We investigate the influence of assumed height for the thin shell ionosphere model on the Total Electron Content(TEC) derived from a small scale Global Positioning System(GPS) network. TEC and instrumental bias ar...We investigate the influence of assumed height for the thin shell ionosphere model on the Total Electron Content(TEC) derived from a small scale Global Positioning System(GPS) network. TEC and instrumental bias are determined by applying a grid-based algorithm to the data on several geomagnetically quiet days covering a 10 month period in 2006. Comparisons of TEC and instrumental bias are made among assumed heights from 250 km to 700 km with an interval of 10 km. While the TEC variations with time follow the same trend, TEC tends to increase with the height of the thin shell. The difference in TEC between heights 250 km and 700 km can be as large as~8 TECU in both daytime and nighttime. The times at which the TEC reaches its peak or valley do not vary much with the assumed heights. The instrumental biases, especially bias from the satellite, can vary irregularly with assumed height. Several satellites show a large deviation of~3 ns for heights larger than 550 km. The goodness of fit for different assumed heights is also examined. The data can be generally well-fitted for heights from 350 km to 700 km. A large deviation happens at heights lower than 350 km. Using the grid-based algorithm, there is no consensus on assumed height as related to data fitting. A thin shell height in the range 350-500 km can be a reasonable compromise between data fitting and peak height of the ionosphere.展开更多
Since ancient times,solar eclipses have fascinated—and sometimes terrified—humankind.Solar eclipses are direct sensory experiences.As the sun vanishes from the sky,birds fall silent during the midday twilight.Modern...Since ancient times,solar eclipses have fascinated—and sometimes terrified—humankind.Solar eclipses are direct sensory experiences.As the sun vanishes from the sky,birds fall silent during the midday twilight.Modern instrumentation has enabled research into the consequences of this sudden change in irradiation within the upper atmosphere.For the first time in 26 years。展开更多
基金supported by the National Natural Science Foundation of China(Grant Nos.11473045,11403045 and 11503040)
文摘We investigate the influence of assumed height for the thin shell ionosphere model on the Total Electron Content(TEC) derived from a small scale Global Positioning System(GPS) network. TEC and instrumental bias are determined by applying a grid-based algorithm to the data on several geomagnetically quiet days covering a 10 month period in 2006. Comparisons of TEC and instrumental bias are made among assumed heights from 250 km to 700 km with an interval of 10 km. While the TEC variations with time follow the same trend, TEC tends to increase with the height of the thin shell. The difference in TEC between heights 250 km and 700 km can be as large as~8 TECU in both daytime and nighttime. The times at which the TEC reaches its peak or valley do not vary much with the assumed heights. The instrumental biases, especially bias from the satellite, can vary irregularly with assumed height. Several satellites show a large deviation of~3 ns for heights larger than 550 km. The goodness of fit for different assumed heights is also examined. The data can be generally well-fitted for heights from 350 km to 700 km. A large deviation happens at heights lower than 350 km. Using the grid-based algorithm, there is no consensus on assumed height as related to data fitting. A thin shell height in the range 350-500 km can be a reasonable compromise between data fitting and peak height of the ionosphere.
基金supported by NASA grant NNX17AH71GNASA LWS funding support (NNX15AB83G)+1 种基金the DoD Multidisciplinary Research Program of the University Research Initiative (MURI) project ONR15FOA-0011NAF is supported in part by AGS-1552188/47950519C75
文摘Since ancient times,solar eclipses have fascinated—and sometimes terrified—humankind.Solar eclipses are direct sensory experiences.As the sun vanishes from the sky,birds fall silent during the midday twilight.Modern instrumentation has enabled research into the consequences of this sudden change in irradiation within the upper atmosphere.For the first time in 26 years。
