22/43/88/132 千兆赫大地测量和天体测量 VLBI 试验

arXiv - PHYS - Instrumentation and Methods for Astrophysics Pub Date : 2024-09-11 DOI:arxiv-2409.07309

Shuangjing Xu, Taehyun Jung, Bo Zhang, Ming Hui Xu, Do-Young Byun, Xuan He, Nobuyuki Sakai, Oleg Titov, Fengchun Shu, Hyo-Ryoung Kim, Jungho Cho, Sung-Moon Yoo, Byung-Kyu Choi, Woo Kyoung Lee, Yan Sun, Xiaofeng Mai, Guangli Wang

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引用次数: 0

摘要

将大地测量和天体测量甚长基线干涉测量（VLBI）观测从传统的厘米波带扩展到毫米波带具有许多科学潜力和益处。然而，由于各种因素，包括大气不透明度和湍流对毫米波长的影响增大，这项工作被认为具有相当大的挑战性。在此，我们介绍了首次大地测量模式 VLBI 实验的结果，该实验利用韩国 VLBIN 网络（KVN）在 22/43/88/132 GHz（K/Q/W/D 波段）同时观测了 82 个源。我们在大地 VLBI 分析中引入了频率相位转移（FPT）方法，这是一种通过转移低频相位解来校准高频大气相位波动的方法。通过 2 分钟的扫描，FPT 提高了大多数条纹的信噪比（SNR），有些提高了 100%以上，从而提高了毫米波段弱源的探测率。此外，FPT 减少了群延迟和延迟率的系统性误差，拟合后残差的加权均方根（WRMS）在 W 波段从 25.0 ps 下降到 20.5 ps，在 D 波段从 39.3 ps 下降到 27.6 ps。在用 KVN 基线校准 K 波段（WRMS = 12.4 ps）和 Q 波段（WRMS = 11.8 ps）的大气相位波动时，没有观察到明显的差异。这项实验表明，毫米波带可用于高精度大地测量和天体测量应用。

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A Geodetic and Astrometric VLBI Experiment at 22/43/88/132 GHz

Extending geodetic and astrometric Very Long Baseline Interferometry (VLBI) observations from traditional centimeter wavebands to millimeter wavebands offers numerous scientific potentials and benefits. However, it was considered quite challenging due to various factors, including the increased effects of atmospheric opacity and turbulence at millimeter wavelengths. Here, we present the results of the first geodetic-mode VLBI experiment, simultaneously observing 82 sources at 22/43/88/132 GHz (K/Q/W/D bands) using the Korean VLBI Network (KVN). We introduced the frequency phase transfer (FPT) method to geodetic VLBI analysis, an approach for calibrating atmospheric phase fluctuations at higher frequencies by transferring phase solutions from lower frequencies. With a 2-minute scan, FPT improved the signal-to-noise ratio (SNR) of most fringes, some by over 100%, thereby enhancing the detection rate of weak sources at millimeter wavebands. Additionally, FPT reduced systematic errors in group delay and delay rate, with the weighted root-mean-squares (WRMS) of the post-fitting residuals decreasing from 25.0 ps to 20.5 ps at the W band and from 39.3 ps to 27.6 ps at the D band. There were no notable differences observed in calibrating atmospheric phase fluctuations at the K band (WRMS = 12.4 ps) and Q band (WRMS = 11.8 ps) with the KVN baselines. This experiment demonstrated that the millimeter waveband can be used for geodetic and astrometric applications with high precision.

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arXiv - PHYS - Instrumentation and Methods for Astrophysics

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