Add to ORKGPath length changes through the atmosphere cause significant errors for astronomical radio interferometry at high frequencies (e.g. 100 GHz). Path length differences typically give rise to a differential excess path of 1mm for antennas separated by 1km, and have fluctuation time scales of greater than 10 seconds. To measure these fluctuations, we are building a four-channel radiometer centred on the 22 GHz water line. By sensing the water vapour emission, the excess path can be deduced and corrected. Multiple channels give us robustness against various systematic errors, but gain stability of the radiometer of 1 pair in 10^4 is still required
xii, 143 leaves : ill. ; 28 cm.The performance of astronomical interferometer arrays operating at (s...
A dual-channel, ground-based microwave radiometer, working at the frequencies 21.0 and 31.4 GHz, an ...
An important source of error in very-long-baseline interferometry (VLBI) estimates of baseline lengt...
Correcting for the fluctuations in atmospheric path length caused by water vapor is a major challeng...
Microwave radiometer techniques were evaluated for use in atmospheric path length correction of Paci...
Water vapor as an error source in radio interferometry systems is briefly examined. At microwave fre...
Range measuring systems are limited in accuracy by uncertainties in the atmospheric refraction corre...
The accuracy of very long baseline interferometry in geodetic and astrometric applications is primar...
Phase noise caused by an inhomogeneous, time-variable water vapor distribution in our atmosphere red...
Microwave radiometers were used to measure the emission line due to the water vapor molecules of atm...
Simultaneous very long baseline interferometry (VLBI) and water vapor radiometer (WVR) measurements ...
We present results from phase correction efforts at the Owens Valley Radio Observatory millimeter ar...
This report describes the research and development phase for eight dual-channel water vapor radiomet...
We demonstrate phase correction of 3 mm VLBI observations using the scanning 18 GHz to 26 GHz water ...
It is well known that the water vapor in the troposphere plays a fundamental role in radio propagati...
xii, 143 leaves : ill. ; 28 cm.The performance of astronomical interferometer arrays operating at (s...
A dual-channel, ground-based microwave radiometer, working at the frequencies 21.0 and 31.4 GHz, an ...
An important source of error in very-long-baseline interferometry (VLBI) estimates of baseline lengt...
Correcting for the fluctuations in atmospheric path length caused by water vapor is a major challeng...
Microwave radiometer techniques were evaluated for use in atmospheric path length correction of Paci...
Water vapor as an error source in radio interferometry systems is briefly examined. At microwave fre...
Range measuring systems are limited in accuracy by uncertainties in the atmospheric refraction corre...
The accuracy of very long baseline interferometry in geodetic and astrometric applications is primar...
Phase noise caused by an inhomogeneous, time-variable water vapor distribution in our atmosphere red...
Microwave radiometers were used to measure the emission line due to the water vapor molecules of atm...
Simultaneous very long baseline interferometry (VLBI) and water vapor radiometer (WVR) measurements ...
We present results from phase correction efforts at the Owens Valley Radio Observatory millimeter ar...
This report describes the research and development phase for eight dual-channel water vapor radiomet...
We demonstrate phase correction of 3 mm VLBI observations using the scanning 18 GHz to 26 GHz water ...
It is well known that the water vapor in the troposphere plays a fundamental role in radio propagati...
xii, 143 leaves : ill. ; 28 cm.The performance of astronomical interferometer arrays operating at (s...
A dual-channel, ground-based microwave radiometer, working at the frequencies 21.0 and 31.4 GHz, an ...
An important source of error in very-long-baseline interferometry (VLBI) estimates of baseline lengt...