Link Budget Analysis with Laser Energy for Time Transfer Using the Ajisai Satellite
Abstract
:1. Introduction
2. TLTT Link Budget
2.1. Link Budget Equation for TLTT
2.1.1. Free Space Loss and Atmospheric Effects for TLTT
2.1.2. Effective Cross Section of Ajisai’s Mirror for TLTT
2.2. Minimum Required Laser Energy for TLTT
3. Simulation Results
3.1. Simulation Parameters
3.1.1. Characteristics of Ajisai for TLTT
3.1.2. Parameters of SLR Stations in the Target Network
3.2. Results
3.2.1. Effects of Geometric Configuration
3.2.2. Optimal Laser Energy
4. Discussion
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Acknowledgments
Conflicts of Interest
References
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Number of mirrors | 318 pieces |
Curvature of mirrors | 8.35~8.7 m (8.5 m for simulation) |
Reflectivity | 0.85~0.92 (0.85 for simulation) |
Duration of light flash | 5 msec |
Rate of flashing | 1.25 Hz (2 Hz at initial) |
Spin rate | 25 rpm (40 rpm at initial) |
Parameters | Sejong | Geochang | Beijing | Koganei | ||
---|---|---|---|---|---|---|
Laser | λ | Wavelength | 532 nm | 532 nm | 532 nm | 532 nm |
Pulse energy | 2.5 mJ | 15 mJ | 1 mJ | 50 mJ | ||
Pulse width | 50 ps | 9.2 ps | 200 ps | 35 ps | ||
Repetition rate | 1 KHz | 60 Hz | 1 KHz | 20 Hz | ||
Telescope | Tx Primary mirror | 0.1 m | 1.0 m | 0.16 m | 1.5 m | |
Tx Secondary mirror | - | 0.25 m | - | |||
Transmit optic efficiency | 92.3% | 75% | 70% | 30% | ||
Beam divergence angle | 5~200 arcsec | 8 arcsec | <103 arcsec | 5 arcsec | ||
Beam pointing error | <5 arcsec | <4 arcsec | <5 arcsec | <5 arcsec | ||
Rx Primary mirror | 0.4 m | 1.0 m | 0.60 m | 1.5 m | ||
Rx Secondary mirror | 0.1 m | 0.25 m | - | - | ||
Receiver optic efficiency | 64.9% | 35% | 70% | 10% | ||
Detector | Quantum efficiency | 20% | 20% | 20% | 15% | |
Position | Longitude | 127.3029E | 127.9201E | 115.8920E | 139.489E | |
Latitude | 36.5210N | 35.5902N | 39.6069N | 35.710N | ||
Altitude | 176.415 m | 934.063 m | 82.300 m | 121.820 m |
Laser Energy | Number of TLTT Paths | Total TLTT Passage Times (min) | ||||
---|---|---|---|---|---|---|
Geochang | Beijing | Koganei | Geochang | Beijing | Koganei | |
2.5 mJ | 0(0%) | 0(0%) | 0(0%) | 0 | 0 | 0 |
5.0 mJ | 48(47%) | 33(33%) | 15(16%) | 238.3 | 104.4 | 26.0 |
10.0 mJ | 61(60%) | 50(50%) | 34(36%) | 359.7 | 232.5 | 131.5 |
25.0 mJ | 86(84%) | 78(79%) | 51(54%) | 561.6 | 433.2 | 278.6 |
50.0 mJ | 96(94%) | 94(95%) | 65(68%) | 732.5 | 618.1 | 400.7 |
Observable | 102 | 99 | 95 | 1163.8 | 930.5 | 837.6 |
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Park, J.U.; Lim, H.-C.; Sung, K.-P.; Choi, M. Link Budget Analysis with Laser Energy for Time Transfer Using the Ajisai Satellite. Remote Sens. 2021, 13, 3739. https://doi.org/10.3390/rs13183739
Park JU, Lim H-C, Sung K-P, Choi M. Link Budget Analysis with Laser Energy for Time Transfer Using the Ajisai Satellite. Remote Sensing. 2021; 13(18):3739. https://doi.org/10.3390/rs13183739
Chicago/Turabian StylePark, Jong Uk, Hyung-Chul Lim, Ki-Pyoung Sung, and Mansoo Choi. 2021. "Link Budget Analysis with Laser Energy for Time Transfer Using the Ajisai Satellite" Remote Sensing 13, no. 18: 3739. https://doi.org/10.3390/rs13183739
APA StylePark, J. U., Lim, H. -C., Sung, K. -P., & Choi, M. (2021). Link Budget Analysis with Laser Energy for Time Transfer Using the Ajisai Satellite. Remote Sensing, 13(18), 3739. https://doi.org/10.3390/rs13183739