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    • 1. 发明申请
    • AD STALKING DEFENSE
    • US20110288934A1
    • 2011-11-24
    • US12786231
    • 2010-05-24
    • John R. DouceurJacob R. LorchJames MickensThomas MoscibrodaDavid Levin
    • John R. DouceurJacob R. LorchJames MickensThomas MoscibrodaDavid Levin
    • G06Q30/00G06F17/30G06F3/048
    • G06Q30/0241G06Q30/0251G06Q30/0255G06Q30/0269
    • Techniques are described to mitigate ad stalking and other user concerns resulting from user-targeted advertising. A user may be informed of advertising information by a process in which an advertising server receives a request for an ad. The request may have been generated in response to a user request for a landing web page. An ad may be selected based on user information available to the advertising server, where the user information is associated with the user and describes behavior and/or attributes and/or preferences associated with the user. Text about how the ad was selected may be incorporated into the ad. Such text may describe the user information used to select the ad. The selection-disclosing text may be incorporated in the ad in a form that is displayable to the user by a browser. The ad may then be transmitted for display in the landing web page.
    • 描述技术来减轻由用户定向广告产生的广告跟踪和其他用户关注的问题。 可以通过广告服务器接收到广告请求的处理来向用户通知广告信息。 请求可能是响应于用户对登陆网页的请求而产生的。 可以基于广告服务器可用的用户信息来选择广告,其中用户信息与用户相关联并且描述与用户相关联的行为和/或属性和/或偏好。 关于广告如何选择的文字可能会纳入广告。 这样的文本可以描述用于选择广告的用户信息。 选择公开的文本可以以浏览器向用户显示的形式并入广告中。 该广告然后可以被传输以在着陆网页中显示。
    • 2. 发明申请
    • Trusted Hardware Component for Distributed Systems
    • 分布式系统的可信硬件组件
    • US20100318786A1
    • 2010-12-16
    • US12483338
    • 2009-06-12
    • John R. DouceurDavid M. LevinJacob R. LorchThomas Moscibroda
    • John R. DouceurDavid M. LevinJacob R. LorchThomas Moscibroda
    • H04L29/06
    • H04L63/123H04L9/3247H04L29/06H04L2209/127
    • Techniques for utilizing trusted hardware components for mitigating the effects of equivocation amongst participant computing devices of a distributed system are described herein. For instance, a distributed system employing a byzantine-fault-resilient protocol—that is, a protocol intended to mitigate (e.g., tolerate, detect, isolate, etc.) the effects of byzantine faults—may employ the techniques. To do so, the techniques may utilize a trusted hardware component comprising a non-decreasing counter and a key. This hardware component may be “trusted” in that the respective participant computing device cannot modify or observe the contents of the component in any manner other than according to the prescribed procedures, as described herein. Furthermore, the trusted hardware component may couple to the participant computing device in any suitable manner, such as via a universal serial bus (USB) connection or the like.
    • 在此描述了利用可信硬件组件来减轻分布式系统的参与者计算设备之间的混淆效应的技术。 例如,采用拜占庭故障弹性协议的分布式系统 - 即旨在减轻(例如,容忍,检测,隔离等)拜占庭故障的影响的协议 - 可以采用这些技术。 为了这样做,这些技术可以利用包括非递减计数器和密钥的可信硬件组件。 该硬件组件可能是“可信赖的”,因为如本文所述,相应的参与者计算设备不能以除了根据规定的过程之外的任何方式修改或观察组件的内容。 此外,可信硬件组件可以以任何合适的方式,例如经由通用串行总线(USB)连接等耦合到参与者计算设备。
    • 3. 发明授权
    • Trusted hardware component for distributed systems
    • 分布式系统的可信硬件组件
    • US09455992B2
    • 2016-09-27
    • US12483338
    • 2009-06-12
    • John R. DouceurDavid M LevinJacob R. LorchThomas Moscibroda
    • John R. DouceurDavid M LevinJacob R. LorchThomas Moscibroda
    • G06F15/16H04L29/06H04L9/32
    • H04L63/123H04L9/3247H04L29/06H04L2209/127
    • Techniques for utilizing trusted hardware components for mitigating the effects of equivocation amongst participant computing devices of a distributed system are described herein. For instance, a distributed system employing a byzantine-fault-resilient protocol—that is, a protocol intended to mitigate (e.g., tolerate, detect, isolate, etc.) the effects of byzantine faults—may employ the techniques. To do so, the techniques may utilize a trusted hardware component comprising a non-decreasing counter and a key. This hardware component may be “trusted” in that the respective participant computing device cannot modify or observe the contents of the component in any manner other than according to the prescribed procedures, as described herein. Furthermore, the trusted hardware component may couple to the participant computing device in any suitable manner, such as via a universal serial bus (USB) connection or the like.
    • 在此描述了利用可信硬件组件来减轻分布式系统的参与者计算设备之间的混淆效应的技术。 例如,采用拜占庭故障弹性协议的分布式系统 - 即旨在减轻(例如,容忍,检测,隔离等)拜占庭故障的影响的协议 - 可以采用这些技术。 为了这样做,这些技术可以利用包括非递减计数器和密钥的可信硬件组件。 该硬件组件可能是“可信赖的”,因为如本文所述,相应的参与者计算设备不能以除了根据规定的过程之外的任何方式修改或观察组件的内容。 此外,可信硬件组件可以以任何合适的方式,例如经由通用串行总线(USB)连接等耦合到参与者计算设备。
    • 6. 发明授权
    • Mutual-exclusion algorithms resilient to transient memory faults
    • 相互排除算法对瞬态存储器故障有弹性
    • US08943510B2
    • 2015-01-27
    • US12971983
    • 2010-12-17
    • Rotem OshmanJohn R. DouceurThomas Moscibroda
    • Rotem OshmanJohn R. DouceurThomas Moscibroda
    • G06F9/46G06F9/52G06F11/14
    • G06F9/526G06F11/1479G06F2201/825
    • Techniques for implementing mutual-exclusion algorithms that are also fault-resistant are described herein. For instance, this document describes systems that implement fault-resistant, mutual-exclusion algorithms that at least prevent simultaneous access of a shared resource by multiple threads when (i) one of the multiple threads is in its critical section, and (ii) the other thread(s) are waiting in a loop to enter their respective critical sections. In some instances, these algorithms are fault-tolerant to prevent simultaneous access of the shared resource regardless of a state of the multiple threads executing on the system. In some instances, these algorithms may resist (e.g., tolerate entirely) transient memory faults (or “soft errors”).
    • 本文描述了用于实现也是故障抵抗的互斥算法的技术。 例如,本文档描述了实现防故障互斥算法的系统,当(i)多个线程中的一个处于其关键部分时,至少防止多个线程同时访问共享资源,以及(ii) 其他线程正在等待循环进入各自的关键部分。 在某些情况下,这些算法是容错的,以防止共享资源的同时访问,而不管系统上执行多个线程的状态如何。 在某些情况下,这些算法可以抵抗(例如,完全容忍)瞬态存储器故障(或“软错误”)。
    • 8. 发明申请
    • Mutual-Exclusion Algorithms Resilient to Transient Memory Faults
    • 相互排斥算法抵抗瞬态记忆故障
    • US20120159504A1
    • 2012-06-21
    • US12971983
    • 2010-12-17
    • Rotem OshmanJohn R. DouceurThomas Moscibroda
    • Rotem OshmanJohn R. DouceurThomas Moscibroda
    • G06F9/46
    • G06F9/526G06F11/1479G06F2201/825
    • Techniques for implementing mutual-exclusion algorithms that are also fault-resistant are described herein. For instance, this document describes systems that implement fault-resistant, mutual-exclusion algorithms that at least prevent simultaneous access of a shared resource by multiple threads when (i) one of the multiple threads is in its critical section, and (ii) the other thread(s) are waiting in a loop to enter their respective critical sections. In some instances, these algorithms are fault-tolerant to prevent simultaneous access of the shared resource regardless of a state of the multiple threads executing on the system. In some instances, these algorithms may resist (e.g., tolerate entirely) transient memory faults (or “soft errors”).
    • 本文描述了用于实现也是故障抵抗的互斥算法的技术。 例如,本文档描述了实现防故障互斥算法的系统,当(i)多个线程中的一个处于其关键部分时,至少防止多个线程同时访问共享资源,以及(ii) 其他线程正在等待循环进入各自的关键部分。 在某些情况下,这些算法是容错的,以防止共享资源的同时访问,而不管系统上执行多个线程的状态如何。 在某些情况下,这些算法可以抵抗(例如,完全容忍)瞬态存储器故障(或“软错误”)。