`dmarfadd' will add several Auxiliary Response Files (ARF)
together to create a single output ARF file. In the Chandra
case, there is a separate ARF for each detector
element (ACIS CCD or HRC MCP). The
user can use `dmarfadd' to combine these
files to create an ARF that covers the region (spatial or
spectral) of interest. Each CCD generally has different
good-time intervals (GTI), and hence, a different EXPOSURE.
`dmarfadd'
weights the ARF by the exposure time and derives a mean EXPOSURE. For
grating spectra,
where aspect dither causes different chips to overlap the same
spectral region, this produces the correct ARF.
Although 'dmarfadd' was designed to add ARFs for grating
observations, it can also work on imaging ARFs. When
adding imaging ARFs for point sources, it is assumed that the
same RMF applies to every ARF. If the RMFs are significantly
different, it is advised to NOT combine the ARFs using dmarfadd, but
to analyse these data separately.
In addition to the effective area column (SPECRESP),
'dmarfadd' also averages the 'FRACEXPO' column, which is
primarily needed for grating pileup modeling. FRACEXPO is a
value between zero and one, which indicates the fractional
time that region was exposed by a detector (e.g., it is 1.0
on chip, and drops in chip gaps).
NOTE: (1) The energy grids across the files to be combined
must be the same. (2) For grating observations, the
keywords, GRATING, (HETG or LETG), TG_PART (which indicates
HEG or MEG grating types for HETG), and TG_SCRID must match
across the files. (3) The keyword EXPOSURE must exist in all input
files. (4) For gratings, TG_M must match in absolute value (that
is, orders -1 and +1 may be added, but not 1 and 2). For
imaging-mode (GRATING='NONE'), the grating keywords are
ignored.
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