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ORR Readiness

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ORR Readiness Mark Colavita & Peter Wizinowich KISWG Pasadena 10/29/2003 – PowerPoint PPT presentation

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Title: ORR Readiness


1
ORR Readiness
  • Mark Colavita Peter Wizinowich
  • KISWG
  • Pasadena 10/29/2003

2
Question to Address (2/3/2003 pre-ORR
presentation)
  • At the ORR
  • Will the instrument be capable of achieving the
    requirements in the PLRA at the start of routine
    science operations? (V2 mode)
  • What are the relevant performance metrics and
    current performance? (V2 mode)
  • Today
  • What are the specific performance requirements,
    and how do they relate to the PLRA?
  • How will compliance be demonstrated?
  • Are they technically achievable?
  • What is the current performance?
  • What is the plan to get from current performance
    to ORR? Is the plan realistic?
  • What are the risks for routine science operation?
    How will they be mitigated? Are there additional
    risks not yet identified that need to be
    addressed?

3
Specific Performance Requirements (2/3/2003
pre-ORR presentation)
  • PLRA requirements for V2
  • System Performance Goals
  • Provide 5 rms accuracy V2 amplitude measurements
    for targets as faint as K9 using the two Keck
    telescopes
  • Provide at least 90 uptime for the
    interferometer and 90 uptime for the two 10m
    telescopes and their AO systems
  • System Performance Requirement
  • Provide at least 90 uptime for the
    interferometer and 80 uptime for the two 10m
    telescopes and their AO systems

Program Level Requirements Appendix to Navigator
Program Plan
4
Pre-ORR Testing from Oct Observing Run
  • Targets included measurements of
    well-characterized PTI binary
  • Used neutral density filters to attenuate this
    bright star to simulate K9 ORR requirements
  • Data accuracy still being assessed
  • Observation
  • K9 spec will need to be qualified with a V or R
    magnitude, as stars faint to AO are less well
    corrected, and provide less flux into fringe
    tracker
  • (Fringe tracker measures flux Strehl)
  • Plan to provide this for ORR
  • Also tests of fringe tracker low-V2 tracking limit

5
Oct Data(Most processing still in-progress)
6
Prior (May, Jan) accuracy tests
7
Other tests
8
Provide at least 90 uptime for the
interferometer and 90 uptime for the two 10m
telescopes and their AO systems (2/3/2003 pre-ORR
presentation)
  • Quoted directly from the PLRA
  • NB not a measure of open shutter time or
    efficiency, which is actually quite low for any
    instrument, like IF, that is calibration-limited
  • A measure equal to 100 minus the downtime
    required to fix IF hardware or software problems
    during scheduled science observing
  • Telescopes/AO addressed in a few slides
  • Demonstrating compliance
  • Mostly proper bookkeeping
  • Identify a timekeeper to track system state vs.
    time
  • Demonstrate compliance on two runs prior to ORR
    with good weather and median or better seeing

9
System uptime scans per hour
10
Uptime summary
  • Interferometer uptime ? 90 2/5 runs
  • Facility uptime ? 90 1/5 runs ? 80 3/5 runs
  • October run problem areas
  • Major
  • Telescope control system crashes
  • K2 continued to have problems after the IF run
    supporting DEIMOS
  • Problem may be resolved need to test
  • Minor most in process of being addressed
  • Facility
  • AO offload problem (possible interaction from IF
    angle tracker)
  • K2 AO Wavefront controller crashes
  • Interferometer
  • Sequencer crashes
  • Aligner crate reboots
  • Telemetry server memory growth solved
  • Goal is to achieve ORR metric performance on next
    two runs

11
Performance, functionality, efficiency goals
(2/3/2003 pre-ORR presentation)
  • These follow from the desire to maximize the
    science achievable at the specified performance
    level

12
Performance, functionality, efficiency goals, 1
(2/3/2003 pre-ORR presentation)
13
System uptime scans per hour
14
Scans per hour
  • 86 science plus engineering scans in 22.5 clear
    hours
  • Peak scans on each of 4 nights
  • 2, 3, 6, 8
  • Sustained high throughput impacted by
  • System faults
  • Ease of observing target
  • Faint targets, requiring optimization of AO, KAT,
    FATCAT, or which end up not being trackable,
    count against scans per hour
  • Weather (light to moderate cirrus, which doesnt
    count against weather loss)
  • May need to qualify our 6 scan/hr goal to apply
    to sources not pushing system limits

Night 3 of Oct run
Peak scans/hr for this night
15
Performance, functionality, efficiency goals,
1updates to 2/3/2003 pre-ORR presentation
16
Performance, functionality, efficiency goals, 2
17
Performance, functionality, efficiency goals, 3
18
Procedural Requirements for the ORR
  • From the PLRA
  • Provide an operational infrastructure including
    trained staff, facilities, hardware and software,
    so that the Keck Interferometer will operate as a
    facility for use by the community scientists.

19
Procedural Requirements for the ORR
  • From LaPiana Need (A) requirements which you
    can track against your progress to actually
    achieve the metric performances, and the (B)
    ability to do it routinely and having an
    organization in place that is well trained to do
    so with robust and stable software (at WMKO
    MSC).
  • Questions to address at the ORR from LaPiana
  • Will the ground data system (at WMKO and at MSC)
    implementation and testing be complete prior to
    the start of routine science operations?
  • Will the required operations plans and
    procedures, including those for anomaly
    responses, be completed and tested prior to start
    of routine science operations?
  • Are the operations organization, staff and
    facilities in place (WMKO and MSC)?
  • Will the necessary training activities be
    completed prior to start of routine science
    operations?
  • Are the necessary set of commands and sequences
    ready to support nominal operations? Will all
    action items, liens, etc., be satisfactorily
    dispositioned?
  • Are the risks well understood and acceptable for
    routine science operations?

20
1. Ground Data System Completion
  • Will the ground data system (at WMKO and at MSC)
    implementation and testing be complete prior to
    the start of routine science operations?
  • At the pre-ORR The primary demonstration will be
    successful CARA operation of the interferometer
    for V2 science.
  • We will track this performance over the next 7
    runs.
  • The last 3-runs prior to the ORR will be
    performed at the full ORR requirement level.
  • CARA personnel have successfully operated the
    interferometer for most of these runs. We have
    tracked performance during these runs. Many, but
    not all, of performance numbers demonstrated in
    Oct. run.
  • At most can demonstrate full ORR-level compliance
    during only 2 runs (Nov. Jan.) prior to ORR.

21
2. Operations Plans Procedures
  • Will the required operations plans and
    procedures, including those for anomaly
    responses, be completed and tested prior to start
    of routine science operations?
  • Operations procedures for daytime checkout
    night-time operation are in place.
  • Anomaly responses need completion
  • Including spares troubleshooting training
  • Configuration management (software,
    opto-mechanical electronics) need to be defined
    agreed upon
  • Especially important during ongoing development
  • Major software upgrade will happen with RTC 2.1
  • Also need upgrade plan (plan to implement
    upgrades without compromising operational
    system).
  • Would be easier if some subsystems had already
    been handed over to CARA
  • Need to approve/implement plan for maintaining
    cleanliness of optics/basement

22
2. Operations Plans Procedures
  • Current operations procedures
  • Punchlist with new priorities distributed after
    each run. Reviewed bi-weekly.
  • Schedule for summit activities maintained.
    Reviewed weekly. Incorporated in Observatory
    scheduling.
  • Daytime summit activities entered into IFDEV
    Observatory daylog.
  • Observing support personnel (daytime, nighttime
    on-call) list distributed prior to run.
  • Setup observing procedures available on-line
    (next slide).
  • Afternoon pre-observing checklist/procedure
    performed.
  • Plan for nights observing distributed.
  • Observing log maintained published to telescope
    nightlog.
  • Post-run summary distributed, including
    priorities for next run.
  • Punchlist with old priorities closed out.
  • Post-run review held with Observatory/Project
    management.

23
OperationsProcedures
24
34. Operations Organization Training
  • Are the operations organization, staff and
    facilities in place (WMKO and MSC)?
  • Will the necessary training activities be
    completed prior to start of routine science
    operations?
  • Organization
  • John Gathright has assumed Operations Coordinator
    role
  • Responsible for coordinating/scheduling/staffing
    activities in support of observing runs,
    observing prep daytime experiments
  • 2 (of 3) technicians report directly to him

25
34. Operations Organization Training
  • Facilities
  • Control rooms set up at headquarters summit
  • Control rooms routinely used for interferometer
    operation
  • Instrument performance capabilities need to be
    made available to the community for observing
    planning

26
34. Operations Organization Training
  • Staff
  • 3 Interferometer specialists trained in operation
    of Interferometer for daytime alignments,
    checkouts tests, night-time operations
  • 2 technicians trained in daytime alignments
    checkouts
  • Plan to hire an interferometer operator an
    interferometer specialist to relieve operational
    load on above personnel
  • Software engineers (2) able to support day
    night-time troubleshooting.
  • Electronics engineer able to support daytime
    troubleshooting.
  • Mechanical engineer gaining some instrument
    familiarity.

27
34. Operations Organization Training
  • Staff
  • Currently 1 JPL 1 MSC person participates in
    each run. Can we fill their roles after the ORR?
  • JPL person really helps with troubleshooting
  • We are gaining more familiarity with instrument
    resolving problems (JPL still on-call)
  • MSC person really understands science priorities
  • We need more insight /or MSC on-call

28
5. Commands Sequences
  • Are the necessary set of commands and sequences
    ready to support nominal operations? Will all
    action items, liens, etc., be satisfactorily
    dispositioned?
  • Alignment
  • Procedures exist and are used.
  • All mirrors and shutters needed are remotely
    controlled.
  • Pre-Observing checklist
  • Checklist exists and routinely used by CARA
    personnel.
  • Observing procedure/checklist
  • CARA personnel routinely operate.
  • MSC tools procedures
  • CARA personnel recently operating.
  • Post-Observing
  • Tapes written and shipped.

29
5. Commands Sequences
  • Target acquisition (Manual Automated steps)
  • Interferometer Sequencer (IS) operator selects
    target from list
  • IS loads parameters initiates Telescope
    Sequencer (TS)
  • IS configures FDLs for observation
  • TS initiates the following (can change for repeat
    observation)
  • Telescope control system slews, then tracks, the
    telescopes
  • Auto-acquisition tool positions brightest target
    on acquisition camera for AO system
  • AO auto-setting tool optimizes AO parameters on
    target
  • AO operator reports AO loops locked to IS
    operator
  • AO system offloads tip/tilt and focus to the
    telescope
  • IS operator closes Angle Tracker (KAT) loop
  • KAT loop automatically offloads IF tip/tilt
    mirror to AO wavefront sensor offsets
  • AO operator unloads offsets to field steering
    mirrors if gt threshold
  • IS operator initiates IS to acquire fringes
  • IS scans to peak signal on fringe tracker
  • IS searches for fringes

30
5. Commands Sequences
  • Remaining issues
  • Automated night-time LDL repositioning (manual
    too slow)
  • This is currently a high priority
  • Automated daytime alignment (labor telescope
    intensive)
  • Likely a lien at the ORR
  • User interface is complex distributed (can make
    mistakes)
  • Plan to implement a simpler quick-look
  • Better version will come after RTC 2.1 upgrade
  • Observing sequence automation should be improved
    to achieve scans/hour with reduced human
    interaction
  • Selectable level of telescope sequencer operation
  • Offloading wavefront sensor centroids to FSMs
  • Reuse of AO parameters
  • Remote configuration
  • A few remaining hands-on operations

31
6. Risks
  • Are the risks well understood and acceptable for
    routine science operations?
  • Risks identified at ORR requirements review
  • Weather, wind shake and seeing
  • There are nights when IF observing simply cannot
    be done productively or when only bright targets
    can be used.
  • Best choice in some conditions would be to switch
    to another instrument program that can succeed
    with poor seeing.
  • Hardware failures
  • Mitigation List of critical spares and backup
    approaches to be identified implemented prior
    to ORR.

32
6. Risks
  • Development during operations
  • Mitigation Configuration control.
  • Observatory-wide software configuration plan
    currently being approved. Will apply to
    Interferometer AO ops.
  • Inteng tag of intdev nearly in place to protect
    software.
  • ECR process in place for AO opto-mechanics.
  • Mitigation Careful coordination of development
    operations activities (using current operations
    procedures).
  • Number of shared risk TAC allocated V2 science
    nights
  • Too many nights could result in inadequate CARA
    involvement in development /or inadequate access
    to interferometer for development.
  • Possible mitigation
  • Limit the number of science nights.
  • Additional operations staff.
  • New Load on CARA staff if system requires lots
    of hand-holding

33
ORR readiness summary
  • Will probably be OK on V2 accuracy spec need to
    complete analysis of Oct data
  • Uptime still problematic
  • Working on major (and minor) problems from Oct
  • With satisfactory resolution of major, and
    several of the minor problems, should be possible
    to achieve in November Jan.
  • Scans per hour still low, although brief good
    peak performance
  • Some issues with brightness of target will not
    apply if target requires extensive optimization
  • Improvements to system uptime and user interface
    should improve performance
  • OK on most other areas, except for LDL
    automation, which is a current focus
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