共查询到19条相似文献,搜索用时 161 毫秒
1.
针对单一电离层总电子含量(TEC)预报模型存在的缺陷,如受外界因素干扰较大、预报精度随预报时间的增加明显降低等,本文提出一种基于补充集合经验模态分解(CEEMD)电离层TEC组合预报模型。该模型实现电离层TEC预报的关键途径为:首先,利用CEEMD对TEC原始序列进行自适应分解,得到具有不同频率的分量并依据分量复杂度分析结果进行重构;其次,使用广义回归神经网络(GRNN)模型对高频分量进行建模与预报,使用Holt-Winters模型对低频分量进行建模与预报;最后,重构高频分量预报结果与低频分量预报结果得到电离层TEC预报值。根据太阳活动选取两段不同年积日、不同纬度电离层TEC序列进行实验,结果表明本文提出组合预报模型较单一的Holt-Winters模型、GRNN模型预报精度更高,在太阳活动平静期预报结果的平均相对精度为92.83%,在太阳活动剧烈期预报结果的平均相对精度为84.35%,对于长时间TEC预报也具有较好的效果,稳定性高。 相似文献
2.
胡文权 《测绘与空间地理信息》2023,(8):164-167
为了提高电离层TEC值的预报精度,建立更高精度的电离层TEC预报模型,本文在RBF神经网络模型的基础上引入奇异谱分析(Singular Spectrum Analysis, SSA)方法,构建新的电离层TEC预报模型。该组合模型首先通过SSA提取原始序列中的特征分量,避免噪声分量对预报结果的影响,其次将去噪后特征分量作为RBF神经网络模型的输入值。使用IGS中心提供的TEC数据序列进行模型验证,结果表明,无论是对平静期电离层TEC预报还是磁暴期电离层TEC预报,相比于单一的RBF神经网络模型预报结果,本文提出的SSA-RBF神经网络模型的预报结果均更优,其中平静期预报残差在2 TECU以内,磁暴期预报残差在3—4 TECU以内,验证了本文提出组合模型的优越性。 相似文献
3.
电离层总电子含量(TEC)是描述电离层变化特性的关键参量,构建实时电离层TEC模型可为实时导航定位用户提供电离层延迟改正,加快精密单点定位收敛速度,实现对空间天气的精准监测。基于此,论文以构建实时电离层TEC模型为目标,从融合多源电离层数据构建电离层TEC模型和高精度电离层TEC预报模型的构建展开研究,主要研究内容及贡献如下:(1)使用不同方法评估了2002年001天-2018年365天IRI-2016模型、NeQuick2模型与IGS提供的电离层最终产品(IGSG)的精度。 相似文献
4.
利用球冠谐分析方法和GPS数据建立中国区域电离层TEC模型 总被引:1,自引:0,他引:1
利用GPS实测资料建立了中国区域电离层TEC球冠谐分析模型(spherical cap harmonic analysis,SCHA),评估了该模型的精度和有效性.结果表明,该模型有较高的拟合精度,其拟合残差约为±3 TECU,且精度在时间和空间上分布较均匀.根据IGS分析中心发布的IONEX全球电离层数据(GIM),内插得到了区域内相应时段的平均电离层电子含量,并利用它对CSHA模型的零阶项系数C0.0所表示的区域平均电离层电子含量进行了检核.结果表明,二者具有较高的一致性和相关性,其谱特征相关系数为0.993.由于SCHA模型较GIM模型利用了更多本区域的GPS观测数据,因此其拟舍精度更高,拟合结果与实测数据更一致.时SCHA模型参数的时间序列进行谱分析,结果表明,该模型的模型系数较好地描述了区域电离层TEC的周期性变化特征. 相似文献
5.
F2层临界频率foF2是高频通信的重要参数,目前获取F2层临界频率(foF2)最有效的手段是电离层测高仪,但磁暴期间电离层自身剧烈变化会造成测高仪foF2数据严重缺失。经验模型如NeQuick虽能给出foF2估计值,但磁暴期精度却不及磁静日水平。本文选取2015年12月19日至2015年12月22日磁暴期中国地壳运动监测网GNSS双频数据进行区域建模并估算出电子总含量(total electron content,TEC),利用实测区域TEC对NeQuick模型有效电离参数Az进行估计,得出NeQuick模型优化后TEC总含量和F2层临界频率foF2,并反演出磁暴期初相,主相及恢复相阶段变化过程。以中国地区台站实测数据作为参考对比,结果表明:GNSS数据优化后的NeQuick模型TEC精度大概提升了20%~40%,foF2的实时精度提升了10%~25%。GNSS优化后NeQuick模型能准确反演出电离层的由正相暴转为负相暴演化过程,而原始模型由于仅依赖于输入的太阳活动水平,只能反映出与磁静日水平相当的日变化趋势值。利用该方法可以有效提高磁暴期TEC和foF2的经验模型的计算精度,特别是弥补磁暴期foF2数据缺失的不足,可以作为磁暴期电离层垂直探测仪的有益补充或者有效参考。 相似文献
6.
7.
《武汉大学学报(信息科学版)》2016,(6)
电离层总电子含量TEC(total electron content)是影响卫星导航定位的主要误差源之一。为了构建精确的电离层TEC模型,基于Chapman函数建立了基于物理机制的电离层TEC同化模型背景场,并着重以IGS发布的2008年4个时段低纬度、中纬度和高纬度地区的电离层TEC数据为样本,同化稀疏点上的已知电离层TEC值,分析模型计算值的残差和相对精度分布,利用模型对电离层TEC进行了2h短期预报和1d预报,并将1d的预报值和IGS发布值进行对比。实验结果表明:(1)由同化模型计算得到的TEC残差值超过92%分布在±2TECU以内,并且除边缘区域外,同化模型TEC计算值的相对精度均在90%以上;(2)2h和1d预报残差小于±3TECU的比例分别为81.8%和81.5%。 相似文献
8.
针对电离层电子总含量(TEC)存在非线性、非平稳,由多因素影响导致高噪声的问题,建立了补充集合经验模态分解(CEEMD)和广义回归神经网络(GRNN)模型相结合的CEEMD-GRNN电离层TEC预报模型. 以解决直接使用原始数据进行预测会导致拟合效果差、预测精度低的问题. 采用国际GNSS服务(IGS)中心提供的2019年电离层数据对高、中、低纬度磁暴和非磁暴的不同年积日数据进行实验,低纬处均方根误差(RMSE)最优可达到0.97 TECU,相对精度为91.28,验证了CEEMD-GRNN预报模型精度高于EMD-GRNN以及单一的GRNN模型. 相似文献
9.
针对国际GNSS服务(IGS)各电离层分析中心发布的全球电离层图(GIM)在南极地区精度有限的问题,该文在收集IGS、极地对地观测网络(POLENET)计划和中国南极测绘研究中心(CACSM)的GPS数据的基础上,采用球冠谐分析理论建立了南极地区电离层电子总含量(TEC)模型。通过球冠谐分析的零阶项系数表示的日均值与实测TEC日均值的对比,表明二者具有很强相关性,验证了球冠谐分析具有良好的物理意义,可以有效提取南极电离层的周期特征。利用球冠谐函数模型对全南极电离层在2012年季节变化、空间分布和10月地磁暴期间的响应特征进行了分析。实验结果表明,基于球冠谐分析构建的电离层模型更适用于探测南极电离层的特征。 相似文献
10.
《武汉大学学报(信息科学版)》2020,(5)
卫星导航定位中,电离层延迟是影响用户实时定位精度的重要因素之一。利用全球电离层格网(global ionosphere maps,GIM)提供电离层延迟改正是较为常用的方法,而GIM格网的精度受限于地面GNSS(global navigation satellite system)跟踪站的分布密度。利用区域内少量或1个GNSS跟踪站建立实时区域电离层总电子含量(total electron content,TEC)模型,生成高精度的实时区域电离层格网,为用户提供区域电离层延迟改正显得尤为重要。基于CODE(Center for Orbit Determination in Europe)分析中心2016—2018年995 d的GIM格网数据,分析了相邻格网点TEC的变化范围以及不同时间间隔同一格网点TEC的变化范围。结果表明,GIM在经度方向上分辨率为5°变化的均值范围为0.2~1.0 TECU,在纬度方向上分辨率为2.5°变化的均值范围为0.4~1.4 TECU,在经度和纬度分辨率均小于1°时,电离层TEC的变化小于1.0 TECU;1 h内同一格网点电离层TEC的变化均值约为1.28 TECU,30 min内同一格网点电离层TEC的变化小于1.0 TECU。该研究为小范围内(半径小于100 km)实时区域电离层TEC模型的建立及电离层格网的时间适用范围提供了有效的数据支撑和理论验证,同时对区域电离层TEC时空变化的研究、电离层TEC预报、电离层异常监测和磁暴监测等具有一定的参考意义。 相似文献
11.
为了分析单站区域电离层总电子含量(total electron content,TEC)模型的适用范围和精度,基于2~15阶次球谐函数,分别建立了欧洲区域16个单站区域电离层TEC模型,生成了区域格网TEC,并与欧洲定轨中心(Center for Orbit Determination in Europe,CODE)、... 相似文献
12.
13.
基于北斗GEO卫星独有的静地特性,本文利用其观测数据提取电离层TEC进行磁暴期间电离层TEC时空变化研究。同时利用全球电离层格网图GIM值进行试验对比,结果表明:北斗GEO卫星提取的TEC与GIM模型值变化趋势一致,并且前者可更有效地监测电离层的细微扰动变化。在此次磁暴发生期间,亚太地区电离层TEC变化及扰动响应特征在纬度方向差异明显。其中南北半球较高纬度区域,电离层TEC在磁暴主相阶段主要表现为正响应扰动,而赤道及北半球较低纬度区域,电离层TEC在磁暴主相及恢复相阶段均产生了强度更大、持续时间更长的正响应扰动。结合现有研究,认为造成此次电离层异常扰动的激励因素主要为东向快速穿透电场的增强及热层中性成分的变化。试验结果也证明了GEO卫星可以精准有效地监测在磁暴发生时电离层TEC的变化规律及不同空间位置处TEC产生的扰动响应特征。 相似文献
14.
Application of SWACI products as ionospheric correction for single-point positioning: a comparative study 总被引:1,自引:0,他引:1
In Global Navigation Satellite Systems (GNSS) using L-band frequencies, the ionosphere causes signal delays that correspond with link related range errors of up to 100 m. In a first order approximation the range error is proportional to the total electron content (TEC) of the ionosphere. Whereas this first order range error can be corrected in dual-frequency measurements by a linear combination of carrier phase- or code-ranges of both frequencies, single-frequency users need additional information to mitigate the ionospheric error. This information can be provided by TEC maps deduced from corresponding GNSS measurements or by ionospheric models. In this paper we discuss and compare different ionospheric correction methods for single-frequency users. The focus is on the comparison of the positioning quality using dual-frequency measurements, the Klobuchar model, the NeQuick model, the IGS TEC maps, the Neustrelitz TEC Model (NTCM-GL) and the reconstructed NTCM-GL TEC maps both provided via the ionosphere data service SWACI (http://swaciweb.dlr.de) in near real-time. For that purpose, data from different locations covering several days in 2011 and 2012 are investigated, including periods of quiet and disturbed ionospheric conditions. In applying the NTCM-GL based corrections instead of the Klobuchar model, positioning accuracy improvements up to several meters have been found for the European region in dependence on the ionospheric conditions. Further in mid- and low-latitudes the NTCM-GL model provides results comparable to NeQuick during the considered time periods. Moreover, in regions with a dense GNSS ground station network the reconstructed NTCM-GL TEC maps are partly at the same level as the final IGS TEC maps. 相似文献
15.
太阳耀斑的GPS监测方法及实例分析 总被引:3,自引:1,他引:3
利用GPS伪距与载波相位联合数据处理的方法,分析了2000年7月14日太阳耀斑爆发期间,武汉、北京、乌鲁木齐GPS观测数据得到的电离层TEC,提出了利用多项式拟合计算由耀斑引起的电离层TEC增加量的方法。 相似文献
16.
Application of the TaiWan Ionospheric Model to single-frequency ionospheric delay corrections for GPS positioning 总被引:2,自引:2,他引:0
The performance of a three-dimensional ionospheric electron density model derived from FormoSat3/COSMIC GPS Radio Occultation measurements, called the TaiWan Ionosphere Model (TWIM), in removing the ionospheric delays in single-frequency pseudorange observations is presented. Positioning results using TWIM have been compared with positioning results using other ionospheric models, such as the Klobuchar (KLOB) and the global ionospheric model (GIM). C/A code pseudoranges have been observed at three International GPS Service reference stations that are representative of mid-latitude (BOR1 and IRKJ) and low-latitude (TWTF) regions of the ionosphere. The observations took place during 27 geomagnetically quiet days from April 2010 to October 2011. We perform separate solutions using the TWIM, KLOB, GIM ionospheric models and carry out a solution applying no ionospheric correction at all. We compute the daily mean horizontal errors (DMEAN) and the daily RMS (DRMS) for these solutions with respect to the published reference station coordinates. It has demonstrated that TEC maps generate using the TWIM exhibit a detailed structure of the ionosphere, particularly at low-latitude region, whereas the Klobuchar and the GIM only provide the basic diurnal and geographic features of the ionosphere. Also, it is shown that even for lower satellite elevations, the TWIM provides better positioning than the Klobuchar and GIM models. Specifically, using TWIM, the difference of the uncorrected solution (no ionospheric correction), and the other solutions, relative to the uncorrected solution, is 45 % for the mean horizontal error (DMEAN) and 42 % for the horizontal root-mean-square error (DRMS). Using Klobuchar and GIM, the percent for DMEAN only reaches to about 12 % and 3 %, while the values for the DRMS are only 12 and 4 %, respectively. In the vertical direction, all models have a percentage of about 99 and 70 % for the mean vertical error (VMEAN) and vertical root-mean-square error (VRMS), respectively. These percentages show the greater impact of TWIM on the ionospheric correction compared to the other models. In at least 40 % of the observed days and across all stations, TWIM has the smallest DMEAN, VMEAN, DRMS, and VRMS daily values. These values reach 100 % at station TWTF. This shows the overall performance of TWIM is better than the Klobuchar and GIM. 相似文献
17.
Ionospheric delay is a dominant error source in Global Navigation Satellite System (GNSS). Single-frequency GNSS applications require ionospheric correction of signal delay caused by the charged particles in the earth’s ionosphere. The Chinese Beidou system is developing its own ionospheric model for single-frequency users. The number of single-frequency GNSS users and applications is expected to grow fast in the next years in China. Thus, developing an appropriate ionospheric model is crucially important for the Chinese Beidou system and worldwide single-frequency Beidou users. We study the performance of five globally accessible ionospheric models Global Ionospheric Map (GIM), International Reference Ionosphere (IRI), Parameterized Ionospheric Model (PIM), Klobuchar and NeQuick in low- and mid-latitude regions of China under mid-solar activity condition. Generally, all ionospheric models can reproduce the trend of diurnal ionosphere variations. It is found that all the models have better performances in mid-latitude than in low-latitude regions. When all the models are compared to the observed total electron content (TEC) data derived from GIM model, the IRI model (2012 version) has the best agreement with GIM model and the NeQuick has the poorest agreement. The RMS errors of the IRI model using the GIM TEC as reference truth are about 3.0–10.0 TECU in low-latitude regions and 3.0–8.0 TECU in mid-latitude regions, as observed during a period of 1 year with medium level of solar activity. When all the ionospheric models are ingested into single-frequency precise point positioning (PPP) to correct the ionospheric delays in GPS observations, the PIM model performs the best in both low and mid-latitudes in China. In mid-latitude, the daily single-frequency PPP accuracy using PIM model is ~10 cm in horizontal and ~20 cm in up direction. At low-latitude regions, the PPP error using PIM model is 10–20 cm in north, 30–40 cm in east and ~60 cm in up component. The single-frequency PPP solutions indicate that NeQuick model has the lowest accuracy among all the models in both low- and mid-latitude regions of China. This study suggests that the PIM model may be considered for single-frequency GNSS users in China to achieve a good positioning accuracy in both low- and mid-latitude regions. 相似文献
18.
19.
Single layer ionosphere models are frequently used for ionospheric modeling and estimation using GPS measurements from a network of GPS reference stations. However, the accuracies of single layer models are inherently constrained by the assumption that the ionospheric electrons are concentrated in a thin shell located at an altitude of about 350 km above Earths surface. This assumption is only an approximation to the physical truth because the electrons are distributed in the entire ionosphere region approximately from 50 to 1,000 km. To provide instantaneous ionospheric corrections for the real-time GPS positioning applications, the ionospheric corrections need to be predicted in advance to eliminate the latency caused by the correction computation. This paper will investigate ionospheric total electron content (TEC) predictions using a multiple-layer tomographic method for ionospheric modeling over a local area GPS reference network. The data analysis focuses on the accuracy evaluation of short-term (5 min in this study) TEC predictions. The results have indicated that the obtainable TEC prediction accuracy is at a level of about 2.8 TECU in the zenith direction and 95% of the total electron content can be recovered using the proposed tomography-based ionosphere model. 相似文献