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Chunyu Ding

Orcid: 0000-0002-9405-6245

According to our database¹, Chunyu Ding authored at least 17 papers between 2018 and 2025.

Collaborative distances:

Dijkstra number² of five.
Erdős number³ of four.

Timeline

Legend:

Book

In proceedings

Article

PhD thesis

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Other

Links

On csauthors.net:

Bibliography

2025

The Outlook of Lunar Observation by 1.3-m Wavelength EISCAT_3D Radar With Large Telescope Antennas of Chinese Meridian Project.

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IEEE Trans. Geosci. Remote. Sens., 2025

Quantitative Analysis of Subsurface Dielectric Properties by Chang'E-4 Lunar Penetrating Radar Over Lunar Days 24-31.

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Francesco Soldovieri

IEEE Trans. Geosci. Remote. Sens., 2025

2024

Lunar Exploration Based on Ground-Based Radar: Current Research Progress and Future Prospects.

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Remote. Sens., September, 2024

Applications of Ground-Penetrating Radar in Asteroid and Comet Exploration.

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Remote. Sens., June, 2024

Water Ice Resources on the Shallow Subsurface of Mars: Indications to Rover-Mounted Radar Observation.

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Remote. Sens., March, 2024

Investigating Martian Subsurface Features in Utopia Planitia With Tianwen-1 Ground-Penetrating Radar.

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Francesco Soldovieri

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Gianluca Gennarelli

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IEEE Trans. Geosci. Remote. Sens., 2024

Rover-Mounted Radar Observation of Discrete Layers Within the Top 4 Meters of Regolith at the Chang'E-3 Landing Site, the Moon.

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IEEE Trans. Geosci. Remote. Sens., 2024

2023

In-Situ Radar Observation of Shallow Lunar Regolith at the Chang'E-5 Landing Site: Research Progress and Perspectives.

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Iraklis Giannakis

Remote. Sens., November, 2023

Moon-Based Ground-Penetrating Radar Observation of the Latest Volcanic Activity at the Chang'E-4 Landing Site.

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IEEE Trans. Geosci. Remote. Sens., 2023

Moon-Based Ground Penetrating Radar Derivation of the Helium-3 Reservoir in the Regolith at the Chang'E-3 Landing Site.

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IEEE J. Sel. Top. Appl. Earth Obs. Remote. Sens., 2023

Radar Observation of the Lava Tubes on the Moon and Mars.

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Remote. Sens., 2023

2022

Yutu-2 Radar Sounding Evidence of a Buried Crater at Chang'E-4 Landing Site.

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IEEE Trans. Geosci. Remote. Sens., 2022

Hyperfine Structure of Regolith Unveiled by Chang'E-5 Lunar Regolith Penetrating Radar.

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IEEE Trans. Geosci. Remote. Sens., 2022

Electromagnetic Signal Attenuation Characteristics in the Lunar Regolith Observed by the Lunar Regolith Penetrating Radar (LRPR) Onboard the Chang'E-5 Lander.

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Remote. Sens., 2022

2021

A Novel Approach for Permittivity Estimation of Lunar Regolith Using the Lunar Penetrating Radar Onboard Chang'E-4 Rover.

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Remote. Sens., 2021

Flight Experiment Validation of Altitude Measurement Performance of MOSIR on Tianwen-1 Orbiter.

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Remote. Sens., 2021

2018

Pitfalls in GPR Data Interpretation: False Reflectors Detected in Lunar Radar Cross Sections by Chang'e-3.

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Sebastian Emanuel Lauro

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Barbara Cosciotti

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Federico Di Paolo

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Elisabetta Mattei

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Elena Pettinelli

IEEE Trans. Geosci. Remote. Sens., 2018

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