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1. s 23 6 4 1 MB SiS CUS a wes vate ate ects cca ia 23 PC13 DATA ANALYSIS RED INTERFACE GD01 ccccccccccccccccccccccceccoeco0eeo0eeo0ecoueses 26 7 1 GIADA STATUS EE 26 SES GRAIN DETECTION SYSTEM GDS 29 E24 SEC ERRE EE 29 7 3 IMPACTESENSOR Sissi ais 32 7 3 1 a E EE 32 7 3 1 1 EE EE 34 7 4 MICRO BALANCE SYSTEM MBS s 36 74 1 MBS EU e de rg 36 TIMELINES FOR GIADA PETS iaa 38 8 1 TIMELINE FOR MAIN INTERFACE GD301 38 8 2 TIMELINE FOR REDUNDANT INTERFACE GD01 40 GIAD A R OS ETT A rl REECH Consortium GIADA Date 9 01 2012 Page 4 GIAD A R OS ETT A na id teste Consortium GIADA Date 9 01 2012 Page 5 REVISIONS LOG DOCUMENT CHANGE ORDER DATE CHANGES DESCRIPTION PREPARED GIAD A R OS ETT A na BEER Consortium GIADA Date 9 01 2012 Page 6 1 SCOPE AND APPLICABILITY Payload Checkout 13 PC13 was the final Cruise Phase Checkout of several payload checkouts performed with the Rosetta Payload Since PC13 was scheduled as the final Cruise Phase Checkout a number of additional payload operations were also executed to close out pending and essential requirements and or configure instruments for the upcoming Deep Space Hibernation Phase Given the importance of this final checkout all Rosetta payload except Osiris took pa
2. Reference RO GIA OACUPA RP 116 Issue 1 Rev 0 Date 9 01 2012 Page 24 PC13 HK T Main PC13 HK T Main MBS3 MBS4 MB3_nn MB4_nn EI uo EH El a MB3 HEAT E 2 MB4_HEAT 2 Es 2 E 32 5 MBS3 TEMP MBS4 TEMP 31 T T T T 10 31 T T T T 5 250148000 250158000 250168000 250178000 250188000 250198000 250148000 250158000 250168000 250178000 250188000 250198000 Event Time s Event Time s PC13 HK T Main MBS5 42 80 MB5 nn 41 10 40 60 39 50 38 37 40 o 2 o MB5 HEAT 36 30 35 20 34 10 33 z 0 3 MBS5_TEMP 31 T T T T 10 250148000 250158000 250168000 250178000 250188000 250198000 Event Time s Fi 4 3 MBSs F d T j j igure 6 4 3 MBSs Frequency and Temperature vs time Main Main PC13 Main PC13 MBS 1 Normal MBS 2 Normal f and T vs time fand T vs time 60 5870 60 2645 2640 50 50 2635 5850 40 40 2630 5840 TEMP 5 7 TEMP 2 30 2 30 2625 x e FREQ E FREQ 5830 2620 20 20 5820 2615 10 10 3830 2610 0 5800 0 2605 250148000 250158000 250168000 250178000 250188000 250198000 250148000 250158000 250168000 250178000 250188000 250198000 MB Event Time s MB Event Time s Main PC13 Main PC13 MBS 3 Normal MBS 4 Normal fand T vs time fand T vs time 60 4100 50 2640 45 4090 50 2620 40 4080 35 40 2600 70 e 30 m TEMP gt gt TEMP 9 30 4060 9 25 2580 E ew rBER E
3. Author PP AA GIADA Date 07 OGtobet 2010 Proposed by GIADA team c ESA Estec mc rc CLE f i EPS required but RSOC will use CVS version Version 00001 Ref date 05 Dec 2010 Start times DOO 00200200 Eno trime QOO 12 00 00 GIADA R OS ETT A nen da e Consortium GIADA Date 9 01 2012 Page 40 SS SS SS SS SS SS SS SS SS SS SS SS SS SS SS i Description l Switch on and test Main I F EE EE 000 0020000 GIADA OFF AGDSOOIA VGD0001B nom branch ENG GIADA on Main IF VGDOODIA YES ENG Context exists TODO 00703200 GIADA SAFE AGDS003A Patch SW v 2 3 E000 00207 00 GIADA SAFE AGDS005A Dump CT RAM 000 00 08 00 GIADA SAFE AGDS035A Go to Cover Mode F000 00409400 GIADA COVER AGDF090A Open cover Description 5 minutes waiting then 1 min for OBCP ezecution and 4 min for a margin of heating time 000_00 19 00 GIADA COVER AGDS065A Go to Safe mode FO00 00 20 00 GIADA SAFE AGDS110A Go to Normal mode Description GIADA operating in Normal mode TODO Oe e GIADA NORMAL AGDS120A VGDS0010 OxF8 VGDS0011 0x04 X Calibrate IS GDS MBS REPEAT 110 SEPARATION 00 05 00 Description Change GIADA settings and check effects 1100 09252200 GIADA NORMAL AGDF100A Self interference test FOOD LOES 2000 GIADA NORMAL AGDFO55A MBS heating E ennen nennen enn
4. KA z MB1_nn v BS HEAT MB4 HEAT HMB3 HEAT MB2 HEAT 250185000 250195000 250205000 250215000 250225000 250235000 250245000 Event Time s MBI HEAT Figure 7 4 2 MBSs Temperature vs time SCI Red PC13 HK T Red PC13 HK T Red MBS1 MBS2 42 80 42 80 f MB1 nn MB2 nn 41 1 70 41 70 40 ee 60 1 60 39 39 38 E 38 d Be 97 i Te 9E 40 _ Ei Y ge MB1 HEAT Ei amp g MB2 HEAT 36 4 30 F 36 i 30 35 35 20 20 34 3 34 ds 10 33 33 i 0 i 0 32 MBS1 TEMP 32 1 MBS2 TEMP 250185000 250195000 250205000 250215000 250225000 250235000 250245000 250185000 250195000 250205000 250215000 250225000 250235000 250245000 Event Time s Event Time s Status GIADA Consortium PC13 HK T Red MBS3 R Reference RO GIA OACUPA RP 116 OSETTA nae Rev 0 Date 9 01 2012 GIADA PC13 HK T Red MB3 nn T C MB3 HEAT Status 32 MBS3 TEMP 31 T T T T T 250185000 250195000 250205000 250215000 250225000 250235000 250245000 Event Time s PC13 HK T Red MBS5 MB5 nn MB5 HEAT T C MBS5 TEMP T T T T 250205000 250215000 250225000 250235000 250245000 Event Time s Figure 7 4 3 MBSs Frequency and Temperature vs time Red g E 31 T T T T T 10 250185000 250195000 250205000 250215000 2502
5. FREQ 20 4050 20 2560 15 4040 10 10 2540 4030 0 4020 0 2520 250148000 250158000 250168000 250178000 250188000 250198000 250148000 250158000 250168000 250178000 250188000 250198000 MB Event Time s MB Event Time s GIADA Consortium TEC ROSETTA GIADA Main PC13 MBS 5 Normal fand T vs time Reference RO GIA OACUPA RP 116 Issue Date 9 01 2012 50 7 3820 45 3800 40 35 3780 30 25 3760 3740 3720 3700 0 zi 250148000 gt 250158000 T T 250168000 250178000 MB Event Time s 250188000 250198000 1 TEMP s FREQ Rev O Page 25 Status GIADA R OS ETTA Beleeg RO RP Consortium GIADA Date 9 01 2012 7 1 GIADA STATUS Figure 7 1 1 HK Status of GIADA vs time Red PC13 GIADA HK Status Red Page 26 EV REP TM OFW nn SCI TM OFW nn SCLTM EN MOTOR A V5POS PC 250185000 250195000 250205000 250215000 250225000 250235000 250245000 Event Time s Figure 7 1 2 Power profile and Power Supply temperature vs time HK Red PC13 HK Red PS T Power 35 1600 PS TEMP 30 1400 25 1200 20 T O 1000 E 5 5 15 E 800 5 E 10 S a 600 o D 200 10 250185000 250195000 250205000 250215000 250225000 250235000 250245000 Event Time s V15POS_PC V15NEG PC Temperature C GIADA R O S ETTA Beleeg BEE Consortium GIADA Date 9 01 2012 Page
6. 27 40 30 20 30 250185000 Temperature C 250185000 Figure 7 1 3 Evolution of temperatures of system elements vs time HK Red Temperatures of System Elements PC13 Red HK 30 25 20 E 1 SN I FB TEMP PS TEMP ADC TEMP 250195000 250205000 250215000 250225000 250235000 250245000 Event Time s Figure 7 1 4 Evolution of temperatures of sub systems vs time with instrument in Normal Mode Red Temperatures of Sub Systems PC13 Red Normal Mode OL1 TEMP L2 TEMP sL3 TEMP ett 7444 L4_TEMP n 4 n 1S PLATE TEMP E we N Stine M eo E A ih MB1_TEMP MB2 TEMP MB3 TEMP eMB4 TEMP EMBS TEMP 250195000 250205000 250215000 250225000 250235000 250245000 Event Time s Status Status GIADA R O S ETT A Beleeg RO RP Consortium GIADA Date 9 01 2012 Page 28 Figure 7 1 5 HK Status versus Temperatures of system elements Red PC13 Red OP MODE nn HK Status System Temperatures SCLTM EN MOTOR GDS STATUS nn Temperature C LASER POW nn IS STATUS na MBS STATUS nn FB TEMP IS TEMP 250185000 250195000 250205000 250215000 250225000 250235000 250245000 Event Time s PS TEMP Figure 7 1 6 Operation Status versus Temperatures of system elements Red In the diagram are reported operative parameters with relevant variations PC13 HK Red
7. GAIN PZT2 GAIN PZT1 S STATUS nn P 7 T5 nn P7 TA nn PZT3 nn P7T2 nn PZT1 nn GAIN PZT5 DAIN PZT4 AIN PZT3 GAIN_PZT2 GAIN PZT1 a IS TEMP IS PLATE TEMP GIADA Consortium 7 3 1 1 CAL ROSETTA GIADA Reference RO GIA OACUPA RP 116 Issue 1 Rev 0 Date 9 01 2012 Page 34 Figure 7 3 5 PZTs Mean and St Dev CAL vs time Red PC13 Red PC13 Red PZT1 MEAN PZT2 MEAN 0 08 0 08 0 06 0 06 0 04 0 04 0 02 0 02 o k 0 02 k 002 o o 0 04 0 04 0 06 0 06 0 08 0 08 0 1 0 1 250185000 250195000 250205000 250215000 250225000 250235000 250185000 250195000 250205000 250215000 250225000 250235000 Event Time s Event Time s PC13 Red PC13 Red PZT3 MEAN PZT4 MEAN 0 08 0 08 0 06 BS 0 04 0 04 0 02 0 02 o E 5 P i 0 02 S E 0 02 0 04 0 04 0 06 0 06 0 08 0 08 0 1 250185000 250195000 250205000 250215000 250225000 250235000 250185000 250195000 250205000 250215000 250225000 250235000 Event Time s Event Time s PC13 Red PZT5 MEAN 250205000 0 1 250185000 250195000 PZT5 MEAN 250215000 250225000 250235000 Event Time s Reference RO GIA OACUPA RP 116 Issue 1 Rev 0 Date 9 01 2012 Page 35 GIADA Consortium ROSETTA GIADA Figure 7 3 6 Reference Voltages for IS calibration vs time Red Voltages values for the calibrator don t show level variation PC13 Red IS CA
8. i T Gees 6 2 T 2 5 i H o PZT3 Stim2 2 4 o PZT 4 Stim2 3 vy 4 gt qe 5 L EL AW LL B LI OM mil illl 7 Ki I II WK 3 1 Dulli Ze ND IL W M UL VAL ATE HUE NI SS Fini T 12 2 bu s PZT 3 Stim 3 2 s PZT 4 Stim3 2 L 0 14 lo 1 04 T e T 2 04 i e e e 2 is TEMP 250185000 250195000 250205000 250215000 250225000 250235000 250245000 250185000 250195000 250205000 250215000 250225000 250235000 250245000 Event Time s Event Time s 1S TEMP GIADA R OS ETT A Beleeg RO REA Consortium GIADA Date 9 01 2012 Page 36 PC13 Red IS PZT5 CAL T 4 PZT 5 Stim0 10 12 10 IW a y y PZT 5 Stim 1 7 M 78 a S T T 2 n 6 al e I o 8 5 A ENEE ge YA PZT 5 Stim2 o H 4 E 4 3 V 4 55 PZT 5 Stim3 2 0 1 0 4 r r T T 2 IS_TEMP 250185000 250195000 250205000 250215000 250225000 250235000 250245000 Event Time s 7 4 MICRO BALANCE SYSTEM MBS 7 4 1 MBS Status Figure 7 4 1 MBS Operation Status vs time Red PC13 HK Red MBS STATUS nn hi BS nn BA nn MB3 nn 1182 nn
9. last packet received The first expected packet Connection Test Report service 17 2 was not received in the time window of any test because the DDS has marked it with a wrong UTC time being an unsynchronised time tag bad time quality TM report At the 3 IS power on both on Main I F Sun Dec 05 2010 16 32 01 and Red I F Mon Dec 06 2010 04 32 01 the event Hardware error in IS event detection circuitry No IRO received was received see TCTM report file residing in the log directory of GES This is a false message produced by the ME of GIADA when the IS electronics is powered on This is a known problem see relevant Remark in GIADA FS UM AD 41 The time line was modified respect to the PC12 the procedure AGDS065A Go to Safe mode was eliminated and we changed the procedure AGDFO60A Go to Safe mode amp Power off including AGDS007A Dump CF NVRAM In this way during PC13 all the tele commands was accepted and executed As reported in the Cover Reports CREP no OPEN CLOSE problem occurred during PC13 5 2 GIADA STATUS The current consumption and power supply temperatures are shown in Errore L origine riferimento non stata trovata for Main on GDO1 Errore L origine riferimento non stata trovata for Red on GD01 Power values must be compared with soft and hard limits reported in GIADA FS UM ADA and summarised in Table 5 2 1 GIADA R OS ETTA Reference RO GIA OACUPA RP 116 Issue 1 Rev 0
10. L origine riferimento non stata trovata 4 The peaks visible at the beginning and at the end of Frangibolt and IS temperature profiles are features due to the temporary increasing of power consumption at Power on of the motor heaters see Figure 6 1 5 and Figure 6 1 6 for Main on GDO1 Errore L origine riferimento non stata trovata and Errore L origine riferimento non stata trovata for Red on The trend of the IS Temperature is more noisy with the Main than with the Red I F Main on GDOI Figure 6 3 4 Red on GDO1 Errore L origine riferimento non stata trovata The detection Thresholds applied on GDS are shown in GIADA R OS ETTA Reference RO GIA OACUPA RP 116 Issue 1 Rev 0 Consortium GIADA Date 9 01 2012 Page 12 Figure 6 2 2 Main on GD01 Errore L origine riferimento non stata trovata Red on GDO1 Errore L origine riferimento non stata trovata while those applied to PZT3 and PZTS of IS are shown in Figure 6 3 23 and Figure 6 3 34 Main on GD01 Errore L origine riferimento non stata trovata 3 and Errore L origine riferimento non stata trovata 4 Red on GD01 Moreover Range and Gain for IS are set as shown in Table 5 2 2 GAIN RANGE PZTA PZTB PZTC PZID PZTE Low High High High High High Table 5 2 2 IS Range and Gain configuration During PC13 no scientific data were occurred During PC13 test the GDS CAL data show for the GDS Left side an output level of about 1 V and for the GDS
11. OP_MODE_nn OPs System Temperatures EV REP TM OFW nn rr SCL TM OFW nn SCI TM EN FRANGIBOLT aa MOTOR o ero CU 3 o E o E S TEMP 250185000 250195000 250205000 250215000 250225000 250235000 250245000 Event Time s PS TEMP GIADA R OS ETTA Beleeg RO RE Consortium GIADA Date 9 01 2012 7 2 GRAIN DETECTION SYSTEM GDS 7 2 1 GDS Status Status Status A C CO e o o o A O co Figure 7 2 1 GDS Operation Status vs time Red PC13 HK Main GDS 17 16 ES 15 Pg 14 13 e 12 e CS z 250185000 250195000 250205000 250215000 250225000 250235000 250245000 Event Time s Figure 7 2 2 GDS Thresholds change vs time Red PC13 HK Red GDS THRs 18 1 8 16 1 6 14 1 4 12 1 2 N o 7 A 41 250185000 250195000 250205000 250215000 250225000 250235000 250245000 Event Time s Page 29 GDS STATUS nn LASER POW nn REC LEFT nn REC RIGHT nn ASER STATUS nn OP MODE nn GDS STATUS nn LASER STATUS nn Status Status GIAD A R O S ETT A Beleeg a np Consortium GIADA Date 9 01 2012 250185000 39 33 32 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 250185000 Figure 7 2 3 GDS Laser Temperatures vs time Red PC13 NM T Red GDS Core nts A TA HR d c e K Ur IE AA A en A Ring KD EEE e A E T
12. 00 00 GIADA Update and optimization of timing amongst all the sequences now GIADA is fully operating in Normal Mode after only 25 minutes The sequence AGDS002A Patch CT v flight 1 has been removed as it was unnecessary GIADA R OS ETT A Reference RO GIA OACUPA RP 116 Issue 1 Rev 0 Consortium GIADA Date 9 01 2012 Page 39 T Revision 159 2006 10 07 11222235 GIADA timing changed after results of PC2 sequences updated after PCl have internal timing slightly different wrt previous sequences and requires this correction in the timeline for future PCn Also IS and GDS thresholds have been modified t Revision 1 7 2006 09 05 112224253 vanir Updated to have relative timing Note No Generic Switch ON OFF used Use in PC4 Passive PCn to Revision Loo 2006 07 18 09 05 58 dhrri t Updated for PC3 And use of top level itl that was necessary for use of PORG F Revision 1 5 2006 01 24 18 51 20 kwirth Final GD OIOR for PC2 Original filename OIOR PIHRSO D 0000 GD PCA3 00013 ROS Version 1 3 2005 12 12 giada MAIN for PCn Passive Checkout OIOR for GD after sequences update RSOC Assumption MSP Il ff SSS SS SS SS SSS SSS SS SSS SS SS SS SS SSS SS SS SS SS SS SS SS SS SS SS SSS SS SS SSS SSS SSS SSS HF Filename OIOR PIHRSO D 0000 GD OIM 00054 ROS Type Input Timeline file Description Ultimate timeline for the GIADA Passive Checkout operations on Main I F
13. 08 0 1 0 1 250147000 250157000 250167000 250177000 250187000 250197000 250148000 250158000 250168000 250178000 250188000 250198000 Event Time s Event Time s PC13 Main PC13 Main PZT3 MEAN PZT4 MEAN 0 08 0 08 0 06 EES 0 04 0 04 0 02 0 02 0 0 02 X 0 02 0 04 0 04 0 06 0 06 0 08 0 08 0 1 250148000 250158000 250168000 250178000 250188000 250198000 250148000 250158000 250168000 250178000 250188000 250198000 Event Time s Event Time s PC13 Main PZT5 MEAN 0 08 0 06 0 04 0 02 0 i 0 02 ki 0 04 0 06 0 08 0 1 250148000 250158000 250168000 250178000 250188000 250198000 Event Time s Reference RO GIA OACUPA RP 116 Rev 0 Page 22 GIADA Consortium ROSETTA GIADA Issue 1 Date 9 01 2012 Figure 6 3 6 Reference Voltages for IS calibration vs time Main Voltages values for the calibrator don t show level variation PC13 Main IS CAL Ref Voltage T n gt 5 a o o 3 O E D ISLTEMP 250148000 250158000 250168000 250178000 250188000 250198000 Event Time s Figure 6 3 7 PZTs CAL Signal vs time Main PC13 Main PC13 Main IS PZT1 CAL T IS PZT2 CAL T PZT 1 Stim 0 PZT 2 Stim 0 9 12 0 5 12 10 1
14. C 250195000 250205000 250215000 250225000 250235000 250245000 Event Time s Figure 7 2 4 GDS Laser Monitor vs time Red PC13 NM Light Mon Red GDS 0 7 0 65 0 55 0 45 Light Mon W 0 35 0 25 0 2 250195000 250205000 250215000 250225000 250235000 250245000 Event Time s Page 30 GDS STATUS nn LASER nn LASER POW nn REC LEFT nn REC RIGHT nn a ASER STATUS nn L1 TEMP L3 TEMP L4 TEMP GDS STATUS nn LASER nn LASER POW nn REC LEFT nn REC RIGHT nn ASER STATUS nn L1 LIGHT L3 LIGHT L4 LIGHT GIADA R O S ETTA Reference RO GIA OACUPA RP 116 Issue 1 Rev 0 Consortium GIADA Date 9 01 2012 Page 31 Figure 7 2 5 Lasers Light Monitor versus Temperature HK HK SCI SCI Red PC13 Red PC13 Red Laser 1 Mon vs T Laser 2 Mon vs T L2 LMON HK OL2 MON L2 LIGHT Laser Mon W oo o Laser Mon W o S 0 58 L1 LMON HK OLA MON L1 LIGHT 5 3 4 1 3 5 7 9 Laser Mon W T C PC13 Red Laser 4 Mon vs T L4 LMON HK OL4 MON LA LIGHT Laser Mon W 4 2 0 2 4 6 8 10 T C T C Figure 7 2 6 GDS Laser Monitor vs time Red PC13 Red GDS CAL T vs time 1 6 15 LEFT MEAN RIGHT MEAN 10 GDS CAL Signal V 1 5 0 8 A OL1_TEMP oL2 TEMP E 0 0 6 5 OL3_TEMP AL4_TEMP 0 10 250190000 250200000 250210000 250220000 250230000 250240000 Event Time s G
15. Consortium GIADA Date 9 01 2012 Page 11 As reported in GIADA FS UM ADA the Soft and Hard Alarm Limits for Power consumption in Table 5 2 1 for parameters NGDD0086 NGDD0087 and or NGDD0088 refer to the different GIADA operating modes The Soft Alarm Limits in Normal and Flux Modes refer to nominal conditions 1 e with all sub systems switched ON This means that when GIADA is in Normal Mode but not with all sub systems ON or in Flux with MBS OFF the lower Soft Alarm Limits indicated in the Table can be overcome In order to avoid flood of Out Of Limits OOL alarms it has been decided July 2006 to refer the Hard Alarm Limits to the extreme instrument status for each mode eg in normal mode with all subsystems off lower or at maximum power consumption upper Other configurations not related to real GIADA failure may still give OOL related to operation in non nominal temperature conditions although such conditions have never been experienced so far In general all functional parameters measured during the PC13 test behave as expected with the exception of some OOLs reported in the previous section 5 1 Table 5 2 1 Hard and Soft limits for GIADA FS power consumption Safe mode Cover mode Normal mode Flux mode All Temperatures behave as expected Main on GDO1 Errore L origine riferimento non stata trovata 3 Figure 6 1 4 Red on GDO1 Errore L origine riferimento non stata trovata 3 Errore
16. XA JN Y NW MI el ON N d M Ivy 8 Mn e PZT 5 Stim 1 M 7 MI 6 P N gt B AA 4 p H KE RARA RIONI o PZT 5 Stim2 5 5 uc 2 im o A D hi 4 0 Ii II 5 2 s PZT 5 Stim3 2 4 1 6 04 T T T T 8 IS TEMP 250148000 250158000 250168000 250178000 250188000 250198000 Event Time s 6 4 MICRO BALANCE SYSTEM MBS 6 4 1 MBS Status Figure 6 4 1 MBS Operation Status vs time Main PC13 HK Main MBS STATUS nn MBS 42 BS nn 41 BA nn 40 39 MB3 nn 38 MB2 nn of z MB1_nn o 36 MB5_HEAT 39 34 MB4 HEAT 33 MB3 HEAT 32 MB2 HEAT 31 250148000 250158000 250168000 250178000 250188000 250198000 Event Time s MBI HEAT Figure 6 4 2 MBSs Temperature vs time SCI Main PC13 HK T Main PC13 HK T Main MBS1 MBS2 42 80 42 80 41 Gi n mn 8 B2_nn 40 dl ee 60 60 39 39 38 e 38 pa dI 1 DI 40 _ Zeg 31 gt MB1_HEAT 2 5 MB2 HEAT 36 4 30 F 36 Da 30 35 35 x 20 20 34 mg A 34 40 10 33 33 32 4 1 MBS1 TEMP 32 1 MBS2 TEMP 2501486000 250158000 250168000 250178000 250188000 320146000 250158000 250168000 250178000 250188000 Event Time s Event Time s GIADA Consortium ROSETTA GIADA
17. 0 250185000 250195000 250205000 250215000 250225000 250235000 250245000 MB Event Time s 8 TIMELINES FOR GIADA PC13 8 1 TIMELINE FOR MAIN INTERFACE GD01 SLog OIOR PIHRSO D 0000 GD OIM 00054 ROS v Revision 1 11 2010 10 07 12 00 00 GIADA This is intended to be the ultimate timeline for the Passive Payload Checkout operations GIADA is fully operating in Normal Mode after 20 minutes Sequences AGDS004A Patch CT in RAM and AGDS006A Patch CF in NVRAM have been removed as they are now unnecessary after the last memory patch successfully performed during PC12 The sequence AGDS007A Dump CF NVRAM has been removed as it is now ingested in the sequence AGDFO60A Go to Safe mode Power off after the recent FOP updates As a consequence the previous sequence AGDS065A Go to Safe mode was useless and it has been removed as well Revision 1 10 2010 02 05 12 00 00 GIADA Dump CT RAM inserted after Power ON and Patch SW in order to check the last functional configuration of GIADA i e the configuration at the previous Power OFF Dump CF NVRAM inserted before shut down in order to get a report of the last Contezt file Only for Main I F gt Patch CT in RAM and CF in NVRAM in order to load on board the parameters settings again after the erasing of SSMM Payload Context file occurred during the last DSHM commissioning test 20 27 Jan 2010 Revision 1 9 2009 06 22 12
18. 01 2012 Page 8 3 DEFINITIONS AND ABBREVIATIONS 3 1 ABBREVIATIONS CAL Calibration CF Context File CREP Cover REPort CT Configuration Table DDS Data Disposition System EGSE Electrical Ground Support Equipment EQM Electrical Qualification Model ESA European Space Agency FCP Flight Control Procedure FS Flight Spare GDS Grain Detection System GES GIADA EGSE SW GIADA Grain Impact Analyser and Dust Accumulator HK House Keeping I F InterFace INAF OAC INAF Osservatorio Astronomico di Capodimonte Napoli 1 IRQ Interrupt ReQuest IS Impact Sensor IWS Instrument Work Station MBS Micro Balance System ME Main Electronics MTL Mission TimeLine MON Monitor OBCP On Board Control Procedure PC Payload Checkout PI Principal Investigator PS GIADA Power Supply PZT IS Piezoelectric Sensor RED Redundant REV Revision RMOC Rosetta Mission Operation Centre RSOC Rosetta Science Operation Centre S C Rosetta Spacecraft S S GIADA Sub system e g IS or GDS or MBS SCI Scientific SSC Source Sequence Count SSMM Solid State Mass Memory on board of Rosetta Spacecraft SW Software TC TeleCommand TM Telemetry UM User Manual UTC Coordinated Universal Time VCO Virtual Channel 0 Real Time TM packets VCI Virtual Channel 1 TM packets coming from Mass Memory GIAD A R OS ETT A na BEER Consortium GIADA Date 9 01 2012 Page 9 4 DESCRIPTION OF ACTIVITIES The Passive Payload Checkout n 13 PC13 scenario beg
19. 25000 250235000 250245000 Event Time s EI 3 7 2 31 250185000 250195000 Red PC13 MBS 1 Normal fand T vs time 9 E 0 250185000 TEC 0 250185000 250195000 250195000 250205000 250205000 250215000 250225000 MB Event Time s Red PC13 MBS 3 Normal fand T vs time 250215000 MB Event Time s 250225000 250235000 250235000 Red PC13 MBS 2 Normal fand T vs time TEC 250245000 250185000 250195000 250205000 250215000 250225000 250235000 MB Event Time s Red PC13 MBS 4 Normal fand T vs time TEC 60 4090 50 2640 45 50 4080 2620 40 4070 35 40 2600 30 4060 ke TEMP 30 T 25 2580 FREQ 4050 20 20 2560 4040 13 10 10 4030 2540 5 4020 0 2520 250245000 250185000 250195000 250205000 250215000 250225000 250235000 MB Event Time s Page 37 MB4_nn 250245000 250245000 MB4_HEAT MBS4_TEMP 60 5870 60 2645 5060 2640 50 50 2635 5850 40 40 2630 5840 m TEMP a 30 E 30 2625 Y FREQ FREQ 5830 2620 20 20 5820 2615 10 10 5810 2610 5800 0 2605 GIADA R OS ETT A Reference RO GIA OACUPA RP 116 Issue 1 Rev 0 Consortium GIADA Date 9 01 2012 Page 38 Red PC13 MBS 5 Normal f and T vs time 45 7 4 3800 40 3790 35 3780 3770 30 3760 3750 TEMP s FREQ T C 3740 3730 3720 3710 0 T T T T t 370
20. 50198000 Event Time s GAIN_PZT1 Figure 6 3 2 IS PZT 3 Thresholds change vs time Main PC13 HK Main OP MODE mn PZT3 THS 0 16 IS STATUS n 0 14 0 12 0 1 3 S 0 08 a GAIN PZT5 0 06 GAIN PZT4 0 04 GAIN PZT3 0 02 GAIN FZT2 0 GAIN PZTt 250148000 250158000 250168000 250178000 250188000 250198000 Event Time s mo PZTI_THS Status Status GIADA R O S ETTA Beleeg Renee Page 20 Consortium GIADA Date 9 01 2012 Figure 6 3 3 IS PZT 5 Thresholds change vs time Main PC13 HK Main OP MODE nm PZT5 THS 0 25 IS STATUS nn 0 2 0 15 0 1 GAIN PZT4 0 05 GAIN PZT3 GAIN PZT2 0 250148000 250158000 250168000 250178000 250188000 250198000 Event Time s e Pers Figure 6 3 4 IS Temperature vs time HK HK SCI SCI Main PC13 Main IS STATUS m IS Status T 7T5 nn 774 nn P7 13 nn P712 nn PZT1 nn o E GAIN_PZT5 GAIN_PZT4 GAIN PZT3 GAIN PZT2 GAIN PZT 1 O IS TEMP 250148000 250158000 250168000 250178000 250188000 250198000 Event Time s IS PLATE TEMP GIADA R O S ETTA Reference RO GIA OACUPA RP 116 Issue 1 Rev 0 Consortium GIADA Date 9 01 2012 Page 21 6 3 1 1 CAL PZT Mean V PZT Mean V Figure 6 3 5 PZTs Mean and St Dev CAL vs time Main PC13 Main PC13 Main PZT1 MEAN PZT2 MEAN 0 08 0 08 0 06 0 06 0 04 0 04 0 02 0 02 0 e 0 0 02 0 02 s 0 04 0 04 0 06 0 06 0 08 0
21. 8 7 PZT 1 Stim 1 PZT 2 Stim 1 T6 6 r 4 e 5 See 3 i S i d 1 9 PZT 1 Stim2 Bo PZT2 Stim2 5 A 5 e 4 E FR e hi d 0 hi 3 des PZT 1 Stim3 PZT 2 Stima 2 4 0 1 4 1 6 0 05 6 o T T B 18 TEMP 04 T T T T 8 IS TEMP 250148000 250158000 250168000 250178000 250188000 250198000 250148000 250158000 250168000 250178000 250188000 250198000 Event Time s Event Time s PC13 Main PC13 Main IS PZT3 CAL T IS PZT4 CAL T PZT 3 Stim 0 PZT 4 Stim 0 10 12 8 12 9 S Ka mat 10 E A LK N 10 A A r N 7 7 PILA ar MN N AMANTI y IN A MM WWW ES S MY e AM nV T8 ik n V PZT 3 Stim 1 6 A Y en j y i i M i H 6 s 8 A 4 m A j lug gt P ik B 5 ru 2 9 PZT3 Stim2 B 4 2 O PZT4 Stim2 B WI kl Mi A Ill A 5 Le UA At i 31 NAVI UNTIL TELE 2 La GER PZT 3 Stima 2 PZT 4 Stima 2 4 do V 1 1 6 6 04 T T T T 8 IS TEMP 0 T T T T 8 IS TEMP 250148000 250158000 250168000 250178000 250188000 250198000 250148000 250158000 250168000 250178000 250188000 250198000 Event Time s Event Time s GIADA R OS ETTA Reference RO GIA OACUPA RP 116 Issue 1 Rev 0 Consortium GIADA Date 9 01 2012 Page 23 PC13 Main IS PZT5 CAL T 4 PZT 5 Stim0 10 12 A A A A Kal 10 Il saar
22. GIADA R OS ETT A Reference RO GIA OACUPA RP 116 Issue 1 Rev 0 Consortium GIADA Date 9 01 2012 Page 1 GIADA FS MODEL REPORT ON IN FLIGHT PASSIVE PAYLOAD CHECKOUT N 13 PC13 performed on 1 12 2010 and 9 12 2010 PREPARED APPROVED AUTHORIZED GIADA TEAM GIADA PI GIADA PI A ROTUNDI V DELLA CORTE R SORDINI M ACCOLLA A ROTUNDI A ROTUNDI INAP Osservatorio Astronomico di Capodimonte Napoli 1 Universit Parthenope Napoli 1 GIAD A R OS ETT A rl han an eee di Consortium GIADA Date 9 01 2012 Page 2 Led leg c Ste 9 Ee Es GIADA R OS ETT A na BEER Consortium GIADA Date 9 01 2012 Page 3 TABLE OF CONTENTS SCOPEANDAPPLICGABIENEN cian 6 REFERENCES IN ASS 7 2 1 APPLICABLE DOCUMENT sirio nai 7 2 2 REFERENCE DOCUMEN T susino 7 DEFINITIONS AND ABBREVIATIONS s 8 3 1 ABBREVIATIONS EE 8 ESCRIPTION OF ACTIVITIES 000 9 SUMMARY OF DATA ANALYSIS EE 10 5 1 GENERAL CONSIDERATIONS s 10 5 2 GIADASTA TU Sra 10 PC13 DATA ANALYSIS MAIN INTERFACE GDOD cccccccccccccccccccccccooooooccccooouuueee 13 6 1 GIADA STATUS rc 13 6 2 GRAIN DETECTION SYSTEM GDS s s 16 6 2 1 GDS E EE 16 6 3 IMPACT SENSOR ES lisina siii 19 6 3 1 DESH IR eenen eetset 19 6 3 1 1 A E ENS 21 6 4 MICRO BALANCE SYSTEM MBS
23. IADA R O S ETT A Reference RO GIA OACUPA RP 116 Issue 1 Rev 0 Consortium GIADA Date 9 01 2012 Page 32 7 3 IMPACT SENSOR IS 7 3 1 IS Status Figure 7 3 1 IS Operation Status vs time Red PC13 HK Red 18 STATUS m IS 31 PZT5 nn 30 P7 T4 nn 29 PZT3 nn 28 21 PZ T2 nn 26 PZT1 nn 5 E 25 a 24 23 GAIN_PZT5 22 GAIN PZT4 21 GAIN PZT3 20 GAIN PZT2 19 250185000 250195000 250205000 250215000 250225000 250235000 250245000 Event Time s GAIN_PZT1 Figure 7 3 2 IS PZT 3 Thresholds change vs time Red PC13 HK Red OP MODE nn PZT3 THS 35 0 16 IS STATUS nn 30 0 14 0 12 25 0 1 20 3 5 0 08 a 15 0 06 GAIN_PZT4 10 0 04 GAIN_PZT3 5 0 02 GAIN_PZT2 0 RE e 0 GAIN EZ 250185000 250195000 250205000 250215000 250225000 250235000 250245000 Event Time s mo PZT3 THS Status Status GIADA Consortium 250185000 250185000 Figure 7 3 3 IS PZT 5 Thresholds change vs time Red PC13 HK Red PZT5 THS 250195000 250195000 250205000 250205000 ROSETTA GIADA 250215000 Event Time s 250225000 PC13 Red IS Status T 250215000 Event Time s 250225000 Reference RO GIA OACUPA RP 116 Issue 1 Date 9 01 2012 250235000 250235000 0 25 0 2 0 15 0 1 0 05 250245000 T C 250245000 Rev O Page 33 OP_MODE_nn IS STATUS nn GAIN PZT4
24. L Ref Voltage T PZT Output V 250185000 250195000 250205000 250215000 Event Time s 250225000 T C 250235000 250245000 Figure 7 3 7 PZTs CAL Signal vs time Red PC13 Red PC13 Red IS PZT1 CAL T IS PZT2 CAL T PZT 1 Stim 0 PZT 2 Stim 0 9 12 0 5 12 NA JU M YA 8 M PY T a xfi fh E cts QN 10 PERE POR Zwee ETE A 10 NV A 0 4 7 5 PZT 1 Stim1 r e PZT 2 Stim 1 T 035 M 1 6 V 034 t 2 5 y 6 wA i A 76 ka 2 o PZT 1 Stim2 025 E o PZT2 Stim2 W 6 4 E 6 E d 4 J 4 hi 0 2 i 3 1 la 0 15 V T2 s PZT 1 Stim3 s PZT 2 Stim3 014 0 0 1 0 05 E 04 T e T e i 2 TER o4 Y e r 2 is TEMP 250185000 250195000 250205000 250215000 250225000 250235000 250245000 250185000 250195000 250205000 250215000 250225000 250235000 250245000 Event Time s Event Time s PC13 Red PC13 Red IS PZT3 CAL T IS PZT4 CAL T PZT 3 Stim 0 3 PZT 4 Stim 0 10 12 8 12 n AA AA NA S p V v A ADAM NJ ATA pa Aff Ww di 7 zul v wW M Win s d MIN 1 10 wrt 10 GES A nv g Ww t A A y e PZT 3 Stim 1 6 f e PZT 4 Stim 1 d d HR 7 A CH 7 8 S ul s i 5
25. PC13 Main Normal Mode 28 OL1 TEMP L2 TEMP 23 sL3 TEMP 18 L4 TEMP 13 A rar Ma d AN AIS PLATE TEMP MB1 TEMP 8 MB2 TEMP 3 MB3 TEMP MB4 TEMP 2 EMB5 TEMP 1 250145000 250155000 250165000 250175000 250185000 250195000 Event Time s Status Status GIAD A R O S ETT A Beleeg ROANNE Consortium GIADA Date 9 01 2012 Page 15 Figure 6 1 5 HK Status versus Temperatures of system elements Main PC13 Main HK Status System Temperatures 15 10 OF MODE nn SCLTM EN MOTOR GDS STATUS nn IS STATUS nn MBS STATUS nn FB TEMP IS TEMP PS TEMP EN REP TM OFW nn SCIL TM OFW nn 5 0 o 5 E E E 4108 E o po 15 20 25 30 250148000 250158000 250168000 250178000 250188000 250198000 Event Time s Figure 6 1 6 Operation Status versus Temperatures of system elements Main In the diagram are reported operative parameters with relevant variations PC13 HK Main OP MODE nn OPs System Temperatures SCI TM EN FRA NGIBOLT o Si OPEN RS 3 S o CLOSE D RS o E o E FB TEMP S TEMP 250148000 250158000 250168000 250178000 250188000 250198000 Event Time s PS TEMP GIADA R OS ETTA Reference RO GIA OACUPA RP 116 Issue 1 Rev 0 Consortium GIADA Date 9 01 2012 Page 16 6 2 GRAIN DETECTION SYSTEM GDS 6 2 1 GDS Status Figure 6 2 1 GDS Operation Status vs time Main PC13 HK Main GD
26. Right side a saturation level of about 0 2 V depending on temperature These are the nominal values occurring when the GDS is not saturated The frequency level of all MBS has not relevant changes with respect PC 12 GIADA R OS ETTA Reference RO GIA OACUPA RP 116 Issue 1 Rev 0 Consortium GIADA Date 9 01 2012 Page 13 6 1 GIADA STATUS Figure 6 1 1 HK Status of GIADA vs time Main PC13 GIADA HK Status Main EV REP TM OFW nn SCI TM OFW nn SCI TM EN MOTOR Status 250145000 250155000 250165000 250175000 250185000 250195000 Event Time s PC13 HK Main PS T Power 1600 PS TEMP 1400 1200 2 4 V5POS_PC O 1000 c o o 2 2 B d 800 E 2 o E 5 Y 600 2 e 3 V45POS PC D 400 8 200 V15NEG PC 10 0 250148000 250158000 250168000 250178000 250188000 250198000 Event Time s Temperature C Temperature C GIADA R OS ETTA Reference RO GIA OACUPA RP 116 Issue 1 Rev 0 Consortium GIADA Date 9 01 2012 Page 14 Figure 6 1 3 Evolution of temperatures of system elements vs time HK Main Temperatures of System Elements PC13 Main HK 40 30 EB TEMP 20 hig ee 10 gt 0 MTO Ma L PS_TEMP 10 20 ADC TEMP 30 250148000 250158000 250168000 250178000 250188000 250198000 Event Time s Figure 6 1 4 Evolution of temperatures of sub systems vs time with instrument in Normal Mode Main Temperatures of Sub Systems
27. S ENG Context exists 000_12 03 00 GIADA SAFE AGDS003A Patch SW v 2 3 FUSO LZ 07 200 GIADA SAFE AGDSOO5A F Dump CT RAM 000 12 08 00 GIADA SAFE AGDS035A Go to Cover Mode SEA 12 09 00 GIADA COVER AGDF090A Open cover Description 5 minutes waiting then 1 min for OBCP execution and 4 min for a margin of heating time 000 12271000 GIADA COVERAGDS065A Go to Safe mode TOU 12020200 GIADA SAFE AGDS110A Go to Normal mode Description GIADA operating in Normal mode GIADA R OS ETT A na WA hia di Consortium GIADA Date 9 01 2012 Page 43 POOO 12222200 GIADA NORMAL AGDS120A VEDSO00LO OXF X VGDS0011 0x04 Calibrate IS GDS MBS REPEAT 110 X SEPARATION 00 05 00 Description Change GIADA settings and check effects 000 2199200 GIADA NORMAL AGDF100A Self interference test 000_22 32 00 GIADA NORMAL AGDF055A MBS heating SS ecc t Descriptions YA Shut down EE HOOD 28752400 GIADA NORMAL AGDF060A Go to Safe mode amp Power off
28. S GDS STATUS nn 19 18 17 LASER POW mn 16 KA s v 15 REC LEFT nn 14 REC RIGHT nn 13 12 AAA i AAA 250148000 250158000 250168000 250178000 250188000 250198000 LASER STATUS nn Event Time s Figure 6 2 2 GDS Thresholds change vs time Main PC13 HK Main GDS THRs ge GDS_STATUS_nn KA s Vv LASER_STATUS_nn 250148000 250158000 250168000 250178000 250188000 250198000 Event Time s Status Status GIAD A R O S ETT A Beleeg SOE ONCE RANE Consortium GIADA Date 9 01 2012 250148000 35 33 32 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 250148000 Figure 6 2 3 GDS Laser Temperatures vs time Main PC13 NM T Main GDS T C 250158000 250168000 250178000 250188000 250198000 Event Time s Figure 6 2 4 GDS Laser Monitor vs time Main PC13 NM Light Mon Main GDS 0 7 Light Mon W 0 2 250158000 250168000 250178000 250188000 250198000 Event Time s Page 17 GDS_STATUS_nn LASER_nn LASER POW nn REC LEFT nn REC RIGHT nn _ ASER STATUS nn L1 TEMP L3 TEMP L4 TEMP GDS STATUS nn LASER nn LASER POW nn REC LEFT nn REC RIGHT nn ASER STATUS nn L1 LIGHT L3 LIGHT L4 LIGHT Laser Mon W Laser Mon W GIADA R O S ETTA Reference RO GIA OACUPA RP 116 Issue 1 Rev 0 Consortium GIADA Date 9 01 2012 Page 18 Figure 6 2 5 Las
29. ers Light Monitor versus Temperature HK HK SCI SCI Main PC13 Main PC13 Main Laser 1 Mon vs T Laser 2 Mon vs T 0 54 0 53 0 52 0 51 ta L1 LMON HK E L2 LMON HK 0 49 OL1_MON E OL2 MON LI LIGHT S 12 LIGHT 0 48 8 I 0 47 0 46 0 45 0 44 5 3 A 1 3 5 7 9 T C T C PC13 Main PC13 Main Laser 3 Mon vs T Laser 4 Mon vs T 0 67 0 68 0 67 0 66 0 66 0 65 0 65 ani 0 64 0 63 0 62 0 63 _ 061 L3 LMON HK E 0 6 L4 LMON HK 0 62 HL3 MON El 0 59 OL4_MON L3 LIGHT 5 058 gt L4 LIGHT 0 61 8 0 57 0 56 0 6 SS 0 59 wen 0 53 0 58 0 52 0 51 0 57 0 5 4 2 0 2 4 6 8 10 4 T C T C Figure 6 2 6 GDS Laser Monitor vs time Main PC13 Main GDS CAL T vs time 1 6 RIGHT MEAN 14 1 2 OA AS AO i Ta i E ges A i i E ais ap E veil IT o 4 SC sti hrs i A i c 7 o 2 0 8 Re n o 06 0 4 0 2 AL4 TEMP 0 250140000 250150000 250160000 250170000 250180000 250190000 250200000 Event Time s GIADA R O S ETTA Reference RO GIA OACUPA RP 116 Issue 1 Rev 0 Consortium GIADA Date 9 01 2012 Page 19 6 3 IMPACT SENSOR IS 6 3 1 IS Status Figure 6 3 1 IS Operation Status vs time Main PC13 HK Main 18 STATUS m IS 31 PZT5 nn 30 PZT4 nn 29 PZT3 nn 28 27 PZT2_nn 26 PZT1 nn 3 Z 25 a 24 23 GAIN_PZT5 22 GAIN_PZT4 21 GAIN PZT3 20 19 GAIN_PZT2 250148000 250158000 250168000 250178000 250188000 2
30. g changed after results of PC2 sequences updated after PCL have internal timing slightly different wrt previous sequences and requires this correction in the timeline for future PCn Also IS and GDS thresholds have been modified i Revision 1 7 2000709705 1122223 waver Updated to have relative timing Note No Generic Switch ON OFF used Use in PC4 Passive PCn it Revision L6 2006 07 13 09 05 50 Sanit Updated for PC3 And use of top level itl that was necessary for use of PORG Revision l5 2006 01 24 18 51 46 weth Pirtek GD TOR Tor BEZ Original filename OIOR PIHRSO D 0000 GD PCB3 00014 ROS Version 1 3 2005 12 12 giada REDUNDANT for PCn Passive Checkout OIOR for GD after sequences update RSOC Assumption MSP 11 Filename OTOR PLARSO Dv 0000 GD VIR 00055 ROS Type Input Timeline file H GIADA R OS ETT A na WA tes Consortium GIADA Date 9 01 2012 Page 42 Description Ultimate timeline for the GIADA Passive Checkout operations on Red I F LUCIO PP AA GIADA Date 07 October 2010 Proposed by GIADA team c ESA Estec EPS required but RSOC will Use CVS version Version 00001 Ref gate 0s Dec 2010 Start time 000 0020000 Bnd time 00901 00400400 EE Description TI Switch on and test Redundant I F EE POOO T22 U0 010 GIADA OFF AGDS001A N VGD0001B red branch ENG GIADA on Red IF VGDOO0O1A YE
31. ins on the 1st December 2010 and ran for 9 days to the 9th December 2010 according to the timelines reported 13 PC13 in Section About GIADA PC13 consists only of a passive test named GDOI in ESA document GDO1 is the passive test routinely executed in every payload checkout 6 Months status check PC13 1s a maintenance and calibration scenario plan and therefore there are no scientific objectives Details of the plan of activities referred to as passive part of PC13 are in Section 8 1 No problem appeared during PC13 open close cover procedures In the next table there are some information about PC13 36 AU Earth distance 4 4 AU The data were off line elaborated on the PI IWS at INAF OAC in Naples GIADA R OS ETTA Reference RO GIA OACUPA RP 116 Issue 1 Rev 0 Consortium GIADA Date 9 01 2012 Page 10 5 SUMMARY OF DATA ANALYSIS The full sets of plots about Housekeeping data are reported in Sections 6 and 7 for GDOI test on the Main and Redundant I F s respectively Here following the main findings are summarised 5 1 GENERAL CONSIDERATIONS Test started on Sun Dec 05 2010 06 16 12 473107 when the first TM packet was received from GIADA switched on the Main interface the last TM packet on the Main interface was received on Sun Dec 05 2010 17 55 01 515007 Test on the Redundant interface started on Sun Dec 05 2010 18 16 12 476032 1 packet received and ended on Mon Dec 06 2010 20 40 45 987052
32. n SS SS AAA AAA i Description 2 Shut down gere eeu oci SERES E 5 000 11922 7040 GIADA NORMAL AGDF060A Go to Safe mode Power off 8 2 TIMELINE FOR REDUNDANT INTERFACE GD01 i oLhog OIOR EIHRSO D 0000 GD 01R 00055 ROS v S Revision 1 11 2010 10 07 12 00 00 GIADA GIADA R OS ETT A Reference RO GIA OACUPA RP 116 Issue 1 Rev 0 Consortium GIADA Date 9 01 2012 Page 41 This is intended to be the ultimate timeline for the Passive Payload Checkout operations GIADA is fully operating in Normal Mode after 20 minutes The sequence AGDS007A Dump CF NVRAM has been removed as it is now ingested in the sequence AGDFO60A Go to Safe mode Power off after the recent FOP updates As a consequence the previous sequence AGDSO65A Go to Safe mode was useless and it has been removed as well Revision LLO 2010502705 12 00 00 GIADA Dump CT RAM inserted after Power ON and Patch SW in order to check the Last Turetional configuration of GIADA i e the configuration at the previous Power OFF Dump CF NVRAM inserted before shut down in order to have a report of the last Context file t Revision Leo 2009 06 22 12200400 GIADA Update and optimization of timing amongst all the sequences now GIADA is fully operating in Normal Mode after only 25 minutes The sequence AGDS002A Patch CT v flight 1 has been removed as it was unnecessary Revision 1 8 2006 10 07 11 22 23 GIADA timin
33. rt in this scenario The Payload Checkout 13 ran for 9 consecutive days starting on the Ist December 2010 until the 9th December 2010 An RSI passive checkout was also completed on 14 December 2010 The Scenario was covered by dedicated NNO and DSN During PC13 GIADA performs only a passive test GDO1 similar to the previous Passive Payload Checkouts This passive test GDO1 which includes standard procedures and full functional verification was executed by switching on Main and Redundant I Fs in sequence and executing similar procedures for the two cases This document reports the results obtained on GIADA experiment during PC13 This report is applicable to GIADA FS model on board the Rosetta S C The data were retrieved from DDS by means of the PI Workstation located at Universit Parthenope in Naples GIADA IWS software configuration 1s GES v 4 2 2 plus RSOC Converter v 1 1 2 GIADA in flight software configuration 1s 2 3 plus three additional patches one more patch 1s used to update the context file GIAD A R OS ETT A na BEER Consortium CIADA Date 9 01 2012 Page 7 2 REFERENCES 2 1 APPLICABLE DOCUMENT RO EST RS 3001 EID A ROSETTA Experiment Interface Document Part A RO EST RS 3009 EIDB e GIADA Experiment Interface Document RO ESC PL 5000 last issue Flight Control Procedure GIA GAL MA 007 Issue 4 GIADA Hight Spare Experiment User Manual last version GIAD A R OS ETT A na id hice Consortium GIADA Date 9

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