CCSD3ZF0000100000001CCSD3VS00002MRK**001 /* VOLDESC.SFD file */ Vol_Ident: USA_NASA_NSSD_P11A_0001 /* Last four digits of succeeding volumes will be 0002, 0003, etc. */ Vol_Creation_Date: 1992-06-30 /* For example */ Medium_Description: Half-inch magnetic tape, 9 track, 6250 bpi Technical_Contact: Joyce Wolf Mail Stop 169-506 Jet Propulsion Laboratory 4800 Oak Grove Drive Pasadena, CA 91109 Electronic Mail (SPAN): JPLSP::JWOLF Phone: 818-354-7361 Prev_Vols: None /* or USA_NASA_NSSD_P11A_0001 USA_NASA_NSSD_P11A_0002, etc. */ CCSD$$MARKERMRK**001CCSD3SS00002MRK**002 Data_Set_Name: Pioneer 11 HVM Cruise Data Archive Data_Source: Pioneer 11 Helium Vector Magnetometer Scientific_Contact: Dr. Edward J. Smith Jet Propulsion Laboratory Mail Stop 169-506 4800 Oak Grove Drive Pasadena, CA 91109 Electronic Mail: JPLSP::ESMITH Telephone: 818-354-2248 Spacecraft_Characteristics: Launched in April of 1973, Pioneer 11 made its closest approach to Jupiter on Dec. 3, 1974. During late 1975 and early 1976, Pioneer 11 attained heliographic latitudes of 16 deg and higher; the sector structure of the IMF disappeared at these latitudes. On Sept. 1, 1979, Pioneer 11 made its closest approach to Saturn. Since then, it has been heading out of the Solar System, upstream with respect to the direction of the interstellar wind. It passed Neptune's orbit in 1990. The spacecraft spins at about 7.8 rpm, with the spin axis directed toward the Earth. It carries 12 instruments for measuring fields and particles, and is powered by radioisotope thermal generators (RTG's). Investigation_Objectives: The primary investigation objectives for the Pioneer 11 Helium Vector Magnetometer cruise data are to determine the large- scale structure and dynamics of the interplanetary magnetic field in the outer solar system and to study how they are influenced by changing solar activity, and the interaction of the solar wind with the interstellar medium. Instrument_Attributes: A. Instrument_Description: The Helium Vector Magnetometer produces measurements of the 3 orthogonal components of the ambient magnetic field in a 0-3 Hz passband. The instrument switches automatically among 8 ranges, plus or minus 4, 14, 42, 144, 640, 4000, 22000, and 140000 nT. The measurements are digitized to 8 bits and a sign bit, giving a sensitivity of 1/256 of full- scale in each range. For more information, refer to Smith, E. J., B. V. Connor, and G. T. Foster, Jr., "Measuring the magnetic fields of Jupiter and the outer solar system," IEEE Trans. Magn., vol. MAG-11, pp. 962-980, 1975. B. Instrument_Performance: The instrument has functioned normally throughout the mission. C. Measured_Parameters: Three orthogonal components of magnetic field; the third component is parallel to the spacecraft spin axis. D. Instrument_Accuracy: Two factors determine the accuracy with which each component of the field is determined. One is the scale factor relating the change in field to the corres-ponding change in output voltage. The straight line representing this scale factor intercepts the B axis (V = 0) at a non- zero value (the instrument "offset" or "zero level"). The HVM is operated in a feedback mode so that the scale factor is highly linear and very stable. An in-flight calibration (IFC) is incorporated into the instrument such that, on receipt of a command, carefully calibrated step field changes are applied to the sensor to produce an end-to-end calibration of all three axes. During the lifetime of Pioneer 10 and 11, we performed an in-flight calibration approximately every two weeks. No change in instrument response as large as one bit has ever been observed on either instrument. Thus, the scale factors are considered known to within 0.25 percent, and, accordingly, the errors are negligible. Accurate estimates of the offsets must be determined in flight. Since Pioneer 11 is a spinning spacecraft with two magnetometer axes lying in the spin plane, two of the offsets can be continuously monitored by averaging the data on a given axis over a large number of revolutions. By analyzing the results over many long intervals, it is estimated that these two offsets are being determined to within 0.005 nT. Since the spin axis is continuously oriented toward Earth and is very nearly radial at large distances (about 30 AU) the two transverse components (B-Theta and B-Phi) are extremely well known. At 30 AU, the field magnitude, B, is typically 0.2 nT and the relative accuracy is, therefore, about 2.5 percent. The offset on the sensor axis parallel to the spin axis is more difficult to determine. We use the method developed by Davis and Smith (also independently developed by Hedgecock), as improved upon by Belcher. The basis of this so- called variance method is to choose the BZ offset so as to reduce the variations in B-magnitude to a minimum in the least squares sense. Experience indicates that the method yields a relative accuracy of greater than 5 percent. For Pioneer 11 we estimate that the offset is known to about 0.02 nT so that in a typical field of 0.2 nT, the offset is determined to within about 10 percent. This number is probably conservative and we may actually be doing slightly better. Data_Set_Parameters: Averages of field components (BX, BY, BZ); averages of squares and crossproducts of components (BX2, BY2, BZ2 and BXBY, BXBZ, BYBZ); averages of field direction cosines (BXCOS, BYCOS, BZCOS); average of field magnitude (BMAG) and average of square of field magnitude (BMAG2). Heliocentric positions of the spacecraft and Earth, referred to the ecliptic and equinox of date, are also included. Data_Set_Quality: There are no significant known errors in the data; however, in 1987 and afterward, the cyclic switching on and off of other instruments on Pioneer 11 caused random fluctuations of the instrument's Z axis zero levels. These fluctuations are of the order of 0.05 nT, with a period of several days. We have been able to remove most, but not all, of these fluctuations. Data_Processing_Overview: Data reduction until 1976 was done on an IBM 7044 and a Univac 1108; after that time a SEL/32 was used. Raw data points consisted of Ground Received Time, triaxial magnetometer measurements in counts (0 to 511), and magnetometer range (0 to 7). Each measurement was converted into nanotesla using range-dependent scaling factors and offsets. Spin-plane offsets were calculated daily by averaging spinning data. The other offset (parallel to the spin axis) was estimated over periods of several weeks using either the Leverett Davis method of minimizing the variance of the square of the magnitude, or John Belcher's variation of that method. The magnetic field vectors were then despun into spacecraft inertial coordinates and rotated through the roll angle CKAH (Clock Angle of Sun, provided by Ames in File 3 on our EDR tapes). In this PE coordinate system, field vectors from 1976 and later were written onto RDR (Reduced Data Record) tapes. Prior to 1976, data were transformed from PE to SH (or SJ during Jupiter Encounter) before being written onto the RDR tapes. (In the PE system, Z is along the Pioneer spin axis, nominally toward Earth, and X lies in the plane containing the directions from Pioneer to the Earth and Sun and is orthogonal to the spin axis, Z. In SH, also known as Radial-Tangential- Normal, X is the Sun-to-Pioneer direction and Y is parallel to the Sun's equatorial plane. For a complete definition of these systems, see the description of COORDSYS in file FORMAT.SFD.) From the RDR tapes, Ground Received Time 1-minute, 1-hour, and 1-day averages of the field components, crossproducts of components, squares of components, direction cosines of components, field magnitude, and square of field magnitude were calculated and submitted on tapes to NSSDC. For this cruise data archive, each 15-minute (or 1 hour) Spacecraft Event Time parameter average has been constructed from those GRT 1-minute parameter averages whose midpoints (converted to SCET) lie within the SCET averaging interval. The number of seconds in each minute for which data existed was used as a weighting factor. Averages in PE coordinates have been converted to SH. Lit_References: Smith, E. J., B. V. Connor, and G. T. Foster, Jr., "Measuring the magnetic fields of Jupiter and the outer solar system," IEEE Trans. Magn., vol. MAG-11, pp. 962-980, 1975. Smith, E. J., et al., "Saturn's Magnetosphere and Its Interaction with the Solar Wind," J. Geophys. Res., vol. 85, pp. 5655-5674, 1980. Smith, E.J., D. Winterhalter, and J. A. Slavin, "Recent Pioneer 11 observations of the distant heliospheric magnetic field," Solar Wind 6, eds. V.J. Pizzo, T.E. Holzer, and D.G. Sime, NCAR/TN-306, HAO/NCAR, Boulder, Colorado, 1988, p. 581. Other references may be found in these articles. CCSD$$MARKERMRK**002CCSD3KS00002MRK**003 Vol_Time_Coverage: 1973-04-05 to 1973-12-31 /* for example */ File_Naming_Convention: Pioneer 11 HVM average files are named according to the time of the data in the file as follows: HVM_P11_yyz.DAT, where yy stands for the last two digits of the year, and z is either A for the first six months of the year or B for the last six months of the year. File_Time_Coverage: File HVM_P11_73A.DAT 1973-04-05 through 1973-06-30. File HVM_P11_73B.DAT 1973-07-01 through 1973-12-31. /* Above time coverages are only for files on the present data volume. */ /* Time Coverages of files on other data volumes are as follows: File HVM_P11_74A.DAT 1974-01-01 through 1974-06-30. File HVM_P11_74B.DAT 1974-07-01 through 1974-12-31. File HVM_P11_75A.DAT 1975-01-01 through 1975-06-30. File HVM_P11_75B.DAT 1975-07-01 through 1975-12-31. File HVM_P11_76A.DAT 1976-01-01 through 1976-06-30. File HVM_P11_76B.DAT 1976-07-01 through 1976-12-31. File HVM_P11_77A.DAT 1977-01-01 through 1977-06-30. File HVM_P11_77B.DAT 1977-07-01 through 1977-12-31. File HVM_P11_78A.DAT 1978-01-01 through 1978-06-30. File HVM_P11_78B.DAT 1978-07-01 through 1978-12-31. File HVM_P11_79A.DAT 1979-01-01 through 1979-06-30. File HVM_P11_79B.DAT 1979-07-01 through 1979-12-31. File HVM_P11_80A.DAT 1980-01-01 through 1980-06-30. File HVM_P11_80B.DAT 1980-07-01 through 1980-12-31. File HVM_P11_81A.DAT 1981-01-01 through 1981-06-30. File HVM_P11_81B.DAT 1981-07-01 through 1981-12-31. File HVM_P11_82A.DAT 1982-01-01 through 1982-06-30. File HVM_P11_82B.DAT 1982-07-01 through 1982-12-31. File HVM_P11_83A.DAT 1983-01-01 through 1983-06-30. File HVM_P11_83B.DAT 1983-07-01 through 1983-12-31. File HVM_P11_84A.DAT 1984-01-01 through 1984-06-30. File HVM_P11_84B.DAT 1984-07-01 through 1984-12-31. File HVM_P11_85A.DAT 1985-01-01 through 1985-06-30. File HVM_P11_85B.DAT 1985-07-01 through 1985-12-31. File HVM_P11_86A.DAT 1986-01-01 through 1986-06-30. File HVM_P11_86B.DAT 1986-07-01 through 1986-12-31. File HVM_P11_87A.DAT 1987-01-01 through 1987-06-30. File HVM_P11_87B.DAT 1987-07-01 through 1987-12-31. File HVM_P11_88A.DAT 1988-01-01 through 1988-06-30. File HVM_P11_88B.DAT 1988-07-01 through 1988-12-31. File HVM_P11_89A.DAT 1989-01-01 through 1989-06-30. File HVM_P11_89B.DAT 1989-07-01 through 1989-12-31. File HVM_P11_90A.DAT 1990-01-01 through 1990-06-30. File HVM_P11_90B.DAT 1990-07-01 through 1990-12-31. File HVM_P11_91A.DAT 1991-01-01 through 1991-06-30. File HVM_P11_91B.DAT 1991-07-01 through 1991-12-31. File HVM_P11_92A.DAT 1992-01-01 through 1992-03-31. */ CCSD$$MARKERMRK**003CCSD3RF0000300000001 REFERENCETYPE=$VMS; LABEL=ATTACHED; REFERENCE=FORMAT.SFD; LABEL=NSSD3IF0012200000001; REFERENCE=HVM_P11_*.DAT; /* End of file occurs here */ /* format file begins at next record */ CCSD3FF0000500000001CCSD3CS00004MRK**001 ADIDNAME=NSSD0122; CCSD$$MARKERMRK**001CCSD3KS00002MRK**002 Subm_Name: Joyce Wolf Subm_Addr: Mail Stop 169-506 Jet Propulsion Laboratory 4800 Oak Grove Drive Pasadena, CA 91109 Telephone: 818-354-7361 Electronic Mail (SPAN): JPLSP::JWOLF Subm_Date: 1992-05-03 Title: Format for Pioneer 11 HVM Cruise Data Archive Descr: Format description of the Pioneer 11 Helium Vector Magnetometer cruise phase archive data set, March 1973 through March 1992. Rel_Date: 1992-06-01 CCSD$$MARKERMRK**002CCSD3DF0000200000001 File_Class_Name: HVM_AVG_FILE Record_Type_Names: HVM_AVG_REC File_Class_Syntax: All records in the Pioneer 10 and 11 HVM cruise phase data archive are of the same type, size, and format. Record_Name: HVM_AVG_REC Record_Structure: Fixed length records; no record terminators. Record_Length: 372 bytes (each byte is one ASCII character) Record_Field_Names: STARTAV, COORDSYS, LENGTHAV, TOTDATA, SCETFIRST, SCETLAST, GRTFIRST, GRTLAST, BX, BY, BZ, BX2, BXBY, BXBZ, BY2, BYBZ, BZ2, BXCOS, BYCOS, BZCOS, BMAG, BMAG2, HRANGP, CELLTP, CELLNP, REARSU, CELLTE, CELLNE, BLANK Record_Syntax: There are 29 fields in each record. SCET indicates Spacecraft Event Time; GRT indicates Ground Received Time. If no data exists for a particular averaging interval, TOTDATA = 0, and fields 5 through 22 are also set to zero. FIELD NAME FORMAT BRIEF DESCRIPTION 1 STARTAV A16 SCET start of averaging interval (Time Code A) 2 COORDSYS 1X,A2 Coordinate System Identifier 3 LENGTHAV 1X,I5 Length of averaging interval in seconds 4 TOTDATA 1X,F9.3 Total seconds of data included in this interval 5 SCETFIRST 1X,F9.3 SCET of first data in this interval (sec of day) 6 SCETLAST 1X,F9.3 SCET of last data in this interval (sec of day) 7 GRTFIRST 1X,F7.0 GRT of first data in this interval (sec of day) 8 GRTLAST 1X,F7.0 GRT of last data in this interval (sec of day) 9 BX 1X,E14.6 Average of X component of field 10 BY 1X,E14.6 Average of Y component of field 11 BZ 1X,E14.6 Average of Z component of field 12 BX2 1X,E14.6 Average of square of X component 13 BXBY 1X,E14.6 Average of product of X and Y components 14 BXBZ 1X,E14.6 Average of product of X and Z components 15 BY2 1X,E14.6 Average of square of Y component 16 BYBZ 1X,E14.6 Average of product of Y and Z components 17 BZ2 1X,E14.6 Average of square of Z component 18 BXCOS 1X,E14.6 Average of X direction cosine of field 19 BYCOS 1X,E14.6 Average of Y direction cosine of field 20 BZCOS 1X,E14.6 Average of Z direction cosine of field 21 BMAG 1X,E14.6 Average of field magnitude 22 BMAG2 1X,E14.6 Average of square of field magnitude 23 HRANGP 1X,E14.6 Distance of spacecraft from Sun 24 CELLTP 1X,E14.6 Heliocentric celestial latitude of spacecraft 25 CELLNP 1X,E14.6 Heliocentric celestial longitude of spacecraft 26 REARSU 1X,E14.6 Distance of Earth from Sun 27 CELLTE 1X,E14.6 Heliocentric celestial latitude of Earth 28 CELLNE 1X,E14.6 Heliocentric celestial longitude of Earth 29 BLANK 1X One blank Field_Name: SCET Start of averaging interval Field_Mnemonic: STARTAV Field_Units: ASCII Timecode A (YYYY-MM-DDThh:mm in UTC) Field_Resolution: 1 Minute Field_Range: 1973-04-06T00:00 to 1992-06-30T23:59 Field_Description: Spacecraft event time of start of averaging interval. The subfield YYYY is the four digit year, MM is the month (01 to 12), DD is the day of month (01 to 31), hh represents hours (00 to 23), and mm represents minutes (00 to 59). For hour averages, the minutes subfield will always be '00', and for 15-minute averages, it will be '00' or '15' or '30' or '45'. Field_Representation: 16 ASCII characters (I4,'-',I2,'-',I2,'T',I2,':',I2) Field_Name: Coordinate System Identifier Field_Mnemonic: COORDSYS Field_Units: Not applicable Field_Range: Value is ' SH' or ' SJ' or ' PE' Field_Description: Coordinate System identifier for the field vector components. The SH system has its X axis in the Sun-to-Pioneer direction; Y is the unit vector in the direction of the cross-product H x X, where H is the Sun's rotation axis; Z = X x Y. Referred to the mean equinox and ecliptic of date, the components of H are 0.126199 COS(A), 0.126199 SIN(A), 0.992005, where A = -14.6304 + .0139583(t-1972.0) deg, t = year. The SJ system has its X axis in the Pioneer-to-Sun direction; Y is the unit vector in the direction J x X, where J is Jupiter's rotation axis; and Z = X x Y. J = (-0.01448, -0.03482, 0.99929), referred to mean equinox and ecliptic of 1974.0. The PE system has its Z axis along Pioneer's spin axis, which nominally points toward the Earth; its X axis is the unit vector in the direction E x Z, where E is the north perpendicular to the Ecliptic; and Y = Z x X. Field_Representation: 3 ASCII characters (1X,A2) Field_Name: Length of averaging interval in seconds Field_Mnemonic: LENGTHAV Field_Units: Seconds Field_Resolution: 1 second Field_Range: Always equal to 3600 for hour averages, 900 for 15-minute averages. Field_Description: Number of seconds in averaging interval. Field_Representation: 6 ASCII characters (1X,I5) Field_Name: Total seconds of data included in this interval Field_Mnemonic: TOTDATA Field_Units: Seconds Field_Resolution: .001 sec. Field_Range: 0 to 3612 for hour averages; 0 through 912 for 15-minute averages. Field_Description: This value is the sum of the sample time for each high resolution data point included in the averages. The sampling time varied with bit rate; at the highest bit rate of 2048 bps, the time between successive points was 3/32 sec; at the lowest rate of 16 bps, it is 12 sec. (Bit rates typically changed several times during a day.) A value of zero means that there was no data at all during the averaging interval. The value of TOTDATA should be used as a weighting factor when using a number of these averages to compute averages over a longer time interval. Field_Representation: 10 ASCII characters (1X,F9.3) Field_Name: SCET of first data for this interval (sec of day) Field_Mnemonic: SCETFIRST Field_Units: Seconds from start of day Field_Resolution: .001 sec. Field_Range: 0 to 86400 Field_Description: Spacecraft event time of the midpoint of the first GRT (Ground Received Time) 1-minute interval with data that is included in this averaging interval, measured in seconds from start of day specified in STARTAV. Field_Representation: 10 ASCII characters (1X,F9.3) Field_Name: SCET of last data for this interval (sec of day) Field_Mnemonic: SCETLAST Field_Units: Seconds from start of day Field_Resolution: .001 sec. Field_Range: 0 to 86400 Field_Description: Spacecraft event time of the midpoint of the last GRT (Ground Received Time) 1-minute interval with data that is included in this averaging interval, measured in seconds from start of day specified in STARTAV. Field_Representation: 10 ASCII characters (1X,F9.3) Field_Name: GRT of first data for this interval (sec of day) Field_Mnemonic: GRTFIRST Field_Units: Seconds from start of day Field_Resolution: 1 sec. Field_Range: 0 through 108000 Field_Description: Ground Received time of the midpoint of the first 1-minute interval with data that is included in this averaging interval, measured in seconds from start of day specified in STARTAV. Field range allows for up to 6 hours one-way light time. Field_Representation: 8 ASCII characters (1X,F7.0) Field_Name: GRT of last data for this interval (sec of day) Field_Mnemonic: GRTLAST Field_Units: Seconds from start of day Field_Resolution: 1 sec. Field_Range: 0 through 108000 Field_Description: Ground Received time of the midpoint of the last 1-minute interval with data that is included in this averaging interval, measured in seconds from start of day specified in STARTAV. Field range allows for up to 6 hours one-way light time. Field_Representation: 8 ASCII characters (1X,F7.0) Field_Name: Average of X component of field Field_Mnemonic: BX Field_Units: Nanotesla Field_Range: -1.4E5 to 1.4E5 (instrument limits) Field_Description: Average of X Component of magnetic field vector Field_Representation: 15 ASCII characters (1X,E14.6) Field_Name: Average of Y component of field Field_Mnemonic: BY Field_Units: Nanotesla Field_Range: -1.4E5 to 1.4E5 (instrument limits) Field_Description: Average of Y Component of magnetic field vector Field_Representation: 15 ASCII characters (1X,E14.6) Field_Name: Average of Z component of field Field_Mnemonic: BZ Field_Units: Nanotesla Field_Range: -1.4E5 to 1.4E5 (instrument limits) Field_Description: Average of Z Component of magnetic field vector Field_Representation: 15 ASCII characters (1X,E14.6) Field_Name: Average of square of X component Field_Mnemonic: BX2 Field_Units: Nanotesla squared Field_Range: 0 to 1.9E10 (instrument limits) Field_Description: Average of square of X component of magnetic field vector. Field_Representation: 15 ASCII characters (1X,E14.6) Field_Name: Average of product of X and Y components Field_Mnemonic: BXBY Field_Units: Nanotesla squared Field_Range: -1.9E10 to 1.9E10 (instrument limits) Field_Description: Average of product of X and Y components of magnetic field vector. Field_Representation: 15 ASCII characters (1X,E14.6) Field_Name: Average of product of X and Z components Field_Mnemonic: BXBZ Field_Units: Nanotesla squared Field_Range: -1.9E10 to 1.9E10 (instrument limits) Field_Description: Average of product of X and Z components of magnetic field vector. Field_Representation: 15 ASCII characters (1X,E14.6) Field_Name: Average of square of Y component Field_Mnemonic: BY2 Field_Units: Nanotesla squared Field_Range: 0 to 1.9E10 (instrument limits) Field_Description: Average of square of Y component of magnetic field vector Field_Representation: 15 ASCII characters (1X,E14.6) Field_Name: Average of product of Y and Z components Field_Mnemonic: BYBZ Field_Units: Nanotesla squared Field_Range: 0 to 1.9E10 (instrument limits) Field_Description: Average of product of Y and Z components of magnetic field vector Field_Representation: 15 ASCII characters (1X,E14.6) Field_Name: Average of square of Z component Field_Mnemonic: BZ2 Field_Units: Nanotesla squared Field_Range: -1.9E10 to 1.9E10 (instrument limits) Field_Description: Average of square of Z component of magnetic field vector Field_Representation: 15 ASCII characters (1X,E14.6) Field_Name: Average of X direction cosine of field Field_Mnemonic: BXCOS Field_Units: Unitless number Field_Range: -1 to +1 Field_Description: Average of the quotient of the X component divided by the magnitude of the magnetic field vector Field_Representation: 15 ASCII characters (1X,E14.6) Field_Name: Average of Y direction cosine of field Field_Mnemonic: BYCOS Field_Units: Unitless number Field_Range: -1 to +1 Field_Description: Average of the quotient of the Y component divided by the magnitude of the magnetic field vector Field_Representation: 15 ASCII characters (1X,E14.6) Field_Name: Average of Z direction cosine of field Field_Mnemonic: BZCOS Field_Units: Unitless number Field_Range: -1 to +1 Field_Description: Average of the quotient of the Z component divided by the magnitude of the magnetic field vector Field_Representation: 15 ASCII characters (1X,E14.6) Field_Name: Average of field magnitude Field_Mnemonic: BMAG Field_Units: Nanotesla Field_Range: 0 to 2.4E5 (instrument limits) Field_Description: Average of the magnitude of the magnetic field vector Field_Representation: 15 ASCII characters (1X,E14.6) Field_Name: Average of square of field magnitude Field_Mnemonic: BMAG2 Field_Units: Nanotesla squared Field_Range: 0 to 5.8E10 (instrument limits) Field_Description: Average of the square of the magnitude of the magnetic field vector Field_Representation: 15 ASCII characters (1X,E14.6) Field_Name: Distance of spacecraft from Sun Field_Mnemonic: HRANGP Field_Units: Kilometers Field_Range: 1.E8 to 1.E10 Field_Description: Distance of the spacecraft from the Sun at the start of the averaging interval Field_Representation: 15 ASCII characters (1X,E14.6) Field_Name: Heliocentric celestial latitude of the spacecraft Field_Mnemonic: CELLTP Field_Units: Degrees Field_Range: -90 to 90 Field_Description: Heliocentric latitude of the spacecraft at the start of the averaging interval, referred to Ecliptic of date Field_Representation: 15 ASCII characters (1X,E14.6) Field_Name: Heliocentric celestial longitude of the spacecraft Field_Mnemonic: CELLNP Field_Units: Degrees Field_Range: 0 to 360 Field_Description: Heliocentric longitude of the spacecraft at the start of the averaging interval, referred to Ecliptic and Equinox of date Field_Representation: 15 ASCII characters (1X,E14.6) Field_Name: Distance of Earth from Sun Field_Mnemonic: REARSU Field_Units: Kilometers Field_Range: 1.4E8 to 1.6E8 Field_Description: Distance of Earth from the Sun at the start of the averaging interval Field_Representation: 15 ASCII characters (1X,E14.6) Field_Name: Heliocentric celestial latitude of Earth Field_Mnemonic: CELLTE Field_Units: Degrees Field_Range: -90 to 90 Field_Description: Heliocentric latitude of Earth at the start of the averaging interval, referred to Ecliptic of date Field_Representation: 15 ASCII characters (1X,E14.6) Field_Name: Heliocentric celestial longitude of Earth Field_Mnemonic: CELLNE Field_Units: Degrees Field_Range: 0 to 360 Field_Description: Heliocentric longitude of Earth at the start of the averaging interval, referred to Ecliptic and Equinox of date Field_Representation: 15 ASCII characters (1X,E14.6) Field_Name: One blank Field_Mnemonic: BLANK Field_Units: Not applicable Field_Range: Always blank Field_Description: One ASCII blank character Field_Representation: 1 ASCII character (1X) /* End of file occurs here */