传感器节点能够感知的物理世界的最远距离称为节点的感知距离。
Sensing range is the maximum range within which a sensor node can detect a target.
另外,虽然高级模式感知处理器确实支持这些节点测试,但它们的数量很少,并且在实际操作中常常耦合了验证过程和数据处理过程。
Also, although the advanced schema-aware processors do support these node tests, they are rare and in practice usually couple the validation with data processing.
这种ANW2波形30个节点的网络模式非常适合语音传输、态势感知和短信息服务。
The ANW2 30-node networking mode is ideal for voice, situational awareness, and short messaging services.
模式感知允许instance of根据模式中定义的所有类型确认节点的类型。
Schema awareness allows instance of to confirm the type of a node against all types defined in the schema.
利用感知器异或函数获得了节点之间不断优化的连接关系,然后得到最优路径图。
The continually optimized connecting relation is gained via perceptron and XOR function, then the optimal path graph is found.
利用无线传感器网络中节点感知数据的相关性,提出了一种基于预测修正的动态数据传送机制。
A dynamic data transmission mechanism based on prediction revision is presented according to the inherent correlation of sampling data between nodes in WSNs.
然后,给出了一种可对上述三层感知器进行压缩的隐节点的压缩方法,它可以推广到三层以上的感知器和节点激发函数不同的情形。
Then, a method is presented to compress the number of hidden nodes, which can be extended to more than three layer perceptrons and to the case of using different activation functions.
当前对频谱感知技术的研究主要集中在单节点频谱检测和多节点合作频谱检测方面。
Now the research on spectrum sensing technology was mainly focused on the field of single node spectrum detection and multi-node spectrum detection.
无线传感器网络中,感知节点的合理分布对于提高网络的感知能力和信息收集能力以及提高网络的生存期限都具有重要的作用。
In sensor networks, a reasonable distribution of sensor nodes will do much good to the improvement of sensor ability, information aggregation ability and network survival.
如果布置一个无线感知网络去担任监测任务,其节点需要配置多种不同类型的传感器单元。
To monitor the objects, the sensor node has to set up different types of sensor units.
通过大量节点间的分工协作,WSN可实时监测、感知和采集网络分布区域内的各种环境或监测对象的信息。
WSN can monitor the targets and collect the information of the environment through the cooperation of large amount of sensors.
大量传感器节点通过相互之间的分工协作,可实时感知、监测和采集分布区域内的监测对象或周围环境的信息。
By the mutual cooperation of large number of sensor nodes, sensor network can sense, monitor and gather the information of a given object or environment.
本论文主要针对自感知光网络中硬件平台和核心节点的实现进行研究。
In this paper, aimed at self-sensing optical network hardware platforms and core nodes, the author has made the implementation and research.
为减小单个根节点的负载,选择多个能感知到相同空闲信道数量的次要用户作为根节点。
To reduce the loading of root in a spectrum-tree, some users, which sense the same number of idle channels, are selected as roots.
为了更好地部署这些移动机器人节点,形成最大化覆盖感知区域,提出了一种基于机器人局部信息的分布式感知网覆盖方法。
Presented a new distributed coverage method of mobile robot nodes based local information in order to deploy these nodes for forming maximum coverage of sensing area.
无线传感器网络中的各个节点相互协作可以进行实时监测,感知和采集测试对象的各种信息,并把收集到的海量数据进行处理,然后通过无线网络及时发送给用户。
Wireless sensor network nodes can collaborate on real-time monitoring, such as tasks, and the collected mass data processing, and then sent through a wireless network in a timely manner to the user.
提出了一种不相交路径路由算法,可以将感知节点采集到的数据通过不相交路径传送到汇聚节点,提高路由的可靠性。
To solve the common-link and common-node problem, disjoint multi-path routing (DMPR) is employed where sensors send data to the sink through link-disjoint or node-disjoint path.
针对相机节点的有向感知模型,提出了一种基于感知域划分的分布式相机节点协调唤醒机制。
According to the directional sensing model of the camera-equipped node, a region-division-based distributed camera coordinative wakeup mechanism is proposed.
针对相机节点的有向感知模型,提出了一种基于感知域划分的分布式相机节点协调唤醒机制。
According to the directional sensing model of the camera-equipped node, a region-division-based distributed camera coordinative wakeup mechanism is proposed.
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