Abstract
This article proposes a method for the prediction of wide range two-dimensional refractivity for synthetic aperture radar (SAR) applications, using an inverse distance weighted (IDW) interpolation of high-altitude radio refractivity data from multiple meteorological observatories. The radio refractivity is extracted from an atmospheric data set of twenty meteorological observatories around the Korean Peninsula along a given altitude. Then, from the sparse refractive data, the two-dimensional regional radio refractivity of the entire Korean Peninsula is derived using the IDW interpolation, in consideration of the curvature of the Earth. The refractivities of the four seasons in 2019 are derived at the locations of seven meteorological observatories within the Korean Peninsula, using the refractivity data from the other nineteen observatories. The atmospheric refractivities on 15 February 2019 are then evaluated across the entire Korean Peninsula, using the atmospheric data collected from the twenty meteorological observatories. We found that the proposed IDW interpolation has the lowest average, the lowest average root-mean-square error (RMSE) of ∇M (gradient of M), and more continuous results than other methods. To compare the resulting IDW refractivity interpolation for airborne SAR applications, all the propagation path losses across Pohang and Heuksando are obtained using the standard atmospheric condition of ∇M = 118 and the observation-based interpolated atmospheric conditions on 15 February 2019. On the terrain surface ranging from 90 km to 190 km, the average path losses in the standard and derived conditions are 179.7 dB and 182.1 dB, respectively. Finally, based on the air-to-ground scenario in the SAR application, two-dimensional illuminated field intensities on the terrain surface are illustrated.
Highlights
The dramatic advances in long-range radar technologies have resulted in various functional radar applications, such as synthetic aperture radars (SARs) [1,2,3], airborne weather radars (AWRs) [4], terrain-following radars (TFRs) [5], and airborne early warning radars (AEWs) [6,7]
Excellent range resolution to display the outline of aircraft and vehicles is achieved using surface movement radars (SMRs) [9]
The direction of wave propagation for the long-range radar is significantly influenced by the atmospheric refraction, which is mostly caused by the atmospheric conditions, including air pressure, temperature, and relative humidity [17]
Summary
The dramatic advances in long-range radar technologies have resulted in various functional radar applications, such as synthetic aperture radars (SARs) [1,2,3], airborne weather radars (AWRs) [4], terrain-following radars (TFRs) [5], and airborne early warning radars (AEWs) [6,7]. A novel method is proposed for predicting a wide range of two-dimensional radio refractivity using an inverse distance weighted (IDW) interpolation of high-altitude radio refractivity data from multiple meteorological observatories.
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