近邻宜居行星巡天计划:利用空间天体测量法寻找下一个“地球”

近邻宜居行星巡天计划(Closeby Habitable Exoplanet Survey,CHES)采用空间微角秒级别的高精度天体测量技术,普查太阳系近邻(10 pc内)约100颗FGK等类型恒星,探测宜居带类地行星或超级地球;详细普查宜居行星的数目、真实质量和三维轨道等信息,这将是国际上首次近邻宜居带类地行星的空间探测任务.CHES的有效载荷是一台口径为1.2 m,视场为0.44°×0.44°,焦距为36 m的高像质、低畸变、高稳定光学望远镜,采用同轴三反TMA光学成像系统.为实现宜居带类地行星探测,CHES任务中的测量精度为1μas,是目前国际测量精度最高的空间探测项目.在空间科学先导专项背景型号项目的支持下,CHES团队深入凝练和论证科学目标,成功突破了三项关键技术难题:实现了畸变大视场高像质空间望远镜光学系统技术的重要突破;突破了10–5 pixel级别星间距测量技术;实现了卫星系统高稳定度姿态控制精度及热控精度的创新.CHES预计发现50颗类地行星,引领中国空间科学探测技术的跨越式发展.

Analysis of prospecting polymetallic metallogenic belts by comprehensive geophysical method

This paper is based on the analysis and research on the silver-lead-zinc polymetallic ore in New Ballyhoo Banner in southern Manzhouli of Inner Mongolia.Because metal mineralization brings rock formations,the geophysical features such as low resistivity,high polarization rate and uneven distribution of magnetization,the comprehensive geophysical methods are adopted including high-precision magnetic measurement,high-power induced polarization,IP field middle gradient and controlled source audio-frequency magnetotellurics.In the survey work of multi-metal ore deposits,from surface sweeping to single point measurement,and from single point to section going deeper layer by layer,the resolution of measurement is continuously improved,and various geophysical methods support and complement each other,so explorers can successfully predict the direction,scale and volume of the metallogenic belts in conjunction with geochemical exploration,geological survey and drilling.It has provided a strong basis for completing the exploration task of predicting the reserve volume of ore bodies.The research conclusions of this exploration case have thus a high reference value in the same type of exploration work.

Combination of terrestrial reference frames based on space geodetic techniques in SHAO:methodology and main issues

Based on years of input from the four geodetic techniques （SLR, GPS, VLBI and DORIS）, the strategies of the combination were studied in SHAO to generate a new global terrestrial reference frame as the material realization of the ITRS defined in IERS Conventions. The main input includes the time series of weekly solutions （or fortnightly for SLR 1983-1993） of observational data for satellite techniques and session-wise normal equations for VLBI. The set of estimated unknowns includes 3- dimensional Cartesian coordinates at the reference epoch 2005.0 of the stations distributed globally and their rates as well as the time series of consistent Earth Orientation Parameters （EOPs） at the same epochs as the input. Besides the final solution, namely SOL-2, generated by using all the inputs before 2015.0 obtained from short-term observation processing, another reference solution, namely SOL- 1, was also computed by using the input before 2009.0 based on the same combination of procedures for the purpose of comparison with ITRF2008 and DTRF2008 and for evaluating the effect of the latest six more years of data on the combined results. The estimated accuracy of the x-component and y-component of the SOL- 1 TRF-origin was better than 0.1 mm at epoch 2005.0 and better than 0.3 mm yr- 1 in time evolution, either compared with ITRF2008 or DTRF2008. However, the z-component of the translation parameters from SOL-1 to ITRF2008 and DTRF2008 were 3.4 mm and -1.0 ram, respectively. It seems that the z-component of the SOL-1 TRF-origin was much closer to the one in DTRF2008 than the one in ITRF2008. The translation parameters from SOL-2 to ITRF2014 were 2.2, -1.8 and 0.9 mm in the x-, y- and z-components respectively with rates smaller than 0.4 mmyr-1. Similarly, the scale factor transformed from SOL-1 to DTRF2008 was much smaller than that to ITRF2008. The scale parameter from SOL-2 to ITRF2014 was -0.31 ppb with a rate lower than 0.01 ppb yr-1. The external precision （WRMS） compared with IERS EOP 08 C04 of the combined EOP series was smaller than 0.06 mas for the polar motions, smaller than 0.01 ms for the UT1-UTC and smaller than 0.02 ms for the LODs. The precision of the EOPs in SOL-2 was slightly higher than that of SOL-1.

Improved astrometry of space debris with image restoration

In order to implement an observing strategy, image degradation that occurs during optical observation of space debris is ineluctable and has distinct characteris- tics. Image restoration is presented as a way to remove the influence of degradation in CCD images of space debris, based on assumed PSF models with the same F-WHM as images of the object. In the process of image restoration, the maximum entropy method is adopted. The results of reduction using observed raw CCD images indi- cate that the precision in estimating positions of objects is improved and the effects of degradation are reduced. Improving the astrometry of space debris using image restoration is effective and feasible.

An improved astrometric calibration technique for space debris observation

An optical survey is the main technique for detecting space debris. Due to the specific character- istics of observation, the pointing errors and tracking errors of the telescope as well as image degradation may be significant, which make it difficult for astrometric calibration. Here we present an improved method that corrects the pointing and tracking errors, and measures the image position precisely. The pipeline is tested on a number of CCD images obtained from a 1-m telescope administered by Xinjiang Astronomical Observatory while observing a GPS satellite. The results show that the position measurement error of the background stars is around 0.1 pixel, while the time cost for a single frame is about 7.5 s; hence the relia- bility and accuracy of our method are demonstrated. In addition, our method shows a versatile and feasible way to perform space debris observation utilizing non-dedicated telescopes, which means more sensors could be involved and the ability to perform surveys could be improved.

Astrometric calibration of the Xuyi Schmidt Telescope Photometric Survey of the Galactic Anti-center(XSTPS-GAC)

Abstract We present astrometric calibration of the Xuyi Schmidt Telescope Photometric Survey of the Galactic Anti-center （XSTPS-GAC）. XSTPS-GAC is the photometric part of the Digital Sky Survey of the Galactic Anti-center （DSS-GAC）, which is a photometric and spectroscopic sky survey, in combination with LAMOST. In order to select an astrometric reference catalog, we made comparisons between the four widely used astrometric catalogs, GSC2.3, USNO-B1.0, UCAC3 and PPMXL. PPMXL shows relatively small systematic errors in positions and more homogeneous proper motion distributions toward the Galactic Anti-center （GAC）, and was selected as the reference catalog. Based on the high quality and bright reference stars that were picked out from PPMXL, we performed a 4th-order polynomial fitting in image units, to construct the transformation relation between coordinates used by XSTPS-GAC and standard coordinates, and to simultaneously correct the image distortions in the CCD. Then we applied the derived relation to all sources to obtain their mean celestial coordinates based on the Intemational Celestial Reference System. For bright point sources with r 〈 17.0 mag, the accuracy of astrometric calibration could reach about 80 mas for each of the g, r, i bands, with systematic errors being less than 10 mas. But for the faint sources at the brightness limit of the survey, which was r - 19.0 mag, the accuracy can still reach 200 mas. After combining all observations, the final weighted average coordinates could reach an accuracy of less than 70 mas for bright stars. For faint stars, the rms residuals of weighted coordinates decrease to -110 mas. The final combined XSTPS-GAC coordinates show a good consistency with the Sloan Digital Sky Survey.

An improved solution to geometric distortion using an orthogonal method

The geometric distortion of a CCD field of view has a direct influence on the positional measurements of CCD observations. In order to obtain high precision astrometric results, the geometric distortion should be derived and corrected precisely. As presented in our previous work, a convenient solution has been carried out and has also been applied to observations of Phoebe. In order to fur- ther improve the solution, an orthogonal method based on Zernike polynomials is used in this work. Four nights of CCD observations including Himalia, the sixth satellite of Jupiter, and open clusters （NGC 1664 or NGC 2324） on each night have been processed as an application. The observations were obtained from the 2.4 m telescope administered by Yunnan Observatories. The catalog UCAC4 was used to match reference stars in all of the CCD frames. The ephemeris of Himalia is retrieved from the Institut de M6canique C61este et de Calcul des Ephemerides （IMCCE）. Our results show that the means of observed minus calculated （O - C） positional residuals are -0.034 and -0.026 arcsec in right ascension and declination, respectively. The corresponding standard deviations are 0.031＂ and 0.028＂. The measurement dispersion is significantly improved compared to that by using our previous solution.

High-precision method for measuring the photothermal properties of transparent media with digital holography

Quantitative phase microscopy by digital holography provides direct access to the phase profile of a transparent subject with high precision. This is useful for observing phenomena that modulate phase, but are otherwise difficult or impossible to detect. In this letter, a carefully constructed digital holographic apparatus is used to measure optically induced thermal lensing with an optical path difference precision of less than 1 nm. Furthermore, by taking advantage of the radial symmetry of a thermal lens, such data are processed to determine the absorption coefficient of transparent media with precisions as low as 1 × 10-5cm-1 using low power （30 mW） continuous wave （CW） excitation.

CCD图像数字定心算法的比较

从CCD采集的数字图像中提取天体的位置和光度信息对于天文研究具有基础意义。其中,恒星星像中心像素位置的精确测量对于天体测量至关重要。针对国际上常用的三种位置测量算法:修正矩方法、Gauss拟合法和中值法,利用实测的CCD图像进行了试验研究。具体地,采用云南天文台1m望远镜观测的CCD图像同时使用这些算法进行了实际测量,根据每幅图像中测得的像素位置,对这三类定心算法进行了比较和精度分析。可视化方法被用于不同阈值的选取和设定比较。实验数据表明,无阈值的二维Gauss拟合方法是一种精度相对较高的定心算法。

NTSC守时氢钟性能分析

首先对NTSC(National Time Service Center)守时实验室的氢原子钟进行了测试,为了规避铯原子钟噪声较大的影响,没有采用TA(k)或UTC(k)作为参考,而是以4台氢原子钟互为参考进行测试,利用四角帽法对氢原子钟的频率稳定度进行分析,估计出单台氢原子钟在不同取样时间上的Allan标准差.然后根据氢原子钟的特性,扣除趋势项,剔除异常值,利用数学方法平滑,分离出了氢原子钟的高斯噪声,并且通过了Kolmogorov-Smirnov检验,估计出单台氢原子钟高斯噪声.

计时观测测量脉冲星参数的数学模型与精度估计

脉冲星计时观测能够精确测量脉冲星自转参数和天体测量参数.概述了脉冲星计时模型和利用最小二乘拟合测量脉冲星各个参数并估计其方差的数学方法.在黄道坐标系导出了脉冲星各个参数误差与计时残差之间关系的数学表达式.给出了脉冲星黄经、黄纬和周年视差测量精度与脉冲星黄纬绝对值之间的关系曲线.讨论了脉冲星各个天体测量参数测量精度与脉冲星纬向参数本身的关系.

广义回归神经网络在日长变化预报中的应用

传统的日长变化预报多是基于线性模型,如最小二乘模型、自回归模型等,但是日长变化包含了复杂的非线性因素,线性模型预报的效果往往不甚理想.所以尝试使用一种非线性神经网络—广义回归神经网络(GRNN)模型进行日长变化预报,并将结果与使用BP(Back Propagation)神经网络模型和其它模型的预报结果进行比较.结果表明,GRNN用于日长变化预报是高效可行的.

区域GPS网实测电离层变化和卫星硬件延迟的可靠性研究

根据高精度卫星导航定位的实际需要,介绍了利用中国GPS区域网双频相位平滑伪距实测数据,准实时监测区域网电离层电子总含量(TEC)变化和GPS卫星硬件延迟(DCB)的方法和结果.着重研究了区域网独立测定DCB的可靠性,利用中国境内的GPS站点分别构造了3个大小不同的区域网,通过实测DCB和垂直电子总含量(VTEC)与CODE(Center for Orbit Determination in Europe)结果的比对表明:为了获得区域网准实时测定DCB的可靠结果,对区域网的大小有一定的要求;利用中国GPS区域网,准实时测定的VTEC和DCB的比较精度可达2.0 TECu和0.25 ns.

一种改进钟差二次多项式模型的导航卫星钟差预报方法

为了更好地反映钟差特性并提高其预报精度,建立一种能够同时考虑星载原子钟物理特性、钟差周期性变化与随机性变化特点的钟差预报模型.首先采用附有周期项的二次多项式模型进行拟合提取卫星钟差(Satellite Clock Bias,SCB)的趋势项与周期项,然后根据拟合残差的特点采用时间序列ARIMA(Auto-Regressive Integrated Moving Average)模型对残差进行建模;最后将两种模型的预报结果结合得到最终钟差预报值.使用IGS(International GNSS Service)精密钟差数据进行预报试验,将新方法与二次多项式模型、灰色模型及ARIMA模型进行对比,证明了新方法能够更高精度地预报卫星钟差,且可以一定程度上改善ARIMA存在模型识别与定阶不准的不足.

大气角动量函数在日长变化非线性预报中的重要作用

日长变化具有复杂的时变特性,传统的线性时间序列分析方法往往难以取得良好的预报效果.采用非线性人工神经网络技术对日长变化进行预报,网络模型的拓扑结构由最小均方误差法来确定.考虑到日长变化与大气环流运动间的密切关系,在神经网络预报模型中引入轴向大气角动量序列.结果表明,联合日长和大气角动量序列,比起单独采用日长资料,预报精度得到显著的提高.

灰色模型修正及其在实时GPS卫星钟差预报中的应用研究

在GPS实时精密单点定位中,卫星钟差的实时可靠预报是实现GPS实时高精度单点定位的关键之一.星载GPS原子钟频率高,非常敏感,极易受到外界及其本身因素的影响,从而很难掌握其复杂细致的变化规律,这些属性符合灰色系统理论的特点.因此,考虑将钟差的变化过程看作一个灰色系统.在探讨二次多项式和灰色模型卫星钟差预报局限性基础上,提出了利用改进的灰色模型实时预报GPS卫星钟差的研究,最后利用3个不同时段的GPS卫星钟差资料进行不同采样间隔钟差预报精度分析、灰色模型指数系数与预报精度的关系、与二次多项式预报精度比较分析,总结不同卫星钟差类型与模型指数系数的一般关系,并与IGS最终钟差星历产品比较,验证本文提出的改进预报模型的可行性和有效性.为实时GPS动态精密单点定位提供较高精度的卫星钟差产品.

Crab脉冲星X射线计时观测数据处理与分析

对我国公开发布的空间试验卫星X射线探测器观测Crab脉冲星的数据进行了处理与分析,描述了利用X射线脉冲星观测数据与卫星轨道数据建立积分脉冲轮廓与标准脉冲轮廓的方法,给出了在频域测量脉冲星脉冲到达时刻(toa)的原理方法与算法.利用每组观测数据,计算得到Crab脉冲星脉冲toa,通过与Crab脉冲星星历预报脉冲toa的比较,分析得到卫星载荷X射线探测器观测Crab脉冲星,在消除掉系统误差后,50 min积分时间的观测精度约14μs.

BDS/GPS接收机系统间偏差稳定性分析

接收机系统间偏差(Inter-System Bias,ISB)稳定性分析对于了解ISB误差特性和建模预报具有重要意义.为了分析ISB的长期稳定性,选择MGEX(Multiple Global Navigation Satellite System Experiment)网2014—2016年每年各1周的数据,分别采用武汉大学和德国地学研究中心提供的精密钟差和轨道产品,利用BDS(Bei Dou Navigation Satellite System)/GPS(Global Positioning System)组合精密单点定位(Precise Point Positioning,PPP)计算测站的ISB值,并对ISB的日稳定性和周稳定性进行了深入分析.实验结果表明:ISB的日变化比较稳定,日标准差平均值约为0.5 ns.不同年份数据的ISB周平均值和周标准差的差异较大,并且ISB周平均值与测站的接收机类型有关.采用不同精密产品计算得到的ISB之间存在系统性偏差,对于同一周不同测站的ISB周平均值,该系统性偏差一致性较好.

上海地区地基GPS水汽三维层析技术和初步应用

地基GPS(Global Positioning System)探测大气水汽主要包括3个方面的内容:一是观测天顶方向的大气水汽总量(Precipitable Water vapor,PW);二是遥测倾斜的信号路径上的水汽总量(Slant-path Water vapor,SW);三是应用组网的GPS站倾斜路径观测反演局地上空的水汽三维信息,即水汽层析(watervapor tomography)技术.简单介绍了上海地区稠密的地基GPS网,并且在该网的基础上通过GAMIT软件计算出的整层水汽PW和各个方向上的梯度信息及观测残差,来获得GPS测定的SW,运用层析的技术可获得上海地区水汽的三维分布信息.以2008年8月25日上海罕见的大暴雨为例,分析了水汽三维结果在强对流天气中的应用.

GPS BLOCK IIF星载原子钟长期性能分析

星载原子钟长期性能的分析对于系统完好性监测、卫星钟差确定与预报等具有重要的作用.GPS最新型的BLOCK IIF系列卫星于2016年2月6日部署完成.通过星载原子钟的频率准确度、频率漂移率、频率稳定度、观测噪声水平和钟差周期特性这5个指标的长期变化,分析评估了GPS BLOCK IIF星载原子钟的长期性能.计算分析表明:铷钟的频率准确度为7.1×10^(-12)±2.1×10^(-13),频率漂移率为(5.5×10^(-14)±1.1×10^(-14))/d,平均噪声水平约为0.2 ns;铯钟的频率准确度为1.0×10^(-12)±2.9×10^(-15),频率漂移率为(3.4×10^(-15)±5.4×10^(-16))/d,平均噪声水平约为1.0 ns,并且指标变化相对平稳;铷钟的2 h、6 h、12 h和天稳定度分别为3.4×10^(-14)、2.3×10^(-14)、7.3×10^(-15)与6.0×10^(-15);铯钟对应的稳定度指标分别为1.9×10^(-13)、1.1×10^(-13)、7.9×10^(-14)和5.5×10^(-14);卫星钟差存在显著周期项,主周期分别近似为卫星轨道周期的1/2、1倍或2倍.