Detecting State Estimation Network Model Data Errors
    1.
    发明申请
    Detecting State Estimation Network Model Data Errors 审中-公开
    检测状态估计网络模型数据错误

    公开(公告)号:US20130226538A1

    公开(公告)日:2013-08-29

    申请号:US13700737

    申请日:2011-06-11

    IPC分类号: G06F17/50

    摘要: Methods for detecting network model data errors are disclosed. In some examples, methods for detecting network model data errors may include splitting a network model into a first plurality of portions, executing an algorithm on each of the portions, identifying a portion for which the algorithm is determined to be non-converged, splitting the identified portion into a second plurality of portions, repeating the executing, identifying and splitting the identified portion until a resulting identified portion is smaller than a predefined threshold, and examining the resulting identified portion to identify plausible data errors therein. In some examples, examining the resulting identified portion to identify plausible data errors therein may include executing a modified algorithm, which may include an augmented measurement set, on the identified portion.

    摘要翻译: 公开了网络模型数据错误检测方法。 在一些示例中,用于检测网络模型数据错误的方法可以包括将网络模型分解成第一多个部分,在每个部分上执行算法,识别算法被确定为不收敛的部分, 将所识别的部分分成多个第二部分,重复执行,识别和分割所识别的部分,直到得到的识别部分小于预定义的阈值,并且检查所得到的识别部分以识别其中似乎合理的数据错误。 在一些示例中,检查所得到的识别部分以识别其中可能的数据错误可以包括在所识别的部分上执行修改的算法,其可以包括增强的测量集合。

    Battery case
    2.
    外观设计

    公开(公告)号:USD850373S1

    公开(公告)日:2019-06-04

    申请号:US29675883

    申请日:2019-01-07

    申请人: Yan Zhang

    设计人: Yan Zhang

    Intelligent Pipeline Small Leaks and Thefts Detection Methods and Systems

    公开(公告)号:US20180246004A1

    公开(公告)日:2018-08-30

    申请号:US15443658

    申请日:2017-02-27

    申请人: Yan Zhang

    发明人: Yan Zhang

    IPC分类号: G01M3/24 G01M3/28

    CPC分类号: G01M3/243 G01M3/2815

    摘要: Four (4) methods and systems that utilize these methods are claimed in the present invention for intelligently detecting pipeline small leaks, thefts, and their details.In the Energy Flow Line Method, the measured flow data at both ends of the pipeline will be monitored and analyzed. If flow changes that meet the criteria are identified, a leak or a theft is detected. The energy wave front speed is introduced and the unsteady flow mathematical model of the subject pipeline is utilized to calculate leak details.In the Filtered Pressure Waves Method, the measured pressure data at both ends of the pipeline will be monitored and analyzed. After filtering, only those pressure waves that are not originated at the ends of the pipeline will be selected as candidates. For each computation step, consecutively apply the 2 travelling time windows template 1 and template 2 to those candidates, and process those candidates within each window. Leaks, thefts and their details (except for leaked amount) can be obtained if the detected leak locations meet the criteria, even when the fluid is stagnant for some time.The Enhanced Filtered Pressure Waves Method, as the name suggests, is the enhanced version of the Filtered Pressure Waves Method if the fluid is not stagnant for some time. The essential part of the Energy Flow Line Method is used to extend the function not only to provide the leaked amount, but also to verify the leak and the leak location in order to avoid sending false alarms. The measured flow data at the outlet end of the pipeline is also monitored and the unsteady flow mathematical model of the subject pipeline is utilized. If the fluid is stagnant for some time, the leaked amount will be calculated without measured data to be compared. The estimated leak location will be provided with a search range.In the Mutual Confirmation Method, essential parts of the above 3 methods are utilized to extend the capability and to confirm each finding. If any result that contradicts the solution is identified, find a new one that fits. By providing the solution that is mutually confirmed with 2 sets of leak details, sending false alarms can be avoided. This method is particularly developed to solve some issues in the real time monitoring applications, especially in SCADA environments, to have shorter calculation time. The unsteady flow mathematical model of the subject pipeline is indispensable for this method. If the fluid is stagnant for some time, the leaked amount will be calculated without measured data to be compared. Also the estimated leak location will be provided with a search range.The present invention is suitable for most pipeline applications, including very long pipelines (for instance, over 200 km), existing pipelines (with min or no modification on existing sensor groups), and pipelines that are shut for some time (excluding using the Energy Flow Line Method), and easily used as a cross checking tool to other pipelines and other online leak detection systems. The fluids in pipelines can be gases, liquids, and multi-phase fluids.

    Fair quantized congestion notification (FQCN) to mitigate transport control protocol (TCP) throughput collapse in data center networks
    6.
    发明授权
    Fair quantized congestion notification (FQCN) to mitigate transport control protocol (TCP) throughput collapse in data center networks 有权
    公平的量化拥塞通知(FQCN),以缓解数据中心网络中的传输控制协议(TCP)吞吐量崩溃

    公开(公告)号:US09237107B2

    公开(公告)日:2016-01-12

    申请号:US13297101

    申请日:2011-11-15

    摘要: Technologies are generally described for an enhanced Quantized Congestion Notification (QCN) congestion control approach, referred to as Fair QCN (FQCN) for enhancing fairness of multiple flows sharing link capacity in a high bandwidth, low latency data center network. QCN messages may be fed back to flow sources (e.g., servers) which send packets with a sending rate over their share of the bottleneck link capacity. By enabling the flow sources to regulate their data traffic based on the QCN messages from a congestion control component, the queue length at the bottleneck link may converge to an equilibrium queue length rapidly and TCP throughput performance may be enhanced substantially in a TCP incast circumstance.

    摘要翻译: 技术通常被描述用于增强的量化拥塞通知(QCN)拥塞控制方法,称为公平QCN(FQCN),用于增强在高带宽,低延迟数据中心网络中共享链路容量的多个流的公平性。 QCN消息可以被反馈到以发送速率超过其瓶颈链路容量的份额发送分组的流源(例如,服务器)。 通过使流量源能够根据来自拥塞控制组件的QCN消息来调节其数据流量,瓶颈链路上的队列长度可以快速收敛到平衡队列长度,并且TCP吞吐量性能可能在TCP恶劣情况下显着提高。

    Fiber Optic Coupler Array
    7.
    发明申请
    Fiber Optic Coupler Array 有权
    光纤耦合器阵列

    公开(公告)号:US20150316723A1

    公开(公告)日:2015-11-05

    申请号:US14104230

    申请日:2013-12-12

    摘要: An assembly includes optical fibers each having a waveguide core, a photonic integrated circuit (IC) that includes in-plane waveguides corresponding to the optical fibers, and a substrate bonded to the photonic IC with grooves that support the optical fibers. The substrate and photonic IC can have metal bumps that cooperate to provide mechanical bonding and electrical connections between the substrate and photonic IC. Portions of the optical fibers supported by the substrate grooves can define flat surfaces spaced from the optical fiber cores. The photonic IC can include passive waveguide structures with a first coupling section that interfaces to the flat surface of a corresponding optical fiber (for evanescent coupling of optical signals) and a second coupling section that interfaces to a corresponding in-plane waveguide (for adiabatic spot-size conversion of optical signals).

    摘要翻译: 一种组件包括各自具有波导芯的光纤,包括对应于光纤的面内波导的光子集成电路(IC)以及与支撑光纤的凹槽连接到光子IC的基板。 衬底和光子IC可以具有金属凸块,其配合以在衬底和光子IC之间提供机械结合和电连接。 由基板槽支撑的光纤的一部分可以限定与光纤芯间隔开的平坦表面。 光子IC可以包括无源波导结构,其具有与对应光纤的平坦表面(用于光信号的渐逝耦合)相接合的第一耦合部分和与对应的平面波导(用于绝热光点)相连接的第二耦合部分 光信号的尺寸转换)。

    System and method for transmission control protocol slow-start
    8.
    发明授权
    System and method for transmission control protocol slow-start 有权
    传输控制协议的启动系统和方法

    公开(公告)号:US09178789B2

    公开(公告)日:2015-11-03

    申请号:US13340354

    申请日:2011-12-29

    摘要: An embodiment of a system and method that uses inline measurements to probe available bandwidth for a transmission control protocol, and adaptively sets a slow-start threshold according to the available bandwidth. The method includes initializing a congestion window “cwnd,” sending cwnd packets, estimating an available bandwidth for the cwnd packets. The congestion window cwnd is set to a higher number, and the higher number of further packets is sent if the available bandwidth is greater than a first threshold level. The available bandwidth is re-estimated for the higher number of the further packets, and a soft start threshold “ssthresh” is set to the re-estimated available bandwidth. A statistical measure is calculated for the re-estimated available bandwidth, and the congestion window cwnd is set equal to ssthresh if a ratio of the statistical measure to the re-estimated available bandwidth is less than a second threshold level.

    摘要翻译: 使用在线测量来探测传输控制协议的可用带宽的系统和方法的实施例,并且根据可用带宽自适应地设置慢启动阈值。 该方法包括初始化拥塞窗口“cwnd”,发送cwnd数据包,估计cwnd数据包的可用带宽。 拥塞窗口cwnd被设置为更高的数量,并且如果可用带宽大于第一阈值水平,则发送更多数量的另外的分组。 对于更多数量的另外的分组重新估计可用带宽,并且将软启动阈值“ssthresh”设置为重新估计的可用带宽。 对于重新估计的可用带宽计算统计度量,并且如果统计度量与重新估计的可用带宽的比率小于第二阈值水平,则将拥塞窗口cwnd设置为等于ssthresh。

    Measuring moisture in a CNT based fluid or paste
    9.
    发明授权
    Measuring moisture in a CNT based fluid or paste 有权
    测量基于CNT的流体或糊状物中的水分

    公开(公告)号:US09087626B2

    公开(公告)日:2015-07-21

    申请号:US13285243

    申请日:2011-10-31

    摘要: The present disclosure relates to pastes and methods of making a moisture determination of the paste during manufacture; optionally, the pastes comprise carbon nanotubes. The instant invention provides a simple and repeatable measurement protocol to determine the moisture or water content in paste comprising a non-aqueous solvent and a solid component, optionally, carbon nanotubes, CNT, and subsequently provide a method to monitor and control moisture level during electrode preparation and battery manufacturing.

    摘要翻译: 本公开涉及在制造期间进行糊状物的水分测定的糊剂和方法; 任选地,糊状物包含碳纳米管。 本发明提供了一种简单且可重复的测量方案,以确定包含非水溶剂和固体组分(任选地,碳纳米管,CNT)的糊状物中的水分或水分含量,随后提供一种监测和控制电极中的水分含量的方法 准备和电池制造。