Rayleigh-Scatter lidar systems effectively use remote sensing techniques to continuously measure atmospheric regions, such as the mesosphere (45-100km) where in situ measurements are rarely possible. The Rayleigh lidar located at the Atmospheric Lidar Observatory (ALO) on the Utah State campus is currently undergoing upgrades to make it the most sensitive of its kind. Here, the important components of these upgrades and how they will effect the study of a particular atmospheric phenomena, atmospheric gravity waves, will be discussed. We will also summarize what has been done to the system during this year to bring us to the threshold of initial operations
The original Rayleigh-scatter lidar that operated at the Atmospheric Lidar Observatory (ALO; 41.7°N,...
As the impetus for extended observational measurements throughout the middle atmosphere has increase...
Forty-two monochromatic gravity wave events were observed in the 25 to 55 km altitude region during ...
Rayleigh-Scatter lidar systems effectively use remote sensing techniques to continuously measure atm...
The Rayleigh-Scatter lidar system at the Atmospheric Lidar Observatory (ALO) on the Utah State campu...
Extensive measurements have been made of the upper atmosphere by satellites and the lower atmosphere...
In the last few years, the Rayleigh-scatter lidar at the Atmospheric Lidar Observatory at Utah State...
Rayleigh lidar systems have historically made ground-based observations of the upper atmosphere (str...
In June–July 2012, observations were carried out using the recently upgraded, large-aperture, Raylei...
The Rayleigh-scatter lidar at the Atmospheric Lidar Observatory at Utah State University (ALO-USU; 4...
Rayleigh lidar technology opened the middle atmosphere (from 30–90 km) to ground-based observations....
Rayleigh lidar opened a portion of the atmosphere, from 30 to 90 km, to ground-based observations. R...
The Earth’s middle atmosphere is comprised of the stratosphere, mesosphere and thermosphere, from ap...
In June–July 2012, observations were carried out using the recently upgraded, large-aperture, Raylei...
Rayleigh-scatter lidar observations were made at the Atmospheric Lidar Observatory (ALO) at Utah Sta...
The original Rayleigh-scatter lidar that operated at the Atmospheric Lidar Observatory (ALO; 41.7°N,...
As the impetus for extended observational measurements throughout the middle atmosphere has increase...
Forty-two monochromatic gravity wave events were observed in the 25 to 55 km altitude region during ...
Rayleigh-Scatter lidar systems effectively use remote sensing techniques to continuously measure atm...
The Rayleigh-Scatter lidar system at the Atmospheric Lidar Observatory (ALO) on the Utah State campu...
Extensive measurements have been made of the upper atmosphere by satellites and the lower atmosphere...
In the last few years, the Rayleigh-scatter lidar at the Atmospheric Lidar Observatory at Utah State...
Rayleigh lidar systems have historically made ground-based observations of the upper atmosphere (str...
In June–July 2012, observations were carried out using the recently upgraded, large-aperture, Raylei...
The Rayleigh-scatter lidar at the Atmospheric Lidar Observatory at Utah State University (ALO-USU; 4...
Rayleigh lidar technology opened the middle atmosphere (from 30–90 km) to ground-based observations....
Rayleigh lidar opened a portion of the atmosphere, from 30 to 90 km, to ground-based observations. R...
The Earth’s middle atmosphere is comprised of the stratosphere, mesosphere and thermosphere, from ap...
In June–July 2012, observations were carried out using the recently upgraded, large-aperture, Raylei...
Rayleigh-scatter lidar observations were made at the Atmospheric Lidar Observatory (ALO) at Utah Sta...
The original Rayleigh-scatter lidar that operated at the Atmospheric Lidar Observatory (ALO; 41.7°N,...
As the impetus for extended observational measurements throughout the middle atmosphere has increase...
Forty-two monochromatic gravity wave events were observed in the 25 to 55 km altitude region during ...