几种气象因素对云台太阳光谱仪成像质量的影响规律

在多年的太阳光谱观测中，通过观察各种天气条件的变化对光谱仪成像质量的影响，初步总结出使像质优良的几条规律：1）在连续刮风过程中当风突然停止或减弱的短暂时间内像质明显变好；2）当夜间通宵有风而次日天气晴朗时像质变好；3）多云过后的短暂晴天成像优良；4）连接阴雨几天后的开始晴天像抽较好。     

云台太阳光谱仪像质优良的时间分布规律

通过对云台水平式太阳光谱仪 1 982年太阳光谱观测中的成像质量情况统计分析 ,初步得到光谱仪一年中成像质量优良的时间在秋夏 9月和 8月份 ;一天内有两次像质优良的时间 ,上、下午各有一次 ,分别在日出后 2～ 3小时和日落前 3～ 4小时各有半小时到 1小时左右的时间。     

PSSN在TMT宽视场光谱仪中的应用研究

光学系统像质评价是光学设计的核心,通过对常用像质评价方法与在30 m望远镜(Thirty Meter Telescope,TMT)的像质评价中提出的归一化点源灵敏度函数(Normalized Point Source Sensitivity,PSSN)的分析比较,对PSSN在TMT宽视场光谱仪(Wide Field Optical Spectrometer,WFOS)中的应用进行了研究.包括对大气视宁度的简化模拟、TMT中M3的移动对系统PSSN的影响、WFOS中准直镜的移动对系统PSSN的影响、在不同大气湍流的条件下PSSN与天顶角的关系以及PSSN与波像差的均方根值(root mean square of wavefront error,RMS WFE)μ之间的关系.结果表明,PSSN对视宁度受限下的TMT的像质评价是有效的.     

近地天体望远镜配置大阵面CCD后轴外像差的校正

近地天体望远镜由SI600S (4k×4k) CCD升级为STA1600LN (10k×10k) CCD后,观测视场由4 deg~2增至9 deg~2,可用视场直径由望远镜原设计视场的3.14°增至4.28°,超出原设计36%,同时作为CCD密封窗的场镜增厚8.75 mm;两个因素导致10k CCD成像的轴外像差增大,视场外围的像质变差.依据望远镜原始设计光学参数,借助光学设计软件ZEMAX进行像质改善尝试,最终选择在10k CCD场镜前插入一个由两片球面透镜组成的场改正镜,使10k CCD的轴外像差得到校正.同时还提出了一个进一步拓展近地天体望远镜观测能力的设计方案,将望远镜的可用视场从目前的14.38 deg~2扩展至28.27 deg~2.     

一米新真空太阳望远镜离焦对高分辨太阳观测图像重建的影响

由于太阳辐射、环境温度等因素,太阳望远镜在一个观测日内往往有较明显的像差变化,而离焦是其中的主要像差。针对抚仙湖1 m太阳望远镜的高分辨成像观测系统,对其离焦像差及变化进行了简要分析,在此基础上模拟分析了离焦像差对图像高分辨统计重建的影响。分析结果表明,离焦像差对高分辨重建图像的相位传递函数影响不大,但对调制传递函数有明显的影响,进而造成像质衰减,应当进行补偿。     

天文高分辨像复原技术检测地基天文光学望远镜成像质量

在天文高分辨像复原技术的基础上，根据谱比法较准确地测量视宁度参数r0后，计算得到大气系统的平均短曝光传递函数，从而把大气湍流对检测结果的影响从综合成像系统中分离了出来。利用望远镜摄取大量目标源的短曝光像(斑点图)作为原始数据，通过分析这些含有望远镜衍射极限分辨率信息的斑点图，实现天文光学望远镜系统点扩展函数(PSF)中低频信息的重建，得到半峰全宽(FWHM)和80％的能量集中度(EE)。     

当晴天娃娃失灵时

有人说天文爱好者是“靠天吃饭,以天为乐”的,此话不假,一次成功的活动是很需要老天爷给面子的。作为组织者,确定活动计划前,往往要一日“四顾茅庐”（睛天钟所用的GFS模型一天运行四次）,听听晴天钟有没有传来天气睛好的佳音。若是临近众人期待已久的少见天象,更是要想尽办法求个晴天：比如,打听打听阴天教有没有转移的意图,赶紧避开;再比如,四处接上晴天娃娃。     

成像硬X射线望远镜在美国和欧洲的发展

硬X射线能带（20KeV-1MeV)是我们了解天体物理中高能辐射过程的一个好窗口。成像硬X射线望远镜可以提供更好的分辨率和灵敏度来研究硬X射线天体物理学。本文介绍了成像硬X射线望远镜在美国和欧洲的发展，这包括：1）EXITE2，由美国哈佛－史密松林天体物理中心设计和运行的一个光电开关成像硬X射线望远镜；2）EXIST，一个成像硬X射线全天巡天望远镜，将于2010年由ULDB（EXIST－LINE）或国际空间站（EXIST－ISS）承载；3）HERO，由NASA／MSFC建造的一个新的硬X射线光学仪器。     

2008年10月重要天象预告

秋高气爽,风和日丽,美丽的十月正向我们走来。进入秋季后,我国北方大部分地区的晴天会越来越多,并不太寒冷的天气也非常适宜进行天文观测。在这样的好日子里,我们的天象剧场将有哪些好戏上演呢？     

基于大视场反卷积的天文图像叠加方法

地基望远镜在成像过程中,由于受大气湍流、望远镜静态像差、跟踪误差、指向误差及视场变化的影响,不同视场区域的PSF (Point Spread Function)具有差异;同时,不同望远镜获取的图像PSF也存在差异.将多个望远镜获取的星象直接叠加至相同的区域后,图像质量受像质最差的望远镜限制,最终观测分辨率和灵敏度均会受到影响.通过图像复原,可以提高图像质量,进而提高叠加效果.根据该思路提出了1种基于PSF分区的迭代图像复原方法:该方法首先通过SOM (Self-organizing Maps)对PSF进行聚类分析,利用同类别PSF的平均PSF进行反卷积,再将反卷积结果按PSF聚类结果分割为不同大小的子图,最后将子图进行拼接.图像复原在提高图像质量的同时,降低了PSF不一致性对图像叠加带来的影响.将几个望远镜在同一时刻获取的图像经反卷积处理之后利用图像配准算法进行矫正并叠加,可获得高信噪比图像.对实际望远镜获取的数据处理后的结果表明:图像在进行复原和叠加过程中,星象目标信噪比不断提升,提高了成像系统对暗星的探测能力.     

太阳活动22周以来的冕洞和地磁指数

本文对２２太阳活动用以来的中低纬冕洞和地磁指数Ａｐ进行了统计。对以月、季、年及２２周以来不同时段冕洞和地磁指数（Ｐｌａｎｅｔａｒｙ的Ａ指教）的时段合成图进行了分析。     

Correcting for the solar wind in pulsar timing observations: the role of simultaneous and low-frequency observations

The primary goal of pulsar timing array projects is to detect ultra-low-frequency gravitational waves. Pulsar data sets are affected by numerous noise processes including varying dispersive delays in the interstellar medium and from the solar wind. The solar wind can lead to rapidly changing variations that, with existing telescopes, can be hard to measure and then remove. In this paper we study the possibility of using a low frequency telescope to aid in such correction for the Parkes Pulsar Timing Array(PPTA) and also discuss whether the ultra-wide-bandwidth receiver for the FAST telescope is sufficient to model solar wind variations. Our key result is that a single wide-bandwidth receiver can be used to model and remove the effect of the solar wind. However, for pulsars that pass close to the Sun such as PSR J1022+1022, the solar wind is so variable that observations at two telescopes separated by a day are insufficient to correct the solar wind effect.     

Comet Hyakutake (C/1996 B2): Spectacular disconnection event and the latitudinal structure of the solar wind

Images of comet Hyakutake (C/1996 B2) are analyzed in conjunction with solar wind data from spacecraft to determine the relationship between solar wind conditions and plasma tail morphology. The disconnection event (DE) on March 25, 1996 is analyzed with the aid of data from the IMP-8 and WIND Earth-orbiting spacecraft and the DE is found to be correlated with a crossing of the heliospheric current sheet. The comet was within of Earth at the time of the DE and data from IMP-8 and WIND show no high-speed streams, significant density enhancements or shocks.The latitudinal variation in the appearance and orientation of the plasma tail are interpreted based on results from the Ulysses spacecraft. In the polar solar wind region, the comet has a relatively undisturbed appearance, no DEs were observed, and the orientation of the plasma tail was consistent with a higher solar wind speed. In the equatorial solar wind region, the comet's plasma tail had a disturbed appearance, a major DE was observed, and the orientation of the plasma tail was consistent with a lower solar wind speed. The boundary between the equatorial and polar regions crossed by comet Hyakutake in April 1996 was near 30°N (ecliptic) or 24°N (solar) latitude.     

Study of cosmic ray intensity in relation to the interplanetary magnetic field and geomagnetic storms for solar cycle 24

In the present study, we investigate the association of cosmic ray intensity (CRI) with various solar wind parameters (i.e. solar wind speed V, plasma proton temperature, plasma proton density), interplanetary magnetic field (IMF B), geomagnetic storms (GSs), averaged planetary A-index (Ap index) and sun spot number (SSN) for the period 2009–2016 (solar cycle 24) by using their daily mean average. To find the association of CRI with various solar wind parameters, GSs, IMF B, Ap index and SSN, we incorporate the analysis technique by superposed-epoch method. We have observed that CRI decreases with the increase in IMF B. Moreover the time-lag analysis has been performed by the method of correlation coefficient and observed a time lag of 0 to 2 day between the decrease in CRI and increase in IMF B. In addition, we show that the CRI is found to decrease in a similar pattern to disturbance storm time (Dst index) for most of the period of solar cycle 24. The high and positive correlation is found between CRI and Dst index. The CRI and Ap index are better anti-correlated to each other than CRI and IMF. CRI and SSN are positively correlated with each other. Solar wind parameters such as solar wind speed V is a CR-effective parameter while plasma proton temperature and plasma proton density are not CR-effective parameters. The indicated parameters such as Dst index, Ap index, IMF B and solar wind parameters such as solar wind speed V, plasma proton temperature, plasma proton density shows a kind of irregular variations for solar cycle 23 and 24 while CRI and SSN shows distinct behaviour for the two cycle.     

Sharp Changes of Solar Wind Ion Flux and Density Within and Outside Current Sheets

Analysis of the Interball-1 spacecraft data (1995 – 2000) has shown that the solar wind ion flux sometimes increases or decreases abruptly by more than 20% over a time period of several seconds or minutes. Typically, the amplitude of such sharp changes in the solar wind ion flux (SCIFs) is larger than 0.5×10⁸ cm⁻² s⁻¹. These sudden changes of the ion flux were also observed by the Solar Wind Experiment (SWE), on board the Wind spacecraft, as the solar wind density increases and decreases with negligible changes in the solar wind velocity. SCIFs occur irregularly at 1 AU, when plasma flows with specific properties come to the Earth’s orbit. SCIFs are usually observed in slow, turbulent solar wind with increased density and interplanetary magnetic field strength. The number of times SCIFs occur during a day is simulated using the solar wind density, magnetic field, and their standard deviations as input parameters for a period of five years. A correlation coefficient of ∼0.7 is obtained between the modelled and the experimental data. It is found that SCIFs are not associated with coronal mass ejections (CMEs), corotating interaction regions (CIRs), or interplanetary shocks; however, 85% of the sector boundaries are surrounded by SCIFs. The properties of the solar wind plasma for days with five or more SCIF observations are the same as those of the solar wind plasma at the sector boundaries. One possible explanation for the occurrence of SCIFs (near sector boundaries) is magnetic reconnection at the heliospheric current sheet or local current sheets. Other probable causes of SCIFs (inside sectors) are turbulent processes in the slow solar wind and at the crossings of flux tubes.     

Remote sensing of the heliospheric solar wind using radio astronomy methods and numerical simulations

The ground-based radio astronomy method of interplanetary scintillations (IPS) and spacecraft observations have shown, in the past 25 years, that while coronal holes give rise to stable, reclining high speed solar wind streams during the minimum of the solar activity cycle, the slow speed wind seen more during the solar maximum activity is better associated with the closed field regions, which also give rise to solar flares and coronal mass ejections (CME’s). The latter events increase significantly, as the cycle maximum takes place. We have recently shown that in the case of energetic flares one may be able to track the associated disturbances almost on a one to one basis from a distance of 0.2 to 1 AU using IPS methods. Time dependent 3D MHD models which are constrained by IPS observations are being developed. These models are able to simulate general features of the solar-generated disturbances. Advances in this direction may lead to prediction of heliospheric propagation of these disturbances throughout the solar system.     

Solar Modulation of Cosmic Rays during the Declining and Minimum Phases of Solar Cycle 23: Comparison with Past Three Solar Cycles

We study solar modulation of galactic cosmic rays (GCRs) during the deep solar minimum, including the declining phase, of solar cycle 23 and compare the results of this unusual period with the results obtained during similar phases of the previous solar cycles 20, 21, and 22. These periods consist of two epochs each of negative and positive polarities of the heliospheric magnetic field from the north polar region of the Sun. In addition to cosmic-ray data, we utilize simultaneous solar and interplanetary plasma/field data including the tilt angle of the heliospheric current sheet. We study the relation between simultaneous variations in cosmic ray intensity and solar/interplanetary parameters during the declining and the minimum phases of cycle 23. We compare these relations with those obtained for the same phases in the three previous solar cycles. We observe certain peculiar features in cosmic ray modulation during the minimum of solar cycle 23 including the record high GCR intensity. We find, during this unusual minimum, that the correlation of GCR intensity is poor with sunspot number (correlation coefficient R=?0.41), better with interplanetary magnetic field (R=?0.66), still better with solar wind velocity (R=?0.80) and much better with the tilt angle of the heliospheric current sheet (R=?0.92). In our view, it is not the diffusion or the drift alone, but the solar wind convection that is the most likely additional effect responsible for the record high GCR intensity observed during the deep minimum of solar cycle 23.     

地球大气边界层结构和天文视宁度

依据声雷达资料和其他边界层资料讨论了大气边界层结构、地形等对视宁度的影响和有关选址问题．     

Preferred bartels days of high-speed plasma streams in the solar wind

An analysis of 346 high-speed solar wind streams observed at 1 AU during 1964–75 is presented. The analysis shows that a two-sector structure was the dominant feature of the interplanetary magnetic field associated with the high-speed solar wind plasma. The high-speed streams occurred at preferred Bartels days: Positive polarity streams were most frequent near Bartels day 4, negative polarity streams were most frequent near Bartels day 17. Since the solar wind carries with it the photospheric magnetic polarity of the solar source region, the observed distribution of Bartels days must indicate a fundamental property of the distribution of the solar sources of high-speed plasma streams. The observations are explained in terms of a tilted dipole model of the solar-interplanetary field.Proceedings of the 14th ESLAB Symposium on Physics of Solar Variations, 16–19 September 1980, Scheveningen, The Netherlands.     

Galactic Cosmic Ray Modulation near the Heliospheric Current Sheet

Galactic cosmic rays (GCRs) are modulated by the heliospheric magnetic field (HMF) both over decadal time scales (due to long-term, global HMF variations), and over time scales of a few hours (associated with solar wind structures such as coronal mass ejections or the heliospheric current sheet, HCS). Due to the close association between the HCS, the streamer belt, and the band of slow solar wind, HCS crossings are often associated with corotating interaction regions where fast solar wind catches up and compresses slow solar wind ahead of it. However, not all HCS crossings are associated with strong compressions. In this study we categorize HCS crossings in two ways: Firstly, using the change in magnetic polarity, as either away-to-toward (AT) or toward-to-away (TA) magnetic field directions relative to the Sun and, secondly, using the strength of the associated solar wind compression, determined from the observed plasma density enhancement. For each category, we use superposed epoch analyses to show differences in both solar wind parameters and GCR flux inferred from neutron monitors. For strong-compression HCS crossings, we observe a peak in neutron counts preceding the HCS crossing, followed by a large drop after the crossing, attributable to the so-called ‘snow-plough’ effect. For weak-compression HCS crossings, where magnetic field polarity effects are more readily observable, we instead observe that the neutron counts have a tendency to peak in the away magnetic field sector. By splitting the data by the dominant polarity at each solar polar region, we find that the increase in GCR flux prior to the HCS crossing is primarily from strong compressions in cycles with negative north polar fields due to GCR drift effects. Finally, we report on unexpected differences in GCR behavior between TA weak compressions during opposing polarity cycles.