32 research outputs found
Mapping the CMB I: the first flight of the QMAP experiment
We report on the first flight of the balloon-borne QMAP experiment. The
experiment is designed to make a map of the cosmic microwave background
anisotropy on angular scales from 0.7 to several degrees. Using the map we
determine the angular power spectrum of the anisotropy in multipole bands from
l~40 to l~140. The results are consistent with the Saskatoon (SK) measurements.
The frequency spectral index (measured at low l) is consistent with that of CMB
and inconsistent with either Galactic synchrotron or free-free emission. The
instrument, measurement, analysis of the angular power spectrum, and possible
systematic errors are discussed.Comment: 4 pages, with 5 figures included. Submitted to ApJL. Window functions
and color figures are available at
http://pupgg.princeton.edu/~cmb/welcome.htm
Galactic microwave emission at degree angular scales
We cross-correlate the Saskatoon Ka and Q-Band Cosmic Microwave Background
(CMB) data with different maps to quantify possible foreground contamination.
We detect a marginal correlation (2 sigma) with the Diffuse Infrared Background
Experiment (DIRBE) 240, 140 and 100 microm maps, but we find no significant
correlation with point sources, with the Haslam 408 MHz map or with the Reich
and Reich 1420 MHz map. The rms amplitude of the component correlated with
DIRBE is about 20% of the CMB signal. Interpreting this component as free-free
emission, this normalization agrees with that of Kogut et al. (1996a; 1996b)
and supports the hypothesis that the spatial correlation between dust and warm
ionized gas observed on large angular scales persists to smaller angular
scales. Subtracting this contribution from the CMB data reduces the
normalization of the Saskatoon power spectrum by only a few percent.Comment: Minor revisions to match published version. 14 pages, with 2 figures
included. Color figure and links at
http://www.sns.ias.edu/~angelica/foreground.htm
Mapping the Cosmic Microwave Background Anisotropy:The First Flight of the QMAP Experiment
We report on the first flight of the balloon-borne QMAP experiment. The experiment is designed to make a map of the cosmic microwave background (CMB) anisotropy on angular scales from 0fdg70 to several degrees. Using the map, we determine the angular power spectrum of the anisotropy in multipole bands from l~40 to l~140. The results are consistent with the SK (from Saskatoon, Saskatchewan, Canada) measurements. The frequency spectral index (measured at low l) is consistent with that of CMB and inconsistent with either Galactic synchrotron or free-free emission. The instrument, measurement, analysis of the angular power spectrum, and possible systematic errors are discussed
Comparing and combining the Saskatoon, QMAP and COBE CMB maps
We present a method for comparing and combining maps with different
resolutions and beam shapes, and apply it to the Saskatoon, QMAP and COBE/DMR
data sets. Although the Saskatoon and QMAP maps detect signal at the 21 sigma
and 40 sigma levels, respectively, their difference is consistent with pure
noise, placing strong limits on possible systematic errors. In particular, we
obtain quantitative upper limits on relative calibration and pointing errors.
Splitting the combined data by frequency shows similar consistency between the
Ka- and Q-bands, placing limits on foreground contamination. The visual
agreement between the maps is equally striking. Our combined QMAP+Saskatoon
map, nicknamed QMASK, is publicly available at
www.hep.upenn.edu/~xuyz/qmask.html together with its 6495x6495 noise covariance
matrix. This thoroughly tested data set covers a large enough area (648 square
degrees -- currently the largest degree-scale map available) to allow a
statistical comparison with COBE/DMR, showing good agreement.Comment: Replaced to match accepted PRD version. 12 pages, 11 figs. Map and
covariance matrix at http://www.hep.upenn.edu/~xuyz/qmask.html or from
[email protected]
The balloon-borne large-aperture submillimeter telescope for polarimetry: BLAST-Pol
The Balloon-borne Large Aperture Submillimeter Telescope for Polarimetry
(BLAST-Pol) is a suborbital mapping experiment designed to study the role
played by magnetic fields in the star formation process. BLAST-Pol is the
reconstructed BLAST telescope, with the addition of linear polarization
capability. Using a 1.8 m Cassegrain telescope, BLAST-Pol images the sky onto a
focal plane that consists of 280 bolometric detectors in three arrays,
observing simultaneously at 250, 350, and 500 um. The diffraction-limited
optical system provides a resolution of 30'' at 250 um. The polarimeter
consists of photolithographic polarizing grids mounted in front of each
bolometer/detector array. A rotating 4 K achromatic half-wave plate provides
additional polarization modulation. With its unprecedented mapping speed and
resolution, BLAST-Pol will produce three-color polarization maps for a large
number of molecular clouds. The instrument provides a much needed bridge in
spatial coverage between larger-scale, coarse resolution surveys and narrow
field of view, and high resolution observations of substructure within
molecular cloud cores. The first science flight will be from McMurdo Station,
Antarctica in December 2010.Comment: 14 pages, 9 figures Submitted to SPIE Astronomical Telescopes and
Instrumentation Conference 201
A cryogenic rotation stage with a large clear aperture for the half-wave plates in the Spider instrument
We describe the cryogenic half-wave plate rotation mechanisms built for and
used in Spider, a polarization-sensitive balloon-borne telescope array that
observed the Cosmic Microwave Background at 95 GHz and 150 GHz during a
stratospheric balloon flight from Antarctica in January 2015. The mechanisms
operate at liquid helium temperature in flight. A three-point contact design
keeps the mechanical bearings relatively small but allows for a large (305 mm)
diameter clear aperture. A worm gear driven by a cryogenic stepper motor allows
for precise positioning and prevents undesired rotation when the motors are
depowered. A custom-built optical encoder system monitors the bearing angle to
an absolute accuracy of +/- 0.1 degrees. The system performed well in Spider
during its successful 16 day flight.Comment: 11 pages, 7 figures, Published in Review of Scientific Instruments.
v2 includes reviewer changes and longer literature revie