PDS_VERSION_ID       = 3
LABEL_REVISION_NOTE  = "2004-09-29, YL first draft"               
RECORD_TYPE          = STREAM                                               
RELEASE_ID           = 0001
REVISION_ID          = 0000                                                                                
OBJECT               = INSTRUMENT
  INSTRUMENT_HOST_ID = MEX
  INSTRUMENT_ID      = OMEGA

  OBJECT             = INSTRUMENT_INFORMATION
    INSTRUMENT_NAME  = "Observatoire Mineralogie, Eau, Glaces, Activite"
    INSTRUMENT_DESC  = "

Instrument Overview
===================

OMEGA is a mapping spectrometer working both in the visible and the infrared spectral  ranges.
It is made of two co-aligned channels, one working in the 0.38 to 1.05 micrometers visible and
near infrared range (VNIR channel), the other in the 0.93 to 5.1 micrometers short wavelength
infrared range (SWIR channel). The data products constitute three-dimensional (X,Y,lamda)
image-cubes,  with two spatial and one spectral dimensions. The VNIR channel uses a bi-dimensional
CCD detector, operated in a pushbroom mode. Its telescope acquires at once in its focal plane one
cross-track line corresponding to the entire 8.8 degrees FOV, defined by an entrance slit; the
second dimension of the image is provided by the motion of the S/C. Each line is spectrally
dispersed along the columns of the array, the slit being imaged through a concave holographic
grating. The SWIR channel operates in the whiskbroom mode: each imaged pixel is acquired at once
by an IR telescope; a scanning mirror, in front of the telescope, permits to acquire crosstrack
swaths of 16 up to 128 pixels width, for a maximum FOV of 8.8 degrees, thus matching the VNIR FOV,
while the S/C motion provides the second spatial dimension. The imaged pixel is focused by the
telescope on a slit, followed by a collimator. The beam is then split towards two separated
spectrometers, to acquire the IR spectrum of each resolved pixel onto two InSb linear arrays of
128 spectels each, from 0.93 to 2.73 micrometers and from 2.55 to 5.1 micrometers respectively.
Each array is cooled down 70K by a dedicated cryocooler, while the entire spectrometer is cooled
down 190 K by a conductive link to a passive radiator. The typical IR integration time, defined
by the S/C ground track velocity and the spatial sampling chosen, is 5 msec. The corresponding
VNIR integration times are 100 to 800 ms, depending on the swath width, thus the altitude.
With such integration times, SNR > 100, over the entire spectral range, is the specification.

OMEGA is made of two distinct units:

   - a Camera unit (OMEGA-C) with the VNIR and SWIR spectrographs,
        their associated electrical devices, and one electronics assembly
        for the control of the camera. All units are integrated onto a
        common base plate; its mass is 23.8 kg.

   - a Main Electronics module (OMEGA-ME), for the data processing and
     the general management of the instrument; its mass is 5.1 kg.


VNIR spectrograph
-----------------

VNIR is made of two optical subsystems: a focusing telescope with its focal plane on a slit, and
a spectrometer, that spreads the slit image in the spectral dimension. It provides image data in
the spectral range 0.38 to 1.05 micrometers achieving a maximum spatial sampling of 0.4 mrad and
a maximum spectral sampling of 50 Angstrom. A refractive telescope focuses the image on a slitplaced
on the Rowland circle of an aberration corrected concave holographic grating mirror. This element
reflects and disperses the light on a CCD detector tangent to the Rowland circle. The detector
used is the TH7863 frame transfer CCD produced by Thomson. The chosen grating mirror can create a
flat image onto the focal plane. This property allows to match very well the flat detector matrix
to the grating, without other optical components. A CCD frame is then composed of N rows each
containing an image of the slit at a given wavelength, and M columns each containing the spectrum
of a point along the slit. The bi-dimensional image of the surface is obtained by the pushbroom
technique, in which the spacecraft movement along its orbit performs a scan of the slit across the
planetary surface. The electrical signal from the detector is amplified and then digitized by a
fast 12 bit A/D converter; after conversion, all data are processed within the OMEGA-ME.

In order to decrease the detector noise, VNIR is cooled down 190 K by conduction to the SWIR
mechanical unit. The choice of refractive over reflective optics was made because of the large
(8.8 degrees) field of view requirement. The telescope has a 6 elements objective similar to that
of a modern commercial photographic camera. The shape of the elements and the types of optical
glass were chosen to obtain the best chromatic aberration corrections over the entire spectral
range. The last element serves as a field lens which matches the entire objective with the grating
to avoid light losses. To avoid stress in the lenses at the working temperature, the two doublets
are not cemented. The two glasses, FK54 and fused silica, have very different expansion
coefficients of 8 and 0.55 x 10E-6/K at room  temperature. The entrance aperture of 15.6 mm is
defined by a diaphragm between the two doublets.

An aberration corrected concave holographic grating is placed 142.7 mm from the entrance  slit
(which is in the focal plane of the telescope). The grating is tilted to form the spectrum at
an angle of roughly 6 degrees from the optical axis. This angle does not allow CCD insertion
near the entrance without beam obscuration; therefore, a folding mirror deflects the beam toward
the side of the assembly, where the CCD can be mounted with ample clearance
The zero order spectrum, at 4.5 degrees from the folded optical axis (lying in the y-z plane) is
directed into a light trap to prevent degradation of the image. The first order spectrum ranges
in angle from 6 degrees at lamda = 0.35 micrometers to 10 degrees for lamda = 1.05 micrometers.
The second and higher order spectra can, in principle, also degrade the data. Its contribution
depends both on the grating efficiency, and the spectral distribution of the incident radiation.
For this reason, a dedicated filter is mounted, in front of the detector. The concave, spherical,
holographic grating in a Rowland mounting - where the entrance slit and the spectrum are on radii
of curvature of the grating - makes the spectrometer compact, light, and simple. In fact, no
collimator or camera lens is required and the spectrometer has only one element. Moreover, the
focal plane image can be flat, to match the planar CCD sensors. Since the concave holographic
grating is obtained by recording a perfect optical pattern with groove spacing absolutely constant,
it has no ghosts. Stray light has also a much lower level than the best ruled gratings. Therefore,
concave holographic gratings generally have a much higher signal to noise ratio than classically
ruled gratings.

The optical performances have been computed by ray tracing. In the focal plane the spot diagram
is about the pixel size (23x23 microns). For off-axis propagation (4.4 degrees off-axis), the
total spot size is about 2 pixels in the sagittal direction. More precisely, on axis and at 0.7
micrometers, 98.8 % of the energy falls within a 23x23 micron pixel; at 4.4 degrees off-axis and
lamda = 0.4 micrometers, 74 % of the energy falls within a CCD element. When the light propagates
off-axis, the spot size is smaller for the shorter wavelengths. 

The Pattern Generator (PG) determines the CCD integration time, and generates the timing signals
necessary to transfer an image from the light sensitive area to the masked zone and then to the
output shift register of the CCD. The output of the CCD is then amplified and converted by a fast
12 bit A/D converter under control of the PG. The timing of the instrument imposes a relatively
high frequency for CCD operation. In fact, depending on the distance from the planet and hence on
the spacecraft speed, the time TR between consecutive frames can be chosen as: 100, 200, 400 or
800 ms. During the TR period the integration, readout and data transmission processes must occur.
To save time, integration and transmission of the previous frame are overlapped. Because the
maximum data value which can be transmitted during TR is limited to 12288 bytes, it is not possible
to read the total frame of 384x288 pixels, corresponding to 110592 bytes. We are forced to read only
a sub-frame, or to reduce the number of pixels by summing them on chip. The combination of different
scientific requirements, integration times and hardware limitations led us to the definition of
40 operation modes, which can be selected through commands sent to the spacecraft, ranging from the
nominal (spatial x spectral) mode (128x96 with summation of 3x3 pixels), to the high spectral
resolution mode (64x144), to the high speed mode (16x96). Summation along columns and rows will
decrease the spatial and spectral resolution, but increases signal-to-noise ratio considerably.
The implementation of mode 16x74 is the most critical due to the short time available to complete
all the operations (TR = 100 ms). For this reason the Pattern Generator provides two values for the
pixel readout frequency: f slow= 500 kHz when the pixel voltage has to be digitized and ffast = 4
MHz when the pixel is simply read from the CCD output register without any digital conversion.


SWIR Spectrograph
-----------------

The IR channel is constituted of a telescope and its fore-optics, a beam splitter and two spectrometers,
each with its detector array actively cooled. The telescope is a Cassegrain type one with a 200 mm
focal length, a f/4 aperture, leading to a 1.2 mrad (4.1 arcmin) IFOV, and a 15 arcmin free field of
view (including the positioning tolerances). The distance between the primary and the secondary mirrors
is 51 mm; that between the secondary mirror and the image plane is 82 mm. In front of the telescope,
a fore-optics system has the primary goal of providing a cross-track scanning of the IFOV. It includes
two mirrors, a moving and a fixed one. The total scanning angle is +/- 4.4 degrees (FOV = 128 IFOV),
and is adjusted to the OMEGA viewing direction. The control of the scanning mechanism is performed by
a dedicated FPGA-based electronic sub-system.

Focused by the telescope on an entrance slit, through a shutter, the beam is first collimated, then
separated, by a dichroic filter with its cut-off wavelength at 2.7 micrometres towards two spectrometers,
operating in the following spectral ranges: 0.93 to 2.73 micrometers and 2.55 to 5.1 micrometers.
Each spectrometer includes a blazed grating working at its first order, and an optical reflective system,
then a field mirror and a refractive refocusing system which gives a large aperture on the detection
block (f/1.6): it images the spectrum onto a 128 elements InSb linear array, cooled down a temperature
of < 80K, and multiplexed by a charge transfer device. Sets of filters are implemented in front of the
detector to reject the contribution of other orders from the grating.

The InSb photodiodes have been manufactured by SAT. The dimensions of each photosensitive element is
90 micron x 120 micron, with a pitch of 120 micron. All elements of the focal planes are hybridized on
a ceramic with two electric circuit layers to connect the elements together. The ceramic is glued on
a titanium base plate and covered with a titanium closure, which includes the filters. An internal
calibration source is implemented, to control potential shifts of the overall spectrometer transmission,
and to calibrate the relative response of each pixel. It is made of a tungsten lamp, operated as a black
body which can be power heated at different temperatures. The calibration beam is reflected towards the
spectrometer by diffusion on the back side of the entrance slit.

SWIR requires an accurate thermal control, at three levels:

  - the IR detectors must be cooled down a temperature of < 80 K, controlled with
    an accuracy better than 0.1K. This is done by connecting them (copper heat link)
    to two cryocoolers, one for each array: they consist in Inframetrics 13000 series
    integral Stirling cycle coolers. Their guarantied lifetimes are > 2500 hours.
    They are controlled by a dedicated electronics;

  - the spectrometer must be cooled down to 190 K, in order both to allow the detectors
    to reach their required operational temperature (< 80 K), and to minimize the thermal
    background. This is achieved by conductive coupling (heat pipes) to a “low temperature”
    radiator, provided by the S/C;

  - the electronics and the cryocoolers heads must be coupled (copper links) to a “high
    temperature” (280 K) radiator to dissipate their energy.

OMEGA-ME Unit
-------------

The OMEGA main electronics is designed to power and control the instrument, to acquire and
compress all scientific data on line, and to interface with the S/C telecommand/telemetry system.
The entire system is cold redundant. Within OMEGA-ME, the Command and Data Processing Unit(CDPU)
has the following tasks: 

  - acquisition of all scientific data from VNIR and SWIR;
  - formatting for real time data compression
  - wavelet based data compression, followed by formatting of processed data
  - reception and formatting of HK data
  - forward all data to the S/C telemetry system

The CDPU is based on a TSC21020 Temic processor, and integrated, together with a 6Mbyte SRAM,
into a 3D packaged highly miniaturized cube, inherited from a ÇIVA/Rosetta development."

    INSTRUMENT_TYPE  = "IMAGING SPECTROMETER"

  END_OBJECT         = INSTRUMENT_INFORMATION


  OBJECT             = INSTRUMENT_REFERENCE_INFO
    REFERENCE_KEY_ID = "BIBRINGETAL2002"
  END_OBJECT         = INSTRUMENT_REFERENCE_INFO

END_OBJECT           = INSTRUMENT

END