We present a novel method of nonuniformity correction (NUC) of infrared cameras and focal plane arrays (FPA) in a wide optical spectral range by reading radiance temperatures and by applying a radiation source with an unknown and spatially nonhomogeneous radiance temperature distribution. The benefit of this novel method is that it works with the display and the calculation of radiance temperatures, it can be applied to radiation sources of arbitrary spatial radiance temperature distribution, and it only requires sufficient temporal stability of this distribution during the measurement process. In contrast to this method, an initially presented method described the calculation of NUC correction with the reading of monitored radiance values. Both methods are based on the recording of several (at least three) images of a radiation source and a purposeful row- and line-shift of these sequent images in relation to the first primary image. The mathematical procedure is explained in detail. Its numerical verification with a source of a predefined nonhomogeneous radiance temperature distribution and a thermal imager of a predefined nonuniform FPA responsivity is presented.
[1]
J. Hollandt,et al.
Nonuniformity correction of imaging systems with a spatially nonhomogeneous radiation source.
,
2015,
Applied optics.
[2]
J. Hollandt,et al.
Determination of the responsivity non-uniformity of an infrared camera with regard to the measurement of radiance temperatures
,
2015
.
[3]
J. Hollandt,et al.
Analysis of Reference Sources for the Characterization and Calibration of Infrared Cameras
,
2015
.
[4]
A. Sperling,et al.
Spatial characterization of cameras for low-uncertainty radiometric measurements
,
2014
.
[5]
Gerald C. Holst,et al.
Testing and evaluation of infrared imaging systems
,
1993
.