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ISOC Status Review

ISOC Status Review. June 3, 2004. Overview. We have developed an organization and staffing plan in concert with the SLAC management. ISOC buildup started, rapid ramp up over next year We have completed initial work on an operations architecture.

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ISOC Status Review

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  1. ISOC Status Review June 3, 2004

  2. Overview • We have developed an organization and staffing plan in concert with the SLAC management. • ISOC buildup started, rapid ramp up over next year • We have completed initial work on an operations architecture. • We have made good progress in addressing peer review RFAs • Substantial work remains before CDR but we believe we now understand the scope and will be ready by 7/15.

  3. LAT/ISOC Organization Post Launch SSAC NASA GLAST Project Science Analysis Coordination Committee SAC head, Analysis leads, ISOC rep, SAS head 4.1 PI: P. Michelson Inst Sci: S.Ritz Instrument Ops Advisory Board H/W subsystem leads, key Technical Advisors from throughout collaboration 4.1.B 4.1.B.4 ISOC Manager W. Craig (Acting) Science Analysis Center Resources Only 4.1.B.1 4.1.B.2 4.1.B.3 LAT Ops Facility (LOF) Sci. Ops Group (SOG) Sci. Analysis SW (SAS) R. Dubois Software Calib Flt S/w & Testbed Pipeline Collab Operations Optimization Pipeline Config. Anayl Tools Computing

  4. Staffing • Rob Cameron has accepted the ISOC manager position, so there will (finally) be a permanent ISOC manager in place in August. • Craig will be responsible for a successful CDR and will keep Cameron updated throughout. • Several month transition period planned • Steve Culp has accepted S/W developer position and will start within a week. He will be responsible for fleshing out the architecture and first database implementations.

  5. Staffing Profiles Excludes SAS and SAC.

  6. Staffing Profiles (with SAS/SAC) Does not include Stanford, UCSC, NRL, GSFC or collaboration members.

  7. Architecture • Drivers • Minimize V&V burden and total cost • Maintain all science capabilities • Simplify interfaces and allow early testing • Recognized that neither of the previously considered options were particularly attractive • ITOS/Commercial packages don’t accommodate complexities of science data • Homegrown system doesn’t have heritage, not ready in time to make project timelines. • Most of additional code needed duplicates that in existing packages •  Studied hybrid solutions

  8. ITOS/Astro RT Trade • In favor of either • Both AstroRT and ITOS would provide basic instrument health and safety functions • Telemetry display • EU conversion • Limit checking and monitoring • Trending • Command and telemetry database access • Both products have learnable interfaces and scripting • AstroRT uses LabView for display and Perl scripts for automation • ITOS displays are reportedly easy to create, uses STOL for input

  9. ITOS/Astro RT Trade • Against either • Requires use of ITOS or Astro-RT specific interfaces and scripting • Both have ITAR issues • Limitations are not fully understood • Believe limitations will not affect monitoring and trending of housekeeping data – only science and instrument diagnostics

  10. ITOS/Astro RT Trade • In favor of AstroRT • LAT is using AstroRT for LAT flight software testing • Against AstroRT • Does not handle character strings – not sure if that’s an issue for us (it is with GBM) • Commercial product costing $$$ upfront and for support throughout program life • Probably unable to alter AstroRT code • In favor of ITOS • MOC and GBM will be using ITOS • May be able to alter ITOS code or have changes made • Against ITOS • None that don’t also exist for AstroRT

  11. Proposed ISOC S/W Architecture No req’ts on MOC that require LATOPS layer All State of Health requirements satisfied within ITOS MOC/GSSC ITOS Cmd DB SOH trending and display Data Cmd LATTE Ops  LATOPS Science data/performance trending Register load generation Relational database interaction Pipeline/SAS interactions

  12. RFA responses

  13. RFA responses, cont’d

  14. RFA 2 – ISOC Functional Block Diagram • RFA 2 Specific Request: • Need an overall functional block diagram illustrating the functional capabilities and a data flow diagram showing the various data flows, with the differences among the I&T (pre-launch w/GSE) phase, L&EO phase, and nominal on-orbit phase configurations specified • Diagrams for each phase might be needed

  15. ISOC Dataflow During I&T Single Tower Testing • Obtain data during I&T EM2 testing • Goal is to read houskeeping data off flat file produced by Online • Database development and maintenance is shared between I&T and ISOC

  16. ISOC Dataflow During I&T Multi-Tower Testing • Obtain data during I&T testing • Increase in ISOC functionality

  17. ISOC Dataflow with TestBed - Direct to SIU • Direct interface with SIU for CCSDS command and telemetry packets • Obtain testbed simulated data via SIU • Demonstration of ISOC capability increases as functionality is developed

  18. ISOC Dataflow with TestBed - With SIIS • Interface with SIIS/AstroRT for telemetry packets and commanding • Obtain testbed simulated data via SIU and SIIS • Demonstration of ISOC capability increases as functionality is developed

  19. ISOC Dataflow During GRTs, L&EO and On-orbit • Shows full ISOC capability for L&EO and On-orbit • GRTs will test capabilities as they are available

  20. RFA 3 - ISOC Risk Analysis • Process • Discussion with I&T personnel on risks • Internal discussion performed in concert with RFA’s from peer review • Review and approval by ISOC stakeholders • Follow-up • Entry into LAT risk management database by 06/01/04 • Weekly tracking, updating by ISOC management

  21. RFA 3 – ISOC Risk Analysis

  22. RFA 3 – ISOC Risk Analysis

  23. RFA 7 – ISOC Reports • Specific Request • Define and document the types of reports that will be generated by the ISOC for both internal use and for use by external systems (like the MOC and GSSC) • Response • Reports will be documented in the Operations Product ICD (external reports) and LAT Ops Plan (internal-only reports)

  24. RFA 7 – ISOC Reports • LAT status and planning • Reported daily (TBR) • Summary of LAT health status • Limit violations • Alerts received • Current LAT configuration • Commanding and any other special activities that occurred • Mission planning outlook for near term (time period TBD) • Generated by LOF with automatic and manual inputs • Published to web server

  25. RFA 7 – ISOC Reports • LAT performance • Reported daily (TBR) • Quick look science data • Performance metrics (details TBD) • Generated by SOG • Published to web server • Level 0 data transmission report • Data transmission metrics (details TBD) • Automatically generated and sent to MOC following receipt of Level 0 data

  26. RFA 7 – ISOC Reports • Data Trending • Housekeeping data • Environmental data (temp, voltages, currents) • Derived science quantities • Trigger efficiency • Total count rate • Bright source monitoring • Includes statistical analysis • Generated automatically daily/weekly/monthly • Published to the web

  27. RFA 9 - ISOC Lessons Learned • Issue • No writeup on lessons learned from visits to other instrument/mission operations center • Resolution • Members of the ad hoc planning group for the definition of the LAT IOC (now ISOC) made visits to the operations centers for GP- B (launched April, 2004; Stanford Univ., Tom Langenstein & Brett Stroozas), RHESSI (launched 2002; Berkeley Space Sciences Lab., David Smith & Manfred Bester), and Chandra (launched in 1999; MIT & Harvard-Smithsonian Center for Astrophysics, Dan Schwartz & Paul Plucinsky) • Each of these operations centers integrates mission operations with science (instrument) operations, and so they are not directly comparable to the ISOC in terms of complexity or staffing. (The operations center for RHESSI includes the ground station.) • LAT ISOC can learn from others but there are no direct models.

  28. RFA 9 - Lessons Learned • The science operations center for GP-B is co-located with the science team at Stanford. The GP-B data also will be distributed widely to collaborating institutions, but the co-location at Stanford was deliberate to maximize the interaction with the SOC on data issues. • Colocation important to maximize science. • The staffing for RHESSI operations is especially spare. The facility itself is also used to run operations for FAST and CHIPS and the routine operations, like scheduling of contacts and pipeline processing, are automated. Testbeds (simulators for the instrument computers) are maintained, and have been found vital for understanding anomalies as well as for testing flight software updates. • Testbeds important for flight software updates.

  29. RFA 9 - Lessons Learned • The Chandra Operations Control Center has a room with about 4 consoles for the ACIS instrument team to monitor and command the instruments. The ACIS team has developed an impressive, flexible facility for trend analysis. The importance of a flexible system that does not require deciding in advance what needs to be monitored routinely was stressed to us. The ground-based calibration data are still actively used, >4 years into the mission. Colocation of the operations (mission and instrument) and the ACIS instrument team has been important, at least in terms of increased efficiency. Instrument team members (like the PI) at Penn State can feel out of the loop or behind the times. • Colocation important to keep all science members in the loop.

  30. RFA 11 – LAT Modes • Specific Request: • LAT Operations Team and Spectrum Astro should work together to verify if any interactions between LAT modes and spacecraft modes need to occur. For example, if a LAT mode change requires the spacecraft to change spacecraft mode and/or configuration • Response: • SC modes are understood and accommodate the LAT modes as designed

  31. RFA 11 – LAT Modes, cont’d

  32. LAT Modes, cont’d

  33. RFA-12: Number of EEPROM Writes • Specific Request • Understand the number of writes to EEPROM on LAT from all sources • Reason • EEPROMs have a limited number of write cycles before they become unreliable • Response • Not an issue due to use of TrueFlash File System overlay (full description is on RFA response, available on ISOC web page)

  34. RFA 14 - ISOC Data Storage • Issue • No agreement with SLAC management on how data storage and processing requirements will be funded. • Resolution • Estimate of processing and data storage requirements performed for SAS by R. DuBois. Cost determined and built into ISOC outyear funding plan and accepted by SLAC Director of Research • Database costs still being evaluated by database working group but now expected to be minimal or covered completely by SLAC central computing services due to small size (~ 1Tb) of database.

  35. RFA 14 - Monthly Costs 2005 2007 2008 2006

  36. RFA 17 – Define LOF/SOG Tools • Specific Request: • The tools needed to run the LOF/SOG need to be specified • Which HK and science parameters will be monitored and in what way? • What actions would be taken based on the results seen with these tools? • How does the ISOC team know from a design perspective that the collection of the described I&T tools will function in the operations environment as an integrated system? • Reason/Comment: • The overall requirements on the ISOC have been given • Detailed plans for which software components/libraries such as Python will be used were given • However, lists of which software tools are required to achieve the ISOC’s requirements are needed

  37. RFA 17 - Response • Which HK and science parameters will be monitored and in what way? • HK parameters are defined in LAT-TD-02905 • Routinely monitored science parameters are included within the HK data as Low Rate Science • Use of high rate science data is being developed by SVAC and will be further developed by SOG • Limits and use of HK data for monitoring are TBD • What actions would be taken based on the results seen with these tools? • Calibration activities are in development in the SVAC • Contingency actions are TBD

  38. RFA 17 - Response, cont’d • How does the ISOC team know from a design perspective that the collection of the described I&T tools will function in the operations environment as an integrated system? • Development and testing of ISOC tools is in conjunction with I&T • Lists of which software tools are required to achieve the ISOC’s requirements are needed • The following slides detail the ISOC software tools

  39. RFA 17 - ISOC Software Tools

  40. RFA 17 - ISOC Software Tools, cont’d

  41. RFA 17 - ISOC Software Tools, cont’d

  42. RFA 17 - ISOC Software Tools, cont’d

  43. RFA 17 - ISOC Software Tools, cont’d

  44. RFA-18: ISOC Operations automation • Specific Request • Specify plans and requirements for automation of operations software • Describe the software design for how the automation needs will be met • Response • Draft of the plans and requirements has been completed • Software design will commence when ISOC software engineer is hired

  45. RFA-18: ISOC Operations automation • Data retrieval from MOC • OPUS: • Archiving raw data • Dispatch science data to SOG • Dispatch housekeeping to LOF • LOF automated processing • Housekeeping: limit checks, warnings • Science data: raw data quality • Automated reporting of above (web/paging/email) • Trending: • Weekly/monthly characterization of data • Calibration tracking & computation • External agency alert retrieval (i.e., SEC, NIST)

  46. Roadmap to CDR • Primary tasks • 1) Scenario definition • Work with FSW and I&T for all operational modes (BC, LB, SC) July 1 • Detailed early orbit plans (BC,LB) July 15 • 2) Contingency operations analysis • Define possible actions by subsystem (BC,LB) July 7 • 3) Draft Instrument Ops Section of Mission Plan (LB, SC, who at GSFC?) July 15 • 4) Update requirements documents to reflect architecture (SC, LB) July 15

  47. CDR Prep Schedule • July 8th Revisit roadmap • July 21st Laydown • July 26th Slides to GSFC • July 29th Dry Run • August 4th ISOC Peer Level CDR • August 18th CDR

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