3,509 research outputs found
Theory and applications of four-wave mixing in photorefractive media
The development of a theory of four-wave mixing in photo-refractive crystals is described. This theory is solved in the undepleted pumps approximation with linear absorption and without using the undepleted pumps approximation for negligible absorption. Both the transmission and reflection gratings are treated individually. The results are used to analyze several photorefractive phase conjugate mirrors, yielding reflectivities and thresholds. The use of photorefractive crystals as optical distortion correction elements and experimental demonstrations of several of the passive phase conjugate mirrors are described
Geometric calibration of Colour and Stereo Surface Imaging System of ESA's Trace Gas Orbiter
There are many geometric calibration methods for "standard" cameras. These
methods, however, cannot be used for the calibration of telescopes with large
focal lengths and complex off-axis optics. Moreover, specialized calibration
methods for the telescopes are scarce in literature. We describe the
calibration method that we developed for the Colour and Stereo Surface Imaging
System (CaSSIS) telescope, on board of the ExoMars Trace Gas Orbiter (TGO).
Although our method is described in the context of CaSSIS, with camera-specific
experiments, it is general and can be applied to other telescopes. We further
encourage re-use of the proposed method by making our calibration code and data
available on-line.Comment: Submitted to Advances in Space Researc
Optical Distortion in the NACO Imager
In this research note, we present a set of distortion solutions that may be
used to correct geometric optical distortion in images taken with the S13
camera of the NACO adaptive optics imager.Comment: published in the RNAA
SPHERE IRDIS and IFS astrometric strategy and calibration
We present the current results of the astrometric characterization of the VLT
planet finder SPHERE over 2 years of on-sky operations. We first describe the
criteria for the selection of the astrometric fields used for calibrating the
science data: binaries, multiple systems, and stellar clusters. The analysis
includes measurements of the pixel scale and the position angle with respect to
the North for both near-infrared subsystems, the camera IRDIS and the integral
field spectrometer IFS, as well as the distortion for the IRDIS camera. The
IRDIS distortion is shown to be dominated by an anamorphism of 0.60+/-0.02%
between the horizontal and vertical directions of the detector, i.e. 6 mas at
1". The anamorphism is produced by the cylindrical mirrors in the common path
structure hence common to all three SPHERE science subsystems (IRDIS, IFS, and
ZIMPOL), except for the relative orientation of their field of view. The
current estimates of the pixel scale and North angle for IRDIS are
12.255+/-0.009 milliarcseconds/pixel for H2 coronagraphic images and
-1.75+/-0.08 deg. Analyses of the IFS data indicate a pixel scale of
7.46+/-0.02 milliarcseconds/pixel and a North angle of -102.18+/-0.13 deg. We
finally discuss plans for providing astrometric calibration to the SPHERE users
outside the instrument consortium.Comment: 12 pages, 6 figures, 3 table
Multi-aperture foveated imaging
Foveated imaging, such as that evolved by biological systems to provide high angular resolution with a reduced spaceâbandwidth product, also offers advantages for man-made task-specific imaging. Foveated imaging systems using exclusively optical distortion are complex, bulky, and high cost, however. We demonstrate foveated imaging using a planar array of identical cameras combined with a prism array and superresolution reconstruction of a mosaicked image with a foveal variation in angular resolution of 5.9:1 and a quadrupling of the field of view. The combination of low-cost, mass-produced cameras and optics with computational image recovery offers enhanced capability of achieving large foveal ratios from compact, low-cost imaging systems
A Radio--Optical Reference Frame VIII. CCD observations from KPNO and CTIO: internal calibration and first results
In this pilot investigation, precise optical positions in the FK5 system are
presented for a set of 16 compact extragalactic radio sources, which will be
part of the future radio--optical reference frame. The 0.9 m KPNO and CTIO
telescopes equipped with 2K CCD's have been used for this project. The
astrometric properties of these instruments are investigated in detail. New
techniques of using wide field CCD observations for astrometry in general are
developed. An internal precision of 5 to 31 mas in position per single exposure
is found, depending on the brightness of the object. The tie to the primary
optical reference system is established by photographic astrometry using
dedicated astrographs on both hemispheres. An accuracy of mas per
source is estimated for the multi--step reduction procedure when based on the
future Hipparcos catalog, while the FK5--based positions suffer from system
errors of 100 to 200 mas as compared to the radio positions. This work provides
a contribution to the international effort to link the Hipparcos instrumental
coordinate system to the quasi--inertial VLBI radio reference frame. Precise
radio and optical astrometry of a large sample of compact extragalactic sources
will also contribute to the astrophysics of these objects by comparing the
respective centers of emission at the optical and radio wavelengths.Comment: AAS v.4 LaTeX, 2 parts on 1 file (main text + deluxetable), accepted
by AJ, Dec.95, fig. with reprint
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