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8 results on '"Q. F. Du"'

1. An introduction to the FY3 GNOS instrument and mountain-top tests

Author

W. H. Bai, Y. Q. Sun, Q. F. Du, G. L. Yang, Z. D. Yang, P. Zhang, Y. M. Bi, X. Y. Wang, C. Cheng, and Y. Han

Subjects
Environmental engineering, TA170-171, Earthwork. Foundations, TA715-787
Abstract

The FY3 (Feng-Yun-3) GNOS (GNSS Occultation Sounder) mission is a GNSS (Global Navigation Satellite System) radio occultation mission of China for remote sensing of Earth's neutral atmosphere and the ionosphere. GNOS will use both the global positioning system (GPS) and the Beidou navigation satellite systems on the China Feng-Yun-3 (FY3) series satellites. The first FY3-C was launched at 03:07 UTC on 23 September 2013. GNOS was developed by the Center for Space Science and Applied Research, Chinese Academy of Sciences (CSSAR). It will provide vertical profiles of atmospheric temperature, pressure, and humidity, as well as ionospheric electron density profiles on a global basis. These data will be used for numerical weather prediction, climate research, and ionospheric research and space weather. This paper describes the FY3 GNOS mission and the GNOS instrument characteristics. It presents simulation results of the number and distribution of GNOS occultation events with the regional Beidou constellation and the full GPS constellation, under the limitation of the GNOS instrument occultation channel number. This paper presents the instrument performance as derived from analysis of measurement data in laboratory and mountain-based occultation validation experiments at Mt. Wuling in Hebei Province. The mountain-based GNSS occultation validation tests show that GNOS can acquire or track low-elevation radio signal for rising or setting occultation events. The refractivity profiles of GNOS obtained during the mountain-based experiment were compared with those from radiosondes. The results show that the refractivity profiles obtained by GNOS are consistent with those from the radiosonde. The rms of the differences between the GNOS and radiosonde refractivities is less than 3%.

Published
2014
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2. Automated detection and statistical study of solar radio spikes

Author

P. R. Lv, Y. C. Hou, S. W. Feng, Q. F. Du, and C. M. Tan

Subjects
Space and Planetary Science, Astronomy and Astrophysics
Abstract

The most typical observational features of solar radio spikes are their short duration and narrow bandwidth. For these characteristics, we have improved the YOLOv5s network model, by adding inclined bounding frames, and attention and feature fusion mechanism modules. The decimeter- and meterwavelength spikes observed by the Solar Broad-band Radio Spectrometer in Huairou and the spectrograph in the Chashan Solar Radio Observatory are used to carry out experiments, respectively. The results demonstrate that the AP value obtained by the improved network is 74%, which is almost 14% higher than the original network. The improved network detects 9709 (1379) decimeter- (meter-) wavelength spikes in two events with the durations, bandwidths, relative bandwidths, and frequency-drift rates. The spikes at decimeter and meter wavelengths are categorized again based on their frequency-drift rates, such as, positive, negative, and no measurable frequency-drift rates, respectively. We have carried out a statistical study on these categorized spikes. An interesting finding is that the distribution of relative bandwidths at decimeter wavelengths is changed after the classification. The distribution is asymmetric without the classification. However, after the classification the positive, negative, and no measurable frequency-drift spikes show a symmetrical distribution. These statistical results and findings provide constraints on the formation of solar radio spikes.

Published
2023

3. Preliminary validation of the refractivity from the new radio occultation sounder GNOS/FY-3C

Author

M. Liao, P. Zhang, G.-L. Yang, Y.-M. Bi, Y. Liu, W.-H. Bai, X.-G. Meng, Q.-F. Du, and Y.-Q. Sun

Subjects
Environmental engineering, TA170-171, Earthwork. Foundations, TA715-787
Abstract

As a new member of the space-based radio occultation sounders, the GNOS (Global Navigation Satellite System Occultation Sounder) mounted on Fengyun-3C (FY-3C) has been carrying out atmospheric sounding since 23 September 2013. GNOS takes approximately 800 daily measurements using GPS (Global Positioning System) and Chinese BDS (BeiDou navigation satellite) signals. In this work, the atmospheric refractivity profiles from GNOS were compared with the ones obtained from the co-located ECMWF (European Centre for Medium-Range Weather Forecasts) reanalysis. The mean bias of the refractivity obtained through GNOS GPS (BDS) was found to be approximately −0.09 % (−0.04 %) from the near surface to up to 46 km. While the average standard deviation was approximately 1.81 % (1.26 %), it was as low as 0.75 % (0.53 %) in the range of 5–25 km, where best sounding results are usually achieved. Further, COSMIC (Constellation Observing System for Meteorology, Ionosphere and Climate) and MetOp/ GRAS (GNSS Receiver for Atmospheric Sounding) radio occultation data were compared with the ECMWF reanalysis; the results thus obtained could be used as reference data for GNOS. Our results showed that GNOS/FY-3C meets the design requirements in terms of accuracy and precision of the sounder. It possesses a sounding capability similar to COSMIC and MetOp/GRAS in the vertical range of 0–30 km, though it needs further improvement above 30 km. Overall, it provides a new data source for the global numerical weather prediction (NWP) community.

Published
2016
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6. Preliminary validation of refractivity from a new radio occultation sounder GNOS/FY-3C

Author

M. Liao, P. Zhang, G. L. Yang, Y. M. Bi, Y. Liu, W. H. Bai, X. G. Meng, Q. F. Du, and Y. Q. Sun

Abstract

As a new member of space-based radio occultation sounder, the GNOS (Global Navigation Satellite System Occultation Sounder) mounted on FY-3C has been carrying out the atmospheric sounding since 23 September 2013. GNOS takes a daily measurement up to 800 times with GPS (Global Position System) and Chinese BDS (BeiDou navigation satellite) signals. The refractivity profiles from GNOS are compared with the co-located ECMWF (European Centre for Medium-Range Weather Forecasts) analyses in this paper. Bias and standard deviation have being calculated as the function of altitude. The mean bias is about 0.2 % from the near surface to 35 km. The average standard deviation is within 2 % while it is down to about 1 % in the range 5–30 km where best soundings are usually made. To evaluate the performance of GNOS, COSMIC (Constellation Observing System for Meteorology, Ionosphere and Climate) and GRAS/METOP-A (GNSS Receiver for Atmospheric Sounding) data are also compared to ECMWF analyses as the reference. The results show that GNOS/FY-3C meets the requirements of the design well. It possesses a sounding capability similar to COSMIC and GRAS in the vertical range of 0–30 km, though it needs improvement in higher altitude. Generally, it provides a new data source for global NWP (numerical weather prediction) community.

Published
2015

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