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    • 1. 发明申请
    • METHOD AND APPARATUS FOR BATTERY-AWARE DYNAMIC BANDWIDTH ALLOCATION FOR GROUPS OF WIRELESS SENSOR NODES IN A WIRELESS SENSOR NETWORK
    • 无线传感器网络无线传感器组的电池动态带宽分配方法与装置
    • US20080211666A1
    • 2008-09-04
    • US11681634
    • 2007-03-02
    • Ali SaidiSilviu ChiricescuPhilip E. MayKent D. Moat
    • Ali SaidiSilviu ChiricescuPhilip E. MayKent D. Moat
    • H04Q7/00G08B19/00H04B7/00
    • G01D21/00H04W4/06H04W52/0261H04W72/085H04W84/18
    • A method and apparatus that allocates bandwidth among wireless sensor nodes in wireless sensor groups in a wireless sensor network (WSN) is disclosed. The method may include forming a plurality of wireless sensor node groups from a plurality of wireless sensor nodes based on battery levels of the wireless senor nodes, allocating transmission time slots for the wireless sensor nodes in each of the wireless sensor node groups based on at least one channel quality metric, determining average battery levels for each of the wireless sensor node groups and average battery level of all of the wireless sensor nodes, determining differences between the average battery levels of each of the wireless sensor node groups and the average battery level of all of the wireless sensor nodes, wherein if any difference in the average battery levels is above a predetermined threshold, regrouping the plurality of wireless sensor nodes according to the battery levels of the plurality wireless sensor nodes to minimize any variance in average battery level across all of the wireless sensor node groups.
    • 公开了一种在无线传感器网络(WSN)中的无线传感器组中的无线传感器节点之间分配带宽的方法和装置。 该方法可以包括基于无线传感器节点的电池电平从多个无线传感器节点形成多个无线传感器节点组,至少基于至少基于无线传感器节点组中的无线传感器节点组中的无线传感器节点分配传输时隙 单通道质量度量,确定每个无线传感器节点组的平均电池电量和所有无线传感器节点的平均电池电量,确定每个无线传感器节点组的平均电池电量与平均电池电量之间的差异 所有无线传感器节点,其中如果平均电池电平中的任何差异高于预定阈值,则根据多个无线传感器节点的电池电平重新分组多个无线传感器节点,以最小化所有的平均电池电平的任何差异 的无线传感器节点组。
    • 2. 发明授权
    • Method and apparatus for battery-aware dynamic bandwidth allocation for groups of wireless sensor nodes in a wireless sensor network
    • 无线传感器网络中无线传感器节点组的电池感知动态带宽分配的方法和装置
    • US07801079B2
    • 2010-09-21
    • US11681634
    • 2007-03-02
    • Ali SaidiSilviu ChiricescuPhilip E. MayKent D. Moat
    • Ali SaidiSilviu ChiricescuPhilip E. MayKent D. Moat
    • H04W4/00H04B7/212
    • G01D21/00H04W4/06H04W52/0261H04W72/085H04W84/18
    • A method and apparatus that allocates bandwidth among wireless sensor nodes in wireless sensor groups in a wireless sensor network (WSN) is disclosed. The method may include forming a plurality of wireless sensor node groups from a plurality of wireless sensor nodes based on battery levels of the wireless senor nodes, allocating transmission time slots for the wireless sensor nodes in each of the wireless sensor node groups based on at least one channel quality metric, determining average battery levels for each of the wireless sensor node groups and average battery level of all of the wireless sensor nodes, determining differences between the average battery levels of each of the wireless sensor node groups and the average battery level of all of the wireless sensor nodes, wherein if any difference in the average battery levels is above a predetermined threshold, regrouping the plurality of wireless sensor nodes according to the battery levels of the plurality wireless sensor nodes to minimize any variance in average battery level across all of the wireless sensor node groups.
    • 公开了一种在无线传感器网络(WSN)中的无线传感器组中的无线传感器节点之间分配带宽的方法和装置。 该方法可以包括基于无线传感器节点的电池电平从多个无线传感器节点形成多个无线传感器节点组,至少基于至少基于无线传感器节点组中的无线传感器节点组中的无线传感器节点分配传输时隙 单通道质量度量,确定每个无线传感器节点组的平均电池电量和所有无线传感器节点的平均电池电量,确定每个无线传感器节点组的平均电池电量与平均电池电量之间的差异 所有无线传感器节点,其中如果平均电池电平中的任何差异高于预定阈值,则根据多个无线传感器节点的电池电平重新分组多个无线传感器节点,以最小化所有的平均电池电平的任何差异 的无线传感器节点组。
    • 4. 发明授权
    • Memory interface with fractional addressing
    • 具有分数寻址的存储器接口
    • US06799261B2
    • 2004-09-28
    • US10184582
    • 2002-06-28
    • Philip E. MayKent Donald MoatRaymond B. Essick, IVSilviu ChiricescuBrian Jeffrey LucasJames M. NorrisMichael Allen SchuetteAli Saidi
    • Philip E. MayKent Donald MoatRaymond B. Essick, IVSilviu ChiricescuBrian Jeffrey LucasJames M. NorrisMichael Allen SchuetteAli Saidi
    • G06F1200
    • G06F9/3552G06F9/345G06F12/04
    • A memory interface device (100) providing a fractional address interface between a data processor (104) and a memory system (102) and a method for retrieving intermediate data values from a memory system using fractional addressing. The device includes an address generator (108) for generating first and second memory addresses, the first memory address being less than or equal to a specified fractional address, the second memory address being greater than or equal to the fractional address. The device also includes a memory access unit (110) coupled to the address generator (108) for retrieving first and second data values from the memory system (102) at the first and second memory addresses, respectively. The device also includes a data access unit (112) for interpolating between the first and second data values and passing the interpolated value to the data processor (104). The memory interface has application in a variety of data processing systems, including digital signal processors and streaming vector processors.
    • 在数据处理器(104)和存储器系统(102)之间提供分数地址接口的存储器接口设备(100)以及用于使用分数寻址从存储器系统检索中间数据值的方法。 该设备包括用于产生第一和第二存储器地址的地址发生器(108),第一存储器地址小于或等于指定的分数地址,第二存储器地址大于或等于分数地址。 该设备还包括耦合到地址发生器(108)的存储器访问单元(110),用于分别在第一和第二存储器地址处从存储器系统(102)检索第一和第二数据值。 该装置还包括用于在第一和第二数据值之间进行内插并将内插值传递给数据处理器(104)的数据访问单元(112)。 存储器接口在各种数据处理系统中具有应用,包括数字信号处理器和流媒体矢量处理器。
    • 8. 发明申请
    • METHOD AND APPARATUS FOR RESOURCE ALLOCATION
    • 资源分配的方法和装置
    • US20100111000A1
    • 2010-05-06
    • US12264681
    • 2008-11-04
    • Ali SaidiSilviu ChiricescuLoren J. RittleYang Yu
    • Ali SaidiSilviu ChiricescuLoren J. RittleYang Yu
    • H04W72/04
    • H04W72/04H04W84/18
    • A method and apparatus for allocating resources to a node in an ad-hoc communication system is provided herein. During operation, nodes of the system will receive resource allocations from their parent node. The resource allocation comprises a portion of available resources that may vary in size. Each node will determine the resource needs for its children nodes only and then dynamically assign resources to them. The resources assigned to the children nodes comprise a portion of the resources assigned to the node by its parent node. Additionally, knowledge as to how the children further allocate resources to their own children is not known by the parent, however, the children nodes must allocate a portion of their resource to their children nodes.
    • 本文提供了一种用于向自组织通信系统中的节点分配资源的方法和装置。 在运行期间,系统的节点将从其父节点接收资源分配。 资源分配包括可能在大小上可能变化的可用资源的一部分。 每个节点将仅确定其子节点的资源需求,然后动态地为其分配资源。 分配给子节点的资源包括其父节点分配给节点的资源的一部分。 此外,有关孩子如何进一步向自己的孩子分配资源的知识不是父母知道的,但是,子节点必须将其资源的一部分分配给子节点。
    • 10. 发明申请
    • METHOD AND SYSTEM FOR GAS LEAK DETECTION AND LOCALIZATION
    • 用于气体泄漏检测和局部化的方法和系统
    • US20080168826A1
    • 2008-07-17
    • US11623892
    • 2007-01-17
    • Ali SaidiSilviu ChiricescuJames M. NorrisMichael A. Schuette
    • Ali SaidiSilviu ChiricescuJames M. NorrisMichael A. Schuette
    • G01M3/04
    • G01M3/20
    • A system includes a first gas sensor [110] to detect a first concentration of a predetermined gas and to determine a first rate of change in the first concentration over a time interval. A second gas sensor [115] detects a second concentration of the predetermined gas and determines a second rate of change in the second concentration over the time interval. A third gas sensor [120] detects a third concentration of the predetermined gas and determines a third rate of change in the third concentration over the time interval. The first, second, and third gas sensors each have a known location. At least one processing device [510] (a) determines respective distances between a gas leak location and the respective locations of the gas sensors based on the detected rates of change, and (b) calculates a location of the gas leak based on a triangulation of the first distance, the second distance, and the third distance.
    • 系统包括:第一气体传感器[110],用于检测预定气体的第一浓度,并确定在一段时间间隔内第一浓度的第一变化率。 第二气体传感器检测预定气体的第二浓度,并确定在该时间间隔内的第二浓度的第二变化率。 第三气体传感器检测预定气体的第三浓度,并确定在该时间间隔内第三浓度的第三变化率。 第一,第二和第三气体传感器各自具有已知的位置。 至少一个处理装置(a)基于检测到的变化率来确定气体泄漏位置和气体传感器的相应位置之间的相应距离,以及(b)基于三角测量计算气体泄漏的位置 的第一距离,第二距离和第三距离。