Title :
Airborne imaging radiometer scan simulation
Author :
Kemppinen, Martti
Author_Institution :
Lab. of Space Technol., Helsinki Univ. of Technol., Espoo, Finland
fDate :
5/1/1995 12:00:00 AM
Abstract :
An imaging radiometer scan simulation program is developed for comparing the performance of different scan patterns and process behavior under varying circumstances. The program gives the radiometer´s antenna beam the desired scan motion over an artificial target scene, computes the antenna radiometric temperature as the convolution of the antenna pattern with the scene brightness temperature deviation, computes a moving average of the antenna output, and records the data values as well as the corresponding coordinates at the sampling moments. The simulation indicated that a helicopter-borne imager needs at least passive attitude stabilization. In addition, the state-of-the-art sampling rate was found to be too slow, if the sampling period is set equal to the integration time. A detailed study revealed the achievable spatial resolution (line pairs/length unit-definition) to be 1.0-1.2×footprint dimensions, but the integration and sampling periods should be as short as 0.2-0.4×footprint dimensions
Keywords :
geophysical techniques; microwave imaging; microwave measurement; millimetre wave imaging; millimetre wave measurement; radiometry; remote sensing; 93 GHz; EHF mm wave millimetric; airborne imaging radiometer scan simulation; antenna pattern; antenna radiometric temperature; geophysical measurement technique; helicopter-borne imager; land surface; microwave radiometry; passive attitude stabilization; process behavior; radiometric imaging; radiometry; remote sensing; scan pattern; spatial resolution; terrain mapping; Antenna measurements; Brightness temperature; Computational modeling; Image sampling; Layout; Radiometry; Sampling methods; Shape measurement; Size measurement; Space technology;
Journal_Title :
Geoscience and Remote Sensing, IEEE Transactions on
