Document title: Annotated_output_listing.txt for NDADS DE EICS datatype Project: DE NDADS Datatype: EICS Super-EID: DOCUMENT There may be other documents also identified by this super-EID. NDADS filename: EICS_ANNOTATED_OUTPUT_LISTING.TXT TRF entry B46584.txt in NSSDC's controlled digital document library. Feb. 1998. Document text follows: ---------------------- ANNOTATED_OUTPUT_LISTING.TXT W.K. Peterson July, 1989 Annotated output listings from the general purpose EICS analysis program EICS.EXE described in the file TEXT_DESCRIBING_THE_ANALYSIS_SOFTWARE.TXT >NOTE: in the following lines beginning with the symbol ">" are annotation >other lines are actual output from the code that have been "captured" >and included in this file. > > > This test output has been obtained from the EICS SATF file >EICS_84004A_1416_1616_T76.DAT. The entry in the EICS SATF INDEX >(CATALOG) for this file shows that it includes data from ~14:16 to >~16:16 on day 004 of 1984. The entry is reproduced below. (note that >the A in the seventh column indicates that spin-phase attitude >information is not available for this interval, therefore we must >use only pitch angle binning (normal or 360 degree) >--- 84004A 900 1416 1616 51360000 58557102 A T76 07/21/86 >---- >Following the instructions on use of the general purpose analysis >program we entered the file name and selected times (items 2 and 3) >from 15:00:00 to 15:05:00. Default options were used for all parameters; >specifically, a single average is returned for the entire interval with >8 normal pitch angle bins and with a standard listing of the output in >Flux units. > >The following diagnostic lines were output to the screen when the program >was run: These outputs are normal. This code runs on several >overcommitted computer systems. The rate at which these diagnostic >lines appear on the screen is a measure of the loading of the computer >system. :UNFLAG 4/16/81 CALESTP: 13 MAY 81 $$$$$$$$$$$NEW IEFLG IN CALESTP 2 $$$$$$$ CALMSTP: 16 JULY 81 from fpacum times, jrtcode 84004 53999522 84004 54299996 31248 0 CONVERTING TO FLUX Outputting /FPBUF/ to unit 108 the DCBS must be set >Two files were created in the current working directory: > NAME Size in VAX Blocks FOR007.DAT;1 1/3 FOR108.DAT;1 67/69 > >The file FOR007.dat;1 contained the following line: Spinfo: 34 33 1 4 192 2 0 84004 54195025 31251 50 1 > > If the telemetry data stream is noisy, an additional file named >FOR009.DAT will be created which will contain one line for each four >second block of data omitted from the average because of incomplete >telemetry. > The two lines below are from a FOR009.DAT file which did have incomplete >telemetry Major frame skipped in kwikvert due to fill data. 84004 51372996 Major frame skipped in kwikvert due to fill data. 84004 51372996 >The File FOR108.DAT;1 contains over 800 lines. The output consists of a >header block of 11 lines, a trailer block of 7 lines, and the bulk of the >output listing the selected geophysical unit (counts, count rate, flux, or >velocity space density) for each angle bin for up to 32 energy steps and >up to 4 selected masses. The output will be described in three sections: > The header block, the trailer block, and the average geophysical unit >listing > > > THE HEADER BLOCK > >The 11 lines of the header block for the example output are: TIMES FOR THE ACCUMULATION: 84004 53999522 84004 54299996 31248 FPACUM USED IAFLG, NSPINS, NGPAR: 0 51 13 BKGS(2,4) 0.323E-01 0.741E-02 0.323E-01 0.741E-02 0.000E+00 0.000E+00 0.340E- 02 0.241E-02 ICJFCODES 2 2 BACKGROUND IS SUBTRACTED AVERAGE B FIELD -531.41 -221.70 22.01 576.22 IMQFLG, IMDCODE, IECODE, IEDCODE, NANG, 2 2 2 2 8 XMQ(*,1): 1.00 16.00 0.00 0.00 XMQ(*,2): 9.00 50.00 0.00 0.00 IESTP(32): 1 2 3 4 5 6 8 10 12 14 17 20 24 28 32 65 66 67 68 69 70 71 7 3 75 78 81 84 87 90 93 96 0 STATUS VARIABLES: 8 0 0 0 0 0 0 0 1 1 3 SUB SUBS: 1 0 0 0 0 1 1 1 1 0 0 60 0 0 0 18 3 1 1 1 1 1 1 2 1 > > The first line of the header gives the start and stop times included in >the average, the times reported are the first and last accumulation >intervals (~1/32 of a second periods) included in the averages. The basic >structure of the telemetry is such that start and stop times can be >specified no finer than at a 0.5 second granularity. Thus specifying >the interval 15:00:00 (54000 seconds) to 15:05:00 (54300) seconds results >in an actual accumulation period. from 53999.522 to 54299.996 seconds. > TIMES FOR THE ACCUMULATION: 84004 53999522 84004 54299996 31248 > > The second line reports the angular binning method selected (IAFLG), the >number of spacecraft spin periods (including partial spin periods) in the >accumulation interval (NSPINS), and the number of instrumental cycles >started during the interval (NGPAR). > The Angle binning code, IAFLG, is selected using option 10 of the EICS >program: The 4 possible options are: >0: Normal (180 degree) pitch angle 1: Spin phase (ram) angle >2: Spin (360 degree) pitch angle > When there are gaps in the telemetry, the number of spin periods (NSPINS) and >instrumental cycles begun (NGPAR) may be less than that indicated by the >start and stop times. In the example here we used normal (180 degree) >pitch angle to bin the data. The accumulation interval included 51 spin >periods and the start of 13 instrumental cycles. > FPACUM USED IAFLG, NSPINS, NGPAR: 0 51 13 > >The third line gives the background counting rates and one sigma >uncertainty in the rate calculated using from the total number of >background counts observed in each of the two levels of mass detector >threshold (MD1/MD2) and energy detector threshold. The units are in >counts per sample. The line is longer than 80 characters and so will >spill off the side of an 80 character wide terminal. However the mass >detector counting rates and uncertainties are given first. The order >is background counting rate followed by uncertainty for the higher MD1 >threshold followed by the same pair of numbers for the lower MD2 >threshold and then the background numbers for the two possible energy >detectors. > We used the default selection for option 6 (MD2) so the appropriate >background counting rate for this interval is 0.0323 counts/sample >with a one sigma uncertainty of +/- 0.00741 counts/sample (the third >and fourth numbers in the third line of the header block. > We also used the default selection for option 7. During the >accumulation interval only ED2 was sampled so there is no background >counting rate reported for ED1, the fifth and sixth numbers in the >background line are zeros. The background counting rate and uncertainty >for ED2 are 0.0034 +/- 0.00241 counts per sample > BKGS(2,4) 0.323E-01 0.741E-02 0.323E-01 0.741E-02 0.000E+00 0.000E+00 0.340E- 02 0.241E-02 > > > The fourth line of the header gives a code (ICJFCODE) indicating the units >of the geophysical units reported in the main body of the listing and an >annotation indicating that background has been subtracted in all of the >numbers reported. (We have a diagnostic program that uses a similar output >format that does not subtract background). > The code reported for the units is the one used in option 15 to select >the units. >Final output format codes: > 0: Counts 1: Counts/Sample 2: Flux 3: Phase Space Density >The default is Flux (2), but you can select total counts (0), >counts/sample (1) or phase (velocity) space density(3). The units are >total counts, counts per instrument accumulation period, number >flux in units of 1/(cm^2-sec-sr-keV), and velocity space density in >units of sec^3/km^6. > The code is listed twice. The first entry is a record of what units were >requested and the second entry is updated when the conversion from raw >counts to the final units is preformed. ICJFCODES 2 2 BACKGROUND IS SUBTRACTED > >The fifth line should be ignored. The values reported are meaningless >We had planned to report an average magnetic field in appropriate >coordinates on this line, but this feature was never implemented. >For magnetometer data consult the archive of DE-1 magnetometer data. AVERAGE B FIELD -531.41 -221.70 22.01 576.22 > > The sixth line of the header reports codes for four of the selectable >options and the total number of masses included in the bulk of the >listing. Specifically: > IMQFLG is a number from 0 to 4 indicating the number of masses included >in the bulk of the listing. In this listing data for two masses are >reported > IMDCODE indicates if the MD1 or MD2 detector threshold data are selected >(Option #6) For this output we used the default MD2 detector. > IECODE is the Energy Detector (ED) selection made using Option #7. We >chose the default selection (0). The program then uses the data from >the first energy detector it encounters which in this interval was ED2. >IEDCODE indicates which of the three possible sets of energy step >information was selected by option #8. In this interval the default >selection including the 15 standard ESA steps (code 2) was selected. > NANG is the number of angular bins selected by option 9. In this interval >we selected the default number of 8 angular bins. IMQFLG, IMDCODE, IECODE, IEDCODE, NANG, 2 2 2 2 8 > > The seventh and eighth lines report the m/q Values (line 7) and mass step >number (line 8) for each of the up to 4 masses include in the bulk of the >listing. Mass selection is controlled by option #12. In the accumulation >here we used the default, which is to accumulate data for the first four >mass steps (as opposed to m/q values) encountered in the data stream after >the start time of the accumulation. In this case H+ (m/q=1, mass step=9) and >O+ (m/q=16, mass step=50) were the only mass steps encountered in the >accumulation interval. XMQ(*,1): 1.00 16.00 0.00 0.00 XMQ(*,2): 9.00 50.00 0.00 0.00 > > The ninth line of the header reports the energy step numbers accumulated >in the interval. The EICS instrument has 64 possible energy settings as >discussed in the Shelley et al. (1981) instrument paper. This code >returns directly interpretable differential number fluxes or velocity >space densities for ONLY THE 32 ESA energy settings (step #'s 1-32). The >instrument has a retarding potential mode where the energy width of the >lowest ESA energy setting is modified. The 32 possible RPA energy >settings are numbered 65-96. The numbers in the 32 elements of the >IESTP array encode the instrumental energy setting. This information >is repeated again in the bulk of the listing. > Most EICS modes accumulate data in a selected standard sub-set consisting >of 15 of the possible ESA settings settings. In this accumulation >interval we selected the default for option 8 and used the 32 energy bins >available to accumulate the 15 standard ESA steps and the 16 standard RPA >settings. The energies associated with each energy step are give at the >end of note. IESTP(32): 1 2 3 4 5 6 8 10 12 14 17 20 24 28 32 65 66 67 68 69 70 71 7 3 75 78 81 84 87 90 93 96 0 > > The tenth and eleventh lines lists instrument status variables that >partially define the instrumental mode. One of the values reported in the >list of SUB SUBS gives a number that determines the energy range of the >lowest energy step, the other numbers are included for instrumental diagnostic >purposes. Specifically the 16'th number in the list of SUB SUBS (18 >below) is related to the the retarding potential applied to the EICS input >aperture. For normal modes, (i.e. Data intervals NOT marked by the >letter "N" in the data catalog), the 16'th number will be 18 or 31. A >listing is given at the end of this note of the possible low-energy >cut-off, and center energies of the lowest energy channel for all >possible values including 18 and 31. > STATUS VARIABLES: 8 0 0 0 0 0 0 0 1 1 3 SUB SUBS: 1 0 0 0 0 1 1 1 1 0 0 60 0 0 0 18 3 1 1 1 1 1 1 2 1 > >The 11 line header block is immediately followed by the variable length body >of the listing containing the the average geophysical unit listing. >Before discussing the body of the listing, we want to document the >7 line trailer block > > THE TRAILER BLOCK > >The 7 lines of the header block for the example output are: LOGICAL...BATCH, REPEAT, SYNC, MQSEL, MDCHECK, IDCHECK: F F F F F F OUTPUT(9): T T T T T T F T T INTTYPE, KRSPINS, NSYNC, IUNIT, TYPEOUT: 0 -1 -1 108 0 FIRST LAST TIMES OF LAST SPIN 84004 54297026 84004 54299996 MQLIST(*,1) 0.00 0.00 0.00 0.00 MQLIST(*,2) 0.00 0.00 0.00 0.00 MODESEL: -1 > > The first line of the trailer block lists the status of six logical >variables used to control the accumulation. >The BATCH variable is set true if the the answer to the first question > Interactive? (Y/N): If the answer is N the program does not >output prompts to the screen but expects input from a terminal or batch >stream file for each of the 15 options in the order and format prompted >for in the interactive branch. > The REPEAT variable is set by option #4, if only one average is to be >returned for the time interval (the default) then REPEAT is False. > The SYNC variable is also set by option #4. If the sub-option #4 'C' is >selected then the SYNC variable is set True. Sub-option 'C' requests >that a fixed number of instrument cycles be included in each average >period between the start and stop times specified in options 1 and 2. > The MQSEL variable is set by option #12. If the program is to accept >only specified m/q and mass step values the MQSEL variable is set True. > The MDCHECK variable is set by option #5. If no specific mode is >selected MDCHECK is set False. > The IDCHECK variable is also set by option #5, but is normally not >used. Its default value is False. LOGICAL...BATCH, REPEAT, SYNC, MQSEL, MDCHECK, IDCHECK: F F F F F F > > The second line of the trailer lists nine more logical variables. >These variables are set by the subroutine SPINSORT and define the >conditions in the an internal data buffer at the termination of the >accumulation interval. This output has no geophysical significance. OUTPUT(9): T T T T T T F T T > > The third line of the trailer reports some internal variables, some of >which are set by the input options, others of which are set internally. > INTTYPE is set by option #4. 0 is the default (one average reported >from the start to the stop times. INTTYPE is set to 1 if option #4 is set to >accumulate a fixed number of spin periods per average period. INTTYPE >is set to 2 if option #4 is set to accumulate a fixed number of >instrument cycles per average period. > KRSPINS is the number of requested spins per average interval if this method >is selected under option #4, KRSPINS is -1 otherwise. > NSYNC is the number of requested instrument cycle beginnings per >average interval if this method is selected under option #4. NSYNC >is -1 otherwise. > IUNIT is the logical unit for the printer output selected by option >#14. It is fixed to the value 108. > TYPEOUT is a parameter passed to the subroutine that prints the output >selected by option #14. It is fixed to the value 0 is the EICS code. INTTYPE, KRSPINS, NSYNC, IUNIT, TYPEOUT: 0 -1 -1 108 0 > > The fourth line is again mainly a diagnostic output. Data is >accumulated in an internal program buffer before being added to the >accumulation. This line gives the start and stop times of the data >in this buffer in milliseconds of the day. FIRST LAST TIMES OF LAST SPIN 84004 54297026 84004 54299996 > > The fifth and sixth line report the list of up to 4 m/q and associated >mass step numbers optionally input in response to option 12. The default >is not to specify these values. When they have not been specified they >are shown as 0's. MQLIST(*,1) 0.00 0.00 0.00 0.00 MQLIST(*,2) 0.00 0.00 0.00 0.00 > > The last line lists the MODSEL parameter set by option #5. When no >specific mode is selected it is -1. MODESEL: -1 > > THE AVERAGE GEOPHYSICAL UNIT LISTING > > After the 11 lines of the header block and before the 7 lines of the trailer >block is the main body of the program output for each average interval. >This main block of geophysical units is of variable length and is divided >into mass sections. There is one section for each mass selected with >option #12. If a mass step selected using option 12, but NOT sampled by >the instrument during the accumulation interval, it will be omitted from >the listing. Each section in the geophysical unit listing is headed >by a line indicating the mass (m/q value) and the mass step used in the >accumulation. For example > M/Q = 1.00 MSTEP(1-64) = 9.00 > > If the optional ED output is selected using option #15, there will be an >additional section at the end with the header > ENERGY DETECTOR ASSUMING M/Q = 1 > >NOTE: the ED output is NOT calibrated. > > > The program can accumulate data in up to 64 angular and 32 energy bins. >For normal EICS modes and the default program settings 8 angular and 15 >energy bins are accumulated. Data for energy steps selected by option #8, >but not sampled are omitted from the listing. > For each mass/energy/angle bin two numbers are reported. One is the >counts, count rate, flux or velocity space density for the mass/energy/angle >bin and the other is an estimate of the uncertainty in the number. >The uncertainty reported is the one sigma value calculated using the >total number of counts observed. It is, of course a relative uncertainty. >We estimate that the absolute uncertainty in the EICS fluxes is ~ +/- >30%. This estimate is based on calibration data and intercomparison with >RIMS and HAPI data. > The UNITS of the numbers reported is determined by option #15, and >reported (encoded) on the fourth line of the header block as ICJFCODES > The code reported for the units is the one used in option 15 to select >the units. >Final output format codes: > 0: Counts 1: Counts/Sample 2: Flux 3: Velocity Space Density >The default is Flux (2), but you can select total counts (0), >counts/sample (1) or velocity space density(3). The units are >total counts, counts per instrument accumulation period, number >flux in units of 1/(cm^2-sec-sr-keV), and velocity space density in >units of sec^3/km^6. > In the listing below the units are FLUX > > If the number of angular bins is more than 8, then an additional pair >of lines for each 8 angular bins, up to a total of 8 pairs of lines for >64 angular bins, are given for each sampled energy step. > M/Q = 1.00 MSTEP(1-64) = 9.00 ### ESTEP 1 ### 8 ANGULAR INTERVALS FOR M/Q = 1.00 1 0.113E+08 0.784E+07 0.521E+07 0.445E+07 0.469E+07 0.563E+07 0.795E+07 0.895E +07 0.161E+06 0.131E+06 0.107E+06 0.103E+06 0.101E+06 0.109E+06 0.133E+06 0.134E +06 ### ESTEP 2 ### 8 ANGULAR INTERVALS FOR M/Q = 1.00 1 0.296E+07 0.362E+07 0.243E+07 0.196E+07 0.191E+07 0.211E+07 0.245E+07 0.975E +06 0.740E+05 0.841E+05 0.680E+05 0.587E+05 0.602E+05 0.609E+05 0.646E+05 0.419E +05 ### ESTEP 3 ### 8 ANGULAR INTERVALS FOR M/Q = 1.00 1 0.370E+06 0.111E+07 0.110E+07 0.976E+06 0.915E+06 0.101E+07 0.964E+06 0.255E +06 0.272E+05 0.457E+05 0.455E+05 0.435E+05 0.416E+05 0.437E+05 0.427E+05 0.218E +05 ### ESTEP 4 ### 8 ANGULAR INTERVALS FOR M/Q = 1.00 1 0.142E+06 0.548E+06 0.629E+06 0.683E+06 0.627E+06 0.723E+06 0.483E+06 0.126E +06 0.170E+05 0.337E+05 0.356E+05 0.366E+05 0.355E+05 0.381E+05 0.300E+05 0.159E +05 ### ESTEP 5 ### 8 ANGULAR INTERVALS FOR M/Q = 1.00 1 0.957E+05 0.348E+06 0.499E+06 0.531E+06 0.464E+06 0.441E+06 0.441E+06 0.118E +06 0.145E+05 0.270E+05 0.318E+05 0.337E+05 0.307E+05 0.295E+05 0.295E+05 0.154E +05 ### ESTEP 6 ### 8 ANGULAR INTERVALS FOR M/Q = 1.00 1 0.648E+05 0.279E+06 0.330E+06 0.370E+06 0.321E+06 0.304E+06 0.248E+06 0.483E +05 0.121E+05 0.241E+05 0.273E+05 0.277E+05 0.265E+05 0.251E+05 0.224E+05 0.997E +04 ### ESTEP 8 ### 8 ANGULAR INTERVALS FOR M/Q = 1.00 1 0.447E+05 0.999E+05 0.151E+06 0.128E+06 0.149E+06 0.143E+06 0.785E+05 0.223E +05 0.103E+05 0.148E+05 0.184E+05 0.167E+05 0.182E+05 0.174E+05 0.132E+05 0.721E +04 ### ESTEP 10 ### 8 ANGULAR INTERVALS FOR M/Q = 1.00 1 0.312E+05 0.956E+05 0.983E+05 0.961E+05 0.109E+06 0.895E+05 0.661E+05 0.244E +05 0.873E+04 0.145E+05 0.149E+05 0.147E+05 0.157E+05 0.142E+05 0.120E+05 0.750E +04 ### ESTEP 12 ### 8 ANGULAR INTERVALS FOR M/Q = 1.00 1 0.292E+05 0.134E+06 0.164E+06 0.148E+06 0.160E+06 0.108E+06 0.114E+06 0.316E +05 0.819E+04 0.172E+05 0.188E+05 0.178E+05 0.183E+05 0.149E+05 0.153E+05 0.827E +04 ### ESTEP 14 ### 8 ANGULAR INTERVALS FOR M/Q = 1.00 1 0.450E+05 0.154E+06 0.169E+06 0.194E+06 0.164E+06 0.148E+06 0.138E+06 0.451E +05 0.988E+04 0.177E+05 0.188E+05 0.198E+05 0.183E+05 0.169E+05 0.164E+05 0.951E +04 ### ESTEP 17 ### 8 ANGULAR INTERVALS FOR M/Q = 1.00 1 0.656E+05 0.210E+06 0.219E+06 0.207E+06 0.207E+06 0.196E+06 0.152E+06 0.740E +05 0.108E+05 0.195E+05 0.193E+05 0.186E+05 0.193E+05 0.183E+05 0.157E+05 0.113E +05 ### ESTEP 20 ### 8 ANGULAR INTERVALS FOR M/Q = 1.00 1 0.829E+05 0.260E+06 0.319E+06 0.334E+06 0.310E+06 0.289E+06 0.249E+06 0.750E +05 0.113E+05 0.196E+05 0.217E+05 0.225E+05 0.208E+05 0.204E+05 0.190E+05 0.104E +05 ### ESTEP 24 ### 8 ANGULAR INTERVALS FOR M/Q = 1.00 1 0.105E+06 0.309E+06 0.337E+06 0.330E+06 0.338E+06 0.310E+06 0.284E+06 0.863E +05 0.110E+05 0.191E+05 0.194E+05 0.192E+05 0.197E+05 0.186E+05 0.174E+05 0.986E +04 ### ESTEP 28 ### 8 ANGULAR INTERVALS FOR M/Q = 1.00 1 0.664E+05 0.226E+06 0.241E+06 0.295E+06 0.289E+06 0.242E+06 0.208E+06 0.482E +05 0.785E+04 0.142E+05 0.148E+05 0.164E+05 0.156E+05 0.143E+05 0.136E+05 0.636E +04 ### ESTEP 32 ### 8 ANGULAR INTERVALS FOR M/Q = 1.00 1 0.558E+05 0.161E+06 0.189E+06 0.246E+06 0.260E+06 0.210E+06 0.180E+06 0.530E +05 0.618E+04 0.109E+05 0.112E+05 0.129E+05 0.138E+05 0.118E+05 0.109E+05 0.594E +04 M/Q = 16.00 MSTEP(1-64) = 50.00 ### ESTEP 1 ### 8 ANGULAR INTERVALS FOR M/Q = 16.00 1 0.103E+06 0.101E+06 0.843E+05 0.631E+05 0.525E+05 0.800E+05 0.383E+06 0.116E +07 0.150E+05 0.146E+05 0.136E+05 0.118E+05 0.108E+05 0.132E+05 0.286E+05 0.504E +05 ### ESTEP 2 ### 8 ANGULAR INTERVALS FOR M/Q = 16.00 1 0.831E+05 0.587E+05 0.756E+05 0.821E+05 0.607E+05 0.509E+05 0.700E+05 0.642E +05 0.127E+05 0.106E+05 0.121E+05 0.130E+05 0.106E+05 0.100E+05 0.119E+05 0.112E +05 ### ESTEP 3 ### 8 ANGULAR INTERVALS FOR M/Q = 16.00 1 0.981E+05 0.639E+05 0.783E+05 0.841E+05 0.656E+05 0.694E+05 0.712E+05 0.381E +05 0.134E+05 0.110E+05 0.120E+05 0.126E+05 0.113E+05 0.116E+05 0.116E+05 0.862E +04 ### ESTEP 4 ### 8 ANGULAR INTERVALS FOR M/Q = 16.00 1 0.730E+05 0.816E+05 0.689E+05 0.437E+05 0.536E+05 0.321E+05 0.458E+05 0.227E +05 0.122E+05 0.135E+05 0.121E+05 0.983E+04 0.110E+05 0.862E+04 0.101E+05 0.726E +04 ### ESTEP 5 ### 8 ANGULAR INTERVALS FOR M/Q = 16.00 1 0.812E+05 0.572E+05 0.663E+05 0.671E+05 0.607E+05 0.850E+05 0.620E+05 0.353E +05 0.131E+05 0.109E+05 0.122E+05 0.118E+05 0.114E+05 0.132E+05 0.118E+05 0.868E +04 ### ESTEP 6 ### 8 ANGULAR INTERVALS FOR M/Q = 16.00 1 0.502E+05 0.778E+05 0.548E+05 0.777E+05 0.890E+05 0.869E+05 0.800E+05 0.456E +05 0.110E+05 0.134E+05 0.115E+05 0.138E+05 0.143E+05 0.143E+05 0.140E+05 0.105E +05 ### ESTEP 8 ### 8 ANGULAR INTERVALS FOR M/Q = 16.00 1 0.262E+05 0.407E+05 0.496E+05 0.262E+05 0.189E+05 0.109E+05 0.307E+05 0.230E +05 0.808E+04 0.103E+05 0.107E+05 0.808E+04 0.727E+04 0.563E+04 0.868E+04 0.782E +04 ### ESTEP 10 ### 8 ANGULAR INTERVALS FOR M/Q = 16.00 1 0.273E+05 0.264E+05 0.298E+05 0.197E+05 0.237E+05 0.184E+05 0.961E+04 0.767E +04 0.875E+04 0.886E+04 0.911E+04 0.758E+04 0.845E+04 0.756E+04 0.565E+04 0.534E +04 ### ESTEP 12 ### 8 ANGULAR INTERVALS FOR M/Q = 16.00 1 0.214E+05 0.543E+05 0.631E+05 0.497E+05 0.239E+05 0.232E+05 0.305E+05 0.136E +05 0.775E+04 0.117E+05 0.127E+05 0.115E+05 0.813E+04 0.793E+04 0.931E+04 0.632E +04 ### ESTEP 14 ### 8 ANGULAR INTERVALS FOR M/Q = 16.00 1 0.474E+05 0.296E+05 0.718E+05 0.391E+05 0.182E+05 0.261E+05 0.543E+05 0.208E +05 0.116E+05 0.907E+04 0.139E+05 0.109E+05 0.751E+04 0.881E+04 0.125E+05 0.797E +04 ### ESTEP 17 ### 8 ANGULAR INTERVALS FOR M/Q = 16.00 1 0.108E+05 0.267E+05 0.619E+04 0.346E+05 0.322E+05 0.275E+05 0.291E+05 0.139E +05 0.560E+04 0.857E+04 0.458E+04 0.939E+04 0.909E+04 0.846E+04 0.856E+04 0.637E +04 ### ESTEP 20 ### 8 ANGULAR INTERVALS FOR M/Q = 16.00 1 0.178E+05 0.184E+05 0.899E+04 0.277E+05 0.166E+05 0.155E+05 0.113E+05 0.691E +04 0.684E+04 0.703E+04 0.524E+04 0.845E+04 0.682E+04 0.645E+04 0.574E+04 0.482E +04 ### ESTEP 24 ### 8 ANGULAR INTERVALS FOR M/Q = 16.00 1 0.155E+05 0.198E+05 0.324E+04 0.689E+04 0.209E+05 0.487E+04 0.109E+05 0.622E +04 0.563E+04 0.610E+04 0.316E+04 0.408E+04 0.641E+04 0.356E+04 0.496E+04 0.378E +04 ### ESTEP 28 ### 8 ANGULAR INTERVALS FOR M/Q = 16.00 1 0.751E+04 0.118E+05 0.122E+05 0.137E+05 0.595E+04 0.937E+04 0.751E+04 0.906E +04 0.380E+04 0.453E+04 0.466E+04 0.491E+04 0.347E+04 0.422E+04 0.380E+04 0.411E +04 ### ESTEP 32 ### 8 ANGULAR INTERVALS FOR M/Q = 16.00 1 0.145E+05 0.152E+05 0.907E+04 0.965E+04 0.102E+05 0.880E+04 0.653E+04 0.653E +04 0.425E+04 0.429E+04 0.350E+04 0.351E+04 0.369E+04 0.341E+04 0.301E+04 0.301E +04 LOGICAL...BATCH, REPEAT, SYNC, MQSEL, MDCHECK, IDCHECK: F F F F F F OUTPUT(9): T T T T T T F T T INTTYPE, KRSPINS, NSYNC, IUNIT, TYPEOUT: 0 -1 -1 108 0 FIRST LAST TIMES OF LAST SPIN 84004 54297026 84004 54299996 MQLIST(*,1) 0.00 0.00 0.00 0.00 MQLIST(*,2) 0.00 0.00 0.00 0.00 MODESEL: -1 >---------------------END OF THE LISTING------------------------ > The table below gives the center energy and fwhm of each of the ESA energy >steps. The column on the right gives energy step number that appears in >the listing above. The second column has the numbers 1-15 for those >energy steps included in the standard 15, and a "-" for the other energy >steps. The final column gives the full width at half maximum in keV of >each energy step. The CENTER energy and width of the lowest (i.e. first) >energy step is variable. The center energy is normally 0.062 keV with >a sharp low energy cut-off at 10 eV. The exact low energy cut off and >center energy of the first energy channel depends on the RPA setting which >is 16'th number in the 11th line of the header block. For normal operations, >i.e. for intervals NOT marked with a 'N' or '---' in the data catalog, the >rpa setting is 0, 18, or 31. In the line below the RPA setting is 18 SUB SUBS: 1 0 0 0 0 1 1 1 1 0 0 60 0 0 0 18 3 1 1 1 1 1 1 2 1 >which corresponds to a low-energy cut off of 10 eV and a center energy >of 62 eV. The low energy cut off's and center energies for all >possible RPA settings are given in the second table below. > > TABLE OF EICS ENERGY SETTINGS > ESTEP # ORDER # Center FWHM > (1-32) (1-15) Energy (keV) (keV) > 1 1 *** *** see table below > 2 2 0.231 0.162 > 3 3 0.433 0.172 > 4 4 0.647 0.182 > 5 5 0.874 0.194 > 6 6 1.116 0.206 > 7 - 1.373 0.219 > 8 7 1.646 0.232 > 9 - 1.937 0.247 > 10 8 2.246 0.262 > 11 - 2.574 0.279 > 12 9 2.923 0.296 > 13 - 3.295 0.315 > 14 10 3.689 0.334 > 15 - 4.109 0.355 > 16 - 4.555 0.378 > 17 11 5.029 0.401 > 18 - 5.533 0.427 > 19 - 6.068 0.453 > 20 12 6.638 0.482 > 21 - 7.244 0.512 > 22 - 7.888 0.544 > 23 - 8.572 0.579 > 24 13 9.300 0.615 > 25 - 10.07 0.654 > 26 - 10.90 0.695 > 27 - 11.77 0.739 > 28 14 12.70 0.785 > 29 - 13.69 0.835 > 30 - 14.74 0.887 > 31 - 15.86 0.943 > 32 15 17.04 1.002 > > TABLE OF EICS RPA SETTINGS (0-31), LOWER CUT-OFF ENERGY AND CENTER >ENERGY OF THE LOWEST ENERGY STEP. > RPA SETTING LOWER CUT-OFF ENERGY CENTER ENERGY > (0-31) (eV above spacecraft (eV above spacecraft > potential) potential) > 0 0.05 56. > 1 0.09 56. > 2 0.2 56. > 3 0.3 56. > 4 0.5 56. > 5 0.7 57. > 6 0.9 57. > 7 1.2 57. > 8 1.5 57. > 9 1.8 57. > 10 2.3 57. > 11 2.8 58. > 12 3.4 58. > 13 4.1 59. > 14 5.0 59. > 15 6.0 60. > 16 7.2 60. > 17 8.7 61. > 18 10.4 62. > 19 12.4 63. > 20 14.8 65. > 21 17.7 66. > 22 21.1 68. > 23 25.1 70. > 24 29.9 73. > 25 35.5 76. > 26 42.2 79. > 27 50.2 84. > 28 59.7 89. > 29 70.9 95. > 30 84.2 104. > 31 93.5 110. >-------------------------------end 3/29/89-------------wkp------------