PDS_VERSION_ID = PDS3

LABEL_REVISION_NOTE  = "2015-07-02, IAS, initial release;
                        2016-01-11, IAS, calibration steps
                        for FSS and RBD pahses modified;
 "

RECORD_TYPE                       = STREAM


OBJECT     = INSTRUMENT
  INSTRUMENT_HOST_ID = "RL"
  INSTRUMENT_ID      ="CIVA"

  OBJECT     = INSTRUMENT_INFORMATION
    INSTRUMENT_NAME ="CIVA - COMETARY INFRARED AND VISIBLE ANALYSER"
    INSTRUMENT_TYPE ={"IMAGING CAMERA", "IMAGING SPECTROMETER",
                       "INFRARED SPECTROMETER"}
    INSTRUMENT_DESC = "

      Instrument Overview
      ===================
      Integrated set of imaging instruments, designed to characterize
      the 360 degrees panorama (CIVA-P) as seen from the Rosetta
      Lander Philae, and to study surface and subsurface samples
      (CIVA-M). CIVA-P is a panoramic stereo camera, while CIVA-M is
      an optical microscope coupled to a near infrared microscopic
      hyperspectral imager

      Scientific Objectives
      =====================
      stereoscopic imaging of the site surrounding the Lander
      (CIVA-P), and by optical imaging and infrared spectral imaging
      of surface and subsurface samples of the cometary nucleus, at
      a microscopic scale (CIVA-M)

      Calibration
      ===========
      Following calibration functions are applied to the CIVA-P
      images, at IAS level:

Non-linearity correction

The TH7888A detector presents a strong deviation
from linearity when the signal is higher than ~ 80%
of the saturation level. This saturation level depends
on the camera, on the gain setting and on the
temperature of the detector. A linearity correction
transformation which includes the subtraction of the offest
has therefore been applied to level 1 CIVA images which
reach levels close to saturation (CIVA 1, CIVA 2, CIVA 3
and CIVA4). The linearity files providing the actual DN level
from the measured DN level (1024 floating point values)
are civa1scale.txt, civa2scale.txt, civa3scale.txt,
civa4scale.txt. The offset was evaluated as 18.4 DN, 19 DN,
13 DN and 20.9 DN for these four cameras.

Cameras CIVA 5, CIVA 6 and CIVA 7 have low DN values,
hence the corrected values correspond to the subtraction
of an offset of 17.8 DN, 20.5 DN and 14.5 DN for CIVA 5,
CIVA 6 and CIVA 7 respectively.

Regions of images from the CIVA 1, CIVA 2, CIVA 3 and CIVA 4
cameras are saturated. This situation is indicated in
the image file by a value of the recovered DN equal to
the maximum floating value of the transformation table
provided in 'civaNscale.txt' (N=1 to 4).

      Operational Considerations
      ==========================
      CIVA-P will be operated to take one stereo image of the Orbiter
      jus after release of Philae, to be used as calibration for the
      on-comet images. Then, immediately after touch-down, a full
      panorama of the landing site, with a partial stereoscopic
      coverage, will be taken by CIVA-P, and immediately transmitted
      to the Earth for quick look data reduction. This first panorama
      will be key to assess the landing conditions, and to declare
      secure the planned Philae sequence of operations. Follow-ons
      partial or global panoramas could be acquired either to monitor
      changes with solar illumination and/or cometary activity, to
      increase the stereoscopic coverage, and to image after their
      deployment Philae systems and sensors.

      CIVA-M will be turned on after all samplings (surface and
      subsurface) by SD2. It will consist in sequences of calibration
      (by imaging an oven with a calibration target), imaging of ovens
      prior to be filled, and after being filled by SD2 with cometary
      samples. CIVA-M/V will image each oven in three colors, while
      CIVA-M/I will acquire a complete 3D (x,y,lambda) image cube of
      them. After compression and storage in the IME mass memory, the
      data will be transferred to CDMS for downlink.

      Electronics
      ===========
      This Imaging Main Electronics (IME) is a facility, developed
      under the co-responsibility of IWP/DLR and IAS, for both ROLIS
      and CIVA: they share a common I/F with the Lander, for both the
      power subsystem and the Central Data Management System (CDMS).
      Thus the IME includes the CIVA-Central Electronics (CIVA-CE),
      mainly based on a dedicated CDPU (Command and Data Processing
      Unit); it is equipped with a 16 Mbytes mass memory.
      The CIVA-CDPU (Command and Data Processing Unit), developed by
      IAS, has the following functions: on/off power control; camera
      program uploading; camera heads check out; command reception
      (from ROLIS-DPU) and management; CIVA payload sequencing;
      status monitoring; image acquisition; integration time
      optimization; image compression (using wavelet based software);
      error encoding and data formatting. It consists of a TEMIC
      TSC21020 processor, 2 Kword PROMs for boot sequence, 512 Kbyte
      EEPROM for application program and parameters storage, 128
      KWord Fast SRAM for application program, 128 KWord Fast SRAM for
      application data and 6 Mbyte SRAM for 2 images data (1024x1024
      pixels) storage/processing. The CDPU electronics is integrated
      into a 3D-packaged cube which is implemented into the IME.
      The CIVA-CE includes two more electrical boards:
      one is dedicated to the IR detector, and the second to the CIVA
      peripherics.

      Location
      ========
      CIVA-P is constituted of 7 identical miniaturized cameras,
      implemented as 5 single cameras and one stereoscopic pair of
      two co-aligned ones, thus filling the 360 deg. panoramic field
      of view by six contiguous and overlapping FOV of 70 deg. each,
      60 deg. apart one from the next.
      CIVA-M is constituted of a visible microscope, CIVA-M/V and a
      near infrared hyperspectral imager CIVA-M/I. CIVA-M/V and CIVA-M/I
      are mounted on the Philae base-plate
      (balcony), close to the drill and sample distribution system
      (SD2). They will image and analyse the samples (from a distance
      of 13.0 mm) whenever they will be deposited within containers
      (Mid Temperature Ovens), mounted on a rotating carousel, and
      closed by a sapphire window transparent in both the Visible and
      the near IR.

      Operational Modes
      =================
      CIVA can be basically operated in 4 modes:
      - Software upload.
      - Pannoramic imaging
      - Visible Microscopic imaging
      - Hyperspectral Microscopic imaging

      Subsystems
      ==========
      The sub-systems are described in Bibring et al, 2007.


      Measured Parameters
      ===================
      Stereoscopic imaging of the site surrounding the Lander
      (CIVA-P), and  optical imaging and infrared spectral imaging of
      surface and subsurface samples of the cometary nucleus, at a
      microscopic scale (CIVA-M).
      CIVA will analyse cometary material from micron size particles
      to meter size features: 7 micrometres to a few mm with the
      microscope, 1 mm to meters with the panoramic cameras.
    "
  END_OBJECT = INSTRUMENT_INFORMATION


  OBJECT     = INSTRUMENT_REFERENCE_INFO
    REFERENCE_KEY_ID ="BIBRINGETAL2007A"
  END_OBJECT = INSTRUMENT_REFERENCE_INFO

END_OBJECT = INSTRUMENT

END