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
    • 3. 发明授权
    • Intelligent routing
    • 智能路由
    • US06687366B1
    • 2004-02-03
    • US09355484
    • 1999-11-05
    • Lars JonssonGöran Pettersson
    • Lars JonssonGöran Pettersson
    • H04M700
    • H04Q3/0029H04Q2213/13541H04Q2213/13547
    • The present invention relates to an arrangement, a network and methods for identifying the relevant SDP for a question from an SCP in a telecommunication network with a large amount of subscribers and handling and administration of a large amount of subscribers by introducing a function for intelligent routing. The intelligent routing between SCP and SDP can be handled by a node standing by itself in the network or as a part-function in an already existing node, for example an SCP. When a new subscriber shall be stored in an SDP subscriber data is transferred from the service administration to a master IRF (Intelligent Routing Function). The IRF comprises a function for determining which SDP that shall store the subscriber data and the IRF thereafter transfer the subscriber data to the SDP. The IRF also stores this information. The information is also transferred to the other IRFs. When an SCP gets a call from an SSP, the SCP contacts an IRF which contacts an SDP.
    • 本发明涉及一种用于通过具有大量用户的电信网络中的SCP识别问题的相关SDP的方法,以及通过引入用于智能路由的功能来处理和管理大量用户的方法 。 SCP和SDP之间的智能路由可以由一个站在网络中的节点或已经存在的节点(例如SCP)中的部分功能来处理。 当新的用户存储在SDP用户中时,数据从服务管理传输到主IRF(智能路由功能)。 IRF包括用于确定将存储用户数据的SDP的功能,然后IRF将用户数据传送到SDP。 IRF还存储这些信息。 信息也转交给其他IRF。 当一个SCP从一个SSP呼叫时,SCP会联系一个与SDP联系的IRF。
    • 4. 发明授权
    • Device and method for measuring birefringence in an optical data carrier
    • 用于测量光学数据载体中的双折射的装置和方法
    • US06023332A
    • 2000-02-08
    • US180261
    • 1999-01-14
    • Hakan BergstromUlf WilhelmsonLars Jonsson
    • Hakan BergstromUlf WilhelmsonLars Jonsson
    • G11B7/26G01N21/23G01N21/88G01N21/95G01J4/00
    • G01N21/23G11B7/26
    • A device for measuring birefringence in an optical data carrier has a laser light source with a polarization modifier, a beamsplitter, a polarizer, a photodetector, and a controller operatively connected to the photodetector. The laser light source illuminates various spots on the optical data carrier by means of a laser beam. The photodetector receives a reflected laser beam, converts it into an electric signal and supplies this signal to the controller, which determines a value for the birefringence in the illuminated spot on the optical data carrier. Furthermore, the device is provided with a transparent reference element with known birefringence properties, a mirror, and for directing the laser beam towards the reference element in a first calibration position; directly towards the mirror in a second calibration position; and towards the optical data carrier during non-calibration time. In the first calibration position the controller calculates a first calibration value from the signal received from the photodetector, said first calibration value corresponding to a given birefringence in the optical data carrier, and in the second calibration position the controller calculates a second calibration value, corresponding to a situation essentially without any birefringence at all in the optical data carrier. These calibration values are used for determining the birefringence in a given spot on the optical data carrier.
    • 用于测量光数据载体中的双折射的装置具有带有偏振调节器的激光光源,分束器,偏振器,光电检测器和可操作地连接到光电检测器的控制器。 激光光源通过激光束照射光学数据载体上的各个点。 光电检测器接收反射的激光束,将其转换为电信号,并将该信号提供给控制器,该控制器确定光数据载体上的照明光点中的双折射值。 此外,该装置设置有具有已知双折射性质的透明参考元件,反射镜,并且用于在第一校准位置将激光束引向参考元件; 在第二校准位置直接朝向镜子; 并且在非校准时间期间朝向光学数据载体。 在第一校准位置,控制器根据从光电检测器接收的信号计算第一校准值,所述第一校准值对应于光数据载体中给定的双折射,并且在第二校准位置,控制器计算第二校准值,对应于 在光学数据载体中基本上没有任何双折射的情况。 这些校准值用于确定光学数据载体上的给定光斑中的双折射。
    • 7. 发明申请
    • Method and device for controlling a roll gap
    • 用于控制辊间隙的方法和装置
    • US20090277241A1
    • 2009-11-12
    • US12308961
    • 2007-05-21
    • Lars Jonsson
    • Lars Jonsson
    • B21B37/16
    • B21B37/28B21B37/16B21B37/58B21B37/62B21B38/04B21B2263/02B21B2271/02
    • The invention relates to a method and a device for controlling a roll gap when rolling a strip (1) in a rolling mill including at least two rolls (3a-b,4a-b), and at least two roll gap actuators (6,7) that independently control the size of the roll gap. The device is adapted to receive information on the amount of wedge shape (POSactOS,POSactDS) in the strip thickness profile across the strip width, and to control said actuators, based on said information on the amount of wedge shape in the strip thickness profile, such that the relative reduction of the strip on both sides of the rolling mill become essentially the same.
    • 本发明涉及一种在包括至少两个辊(3a-b,4a-b)的轧机中轧制带材(1)时控制轧辊间隙的方法和装置,以及至少两个轧辊间隙致动器(6, 7)独立地控制辊隙的尺寸。 该装置适于接收关于条带宽度上的条带厚度分布中的楔形形状量(POSactOS,POSactDS)的信息,并且基于关于带材厚度分布中的楔形形状量的所述信息来控制所述致动器, 使得轧机两侧的带材的相对减少变得基本相同。
    • 10. 发明授权
    • Method and device for controlling flatness
    • US06513358B2
    • 2003-02-04
    • US09742307
    • 2000-12-22
    • Lars JonssonKlaus Meyer
    • Lars JonssonKlaus Meyer
    • B21B3728
    • B21B37/28B21B2001/228
    • A method for controlling flatness of a strip (1) of rolled material rolled to a first flatness target and coiled and that is subsequently uncoiled, and a system which employs the method. Measurements of the flatness of the strip (1) during rolling are compared to both the first flatness target and to a second flatness target, a Mill Flatness Target 2. A flatness target for each of one or more subsequent processes, a Post Rolling Flatness Target (PRFT) and a measured flatness error is used to adapt a control signal for a mill stand (5) to control and regulate the flatness of subsequent production of rolled material of the same specification. The adaption may be made using different statistical techniques including fuzzy logic and neuro-fuzzy logic control methods. In the preferred embodiment, flatness measurements after decoiling are also fed forward to at least one subsequent process 12 and used to adapt control signals to regulate flatness of the current strip in the subsequent process 12. The advantages include that the rolled strip is more flat after decoiling, and that flatness control over the strip in a subsequent process is more accurate.