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Revision as of 14:52, 15 April 2018
(the following is excerpted from the book published by Cambridge University Press in 1960)
Contents
TENTH GENERAL ASSEMBLY HELD AT MOSCOW 12-20 AUGUST 1958
Table of Contents
EDITED BY
D. H. SADLER
(General Secretary)
PRINTED WITH FINANCIAL ASSISTANCE FROM U.N.E.S.C.O.
CAMBRIDGE AT THE UNIVERSITY PRESS 1960
(from p. 249)
16. COMMISSION POUR L'ETUDE PHYSIQUE DES PLANETES ET DES SATELLITES
PRÉSIDENT: G. P. Kuiper.
MEMBRES : MM. Adel, Ahmed, Alexander, Baldwin, Barabashev, Brouwer, Bullard, Bullen, Camichel, de Marcus, de Mottoni, de Vaucouleurs, Dollfus, Elsasser, Mme Flammarion, MM. Gentili, Giclas, Harris, Heath, Herzberg, Jeffreys, Lipsky, Luplau Janssen, Peek, Plakidis, Rösch, Ryves+, Schoenberg, Sharonov, E. C. Slipher, Steavenson, Mme Sytinskaya, MM. Tchekirda, Tikhov, Urey, Weimer, Wildt, Wilkins.
PROGRESS OF RESEARCH
The successful launching of artificial satellites has inaugurated a new era in planetary astronomy. Already a greatly improved model for the uppermost layers of the terrestrial atmosphere has resulted [1] which has repercussions on the general problem of escape of planetary atmospheres to space. The interaction of planetary atmospheres with the interplanetary gas flowing from the Sun and the effects of planetary magnetic fields on the motion of this gas promise to be clarified next. The surface of the Moon, of such great interest to both planetary astronomy and geophysics, may soon be accessible to direct exploration. A much-broadened interest in planetary astronomy has resulted.
Progress has not been limited to these spectacular developments. Radio astronomy has progressed to the point where both extremes of the spectrum transmitted by the atmosphere (lambda ~ 2 cm and 15 meters) are well observable for some of the planets; and radar pulses reflected by the Moon have been recorded in such detail that they aid materially in the study of its surface texture. Norhave the more conventional approaches-visual, photographic, photo-electric, polarimetric, and spectroscopic-been lacking in important results.
Books or monographs were published on the following topics: The Planet Jupiter, by B. M. Peek [2]; Transfer of Radiation in the Atmospheres of Stars and Planets, by V. V. Sobolev [3]; 'Planetary Investigations at Kharkov', by N. P. Barabashev [4]; 'The Nature of Planets', by V. V. Sharonov [5]; The Moon, by H. P. Wilkins and P. Moore [6]; 'Lunar Eclipses', by F. Link [7]; `Study of the Planets from the Polarization of their Light', by A. Dollfus [8].
...
(from p. 249)
RADIO AND RADAR OBSERVATIONS
...
The lunar microwave emission, in its dependence on the monthly phase cycle, has been derived by Piddington and Minnett [62] at lambda = 1.25 cm, by Akabane [63] at lambda= 10 cm, by Zelinskaya and Troitski [64] at lambda =3.2 cm, and by Gibson [65] at lambda = 0.85 cm. Gibson also observed the total lunar eclipses of 1953 January 29, and 1954 January 18, which caused no decrease in the radio emission. The phase curve for 8.5 mm was found to indicate a dust layer on the average of several cm or more in depth [65].
Lunar radar echoes have become an important tool. The principal result to date is that at lambda = 10 cm and lambda = 150 cm the lunar surface is quite smooth [66, 67]; this is found from the sharpness of the returned pulse: half of the returned energy at lambda = 150 cm is received in the first 30-40 µsec. This is very different from the optical range where the Moon has no limb darkening. The Moon is, therefore, very rough in the micron and submicron range. At 1.5 meters the reflected beam has half the energy confined to a circle of one-tenth of the lunar radius [67]. Similar results have been obtained by Lovell. Such near-specular reflexion may be observed on the Earth above dry sandy soil [66). The reflexion at lambda= 10 cm seems to depend on the lunar libration, which adds to its potential interest.
...
(from p. 255)
LUNAR STUDIES
A. Dollfus [104] made polarimetric and photometric observations with the coronograph which enabled him to put an upper limit of 10^-10 terrestrial atm. for a possible lunar atmosphere. Costain, Elsmore and Whitfield [105] observed a radio occultation of the Crab Nebula and Elsmore [106] derived 10^-13 atm. as a plausible upper limit. Observation of the phase lag of the emission at lambda = 1.5 mm allowed W. M. Sinton [107] to derive a mass absorption coefficient of 2.9 cm2 g-1 for the lunar surface material. Gilvarry and Hill [108] studied the theory of lunar impacts. R. B. Baldwin reports that he has derived improved relationships between diameter, depth, rim width, rim height, and energy, for explosive craters ranging in diameter from 6 cm to the largest lunar craters. He derived similar relationships from sub-surface bursts.
A. Senouque attempted to determine from stereoscopic measures the relief and figure of the Moon by a method described before [109]; the uncertainty is ± 0.5 km per point. Th. Weimer is measuring 120 plates for a new determination of the physical libration and the quantity f. Preliminary result is f=0.60. He is also deriving for 24 small craters the three polar co-ordinates. Reference is made to Dr Watt's report in Commission 17.
G. Fielder [110] and D. Alter [111] have discussed the significance of certain lunar surface detail. H. C. Urey [112] gives a survey of previous lunar studies and presents his own views. G. P. Kuiper [113] discusses a set of new photographs and an interpretation of lunar surface features.
Many investigations of the lunar surface and its spectro-photometric properties have. been carried out in the U.S.S.R. J. Dubois [114] had reported evidence of luminescence on the Moon in the visual spectrum. N. S. Kozyrev [115] appears to have found confirmatory evidence in the Aristarchus-Herodotus region. Colorimetric studies were made by N. P. Barabashev and colleagues at Kharkov [116] and by V. V. Sharonov et al. at Leningrad [117]. The results obtained by V. V. Sharonov, N. S. Orlova, L. N. Radlova, and N. N. Sytinskaya have enabled the last author to develop the hypothesis that the lunar surface is covered with a (lark scoria originating from bedrock through high temperatures due to meteorite impact explosions [118]. N. S. Orlova published a photometric list of eighty-six lunar details [119] and obtained diffusion curves for maria and continents [120]. She further compared these curves with terrestrial samples and artificial models with very rough surfaces. The lunar diagrams are even more extreme, showing that the lunar surface is more cut up than any laboratory samples [121]. A. V. Markov [122] constructed a self-recording electro-polarimeter and measured forty lunar areas of different types. Dark-bottomed craters (Schickard, Grimaldi, etc.) were found to have less polarization than maria of the same albedo. Comparisons with meteorites were also made. N. N. Sytin-
(from p. 256)
skaya [123] derived the brightness of full Moon as 0.34 ± 0.01 lux. A study of the physical libration was published by G. S. Rechtenstamm [124].
G. P. Kuiper and associates are producing a photographic Lunar Atlas. The visible part of the Moon is divided into forty-four areas, each of which is shown under four different illuminations in Part I of the Atlas, which contains also a co-ordinate grid and names or other designations.
Lunar eclipses were observed by J. H. Focas [125] at Athens and by V. V. Sharonov and collaborators at Leningrad [126]. They were treated in monographs by F. Link [7] and D. Barbier [24].
G. P. KUIPER President of the Commission
(bibliography omitted)
(from p. 265)
17. COMMISSION DU MOUVEMENT ET DE LA FIGURE DE LA LUNE
PRÉSIDENT: C. B. Watts.
MEMBRES: MM. Atkinson, Boneff, Botelheiro, Brouwer, Eckert, Guth, Hirose, Koziel, Markowitz, Meyer, Nefediev, O'Keefe, Mme McBain Sadler, MM. Ueta, Weimer, Yakovkin.
PROGRESS OF RESEARCH
At the Royal Greenwich Observatory, Murray has made a study of the Moon's latitude as derived from occultations. He examined the term having the period of the libration in longitude and suggests that it may arise through a real ellipticity of the lunar surface. In a paper now in press he has investigated the negative acceleration of the Moon due to the reaction of the lunar oceanic tidal couple. From the eclipse and equinox observations of Hipparchus he derives a value twice as large as that given by the modern observations. He points out that if the acceleration actually does change, Ephemeris Time derived from lunar observations will not be uniform in the Newtonian sense.
Mrs McBain Sadler reports that the British Nautical Almanac Office has continued its routine programme of prediction of occultations for about seventy stations. It lias also started to provide approximate predictions of occultations of the twenty-six brightest radio sources in the second Cambridge survey for fifteen radio observatories.
The discussion of reduced observations has been published for the years 1951-52 in Astr. J. 6o, 315, 1955, and that for 1953- 55 has been submitted for publication. These observations have been reduced without limb corrections.
Many observations are still being received too late for the first discussion. These are being reduced as soon as available and prepared for inclusion in the re-discussion which will be made when corrections of limb errors become available from the results of the Washington survey of the marginal zone.
The combined list of all observations included in the discussion for 1948-53 has been prepared. It will be published as soon as possible and copies distributed to all the observers.
A. Botelheiro, of the Lisbon Observatory, reports that the Observatory continues as routine work the observation of occultations. Since 1938, when the programme was begun at Lisbon, 1023 occultations had been observed up to the end of 1956.
At Sofia, N. Boneff has continued his examination of the distribution of craters on the Moon's surface. Taking into account the circumstance that the eastern hemisphere is always in advance in the orbital motion of the Moon about the Earth, he finds no evidence in the relative distribution of craters between the two hemispheres to confirm the meteoritic theory of their origin.
K. Koziel is continuing his investigations of the Moon's rotation elements at the University Observatory, Cracow, and is about to complete the re-reduction of the Strassburg series of observations by Hartwig, 1877-79. The adjustment of these measures gives for the coefficient of the Yakovkin effect (the relation of the Moon's apparent radius to the latitude libration) the values:
- without limb corrections, + o"•oig±o"•oZ3;
- with Hayn's corrections, +o"oi8 ± o'•'ozo.
These are negligible quantities, as was the case with the Dorpat series of Hartwig. The Kazan series of measures by Banachiewicz, igio-Z5, is being re-reduced by J. Mietelski, as is the Bamberg series of Hartwig, 1890-1922, by J. Maslowski and Mrs H. Jasko.
G. Schrutka-Rechtenstamm, at the University Observatory, Vienna, has recently completed a new discussion of the rotation elements of the Moon utilizing observations made at Bamberg and Kasan. He takes into account a discrepancy which he has found
(from p. 266)
in the Berliner Jahrbuch for the years 1883-1922 between the mean longitude of the Moon and its right ascension and declination. His results are for I, T° 31' 52"±7", and for f, 0•625 ± 0•007. He has also re-reduced the heliometer measures of Franz at K6nigsberg, involving eight craters, as well as those of Hayn involving four craters. On the basis of these revised results a new reduction of the positions of z5o points measured by Franz on photographs has been made. It is planned to utilize these in forming a chart giving elevations referred to a level surface similar to that of Franz.
At the Paris Observatory, Senouque has continued his measures of photographs to determine the relief of the Moon by stereoscopic viewing.
Following the completion of his Atlas de profils lunaires Weimer has sought to obtain a new determination of the elements of the physical libration, and in particular of the value of f. A graphical representation of the residuals seems to confirm the results obtained earlier ( f=o•6o, approximately). The definitive calculations will be made later. He has also undertaken the determination of the selenographic co-ordinates (including the distance from the centre of the Moon) of twenty-four craters, with the purpose of establishing a sound basis for other researches.
At the Naval Observatory, Washington, the survey of the marginal zone of the Moon by Watts has progressed as follows : The measurement and analysis in 1956 of the last of 867 photographs, exposed on 503 nights, made possible the final adjustment of the datum surface. This operation, which required considerable experimentation, was finished in July z957 and the formation of the libration frame charts was then begun. These charts, to be based on about 480 00o measured elevations, are nearly one-fourth completed. It is hoped that the survey will be ready for publication late in 1958.
Markowitz has continued his programme with the dual-rate Moon position camera. The work is being arranged for reduction by punched-card methods. Twenty of these cameras and four measuring engines have been constructed for use in L(=.I'. programmes.
C. B. WATTS President of the Commission
ADDITIONS TO THE DRAFT REPORT
In the U.S.S.R. investigations of the rotational elements and of the figure of the Moon have been continued. At Engelhardt Observatory, Kazan, A. A. Nefediev continued his heliometer measures and made forty observations of M6sting A, which brings the total number of observations since i938 to 4ofi. S. T. Habibulin obtained i33 photographs of the Moon with the horizontal telescope. At Kiev, a series of I35 photographs has been completed at the University Observatory. L V. Gavrylov, at the Central Astronomical Observatory of the Ukrainian Academy of Sciences, Kiev, continued his series of photographic observations of the Moon, for examination of figure, and 250 photographs were obtained. Photographic observations by the Markowitz method have been started at Engelhardt Observatory, at Pulkovo Observatory, and at the Central Astronomical Observatory, Kiev. During the period zg55 to z957 about ioo observations of lunar occultations were made at Soviet Observatories.
At Engelhardt Observatory, Nefediev has drawn maps of the marginal zone of the Moon referred to the general zero level and to the selenographic system of co-ordinates introduced by Hayn. The maps are based on the heliometric observations of the crater Mbsting A which have been carried on continuously for nearly half a century at Engelhardt Observatory since Krasnov first began this work. Yakovkin has demonstrated that such maps must satisfy two conditions (Tvans. I.A.U. 8, 230, i952), namely
(i) After the reduction of the measured distances between the centre of the Moon and points on the limb, the value of the Moon's radius obtained when using the maps should be constant for all values of the libration. (It is well known that Hayn's maps do not satisfy this condition.)
(from p. 267)
(ii) The correction to the latitude of the Moon, derived from observations corrected for limb irregularities, should be sufficiently close to zero to be attributed to accidental errors. A considerable negative latitude correction is obtained from conventional methods of discussion. With Nefediev's new maps it is found that the libration effect on the Moon's radius is practically eliminated. The absolute value of the latitude correction derived from occultations was decreased by o'•'32 when corrections for limb irregularities were applied.
Habibulin has found from forty photographs (Z94q to 1952) the following system of elements for the physical libration.
A= -5° 10' 08"± 12" (m.e.) I=1133'06'+11" ,8=-3'10'3T'+ 8" Ro =15' 32•'59±W03 h=15' 33•'7±0"7 f =0•50±0•05
From a discussion of six series of heliometric observations made at Kazan, he has found, using the main term of the physical libration with annual period, the following values off, the function of the inertial moments of the Moon.
Observer f
Krasnov 0•58+0•08
Mikhailovsky 0•61±0•09
Banachiewicz 0•fi0+_0•03
Yakovkin 0•63+_0•O1
Belkovich 0•61+_0•03
Nefediev 0•59+0•04
He has also re-reduced the Dorpat heliometric series of Hartwig in order to determine the elements of physical libration. He used a slightly modified method, in which the coefficients of the two largest terms of physical libration in longitude were unknown. He found
A = -5° 11' 03"±9" (m.e.) I=1° 31' 22"+_ 14"
(3=-3° 10' 04"±8" f=0•60±0•03 h=15' 33"28+W35
At the Central Astronomical Observatory of the Ukrainian Academy of Sciences, Kiev, Gavrilov has completed the discussion of the first series of photographic observations consisting of ioo plates. He confirms the existence of a libration effect in the Moon's radius and finds a preliminary value of +0'•'04 for the coefficient corresponding to a change of z° in the libration in latitude.
At Kiev University Observatory, Gorynya and Drofa, from their photographic observations, found a corresponding value of +0'06.
Yakovkin applied harmonic analysis to the determination of the largest term of the physical libration in longitude, the argument of which is the Sun's mean anomaly. Assuming the five large Kazan series to be a continuous series of about 5o years, he found for this coefficient the value 76" ± 9", from which can be derived f= o•6q ± 0•02.
J. A. O'Keefe reports that during the past three years, the programme of determining island positions in the Pacific by occultations, observed photo-electrically with electronmultiplier tubes, has progressed to the operational stage. Hirose in Japan and Henriksen and his co-workers in the United States have developed methods of reduction. Positions have been obtained for Palau relative to the Philippines and for Marcus relative to Japan.
(from p. 268)
Report of Meeting. 18 August Z958 ACTING PRESIDENT: A. A. Nefediev.
SECRETARY: Mrs F. M. McBain Sadler.
The meeting, which was attended by over fifty members, was opened by Dr A. A. Nefediev explaining that the Executive Committee had asked him to be Acting President of the Commission, as Dr C. B. Watts was unfortunately unable to attend.
The Chairman called on A. A. Yakovkin to give an account of the work performed at Soviet Observatories during 1955-7 as this report had not been included in the Draft Refiorts; it is included in the additional reports above. The Draft Rel5ort was then approved.
The first part of the meeting was devoted to the Moon's rotation and figure, and the first speaker was A. A. Yakovkin, who reported on his work on the question of the zero level to be used for charts of the marginal zone. As the centre of mass is unknown, observations made only at the limb, at different phases and latitudes, cannot be represented by a single circle. The radius depends on the libration in latitude and can be expressed empirically by R_Ro+o,•'o5A*
A much better representation of the disk is obtained by considering the northern part as a semi-circle, whose centre coincides with the centre of mass, and the southern part by an ellipse whose semi-minor and semi-major axes respectively are Ro and 12o+a where
a = 0°96 + 0"08fl°. 0
He considers that this effect should be taken into account in the reduction of all observations of the Moon, as, for example, occultations. He emphasized that the result was empirical, but it is obtained from a very large number of observations and gives the best available representation of the figure of the Moon. Although the quantity a represents an additional layer due to craters and mountains, the coincidence of the centre of curvature of the northern part with the centre of mass means that this extra layer must have negligible mass. He is at present making a second approximation to take account of the asymmetry of the east and west hemispheres, so that all other observations such as heliometric and photographic may be satisfactorily represented.
In the discussion which followed, Clemence remarked that the datum surface adopted by Watts has the effect of reducing the value of 4/3 from o•6 to 0'•'3 which would still leave 0'•3 to be explained by the internal constitution of the Moon.
J. Hopmann described the work completed by G. Schrutl:a-Rechtenstamm at Vienna since the presentation of the Draft Report and showed the meeting Schrutka's design for the chart giving elevations referred to a level surface, and also a copy of his catalogue containing rectangular co-ordinates, selenographic longitudes and latitudes, and absolute altitudes. The altitudes are accurate to ± i•o km and seldom exceed i hm above and 5 km below the mean level, which indicates that the part of the Moon towards the Earth must be nearly spherical. Attention was called to an investigation by K. H. Engel of New York, using Schrutka's chart, which shows that on the average the belt of maria and the continents are about 2 km lower and 2 km higher respectively than the mean level.
W. Markowitz reported that C. B. Watts hoped to complete and send to the printer in July 1959 the charts derived from his survey of the marginal zone of the Moon. His data will also provide details on the figure of the Moon.
In the subsequent discussion Habibulin asked if details were available of Kuiper's proposed investigation. Clemence replied that Kuiper intends to study the librations of the Moon by using small bright specks on the surface in preference to craters, but this work has not been completed.
N. Boneff brought up to date the account of his work as described in the Draft Reports. He is preparing for publication the results of his statistical analyses. He emphasized that he had found no evidence in the relative distribution of craters between the eastern and
(from p. 269)
western hemispheres to confirm the meteoric theory of their origin. Sharonov questioned whether the effect would be appreciable in view of the smallness of the orbital motion. Boneff considered the effect cumulative and that the Moon has existed so long that it would not be negligible.
K. Koziel reported further on the work described in the Draft Re~orts. He has completed his re-reduction of the Strasbourg series of observations by Hartwig. His final values for the coefficient of the Yakovkin effect are
without limb corrections, -}-o•'or8±o<'oio; with Hayn's corrections, + o"o t 3± o°• or o.
These are negligible quantities as had been found with the Dorpat series.
A. A. Yakovkin said he regarded the customary method of combining observations for one hemisphere at a time as not permissible; if observations for the complete circle of the disk were taken at once, the polar diameter would exceed the equatorial by i". O'Keefe remarked that at the annular eclipse in i948 the Moon was found to fit the Sun exactly and gave no sign of prolateness.
The Acting President then discussed his own work on the marginal zone of the Moon and showed copies of his published charts. The compilation was completed at Lngelhardt Observatory in ic~57. The elevations are referred to a common zero level, which is the surface of a baricentric sphere. The position of the centre of this sphere was determined by using (i) the relation between the Moon's radius and optical libration in latitude as determined by Yakovkin and (ü) the value of the latitude correction derived from occultations by Spencer Jones. The charts were constructed using 563o elevations of points on the Moon's limb, based on the heliometric observations of Müsting A during the 5o ycars, I895-Z945• The charts are drawn in the selenographic co-ordinate system introduced by Hayn. For examination of the charts the libration efiect on the Moon's radius was computed using heliometric observations made by Hartwig at Bamberg and by Krasnov and Nefediev at Kazan. The results are given in a table published with the charts and they show that, when these observations are reduced with the new charts, the libration effect is practically zero, The reduction, using the new charts, of ic~~ occultations observed in Poland from igoi to Iq22 showed that the observed latitude correction is considerably less than when using Hayn's charts. The mean error of a limb irregularity - JimMosher JimMosherith the new charts is about +_ o'•'za.
In the discussion which followed Yalcovlcin pointed out that care must be taken in the reductions by different methods to ensure that the etfect of libration is taken into account. The different charts used different fundamental disks. Koziel said that his method had been adapted so that all reductions were made without charts and the necessary corrections, depending on the charts, easily applied.
S. T. Habibulin asked that a recommendation should be made that Commissions 4 and 7 should consider the publication of the ephemeris of Mtisting A, subsequent to the cessation of the Berliner • jalarbuch, and also the value to be used for the constant f. In the course of the discussion it was pointed out that the ephemeris of Môsting A will be published in the `Astronomical l;phemeris of the U.S.S.R.' It was considered that the value of f is still too uncertain to warrant a change in the adopted value. It was decided to adopt only the first part of the recommendation, namely that the publication of an ephemeris of M~sting A should be continued.
The meeting then directed its attention to the orbital motion of the Moon. W. Markowitz gave an account of the results obtained from the Moon cameras. Results were first obtained for rc~55 and did not give a smooth variation in AT. There were differences from lunation to lunation and often marked differences between first and third quarters. From I956, a new measuring machine was used which should give results freer from systematic error. R. G. Hall had completed a programme for the electronic computer for the 500 plates for Z957 to I958'5• There are still systematic errors present which are thought to be due to limb effects. Reference was made to the possibility of obtaining from the reductions the term o'•'27 cos l, due to the mean anomaly, of the correction derived by Brouwer
(from p. 270)
and Watts in their paper on occultation and transit observations; a fuller account of this would be given at the symposium on `The Rotation of the Earth and Atomic TimeStandards'. The final analyses will be made when Watts's results are available.
Some discussion followed in which Sharonov asked about the effects of irradiation. Potter said that experiments were to be made at Pulkovo Observatory to obtain the effects of irradiation, by photographing a sphere under different conditions.
J. A. O'Keefe drew the attention of the meeting to the results obtained on decimetre wave-lengths of the direct measurements of the distance of the Moon. These combined with the dynamical parallax give the best determination of the figure of the Earth. Yaplee has found good agreement with the generally adopted values of the Earth's equatorial radius and the Moon's horizontal parallax.
A. A. Yakovkin reported that he had examined i5oo meridian observations made at Greenwich and has deduced that the effect of libration causes the inclination derived from observations of the south limb to exceed by o'•'6 the inclination derived from north limb observations. This gives a libration effect in radius of o~'05 /3o agreeing with the value from general measures.
H. I. Potter reported that the Markowitz type of Moon camera had been used at Pulkovo Observatory since May 1957. The measurement and reduction of the plates is now being made. The Pulkovo Moon camera differs slightly from the Washington one, described by Markowitz in Astr. J. 59, 69, 1954. The Pulkovo camera cannot be called `dual rate' as it uses the clockwork of the 'Carte du Ciel' type astrograph, to which it is attached. The rotation of the plane-parallel filter is carried out by means of a synchronous motor, the change in the angular velocity of rotation being made, not mechanically, but by changing the frequency. It is well known that the plane parallel glass does not shift the image proportionally to the angle of tilt. The relation is
x=d sin z(i- ~~nz o sin2 z))=d (tan x+ Z z31,
where z is in radians. Tilting the filter as in the Washington camera eliminates only the terms given by tan z=mt and therefore some non-uniformity remains in the shift. In the Pulkovo camera the angular velocity of tilting the filter corresponds exactly to this nonuniformity of the shift and compensates for it. During the exposure time of 409 the error could otherwise amount to 0'•'06. In calculating the Moon's velocity before observation, account is taken of refraction, as its neglect can lead to an error exceeding i" at zenith distances of 70°-75° for an exposure time of qo9. The error depends on hour angle and therefore can distort considerably conclusions about geodetic data derived from Moon observations.
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