2016 , Volume 21, № 1, p.40-48

Purpose. Development and testing of an automatic method for detection of shelterwood cutting areas on medium resolution multispectral satellite imagery.

Methodology. The proposed algorithm involves pairwise comparisons of images available for the desired period of time along with the post-processing of changes in the generated map-charts collection for correction of the accepted decisions. Pairwise comparison of images uses a method based on the detection of changes due to blockbased (with bilinear interpolation) matching of the brightness of multi-temporal images and allocation of anomaly pixels based on the analysis for the diagrams of the brightness change. Additionally, the decision has three levels: yes, no, and maybe. The pixels in the direct spread histogram are deviated from the maximum, which is greater than one-and-a-half width of the half-decay of histogram of the reverse spread. They are marked in map-charts of changes as “maybe”, trebled ones are marked as “yes” and others are marked as “no”. At the stage of post-processing of collection of map-charts changes, generated by pairwise comparison of multi-temporal images, we determine the sharpness of changes and whether these changes were kept in the subsequent pictures.

Findings. The method was demonstrated on the example of detection of shelterwood cutting areas based on multi-temporal images of satellite SPOT 4. If there are no such areas on a site of observation, all pixels with identical brightness of the basic image have similar brightness on the test image. Upon appearance of shelterwood cutting areas, brightness of channels R and SWIR increases in the corresponding sites so the spread of pixels brightness grows. The width of reverse spread (from the tested image to basic) is determined by hardware errors in registration system, as well as natural changes, and is used as value of tolerance. This allows for the automatization of image processing, eliminating the necessity for experimental selection of threshold values.

Conclusions. The estimation of efficiency of the proposed method is made by comparison of detection results with a mask generated on the basis of the visual analysis of images. The example of processing images of satellite SPOT indicates that the use of the proposed post-processing procedures doubles the percentage of correct marks in the resulting map-chart of changes.