Determination of Physical Heights via Time Transfer

通过时间传递确定物理高度

• 批准号: 513099514
• 负责人: Privatdozent Dr. Christian Lisdat
• 金额: --
• 依托单位: Physikalisch-Technische Bundesanstalt (PTB)
• 依托单位国家: 德国
• 项目类别: Research Units
• 资助国家: 德国
• 项目状态: 未结题
• 来源: https://gepris.dfg.de/gepris/projekt/513099514?language=en
• 关键词: Determination; Physical; Heights; via; Time

As central observation quantity, we exploit the gravitational effect on the time scales at different locations as predicted by Einstein’s theory (i.e. the gravitational redshift). Using optical time transfer via satellite between highly-precise optical clocks, we will measure the difference of elapsed time between Wettzell and Braunschweig for observation periods of a few days. From this observable, we will determine the physical height difference between both sites. Innovative research elements in this project are i) the use of time instead of frequency as basic quantity to determine the physical heights or gravity potential differences between distant sites and ii) the exploitation of optical free-space links to a satellite instead of optical fibres over a rather long timespan, i.e. integration over days to achieve the required high accuracy. This does not only pose challenges on the involved clocks and links, but also on the data analysis. We will investigate the dominant error sources (like different clock/link behavior, instrumental effects) as well as all relevant corrections and reductions to the data such as tidal effects or changes due to more local mass variations to finally determine height differences with an accuracy of 20 cm.

作为中心观测量，我们利用爱因斯坦理论预测的不同位置的时间尺度上的引力效应（即引力红移）。利用高精度光学钟之间通过卫星进行的光学时间传递，我们将在几天的观测期内测量韦策尔和布伦瑞克之间的经过时间差。根据这个观测值，我们将确定两个站点之间的物理高度差。该项目中的创新研究元素是i）使用时间而不是频率作为基本量来确定遥远地点之间的物理高度或重力势差，以及ii）利用与卫星的光学自由空间链路而不是光纤在相当长的时间跨度内，即几天内的积分以实现所需的高精度。这不仅对所涉及的时钟和链路提出了挑战，而且对数据分析也提出了挑战。我们将调查主要的误差来源（如不同的时钟/链路行为，仪器效应）以及所有相关的校正和减少的数据，如潮汐效应或变化，由于更多的本地质量变化，以最终确定高度差与20厘米的精度。