无线传感器网络的英文文献

1. 翻译一个英语小论，关于无线传感器网络的，论文不长

论文呢？看了才可以翻译

2. 急求有关传感器的外文文献翻译，包括英文全文和中文翻译

节能机制无线传感器网络

Bonuccelli毛主管:

论文commettee:保罗·Ferraggina,皮耶罗Maestrini

外部裁判Basagni,摩尼Srivastava:斯蒂法诺

国家commettee:Bugliesi,Panzieri,Meo

2005年12月27日起,

文摘

本文解决这个问题降低能耗的无线传感器网络。我们提出一套技术和

进口策略研究领域,可以应用于设计节能协议传感器网络。他们包括

时间序列预测,quorums系统的传感器性能和相互作用的协议设计的。我们运用这些技术能有效时间同步问题,从传感器网络数据收集,并确保较强的数据一致性保证在移动网络。

我们表现出[1、2、3、4]时间序列预测技术,特别是AR模型,可适用于传感器网络,以节省能源。我们学习一个简单的类型的时间序列模型的构建与短预测的窗口。我们已经选择了这个模式,它很能干

预测的数据得到了真实世界的传感器测量的物理现象,它非常容易加工的在modern-generation传感器网络。我们运用这些模式,解决两个有关问题进行传感器网络:问题能有效地收集传感器的数据在水槽,和时间同步的问题。

提出了一种节能框架,叫爱相似-通过适应性强的查询框架[1,2]),为近似查询及检测孤立点价值在传感器网络。这个想法是基于“增大化现实”技术结合当地建立在每个节点模型成为一个全球性的模型存储的根源,网络

(库),用来大约回答用户的查询。我们的方法使用显着比以前更少的传输采用基于“增大化现实”技术近似方法模型和组织网络集群基于数据之间的相似节点。数据定义基于相似系数模型的地方基于“增大化现实”技术,在水槽储存在技术,降低了能耗直接比较数据值,让我们可以得到有效的聚类算法大概是最佳的,总分组数所形成的网络。我们的集群建设有几个有趣的特点,使适宜也针对移动网络:首先,他们可以捕捉相似性地理相邻节点;二、聚类成员,不需要额外消耗适应节点;三、集群内不需要跟踪加入其他节点在产业集群。此外,大概正确的误差界爱提供并允许用户动态调整回答质量解答疑问在能源和资源有效地进行。

此外,我们运用AR模型来解决时间同步问题的一种新的视角生物系的互补时钟同步问题[3,4]。更确切地说,我们分析的案例传感节点决定跳过一个或多个时钟调整,达到节能效果,或是暂时孤立的,但仍需要一个精确计算时间。提出了一种基于大概正确的时钟返回一个模型,是基于“增大化现实”技术一时间估计在一个常数(可调误差概率约束和问题。该方法是高度适应性强,并允许传感器来决定有多少

时钟调整它可以跳过同时保持精度,从而节约能源。此外,我们提出一套确定方法,降低了时间估计误差由至少一个因素2。更确切地说,我们提出大概正确的确定性时钟读数方法,叫做DCR方法,利用相关信息时钟偏差的标志,可应用于减少一半时钟周期的频率调整,同时还保持了同样的错误一定[3,4]。

该方法的实践和理论两个方面的兴趣。事实上,它导致了一个明显的节能,并详细地说明了较强的现实时钟模型可以导致精化的最优开往最大偏差时钟的定时同步。此外,我们还提出了一种广义版本的DCR方法,以提高其精度取决于稳定的时钟,一个方法的单调性,保证了生产的时间值。

第一次我们分析系统技术背景法定传感器网络:我们改造,并向自己的利益能耗方面[6]。法定人数系统有潜力在节约能源方面传感器网络,因为他们可以减少的数量明显的沟通,提高传感器节点之间的负载平衡,提高系统的可扩充性。然而,以前的法定人数系统和法定人数的度量标准,有线网络提出了,不适合传感器网络,因为他们并没有解决它们的性能特点和局限性。这些观察推动了我们重新设计的法定人数系统及相应的度量标准,考虑到限制和特点的感测器(例如,传输成本,有限的能量

源、物理的无线电广播),网络拓扑结构。更确切地说,我们重新定义下列法定度量标准:负载均衡、访问成本和法定人数能力,并设计策略的一些特点的基础上,对传感器网络的沟通量减少的人数系统设计时传感器网络。我们运用这些策略设计一个家庭的人数系统节能高弹性。特别是,我们提出一种法定人数减少建设成本,提出了一个访问数据扩散协议建立在节能上面减少能源消费的传输,缩短了碰撞产生的。

此外,我们分析的情况下的人数系统高节点移动性。更确切地说,我们学习困难的问题保证在两个quorums十字路口时不断移动路径沿着未知节点[7]。我们解决这个问题,并定义了一小说,提供流动性模型最低约束集推导出足够强劲的经济数据保证在高机动性的网络。在这种情况下,我们会告诉名校以前的法定人数系统,并提供一个条件是必要的,以保证数据的可用性和原子一致性在高节点移动性。我们还提出了一种新的班

法定人数的系统,被叫做移动传播(苦咸水淡化,适合于高度quorums移动网络,提出了一种最优建设法定人数方面,大小(例如,通信传输)[7]。然后,我们运用总经理法定人数体系,实行大概正确的原子读/写共享内存移动、稀疏的网络。

书目

[1],国立台湾Tulone·d·马登上尉。PAQ:时间序列预测为近似查询回答

在传感器网络。在第三Proc.欧洲研讨会,第1 - 11页。无线传感器网络21-37 2006年2月。

[2],国立台湾Tulone·d·马登上尉。查询框架了节能检测传感器网络中节点相似之处。

提交会议。

[3]·d·Tulone。全球的可行性评价隔离条件下的无线传感器网络。

出现在Algorithmica。

[4]·d·Tulone。节约型时间估计的无线传感器网络。在Proc.的第四届车间的原则下,第1 - 11页。52-59移动计算,2004年10月。

Tulone >[5]。如何能有效率及准确地得到参考时间之间的过程吗?国际。Symp.分布式计算,10月

2003年。简短的声明。25-32页。

[6]D。Demaine Tulone > >。重新设计的法定人数系统的无线传感器网络。提交会议。

Tulone >[7]。是否有可能确保强劲的经济数据保证在高机动性的网有关吗?提交会议。

3. 无线网络优化的参考英文文献有哪些

无线网络优化的参考英文文献
关于信息优化主题相关的外文文献，在《WirelessCommunications,IEEETransactionson》、《Renewableenergy》、《》、《IEEETransactionsonComputer-》、《》等期刊中都有相关的内容，小编为大家整理出了的10篇外文毕业论文文献，其中包括5篇期刊论文，5篇学位论文，希望能对还在为寻找信息优化选题的相关人员撰写论文提供参考帮助。

4. 无线传感网络 英文翻译

Abstract
This thesis provides a brief survey of the definition, constituent elements and features of wireless sensor network. Moreover, this thesis gives a brief sketch of the extensive using value and the future of wireless sensor network in light of its features.Finally, this thesis discusses the exsisting technique problems.

Key words: wireless sensor network, constituent elements,application,development

咕~~(╯﹏╰)b，头痛发烧中。。。开始不想翻了，后来想你肯定急用，就翻了。

5. 无线传感器网络的国外期刊

我的研究方向也是WSN方面的，有很多WSN的文章发在AD HOC方面的期刊，这是我自己整理的期刊，大多是SCIE检索的：
ISSN 期刊名称
1556-4665 ACM TRANS ON Autonomous and Adaptive Systems
1550-4859 ACM TRANSACTIONS ON SENSOR NETWORKS
1570-8705 Ad Hoc Networks
1551-9899 AD HOC & SENSOR WIRELESS NETWORKS
1743-8225 International Journal of Ad Hoc and Ubiquitous Computing
1754-3916 International Journal of Communication Networks and Distributed Systems
1550-1329 INTERNATIONAL JOURNAL OF DISTRIBUTED SENSOR NETWORKS
1748-1279 International Journal of Sensor Networks
0914-4935 SENSORS AND MATERIALS
1424-8220 SENSORS
1546-198X SENSOR LETTERS
0260-2288 SENSOR REVIEW
1530-437X IEEE SENSORS JOURNAL
1341-8939 IEEE Transactions on Sensors and Micromachines

6. 哪位大神有关于无线传感器网络方面的英文文献。摆脱了

文献很多，具体要哪方面的？综述还是别的什么？我是搞无线传感器网络故障管理的。

7. 跪求一篇“关于传感器的英语文献”最好有翻译成中文的！

给你一个网址，收集了很多关于无线传感器网络的文献。
Related to Wireless Sensor Networks:
TinyOS、NesC程序开发经验谈
Location in Wireless Sensor Networks_06-07Year(无线传感器网络定位06-07年)
Survey on Wireless Sensor Networks(无线传感器网络综述)
Hardware on Wireless Sensor Networks(无线传感器网络硬件)
Security in Wireless Sensor Networks(无线传感器网络安全)
Time Synchronization in Wireless Sensor Networks(无线传感器网络时间同步)
Target Tracking in Wireless Sensor Networks(无线传感器网络目标跟踪)
Location in Wireless Sensor Networks_1/3(无线传感器网络定位1/3)
Location in Wireless Sensor Networks_2/3(无线传感器网络定位2/3)
Location on Wireless Sensor Networks_3/3(无线传感器网络定位3/3)
参考资料：http://chinawangquan.spaces.live.com
再到http://www.hao123.com/ss/fy.htm 去翻译

8. 是这样的：中国知网上没有账号 想搜索关于无线传感器网络监测的英文，以及中文翻译~求发送过来

额·放假了 要不在学校的话 能给你下几篇

文献
期刊
博硕士
会议
报纸
外文文献
年鉴
网络
词典
统计数据
专利

你要以上哪种的呢？

还有个笨方法 你可以试试 在网络搜索
无线传感器网络监测
然后找到你需要的文章 用翻译器翻译成英文 ，不过可能不会太准确。

9. 急求有关传感器的英文文献翻译，包括英文原文以及中文翻译

中，英己送出
A transcer is a device that converts one type of energy to another. The conversion can be to/from electrical, electro-mechanical, electromagnetic, photonic, photovoltaic, or any other form of energy. While the term transcer commonly implies use as a sensor/detector, any device which converts energy can be considered a transcer.

Transcers are electric or electronic devices that transform energy from one manifestation into another. Most people, when they think of transcers, think specifically of devices that perform this transformation in order to gather or transfer information, but really, anything that converts energy can be considered a transcer.

Transcers that detect or transmit information include common items such as microphones, Geiger meters, potentiometers, pressure sensors, thermometers, and antennae. A microphone, for example, converts sound waves that strike its diaphragm into an analogous electrical signal that can be transmitted over wires. A pressure sensor turns the physical force being exerted on the sensing apparatus into an analog reading that can be easily represented. While many people think of transcers as being some sort of technical device, once you start looking for them, you will find transcers everywhere in your everyday life.
Most transcers have an inverse that allows for the energy to be returned to its original form. Audio cassettes, for example, are created by using a transcer to turn the electrical signal from the microphone pick-up – which in turn went through a transcer to convert the sound waves into electrical signal – into magnetic fluctuations on the tape head. These magnetic fluctuations are then read and converted by another transcer – in this case a stereo system – to be turned back into an electrical signal, which is then fed by wire to speakers, which act as yet another transcer to turn the electrical signal back into audio waves
Other transcers turn one type of energy into another form, not for the purpose of measuring something in the external environment or to communicate information, but rather to make use of that energy in a more proctive manner. A light bulb, for example, one of the many transcers around us in our day-to-day lives, converts electrical energy into visible light. Electric motors are another common form of electromechanical transcer, converting electrical energy into kinetic energy to perform a mechanical task. The inverse of an electric motor – a generator – is also a transcer, turning kinetic energy into electrical energy that can then be used by other devices.
As in all energy conversions, some energy is lost when transcers operate. The efficiency of a transcer is found by comparing the total energy put into it to the total energy coming out of the system. Some transcers are very efficient, while others are extraordinarily inefficient. A radio antenna, for example, acts as a transcer to turn radio frequency power into an electromagnetic field; when operating well, this process is upwards of 80% efficient. Most electrical motors, by contrast, are well under 50% efficient, and a common light bulb, because of the amount of energy lost as heat, is less than 10% efficient.

What is the Difference Between Transcers and Sensors

Transcers are machines used to change one type of energy into another. They can often be found as a component of more complex devices. Sensors are explicitly intended to measure and express levels of measurement. Quite often, sensors are composed of transcers; therefore, one can see how easy it can be to confuse the two.

Generally, transcers come in basic varieties of which there are almost endless applications. The first variety is contact transcers. This type is categorized by a single point of contact used to detect energy. There is generally a coupling material, such as water or oil, employed in order to prevent distortion between the source of energy and the point of detection.

Many sensors utilize contact transcers in order to detect energy levels and convert that into an electrical energy which would then influence a display meter. One type of contact transcer that was almost ubiquitous in the late 1980s and early 1990s were tape heads. These were found in any cassette player, touching the magnetic tape and reading the magnetic information that was on it. This information was then converted to an electric signal that was carried by wire to speakers or headphones and then converted back into sound waves.
The second most common type of transcers is the immersion type. These are intended to work in liquid environments. This type is effective at measuring sound, pressure, or other forms of mechanical energy. Paintbrush transcers are used like immersion types are, but they work in open environments and have highly sensitive crystals to detect even the faintest levels of energy. Antennae for radio waves are paintbrush types as they collect the broadcast radio waves and convert them into electrical energy that is converted back into sound by a radio’s speakers.
Vibration Transcer Current Transcer Capacitive Transcers MEMS Sensors