CDPP / CNES

Commit 9a4898cb558151bfa56164b1c70537f148579c9e

Authored by Benjamin Renard
1 parent 628bd391
Exists in master

Merge Ephemerides Ganymede&Europa from amdadev into master

Showing 4 changed files with 428 additions and 2 deletions   Show diff stats
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NumericalData/CDPP-AMDA/Ephemerides/europa-orb-all.xml
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... ... @@ -4,7 +4,7 @@
4 4 <NumericalData>
5 5 <ResourceID>spase://CNES/NumericalData/CDPP-AMDA/Ephemerides/europa-orb-all</ResourceID>
6 6 <ResourceHeader>
7   - <ResourceName>Europa</ResourceName>
  7 + <ResourceName>Europa - 20 min</ResourceName>
8 8 <ReleaseDate>2018-09-07T11:41:29Z</ReleaseDate>
9 9 <Description>Europa orbits Jupiter in just over three and a half days,
10 10 with an orbital radius of about 670,900 km. With an eccentricity of only
... ...
NumericalData/CDPP-AMDA/Ephemerides/europa-orb-all1s.xml 0 → 100644
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  1 +<?xml version="1.0" encoding="UTF-8"?>
  2 +<Spase xmlns="http://www.spase-group.org/data/schema" xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance" xsi:schemaLocation="http://www.spase-group.org/data/schema http://www.spase-group.org/data/schema/spase-2.4.1.xsd">
  3 + <Version>2.4.1</Version>
  4 + <NumericalData>
  5 + <ResourceID>spase://CNES/NumericalData/CDPP-AMDA/Ephemerides/europa-orb-all1s</ResourceID>
  6 + <ResourceHeader>
  7 + <ResourceName>Europa - 1 sec</ResourceName>
  8 + <ReleaseDate>2018-09-07T11:41:29Z</ReleaseDate>
  9 + <Description>Europa orbits Jupiter in just over three and a half days,
  10 + with an orbital radius of about 670,900 km. With an eccentricity of only
  11 + 0.009, the orbit itself is nearly circular, and the orbital inclination
  12 + relative to Jupiter's equatorial plane is small, at 0.470°.
  13 + Like its fellow Galilean satellites, Europa is tidally locked to Jupiter,
  14 + with one hemisphere of Europa constantly facing Jupiter. Because of this,
  15 + there is a sub-Jovian point on Europa's surface, from which Jupiter would
  16 + appear to hang directly overhead. Europa's prime meridian is the line
  17 + intersecting this point. Research suggests that the tidal locking may not be
  18 + full, as a non-synchronous rotation has been proposed: Europa spins faster
  19 + than it orbits, or at least did so in the past.
  20 + This suggests an asymmetry in internal mass distribution and that a layer of
  21 + subsurface liquid separates the icy crust from the rocky interior.
  22 +
  23 +The slight eccentricity of Europa's orbit, maintained by the gravitational disturbances from
  24 +the other Galileans, causes Europa's sub-Jovian point to oscillate around a mean position.
  25 +As Europa comes slightly nearer to Jupiter, Jupiter's gravitational attraction increases,
  26 +causing Europa to elongate towards and away from it. As Europa moves slightly away from
  27 +Jupiter, Jupiter's gravitational force decreases, causing Europa to relax back into a more
  28 +spherical shape, and creating tides in its ocean. The orbital eccentricity of Europa is
  29 +continuously pumped by its mean-motion resonance with Io.
  30 +Thus, the tidal flexing kneads Europa's interior and gives it a source of heat, possibly
  31 +allowing its ocean to stay liquid while driving subsurface geological processes.
  32 +The ultimate source of this energy is Jupiter's rotation, which is tapped by Io
  33 +through the tides it raises on Jupiter and is transferred to Europa and Ganymede by the
  34 +orbital resonance.</Description>
  35 + <Contact>
  36 + <PersonID>spase://CNES/Person/CDPP-AMDA/NAIF</PersonID>
  37 + <Role>PrincipalInvestigator</Role>
  38 + </Contact>
  39 + <Association>
  40 + <AssociationID>jup-moons-orb</AssociationID>
  41 + <AssociationType>PartOf</AssociationType>
  42 + <Note>Jupiter Moons</Note>
  43 + </Association>
  44 + </ResourceHeader>
  45 + <AccessInformation>
  46 + <RepositoryID>spase://SMWG/Repository/CDPP/AMDA</RepositoryID>
  47 + <Availability>Online</Availability>
  48 + <AccessRights>Open</AccessRights>
  49 + <AccessURL>
  50 + <Name>CDPP/AMDA HAPI Server</Name>
  51 + <URL>https://amda.irap.omp.eu/service/hapi</URL>
  52 + <Style>HAPI</Style>
  53 + <ProductKey>europa-orb-all</ProductKey>
  54 + <Description>Web Service to this product using the HAPI interface.</Description>
  55 + </AccessURL>
  56 + <Format>CSV</Format>
  57 + <Acknowledgement>Thank you for acknowledging the use of AMDA in publications with wording like "Data analysis was performed with the AMDA science analysis system provided by the Centre de Données de la Physique des Plasmas (CDPP) supported by CNRS, CNES, Observatoire de Paris and Université Paul Sabatier, Toulouse". See the Rules of the road at https://amda.cdpp.eu/help/policy.html . Please acknowledge the Data Providers.</Acknowledgement>
  58 + </AccessInformation>
  59 + <AccessInformation>
  60 + <RepositoryID>spase://SMWG/Repository/CDPP/AMDA</RepositoryID>
  61 + <Availability>Online</Availability>
  62 + <AccessRights>Open</AccessRights>
  63 + <AccessURL>
  64 + <Name>CDPP/AMDA Web application</Name>
  65 + <URL>https://amda.cdpp.eu</URL>
  66 + <Description>Access to Data via CDPP/AMDA Web application.</Description>
  67 + </AccessURL>
  68 + <Format>CSV</Format>
  69 + <Format>VOTable</Format>
  70 + <Format>CDF</Format>
  71 + <Format>PNG</Format>
  72 + <Acknowledgement>Thank you for acknowledging the use of AMDA in publications with wording like "Data analysis was performed with the AMDA science analysis system provided by the Centre de Données de la Physique des Plasmas (CDPP) supported by CNRS, CNES, Observatoire de Paris and Université Paul Sabatier, Toulouse". See the Rules of the road at https://amda.cdpp.eu/help/policy.html . Please acknowledge the Data Providers.</Acknowledgement>
  73 + </AccessInformation>
  74 + <ProviderName>SPICE</ProviderName>
  75 + <InstrumentID>spase://CNES/Instrument/CDPP-AMDA/Ephemerides</InstrumentID>
  76 + <MeasurementType>Ephemeris</MeasurementType>
  77 + <TemporalDescription>
  78 + <TimeSpan>
  79 + <StartDate>1970-01-01T00:00:05Z</StartDate>
  80 + <StopDate>2036-12-31T23:40:04Z</StopDate>
  81 + </TimeSpan>
  82 + <Cadence>PT1S</Cadence>
  83 + </TemporalDescription>
  84 + <ObservedRegion>Jupiter</ObservedRegion>
  85 + <ObservedRegion>Jupiter.Europa</ObservedRegion>
  86 + <Parameter>
  87 + <Name>xyz_jsm</Name>
  88 + <ParameterKey>eur_jup_jsm1s</ParameterKey>
  89 + <Units>Rj</Units>
  90 + <CoordinateSystem>
  91 + <CoordinateRepresentation>Cartesian</CoordinateRepresentation>
  92 + <CoordinateSystemName>JSM</CoordinateSystemName>
  93 + </CoordinateSystem>
  94 + <RenderingHints>
  95 + <DisplayType>TimeSeries</DisplayType>
  96 + </RenderingHints>
  97 + <Structure>
  98 + <Size>3</Size>
  99 + <Element>
  100 + <Name>x</Name>
  101 + <Index>1</Index>
  102 + <ParameterKey>eur_jup_jsm1s(0)</ParameterKey>
  103 + </Element>
  104 + <Element>
  105 + <Name>y</Name>
  106 + <Index>2</Index>
  107 + <ParameterKey>eur_jup_jsm1s(1)</ParameterKey>
  108 + </Element>
  109 + <Element>
  110 + <Name>z</Name>
  111 + <Index>3</Index>
  112 + <ParameterKey>eur_jup_jsm1s(2)</ParameterKey>
  113 + </Element>
  114 + </Structure>
  115 + <Support>
  116 + <SupportQuantity>Positional</SupportQuantity>
  117 + </Support>
  118 + </Parameter>
  119 + <Parameter>
  120 + <Name>xyz_jso</Name>
  121 + <ParameterKey>eur_jup_jso1s</ParameterKey>
  122 + <Units>Rj</Units>
  123 + <CoordinateSystem>
  124 + <CoordinateRepresentation>Cartesian</CoordinateRepresentation>
  125 + <CoordinateSystemName>JSO</CoordinateSystemName>
  126 + </CoordinateSystem>
  127 + <RenderingHints>
  128 + <DisplayType>TimeSeries</DisplayType>
  129 + </RenderingHints>
  130 + <Structure>
  131 + <Size>3</Size>
  132 + <Element>
  133 + <Name>x</Name>
  134 + <Index>1</Index>
  135 + <ParameterKey>eur_jup_jso1s(0)</ParameterKey>
  136 + </Element>
  137 + <Element>
  138 + <Name>y</Name>
  139 + <Index>2</Index>
  140 + <ParameterKey>eur_jup_jso1s(1)</ParameterKey>
  141 + </Element>
  142 + <Element>
  143 + <Name>z</Name>
  144 + <Index>3</Index>
  145 + <ParameterKey>eur_jup_jso1s(2)</ParameterKey>
  146 + </Element>
  147 + </Structure>
  148 + <Support>
  149 + <SupportQuantity>Positional</SupportQuantity>
  150 + </Support>
  151 + </Parameter>
  152 + <Parameter>
  153 + <Name>xyz_IAU_jupiter</Name>
  154 + <ParameterKey>eur_jup_xyz1s</ParameterKey>
  155 + <Units>Rj</Units>
  156 + <RenderingHints>
  157 + <DisplayType>TimeSeries</DisplayType>
  158 + </RenderingHints>
  159 + <Structure>
  160 + <Size>3</Size>
  161 + <Element>
  162 + <Name>x</Name>
  163 + <Index>1</Index>
  164 + <ParameterKey>eur_jup_xyz1s(0)</ParameterKey>
  165 + </Element>
  166 + <Element>
  167 + <Name>y</Name>
  168 + <Index>2</Index>
  169 + <ParameterKey>eur_jup_xyz1s(1)</ParameterKey>
  170 + </Element>
  171 + <Element>
  172 + <Name>z</Name>
  173 + <Index>3</Index>
  174 + <ParameterKey>eur_jup_xyz1s(2)</ParameterKey>
  175 + </Element>
  176 + </Structure>
  177 + <Support>
  178 + <SupportQuantity>Positional</SupportQuantity>
  179 + </Support>
  180 + </Parameter>
  181 + <Parameter>
  182 + <Name>distance europa-jupiter</Name>
  183 + <ParameterKey>eur_jup_r1s</ParameterKey>
  184 + <Units>Rj</Units>
  185 + <RenderingHints>
  186 + <DisplayType>TimeSeries</DisplayType>
  187 + </RenderingHints>
  188 + <Support>
  189 + <SupportQuantity>Positional</SupportQuantity>
  190 + </Support>
  191 + </Parameter>
  192 + <Parameter>
  193 + <Name>latitude IAU_jupiter</Name>
  194 + <ParameterKey>eur_jup_lat1s</ParameterKey>
  195 + <Units>deg</Units>
  196 + <Support>
  197 + <SupportQuantity>Positional</SupportQuantity>
  198 + </Support>
  199 + </Parameter>
  200 + <Parameter>
  201 + <Name>longitude IAU_jupiter</Name>
  202 + <ParameterKey>eur_jup_lon1s</ParameterKey>
  203 + <Units>deg</Units>
  204 + <Support>
  205 + <SupportQuantity>Positional</SupportQuantity>
  206 + </Support>
  207 + </Parameter>
  208 + <Parameter>
  209 + <Name>mlat</Name>
  210 + <ParameterKey>eur_jup_mlat1s</ParameterKey>
  211 + <Description>mlat=10.31°xcos(196.61°-lon_iau_west)+lat_iau</Description>
  212 + <Units>deg</Units>
  213 + <Support>
  214 + <SupportQuantity>Positional</SupportQuantity>
  215 + </Support>
  216 + </Parameter>
  217 + </NumericalData>
  218 +</Spase>
... ...
NumericalData/CDPP-AMDA/Ephemerides/ganymede-orb-all.xml
  Diff comments   View file @9a4898c
... ... @@ -4,7 +4,7 @@
4 4 <NumericalData>
5 5 <ResourceID>spase://CNES/NumericalData/CDPP-AMDA/Ephemerides/ganymede-orb-all</ResourceID>
6 6 <ResourceHeader>
7   - <ResourceName>Ganymede</ResourceName>
  7 + <ResourceName>Ganymede - 20 min</ResourceName>
8 8 <ReleaseDate>2018-09-07T11:33:03Z</ReleaseDate>
9 9 <Description>Ganymede orbits Jupiter at a distance of 1,070,400 km, third among the Galilean satellites,
10 10 and completes a revolution every seven days and three hours. Like most known moons,
... ...
NumericalData/CDPP-AMDA/Ephemerides/ganymede-orb-all1s.xml 0 → 100644
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  1 +<?xml version="1.0" encoding="UTF-8"?>
  2 +<Spase xmlns="http://www.spase-group.org/data/schema" xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance" xsi:schemaLocation="http://www.spase-group.org/data/schema http://www.spase-group.org/data/schema/spase-2.4.1.xsd">
  3 + <Version>2.4.1</Version>
  4 + <NumericalData>
  5 + <ResourceID>spase://CNES/NumericalData/CDPP-AMDA/Ephemerides/ganymede-orb-all1s</ResourceID>
  6 + <ResourceHeader>
  7 + <ResourceName>Ganymede - 1 sec</ResourceName>
  8 + <ReleaseDate>2018-09-07T11:33:03Z</ReleaseDate>
  9 + <Description>Ganymede orbits Jupiter at a distance of 1,070,400 km, third among the Galilean satellites,
  10 + and completes a revolution every seven days and three hours. Like most known moons,
  11 + Ganymede is tidally locked, with one side always facing toward the planet, hence its day is
  12 + seven days and three hours. Its orbit is very slightly eccentric and inclined to the Jovian
  13 + equator, with the eccentricity and inclination changing quasi-periodically due to solar and
  14 + planetary gravitational perturbations on a timescale of centuries.
  15 + The ranges of change are 0.0009–0.0022 and 0.05–0.32°, respectively.
  16 + These orbital variations cause the axial tilt to vary between 0 and 0.33°.
  17 +
  18 +Ganymede participates in orbital resonances with Europa and Io: for every orbit of Ganymede,
  19 +Europa orbits twice and Io orbits four times. The superior conjunction between Io and Europa
  20 +always occurs when Io is at periapsis and Europa at apoapsis.
  21 +The superior conjunction between Europa and Ganymede occurs when Europa is at periapsis.
  22 +The longitudes of the Io–Europa and Europa–Ganymede conjunctions change with the same rate,
  23 +making triple conjunctions impossible. Such a complicated resonance is called the Laplace
  24 +resonance. </Description>
  25 + <Contact>
  26 + <PersonID>spase://CNES/Person/CDPP-AMDA/NAIF</PersonID>
  27 + <Role>PrincipalInvestigator</Role>
  28 + </Contact>
  29 + <Association>
  30 + <AssociationID>jup-moons-orb</AssociationID>
  31 + <AssociationType>PartOf</AssociationType>
  32 + <Note>Jupiter Moons</Note>
  33 + </Association>
  34 + </ResourceHeader>
  35 + <AccessInformation>
  36 + <RepositoryID>spase://SMWG/Repository/CDPP/AMDA</RepositoryID>
  37 + <Availability>Online</Availability>
  38 + <AccessRights>Open</AccessRights>
  39 + <AccessURL>
  40 + <Name>CDPP/AMDA HAPI Server</Name>
  41 + <URL>https://amda.irap.omp.eu/service/hapi</URL>
  42 + <Style>HAPI</Style>
  43 + <ProductKey>ganymede-orb-all</ProductKey>
  44 + <Description>Web Service to this product using the HAPI interface.</Description>
  45 + </AccessURL>
  46 + <Format>CSV</Format>
  47 + <Acknowledgement>Thank you for acknowledging the use of AMDA in publications with wording like "Data analysis was performed with the AMDA science analysis system provided by the Centre de Données de la Physique des Plasmas (CDPP) supported by CNRS, CNES, Observatoire de Paris and Université Paul Sabatier, Toulouse". See the Rules of the road at https://amda.cdpp.eu/help/policy.html . Please acknowledge the Data Providers.</Acknowledgement>
  48 + </AccessInformation>
  49 + <AccessInformation>
  50 + <RepositoryID>spase://SMWG/Repository/CDPP/AMDA</RepositoryID>
  51 + <Availability>Online</Availability>
  52 + <AccessRights>Open</AccessRights>
  53 + <AccessURL>
  54 + <Name>CDPP/AMDA Web application</Name>
  55 + <URL>https://amda.cdpp.eu</URL>
  56 + <Description>Access to Data via CDPP/AMDA Web application.</Description>
  57 + </AccessURL>
  58 + <Format>CSV</Format>
  59 + <Format>VOTable</Format>
  60 + <Format>CDF</Format>
  61 + <Format>PNG</Format>
  62 + <Acknowledgement>Thank you for acknowledging the use of AMDA in publications with wording like "Data analysis was performed with the AMDA science analysis system provided by the Centre de Données de la Physique des Plasmas (CDPP) supported by CNRS, CNES, Observatoire de Paris and Université Paul Sabatier, Toulouse". See the Rules of the road at https://amda.cdpp.eu/help/policy.html . Please acknowledge the Data Providers.</Acknowledgement>
  63 + </AccessInformation>
  64 + <ProviderName>SPICE</ProviderName>
  65 + <InstrumentID>spase://CNES/Instrument/CDPP-AMDA/Ephemerides</InstrumentID>
  66 + <MeasurementType>Ephemeris</MeasurementType>
  67 + <TemporalDescription>
  68 + <TimeSpan>
  69 + <StartDate>1970-01-01T00:00:05Z</StartDate>
  70 + <StopDate>2036-12-31T23:40:04Z</StopDate>
  71 + </TimeSpan>
  72 + <Cadence>PT1S</Cadence>
  73 + </TemporalDescription>
  74 + <ObservedRegion>Jupiter</ObservedRegion>
  75 + <ObservedRegion>Jupiter.Ganymede</ObservedRegion>
  76 + <Parameter>
  77 + <Name>xyz_jsm</Name>
  78 + <ParameterKey>gan_jup_jsm1s</ParameterKey>
  79 + <Units>Rj</Units>
  80 + <CoordinateSystem>
  81 + <CoordinateRepresentation>Cartesian</CoordinateRepresentation>
  82 + <CoordinateSystemName>JSM</CoordinateSystemName>
  83 + </CoordinateSystem>
  84 + <RenderingHints>
  85 + <DisplayType>TimeSeries</DisplayType>
  86 + </RenderingHints>
  87 + <Structure>
  88 + <Size>3</Size>
  89 + <Element>
  90 + <Name>x</Name>
  91 + <Index>1</Index>
  92 + <ParameterKey>gan_jup_jsm1s(0)</ParameterKey>
  93 + </Element>
  94 + <Element>
  95 + <Name>y</Name>
  96 + <Index>2</Index>
  97 + <ParameterKey>gan_jup_jsm1s(1)</ParameterKey>
  98 + </Element>
  99 + <Element>
  100 + <Name>z</Name>
  101 + <Index>3</Index>
  102 + <ParameterKey>gan_jup_jsm1s(2)</ParameterKey>
  103 + </Element>
  104 + </Structure>
  105 + <Support>
  106 + <SupportQuantity>Positional</SupportQuantity>
  107 + </Support>
  108 + </Parameter>
  109 + <Parameter>
  110 + <Name>xyz_jso</Name>
  111 + <ParameterKey>gan_jup_jso1s</ParameterKey>
  112 + <Units>Rj</Units>
  113 + <CoordinateSystem>
  114 + <CoordinateRepresentation>Cartesian</CoordinateRepresentation>
  115 + <CoordinateSystemName>JSO</CoordinateSystemName>
  116 + </CoordinateSystem>
  117 + <RenderingHints>
  118 + <DisplayType>TimeSeries</DisplayType>
  119 + </RenderingHints>
  120 + <Structure>
  121 + <Size>3</Size>
  122 + <Element>
  123 + <Name>x</Name>
  124 + <Index>1</Index>
  125 + <ParameterKey>gan_jup_jso1s(0)</ParameterKey>
  126 + </Element>
  127 + <Element>
  128 + <Name>y</Name>
  129 + <Index>2</Index>
  130 + <ParameterKey>gan_jup_jso1s(1)</ParameterKey>
  131 + </Element>
  132 + <Element>
  133 + <Name>z</Name>
  134 + <Index>3</Index>
  135 + <ParameterKey>gan_jup_jso1s(2)</ParameterKey>
  136 + </Element>
  137 + </Structure>
  138 + <Support>
  139 + <SupportQuantity>Positional</SupportQuantity>
  140 + </Support>
  141 + </Parameter>
  142 + <Parameter>
  143 + <Name>xyz_IAU_jupiter</Name>
  144 + <ParameterKey>gan_jup_xyz1s</ParameterKey>
  145 + <Units>Rj</Units>
  146 + <RenderingHints>
  147 + <DisplayType>TimeSeries</DisplayType>
  148 + </RenderingHints>
  149 + <Structure>
  150 + <Size>3</Size>
  151 + <Element>
  152 + <Name>x</Name>
  153 + <Index>1</Index>
  154 + <ParameterKey>gan_jup_xyz1s(0)</ParameterKey>
  155 + </Element>
  156 + <Element>
  157 + <Name>y</Name>
  158 + <Index>2</Index>
  159 + <ParameterKey>gan_jup_xyz1s(1)</ParameterKey>
  160 + </Element>
  161 + <Element>
  162 + <Name>z</Name>
  163 + <Index>3</Index>
  164 + <ParameterKey>gan_jup_xyz1s(2)</ParameterKey>
  165 + </Element>
  166 + </Structure>
  167 + <Support>
  168 + <SupportQuantity>Positional</SupportQuantity>
  169 + </Support>
  170 + </Parameter>
  171 + <Parameter>
  172 + <Name>distance ganymede-jupiter</Name>
  173 + <ParameterKey>gan_jup_r1s</ParameterKey>
  174 + <Units>Rj</Units>
  175 + <RenderingHints>
  176 + <DisplayType>TimeSeries</DisplayType>
  177 + </RenderingHints>
  178 + <Support>
  179 + <SupportQuantity>Positional</SupportQuantity>
  180 + </Support>
  181 + </Parameter>
  182 + <Parameter>
  183 + <Name>latitude IAU_jupiter</Name>
  184 + <ParameterKey>gan_jup_lat1s</ParameterKey>
  185 + <Units>deg</Units>
  186 + <Support>
  187 + <SupportQuantity>Positional</SupportQuantity>
  188 + </Support>
  189 + </Parameter>
  190 + <Parameter>
  191 + <Name>longitude IAU_jupiter</Name>
  192 + <ParameterKey>gan_jup_lon1s</ParameterKey>
  193 + <Units>deg</Units>
  194 + <Support>
  195 + <SupportQuantity>Positional</SupportQuantity>
  196 + </Support>
  197 + </Parameter>
  198 + <Parameter>
  199 + <Name>mlat</Name>
  200 + <ParameterKey>gan_jup_mlat1s</ParameterKey>
  201 + <Description>mlat=10.31°xcos(196.61°-lon_iau_west)+lat_iau</Description>
  202 + <Units>deg</Units>
  203 + <Support>
  204 + <SupportQuantity>Positional</SupportQuantity>
  205 + </Support>
  206 + </Parameter>
  207 + </NumericalData>
  208 +</Spase>
... ...