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UVS_IO_TORUS_STAREMonitor emissions from the Io torus. Slit aligned parallel with Jupiter's equator.UVS
UVS_JUP_AP_LIMB_SCANMonitoring auroral and airglow emissions in limb scans which requires a continuous S/C motion to point to limb and scan over planetary limb, using the AP port. Observation performed in pixel list mode to reach a time resolution of 0.001 s.UVS
UVS_JUP_AP_AIRGLOW_STAREMonitoring auroral and airglow emissions in stare mode using the Airglow Port (AP). Slit held along Jupiter' s North/South and on the central meridian, while Jupiter rotates below S/C creating a map. Histogram mode.UVS
UVS_GCO_HISTOGRAM_001Monitoring auroral emissions and surface reflectance during GCO. Limited spectral resolution.UVS
PEP_FLYBY_FAR_APPROACH_MEDIUM_RATEMoon environment monitoring: plasma moments, energetic particle spectra and pitch angle distributions (low time resolution). Europa torus (JNA imaging + in-situ) if near Europa Sensors on: all Corotation in JEI or JDC FoV Full pitch angle coverage (JDC, JEI, JoEE, JENI ions) Moon in JNA FoV Angle of NIM_THERMAL_1 or THERMAL_2 from JUICE_EUROPA_RAM or JUICE_GANYMEDE_RAM or JUICE_CALLISTO_RAM velocity less than 60 degPEPLO
PEP_FLYBY_FAR_APPROACH_LOW_RATEMoon environment monitoring: plasma moments, energetic particle spectra and pitch angle distributions (low time resolution). Europa torus (JNA imaging + in-situ) if near Europa Sensors on: all Corotation in JEI or JDC FoV Full pitch angle coverage (JDC, JEI, JoEE, JENI ions)PEPLO
PEP_FLYBY_APPROACHMoon environment monitoring: plasma moments, energetic particle spectra and pitch angle distributions (low time resolution). Moon imaging (JNA) & Europa torus (JNA imaging + in-situ) if near Europa. High altitude exosphere (NIM) Sensors on: all Corotation in JEI or JDC FoV Full pitch angle coverage (JDC, JEI, JoEE, JENI ions) Moon in JNA FoV Angle of NIM_THERMAL_1 or THERMAL_2 from JUICE_EUROPA_RAM or JUICE_GANYMEDE_RAM or JUICE_CALLISTO_RAM velocity less than 60 degPEPLO
MAJ_JovianRING_MOSAICMosaicking the 2 ring ansa from 90000 to 230000 km. 3 overlapping cubes of 20 vertical lines performed by the scanner (or S/Cslew if compatible with JANUS). This requires re-pointing between individual cubes. Pointing: OFF-NADIR, S/C pointing projected ring plane, S/C depointing required for the two ansa Satellite orientation: Maintaining the horizontal orientation of MAJIS slit, MAJIS scan mode activated for vertical sampling (20 vertical lines) centered on the rings, S/C depointing required for mosaicking each ansa (3 overlapping cubes to perform a radial mosaic of one ansa of the rings with radial distance from 90000 to 230000 km) Duration: 1200 sec (excluding the S/C repointings)MAJIS
GAL_WARMUP_GANneeded right before ANY science observation from GALA during Ganymede phase Duration: 90minGALA
PEP_FLYBY_FAR_APPROACH_NIM_BACKGROUNDNIM background measurements part of switch on procedure. Moon environment monitoring: plasma moments, energetic particle spectra and pitch angle distributions (low time resolution). Europa torus (JNA imaging + in-situ) if near Europa Sensors on: all Corotation in JEI or JDC FoV Full pitch angle coverage (JDC, JEI, JoEE, JENI ions)PEPLO
JAN_IDLENo observations, but instrument ON for thermal stabilization before observations or between two observation phases that are too close to switch the instrument OFF.JANUS
JAN_CONFIGNo observations, but instrument ON for thermal stabilization of the complete electronics (PEU and detector are ON) and for setting the observation sequences and between two observation sequences that are too close to switch the detector OFF.JANUS
JAN_OFFNo observations, instrument OFF.JANUS
UVS_DECONTAMINATIONNot a true observation, but included so other instruments are aware that our heaters are onUVS
MAJ_SAT_DISK_SCANObservation of a distant satellite dayside or nightside surface. Satellite offset required for pointing then disk coverage is achieved using the internal pointing mirror scanning in the Y (N-S) direction. Pointing: NADIR-P with possible offset around Y, YS, MAJIS scan (‘Nadir scan’). Satellite orientation: MAJIS slit perpendicular to the ground-track Duration: 30minMAJIS
MAJ_Ring_OccultationObservation of a star occulted by the rings Scan windowing of 9 lines centered on the star (1 scan step = 1/3 MAJIS IFOV) possible Pointing: Inertial. For each occultation, transit of TBD min Satellite orientation: Inertial pointing of the S/C towards the position of the star to maintain MAJIS slit fixed on it. These occultation observations need to be consolidated in the future (star atlas, signal, Tint, S/C inertial capabilities). Scan mirror can be used to mitigate APE driftMAJIS
MAJ_GCO5000_AURORAObservations at auroral latitudes (30-35° N-S), at least in the dawn and dusk sides of Jovian magnetosphere. Mapping at spatial resolution of about 1 km using the MAJIS scan Pointing: S/C limb; no requirements on the slit orientation Saletllite orientation: Off-nadir orientationMAJIS
MAJ_GCO500_HRObservations in true push-broom of specific targets on the surface using motion compensation with the scanner 30 km cross-track x 8.7 km along-track @ 75 m/pixel 30 km cross-track x 17.4 km along-track @ 150 m/pixel (spatial binning x2) Pointing: Nadir pointing, NYS ( ‘motion compensation PB’) Satellite orientation: MAJIS slit perpendicular to the ground-track Duration: One acquisition: 60 sec; switch-on procedure: 10 minutes (TBC)MAJIS
MAJ_JUP_DISK_SCANObservations of Jupiter clouds and spectroscopy of minor gases. Scanning the instrument slit over Jovian disk (vertical direction) by means of internal pointing mirror, both dayside and nightside. Aims to cover at least the entire equatorial region (-30°:+30°) during low inclination phases and the polar regions during high inclination phase. Duration: typically 20min/cube, max 30 min/cube, assuming 2.1 s per lineMAJIS
MAJ_JUP_DISK_SLEWObservations of Jupiter clouds and spectroscopy of minor gases. Scanning the instrument slit over Jovian disk (vertical direction) by means of the S/C slew. aims to cover the entire equatorial region (-30°:+30°) Pointing: OFF_NADIR, CONTINUOUS SLEW (« continuous S/C scan ») Satellite orientation: HORIZONTAL Duration: 20 min per cubeMAJIS
JAN_SCI_SLEWObservations of multiple frames in (m x n) positions targeted with a raster pointing of the S/C made with a continuous slew. The raster is done with continuous slew approach: images are acquired while the S/C is slewing; slew rate shall be adapted with the instrument angular sampling and the integration time. To be used while in J orbit or during FBs (out from CA phase)JANUS
JAN_SCI_RASTERObservations of multiple frames in (m x n) positions targeted with a raster pointing of the S/C. The raster is done with a stop-and-go approach: the S/C maintain an inertial pointing allowing images acquisitions, then perform a slew to the new position and repeat the cycle till the (m x n) raster is completed. To be used while in J orbit or during FBs (out from CA phase). Children observation defined during scenarios: │ ├── JAN_SCI_RASTER_AMALTHEA_HIGH_RES │ ├── JAN_SCI_RASTER_AURORAS │ ├── JAN_SCI_RASTER_FEATURES │ ├── JAN_SCI_RASTER_GLOBAL_MAP │ ├── JAN_SCI_RASTER_HIGH_RES_MAP_JOINED_SET_003_S007_01_S00P01.def │ ├── JAN_SCI_RASTER_HIGH_RES_MAP │ ├── JAN_SCI_RASTER_IO_TRANSIT_001_PART_1_S007_01_S00P01.def (name non compliant) │ ├── JAN_SCI_RASTER_IO_TRANSIT_001_PART_2_S007_01_S00P01.def (name non compliant) │ ├── JAN_SCI_RASTER_IO_TRANSIT_001_S007_01_S00P01.def │ ├── JAN_SCI_RASTER_LIGHTING_MAP │ ├── JAN_SCI_RASTER_POLAR_SOUTHJANUS
JAN_SCI_PBObservations of single or multiple frames with a pointing offset wrt to nominal S/C pointing (e.g., wrt nadir-looking while in G orbit, during FB or while in Jupiter orbit)JANUS
MAJ_MainRING _HighPhaseObservations of the main rings (2 ansa) at high phase (forward scattering light), no tracking of azimuthal structure, no spatial binning to increase spatial resolution. Pointing: OFF-NADIR, S/C pointing centered on the extremity of main rings, S/C depointing required for the two ansa Satellite orientation: Maintaining the MAJIS slit parallel to radial axis of main rings, MAJIS scan mode activated for vertical sampling (20 vertical lines) centered on the rings Duration: 400 sec (excluding the S/C repointing to the other ansae)MAJIS
MAJ_MainRING _LowPhaseObservations of the main rings (2 ansa), no tracking of azimuthal structure, 20 vertical lines pointing: OFF-NADIR, S/C pointing centered on the extremity of main rings, S/C depointing required for the two ansa Satellite orientation: Maintaining the MAJIS slit parallel to radial axis of main rings, MAJIS scan mode activated for vertical sampling centered on the rings (20 vertical lines) Duration:400 sec (excluding the S/C repointing to the other ansae)MAJIS
MAJ_MainRING _PhaseCurveObservations of the main rings at various phase angles (N angles), one ansae (always the same), 20 vertical lines Pointing: S/C pointing ring plane at 1.8 R_J (extremity of main rings) Satellite orientation: OFF-NADIR, Ring plane while maintaining horizontal orientation of MAJIS slit, MAJIS scan mode activated for vertical sampling centered on the rings (20 lines) Duration: 200 sec for one observations at a given phase angleMAJIS
UVS_IRR_SATObtain reflectance spectra of irregular satellitesUVS
PEP_GANYMEDE_IN_SITU_LOW_8Only PEP-Hi on (all in-situ), max power savings PEPLo Sensors ON: None PEPHi Sensors ON: JENI_Ion, JoEEPEPLO
SWI_STANDBYOnly the instrument DPU will be switched on and be able to accept instrument commands. Only housekeeping telemetry is generated in this mode.SWI
MAG_BURSTOperation of J-MAG in burst mode (measurement at rate of 128 vectors/s) starting 10 minutes before and ending 10 minutes after a predicted crossing of a thin current sheet in Ganymedes magnetosphere (magnetopause/magnetotail current sheet).JMAG
RIM_GANYMEDE_N4Passive Radar Acquisitions on Jovian side of Ganymede.RIME
PEP_IDLEPEP in IDLE mode PEPLO
PEP_SENSORS_STBYPEP in standbyPEPLO
SWI_SCIENCEPlace holder: one of the ASW mode, where the science script will be run ( i.e. from SWI_TSYS_CTS down to SWI_MOON_NADIR_STARE_FS) during the missionSWI
UVS_JUP_ROLL_SCANPoint to nadir. Rotate about nadir so that we scan a circle (or a fraction of a circle - e.g. covering the auroral regions) over Jupiter's disk. Rotation rate ~0.1 degree per secondUVS
UVS_SAT_SURF_APPushbroom observations near flyby closest approach to investigate surface compositionUVS
GAL_HR_TARGET_GANRegion of Interest Observation at GanymedeGALA
PEP_GANYMEDE_IN_SITU_NOMINAL_3Regular in-situ mode, ganymede phase. CA of moon flybys later in the mission (higher power consumption). Good for high quality, extended survey in charged particles. NIM, JNA off. PEP Hi on, all in-situ. PEPLo Sensors ON: JDC, JEI on, JNA & NIM off PEPHi Sensors ON: JENI_Ion, JoEEPEPLO
PEP_GANYMEDE_IN_SITU_NOMINAL_2Regular in-situ mode, ganymede phase. CA of moon flybys later in the mission (higher power consumption). Good for high quality, extended survey. All instruments on, NIM in ion mode (response of ionosphere to charged particles). PEP Hi on, all in-situ PEPLo Sensors ON: All sensors ON, NIM, JNA ion mode PEPHi Sensors ON: JENI_Ion, JoEEPEPLO
PEP_GANYMEDE_IN_SITU_NOMINAL_1Regular in-situ mode, ganymede phase. CA of moon flybys later in the mission (higher power consumption). Good for high quality, extended survey. All instruments on, NIM in neutral mode (response of exosphere to charged particles). PEP Hi on, all in-situ PEPLo Sensors ON: All sensors ON, NIM neutral mode, JNA ion mode PEPHi Sensors ON: JENI_Ion, JoEEPEPLO
PEP_JUPITER_IN_SITU_IMAGING_NOMINAL_1Regular magnetosphere in-situ & ENA imaging monitoring mode. Can work on flybys, if NIM off. PEPLo Sensors ON: JDC_LP, JEI (8 sectors), JNA PEPHi Sensors ON: Option 1: JENI_Combo, JoEE. Option 2: JENI_ENA, JoEEPEPLO
PEP_JUPITER_IN_SITU_NOMINAL_1Regular magnetosphere in-situ monitoring mode. Can work on flybys, if NIM off. PEPLo Sensors ON: JDC, JEI PEPHi Sensors ON: JENI_Ion, JoEEPEPLO
UVS_JUP_MONITORING_APReplaces previous monitoring stare. We perform a slow scan across the disk: assume 3 seconds per slit width, so 0.033 / s scan rateUVS
RIM_EUROPA_FLYBYRIME flyby observations or observations without on-board processingRIME
RIM_GANYMEDE_FLYBYRIME flyby observations or observations without on-board processing.RIME
RIM_CALLISTO_FLYBYRIME flyby observations or observations without on-board processing.RIME
RPW_DLRPWI observation during downlink windowsRPWI
RPW_STANDBYRPWI Safe mode where the instrument can survive indefinitely and where memory patch, dump and check commands are acceptedRPWI
RPW_INITRPWI Transient mode while instrument is initialising after being powered onRPWI
MAJ_AmaltheaS/C pointing Amalthea preferentially near maximal elongation of (2.54 R_J), 2 hemispheres, MAJIS spatial windowing (16 rows) pointing: OFF-NADIR, S/C pointing Amalthea at 2.54 R_J while maintaining horizontal orientation of MAJIS slit satellite orientation: Maintaining horizontal orientation of MAJIS slit, MAJIS scan mode activated for vertical sampling centered on the satellite (10 lines) Duration: 100 sec for one hemisphereMAJIS
PEP_GANYMEDE_IN_SITU_LOW_5Same as PEP_GANYMEDE_IN_SITU_LOW_1 but with lowest performance in JDC, JEI for max power savings while PEP-Lo is no (JEI 4 sectors, JDC low power). NIM, JNA off. Low power mode for Ganymede, good for long duration surveys. PEP Hi on, all in-situ PEPLo Sensors ON: JDC_LP, JEI 4 sectors, JNA & NIM off PEPHi Sensors ON: JENI_Ion, JoEEPEPLO
PEP_GANYMEDE_IN_SITU_LOW_2Same as PEP_GANYMEDE_IN_SITU_NOMINAL_1 but with low performance in JDC, JEI to limit power (JE 4 sectors, JDC low power). NIM neutral, JNA on. Low power mode for Ganymede, good for long duration surveys with multiple instruments. PEP Hi on, all in-situ. PEPLo Sensors ON: JEI: 4 sectors, JDC: LP, NIM: Neutral mode PEPHi Sensors ON: JENI_Ion, JoEEPEPLO
PEP_GANYMEDE_IN_SITU_LOW_3Same as PEP_GANYMEDE_IN_SITU_NOMINAL_1 but with low performance in JDC, JEI to limit power (JEI 4 sectors, JDC low power). NIM ion, JNA on. Low power mode for Ganymede, good for long duration surveys with multiple instruments. PEP Hi on, all in-situ PEPLo Sensors ON: JEI: 4 sectors, JDC: LP, NIM: Ion mode PEPHi Sensors ON: JENI_Ion, JoEEPEPLO
PEP_GANYMEDE_IN_SITU_LOW_4Same as PEP_GANYMEDE_IN_SITU_NOMINAL_1 but with low performance in JDC, JEI to limit power (JEI 4 sectors, JDC low power). NIM ion, JNA on. Low power mode for Ganymede, good for long duration surveys with multiple instruments. PEP Hi on, all in-situ PEPLo Sensors ON: JEI: 4 sectors, JDC: LP, NIM: Ion mode PEPHi Sensors ON: JENI_Ion, JoEEPEPLO
PEP_GANYMEDE_IN_SITU_LOW_1Same as PEP_GANYMEDE_IN_SITU_NOMINAL_3 but with low performance in JDC, JEI to limit power (JEI 8 sectors, JDC low power). NIM, JNA off. Low power mode for Ganymede, good for long duration surveys PEP Hi on, all in-situ PEPLo Sensors ON: JDC_LP, JEI (8 sectors) PEPHi Sensors ON: JENI_Ion, JoEEPEPLO
SWI_2D_MAP_FS_V1Same as SWI 2D MAP PS, except a frequency-switch calibration mode is used instead of position-switch. It enables spending  100% of the integration time on-source. If the purity of the spectral band is good enough, there is an option to pre-compute ON-OFF for the CTS before downlink.SWI
SWI_5POINT_CROSS_FS_V1Same as SWI 5POINT CROSS PS, except a frequency-switch calibration mode is used instead of position-switch. It enables spending  100% of the integration time onsource. For Jupiter, two CTS spectra are recorded for 60 seconds over 10000 channels (16 bits coding). For moon monitoring, two CTS spectra are recorded for 30 seconds over 210 channels (16 bits coding). For both cases, and in parallel, two CCH measurements (20 bits coding) are recorded for 0.1 second. If the purity of the spectral band is good enough, there is an option to pre-compute ON-OFF for the CTS before downlink. Frequency-switch calibration method for CTS data.SWI
SWI_JUP_LIMB_RASTER_FS_V1Same as SWI JUP LIMB RASTER PS, except a frequency-switch calibration mode is used instead of position-switch. It enables spending  100% of the integration time on-source. If the purity of the spectral band is good enough, there is an option to pre-compute ON-OFF for the CTS before downlink.SWI
SWI_JUP_LIMB_STARE_FS_V1Same as SWI JUP LIMB STARE PS, except a frequency-switch calibration mode is used instead of position-switch. It enables spending  100% of the integration time on-source. If the purity of the spectral band is good enough, there is an option to pre-compute ON-OFF for the CTS before downlink.SWI
SWI_MOON_LIMB_SCAN_FS_V1Same as SWI MOON LIMB STARE PS, except a frequency-switch calibration mode is used instead of position-switch. It enables spending  100% of the integration time on-source. Flyby: Two CTS spectra are recorded for 30 sec over 210 channels (16 bits coding). GCO: Two CTS spectra are recorded for 30 sec over 130 channels (16 bits coding) and a different altitude (5, 10, 20, 40, and 50 km) is scanned every orbit. If the purity of the spectral band is good enough, there is an option to pre-compute ON-OFF for the CTS before downlink.SWI
SWI_MOON_LIMB_STARE_FS_V1Same as SWI MOON LIMB STARE PS, except a frequency-switch calibration mode is used instead of position-switch. It enables spending  100% of the integration time on-source. Flyby: Two CTS spectra are recorded for 30 sec over 210 channels (16 bits coding). GCO: Two CTS spectra are recorded for 30 sec over 130 channels (16 bits coding) and a different altitude (5, 10, 20, 40, and 50 km) is scanned every orbit. If the purity of the spectral band is good enough, there is an option to pre-compute ON-OFF for the CTS before downlink.SWI
SWI_NADIR_STARE_FS_V1Same as SWI NADIR STARE PS, except a frequency-switch calibration mode is used instead of position-switch. It enables spending  100% of the integration time on-source. If the purity of the spectral band is good enough, there is an option to pre-compute ON-OFF for the CTS before downlink.SWI
SWI_SPECTRAL_SCAN_ACS_FS_V1Same as SWI SPECTRAL SCAN ACS PS, except a frequency-switch calibration mode is used instead of position-switch. It enables spending  100% of the integration time on-source. The ACS does not allow to pre-compute ON/OFF before downlink. A single execution can cover up to 11 tunings.SWI
SWI_SPECTRAL_SCAN_CTS_FS_V1Same as SWI SPECTRAL SCAN CTS PS, except a frequency-switch calibration mode is used instead of position-switch. It enables spending  100% of the integration time on-source. If the purity of the spectral band is good enough, there is an option to precompute ON-OFF for the CTS before downlink. A single execution can cover up to 9 tunings.SWI
UVS_JUP_HP_AIRGLOW_STARESame as UVS_JUP_AP_AIRGLOW_STARE but for High spatial resolution Port (HP). Monitoring auroral and airglow emissions in stare mode using the Airglow Port (AP). Slit held along Jupiter' s North/South and on the central meridian, while Jupiter rotates below S/C creating a map. Histogram mode.UVS
UVS_JUP_HP_LIMB_SCANSame as UVS_JUP_AP_LIMB_SCAN but through the HP portUVS
UVS_JUP_HP_SCAN_MAPSame as UVS_JUP_AP_SCAN_MAP but for High spatial resolution Port (HP). Scan the UVS slit in the cross slit direction across a region (e.g., auroral (N or S)) or entire disk using the Airglow (AP) port, scan at a constant rate across Jupiter to produce a map. Observation performed in pixel list mode to reach a time resolution of 0.001 s.UVS
UVS_JUP_AP_SCAN_MAPScan the UVS slit in the cross slit direction across a region (e.g., auroral (N or S)) or entire disk using the Airglow (AP) port, scan at a constant rate across Jupiter to produce a map. Observation performed in pixel list mode to reach a time resolution of 0.001 s.UVS
UVS_SAT_LIMB_STARE_HPSearch for faint atmospheric emissions by building signal to noise through long integrations.UVS
UVS_SAT_LIMB_STARE_APSearch for faint atmospheric emissions by building signal to noise through long integrations.UVS
UVS_SAT_LIMB_SCAN_HPSimilar to disc scan observations, but holding the pointing relative to the limb during flyby sequences.UVS
UVS_SAT_LIMB_SCAN_APSimilar to disc scan observations, but holding the pointing relative to the limb during flyby sequences.UVS
UVS_GCO_HISTOGRAM_003Similar to observation 001 but with increased spectral resolution to achieve < 2 nm resolution between 100 and 200 nm as specified in SciRDUVS
UVS_GCO_HISTOGRAM_002Similar to observation 001 but with Increased time sampling to capture auroral morphology and variabilityUVS
SWI_2D_MAP_OTF_CCH_V1Similar to SWI 2D MAP PS, but using an on-the-fly recording sequence, i.e. the OFF position per map row is only observed once.SWI
SWI_2D_MAP_OTF_V1Similar to SWI 2D MAP PS, but using an on-the-fly recording sequence, i.e. the OFF position per map row is only observed once.SWI
SWI_2D_MAP_OTFSimilar to SWI 2D MAP PS, but using an on-the-fly recording sequence, i.e. the OFF position per map row is only observed once.SWI
UVS_EUR_SCAN_HIGH_RES_OBSOLETESimilar to UVS_DISK_SCAN but higher resolution. pointing: start at -1.5 satellite radii from the satellite centre, scan in the direction perpendicular to the slit across the disk, ending at +1.5 satellite radii from the centreUVS
UVS_IO_SCANSimilar to UVS_DISK_SCAN, but including extra emission lines e.g. from S and Cl. Also requires different spatial binning since Io is more distantUVS
GAL_GAN_OFF_POINTINGspecific observation for polar geometry with off-pointing w.r.t Nadir during GCO500. Only to be executed TBD time. Similar profile than GAL_MONITORING_GAN but with off nadir pointing requestGALA
SWI_TSYS_ACS_CCH_V1Spectral scan to measure the system temperature spectra of the 2 bands with the ACS & CCH 1 & 2 by observing the hot load and cold sky. Integration time on ACS is 1 second. A single execution can cover up to 15 tunings.SWI
SWI_TSYS_ACS_CCHSpectral scan to measure the system temperature spectra of the 2 bands with the ACS & CCH 1 & 2 by observing the hot load and cold sky. Integration time on ACS is 1 second. A single execution can cover up to 15 tunings.SWI
SWI_TSYS_ACS_V1Spectral scan to measure the system temperature spectra of the 2 bands with the ACS 1 & 2 by observing the hot load and cold sky. Integration time on ACS is 1 second. A single execution can cover up to 16 tunings.SWI
SWI_TSYS_CCH_V1Spectral scan to measure the system temperature spectra of the 2 bands with the CCH 1 & 2 by observing the hot load and cold sky. A single execution can cover up to 16 tunings.SWI
SWI_TSYS_CTS_V1Spectral scan to measure the system temperature spectra of the 2 bands with the CTS 1 & 2 by observing the hot load and cold sky. Integration time on CTS is 2 seconds. A single execution can cover up to 15 tunings.SWI
MAJ_BORESIGHT_ALIGNEMENTStar sequence for geometrical calibration. A star is initially pointed using the MAJIS boresight, then MAJIS is operated with the scan mechanism at high resolution (1/3 of IFOV) over 18 lines centered in the star. Then this operation is successively observed after 4 S/C repointings of 1.5° around X and Y. Pointing : inertial Satellite orientation: S/C pointing the star and MAJIS scans Duration: 18 to 180 sec per position (5 positions in total)+ stabilization time for repointing not taken into accountMAJIS
MAJ_JUP_EVENT_MONITORINGStudy of the evolution of unusual phenomena in Jupiter atmosphere, especially in their zonal evolution MAJIS will acquire several “subcubes” with limited number of lines (about 80) as follows: 1. a series of sub-cubes (from 1 to 4) is acquired with the scan mirror to get the coverage of a limited latitude region at all longitudes on the visible side of the planet. Satellite is re-pointed before acquiring each sub-cube 2. the series at previous point is repeated at fixed time intervals (in the order of 1 h, TBC) to monitor the temporal evolution. Pointing type: YS, Series of OFF-NADIR pointings (‘off-nadir scan mode’) satellite orientation: HORIZONTAL Duration: 160 sec for each sub-cube. Time between series defines actual temporal sampling and is variable (zero data rate here). Total duration about 5 h (1/2 of rotation period)MAJIS
MAJ_GCO5000_GLOBALSystematic mapping performed with cross-track binning by 4 during circular phase (~120 days) 3 km/pixel, 300x300 km swaths, spatial binning x 4. Pointing: YS, Nadir Satellite orientation: MAJIS slit at a slant with the ground track except at the equator Duration: 4H per orbit (one cube: 6 min)MAJIS
JAN_SCI_INERTIALTBWJANUS
UVS_JUP_SP_SOL_OCCThe large solar disc and the substantial distance from Jupiter mean that this will not provide the same vertical resolution as stellar occultations, but are useful for measurements of minor/trace constituents due to high S/N. This uses a fixed scan through the Solar Port (SP) at a selected RA and DEC, holding the pointing for an extended amount of time. Note: Here histograms, but pixellist mode possible.UVS
MAJ_JUP_LIMB_SCANThe MAJIS pointing mirror is used to scan the atmosphere of Jupiter over the limb up to 1500km. Exposure times are optimized for weak limb emissions. The scan mirror step of 1/10 MAJIS IFOV shall constrain the spatial sampling provides a spatial supersampling adequate to reconstruct, by deconvolution, the signal vertical profile at sub-pixel scale. Observations consists in sets of max. 8 cubes at different latitudes, around the limb of the planet. Duration: Typically 20 min for each cube (110 lines), assuming 11 s per lineMAJIS
MAJ_JUP_HIGH_FREQ_MONITORINGThe observing type is designed to study the evolution of atmospheric features at high temporal frequency as well as to map specific atmospheric features at regional scale. Scanning of features on the Jovian disc, on dayside as well as on nightside, with limited latitudinal coverage. MAJIS will acquire one or more several “subcubes” with a limited number of lines (about between 64 and 160) Duration: between 84 and 315 s for each cube, assuming 2.1 s per lineMAJIS
DRAFT_3GM_OCCULTATIONThe radio science experiment 3GM, with its dual-frequency radio links (X and Ka-band) referenced to an ultrastable oscillator (USO), is performed as JUICE spacecraft moves in and out of occultation. Occultations occur throughout the jovian tour, but their phasing is not always synchronized with the timing of dedicated Jupiter observations by the other orbiter experiments. USO unmuted, HAA in NOMINAL SCIENCE. Note that 2 other options exist for torus occultations but are not (yet) defined in the database3GM
3GM_RADIO_OCCULTATIONSThe radio science experiment 3GM, with its dual-frequency radio links (X and Ka-band) referenced to an ultrastable oscillator (USO), is performed as JUICE spacecraft moves in and out of occultation. USO unmuted, HAA in NOMINAL SCIENCE. Note that 2 other options exist for torus occultations but are not (yet) defined in the database3GM
RPW_In_situ_burst_Radio_burstThe RPWI In-situ_burst + Radio_burst mode: - Makes continuous In-situ_burst mode measurement. In addtion to in-situ_slow modes, In-situ_burst mode adds continuous measurements of electric and magnetic fields at higher cadence (763 smpl/s) as well as more frequent snapshots at higher frequencies (MF - 50 ksmpl/s and HF - 312 ksmpl/s) - Makes full plasma wave measurements and high-time resolution monitoring up to 1.6MHz as well as cover the low frequency and DC electric field and density measurements.RPWI
RPW_In_situ_burst_Radio_FullThe RPWI In-situ_burst + Radio_Full mode: - Makes continuous In-situ_burst mode measurement. In addtion to in-situ_slow modes, In-situ_burst mode adds continuous measurements of electric and magnetic fields at higher cadence (763 smpl/s) as well as more frequent snapshots at higher frequencies (MF - 50 ksmpl/s and HF - 312 ksmpl/s); - Makes detailed radio emissions from Jupiter as well as moons (Ganymede, Callisto, Europa). Will also support RIME measurements, giving the background natural radio emissions. Monitor the radio emission spectrum as well as polarization.RPWI
RPW_In_situ_burst_Radar_mode_3The RPWI In-situ_burst + Radio_mode_3 mode: - Makes continuous In-situ_burst mode measurement. In addtion to in-situ_slow modes, In-situ_burst mode adds continuous measurements of electric and magnetic fields at higher cadence (763 smpl/s) as well as more frequent snapshots at higher frequencies (MF - 50 ksmpl/s and HF - 312 ksmpl/s); - Radio mode TBDRPWI
RPW_OBSOLETE_In_situ_low_Radio_burstThe RPWI In-situ_low + Radio_burst mode: - Makes continuous In-situ_low mode measurement, the lowest in-situ possible power and TM, which implements only the Mutual Impedance sweeps and DC electric field measurements; - Makes full plasma wave measurements and high-time resolution monitoring up to 1.6MHz as well as cover the low frequency and DC electric field and density measurements.RPWI
RPW_IN_SITU_LOW_RADIO_FULLThe RPWI In-situ_low + Radio_Full mode - Makes continuous In-situ_low mode, the lowest in-situ possible power and TM, which implements only the Mutual Impedance sweeps and DC electric field measurements; - Makes detailed radio emissions from Jupiter as well as moons (Ganymede, Callisto, Europa). Will also support RIME measurements, giving the background natural radio emissions. Monitor the radio emission spectrum as well as polarization.RPWI
RPW_OBSOLETE_In_situ_low_Radar_mode_3The RPWI In-situ_low + Radio_mode_3 mode: - Makes continuous In-situ_low mode measurement, the lowest in-situ possible power and TM, which implements only the Mutual Impedance sweeps and DC electric field measurements; - Radio TBDRPWI

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