CDPP / CNES

Commit 48dcf581778b3c6d1813b41ff8630c06a96cff73

Authored by Elena.Budnik
1 parent 40cf2882
Exists in master and in 12 other branches amdadev, aschulz, autocommit, bepi_master, bepi_update, branch_q, cleanup_registry, cleanup_registry_master, cleanup_registry_merged, juice_jdc, juno_jade, soar

caveats mag/maven

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NumericalData/AMDA/MAVEN/MAG/mav-mag-all.xml
  Diff comments   View file @48dcf58
@@ -41,8 +41,8 @@ @@ -41,8 +41,8 @@
41 <MeasurementType>MagneticField</MeasurementType> 41 <MeasurementType>MagneticField</MeasurementType>
42 <TemporalDescription> 42 <TemporalDescription>
43 <TimeSpan> 43 <TimeSpan>
44 - <StartDate>2014-01-01T00:05:22Z</StartDate>  
45 - <StopDate>2016-07-01T23:39:08Z</StopDate> 44 + <StartDate>2013-12-05T16:44:02Z</StartDate>
  45 + <StopDate>2016-08-15T00:00:01Z</StopDate>
46 </TimeSpan> 46 </TimeSpan>
47 <Cadence>PT1S</Cadence> 47 <Cadence>PT1S</Cadence>
48 </TemporalDescription> 48 </TemporalDescription>
NumericalData/AMDA/MAVEN/MAG/mav-mag-pds.xml
  Diff comments   View file @48dcf58
@@ -6,12 +6,8 @@ @@ -6,12 +6,8 @@
6 <ResourceHeader> 6 <ResourceHeader>
7 <ResourceName>0.03 sec</ResourceName> 7 <ResourceName>0.03 sec</ResourceName>
8 <ReleaseDate>2015-10-12T10:48:29Z</ReleaseDate> 8 <ReleaseDate>2015-10-12T10:48:29Z</ReleaseDate>
9 - <Description> * Calibrated science vector magnetic-field data in  
10 - Planetocentric coordinates (IAU Mars) vs. time  
11 - (LID = urn:nasa:pds:maven.mag.calibrated:data.pc)  
12 - * Calibrated science vector magnetic-field  
13 - in Sun-State (MSO) coordinates vs. time  
14 - (LID = urn:nasa:pds:maven.mag.calibrated:data.ss) 9 + <Description> * Calibrated science vector magnetic-field data in Planetocentric coordinates (IAU Mars) vs. time (LID = urn:nasa:pds:maven.mag.calibrated:data.pc)
  10 + * Calibrated science vector magnetic-field in Sun-State (MSO) coordinates vs. time (LID = urn:nasa:pds:maven.mag.calibrated:data.ss)
15 </Description> 11 </Description>
16 <Acknowledgement>Principal Investigator : John E.P. Connerney, NASA GODDARD, Greenbelt</Acknowledgement> 12 <Acknowledgement>Principal Investigator : John E.P. Connerney, NASA GODDARD, Greenbelt</Acknowledgement>
17 <Contact> 13 <Contact>
@@ -58,32 +54,11 @@ available. The MAG observations contain some known artifacts that you may encoun @@ -58,32 +54,11 @@ available. The MAG observations contain some known artifacts that you may encoun
58 data that you should be aware of. These are related to several different sources on the spacecraft that have 54 data that you should be aware of. These are related to several different sources on the spacecraft that have
59 been, and continue to be, under investigation. This message is dated April 10, 2015, and it represents 55 been, and continue to be, under investigation. This message is dated April 10, 2015, and it represents
60 our current (and evolving) understanding of the status of the spacecraft and its influence on MAG 56 our current (and evolving) understanding of the status of the spacecraft and its influence on MAG
61 -data. These include:  
62 -* rapid magnetic field variations of ~6 nT in magnitude (in spacecraft payload coordinate axes y and z)  
63 -associated with infrequent thruster firings (every few days) that are employed in trajectory correction  
64 -maneuvers (TCM). These are relatively easy to identify.  
65 -* variations (in spacecraft payload coordinate axes y and z) of ~1 nT in magnitude associated with solar  
66 -array currents in circuits at the outer edge of the solar arrays, near the magnetometer sensor. MAG  
67 -processing mitigates these signatures where spacecraft engineering telemetry is available at high time  
68 -resolution. The necessary spacecraft engineering data was made available after Jan 9, 2015, following in-  
69 -flight spacecraft testing to isolate the problem. Prior to this time, we use a coarse indication of solar array  
70 -currents to correct the data, and this correction will be out of time step with the actual needed correction  
71 -part of the time. Corrections applied are listed on each record along with the corrected data. These  
72 -variations may appear as step functions, e.g., when the spacecraft enters eclipse, or slow variations as the  
73 -spacecraft attitude with respect to the sun varies. They were identified in the quiet, weak field  
74 -environment of cruise and when illumination on the solar arrays was more intense than experienced in  
75 -cruise.  
76 -* multiple sinewave variations usually of ~0.1 nT in magnitude, that track the frequency of operation of  
77 -the four Reaction Wheel Assemblies (RWAs). The magnitude of these variations has been observed to  
78 -increase substantially when the RWAs are operated at very low frequencies; at such times they may  
79 -appear prominently in spectra of MAG observations.  
80 -* the "static" or slowly-varying spacecraft field has been estimated using spacecraft roll maneuvers that  
81 -are scheduled to occur approximately every 2 months. The MAVEN static sc field specification was NTE  
82 -2 nT. The MAG data processed for December 2014 use an estimate of the spacecraft field obtained from  
83 -the day 353 2014 magroll maneuvers, the only set performed subsequent to deployment of the APP after  
84 -insertion into Mars orbit. We have yet to verify if this sc field estimate remains relatively constant or if it  
85 -varies over the interval between magroll maneuvers. Investigation of the time variability of this part of the  
86 -sc field is expected shortly. 57 +data. These include:
  58 +* rapid magnetic field variations of ~6 nT in magnitude (in spacecraft payload coordinate axes y and z) associated with infrequent thruster firings (every few days) that are employed in trajectory correction maneuvers (TCM). These are relatively easy to identify.
  59 +* variations (in spacecraft payload coordinate axes y and z) of ~1 nT in magnitude associated with solar array currents in circuits at the outer edge of the solar arrays, near the magnetometer sensor. MAG processing mitigates these signatures where spacecraft engineering telemetry is available at high time resolution. The necessary spacecraft engineering data was made available after Jan 9, 2015, following in-flight spacecraft testing to isolate the problem. Prior to this time, we use a coarse indication of solar array currents to correct the data, and this correction will be out of time step with the actual needed correction part of the time. Corrections applied are listed on each record along with the corrected data. These variations may appear as step functions, e.g., when the spacecraft enters eclipse, or slow variations as the spacecraft attitude with respect to the sun varies. They were identified in the quiet, weak field environment of cruise and when illumination on the solar arrays was more intense than experienced in cruise.
  60 +* multiple sinewave variations usually of ~0.1 nT in magnitude, that track the frequency of operation of the four Reaction Wheel Assemblies (RWAs). The magnitude of these variations has been observed to increase substantially when the RWAs are operated at very low frequencies; at such times they may appear prominently in spectra of MAG observations.
  61 +* the "static" or slowly-varying spacecraft field has been estimated using spacecraft roll maneuvers that are scheduled to occur approximately every 2 months. The MAVEN static sc field specification was NTE 2 nT. The MAG data processed for December 2014 use an estimate of the spacecraft field obtained from the day 353 2014 magroll maneuvers, the only set performed subsequent to deployment of the APP after insertion into Mars orbit. We have yet to verify if this sc field estimate remains relatively constant or if it varies over the interval between magroll maneuvers. Investigation of the time variability of this part of the sc field is expected shortly.
87 </Caveats> 62 </Caveats>
88 <Parameter> 63 <Parameter>
89 <Name>b_mso</Name> 64 <Name>b_mso</Name>