Recipe. The
pipeline recipe vmImFlatScreen corresponds to the template VIMOS_img_cal_FlatDome and produces a normalized master screen flat. The raw frames are bias subtracted and combined, the result is then divided by its smoothed image
to eliminate large scale illumination trends and to normalize.
The pipeline recipe corresponding to the template VIMOS_cal_DetLin
is vmDet and produces a bad-pixel map. A pixel is considered bad when
the slope of the linear fit of each
image exposure time versus pixel value deviates from the
average of all the slopes found for each pixel by more than
a given threshold (we use 5 sigma).
QC checks.
Screen flats of each quadrant are compared with a standard master. The following parameters are monitored: average CONAD (conversion factor between ADU and electrons), photon-noise, fixed-pattern-noise and lamp efficiency. These values are accessible via the trending
page.
Products.
| template name |
product name |
contents |
| VIMOS_img_cal_FlatDome |
VI_MSFI_<date><v>_<filter>.fits |
normalized master screen flat |
| VIMOS_cal_DetLin |
ccdTable.fits |
bad pixel map |
|
IMG
twilight flat
Relevant FITS keys are:
TPL ID = VIMOS_img_cal_FlatSky,
DPR CATG = CALIB,
DPR TYPE = FLAT,SKY
DPR TECH = IMAGE
![[skyflat.gif 14K]](../img/skyflat.gif) |
Raw imaging sky flat frame of quadrant 1 in the R filter
showing vignetting at the 2 upper corners , and at the 2 upper and left sides and some stars. The right dark region is the 50 pixels overscan. Stars are present in the raw flat frames. The telescope jitters so that the stars can be removed when the raw flats are combined |
Purpose. The sky flats are used to produce
the pixel-to-pixel efficiency maps that are used to devide the science images.
In general they come in stack of 5 raw frames per quadrant. Sky flats are routinely measured every night during twilight when VIMOS is operational in imaging mode. They are processed into master sky flat and quality-checked by QC Garching.
Recipe. The
pipeline recipe vmImFlatSky produces a normalized master screen flat. The raw frames are bias subtracted and combined, the result is then normalized by its mean value (the normalization process is different if a master screen flat is given: the combined sky flat fields are smoothed, and then multiplied by the master screen flat field)
QC checks.
Twilight flats of each quadrant are visually checked for star removal, vignetting and structure and compared with a standard master. The following parameters are monitored: structure and noise.These values are accessible via the trending
page.
Products.
| template name |
product name |
contents |
| VIMOS_img_cal_FlatDome |
VI_MSFI_<date><v>_<filter>.fits |
normalized master screen flat |
| VIMOS_cal_DetLin |
ccdTable.fits |
bad pixel map |
|
Photometric
Zeropoints
relevant FITS keys are:
TPL ID = VIMOS_img_cal_Photom,
DPR CATG = CALIB,
DPR TYPE = STD,
DPR TECH = IMAGE
 |
Reduced (i.e. bias-subtracted, flat-fileded) standard stars image in the R filter and quadrant 1. The overscans have been removed and the vignetting is apparent on three sides.
The photometric field shown is PG0231 (RA 02:33:23.2, DEC 05:13:34.1 J2000) and the Stetson
photometric standard stars used to compute zeropoins are indicated with circles. |
Purpose. Photometric standard stars are observed almost every night VIMOS is
operational in some of the five filters U,
B,V,R,I and they are used to compute the magnitude zeropoints. This parameter provides information on the total throughput of the telescope and the instrument. On Paranal the zeropoints are computed on a frame-by-frame basis at the beginning of the night to check the total throughput. QC Garching computes the night zeropoints per filter and per quadrant using all the night standard stars observations. The photometric night zeropoint are then
used to calibrate science imaging observations and to monitor the total
throughput.
Recipe. Two recipes are used by QC garching to compute the night
magnitude
zeropoints:
vmImObs does the bias-subtraction, overscans removal and flat fielding of each single photometric field
image, then runs S-Extractor ( Bertin & Arnouts 1996 (A&A 117, 393) ) to find all the objects in the field and to compute their instrumental magnitude
(i.e. the SExtractor MAG_BEST). The photometric standard stars are identified
using a photometric catalog, and written in a table together with their instrumental and
catalog magnitudes. The recipe also outputs the reduced standard star frame.
vmImCalOpt computes the airmass and color corrected magnitude zeropoints of the night. The input is the set of all available tables per filter and
per quadrant produced by vmImObsStare , the number of table is equal to the number of frames per filter and per quadrant observed during the night.
The output is a zeropoint table containing the magnitude zeropoint value (in ADU), the color term, the color index and the extinction coefficient used. This zeropoint is then used in ADU to calibrate science
images and it is converted into electrons for trending.
QC checks.
Night zeropoints in electrons corrected by extinction and color are monitored for each quadrant and each filter by QC Garching (see trending
page).
Products.
| template name |
product name |
content |
| VIMOS_img_cal_Photom |
VI_PSMI_<date><filter>_<quadrant>.tfits |
magnitudes |
| VIMOS_img_cal_Photom |
VI_PZPI_<date><filter>_<quadrant>.tfits |
zeropoint |
|
Note The standard star fields are in general observed with the
standard setting for imaging: 1x1 binning and low gain.
MOS flat
Relevant FITS keys are:
TPL ID = VIMOS_mos_cal_FLAT, VIMOS_mos_cal_NightCalib
DPR CATG = CALIB,
DPR TYPE = FLAT,LAMP
DPR TECH = MOS
![[std.gif 10K]](../img/mosflatraw.gif) |
![[std.gif 10K]](../img/mosflatred.gif) |
Raw and reduced MOS flat frame of quadrant 1, here
for the LowRes Red grism. Fringing is visible in the redder regions (i.e. toward the right) of the reduced frame |
Purpose.
MOS flats are in general taken the morning following the science observations. When required that are also taken during the night together with an arc-lamp exposure, just after the science acquisition.
Spectroscopic flats in principle contain the lamp function the slit function,
the fixed pattern noise. The red flats show also fringes, that are
different from the science exposure. For this reason, the flat-fielding introduces artificial features
in the science frames, therefore science data in the red grisms
are not flat-fielded. The flat fields are instead used to
refine the spectral curvature model.
Recipe. The vmSpFlat
recipe expects a stack of frames that can also be obtained with different mask shutter positions to avoid spectra contamination. The product is a master flat
normalized.
QC checks.
Each product is visually checked and the trended parameter is the lamp flux at reference wavelength for the slit closest to the center
(see trending
page).
Products.
| template name |
product name |
comments |
| VIMOS_mos_cal_FLAT or VIMOS_mos_cal_NightCalib |
VI_MSFM_<date><grism>_<>mask<.fits
|
normalized flat frame |
|
MOS arc lamp,
Relevant FITS keys are:
TPL ID = VIMOS_mos_cal_arc, VIMOS_mos_cal_NightCalib
DPR CATG = CALIB,
DPR TYPE = WAVE,LAMP,
DPR TECH = MOS
![[mosarc.gif 10K]](../img/mosarc.gif) |
Raw MOS arc frame of quadrant 1 obtained with the LR_red grism. Cleary visible are the spectra of the two
reference slits (at the top-right, and the low-middle regions) |
Purpose.
Arc lamp frames are in general taken the morning after the science observations. When required, they are taken also during the night together with 3 flat exposures, just after the science
acquisition.
The position of the arc lines is used for wavelength calibration.
Recipe. The vmSpCalDisp
recipe expects one arc lamp exposure that has written
in the header the first guesses of the inverse dispersion solution (ESO PRO IDS MAT_i_j_k),
of the spectral curvature (ESO PRO CRV MOD_i_j_k) and optical distorsions models (ESO PRO OPT DIS X/Y_i_j).
A master flat field can be also given in case the refined curvature and distorsion models are to be computed. The inverse dispersion solution, and the spectral curvature are computed for each line spectrum of each slit and written in a table (VI_PWDM). The RMS of the inverse dispersion solution residuals is also evaluated.
QC checks.
The inverse dispersion solution and curvature model
found are applied to
the arc-lamp frame to produce an image containing the 2-dimensional
extracted spectra of all slits. At this point the residuals are
computed for all arc lines listed in the catalog in the grism spectral range.
These residuals are the difference between the expected line catalog position
in the arc-lamp 2D extracted spectra,
and the position of the closest line to the expected position
found. The RMS of these residuals (in pixels) is the indicator of the precision
of the inverse dispersion solution for all slits and the entire wavelength range, and is listed in the product header under the keyword "HIERARCH ESO QC MOS IDS RMS" and
monitored in the trending
page, together with the resolution at three different wavelengths.
Products.
| template name |
product name |
comments |
| VIMOS_mos_cal_arc or VIMOS_mos_cal_NightCalib |
VI_PWDM_<date><quad>_<grism>_<mask>.tfits
|
inverse dispersion solution table
|
|
The inverse dispersion solution table (product name:VI_PWDM, category name: EXTRAC_TABLE) contains the following columns used for MOS science spectra calibration and for spectra extraction:
| column name |
description |
| SLIT |
slit identification number (as in header) |
| Y |
row co-ordinate in 2D-extracted frame (pix) |
| CCD_X |
X0, x position on CCD of the center of the slit of the mask at lambda0 (pix) |
| CCD_Y |
Y0, y position on CCD of the center of the slit of the mask at lambda0(pix) |
| MASK_X |
x position on mask of the center of the slit (mm) |
| MASK_Y |
y position on mask of the center of the slit (mm) |
| CRV_POL_i |
coefficient Ci of curvature polynomial of this row |
| INV_DIS_i |
coefficient Di of inverse dispersion relation of this row |
| INVDIS_RMS |
RMS of inverse dispersion relation of this row |
| DIS_QUAL |
quality of inverse dispersion relation (0: the fit failed for too few parameters, 1: the fit was successful |
|
Y is the dispersion direction coordinate. The image position X0,Y0 of the center of the slit
x,y on the mask, for a given wavelength
lambda0 assumed as the reference wavelength
and written in the grism table, is derived using the optical distorsion
model written in the header coefficients
"ESO PRO OPT DIS X_i_j" = Oij,
"ESO PRO OPT DIS Y_i_j" = Qij
X0=O00+O10xm+O01ym+O20xm2+......
and Y0=Q00+Q10xm+Q01ym+Q20xm2+......
Then the spectral curvature model (i.e. the curvature on the CCD of spectrum corresponding to the point x,y of the mask) is refined for each row using the
slit borders of the flat-field and starting from the first guess to find the coefficients CRV_POLi = Ci:
X-Xs=C1(Y-Y0)+C2(Y-Y0)2+...
Similarly the inverse dispersion relation is given by the coefficients INV_DISi=Di:
Y-Y0=D0+D1(lambda-lambda0)+D2(lambda-lambda0)2+...
By construction we have: lambda(Y0)=lambda0 and
lambda(X0)=lambda0
MOS spectrophotometric standards
DPR CATG = CALIB, DPR TYPE =
STD, DPR TECH = MOS
![[mosstd.gif 10K]](../img/mosstd.gif) |
Raw MOS spectrum with grism LR_red of a photometric standard star (visible in slit 7).
|
Purpose.Specrophotometric calibration of science frames (not yet
pipeline supported). The spectrophotometric standards are acquired with an 8-slits mask, and the telescope is shifted in order to have the same standard
in each of the four quadrants.
Recipe. The recipe vmSpCalPhot is under testing.
Products.
| template |
product name |
comments |
| VIMOS_mos_cal_Photom |
presently none
|
spectrophotometric table |
|
IFU flat and IFU arc lamp
IFU flat and arc lamp frames are taken within the same templates and are
both required by the vmifucalib recipe.
Relevant FITS keys are:
TPL ID = VIMOS_ifu_cal_NightCalib, VIMOS_ifu_cal_DayCalib
DPR CATG = CALIB,
DPR TYPE = FLAT,LAMP (for flats)
DPR TYPE = WAVE,LAMP (for arc-lamps)
DPR TECH = IFU
![[std.gif 10K]](../img/ifuflatLRredraw.gif) |
![[std.gif 10K]](../img/ifuflatLRredred.gif) |
Raw (left) and extracted (right) IFU flat frame of quadrant 1, taken with
the LowRes Red grism. In Low Resolution all the 4 IFU
pseudo-slits with 1600 fibers are
exposed (multiplexing 4). The 1600 extracted fiber spectra are wavelength calibrated and are stored in the image successively, pseud-slit by pseudo-slit counting fiber from left to right. In the raw frame, since the data are of quadrant 1, the first pseudo-slit is
the one at the bottom (the first pseudo-slit is at the top
in quadrant 3 and 4). Then, the first row of the extracted image corresponds to the first fiber to the left of the sequence at the bottom of the raw image (i.e. pseudo-slit1), and the last row of the extracted image corresponds to the last fiber to the right of the uppermost fiber sequence (i.e. pseudo-slit 4).
The zero order contamination is clearly visible in pseudo-slits 1 and 2
(i.e. the first two pseudo-slits starting from the bottom of the frame).
Fringing is visible in the redder regions (toward the right side) of the extracted frame |
![[ifuflatHRredraw.gif 10K]](../img/ifuflatHRredraw.gif) |
Raw (left) and extracted (bottom) IFU flat frame of quadrant 1, here
for the HighRes Red grism. In high resolution only the central IFU pseudo-slit, with 400 fibers, is exposed. The extracted fiber spectra are wavelength calibrated and are stored in the image successively starting from the first fiber to the left of the raw frame.
Fringing is visible in the redder regions (toward the top on the raw and toward the right in the extracted frame). |
![[std.gif 10K]](../img/ifuwaveLRredraw.gif) |
![[std.gif 10K]](../img/ifuwaveHRredraw.gif) |
Raw IFU arc lamp frames of quadrant 1. On the left the exposure is taken with the
LowRes Red grism and all the 4 pseudo-slits (1600 fibers) are used.
On the right the exposure is taken with the HighRes Red grism and only the central pseudo-slit is used (400 fibers). Redder wavelengths are toward the top of the frame.
|
Purpose.
IFU arc lamp and flat frames are taken during the night (template VIMOS_ifu_cal_NightCalib), immediately after the science acquisition template, with the same
instrument rotation angle as the science. They are also taken
during the day (template VIMOS_ifu_cal_DayCalib).
Due to the instability of the instrument,
the night calibration are required for the science reduction. The flat-fields are used for identifying and tracing the fibers and for computing their relative transmission, the arc-lamps are used for the wavelength calibration.
Recipe. The vmifucalib
recipe expects one arc lamp and at least one flat field exposure. The recipe uses also a fiber identification file containing information on the fiber positions. The spectral distorsion are computed by tracing the flat field spectra. The wavelength calibration is done after extracting the arc lamp spectra along the flat-field traces. The RMS of the inverse dispersion solution residuals is also evaluated and written in the header keyword "HIERARC ESO QC IFU IDS RMS"
Products.
| template name |
product name |
comments |
| VIMOS_ifu_cal_Night/DayCalib |
VI_PWDF_<date>_<filte>_<grism>_<ifuset>_<quad>.tfits
|
inverse dispersion solution file
|
| VIMOS_ifu_cal_Night/DayCalib |
VI_PTCF_<date>_<filt>_<grism>_<ifuset>_<quad>.tfits
|
extraction/tracing file
|
| VIMOS_ifu_cal_Night/DayCalib |
VI_PTNF_<date><filt>_<grism>_<ifuset><quad>;.tfits
|
transmission file
|
| VIMOS_ifu_cal_Night/DayCalib |
VI_MXFF_<date><filt>_<grism>_<ifuset><quad>.fits
|
extracted flat spectra image
|
|
The inverse dispersion solution file (product tag PWDF, category name: IFU_IDS) contains one table extension for each active pseudo-slit. Each table contains the coefficients of the polynomial fits for each of the 400 fibers, starting from
the first fiber to the left.
| column name |
description |
| Ci |
ist coefficient of the inverse dispersion polynomial. |
| RMS |
standard deviation of polynomial fit |
| NLINES |
number of identified arc lines used in fit |
|
The extraction file (product tag:PTCF, category name: IFU_TRACE) contains two table extension for each active pseudo-slit. Each table contains the coefficients of the polynomial fits for each of the 400 fibers,
starting from
the first fiber to the left. The first table extension coefficients are referred to the whole spectral range, the second extension coefficients are obtained by linear fitting of the traces on a shorter spectral range.
| column name |
description |
| Ci |
ist coefficient of the spectrum tracing polynomial. |
| RMS |
standard deviation of polynomial fit |
|
The transmission file (product tag: PTNF, category name: IFU_TRANSMISSION) contains the fiber to fiber relative transmission correction factors for each of the 400 (High or Medium resolution) or 1600 fibers (Low resolution), starting from the first fiber spectrum of the first pseudo-slit.
| column name |
description |
| TRANS |
ist relative transmission factor for each fiber |
|
IFU spectrophotometric standards
Relevant FITS keys are:
TPL ID = VIMOS_ifu_cal_Specphot
DPR CATG = CALIB,
DPR TYPE = STD
DPR TECH = IFU
![[ifustd.gif 10K]](../img/ifustd.gif) |
| ![[ifustd.gif 10K]](../img/ifustdred.gif) |
Raw (left) and reduced (right) IFU spectrophotometric standard star spectrum of quadrant 1 obtained with grism HighRes Orange. . The standard star is LTT-7379. The reduced spectrum is the sum of all the fiber extracted spectra, it is wavelength calibrated and the signal
is given in ADU per wavelength interval. The wavelength interval used is listed in the header keyword CDELT1. For the HighResOrange grism CDELT1is 0.62 A/pix. To have the signal per Angstrom one should then divide for 0.62.
|
Purpose.Specrophotometric calibration of science frames is not yet
pipeline supported. The standard star frames are reduced but no spectral response curve is computed.
The acquisition of spectrophotometric standards consists in four exposures with the telescope shifted in order to have the same standard star
in each of the four quadrants.
Recipe. The recipe vmifustandard requires in addition
to the raw standard star frame, the three files produced with the vmifucalib recipe (product tags: PWDF, PTCF and PTNF) that contain information
on the inverse dispersion solution, fiber extraction and transmission respectively. The standard star spectra are extracted and resampled to a constant wavelength step written under the header keyword CDELT1 (CDELT1 is 0.62 A/pix for the grism HighResOrange). The extracted spectra are transmission corrected, subtracted and stored in the product with product tag STRF.
The extracted spectra are stored in the output image in the usual order: successively from pseudo-slit1 to pseudo-slit4 counting fibers from left to right.
The blue wavelengths are on the left.
The sum of all the fiber extracted spectra is stored in the product with tag
STXF, and the median sky spectrum that have been subtracted in the product with tag STSF.
Products.
| template |
product name |
comments |
| VIMOS_ifu_cal_Specphot |
VI_STXF_<date>_<filter>_<grism>_<ifuset>_<quadrant>.fits
|
total standard star spectrum |
| VIMOS_ifu_cal_Specphot |
VI_STRF_<date>_<filter>_<grism>_<ifuset>_<quadrant>.fits
|
extracted fiber spectra |
| VIMOS_ifu_cal_Specphot |
VI_STSF_<date>_<filter>_<grism>_<ifuset>_<quadrant>.fits
|
total sky subtracted spectrum |
|
|
Last update: Jul 21, 2008
|
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