基于核主成分分析的时间域航空电磁去噪方法

时间域航空电磁数据往往在测量过程中受到天然和人文噪声的干扰.如果不能很好滤除这些电磁噪声,那么将会降低资料质量、影响反演的精度,甚至获得错误的解释结果.本文提出了一种基于核主成分分析的去噪方法,通过核主成分分析提取叠加后衰减曲线的主成分,然后使用能量占比方法分离反映地下介质的有效信号和噪声,最后使用反映地下介质的特定成分进行重构.本文所推荐的去噪方法不仅能剔除天然噪声,例如天电产生的尖脉冲或者振荡,而且能有效地抑制人文噪声.分别使用基于核主成分分析的去噪方法,以及AeroTEM软件的处理方法对同样的吊舱式时间域直升机航空电磁勘查系统实测数据进行处理,并比较其结果.处理结果表明：所推荐的去噪方法要优于AeroTEM软件.     

Remote sensing of thunderstorm activity by means of VLF sferics

The results of a three-month observational period (June–August 1981) during sunlit hours (9:00–15:00 GMT) with VLF sferics at the two stations Tel Aviv, Israel, and Pretoria, South Africa, are presented and compared with rainfall data for the European-African area, with two lability indices of thunderstorm prediction, and with synoptic thunderstorm reports for the same time interval. The locations of thunderstorm centers on the continents determined from the sferics stations compare reasonably well with the distribution of rainfall, indicating that the VLF sferics method is a useful measure of rainfall, particularly in remote regions with inadequate coverage of observing stations. The lability index of Showalter (1953) appears to be rather qualitative for the prediction of thunderstorm occurrence, and any fine structure in the distribution of thunderstorm centers as seen in the sferics data is lost. The same is true of the synoptic reports of thunderstorm days. A new lability index has been developed. This index leads to a more detailed structure of thunderstorm prediction, which is consistent with the sferics data.     

Thunderstorms,Lightning, Sprites and Magnetospheric Whistler-Mode Radio Waves

Thunderstorms and the lightning that they produce are inherently interesting phenomena that have intrigued scientists and mankind in general for many years. The study of thunderstorms has rapidly advanced during the past century and many efforts have been made towards understanding lightning, thunderstorms and their consequences. Recent observations of optical phenomena above an active lightning discharge along with the availability of modern technology both for data collection and data analysis have renewed interest in the field of thunderstorms and their consequences in the biosphere. In this paper, we review the electrification processes of a thunderstorm, lightning processes and their association with global electric circuit and climate. The upward lightning discharge can cause sprites, elves, jets, etc. which are together called transient luminous events. Their morphological features and effects in the mesosphere are reviewed. The wide spectrum of electromagnetic waves generated during lightning discharges couple the lower atmosphere with the ionosphere/magnetosphere. Hence various features of these waves from ULF to VHF are reviewed with reference to recent results and their consequences are also briefly discussed.