廊坊中频雷达流星观测及初步结果

中频雷达用来开展夜间100km高度以上的流星观测,获得流星随时间、高度、方位的分布情况及流星体速度、流星辐射点、流星余迹径向速度等参数,其探测数据可用于流星天文学、中层大气动力学等领域的研究.利用2017年11月16日12:00UT-22:00UT期间廊坊观测站（39.4°N,116.7°E）的中频雷达数据,首次开展了中国中纬度地区夜间流星观测实验,共检测到94个流星回波信号,集中分布在97～115km高度范围内,平均高度为106.5km,计算得到了流星回波的双极扩散系数、方位分布等相关参数,并与国外中频雷达流星探测结果进行了初步比较.      

用武汉流星雷达观测象限仪座流星雨期间的流星速度

利用武汉流星雷达,首次成功地观测了象限仪座流星雨及流星雨期间的流星速度,讨论了利用单站全天空流星雷达观测流星雨的相关问题.从观测结果可以发现此次象限仪座流星雨发生在2004年1月4日的0000-0800LT,其中流星峰值出现在0400LT,而且通过流星雷达观测到的流星雨期间的流星回波平面推测得到的流星雨辐射点也与该流星雨的理论辐射点位置对应非常好.利用流星回波振幅的Fresnel振荡方法计算了此次流星雨期间观测到的流星的速度,分析了该流星速度的分布,这次流星雨期间观测到的流星速度主要集中在10-30 km/s,可以看出这种速度分布是由流星雨进入地球大气的初始速度和流星在大气中的减速过程共同决定的.最后研究了流星速度随高度的变化,并且由此讨论了地球大气对于流星体的减速作用.      

流星突发通信信道日变化预测模型

流星突发通信不同于传统的通信, 其是低速率通信, 具有突发、不连续、不定时的特性. 因此, 流星余迹通信的复杂性要求有必要对其通信信道进行建模. 在流星通信链路中, 流星的辐射分布、可用流星率和占空比是影响流星通信信道性能的重要参数. 流星辐射分布在不同季节不同时间都各不相同, 因此准确预测流星通信链路在不同时间的流星辐射分布, 从而改变大圆路径上天线的指向, 对提高通信速率显得非常重要. 同时, 准确预测流星突发通信链路上的可用流星率和占空比, 有助于准确预测并建立流星突发信道模型. 本文分析研究了偶发流星辐射分布建模的发展, 建立了偶发流星日心空间和地心空间的几何关系, 得到了流星突发通信信道参数预测模型. 并将预测模型应用于流星通信链路, 预测结果与通信链路观测结果比较一致, 为流星通信系统的建立提供了技术支持.      

全天空流星雷达相位差监测分析方法研究

介绍了一种直接利用流星观测数据, 根据流星的时空分布特性和天线的空间布阵关系建立数学模型, 对全天空流星雷达各天线通道的相位差进行监测分析和估算的新方法. 通过分析全天空流星雷达的流星观测数据, 获得了流星时空分布特性, 天线阵相位差变化对流星空间分布的影响, 特别是流星高度分布的标准差特性与各天线相位差的关系. 在此基础上, 模拟研究了利用流星高度分布的标准差来估算天线相位差的偏差, 并应用于中国三亚地区全天空流星雷达进行相位差监测分析和校正. 结果表明, 新方法无需任何附加硬件, 通过日常观测数据就能对某一通道的相位差变化或多个通道的相位差变化进行估算和分析,相位差监测精度优于2°. 对这些相位差变化进行校正, 可有效提高全天空流星雷达对流星的定位测量精度.      

流星雷达系统相位差偏差的估计和校正

介绍了一种新的流星雷达系统的相位偏差估计和校正方法.利用流星回波的观测数据,用回波信号在各个接收通道之间的相位差,结合干涉式接收天线阵的几何关系,建立了各天线相位差测量值与偏差值之间的线性方程组,利用最小二乘法求解方程组,得到了流星雷达系统各个接收通道之间的相位差偏差估计值及校正后的流星回波到达角.与已有的流星雷达相位偏差估计和校正的方法相比,这种方法可以通过流星雷达的观测数据来计破算雷达系统各个接收天线通道之间的相位差偏差量,而不需要增加额外的硬件,实现了对观测数据的事后处理,可以方便地对已有数据进行校正.以2004年4-6月的武汉流星雷达观测数据为例,计算了流星雷达系统的偏差估计量,并用校正后的数据来计算流星回波的空间位置.结果表明,校正后流星回波数在各个方向上随高度的分布比校正前更符合统计分布.      

长时间流星不均匀体母体特征个例研究

流星体坠入地球大气烧蚀电离产生流星等离子体尾迹,在等离子体不稳定性过程作用下产生流星不均匀体.利用光学视频和无线电雷达在低纬三亚开展流星体烧蚀和流星不均匀体综合探测结果,发展了一种获取流星不均匀体母体（流星体）特征参数的方法,并对2015年12月双子座流星雨期间观测的一次长持续时间流星不均匀体事例进行了分析,得到了其母体速度、质量和轨道等特征,结果显示产生这次流星不均匀体的流星体速度和轨道等具有双子座流星特点.该方法可应用于流星不均匀体及其母体特征研究.      

微流星消融对中高层区域金属层的影响

采用连续的微流星体消融模型,对小微粒的流星颗粒(半径＜100μm)消融过程进行分析,并估计对中高层区域(80～110 km)金属层的影响．无线电流星雷达与激光雷达的探测结果表明,半径在100μm以上的流星颗粒的消融物并不是金属层主要的源．本文从流星颗粒的动量方程和能量方程出发,计算不同半径下的流星微粒在不同的注入速度下的消融剖面,并分析了流星消融截止高度的变化趋势．结合长期的激光雷达观测,计算表明,10～4μ半径的流星微粒是普通金属层的主要影响因素．     

武汉上空中层和低热层大气潮汐的流星雷达观测

武汉流星雷达是2002年元月建成的我国第一部全天空流星雷达，本文对2002年2月19日到7月31日流星雷达观测的潮汐的讨论表明，武汉中层顶以周日潮汐为潮汐运动的主要分量，它的强度远大于半日潮汐，周日潮汐和半日潮汐的波源都在80km以下．周日潮汐分量在3、4月份最强，并且经向分量略强于纬向分量．两个分量的峰值在约95km处出现，分别达到44m／s和60m／s．半日潮的最大值24m／s出现在4月初约93km处．周日潮汐和半日潮汐的振幅和相位随时间呈现出拟周期变化的特征，这可能是潮汐与行星波非线形相互作用的结果．观测结果与GSWM模型的比较表明，GSWM模型在相位随高度变化趋势上与观测结果一致，但模型的周日潮相位比观测约超前1—2h，半日潮相位约滞后1—4h．在周日潮汐较强的月份，模型与观测有较大的差异，观测的幅度通常在95km附近有极大值，而模型并没有极大值．GSWM模型对半日潮的幅度的估计通常过小，观测的半日潮汐幅度有时甚至超过模型值的一倍以上．     

电离层Es离子分布数值建模

从离子连续性方程和动量方程出发,比较全面地考虑了太阳光电离、星光电离、地冕电离、星际背景电离和流星离子流等电离源,综合分析Es层的主要动力学过程和光化学过程,以风剪切理论为基础,研究中性成分碰撞、电场作用、金属离子作用和分子离子作用等机制对离子分布的影响,建立了一维时变电离层Es物理模型.对离子产生率、垂直方向的离子速度在高度和时间上的变化进行仿真和计算,得到了在电场及风剪切作用下的离子密度剖面24h内的变化规律.根据建立的模型,以昆明相干散射雷达观测的径向风结果作为模型输入参考,仿真并得到了电离层Es电子密度的时空分布,据此反演出电离层Es临界频率f₀E_s.与昆明站电离层测高仪同时间观测的情况进行对比,结果比较一致,验证了建立的Es层物理模型正确性.      

鸡公山上听流星

无线电观测流星的最大优点是可以不受天气状况的影响,不论阴天雨天,不是白昼黑夜,都可以得到观测结果。     

Meteor radar temperatures over Collm (51.3°N, 13°E)

The method of obtaining absolute temperature estimates by measuring the ambipolar diffusion coefficient with meteor radars in the mesopause region is basically well known. However, there is still a need to refine and adjust the background temperature gradient model which is necessary to calculate the temperature values. Therefore, a detailed comparison with independent temperature measurements is necessary to evaluate the performance of the method and to obtain more information about the temperature gradient. Recent studies provide some evidence that the impact of the gradient model on temperature estimates affects the absolute temperatures, but that it is of minor importance for wave analysis. This paper focuses on a detailed evaluation of the meteor radar temperatures by comparing them with SABER satellite and OH-emission mesopause region temperatures. The seasonal variation of the observed temperatures is well reproduced by the COMMA general circulation model.     

Plasma and electromagnetic wave simulations of meteors

Every day billions of meteoroids impact and disintegrate in the Earth’s atmosphere. Current estimates for this global meteor flux vary from 2000 to 200,000 tons per year, and estimates for the average velocity range between 10 km/s and 70 km/s. The basic properties of this global meteor flux, such as the average mass, velocity, and chemical composition remain poorly constrained. We believe much of the mystery surrounding the basic parameters of the interplanetary meteor flux exists for the following reason, the unknown sampling characteristics of different radar meteor observation techniques, which are used to derive or constrain most models. We believe this arises due to poorly understood radio scattering characteristics of the meteor plasma, especially in light of recent work showing that plasma turbulence and instability greatly influences meteor trail properties at every stage of evolution. We present our results on meteor plasmas simulations of head echoes using particle in cell (PIC) ions, which show that electric fields strongly influence early stage meteor plasma evolution, by accelerating ions away from the meteoroid body. We also present the results of finite difference time domain electromagnetic simulations (FDTD), which can calculate the radar cross section of the simulated meteor plasmas. These simulations have shown that the radar cross section depends in a complex manner on a number of parameters. These include the angle between radar and meteor entry, a large dependence on radar frequency, which shows that for a given meteor plasma size and density, the reflectivity as a function of probing radar frequency varies, but typically peaks below 100 MHz.     

Seasonal variations in vertical distribution of meteor decay time as observed from meteor radars at 8.5°N and 80°N

The decay times of meteor radar echoes have been used for decades to investigate characteristics of the mesosphere and lower thermosphere (MLT) region. As the meteor echo decay time depends on background atmospheric parameters, in the present communication, we examine the seasonal variation of the vertical distributions of underdense meteor echo decay times with respect to echo strength. Observations from two similar radars located at two distinct geographical locations, Thumba (8.5°N, 77°E) and Eureka (80°N, 85.8°W) were used for the present study. Here, the radar received signal power is categorized into strong and weak echoes and vertical profiles of their decay times are constructed. It has been noticed that the monthly mean decay time vertical profile turning altitude (i.e., inflection point) varies in the range of 80–87?km of altitude depending on latitude. The turning altitude is observed at relatively lower heights in the winter than in summer at both the latitudes. The present analysis shows that the meteor decay time below the mean turning altitude follows a decreasing trend with decreasing altitude, which is quite distinct to the behaviour of ambipolar diffusion. It is also observed that there is a difference in mean decay time of strong and weak echoes below 90?km of altitude, which is very prominently seen at lower altitudes. This difference shows a seasonal pattern at high latitude, but does not show any seasonal variation at low latitude. The present results are discussed in light of current understanding of the meteor decay time.     

Nonlinear Interactions between the Quasi 5-day Wave and Tides Based on Meteor Radar Observations at Maui

Nonlinear interactions between the quasi 5-day wave and tides based on meteor radar observation in the Mesosphere and Lower Thermosphere(MLT) at Maui are studied in this paper.Strong sum interaction between quasi 5-day wave and diurnal tide,and evident difference interaction between quasi 5-day wave and semidiurnal tide are observed during the time of attention.However,their difference and sum counterparts are clearly weaker.The secondary waves generated from those interactions beat with the tide and show intense modulation at the period of 5 days which confirms the existence of their interactions.Additionally,correlation coefficients among these waves are calculated to further explore their interactions and find that they can persist for several days although they are highly intermittent.The energy exchange among these waves can be reversible during the observational time.The periods when the significant difference interaction between the quasi 5-day wave and semidiurnal tide occur are much shorter than those when the significant sum interaction between the quasi 5-day wave and diurnal tide occur.Moreover,these two strong interactions can take place simultaneously.In generally,this study provides the proof of nonlinear interactions between quasi 5-day wave and tides which were seldom reported before.     

Antarctic meteor observations using the Davis MST and meteor radars

This paper presents the meteor observations obtained using two radars installed at Davis (68.6°S, 78.0°E), Antarctica. The Davis MST radar was installed primarily for observation of polar mesosphere summer echoes, with additional transmit and receive antennas installed to allow all-sky interferometric meteor radar observations. The Davis meteor radar performs dedicated all-sky interferometric meteor radar observations. The annual count rate variation for both radars peaks in mid-summer and minimizes in early Spring. The height distribution shows significant annual variation, with minimum (maximum) peak heights and maximum (minimum) height widths in early Spring (mid-summer). Although the meteor radar count rate and height distribution variations are consistent with a similar frequency meteor radar operating at Andenes (69.3°N), the peak heights show a much larger variation than at Andenes, while the count rate maximum-to-minimum ratios show a much smaller variation. Investigation of the effects of the temporal sampling parameters suggests that these differences are consistent with the different temporal sampling strategies used by the Davis and Andenes meteor radars. The new radiant mapping procedure of [Jones, J., Jones, W., Meteor radiant activity mapping using single-station radar observations, Mon. Not. R. Astron. Soc., 367(3), 1050–1056, doi: 10.1111/j.1365-2966.2006.10025.x, 2006] is investigated. The technique is used to detect the Southern delta-Aquarid meteor shower, and a previously unknown weak shower. Meteoroid speeds obtained using the Fresnel transform are presented. The diurnal, annual, and height variation of meteoroid speeds are presented, with the results found to be consistent with those obtained using specular meteor radars. Meteoroid speed estimates for echoes identified as Southern delta-Aquarid and Sextantid meteor candidates show good agreement with the theoretical pre-atmospheric speeds of these showers (41 km s⁻¹ and 32 km s⁻¹, respectively). The meteoroid speeds estimated for these showers show decreasing speed with decreasing height, consistent with the effects of meteoroid deceleration. Finally, we illustrate how the new radiant mapping and meteoroid speed techniques can be combined for unambiguous meteor shower detection, and use these techniques to detect a previously unknown weak shower.