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1 原理近年来 ,石英钟表越来越多 ,特别是石英电子秒表在工业上以其高精度和无方向性逐渐取代机械秒表 ,而随之对它的计量就显得尤为重要。本文介绍的就是这样一台检定仪器 ,它既能测量石英钟表 ,又能检定石英电子秒表和机械秒表。它结合了石英钟表瞬时日差测量仪和机械秒表检定仪的基本思想 ,并根据目前各类石英表的具体情况进行了精心的设计和调试 ,从而保证了该仪器良好的技术性能。仪器原理框图见图 1。图 1 图 1中 ,磁、电传感器分别能将指针式石英钟表的漏磁场信号转变成电信号以及将数显石英电子表的电场信号感应拾取。精密放… 相似文献
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星地链路计算作为卫星通信的重要技术,是卫星通信系统设计的基础和理论依据,直接决定了卫星通信系统的链路通信质量。由于影响卫星链路的因素很多,设计中存在一处不合理即使得整条星地链路不可用,造成巨大的损失。而且在实际设计中无法做到最理想的链路状态,往往需要在某方面有所取舍,这也是链路计算中的一大难点。基于目前国际通用的链路计算方法,将星地链路上下行拆分,独立计算,综合分析,再结合实际工程经验,分析和计算实际工程案例,针对不同的链路配置给出相应合理的设计方法,可作为静止轨道通信卫星星地链路计算分析的参考。 相似文献
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The ultimate goal of a comprehensive life detection strategy is never to miss life when we encounter it. To accomplish this goal, we must define life in universal, that is, non-Earthcentric, measurable terms. Next, we must understand the nature of biosignatures observed from the measured parameters of life. And finally, we must have a clear idea of the end-member states for the search--what does life, past life, or no life look like (in terms of the measured parameters) at multiple spatial and temporal scales? If we can approach these problems both in the laboratory and in the field on Earth, then we have a chance of being able to detect life elsewhere in our solar system. What are the required limits of detection at each of those scales? What spatial, spectral, and temporal resolutions are necessary to detect life? These questions are actively being investigated in our group, and in this report, we present our strategy and approach to non-Earthcentric life detection. 相似文献
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Smith PG 《Aerospace America》2004,42(2):10-13
Ms. Smith, associate administrator for commercial space transportation within the Federal Aviation Administration, answers questions about regulations and licensing related to reusable launch vehicles, space passenger vehicles, and commercial space ventures. 相似文献
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Xu J Ramian GJ Galan JF Savvidis PG Scopatz AM Birge RR Allen SJ Plaxco KW 《Astrobiology》2003,3(3):489-504
We propose a terahertz (far-infrared) circular dichroism-based life-detection technology that may provide a universal and unequivocal spectroscopic signature of living systems regardless of their genesis. We argue that, irrespective of the specifics of their chemistry, all life forms will employ well-structured, chiral, stereochemically pure macromolecules (>500 atoms) as the catalysts with which they perform their metabolic and replicative functions. We also argue that nearly all such macromolecules will absorb strongly at terahertz frequencies and exhibit significant circular dichroism, and that this circular dichroism unambiguously distinguishes biological from abiological materials. Lastly, we describe several approaches to the fabrication of a terahertz circular dichroism spectrometer and provide preliminary experimental indications of their feasibility. Because terahertz circular dichroism signals arise from the molecular machinery necessary to carry out life's metabolic and genetic processes, this life-detection method differs fundamentally from more well-established approaches based on the detection of isotopic fractionation, "signature" carbon compounds, disequilibria, or other by-products of metabolism. Moreover, terahertz circular dichroism spectroscopy detects this machinery in a manner that makes few, if any, assumptions as to its chemical nature or the processes that it performs. 相似文献
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在现有的雷达文献中,几乎一例外地对旁视机载雷达杂波抑制及干扰抑制的空时适应处理技术作了专门的讨论。在SLAR中,杂波多普勒与杂波角位置间存在一种单线的线性关系,这种关系的存在,导致从理论上计可以得到杂波完全抑制掉的STAP法。 相似文献
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The objective of the 2009 Mars Science Laboratory (MSL), which is planned to follow the Mars Exploration Rovers and the Phoenix lander to the surface of Mars, is to explore and assess quantitatively a site on Mars as a potential habitat for present or past life. Specific goals include an assessment of the past or present biological potential of the target environment and a characterization of its geology and geochemistry. Included in the 10 investigations of the MSL rover is the Sample Analysis at Mars (SAM) instrument suite, which is designed to obtain trace organic measurements, measure water and other volatiles, and measure several light isotopes with experiment sequences designed for both atmospheric and solid-phase samples. SAM integrates a gas chromatograph, a mass spectrometer, and a tunable laser spectrometer supported by sample manipulation tools both within and external to the suite. The sub-part-per-billion sensitivity of the suite for trace species, particularly organic molecules, along with a mobile platform that will contain many kilograms of organic materials, presents a considerable challenge due to the potential for terrestrial contamination to mask the signal of martian organics. We describe the effort presently underway to understand and mitigate, wherever possible within the resource constraints of the mission, terrestrial contamination in MSL and SAM measurements. 相似文献
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