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China-Satellite Constellation/Earth-moon Space
Beijing, China - Recent (CCTV - No access Chinese mainland)
1. Sign of Earth-moon Space Exploration department at space utilization center of Chinese Academy of Sciences (CAS)
2. Researchers working
China - Recent (CCTV - No access Chinese mainland)
3. Various of animation showing satellites
4. Animation showing satellites operating in Distant Retrograde Orbit (DRO)
5. Various of animation showing DRO, Earth, moon, satellites in operation
Beijing, China - Recent (CCTV - No access Chinese mainland)
6. Technology and Engineering Center for Space Utilization (CSU) of CAS
7. Various of researchers working
China - Recent (CCTV - No access Chinese mainland)
8. Various of animation showing orbits. Earth, moon
Beijing, China - Recent (CCTV - No access Chinese mainland)
9. SOUNDBITE (Chinese) Wang Wenbin, researcher, Technology and Engineering Center for Space Utilization, Chinese Academy of Sciences (ending with shots 10-11):
"For the first time internationally, we have achieved the ability to use satellites to track other satellites, instead of relying on ground stations. In essence, the ground station has been converted into a satellite and placed in low orbit. This breakthrough paves the way for new technological advancements in future Earth-moon space and deep space exploration."
China - Recent (CCTV - No access Chinese mainland)
10. Various of animation showing satellites operating in orbit
11. Various of animation showing moon; satellite orbiting moon
China has successfully established the world's first three-satellite constellation based on the Distant Retrograde Orbit (DRO) in the Earth-moon region of space, laying a foundation for the exploration and utilization of space, and for future crewed deep-space exploration.
DRO-A and DRO-B, two satellites developed by the Chinese Academy of Sciences (CAS) and deployed in the DRO, have established inter-satellite measurement and communication links with DRO-L, a previously launched near-Earth orbit satellite. The achievement was disclosed at a symposium on Earth-moon space DRO exploration in Beijing on Tuesday.
DRO is a unique type of orbit, and the Earth-moon space refers to the region extending outward from near-Earth and near-lunar orbits, reaching a distance of up to 2 million kilometers from Earth. In the Earth-moon space, DRO is characterized by a prograde motion around Earth and a retrograde motion around the moon, said Wang Wenbin, a researcher at the CAS' Technology and Engineering Center for Space Utilization (CSU).
Since DRO provides a highly stable orbit where spacecraft require little fuel to enter and stay, it serves as natural space hub connecting Earth, the moon and deep space, offering support for space science exploration, the deployment of space infrastructure, and crewed deep-space missions, Wang said.
On Feb. 3, 2024, the experimental DRO-L satellite was sent into a sun-synchronous orbit and began conducting experiments as planned. The DRO-A/B dual-satellite combination was launched from the Xichang Satellite Launch Center in southwest China's Sichuan Province on March 13, 2024, but failed to enter its intended orbit due to an anomaly in the upper stage of the carrier rocket.
Facing this challenge, the satellite team performed a "life-or-death" rescue operation under extreme conditions, promptly executing multiple emergency orbit maneuvers to correct the trajectory of the two satellites.
After a journey of 8.5 million kilometers, the DRO-A/B dual-satellite combination ultimately reached its designated orbit.
On Aug. 28, 2024, the two satellites were successfully separated. Later, both DRO-A and DRO-B established K-band microwave inter-satellite measurement and communication links with DRO-L, testing the networking mode of the three-satellite constellation.
Currently, the DRO-A satellite stays in DRO, while the DRO-B satellite operates in Earth-moon space maneuver orbits, according to CSU.
The satellites ultimately succeeded in entering their designated orbit, demonstrating China's breakthroughs in deep-space fault recovery and autonomous navigation technologies.
In 2017, the CSU research team initiated studies on DRO in the Earth-moon space and tackled key technological challenges, proposing the concept of a DRO-based spaceport. In February 2022, CAS launched a plan to build the DRO-based three-satellite constellation in the Earth-moon space.
The project achieved the world's first spacecraft entry into DRO with low energy consumption. Through innovative design, the team completed a lunar transfer and DRO entry by using just one-fifth of the fuel usually required.
Additionally, the project validated the K-band microwave measurement and communication links between the satellites and the ground at a distance of 1.17 million kilometers, achieving a key-technology breakthrough for large-scale constellation construction in the Earth-moon space.
Addressing challenges such as insufficient ground-based tracking and control precision, as well as the high costs and low efficiency of lunar and deep-space exploration missions, the research team pioneered a satellite-to-satellite, space-based orbit determination system.
"For the first time internationally, we have achieved the ability to use satellites to track other satellites, instead of relying on ground stations. In essence, the ground station has been converted into a satellite and placed in low orbit. This breakthrough paves the way for new technological advancements in future Earth-moon space and deep space exploration," said Wang.
In the future, the research team will continue investigating the complex and diverse orbits in the Earth-moon space, and study the laws of the lunar space environment. Leveraging the long-term stability of DRO, scientists will carry out fundamental scientific research in such fields as quantum mechanics and atomic physics, Wang added.
China-Satellite Constellation/Earth-moon Space
Dateline : Recent
Location : China
Duration : 1'08
Beijing, China - Recent (CCTV - No access Chinese mainland)
1. Sign of Earth-moon Space Exploration department at space utilization center of Chinese Academy of Sciences (CAS)
2. Researchers working
China - Recent (CCTV - No access Chinese mainland)
3. Various of animation showing satellites
4. Animation showing satellites operating in Distant Retrograde Orbit (DRO)
5. Various of animation showing DRO, Earth, moon, satellites in operation
Beijing, China - Recent (CCTV - No access Chinese mainland)
6. Technology and Engineering Center for Space Utilization (CSU) of CAS
7. Various of researchers working
China - Recent (CCTV - No access Chinese mainland)
8. Various of animation showing orbits. Earth, moon
Beijing, China - Recent (CCTV - No access Chinese mainland)
9. SOUNDBITE (Chinese) Wang Wenbin, researcher, Technology and Engineering Center for Space Utilization, Chinese Academy of Sciences (ending with shots 10-11):
"For the first time internationally, we have achieved the ability to use satellites to track other satellites, instead of relying on ground stations. In essence, the ground station has been converted into a satellite and placed in low orbit. This breakthrough paves the way for new technological advancements in future Earth-moon space and deep space exploration."
China - Recent (CCTV - No access Chinese mainland)
10. Various of animation showing satellites operating in orbit
11. Various of animation showing moon; satellite orbiting moon
China has successfully established the world's first three-satellite constellation based on the Distant Retrograde Orbit (DRO) in the Earth-moon region of space, laying a foundation for the exploration and utilization of space, and for future crewed deep-space exploration.
DRO-A and DRO-B, two satellites developed by the Chinese Academy of Sciences (CAS) and deployed in the DRO, have established inter-satellite measurement and communication links with DRO-L, a previously launched near-Earth orbit satellite. The achievement was disclosed at a symposium on Earth-moon space DRO exploration in Beijing on Tuesday.
DRO is a unique type of orbit, and the Earth-moon space refers to the region extending outward from near-Earth and near-lunar orbits, reaching a distance of up to 2 million kilometers from Earth. In the Earth-moon space, DRO is characterized by a prograde motion around Earth and a retrograde motion around the moon, said Wang Wenbin, a researcher at the CAS' Technology and Engineering Center for Space Utilization (CSU).
Since DRO provides a highly stable orbit where spacecraft require little fuel to enter and stay, it serves as natural space hub connecting Earth, the moon and deep space, offering support for space science exploration, the deployment of space infrastructure, and crewed deep-space missions, Wang said.
On Feb. 3, 2024, the experimental DRO-L satellite was sent into a sun-synchronous orbit and began conducting experiments as planned. The DRO-A/B dual-satellite combination was launched from the Xichang Satellite Launch Center in southwest China's Sichuan Province on March 13, 2024, but failed to enter its intended orbit due to an anomaly in the upper stage of the carrier rocket.
Facing this challenge, the satellite team performed a "life-or-death" rescue operation under extreme conditions, promptly executing multiple emergency orbit maneuvers to correct the trajectory of the two satellites.
After a journey of 8.5 million kilometers, the DRO-A/B dual-satellite combination ultimately reached its designated orbit.
On Aug. 28, 2024, the two satellites were successfully separated. Later, both DRO-A and DRO-B established K-band microwave inter-satellite measurement and communication links with DRO-L, testing the networking mode of the three-satellite constellation.
Currently, the DRO-A satellite stays in DRO, while the DRO-B satellite operates in Earth-moon space maneuver orbits, according to CSU.
The satellites ultimately succeeded in entering their designated orbit, demonstrating China's breakthroughs in deep-space fault recovery and autonomous navigation technologies.
In 2017, the CSU research team initiated studies on DRO in the Earth-moon space and tackled key technological challenges, proposing the concept of a DRO-based spaceport. In February 2022, CAS launched a plan to build the DRO-based three-satellite constellation in the Earth-moon space.
The project achieved the world's first spacecraft entry into DRO with low energy consumption. Through innovative design, the team completed a lunar transfer and DRO entry by using just one-fifth of the fuel usually required.
Additionally, the project validated the K-band microwave measurement and communication links between the satellites and the ground at a distance of 1.17 million kilometers, achieving a key-technology breakthrough for large-scale constellation construction in the Earth-moon space.
Addressing challenges such as insufficient ground-based tracking and control precision, as well as the high costs and low efficiency of lunar and deep-space exploration missions, the research team pioneered a satellite-to-satellite, space-based orbit determination system.
"For the first time internationally, we have achieved the ability to use satellites to track other satellites, instead of relying on ground stations. In essence, the ground station has been converted into a satellite and placed in low orbit. This breakthrough paves the way for new technological advancements in future Earth-moon space and deep space exploration," said Wang.
In the future, the research team will continue investigating the complex and diverse orbits in the Earth-moon space, and study the laws of the lunar space environment. Leveraging the long-term stability of DRO, scientists will carry out fundamental scientific research in such fields as quantum mechanics and atomic physics, Wang added.
ID : 8424201
Published : 2025-04-16 11:52
Last Modified : 2025-04-16 17:09:16
Source : China Central Television (CCTV)
Restrictions : No access Chinese mainland
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