Abstract
Recent progress in the domain of time and frequency (T/F) standards requires important improvements in existing time distribution links, in term of accuracy in particular. Satellite Laser Ranging (SLR) has proven to be a fundamental tool, offering a straightforward, conceptually simple, highly accurate, and unambiguous observable. Several time transfers by laser link projects have been carried out over the past 10 years with numerous scientific and metrological objectives. Depending on the mission, SLR is used to transmit time over two-way or one-way distances from 500 to several millions of kilometer. The following missions and their objectives employed this technique: European Laser Timing (ELT, expected in 2020) at 450 km, Time Transfer by Laser Link (T2L2) at 1336 km, Laser Time Transfer at 36,000 km, Lunar Reconnaissance Orbiter at 350,000 km, and MErcury Surface, Space ENvironment, GEochemistry, and Ranging at tens of million km. This article describes the synergy between SLR and T/F technologies developed on the ground and in space and as well as the state of the art of their exploitation. The performance and sources of limitation of such space missions are analyzed. It shows that current and future challenges lie in the improvement in the time accuracy and stability of the time for ground geodetic observatories. The role of the next generation of SLR systems is emphasized both in space and at ground level, from the point of view of Global Geodetic Observing System and valuable exploitation of the synergy between time synchronization, ranging, and data transfer.
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Abshire JB, Sun X, Afzal R (2000) Mars orbiter laser altimeter: receiver model and performance analysis. Appl Opt 39:2449–2460
Abshire JB, Sun X, Riris H, Sirota JM, McGarry JF, Palm S, Yi D, Liiva P (2005) Geoscience laser altimeter system (GLAS) on the ICESat mission: on-orbit measurement performance. Geophys Res Lett 32:L21S02
Abshire JB, Sun X, Neumann GA, McGarry JF, Zagwodzki T, Jester P, Riris H, Zuber MT, Smith DE (2007) Laser pulses from Earth detected at Mars. In: Conference on laser and electro optics/international quantum electronics conference (CLEO/IQEC), Paper CThT6
Albee A, Palluconi FD, Arvidson RE (1998) Mars global surveyor mission: overview and status. Science 279:1671–1672
Ashby N, Allan DW (1979) Practical implication of relativity for a global coordinate time scale. Radio Sci 14(4):649–669
Auriol A, Tourain C (2010) DORIS system: the new age. Adv Space Res 46:1484–1496
Bauer S, Hussmann H, Oberst J, Dirkx D, Mao D, Neumann GA, Zuber MT (2016) Demonstration of orbit determination for the Lunar Reconnaissance Orbiter using one-way laser ranging data. Planet Space Sci 129:32–46
Belli A, Exertier P, Samain E, Courde C, Vernotte F, Jayles C, Auriol A (2016) Temperature, radiation and aging analysis of the DORIS Ultra Stable Oscillator by means of the Time Transfer by Laser Link experiment on Jason-2. Adv Space Res 58(12):2589–2600
Belli A, Exertier P, Pavlis EC, Lemoine FG (2017) Time bias of laser ranging observations. In: Proceeding of the ILRS technical workshop improving ILRS performance to meet future GGOS requirements. Riga, Latvia, p 2017
Bloch M, Mancini O, McClelland T (2008) History and performance of FEI space-class oscillators. In: Proceedings of the 40th annual precise time and time interval (PTTI) meeting, pp 29–50
Buccino DR, Seubert JA, Asmar SW, Park RS (2016) Optical ranging measurement with a lunar orbiter: limitations and potential. J Spacecr Rocket 53:457–463
Cash P, Emmons D, Welgemoed J (2008) Ultrastable oscillators for space applications. In: Proceedings of he 40th annual precise time and time interval (PTTI) meeting. pp 51–56
Cacciapuoti L, Salomon C (2009) Space clocks and fundamental tests: the ACES experiment. Eur Phys J Special Top 172:57–68
Cavanaugh JF, Smith JC, Sun X et al (2007) The mercury laser altimeter instrument for the MESSENGER mission. Sp Sci Rev 131:451–479
Cooper SB, Jensen JR, Weaver GL (2012) MESSENGER onboard time keeping accuracy during the first year in orbit at Mercury. In: Proceedings of the 44th annual precise time and time interval (PTTI) meeting, pp 361–370
Degnan JJ (1993) Millimeter accuracy satellite laser ranging: a review. In: Smith DE, Turcotte DL (eds) Contributions of space geodesy to geodynamics: technology. American Geophysical Union, Washington, pp 133–162
Degnan JJ (2002) Asynchronous laser transponders for precise interplanetary ranging and time transfer. J Geodyn 34:551–594
Dehant V, Park R, Dirkx D, Iess L, Neumann G, Turyshev S (2017) Van Hoolst T survey of capabilities and applications of accurate clocks: directions for planetary science. Space Sci Rev 212:1433–1451
Dirkx D, Noomen R, Visser PNAM, Gurvits LI, Vermeersen LLA (2016) Space-time dynamics estimation from space mission tracking data. Astron Astrophys 587:A156
Djerroud K, Samain E, Clairon A, Acef O, Man N, Lemonde P, Wolf P (2010) A coherent optical link through the turbulent atmosphere. In: Proceeding of the EFTF-2010 24th European frequency and time forum, IEEE, pp 1–6
Exertier P, Samain E, Courde C et al (2016) Sub-ns comparison between calibrated GPS(CV) and T2L2 links. Metrologia 53(6):1395
Exertier P, Belli A, Lemoine JM (2017) Time biases in laser ranging observations: a concerning issue of space geodesy. Adv Space Res 60:948–968
Fernandez A, Sanchez M, Beck T, Amarillo F (2010) Future satellite navigation system architecture: inter-satellite ranging and orbit determination. In: ION international technical meeting, San Diego, CA
Fernandez FA (2011) Inter-satellite ranging and inter-satellite communication links for enhancing GNSS satellite broadcast navigation data. Adv Space Res 47:786–801
Hess MP, Stringhetti L, Hummelsberger B, Hausner K, Stalford R, Nasca R, Léger B et al (2011) The ACES mission: system development and test status. Acta Astronautica 69(11—-12):929–938
JPL-DSAC (2017) Deep space atomic clock. https://www.nasa.gov/mission_pages/tdm/clock/index.html
Kalisz J (2004) Review of methods for time interval measurements with picosecond resolution. Metrologia 41:17–32
Kouba J (2015) A guide to using International GNSS service (IGS) products. https://kb.igs.org/hc/en-us/articles/201271873-A-Guide-to-Using-the-IGS-Products
Laurent P, Massonnet D, Cacciapuoti L, Salomon C (2015) The ACES/PHARAO space mission. Comptes-Rendus Acad Sci 16:540
Lee SW, Schutz BE, Lee CB, Yang SH (2008) A study on the common-view and all-in-view GPS time transfer using carrier-phase measurements. Metrologia 45:156–167
Leute J, Petit G, Exertier P, Samain E, Rovera DG, Uhrich P (2018) High accuracy continuous time transfer with GPS IPPP and T2L2. In: Proceeding of the 32nd EFTFT meeting, advanced GNSS session, Paper 7126
Lion G, Panet I, Wolf P, Guerlin C, Bize S, Delva P (2017) Determination of a high spatial resolution geopotential model using atomic clock comparisons. J Geodesy 91(6):597–611
Lisdat C, Grosche G, Quintin N et al (2016) A clock network for geodesy and fundamental science. Nat Commun 7:12443
Lombardi MA (2008) The use of GPS disciplined oscillators as primary frequency standards for calibration and metrology laboratories. Measure 3(3):56–65
Magruder L, Silverberg E, Webb C, Schutz B (2005) In situ timing and pointing verification of the ICESat altimeter using a ground-based system. Geophys Res Lett 32(21). https://doi.org/10.1029/2005GL023504
Mao D, McGarry J, Torrence, et al. (2011) Laser ranging experiment on Lunar Reconnaissance Orbiter: timing determination and orbit constraints. In: 17th international workshop on laser ranging, Bad Koetzting, Germany
Mao D, Sun X, Skillman D, et al. (2014) Time-transfer experiments between satellite laser ranging stations via one-way laser ranging to the Lunar Reconnaissance Orbiter. In: 19th international workshop on laser ranging, Annapolis, Maryland
Mao D, McGarry JF, Mazarico et al (2017) The laser ranging experiment of the lunar reconnaissance orbiter. Icarus 283:55–69
Marz S, Schlicht A, Bamann C (2016) Relativistic corrections in the European laser timing (ELT) experiment. Astron Astrophys 370:320
Meng W, Zhang H, Huang P et al (2013) Design and experiment of onboard laser time transfer in Chinese BeiDou navigation satellites. Adv Space Res 51:951–958
Meng W, Zhang H, Zhang Z, Prochazka I (2013) The application of single photon detector technique in laser time transfer for Chinese navigation satellites. In: Proceeding SPIE 8773, photon counting applications IV; and quantum optics and quantum information transfer and processing, 87730E. https://doi.org/10.1117/12.2020766
Neumann GA, Barker MH, Mao D, et al. (2014) Interplanetary spacecraft laser ranging: the quest for 1 AU. In: Proceeding of the 19th international workshop on laser ranging, Annapolis, Maryland
Norton JR, Cloeren JM (1996) Brief history of the development of ultra-precise oscillators for ground and space applications. In: Proceedings of the 1996 IEEE international frequency control symposium, pp 46–57
Paschalidis N et al (2002) A CMOS time-of-flight system-on-a-chip for space instrumentation. IEEE Trans Nucl Sci 49(3):1156–1163
Pearlman M, Noll C, McGarry J, Gurtner W, Pavlis E (2009) The international laser ranging service. Adv Geosci 13:129–153
Petit G, Wolf P (2005) Relativistic theory for time comparisons: a review. Metrologia 42(3):S138
Prochazka I, Kodet J, Blazej J (2016) Space qualified photon counting detector for laser time transfer with picosecond precision and stability. Rev Sci Instrum 7(5):056102
Rajan JA, Orr M, Wang P (2003) On-orbit validation of GPS IIR autonomous navigation. In: ION 59th annual meeting/CIGTF 22nd guidance test symposium, Albuquerque, NM
Ray J, Senior K (2005) Geodetic techniques for time and frequency comparisons using GPS phase and code measurements. Metrologia 42:215–232
Rovera GD, Torre JM, Sherwood R, Abgrall M, Courde C, Laas-Bourez M, Uhrich P (2014) Link calibration against receiver calibration: an assessment of GPS time transfer uncertainties. Metrologia 51(5):476
Rowlands DD, Pavlis DE, Lemoine FG, Neumann GA, Luthcke SB (1999) The use of laser altimetry in the orbit and attitude determination of Mars Global Surveyor. Geophys Res Lett 26(9):1191–1194
Samain E et al (2008) T2L2 experiment on Jason-2 and further experiments. Int J Mod Phys D 17(7):1043–1054
Samain E, Vrancken P, Guillemot P, Fridelance P, Exertier P (2014) Time transfer by laser link (T2L2): characterization and calibration of the flight instrument. Metrologia 51(5):503
Samain E, Exertier P, Courde C, Fridelance P, Guillemot P, Laas-Bourez M, Torre JM (2015) Time transfer by laser link: a complete analysis of the error budget. Metrologia 52:423–432
Samain E, Rovera GD, Torre J-M, Courde C, Belli A, Exertier P, Uhrich P, Guillemot Ph, Sherwood R, Xue D, Xingwei H, Zhang Z, Meng W, Zhongpin Z (2018) Time transfer by laser link (T2L2) in non-common view between Europe and China. In: Transactions on Ultrasonics, Ferroelectrics, and Frequency Control, Special Issue, https://doi.org/10.1109/TUFFC.2018.2804221
Sanchez M, Pulido JA, Amarillo F, Gerner JL (2008) The ESA ”GNS+“ project. Inter-satellite ranging and communication links in the frame of the GNSS infrastructure evolutions. In: ION GNSS 21th international technical meeting of the satellite devision, Savannah, GA
Schlicht A, Schreiber U, Prochazka I, Cacciapuoti L (2012) The european laser timing experiment (ELT) and data centre (ELT-DC); Mitteilung des Bundesamtes für Kartographie und Geodäsie. In: Proceeding of the 17th international workshop on laser ranging, Vol. 48
Schreiber KU, Kodet J, Schlicht A, Prochazka I, Eckl J, Herold G (2014) European laser time transfer (ELT) and laser safety for the ISS. In: Proceedings of the 18th international workshop on laser ranging, pp 1–5
Schreiber KU, Kodet J (2017) The application of coherent local time for optical time transfer and the quantification of systematic errors in satellite laser ranging. Space Sci Rev 214(1):22
Schutz BE, Zwally HJ, Schuman CA, Hancock D, Dimarzio JP (2005) Overview of the ICESat mission. Geophys Res Lett 32(21). https://doi.org/10.1029/2005GL024009
Shargorodsky VD, Pasynkov VV, Sadovnikov MA, Chubykin AA (2013) Laser GLONASS: Era of extended precision. Glonass Herald 14:22–26
Smith DE, Zuber MT, Sun X, Neumann GA, Cavanaugh JF, McGarry JF, Zagwodzki TW (2006) Two-way laser link over interplanetary distance. Science 331:53
Smith DE, Zuber MT, Jackson GB et al (2010) The lunar orbiter laser altimeter investigation on the lunar reconnaissance orbiter mission. Space Sci Rev 150(1–4):209–241
Smith DE, Zuber MT (2017) The transfer of earth-time to the planets. In: The science of time 2016, astrophysics and space science proceedings, 50 Springer, New York, pp 319–328
Sosnica K, Thaller D, Dach R, Steigenberger P, Beutler G, Arnold D, Jäggi A (2015) Satellite laser ranging to GPS and GLONASS. J Geodesy 89:725–743. https://doi.org/10.1007/s00190-0015-0810-8
Solomon SC, McNutt RL Jr, Gold RE, Domingue DL (2007) MESSENGER mission overview. Space Sci Rev 131:3–39
Sun X, Skillman DR, McGarry JF, Neumann GA, Mao D, Torrence MH, Hoffman ED (2013) Time transfer between satellite laser ranging stations via simultaneous laser ranging to the Lunar Reconnaissance Orbiter. In: Proceeding of the 18th international workshop on laser ranging, Fujiyoshida, Japan, Poster 13-Pos54
Thaller D, Dach R, Seitz M, Beutler G, Marayen M, Richter B (2011) Combination of GNSS and SLR observations using satellite co-locations. J Geodesy 85:257–272. https://doi.org/10.1007/s00190-010-0433-z
Tooley CR, Houghton MB, Saylor RS, Peddie C, Everett DF, Baker CL, Safdie KN (2010) Lunar reconnaissance orbiter mission and spacecraft design. Space Sci Rev 150(1–4):23–62
Urschl C, Beutler G, Gurtner W, Hugentobler U, Schaer S (2007) Contribution of SLR tracking data to GNSS orbit determination. Adv Space Res 39:1515–1523
Wang K, Rothacher M (2013) Stochastic modeling of high-stability ground clocks in GPS analysis. J Geodesy 87:427–437. https://doi.org/10.1007/s00190-013-0616-5
Weaver G, Reinhart M, Miranian M (2004) Development in ultra-stable quartz oscillators for deep space reliability. In: 36th annual precise time and time interval (PTTI) meeting, Washington
Weinbach U, Schön S (2011) GNSS receiver clock modelling when using high precision oscillators and IST impact on PPP. Adv Space Res 47:229. https://doi.org/10.1016/j.ar.201006031
Wolf P (2000) Satellite orbit and ephemeris determination using inter satellite links. PhD Thesis Universität der Bundeswehr Muenchen
Zuber MT (2006) Seconds of data, years of trying. Photonics Spectra 40(5):56–58
Zuber MT, Smith DE, Zellar RS et al (2010) The lunar reconnaissance orbiter laser ranging investigation. Space Sci Rev 150:63–80
Acknowledgements
The authors want to thank SLR stations of the ILRS network for providing ranging data to numerous space missions including GNSS satellites. They want to thank the Labex FIRST-TF for its support in 2017, and DLR for the orbit prediction and analysis data of the ISS to perform the relativistic correction tests. Finally, the authors want to thank the reviewers for helpful and very constructive remarks
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Appendix: List of acronyms
Appendix: List of acronyms
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Exertier, P., Belli, A., Samain, E. et al. Time and laser ranging: a window of opportunity for geodesy, navigation, and metrology. J Geod 93, 2389–2404 (2019). https://doi.org/10.1007/s00190-018-1173-8
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DOI: https://doi.org/10.1007/s00190-018-1173-8