low-power wide-band communication links in high-voltage transmission lines | US14320133 | 2014-06-30 | US09838081B1 | 2017-12-05 | Kurt Hallamasek; Geoff Dolan; George Edward Homsy; Leo Casey; Elias Wolfgang Patten |
| Embodiments described herein may relate to power-line communication (PLC) systems that are suitable for high-voltage and electrically noisy applications. In one example system, PLC technology is used to carry data on at least one pair of conductors of a high-voltage (e.g., kilovolt) transmission line that is simultaneously used for power transmission. Further, in some instances, the transmission line may be part of a tether that connects an aerial vehicle to a ground station. | ||||||
| 12 | Device and method for transmitting energy and data between a control unit and a position-measuring device | US13859926 | 2013-04-10 | US09627898B2 | 2017-04-18 | Bernhard Beaury; Hermann Hofbauer; Markus Mooshammer; Erich Strasser; Ernst Thielicke; Sebastian Tondorf |
| In a device and a method for transmitting energy and data between a control unit and a position-measuring device via a line pair, the energy transmission takes place in a charge mode and the data transmission takes place in a communication mode, and an energy storage device is provided in the position-measuring device, which is able to be charged in the charge mode via the line pair, and which is able to supply energy to the position-measuring device in the communication mode, and a charge unit and a switching device are provided in the control unit. The switching unit is adapted to the charge unit to the line pair in two-pole manner. | ||||||
| 13 | Channel reuse among communication networks sharing a communication channel | US13838678 | 2013-03-15 | US09413601B2 | 2016-08-09 | Joubin Karimi; Ehab Tahir; Brian James Langlais; John Fraser Chappel; Son Binh Cam; Richard David Roze; Gregory Allen Magin; Celestino A. Corral; Syed Adil Hussain; Keith Riley |
| A first network device determines whether a first reference code included in at least a first transmission on a communication channel is associated with a code configured in the first network device. The communication channel is shared among a plurality of communication networks and the first reference code is associated with a first communication network of the plurality of communication networks. The first network device joins the first communication network associated with the first reference code in response to determining the first reference code is associated with the code configured in the first network device. The first network device communicates with a second network device in the first communication network using the code configured in the first network device. | ||||||
| 14 | Sliding-window transform with integrated windowing | US09883834 | 2001-06-18 | US07020218B2 | 2006-03-28 | David M. Arnesen |
| A system for a sliding-window transform with integrated windowing is described. The system provides a Direct Fourier Transform kernel with an integrated windowing filter having a desired number of stages. In one embodiment, the windowing filter is a lowpass filter. In one embodiment, the lowpass filter has a rectangular filter transfer characteristic. The DFT includes a complex multiplier. A first portion of the windowing filter is provided before the complex multiplier and can be implemented using real arithmetic. A second portion of the windowing filter is provided after the complex multiplier and is implemented using complex arithmetic. In one embodiment, the filter weights of the second portion of the windowing filter are unity and thus no multiplier is needed for the filter weights in the second portion of the windowing filter. | ||||||
| 15 | TWO WIRE POWER AND SERIAL COMMUNICATION | US15600059 | 2017-05-19 | US20180335461A1 | 2018-11-22 | Robbie W. Hall |
| A power and data communication system includes an inboard computer, an outboard computer, and first and second wires. The first and second wires connect a first isolation transformer of the inboard computer to a second isolation transformer of the outboard computer. The inboard computer drives a driven voltage through the first isolation transformer. The outboard computer is configured to receive the driven voltage through the second isolation transformer to power the outboard computer. The outboard computer includes a load that is selectively connected across the second isolation transformer to transmit data to the inboard computer. The inboard computer receives the data through the first isolation transformer. | ||||||
| 16 | Two wire power and serial communication | US15600059 | 2017-05-19 | US10132849B1 | 2018-11-20 | Robbie W. Hall |
| A power and data communication system includes an inboard computer, an outboard computer, and first and second wires. The first and second wires connect a first isolation transformer of the inboard computer to a second isolation transformer of the outboard computer. The inboard computer drives a driven voltage through the first isolation transformer. The outboard computer is configured to receive the driven voltage through the second isolation transformer to power the outboard computer. The outboard computer incudes a load that is selectively connected across the second isolation transformer to transmit data to the inboard computer. The inboard computer receives the data through the first isolation transformer. | ||||||
| 17 | Auto-addressing of communication nodes | US15048354 | 2016-02-19 | US10013379B2 | 2018-07-03 | Bernd Uwe Gerhard Elend; Rainer Evers |
| A system for assigning addresses to a plurality of communication nodes coupled via a power line is disclosed. Each of the plurality of communication nodes includes a current sensor. The plurality of communication nodes includes one master communication node and the master communication node is configured to start an auto-addressing process by asking the each of the plurality of communication nodes to sink a preselect amount of current and measure current, through the current sensor, flowing through the powerline under the each of the plurality of communication nodes. A first communication node in the plurality of communication nodes that does not measure any current flowing under the first communication node is assigned a first address. | ||||||
| 18 | AUTO-ADDRESSING OF COMMUNICATION NODES | US15048354 | 2016-02-19 | US20170242816A1 | 2017-08-24 | Bernd Uwe Gerhard Elend; Rainer Evers |
| A system for assigning addresses to a plurality of communication nodes coupled via a power line is disclosed. Each of the plurality of communication nodes includes a current sensor. The plurality of communication nodes includes one master communication node and the master communication node is configured to start an auto-addressing process by asking the each of the plurality of communication nodes to sink a preselect amount of current and measure current, through the current sensor, flowing through the powerline under the each of the plurality of communication nodes. A first communication node in the plurality of communication nodes that does not measure any current flowing under the first communication node is assigned a first address. | ||||||
| 19 | METHOD, APPARATUS AND COMPUTER PROGRAM FOR TRANSMITTING AND/OR RECEIVING SIGNALS | US14851551 | 2015-09-11 | US20160006591A1 | 2016-01-07 | Heikki HUOMO |
| Methods, apparatus and computer programs for transmitting and/or receiving information are described. Information encoded in a carrier signal comprising a modulation pattern superimposed on a grid frequency at which electricity flows in a synchronous area of an electric power grid, is decoded by measuring, at a receiving device, a characteristic relating to a frequency of electricity flowing in the electric power grid, accessing data indicative of one or more predetermined code patterns and performing a correlation process to determine a correlation between the modulation pattern and one of the one or more predetermined code patterns. The information is decoded on the basis of the determined correlation. This enables information to be easily transmitted within a synchronous area of the electric power grid. | ||||||
| 20 | Validating physical and logical system connectivity of components in a data processing system | US11862593 | 2007-09-27 | US07870374B2 | 2011-01-11 | Brian James Cagno; John Charles Elliott; Kenny Nian Gan Qiu; Donald Scott Smith |
| A mechanism is provided for validating a connection of powered elements within a data processing system. A request for data is issued to a set of powered elements using a set of communication channels. The set of communication channels comprises one or more alternating current power lines. The request is sent as a set of instructions injected onto the communication channels to the set of powered elements. Data received from the set of powered elements using the set of communication channels includes physical connection information for the set of powered elements. A determination is made as to whether each powered element in the set of powered elements is connected in a predetermined configuration. A notification is presented to a user identifying each powered element in the set of powered elements that is not connected in the predetermined configuration. | ||||||
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