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Lunar Laser Ranging experiments

January 01, 1970

Lunar Laser Ranging (LLR) is the practice of measuring the distance between the surfaces of the Earth and the Moon using laser ranging. The distance can be calculated from the round-trip time of laser light pulses travelling at the speed of light, which are reflected back to Earth by the Moon's surface or by one of several retroreflectors installed on the Moon. Three were placed by the United States' Apollo program (11, 14, and 15), two by the Soviet Lunokhod 1 and 2 missions,[1] and one by India's Chandrayaan-3 mission.[2][3]

Lunar Laser Ranging Experiment from the Apollo 11 mission

Although it is possible to reflect light or radio waves directly from the Moon's surface (a process known as EME), a much more precise range measurement can be made using retroreflectors, since because of their small size, the temporal spread in the reflected signal is much smaller.[4]

Laser ranging measurements can also be made with retroreflectors installed on Moon-orbiting satellites such as the LRO.[5][6]

History edit

 
Apollo 15 LRRR
 
Apollo 15 LRRR schematic

The first successful lunar ranging tests were carried out in 1962 when Louis Smullin and Giorgio Fiocco from the Massachusetts Institute of Technology succeeded in observing laser pulses reflected from the Moon's surface using a laser with a 50J 0.5 millisecond pulse length.[7] Similar measurements were obtained later the same year by a Soviet team at the Crimean Astrophysical Observatory using a Q-switched ruby laser.[8]

Shortly thereafter, Princeton University graduate student James Faller proposed placing optical reflectors on the Moon to improve the accuracy of the measurements.[9] This was achieved following the installation of a retroreflector array on July 21, 1969 by the crew of Apollo 11. Two more retroreflector arrays were left by the Apollo 14 and Apollo 15 missions. Successful lunar laser range measurements to the retroreflectors were first reported on Aug. 1, 1969 by the 3.1 m telescope at Lick Observatory.[9] Observations from Air Force Cambridge Research Laboratories Lunar Ranging Observatory in Arizona, the Pic du Midi Observatory in France, the Tokyo Astronomical Observatory, and McDonald Observatory in Texas soon followed.

The uncrewed Soviet Lunokhod 1 and Lunokhod 2 rovers carried smaller arrays. Reflected signals were initially received from Lunokhod 1 by the Soviet Union up to 1974, but not by western observatories that did not have precise information about location. In 2010 NASA's Lunar Reconnaissance Orbiter located the Lunokhod 1 rover on images and in April 2010 a team from University of California ranged the array.[10] Lunokhod 2's array continues to return signals to Earth.[11] The Lunokhod arrays suffer from decreased performance in direct sunlight—a factor considered in reflector placement during the Apollo missions.[12]

The Apollo 15 array is three times the size of the arrays left by the two earlier Apollo missions. Its size made it the target of three-quarters of the sample measurements taken in the first 25 years of the experiment. Improvements in technology since then have resulted in greater use of the smaller arrays, by sites such as the Côte d'Azur Observatory in Nice, France; and the Apache Point Observatory Lunar Laser-ranging Operation (APOLLO) at the Apache Point Observatory in New Mexico.

In the 2010s several new retroreflectors were planned. The MoonLIGHT reflector, which was to be placed by the private MX-1E lander, was designed to increase measurement accuracy up to 100 times over existing systems.[13][14][15] MX-1E was set to launch in July 2020,[16] however, as of February 2020, the launch of the MX-1E has been canceled.[17] India's Chandrayaan-3 lunar lander successfully placed a sixth reflector on the Moon in August 2023.[3] MoonLIGHT will be launched in early 2024 with a Commercial Lunar Payload Services (CLPS) mission.[18]

Principle edit

See also: Apache Point Observatory Lunar Laser-ranging Operation § Principle of operation
 
Annotated image of the near side of the Moon showing the location of retroreflectors left on the surface by Apollo and Lunokhod missions[19]

The distance to the Moon is calculated approximately using the equation: distance = (speed of light × duration of delay due to reflection) / 2. Since the speed of light is a defined constant, conversion between distance and time of flight can be made without ambiguity.

To compute the lunar distance precisely, many factors must be considered in addition to the round-trip time of about 2.5 seconds. These factors include the location of the Moon in the sky, the relative motion of Earth and the Moon, Earth's rotation, lunar libration, polar motion, weather, speed of light in various parts of air, propagation delay through Earth's atmosphere, the location of the observing station and its motion due to crustal motion and tides, and relativistic effects.[20][21] The distance continually changes for a number of reasons, but averages 385,000.6 km (239,228.3 mi) between the center of the Earth and the center of the Moon.[22] The orbits of the Moon and planets are integrated numerically along with the orientation of the Moon called physical libration.[23]

At the Moon's surface, the beam is about 6.5 kilometers (4.0 mi) wide[24][i] and scientists liken the task of aiming the beam to using a rifle to hit a moving dime 3 kilometers (1.9 mi) away. The reflected light is too weak to see with the human eye. Out of a pulse of 3×1017 photons[25] aimed at the reflector, only about 1–5 are received back on Earth, even under good conditions.[26] They can be identified as originating from the laser because the laser is highly monochromatic.

As of 2009, the distance to the Moon can be measured with millimeter precision.[27] In a relative sense, this is one of the most precise distance measurements ever made, and is equivalent in accuracy to determining the distance between Los Angeles and New York to within the width of a human hair.

List of retroreflectors edit

Main article: List of retroreflectors on the Moon

List of observatories edit

The table below presents a list of active and inactive Lunar Laser Ranging stations on Earth.[22][28]

Lunar Laser Ranging stations
Observatory Project Operating timespan Telescope Laser Range accuracy Ref.
McDonald Observatory, Texas, US MLRS 1969–1985

1985–2013

2.7 m 694 nm, 7 J

532 nm, 200 ps, 150 mJ

[29]

[22]

Crimean Astrophysical Observatory (CrAO), USSR 1974, 1982–1984 694 nm 3.0–0.6 m [30]
Côte d'Azur Observatory (OCA), Grasse, France MeO 1984–1986

1986–2010

2010–present (2021)

694 nm

532 nm, 70 ps, 75 mJ

532/1064 nm

[22][31]
Haleakala Observatory, Hawaii, US LURE 1984–1990 532 nm, 200 ps, 140 mJ 2.0 cm [22][32]
Matera Laser Ranging Observatory (MLRO), Italy 2003–present (2021) 532 nm
Apache Point Observatory, New Mexico, US APOLLO 2006–2021

2021–present (2023)

532 nm, 100 ps, 115 mJ 1.1 mm [22]

[33]

Geodetic Observatory Wettzell, Germany WLRS 2018–present (2021) 1064 nm, 10 ps, 75 mJ [34]
Yunnan Astronomical Observatory, Kunming, China 2018 1.2 m 532 nm, 10 ns, 3 J meter level [35]

Data analysis edit

The Lunar Laser Ranging data is collected in order to extract numerical values for a number of parameters. Analyzing the range data involves dynamics, terrestrial geophysics, and lunar geophysics. The modeling problem involves two aspects: an accurate computation of the lunar orbit and lunar orientation, and an accurate model for the time of flight from an observing station to a retroreflector and back to the station. Modern Lunar Laser Ranging data can be fit with a 1 cm weighted rms residual.

  • The center of Earth to center of Moon distance is computed by a program that numerically integrates the lunar and planetary orbits accounting for the gravitational attraction of the Sun, planets, and a selection of asteroids.[36][23]
  • The same program integrates the 3-axis orientation of the Moon called physical Libration.

The range model includes[36][37]

  • The position of the ranging station accounting for motion due to plate tectonics, Earth rotation, precession, nutation, and polar motion.
  • Tides in the solid Earth and seasonal motion of the solid Earth with respect to its center of mass.
  • Relativistic transformation of time and space coordinates from a frame moving with the station to a frame fixed with respect to the solar system center of mass. Lorentz contraction of the Earth is part of this transformation.
  • Delay in the Earth's atmosphere.
  • Relativistic delay due to the gravity fields of the Sun, Earth, and Moon.
  • The position of the retroreflector accounting for orientation of the Moon and solid-body tides.
  • Lorentz contraction of the Moon.
  • Thermal expansion and contraction of the retroreflector mounts.

For the terrestrial model, the IERS Conventions (2010) is a source of detailed information.[38]

Results edit

Lunar laser ranging measurement data is available from the Paris Observatory Lunar Analysis Center,[39] the International Laser Ranging Service archives,[40][41] and the active stations. Some of the findings of this long-term experiment are:[22]

Properties of the Moon edit

  • The distance to the Moon can be measured with millimeter precision.[27]
  • The Moon is spiraling away from Earth at a rate of 3.8 cm/year.[24][42] This rate has been described as anomalously high.[43]
  • The fluid core of the Moon was detected from the effects of core/mantle boundary dissipation.[44]
  • The Moon has free physical librations that require one or more stimulating mechanisms.[45]
  • Tidal dissipation in the Moon depends on tidal frequency.[42]
  • The Moon probably has a liquid core of about 20% of the Moon's radius.[11] The radius of the lunar core-mantle boundary is determined as 381±12 km.[46]
  • The polar flattening of the lunar core-mantle boundary is determined as (2.2±0.6)×10−4.[46]
  • The free core nutation of the Moon is determined as 367±100 yr.[46]
  • Accurate locations for retroreflectors serve as reference points visible to orbiting spacecraft.[47]

Gravitational physics edit

Gallery edit

See also edit

References edit

  1. ^ During the round-trip time, an Earth observer will have moved by around 1 km (depending on their latitude). This has been presented, incorrectly, as a 'disproof' of the ranging experiment, the claim being that the beam to such a small reflector cannot hit such a moving target. However the size of the beam is far larger than any movement, especially for the returned beam.
  1. ^ Chapront, J.; Chapront-Touzé, M.; Francou, G. (1999). "Determination of the lunar orbital and rotational parameters and of the ecliptic reference system orientation from LLR measurements and IERS data". Astronomy and Astrophysics. 343: 624–633. Bibcode:1999A&A...343..624C.
  2. ^ "Chandrayaan-3". ISRO. Retrieved 15 August 2023.
  3. ^ a b Dhillon, Amrit (23 August 2023). "India lands spacecraft near south pole of moon in historic first". The Guardian. Retrieved 23 August 2023.
  4. ^ Müller, Jürgen; Murphy, Thomas W.; Schreiber, Ulrich; Shelus, Peter J.; Torre, Jean-Marie; Williams, James G.; Boggs, Dale H.; Bouquillon, Sebastien; Bourgoin, Adrien; Hofmann, Franz (2019). "Lunar Laser Ranging: a tool for general relativity, lunar geophysics and Earth science". Journal of Geodesy. 93 (11): 2195–2210. Bibcode:2019JGeod..93.2195M. doi:10.1007/s00190-019-01296-0. ISSN 1432-1394. S2CID 202641440.
  5. ^ Mazarico, Erwan; Sun, Xiaoli; Torre, Jean-Marie; Courde, Clément; Chabé, Julien; Aimar, Mourad; Mariey, Hervé; Maurice, Nicolas; Barker, Michael K.; Mao, Dandan; Cremons, Daniel R.; Bouquillon, Sébastien; Carlucci, Teddy; Viswanathan, Vishnu; Lemoine, Frank; Bourgoin, Adrien; Exertier, Pierre; Neumann, Gregory; Zuber, Maria; Smith, David (6 August 2020). "First two-way laser ranging to a lunar orbiter: infrared observations from the Grasse station to LRO's retro-reflector array". Earth, Planets and Space. 72 (1): 113. Bibcode:2020EP&S...72..113M. doi:10.1186/s40623-020-01243-w. hdl:11603/19523. ISSN 1880-5981.
  6. ^ Kornei, Katherine (15 August 2020). "How Do You Solve a Moon Mystery? Fire a Laser at It". The New York Times. ISSN 0362-4331. Retrieved 1 June 2021.
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  8. ^ Bender, P. L.; et al. (1973). "The Lunar Laser Ranging Experiment: Accurate ranges have given a large improvement in the lunar orbit and new selenophysical information" (PDF). Science. 182 (4109): 229–238. Bibcode:1973Sci...182..229B. doi:10.1126/science.182.4109.229. PMID 17749298. S2CID 32027563.
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  28. ^ Biskupek, Liliane; Müller, Jürgen; Torre, Jean-Marie (3 February 2021). "Benefit of New High-Precision LLR Data for the Determination of Relativistic Parameters". Universe. 7 (2): 34. arXiv:2012.12032. Bibcode:2021Univ....7...34B. doi:10.3390/universe7020034.
  29. ^ Bender, P. L.; Currie, D. G.; Dickey, R. H.; Eckhardt, D. H.; Faller, J. E.; Kaula, W. M.; Mulholland, J. D.; Plotkin, H. H.; Poultney, S. K.; et al. (1973). "The Lunar Laser Ranging Experiment". Science. 182 (4109): 229–238. Bibcode:1973Sci...182..229B. doi:10.1126/science.182.4109.229. ISSN 0036-8075. PMID 17749298. S2CID 32027563.
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  36. ^ a b Pavlov, Dmitry A.; Williams, James G.; Suvorkin, Vladimir V. (2016). "Determining parameters of Moon's orbital and rotational motion from LLR observations using GRAIL and IERS-recommended models". Celestial Mechanics and Dynamical Astronomy. 126 (1): 61–88. arXiv:1606.08376. Bibcode:2016CeMDA.126...61P. doi:10.1007/s10569-016-9712-1. ISSN 0923-2958. S2CID 119116627.
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External links edit

  • "Theory and Model for the New Generation of the Lunar Laser Ranging Data" by Sergei Kopeikin
  • Apollo 15 Experiments - Laser Ranging Retroreflector by the Lunar and Planetary Institute
  • "History of Laser Ranging and MLRS" by the University of Texas at Austin, Center for Space Research
  • "Lunar Retroreflectors" by Tom Murphy
  • in Grasse, France
  • Lunar Laser Ranging from International Laser Ranging Service
  • "UW researcher plans project to pin down moon's distance from Earth" by Vince Stricherz, UW Today, 14 January 2002
  • "What Neil & Buzz Left on the Moon" by Science@NASA, 20 July 2004
  • "Apollo 11 Experiment Still Returning Results" by Robin Lloyd, CNN, 21 July 1999
  • "Shooting Lasers at the Moon: Hal Walker and the Lunar Retroreflector" by Smithsonian National Air and Space Museum, YouTube, 20 Aug 2019

January 01, 1970
lunar, laser, ranging, experiments, lunar, laser, ranging, practice, measuring, distance, between, surfaces, earth, moon, using, laser, ranging, distance, calculated, from, round, trip, time, laser, light, pulses, travelling, speed, light, which, reflected, ba. Lunar Laser Ranging LLR is the practice of measuring the distance between the surfaces of the Earth and the Moon using laser ranging The distance can be calculated from the round trip time of laser light pulses travelling at the speed of light which are reflected back to Earth by the Moon s surface or by one of several retroreflectors installed on the Moon Three were placed by the United States Apollo program 11 14 and 15 two by the Soviet Lunokhod 1 and 2 missions 1 and one by India s Chandrayaan 3 mission 2 3 Lunar Laser Ranging Experiment from the Apollo 11 mission Although it is possible to reflect light or radio waves directly from the Moon s surface a process known as EME a much more precise range measurement can be made using retroreflectors since because of their small size the temporal spread in the reflected signal is much smaller 4 Laser ranging measurements can also be made with retroreflectors installed on Moon orbiting satellites such as the LRO 5 6 Contents 1 History 2 Principle 3 List of retroreflectors 4 List of observatories 5 Data analysis 6 Results 6 1 Properties of the Moon 6 2 Gravitational physics 7 Gallery 8 See also 9 References 10 External linksHistory edit nbsp Apollo 15 LRRR nbsp Apollo 15 LRRR schematic The first successful lunar ranging tests were carried out in 1962 when Louis Smullin and Giorgio Fiocco from the Massachusetts Institute of Technology succeeded in observing laser pulses reflected from the Moon s surface using a laser with a 50J 0 5 millisecond pulse length 7 Similar measurements were obtained later the same year by a Soviet team at the Crimean Astrophysical Observatory using a Q switched ruby laser 8 Shortly thereafter Princeton University graduate student James Faller proposed placing optical reflectors on the Moon to improve the accuracy of the measurements 9 This was achieved following the installation of a retroreflector array on July 21 1969 by the crew of Apollo 11 Two more retroreflector arrays were left by the Apollo 14 and Apollo 15 missions Successful lunar laser range measurements to the retroreflectors were first reported on Aug 1 1969 by the 3 1 m telescope at Lick Observatory 9 Observations from Air Force Cambridge Research Laboratories Lunar Ranging Observatory in Arizona the Pic du Midi Observatory in France the Tokyo Astronomical Observatory and McDonald Observatory in Texas soon followed The uncrewed Soviet Lunokhod 1 and Lunokhod 2 rovers carried smaller arrays Reflected signals were initially received from Lunokhod 1 by the Soviet Union up to 1974 but not by western observatories that did not have precise information about location In 2010 NASA s Lunar Reconnaissance Orbiter located the Lunokhod 1 rover on images and in April 2010 a team from University of California ranged the array 10 Lunokhod 2 s array continues to return signals to Earth 11 The Lunokhod arrays suffer from decreased performance in direct sunlight a factor considered in reflector placement during the Apollo missions 12 The Apollo 15 array is three times the size of the arrays left by the two earlier Apollo missions Its size made it the target of three quarters of the sample measurements taken in the first 25 years of the experiment Improvements in technology since then have resulted in greater use of the smaller arrays by sites such as the Cote d Azur Observatory in Nice France and the Apache Point Observatory Lunar Laser ranging Operation APOLLO at the Apache Point Observatory in New Mexico In the 2010s several new retroreflectors were planned The MoonLIGHT reflector which was to be placed by the private MX 1E lander was designed to increase measurement accuracy up to 100 times over existing systems 13 14 15 MX 1E was set to launch in July 2020 16 however as of February 2020 the launch of the MX 1E has been canceled 17 India s Chandrayaan 3 lunar lander successfully placed a sixth reflector on the Moon in August 2023 3 MoonLIGHT will be launched in early 2024 with a Commercial Lunar Payload Services CLPS mission 18 Principle editSee also Apache Point Observatory Lunar Laser ranging Operation Principle of operation nbsp Annotated image of the near side of the Moon showing the location of retroreflectors left on the surface by Apollo and Lunokhod missions 19 The distance to the Moon is calculated approximately using the equation distance speed of light duration of delay due to reflection 2 Since the speed of light is a defined constant conversion between distance and time of flight can be made without ambiguity To compute the lunar distance precisely many factors must be considered in addition to the round trip time of about 2 5 seconds These factors include the location of the Moon in the sky the relative motion of Earth and the Moon Earth s rotation lunar libration polar motion weather speed of light in various parts of air propagation delay through Earth s atmosphere the location of the observing station and its motion due to crustal motion and tides and relativistic effects 20 21 The distance continually changes for a number of reasons but averages 385 000 6 km 239 228 3 mi between the center of the Earth and the center of the Moon 22 The orbits of the Moon and planets are integrated numerically along with the orientation of the Moon called physical libration 23 At the Moon s surface the beam is about 6 5 kilometers 4 0 mi wide 24 i and scientists liken the task of aiming the beam to using a rifle to hit a moving dime 3 kilometers 1 9 mi away The reflected light is too weak to see with the human eye Out of a pulse of 3 1017 photons 25 aimed at the reflector only about 1 5 are received back on Earth even under good conditions 26 They can be identified as originating from the laser because the laser is highly monochromatic As of 2009 the distance to the Moon can be measured with millimeter precision 27 In a relative sense this is one of the most precise distance measurements ever made and is equivalent in accuracy to determining the distance between Los Angeles and New York to within the width of a human hair List of retroreflectors editMain article List of retroreflectors on the MoonList of observatories editThe table below presents a list of active and inactive Lunar Laser Ranging stations on Earth 22 28 Lunar Laser Ranging stations Observatory Project Operating timespan Telescope Laser Range accuracy Ref McDonald Observatory Texas US MLRS 1969 1985 1985 2013 2 7 m 694 nm 7 J 532 nm 200 ps 150 mJ 29 22 Crimean Astrophysical Observatory CrAO USSR 1974 1982 1984 694 nm 3 0 0 6 m 30 Cote d Azur Observatory OCA Grasse France MeO 1984 1986 1986 20102010 present 2021 694 nm 532 nm 70 ps 75 mJ532 1064 nm 22 31 Haleakala Observatory Hawaii US LURE 1984 1990 532 nm 200 ps 140 mJ 2 0 cm 22 32 Matera Laser Ranging Observatory MLRO Italy 2003 present 2021 532 nm Apache Point Observatory New Mexico US APOLLO 2006 2021 2021 present 2023 532 nm 100 ps 115 mJ 1 1 mm 22 33 Geodetic Observatory Wettzell Germany WLRS 2018 present 2021 1064 nm 10 ps 75 mJ 34 Yunnan Astronomical Observatory Kunming China 2018 1 2 m 532 nm 10 ns 3 J meter level 35 Data analysis editThe Lunar Laser Ranging data is collected in order to extract numerical values for a number of parameters Analyzing the range data involves dynamics terrestrial geophysics and lunar geophysics The modeling problem involves two aspects an accurate computation of the lunar orbit and lunar orientation and an accurate model for the time of flight from an observing station to a retroreflector and back to the station Modern Lunar Laser Ranging data can be fit with a 1 cm weighted rms residual The center of Earth to center of Moon distance is computed by a program that numerically integrates the lunar and planetary orbits accounting for the gravitational attraction of the Sun planets and a selection of asteroids 36 23 The same program integrates the 3 axis orientation of the Moon called physical Libration The range model includes 36 37 The position of the ranging station accounting for motion due to plate tectonics Earth rotation precession nutation and polar motion Tides in the solid Earth and seasonal motion of the solid Earth with respect to its center of mass Relativistic transformation of time and space coordinates from a frame moving with the station to a frame fixed with respect to the solar system center of mass Lorentz contraction of the Earth is part of this transformation Delay in the Earth s atmosphere Relativistic delay due to the gravity fields of the Sun Earth and Moon The position of the retroreflector accounting for orientation of the Moon and solid body tides Lorentz contraction of the Moon Thermal expansion and contraction of the retroreflector mounts For the terrestrial model the IERS Conventions 2010 is a source of detailed information 38 Results editLunar laser ranging measurement data is available from the Paris Observatory Lunar Analysis Center 39 the International Laser Ranging Service archives 40 41 and the active stations Some of the findings of this long term experiment are 22 Properties of the Moon edit The distance to the Moon can be measured with millimeter precision 27 The Moon is spiraling away from Earth at a rate of 3 8 cm year 24 42 This rate has been described as anomalously high 43 The fluid core of the Moon was detected from the effects of core mantle boundary dissipation 44 The Moon has free physical librations that require one or more stimulating mechanisms 45 Tidal dissipation in the Moon depends on tidal frequency 42 The Moon probably has a liquid core of about 20 of the Moon s radius 11 The radius of the lunar core mantle boundary is determined as 381 12 km 46 The polar flattening of the lunar core mantle boundary is determined as 2 2 0 6 10 4 46 The free core nutation of the Moon is determined as 367 100 yr 46 Accurate locations for retroreflectors serve as reference points visible to orbiting spacecraft 47 Gravitational physics edit Einstein s theory of gravity the general theory of relativity predicts the Moon s orbit to within the accuracy of the laser ranging measurements 11 48 Gauge freedom plays a major role in a correct physical interpretation of the relativistic effects in the Earth Moon system observed with LLR technique 49 The likelihood of any Nordtvedt effect a hypothetical differential acceleration of the Moon and Earth towards the Sun caused by their different degrees of compactness has been ruled out to high precision 50 48 51 strongly supporting the strong equivalence principle The universal force of gravity is very stable The experiments have constrained the change in Newton s gravitational constant G to a factor of 2 7 10 13 per year 52 Gallery edit nbsp Apollo 14 Lunar Ranging Retro Reflector LRRR nbsp APOLLO collaboration photon pulse return times nbsp Laser ranging facility at Wettzell fundamental station Bavaria Germany nbsp Laser Ranging at Goddard Space Flight CenterSee also edit nbsp Solar System portal Carroll Alley first principal investigator of the Apollo Lunar Laser Ranging team Lidar Lunar distance astronomy Satellite laser ranging Space geodesy Third party evidence for Apollo Moon landings List of artificial objects on the MoonReferences edit During the round trip time an Earth observer will have moved by around 1 km depending on their latitude This has been presented incorrectly as a disproof of the ranging experiment the claim being that the beam to such a small reflector cannot hit such a moving target However the size of the beam is far larger than any movement especially for the returned beam Chapront J Chapront Touze M Francou G 1999 Determination of the lunar orbital and rotational parameters and of the ecliptic reference system orientation from LLR measurements and IERS data Astronomy and Astrophysics 343 624 633 Bibcode 1999A amp A 343 624C Chandrayaan 3 ISRO Retrieved 15 August 2023 a b Dhillon Amrit 23 August 2023 India lands spacecraft near south pole of moon in historic first The Guardian Retrieved 23 August 2023 Muller Jurgen Murphy Thomas W Schreiber Ulrich Shelus Peter J Torre Jean Marie Williams James G Boggs Dale H Bouquillon Sebastien Bourgoin Adrien Hofmann Franz 2019 Lunar Laser Ranging a tool for general relativity lunar geophysics and Earth science Journal of Geodesy 93 11 2195 2210 Bibcode 2019JGeod 93 2195M doi 10 1007 s00190 019 01296 0 ISSN 1432 1394 S2CID 202641440 Mazarico Erwan Sun Xiaoli Torre Jean Marie Courde Clement Chabe Julien Aimar Mourad Mariey Herve Maurice Nicolas Barker Michael K Mao Dandan Cremons Daniel R Bouquillon Sebastien Carlucci Teddy Viswanathan Vishnu Lemoine Frank Bourgoin Adrien Exertier Pierre Neumann Gregory Zuber Maria Smith David 6 August 2020 First two way laser ranging to a lunar orbiter infrared observations from the Grasse station to LRO s retro reflector array Earth Planets and Space 72 1 113 Bibcode 2020EP amp S 72 113M doi 10 1186 s40623 020 01243 w hdl 11603 19523 ISSN 1880 5981 Kornei Katherine 15 August 2020 How Do You Solve a Moon Mystery Fire a Laser at It The New York Times ISSN 0362 4331 Retrieved 1 June 2021 Smullin Louis D Fiocco Giorgio 1962 Optical Echoes from the Moon Nature 194 4835 1267 Bibcode 1962Natur 194 1267S doi 10 1038 1941267a0 S2CID 4145783 Bender P L et al 1973 The Lunar Laser Ranging Experiment Accurate ranges have given a large improvement in the lunar orbit and new selenophysical information PDF Science 182 4109 229 238 Bibcode 1973Sci 182 229B doi 10 1126 science 182 4109 229 PMID 17749298 S2CID 32027563 a b Newman Michael E 26 September 2017 To the Moon and Back in 2 5 Seconds NIST Retrieved 27 January 2021 McDonald K 26 April 2010 UC San Diego Physicists Locate Long Lost Soviet Reflector on Moon University of California San Diego Archived from the original on 30 April 2010 Retrieved 27 April 2010 a b c Williams James G Dickey Jean O 2002 Lunar Geophysics Geodesy and Dynamics PDF 13th International Workshop on Laser Ranging 7 11 October 2002 Washington D C It s Not Just The Astronauts That Are Getting Older Universe Today 10 March 2010 Retrieved 24 August 2012 Currie Douglas Dell Agnello Simone Delle Monache Giovanni April May 2011 A Lunar Laser Ranging Retroreflector Array for the 21st Century Acta Astronautica 68 7 8 667 680 Bibcode 2011AcAau 68 667C doi 10 1016 j actaastro 2010 09 001 Tune Lee 10 June 2015 UMD Italy amp MoonEx Join to Put New Laser Reflecting Arrays on Moon UMD Right Now University of Maryland Archived from the original on 22 March 2018 Retrieved 21 March 2018 Boyle Alan 12 July 2017 Moon Express unveils its roadmap for giant leaps to the lunar surface and back again GeekWire Retrieved 15 March 2018 Moon Express Lunar Scout MX 1E RocketLaunch Live archived from the original on 27 July 2019 retrieved 27 July 2019 MX 1E 1 2 3 Retrieved 24 May 2020 NASA Payloads for CLPS PRISM CP 11 Was Galileo Wrong NASA 6 May 2004 Archived from the original on 30 April 2022 Seeber Gunter 2003 Satellite Geodesy 2nd ed de Gruyter p 439 ISBN 978 3 11 017549 3 OCLC 52258226 Williams James G Boggs Dale H 2020 The JPL Lunar Laser range model 2020 ssd jpl nasa gov Retrieved 24 May 2021 a b c d e f g Murphy T W 2013 Lunar laser ranging the millimeter challenge PDF Reports on Progress in Physics 76 7 2 arXiv 1309 6294 Bibcode 2013RPPh 76g6901M doi 10 1088 0034 4885 76 7 076901 PMID 23764926 S2CID 15744316 a b Park Ryan S Folkner William M Williams James G Boggs Dale H 2021 The JPL Planetary and Lunar Ephemerides DE440 and DE441 The Astronomical Journal 161 3 105 Bibcode 2021AJ 161 105P doi 10 3847 1538 3881 abd414 ISSN 1538 3881 S2CID 233943954 a b Espenek F August 1994 NASA Accuracy of Eclipse Predictions NASA GSFC Retrieved 4 May 2008 The Basics of Lunar Ranging Retrieved 21 July 2023 Merkowitz Stephen M 2 November 2010 Tests of Gravity Using Lunar Laser Ranging Living Reviews in Relativity 13 1 7 Bibcode 2010LRR 13 7M doi 10 12942 lrr 2010 7 ISSN 1433 8351 PMC 5253913 PMID 28163616 a b Battat J B R Murphy T W Adelberger E G et al January 2009 The Apache Point Observatory Lunar Laser ranging Operation APOLLO Two Years of Millimeter Precision Measurements of the Earth Moon Range1 Publications of the Astronomical Society of the Pacific 121 875 29 40 Bibcode 2009PASP 121 29B doi 10 1086 596748 JSTOR 10 1086 596748 Biskupek Liliane Muller Jurgen Torre Jean Marie 3 February 2021 Benefit of New High Precision LLR Data for the Determination of Relativistic Parameters Universe 7 2 34 arXiv 2012 12032 Bibcode 2021Univ 7 34B doi 10 3390 universe7020034 Bender P L Currie D G Dickey R H Eckhardt D H Faller J E Kaula W M Mulholland J D Plotkin H H Poultney S K et al 1973 The Lunar Laser Ranging Experiment Science 182 4109 229 238 Bibcode 1973Sci 182 229B doi 10 1126 science 182 4109 229 ISSN 0036 8075 PMID 17749298 S2CID 32027563 Yagudina 2018 Processing and analysis of lunar laser ranging observations in Crimea in 1974 1984 Institute of Applied Astronomy of the Russian Academy of Sciences Retrieved 1 June 2021 Chabe Julien Courde Clement Torre Jean Marie Bouquillon Sebastien Bourgoin Adrien Aimar Mourad Albanese Dominique Chauvineau Bertrand Mariey Herve Martinot Lagarde Gregoire Maurice Nicolas 2020 Recent Progress in Lunar Laser Ranging at Grasse Laser Ranging Station Earth and Space Science 7 3 e2019EA000785 Bibcode 2020E amp SS 700785C doi 10 1029 2019EA000785 ISSN 2333 5084 S2CID 212785296 Lure Observatory Institute for Astronomy University of Hawaii 29 January 2002 Retrieved 3 June 2021 APOL Apache Point Observatory Eckl Johann J Schreiber K Ulrich Schuler Torben 30 April 2019 Lunar laser ranging utilizing a highly efficient solid state detector in the near IR In Domokos Peter James Ralph B Prochazka Ivan Sobolewski Roman Gali Adam eds Quantum Optics and Photon Counting 2019 Vol 11027 International Society for Optics and Photonics p 1102708 Bibcode 2019SPIE11027E 08E doi 10 1117 12 2521133 ISBN 9781510627208 S2CID 155720383 Li Yuqiang 李语强 Fu Honglin 伏红林 Li Rongwang 李荣旺 Tang Rufeng 汤儒峰 Li Zhulian 李祝莲 Zhai Dongsheng 翟东升 Zhang Haitao 张海涛 Pi Xiaoyu 皮晓宇 Ye Xianji 叶贤基 Xiong Yaoheng 熊耀恒 27 January 2019 Research and Experiment of Lunar Laser Ranging in Yunnan Observatories Chinese Journal of Lasers 46 1 0104004 doi 10 3788 CJL201946 0104004 S2CID 239211201 a b Pavlov Dmitry A Williams James G Suvorkin Vladimir V 2016 Determining parameters of Moon s orbital and rotational motion from LLR observations using GRAIL and IERS recommended models Celestial Mechanics and Dynamical Astronomy 126 1 61 88 arXiv 1606 08376 Bibcode 2016CeMDA 126 61P doi 10 1007 s10569 016 9712 1 ISSN 0923 2958 S2CID 119116627 Williams James G Boggs Dale H 2020 The JPL Lunar Laser range model 2020 ssd jpl nasa gov Retrieved 1 June 2021 IERS IERS Technical Notes IERS Conventions 2010 www iers org Retrieved 1 June 2021 Lunar Laser Ranging Observations from 1969 to May 2013 SYRTE Paris Observatory Retrieved 3 June 2014 International Laser Ranging Service International Laser Ranging Service a b Williams James G Boggs Dale H 2016 Secular tidal changes in lunar orbit and Earth rotation Celestial Mechanics and Dynamical Astronomy 126 1 89 129 Bibcode 2016CeMDA 126 89W doi 10 1007 s10569 016 9702 3 ISSN 0923 2958 S2CID 124256137 Bills B G Ray R D 1999 Lunar Orbital Evolution A Synthesis of Recent Results Geophysical Research Letters 26 19 3045 3048 Bibcode 1999GeoRL 26 3045B doi 10 1029 1999GL008348 Williams James G Boggs Dale H Yoder Charles F Ratcliff J Todd Dickey Jean O 2001 Lunar rotational dissipation in solid body and molten core Journal of Geophysical Research Planets 106 E11 27933 27968 Bibcode 2001JGR 10627933W doi 10 1029 2000JE001396 Rambaux N Williams J G 2011 The Moon s physical librations and determination of their free modes PDF Celestial Mechanics and Dynamical Astronomy 109 1 85 100 Bibcode 2011CeMDA 109 85R doi 10 1007 s10569 010 9314 2 S2CID 45209988 a b c Viswanathan V Rambaux N Fienga A Laskar J Gastineau M 9 July 2019 Observational Constraint on the Radius and Oblateness of the Lunar Core Mantle Boundary Geophysical Research Letters 46 13 7295 7303 arXiv 1903 07205 Bibcode 2019GeoRL 46 7295V doi 10 1029 2019GL082677 S2CID 119508748 Wagner R V Nelson D M Plescia J B Robinson M S Speyerer E J Mazarico E 2017 Coordinates of anthropogenic features on the Moon Icarus 283 92 103 Bibcode 2017Icar 283 92W doi 10 1016 j icarus 2016 05 011 ISSN 0019 1035 a b Williams J G Newhall X X Dickey J O 1996 Relativity parameters determined from lunar laser ranging Physical Review D 53 12 6730 6739 Bibcode 1996PhRvD 53 6730W doi 10 1103 PhysRevD 53 6730 PMID 10019959 Kopeikin S Xie Y 2010 Celestial reference frames and the gauge freedom in the post Newtonian mechanics of the Earth Moon system Celestial Mechanics and Dynamical Astronomy 108 3 245 263 Bibcode 2010CeMDA 108 245K doi 10 1007 s10569 010 9303 5 S2CID 122789819 Adelberger E G Heckel B R Smith G Su Y Swanson H E 1990 Eotvos experiments lunar ranging and the strong equivalence principle Nature 347 6290 261 263 Bibcode 1990Natur 347 261A doi 10 1038 347261a0 S2CID 4286881 Viswanathan V Fienga A Minazzoli O Bernus L Laskar J Gastineau M May 2018 The new lunar ephemeris INPOP17a and its application to fundamental physics Monthly Notices of the Royal Astronomical Society 476 2 1877 1888 arXiv 1710 09167 Bibcode 2018MNRAS 476 1877V doi 10 1093 mnras sty096 Muller J Biskupek L 2007 Variations of the gravitational constant from lunar laser ranging data Classical and Quantum Gravity 24 17 4533 doi 10 1088 0264 9381 24 17 017 S2CID 120195732 External links edit Theory and Model for the New Generation of the Lunar Laser Ranging Data by Sergei Kopeikin Apollo 15 Experiments Laser Ranging Retroreflector by the Lunar and Planetary Institute History of Laser Ranging and MLRS by the University of Texas at Austin Center for Space Research Lunar Retroreflectors by Tom Murphy Station de Telemetrie Laser Lune in Grasse France Lunar Laser Ranging from International Laser Ranging Service UW researcher plans project to pin down moon s distance from Earth by Vince Stricherz UW Today 14 January 2002 What Neil amp Buzz Left on the Moon by Science NASA 20 July 2004 Apollo 11 Experiment Still Returning Results by Robin Lloyd CNN 21 July 1999 Shooting Lasers at the Moon Hal Walker and the Lunar Retroreflector by Smithsonian National Air and Space Museum YouTube 20 Aug 2019 Retrieved from https en wikipedia org w index php title Lunar Laser Ranging experiments amp oldid 1195327973, wikipedia, wiki, book, books, library,

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