ShuWang Chang, Bing Wang, Guang Lu, YuPeng Shen, Yu Bai, ZiQian Shang, Lei Zhang, Zhao Wu, YanRui Su, Yao Chen, FaBao Yan
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引用次数: 0
摘要
射电观测对于了解日冕物质抛射(CME)、日冕冲击波和高能电子加速非常重要。在这里,我们开发了一种新的米波长茶山宽带太阳射电频谱仪,用于观测太阳射电爆发频谱的(超)精细结构。在信号接收单元,我们采用了由 12 米大口径抛物面反射镜和双线极化对数周期馈源组成的天线系统,以及高精度太阳跟踪转台系统,这些都确保了太阳辐射信号的高精度采集。在数字接收机方面,我们采用采样率为 1.25 GSPS 的高速模数转换器,直接对模拟接收机放大和滤波后的信号进行采样,简化了模拟接收机的结构,并在现场可编程门阵列中设计了 16k 点快速傅里叶变换算法,对采样后的信号进行时频变换。系统的默认频率和时间分辨率分别为 76.294 kHz 和 0.839 ms(最高 0.21 ms)。系统的噪声系数小于 1 dB,动态范围超过 60 dB,灵敏度高达 1 sfu。在过去的一年中,我们观测到了大量的射电暴,包括 I 型射电暴、数百个 III 型射电暴、∼20 个 II 型射电暴和∼15 个 IV 型射电暴。这些高质量的数据有助于进一步研究CME和相关的粒子加速以及太阳射电暴的起源。
Development of a 90–600 MHz Meter-wave Solar Radio Spectrometer
Radio observation is important for understanding coronal mass ejections (CMEs), coronal shock waves, and high-energy electron acceleration. Here, we developed a new Chashan broadband solar radio spectrometer at a meter wavelength for observing the (super)fine structure of the solar radio burst spectrum. In the signal-receiving unit, we adopt an antenna system consisting of a 12 m large-aperture parabolic reflector and dual-line polarized logarithmic periodic feed source, as well as a high-precision Sun-tracking turntable system, all of which ensure the high-precision acquisition of solar radiation signals. For the digital receiver, we use a high-speed analog-to-digital converter with a sampling rate of 1.25 GSPS to directly sample the signal amplified and filtered by the analog receiver, simplifying the structure of the analog receiver, and design a 16k-point fast Fourier transform algorithm in the field programmable gate array to perform time–frequency transformation on the sampled signals. The default frequency and temporal resolution of the system are 76.294 kHz and 0.839 ms (up to 0.21 ms), respectively. The noise coefficient of the system is less than 1 dB, the dynamic range is more than 60 dB, and the sensitivity is as high as 1 sfu. We have observed a large number of radio bursts, including type I radio storms, hundreds of type III, ∼20 type II, and ∼15 type IV bursts in the past year. These high-quality data are useful in the further study of CMEs and associated particle acceleration and the origins of solar radio bursts.