$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ NEAR $ $ Near Earth Asteroid Rendevous DPTRAJ-ODP CRUISE LOCKFILE, VERSION 1.3 $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ This file contains the text used to create near_lock_eros_V1.3.nio, $ the master DPTRAJ-ODP GIN file for NEAR radio science. $ $ Throughout this file, it is assumed EROS will take the place of Pluto $ as the object with ID code #9. $ $ $ -- CHANGE HISTORY -- $ $ June 1998 Version 1.0 $ Sept 1998 Version 1.1 Update station covariance (APNAM4, APNAM5) $ Add Eros Set III covariance $ Jan 2000 Version 1.2 Tweaked dates, new EOP. $ Feb 2000 Version 1.3 Nominal Eros gravity model, rotation. $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ IDPXIT = 0, $ LABL(1) = 'EROS LOCKFILE V1.3 - JANUARY 2000', LABL(2) = 'NEAR NAV/RADIO SCIENCE', LABL(3) = ' ', SCNAME = 'NEAR', SCID = 93, REF50 = .FALSE., $ Reference epoch: .FALSE. => 2000, .TRUE. => 1950 $ $ J2000 is an inertial coordinate system defined here by the planetary $ ephemeris and has a standard epoch of January 1.5, 2000, JD 2451545.0 $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ Astrodynamic constants from planetary & satellite ephemerides: $ $ The following astrodynamic constants are nominally obtained from the $ planetary and satellite ephemerides, unless explicitly specified in $ the GIN inputs. $ $ For these constants, the program GINUPDATE does the following: $ $ i) If the GIN inputs contain the values, it uses these. $ $ Otherwise: $ ii) If a satellite ephemeris is used, it gets the values from there. $ $ Otherwise: $ iii) It will read the values from the planet ephemeris, if used. $ $ In summary, all parameters are obtained from the assigned ephemerides; $ however, these values may be overwritten by GIN inputs. Two exceptions $ are AU and C: they cannot be overwritten by GIN inputs. $ $ $ Constants nominally obtained from the satellite ephemeris: $ $ GM of planet and satellites: GM, SATGM $ J2 & J3 of the planet: OBAJ(2), OBAJ(3) $ Planet pole right ascension, declination & rates & time: PLCOF $ $ The names on the satellite ephemeris file for Mars are: $ GM4, RADIUS, J402, J404, ZACPL4, ZDEPL4, DACPL4, $ DDEPL4, POLTIM, 401GM, 402GM, 400GM $ $ $ Constants nominally obtained from the planetary ephemeris: $ AU, BETREL, C, GAMREL, GM $ $ Note: Here GM(3) = GM0300 is calculated from GM0301 and EMRAT on the $ file by using GM0300 = EMRAT x GM301. $ $ Parameters gotten directly from the planetary ephemeris file: $ $ The values in DE403 are: $ $ AU = 0.1495978706910000D+09, $ Astronomical Unit. $ C = 0.2997924580000000D+06, $ Speed of light. $ EMRAT = 0.8130058500000000D+02, $ Earth-Moon GM ratio. $ NTSEC = 0.2062648062470964D+06, $ Arc seconds per radian. $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ BEGIN DPTRAJ $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ Astrodynamic Constants: $ $ 1) Davies, M. E., et al., "Report of the IAU/IAG/COSPAR Working Group $ on Cartographic Coordinates and Rotational Elements of the Planets $ and Satellites: 1994," Celestial Mechanics and Dynamical Astronomy, $ Vol. 63, 1996, pp. 127-148. $ $ 2) "The Introduction of the Improved IAU System of Astronomical $ Constants, Time Scales and Reference Frame into the Astronomical $ Almanac," Supplement to the Astronomical Almanac, Prepared $ Jointly by the Nautical Almanac Office, U.S. Observatory and $ H.M. Nautical Almanac Office, Royal Greenwich Observatory, 1983. $ $ 3) "Planetary Constants and Models," Mars Observer Project Document $ 642-321, JPL Document D-3444, November 1990. $ $ 4) Standish, E. M., et al., "JPL Planetary and Lunar Ephemerides, $ DE403/LE403", JPL IOM 314.10-127, May 22, 1995. $ $ Planetary radii (km): $ $ These are geometric equatorial radii of the planets. Note that there $ are also 'dynamic' radii used in the oblateness models specified by $ the variable 'ORB' which is independent of the geometric radii, 'RADI'. $ 'RADI' values are taken from Davies, except for Mars which is from the $ USGS model, as referenced by the Mars Project Planetary Constants Document. $ (Radii of planets 5, 6, 7, 8, correspond to a 1 bar surface). $ RADI( 1) = 0.243970D4, RADI( 2) = 0.605180D4, RADI( 3) = 0.637814D4, RADI( 4) = 0.339340D4, $ Mars - USGS model (See ref. 3). RADI( 5) = 0.714920D5, RADI( 6) = 0.602680D5, RADI( 7) = 0.255590D5, RADI( 8) = 0.247640D5, RADI( 9) = 0.119500D4, $ Pluto (over-written by Eros) RADI( 9) = 15.7D0 , $ EROS RADI(10) = 0.696000D6, RADI(11) = 0.173740D4, $ $ Planetary flatness: $ $ These values are calculated from data taken from Davies, except for $ Mars, which is from the USGS model, as referenced by the Mars Project $ Planetary Constants Document, and Eros, which is from '98 flyby data. $ $ The flatness factor is the geometric ellipticity of the body, equal $ to the ratio of the difference between the equatorial and polar $ radii to the equatorial radius. $ FLAT(1) = 11*0.0D0, $ Spherical model used for zero values. $ FLAT(3) = 0.003353642D0, $ Earth FLAT(4) = 0.005208300D0, $ Mars - USGS model (See ref. 3). FLAT(5) = 0.064874391D0, $ Jupiter FLAT(6) = 0.097962434D0, $ Saturn FLAT(7) = 0.022927344D0, $ Uranus FLAT(8) = 0.017081246D0, $ Neptune FLAT(9) = 0.055605095D0, $ EROS (Req= 15.7 km, Rp=6.97 km) $ $ Gravitational constants -- from ephemeris DE403: $ $ GM( 1) =.2203208048641792D+05, $ GM( 2) =.3248585988264597D+06, $ GM( 3) =.3986004356081032D+06, $ Updated later (gravity model) $ GM( 4) =.4282831425806710D+05, $ Updated later (gravity model) $ GM( 5) =.1267127678577960D+09, $ GM( 6) =.3794062606113727D+08, $ GM( 7) =.5794549007071872D+07, $ GM( 8) =.6836534063879259D+07, $ GM( 9) =.9816008877070042D+03, $ Pluto (not used) GM( 9) = .00048D0, $ EROS $ GM(10) =.1327124400179870D+12, $ GM(11) =.4902799107879768D+04, $ Updated in the gravity field model. $ $ BETREL = 1.0D0, $ Beta relativity parameter. $ GAMREL = 1.0D0, $ Gamma relativity parameter. LREL = 0.0D0, $ Relativity parameter. $ LOVENO(1,0,1) = 132*0.0D0, $ Zero out and initialize love numbers. $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ Oblateness model for Earth: $ $ Normalized Zonal, Sectorial & Tesseral harmonic coefficients. $ $ 1) B. D. Tapley, et al., "The JGM-3 Gravity Model," Annales Geophysicae, $ Supplement 1, C192, 1994. $ $ 2) R. S. Nerem, et al., "Gravity Model Development for TOPEX/Poseidon: $ Joint Gravity Models 1 and 2," Journal of Geophysical Research, $ paper number 94JC01376, 1994. $ $ 3) L. A. Cangahuala, et al., "TOPEX/Poseidon Precision Orbit Determination: $ Quick-Look Operations with SLR & GPS Data," Paper AAS 95-368 presented $ at AAS/AIAA Astrodynamics Specialist Conference, Halifax, Nova Scotia, $ Canada, 14-17 August 1995. $ $ An Earth GM value of 398600.4415 km3/s2 is used with the JGM-3 field. $ This value exceeds the DE403 value by 0.005892 km3/s2. $ $ The reference epoch for the J2, C21, S21 values was 01-JAN-1986. $ The following rates on J2, C21, S21 were applied: $ $ J2 rate = -1.16275535D-11 per year $ C21 rate = -1.3D-11 per year $ S21 rate = 1.1D-11 per year $ $ The values for J2, C21, S21 are for an epoch of 06-NOV-1996. $ OBF(1,2) = 'EARTH',8,0,8, $ 8 x 8 field. OBD(2) = 9.24649D5, $ Distance to end oblateness calculations(km). OBR(2) = 6378.1363D0, $ Gravitational equatorial mean radius (km). OBNORM(2) = .TRUE., $ Normalized harmonics. $ GM( 3) = 3.986004415D+5, $ Earth GM value in km3/s2. $ $ Zero out and initialize the harmonic coefficient array: $ OBXJ(1,1) = 15*0.0D0, OBXC(1,1,1) = 64*0.0D0, OBXS(1,1,1) = 64*0.0D0, $ $ The truncated (8x8) JGM-3 geopotential: $ OBXJ(1,1) = .000000000000D+00, OBXJ(2,1) = .484165249330D-03, OBXJ(3,1) = -.957170590888D-06, OBXJ(4,1) = -.539777068357D-06, OBXJ(5,1) = -.686589879865D-07, OBXJ(6,1) = .149671561786D-06, OBXJ(7,1) = -.907229416432D-07, OBXJ(8,1) = -.491180031747D-07, $ OBXC(1,1,1) = .000000000000D+00, OBXS(1,1,1) = .000000000000D+00, OBXC(2,1,1) = -.327998640000D-09, OBXS(2,1,1) = .131459710000D-08, OBXC(2,2,1) = .243926074866D-05, OBXS(2,2,1) = -.140026639759D-05, OBXC(3,1,1) = .203013720555D-05, OBXS(3,1,1) = .248130798256D-06, OBXC(3,2,1) = .904706341273D-06, OBXS(3,2,1) = -.618922846478D-06, OBXC(3,3,1) = .721144939823D-06, OBXS(3,3,1) = .141420398474D-05, OBXC(4,1,1) = -.536243554299D-06, OBXS(4,1,1) = -.473772370616D-06, OBXC(4,2,1) = .350670156459D-06, OBXS(4,2,1) = .662571345943D-06, OBXC(4,3,1) = .990868905774D-06, OBXS(4,3,1) = -.200987354847D-06, OBXC(4,4,1) = -.188481367425D-06, OBXS(4,4,1) = .308848036904D-06, OBXC(5,1,1) = -.627273696977D-07, OBXS(5,1,1) = -.941946321344D-07, OBXC(5,2,1) = .652459102764D-06, OBXS(5,2,1) = -.323334352444D-06, OBXC(5,3,1) = -.451837048088D-06, OBXS(5,3,1) = -.214954193464D-06, OBXC(5,4,1) = -.295123393022D-06, OBXS(5,4,1) = .497414272309D-07, OBXC(5,5,1) = .174831577700D-06, OBXS(5,5,1) = -.669392937249D-06, OBXC(6,1,1) = -.761035804073D-07, OBXS(6,1,1) = .268998189326D-07, OBXC(6,2,1) = .483274721249D-07, OBXS(6,2,1) = -.373815919444D-06, OBXC(6,3,1) = .570209657580D-07, OBXS(6,3,1) = .888947380083D-08, OBXC(6,4,1) = -.862280326198D-07, OBXS(6,4,1) = -.471405112321D-06, OBXC(6,5,1) = -.267112271720D-06, OBXS(6,5,1) = -.536410164664D-06, OBXC(6,6,1) = .950165183386D-08, OBXS(6,6,1) = -.237261478895D-06, OBXC(7,1,1) = .280286522037D-06, OBXS(7,1,1) = .947773178133D-07, OBXC(7,2,1) = .329760227424D-06, OBXS(7,2,1) = .931936968310D-07, OBXC(7,3,1) = .250501526750D-06, OBXS(7,3,1) = -.217320108453D-06, OBXC(7,4,1) = -.275540963074D-06, OBXS(7,4,1) = -.124141512485D-06, OBXC(7,5,1) = .164400381464D-08, OBXS(7,5,1) = .180753352335D-07, OBXC(7,6,1) = -.358842633079D-06, OBXS(7,6,1) = .151778084434D-06, OBXC(7,7,1) = .137951705641D-08, OBXS(7,7,1) = .241285940808D-07, OBXC(8,1,1) = .233337516872D-07, OBXS(8,1,1) = .584992749394D-07, OBXC(8,2,1) = .800706639316D-07, OBXS(8,2,1) = .655185590975D-07, OBXC(8,3,1) = -.192517643314D-07, OBXS(8,3,1) = -.862858365342D-07, OBXC(8,4,1) = -.244358064393D-06, OBXS(8,4,1) = .698570748504D-07, OBXC(8,5,1) = -.254984100103D-07, OBXS(8,5,1) = .890902974946D-07, OBXC(8,6,1) = -.658593538644D-07, OBXS(8,6,1) = .308920641580D-06, OBXC(8,7,1) = .672627018487D-07, OBXS(8,7,1) = .748131967687D-07, OBXC(8,8,1) = -.123970613955D-06, OBXS(8,8,1) = .120441006688D-06, $ $ Love number for Earth: $ $ 1) Global Earth Physics - A Handbook of Physical Constants, $ AGU Reference Shelf 1, American Geophysical Union, 1995. $ $ See the section by Charles F. Yoder (JPL): $ "Astrometric and Geodetic Properties of Earth and the Solar System" $ $ 2) Merit Standard from D. N. Yuan, June 5, 1992. $ LOVENO(2,0,3) = 0.2990D0, LOVENO(2,1,3) = 0.3000D0, LOVENO(2,2,3) = 0.3020D0, LOVENO(3,0,3) = 0.0930D0, LOVENO(3,1,3) = 0.0930D0, LOVENO(3,2,3) = 0.0930D0, LOVENO(3,3,3) = 0.0940D0, $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ Oblateness model for the Moon: $ $ Normalized Zonal, Sectorial & Tesseral harmonic coefficients. $ $ LUN60D: 60th degree and order lunar gravity field based upon Lunar $ Orbiters I through V and Apollo 15 and 16 subsatellites. $ $ The reference for this gravity field is: $ $ 1) A. S. Konopliv, W. L. Sjogren, R. N. Wimberly, R. A. Cook, and $ V. Alwar, "A High Resolution Lunar Gravity Field and Predicted $ Orbit Behavior," paper AAS 93-622 presented at AAS/AIAA Astrodynamics $ Specialist Conference, Victoria, B.C., Canada, August 16-19, 1993. $ $ A lunar GM value of 4902.797814 km3/s2 is used with the LUN60D field. $ This value is less than the DE403 value by 0.001294 km3/s2. $ $ The harmonic coefficients below are normalized and use an equatorial $ radius for the Moon of 1738.0 km. $ OBF(1,3) = 'MOON',8,0,8, $ 8 x 8 field. OBD(3) = 6.6183D4, $ Distance to end oblateness calculations (km). OBR(3) = 1738.0D0, $ Gravitational equatorial mean radius (km). OBNORM(3) = .TRUE., $ Normalized harmonics. $ GM(11) = 4902.797814D0, $ Moon GM value in km3/s2. $ $ Zero out and initialize the harmonic coefficient array: $ OBXJ(1,2) = 15*0.0D0, OBXC(1,1,2) = 64*0.0D0, OBXS(1,1,2) = 64*0.0D0, $ $ The truncated (8x8) LUN60D potential: $ OBXJ(1,2) = .000000000000D+00, OBXJ(2,2) = .911441850621D-04, OBXJ(3,2) = .311902819637D-05, OBXJ(4,2) = -.307835221987D-05, OBXJ(5,2) = .769368830934D-06, OBXJ(6,2) = -.420247761012D-05, OBXJ(7,2) = -.555725061234D-05, OBXJ(8,2) = -.258213200841D-05, $ OBXC(1,1,2) = .000000000000D+00, OBXS(1,1,2) = .000000000000D+00, OBXC(2,1,2) = -.251087450783D-06, OBXS(2,1,2) = .189247705893D-06, OBXC(2,2,2) = .346584314967D-04, OBXS(2,2,2) = -.105183661563D-06, OBXC(3,1,2) = .264955051975D-04, OBXS(3,1,2) = .543526879871D-05, OBXC(3,2,2) = .143205732800D-04, OBXS(3,2,2) = .481901453019D-05, OBXC(3,3,2) = .123281980475D-04, OBXS(3,3,2) = -.151614566810D-05, OBXC(4,1,2) = -.601000708063D-05, OBXS(4,1,2) = .144154958330D-05, OBXC(4,2,2) = -.756048899234D-05, OBXS(4,2,2) = -.660908653420D-05, OBXC(4,3,2) = -.157205412560D-05, OBXS(4,3,2) = -.134147521823D-04, OBXC(4,4,2) = -.606603204952D-05, OBXS(4,4,2) = .356365436446D-05, OBXC(5,1,2) = -.993581295251D-06, OBXS(5,1,2) = -.409939311978D-05, OBXC(5,2,2) = .430063826944D-05, OBXS(5,2,2) = .121711990315D-05, OBXC(5,3,2) = .902472365556D-06, OBXS(5,3,2) = .850307049372D-05, OBXC(5,4,2) = .276860468026D-05, OBXS(5,4,2) = .552557057068D-07, OBXC(5,5,2) = .322944662780D-05, OBXS(5,5,2) = -.222204702132D-05, OBXC(6,1,2) = .196677219382D-05, OBXS(6,1,2) = -.317395782132D-05, OBXC(6,2,2) = -.416720046585D-05, OBXS(6,2,2) = -.211311689024D-05, OBXC(6,3,2) = -.316953232988D-05, OBXS(6,3,2) = -.376535765877D-05, OBXC(6,4,2) = -.180602664212D-06, OBXS(6,4,2) = -.358296927763D-05, OBXC(6,5,2) = .145132004062D-05, OBXS(6,5,2) = -.103266424334D-04, OBXC(6,6,2) = -.482864333845D-05, OBXS(6,6,2) = .644590137048D-05, OBXC(7,1,2) = .728684437826D-05, OBXS(7,1,2) = -.158503139890D-06, OBXC(7,2,2) = -.100389024426D-05, OBXS(7,2,2) = .285458316571D-05, OBXC(7,3,2) = .287132227683D-06, OBXS(7,3,2) = .217926631287D-05, OBXC(7,4,2) = -.112896199507D-05, OBXS(7,4,2) = .118350939045D-05, OBXC(7,5,2) = .460145803221D-06, OBXS(7,5,2) = .438750435056D-07, OBXC(7,6,2) = -.121628912845D-05, OBXS(7,6,2) = .976728544757D-06, OBXC(7,7,2) = -.164471397816D-05, OBXS(7,7,2) = -.607247211380D-06, OBXC(8,1,2) = .283644952155D-06, OBXS(8,1,2) = .130269495198D-05, OBXC(8,2,2) = .359236596796D-05, OBXS(8,2,2) = .192706617599D-05, OBXC(8,3,2) = -.157578446767D-05, OBXS(8,3,2) = .410590400224D-06, OBXC(8,4,2) = .397422040228D-05, OBXS(8,4,2) = -.614403578567D-06, OBXC(8,5,2) = -.112498071178D-05, OBXS(8,5,2) = .228062269000D-05, OBXC(8,6,2) = -.243673445826D-05, OBXS(8,6,2) = -.370214046613D-06, OBXC(8,7,2) = -.116915198183D-05, OBXS(8,7,2) = .352222836341D-05, OBXC(8,8,2) = -.259980412308D-05, OBXS(8,8,2) = .974066807776D-06, $ $ Love number for the Moon: $ $ 1) Global Earth Physics - A Handbook of Physical Constants, $ AGU Reference Shelf 1, American Geophysical Union, 1995. $ $ See the section by Charles F. Yoder (JPL): $ "Astrometric and Geodetic Properties of Earth and the Solar System" $ $ 2) Ferrari, A. J., et al., "Geophysical Parameters of the Earth-Moon $ System," Journal of Geophysical Research, Vol. 85, pp. 3939-3951. $ LOVENO(2,0,11) = 0.0302D0, $ +/- 0.0012 LOVENO(2,1,11) = 0.0302D0, $ From Ferrari: 0.022 +/- 0.013 LOVENO(2,2,11) = 0.0302D0, $ $ Earth-Moon indirect oblateness: $ IOBF = 1, $ 1 => On, 0 => Off $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ Oblateness model for Mars: $ $ Normalized Zonal, Sectorial & Tesseral harmonic coefficients. $ $ The following is the "header" information which was on the original $ gravity coefficient file obtained from Alex Konopliv: $ $ JPL Gravity field MARS50C $ From Viking 1,2 and Mariner 9 data $ $ Alex Konopliv $ Jet Propulsion Laboratory $ ask@krait.jpl.nasa.gov $ (818) 354-6105 $ $ 1) Alexander S. Konopliv, William L. Sjogren, "The JPL Mars Gravity $ Field, Mars50c, Based Upon Viking and Mariner 9 Doppler Tracking $ Data", JPL Publication 95-5, February 1995. $ $ 2) Davies, M. E., et al., "Report of the IAU/IAG/COSPAR Working Group $ on Cartographic Coordinates and Rotational Elements of the Planets $ and Satellites: 1991," Celestial Mechanics and Dynamical Astronomy, $ Vol. 53, 1992, pp. 377-397. $ $ The following paragraphs from the above reference describe some of $ the parameters used in the gravity field generation. $ $ The International Astronomical Union (IAU) 1991 (Davies et al., $ 1992) rotational constants specified the orientation of Mars and, $ hence, the gravity field. The JPL DE200 planetary ephemeris $ (Standish, 1990) was used for calculation of the planetary point $ mass perturbations. The MAR027 Phobos and Deimos satellite ephemeris $ covered the Viking data time span for the calculation of the point $ mass accelerations of Phobos and Deimos on the spacecraft, but no $ forces on Mariner 9 were included due to Phobos and Deimos. MAR027 $ is a fit of the observations of Phobos and Deimos to the Sinclair/Morley $ theory. $ $ For the Doppler observables, averaged seasonal troposphere $ calibrations as given by Chao (1972) were applied. Any observations $ below 10-degrees elevation were deleted because of unmodeled troposphere $ effects. Daily UT1 and polar motion values from the JPL Space91 $ solution (Gross, 1992) were included and DSN station locations are $ in the International Earth Rotation Service (IERS) reference frame $ as given by Folkner (1991) with the AMO-2 plate motion model and $ solid-Earth tides corrections added. Ideally, future solutions will $ include the frame tie rotational offset between the IERS and planetary $ ephemeris frames, solve for the Mars ephemeris, or use an ephemeris $ such as DE400 in the radio frame. $ $ Planetary constants related to the gravity field: $ $ The following are the ODP Mars rotational parameters namelist inputs $ which are consistent with the Mars50c gravity field. They are from the $ 1991 IAU/IAG/COSPAR working group report on coordinates and rotational $ elements. $ $ Size of gravity field to activate in trajectory calculations: $ OBF(1,4) = 'MARS',8,0,8, $ Truncated to an 8 x 8 field. $ $ Distance within which oblateness calculations begin (km): $ OBD(1) = 5.77232D5, $ $ Gravitational equatorial mean radius (km): $ OBR(1) = 3394.2D0, $ $ Mars GM associated with gravity field (km3/s2): $ Note: This value may overwrite, or be overwritten by, the values on $ the planetary or satellite ephemeris files. $ GM( 4) = 42828.370371D0, $ $ Are the spherical harmonics normalized or unnormalized: $ OBNORM(1) =.TRUE., $ Normalized harmonics $ $ Zero out and initialize the harmonic coefficient array: $ OBAJ(1) = 50*0.0D0, OBAC(1,1) = 2500*0.0D0, OBAS(1,1) = 2500*0.0D0, $ $ Zonal harmonics (normalized): $ OBAJ(1) = .000000000000D+00, OBAJ(2) = .875919760273D-03, OBAJ(3) = .119340679166D-04, OBAJ(4) = -.515052493229D-05, OBAJ(5) = .182402897065D-05, OBAJ(6) = -.145665966143D-05, OBAJ(7) = -.840128810448D-06, OBAJ(8) = -.498316049196D-06, $ $ Sectorial & Tesseral harmonic coefficients (normalized): $ $ OBAC & OBAS are stored on the GIN file as OBACS. $ OBAC(1,1) = .000000000000D+00, OBAS(1,1) = .000000000000D+00, OBAC(2,1) = .132033468405D-07, OBAS(2,1) = .675285290457D-09, OBAC(2,2) = -.843122022711D-04, OBAS(2,2) = .496785329690D-04, OBAC(3,1) = .386567700057D-05, OBAS(3,1) = .252774247650D-04, OBAC(3,2) = -.159257903505D-04, OBAS(3,2) = .846687289437D-05, OBAC(3,3) = .354141266874D-04, OBAS(3,3) = .251996626619D-04, OBAC(4,1) = .423920765688D-05, OBAS(4,1) = .374755584188D-05, OBAC(4,2) = -.111646822443D-05, OBAS(4,2) = -.896339096830D-05, OBAC(4,3) = .651418723273D-05, OBAS(4,3) = -.272352421181D-06, OBAC(4,4) = .113002982991D-06, OBAS(4,4) = -.128953895406D-04, OBAC(5,1) = .483319737757D-06, OBAS(5,1) = .209711155235D-05, OBAC(5,2) = -.424950879878D-05, OBAS(5,2) = -.122480912838D-05, OBAC(5,3) = .330314698123D-05, OBAS(5,3) = .254191256762D-06, OBAC(5,4) = -.468758582735D-05, OBAS(5,4) = -.332592263843D-05, OBAC(5,5) = -.442180487607D-05, OBAS(5,5) = .383605422433D-05, OBAC(6,1) = .189292146731D-05, OBAS(6,1) = -.162575855711D-05, OBAC(6,2) = .952881708647D-06, OBAS(6,2) = .161247203944D-05, OBAC(6,3) = .951313518098D-06, OBAS(6,3) = .244050571795D-06, OBAC(6,4) = .103496966548D-05, OBAS(6,4) = .265185330216D-05, OBAC(6,5) = .178175240614D-05, OBAS(6,5) = .162897120977D-05, OBAC(6,6) = .278529844665D-05, OBAS(6,6) = .785346403849D-06, OBAC(7,1) = .114392658047D-05, OBAS(7,1) = -.121424715130D-06, OBAC(7,2) = .279913674214D-05, OBAS(7,2) = -.731916050571D-06, OBAC(7,3) = .840389648008D-06, OBAS(7,3) = -.423723215581D-06, OBAC(7,4) = .239819519371D-05, OBAS(7,4) = -.525983697776D-06, OBAC(7,5) = -.308772049354D-06, OBAS(7,5) = -.133474272819D-05, OBAC(7,6) = -.572301952896D-06, OBAS(7,6) = -.193627126643D-05, OBAC(7,7) = .419198548050D-06, OBAS(7,7) = -.177122313587D-05, OBAC(8,1) = .202856025184D-06, OBAS(8,1) = .626151101085D-06, OBAC(8,2) = .166759972810D-05, OBAS(8,2) = .659128506006D-06, OBAC(8,3) = -.108712385793D-05, OBAS(8,3) = -.132729727828D-05, OBAC(8,4) = .162651101420D-05, OBAS(8,4) = .415430115159D-07, OBAC(8,5) = -.279554256497D-05, OBAS(8,5) = -.162629432881D-05, OBAC(8,6) = -.100692473264D-05, OBAS(8,6) = -.176741453509D-05, OBAC(8,7) = -.493709063200D-06, OBAS(8,7) = .165618103486D-05, OBAC(8,8) = -.306068555105D-06, OBAS(8,8) = -.263871691654D-06, $ $ Love number for Mars: $ $ 1) Global Earth Physics - A Handbook of Physical Constants, $ AGU Reference Shelf 1, American Geophysical Union, 1995. $ $ See the section by Charles F. Yoder (JPL): $ "Astrometric and Geodetic Properties of Earth and the Solar System" $ $ These values are based on a planetary (Mars) structure model: $ LOVENO(2,0,4) = 0.1400D0, LOVENO(2,1,4) = 0.1400D0, LOVENO(2,2,4) = 0.1400D0, $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ Eros nominal gravity model. $ $ Based on "Determination of Eros Physical Parameters for Near Earth $ Asteroid Rendevous Orbit Phase Navigation", Miller, Antreasian, Gaskell, $ Giorgini, Helfrich, Owen, Williams, Yeomans. AAS 99-463, Girdwood, $ Alaska, 1999. $ OBF(1,1) = 'PLUTO',8,0,8, $ $ Gravitational equatorial mean radius (km): $ OBR(1) = 16.D0, $ $ Distance within which oblateness calculations begin (km): $ OBD(1) = 1500.D0, $ $ Eros GM associated with gravity field (km3/s2): $ Note: This value may overwrite, or be overwritten by, the values on $ the planetary or satellite ephemeris files. $ GM( 9) = 4.8D-4, $ $ Are the spherical harmonics normalized or unnormalized: $ OBNORM(1) =.TRUE., $ Normalized harmonics $ $ Zero out and initialize the harmonic coefficient array: $ OBAJ(1) = 50*0.0D0, OBAC(1,1) = 2500*0.0D0, OBAS(1,1) = 2500*0.0D0, $ $ Zonal harmonics (normalized): $ OBAJ(2) = -4.7D-2, OBAJ(4) = 1.1D-2, OBAJ(6) = -3.9D-3, $ $ Sectorial & Tesseral harmonic coefficients (normalized): $ $ OBAC & OBAS are stored on the GIN file as OBACS. $ OBAC(2,2) = 8.1D-2, OBAC(4,2) = -1.5D-2, OBAC(4,4) = 1.7D-2, OBAC(6,2) = 5.3D-3, OBAC(6,4) = -4.3D-3, OBAC(6,6) = 5.0D-3, $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ Resonant harmonics: $ $ This model may be used to input (and solve for) harmonic terms higher than $ the gravity field specified -- e.g. for harmonics which may be large due $ to gravity field resonance. $ $ For example, suppose one was using a 20x20 gravity field (defined in OBF), $ and there should be gravity resonance at this orbit around the 51st $ harmonic order. One may set: $ $ RESNAM(1) = '4J51', 4C51_50', $ $ and input the appropriate nominal values in RESJCS. $ These parameters may also be estimated using the usual naming convention $ for gravity harmonic partials. $ RESNAM( 1) = 20*' ', RESJCS( 1) = 20*0.0D0, $ $ Lumped sum gravity parameters: $ $ This model allows one to generate a partial (LSGM?) for a lumped sum $ gravity field: $ $ LSGMD = d/dJi(dr/dtdt) * DELJi + d/dJi(dr/dtdt) * DELCnm $ $ The partial is specified by the user inputting values for the DELJi, $ DELCnm, DELSnm for use in the above equation, through the GIN inputs $ DELJ(i), DELC(i,j), DELS(i,j). $ $ NOTE: This model has no effect on the trajectory. It just defines how $ to compute a partial. One cannot iterate on the estimated value $ for LSGMD. Therefore its usefulness is very limited. It was put $ into the ODP at the request of section 335(?) for study purposes. $ $ The DELC & DELS parameters are stored in the GIN file as DELCS. $ DELJ(1) = 50*0.0D0, DELC(1,1) = 2500*0.0D0, DELS(1,1) = 2500*0.0D0, DELRES(1) = 20*0.0D0, $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ Coordinate transformation data: $ $ For precession values (J2000 coordinate transformation): $ $ 1) J. H. Lieske et al, "Expressions for the Precession Quantities $ Based Upon the IAU (1976) System of Astronomical Constants", $ Table 5, Astronomy & Astrophysics, Vol. 58, 1977. $ $ 2) J. H. Lieske, 'Precession Matrix Based on IAU (1976) System of $ Astronomical Constants," Astronomy & Astrophysics, Vol. 73, $ pp. 282-284, 1979. $ $ For obliquity values: $ $ 3) The Astronomical Almanac for the Year 1996, Page B18. $ Units (C=Century): ', '/C, '/(C**2), '/(C**3) $ $ For sidereal values: $ $ 4) T. D. Moyer, "Proposed Changes to ODP Transformation Between $ Body-Fixed and Space-Fixed Coordinates for the Planets and $ the Sun," JPL EM 314-271, June 16, 1982. $ $ For north pole & prime meridian directions: $ $ 5) Davies, M. E., et al., "Report of the IAU/IAG/COSPAR Working Group $ on Cartographic Coordinates and Rotational Elements of the Planets $ and Satellites: 1994," Celestial Mechanics and Dynamical Astronomy, $ Vol. 63, 1996, pp. 127-148. $ $ Coefficients for Earth precession polynomials: $ PRECES(1,1) = 2306.2181D0, 0.301880D0, 0.017998D0, $ ZETA(A) 2004.3109D0, -0.426650D0, -0.041833D0, $ THETA(A) 2306.2181D0, 1.094680D0, 0.018203D0, $ Z(A) $ OBLQTY(1) = 84381.45000D0, -46.81500D0, -0.00060D0, 0.00181D0, $ $ Coefficients for Earth mean sidereal time polynomials: $ SIDERL(1) = 67310.54841D0, 3.164400184812866D9, 0.093104D0, -0.620D-5, $ $ Interpolate the Earth's nutation from the planetary ephemeris: $ (.TRUE. => compute values) $ NUTCMP = .FALSE., $ $ If NUTCMP is TRUE, set the following parameters: $ NFUND( 1, 1) = 20*0.0D0, NUTAMP(1,1,1) = 424*0.0D0, NUTARG( 1, 1) = 530*0, $ $ North pole and prime meridian direction of the planets and Sun. $ The sets of 'PLCOF's below mean the following: $ $ 1,1 RA of mean North Pole at January 1.5, 2000 in EME2000, degrees. $ 2,1 RA DOT, same epoch as above, degree/Julian century. $ 1,2 DEC of mean North Pole at January 1.5, 2000 in EME2000, degrees. $ 2,2 DEC DOT, same epoch as above, degree/Julian century. $ 1,3 Angle from the ascending node to planet prime meridian, degrees. $ 2,3 Mean sidereal rotation rate, degree/day. $ PLREF(1) = 9*0.0D0, $ Seconds past the reference epoch for PLCOF. PLCOF(1,1,1) = 54*0.D0, $ Initialize 2x3x9 array $ PLCOF(1,1,1) = 281.01D0, $ Mercury PLCOF(2,1,1) =-0.033D0, PLCOF(1,2,1) = 61.450D0, PLCOF(2,2,1) =-0.005D0, PLCOF(1,3,1) = 329.68D0, PLCOF(2,3,1) = 6.1385025D0, $ PLCOF(1,1,2) = 272.76D0, $ Venus PLCOF(2,1,2) = 0.0D0, PLCOF(1,2,2) = 67.16D0, PLCOF(2,2,2) = 0.0D0, PLCOF(1,3,2) = 160.20D0, PLCOF(2,3,2) =-1.4813688D0, $ PLCOF(1,1,3) = 317.681D0, $ Mars PLCOF(2,1,3) =-0.108D0, PLCOF(1,2,3) = 52.886D0, PLCOF(2,2,3) =-0.061D0, PLCOF(1,3,3) = 176.901D0, PLCOF(2,3,3) = 350.8919830D0, $ PLCOF(1,1,4) = 268.05D0, $ Jupiter PLCOF(2,1,4) =-0.009D0, PLCOF(1,2,4) = 64.49D0, PLCOF(2,2,4) = 0.003D0, PLCOF(1,3,4) = 284.95D0, PLCOF(2,3,4) = 870.5360000D0, $ PLCOF(1,1,5) = 40.589D0, $ Saturn PLCOF(2,1,5) =-0.036D0, PLCOF(1,2,5) = 83.537D0, PLCOF(2,2,5) =-0.004D0, PLCOF(1,3,5) = 38.90D0, PLCOF(2,3,5) = 810.7939024D0, $ PLCOF(1,1,6) = 257.311D0, $ Uranus PLCOF(2,1,6) = 0.0D0, PLCOF(1,2,6) =-15.175D0, PLCOF(2,2,6) = 0.0D0, PLCOF(1,3,6) = 203.81D0, PLCOF(2,3,6) =-501.1600928D0, $ PLCOF(1,1,7) = 299.36D0, $ Neptune (trigonometric terms ignored) PLCOF(2,1,7) = 0.0D0, PLCOF(1,2,7) = 43.46D0, PLCOF(2,2,7) = 0.0D0, PLCOF(1,3,7) = 253.18D0, PLCOF(2,3,7) = 536.3128492D0, $ PLCOF(1,1,8) = 313.02D0, $ Pluto (over-written by Eros) PLCOF(2,1,8) = 0.0D0, PLCOF(1,2,8) = 9.09D0, PLCOF(2,2,8) = 0.0D0, PLCOF(1,3,8) = 236.77D0, PLCOF(2,3,8) = -56.3623195D0, $ PLCOF(1,1,8) = 15.6 , $ Eros (nominal) PLCOF(2,1,8) = 0.0D0, PLCOF(1,2,8) = 16.4 , PLCOF(2,2,8) = 0.0D0, PLCOF(1,3,8) = 324.1D0, $ W(J2000.0), deg, 01/99 PLCOF(2,3,8) = 1639.4344704D0, $ Wdot (deg/day), 01/99 $ PLCOF(1,1,9) = 286.13D0, $ Sol PLCOF(2,1,9) = 0.0D0, PLCOF(1,2,9) = 63.87D0, PLCOF(2,2,9) = 0.0D0, PLCOF(1,3,9) = 84.10D0, PLCOF(2,3,9) = 14.1844000D0, $ $ North pole and prime meridian direction of the Moon. There are $ additional terms in the model which are not implemented in ODP. $ LUNREF = 0.0D0, $ The reference epoch is J2000. $ LUNCOF(1,1) = 269.9949D0, $ RA, constant term LUNCOF(2,1) = 0.0031D0, $ RA, linear term LUNCOF(3,1) = 0.0D0, $ RA, quadratic term LUNCOF(4,1) = -3.8787D0, $ RA, coefficient of SIN(E1) LUNCOF(5,1) = -0.1204D0, $ RA, coefficient of SIN(E2) LUNCOF(6,1) = 0.0700D0, $ RA, coefficient of SIN(E3) LUNCOF(7,1) = -0.0172D0, $ RA, coefficient of SIN(E4) LUNCOF(8,1) = 0.0D0, $ RA, coefficient of SIN(E5) $ LUNCOF(1,2) = 66.5392D0, $ DEC, constant term LUNCOF(2,2) = 0.013D0, $ DEC, linear term LUNCOF(3,2) = 0.0D0, $ DEC, quadratic term LUNCOF(4,2) = 1.5419D0, $ DEC, coefficient of COS(E1) LUNCOF(5,2) = 0.0239D0, $ DEC, coefficient of COS(E2) LUNCOF(6,2) = -0.0278D0, $ DEC, coefficient of COS(E3) LUNCOF(7,2) = 0.0068D0, $ DEC, coefficient of COS(E4) LUNCOF(8,2) = 0.0D0, $ DEC, coefficient of COS(E5) $ LUNCOF(1,3) = 38.3213D0, $ W, constant term LUNCOF(2,3) = 13.17635815D0,$ W, linear term LUNCOF(3,3) = 0.0D0, $ W, quadratic term LUNCOF(4,3) = 3.5610D0, $ W, coefficient of SIN(E1) LUNCOF(5,3) = 0.1208D0, $ W, coefficient of SIN(E2) LUNCOF(6,3) = -0.0642D0, $ W, coefficient of SIN(E3) LUNCOF(7,3) = 0.0158D0, $ W, coefficient of SIN(E4) LUNCOF(8,3) = 0.0252D0, $ W, coefficient of SIN(E5) $ LUNCF2(1,1) = 125.045D0, $ E1, constant term LUNCF2(2,1) = -0.0529921D0, $ E1, linear term LUNCF2(3,1) = 0.0D0, $ E1, quadratic term $ LUNCF2(1,2) = 250.089D0, $ E2, constant term LUNCF2(2,2) = -0.1059842D0, $ E2, linear term LUNCF2(3,2) = 0.0D0, $ E2, quadratic term $ LUNCF2(1,3) = 260.008D0, $ E3, constant term LUNCF2(2,3) = -13.0120009D0,$ E3, linear term LUNCF2(3,3) = 0.0D0, $ E3, quadratic term $ LUNCF2(1,4) = 176.625D0, $ E4, constant term LUNCF2(2,4) = 13.3407154D0, $ E4, linear term LUNCF2(3,4) = 0.0D0, $ E4, quadratic term $ LUNCF2(1,5) = 357.529D0, $ E5, constant term LUNCF2(2,5) = -0.9856003D0, $ E5, linear term LUNCF2(3,5) = 0.0D0, $ E5, quadratic term $ $ Phobos and Deimos RA, DEC and W angle data: $ MSREF( 1) = 0.0D0, 0.0D0, $ Reference epochs are J2000. $ MSCOF(1,1,1) = 317.68D0, -0.108D0, 0.0D0, $ RA 1.79D0, 0.0D0, 0.0D0, 0.0D0, 0.0D0, MSCOF(1,2,1) = 52.90D0, -0.061D0, 0.0D0, $ DEC -1.080D0, 0.0D0, 0.0D0, 0.0D0, 0.0D0, MSCOF(1,3,1) = 35.06D0, 1128.8445850D0, 0.66443D-08, $ W -1.42D0, -0.78D0, 0.0D0, 0.0D0, 0.0D0, $ MSCF2(1,1,1) = 169.51D0, 0.435764D0, 0.0D0, $ M1 192.93D0, 1128.4096700D0, 6.644300993057D-09,$ M2 53.47D0, -0.0181510D0, 0.0D0, $ M3 $ MSCOF(1,1,2) = 316.65D0, -0.108D0, 0.0D0, $ RA 0.0D0, 0.0D0, 2.98D0, 0.0D0, 0.0D0, MSCOF(1,2,2) = 53.52D0, -0.061D0, 0.0D0, $ DEC 0.0D0, 0.0D0, -1.78D0, 0.0D0, 0.0D0, MSCOF(1,3,2) = 79.41D0, 285.161897D0, -0.389783D-09, $ W 0.0D0, 0.0D0, -2.58D0, 0.19D0, 0.0D0, $ MSCF2(1,1,2) = 169.51D0, 0.435764D0, 0.0D0, $ M1 192.93D0, 1128.40967D0, 6.644300993057D-09, $ M2 53.47D0, -0.018151D0, 0.0D0, $ M3 143.47D0, -0.018151D0, 0.0D0, $ M3 + 90 $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ Perturbing bodies: $ PERB( 1) = 11*1, $ Newtonian point masses for planets, Sun & Moon. PERB( 5) = 2, $ Turns on relativistic influence of Jupiter. PERB(10) = 2, $ Turns on relativistic influence of Sun. $ SAPERB(1) = 22*0, $ Satellite perturbations are OFF $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ Initial conditions: $ CENT = 'SUN' $ The ICs will be Sun centered. GEOFRM = .FALSE., $ Use the solar system barycenter reference frame. PLANET = 'YES', $ NO => Barycentric ; YES => Planet centered. $ $ When Earth is center, 'PLANET' is always 'YES', i.e., the PLANET flag $ doesn't affect the Earth state vector. In the Earth-Moon system it is $ always Earth centered regardless of the PLANET flag. $ $ Input coordinate system for ICs: $ IEQX = '2000', IMES = 'CARTES', IXAX = 'SPACE', IZAX = 'EARTH','MEAN','EQUATO', $ $ Output coordinate system: $ OCEN = 'SUN', OEQX = '2000', OMES = 'CARTES', OXAX = 'SPACE', OZAX = 'EARTH','MEAN','EQUATO', $ $ Print rotation matrices/angles when transforming ICs: $ GINBUG = .TRUE., $ $ Note: these initial conditions are given as an example only. $ $ ITIM = '12-FEB-1998 00:00:00.00000 ET', IC(1) = -1.21614904748071700D+08, $ X (km) IC(2) = 8.11510855294633360D+07, $ Y IC(3) = 2.43586850288667380D+07, $ Z IC(4) = -2.03601424696443870D+01, $ X DOT (km/s) IC(5) = -2.20724287414060070D+01, $ Y DOT IC(6) = -1.56541767565315690D+01, $ Z DOT TEND = '01-MAR-1998 00:00:00.0000 ET', $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ Integration control: $ PVBUG(1) = 0, $ No acceleration or A matrix printout is requested. PVBUG(2) = 0, $ Stop PV debug print at the trajectory end. PVBUG(3) = 1, $ Print S/C block parameters for antenna pointing $ events, solar panel tilt change events and for $ start & end of finite motor burns. PVBUG(4) = 0, $ Standard diagnostic print. MAKEPV = .TRUE., $ A P/PV file is written out (on 16). RUNOUT = -1, $ Terminate post convergence on time or radius, $ whichever comes first. $ $ Spheres of influence (km): $ (Inside this radius, PVDRIVE switches center of integration. For Mathilde, $ we want this to remain the Sun) $ RSPH( 1) = 1.1241000D5, RSPH( 2) = 6.1626900D5, RSPH( 3) = 9.2464900D5, RSPH( 4) = 5.7723200D5, RSPH( 5) = 4.8208797D7, RSPH( 6) = 5.4563002D7, RSPH( 7) = 5.1744166D7, RSPH( 8) = 8.6626753D7, RSPH( 9) = 3.2995530D6, $ Pluto (overwritten by Eros) RSPH( 9) = 0.0D0, $ EROS RSPH(10) = 0.0D0, $ Placeholder for Sun (not used) RSPH(11) = 6.6183000D4, $ $ The above spheres of influence were calculated using a formula attributed $ to Laplace. It's derivation can be found in Richard Battin's book: $ $ "An Introduction to the Mathematics and Methods of Astrodynamics" $ $ chapter 8, pages 395-398. The GMs used were from DE403. $ $ The traditional values: $ $ RSPH( 1) = 0.5D6, 2.5D6, 2.5D6, 2.0D6, 5.0D7, 5.0D7, $ 5.0D7, 8.0D7, 4.0D7, 0.0D0, 4.0D4, $ $ Integration independent variable: $ BASE0 = .TRUE., $ $ BASE0 = .TRUE. sets the independent variable to seconds past the trajectory $ epoch. This is the default and recommended value. Fred Krogh says that $ this will be better for the integrator. $ $ BASE0 = .FALSE. sets the independent variable to seconds past the reference $ epoch. If an old GIN file is converted to a new one using GINCONVERT, $ BASE0 is set to .FALSE., which is consistent with the old integrator. $ $ State equation tolerance; local absolute integration error (km/sec): $ EPS = 1.0D-11, $ $ Voyager NAV: EPS = 1.0D-9 $ Magellan: EPS = 1.0D-9 $ Galileo NAV: EPS = 1.0D-9 $ Ulysses NAV: EPS = 1.0D-9 $ TOPEX PVT: EPS = 7.0D-13 $ MGS NAV: EPS = 1.0D-10 $ NEAR NAV: EPS = 1.0D-9 (1.D-11 in lock-file) $ $ Tolerance for variational equations (recommended value): $ EPSV = 1.0D12, $ $ Scale factors for EPSV: $ EPSCAL(1) = 200*1.0D0, $ $ If EPSCAL = 0.0D0, the ODP uses EPSCAL = 1.0D0. $ If MASCONS are included in the partials list, set the EPSCAL factors for $ them at 1.0D0 for disk and point, and 1.0D-5 for curved mascons. $ For flat mascons, 1.0D5 is maximum! $ $ Maximum step size in seconds (5 days): $ HMAX = 432000.0D0, $ $ Minimum step size in seconds: $ HMIN = 0.005D0, $ $ Integration restarts: $ RESTRT(1) = .FALSE., $ No restart for shadow events. RESTRT(2) = .FALSE., $ No restart for attitude change events. RESTRT(3) = .FALSE., $ No restart for small force events. RESTRT(4) = .FALSE., $ No restart in the exponential atmosphere model. $ $ Termination control DISABLED for EROS: $ DRVL = 0.0D0, $ Begin testing for closest approach (km). DRBD = 'PLUTO', $ Terminate integration 'TMPC' secs after cl appr. TMPC = 9.999D99, $ Do NOT stop integrating after cl appr to DRBD. RVAL = 0.0D0, $ Radius (km) at which to end the integration. RBOD = 'PLUTO', $ Terminate integration at radius 'RVAL' from RBOD. $ $ Trajectory end time: $ TEND = '01-MAR-1999 00:00:00.0000 ET', $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ Spacecraft mass: $ MASS = 800.72257, $ Mass of S/C (kg) (1997 Jun 12 16:23 gin file) $ $ (tube://usr2/nnav/mirage/solns/tcm5_n0c/gin16152.nio $ $ Historical: $ MASS = 804.57, $ NEAR injection mass minus 1kg de-spin yo-yo's $ (Larry Mosher 2/1/96) $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ Solar radiation pressure (SRP) model: $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ Zero out and initialize the SRP & orientation model parameters: $ ACANO(1,1) = 120*-1.0D30, $ Inertial reference direction. ANGL = 0.0D0, $ Angle about the Sun-S/C axis. ANGLS(1,1) = 600*0.0D0, $ Euler rotation angles. COMP(1) = 10*' ', $ Component type declarations (i.e. sphere). CSIZE(1,1) = 20*0.0D0, $ Component dimensions. DELFM(1,1) = 30*0.0D0, $ Effective area change increments. DUPRC(1,1,1) = 6000*0.0D0, $ Component orientation definitions. DUPRS(1,1) = 600*0.0D0, $ Direction of the S/C Z* axis. GANG(1) = 36*0.0D0, $ Antenna model: theta angles for GCO & GCOP. GCO(1,1) = 180*0.0D0, $ Antenna model: integral tables. GCONO(1) = 2*0, $ Antenna model: Chebyshev polynomial degree. GCOP(1,1) = 90*0.0D0, $ Antenna model: integral tables. ITDFC(1,1) = 1000*' ', $ Reflectivity degradation change epochs. $ or use: TDFC(1,1) = 1000*-1.0D30 ITDFM(1) = 10*' ', $ Effective area change epochs. $ or use: TDFM(1) = 10*-1.0D30 KMNC(1,1,1) = 4000*1.0D0, $ Component reflectivity degradation factors. REFBS(1,1) = 400*' ', $ Reference direction to compute X* & Y*. SCOFC(1,1) = 40*0.0D0, $ Component reflectivity coefficients. STABLE(1) = 2*0, $ Transformations of the S/C X*, Y*, Z* axes. TABVAL(1,1) = 200*0.0D0, $ Rotation angles applied in STABLE. TCANO(1) = 40*' ', $ Start time for ACANO interval. $ or use: DTCANO(1) = 40*-1.0D30 TUPRS(1) = 200*' ', $ S/C orientation change epochs. $ or use: DTUPRS(1) = 200*-1.0D30 UPRC(1,1) = 2000*' ', $ S/C component orientation reference. UPRS(1) = 200*' ', $ Direction of the S/C Z* axis. $ $ Other parameters required for the SRP model: $ $ GCOFL, MASS, MASDEC, P0A, P1A, REFB, SC, SHDFLG, SRPFLG, TTYPE, USECMP $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ Activate the solar radiation pressure model: $ SRPFLG = .TRUE., SHDWFL = 0, $ 0 -> shadow model with integration restarts. $ 1 -> shadow model without restarts. SOLCOF = 1.0D0, $ General SRP scale factor. SOLSCL(1) = 10*1.0D0, $ Spacecraft component scale factors. $ ICMPTM( 1) = '01-FEB-1999 00:00:00 ET', ICMPTM( 2) = '01-MAR-2003 00:00:00 ET', $ $ No mass decrements are applied & all specified components are used: $ MASDEC( 1) = 0.0D0, USECMP(1,1) = 1,2,3,4,5, $ MASDEC( 2) = 0.0D0, USECMP(1,2) = 1,2,3,4,5, $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ Solar flux at 1 AU (kgkm3/m2s2): $ $ SC = (L*d*d/c) * (1000 m/km) * (1 km^3 / (1000 m)^3 ) where $ L = luminosity at 1 AU (1369 W/m^2) (1 W = 1 kg m^2/s^3 ) $ d = 149.6 Mkm/AU = 149597870.691 km/AU $ c = light speed = 299792.458 km/s $ $ SC = 1.020506244D8, $ MGS/TOPEX/Poseidon value: L = 1367.053608 W/m2 $ SC = 1.032200000D8, $ Magellan and PVO value. $ SC = 1.013048D8, $ NEAR NAV value SC = 1.01994367581D8, $ L=1366.3 W/m2 (6/97), S. Dewitte, DIARAD/VIRGO/SOHO $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ S/C component definitions: $ $ The following S/C components are all fixed in the ODP's S/C coordinate $ system: $ $ X* ---> NEAR spacecraft X-axis $ Y* ---> NEAR spacecraft Y-axis $ Z* ---> NEAR spacecraft Z-axis $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ NEAR S/C components & properties updated with JPL IOM 312.B-95-682 values. $ COMP(1)='ANTENNA', $ High gain CSIZE(1,1)=0.233D0, $ ... depth (m) CSIZE(2,1)=0.86027349D0, $ ... radius (m) SCOFC(1,1)=0.0375, 0.0D0, $ ... spec (fr & bk) 0.258333D0, 0.0D0, $ ... diff (fr & bk) $ COMP(2)='FLAT PLATEF', $ Front of solar panels CSIZE(1,2)=8.92D0, $ ... area (m^2) SCOFC(1,2)=0.05625D0, 0.0408333D0, $ ... spec & diff $ COMP(3)='FLAT PLATEB', $ Back of solar panels CSIZE(1,3)=8.92D0, $ ... area (m^2) SCOFC(1,3)=0.0375D0, 0.258333D0, $ ... spec & diff $ COMP(4)='FLAT PLATEF', $ Backside of s/c bus CSIZE(1,4)=2.33D0, $ ... area (m^2) SCOFC(1,4)=0.0375D0, 0.258333D0, $ ... spec & diff $ COMP(5)='CYLINDER', $ S/C body CSIZE(1,5)=1.452D0, $ ... length (m) CSIZE(2,5)=0.778D0, $ ... radius (m) SCOFC(1,5)=0.0295D0, 0.2316667D0, $ ... spec & diff $ $ Chebyshev transformation parameters: $ $ Note that the numerical integral tables -- GCO & GCOP & GANG -- were $ calculated for the NEAR high gain antenna. They were calculated from $ the ODP Utility program "ANTTAB" written by Rick Sunseri. $ $ radius= 0.86027349 m, depth= 0.233 m $ (omega= arctan(2*depth/radius)) $ $ P0A If the angle between the antenna pointing direction and $ the spacecraft-Sun direction is less than P0A, then the $ antenna front is under full illumination (deg) $ $ P1A If the angle between the antenna pointing direction and $ the spacecraft-Sun direction is between P1A and 180 $ degrees, then the antenna back is under full illumination $ (deg) $ P0A = 61.556118, $ Angle limit between full/partial front illumination. P1A = 118.44389 , $ Angle limit between full/partial back illumination. $ GCOFL = 1, $ GCO, GCOP tables are Chebyshev polynomial coefficients. GCONO = 12, 7, $ Polynomial degree for back (GCO) & front (GCOP). $ $ Backside: $ The first two rows below equal (P1A+P0A)/2, (P1A-P0A)/2. $ $ I21 I22 I31 I32 I33 GCO(1,1) = 0.90000000E+02, 0.90000000E+02, 0.90000000E+02, 0.90000000E+02, 0.90000000E+0 0.28443884E+02, 0.28443884E+02, 0.28443884E+02, 0.28443884E+02, 0.28443884E+0 -0.26155570E+00,-0.29125383E+00, 0.18434623E+00, 0.16779085E+00, 0.17778791E+0 -0.38103083E+00,-0.38020518E+00, 0.29237321E+00, 0.25141585E+00, 0.24065098E+0 -0.13048425E+00,-0.76069325E-01, 0.14044109E+00, 0.98506585E-01, 0.61787140E-0 -0.38353868E-02, 0.16647017E-01, 0.34320455E-01, 0.13107652E-01,-0.25099039E-0 0.77821305E-02, 0.31406560E-02, 0.79130131E-03,-0.20920534E-02,-0.12092999E-0 0.41518494E-03,-0.20942891E-03,-0.11815116E-02,-0.27759821E-03, 0.77593158E-0 -0.15108149E-03, 0.34480565E-03,-0.46769565E-04, 0.17433082E-04,-0.18146055E-0 0.38328904E-04, 0.12406651E-05, 0.16228323E-04,-0.20481782E-04,-0.12965002E-0 0.15267527E-05, 0.55911853E-04,-0.31315326E-05,-0.88088917E-07,-0.27820495E-0 0.47232952E-05,-0.10664182E-07,-0.12803476E-06,-0.23968007E-05,-0.26717537E-0 -0.10781563E-07, 0.12031040E-04,-0.29109935E-06,-0.22984232E-08,-0.59725503E-0 0.70813815E-06,-0.87677127E-09, 0.16407470E-08,-0.35437390E-06,-0.23237412E-0 -0.25287881E-08, 0.30184353E-05,-0.29843989E-07, 0.19690543E-08,-0.15008067E-0 $ $ Frontside: $ $ I21P I22P I31P I32P I33P GCOP(1,1) = 0.75778061E+02, 0.75778061E+02, 0.75778061E+02, 0.75778061E+02, 0.75778061E+0 0.14221941E+02, 0.14221941E+02, 0.14221941E+02, 0.14221941E+02, 0.14221941E+0 0.37802729E+00, 0.38885963E+00, 0.27412271E+00, 0.24418947E+00, 0.24190886E+0 -0.38505456E+00,-0.36731386E+00,-0.31958723E+00,-0.26198807E+00,-0.23876369E+0 0.63697062E-02,-0.25083797E-01, 0.51728338E-01, 0.19997321E-01,-0.37648750E-0 0.56982721E-03, 0.35894278E-02,-0.60934629E-02,-0.23039875E-02, 0.61530527E-0 0.45956298E-04,-0.99189065E-05,-0.32436440E-03, 0.51315754E-04, 0.48326851E-0 0.73560725E-04,-0.43227799E-04, 0.15717626E-03, 0.68185684E-04,-0.47059081E-0 -0.35789351E-04, 0.54123097E-06, 0.14567665E-05,-0.15404394E-04,-0.12586420E-0 0.39581369E-05, 0.12013402E-05,-0.48121838E-05, 0.11929963E-05,-0.14064504E-0 $ $ Values for the attack angle, theta, corresponding to GCO & GCOP entries. $ Only needed when GCOFL=0 (for linear interpolation) $ $ GANG = $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ S/C attitude definitions: $ ANGL = 0.0D0 $ Angle about Sun-S/C axis. REFB = 'STAR', $ Ref direction is wrt this body ACANO(1,1)= -1.D0, 0.0, 0.0, $ Inertial ref. dir. in xyz EME200 TCANO(1) = '01-JAN-1996 0:00:00.0 ET', $ Beginning of ACANO ref system $ Spacecraft orientation changes occur at specific epochs. TTYPE(1) = 'TIME', TTYPE(2) = ' ' $ $ TUPRS: defines the epoch of the S/C orientation change. $ UPRS: defines the direction in which Z* points. $ REFBS: defines the direction of the reference vector, R. $ R is used to compute X* and Y*: $ Y* = R x Z* $ X* = Y* x Z* = (R x Z*) x Z* $ ANGLS: defines a set of Euler rotations about Z*, X*', Z*'' $ TUPRS(1) = '01-JAN-1996 0:00:00.0 ET', UPRS(1) = 'SUN', $ S/C nom. -> Sun during cruise REFBS(1,1) = 'STAR', ANGLS(1,1) = 0.0D0, 0.0D0, 0.0D0, $ No rotations $ DUPRS(1,1) = 0.0, 0.0, 1.0, $ S/C z-dir (unused; UPRS is body) UPRC(1,1) = 'SC ANG', DUPRC(1,1,1)=0.0D0, 0.0D0, 1.0D0, $ Antenna UPRC(1,2) = 'SC ANG', DUPRC(1,1,2)=0.0D0, 0.0D0, 1.0D0, $ F. solar panel UPRC(1,3) = 'SC ANG', DUPRC(1,1,3)=0.0D0, 0.0D0, 1.0D0, $ B. solar panel UPRC(1,4) = 'SC ANG', DUPRC(1,1,4)=0.0D0, 0.0D0,-1.0D0, $ B. s/c bus UPRC(1,5) = 'SC ANG', DUPRC(1,1,5)=0.0D0, 0.0D0, 1.0D0, $ s/c body $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ Reflectivity coefficient degradation model. $ $ Linearly interpolate the degradation factors: $ INDEG = 1, $ $ Degradation intervals and factors for each component: $ ITDFC(1, 1) = '01-JAN-1996 00:00:00 ET', ITDFC(2, 1) = '01-JUN-2002 00:00:00 ET', KMNC(1,1,1) = 1.0D0, 1.0D0, KMNC(1,2,1) = 1.0D0, 1.0D0, $ ITDFC(1, 2) = '01-JAN-1996 00:00:00 ET', ITDFC(2, 2) = '01-JUN-2002 00:00:00 ET', KMNC(1,1,2) = 1.0D0, 1.0D0, KMNC(1,2,2) = 1.0D0, 1.0D0, $ ITDFC(1, 3) = '01-JAN-1996 00:00:00 ET', ITDFC(2, 3) = '01-JUN-2002 00:00:00 ET', KMNC(1,1,3) = 1.0D0, 1.0D0, KMNC(1,2,3) = 1.0D0, 1.0D0, $ ITDFC(1, 4) = '01-JAN-1996 00:00:00 ET', ITDFC(2, 4) = '01-JUN-2002 00:00:00 ET', KMNC(1,1,4) = 1.0D0, 1.0D0, KMNC(1,2,4) = 1.0D0, 1.0D0, $ ITDFC(1, 5) = '01-JAN-1996 00:00:00 ET', ITDFC(2, 5) = '01-JUN-2002 00:00:00 ET', KMNC(1,1,5) = 1.0D0, 1.0D0, KMNC(1,2,5) = 1.0D0, 1.0D0, $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ Planetary radiation model: $ $ The planetary radiation model accounts for the forces on s/c due to a $ nearby planet's albedo and infrared emissivity. $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ Zero out and initialize planetary radiation model parameters: $ RPBOD = ' ', $ Radiating planetary body: NONE $ If no planet is set, the model is off. $ ALBCOF = 1.0D0, $ General albedo scale factor. ALBSCL(1) = 10*1.0D0, $ S/C component area scale factors (albedo). ALCOFC(1,1) = 40*0.0D0, $ CAL(0,0) = 100*0.0D0, $ C(n,m) albedo series coefficient. CEP(0,0) = 100*0.0D0, $ C(n,m) infrared emission series coefficient. EPSIMP = 1.0D-4, $ Relative epsilon of convergence. IFRCOF = 1.0D0, $ General infrared scale factor. IFRSCL(1) = 10*1.0D0, $ S/C component area scale factors (IR). IRCOFC(1,1) = 40*0.0D0, $ LMXAL = 0, $ Degree of the albedo series. LMXEP = 0, $ Degree of the infared emission series. MXSIMP = 5, $ Maximum iterations in the quadrature. NPRING = 0, $ Number of rings in the albedo/IR model. SAL(0,0) = 100*0.0D0, $ S(n,m) albedo series coefficient. SEP(0,0) = 100*0.0D0, $ S(n,m) infrared emission series coefficient. $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ The following example inputs for the Mars albedo model were taken from: $ $ 1) Creel, D. D., "General Inputs for DPTRAJ/ODP Planetary Radiation Model", $ IOM 314.6-1321, August 6, 1991. $ $ RPBOD = 'MARS', $ LMXAL = 7, $ Degree of the albedo series. $ $ CAL(0,0) = 0.294838D0, $ Mars perihelion albedo coefficients. $ CAL(1,0) = 0.046034D0, $ CAL(2,0) = 0.049287D0, $ CAL(3,0) = 0.009035D0, $ CAL(4,0) = 0.031791D0, $ CAL(5,0) =-0.004347D0, $ CAL(6,0) =-0.012938D0, $ CAL(7,0) =-0.012793D0, $ $ CAL(0,0) = 0.231281D0, $ Mars aphelion albedo coefficients. $ CAL(1,0) =-0.040753D0, $ CAL(2,0) = 0.031974D0, $ CAL(3,0) =-0.032247D0, $ CAL(4,0) = 0.021980D0, $ CAL(5,0) =-0.025561D0, $ CAL(6,0) =-0.008054D0, $ CAL(7,0) = 0.005228D0, $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ Thermal imbalance model: $ THMCMP = .FALSE., $ The thermal imbalance acceleration is off. $ EMISS( 1) = 10*0.0D0, $ S/C component emissivity coefficients. $ FACE( 1) = 10*' ', $ Parameter only used by TOPEX/Poseidon. THAREA( 1) = 10*0.0D0, $ Thermal imbalance S/C component areas. THMCOF(1,1) = 50*0.0D0, $ Thermal coefficients for each component. $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ Maneuver and Nongravitational acceleration models: $ $ Zero out and initialize the maneuver & nongrav model parameters: $ $ STABLE(1) = 0, 0, $ TABVAL(1,1) = 200*0.0D0, $ List of times when 'STABLE' events occur. $ SAAT(1,1) = 1998*' ', SAAP(1,1) = 8991*0.0D0, ISTREX(1) = 100*' ', ISTPEX(1) = 100*' ', AR(1) = 100*0.0D0, AX(1) = 100*0.0D0, AY(1) = 100*0.0D0, BB(1) = 100*0.0D0, DELVB1(1) = 99*0.0D0, MB1T(1) = 99*' ', MB1V(1,1) = 297*0.0D0, MB1P(1) = 99*0.0D0, MA1A(1,1) = 990*0.0D0, MA1D(1) = 99*0.0D0, MA1K(1) = 99*0.0D0, MA1F(1,1) = 495*0.0D0, MA1M(1,1) = 396*0.0D0, MA1T(1) = 99*' ', BURN(1) = 99*0, LPLANE(1) = 99*' ', TPEQ(1) = 99*0.0D0, C3(1) = 99*0.0D0, DELV(1) = 99*0.0D0, ISMFTM(1) = 1000*' ', SMFDR(1,1) = 3000*0.0D0, SMFDV(1,1) = 3000*0.0D0, $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ Quadratic acceleration model: $ $ Start and stop epochs: $ $ SAAT(1,1) = '17-FEB-1996 00:00:00.0000 ET', $ SAAT(2,1) = '01-FEB-1999 00:00:00.0000 ET', $ $ Accelerations (I,J): $ SAAP(1,1) = $ Index I = 1 => acceleration in R (ATAR nominal) $ SAAP(4,1) = $ Index I = 4 => acceleration in X (ATAX nominal) $ SAAP(7,1) = $ Index I = 7 => acceleration in Y (ATAY nominal) $ Index J provides a time table. $ $ Exponential acceleration model: $ $ Start and stop epochs: $ $ ISTREX(1) = '17-FEB-1996 00:00:00.0000 ET', $ ISTPEX(1) = '01-FEB-1999 00:00:00.0000 ET', $ $ Exponent coefficients: $ AR(1) = $ R (GLAR nominal) $ AX(1) = $ X (GLAX nominal) $ AY(1) = $ Y (GLAY nominal) $ BB(1) = $ Time scale factor (GLBT nominal) $ $ Impulsive burn maneuvers: $ BRNCRD(1) = 99*1, $ 1 => delta-V wrt S/C X*,Y*,Z* $ $ MB1T(1) = '02-MAR-1996 00:00:00.0000 UTC', $ $ Delta velocity components: $ DELVB1(1) = $ Burn magnitude (km/s). $ MB1D(1) = $ Burn duration (s). $ MB1V(1,1) = $ Delta-V increments (IDLX,Y,Z nominals $ MB1P(1) = $ Mass decrement (kg). $ $ Finite burn maneuvers: $ ITPEQ(1) = 99*'2000', $ Epoch of burn coordinate system. LPLANE(1) = 99*' ', $ Thrust vector reference system. MA1K(1) = 99*1.0D-03, $ Conversion factors for finite burns. $ COORS(1,1) = ' ','SPACE','EARTH','MEAN','EQUATO', COORS(1,2) = ' ','SPACE','EARTH','MEAN','EQUATO', COORS(1,3) = ' ','SPACE','EARTH','MEAN','EQUATO', COORS(1,4) = ' ','SPACE','EARTH','MEAN','EQUATO', COORS(1,5) = ' ','SPACE','EARTH','MEAN','EQUATO', $ $ The following example inputs were generated from SEPV and used biased $ Mars Mean Equator of Date B-plane targets: $ $ BDOTT = -44000.0 km BDOTR = -52000.0 km +3 hrs in flight time $ $ The thrust and mass flow rate values came from the following: $ $ 1) Dominick, S., "Updated Thrust Levels for Main Engine and Thrusters", $ Lockheed Martin IOM, March 25, 1996. $ $ MA1T(1) = '21-NOV-1996 22:00:00.0000 UTC', $ $ BURN(1) = 1, $ Termination flag (DURAT, DV, C3). $ MA1F(1,1) = 656.0D0, $ Thrust coefficients (kilo-Newtons). $ 4*0.0D0, $ MA1M(1,1) = 0.2107D0, $ Mass flow rate (kg/s). $ 3*0.0D0, $ MA1A(1,1) = 249.6836008603889D0, $ RA coefficients (degree). $ 4*0.0D0, $ MA1A(6,1) = -48.06990205194584D0, $ DEC coefficients (degree). $ 4*0.0D0, $ MA1D(1) = 0.1126066527720419D0, $ Burn duration cutoff (s). $ $ DELV(1) = 0.0D0, $ DV magnitude cutoff. $ ACELC(1,1) = 0.0D0, 0.0D0, 0.0D0, $ Thruster misalign coeffs, DV stop. $ BRD(1) = $ Reference planet, C3 cutoff. $ C3(1) = $ Twice energy per unit mass limit. $ $ Gyro control: $ $ ITVDIL(1) = $ Inertial lock epoch. $ ITVTRN(1) = $ Turn epoch. $ LDYN(1) = $ Thrust vector reference plane flag. $ TVDGDR(1,1) = $ Pitch, Yaw, Roll rates. $ TVDORA(1,1) = $ Turn angles. $ TVDORT(1,1) = $ Turn sequences. $ TVEPS(1,1) = $ Pitch, Yaw, Roll offsets. $ $ Gyro drift: $ IROLLX(1) = 99*0, $ Impulsive burn not under gyros. ROLLAX(1) = 99*0, $ Finite burn not under gyros. $ $ Angular momentum desaturation events: $ $ 1) "NEAR Thruster Location and Utilization Matrix", provided by $ Cliff Helfrich, Aug 14, 1997. $ $ Thruster orientation is in the ODP's s/c X*,Y*,Z* system. $ $ NOTE: No 2b thruster. 3b and 4b fired in pairs at 50%. $ THRSTR(1, 1) = 60*0.0D0, $ THRSTR(1, 1) = 1.000D0, 0.000D0, 0.000D0, $ 1a ( 21 N) THRSTR(1, 2) = 1.000D0, 0.000D0, 0.000D0, $ 2a ( 21 N) THRSTR(1, 3) = 1.000D0, 0.000D0, 0.000D0, $ 3a ( 21 N) THRSTR(1, 4) = 1.000D0, 0.000D0, 0.000D0, $ 4a ( 21 N) THRSTR(1, 5) = 0.000D0, 0.000D0, 1.000D0, $ 5a ( 3.5 N) THRSTR(1, 6) = 0.000D0, 0.000D0, 1.000D0, $ 6a ( 3.5 N) THRSTR(1, 7) = -1.000D0, 0.000D0, 0.000D0, $ 1b ( 3.5 N) THRSTR(1, 8) = -1.000D0, 0.000D0, 0.000D0, $ 3b ( 3.5 N) THRSTR(1, 9) = -1.000D0, 0.000D0, 0.000D0, $ 4b ( 3.5 N) THRSTR(1,10) = 0.000D0, 0.000D0, -1.000D0, $ 5b ( 3.5 N) THRSTR(1,11) = 0.000D0, 0.000D0, -1.000D0, $ 6b ( 3.5 N) THRSTR(1,12) = 1.000D0, 0.000D0, 0.000D0, $ LVA (467 N) $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ TWIST $ $ Standard print control: $ BARYFL = 0, $ Get the barycenter shift vector from: $ 0 => internal computation $ 1 => satellite ephemeris DATAFL = 0, $ Read constants for TWIST from: $ 0 => the P/PV file $ 1 => the GIN file PCBPRT = 2, $ Reference center for TWIST print: $ 0 => use the planet center $ 1 => use the barycenter $ 2 => use both PBUG(1) = 10*0, $ Turn off TWIST debugging print. $ PBUG(3) = 1, for aerobraking data HPEP = 3600.0D0, $ Interval to check trigger (seconds) TPWANT = 'UTC', $ Time listed in ET & UTC. $ $ Print termination control: $ FAPSIS = -1, $ Terminate print at periapsis. CLOS = 'PLUTO', CRBD = 'PLUTO', CRFL = 'INTERN', $ Closest approach testing within 'CRAD'. CRAD = 1.0D8, $ Radius for closest approach test (km). EBOD = 'PLUTO', EDIS = 0.0D0, $ Distance from EBOD to end print (km). ELIS(1) = 5, 6, 4*0, $ Print at time supplied in ETIM. $ ETIM = '31-MAR-2000 00:00:00 ET', $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ The print lists are given below. The arrays PHSTRL(J,I), PHENDL, MOA1, $ etc. are assigned to integers which reference the lists. The index 'I' $ denotes 'PHASE', that part of the trajectory when the body in PCBBOD $ corresponds to the primary body (integration center) of the trajectory. $ $ Phase (integration center) order for the launch & cruise: $ PCBBOD(1) = 'EARTH', 'SUN', 'PLUTO', 2*' ', $ $ Geometric & phase events: $ EQUTXL(1,1) = 30*0, $ Print at equator crossings. NPOLXL(1,1) = 30*0, $ Print at north pole minimum range. PCBCAL(1,1) = 30*0, $ Print at body closest approach. PCBCAL(1,1) = 1, PCBCAL(1,3) = 3, PCBDST(1) = 5*0.0D0, $ Distance for print from PCBBOD(I). PCBDSL(1,1) = 30*0, $ Print lists for PCBDST. PCBGOL(1,1) = 30*0, $ Print at geocentric occultations. PCBGOL(1,1) = 0, PCBGOL(1,2) = 0, PCBGOL(1,3) = 3, ATMRAD( 4) = 25.9D0, $ Mathilde radius + 0 km. PCBSOC(1,1,1) = 150*0, $ Print at star occultations. OCSTAR(1) = 5*' ', $ Star names. STARDC(1) = 5*0.0D0, $ DEC of stars in OCSTAR (degrees). STARRA(1) = 5*0.0D0, $ RA of stars in OCSTAR (degrees). PCBTRG = 0, $ -1 => print at each periapsis. $ 0 => print at apoapsis & periapsis. $ 1 => print at each apoapsis. PHENDL(1,1) = 30*0, $ Print at the phase end. PHSTRL(1,1) = 30*0, $ Print at the phase start. PHSTRL(1,1) = 1, PHSTRL(1,2) = 2, PHSTRL(1,3) = 3, SPOLXL(1,1) = 30*0, $ Print at south pole minimum range. TERMXL(1,1) = 30*0, $ Print at terminator crossings. TANOM(1) = 0.0D0, $ True anomaly value at which to print. TPPERI = 0.0D0, $ Time after periapsis at which to print. PPERI(1) = 6*0, $ Print lists for TANOM and TPPERI. $ $ Physical model & S/C events: $ ATMPR(1,1) = 30*0, $ Print for atmospheric lift & drag. ATPR(1) = 6*0, $ Print for quadratic gas leaks. GLPRT(1) = 6*0, $ Print for exponential gas leaks. MOA1(1) = 6*0, $ Print at finite maneuvers. MOA1(1) = 1, MOB1(1) = 6*0, $ Print at instantaneous maneuvers. MSCOPR(1,1) = 30*0, $ Print for MASCON sphere. OBPRTL(1,1) = 30*0, $ Print for oblateness sphere. OBPRTL(1,1) = 1, OBPRTL(1,2) = 0, OBPRTL(1,3) = 3, PCBSHL(1,1) = 30*0, $ Print for SRP shadowing events. $ $ Absolute epoch print: $ ABSF(1,1) = 60*0, $ Print at epochs in 'ABST'. ABST(1) = 10*' ', $ $ Radius-Delta-Radius (RDR) print: $ PCBRDR(1,1,1) = 75*0.0D0, PCBRDR(1,1,1) = 0.0D0, $ Start radius for RDR print (km). PCBRDR(2,1,1) = 0.0D0, $ Delta radius (increase) (km). PCBRDR(3,1,1) = 0.0D0, $ Stop radius for RDR print (km). PCBRDL(1,1) = 30*0, $ Print lists for RDR events. $ $ Time-Delta-Time (TDT) print: $ PCBTHW(1) = 'ET', $ HAVE time-type for TDT print. IPCBTD(1,1,1) = 150*' ', $ TDT print in phase 'I'. IPCBTD(1,1,1) = ' ', $ Start times for TDT print. IPCBTD(2,1,1) = ' ', $ Delta times. IPCBTD(3,1,1) = ' ', $ Stop times for TDT print. PCBTDL(1,1) = 30*0, $ No default print lists. PCBTDF(1) = 2, $ Phase independent print. $ $ Satellite event print: $ CLOSAT(1) = 10*' ', CLOLSX(1,1) = 7, CLOLSX(1,2) = 8, RADSAT(1) = 5.0D4, 5.0D4, $ Distance to monitor closest approach (km). $ ECLSAT(1) = 10*' ', $ Satellites for eclipse events. OCSATG(1) = 10*' ', $ Satellites for Earth occultations. OCSATH(1) = 10*' ', $ Satellites for Sun occultations. OCSATS(1,1) = 50*' ', $ Satellites for star occultations. TRNSAT(1) = 10*' ', $ Satellites for occultations & transits. CLOLST(1) = 6*0, $ Print lists of OCSATG, OCSATH, OCSTAR. $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ Initialize and define the print lists: $ BODCOR(1,1, 1) = 360*' ', BODEQX( 1, 1) = 45*'2000', $ Specifies the coordinate system epoch. BODINF( 1, 1) = 45*1, $ The "of date" systems will be inertial. CONCEN( 1) = 15*' ', CONCOR(1,1, 1) = 240*' ', CONEQX( 1, 1) = 60*'2000', $ Nominally J2000 (see below) ANGLEB( 1, 1) = 60*' ', $ $ Print list #1 $ BODCOR(1,1, 1) = 'EARTH','EARTH','MEAN','EQUATO','PLUTO' CONCEN( 1) = 'EARTH', CONCOR(1,1, 1) = 'SPACE','EARTH','MEAN','EQUATO', CONCOR(1,2, 1) = 'SPACE','EARTH','MEAN','ORBITA', ANGLEB( 1, 1) = 'PRINT','PLUTO', $ $ Print list #2 $ BODCOR(1,1,2)= 'SUN','EARTH','MEAN','EQUATO','PLUTO', CONCEN(2) = 'SUN', CONCOR(1,1,2)= 'SPACE','EARTH','MEAN','EQUATO', CONCOR(1,2,2)= 'SPACE','EARTH','MEAN','ORBITA', ANGLEB(1,2) = 'PRINT','PLUTO', $ $ Print list #3 $ BODCOR(1,1,3)= 'PLUTO','EARTH','MEAN','EQUATO', CONCEN(3) = 'PLUTO', CONCOR(1,1,3)= 'SPACE','EARTH','MEAN','EQUATO', CONCOR(1,2,3)= 'SPACE','EARTH','MEAN','ORBITA', CONCOR(1,3,3)= 'SPACE','PLUTO','TRUE','EQUATO', CONEQX(1,3) = '2000','2000','DATE', ANGLEB(1,3) = 'PRINT', $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ SAVE file generation: $ FERP = 31, $ Fixed variable output frame: 31 => EME2000 SPABT(1) = 10*' ', $ Absolute epoch to write out. SPBOD(1) = 'EARTH', $ Extra body name for fixed output SPDBUG = 0, $ Do not print SAVE file data records. SPTAPF = 0, $ >0 => Turn on writing of save tape SPTDT(1,1) = 30*' ', $ TDT times to write out. SPHWTM = 'ET', $ Time type of epochs in SPABT HWSPT = 'ET', $ Time type of epochs in SPTDT $ $ Print lists to examine for PRGVAR names: $ SAPLIS(1) = 1,2,3, $ PRGVAR(1,1) = 400*' ', $ $ PRGVAR(1,1) = 'SMA','ECC','TA','LAN1','APF1','INC1','PER', $ 'ALTP1','DR1','RIP1','VIP1','LATP1','LONP1', $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ OPTG file generation: $ $ OPTG file title & labels: $ OTITLE = 'NEAR Radio Science GIN Lock File: OPTG File', NAMEXT = 'NEAR Radio Science Team', OPTMIS = '93', $ $ Note: If one wants an event printed on the OPTG file, one must also have $ it printed out on TWIST. $ $ First specify TWIST print begin & end times. These define the absolute $ limits of the OPTG file -- it cannot start before or end after these times. $ Now define default OPTG begin & end times. If they are outside of TWIST $ print limits (or blank), then they will be set to the TWIST limits. $ OPTBEG = '01-Jan-1996 00:00:00 ET', OPTEND = '31-Mar-2002 00:00:00 ET', $ OPTBOD(1) = 5*' ', $ OPTG file central body or 'CRUISE'. $ OPTBOD = ' ' turns off OPTG file creation. OBDEVT = ' ', $ Event defining orbit boundary. $ OBDEVT = ' ' defaults to periapsis. OPTGPH = 'CRUISE', $ Mission phase label. CONANG = 0, $ SEP angle denoting conjunction. INORBN = 0, $ Initial orbit number. $ $ W A R N I N G ! ==> OCCRAD & ATMRAD are EQUIVALENT input parameters. $ In the source code, they are "equivalenced". $ OCCRAD( 4) = 0.0D0, $ Radius for atmosphere occultation. $ $ Specify which events to print out on the OPTG file: $ OPTEVT( 1,1) = .TRUE., $ CONST: Write a record with planet constants. OPTEVT( 2,1) = .TRUE., $ PERIAP: Periapsis. OPTEVT( 3,1) = .TRUE., $ APOAP: Apoapsis. OPTEVT( 4,1) = .TRUE., $ EOCCAB: Begin geocen. atmos occult by OPTBOD. OPTEVT( 5,1) = .TRUE., $ EOCCAE: End geocen. atmos occult by OPTBOD. OPTEVT( 6,1) = .FALSE., $ SOCCAB: Begin heliocen. atmos occult by OPTBOD. OPTEVT( 7,1) = .FALSE., $ SOCCAE: End heliocen. atmos occult by OPTBOD. OPTEVT( 8,1) = .TRUE., $ EOCCSB: Begin geocen. surface occult by OPTBOD. OPTEVT( 9,1) = .TRUE., $ EOCCSE: End geocen. surface occult by OPTBOD. OPTEVT(10,1) = .TRUE., $ SOCCSB: Begin heliocen. surface occult by OPTBOD. OPTEVT(11,1) = .TRUE., $ SOCCSE: End heliocen. surface occult by OPTBOD. OPTEVT(12,1) = .TRUE., $ AEQUAX: Ascending OPTBOD equator crossing. OPTEVT(13,1) = .TRUE., $ DEQUAX: Descending OPTBOD equator crossing. OPTEVT(14,1) = .TRUE., $ DLTERM: Dark to light terminator crossing. OPTEVT(15,1) = .TRUE., $ LDTERM: Light to dark terminator crossing. OPTEVT(16,1) = .TRUE., $ NPOLEX: North pole minimum slant range. OPTEVT(17,1) = .TRUE., $ SPOLEX: South pole minimum slant range. $ CONEVT( 1) = .TRUE., $ SCONB: Begin superior conjunction. CONEVT( 2) = .TRUE., $ SCONE: End superior conjunction. CONEVT( 3) = .TRUE., $ ICONB: Begin inferior conjunction. CONEVT( 4) = .TRUE., $ ICONE: End inferior conjunction. CONEVT( 5) = .TRUE., $ SCONJ: Cross integral angle boundary (SUP CONJ). CONEVT( 6) = .TRUE., $ ICONJ: Cross integral angle boundary (INF CONJ). CONEVT( 7) = .TRUE., $ ICONM: Minimum inferior conjunction SEP angle. CONEVT( 8) = .TRUE., $ SCONM: Minimum superior conjunction SEP angle. $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ CRSPOST $ $ Celestial reference set (CRS). S/C centered state placed on output for $ each CRS body: $ CRSBOD(1) = 'PLUTO', 'EARTH', 'SUN', $ CRSM = 0, $ No print. CRSPRT = 1, $ Print CRS Constants, 1st & last data records $ IPSTM = ' ', $ Printout start epoch. $ ETIM = ' ', $ Printout end epoch. SPTDT(1,1) = 30*' ', $ Times to write 'SAVE TAPE' $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ LITIME $ $ Geocentric or topocentric one-way light times (OWLT) calculated for $ specified time increments during some span: $ ITITLE = 'NEAR Radio Scienc GIN Lock File: LITIME File', NAMEXT = 'NEAR Radio Science Team', IHEAD = ' ', ICOMNT = ' ', $ IMISSN = 'NEAR', ISCID = 'NEAR', IOPT = 3, $ Get printout and file. ISTRT = ' ', $ Start time, SCET in GMT. IEND = ' ', $ End time, SCET in GMT. $ STANO(1) = 15, 45, 65, $ Stations for topocentric OWLT. $ 3 ==> geocentric OWLT. TINT = 0.0D0, $ OWLT computation interval (seconds). TOL = 1.0D-6, $ OWLT convergence tolerance (seconds). $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ STATRJ $ $ Generate geocentric and tropocentric information for the DSN. $ STALAB = 2*' ', STALAB(1) = ' ', HVFILE = 'NO', $ Station polynomial file is generated. TRJPRT = 'NO', $ No GEO or TOPO print during burns. STANUM(1) = 12, 14, 15, 42, 43, 45, 46, 61, 63, 65, 10*0, STABEG = ' ', $ Start epoch (UTC) of the file. STASTP = ' ', $ End epoch (UTC) of the file. OCCBOD = 'PLUTO', $ Extra body for geometric calculations. VPACC = 1.0D0, $ Tolerance (min) in rise/set iterations. LTACC = 0.01D0, $ Tolerance (sec) in LT iteration. $ $ Numerical control parameters: $ $ Note: These quantities specify polynomial coefficients for the $ RA & DEC or the AZ & EL for the station-to-S/C vector. $ NSECIT = 5, $ Max # of secant iterations for rise/set. NDEG = 10, $ Degree of polynomials on file. STAPTS = 13, $ Number of points in polynomials. LSPH(1) = 50.0D3, 200.0D3, $ Radii of near & far Earth phases (km). ESPH(1) = 50.0D3, 200.0D3, $ Radii of near & far "PLUTO" phases (km). PSPANS(1) = 0.025D0, $ Geocentric near Earth span (days). PSPANS(2) = 0.1D0, $ Geocentric far Earth span (days). PSPANS(3) = 1.0D0, $ Geocentric cruise span (days). PSPANS(4) = 0.1D0, $ Geocentric far "PLUTO" span (days). PSPANS(5) = 0.025D0, $ Geocentric near "PLUTO" span (days). NPERP(1) = 7, $ TOPO spans/pass, near Earth. NPERP(2) = 3, $ TOPO spans/pass, far Earth. NPERP(3) = 1, $ TOPO spans/pass, cruise. NPERP(4) = 3, $ TOPO spans/pass, far "PLUTO". NPERP(5) = 7, $ TOPO spans/pass, near "PLUTO". NPERP(6) = 3, $ TOPO spans/pass, max ELV > 70 degrees. VPTBLE(1,1) = 1.0D4, 3.0D0, $ Monitor rise/set every 3 min. < 10K km. VPTBLE(1,2) = 2.5D4, 20.0D0, $ Monitor rise/set every 20 min. < 25K km. VPTBLE(1,3) = 5.0D4, 40.0D0, $ Monitor rise/set every 40 min. < 50K km. VPTBLE(1,4) = 1.0D5, 50.0D0, $ Monitor rise/set every 50 min. < 100K km. VPTBLE(1,5) = 1.0D20, 60.0D0, $ Monitor rise/set every 60 min. > 100K km. $ $ Print control parameters: $ STADBG = 'NO', $ No debug print. PRTBEG = ' ', $ Begin STATRJ print (time in UTC). PRTSTP = ' ', $ End STATRJ print (time in UTC). PRTHED = 'YES', $ Print the header records. RISPRT = 'NO', $ Don't print station rise/set events. SUMTAB = 'YES', $ Print rise/set events. $ 'ONLY' => Summary table only. GPRT(1) = 20*1, $ Print all 20 geocentric quantities. TPRT(1) = 0, 24*1, $ Print all 25 topocentric quantities. STADEL(1,1) =30*' ', $ 10 TDT print sequences. STATIM(1) = 10*' ', $ Absolute epoch (UTC) prints. STAPRT(1) = 15, 45, 65, $ Stations to print. $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ Station locations: $ $ 1) Folkner, W. M., "Current DSN Station Locations," JPL IOM 335.1-95-027, $ October 16, 1995. $ $ Modified: 7 Nov 1996; DSS 66 updated, DSS 34, 54 not yet surveyed $ Modified: 25 Nov 1996; DSS 34 survey included $ Modified: 13 May 1997; DSS 54 survey included $ Modified: 09 Jun 1997; error in DSS 54 corrected $ $ Corrections for auto-focusing of the sub-reflector have been applied her $ for the 70m and HEF antennas, so their positions are 7cm and 1.5 cm $ respectively lower in elevation than in IOM 335.1-95-027. $ Station locations are consistent with the ITRF93 system. $ $ Station locations are for use with J2000 ephemerides (i.e. DE403). $ $ Stations included are : 12,13,14,15,16,17, $ 23,24,25,26,27,28, $ 33,34,42,43,45,46, $ 53,54,61,63,65,66. $ $ The following station location and mask data is consistent with the ITRF93 $ reference standard: $ ESTRF = 'ITRF93', $ ESLABL = 'FOLKNER: JPL IOM 335.1-95-027', $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ Zero out and initialize the plate motion parameters: $ ECPLAT(1) = 300*' ', ECNUM(1) = 300*0, ECRATE(1,1) = 900*0.0D0, $ ECEPOC(1) = 300*'01-JAN-1993 00:00:00', PLATEM = 'LINEAR', $ $ North East Vertical $ ECNUM( 1) = 10, ECRATE(1,1) = -0.57, -1.98, -0.01, $Goldstone ECNUM( 2) = 20, ECRATE(1,2) = -0.57, -1.98, -0.01, $ ECNUM( 3) = 30, ECRATE(1,3) = +5.06, +1.97, +0.01, $Canberra ECNUM( 4) = 40, ECRATE(1,4) = +5.06, +1.97, +0.01, $ ECNUM( 5) = 50, ECRATE(1,5) = +2.55, +2.11, +0.11, $Madrid ECNUM( 6) = 60, ECRATE(1,6) = +2.55, +2.11, +0.11, $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ REGRES will compute antenna offset corrections as follows: $ ANTENA = .TRUE., ANTARM(1) = 6.7060D0, $ For 26-M H-D or 34-M H-D (m). ANTARM(2) = 0.9144D0, $ For 26-M A-E (m). ANTARM(3) = 6.7060D0, $ For 26-M X'-Y' (m). ANTARM(4) = 2.4380D0, $ For 9-M X-Y (m). ANTARM(5) = 1.8288D0, $ For 34-M HSB (m). $ $ Antenna corrections are not required for 34-M BWG & 11m VLBI stations. $ ESOFFR = 0.39838D0, $ Offset radius for the 11m VLBI stations. $ $ TROPND(1) = 0.0D0, $ Dry troposphere range correction (m). $ TROPNW(1) = 0.0D0, $ Wet troposphere range correction (m). $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ Zero out and initialize station location parameters: $ ESNUM( 1) = 300*0, ESTYPE( 1) = 300*' ', ESLOCT( 1) = 300*' ', ESLOC(1, 1) = 900*0.0D0, ESNAME( 1) = 300*' ', ESCPLX( 1) = 300*0, $ ESNUM( 1) = 12, ESTYPE( 1) = '34-H-D', ESLOCT( 1) = 'CYLIND', ESLOC(1, 1) = 243.194513046D0, 3665.630988D0, 5212.0544722D0, ESNAME( 1) = 'GOLDSTONE ECHO 34-H-D', ESCPLX( 1) = 10, $ ESNUM( 2) = 13, ESTYPE( 2) = '34-BWG', ESLOCT( 2) = 'CYLIND', ESLOC(1, 2) = +243.2055430, +3660.912787, +5215.524535, ESNAME( 2) = 'GOLDSTONE VENUS 34-BWG', ESCPLX( 2) = 10, $ ESNUM( 3) = 14, ESTYPE( 3) = '70-A-E', ESLOCT( 3) = 'CYLIND', ESLOC(1, 3) = 243.110463799D0, 3677.052330D0, 5203.9968973D0, ESNAME( 3) = 'GOLDSTONE MARS 64-A-E', ESCPLX( 3) = 10, $ ESNUM( 4) = 15, ESTYPE( 4) = '34-HEF', ESLOCT( 4) = 'CYLIND', ESLOC(1, 4) = 243.112806935D0, 3676.670034D0, 5204.2343194D0, ESNAME( 4) = 'GOLDSTONE 34M 34-HEF', ESCPLX( 4) = 10, $ ESNUM( 5) = 16, ESTYPE( 5) = '26-X-Y', ESLOCT( 5) = 'CYLIND', ESLOC(1, 5) = 243.126352287D0, 3669.387069D0, 5209.3707151D0, ESNAME( 5) = 'GDS5 26-X-Y', ESCPLX( 5) = 10, $ ESNUM( 6) = 17, ESTYPE( 6) = '9-X-Y' , ESLOCT( 6) = 'CYLIND', ESLOC(1, 6) = 243.126496674D0, 3669.440659D0, 5209.3240561D0, ESNAME( 6) = 'GOLDSTONE 9M 9-X-Y', ESCPLX( 6) = 10, $ ESNUM( 7) = 23, ESTYPE( 7) = '11VLBI', ESLOCT( 7) = 'CYLIND', ESLOC(1, 7) = 243.127139009D0, 3669.207824D0, 5209.4995031D0, ESNAME( 7) = 'GOLDSTONE 11M 11VLBI', ESCPLX( 7) = 10, $ ESNUM( 8) = 24, ESTYPE( 8) = '34-BWG', ESLOCT( 8) = 'CYLIND', ESLOC(1, 8) = 243.125207895D0, 3669.242317D0, 5209.4824863D0, ESNAME( 8) = 'GOLDSTONE 34M 34-BWG', ESCPLX( 8) = 10, $ ESNUM( 9) = 25, ESTYPE( 9) = '34-BWG', ESLOCT( 9) = 'CYLIND', ESLOC(1, 9) = 243.124638433D0, 3669.040895D0, 5209.6359783D0, ESNAME( 9) = 'GOLDSTONE 34M 34-BWG', ESCPLX( 9) = 10, $ ESNUM( 10) = 26, ESTYPE( 10) = '34-BWG', ESLOCT( 10) = 'CYLIND', ESLOC(1,10) = 243.126984880D0, 3668.872212D0, 5209.7669713D0, ESNAME( 10) = 'GOLDSTONE 34M 34-BWG', ESCPLX( 10) = 10, $ ESNUM( 11) = 27, ESTYPE( 11) = '34-HSB', ESLOCT( 11) = 'CYLIND', ESLOC(1,11) = 243.223351581D0, 3660.096529D0, 5216.0792441D0, ESNAME( 11) = 'GOLDSTONE 34M 34-HSB', ESCPLX( 11) = 10, $ ESNUM( 12) = 28, ESTYPE( 12) = '34-HSB', ESLOCT( 12) = 'CYLIND', ESLOC(1,12) = 243.221110863D0, 3660.103577D0, 5216.0891761D0, ESNAME( 12) = 'GOLDSTONE 34M 34-HSB', ESCPLX( 12) = 10, $ ESNUM( 13) = 33, ESTYPE( 13) = '11VLBI', ESLOCT( 13) = 'CYLIND', ESLOC(1,13) = 148.983089455D0, -3674.570392D0, 5205.3723669D0, ESNAME( 13) = 'CANBERRA 11M 11VLBI', ESCPLX( 13) = 40, $ ESNUM( 14) = 34, ESTYPE( 14) = '34-BWG', ESLOCT( 14) = 'CYLIND', ESLOC(1,14) = +148.9819620, -3674.393542, +5205.507750, ESNAME( 14) = 'CANBERRA 34M 34-BWG', ESCPLX( 14) = 40, $ ESNUM( 15) = 42, ESTYPE( 15) = '34-H-D', ESLOCT( 15) = 'CYLIND', ESLOC(1,15) = 148.981264988D0, -3674.582072D0, 5205.3524323D0, ESNAME( 15) = 'CANBERRA 34-H-D', ESCPLX( 15) = 40, $ ESNUM( 16) = 43, ESTYPE( 16) = '70-A-E', ESLOCT( 16) = 'CYLIND', ESLOC(1,16) = 148.981264989D0, -3674.748540D0, 5205.2515219D0, ESNAME( 16) = 'BELLIMA 64-A-E', ESCPLX( 16) = 40, $ ESNUM( 17) = 45, ESTYPE( 17) = '34-HEF', ESLOCT( 17) = 'CYLIND', ESLOC(1,17) = 148.977683311D0, -3674.381393D0, 5205.4946968D0, ESNAME( 17) = 'CANBERRA 34M 34-HEF', ESCPLX( 17) = 40, $ ESNUM( 18) = 46, ESTYPE( 18) = '26-X-Y', ESLOCT( 18) = 'CYLIND', ESLOC(1,18) = 148.983079363D0, -3674.975508D0, 5205.0754964D0, ESNAME( 18) = 'CAN4 26-X-Y', ESCPLX( 18) = 40, $ ESNUM( 19) = 53, ESTYPE( 19) = '11VLBI', ESLOCT( 19) = 'CYLIND', ESLOC(1,19) = 355.750345311D0, 4114.758758D0, 4862.6994697D0, ESNAME( 19) = 'MADRID 11M 11VLBI', ESCPLX( 19) = 60, $ ESNUM( 20) = 54, ESTYPE( 20) = '34-BWG', ESLOCT( 20) = 'CYLIND', ESLOC(1,20) = +355.7459008, +4114.618643, +4862.832239, ESNAME( 20) = 'MADRID 34M 34-BWG', ESCPLX( 20) = 60, $ ESNUM( 21) = 61, ESTYPE( 21) = '34-H-D', ESLOCT( 21) = 'CYLIND', ESLOC(1,21) = 355.750975313D0, 4114.884445D0, 4862.6103559D0, ESNAME( 21) = 'ROBLEDO 34-H-D', ESCPLX( 21) = 60, $ ESNUM( 22) = 63, ESTYPE( 22) = '70-A-E', ESLOCT( 22) = 'CYLIND', ESLOC(1,22) = 355.751988973D0, 4115.109067D0, 4862.4509267D0, ESNAME( 22) = 'ROBLEDO 210-FT 64-A-E', ESCPLX( 22) = 60, $ ESNUM( 23) = 65, ESTYPE( 23) = '34-HEF', ESLOCT( 23) = 'CYLIND', ESLOC(1,23) = 355.748579509D0, 4114.748765D0, 4862.7172271D0, ESNAME( 23) = 'MADRID 34M 34-HEF', ESCPLX( 23) = 60, $ ESNUM( 24) = 66, ESTYPE( 24) = '26-X-Y', ESLOCT( 24) = 'CYLIND', ESLOC(1,24) = +355.7485798, +4114.995021, +4862.528531, ESNAME( 24) = 'MAD3 26-X-Y', ESCPLX( 24) = 60, $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ Station horizon masks: $ $ 1) Wolf, A. A., "50-Segment vs. 11-Segment Masks for DSN Stations $ in NAV Software," JPL IOM MGN-NAV-89-04, January 20, 1989. $ $ 2) Enright, S., "DSN Horizon Masks," JPL IOM OEA.18/12.18.E.0, $ January 7, 1991. $ $ 3) Sunseri, R. F., "New Station Masks for DSS 12, 14, 15, 16, 17, 42, $ 43, 45, 46, 61, 63, 65, AND 66," JPL IOM 314.9/91-619, March 18, 1991. $ $ ESMASK(J,K,N): $ $ ESMASK entries 'J' are in the following order (per sector): $ constraint type (where 1 = EL, 2 = HA, 3 = DEC) as a function of AZ; $ starting AZ (degrees); the five 4th degree polynomial coefficients; $ the ending AZ (degrees). $ $ Entries 'K' enumerate the sectors or the discrete polynomial segments $ (from 1 to 11) describing the horizon silhouette. $ $ Entries 'N' denote the stations. $ ESMASK(1, 1, 1) = 26400*0.0D0, $ $ Horizon mask for station 12 GOLDSTONE ECHO 34M HA-DEC $ ESMASK(1, 1, 1) = 0.20000000E+01, 0.00000000E+00, 0.26770001E+03, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.78272552E+02, ESMASK(1, 2, 1) = 0.10000000E+01, 0.78272552E+02, -0.95303301E+04, 0.34640482E+03, -0.41888137E+01, 0.16859710E-01, 0.00000000E+00, 0.89003731E+02, ESMASK(1, 3, 1) = 0.10000000E+01, 0.89003731E+02, 0.69569359E+05, -0.27941345E+04, 0.41989853E+02, -0.27979159E+00, 0.69741247E-03, 0.10533190E+03, ESMASK(1, 4, 1) = 0.10000000E+01, 0.10533190E+03, 0.10633186E+07, -0.38247000E+05, 0.51556805E+03, -0.30868518E+01, 0.69263014E-02, 0.11632820E+03, ESMASK(1, 5, 1) = 0.10000000E+01, 0.11632820E+03, 0.42380308E+04, -0.12654492E+03, 0.14084842E+01, -0.69273664E-02, 0.12707357E-04, 0.15477820E+03, ESMASK(1, 6, 1) = 0.10000000E+01, 0.15477820E+03, -0.16075879E+04, 0.32044701E+02, -0.24533567E+00, 0.86667429E-03, -0.11988418E-05, 0.19936530E+03, ESMASK(1, 7, 1) = 0.10000000E+01, 0.19936530E+03, -0.21919068E+05, 0.39109232E+03, -0.26111150E+01, 0.77328146E-02, -0.85710362E-05, 0.25539819E+03, ESMASK(1, 8, 1) = 0.10000000E+01, 0.25539819E+03, 0.42327228E+06, -0.49249419E+04, 0.19097824E+02, -0.24681104E-01, 0.00000000E+00, 0.26459210E+03, ESMASK(1, 9, 1) = 0.10000000E+01, 0.26459210E+03, 0.79551706E+06, -0.89334912E+04, 0.33436848E+02, -0.41711859E-01, 0.00000000E+00, 0.27229779E+03, ESMASK(1,10, 1) = 0.10000000E+01, 0.27229779E+03, -0.33448823E+04, 0.23990385E+02, -0.42939007E-01, 0.00000000E+00, 0.00000000E+00, 0.28144791E+03, ESMASK(1,11, 1) = 0.20000000E+01, 0.28144791E+03, 0.91800003E+02, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.36000000E+03, $ $ Horizon mask for station 13 GOLDSTONE 34 M BWG $ ESMASK(1, 1, 2) = .10000000E+01, .00000000E+00, .88413235E+01, -.10041944E+01, .15172188E+00, -.66063348E-02, .00000000E+00, .13000000E+02, ESMASK(1, 2, 2) = .10000000E+01, .13000000E+02, .70000000E+01, .00000000E+00, .00000000E+00, .00000000E+00, .00000000E+00, .31600000E+03, ESMASK(1, 3, 2) = .10000000E+01, .31600000E+03, -.54634507E+05, .64535163E+03, -.28650581E+01, .56665820E-02, -.42124064E-05, .36000000E+03, $ $ Horizon mask for station 14 GOLDSTONE MARS 70M AZ-EL (6 degrees) $ ESMASK(1, 1, 3) = 0.10000000E+01, 0.00000000E+00, 0.60000000E+01, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.36000000E+03, $ $ Horizon mask for station 15 GOLDSTONE 34M HEF - from R. F. Sunseri $ ESMASK(1, 1, 4) = 0.10000000E+01, 0.00000000E+00, 0.70000000E+01, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.14000000E+03, ESMASK(1, 2, 4) = 0.10000000E+01, 0.14000000E+03, 0.31488140E+06, -0.86396767E+04, 0.88866488E+02, -0.40612354E+00, 0.69580420E-03, 0.15000000E+03, ESMASK(1, 3, 4) = 0.10000000E+01, 0.15000000E+03, -0.14169734E+04, 0.26758388E+02, -0.16661819E+00, 0.34425245E-03, 0.00000000E+00, 0.17400000E+03, ESMASK(1, 4, 4) = 0.10000000E+01, 0.17400000E+03, -0.98703660E+04, 0.21707469E+03, -0.17883522E+01, 0.65457028E-02, -0.89800872E-05, 0.19100000E+03, ESMASK(1, 5, 4) = 0.10000000E+01, 0.19100000E+03, 0.45917977E+05, -0.94315447E+03, 0.72575468E+01, -0.24790218E-01, 0.31712773E-04, 0.20400000E+03, ESMASK(1, 6, 4) = 0.10000000E+01, 0.20400000E+03, 0.70000000E+01, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.36000000E+03, $ $ Horizon mask for station 16 GDS5 26M X-Y $ ESMASK(1, 1, 5) = 0.10000000E+01, 0.00000000E+00, 0.42000000E+01, 0.39159119E-01, -0.37419274E-02, 0.60352892E-04, -0.21321540E-06, 0.76400000E+02, ESMASK(1, 2, 5) = 0.10000000E+01, 0.76400000E+02, -0.13565604E+05, 0.60215993E+03, -0.10026011E+02, 0.74290449E-01, -0.20669569E-03, 0.10370000E+03, ESMASK(1, 3, 5) = 0.10000000E+01, 0.10370000E+03, 0.41643831E+04, -0.13807078E+03, 0.17075052E+01, -0.93242171E-02, 0.18971043E-04, 0.14600000E+03, ESMASK(1, 4, 5) = 0.10000000E+01, 0.14600000E+03, 0.78648803E+01, -0.20605789E-01, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.23110000E+03, ESMASK(1, 5, 5) = 0.10000000E+01, 0.23110000E+03, -0.35610148E+03, 0.30029595E+01, -0.62691000E-02, 0.00000000E+00, 0.00000000E+00, 0.25550000E+03, ESMASK(1, 6, 5) = 0.10000000E+01, 0.25550000E+03, -0.13182052E+07, 0.19524051E+05, -0.10844433E+03, 0.26772248E+00, -0.24786650E-03, 0.28430000E+03, ESMASK(1, 7, 5) = 0.10000000E+01, 0.28430000E+03, 0.99904725E+05, -0.10313754E+04, 0.35485840E+01, -0.40690104E-02, 0.00000000E+00, 0.29870000E+03, ESMASK(1, 8, 5) = 0.10000000E+01, 0.29870000E+03, -0.44732224E+02, 0.26238413E+00, -0.35128134E-03, 0.00000000E+00, 0.00000000E+00, 0.36000000E+03, $ $ Horizon mask for station 17 GOLDSTONE 9M X-Y $ ESMASK(1, 1, 6) = .10000000E+01, .00000000E+00, .75710559E+01, .56745785E+00, -.16053176E+00, -.23797009E-01, .31366550E-02, .90000000E+01, ESMASK(1, 2, 6) = .10000000E+01, .90000000E+01, .30154251E+01, -.27452108E-01, .39314569E-03, .00000000E+00, .00000000E+00, .53000000E+02, ESMASK(1, 3, 6) = .10000000E+01, .53000000E+02, -.31640010E+02, .10188766E+01, -.56055673E-02, -.44994674E-04, .33612912E-06, .10000000E+03, ESMASK(1, 4, 6) = .10000000E+01, .10000000E+03, .39290136E+02, -.15288311E+01, .17916687E-01, -.62774104E-04, .00000000E+00, .14100000E+03, ESMASK(1, 5, 6) = .10000000E+01, .14100000E+03, -.17838515E+04, .33960661E+02, -.21419689E+00, .44869942E-03, .00000000E+00, .17400000E+03, ESMASK(1, 6, 6) = .10000000E+01, .17400000E+03, -.22633994E+06, .47924163E+04, -.38073951E+02, .13452245E+00, -.17834495E-03, .20400000E+03, ESMASK(1, 7, 6) = .10000000E+01, .20400000E+03, .95227542E+05, -.17275105E+04, .11744646E+02, -.35464648E-01, .40133387E-04, .24100000E+03, ESMASK(1, 8, 6) = .10000000E+01, .24100000E+03, .36036412E+05, -.53049295E+03, .29272307E+01, -.71755618E-02, .65933505E-05, .29600000E+03, ESMASK(1, 9, 6) = .10000000E+01, .29600000E+03, -.14245175E+07, .18945540E+05, -.94435372E+02, .20909275E+00, -.17351398E-03, .30500000E+03, ESMASK(1,10, 6) = .10000000E+01, .30500000E+03, .20434410E+05, -.24924857E+03, .11418414E+01, -.23282504E-02, .17827921E-05, .35400000E+03, ESMASK(1,11, 6) = .10000000E+01, .35400000E+03, -.18034422E+05, .96878159E+02, -.11989286E+00, -.27777778E-04, .00000000E+00, .36000000E+03, $ $ Horizon mask for station 23 GOLDSTONE 11VLBI (6 degrees) $ ESMASK(1, 1, 7) = 0.10000000E+01, 0.00000000E+00, 0.60000000E+01, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.36000000E+03, $ $ Horizon mask for station 24 GOLDSTONE 34M BWG (6 degrees) $ ESMASK(1, 1, 8) = 0.10000000E+01, 0.00000000E+00, 0.60000000E+01, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.36000000E+03, $ $ Horizon mask for station 25 GOLDSTONE 34M BWG (6 degrees) $ ESMASK(1, 1, 9) = 0.10000000E+01, 0.00000000E+00, 0.60000000E+01, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.36000000E+03, $ $ Horizon mask for station 26 GOLDSTONE 34M BWG (6 degrees) $ ESMASK(1, 1,10) = 0.10000000E+01, 0.00000000E+00, 0.60000000E+01, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.36000000E+03, $ $ Horizon mask for station 27 GOLDSTONE 34M HSB (6 degrees) $ ESMASK(1, 1,11) = 0.10000000E+01, 0.00000000E+00, 0.60000000E+01, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.36000000E+03, $ $ Horizon mask for station 28 GOLDSTONE 34M HSB (6 degrees) $ ESMASK(1, 1,12) = 0.10000000E+01, 0.00000000E+00, 0.60000000E+01, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.36000000E+03, $ $ Horizon mask for station 33 CANBERRA 11VLBI (6 degrees) $ ESMASK(1, 1,13) = 0.10000000E+01, 0.00000000E+00, 0.60000000E+01, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.36000000E+03, $ $ Horizon mask for station 34 CANBERRA 34M BWG (6 degrees) $ ESMASK(1, 1,14) = 0.10000000E+01, 0.00000000E+00, 0.60000000E+01, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.36000000E+03, $ $ Horizon mask for station 42 CANBERRA 34M HA-DEC $ ESMASK(1, 1,15) = 0.10000000E+01, 0.00000000E+00, 0.75000000E+01, -0.21720202E+00, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.15331349E+02, ESMASK(1, 2,15) = 0.10000000E+01, 0.15331349E+02, -0.44611259E+01, 0.11000934E+01, -0.48064202E-01, 0.94749819E-03, -0.63933544E-05, 0.69000000E+02, ESMASK(1, 3,15) = 0.10000000E+01, 0.69000000E+02, 0.53716763E+02, -0.10629115E+01, 0.27988004E-02, 0.80397658E-04, -0.46864056E-06, 0.12132450E+03, ESMASK(1, 4,15) = 0.20000000E+01, 0.12132450E+03, 0.25726401E+03, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.18000000E+03, ESMASK(1, 5,15) = 0.20000000E+01, 0.18000000E+03, 0.10026200E+03, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.24639012E+03, ESMASK(1, 6,15) = 0.10000000E+01, 0.24639012E+03, -0.27832537E+02, 0.31988880E+00, -0.85958838E-03, 0.29368644E-06, 0.51562044E-09, 0.33679230E+03, ESMASK(1, 7,15) = 0.10000000E+01, 0.33679230E+03, -0.10488942E+03, 0.31219283E+00, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.36000000E+03, $ $ Horizon mask for station 43 BELLIMA 70M AZ-EL $ ESMASK(1, 1,16) = 0.10000000E+01, 0.00000000E+00, 0.60000000E+01, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.42562500E+02, ESMASK(1, 2,16) = 0.10000000E+01, 0.42562500E+02, -0.25039934E+03, 0.16166534E+02, -0.37341598E+00, 0.37759678E-02, -0.14128269E-04, 0.87000000E+02, ESMASK(1, 3,16) = 0.10000000E+01, 0.87000000E+02, 0.63776440E+03, -0.19990196E+02, 0.21002880E+00, -0.73100743E-03, 0.00000000E+00, 0.11292578E+03, ESMASK(1, 4,16) = 0.10000000E+01, 0.11292578E+03, 0.60000000E+01, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.23267383E+03, ESMASK(1, 5,16) = 0.10000000E+01, 0.23267383E+03, -0.25119053E+05, 0.30341229E+03, -0.12195134E+01, 0.16314239E-02, 0.00000000E+00, 0.24874512E+03, ESMASK(1, 6,16) = 0.10000000E+01, 0.24874512E+03, 0.60000000E+01, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.36000000E+03, $ $ Horizon mask for station 45 CANBERRA 34M HEF - from R. F. Sunseri $ ESMASK(1, 1,17) = 0.10000000E+01, 0.00000000E+00, 0.70000000E+01, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.68000000E+02, ESMASK(1, 2,17) = 0.10000000E+01, 0.68000000E+02, 0.24097240E+05, -0.12958382E+04, 0.26076850E+02, -0.23268148E+00, 0.77684081E-03, 0.80000000E+02, ESMASK(1, 3,17) = 0.10000000E+01, 0.80000000E+02, 0.94633318E+04, -0.42512078E+03, 0.71609700E+01, -0.53555049E-01, 0.15001960E-03, 0.95000000E+02, ESMASK(1, 4,17) = 0.10000000E+01, 0.95000000E+02, 0.70000000E+01, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.10000000E+03, ESMASK(1, 5,17) = 0.10000000E+01, 0.10000000E+03, 0.49878000E+04, -0.14455800E+03, 0.13975000E+01, -0.45000000E-02, 0.00000000E+00, 0.10300000E+03, ESMASK(1, 6,17) = 0.10000000E+01, 0.10300000E+03, -0.14829500E+03, 0.30540000E+01, -0.15000000E-01, 0.00000000E+00, 0.00000000E+00, 0.10500000E+03, ESMASK(1, 7,17) = 0.10000000E+01, 0.10500000E+03, 0.70000000E+01, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.11300000E+03, ESMASK(1, 8,17) = 0.10000000E+01, 0.11300000E+03, -0.15984760E+05, 0.41046000E+03, -0.35100000E+01, 0.10000000E-01, 0.00000000E+00, 0.11600000E+03, ESMASK(1, 9,17) = 0.10000000E+01, 0.11600000E+03, 0.70000000E+01, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.19900000E+03, ESMASK(1,10,17) = 0.10000000E+01, 0.19900000E+03, -0.60328490E+04, 0.60400000E+02, -0.15100000E+00, 0.00000000E+00, 0.00000000E+00, 0.20100000E+03, ESMASK(1,11,17) = 0.10000000E+01, 0.20100000E+03, 0.70000000E+01, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.36000000E+03, $ $ Horizon mask for station 46 CAN4 26M X-Y $ ESMASK(1, 1,18) = 0.10000000E+01, 0.00000000E+00, 0.25380811E+01, 0.18499543E+00, -0.11241838E-02, 0.00000000E+00, 0.00000000E+00, 0.78400000E+02, ESMASK(1, 2,18) = 0.10000000E+01, 0.78400000E+02, -0.30596504E+03, 0.71438678E+01, -0.39664356E-01, 0.00000000E+00, 0.00000000E+00, 0.10500000E+03, ESMASK(1, 3,18) = 0.10000000E+01, 0.10500000E+03, -0.60752000E+03, 0.14670667E+02, -0.11480000E+00, 0.29333333E-03, 0.00000000E+00, 0.13000000E+03, ESMASK(1, 4,18) = 0.10000000E+01, 0.13000000E+03, 0.57527477E+03, -0.12406421E+02, 0.99000311E-01, -0.34531242E-03, 0.44508798E-06, 0.25400000E+03, ESMASK(1, 5,18) = 0.10000000E+01, 0.25400000E+03, -0.29045635E+06, 0.42961485E+04, -0.23855177E+02, 0.58938691E-01, -0.54669509E-04, 0.28600000E+03, ESMASK(1, 6,18) = 0.10000000E+01, 0.28600000E+03, -0.49227926E+06, 0.65000900E+04, -0.32160346E+02, 0.70665762E-01, -0.58183973E-04, 0.32300000E+03, ESMASK(1, 7,18) = 0.10000000E+01, 0.32300000E+03, 0.80000000E+01, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.33300000E+03, ESMASK(1, 8,18) = 0.10000000E+01, 0.33300000E+03, -0.32022727E+03, 0.18055556E+01, -0.25252525E-02, 0.00000000E+00, 0.00000000E+00, 0.36000000E+03, $ $ Horizon mask for station 53 MADRID 11VLBI (6 degrees) $ ESMASK(1, 1,19) = 0.10000000E+01, 0.00000000E+00, 0.60000000E+01, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.36000000E+03, $ $ Horizon mask for station 54 MADRID 34M BWG (6 degrees) $ ESMASK(1, 1,20) = 0.10000000E+01, 0.00000000E+00, 0.60000000E+01, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.36000000E+03, $ $ Horizon mask for station 61 ROBLEDO 34M HA-DEC (LABELED 26-H-D) $ ESMASK(1, 1,21) = 0.20000000E+01, 0.00000000E+00, 0.25805301E+03, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.65831207E+02, ESMASK(1, 2,21) = 0.10000000E+01, 0.65831207E+02, 0.10459758E+02, -0.77675313E-01, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.90000000E+02, ESMASK(1, 3,21) = 0.10000000E+01, 0.90000000E+02, 0.56644519E+03, -0.18895845E+02, 0.23353083E+00, -0.12591545E-02, 0.24992182E-05, 0.16023386E+03, ESMASK(1, 4,21) = 0.10000000E+01, 0.16023386E+03, -0.98384564E+03, 0.18665325E+02, -0.13708907E+00, 0.47358446E-03, -0.65782143E-06, 0.20398195E+03, ESMASK(1, 5,21) = 0.10000000E+01, 0.20398195E+03, 0.64192671E+04, -0.11018304E+03, 0.70383865E+00, -0.19836526E-02, 0.20831314E-05, 0.26500000E+03, ESMASK(1, 6,21) = 0.10000000E+01, 0.26500000E+03, -0.75402046E+04, 0.81173515E+02, -0.29088956E+00, 0.34728320E-03, 0.00000000E+00, 0.29311069E+03, ESMASK(1, 7,21) = 0.20000000E+01, 0.29311069E+03, 0.10022400E+03, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.36000000E+03, $ $ Horizon mask for station 63 ROBLEDO 210-FT 70M AZ-EL $ ESMASK(1, 1,22) = 0.10000000E+01, 0.00000000E+00, 0.60000000E+01, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.28389001E+03, ESMASK(1, 2,22) = 0.10000000E+01, 0.28389001E+03, -0.13014862E+06, 0.18010964E+04, -0.93353033E+01, 0.21476801E-01, -0.18501985E-04, 0.31964001E+03, ESMASK(1, 3,22) = 0.10000000E+01, 0.31964001E+03, 0.25367563E+06, -0.29985869E+04, 0.13277709E+02, -0.26100073E-01, 0.19215948E-04, 0.35531900E+03, ESMASK(1, 4,22) = 0.10000000E+01, 0.35531900E+03, 0.60000000E+01, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.36000000E+03, $ $ Horizon mask for station 65 MADRID 34M HEF - from R. F. Sunseri $ ESMASK(1, 1,23) = 0.10000000E+01, 0.00000000E+00, 0.70000000E+01, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.32000000E+02, ESMASK(1, 2,23) = 0.10000000E+01, 0.32000000E+02, -0.16166024E+05, 0.19434577E+04, -0.87669750E+02, 0.17593333E+01, -0.13250000E-01, 0.36000000E+02, ESMASK(1, 3,23) = 0.10000000E+01, 0.36000000E+02, 0.70000000E+01, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.24900000E+03, ESMASK(1, 4,23) = 0.10000000E+01, 0.24900000E+03, -0.19311109E+02, 0.10555152E+00, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.25800000E+03, ESMASK(1, 5,23) = 0.10000000E+01, 0.25800000E+03, 0.14227085E+04, -0.10694387E+02, 0.20196429E-01, 0.00000000E+00, 0.00000000E+00, 0.26500000E+03, ESMASK(1, 6,23) = 0.10000000E+01, 0.26500000E+03, 0.70000000E+01, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.27000000E+03, ESMASK(1, 7,23) = 0.10000000E+01, 0.27000000E+03, -0.56504197E+06, 0.80384227E+04, -0.42879921E+02, 0.10165405E+00, -0.90364797E-04, 0.28900000E+03, ESMASK(1, 8,23) = 0.10000000E+01, 0.28900000E+03, 0.70000000E+01, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.00000000E+00, 0.29300000E+03, ESMASK(1, 9,23) = 0.10000000E+01, 0.29300000E+03, 0.11498156E+06, -0.11651606E+04, 0.39355734E+01, -0.44306527E-02, 0.00000000E+00, 0.30200000E+03, ESMASK(1,10,23) = 0.10000000E+01, 0.30200000E+03, 0.25471217E+06, -0.32142283E+04, 0.15208546E+02, -0.31979315E-01, 0.25214378E-04, 0.33800000E+03, ESMASK(1,11,23) = 0.10000000E+01, 0.33800000E+03, 0.34906007E+05, -0.30158654E+03, 0.86946695E+00, -0.83614067E-03, 0.00000000E+00, 0.36000000E+03, $ $ Horizon mask for station 66 MAD3 26M X-Y $ ESMASK(1, 1,24) = 0.10000000E+01, 0.00000000E+00, 0.12000000E+02, 0.24993513E+00, -0.40909202E-01, 0.20481065E-02, -0.29618674E-04, 0.35000000E+02, ESMASK(1, 2,24) = 0.10000000E+01, 0.35000000E+02, 0.16752528E+03, -0.10797192E+02, 0.27681503E+00, -0.31351753E-02, 0.13126965E-04, 0.75800000E+02, ESMASK(1, 3,24) = 0.10000000E+01, 0.75800000E+02, -0.64016276E+04, 0.28364077E+03, -0.47262108E+01, 0.35182332E-01, -0.98704395E-04, 0.10520000E+03, ESMASK(1, 4,24) = 0.10000000E+01, 0.10520000E+03, 0.26199076E+02, -0.53202228E+00, 0.40564820E-02, -0.95542674E-05, 0.00000000E+00, 0.19080000E+03, ESMASK(1, 5,24) = 0.10000000E+01, 0.19080000E+03, 0.93291735E+04, -0.16469364E+03, 0.10866030E+01, -0.31750667E-02, 0.34686632E-05, 0.25460000E+03, ESMASK(1, 6,24) = 0.10000000E+01, 0.25460000E+03, -0.25411207E+04, 0.18953525E+02, -0.35119688E-01, 0.00000000E+00, 0.00000000E+00, 0.28500000E+03, ESMASK(1, 7,24) = 0.10000000E+01, 0.28500000E+03, -0.25640911E+04, 0.26376951E+02, -0.90468716E-01, 0.10380442E-03, 0.00000000E+00, 0.32880000E+03, ESMASK(1, 8,24) = 0.10000000E+01, 0.32880000E+03, -0.23553326E+05, 0.20709546E+03, -0.60558409E+00, 0.58930594E-03, 0.00000000E+00, 0.36000000E+03, $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ BEGIN ODP $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ PV generates partial derivatives of the state with respect to the $ other dynamic parameters. The matrix is 6 X N where N <= 200. $ PARTLS( 1) = 200*' ', $ $ State partials: $ PARTLS( 1) = 'X','Y','Z','DX','DY','DZ', $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ REGRES $ $ REGRES generates observables and partials of the observables wrt to $ the parameters listed in PARTLS for each data point on the orbit $ data file. $ $ Frequency constants: $ $ 1) DPTRAJ-ODP User's Reference Manual, Vol. 1, July 1, 1990. $ UPBAND(1,1) = 14*0.0D0, SCBAND(1) = 7*0.0D0, BNDRAT(1,1) = 49*0.0D0, $ UPBAND(1,1) = 0.0D0, 96.0D0, $ S-Band up UPBAND(1,2) = 6.5D9, 32.0D0, $ X-Band up UPBAND(1,4) = 0.0D0, 232.0D0, $ C-Band up SCBAND(1) = 1.0D0, $ F1 S-Band SCBAND(2) = 3.66666666666666667D0, $ F1 X-Band BNDRAT(1,1) = 1.08597285067873303D0, $ S-Up/S-Down band ratio, 240/221 BNDRAT(1,2) = 3.98190045248868777D0, $ S-Up/X-Down band ratio, 880/221 BNDRAT(2,1) = 0.32042723631508678D0, $ X-Up/S-Down band ratio, 240/749 BNDRAT(2,2) = 1.17489986648865153D0, $ X-Up/X-Down band ratio, 880/749 BNDRAT(4,3) = 0.33480176211453744D0, $ L-Up/C-Down band ratio, 228/681 $ STNCOR = 2, $ STNMOD( 1) = 20*.FALSE., $ $ STNMOD( 1) = .TRUE., $ The solid earth tide model is on. $ STNMOD( 4) = .TRUE., $ Polar motion. $ STNMOD( 6) = .TRUE., $ Lorentz contraction / relativistic scaling. $ STNMOD(10) = .TRUE., $ The solid earth tides are to 1st order. $ STNMOD(12) = .TRUE., $ ET - TAI "vector" calculation. $ STNMOD(1) = .TRUE. $ solid tides on STNMOD(2) = .TRUE. $ pole tide on STNMOD(3) = .TRUE. $ ocean loading on STNMOD(4) = .TRUE. $ polar motion on STNMOD(5) = .TRUE. $ vector ET-TAI conversion STNMOD(6) = .TRUE. $ convert geocentric to barycentric when necessary STNMOD(7) = .TRUE. $ plate motion STNMOD(8) = .FALSE. $ supplied coordinates are w.r.t center of mass STNMOD(9) = .FALSE. $ permanent solid tide included in solid tide model STNMOD(10)= .TRUE. $ first order solid tide STNMOD(11)= .TRUE. $ second order solid tide STNMOD(12)= .TRUE. $ use vector formulation ET-TAI STNMOD(13)=8*.FALSE. $ not used as of 20 October 1996 version of REGRES $ TIDLOV(1) = 0.6090D0, TIDLOV(2) = 0.0852D0, TIDEPS = 0.0D0, $ Phase offset for the Earth tide (degrees). $ REFCOR = .TRUE., $ Troposphere refraction correction. LTCRIT = 0.1D0, $ LT convergence criterion (seconds, recommended). NOLT = 4, $ LT iterations (recommended). RLTBOD( 4) = .FALSE., $ Relativistic LT delay due to Mars is off. RLTBOD( 5) = .TRUE., $ Relativistic LT delay due to Jupiter is on. RLTBOD( 6) = .FALSE., $ Relativistic LT delay due to Saturn is off. RLTBOD(10) = .TRUE., $ Relativistic LT delay due to Sol is on. $ $ High Gain Antenna model (this model nominally for Mars Observer only and $ is turned off here): $ HGAON = .FALSE., $ The high gain antenna model is off. HGAON2 = .FALSE., HGAS2H = 0.0D0, $ Coordinates of the s/c HGA gimbal axes in the 0.0D0, $ S/C body coordinate system. 0.0D0, HGAH2A = 0.0D0, $ HGA phase center coordinates. 0.0D0, 0.0D0, HGAGAM = 0.0D0, $ Angle to transform between the s/c body coordinate $ system to the s/c gimbal coordinate system. $ HGATIM(1) = '17-FEB-1996 00:00:00.0000', $ $ Center of mass wrt the S/C body coordinate system: $ HGAS2C(1,1) = 300*0.0D0, $ $ Range (SRA) biases: $ FRC(1) = 15, 45, 65, ODRC(1) = '17-FEB-1996 00:00:00', DRC(2,1) = 0.0D0, ODRC(2) = '17-FEB-1996 00:00:00', DRC(2,2) = 0.0D0, ODRC(3) = '17-FEB-1996 00:00:00', DRC(2,3) = 0.0D0, $ $ One-way Doppler (F1) drift: $ DRIFT(1,1) = 204*0.0D0, ODRIFT(1) = '17-FEB-1996 00:00:00', ODRIFT(2) = '31-MAR-2002 00:00:00', $ $ Corrections between UTC and each station: $ FSTPOL(1) = 15, 45, 65, ODSTPO(1) = 100*' ', DSTPOL(1,1) = 400*0.0D0, $ $ Basically, an epoch offset between station time and UTC causes an error $ in the geometry of the computed observable. The data from the Frequency $ & Timing System Clock Reports will correct the computed observables for $ Doppler (F2) and differenced Doppler (F2MF3). $ $ The FTS Clock Reports provide the following clock epoch offset data: $ $ SPC10 - UTC; SPC40 - SPC10; SPC60 - SPC10 $ $ and this data should be applied in this manner: $ $ DSTPOL(2,1) = (SPC10 - UTC) $ DSS 15. $ DSTPOL(2,2) = (SPC10 - UTC) + (SPC40 - SPC10) $ DSS 45. $ DSTPOL(2,3) = (SPC10 - UTC) + (SPC60 - SPC10) $ DSS 65. $ $ The STOIC information file: $ UT1TYP = 'UT1R', $ $ Timing deck $ 1 - 37: A1-UTC: EPOCH(SEC), UTC(SEC), DUTC(SEC/SEC) $ 40 - 148: A1-UT1: EPOCH(SEC), UT1(SEC), DUTC(SEC/SEC) $ 151 - 331: MOTION: EPOCH(SEC), X1(ARC S), DX1(ARC S/UTC S) $ Y1(ARC S), DY1(ARC S/UTC SEC) $ TIMPOL='STOIC/KEOF.LD000124/PT000405 . PREDICTS->000405. UT1TYP=UT1R.', IT( 1)=980715,TP( 1)= -46267200., 31.000000, 0.0000E-10, IT( 4)=990101,TP( 4)= -31579200., 32.000000, 0.0000E-10, IT( 7)=100101,TP( 7)= 315576000., 45.000000, 0.0000E-10, IT( 10)=491231,TP( 10)= 0., 0.000000, 0.0000E-10, IT( 13)=491231,TP( 13)= 0., 0.000000, 0.0000E-10, IT( 16)=491231,TP( 16)= 0., 0.000000, 0.0000E-10, IT( 19)=491231,TP( 19)= 0., 0.000000, 0.0000E-10, IT( 22)=491231,TP( 22)= 0., 0.000000, 0.0000E-10, IT( 25)=491231,TP( 25)= 0., 0.000000, 0.0000E-10, IT( 28)=491231,TP( 28)= 0., 0.000000, 0.0000E-10, IT( 31)=491231,TP( 31)= 0., 0.000000, 0.0000E-10, IT( 34)=491231,TP( 34)= 0., 0.000000, 0.0000E-10, IT( 37)=491231,TP( 37)= 0., 0.000000, 0.0000E-10, IT( 40)=980715,TP( 40)= -46267200., 31.105700, 40.3540E-10, IT( 43)=980802,TP( 43)= -44712000., 31.112499, 64.8710E-10, IT( 46)=980820,TP( 46)= -43156800., 31.121750, 44.9860E-10, IT( 49)=980907,TP( 49)= -41601600., 31.134750, 102.5410E-10, IT( 52)=980925,TP( 52)= -40046400., 31.152660, 132.0860E-10, IT( 55)=981013,TP( 55)= -38491200., 31.175980, 165.7860E-10, IT( 58)=981031,TP( 58)= -36936000., 31.202579, 170.3380E-10, IT( 61)=981118,TP( 61)= -35380800., 31.230350, 171.6900E-10, IT( 64)=981206,TP( 64)= -33825600., 31.256001, 140.3290E-10, IT( 67)=981224,TP( 67)= -32270400., 31.274920, 103.9370E-10, IT( 70)=990111,TP( 70)= -30715200., 31.292250, 121.9860E-10, IT( 73)=990129,TP( 73)= -29160000., 31.309660, 148.3050E-10, IT( 76)=990216,TP( 76)= -27604800., 31.332260, 139.8430E-10, IT( 79)=990306,TP( 79)= -26049600., 31.352180, 108.5350E-10, IT( 82)=990324,TP( 82)= -24494400., 31.372641, 159.4230E-10, IT( 85)=990411,TP( 85)= -22939200., 31.397619, 165.2340E-10, IT( 88)=990429,TP( 88)= -21384000., 31.422840, 163.6310E-10, IT( 91)=990517,TP( 91)= -19828800., 31.443850, 124.6620E-10, IT( 94)=990604,TP( 94)= -18273600., 31.463440, 106.7690E-10, IT( 97)=990622,TP( 97)= -16718400., 31.477619, 69.4440E-10, IT(100)=990710,TP(100)= -15163200., 31.483040, 33.2670E-10, IT(103)=990728,TP(103)= -13608000., 31.489550, 39.1770E-10, IT(106)=990815,TP(106)= -12052800., 31.496401, 53.9900E-10, IT(109)=990902,TP(109)= -10497600., 31.508949, 94.7560E-10, IT(112)=990920,TP(112)= -8942400., 31.521130, 92.5540E-10, IT(115)=991008,TP(115)= -7387200., 31.536850, 134.1130E-10, IT(118)=991026,TP(118)= -5832000., 31.558901, 169.5770E-10, IT(121)=991113,TP(121)= -4276800., 31.584379, 182.5950E-10, IT(124)=991201,TP(124)= -2721600., 31.607941, 139.7450E-10, IT(127)=991219,TP(127)= -1166400., 31.629330, 130.5940E-10, IT(130)=000106,TP(130)= 388800., 31.647560, 96.3340E-10, IT(133)=000124,TP(133)= 1944000., 31.662500, 102.6140E-10, IT(136)=000211,TP(136)= 3499200., 31.680580, 124.8440E-10, IT(139)=000229,TP(139)= 5054400., 31.701370, 142.8190E-10, IT(142)=000318,TP(142)= 6609600., 31.724850, 158.0360E-10, IT(145)=000405,TP(145)= 8164800., 31.750111, 164.5030E-10, IT(148)=100101,TP(148)= 315576000., 45.000000, 317.0000E-10, IT(151)=980715,TP(151)= -46267200.,-.03370,0.26030E-07,0.45910,0.14460E-07, IT(156)=980802,TP(156)= -44712000.,0.00500,0.22110E-07,0.47600,0.69340E-08, IT(161)=980820,TP(161)= -43156800.,0.04520,0.25100E-07,0.47600,-.21010E-09, IT(166)=980907,TP(166)= -41601600.,0.08410,0.28490E-07,0.46810,-.94360E-08, IT(171)=980925,TP(171)= -40046400.,0.11820,0.16240E-07,0.45250,-.15470E-07, IT(176)=981013,TP(176)= -38491200.,0.14120,0.10100E-07,0.42610,-.13130E-07, IT(181)=981031,TP(181)= -36936000.,0.15740,0.13250E-07,0.39860,-.16380E-07, IT(186)=981118,TP(186)= -35380800.,0.16330,-.79590E-08,0.36350,-.23630E-07, IT(191)=981206,TP(191)= -33825600.,0.14400,-.12500E-07,0.33190,-.75410E-08, IT(196)=981224,TP(196)= -32270400.,0.14230,-.88100E-09,0.30570,-.17210E-07, IT(201)=990111,TP(201)= -30715200.,0.13260,-.19530E-07,0.28370,-.11100E-07, IT(206)=990129,TP(206)= -29160000.,0.10970,-.14610E-07,0.25950,-.10680E-07, IT(211)=990216,TP(211)= -27604800.,0.08480,-.13830E-07,0.24580,-.47000E-08, IT(216)=990306,TP(216)= -26049600.,0.06470,-.12570E-07,0.24150,0.54930E-08, IT(221)=990324,TP(221)= -24494400.,0.04300,-.18940E-07,0.24020,0.28640E-08, IT(226)=990411,TP(226)= -22939200.,0.00930,-.68880E-08,0.23980,0.45780E-08, IT(231)=990429,TP(231)= -21384000.,-.00930,-.22690E-08,0.25370,0.13290E-07, IT(236)=990517,TP(236)= -19828800.,-.02030,-.40310E-08,0.27250,0.16780E-07, IT(241)=990604,TP(241)= -18273600.,-.02800,-.67750E-08,0.28610,0.14090E-07, IT(246)=990622,TP(246)= -16718400.,-.03330,0.10890E-08,0.30150,0.12040E-07, IT(251)=990710,TP(251)= -15163200.,-.02740,0.92940E-08,0.31980,0.13960E-07, IT(256)=990728,TP(256)= -13608000.,-.02470,0.20520E-08,0.33350,0.85840E-08, IT(261)=990815,TP(261)= -12052800.,-.01280,0.29450E-08,0.34860,0.11670E-07, IT(266)=990902,TP(266)= -10497600.,-.00770,0.28610E-08,0.36320,0.16770E-08, IT(271)=990920,TP(271)= -8942400.,0.00380,0.18020E-08,0.37400,0.33070E-08, IT(276)=991008,TP(276)= -7387200.,0.00940,0.80140E-08,0.38150,0.31680E-10, IT(281)=991026,TP(281)= -5832000.,0.01760,0.66170E-08,0.38250,-.17340E-08, IT(286)=991113,TP(286)= -4276800.,0.02740,0.67340E-08,0.37460,0.79310E-09, IT(291)=991201,TP(291)= -2721600.,0.03280,0.77420E-08,0.37610,-.31640E-09, IT(296)=991219,TP(296)= -1166400.,0.03690,-.47420E-08,0.38120,-.61170E-09, IT(301)=000106,TP(301)= 388800.,0.04210,-.19280E-08,0.37530,-.16700E-08, IT(306)=000124,TP(306)= 1944000.,0.05520,0.11450E-07,0.37620,0.40180E-08, IT(311)=000211,TP(311)= 3499200.,0.07400,0.12650E-07,0.38000,0.85130E-09, IT(316)=000229,TP(316)= 5054400.,0.09410,0.13050E-07,0.37870,-.25240E-08, IT(321)=000318,TP(321)= 6609600.,0.11410,0.12560E-07,0.37220,-.58860E-08, IT(326)=000405,TP(326)= 8164800.,0.13270,0.11160E-07,0.36060,-.89990E-08, IT(331)=100101,TP(331)= 315576000.,0.00000,0.00000E+00,0.25000,0.00000E+00, $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ Earth Orientation Parameter (EOP) File $ $ 1) Herbert Royden, Section 335, JPL. $ $ A model of Earth motions. Values are updated about twice a week by TSAC. $ This file replaces the older time & polar motion (STOIC) files produced by $ TSAC in the past. A typical element follows: $ $ JPL Earth Orientation Parameter File $ Last Data Point 20-JAN-2000 $ Predicts to 13-APR-2000 $ EOPLBL='EOP. LAST DATUM 20-JAN-2000. PREDICTS->13-APR-2000, UT1TYP=UT1. ' EOPFNG='Enter MAKE_EOP 21-JAN-2000 22:32:08 linked 18-AUG-1998 20:10:46 EOPUT1='UT1' EOPTYP='EOP' EOPTIM='21-JAN-2000 22:32:08 ' EOPTRF='ITRF93' EOPCRF='ICRF93' $ $ MJD PM x PM y TAI-UT1 TAI-UTC dPsi dEps $ (mas) (mas) (sec) (sec) (mas) (mas) EOP= 51281.0, 8.60, 241.30, 31.399040, 32.0, -45.89, -7.99, $ 13-APR-1999 51282.0, 8.20, 242.40, 31.400850, 32.0, -45.90, -7.99, $ 14-APR-1999 51283.0, 7.60, 243.70, 31.402770, 32.0, -45.73, -7.78, $ 15-APR-1999 51284.0, 6.70, 245.00, 31.404700, 32.0, -45.81, -7.64, $ 16-APR-1999 51285.0, 5.50, 246.30, 31.406580, 32.0, -46.28, -7.82, $ 17-APR-1999 51286.0, 3.90, 247.30, 31.408340, 32.0, -46.94, -8.19, $ 18-APR-1999 51287.0, 2.30, 247.80, 31.409940, 32.0, -47.30, -8.48, $ 19-APR-1999 51288.0, 0.80, 247.90, 31.411400, 32.0, -47.21, -8.54, $ 20-APR-1999 51289.0, -0.60, 247.80, 31.412740, 32.0, -46.87, -8.51, $ 21-APR-1999 51290.0, -1.90, 247.80, 31.414000, 32.0, -46.54, -8.48, $ 22-APR-1999 51291.0, -3.40, 248.20, 31.415240, 32.0, -46.39, -8.45, $ 23-APR-1999 51292.0, -4.90, 248.90, 31.416470, 32.0, -46.35, -8.42, $ 24-APR-1999 51293.0, -6.40, 249.80, 31.417780, 32.0, -46.18, -8.44, $ 25-APR-1999 51294.0, -7.70, 250.90, 31.419170, 32.0, -45.89, -8.47, $ 26-APR-1999 51295.0, -8.70, 251.80, 31.420590, 32.0, -45.68, -8.39, $ 27-APR-1999 51296.0, -9.10, 252.70, 31.422060, 32.0, -45.70, -8.16, $ 28-APR-1999 51297.0, -9.30, 253.70, 31.423550, 32.0, -45.97, -7.89, $ 29-APR-1999 51298.0, -9.60, 255.00, 31.424970, 32.0, -46.30, -7.74, $ 30-APR-1999 51299.0, -10.20, 256.40, 31.426320, 32.0, -46.56, -7.80, $ 1-MAY-1999 51300.0, -11.20, 257.50, 31.427580, 32.0, -46.71, -8.02, $ 2-MAY-1999 51301.0, -12.60, 258.30, 31.428720, 32.0, -46.73, -8.28, $ 3-MAY-1999 51302.0, -14.20, 258.60, 31.429730, 32.0, -46.74, -8.48, $ 4-MAY-1999 51303.0, -15.60, 258.80, 31.430600, 32.0, -46.77, -8.66, $ 5-MAY-1999 51304.0, -16.60, 259.00, 31.431350, 32.0, -46.73, -8.81, $ 6-MAY-1999 51305.0, -17.50, 259.60, 31.432070, 32.0, -46.38, -8.84, $ 7-MAY-1999 51306.0, -18.30, 260.40, 31.432860, 32.0, -45.76, -8.64, $ 8-MAY-1999 51307.0, -19.10, 261.30, 31.433760, 32.0, -45.29, -8.33, $ 9-MAY-1999 51308.0, -19.70, 262.30, 31.434840, 32.0, -45.32, -8.16, $ 10-MAY-1999 51309.0, -20.10, 263.30, 31.436050, 32.0, -45.72, -8.20, $ 11-MAY-1999 51310.0, -20.20, 264.50, 31.437440, 32.0, -46.09, -8.24, $ 12-MAY-1999 51311.0, -20.10, 265.80, 31.438970, 32.0, -46.31, -8.15, $ 13-MAY-1999 51312.0, -20.00, 267.50, 31.440560, 32.0, -46.66, -8.07, $ 14-MAY-1999 51313.0, -20.00, 269.30, 31.442090, 32.0, -47.22, -8.21, $ 15-MAY-1999 51314.0, -20.00, 271.00, 31.443500, 32.0, -47.79, -8.48, $ 16-MAY-1999 51315.0, -20.30, 272.50, 31.444710, 32.0, -48.03, -8.66, $ 17-MAY-1999 51316.0, -20.70, 273.90, 31.445770, 32.0, -47.77, -8.63, $ 18-MAY-1999 51317.0, -21.10, 275.00, 31.446790, 32.0, -47.20, -8.57, $ 19-MAY-1999 51318.0, -21.40, 276.00, 31.447850, 32.0, -46.74, -8.59, $ 20-MAY-1999 51319.0, -21.50, 276.90, 31.448940, 32.0, -46.69, -8.61, $ 21-MAY-1999 51320.0, -21.40, 277.50, 31.450120, 32.0, -47.00, -8.54, $ 22-MAY-1999 51321.0, -21.50, 278.10, 31.451400, 32.0, -47.30, -8.46, $ 23-MAY-1999 51322.0, -21.90, 278.70, 31.452700, 32.0, -47.23, -8.42, $ 24-MAY-1999 51323.0, -22.50, 279.40, 31.454000, 32.0, -46.96, -8.37, $ 25-MAY-1999 51324.0, -23.20, 280.00, 31.455270, 32.0, -46.89, -8.19, $ 26-MAY-1999 51325.0, -23.80, 280.60, 31.456390, 32.0, -47.24, -7.95, $ 27-MAY-1999 51326.0, -24.20, 281.10, 31.457380, 32.0, -47.75, -7.82, $ 28-MAY-1999 51327.0, -24.70, 281.70, 31.458250, 32.0, -48.11, -7.88, $ 29-MAY-1999 51328.0, -25.20, 282.40, 31.459020, 32.0, -48.20, -8.09, $ 30-MAY-1999 51329.0, -25.80, 283.00, 31.459700, 32.0, -48.09, -8.31, $ 31-MAY-1999 51330.0, -26.40, 283.60, 31.460320, 32.0, -48.00, -8.42, $ 1-JUN-1999 51331.0, -26.90, 284.20, 31.460880, 32.0, -48.02, -8.47, $ 2-JUN-1999 51332.0, -27.40, 285.00, 31.461450, 32.0, -48.13, -8.53, $ 3-JUN-1999 51333.0, -28.00, 286.10, 31.462080, 32.0, -48.12, -8.56, $ 4-JUN-1999 51334.0, -28.60, 287.40, 31.462790, 32.0, -47.85, -8.43, $ 5-JUN-1999 51335.0, -29.30, 289.00, 31.463650, 32.0, -47.54, -8.13, $ 6-JUN-1999 51336.0, -30.00, 290.50, 31.464640, 32.0, -47.50, -7.82, $ 7-JUN-1999 51337.0, -30.70, 291.80, 31.465790, 32.0, -47.84, -7.67, $ 8-JUN-1999 51338.0, -31.30, 292.60, 31.467080, 32.0, -48.39, -7.66, $ 9-JUN-1999 51339.0, -31.60, 293.10, 31.468440, 32.0, -48.99, -7.66, $ 10-JUN-1999 51340.0, -31.80, 293.40, 31.469810, 32.0, -49.59, -7.72, $ 11-JUN-1999 51341.0, -32.10, 293.80, 31.471070, 32.0, -50.17, -7.94, $ 12-JUN-1999 51342.0, -32.40, 294.50, 31.472120, 32.0, -50.58, -8.17, $ 13-JUN-1999 51343.0, -32.70, 295.40, 31.472980, 32.0, -50.66, -8.22, $ 14-JUN-1999 51344.0, -33.00, 296.50, 31.473700, 32.0, -50.33, -8.07, $ 15-JUN-1999 51345.0, -33.50, 297.50, 31.474350, 32.0, -49.76, -7.96, $ 16-JUN-1999 51346.0, -33.90, 298.20, 31.474960, 32.0, -49.25, -8.04, $ 17-JUN-1999 51347.0, -34.10, 298.70, 31.475610, 32.0, -49.17, -8.15, $ 18-JUN-1999 51348.0, -34.00, 299.00, 31.476330, 32.0, -49.62, -8.12, $ 19-JUN-1999 51349.0, -33.80, 299.60, 31.477080, 32.0, -50.26, -7.98, $ 20-JUN-1999 51350.0, -33.50, 300.40, 31.477810, 32.0, -50.61, -7.87, $ 21-JUN-1999 51351.0, -33.30, 301.50, 31.478530, 32.0, -50.61, -7.86, $ 22-JUN-1999 51352.0, -33.30, 302.50, 31.479180, 32.0, -50.60, -7.86, $ 23-JUN-1999 51353.0, -33.20, 303.40, 31.479680, 32.0, -50.90, -7.80, $ 24-JUN-1999 51354.0, -33.10, 304.30, 31.480030, 32.0, -51.41, -7.74, $ 25-JUN-1999 51355.0, -33.10, 305.30, 31.480270, 32.0, -51.80, -7.73, $ 26-JUN-1999 51356.0, -33.30, 306.30, 31.480390, 32.0, -51.92, -7.79, $ 27-JUN-1999 51357.0, -33.50, 307.20, 31.480390, 32.0, -51.86, -7.89, $ 28-JUN-1999 51358.0, -33.50, 307.80, 31.480300, 32.0, -51.74, -7.93, $ 29-JUN-1999 51359.0, -33.30, 308.20, 31.480170, 32.0, -51.67, -7.90, $ 30-JUN-1999 51360.0, -33.10, 308.70, 31.480050, 32.0, -51.73, -7.84, $ 1-JUL-1999 51361.0, -32.90, 309.50, 31.480000, 32.0, -51.92, -7.81, $ 2-JUL-1999 51362.0, -32.60, 310.60, 31.480040, 32.0, -52.09, -7.76, $ 3-JUL-1999 51363.0, -32.20, 311.90, 31.480170, 32.0, -52.15, -7.62, $ 4-JUL-1999 51364.0, -31.50, 313.30, 31.480500, 32.0, -52.17, -7.42, $ 5-JUL-1999 51365.0, -30.70, 314.70, 31.481020, 32.0, -52.34, -7.26, $ 6-JUL-1999 51366.0, -29.90, 316.10, 31.481680, 32.0, -52.77, -7.20, $ 7-JUL-1999 51367.0, -29.00, 317.40, 31.482350, 32.0, -53.40, -7.24, $ 8-JUL-1999 51368.0, -28.20, 318.60, 31.482950, 32.0, -54.08, -7.43, $ 9-JUL-1999 51369.0, -27.40, 319.80, 31.483420, 32.0, -54.59, -7.73, $ 10-JUL-1999 51370.0, -26.60, 321.00, 31.483800, 32.0, -54.85, -8.00, $ 11-JUL-1999 51371.0, -25.90, 322.30, 31.484110, 32.0, -54.79, -8.01, $ 12-JUL-1999 51372.0, -25.50, 323.40, 31.484360, 32.0, -54.49, -7.79, $ 13-JUL-1999 51373.0, -25.40, 324.50, 31.484650, 32.0, -54.05, -7.60, $ 14-JUL-1999 51374.0, -25.70, 325.50, 31.485020, 32.0, -53.65, -7.64, $ 15-JUL-1999 51375.0, -26.10, 326.40, 31.485460, 32.0, -53.53, -7.80, $ 16-JUL-1999 51376.0, -26.60, 327.10, 31.485990, 32.0, -53.89, -7.85, $ 17-JUL-1999 51377.0, -26.80, 327.60, 31.486530, 32.0, -54.58, -7.72, $ 18-JUL-1999 51378.0, -26.70, 328.00, 31.487060, 32.0, -55.21, -7.58, $ 19-JUL-1999 51379.0, -26.30, 328.70, 31.487530, 32.0, -55.52, -7.56, $ 20-JUL-1999 51380.0, -25.80, 329.40, 31.487940, 32.0, -55.63, -7.66, $ 21-JUL-1999 51381.0, -25.20, 330.20, 31.488270, 32.0, -55.77, -7.76, $ 22-JUL-1999 51382.0, -24.80, 330.90, 31.488510, 32.0, -55.97, -7.74, $ 23-JUL-1999 51383.0, -24.60, 331.50, 31.488650, 32.0, -56.16, -7.65, $ 24-JUL-1999 51384.0, -24.70, 332.00, 31.488700, 32.0, -56.28, -7.59, $ 25-JUL-1999 51385.0, -24.80, 332.40, 31.488670, 32.0, -56.40, -7.60, $ 26-JUL-1999 51386.0, -24.80, 332.90, 31.488630, 32.0, -56.42, -7.69, $ 27-JUL-1999 51387.0, -24.70, 333.50, 31.488630, 32.0, -56.33, -7.73, $ 28-JUL-1999 51388.0, -24.50, 334.40, 31.488700, 32.0, -56.22, -7.66, $ 29-JUL-1999 51389.0, -24.00, 335.50, 31.488900, 32.0, -56.30, -7.53, $ 30-JUL-1999 51390.0, -23.30, 336.60, 31.489270, 32.0, -56.55, -7.42, $ 31-JUL-1999 51391.0, -22.50, 337.60, 31.489830, 32.0, -56.83, -7.38, $ 1-AUG-1999 51392.0, -21.70, 338.60, 31.490500, 32.0, -56.94, -7.37, $ 2-AUG-1999 51393.0, -20.70, 339.50, 31.491280, 32.0, -56.99, -7.36, $ 3-AUG-1999 51394.0, -19.60, 340.40, 31.492150, 32.0, -57.20, -7.36, $ 4-AUG-1999 51395.0, -18.30, 341.20, 31.492920, 32.0, -57.62, -7.40, $ 5-AUG-1999 51396.0, -17.10, 342.20, 31.493540, 32.0, -58.12, -7.55, $ 6-AUG-1999 51397.0, -16.10, 343.40, 31.493990, 32.0, -58.49, -7.80, $ 7-AUG-1999 51398.0, -15.50, 344.50, 31.494300, 32.0, -58.57, -8.01, $ 8-AUG-1999 51399.0, -15.00, 345.40, 31.494510, 32.0, -58.39, -8.01, $ 9-AUG-1999 51400.0, -14.60, 345.90, 31.494710, 32.0, -58.02, -7.80, $ 10-AUG-1999 51401.0, -14.10, 346.30, 31.494990, 32.0, -57.66, -7.56, $ 11-AUG-1999 51402.0, -13.70, 346.50, 31.495370, 32.0, -57.38, -7.47, $ 12-AUG-1999 51403.0, -13.30, 347.00, 31.495840, 32.0, -57.35, -7.54, $ 13-AUG-1999 51404.0, -13.00, 347.70, 31.496400, 32.0, -57.59, -7.58, $ 14-AUG-1999 51405.0, -12.80, 348.60, 31.497040, 32.0, -58.09, -7.53, $ 15-AUG-1999 51406.0, -12.50, 349.60, 31.497710, 32.0, -58.67, -7.43, $ 16-AUG-1999 51407.0, -12.00, 350.80, 31.498390, 32.0, -59.10, -7.43, $ 17-AUG-1999 51408.0, -11.40, 352.00, 31.499000, 32.0, -59.20, -7.54, $ 18-AUG-1999 51409.0, -10.80, 353.30, 31.499510, 32.0, -59.08, -7.66, $ 19-AUG-1999 51410.0, -10.20, 354.60, 31.499910, 32.0, -58.89, -7.67, $ 20-AUG-1999 51411.0, -9.70, 355.70, 31.500210, 32.0, -58.83, -7.57, $ 21-AUG-1999 51412.0, -9.40, 356.70, 31.500500, 32.0, -58.93, -7.46, $ 22-AUG-1999 51413.0, -9.20, 357.70, 31.500800, 32.0, -59.14, -7.50, $ 23-AUG-1999 51414.0, -9.30, 358.70, 31.501060, 32.0, -59.27, -7.65, $ 24-AUG-1999 51415.0, -9.50, 359.60, 31.501430, 32.0, -59.21, -7.77, $ 25-AUG-1999 51416.0, -9.70, 360.60, 31.501960, 32.0, -59.04, -7.73, $ 26-AUG-1999 51417.0, -9.80, 361.40, 31.502750, 32.0, -58.96, -7.50, $ 27-AUG-1999 51418.0, -9.70, 362.10, 31.503750, 32.0, -59.06, -7.23, $ 28-AUG-1999 51419.0, -9.50, 362.50, 31.504870, 32.0, -59.28, -7.11, $ 29-AUG-1999 51420.0, -9.00, 362.70, 31.506070, 32.0, -59.46, -7.19, $ 30-AUG-1999 51421.0, -8.50, 362.90, 31.507310, 32.0, -59.58, -7.37, $ 31-AUG-1999 51422.0, -8.00, 363.10, 31.508470, 32.0, -59.72, -7.52, $ 1-SEP-1999 51423.0, -7.70, 363.20, 31.509450, 32.0, -59.98, -7.56, $ 2-SEP-1999 51424.0, -7.40, 363.40, 31.510370, 32.0, -60.25, -7.56, $ 3-SEP-1999 51425.0, -6.90, 363.80, 31.511130, 32.0, -60.42, -7.59, $ 4-SEP-1999 51426.0, -6.20, 364.50, 31.511820, 32.0, -60.35, -7.64, $ 5-SEP-1999 51427.0, -5.10, 365.20, 31.512490, 32.0, -60.04, -7.61, $ 6-SEP-1999 51428.0, -3.80, 365.90, 31.513160, 32.0, -59.59, -7.46, $ 7-SEP-1999 51429.0, -2.50, 366.50, 31.513860, 32.0, -59.20, -7.26, $ 8-SEP-1999 51430.0, -1.60, 367.10, 31.514610, 32.0, -59.02, -7.11, $ 9-SEP-1999 51431.0, -1.00, 367.90, 31.515390, 32.0, -59.08, -7.03, $ 10-SEP-1999 51432.0, -0.50, 368.50, 31.516170, 32.0, -59.30, -6.98, $ 11-SEP-1999 51433.0, 0.00, 369.10, 31.516910, 32.0, -59.56, -6.95, $ 12-SEP-1999 51434.0, 0.60, 369.70, 31.517590, 32.0, -59.86, -6.95, $ 13-SEP-1999 51435.0, 1.30, 370.50, 31.518190, 32.0, -60.06, -7.05, $ 14-SEP-1999 51436.0, 2.00, 371.40, 31.518680, 32.0, -59.97, -7.21, $ 15-SEP-1999 51437.0, 2.60, 372.10, 31.519060, 32.0, -59.60, -7.34, $ 16-SEP-1999 51438.0, 3.10, 372.80, 31.519360, 32.0, -59.15, -7.35, $ 17-SEP-1999 51439.0, 3.40, 373.20, 31.519630, 32.0, -58.96, -7.26, $ 18-SEP-1999 51440.0, 3.70, 373.70, 31.519930, 32.0, -59.07, -7.20, $ 19-SEP-1999 51441.0, 3.80, 374.00, 31.520310, 32.0, -59.25, -7.24, $ 20-SEP-1999 51442.0, 4.00, 374.20, 31.520830, 32.0, -59.26, -7.34, $ 21-SEP-1999 51443.0, 4.30, 374.50, 31.521530, 32.0, -59.15, -7.40, $ 22-SEP-1999 51444.0, 4.60, 374.80, 31.522410, 32.0, -59.04, -7.31, $ 23-SEP-1999 51445.0, 4.80, 375.20, 31.523450, 32.0, -58.98, -7.03, $ 24-SEP-1999 51446.0, 4.90, 375.40, 31.524600, 32.0, -58.97, -6.67, $ 25-SEP-1999 51447.0, 4.80, 375.40, 31.525780, 32.0, -59.02, -6.43, $ 26-SEP-1999 51448.0, 4.60, 375.30, 31.526950, 32.0, -59.11, -6.50, $ 27-SEP-1999 51449.0, 4.40, 375.50, 31.528030, 32.0, -59.25, -6.80, $ 28-SEP-1999 51450.0, 4.50, 376.10, 31.528960, 32.0, -59.42, -7.08, $ 29-SEP-1999 51451.0, 4.70, 377.20, 31.529820, 32.0, -59.56, -7.12, $ 30-SEP-1999 51452.0, 5.10, 378.40, 31.530560, 32.0, -59.65, -6.98, $ 1-OCT-1999 51453.0, 5.70, 379.60, 31.531220, 32.0, -59.64, -6.81, $ 2-OCT-1999 51454.0, 6.40, 380.60, 31.531880, 32.0, -59.50, -6.72, $ 3-OCT-1999 51455.0, 7.10, 381.00, 31.532670, 32.0, -59.21, -6.67, $ 4-OCT-1999 51456.0, 7.70, 381.10, 31.533620, 32.0, -58.81, -6.61, $ 5-OCT-1999 51457.0, 8.20, 381.30, 31.534720, 32.0, -58.43, -6.54, $ 6-OCT-1999 51458.0, 8.70, 381.40, 31.535960, 32.0, -58.27, -6.46, $ 7-OCT-1999 51459.0, 9.40, 381.50, 31.537290, 32.0, -58.34, -6.33, $ 8-OCT-1999 51460.0, 10.10, 381.40, 31.538630, 32.0, -58.49, -6.18, $ 9-OCT-1999 51461.0, 11.10, 381.40, 31.539970, 32.0, -58.59, -6.08, $ 10-OCT-1999 51462.0, 12.00, 381.30, 31.541230, 32.0, -58.58, -6.11, $ 11-OCT-1999 51463.0, 12.70, 381.30, 31.542370, 32.0, -58.49, -6.28, $ 12-OCT-1999 51464.0, 13.00, 381.40, 31.543390, 32.0, -58.19, -6.51, $ 13-OCT-1999 51465.0, 12.90, 381.60, 31.544330, 32.0, -57.64, -6.65, $ 14-OCT-1999 51466.0, 12.70, 381.80, 31.545200, 32.0, -57.11, -6.64, $ 15-OCT-1999 51467.0, 12.60, 381.90, 31.545960, 32.0, -56.94, -6.56, $ 16-OCT-1999 51468.0, 12.90, 381.80, 31.546680, 32.0, -57.08, -6.50, $ 17-OCT-1999 51469.0, 13.40, 381.70, 31.547430, 32.0, -57.18, -6.47, $ 18-OCT-1999 51470.0, 14.00, 381.70, 31.548270, 32.0, -57.01, -6.40, $ 19-OCT-1999 51471.0, 14.60, 381.70, 31.549260, 32.0, -56.75, -6.26, $ 20-OCT-1999 51472.0, 15.00, 382.10, 31.550470, 32.0, -56.69, -6.07, $ 21-OCT-1999 51473.0, 15.40, 382.60, 31.551980, 32.0, -56.81, -5.83, $ 22-OCT-1999 51474.0, 15.90, 382.80, 31.553690, 32.0, -56.86, -5.54, $ 23-OCT-1999 51475.0, 16.50, 382.80, 31.555570, 32.0, -56.79, -5.30, $ 24-OCT-1999 51476.0, 17.00, 382.70, 31.557470, 32.0, -56.72, -5.32, $ 25-OCT-1999 51477.0, 17.60, 382.50, 31.559340, 32.0, -56.76, -5.60, $ 26-OCT-1999 51478.0, 18.10, 382.40, 31.561050, 32.0, -56.82, -5.87, $ 27-OCT-1999 51479.0, 18.50, 382.40, 31.562560, 32.0, -56.82, -5.89, $ 28-OCT-1999 51480.0, 18.70, 382.30, 31.563890, 32.0, -56.72, -5.64, $ 29-OCT-1999 51481.0, 19.00, 382.30, 31.565150, 32.0, -56.59, -5.39, $ 30-OCT-1999 51482.0, 19.40, 382.00, 31.566380, 32.0, -56.48, -5.27, $ 31-OCT-1999 51483.0, 20.00, 381.60, 31.567670, 32.0, -56.35, -5.25, $ 1-NOV-1999 51484.0, 20.80, 381.10, 31.569040, 32.0, -56.19, -5.25, $ 2-NOV-1999 51485.0, 21.60, 380.50, 31.570460, 32.0, -56.00, -5.26, $ 3-NOV-1999 51486.0, 22.20, 380.10, 31.571950, 32.0, -55.88, -5.28, $ 4-NOV-1999 51487.0, 22.70, 379.90, 31.573480, 32.0, -55.88, -5.22, $ 5-NOV-1999 51488.0, 23.10, 379.60, 31.574960, 32.0, -55.97, -5.06, $ 6-NOV-1999 51489.0, 23.30, 379.10, 31.576430, 32.0, -56.03, -4.88, $ 7-NOV-1999 51490.0, 23.50, 378.30, 31.577790, 32.0, -55.98, -4.83, $ 8-NOV-1999 51491.0, 23.90, 377.20, 31.579100, 32.0, -55.84, -4.97, $ 9-NOV-1999 51492.0, 24.60, 376.10, 31.580350, 32.0, -55.52, -5.20, $ 10-NOV-1999 51493.0, 25.60, 375.30, 31.581500, 32.0, -55.03, -5.35, $ 11-NOV-1999 51494.0, 26.60, 374.80, 31.582640, 32.0, -54.58, -5.34, $ 12-NOV-1999 51495.0, 27.40, 374.60, 31.583780, 32.0, -54.43, -5.24, $ 13-NOV-1999 51496.0, 27.80, 374.90, 31.584950, 32.0, -54.53, -5.16, $ 14-NOV-1999 51497.0, 27.90, 375.60, 31.586210, 32.0, -54.60, -5.08, $ 15-NOV-1999 51498.0, 28.10, 376.40, 31.587560, 32.0, -54.40, -4.89, $ 16-NOV-1999 51499.0, 28.60, 376.80, 31.589010, 32.0, -54.14, -4.61, $ 17-NOV-1999 51500.0, 29.50, 377.00, 31.590620, 32.0, -54.17, -4.39, $ 18-NOV-1999 51501.0, 30.50, 377.10, 31.592360, 32.0, -54.42, -4.28, $ 19-NOV-1999 51502.0, 31.40, 377.10, 31.594160, 32.0, -54.62, -4.19, $ 20-NOV-1999 51503.0, 32.00, 377.20, 31.595990, 32.0, -54.61, -4.05, $ 21-NOV-1999 51504.0, 32.30, 377.10, 31.597730, 32.0, -54.55, -4.01, $ 22-NOV-1999 51505.0, 32.10, 377.00, 31.599290, 32.0, -54.59, -4.17, $ 23-NOV-1999 51506.0, 31.50, 377.00, 31.600640, 32.0, -54.59, -4.36, $ 24-NOV-1999 51507.0, 30.60, 377.40, 31.601850, 32.0, -54.44, -4.30, $ 25-NOV-1999 51508.0, 30.00, 377.90, 31.602880, 32.0, -54.13, -4.02, $ 26-NOV-1999 51509.0, 29.80, 378.10, 31.603840, 32.0, -53.81, -3.77, $ 27-NOV-1999 51510.0, 30.30, 377.80, 31.604860, 32.0, -53.58, -3.73, $ 28-NOV-1999 51511.0, 31.00, 377.10, 31.605990, 32.0, -53.52, -3.77, $ 29-NOV-1999 51512.0, 32.00, 376.40, 31.607230, 32.0, -53.58, -3.74, $ 30-NOV-1999 51513.0, 32.80, 376.10, 31.608590, 32.0, -53.67, -3.68, $ 1-DEC-1999 51514.0, 33.30, 376.30, 31.609980, 32.0, -53.67, -3.67, $ 2-DEC-1999 51515.0, 33.40, 376.80, 31.611270, 32.0, -53.69, -3.70, $ 3-DEC-1999 51516.0, 33.40, 377.20, 31.612530, 32.0, -53.78, -3.66, $ 4-DEC-1999 51517.0, 33.30, 377.50, 31.613720, 32.0, -53.95, -3.54, $ 5-DEC-1999 51518.0, 33.30, 377.70, 31.614770, 32.0, -54.05, -3.49, $ 6-DEC-1999 51519.0, 33.50, 377.80, 31.615720, 32.0, -53.97, -3.58, $ 7-DEC-1999 51520.0, 33.90, 378.00, 31.616570, 32.0, -53.72, -3.76, $ 8-DEC-1999 51521.0, 34.50, 378.10, 31.617380, 32.0, -53.37, -3.90, $ 9-DEC-1999 51522.0, 35.20, 378.20, 31.618160, 32.0, -53.02, -3.91, $ 10-DEC-1999 51523.0, 35.90, 378.50, 31.619010, 32.0, -52.78, -3.83, $ 11-DEC-1999 51524.0, 36.40, 378.90, 31.619900, 32.0, -52.74, -3.75, $ 12-DEC-1999 51525.0, 36.70, 379.50, 31.620860, 32.0, -52.74, -3.68, $ 13-DEC-1999 51526.0, 37.00, 380.00, 31.621920, 32.0, -52.68, -3.53, $ 14-DEC-1999 51527.0, 37.20, 380.40, 31.623130, 32.0, -52.61, -3.31, $ 15-DEC-1999 51528.0, 37.30, 380.80, 31.624480, 32.0, -52.73, -3.16, $ 16-DEC-1999 51529.0, 37.20, 381.10, 31.625910, 32.0, -53.00, -3.18, $ 17-DEC-1999 51530.0, 37.10, 381.20, 31.627430, 32.0, -53.24, -3.24, $ 18-DEC-1999 51531.0, 36.90, 381.20, 31.628970, 32.0, -53.36, -3.21, $ 19-DEC-1999 51532.0, 36.40, 381.10, 31.630460, 32.0, -53.50, -3.16, $ 20-DEC-1999 51533.0, 35.80, 380.60, 31.631790, 32.0, -53.75, -3.22, $ 21-DEC-1999 51534.0, 35.20, 379.80, 31.632950, 32.0, -53.89, -3.33, $ 22-DEC-1999 51535.0, 35.00, 378.90, 31.634010, 32.0, -53.76, -3.27, $ 23-DEC-1999 51536.0, 35.40, 378.00, 31.635050, 32.0, -53.33, -3.04, $ 24-DEC-1999 51537.0, 36.30, 377.20, 31.636120, 32.0, -52.75, -2.86, $ 25-DEC-1999 51538.0, 37.60, 376.70, 31.637220, 32.0, -52.20, -2.89, $ 26-DEC-1999 51539.0, 38.80, 376.70, 31.638420, 32.0, -51.91, -2.96, $ 27-DEC-1999 51540.0, 39.90, 376.90, 31.639720, 32.0, -51.97, -2.88, $ 28-DEC-1999 51541.0, 40.70, 377.10, 31.641040, 32.0, -52.25, -2.66, $ 29-DEC-1999 51542.0, 41.40, 377.20, 31.642280, 32.0, -52.48, -2.53, $ 30-DEC-1999 51543.0, 41.80, 377.20, 31.643390, 32.0, -52.64, -2.56, $ 31-DEC-1999 51544.0, 42.10, 377.10, 31.644390, 32.0, -52.85, -2.66, $ 1-JAN-2000 51545.0, 42.30, 376.70, 31.645260, 32.0, -53.16, -2.73, $ 2-JAN-2000 51546.0, 42.40, 376.30, 31.646020, 32.0, -53.36, -2.79, $ 3-JAN-2000 51547.0, 42.40, 375.80, 31.646650, 32.0, -53.27, -2.89, $ 4-JAN-2000 51548.0, 42.20, 375.50, 31.647120, 32.0, -52.95, -3.03, $ 5-JAN-2000 51549.0, 42.10, 375.30, 31.647530, 32.0, -52.57, -3.14, $ 6-JAN-2000 51550.0, 41.90, 375.20, 31.647930, 32.0, -52.22, -3.16, $ 7-JAN-2000 51551.0, 41.90, 375.10, 31.648330, 32.0, -51.91, -3.09, $ 8-JAN-2000 51552.0, 42.00, 374.90, 31.648760, 32.0, -51.67, -2.99, $ 9-JAN-2000 51553.0, 42.20, 374.50, 31.649300, 32.0, -51.63, -2.92, $ 10-JAN-2000 51554.0, 42.50, 374.10, 31.649990, 32.0, -51.73, -2.87, $ 11-JAN-2000 51555.0, 42.90, 373.70, 31.650810, 32.0, -51.94, -2.78, $ 12-JAN-2000 51556.0, 43.70, 373.40, 31.651820, 32.0, -52.16, -2.75, $ 13-JAN-2000 51557.0, 44.90, 373.30, 31.652940, 32.0, -52.37, -2.83, $ 14-JAN-2000 51558.0, 46.30, 373.20, 31.654130, 32.0, -52.53, -2.96, $ 15-JAN-2000 51559.0, 47.70, 373.10, 31.655320, 32.0, -52.71, -2.99, $ 16-JAN-2000 51560.0, 48.90, 373.10, 31.656360, 32.0, -52.99, -2.98, $ 17-JAN-2000 51561.0, 50.00, 373.30, 31.657280, 32.0, -53.38, -3.04, $ 18-JAN-2000 51562.0, 50.80, 373.70, 31.658150, 32.0, -53.66, -3.16, $ 19-JAN-2000 51563.0, 51.60, 374.20, 31.658920, 32.0, -53.63, -3.18, $ 20-JAN-2000 51564.0, 52.20, 374.80, 31.659780, 32.0, -53.25, -3.07, $ 21-JAN-2000 51565.0, 52.90, 375.30, 31.660700, 32.0, -52.61, -2.99, $ 22-JAN-2000 51566.0, 53.60, 375.90, 31.661740, 32.0, -51.91, -3.10, $ 23-JAN-2000 51567.0, 54.30, 376.40, 31.662900, 32.0, -51.45, -3.23, $ 24-JAN-2000 51568.0, 55.00, 377.00, 31.664130, 32.0, -51.40, -3.18, $ 25-JAN-2000 51569.0, 55.70, 377.50, 31.665390, 32.0, -51.72, -2.93, $ 26-JAN-2000 51570.0, 56.40, 378.00, 31.666600, 32.0, -52.15, -2.71, $ 27-JAN-2000 51571.0, 57.20, 378.50, 31.667720, 32.0, -52.52, -2.69, $ 28-JAN-2000 51572.0, 57.90, 379.00, 31.668730, 32.0, -52.87, -2.84, $ 29-JAN-2000 51573.0, 58.60, 379.50, 31.669600, 32.0, -53.23, -3.05, $ 30-JAN-2000 51574.0, 59.40, 380.00, 31.670370, 32.0, -53.38, -3.21, $ 31-JAN-2000 51575.0, 60.20, 380.40, 31.671030, 32.0, -53.14, -3.33, $ 1-FEB-2000 51576.0, 61.00, 380.90, 31.671630, 32.0, -52.64, -3.44, $ 2-FEB-2000 51577.0, 61.80, 381.30, 31.672210, 32.0, -52.15, -3.52, $ 3-FEB-2000 51578.0, 62.50, 381.70, 31.672810, 32.0, -51.80, -3.55, $ 4-FEB-2000 51579.0, 63.40, 382.10, 31.673490, 32.0, -51.48, -3.47, $ 5-FEB-2000 51580.0, 64.20, 382.50, 31.674280, 32.0, -51.23, -3.32, $ 6-FEB-2000 51581.0, 65.00, 382.90, 31.675220, 32.0, -51.18, -3.19, $ 7-FEB-2000 51582.0, 65.80, 383.30, 31.676320, 32.0, -51.38, -3.15, $ 8-FEB-2000 51583.0, 66.70, 383.70, 31.677550, 32.0, -51.69, -3.21, $ 9-FEB-2000 51584.0, 67.50, 384.00, 31.678880, 32.0, -51.95, -3.33, $ 10-FEB-2000 51585.0, 68.40, 384.40, 31.680260, 32.0, -52.09, -3.48, $ 11-FEB-2000 51586.0, 69.20, 384.70, 31.681620, 32.0, -52.22, -3.62, $ 12-FEB-2000 51587.0, 70.10, 385.00, 31.682910, 32.0, -52.38, -3.69, $ 13-FEB-2000 51588.0, 71.00, 385.30, 31.684090, 32.0, -52.61, -3.75, $ 14-FEB-2000 51589.0, 71.90, 385.60, 31.685160, 32.0, -52.81, -3.85, $ 15-FEB-2000 51590.0, 72.80, 385.90, 31.686160, 32.0, -52.87, -4.00, $ 16-FEB-2000 51591.0, 73.70, 386.20, 31.687140, 32.0, -52.70, -4.09, $ 17-FEB-2000 51592.0, 74.60, 386.40, 31.688190, 32.0, -52.35, -4.08, $ 18-FEB-2000 51593.0, 75.50, 386.70, 31.689370, 32.0, -51.90, -4.09, $ 19-FEB-2000 51594.0, 76.40, 386.90, 31.690690, 32.0, -51.47, -4.23, $ 20-FEB-2000 51595.0, 77.30, 387.10, 31.692120, 32.0, -51.17, -4.44, $ 21-FEB-2000 51596.0, 78.20, 387.30, 31.693610, 32.0, -51.12, -4.52, $ 22-FEB-2000 51597.0, 79.20, 387.50, 31.695090, 32.0, -51.32, -4.40, $ 23-FEB-2000 51598.0, 80.10, 387.60, 31.696500, 32.0, -51.73, -4.23, $ 24-FEB-2000 51599.0, 81.10, 387.80, 31.697790, 32.0, -52.18, -4.18, $ 25-FEB-2000 51600.0, 82.00, 387.90, 31.698950, 32.0, -52.61, -4.29, $ 26-FEB-2000 51601.0, 83.00, 388.10, 31.699980, 32.0, -52.87, -4.48, $ 27-FEB-2000 51602.0, 83.90, 388.20, 31.700900, 32.0, -52.83, -4.64, $ 28-FEB-2000 51603.0, 84.90, 388.30, 31.701750, 32.0, -52.43, -4.74, $ 29-FEB-2000 51604.0, 85.80, 388.40, 31.702560, 32.0, -51.81, -4.79, $ 1-MAR-2000 51605.0, 86.80, 388.50, 31.703380, 32.0, -51.24, -4.85, $ 2-MAR-2000 51606.0, 87.80, 388.50, 31.704260, 32.0, -50.89, -4.89, $ 3-MAR-2000 51607.0, 88.80, 388.60, 31.705260, 32.0, -50.69, -4.83, $ 4-MAR-2000 51608.0, 89.80, 388.60, 31.706400, 32.0, -50.59, -4.65, $ 5-MAR-2000 51609.0, 90.70, 388.60, 31.707710, 32.0, -50.58, -4.45, $ 6-MAR-2000 51610.0, 91.70, 388.60, 31.709170, 32.0, -50.72, -4.36, $ 7-MAR-2000 51611.0, 92.70, 388.60, 31.710760, 32.0, -50.94, -4.46, $ 8-MAR-2000 51612.0, 93.70, 388.60, 31.712410, 32.0, -51.13, -4.72, $ 9-MAR-2000 51613.0, 94.70, 388.50, 31.714030, 32.0, -51.27, -5.02, $ 10-MAR-2000 51614.0, 95.70, 388.50, 31.715580, 32.0, -51.43, -5.23, $ 11-MAR-2000 51615.0, 96.70, 388.40, 31.717010, 32.0, -51.63, -5.31, $ 12-MAR-2000 51616.0, 97.70, 388.30, 31.718310, 32.0, -51.74, -5.32, $ 13-MAR-2000 51617.0, 98.70, 388.20, 31.719510, 32.0, -51.65, -5.36, $ 14-MAR-2000 51618.0, 99.70, 388.10, 31.720680, 32.0, -51.34, -5.44, $ 15-MAR-2000 51619.0, 100.70, 388.00, 31.721880, 32.0, -50.86, -5.51, $ 16-MAR-2000 51620.0, 101.70, 387.80, 31.723180, 32.0, -50.39, -5.52, $ 17-MAR-2000 51621.0, 102.70, 387.70, 31.724630, 32.0, -50.08, -5.55, $ 18-MAR-2000 51622.0, 103.80, 387.50, 31.726210, 32.0, -50.03, -5.65, $ 19-MAR-2000 51623.0, 104.80, 387.30, 31.727890, 32.0, -50.14, -5.82, $ 20-MAR-2000 51624.0, 105.80, 387.10, 31.729590, 32.0, -50.26, -5.93, $ 21-MAR-2000 51625.0, 106.80, 386.90, 31.731250, 32.0, -50.37, -5.92, $ 22-MAR-2000 51626.0, 107.80, 386.70, 31.732810, 32.0, -50.58, -5.84, $ 23-MAR-2000 51627.0, 108.80, 386.40, 31.734240, 32.0, -50.93, -5.80, $ 24-MAR-2000 51628.0, 109.80, 386.20, 31.735530, 32.0, -51.33, -5.87, $ 25-MAR-2000 51629.0, 110.80, 385.90, 31.736680, 32.0, -51.51, -6.01, $ 26-MAR-2000 51630.0, 111.80, 385.60, 31.737730, 32.0, -51.39, -6.14, $ 27-MAR-2000 51631.0, 112.80, 385.30, 31.738720, 32.0, -50.94, -6.21, $ 28-MAR-2000 51632.0, 113.80, 385.00, 31.739700, 32.0, -50.33, -6.23, $ 29-MAR-2000 51633.0, 114.80, 384.70, 31.740720, 32.0, -49.74, -6.24, $ 30-MAR-2000 51634.0, 115.80, 384.30, 31.741820, 32.0, -49.37, -6.24, $ 31-MAR-2000 51635.0, 116.80, 384.00, 31.743060, 32.0, -49.29, -6.20, $ 1-APR-2000 51636.0, 117.80, 383.60, 31.744450, 32.0, -49.40, -6.09, $ 2-APR-2000 51637.0, 118.80, 383.20, 31.746020, 32.0, -49.56, -5.91, $ 3-APR-2000 51638.0, 119.70, 382.80, 31.747730, 32.0, -49.66, -5.77, $ 4-APR-2000 51639.0, 120.70, 382.40, 31.749530, 32.0, -49.76, -5.80, $ 5-APR-2000 51640.0, 121.70, 382.00, 31.751330, 32.0, -49.90, -6.08, $ 6-APR-2000 51641.0, 122.70, 381.50, 31.753070, 32.0, -50.13, -6.50, $ 7-APR-2000 51642.0, 123.60, 381.00, 31.754660, 32.0, -50.41, -6.83, $ 8-APR-2000 51643.0, 124.60, 380.60, 31.756100, 32.0, -50.62, -6.90, $ 9-APR-2000 51644.0, 125.50, 380.10, 31.757400, 32.0, -50.66, -6.79, $ 10-APR-2000 51645.0, 126.50, 379.60, 31.758630, 32.0, -50.46, -6.64, $ 11-APR-2000 51646.0, 127.40, 379.10, 31.759860, 32.0, -50.05, -6.58, $ 12-APR-2000 51647.0, 128.40, 378.50, 31.761150, 32.0, -49.52, -6.59, $ 13-APR-2000 $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ Quasi-Stellar Radio sources: $ $ Since NEAR uses no VLBI data types, there is no list of quasars. $ QNUMBR(1) = 25*0, QNAME(1) = 25*' ', QRA(1) = 25*0.0D0, QDEC(1) = 25*0.0D0, $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ ACCUME $ $ ACCUME accumulates all the partial derivatives from REGRES to form $ an information matrix consisting of state parameters & parameters $ specified in 'YPARAM' and 'RANDOM'. $ ACUPRT(1) = .TRUE., $ ACCUME print flags. ACUPRT(2) = .TRUE., ACUPRT(3) = 8*.FALSE., YPARAM(1) = 994*' ', $ Bias parameters (' ' = all parameters on regres) $ $ Note: YPARAM allows a parameter to be both random and bias. $ $ Instead of using a priori covariances, the ACCUME information array may $ be initialized from a previous ACCUME file: $ SCOLDR = 1.0D0, $ Input ACCUME file scale factor. $ $ Stochastic & sequential estimation inputs: $ COVARY = 100*0, $ Batch numbers to be smoothed. COVOPT = 0, $ Calculate smoothed covariance at batch 1. BCHTIM(1) = ' ', $ First batch will be at PV File epoch. BCHLEN(1) = ' ', $ ' ' => run in single batch mode. OUTBCH(1) = 1, $ List of batch #'s for which an information $ array should be output to ACCUME. $ RANDOM(1) = 20*' ', $ Specify the stochastic parameters. PSIGMA(1,1) = 2000*0.0D0, $ Sigmas of the stochastics. DAPW(1) = 20*0.0D0, $ Variances of the stochastics. MTAU(1) = 20*0.0D0, $ Correlation times in days. MTAUC(1) = 20*' ', NAP(1) = 100*0, NPSIG(1) = 100*0, $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ SOLVE $ $ SOLVE uses the information matrix to estimate parameters while $ considering the effects of other parameters, and generates an $ epoch state covariance. $ SVD = .FALSE., $ TRUE => SVD, Singular Value Decomposition. $ FALSE => SRIF, Square Root Information Filter. EPS2 = 1.0D-30, $ Tolerance for Singular Value Decomposition. SALENT = .TRUE., $ Write salient information file (90). SMOFIL = .FALSE., $ No SMOOTH files are written. SMOSOL = 0, $ SOLUTN(1) = 25*0, $ 0's => "SOLVE" uses the last batch from accume $ to determine a solution. BATCH = 0, $ Initialize batch, solution & iteration numbers. SOLNO = 0, ITNO = 0, $ EST( 1) = 200*' ', CON( 1) = 200*' ', $ EST( 1) = 'X','Y','Z','DX','DY','DZ', $ APVNOM( 1) = 200*.TRUE., $ The a priori values for the EST parameters $ are not from the arrays APVALS or APVALi. $ APVALS( 1) = 200*0.0D0, $ A priori values of the parameters in APNAMS. APVAL1( 1) = 50*0.0D0, $ '' APNAM1. APVAL2( 1) = 50*0.0D0, $ '' APNAM2. APVAL3( 1) = 50*0.0D0, $ '' APNAM3. APVAL4( 1) = 50*0.0D0, $ '' APNAM4. APVAL5( 1) = 50*0.0D0, $ '' APNAM5. $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ a-priori covariances: $ $ Names of the parameters for which apriori covariances exist. $ These names correspond to values in the APQ arrays. $ APNAMS( 1) = 200*' ', APNAM1( 1) = 50*' ', APNAM2( 1) = 50*' ', APNAM3( 1) = 50*' ', APNAM4( 1) = 50*' ', APNAM5( 1) = 50*' ', $ $ Initialize the apriori covariances, APQ. $ APQCOV = .TRUE., $ APQ contains apriori covariances. $ APQ(1,1) = 40000*0.0D0, APQ1(1,1) = 2500*0.0D0, APQ2(1,1) = 2500*0.0D0, APQ3(1,1) = 2500*0.0D0, APQ4(1,1) = 2500*0.0D0, APQ5(1,1) = 2500*0.0D0, $ SCAPQ(1) = 200*1.0D0, $ APQ array scale factors. SCAPQ1(1) = 50*1.0D0, SCAPQ2(1) = 50*1.0D0, SCAPQ3(1) = 50*1.0D0, SCAPQ4(1) = 50*1.0D0, SCAPQ5(1) = 50*1.0D0, $ $ Parameter names corresponding DIAGQ or APQ values: $ APNAMS( 1) = 'X','Y','Z','DX','DY','DZ', $ APNAM1( 1) = 'SPEC01','DIFF01','AREA01', 'SPEC02','DIFF02','AREA02', APNAM1( 7) = 'DIFF03','AREA03', 'DIFF04','AREA04', 'DIFF05','AREA05', APNAM1(13) = 'NUF','NUB', $ APNAM2( 1) = 'GM3','GMM','GM9','J302','J402', APNAM2( 6) = 'ATAR','ATAX','ATAY', 'BTAR','BTAX','BTAY', 'CTAR','CTAX','CTAY', APNAM2(15) = 'DRB04','STB04','F004','ALP004','DLT004', 'DRB05','STB05','F005','ALP005','DLT005', 'DRB06','STB06','F006','ALP006','DLT006', 'DRB07','STB07','F007','ALP007','DLT007', 'DRB08','STB08','F008','ALP008','DLT008', $ APNAM3( 1) = 'TROPD1','TROPW1','IONOD1','IONON1', 'TROPD4','TROPW4','IONOD4','IONON4', 'TROPD6','TROPW6','IONOD6','IONON6', APNAM3(13) = 'RC01','RC02','RC03', $ $ APNAM4 parameter names are included with station locations. $ $ APNAM5 parameter names are included with the stn-loc & ephemeris covariance. $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ a-priori sigmas squared: $ DIAGQ( 1) = $ State uncertainties: 1.0D02, 1.0D02, 1.0D02, $ position (km) 1.0D12, 1.0D12, 1.0D12, $ velocity (km/s) $ DIAGQ1( 1) = $ SRP uncertainties: 4.0000D-4, 0.0289D-4, 0.0025D0, 4.0000D-4, 0.0289D-4, 0.0025D0, DIAGQ1( 7) = 8.5849D-4, 0.0025D0, 8.5849D-4, 0.0025D0, 8.5849D-4, 0.0100D0, DIAGQ1(13) = 8.5849D-4, 8.5849D-4, $ DIAGQ2( 1) = $ Gravity uncertainties: 2.500000D-3, $ Earth GM 1.476225D-6, $ Moon GM 8.1D-07, $ EROS GM (.0009^2 = 100%) 1.000000D-16, $ Earth J2 0.181162896275495D-15, $ Mars J2 (MARS50C) DIAGQ2( 6) = $ Non-gravity uncertainties: 9.0D-24, 9.0D-24, 9.0D-24, $ constant (km/s2) 1.0D-26, 1.0D-26, 1.0D-26, $ linear (km/s3) 1.0D-28, 1.0D-28, 1.0D-28, $ quadratic (km/s4) DIAGQ2(15) = $ Maneuver uncertainties: 6.2500D0, $ start (s) 3.6000D3, $ duration (s) 3.6169D-4, $ thrust (N) 1.7424D0, $ RA degrees 1.7424D0, $ DEC degrees DIAGQ2(20) = 6.2500D0, 3.6000D3, 3.6169D-4, 1.7424D0, 1.7424D0, 6.2500D0, 3.6000D3, 3.6169D-4, 1.7424D0, 1.7424D0, 6.2500D0, 3.6000D3, 3.6169D-4, 1.7424D0, 1.7424D0, $ DIAGQ3( 1) = $ Media uncertainties: 0.0001D0, 0.0016D0, $ dry & wet troposphere 0.5625D0, 0.0225D0, $ day & night ionosphere 0.0001D0, 0.0016D0, 0.5625D0, 0.0225D0, 0.0001D0, 0.0016D0, 0.5625D0, 0.0225D0, DIAGQ3(13) = 2.25D2, 2.25D2, 2.25D2, $ SRA biases (15 meters). $ $ This file contains a covariance matrix for DSN stations $ as documented in IOM 335.1-96-024, 21 October 1996. $ The positions of the 70m, HEF, and 34m standard have been $ determined by VLBI measurements, while the other stations $ have been tied in through a combination of GPS and conventional $ surveys, as described in IOM 335.1-95-027, 16 October 1995 $ and TDA progress Report 42-128, February 1997 $ http://edms-www.jpl.nasa.gov/tda/progress_report/42-128/128F.pdf $ This covariance reflects the appropriate relative uncertainties. $ Note that DSS 34 and DSS 54 uncertaintes are large since $ the definitive surveys are yet to be completed. $ An overall orientation uncertainty of 5 nanoradian is included $ to account for imperfections in relating the DSN stations $ to the IERS Earth orientation series (UT1 and polar motion). $ $ The uncertainty in Earth orientation for real-time solutions $ is not included in this covariance. That uncertainty $ should be accounted for separately with the parameters $ 'UT1','XPOLE','YPOLE'. $ $ Modified 25 Nov 1996; DSS 34 survey added $ Modified 13 May 1997; DSS 54 survey added $ APNAM4(1) = 'CU12 ', 'LO12 ', 'CV12 ', 'CU13 ', 'LO13 ', 'CV13 ', 'CU14 ', 'LO14 ', 'CV14 ', 'CU15 ', 'LO15 ', 'CV15 ', 'CU16 ', 'LO16 ', 'CV16 ', 'CU17 ', 'LO17 ', 'CV17 ', 'CU23 ', 'LO23 ', 'CV23 ', 'CU24 ', 'LO24 ', 'CV24 ', 'CU25 ', 'LO25 ', 'CV25 ', 'CU26 ', 'LO26 ', 'CV26 ', 'CU27 ', 'LO27 ', 'CV27 ', 'CU28 ', 'LO28 ', 'CV28 ', 'CU33 ', 'LO33 ', 'CV33 ', 'CU34 ', 'LO34 ', 'CV34 ', 'CU42 ', 'LO42 ', 'CV42 ', 'CU43 ', 'LO43 ', 'CV43 ', 'CU45 ', 'LO45 ', APNAM5(1) = 'CV45 ', 'CU46 ', 'LO46 ', 'CV46 ', 'CU53 ', 'LO53 ', 'CV53 ', 'CU54 ', 'LO54 ', 'CV54 ', 'CU61 ', 'LO61 ', 'CV61 ', 'CU63 ', 'LO63 ', 'CV63 ', 'CU65 ', 'LO65 ', 'CV65 ', 'CU66 ', 'LO66 ', 'CV66 ', APQ4(1, 1) = 9.541631906369D-10, APQ4(1, 2) = 1.607196046550D-12, 1.867404590425D-13, APQ4(1, 3) = -2.189946488273D-10, 4.081260243988D-13, 1.338311904633D-09, APQ4(1, 4) = 4.337957260149D-10, 3.832707404823D-13, -4.728817061803D-10, 2.407022960939D-09, APQ4(1, 5) = 3.368946976474D-13, 1.353779460550D-13, -4.446253899846D-13, 3.772975383008D-13, 2.443222622066D-13, APQ4(1, 6) = -4.699127504347D-10, -4.121271879039D-13, 8.219851266366D-10, 2.891654266574D-10, -4.266233883491D-13, 2.260617870176D-09, APQ4(1, 7) = 4.802709086880D-10, 2.791953433266D-13, -4.468318590969D-10, 4.264699353114D-10, 3.377689709191D-13, -4.766954782324D-10, 5.230734672599D-10, APQ4(1, 8) = 2.261455924981D-13, 1.364909062508D-13, -4.566904201606D-13, 3.579649622893D-13, 1.350789988838D-13, -4.463312809064D-13, 4.093978910466D-13, 1.431741958675D-13, APQ4(1, 9) = -4.498956054304D-10, -3.934071927372D-13, 8.397856466612D-10, -4.815747749611D-10, -4.705519335829D-13, 8.137279891861D-10, -4.421678461213D-10, -3.919996527954D-13, 9.237422751864D-10, APQ4(1,10) = 4.337957265111D-10, 3.832707409231D-13, -4.728817064872D-10, 4.445068731704D-10, 3.772975387188D-13, -4.665364309743D-10, 4.264699357882D-10, 3.579649626545D-13, -4.815747752913D-10, 4.445068736902D-10, APQ4(1,11) = 3.368946979506D-13, 1.353779461768D-13, -4.446253903848D-13, 3.772975386403D-13, 1.352349885968D-13, -4.266233887331D-13, 3.377689712231D-13, 1.350789990054D-13, -4.705519340064D-13, 3.772975390584D-13, 1.352349887185D-13, APQ4(1,12) = -4.699127507824D-10, -4.121271882067D-13, 8.219851274609D-10, -4.665364310154D-10, -4.266233886772D-13, 8.231339663556D-10, -4.766954785953D-10, -4.463312812775D-13, 8.137279899919D-10, -4.665364313090D-10, -4.266233890612D-13, 8.231339671863D-10, APQ4(1,13) = 4.337957247815D-10, 3.832707393818D-13, -4.728817059330D-10, 4.445068713337D-10, 3.772975372915D-13, -4.665364304798D-10, 4.264699341510D-10, 3.579649614789D-13, -4.815747746264D-10, 4.445068718535D-10, 3.772975376310D-13, -4.665364308146D-10, 7.587567077566D-09, APQ4(1,14) = 3.368946970747D-13, 1.353779458249D-13, -4.446253892287D-13, 3.772975376594D-13, 1.352349882452D-13, -4.266233876238D-13, 3.377689703449D-13, 1.350789986542D-13, -4.705519327830D-13, 3.772975380774D-13, 1.352349883669D-13, -4.266233879520D-13, 3.772975366501D-13, 2.685638780747D-13, APQ4(1,15) = -4.699127499886D-10, -4.121271875226D-13, 8.219851248434D-10, -4.665364302868D-10, -4.266233878855D-13, 8.231339637044D-10, -4.766954777317D-10, -4.463312802912D-13, 8.137279874585D-10, -4.665364305803D-10, -4.266233882695D-13, 8.231339645350D-10, 3.831517849570D-09, -4.266233871602D-13, 4.980073648585D-09, APQ4(1,16) = 4.337957247815D-10, 3.832707393818D-13, -4.728817059330D-10, 4.445068713337D-10, 3.772975372915D-13, -4.665364304798D-10, 4.264699341510D-10, 3.579649614789D-13, -4.815747746264D-10, 4.445068718535D-10, 3.772975376310D-13, -4.665364308146D-10, 6.445068669496D-10, 3.772975366500D-13, -4.665364318051D-10, 7.587567077566D-09, APQ4(1,17) = 3.368946970747D-13, 1.353779458249D-13, -4.446253892287D-13, 3.772975376594D-13, 1.352349882452D-13, -4.266233876238D-13, 3.377689703449D-13, 1.350789986542D-13, -4.705519327830D-13, 3.772975380774D-13, 1.352349883669D-13, -4.266233879520D-13, 3.772975366501D-13, 1.594766043431D-13, -4.266233871602D-13, 3.772975366500D-13, 2.685638780747D-13, APQ4(1,18) = -4.699127499886D-10, -4.121271875226D-13, 8.219851248434D-10, -4.665364302868D-10, -4.266233878855D-13, 8.231339637044D-10, -4.766954777317D-10, -4.463312802912D-13, 8.137279874585D-10, -4.665364305803D-10, -4.266233882695D-13, 8.231339645350D-10, -4.665364318051D-10, -4.266233871602D-13, 1.023133960011D-09, 3.831517849570D-09, -4.266233871602D-13, 4.980073648585D-09, APQ4(1,19) = 4.337957250418D-10, 3.832707396117D-13, -4.728817062167D-10, 4.445068716004D-10, 3.772975375178D-13, -4.665364307598D-10, 4.264699344069D-10, 3.579649616937D-13, -4.815747749154D-10, 4.445068721202D-10, 3.772975378574D-13, -4.665364310945D-10, 5.445068687249D-10, 3.772975368764D-13, -4.665364312254D-10, 5.445068687249D-10, 3.772975368764D-13, -4.665364312254D-10, 7.487567079668D-09, APQ4(1,20) = 3.368946972768D-13, 1.353779459061D-13, -4.446253894955D-13, 3.772975378857D-13, 1.352349883263D-13, -4.266233878798D-13, 3.377689705475D-13, 1.350789987352D-13, -4.705519330653D-13, 3.772975383038D-13, 1.352349884481D-13, -4.266233882079D-13, 3.772975368764D-13, 1.473557962573D-13, -4.266233874162D-13, 3.772975368764D-13, 1.473557962573D-13, -4.266233874162D-13, 3.772975371028D-13, 2.564430700773D-13, APQ4(1,21) = -4.699127502706D-10, -4.121271877699D-13, 8.219851253366D-10, -4.665364305667D-10, -4.266233881415D-13, 8.231339641982D-10, -4.766954780177D-10, -4.463312805590D-13, 8.137279879467D-10, -4.665364308603D-10, -4.266233885254D-13, 8.231339650289D-10, -4.665364312254D-10, -4.266233874162D-13, 9.231339614163D-10, -4.665364312254D-10, -4.266233874162D-13, 9.231339614163D-10, 3.831517849870D-09, -4.266233876722D-13, 4.880073650544D-09, APQ4(1,22) = 4.337957247815D-10, 3.832707393818D-13, -4.728817059330D-10, 4.445068713337D-10, 3.772975372915D-13, -4.665364304798D-10, 4.264699341510D-10, 3.579649614789D-13, -4.815747746264D-10, 4.445068718535D-10, 3.772975376310D-13, -4.665364308146D-10, 6.445068669496D-10, 3.772975366501D-13, -4.665364318051D-10, 6.445068669496D-10, 3.772975366501D-13, -4.665364318051D-10, 5.445068687249D-10, 3.772975368764D-13, -4.665364312254D-10, 7.587567077566D-09, APQ4(1,23) = 3.368946970747D-13, 1.353779458249D-13, -4.446253892287D-13, 3.772975376594D-13, 1.352349882452D-13, -4.266233876238D-13, 3.377689703449D-13, 1.350789986542D-13, -4.705519327830D-13, 3.772975380774D-13, 1.352349883669D-13, -4.266233879520D-13, 3.772975366501D-13, 1.594766043431D-13, -4.266233871602D-13, 3.772975366501D-13, 1.594766043431D-13, -4.266233871602D-13, 3.772975368764D-13, 1.473557962573D-13, -4.266233874162D-13, 3.772975366501D-13, 2.685638780747D-13, APQ4(1,24) = -4.699127499886D-10, -4.121271875226D-13, 8.219851248434D-10, -4.665364302868D-10, -4.266233878855D-13, 8.231339637044D-10, -4.766954777317D-10, -4.463312802912D-13, 8.137279874585D-10, -4.665364305803D-10, -4.266233882695D-13, 8.231339645350D-10, -4.665364318051D-10, -4.266233871602D-13, 1.023133960011D-09, -4.665364318051D-10, -4.266233871602D-13, 1.023133960011D-09, -4.665364312254D-10, -4.266233874162D-13, 9.231339614163D-10, 3.831517849570D-09, -4.266233871602D-13, 4.980073648585D-09, APQ4(1,25) = 4.337957247815D-10, 3.832707393818D-13, -4.728817059330D-10, 4.445068713337D-10, 3.772975372915D-13, -4.665364304798D-10, 4.264699341510D-10, 3.579649614789D-13, -4.815747746264D-10, 4.445068718535D-10, 3.772975376310D-13, -4.665364308146D-10, 6.445068669496D-10, 3.772975366501D-13, -4.665364318051D-10, 6.445068669496D-10, 3.772975366501D-13, -4.665364318051D-10, 5.445068687249D-10, 3.772975368764D-13, -4.665364312254D-10, 6.445068669496D-10, 3.772975366501D-13, -4.665364318051D-10, 7.587567077566D-09, APQ4(1,26) = 3.368946970747D-13, 1.353779458249D-13, -4.446253892287D-13, 3.772975376594D-13, 1.352349882452D-13, -4.266233876238D-13, 3.377689703449D-13, 1.350789986542D-13, -4.705519327830D-13, 3.772975380774D-13, 1.352349883669D-13, -4.266233879520D-13, 3.772975366501D-13, 1.594766043431D-13, -4.266233871602D-13, 3.772975366501D-13, 1.594766043431D-13, -4.266233871602D-13, 3.772975368764D-13, 1.473557962573D-13, -4.266233874162D-13, 3.772975366501D-13, 1.594766043431D-13, -4.266233871602D-13, 3.772975366501D-13, 2.685638780747D-13, APQ4(1,27) = -4.699127499886D-10, -4.121271875226D-13, 8.219851248434D-10, -4.665364302868D-10, -4.266233878855D-13, 8.231339637044D-10, -4.766954777317D-10, -4.463312802912D-13, 8.137279874585D-10, -4.665364305803D-10, -4.266233882695D-13, 8.231339645350D-10, -4.665364318051D-10, -4.266233871602D-13, 1.023133960011D-09, -4.665364318051D-10, -4.266233871602D-13, 1.023133960011D-09, -4.665364312254D-10, -4.266233874162D-13, 9.231339614163D-10, -4.665364318051D-10, -4.266233871602D-13, 1.023133960011D-09, 3.831517849570D-09, -4.266233871602D-13, 4.980073648585D-09, APQ4(1,28) = 4.337957247815D-10, 3.832707393818D-13, -4.728817059330D-10, 4.445068713337D-10, 3.772975372915D-13, -4.665364304798D-10, 4.264699341510D-10, 3.579649614789D-13, -4.815747746264D-10, 4.445068718535D-10, 3.772975376310D-13, -4.665364308146D-10, 6.445068669496D-10, 3.772975366501D-13, -4.665364318051D-10, 6.445068669496D-10, 3.772975366501D-13, -4.665364318051D-10, 5.445068687249D-10, 3.772975368764D-13, -4.665364312254D-10, 6.445068669496D-10, 3.772975366501D-13, -4.665364318051D-10, 6.445068669496D-10, 3.772975366501D-13, -4.665364318051D-10, 7.587567077566D-09, APQ4(1,29) = 3.368946970747D-13, 1.353779458249D-13, -4.446253892287D-13, 3.772975376594D-13, 1.352349882452D-13, -4.266233876238D-13, 3.377689703449D-13, 1.350789986542D-13, -4.705519327830D-13, 3.772975380774D-13, 1.352349883669D-13, -4.266233879520D-13, 3.772975366501D-13, 1.594766043431D-13, -4.266233871602D-13, 3.772975366501D-13, 1.594766043431D-13, -4.266233871602D-13, 3.772975368764D-13, 1.473557962573D-13, -4.266233874162D-13, 3.772975366501D-13, 1.594766043431D-13, -4.266233871602D-13, 3.772975366501D-13, 1.594766043431D-13, -4.266233871602D-13, 3.772975366501D-13, 2.685638780747D-13, APQ4(1,30) = -4.699127499886D-10, -4.121271875226D-13, 8.219851248434D-10, -4.665364302868D-10, -4.266233878855D-13, 8.231339637044D-10, -4.766954777317D-10, -4.463312802912D-13, 8.137279874585D-10, -4.665364305803D-10, -4.266233882695D-13, 8.231339645350D-10, -4.665364318051D-10, -4.266233871602D-13, 1.023133960011D-09, -4.665364318051D-10, -4.266233871602D-13, 1.023133960011D-09, -4.665364312254D-10, -4.266233874162D-13, 9.231339614163D-10, -4.665364318051D-10, -4.266233871602D-13, 1.023133960011D-09, -4.665364318051D-10, -4.266233871602D-13, 1.023133960011D-09, 3.831517849570D-09, -4.266233871602D-13, 4.980073648585D-09, APQ4(1,31) = 4.337957249117D-10, 3.832707394968D-13, -4.728817060748D-10, 4.445068714671D-10, 3.772975374046D-13, -4.665364306198D-10, 4.264699342790D-10, 3.579649615863D-13, -4.815747747709D-10, 4.445068719869D-10, 3.772975377442D-13, -4.665364309545D-10, 5.445068685616D-10, 3.772975367632D-13, -4.665364310855D-10, 5.445068685616D-10, 3.772975367632D-13, -4.665364310855D-10, 5.445068688883D-10, 3.772975369896D-13, -4.665364313654D-10, 5.445068685616D-10, 3.772975367632D-13, -4.665364310855D-10, 5.445068685616D-10, 3.772975367632D-13, -4.665364310855D-10, 5.445068685616D-10, 3.772975367632D-13, -4.665364310855D-10, 7.587567077922D-09, APQ4(1,32) = 3.368946971757D-13, 1.353779458655D-13, -4.446253893621D-13, 3.772975377725D-13, 1.352349882858D-13, -4.266233877518D-13, 3.377689704462D-13, 1.350789986947D-13, -4.705519329242D-13, 3.772975381906D-13, 1.352349884075D-13, -4.266233880800D-13, 3.772975367632D-13, 1.473557962131D-13, -4.266233872882D-13, 3.772975367632D-13, 1.473557962131D-13, -4.266233872882D-13, 3.772975369896D-13, 1.473557963015D-13, -4.266233875442D-13, 3.772975367632D-13, 1.473557962131D-13, -4.266233872882D-13, 3.772975367632D-13, 1.473557962131D-13, -4.266233872882D-13, 3.772975367632D-13, 1.473557962131D-13, -4.266233872882D-13, 3.772975368764D-13, 2.685638781667D-13, APQ4(1,33) = -4.699127501296D-10, -4.121271876463D-13, 8.219851250900D-10, -4.665364304267D-10, -4.266233880135D-13, 8.231339639513D-10, -4.766954778747D-10, -4.463312804251D-13, 8.137279877026D-10, -4.665364307203D-10, -4.266233883974D-13, 8.231339647820D-10, -4.665364310855D-10, -4.266233872882D-13, 9.231339611394D-10, -4.665364310855D-10, -4.266233872882D-13, 9.231339611394D-10, -4.665364313654D-10, -4.266233875442D-13, 9.231339616932D-10, -4.665364310855D-10, -4.266233872882D-13, 9.231339611394D-10, -4.665364310855D-10, -4.266233872882D-13, 9.231339611394D-10, -4.665364310855D-10, -4.266233872882D-13, 9.231339611394D-10, 3.831517849290D-09, -4.266233874162D-13, 4.980073649169D-09, APQ4(1,34) = 4.337957249117D-10, 3.832707394968D-13, -4.728817060748D-10, 4.445068714671D-10, 3.772975374046D-13, -4.665364306198D-10, 4.264699342790D-10, 3.579649615863D-13, -4.815747747709D-10, 4.445068719869D-10, 3.772975377442D-13, -4.665364309545D-10, 5.445068685616D-10, 3.772975367632D-13, -4.665364310855D-10, 5.445068685616D-10, 3.772975367632D-13, -4.665364310855D-10, 5.445068688883D-10, 3.772975369896D-13, -4.665364313654D-10, 5.445068685616D-10, 3.772975367632D-13, -4.665364310855D-10, 5.445068685616D-10, 3.772975367632D-13, -4.665364310855D-10, 5.445068685616D-10, 3.772975367632D-13, -4.665364310855D-10, 6.445068673063D-10, 3.772975368764D-13, -4.665364320850D-10, 7.587567077922D-09, APQ4(1,35) = 3.368946971757D-13, 1.353779458655D-13, -4.446253893621D-13, 3.772975377725D-13, 1.352349882858D-13, -4.266233877518D-13, 3.377689704462D-13, 1.350789986947D-13, -4.705519329242D-13, 3.772975381906D-13, 1.352349884075D-13, -4.266233880800D-13, 3.772975367632D-13, 1.473557962131D-13, -4.266233872882D-13, 3.772975367632D-13, 1.473557962131D-13, -4.266233872882D-13, 3.772975369896D-13, 1.473557963015D-13, -4.266233875442D-13, 3.772975367632D-13, 1.473557962131D-13, -4.266233872882D-13, 3.772975367632D-13, 1.473557962131D-13, -4.266233872882D-13, 3.772975367632D-13, 1.473557962131D-13, -4.266233872882D-13, 3.772975368764D-13, 1.594766044352D-13, -4.266233874162D-13, 3.772975368764D-13, 2.685638781667D-13, APQ4(1,36) = -4.699127501296D-10, -4.121271876463D-13, 8.219851250900D-10, -4.665364304267D-10, -4.266233880135D-13, 8.231339639513D-10, -4.766954778747D-10, -4.463312804251D-13, 8.137279877026D-10, -4.665364307203D-10, -4.266233883974D-13, 8.231339647820D-10, -4.665364310855D-10, -4.266233872882D-13, 9.231339611394D-10, -4.665364310855D-10, -4.266233872882D-13, 9.231339611394D-10, -4.665364313654D-10, -4.266233875442D-13, 9.231339616932D-10, -4.665364310855D-10, -4.266233872882D-13, 9.231339611394D-10, -4.665364310855D-10, -4.266233872882D-13, 9.231339611394D-10, -4.665364310855D-10, -4.266233872882D-13, 9.231339611394D-10, -4.665364320850D-10, -4.266233874162D-13, 1.023133960595D-09, 3.831517849290D-09, -4.266233874162D-13, 4.980073649169D-09, APQ4(1,37) = -1.340671981463D-11, 3.761646769692D-12, -4.882517868276D-11, -3.052363044987D-11, 3.766526881291D-12, -5.908496903096D-11, -8.480975227135D-12, 3.787933645294D-12, -4.160345559616D-11, -3.052363055443D-11, 3.766526884681D-12, -5.908496913896D-11, -3.052363003666D-11, 3.766526874888D-12, -5.908496867353D-11, -3.052363003666D-11, 3.766526874888D-12, -5.908496867353D-11, -3.052363005497D-11, 3.766526877148D-12, -5.908496870898D-11, -3.052363003666D-11, 3.766526874888D-12, -5.908496867353D-11, -3.052363003666D-11, 3.766526874888D-12, -5.908496867353D-11, -3.052363003666D-11, 3.766526874888D-12, -5.908496867353D-11, -3.052363004582D-11, 3.766526876018D-12, -5.908496869125D-11, -3.052363004582D-11, 3.766526876018D-12, -5.908496869125D-11, 7.691288862063D-09, APQ4(1,38) = -3.985290805550D-12, 8.234059229314D-14, 5.410040483586D-12, -4.124940430015D-12, 8.233321636333D-14, 5.322610720858D-12, -3.919288524333D-12, 8.262683542309D-14, 5.498362722389D-12, -4.124940434088D-12, 8.233321643743D-14, 5.322610725392D-12, -4.124940421313D-12, 8.233321622337D-14, 5.322610713011D-12, -4.124940421313D-12, 8.233321622337D-14, 5.322610713011D-12, -4.124940423788D-12, 8.233321627277D-14, 5.322610716205D-12, -4.124940421313D-12, 8.233321622337D-14, 5.322610713011D-12, -4.124940421313D-12, 8.233321622337D-14, 5.322610713011D-12, -4.124940421313D-12, 8.233321622337D-14, 5.322610713011D-12, -4.124940422550D-12, 8.233321624807D-14, 5.322610714608D-12, -4.124940422550D-12, 8.233321624807D-14, 5.322610714608D-12, 1.142494346900D-12, 2.635116861455D-13, APQ4(1,39) = 6.719354433292D-11, 5.382005930526D-12, -6.510666582219D-11, 7.577209575936D-11, 5.406907717006D-12, -5.831055444075D-11, 6.583766077994D-11, 5.402167329998D-12, -6.565227020088D-11, 7.577209586399D-11, 5.406907721872D-12, -5.831055446731D-11, 7.577209545971D-11, 5.406907707814D-12, -5.831055446312D-11, 7.577209545971D-11, 5.406907707814D-12, -5.831055446312D-11, 7.577209550518D-11, 5.406907711059D-12, -5.831055449811D-11, 7.577209545971D-11, 5.406907707814D-12, -5.831055446312D-11, 7.577209545971D-11, 5.406907707814D-12, -5.831055446312D-11, 7.577209545971D-11, 5.406907707814D-12, -5.831055446312D-11, 7.577209548245D-11, 5.406907709437D-12, -5.831055448061D-11, 7.577209548245D-11, 5.406907709437D-12, -5.831055448061D-11, -3.896216864708D-09, -7.367662529443D-13, 4.886232456000D-09, APQ4(1,40) = -1.340671981329D-11, 3.761646769316D-12, -4.882517867788D-11, -3.052363044682D-11, 3.766526880914D-12, -5.908496902505D-11, -8.480975226287D-12, 3.787933644915D-12, -4.160345559200D-11, -3.052363055138D-11, 3.766526884304D-12, -5.908496913305D-11, -3.052363003361D-11, 3.766526874511D-12, -5.908496866762D-11, -3.052363003361D-11, 3.766526874511D-12, -5.908496866762D-11, -3.052363005192D-11, 3.766526876771D-12, -5.908496870307D-11, -3.052363003361D-11, 3.766526874511D-12, -5.908496866762D-11, -3.052363003361D-11, 3.766526874511D-12, -5.908496866762D-11, -3.052363003361D-11, 3.766526874511D-12, -5.908496866762D-11, -3.052363004276D-11, 3.766526875641D-12, -5.908496868534D-11, -3.052363004276D-11, 3.766526875641D-12, -5.908496868534D-11, 7.691288861294D-09, 1.142494346785D-12, -3.896216864318D-09, 7.791288860515D-09, APQ4(1,41) = -3.985290805151D-12, 8.234059228490D-14, 5.410040483045D-12, -4.124940429603D-12, 8.233321635510D-14, 5.322610720325D-12, -3.919288523941D-12, 8.262683541483D-14, 5.498362721839D-12, -4.124940433676D-12, 8.233321642920D-14, 5.322610724859D-12, -4.124940420900D-12, 8.233321621513D-14, 5.322610712479D-12, -4.124940420900D-12, 8.233321621513D-14, 5.322610712479D-12, -4.124940423375D-12, 8.233321626453D-14, 5.322610715672D-12, -4.124940420900D-12, 8.233321621513D-14, 5.322610712479D-12, -4.124940420900D-12, 8.233321621513D-14, 5.322610712479D-12, -4.124940420900D-12, 8.233321621513D-14, 5.322610712479D-12, -4.124940422138D-12, 8.233321623983D-14, 5.322610714076D-12, -4.124940422138D-12, 8.233321623983D-14, 5.322610714076D-12, 1.142494346785D-12, 2.635116861191D-13, -7.367662528706D-13, 1.142494346671D-12, 2.756266348265D-13, APQ4(1,42) = 6.719354432620D-11, 5.382005929988D-12, -6.510666581568D-11, 7.577209575178D-11, 5.406907716466D-12, -5.831055443492D-11, 6.583766077336D-11, 5.402167329457D-12, -6.565227019431D-11, 7.577209585642D-11, 5.406907721332D-12, -5.831055446147D-11, 7.577209545214D-11, 5.406907707274D-12, -5.831055445729D-11, 7.577209545214D-11, 5.406907707274D-12, -5.831055445729D-11, 7.577209549760D-11, 5.406907710518D-12, -5.831055449227D-11, 7.577209545214D-11, 5.406907707274D-12, -5.831055445729D-11, 7.577209545214D-11, 5.406907707274D-12, -5.831055445729D-11, 7.577209545214D-11, 5.406907707274D-12, -5.831055445729D-11, 7.577209547487D-11, 5.406907708896D-12, -5.831055447478D-11, 7.577209547487D-11, 5.406907708896D-12, -5.831055447478D-11, -3.896216864318D-09, -7.367662528706D-13, 4.886232455512D-09, -3.896216863929D-09, -7.367662527969D-13, 4.986232455013D-09, APQ4(1,43) = -3.012454970427D-11, 3.710969041047D-12, -6.910217233911D-11, -1.794575413620D-11, 3.739261929652D-12, -5.934492707307D-11, -5.305860164996D-11, 3.471874868450D-12, -1.082190750340D-10, -1.794575421626D-11, 3.739261933018D-12, -5.934492717194D-11, -1.794575380609D-11, 3.739261923296D-12, -5.934492675910D-11, -1.794575380609D-11, 3.739261923296D-12, -5.934492675910D-11, -1.794575381685D-11, 3.739261925539D-12, -5.934492679470D-11, -1.794575380609D-11, 3.739261923296D-12, -5.934492675910D-11, -1.794575380609D-11, 3.739261923296D-12, -5.934492675910D-11, -1.794575380609D-11, 3.739261923296D-12, -5.934492675910D-11, -1.794575381147D-11, 3.739261924417D-12, -5.934492677690D-11, -1.794575381147D-11, 3.739261924417D-12, -5.934492677690D-11, 6.082184235915D-10, 9.495461049568D-13, 4.221419574641D-10, 6.082184235307D-10, 9.495461048618D-13, 4.221419574219D-10, 1.683101270714D-09, APQ4(1,44) = -3.935526479174D-12, 8.240727569862D-14, 5.440125804280D-12, -4.093707380083D-12, 8.243995933972D-14, 5.343155961293D-12, -3.826540661348D-12, 8.297955785910D-14, 5.584013352759D-12, -4.093707384079D-12, 8.243995941391D-14, 5.343155965880D-12, -4.093707371662D-12, 8.243995919957D-14, 5.343155953249D-12, -4.093707371662D-12, 8.243995919957D-14, 5.343155953249D-12, -4.093707374118D-12, 8.243995924903D-14, 5.343155956455D-12, -4.093707371662D-12, 8.243995919957D-14, 5.343155953249D-12, -4.093707371662D-12, 8.243995919957D-14, 5.343155953249D-12, -4.093707371662D-12, 8.243995919957D-14, 5.343155953249D-12, -4.093707372890D-12, 8.243995922430D-14, 5.343155954852D-12, -4.093707372890D-12, 8.243995922430D-14, 5.343155954852D-12, 1.102384028620D-12, 1.419660420047D-13, -7.197107468543D-13, 1.102384028510D-12, 1.419660419905D-13, -7.197107467823D-13, 1.377025947996D-12, 1.839926793822D-13, APQ4(1,45) = 8.101554365544D-11, 5.420167648836D-12, -4.936299124974D-11, 6.771078555578D-11, 5.430298311598D-12, -5.736095031448D-11, 1.016164581363D-10, 5.644800039365D-12, -1.402753780909D-11, 6.771078564531D-11, 5.430298316485D-12, -5.736095034577D-11, 6.771078530662D-11, 5.430298302366D-12, -5.736095031230D-11, 6.771078530662D-11, 5.430298302366D-12, -5.736095031230D-11, 6.771078534725D-11, 5.430298305625D-12, -5.736095034672D-11, 6.771078530662D-11, 5.430298302366D-12, -5.736095031230D-11, 6.771078530662D-11, 5.430298302366D-12, -5.736095031230D-11, 6.771078530662D-11, 5.430298302366D-12, -5.736095031230D-11, 6.771078532694D-11, 5.430298303996D-12, -5.736095032951D-11, 6.771078532694D-11, 5.430298303996D-12, -5.736095032951D-11, 4.257284913693D-10, -6.105684831122D-13, 8.177598539547D-10, 4.257284913268D-10, -6.105684830511D-13, 8.177598538729D-10, -5.684026217033D-11, -9.642423338831D-13, 1.492556304339D-09, APQ4(1,46) = -3.473746585959D-11, 3.672624892062D-12, -7.417037550867D-11, -1.893897718030D-11, 3.735506688658D-12, -6.014895779732D-11, -5.201987060120D-11, 3.481260208379D-12, -1.063867856004D-10, -1.893897726292D-11, 3.735506692020D-12, -6.014895789810D-11, -1.893897684070D-11, 3.735506682308D-12, -6.014895747644D-11, -1.893897684070D-11, 3.735506682308D-12, -6.014895747644D-11, -1.893897685207D-11, 3.735506684549D-12, -6.014895751253D-11, -1.893897684070D-11, 3.735506682308D-12, -6.014895747644D-11, -1.893897684070D-11, 3.735506682308D-12, -6.014895747644D-11, -1.893897684070D-11, 3.735506682308D-12, -6.014895747644D-11, -1.893897684639D-11, 3.735506683428D-12, -6.014895749449D-11, -1.893897684639D-11, 3.735506683428D-12, -6.014895749449D-11, 6.086382920314D-10, 9.587071442687D-13, 4.221576955884D-10, 6.086382919706D-10, 9.587071441728D-13, 4.221576955462D-10, 8.397591980831D-10, 1.233244199350D-12, 3.483926443135D-10, 8.443443640505D-10, APQ4(1,47) = -3.924289073003D-12, 8.248391629831D-14, 5.452704803589D-12, -4.094879675261D-12, 8.243879205174D-14, 5.343423467963D-12, -3.831433205322D-12, 8.295628848891D-14, 5.579742831378D-12, -4.094879679259D-12, 8.243879212593D-14, 5.343423472550D-12, -4.094879666833D-12, 8.243879191159D-14, 5.343423459922D-12, -4.094879666833D-12, 8.243879191159D-14, 5.343423459922D-12, -4.094879669290D-12, 8.243879196106D-14, 5.343423463128D-12, -4.094879666833D-12, 8.243879191159D-14, 5.343423459922D-12, -4.094879666833D-12, 8.243879191159D-14, 5.343423459922D-12, -4.094879666833D-12, 8.243879191159D-14, 5.343423459922D-12, -4.094879668062D-12, 8.243879193632D-14, 5.343423461525D-12, -4.094879668062D-12, 8.243879193632D-14, 5.343423461525D-12, 1.106369076233D-12, 1.419877620300D-13, -7.220018507293D-13, 1.106369076122D-12, 1.419877620158D-13, -7.220018506571D-13, 1.225141788786D-12, 1.533247481263D-13, -8.375561529511D-13, 1.230677604831D-12, 1.533562393641D-13, APQ4(1,48) = 8.486472579732D-11, 5.451577459099D-12, -4.514118385096D-11, 6.841370532358D-11, 5.433127519585D-12, -5.676158453723D-11, 1.006713386265D-10, 5.637042733084D-12, -1.555587067010D-11, 6.841370541495D-11, 5.433127524474D-12, -5.676158456712D-11, 6.841370506761D-11, 5.433127510348D-12, -5.676158454007D-11, 6.841370506761D-11, 5.433127510348D-12, -5.676158454007D-11, 6.841370510866D-11, 5.433127513608D-12, -5.676158457413D-11, 6.841370506761D-11, 5.433127510348D-12, -5.676158454007D-11, 6.841370506761D-11, 5.433127510348D-12, -5.676158454007D-11, 6.841370506761D-11, 5.433127510348D-12, -5.676158454007D-11, 6.841370508813D-11, 5.433127511978D-12, -5.676158455710D-11, 6.841370508813D-11, 5.433127511978D-12, -5.676158455710D-11, 4.255631543803D-10, -6.166065997965D-13, 8.176677328525D-10, 4.255631543377D-10, -6.166065997348D-13, 8.176677327707D-10, 3.480349491016D-10, -8.433714784460D-13, 9.580110768376D-10, 3.448881851102D-10, -8.405399502554D-13, 9.604595838362D-10, APQ4(1,49) = -1.340672058235D-11, 3.761646776831D-12, -4.882517881624D-11, -3.052363153426D-11, 3.766526888284D-12, -5.908496936846D-11, -8.480975913294D-12, 3.787933652632D-12, -4.160345562245D-11, -3.052363163881D-11, 3.766526891674D-12, -5.908496947646D-11, -3.052363112105D-11, 3.766526881881D-12, -5.908496901102D-11, -3.052363112105D-11, 3.766526881881D-12, -5.908496901102D-11, -3.052363113936D-11, 3.766526884141D-12, -5.908496904648D-11, -3.052363112105D-11, 3.766526881881D-12, -5.908496901102D-11, -3.052363112105D-11, 3.766526881881D-12, -5.908496901102D-11, -3.052363112105D-11, 3.766526881881D-12, -5.908496901102D-11, -3.052363113020D-11, 3.766526883011D-12, -5.908496902875D-11, -3.052363113020D-11, 3.766526883011D-12, -5.908496902875D-11, 6.447192189297D-10, 1.142494369447D-12, 4.006166258969D-10, 6.447192188652D-10, 1.142494369332D-12, 4.006166258568D-10, 6.082184285963D-10, 1.102384050451D-12, 4.257284903842D-10, 6.086382970420D-10, 1.106369098140D-12, 4.255631533936D-10, 6.447192246375D-10, APQ4(1,50) = -3.985290813919D-12, 8.234059246605D-14, 5.410040494947D-12, -4.124940438678D-12, 8.233321653623D-14, 5.322610732035D-12, -3.919288532563D-12, 8.262683559661D-14, 5.498362733936D-12, -4.124940442750D-12, 8.233321661033D-14, 5.322610736569D-12, -4.124940429975D-12, 8.233321639627D-14, 5.322610724189D-12, -4.124940429975D-12, 8.233321639627D-14, 5.322610724189D-12, -4.124940432450D-12, 8.233321644567D-14, 5.322610727382D-12, -4.124940429975D-12, 8.233321639627D-14, 5.322610724189D-12, -4.124940429975D-12, 8.233321639627D-14, 5.322610724189D-12, -4.124940429975D-12, 8.233321639627D-14, 5.322610724189D-12, -4.124940431213D-12, 8.233321642097D-14, 5.322610725785D-12, -4.124940431213D-12, 8.233321642097D-14, 5.322610725785D-12, 1.142494349299D-12, 1.423621993383D-13, -7.367662544915D-13, 1.142494349185D-12, 1.423621993241D-13, -7.367662544178D-13, 9.495461069508D-13, 1.419660423028D-13, -6.105684843944D-13, 9.587071462820D-13, 1.419877623282D-13, -6.166066010914D-13, 1.142494371846D-12, 1.423621996373D-13, APQ5(1,1) = 6.719354499958D-11, 5.382005942369D-12, -6.510666593692D-11, 7.577209664352D-11, 5.406907729012D-12, -5.831055441154D-11, 6.583766139315D-11, 5.402167341780D-12, -6.565227038215D-11, 7.577209674816D-11, 5.406907733878D-12, -5.831055443810D-11, 7.577209634387D-11, 5.406907719820D-12, -5.831055443391D-11, 7.577209634387D-11, 5.406907719820D-12, -5.831055443391D-11, 7.577209638934D-11, 5.406907723064D-12, -5.831055446890D-11, 7.577209634387D-11, 5.406907719820D-12, -5.831055443391D-11, 7.577209634387D-11, 5.406907719820D-12, -5.831055443391D-11, 7.577209634387D-11, 5.406907719820D-12, -5.831055443391D-11, 7.577209636661D-11, 5.406907721442D-12, -5.831055445140D-11, 7.577209636661D-11, 5.406907721442D-12, -5.831055445140D-11, 4.006166251150D-10, -7.367662688090D-13, 8.328023142734D-10, 4.006166250750D-10, -7.367662687354D-13, 8.328023141901D-10, 4.221419557018D-10, -7.197107622344D-13, 8.177598570074D-10, 4.221576938226D-10, -7.220018661624D-13, 8.176677359058D-10, 4.006166236442D-10, -7.367662703562D-13, 8.328023176653D-10, APQ5(1,2) = -1.340672057699D-11, 3.761646775326D-12, -4.882517879671D-11, -3.052363152205D-11, 3.766526886778D-12, -5.908496934482D-11, -8.480975909901D-12, 3.787933651117D-12, -4.160345560581D-11, -3.052363162660D-11, 3.766526890168D-12, -5.908496945282D-11, -3.052363110884D-11, 3.766526880375D-12, -5.908496898739D-11, -3.052363110884D-11, 3.766526880375D-12, -5.908496898739D-11, -3.052363112715D-11, 3.766526882635D-12, -5.908496902284D-11, -3.052363110884D-11, 3.766526880375D-12, -5.908496898739D-11, -3.052363110884D-11, 3.766526880375D-12, -5.908496898739D-11, -3.052363110884D-11, 3.766526880375D-12, -5.908496898739D-11, -3.052363111799D-11, 3.766526881505D-12, -5.908496900512D-11, -3.052363111799D-11, 3.766526881505D-12, -5.908496900512D-11, 6.447192186718D-10, 1.142494368990D-12, 4.006166257367D-10, 6.447192186073D-10, 1.142494368875D-12, 4.006166256966D-10, 6.082184283530D-10, 1.102384050011D-12, 4.257284902139D-10, 6.086382967986D-10, 1.106369097698D-12, 4.255631532234D-10, 6.447192243796D-10, 1.142494371389D-12, 4.006166234840D-10, 1.044719223962D-09, APQ5(1,3) = -3.985290812325D-12, 8.234059243312D-14, 5.410040492783D-12, -4.124940437028D-12, 8.233321650330D-14, 5.322610729906D-12, -3.919288530995D-12, 8.262683556356D-14, 5.498362731736D-12, -4.124940441101D-12, 8.233321657740D-14, 5.322610734440D-12, -4.124940428325D-12, 8.233321636333D-14, 5.322610722060D-12, -4.124940428325D-12, 8.233321636333D-14, 5.322610722060D-12, -4.124940430800D-12, 8.233321641273D-14, 5.322610725253D-12, -4.124940428325D-12, 8.233321636333D-14, 5.322610722060D-12, -4.124940428325D-12, 8.233321636333D-14, 5.322610722060D-12, -4.124940428325D-12, 8.233321636333D-14, 5.322610722060D-12, -4.124940429563D-12, 8.233321638803D-14, 5.322610723656D-12, -4.124940429563D-12, 8.233321638803D-14, 5.322610723656D-12, 1.142494348842D-12, 1.423621992814D-13, -7.367662541968D-13, 1.142494348728D-12, 1.423621992672D-13, -7.367662541231D-13, 9.495461065710D-13, 1.419660422460D-13, -6.105684841502D-13, 9.587071458985D-13, 1.419877622714D-13, -6.166066008447D-13, 1.142494371389D-12, 1.423621995804D-13, -7.367662700615D-13, 1.142494370932D-12, 1.908219944439D-13, APQ5(1,4) = 6.719354497270D-11, 5.382005940216D-12, -6.510666591088D-11, 7.577209661321D-11, 5.406907726849D-12, -5.831055438821D-11, 6.583766136681D-11, 5.402167339619D-12, -6.565227035589D-11, 7.577209671785D-11, 5.406907731715D-12, -5.831055441477D-11, 7.577209631357D-11, 5.406907717657D-12, -5.831055441058D-11, 7.577209631357D-11, 5.406907717657D-12, -5.831055441059D-11, 7.577209635903D-11, 5.406907720901D-12, -5.831055444557D-11, 7.577209631357D-11, 5.406907717657D-12, -5.831055441058D-11, 7.577209631357D-11, 5.406907717657D-12, -5.831055441058D-11, 7.577209631357D-11, 5.406907717657D-12, -5.831055441058D-11, 7.577209633630D-11, 5.406907719279D-12, -5.831055442808D-11, 7.577209633630D-11, 5.406907719279D-12, -5.831055442808D-11, 4.006166249548D-10, -7.367662685143D-13, 8.328023139403D-10, 4.006166249147D-10, -7.367662684407D-13, 8.328023138570D-10, 4.221419555329D-10, -7.197107619465D-13, 8.177598566803D-10, 4.221576936537D-10, -7.220018658736D-13, 8.176677355787D-10, 4.006166234840D-10, -7.367662700615D-13, 8.328023173322D-10, 4.006166233237D-10, -7.367662697668D-13, 1.232802316839D-09, APQ5(1,5) = -2.170107119976D-10, 3.688872881717D-12, 2.277283443896D-10, -2.340567254887D-10, 3.710207277317D-12, 2.183768578055D-10, -2.130808185811D-10, 3.743474491470D-12, 2.363305746613D-10, -2.340567257830D-10, 3.710207280657D-12, 2.183768579425D-10, -2.340567246986D-10, 3.710207271010D-12, 2.183768577131D-10, -2.340567246986D-10, 3.710207271010D-12, 2.183768577131D-10, -2.340567248391D-10, 3.710207273236D-12, 2.183768578442D-10, -2.340567246986D-10, 3.710207271010D-12, 2.183768577131D-10, -2.340567246986D-10, 3.710207271010D-12, 2.183768577131D-10, -2.340567246986D-10, 3.710207271010D-12, 2.183768577131D-10, -2.340567247689D-10, 3.710207272123D-12, 2.183768577787D-10, -2.340567247689D-10, 3.710207272123D-12, 2.183768577787D-10, 4.736287283149D-10, 2.811991013403D-12, 3.839914700296D-10, 4.736287282675D-10, 2.811991013121D-12, 3.839914699912D-10, 4.474230800089D-10, 2.769747768033D-12, 4.015525082460D-10, 4.481107749350D-10, 2.773023807285D-12, 4.011588961491D-10, 4.736287317373D-10, 2.811991019308D-12, 3.839914691108D-10, 4.736287315478D-10, 2.811991018183D-12, 3.839914689572D-10, 6.895379712800D-09, APQ5(1,6) = -3.794585034802D-12, 6.882512381853D-14, 5.276076219786D-12, -3.667174466219D-12, 6.867768489099D-14, 5.345300365634D-12, -3.856943696639D-12, 6.850892079200D-14, 5.194017324709D-12, -3.667174469376D-12, 6.867768495280D-14, 5.345300370546D-12, -3.667174460655D-12, 6.867768477423D-14, 5.345300356070D-12, -3.667174460655D-12, 6.867768477423D-14, 5.345300356070D-12, -3.667174462855D-12, 6.867768481544D-14, 5.345300359277D-12, -3.667174460655D-12, 6.867768477423D-14, 5.345300356070D-12, -3.667174460655D-12, 6.867768477423D-14, 5.345300356070D-12, -3.667174460655D-12, 6.867768477423D-14, 5.345300356070D-12, -3.667174461755D-12, 6.867768479484D-14, 5.345300357674D-12, -3.667174461755D-12, 6.867768479484D-14, 5.345300357674D-12, -3.065221377261D-12, 1.151666400038D-13, -2.002035548670D-12, -3.065221376954D-12, 1.151666399923D-13, -2.002035548470D-12, -2.814390094951D-12, 1.154962774091D-13, -2.172700677043D-12, -2.820470366295D-12, 1.154717356208D-13, -2.169095102862D-12, -3.065221403561D-12, 1.151666402456D-13, -2.002035538759D-12, -3.065221402335D-12, 1.151666401996D-13, -2.002035537958D-12, -1.495016379847D-12, 3.029794676981D-13, APQ5(1,7) = 1.391413955241D-10, -4.089642398621D-12, -2.765408990132D-10, 1.190651250341D-10, -4.101198638754D-12, -2.896537726278D-10, 1.471750215677D-10, -4.068124159116D-12, -2.665809586489D-10, 1.190651250488D-10, -4.101198642445D-12, -2.896537729542D-10, 1.190651252647D-10, -4.101198631782D-12, -2.896537718274D-10, 1.190651252647D-10, -4.101198631782D-12, -2.896537718274D-10, 1.190651253361D-10, -4.101198634242D-12, -2.896537720012D-10, 1.190651252647D-10, -4.101198631782D-12, -2.896537718274D-10, 1.190651252647D-10, -4.101198631782D-12, -2.896537718274D-10, 1.190651252647D-10, -4.101198631782D-12, -2.896537718274D-10, 1.190651253004D-10, -4.101198633012D-12, -2.896537719143D-10, 1.190651253004D-10, -4.101198633012D-12, -2.896537719143D-10, -1.920927570609D-10, -1.145084438640D-12, -6.581631581012D-10, -1.920927570417D-10, -1.145084438526D-12, -6.581631580354D-10, -2.298317612351D-10, -1.197945486829D-12, -6.326185696352D-10, -2.290179567953D-10, -1.193864925316D-12, -6.330746429283D-10, -1.920927541312D-10, -1.145084441045D-12, -6.581631618519D-10, -1.920927540544D-10, -1.145084440587D-12, -6.581631615886D-10, 4.135042944937D-09, -1.020823102462D-12, 5.789384493763D-09, APQ5(1,8) = -2.170107119976D-10, 3.688872881717D-12, 2.277283443896D-10, -2.340567254887D-10, 3.710207277317D-12, 2.183768578055D-10, -2.130808185811D-10, 3.743474491470D-12, 2.363305746613D-10, -2.340567257830D-10, 3.710207280657D-12, 2.183768579425D-10, -2.340567246986D-10, 3.710207271010D-12, 2.183768577131D-10, -2.340567246986D-10, 3.710207271010D-12, 2.183768577131D-10, -2.340567248391D-10, 3.710207273236D-12, 2.183768578442D-10, -2.340567246986D-10, 3.710207271010D-12, 2.183768577131D-10, -2.340567246986D-10, 3.710207271010D-12, 2.183768577131D-10, -2.340567246986D-10, 3.710207271010D-12, 2.183768577131D-10, -2.340567247689D-10, 3.710207272123D-12, 2.183768577787D-10, -2.340567247689D-10, 3.710207272123D-12, 2.183768577787D-10, 4.736287283149D-10, 2.811991013403D-12, 3.839914700296D-10, 4.736287282675D-10, 2.811991013121D-12, 3.839914699912D-10, 4.474230800089D-10, 2.769747768033D-12, 4.015525082460D-10, 4.481107749350D-10, 2.773023807285D-12, 4.011588961491D-10, 4.736287317373D-10, 2.811991019308D-12, 3.839914691108D-10, 4.736287315478D-10, 2.811991018183D-12, 3.839914689572D-10, 7.221852346133D-10, -1.495016379847D-12, -3.571156923444D-10, 6.895379712800D-09, APQ5(1,9) = -3.794585034802D-12, 6.882512381853D-14, 5.276076219786D-12, -3.667174466219D-12, 6.867768489099D-14, 5.345300365634D-12, -3.856943696639D-12, 6.850892079200D-14, 5.194017324709D-12, -3.667174469376D-12, 6.867768495280D-14, 5.345300370546D-12, -3.667174460655D-12, 6.867768477423D-14, 5.345300356070D-12, -3.667174460655D-12, 6.867768477423D-14, 5.345300356070D-12, -3.667174462855D-12, 6.867768481544D-14, 5.345300359277D-12, -3.667174460655D-12, 6.867768477423D-14, 5.345300356070D-12, -3.667174460655D-12, 6.867768477423D-14, 5.345300356070D-12, -3.667174460655D-12, 6.867768477423D-14, 5.345300356070D-12, -3.667174461755D-12, 6.867768479484D-14, 5.345300357674D-12, -3.667174461755D-12, 6.867768479484D-14, 5.345300357674D-12, -3.065221377261D-12, 1.151666400038D-13, -2.002035548670D-12, -3.065221376954D-12, 1.151666399923D-13, -2.002035548470D-12, -2.814390094951D-12, 1.154962774091D-13, -2.172700677043D-12, -2.820470366295D-12, 1.154717356208D-13, -2.169095102862D-12, -3.065221403561D-12, 1.151666402456D-13, -2.002035538759D-12, -3.065221402335D-12, 1.151666401996D-13, -2.002035537958D-12, -1.495016379847D-12, 1.780314342502D-13, -1.020823102462D-12, -1.495016379847D-12, 3.029794676981D-13, APQ5(1,10) = 1.391413955241D-10, -4.089642398621D-12, -2.765408990132D-10, 1.190651250341D-10, -4.101198638754D-12, -2.896537726278D-10, 1.471750215677D-10, -4.068124159116D-12, -2.665809586489D-10, 1.190651250488D-10, -4.101198642445D-12, -2.896537729542D-10, 1.190651252647D-10, -4.101198631782D-12, -2.896537718274D-10, 1.190651252647D-10, -4.101198631782D-12, -2.896537718274D-10, 1.190651253361D-10, -4.101198634242D-12, -2.896537720012D-10, 1.190651252647D-10, -4.101198631782D-12, -2.896537718274D-10, 1.190651252647D-10, -4.101198631782D-12, -2.896537718274D-10, 1.190651252647D-10, -4.101198631782D-12, -2.896537718274D-10, 1.190651253004D-10, -4.101198633012D-12, -2.896537719143D-10, 1.190651253004D-10, -4.101198633012D-12, -2.896537719143D-10, -1.920927570609D-10, -1.145084438640D-12, -6.581631581012D-10, -1.920927570417D-10, -1.145084438526D-12, -6.581631580354D-10, -2.298317612351D-10, -1.197945486829D-12, -6.326185696352D-10, -2.290179567953D-10, -1.193864925316D-12, -6.330746429283D-10, -1.920927541312D-10, -1.145084441045D-12, -6.581631618519D-10, -1.920927540544D-10, -1.145084440587D-12, -6.581631615886D-10, -3.571156923444D-10, -1.020823102462D-12, 1.062579072760D-09, 4.135042944937D-09, -1.020823102462D-12, 5.789384493763D-09, APQ5(1,11) = -2.426163060438D-10, 3.821146992880D-12, 2.144377865165D-10, -2.188288810352D-10, 3.754903690131D-12, 2.258623674916D-10, -2.594916533426D-10, 4.200172601219D-12, 2.159318155760D-10, -2.188288812940D-10, 3.754903693510D-12, 2.258623676509D-10, -2.188288803734D-10, 3.754903683747D-12, 2.258623673138D-10, -2.188288803734D-10, 3.754903683747D-12, 2.258623673138D-10, -2.188288805047D-10, 3.754903686000D-12, 2.258623674493D-10, -2.188288803734D-10, 3.754903683747D-12, 2.258623673138D-10, -2.188288803734D-10, 3.754903683747D-12, 2.258623673138D-10, -2.188288803734D-10, 3.754903683747D-12, 2.258623673138D-10, -2.188288804391D-10, 3.754903684874D-12, 2.258623673815D-10, -2.188288804391D-10, 3.754903684874D-12, 2.258623673815D-10, 4.418730120457D-10, 2.572171538771D-12, 3.999229101909D-10, 4.418730120015D-10, 2.572171538514D-12, 3.999229101509D-10, 4.325893394650D-10, 2.497921066058D-12, 4.040382991981D-10, 4.346978147125D-10, 2.510678531406D-12, 4.029323486789D-10, 4.418730148805D-10, 2.572171544173D-12, 3.999229096757D-10, 4.418730147037D-10, 2.572171543144D-12, 3.999229095157D-10, 5.922557729236D-10, -1.272496314176D-12, -3.946293768461D-10, 5.922557729236D-10, -1.272496314176D-12, -3.946293768461D-10, 1.162531660052D-09, APQ5(1,12) = -3.968020331888D-12, 6.886646580855D-14, 5.195269263674D-12, -3.724767900314D-12, 6.862671864055D-14, 5.326196203625D-12, -4.195170463473D-12, 6.692661183585D-14, 5.194776122727D-12, -3.724767903599D-12, 6.862671870232D-14, 5.326196208467D-12, -3.724767894298D-12, 6.862671852389D-14, 5.326196194346D-12, -3.724767894298D-12, 6.862671852389D-14, 5.326196194346D-12, -3.724767896533D-12, 6.862671856506D-14, 5.326196197542D-12, -3.724767894298D-12, 6.862671852389D-14, 5.326196194346D-12, -3.724767894298D-12, 6.862671852389D-14, 5.326196194346D-12, -3.724767894298D-12, 6.862671852389D-14, 5.326196194346D-12, -3.724767895416D-12, 6.862671854447D-14, 5.326196195944D-12, -3.724767895416D-12, 6.862671854447D-14, 5.326196195944D-12, -2.950010781944D-12, 1.159552422437D-13, -2.063645399649D-12, -2.950010781649D-12, 1.159552422321D-13, -2.063645399443D-12, -2.584351579033D-12, 1.161548564507D-13, -2.322663162506D-12, -2.597260641566D-12, 1.161248610847D-13, -2.314172925299D-12, -2.950010806080D-12, 1.159552424872D-13, -2.063645391234D-12, -2.950010804900D-12, 1.159552424408D-13, -2.063645390408D-12, -1.399241585951D-12, 1.632988546787D-13, -8.907716857863D-13, -1.399241585951D-12, 1.632988546787D-13, -8.907716857863D-13, -1.650275859035D-12, 1.868167321169D-13, APQ5(1,13) = 1.320218305686D-10, -3.993564470741D-12, -2.802932664857D-10, 1.368853813624D-10, -4.057140542127D-12, -2.812928551438D-10, 1.196322386128D-10, -3.919470553775D-12, -2.536363587233D-10, 1.368853814185D-10, -4.057140545778D-12, -2.812928554447D-10, 1.368853814444D-10, -4.057140535230D-12, -2.812928544418D-10, 1.368853814444D-10, -4.057140535230D-12, -2.812928544418D-10, 1.368853815266D-10, -4.057140537664D-12, -2.812928546106D-10, 1.368853814444D-10, -4.057140535230D-12, -2.812928544418D-10, 1.368853814444D-10, -4.057140535230D-12, -2.812928544418D-10, 1.368853814444D-10, -4.057140535230D-12, -2.812928544418D-10, 1.368853814855D-10, -4.057140536447D-12, -2.812928545262D-10, 1.368853814855D-10, -4.057140536447D-12, -2.812928545262D-10, -2.270038980416D-10, -1.408952809839D-12, -6.405589062848D-10, -2.270038980189D-10, -1.408952809698D-12, -6.405589062207D-10, -2.572965873909D-10, -1.479925158377D-12, -6.210620752480D-10, -2.549368630107D-10, -1.467597043676D-12, -6.223685708457D-10, -2.270038957587D-10, -1.408952812798D-12, -6.405589095909D-10, -2.270038956679D-10, -1.408952812234D-12, -6.405589093347D-10, -3.893176834992D-10, -7.693372246272D-13, 9.214277122851D-10, -3.893176834992D-10, -7.693372246272D-13, 9.214277122851D-10, -1.554657694947D-11, -1.144897308828D-12, 1.446594990785D-09, APQ5(1,14) = -2.543362028354D-10, 3.873081710215D-12, 2.102433120571D-10, -2.198449095981D-10, 3.755770947253D-12, 2.254166673542D-10, -2.565440930932D-10, 4.184274554984D-12, 2.166038902508D-10, -2.198449098592D-10, 3.755770950633D-12, 2.254166675121D-10, -2.198449089280D-10, 3.755770940868D-12, 2.254166671819D-10, -2.198449089280D-10, 3.755770940868D-12, 2.254166671819D-10, -2.198449090599D-10, 3.755770943122D-12, 2.254166673171D-10, -2.198449089280D-10, 3.755770940868D-12, 2.254166671819D-10, -2.198449089280D-10, 3.755770940868D-12, 2.254166671819D-10, -2.198449089280D-10, 3.755770940868D-12, 2.254166671819D-10, -2.198449089939D-10, 3.755770941995D-12, 2.254166672495D-10, -2.198449089939D-10, 3.755770941995D-12, 2.254166672495D-10, 4.421447359333D-10, 2.576983590803D-12, 3.998729404636D-10, 4.421447358891D-10, 2.576983590545D-12, 3.998729404236D-10, 4.337743948383D-10, 2.514161285596D-12, 4.037091744436D-10, 4.340446513978D-10, 2.517862113365D-12, 4.036417737134D-10, 4.421447387724D-10, 2.576983596214D-12, 3.998729399456D-10, 4.421447385955D-10, 2.576983595184D-12, 3.998729397857D-10, 5.923006563898D-10, -1.279181979305D-12, -3.942448772949D-10, 5.923006563898D-10, -1.279181979305D-12, -3.942448772949D-10, 7.001265085145D-10, -1.521751499388D-12, -3.341211718177D-10, 7.016050415884D-10, APQ5(1,15) = -3.985223189832D-12, 6.893105396125D-14, 5.188721795218D-12, -3.725228858842D-12, 6.862666780193D-14, 5.326403129167D-12, -4.189364104110D-12, 6.690403797832D-14, 5.197100545253D-12, -3.725228862128D-12, 6.862666786370D-14, 5.326403134009D-12, -3.725228852823D-12, 6.862666768527D-14, 5.326403119889D-12, -3.725228852823D-12, 6.862666768527D-14, 5.326403119889D-12, -3.725228855059D-12, 6.862666772644D-14, 5.326403123085D-12, -3.725228852823D-12, 6.862666768527D-14, 5.326403119889D-12, -3.725228852823D-12, 6.862666768527D-14, 5.326403119889D-12, -3.725228852823D-12, 6.862666768527D-14, 5.326403119889D-12, -3.725228853941D-12, 6.862666770586D-14, 5.326403121487D-12, -3.725228853941D-12, 6.862666770586D-14, 5.326403121487D-12, -2.952062041318D-12, 1.159445379440D-13, -2.062740922375D-12, -2.952062041022D-12, 1.159445379325D-13, -2.062740922169D-12, -2.592095624422D-12, 1.161275656832D-13, -2.318158774126D-12, -2.601342673846D-12, 1.161149804200D-13, -2.311760511522D-12, -2.952062065490D-12, 1.159445381875D-13, -2.062740913935D-12, -2.952062064309D-12, 1.159445381412D-13, -2.062740913110D-12, -1.401297446492D-12, 1.633067896324D-13, -8.928843688886D-13, -1.401297446492D-12, 1.633067896324D-13, -8.928843688886D-13, -1.517490368802D-12, 1.731214697779D-13, -1.049238930536D-12, -1.522218917314D-12, 1.731300275274D-13, APQ5(1,16) = 1.237082161888D-10, -3.956081833731D-12, -2.832275122864D-10, 1.360736591010D-10, -4.056592504507D-12, -2.816658174431D-10, 1.215939482225D-10, -3.930930603930D-12, -2.532536273241D-10, 1.360736591552D-10, -4.056592508158D-12, -2.816658177452D-10, 1.360736591898D-10, -4.056592497611D-12, -2.816658167367D-10, 1.360736591898D-10, -4.056592497611D-12, -2.816658167367D-10, 1.360736592714D-10, -4.056592500045D-12, -2.816658169057D-10, 1.360736591898D-10, -4.056592497611D-12, -2.816658167367D-10, 1.360736591898D-10, -4.056592497611D-12, -2.816658167367D-10, 1.360736591898D-10, -4.056592497611D-12, -2.816658167367D-10, 1.360736592306D-10, -4.056592498828D-12, -2.816658168212D-10, 1.360736592306D-10, -4.056592498828D-12, -2.816658168212D-10, -2.266442819445D-10, -1.404241991895D-12, -6.406698947801D-10, -2.266442819218D-10, -1.404241991755D-12, -6.406698947160D-10, -2.557695814030D-10, -1.464626073833D-12, -6.216666241476D-10, -2.551840639307D-10, -1.461009919682D-12, -6.219696678453D-10, -2.266442796556D-10, -1.404241994844D-12, -6.406698980903D-10, -2.266442795649D-10, -1.404241994282D-12, -6.406698978340D-10, -3.891381910091D-10, -7.753516385574D-13, 9.218945212805D-10, -3.891381910091D-10, -7.753516385574D-13, 9.218945212805D-10, -3.344487080255D-10, -1.053046635014D-12, 1.068687167784D-09, -3.329031632189D-10, -1.053687823213D-12, 1.069982475783D-09, APQ5(1,17) = -2.170107127990D-10, 3.688872887593D-12, 2.277283446443D-10, -2.340567264923D-10, 3.710207283282D-12, 2.183768579397D-10, -2.130808193206D-10, 3.743474497802D-12, 2.363305750172D-10, -2.340567267867D-10, 3.710207286621D-12, 2.183768580768D-10, -2.340567257023D-10, 3.710207276975D-12, 2.183768578474D-10, -2.340567257023D-10, 3.710207276975D-12, 2.183768578474D-10, -2.340567258427D-10, 3.710207279201D-12, 2.183768579784D-10, -2.340567257023D-10, 3.710207276975D-12, 2.183768578474D-10, -2.340567257023D-10, 3.710207276975D-12, 2.183768578474D-10, -2.340567257023D-10, 3.710207276975D-12, 2.183768578474D-10, -2.340567257725D-10, 3.710207278088D-12, 2.183768579129D-10, -2.340567257725D-10, 3.710207278088D-12, 2.183768579129D-10, 4.736287305652D-10, 2.811991026743D-12, 3.839914695971D-10, 4.736287305179D-10, 2.811991026461D-12, 3.839914695587D-10, 4.474230819174D-10, 2.769747780858D-12, 4.015525080437D-10, 4.481107768517D-10, 2.773023820150D-12, 4.011588959422D-10, 4.736287339876D-10, 2.811991032648D-12, 3.839914686783D-10, 4.736287337982D-10, 2.811991031523D-12, 3.839914685247D-10, 6.221852383735D-10, -1.495016394259D-12, -3.571156894693D-10, 6.221852383735D-10, -1.495016394259D-12, -3.571156894693D-10, 5.922557750438D-10, -1.399241599150D-12, -3.893176819191D-10, 5.923006585121D-10, -1.401297459714D-12, -3.891381894257D-10, 6.221852408590D-10, APQ5(1,18) = -3.794585039735D-12, 6.882512390800D-14, 5.276076226645D-12, -3.667174470986D-12, 6.867768498027D-14, 5.345300372583D-12, -3.856943701653D-12, 6.850892088106D-14, 5.194017331461D-12, -3.667174474144D-12, 6.867768504208D-14, 5.345300377495D-12, -3.667174465422D-12, 6.867768486351D-14, 5.345300363019D-12, -3.667174465422D-12, 6.867768486351D-14, 5.345300363019D-12, -3.667174467623D-12, 6.867768490472D-14, 5.345300366226D-12, -3.667174465422D-12, 6.867768486351D-14, 5.345300363019D-12, -3.667174465422D-12, 6.867768486351D-14, 5.345300363019D-12, -3.667174465422D-12, 6.867768486351D-14, 5.345300363019D-12, -3.667174466523D-12, 6.867768488412D-14, 5.345300364623D-12, -3.667174466523D-12, 6.867768488412D-14, 5.345300364623D-12, -3.065221381245D-12, 1.151666401535D-13, -2.002035551272D-12, -3.065221380939D-12, 1.151666401420D-13, -2.002035551072D-12, -2.814390098609D-12, 1.154962775592D-13, -2.172700679867D-12, -2.820470369962D-12, 1.154717357709D-13, -2.169095105682D-12, -3.065221407546D-12, 1.151666403953D-13, -2.002035541361D-12, -3.065221406320D-12, 1.151666403493D-13, -2.002035540561D-12, -1.495016381790D-12, 1.641483196541D-13, -1.020823103790D-12, -1.495016381790D-12, 1.641483196541D-13, -1.020823103790D-12, -1.272496315830D-12, 1.632988548910D-13, -7.693372256273D-13, -1.279181980968D-12, 1.633067898447D-13, -7.753516395653D-13, -1.495016396203D-12, 1.641483198675D-13, APQ5(1,19) = 1.391413952626D-10, -4.089642403016D-12, -2.765408994080D-10, 1.190651245931D-10, -4.101198643113D-12, -2.896537731318D-10, 1.471750213651D-10, -4.068124163156D-12, -2.665809589540D-10, 1.190651246078D-10, -4.101198646804D-12, -2.896537734582D-10, 1.190651248237D-10, -4.101198636141D-12, -2.896537723314D-10, 1.190651248237D-10, -4.101198636141D-12, -2.896537723314D-10, 1.190651248951D-10, -4.101198638601D-12, -2.896537725052D-10, 1.190651248237D-10, -4.101198636141D-12, -2.896537723314D-10, 1.190651248237D-10, -4.101198636141D-12, -2.896537723314D-10, 1.190651248237D-10, -4.101198636141D-12, -2.896537723314D-10, 1.190651248594D-10, -4.101198637371D-12, -2.896537724183D-10, 1.190651248594D-10, -4.101198637371D-12, -2.896537724183D-10, -1.920927559181D-10, -1.145084431879D-12, -6.581631597506D-10, -1.920927558989D-10, -1.145084431765D-12, -6.581631596847D-10, -2.298317604036D-10, -1.197945480528D-12, -6.326185710746D-10, -2.290179559564D-10, -1.193864918980D-12, -6.330746443718D-10, -1.920927529884D-10, -1.145084434284D-12, -6.581631635012D-10, -1.920927529116D-10, -1.145084433826D-12, -6.581631632380D-10, -3.571156904819D-10, -1.020823114412D-12, 9.625790770762D-10, -3.571156904819D-10, -1.020823114412D-12, 9.625790770762D-10, -3.946293762087D-10, -8.907716966387D-13, 9.214277152602D-10, -3.942448766554D-10, -8.928843797611D-13, 9.218945242588D-10, -3.571156885052D-10, -1.020823115739D-12, 9.625790804070D-10, APQ5(1,20) = -2.170107119976D-10, 3.688872881717D-12, 2.277283443896D-10, -2.340567254887D-10, 3.710207277317D-12, 2.183768578055D-10, -2.130808185811D-10, 3.743474491470D-12, 2.363305746613D-10, -2.340567257830D-10, 3.710207280657D-12, 2.183768579425D-10, -2.340567246986D-10, 3.710207271010D-12, 2.183768577131D-10, -2.340567246986D-10, 3.710207271010D-12, 2.183768577131D-10, -2.340567248391D-10, 3.710207273236D-12, 2.183768578442D-10, -2.340567246986D-10, 3.710207271010D-12, 2.183768577131D-10, -2.340567246986D-10, 3.710207271010D-12, 2.183768577131D-10, -2.340567246986D-10, 3.710207271010D-12, 2.183768577131D-10, -2.340567247689D-10, 3.710207272123D-12, 2.183768577787D-10, -2.340567247689D-10, 3.710207272123D-12, 2.183768577787D-10, 4.736287283149D-10, 2.811991013403D-12, 3.839914700296D-10, 4.736287282675D-10, 2.811991013121D-12, 3.839914699912D-10, 4.474230800089D-10, 2.769747768033D-12, 4.015525082460D-10, 4.481107749350D-10, 2.773023807285D-12, 4.011588961491D-10, 4.736287317373D-10, 2.811991019308D-12, 3.839914691108D-10, 4.736287315478D-10, 2.811991018183D-12, 3.839914689572D-10, 7.221852346133D-10, -1.495016379847D-12, -3.571156923444D-10, 7.221852346133D-10, -1.495016379847D-12, -3.571156923444D-10, 5.922557729236D-10, -1.399241585951D-12, -3.893176834992D-10, 5.923006563898D-10, -1.401297446492D-12, -3.891381910091D-10, 6.221852383735D-10, -1.495016381790D-12, -3.571156904819D-10, 6.895379712800D-09, APQ5(1,21) = -3.794585034802D-12, 6.882512381853D-14, 5.276076219786D-12, -3.667174466219D-12, 6.867768489099D-14, 5.345300365634D-12, -3.856943696639D-12, 6.850892079200D-14, 5.194017324709D-12, -3.667174469376D-12, 6.867768495280D-14, 5.345300370546D-12, -3.667174460655D-12, 6.867768477423D-14, 5.345300356070D-12, -3.667174460655D-12, 6.867768477423D-14, 5.345300356070D-12, -3.667174462855D-12, 6.867768481544D-14, 5.345300359277D-12, -3.667174460655D-12, 6.867768477423D-14, 5.345300356070D-12, -3.667174460655D-12, 6.867768477423D-14, 5.345300356070D-12, -3.667174460655D-12, 6.867768477423D-14, 5.345300356070D-12, -3.667174461755D-12, 6.867768479484D-14, 5.345300357674D-12, -3.667174461755D-12, 6.867768479484D-14, 5.345300357674D-12, -3.065221377261D-12, 1.151666400038D-13, -2.002035548670D-12, -3.065221376954D-12, 1.151666399923D-13, -2.002035548470D-12, -2.814390094951D-12, 1.154962774091D-13, -2.172700677043D-12, -2.820470366295D-12, 1.154717356208D-13, -2.169095102862D-12, -3.065221403561D-12, 1.151666402456D-13, -2.002035538759D-12, -3.065221402335D-12, 1.151666401996D-13, -2.002035537958D-12, -1.495016379847D-12, 1.780314342502D-13, -1.020823102462D-12, -1.495016379847D-12, 1.780314342502D-13, -1.020823102462D-12, -1.272496314176D-12, 1.632988546787D-13, -7.693372246272D-13, -1.279181979305D-12, 1.633067896324D-13, -7.753516385574D-13, -1.495016394259D-12, 1.641483196541D-13, -1.020823114412D-12, -1.495016379847D-12, 3.029794676981D-13, APQ5(1,22) = 1.391413955241D-10, -4.089642398621D-12, -2.765408990132D-10, 1.190651250341D-10, -4.101198638754D-12, -2.896537726278D-10, 1.471750215677D-10, -4.068124159116D-12, -2.665809586489D-10, 1.190651250488D-10, -4.101198642445D-12, -2.896537729542D-10, 1.190651252647D-10, -4.101198631782D-12, -2.896537718274D-10, 1.190651252647D-10, -4.101198631782D-12, -2.896537718274D-10, 1.190651253361D-10, -4.101198634242D-12, -2.896537720012D-10, 1.190651252647D-10, -4.101198631782D-12, -2.896537718274D-10, 1.190651252647D-10, -4.101198631782D-12, -2.896537718274D-10, 1.190651252647D-10, -4.101198631782D-12, -2.896537718274D-10, 1.190651253004D-10, -4.101198633012D-12, -2.896537719143D-10, 1.190651253004D-10, -4.101198633012D-12, -2.896537719143D-10, -1.920927570609D-10, -1.145084438640D-12, -6.581631581012D-10, -1.920927570417D-10, -1.145084438526D-12, -6.581631580354D-10, -2.298317612351D-10, -1.197945486829D-12, -6.326185696352D-10, -2.290179567953D-10, -1.193864925316D-12, -6.330746429283D-10, -1.920927541312D-10, -1.145084441045D-12, -6.581631618519D-10, -1.920927540544D-10, -1.145084440587D-12, -6.581631615886D-10, -3.571156923444D-10, -1.020823102462D-12, 1.062579072760D-09, -3.571156923444D-10, -1.020823102462D-12, 1.062579072760D-09, -3.946293768461D-10, -8.907716857863D-13, 9.214277122851D-10, -3.942448772949D-10, -8.928843688886D-13, 9.218945212805D-10, -3.571156894693D-10, -1.020823103790D-12, 9.625790770762D-10, 4.135042944937D-09, -1.020823102462D-12, 5.789384493763D-09, $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ Earth/Moon Barycenter - Mars planetary ephemeris covariance consistent $ with DE403. $ $ 1) Mail message from Myles Standish dated October 13, 1995. $ $ 2) Standish, E. M., et. al., "JPL Planetary and Lunar Ephemerides, $ DE403/LE403", JPL IOM 314.10-127, May 22, 1995. $ $ 3) Standish, E. M., "Updated Covariance of Mars for DE234", $ JPL IOM 314.6-1452, September 4, 1992. $ $ The DE403 ephemeris is now based upon the (J2000) reference frame of the $ International Earth Rotation Service (IERS). $ $ Also, the modeling of the perturbations of asteroids upon the planetary $ orbits has been improved. $ $ Heliocentric position errors on 11-SEP-1997 in VIEW1 coordinates: $ $ Mars Earth-Moon $ $ radial 0.09280 km 0.00823 km $ down track 3.50069 km 2.35441 km $ cross track 4.46716 km 2.41721 km $ $ Note: this covariance is *NOT* the formal covariance originally generated $ by Myles Standish in his ephemeris solution. It has been increased by $ multiplying the formal sigmas by a factor of 3 (9x each covariance term). $ This was done by Myles Standish himself in order to get a "realistic" $ 1-sigma covariance for the MGS NAV Team. $ $ The Eros Set III covariance is from IOM 312.F-98-019 (Feb 12, 1998) $ APNAM5(23) = 'DMWB','DPB','DQB','EDWB','DAB','DEB', 'DMW4','DP4','DQ4','EDW4','DA4','DE4', APNAM5(35) = 'DMW9','DP9','DQ9','EDW9','DA9','DE9', $ SCAPQ5(23) = 12*1.0D0, $ Scale the formal covariance by 1. SCAPQ5(35) = 6*1.0D0, $ APQ5( 23, 23) = .2500619938607D-15, APQ5( 23, 24) = -.9840809907449D-16, .3012307203757D-15, APQ5( 23, 25) = -.6717466164725D-17, .7541612869500D-16, .3776553127620D-15, APQ5( 23, 26) = .4089233839056D-17, -.1642413344515D-17, -.1079032697502D-18, .6878386165598D-19, APQ5( 23, 27) = .4475725810474D-19, .3040308552871D-21, .7921580263731D-22, .2683325412564D-21, .2466195745570D-21, APQ5( 23, 28) = -.2772804565985D-19, .4122777712057D-20, .6754188665159D-20, -.4141840900251D-21, -.1449504322526D-21, .6449830592977D-21, APQ5( 23, 29) = .2526547011753D-15, -.1076259494468D-15, -.1604861006810D-16, .4129793504983D-17, .4471060435654D-19, -.2814441686566D-19, .2557662095781D-15, APQ5( 23, 30) = .5654626665896D-16, -.2374921888668D-15, -.3473195832252D-15, .9331081197412D-18, -.1114333165221D-20, .1201897480483D-20, .6945489596664D-16, .4189305687099D-15, APQ5( 23, 31) = -.7368457704872D-16, .1954231952373D-15, -.1655423108357D-15, -.1215023446591D-17, -.4720420756395D-20, .1934550630169D-20, -.7557637611684D-16, .1791365336996D-16, .2555002296624D-15, APQ5( 23, 32) = .2350198519801D-16, -.1003311983381D-16, -.1485599691033D-17, .3856764479765D-18, .3866037364955D-20, -.2696388560863D-20, .2377747506121D-16, .6453894706049D-17, -.7024295975793D-17, .2216646550056D-17, APQ5( 23, 33) = .7668707454546D-19, -.5831042764528D-21, -.2861548290076D-20, .5559161086068D-21, .4176215548227D-21, -.3369654932988D-21, .8038241575961D-19, .1174626010700D-20, -.8692160071761D-20, .6699776083859D-20, .1062979420069D-20, APQ5( 23, 34) = .1242932383509D-18, .2731396047934D-19, .4283939404765D-20, .8141006826895D-21, .1000976210837D-20, -.8798008951018D-21, .1105354074578D-18, -.1884309554330D-19, .4043864619091D-19, .1314747563459D-19, .1867091352772D-20, .1277903318814D-19, $ APQ5( 35, 35 ) = 3.411944855986297E-15, APQ5( 35, 36 ) = -9.993961098765528E-17, 3.513250664625000E-15, APQ5( 35, 37 ) = -2.437069027383009E-16, 2.807418003050796E-16, 1.409328231433322E-15, APQ5( 35, 38 ) = 1.947452562762970E-15,-4.082974889460758E-17, -1.407282547460761E-16, 1.369360714587576E-15, APQ5( 35, 39 ) = -3.183518148617593E-18,-5.172085285380212E-19, 5.576669917552228E-19, -1.517416422083525E-18, 2.670106258287285E-20, APQ5( 35, 40 ) = 9.869201300502101E-17, 2.187077101195288E-17, -6.115869173141696E-17, 1.383143587683706E-16,-8.976009702447546E-20, 1.253395849018215E-16, $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ Extra print from SOLVE: SOLPRP( 1) = 20*0, $ 0=OFF, 1=SINGLE PRECISION, 2=DOUBLE PRECISION $ SOLPRP( 1) = 1, $ Information with a priori. $ SOLPRP( 2) = 1, $ A priori (APQ). $ SOLPRP( 4) = 2, $ Computed covariance (4 digits). $ SOLPRP( 5) = 1, $ Correlation matrix. SOLPRP( 6) = 1, $ Print 132 column SOLVE page. $ SOLPRP( 7) = 1, $ Sensitivity matrix. $ SOLPRP( 8) = 2, $ Perturbation matrix (4 digits). $ SOLPRP( 9) = 2, $ Consider covariance (4 digits). $ SOLPRP(10) = 1, $ Singular value analysis. $ 3, & 11-20 are not used. $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ TRANSLATE and EDIT $ $ "TRANSLATE" connects a name to a data type & translates the CSP commands. $ $ "EDIT" actually executes the "TRANSLATE" instructions. $ EDFLAG = .TRUE., $ TRUE ==> Data editing is on in REGRES. $ DANAMS( 1) = 100*' ', DANUMS( 1) = 100*0, $ DANAMS( 1) = 'ALL', DANUMS( 1) = 0, DANAMS( 2) = 'INS', DANUMS( 2) = 1, DANAMS( 3) = 'INQ', DANUMS( 3) = 3, DANAMS( 4) = 'IWS', DANUMS( 4) = 5, DANAMS( 5) = 'IWQ', DANUMS( 5) = 6, DANAMS( 6) = 'DDOD', DANUMS( 6) = 7, DANAMS( 7) = 'DDOR', DANUMS( 7) = 8, DANAMS( 8) = 'VLBI', DANUMS( 8) = 070008, DANAMS( 9) = 'DOPPLER', DANUMS( 9) = 110016, DANAMS(10) = 'F1', DANUMS(10) = 11, DANAMS(11) = 'F2', DANUMS(11) = 12, DANAMS(12) = 'F3', DANUMS(12) = 13, DANAMS(13) = 'F3C', DANUMS(13) = 14, DANAMS(14) = 'DF2', DANUMS(14) = 15, DANAMS(15) = 'F2MF3', DANUMS(15) = 16, DANAMS(16) = 'RANGE', DANUMS(16) = 310048, DANAMS(17) = 'ETR', DANUMS(17) = 31, DANAMS(18) = 'MARK1', DANUMS(18) = 32, DANAMS(19) = 'MARK1A', DANUMS(19) = 33, DANAMS(20) = 'TAU', DANUMS(20) = 34, DANAMS(21) = 'MU', DANUMS(21) = 35, DANAMS(22) = 'PLOP', DANUMS(22) = 36, DANAMS(23) = 'SRA', DANUMS(23) = 37, DANAMS(24) = 'MU2', DANUMS(24) = 38, DANAMS(25) = 'GSTDN', DANUMS(25) = 41, DANAMS(26) = 'DOPRNG', DANUMS(26) = 110048, DANAMS(27) = 'ANGLES', DANUMS(27) = 510058, DANAMS(28) = 'AZ', DANUMS(28) = 51, DANAMS(29) = 'EL', DANUMS(29) = 52, DANAMS(30) = 'HA', DANUMS(30) = 53, DANAMS(31) = 'DEC', DANUMS(31) = 54, DANAMS(32) = 'X30', DANUMS(32) = 55, DANAMS(33) = 'Y30', DANUMS(33) = 56, DANAMS(34) = 'X85', DANUMS(34) = 57, DANAMS(35) = 'Y85', DANUMS(35) = 58, DANAMS(36) = 'PLANPX', DANUMS(36) = 61, DANAMS(37) = 'PLANLN', DANUMS(37) = 62, DANAMS(38) = 'STARPX', DANUMS(38) = 145, DANAMS(39) = 'STARLN', DANUMS(39) = 146, DANAMS(40) = 'LDMKPX', DANUMS(40) = 143, DANAMS(41) = 'LDMKLN', DANUMS(41) = 144, $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ MAPPING $ $ Input for the programs MAPGEN and MAPSEM. $ MAPGEN transforms from EME2000 to other coordinate systems. It creates $ the state vectors and mapping matrices. $ MAPSEM prints the mapped output. $ EQEPOC(1) = 99*0.0D0, $ Epoch for reference planes. DMAP(1) = 99*0.0, $ D.P. version of MAPIN(1,J) MAPIN(1,1) = 1188*' ', MAPSAT(1,1) = 792*' ', MAPSEN(1) = 99*0, $ Matrix print (0=OFF, 1=SENS, 2=PERT, 3=BOTH) $ MAPBUG( 1) = 30*0, $ MAPGEN & MAPSEM debug, covariance & planet $ mapping flags. MAPBUG(18) = 1, $ Mapped covariance print (1=OFF, 0=ON) MAPBUG(20) = 2, $ Planetary mapping is to VIEW1. $ MAPRP(1) = 0, $ Mapping matrix print (0=OFF, 1=ON) MAPRP(2) = 0, $ Mapped covariance print (0=OFF,1=S.P.,2=D.P.) MAPAP = 0, $ Mapped statistics: $ (0=FILTERED, 1=APRIORI, 2=SMOOTHED) $ CTOLR = 1.0D-5, CITLIM = 5, $ Parameters for closest approach determination $ $ EXAMPLE: $ $ B-Plane: Earth Mean Equator of Date $ $ MAPIN( 1,1) = ' ', $ Epoch to map. $ MAPIN( 2,1) = 'ET', $ Time scale. $ MAPIN( 3,1) = 'EQUATO', $ Name of the mapped to coordinate frame. $ MAPIN( 4,1) = 'EARTH', $ Body for the reference frame definition. $ MAPIN( 5,1) = 'SPACE', $ The reference plane X-axis orientation. $ MAPIN( 6,1) = 'EARTH', $ The body of the covariance center. $ MAPIN( 7,1) = 'MEAN', $ Reference plane definition. $ MAPIN( 8,1) = 'ASYMPT', $ Coordinate system $ MAPIN( 9,1) = 'EARTH', $ Target body of the event requested. $ MAPIN(10,1) = 'CLOSAP', $ Map to an event. $ MAPIN(11,1) = '01-MAY-1998 00:00:00', $ $ EME2000 Cartesian $ MAPIN(1,1)= ' ', MAPIN(2,1)= 'UTC', MAPIN(3,1)= 'EQUATO','EARTH','SPACE','PLUTO','MEAN','CARTES', 'PLUTO','CLOSAP','27-JAN-2002 00:00:00.0000','UTC', EQEPOC(1) = 2000.D0, $ $ VME2000 Cartesian $ MAPIN(1,2)= ' ', MAPIN(2,2)= 'UTC', MAPIN(3,2)= 'EQUATO','PLUTO','SPACE','PLUTO','MEAN','CARTES', 'PLUTO','CLOSAP','27-JAN-2002 00:00:00.0000','UTC', EQEPOC(2) = 2000.D0, $ $ View frame 1 $ MAPIN(1,3)= ' ', MAPIN(2,3)= 'UTC', MAPIN(3,3)= 'VIEW1',' ',' ','PLUTO',' ','CARTES', 'PLUTO','CLOSAP','27-JAN-2002 00:00:00.0000','UTC', EQEPOC(3) = 2000.D0, $ $ VME2000 classical $ MAPIN(1,4)= ' ', MAPIN(2,4)= 'UTC', MAPIN(3,4)= 'EQUATO','PLUTO','SPACE','PLUTO','MEAN','CLASSI', 'PLUTO','CLOSAP','27-JAN-2002 00:00:00.0000','UTC', EQEPOC(4) = 2000.D0, $ $ Plane-of-sky classical $ MAPIN(1,5)= ' ', MAPIN(2,5)= 'UTC', MAPIN(3,5)= 'SKYPLN','SCRAFT',' ','PLUTO',' ','CLASSI', 'PLUTO','CLOSAP','27-JAN-2002 00:00:00.0000','UTC', EQEPOC(5) = 2000.D0, $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ OUTPUT $ $ OUTPUT displays data residuals on a printed output. The program also $ generates plots and plotfiles of the data residuals. $ RSTA( 1) = 15*' ', RSTA( 1) = 'RESID','CRESID', $ Additional parameters on file. $ IPFLAG(1) = 4*0, $ $ The units of the data types in the ODP are as follows: $ $ F1, F2, F3, F2MF3: Hertz, for Doppler data types. $ SRA: Range Units, for range data. $ IWS, IWQ, DDOR: nanoseconds, for wide-band VLBI types. $ INS, INQ, DDOD: Hertz, for narrow-band VLBI types. $ X85, Y85: degrees, for angle data types. $ $ 1.0 mm/s = 0.02810 Hz for F1 and F2MF3, X-band. $ 1.0 mm/s = 0.05620 Hz for F2 and F3, X-band. $ 1.0 m = 7.01030 RU for SRA. $ 1.0 m = 3.33564 nanoseconds for IWS, IWQ, and DDOR. $ = 141.333 nanoradians. $ 1.0 mm/s = 0.02810 Hz for INS, INQ, and DDOD, X-band. $ PLDTYP( 1) = 'F1', PLTBND( 1) = 'X', PLSCAL( 1) = 1.4050, PLDTYP( 2) = 'F2', PLTBND( 2) = 'X', PLSCAL( 2) = 2.8100, PLDTYP( 3) = 'F3', PLTBND( 3) = 'X', PLSCAL( 3) = 2.8100, PLDTYP( 4) = 'F2MF3', PLTBND( 4) = 'X', PLSCAL( 4) = 1.4050, PLDTYP( 5) = 'SRA', PLTBND( 5) = 'X', PLSCAL( 5) = 35052.0, PLDTYP( 6) = 'IWS', PLTBND( 6) = 'X', PLSCAL( 6) = 50.00, PLDTYP( 7) = 'IWQ', PLTBND( 7) = 'X', PLSCAL( 7) = 50.00, PLDTYP( 8) = 'DDOR', PLTBND( 8) = 'X', PLSCAL( 8) = 50.00, PLDTYP( 9) = 'INS', PLTBND( 9) = 'X', PLSCAL( 9) = 1.4050, PLDTYP(10) = 'INQ', PLTBND(10) = 'X', PLSCAL(10) = 1.4050, PLDTYP(11) = 'DDOD', PLTBND(11) = 'X', PLSCAL(11) = 1.4050, PLDTYP(12) = 'X85', PLTBND(12) = ' ', PLSCAL(12) = 1.00, PLDTYP(13) = 'Y85', PLTBND(13) = ' ', PLSCAL(13) = 1.00, $ OUTBEG = '17-FEB-1996 00:00:00', $ Launch date. OUTEND = '01-JUL-2002 00:00:00', $ End-of-mission? $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $ $ TABWET and TABDRY from C. C. Chao 8/29/77. $ $ The elevation angle (in degrees) corresponding to each TAB value lies $ above it in the table. $ $ 1) Mottinger, N. A., "Reflections on Refraction -- A Historical Overview $ of the Tropospheric Refraction Model in the ODP," JPL IOM 314.10-385, $ January 18, 1984. $ $ 2) Chao, C. C., "Improved Tropospheric Mapping Tables Including Bending $ Effect for SATODP," JPL IOM 391.3-637, December 28, 1972. $ $ 3) Chao, C. C., "Improved Estimation of the Parameters and Mapping Tables $ of Tropospheric Calibration for MM71," JPL IOM 391.3-352, May 25, 1971. $ TABWET(1) = 261*0.0D0, $ TABWET(1) = $ .00 61.5790, $ .10 .20 .30 .40 .50 .60 .70 .80 .90 , 57.8413,54.3927,51.2432,48.3625,45.7235,43.3021,41.0769,39.0284,37.1397, $ 1.00 1.10 1.20 1.30 1.40 1.50 1.60 1.70 1.80 , 35.3955,33.7820,32.2870,30.8996,29.6100,28.4095,27.2901,26.2449,25.2675, $ 1.90 2.00 2.10 2.20 2.30 2.40 2.50 2.60 2.70 , 24.3521,23.4935,22.6873,21.9291,21.2152,20.5420,19.9066,19.3060,18.7377, $ 2.80 2.90 3.00 3.10 3.20 3.30 3.40 3.50 3.60 , 18.1994,17.6889,17.2042,16.7435,16.3053,15.8880,15.4903,15.1108,14.7484, $ 3.70 3.80 3.90 4.00 4.10 4.20 4.30 4.40 4.50 , 14.4021,14.0709,13.7538,13.4500,13.1587,12.8792,12.6109,12.3530,12.1051, $ 4.60 4.70 4.80 4.90 5.00 5.10 5.20 5.30 5.40 , 11.8666,11.6369,11.4157,11.2024,10.9967,10.7982,10.6065,10.4213,10.2423, $ 5.50 5.60 5.70 5.80 5.90 6.00 6.10 6.20 6.30 , 10.0692, 9.9017, 9.7395, 9.5824, 9.4302, 9.2827, 9.1396, 9.0008, 8.8660, $ 6.40 6.50 6.60 6.70 6.80 6.90 7.00 7.10 7.20 , 8.7352, 8.6081, 8.4845, 8.3645, 8.2477, 8.1341, 8.0235, 7.9159, 7.8111, $ 7.30 7.40 7.50 7.60 7.70 7.80 7.90 8.00 8.10 , 7.7090, 7.6094, 7.5125, 7.4179, 7.3256, 7.2356, 7.1478, 7.0621, 6.9784, $ 8.20 8.30 8.40 8.50 8.60 8.70 8.80 8.90 9.00 , 6.8966, 6.8167, 6.7387, 6.6624, 6.5878, 6.5148, 6.4435, 6.3737, 6.3054, $ 9.10 9.20 9.30 9.40 9.50 9.60 9.70 9.80 9.90 , 6.2385, 6.1730, 6.1089, 6.0462, 5.9847, 5.9244, 5.8653, 5.8075, 5.7507, $ 10.00 10.50 11.00 11.50 12.00 12.50 13.00 13.50 14.00 , 5.6951, 5.4323, 5.1929, 4.9739, 4.7728, 4.5876, 4.4164, 4.2578, 4.1104, $ 14.50 15.00 15.50 16.00 16.50 17.00 17.50 18.00 18.50 , 3.9731, 3.8449, 3.7250, 3.6125, 3.5069, 3.4075, 3.3138, 3.2253, 3.1417, $ 19.00 19.50 20.00 20.50 21.00 21.50 22.00 22.50 23.00 , 3.0625, 2.9874, 2.9160, 2.8483, 2.7838, 2.7223, 2.6637, 2.6078, 2.5543, $ 23.50 24.00 24.50 25.00 25.50 26.00 26.50 27.00 27.50 , 2.5032, 2.4542, 2.4073, 2.3624, 2.3192, 2.2778, 2.2380, 2.1997, 2.1629, $ 28.00 28.50 29.00 29.50 30.00 30.50 31.00 31.50 32.00 , 2.1274, 2.0932, 2.0603, 2.0285, 1.9979, 1.9683, 1.9397, 1.9121, 1.8854, $ 32.50 33.00 33.50 34.00 34.50 35.00 35.50 36.00 36.50 , 1.8595, 1.8345, 1.8103, 1.7869, 1.7642, 1.7422, 1.7209, 1.7002, 1.6801, $ 37.00 37.50 38.00 38.50 39.00 39.50 40.00 40.50 41.00 , 1.6606, 1.6417, 1.6233, 1.6055, 1.5882, 1.5713, 1.5549, 1.5390, 1.5235, $ 41.50 42.00 42.50 43.00 43.50 44.00 44.50 45.00 45.50 , 1.5085, 1.4938, 1.4796, 1.4657, 1.4522, 1.4390, 1.4262, 1.4137, 1.4016, $ 46.00 46.50 47.00 47.50 48.00 48.50 49.00 49.50 50.00 , 1.3897, 1.3782, 1.3669, 1.3559, 1.3452, 1.3348, 1.3247, 1.3147, 1.3051, $ 50.50 51.00 51.50 52.00 52.50 53.00 53.50 54.00 54.50 , 1.2957, 1.2865, 1.2775, 1.2687, 1.2602, 1.2519, 1.2438, 1.2358, 1.2281, $ 55.00 55.50 56.00 56.50 57.00 57.50 58.00 58.50 59.00 , 1.2206, 1.2132, 1.2060, 1.1990, 1.1922, 1.1855, 1.1790, 1.1727, 1.1665, $ 59.50 60.00 60.50 61.00 61.50 62.00 62.50 63.00 63.50 , 1.1604, 1.1546, 1.1488, 1.1432, 1.1378, 1.1325, 1.1273, 1.1222, 1.1173, $ 64.00 64.50 65.00 65.50 66.00 66.50 67.00 67.50 68.00 , 1.1125, 1.1078, 1.1033, 1.0989, 1.0946, 1.0904, 1.0863, 1.0823, 1.0785, $ 68.50 69.00 69.50 70.00 70.50 71.00 71.50 72.00 72.50 , 1.0747, 1.0711, 1.0676, 1.0641, 1.0608, 1.0576, 1.0545, 1.0514, 1.0485, $ 73.00 73.50 74.00 7 .50 75.00 75.50 76.00 76.50 77.00 , 1.0457, 1.0429, 1.0403, 1.0377, 1.0353, 1.0329, 1.0306, 1.0284, 1.0263, $ 77.50 78.00 78.50 79.00 79.50 80.00 80.50 81.00 81.50 , 1.0243, 1.0223, 1.0205, 1.0187, 1.0170, 1.0154, 1.0139, 1.0125, 1.0111, $ 82.00 82.50 83.00 83.50 84.00 84.50 85.00 85.50 86.00 , 1.0098, 1.0086, 1.0075, 1.0065, 1.0055, 1.0046, 1.0038, 1.0031, 1.0024, $ 86.50 87.00 87.50 88.00 88.50 89.00 89.50 90.00 , 1.0019, 1.0014, 1.0010, 1.0006, 1.0003, 1.0002, 1.0000, 1.0000, $ TABDRY(1) = 261*0.0D0, $ TABDRY(1) = $ .00 33.1457, $ .10 .20 .30 .40 .50 .60 .70 .80 .90 , 32.0301,30.9687,29.9582,28.9957,28.0787,27.2046,26.3712,25.5761,24.8173, $ 1.00 1.10 1.20 1.30 1.40 1.50 1.60 1.70 1.80 , 24.0929,23.4009,22.7396,22.1074,21.5028,20.9255,20.3703,19.8398,19.3314, $ 1.90 2.00 2.10 2.20 2.30 2.40 2.50 2.60 2.70 , 18.8441,18.3768,17.9283,17.4978,17.0843,16.6870,16.3051,15.9378,15.5844, $ 2.80 2.90 3.00 3.10 3.20 3.30 3.40 3.50 3.60 , 15.2443,14.9167,14.6011,14.2969,14.0036,13.7207,13.4476,13.1840,12.9294, $ 3.70 3.80 3.90 4.00 4.10 4.20 4.30 4.40 4.50 , 12.6834,12.4455,12.2156,11.9931,11.7778,11.5693,11.3675,11.1719,10.9823, $ 4.60 4.70 4.80 4.90 5.00 5.10 5.20 5.30 5.40 , 10.7985,10.6203,10.4473,10.2795,10.1165, 9.9523, 9.8046, 9.6552, 9.5099, $ 5.50 5.60 5.70 5.80 5.90 6.00 6.10 6.20 6.30 , 9.3687, 9.2313, 9.0976, 8.9675, 8.8408, 8.7175, 8.5973, 8.4802, 8.3661, $ 6.40 6.50 6.60 6.70 6.80 6.90 7.00 7.10 7.20 , 8.2548, 8.1463, 8.0405, 7.9373, 7.8365, 7.7382, 7.6421, 7.5484, 7.4567, $ 7.30 7.40 7.50 7.60 7.70 7.80 7.90 8.00 8.10 , 7.3672, 7.2798, 7.1943, 7.1107, 7.0289, 6.9490, 6.8707, 6.7942, 6.7193, $ 8.20 8.30 8.40 8.50 8.60 8.70 8.80 8.90 9.00 , 6.6459, 6.5741, 6.5038, 6.4349, 6.3675, 6.3014, 6.2366, 6.1731, 6.1108, $ 9.10 9.20 9.30 9.40 9.50 9.60 9.70 9.80 9.90 , 6.0529, 5.9930, 5.9342, 5.8735, 5.8170, 5.7615, 5.7071, 5.6537, 5.6012, $ 10.00 10.50 11.00 11.50 12.00 12.50 13.00 13.50 14.00 , 5.5497, 5.3055, 5.0773, 4.8761, 4.6863, 4.5106, 4.3477, 4.1963, 4.0551, $ 14.50 15.00 15.50 16.00 16.50 17.00 17.50 18.00 18.50 , 3.9232, 3.7998, 3.6840, 3.5753, 3.4729, 3.3764, 3.2853, 3.1992, 3.1176, $ 19.00 19.50 20.00 20.50 21.00 21.50 22.00 22.50 23.00 , 3.0403, 2.9668, 2.8971, 2.8307, 2.7674, 2.7071, 2.6496, 2.5946, 2.5420, $ 23.50 24.00 24.50 25.00 25.50 26.00 26.50 27.00 27.50 , 2.4917, 2.4434, 2.3972, 2.3529, 2.3103, 2.2694, 2.2301, 2.1923, 2.1559, $ 28.00 28.50 29.00 29.50 30.00 30.50 31.00 31.50 32.00 , 2.1208, 2.0870, 2.0544, 2.0230, 1.9926, 1.9633, 1.9350, 1.9076, 1.8811, $ 32.50 33.00 33.50 34.00 34.50 35.00 35.50 36.00 36.50 , 1.8555, 1.8307, 1.8067, 1.7834, 1.7609, 1.7391, 1.7179, 1.6973, 1.6774, $ 37.00 37.50 38.00 38.50 39.00 39.50 40.00 40.50 41.00 , 1.6580, 1.6392, 1.6210, 1.6033, 1.5860, 1.5693, 1.5530, 1.5372, 1.5218, $ 41.50 42.00 42.50 43.00 43.50 44.00 44.50 45.00 45.50 , 1.5068, 1.4922, 1.4780, 1.4642, 1.4507, 1.4376, 1.4249, 1.4125, 1.4004, $ 46.00 46.50 47.00 47.50 48.00 48.50 49.00 49.50 50.00 , 1.3886, 1.3771, 1.3659, 1.3549, 1.3443, 1.3339, 1.3238, 1.3139, 1.3043, $ 50.50 51.00 51.50 52.00 52.50 53.00 53.50 54.00 54.50 , 1.2949, 1.2857, 1.2768, 1.2681, 1.2596, 1.2513, 1.2432, 1.2353, 1.2276, $ 55.00 55.50 56.00 56.50 57.00 57.50 58.00 58.50 59.00 , 1.2200, 1.2127, 1.2055, 1.1986, 1.1917, 1.1851, 1.1786, 1.1723, 1.1661, $ 59.50 60.00 60.50 61.00 61.50 62.00 62.50 63.00 63.50 , 1.1601, 1.1542, 1.1485, 1.1429, 1.1375, 1.1322, 1.1270, 1.1220, 1.1171, $ 64.00 64.50 65.00 65.50 66.00 66.50 67.00 67.50 68.00 , 1.1123, 1.1076, 1.1031, 1.0987, 1.0944, 1.0902, 1.0861, 1.0822, 1.0783, $ 68.50 69.00 69.50 70.00 70.50 71.00 71.50 72.00 72.50 , 1.0746, 1.0709, 1.0674, 1.0640, 1.0607, 1.0575, 1.0543, 1.0513, 1.0484, $ 73.00 73.50 74.00 74.50 75.00 75.50 76.00 76.50 77.00 , 1.0456, 1.0428, 1.0402, 1.0377, 1.0352, 1.0328, 1.0305, 1.0283, 1.0262, $ 77.50 78.00 78.50 79.00 79.50 80.00 80.50 81.00 81.50 , 1.0242, 1.0223, 1.0204, 1.0187, 1.0170, 1.0154, 1.0139, 1.0124, 1.0111, $ 82.00 82.50 83.00 83.50 84.00 84.50 85.00 85.50 86.00 , 1.0098, 1.0086, 1.0075, 1.0065, 1.0055, 1.0046, 1.0038, 1.0031, 1.0024, $ 86.50 87.00 87.50 88.00 88.50 89.00 89.50 90.00 , 1.0019, 1.0014, 1.0010, 1.0006, 1.0003, 1.0002, 1.0000, 1.0000, $ $ End TAB table of 8/29/77 $ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$ $$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$$