CCSD3ZF0000100000001NJPL3IF0PDSX00000001
PDS_VERSION_ID                     = PDS3

RECORD_TYPE                        = STREAM
OBJECT                             = INSTRUMENT
  INSTRUMENT_HOST_ID               = ULY
  INSTRUMENT_ID                    = EPAC

  OBJECT                           = INSTRUMENT_INFORMATION
    INSTRUMENT_NAME                = "ENERGETIC PARTICLE COMPOSITION
INSTRUMENT"
    INSTRUMENT_TYPE                = "CHARGED PARTICLE ANALYZER"
    INSTRUMENT_DESC                = "

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

      (excerpted from [KEPPLERETAL1992A])

      The EPAC sensor will measure the fluxes, angular
      distributions, energy spectra, and composition of ions in the
      energy range from 300 keV/nucleon to 25 MeV/nucleon.

      The instrument generates 12 different classes of data. All
      events are categorised by their (dE/dx)-signal into three
      crude classes; their respective numbers are transmitted from
      three event memories. So besides the 32 event strings we also
      get per EDF the total number of events recorded during that
      time interval. Less detailed information on energy spectra are
      obtained with higher time resolution from 4 groups of ions. 8
      energy channels are formed for each group. Bands,
      corresponding to the (dE/dx-E) tracks are stored in a RAM
      look-up table. All events are sorted accordingly for 4 ion
      groups (He, C-N-O, S-group, F-group). For telescopes 2 and 3
      these are in addition resolved into 8 spin-sectors. A full set
      will be transmitted in about 34 min. If only one species is
      selected, time resolution increases to ~ 8.5 min.

      Protons are identified separately in 8 channels (3-bit PHA)
      using the B-detector outputs (500 keV to 1.6 MeV). All
      channels are resolved into eight sectors.

      From the A-detector's output, integral fluxes of ions are
      obtained. Contributions will come from ions above an energy,
      defined by dead-layer thickness and electronic threshold of
      about 145 keV. Contribution from electrons scattered through
      large angles may contribute to the lowest channel, but as the
      detector thickness corresponds to the range of ~ 25 keV
      electrons, its electron detection efficiency is certainly <<
      1.

      The 4 A-detector outputs are connected to the PHA through a
      multiplexer (as are the B-detectors). The thresholds of the
      PHA are adjusted such, that in 'High Gain'-Mode channel 1 to
      3 'protons' (Z >= 1), in channel 4 to 5 '[alpha]-particles'
      (i.e. Z >= 2), in channel 6-8 'oxygen' (i.e. Z >= 6) is
      detected. In 'Low-Gain', the passbands are shifted one channel
      up: channel 1 and 2 record now Z >= 1, channels 3 to 4 Z >= 2,
      channels 5 to 7 Z >= 6 and channel 8 Z >= 10 particles. The
      latter corresponds to about 500 keV/nucleon. This class of
      data is obtained in 16 min.

      Much higher time resolution is obtained from rates, which
      correspond to the integral over energy of the proton and the Z
      >= 1 spectra. Telescopes 2 and 3 are resolved in eight
      sectors.

      The solar aspect angle varies in the course of the mission
      from ~ 90 [degrees] after launch to less than 11.5 [degrees]
      at Jupiter. It will again increase during polar passage. This
      means, that there will be periods, when telescopes 1 or 2 will
      be fully illuminated by the sun and might affect the Z >= 1
      data, but not coincidence rates.

      Two electron channels corresponding to 100 keV <= E <= 0.4 MeV
      and to E >= 0.3 MeV are also formed for each telescope. These
      channels are defined from proper combination of dicriminator
      thresholds. Their energy range is, however, not very
      accurately defined (due to electron scattering). For heavy
      ions there are also 16 rate channels for each of the 4
      telescopes and each of the 4 species. They are read out once
      every 8 minutes.

      For each telescope the background rates of detector B and C
      are transmitted, each accumulated over 4 minutes. The
      equivalent geometrical factor is F[B] = 1.60 cm^2 and F[C] =
      6.02 cm^2. For coincidence rates of all 3 detectors the
      geometrical factor G = 0.08 cm^2 ster applies."
  END_OBJECT                       = INSTRUMENT_INFORMATION

  OBJECT                           = INSTRUMENT_REFERENCE_INFO
    REFERENCE_KEY_ID               = "KEPPLERETAL1980"
  END_OBJECT                       = INSTRUMENT_REFERENCE_INFO
  OBJECT                           = INSTRUMENT_REFERENCE_INFO
    REFERENCE_KEY_ID               = "KEPPLERETAL1991"
  END_OBJECT                       = INSTRUMENT_REFERENCE_INFO
  OBJECT                           = INSTRUMENT_REFERENCE_INFO
    REFERENCE_KEY_ID               = "KEPPLER1992"
  END_OBJECT                       = INSTRUMENT_REFERENCE_INFO
  OBJECT                           = INSTRUMENT_REFERENCE_INFO
    REFERENCE_KEY_ID               = "KEPPLERETAL1992A"
  END_OBJECT                       = INSTRUMENT_REFERENCE_INFO

END_OBJECT                         = INSTRUMENT
END