会员体验
专利管家(专利管理)
工作空间(专利管理)
风险监控(情报监控)
数据分析(专利分析)
侵权分析(诉讼无效)
联系我们
交流群
官方交流:
QQ群: 891211   
微信请扫码    >>>
现在联系顾问~
热词
    • 1. 发明授权
    • Transponder-based beacon transmitter for see and avoid of unmanned aerial vehicles
    • 基于发射机的信标发射机,用于查看和避免无人机
    • US07969346B2
    • 2011-06-28
    • US12246644
    • 2008-10-07
    • Michael R. FranceschiniDavid W. MeyersKelly P. Muldoon
    • Michael R. FranceschiniDavid W. MeyersKelly P. Muldoon
    • G08G5/04G01S13/00G01S13/74
    • G01S13/782G01S13/765G01S13/9303H04W4/046
    • A transponder-based beacon transmitter system in an unmanned aerial vehicle is provided. The transponder-based beacon transmitter system comprises a global positioning system interface communicatively coupled to receive position information indicative of a current location of the unmanned aerial vehicle, a message formatter communicatively coupled to the global positioning system interface, and a transponder-based beacon transmitter. The message formatter formats vehicle identification of the unmanned aerial vehicle and the position information indicative of the current location of the unmanned aerial vehicle into an automatic dependent surveillance broadcast mode-select squitter message. The message formatter operates in one of a military mode, a National Airspace System mode, and a combined military/National Airspace System mode. The transponder-based beacon transmitter transmits the automatic dependent surveillance broadcast mode-select squitter messages from the unmanned aerial vehicle. Receivers in the vicinity of the unmanned aerial vehicle receive unsolicited vehicle identification and location of the unmanned aerial vehicle.
    • 提供了一种无人机中的基于应答器的信标发射机系统。 基于应答器的信标发射机系统包括通信地耦合以接收指示无人驾驶飞行器的当前位置的位置信息的全球定位系统接口,通信地耦合到全球定位系统接口的消息格式化器,以及基于应答器的信标发射机。 消息格式化器将无人机的车辆识别和指示无人驾驶飞行器的当前位置的位置信息形成为自动依赖监视广播模式选择脉冲消息。 信息格式化器以军事模式,国家空域系统模式和军事/国家空域系统组合模式运行。 基于应答器的信标发射机从无人驾驶飞行器发送自动相关监视广播模式选择脉冲信号。 无人驾驶飞机附近的接收器接收无人驾驶飞行器的未经请求的车辆识别和位置。
    • 3. 发明授权
    • Method and device for storing and distributing information in an RFID tag
    • 用于在RFID标签中存储和分发信息的方法和装置
    • US07573370B2
    • 2009-08-11
    • US10235899
    • 2002-09-05
    • Robert C. BeckerDavid W. Meyers
    • Robert C. BeckerDavid W. Meyers
    • H04Q5/22
    • G06K19/0717G06K19/0723G06K19/07769
    • An RFID tag has a memory, an RF transceiver that supports long range RF communications with a long range reader, and an interface that supports short range communications with a short range reader over a secure link. The RF transceiver can be used to transmit an ID stored in the memory of the tag to a long range reader, and the interface can be used to transmit sensitive history information to a short range reader over the secure link. The ID uniquely identifies an article to which the tag is attached, and the history information provides environmental data, and/or maintenance data, and/or shipping data, and/or inventory data, and/or production data, etc. about the article.
    • RFID标签具有存储器,RF收发器,其支持与远程读取器的远程RF通信,以及支持通过安全链路与短距离读取器进行短距离通信的接口。 RF收发器可以用于将存储在标签的存储器中的ID发送到远程读取器,并且该接口可以用于通过安全链路将敏感历史信息发送到短距离读取器。 ID唯一地标识标签附加的文章,并且历史信息提供关于文章的环境数据,/或维护数据,和/或运送数据,和/或库存数据和/或生产数据等 。
    • 7. 发明授权
    • Distributed stand-off ID verification compatible with multiple face recognition systems (FRS)
    • 与多个人脸识别系统(FRS)兼容的分布式对立身份验证
    • US07817013B2
    • 2010-10-19
    • US11290524
    • 2005-12-01
    • Michael E. BazakosDavid W. MeyersVassilios Morellas
    • Michael E. BazakosDavid W. MeyersVassilios Morellas
    • B60R25/00
    • G06K9/00228G06K9/6289G07B15/06G07C9/00087
    • A system for providing stand-off biometric verification of a driver of a vehicle while the vehicle is moving and/or a person on foot at a control gate, including an RFID vehicle tag reader, an RFID personal smart card reader and a facial detection and recognition (verification) system. The driver carries a RFID personal smart card that stores personal information of the driver and a face template of the driver. The vehicle carries a RFID vehicle tag that stores information regarding the vehicle. When the vehicle approaches the control gate, the RFID vehicle tag reader reads data from the RFID vehicle tag and the RFID personal tag reader reads data from the RFID personal smart card. The facial detection and verification system scans and reads a facial image for the driver. All the data and facial images detected by the readers are sent to a local computer at the control gate for further processing (final face verification). The local computer at the control gate decodes and retrieves the face template from the data read from the RFID personal smart card.
    • 一种用于在车辆移动时提供车辆驾驶员的离线生物特征验证和/或在控制门上的人的行动的系统,包括RFID车辆标签读取器,RFID个人智能卡读取器和面部检测, 识别(验证)系统。 驾驶员携带RFID个人智能卡,其存储驾驶员的个人信息和驾驶员的面部模板。 车辆载有存储关于车辆的信息的RFID车辆标签。 当车辆接近控制门时,RFID车辆标签读取器从RFID车辆标签读取数据,并且RFID个人标签读取器从RFID个人智能卡读取数据。 面部检测和验证系统扫描并读取驾驶员的面部图像。 读取器检测到的所有数据和面部图像都将发送到控制门上的本地计算机进行进一步处理(最终面部验证)。 控制门上的本地计算机从RFID个人智能卡读取的数据解码并检索面部模板。
    • 9. 发明申请
    • TRANSPONDER-BASED BEACON TRANSMITTER FOR SEE AND AVOID OF UNMANNED AERIAL VEHICLES
    • 基于TRANSPONDER的信号发射机,用于查看和避免无人驾驶的航空器
    • US20100085236A1
    • 2010-04-08
    • US12246644
    • 2008-10-07
    • Michael R. FranceschiniDavid W. MeyersKelly P. Muldoon
    • Michael R. FranceschiniDavid W. MeyersKelly P. Muldoon
    • G01S13/93
    • G01S13/782G01S13/765G01S13/9303H04W4/046
    • A transponder-based beacon transmitter system in an unmanned aerial vehicle is provided. The transponder-based beacon transmitter system comprises a global positioning system interface communicatively coupled to receive position information indicative of a current location of the unmanned aerial vehicle, a message formatter communicatively coupled to the global positioning system interface, and a transponder-based beacon transmitter. The message formatter formats vehicle identification of the unmanned aerial vehicle and the position information indicative of the current location of the unmanned aerial vehicle into an automatic dependent surveillance broadcast mode-select squitter message. The message formatter operates in one of a military mode, a National Airspace System mode, and a combined military/National Airspace System mode. The transponder-based beacon transmitter transmits the automatic dependent surveillance broadcast mode-select squitter messages from the unmanned aerial vehicle. Receivers in the vicinity of the unmanned aerial vehicle receive unsolicited vehicle identification and location of the unmanned aerial vehicle.
    • 提供了一种无人机中的基于应答器的信标发射机系统。 基于应答器的信标发射机系统包括通信地耦合以接收指示无人驾驶飞行器的当前位置的位置信息的全球定位系统接口,通信地耦合到全球定位系统接口的消息格式化器,以及基于应答器的信标发射机。 消息格式化器将无人机的车辆识别和指示无人驾驶飞行器的当前位置的位置信息形成为自动依赖监视广播模式选择脉冲消息。 信息格式化器以军事模式,国家空域系统模式和军事/国家空域系统组合模式运行。 基于应答器的信标发射机从无人驾驶飞行器发送自动相关监视广播模式选择脉冲信号。 无人驾驶飞机附近的接收器接收无人驾驶飞行器的未经请求的车辆识别和位置。
    • 10. 发明申请
    • RADAR SYSTEM FOR OBSTACLE AVOIDANCE
    • 雷达系统避免障碍
    • US20100085235A1
    • 2010-04-08
    • US12245334
    • 2008-10-03
    • David W. MeyersLong BuiYi-Chi Shih
    • David W. MeyersLong BuiYi-Chi Shih
    • G01S13/93
    • G01S13/4454G01S13/9303G01S13/931H01Q25/02
    • A radar system comprises a transmitter antenna configured to transmit a radio frequency (RF) signal, a first receiver antenna, and a second receiver antenna. Each of the first and second receiver antennas are configured to receive a reflection of the RF signal, wherein the first and second receiver antennas are synchronized and separated by a vertical distance. The radar system also comprises radar processing circuitry configured to control transmission of the RF signal from the transmitter antenna and to determine an elevation of an object reflecting the RF signal based on the phase difference between the reflected RF signal received by the first receiver antenna and the reflected RF signal received by the second receiver antenna; wherein the transmit antenna, first receiver antenna, and second receiver antenna are operable to continuously rotate 360 degrees along an azimuth angle without rotating along an elevation angle.
    • 雷达系统包括被配置为发送射频(RF)信号的发射机天线,第一接收机天线和第二接收机天线。 第一和第二接收机天线中的每一个被配置为接收RF信号的反射,其中第一和第二接收机天线被同步并且被垂直距离分开。 雷达系统还包括雷达处理电路,该雷达处理电路被配置为控制来自发射机天线的RF信号的传输,并且基于由第一接收机天线接收的反射的RF信号与第一接收机天线之间的相位差来确定反射RF信号的物体的高度 由第二接收机天线接收的反射RF信号; 其中所述发射天线,第一接收机天线和第二接收机天线可操作以沿着方位角连续地旋转360度而不沿着仰角旋转。