天文光子学研究现状及其应用展望

天文学是一门观测学科, 其发展受观测技术及仪器进步所推动, 而天文科学发展同样不断对观测仪器提出新的要求. 天文学发展至今, 对观测仪器的要求逐渐走向极致和极端, 这在实现成本及难度两方面均带来极大挑战. 为应对上述挑战, 基于新原理、新技术的下一代天文光学技术及观测仪器已成为天文学发展的内在需要. 近年来, 集成光子学的发展为天文光学技术带来了新的变革性机遇, 在此基础上产生的新兴交叉学科天文光子学(Astrophotonics)可为天文观测提供低成本、高度集成化(芯片化)的新一代高性能光学终端仪器, 这类仪器将在空间天文观测、大规模光谱巡天、高分辨高精度光谱成像等应用中起到关键作用. 主要从仪器/器件功能出发介绍天文光子学主要研究内容及现状, 并简要讨论其发展所面临的主要问题, 最后对其发展趋势做出展望.     

Research Status and Application Prospects of Astrophotonics

Astronomy is an observational discipline, and its improvement is driven by the progress of observation technology and instruments. The advancement of astronomy also constantly puts forward new requirements for observation instruments. Since the development of astronomy, the requirements for observing instruments have gradually become extreme, which brings great challenges in both cost and difficulty. In order to tackle the challenges, a future generation of astronomical optical technology and observation instruments based on new principles and technologies has become an inherent need to promote the advancement of astronomy. In recent years, the growth of integrated photonics has presented revolutionary opportunities for that of astronomical optical technology. On the basis, astrophotonics, an emerging interdisciplinary subject, can provide a new generation of high-performance optical terminal instruments with low cost and high integration (chip-based) for astronomical observation. Such instruments will play a vital role in space astronomical observation, large-scale spectral survey, high-resolution and high-precision spectral imaging, and other applications. This paper mainly introduces the main research contents and status quo of astronomical photonics starting from the instruments/device functions, briefly discusses the major problems in its development, and eventually forecasts its development prospect.     

AstroGridCEA架构的应用研究

AstroGrid是一个成熟并已广泛运用的英国虚拟天文台（VO-Virtual Observatory）项目。公共执行架构（Common Execution Architecture,CEA）作为其重要组成部分,通过构建一套合理的接口和框架实现对虚拟天文台天文应用执行过程的建模。详细介绍了AstroGrid CEA的实现原理、基本架构、接口分析和应用模型,并通过CEA实现中国科学技术大学光谱处理数据的发布,完成基于FITS格式的锥型检索服务,最后在此基础上就如何运用CEA进行完整的讨论。     

AstroGrid CEA架构的应用研究

AstroGrid是一个成熟并已广泛运用的英国虚拟天文台(VO-Virtual Observatory)项目。公共执行架构(Common Execution Architecture,CEA)作为其重要组成部分,通过构建一套合理的接口和框架实现对虚拟天文台天文应用执行过程的建模。详细介绍了AstroGrid CEA的实现原理、基本架构、接口分析和应用模型,并通过CEA实现中国科学技术大学光谱处理数据的发布,完成基于FITS格式的锥型检索服务,最后在此基础上就如何运用CEA进行完整的讨论。     

应用自适应光学望远镜所取得的天文观测成果

自适应光学技术已经成为现代地基天文光学望远镜的重要部分。在世界各地的天文台中 ,许多大型光学望远镜的自适应光学系统正在建造 ,不少的系统已经投入使用。自适应光学技术经过二十多年的发展 ,取得了越来越多的令人激动的天文观测成果 ,自适应光学正在接近成熟并正向天文实际应用的阶段转化。本文根据近几年来自适应光学望远镜在天文中的应用 ,对其所取得的天文成果给予介绍 ,并讨论了自适应光学系统所能开展的天文研究课题。     

Building a VO-compliant Radio Astronomical DAta Model for Single-dish radio telescopes (RADAMS)

The Virtual Observatory (VO) is becoming the de-facto standard for astronomical data publication. However, the number of radio astronomical archives is still low in general, and even lower is the number of radio astronomical data available through the VO. In order to facilitate the building of new radio astronomical archives, easing at the same time their interoperability with VO framework, we have developed a VO-compliant data model which provides interoperable data semantics for radio data. That model, which we call the Radio Astronomical DAta Model for Single-dish (RADAMS) has been built using standards of (and recommendations from) the International Virtual Observatory Alliance (IVOA). This article describes the RADAMS and its components, including archived entities and their relationships to VO metadata. We show that by using IVOA principles and concepts, the effort needed for both the development of the archives and their VO compatibility has been lowered, and the joint development of two radio astronomical archives have been possible. We plan to adapt RADAMS to be able to deal with interferometry data in the future.     

天文学中的数据挖掘和知识发现

综述了数据挖掘和知识发现在天文学中兴起的必然性及其这几年的发展状况、实现过程和具体任务。分析了当前天文数据的复杂性，介绍了天文学中数据挖掘的科学要求。系统地概括了近年来天文学中数据挖掘和知识发现领域研究的进展及其热点，并阐述了其所面临的挑战。天文学中的数据挖掘和知识发现的兴起将对天文学的发展起到巨大的推动作用，同时也在知识和技术等方面对天文学家提出了新的要求。另外，数据挖掘技术能否在虚拟天文台中成功应用，是虚拟天文台充分发挥作用的关键所在。     

Astrophysical Radiation Dynamics: The Prospects for Scaling

The general principles of scaling are discussed, followed by a survey of the important dimensionless parameters of fluid dynamics including radiation and magnetic fields, and of non-LTE spectroscopy. The values of the parameters are reviewed for a variety of astronomical and laboratory environments. It is found that parameters involving transport coefficients – the fluid and magnetic Reynolds numbers – have enormous values for the astronomical problems that are not reached in the lab. The parameters that measure the importance of radiation are also scarcely reached in the lab. This also means that the lab environments are much closer to LTE than the majority of astronomical examples. Some of the astronomical environments are more magnetically dominated than anything in the lab. The conclusion is that a good astronomical environment for simulation in a given lab experiment can be found, but that the reverse is much more difficult. PACS NOS: 95.30.Jx, 95.30.Lz, 97.10.Ex, 97.10.Gz, 98.62.Mw The U.S. Government’s right to retain a non-exclusive, royalty-free license in and to any copyright is acknowledged.     

An exceptional cosmic influence and its bearing on the evolution of human culture as evident in the apparent early development of mathematics and astronomy

The proposal that cometary dust particles play a significant role in the emergence and evolution of both life and disease on suitable planets was first made some 25 years ago by Hoyle and Wickramasinghe. Fundamental to this proposal was a process of punctuated seeding by particular (bio)chemical species believed to originate naturally and predominantly in larger comets, say those with diameters greater than about 100 kilometres. Rather less well known is a parallel proposal likewise favoured by Hoyle that a particular giant comet, the most recent to settle in cis-Jovian space, accounting for the latest significant phase of evolution on Earth, also had a significant part to play in the cultivation by homo sapiens of its civilization and culture. Such proposals may be seen by many as examples of excessively lateral thinking but they by no means lack independent support and have important implications for the otherwise uncertain origin of the latest ice-age (basic to climatology) and for the otherwise uncertain generation of early calendars (basic to the management of society). Aspects of these proposals are considered here in relation to a much respected supposedly Chaldean calendar probably passed down by the dynastic Isins (also the Essenes?) which evidently bears witness to known early mathematical and astronomical skills but which largely ceased to be available to subsequent scholarship beyond the Early Christians (ca. 100 CE) pending its (recent) recovery through the medium of Dead Sea Scrolls.     

Astronomical image data compression by morphological skeleton transformation

Astronomical instruments currently provide a large amount of data. Nowadays, a large part of these data are image frames obtained with receivers of increasing size. The scan of large astronomical plates using fast microdensitometers gives image frames of over 30000×30000 pixels. More and more often, images are transmitted over a network in order to control the observations, to process the data, and to examine or to fill a data bank. The time taken for archiving, the cost of communication, the available memory given by magnetic tapes, and the limited bandwidth of transmission lines are reasons which lead us to examine the data compression of astronomical images.The astronomical image has the characteristic of being a set of astronomical sources in the sky background whose values are not zero. We are, in fact, only interested in the astronomical sources. Once a suitable detection is made, we generally want a compression without any distorsion. In this paper, we present a method which can be adapted for this purpose. It is based on morphological skeleton transformations. The experimental results show that it can give us an efficient compression. Moreover, the flexibility of choosing a structure element adapted to different images and the simplicity of implementation are other advantages of this method. Because of these characteristics, different compression applications may be treated.     

Tectonic framework of grooved terrain on ganymede

An analysis of the tectonic features (grooves and prominent troughs) comprising grooved terrain on Ganymede shows a global tectonic framework. Domains of grooves, bordered by deep structural boundaries that controlled their extent and orientation, developed along preferred orientations. Some of these directions are much more prominent than others and appear to coincide with at least two great circles with pole locations at 152° long. 55° lat. and 65° long. and 50° lat. The great circle hypothesis is in good agreement with several statistical tests of the data set. Several mechanisms for the emplacement of grooved areas along great circles are discussed. A plausible mechanism is a pattern of equatorial-symmetric rising and descending convection cells. Because the studied areas represent only a small portion of Ganymede, interpretations of global tectonic patterns and models of formation must remain tentative.     

Enhanced management of personal astronomical data with FITSManager

Although the roles of data centers and computing centers are becoming more and more important, and on-line research is becoming the mainstream for astronomy, individual research based on locally hosted data is still very common. With the increase of personal storage capacity, it is easy to find hundreds to thousands of FITS files in the personal computer of an astrophysicist. Because Flexible Image Transport System (FITS) is a professional data format initiated by astronomers and used mainly in the small community, data management toolkits for FITS files are very few. Astronomers need a powerful tool to help them manage their local astronomical data. Although Virtual Observatory (VO) is a network oriented astronomical research environment, its applications and related technologies provide useful solutions to enhance the management and utilization of astronomical data hosted in an astronomer’s personal computer. FITSManager is such a tool to provide astronomers an efficient management and utilization of their local data, bringing VO to astronomers in a seamless and transparent way. FITSManager provides fruitful functions for FITS file management, like thumbnail, preview, type dependent icons, header keyword indexing and search, collaborated working with other tools and on-line services, and so on. The development of the FITSManager is an effort to fill the gap between management and analysis of astronomical data.     

黑洞证认的新进展

黑洞是广义相对论的一个重要理论问题，它的存在与否一直是物理学家和天文学家关心的焦点。特别是由于近几年大量先进的观测设备投入使用和观测方法的改进，使得黑洞证认工作有了巨大的进展，成为当今天文学的一个热点。重点综述了恒星级黑洞和星系核的超大质量黑洞的各种天文观测证据，并介绍了与黑洞相关的天体物理学的一些重要前沿。讨论了正在开展的国际重大项目和探索原初黑洞的初步结果，并且展望了未来寻找黑洞天文观测证据的前景和对观测研究的建议。     

Robotic optical telescopes global network MASTER II. Equipment, structure, algorithms

Presented paper describes the basic principles and features of the implementation of a robotic network of optical telescopes MASTER, designed to study the prompt (simultaneous with gamma radiation) optical emission of gamma-ray bursts and to perform the sky survey to detect unknown objects and transient phenomena. With joint efforts of Sternberg astronomical institute, High altitude astronomical station of the Pulkovo observatory, Ural state university, Irkutsk state university, Blagoveshchensk pedagogical university, the robotic telescopes MASTER?II near Kislovodsk, Yekaterinburg, Irkutsk and Blagoveshchensk were installed and tested. The network spread over the longitudes is greater than 6?h. A further expansion of the network is considered.     

“Beautiful and cantankerous instruments”: telescopes, technology, and astronomy’s changing practice

Between the dedication of the 200” Hale Telescope in 1948 and the completion of today’s 8–10 m behemoths, astronomers’ most iconic symbol, the telescope itself—its design, its technology, and its use—was transformed as a research tool. The importance of this is deceptively simple: in astronomy, technological innovations have often led to new discoveries. Driven by the need to get as much observing time as possible and the desire to take advantage of the best observing conditions, modern observatories have experimented with new technologies and modes of collecting images and spectra. This entailed a re-casting of the telescope by astronomers and science managers as a factory of scientific data. At the same time, contemporary astronomers express considerable unease and apprehension about how these technological changes have altered, in ways subtle and profound, the nature of astronomical observing and what it meant to be an astronomer. This short essay addresses the issues associated with these recent changes in astronomical practice and their connections to astronomers’ desire for ever larger and more complex telescopes.     

Using Java for distributed computing in the Gaia satellite data processing

In recent years Java has matured to a stable easy-to-use language with the flexibility of an interpreter (for reflection etc.) but the performance and type checking of a compiled language. When we started using Java for astronomical applications around 1999 they were the first of their kind in astronomy. Now a great deal of astronomy software is written in Java as are many business applications. We discuss the current environment and trends concerning the language and present an actual example of scientific use of Java for high-performance distributed computing: ESA’s mission Gaia. The Gaia scanning satellite will perform a galactic census of about 1,000 million objects in our galaxy. The Gaia community has chosen to write its processing software in Java. We explore the manifold reasons for choosing Java for this large science collaboration. Gaia processing is numerically complex but highly distributable, some parts being embarrassingly parallel. We describe the Gaia processing architecture and its realisation in Java. We delve into the astrometric solution which is the most advanced and most complex part of the processing. The Gaia simulator is also written in Java and is the most mature code in the system. This has been successfully running since about 2005 on the supercomputer “Marenostrum” in Barcelona. We relate experiences of using Java on a large shared machine. Finally we discuss Java, including some of its problems, for scientific computing.     

30m级光学/红外望远镜的宽视场多目标光谱仪

宽视场多目标光谱仪具有宽波段、多分辨率模式和高通光效率的特点,是极大望远镜终端仪器使用率最高的通用型仪器. 30 m级望远镜的宽视场多目标光谱仪因体量和成本急剧增加而面临重要挑战,同时天文学的不断发展对天文新技术的发展提出了更高的要求,尤其是多个巡天项目对于多目标光谱后随观测的迫切需求.综述了几类宽视场多目标光谱仪的发展现状,介绍了国际3架30 m望远镜宽视场多目标光谱仪概念设计的最新进展和仪器特点,着重介绍了中国参与研制的30 m望远镜(TMT)中的宽视场多目标光谱仪的相关进展.     

The use of radar observations of Near-Earth Asteroids in the determination of the dynamical equinox

Near-Earth Asteroids (NEAs) are Solar system special class objects attracting the attention of astronomical community especially during several of the last decades. To some extent the NEAs have an advantage over the minor planets of the main belt: due to close and regular approaches to the Earth the radar observations of NEAs can be obtained for the greater number of objects than for those of the main belt of the minor planets. In this paper the use of all available radar observations together with optical ones resulting in the combined data analysis solution is discussed for different problems such as the asteroid orbits and catalog orientation parameters determination. In particular the problem of the motion of the dynamical equinox in the Hipparcos reference system is considered. About 13000 radar and optical observations of 24 NEAs and main belt minor planets have been used to obtain the precise asteroid orbits, FK5 catalogue orientation parameters and the motion of the dynamical equinox from 1750 till 2000 in the Hipparcos system.