子分类:
| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 21 | 分子通信系统 | CN200680000891.4 | 2006-03-03 | CN101031501B | 2010-08-18 | 桧山聪; 森谷优贵; 须田达也 |
| 本发明提供一种分子通信系统,该系统可将编码有规定信息的信息分子控制性良好地传送到目的地。本发明的分子通信系统包括:送出编码有规定信息的信息分子的分子发送机;接收上述信息分子的分子接收机;以及连接上述分子发送机和分子接收机之间的分子传输路径,上述分子传输路径包含由高分子材料形成的传送路径和沿该传送路径在规定的方向上巡回的载体分子,从上述分子发送机送出的信息分子搭载于上述载体分子,输送到上述分子接收机。 | ||||||
| 22 | 分子通信系统及分子通信方法 | CN200710107734.X | 2007-04-28 | CN101064569A | 2007-10-31 | 森谷优贵; 桧山聪; 须田达也 |
| 本发明提供分子通信系统及分子通信方法。实现在分子发送机侧将信息分子封入分子胶囊,在分子接收机侧将信息分子从分子胶囊取出并取入分子接收机内部的结构。分子通信系统包含:发送编码有规定信息的信息分子的分子发送机;接收信息分子的分子接收机;将信息分子从分子发送机传送到分子接收机的分子传输路径;和将从分子发送机传送到分子接收机的信息分子内包的分子胶囊。分子发送机、分子接收机及分子胶囊的表面由脂质双层膜构成,分子通信系统还包含:使第一化学物质作用于分子发送机、或分子发送机和分子胶囊,将信息分子封入分子胶囊内的单元;和使第二化学物质作用于分子接收机和分子胶囊,从分子胶囊取出信息分子并取入分子接收机内的单元。 | ||||||
| 23 | 在使用空间分集的无线通信网络内将天线连接至基站的网络和方法 | CN02813661.6 | 2002-06-07 | CN1290358C | 2006-12-13 | 桑贾伊·马尼; 大卫·库特雷尔 |
| 一种网络,其具有多个经由所述网络RF或光耦合到多个基站(14)的天线(12)。所述基站被配置成提供蜂窝传输。至少一部分所述基站在公共位置(34)处,至少一部分所述天线在地理上是分散的。多个链路(16)耦合所述天线和所述基站。至少一个链路在至少一部分所述基站与至少一部分所述天线之间提供多个传输路径。 | ||||||
| 24 | 光传输媒体 | CN03804519.2 | 2003-05-14 | CN1639626A | 2005-07-13 | 榊原阳一; 德本圆; 阿知波洋次; 片浦弘道; 田中佑一; 马克·K·杰布伦斯基 |
| 把碳纳米管的非线性光学特征应用于光通信领域。在非线性光传输媒体中引进有光学非线性特征的碳纳米管,把获得的光传输媒体(12),组装在通常的光传输媒体(14a,14b)之间,并用于与光环行器(16)结合,据此得到的产品可用作光学保险丝(断路器),该光学保险丝传输正常的信号光A,但阻断意外产生的反常强度光的传输。 | ||||||
| 25 | 通信装置、通信设备、电路板安装方法和触觉传感器 | CN02820095.0 | 2002-10-09 | CN1568590A | 2005-01-19 | 篠田裕之; 箱崎光弘; 王欣雨; 浅村直也 |
| 这种通信装置(100)具备分散配置的多个通信元件(200)。各通信元件(200)具有只与周边配置的其它通信元件进行通信的功能。通信距离设定成能与配置在周边的其它通信元件进行局部通信的程度,并且通过利用这种局部通信在通信元件之间依次传递信号,能够使信号传递到作为目的的通信元件。多个通信元件根据管理功能分等级,在各等级中设定路由数据,以此能够高效率地将信号传递到最终目的地。 | ||||||
| 26 | 在使用空间分集的无线通信网络内将天线连接至基站的网络和方法 | CN02813661.6 | 2002-06-07 | CN1524390A | 2004-08-25 | 桑贾伊·马尼; 大卫·库特雷尔 |
| 一种网络,其具有多个经由所述网络RF或光耦合到多个基站(14)的天线(12)。所述基站被配置成提供蜂窝传输。至少一部分所述基站在公共位置(34)处,至少一部分所述天线在地理上是分散的。多个链路(16)耦合所述天线和所述基站。至少一个链路在至少一部分所述基站与至少一部分所述天线之间提供多个传输路径。 | ||||||
| 27 | 信号传输设备和方法 | CN02800459.0 | 2002-02-15 | CN1457567A | 2003-11-19 | 松下伸行; 田岛茂; 绫冢佑二; 长谷川踏太; 唐泽英了; 埃杜阿多·A·西亚马雷拉; 暦本纯一 |
| 一种信号传输设备,能够在倾倒液体时交换信息。发送器方容器(20)的容器体(201)拥有导电液体(402)。接收器方容器(21)的容器体(211)具有与其连接的数据接收确认显示器(306)。容器体(201)和容器体(211)通过液体(402)以预定的阻抗进行电气连接。因为数字数据是经大约10MHz的载波调制的,所以产生了电磁场。特别地,由于电磁近场而产生了返回线(404),从而使得从发送器方容器(20)到接收器方容器(21)的通信成为可能。 | ||||||
| 28 | 传输控制信号和/或传感信号的方法及装置 | CN00802560.6 | 2000-08-30 | CN1122954C | 2003-10-01 | D·斯塔尼策克 |
| 建议一种在电子控制及/或数据接收设备(21)与气动设备(10)之间传输控制信号和/或传感信号的装置,所述两个设备之间通过由柔性塑料材料组成的气动线路(13)而相互连接起来。为了借助声信号、微波或线路(13)的气体介质内的压力变化来传输信号,所述的控制及/或数据接收设备(21)和气动设备(10)设有至少一个用于把电信号变换成声信号或压力变化的第一转换器(23)和至少一个用于把所述声信号或压力变化变换成电信号的第二转换器(24)。由此可以取消传输数据的电气线路,并通过所述气动线路(13)内的气体介质来实现数据传输。 | ||||||
| 29 | 向量电势产生方法、能量传播系统、以及通信系统 | CN98115543.X | 1998-07-01 | CN1204903A | 1999-01-13 | 山下治; 川上诚; 西乡恒和 |
| 一种向量电势产生方法、能量传播系统、以及通信系统,使用向量电势来传播能量,并把向量电势作为信号传播媒体进行通信。发射装置具有在两个端面设置了电极的介质,当根据传播信号而被调制的交流电压加到这些电极上时,介质就产生向量电势。把所产生的向量电势经无线线路发送到接收装置。接收装置具有磁传感器,利用磁传感器检测出由传播来的向量电势所产生的磁场,并从该检测结果得到传播信号。 | ||||||
| 30 | APPARATUS AND METHOD FOR TRANSMITTING DATA IN AN AQUEOUS MEDIUM | PCT/US2004033557 | 2004-10-12 | WO2005089089A3 | 2007-02-01 | LACOVARA PHILIP; RODRIGUEZ ROGELIO; CHEAV LAVIRBOTH |
| An apparatus and method for transmitting data in an aqueous medium is provided. The apparatus, comprising a transmitter having one or a plurality of LED transmitting components, which is configured, when immersed in an aqueous medium, to transmit light in a blue or green light wavelength, and a receiver configured, when immersed in the aqueous medium, to receive light in the wavelength of the transmitter. | ||||||
| 31 | CAPACITIVELY COUPLED E-FIELD COMMUNICATIONS SYSTEM | PCT/US0142936 | 2001-11-13 | WO0246859A3 | 2002-11-07 | MACY ROBERT A |
| A low-power, short-range communications system (Figure 1) is disclosed. The communications system comprises a transmitter that is operative to generate a high impedance signal and a receiver that is operative to detect the high impedance signal. In this respect, the transmitter and the receiver (Figure 1, elements 12 and 14) are capacitively coupled by the high impedance electric field generated in response to the high impedance signal. Accordingly, information from the transmitter to the receiver is sent via the high impedance electric field. In accordance with the present invention, the transmitter is configured to generate the high impedance signal with a frequency in the range from about 20 KHz to 10 MHz. Similarly, the voltage of the high impedance signal is from about 1 Vrms to 300 Vrms. | ||||||
| 32 | CABLE TRACKING BY ELECTROMAGNETIC EMISSION | US15823879 | 2017-11-28 | US20190165834A1 | 2019-05-30 | Petra Sabine Buehrer; Florian Graf; Thorsten Muehge; Tim U. Scheideler; Raphael Waltert |
| A method and system for tracking a course of a cable using electromagnetic waves. A first transceiver sends to a second transceiver a first signal wirelessly in a linear line. The second transceiver sends back to the first transceiver the first signal in the linear line. A first distance between the first transceiver and the second transceiver is determined by determining a total transmission time for a first wireless signal travelling from the first transceiver to the second transceiver and back to the first transceiver. A second signal, aligned with the first signal, is transmitted from the first transceiver into the cable. The second transceiver receives the second signal wirelessly from the cable. A second distance between the first transceiver and the second transceiver is determined by comparing a phase difference between the first signal received by the second transmitter and the second signal received by the second transmitter. | ||||||
| 33 | COMMUNICATION SYSTEM NETWORK | US15776890 | 2016-11-18 | US20180337737A1 | 2018-11-22 | Brendan Peter Hyland |
| A wireless communication system network for use with at least one underwater structure, the said communication system network comprising a plurality of communications units disposed around the underwater structure, each communication unit comprising a wireless transmitter, and a wireless receiver, wherein each communication unit is arranged with communicable range of at least three other communication units to form a mesh of communication units operable to work as a network and each communication unit is operable to perform as a master communication unit to at least one of transmit and receive data from the communication system network. The network may extend across multiple static or mobile underwater structures and may be a dynamic network. | ||||||
| 34 | MOBILE TERMINAL AND METHOD OF CONTROLLING SAME | US15766623 | 2016-09-27 | US20180316442A1 | 2018-11-01 | Cheegoog KIM; Mansoo SIN; Hyunghoon OH; Jeunguk HA |
| A mobile terminal and a method for controlling the mobile terminal are disclosed. A mobile terminal according to an embodiment of the present invention, together with an external device separated therefrom, may measure body composition by using human body medium communication. The mobile terminal and the external device have two electrodes that contact areas of a user's body. The mobile terminal outputs a test signal through a first body area contacting a first electrode, and transmits the test signal to the external device through the user's body. The external device generates a feedback signal corresponding to the test signal. The mobile terminal detects a second signal which is the feedback signal that passes through the body and is transmitted through a second electrode. The mobile terminal uses the difference between a reference signal corresponding to the test signal and the second signal to calculate the body composition of the user. | ||||||
| 35 | TRANSMISSION APPARATUS, TRANSMISSION METHOD, AND TRANSMISSION SYSTEM | US15765028 | 2016-06-22 | US20180287716A1 | 2018-10-04 | Takanori WASHIRO |
| A transmission apparatus (10) includes a communication device (30), comprising two input/output terminals (20a, 20b), and a terminal line (40) connected to the first input/output terminal (20a) and having an electrical length of substantially 90°. By the second input/output terminal (20b) electrically coupling with a transmission medium (50) comprising a conductor or a dielectric, a high frequency signal or electric power is transmitted to another transmission apparatus coupled electrically to the transmission medium (50). | ||||||
| 36 | Communications device | US15090933 | 2016-04-05 | US09906272B2 | 2018-02-27 | Anthony Kerselaers |
| One example discloses a communications device, including: a bio-antenna conducting surface configured to receive a set of bio-antenna modulated broadcast signals; wherein the conducting surface is configured to receive the set of bio-antenna modulated broadcast signals through a capacitively coupling; a broadcast receiver coupled to the conducting surface; and wherein the conducting surface is configured to pass the broadcast signals to the broadcast receiver. | ||||||
| 37 | TECHNIQUES FOR SECURING BODY-BASED COMMUNICATIONS | US15463332 | 2017-03-20 | US20180019827A1 | 2018-01-18 | Nicholas D. TRIANTAFILLOU; Todd A. KEAFFABER; Shai Skavas KAVAS |
| Various embodiments are generally directed to techniques to form and maintain secure communications among two or more body-carried devices disposed in close proximity to the body of a person to form a body area network (BAN). An apparatus to establish secure communications includes a processor component; a signal component for execution by the processor component to compare a signal characteristic of a security test signal to a known signal characteristic of the security test signal to derive a bioelectric characteristic, the security test signal received via a tissue; and a bioelectric component for execution by the processor component to determine whether to allow transmission of data through the tissue based on the bioelectric characteristic. Other embodiments are described and claimed. | ||||||
| 38 | Electromagnetic wave transmission sheet and electromagnetic wave transmission device | US14375655 | 2012-12-20 | US09853501B2 | 2017-12-26 | Wataru Hattori |
| An edge portion which defines a planar shape has two long end sides (108a, 108b) which extend in parallel to each other, and two short end sides (107, 109) which have parallel portions extending in parallel to each other. The two long end sides and the two short end sides are reflection terminals. The parallel portion of the first short end side (107) includes a first portion (107a) and a second portion (107b). The positions of the antinodes of a first standing wave formed by a traveling wave directed toward the first portion (107a) and a reflected wave of the traveling wave and a second standing wave formed by a traveling wave directed toward the second portion (107b) and a reflected wave of the traveling wave in a direction substantially parallel to the long end sides (108a, 108b) are deviated by ¼ of the wavelength of an electromagnetic wave propagating through an electromagnetic wave transmission sheet. | ||||||
| 39 | COMMUNICATIONS DEVICE | US15090933 | 2016-04-05 | US20170288731A1 | 2017-10-05 | Anthony Kerselaers |
| One example discloses a communications device, including: a bio-antenna conducting surface configured to receive a set of bio-antenna modulated broadcast signals; wherein the conducting surface is configured to receive the set of bio-antenna modulated broadcast signals through a capacitively coupling; a broadcast receiver coupled to the conducting surface; and wherein the conducting surface is configured to pass the broadcast signals to the broadcast receiver. | ||||||
| 40 | COMMUNICATION DEVICE AND BIOLOGICAL SIGNAL MONITORING DEVICE | US15391003 | 2016-12-27 | US20170111124A1 | 2017-04-20 | Takafumi OHISHI; Kazuhiro INOUE |
| A communication device includes a ground unit, a dielectric plate, a communication circuit, a conductor, and a capacitance element. The ground unit has a reference potential applied to the ground unit. The dielectric plate is provided on the ground unit. The communication circuit is provided on the dielectric plate and performs a transmission and a reception of a signal. The conductor is connected to the communication circuit. An end of the capacitance element is connected to the conductor. An another end of the capacitance element is connected to the ground unit. A capacitance of the capacitance element is smaller than a capacitance formed between the conductor and the ground unit. The capacitance of the capacitance element is bigger than a capacitance formed between the conductor and the ground unit being caused by a human body touching or approximating to the conductor. | ||||||
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