A Minimal Architecture for Real-Time Lunar Surface Positioning Using Joint Doppler and Ranging
A positioning solution for users on the lunar surface is required for the success of upcoming missions. Technological advancements have enabled the use of accurate range and Doppler measurements from a lunar orbiter. This article introduces a filtered approach of joint Doppler and ranging (JDR), a m...
| Published in: | IEEE Transactions on Aerospace and Electronic Systems |
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| Main Authors: | , , , |
| Format: | Article in Journal/Newspaper |
| Language: | unknown |
| Published: |
IEEE
2022
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| Subjects: | |
| Online Access: | https://doi.org/10.1109/taes.2021.3122876 |
| _version_ | 1821715195011006464 |
|---|---|
| author | Jun, William W. Cheung, Kar-Ming Lightsey, Edgar Glenn Lee, Charles |
| author_facet | Jun, William W. Cheung, Kar-Ming Lightsey, Edgar Glenn Lee, Charles |
| author_sort | Jun, William W. |
| collection | Caltech Authors (California Institute of Technology) |
| container_issue | 2 |
| container_start_page | 1367 |
| container_title | IEEE Transactions on Aerospace and Electronic Systems |
| container_volume | 58 |
| description | A positioning solution for users on the lunar surface is required for the success of upcoming missions. Technological advancements have enabled the use of accurate range and Doppler measurements from a lunar orbiter. This article introduces a filtered approach of joint Doppler and ranging (JDR), a minimal architecture that requires as few as one lunar orbiter to perform 3D positioning of lunar surface vehicles. The simulated performance of JDR and Doppler-based positioning methods is compared. Two lunar satellites are simulated: The lunar relay satellite (LRS) in a 12-h frozen orbit with its apogee above the lunar south pole, and the lunar reconnaissance orbiter in a 2-h Polar orbit. The analysis interval is 8 h over a single LRS ground pass. The ground pass has only a few intervals where both satellites are visible to the user and reference station on the lunar south pole. Navigation nodes are simulated with synchronized clocks for all methods. Measurement and satellite ephemeris errors are embedded into a Monte Carlo simulation to evaluate 3D positioning error. The relative JDR method obtains the lowest and most consistent overall 3D root mean squared error, averaging around 10–15 m. The absolute positioning methods are limited by satellite orbit height and other factors. Ultimately, JDR is able to provide reasonably accurate positioning knowledge to users with a minimal required infrastructure. Though this article introduces JDR on the Moon, the same architecture can be applied for other celestial bodies like Venus, Mars, Titan, and asteroids. © 2021 IEEE. Manuscript received January 14, 2021; revised May 29, 2021 and September 13, 2021; released for publication September 13, 2021. Date of publication October 27, 2021; date of current version April 12, 2022. Refereeing of this contribution was handled by J. N. Gross. This work was supported in part by the National Aeronautics and Space Administration (NASA), in part by the Space Communication and Navigation (SCaN) Program, and in part by a NASA Space ... |
| format | Article in Journal/Newspaper |
| genre | South pole |
| genre_facet | South pole |
| geographic | South Pole Venus |
| geographic_facet | South Pole Venus |
| id | ftcaltechauth:oai:authors.library.caltech.edu:g6cjr-csr55 |
| institution | Open Polar |
| language | unknown |
| long_lat | ENVELOPE(-57.842,-57.842,-61.925,-61.925) |
| op_collection_id | ftcaltechauth |
| op_container_end_page | 1376 |
| op_doi | https://doi.org/10.1109/taes.2021.3122876 |
| op_relation | https://doi.org/10.1109/taes.2021.3122876 eprintid:115232 |
| op_rights | info:eu-repo/semantics/closedAccess Other |
| op_source | IEEE Transactions on Aerospace and Electronic Systems, 58(2), 1367-1376, (2022-04) |
| publishDate | 2022 |
| publisher | IEEE |
| record_format | openpolar |
| spelling | ftcaltechauth:oai:authors.library.caltech.edu:g6cjr-csr55 2025-01-17T00:51:57+00:00 A Minimal Architecture for Real-Time Lunar Surface Positioning Using Joint Doppler and Ranging Jun, William W. Cheung, Kar-Ming Lightsey, Edgar Glenn Lee, Charles 2022-04 https://doi.org/10.1109/taes.2021.3122876 unknown IEEE https://doi.org/10.1109/taes.2021.3122876 eprintid:115232 info:eu-repo/semantics/closedAccess Other IEEE Transactions on Aerospace and Electronic Systems, 58(2), 1367-1376, (2022-04) Electrical and Electronic Engineering Aerospace Engineering info:eu-repo/semantics/article 2022 ftcaltechauth https://doi.org/10.1109/taes.2021.3122876 2024-09-25T18:46:46Z A positioning solution for users on the lunar surface is required for the success of upcoming missions. Technological advancements have enabled the use of accurate range and Doppler measurements from a lunar orbiter. This article introduces a filtered approach of joint Doppler and ranging (JDR), a minimal architecture that requires as few as one lunar orbiter to perform 3D positioning of lunar surface vehicles. The simulated performance of JDR and Doppler-based positioning methods is compared. Two lunar satellites are simulated: The lunar relay satellite (LRS) in a 12-h frozen orbit with its apogee above the lunar south pole, and the lunar reconnaissance orbiter in a 2-h Polar orbit. The analysis interval is 8 h over a single LRS ground pass. The ground pass has only a few intervals where both satellites are visible to the user and reference station on the lunar south pole. Navigation nodes are simulated with synchronized clocks for all methods. Measurement and satellite ephemeris errors are embedded into a Monte Carlo simulation to evaluate 3D positioning error. The relative JDR method obtains the lowest and most consistent overall 3D root mean squared error, averaging around 10–15 m. The absolute positioning methods are limited by satellite orbit height and other factors. Ultimately, JDR is able to provide reasonably accurate positioning knowledge to users with a minimal required infrastructure. Though this article introduces JDR on the Moon, the same architecture can be applied for other celestial bodies like Venus, Mars, Titan, and asteroids. © 2021 IEEE. Manuscript received January 14, 2021; revised May 29, 2021 and September 13, 2021; released for publication September 13, 2021. Date of publication October 27, 2021; date of current version April 12, 2022. Refereeing of this contribution was handled by J. N. Gross. This work was supported in part by the National Aeronautics and Space Administration (NASA), in part by the Space Communication and Navigation (SCaN) Program, and in part by a NASA Space ... Article in Journal/Newspaper South pole Caltech Authors (California Institute of Technology) South Pole Venus ENVELOPE(-57.842,-57.842,-61.925,-61.925) IEEE Transactions on Aerospace and Electronic Systems 58 2 1367 1376 |
| spellingShingle | Electrical and Electronic Engineering Aerospace Engineering Jun, William W. Cheung, Kar-Ming Lightsey, Edgar Glenn Lee, Charles A Minimal Architecture for Real-Time Lunar Surface Positioning Using Joint Doppler and Ranging |
| title | A Minimal Architecture for Real-Time Lunar Surface Positioning Using Joint Doppler and Ranging |
| title_full | A Minimal Architecture for Real-Time Lunar Surface Positioning Using Joint Doppler and Ranging |
| title_fullStr | A Minimal Architecture for Real-Time Lunar Surface Positioning Using Joint Doppler and Ranging |
| title_full_unstemmed | A Minimal Architecture for Real-Time Lunar Surface Positioning Using Joint Doppler and Ranging |
| title_short | A Minimal Architecture for Real-Time Lunar Surface Positioning Using Joint Doppler and Ranging |
| title_sort | minimal architecture for real-time lunar surface positioning using joint doppler and ranging |
| topic | Electrical and Electronic Engineering Aerospace Engineering |
| topic_facet | Electrical and Electronic Engineering Aerospace Engineering |
| url | https://doi.org/10.1109/taes.2021.3122876 |