LOFAR Calibration Challenges

机译：LOFAR校准挑战

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The LOw Frequency ARray (LOFAR) will observe at 20-200 MHz. At those frequencies, large ionospheric phase variations considerably distort the observed brightness distribution. Fortunately, the image may be stabilized for long integrations by using bright radio sources in the sky. The downside is that LOFAR fields will be very crowded, which presents calibration challenges of its own. This is expecially true for the bright and extended sources that enter via the relatively high sidelobes of the LOFAR station beams. An extra complication is that these beamshapes vary rather strongly in frequency and time. Altogether, LOFAR will require much more processing than existing radio telescopes, and has only just become possible with the new generation of computers. Even so, new processing techniques like 'peeling' had to be developed to speed things up by several orders of magnitude.

机译：低频率阵列（LOFAR）将在20-200 MHz处观察。在那些频率下，较大的电离层相位变化会大大扭曲观测到的亮度分布。幸运的是，通过使用天空中的明亮无线电源，可以为长时间集成而稳定图像。缺点是LOFAR字段会非常拥挤，这本身就带来了校准挑战。对于通过LOFAR站波束的较高旁瓣进入的明亮光源和扩展光源而言，尤其如此。一个额外的麻烦是这些波束形状在频率和时间上变化很大。总而言之，LOFAR将比现有的射电望远镜需要更多的处理，并且只有在新一代计算机才有可能实现。即便如此，必须开发新的处理技术（例如“剥皮”）以将处理速度提高几个数量级。

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来源
《Conference on Ground-Based Telescopes pt.2; 20040621-20040625; Glasgow; GB》|2004年|P.817-825|共9页
会议地点 Glasgow(GB)801 0
作者
Jan E. Noordam;
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作者单位

ASTRON, P.O.Box 2, 7990AA Dwingeloo, The Netherlands;

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会议组织
原文格式 PDF
正文语种 eng
中图分类天体物理仪器;几何光学;
关键词
LOFAR; radio astronomy; aperture synthesis; calibration; ionosphere; low frequency; SKA;

机译：LOFAR;射电天文学;孔径合成;校准;电离层;低频; SKA;

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机译：Lofar-HBA的概率方向依赖电离层校准
2. Updated Calibration of the LOFAR Low-Band Antennas [J] . K. Mulrey, A. Bonardi, S. Buitink, EPJ Web of Conferences . 2019,第2期

机译：LOFAR低频段天线的更新校准
3. Systematic effects in LOFAR data: A unified calibration strategy [J] . F. de Gasperin, T. J. Dijkema, A. Drabent, Astronomy and astrophysics . 2019,第19期

机译：LOFAR数据的系统影响：统一的校准策略
4. Scaling performance of the SAGECal calibration package: from LOFAR to SKA [C] . J.N. Spreeuw, S. Yatawatta, B.J.C. van Werkhoven, General Assembly and Scientific Symposium of the International Union of Radio Science . 2020

机译：SAGECal校准套件的缩放性能：从LOFAR到SKA
5. Cost-efficient Solutions for Analog and Mixed-signal Test and Calibration Challenges [D] . ?Chaganti, Shravan Kumar 2020

机译：用于模拟和混合信号测试和校准挑战的成本高效的解决方案
6. Experimental Verification of the Concept of Using LOFAR Radio-Telescopes as Receivers in Passive Radiolocation Systems [O] . Julia Kłos, Konrad Jędrzejewski, Aleksander Droszcz, 2021

机译：使用Lofar射频望远镜作为被动式放射系统中的接收器的实验验证
7. Probabilistic direction-dependent ionospheric calibration for LOFAR-HBA [O] . J. G. Albert, R. J. van Weeren, H. T. Intema, 2020

机译：Lofar-HBA的概率方向依赖电离层校准
8. LOFAR Scientific Memorandum Number 6: The LOFAR Site and Its Impact on the Key Astronomical Projects [R] . Lazio, T. J. , Cohen, A. S. , Crane, P. C. , 2004

机译：LOFaR科学备忘录第6号：LOFaR场地及其对关键天文项目的影响

LOFAR Calibration Challenges

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