SU940123A1 - Method of processing images of medicinal-biological objects - Google Patents

Description

(54) METHOD FOR IMAGE PROCESSING

MEDICAL AND BIOLOGICAL OBJECTS 1 The invention relates to optical information processing and can be used in forensic science: expertise, in particular, in the processing of images of dynamic damage marks used to identify sharp tools. A known method of image processing is based on obtaining a holographic matched spatial frequency filter 1. The disadvantage of this method is its relative complexity, due to the need to obtain a hologram. The closest to the proposed technical essence is a method of processing images of biomedical objects, including the creation of the Fourier spectrum of the original image, the spatial filtering of this spectrum, and the reconstruction of the image 2. The disadvantage of this method is the relatively low quality of image processing of dynamic traces of damage used to identify sharp tools, which is due to the following factors. The particular structure of a traceable object, such as wood or bone tissue, as well as the unevenness of the effect of a trace-forming tool, such as an inadequacy of its depth, often result in the trace images corresponding to the same (5th and the same trace-forming feature, such as a notch or -the spike are in the form of small segments located in different parts of the track. This complicates subsequent identification, which requires the simultaneous comparison of all the anti-generative signs, characteristics of the surface of the gun. The purpose of the invention is to improve the quality of image processing of dynamic traces of damage used to identify sharp guns. The goal is achieved by the fact that in the method of image processing

wild biological objects, including the creation of the Fourier spectrum of the original image, the spatial filtering of this spectrum and the restoration of the image. The Fourier spectrum of the original image during the process of spatial filtering is subjected to Fraunhofer diffraction.

Fig. 1 shows the optical layout of the device for carrying out the proposed method; Fig 2 is a diagram of the path of the rays in the optical system. The method of processing images of biomedical objects can be implemented, for example, as follows. The radiation from the coherent source 1 is passed through the flat front formation system 2 and in the back focal plane of the lens 3, the Fourier spectrum of the original image 4 located in the front focal plane of this lens is created. The resulting Fourier transform is subjected to spatial filtering by influencing it with a spatial frequency filter 5, located in the back focal plane of lens 3 and made in the form of a slit, oriented so that its projection onto the plane of the original image 4 forms an image of the paths under study right angle. Simultaneously with filtering, the Fourier spectrum is subjected to a Fraunhofer diffraction filter 5, the Frauofofer diffraction filter 5 is caused by the implementation of the corresponding slit width, the value of t) which is determined by the ratio 1i Ay4rciaf |, where L. is the radiation wavelength of the coherent source 1; P is the focal distance of the Fourier-transforming Zi and restores 6 lenses; L, - the size of the original image 4 It should be noted that the Fourier spectrum is subjected to the Fraunhofer diffraction filter on filter 5, since the front in the transmittance radiation of a coherent source 1 coinciding with the rear focal plane of the lens 3, and therefore with filter 5, is quasi-flat . After filtering with a lens 6, the image is reconstructed in the recording plane.

Claims (1)

system 7 coinciding with the rear focal plane of lens 6. Front focal plane; 1x; this lens is aligned with filter 5. As a result of filtering the Fourier spectrum of the original image 4 using filter 5, spatial frequencies are not informative components of the spectrum are cut off by this filter. At the same time, due to Fraunhofer diffraction implemented on filter 5 for the informative components of the spectrum, the areas of the original image 4 corresponding to individual segments of the traces are converted in the plane of the recording system 7 to the length of the entire image, i.e. all the same segments are averaged. trails, combined into a single, uninterrupted trail. Fig. 2 shows solid lines in the course of the rays in the absence of diffraction on the filter 5, and dotted lines in the presence of it. Thus, the proposed method makes it possible to improve the quality of processing images of dynamic traces of damage used to identify sharp tools, by eliminating the discontinuity of traces in the image due to Fraunhofer diffraction implemented on the spatial frequency filter simultaneously with filtering. Claims The method of image processing of medical and biological objects, including the creation of the Fourier spectrum of the original image, the spatial filtering of this spectrum and the restoration of the image, characterized in that, in order to improve the quality of image processing of dynamic traces of damage, used to identify sharp tools illustrations during spatial filtering 11draw Fraunhofer diffrakvdi. Sources of information taken into account in the examination 1.Gudman J. Introduction to Fourier optics. M., World. 1970, p. 227-235. 2, Ostrovsky Yu. I. Holography and its application. L., Science, 1973, p. 153154 (prototype). 1