射电望远镜馈源舱数字化模型的创建
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摘要
FAST是中国科学家自主设计与实现的口径最大、最具威力的巨型射电望远镜,将为未来天文学的发展、未知星体的发现提供丰富的研究资源。FAST的结构复杂多样,对FAST的结构与工作原理进行简单的介绍,对FAST中的馈源舱、停靠平台的工作原理与结构进行详细描述,并基于中标麒麟操作系统,采用跨平台,根据这两部分的图纸,对这两部分进行模型的创建,管理者可根据馈源舱、停靠平台的模型来了解其结构,将有助于对这两部分的工作机制进行模拟、维护或改进。
FAST is the largest and most powerful giant radio telescope designed and implemented by Chinese scientists, it provides abundant research resources for the development of future astronomy and the discovery of unknown stars. The structure of FAST is complex and diverse. The structure and working principle of FAST are briefly introduced. Describes the working principle and structure of the cabin and docking platforms in FAST in detail. And based on the Neokylin, using cross-platform, according to the drawings of these two parts, the model is created for these two parts. Managers can understand the structure of the cabin and docking platform model, which will help to simulate, maintain or improve the working mechanism of these two parts.
FAST is the largest and most powerful giant radio telescope designed and implemented by Chinese scientists, it provides abundant research resources for the development of future astronomy and the discovery of unknown stars. The structure of FAST is complex and diverse. The structure and working principle of FAST are briefly introduced. Describes the working principle and structure of the cabin and docking platforms in FAST in detail. And based on the Neokylin, using cross-platform, according to the drawings of these two parts, the model is created for these two parts. Managers can understand the structure of the cabin and docking platform model, which will help to simulate, maintain or improve the working mechanism of these two parts.
引文
[1]NAN R D. Five Hundred Meter Aperture Spherical Radio Telescope(FAST)[J]. Science in China:Series G Physics,Mechanics&Astronomy,2006,49(2):129-148.
[2]全球最大单口径射电望远镜在贵州落成启用.中国科学院,2016-09-25.
[3]南仁东,李会贤. FAST的进展——科学、技术与设备[J].中国科学:物理学力学天文学,2014,44(10):1063-1074.
[4]程志峰,黄克亮,金超,范百兴,张万才. FAST馈源舱Stewart机构标定[J].测绘科学技术学报,2017,34(03):221-225.
[5]潘之辰,钱磊,岳友岭.脉冲星搜索技术及FAST望远镜脉冲星搜索展望[J].天文研究与技术,2017,14(01):8-16.
[6]中国天眼首要目标并非外星文明盼寻脉冲星当星际导航.中国新闻网. 2016-11-06.
[7]范茜.关于3DS Max的应用研究[J].信息与电脑(理论版),2019(09):54-55+59.
[8]赵正旭,陶智,徐骞.基于国产操作系统应用软件部署对策的探讨[J].微型机与应用,2016,35(18):16-18.
[9]白英杰,赵正旭,吴晓进,张海龙.国产操作系统PHP服务部署策略的设计与实现[J].计算机应用与软件,2019,36(01):17-21.
[10]刘和彬,廖剑斌,李华川,苏茜. Blender虚拟现实环境下的工业机器人建模[J].轻工科技,2017,33(05):77-78.
[11]朱文白. FAST望远镜天文规划和馈源支撑的相关研究[D].北京中国科学院研究生院,2006.
[12]姚蕊,李庆伟,孙京海,孙才红,朱文白. FAST望远镜馈源舱精度分析研究[J].机械工程学报,2017,53(17):36-42.
[13]李铭哲,李辉. FAST馈源舱倾覆的理论分析及试验研究[J].天文研究与技术,2015,12(04):424-432.
[14]贾彦辉,李建军,王宇哲,李聪聪,段艳宾.大射电望远镜馈源舱的结构分析与数据处理[J].机械制造,2014,52(09):18-21.
[15]邓赛,景奉水,梁自泽,杨国栋,于东俊. FAST馈源支撑系统位姿分配方法研究[J].光学精密工程,2017,25(02):375-384.
[2]全球最大单口径射电望远镜在贵州落成启用.中国科学院,2016-09-25.
[3]南仁东,李会贤. FAST的进展——科学、技术与设备[J].中国科学:物理学力学天文学,2014,44(10):1063-1074.
[4]程志峰,黄克亮,金超,范百兴,张万才. FAST馈源舱Stewart机构标定[J].测绘科学技术学报,2017,34(03):221-225.
[5]潘之辰,钱磊,岳友岭.脉冲星搜索技术及FAST望远镜脉冲星搜索展望[J].天文研究与技术,2017,14(01):8-16.
[6]中国天眼首要目标并非外星文明盼寻脉冲星当星际导航.中国新闻网. 2016-11-06.
[7]范茜.关于3DS Max的应用研究[J].信息与电脑(理论版),2019(09):54-55+59.
[8]赵正旭,陶智,徐骞.基于国产操作系统应用软件部署对策的探讨[J].微型机与应用,2016,35(18):16-18.
[9]白英杰,赵正旭,吴晓进,张海龙.国产操作系统PHP服务部署策略的设计与实现[J].计算机应用与软件,2019,36(01):17-21.
[10]刘和彬,廖剑斌,李华川,苏茜. Blender虚拟现实环境下的工业机器人建模[J].轻工科技,2017,33(05):77-78.
[11]朱文白. FAST望远镜天文规划和馈源支撑的相关研究[D].北京中国科学院研究生院,2006.
[12]姚蕊,李庆伟,孙京海,孙才红,朱文白. FAST望远镜馈源舱精度分析研究[J].机械工程学报,2017,53(17):36-42.
[13]李铭哲,李辉. FAST馈源舱倾覆的理论分析及试验研究[J].天文研究与技术,2015,12(04):424-432.
[14]贾彦辉,李建军,王宇哲,李聪聪,段艳宾.大射电望远镜馈源舱的结构分析与数据处理[J].机械制造,2014,52(09):18-21.
[15]邓赛,景奉水,梁自泽,杨国栋,于东俊. FAST馈源支撑系统位姿分配方法研究[J].光学精密工程,2017,25(02):375-384.