SU1764023A1 - Relief object imaging method - Google Patents

Abstract

The invention relates to special methods of obtaining images of objects reflecting light. The purpose of the invention is to visualize the contour lines of the surface relief of the object and improve the image quality. This is achieved by overlapping the object with one end of the fiber optic plate and illuminating the object through the second end of the plate with a beam of light rays at an angle of incidence from 0 to 20 ° C. or from 90 to 70 °. The image of the contour lines — dark on a light background or light on a dark background — is observed (recorded) in two variants of illumination at the second end of the fiber-optic plate. The invention can be used for visual viewing, photographing or recording by other methods of images of contour lines of relief objects on a light reflecting surface, including on a shiny metal surface, for example, medals, tokens, coins in forensics, phaleristics, numismatics, as well as input of information from relief objects 1 з п. ф-л, 2 Il 10 С

Description

The invention relates to methods for obtaining images reflecting the light of embossed objects, and can be used in forensic science, numismatics, phaleristics in visual viewing of the image.

A known method of obtaining images, its photographic or photoelectric recording of relief objects on a shiny flat surface, according to which the object is illuminated at an oblique angle with a light source consisting of a series of small incandescent lamps installed concentrically around the optical axis of the image recording system.

The disadvantage of this method is the uncertainty of the resulting distribution of light and shade in the region of contour relief lines, which is determined by the lighting conditions, as well as the presence of reflections from the shiny surface that mask the contour lines.

The purpose of the invention is to visualize the contour lines of the surface of the object and improve image quality.

For this, the illumination of the surface of the object under study is carried out through a fiber-optic plate superimposed by one end on the object, and the observation is conducted through the second end of the plate.

In this case, the object is illuminated with a beam directed toward the end of the plate at an angle lying within 90-70 ° or -0 ° -20 °

The method is explained in the drawings where in FIG. 1 shows an example implementation of the method.

The method is carried out as follows.

On the embossed object 1 impose a fiber-optic plate 2 on top of the vi

-N

with

The light of which is illuminated by an oblique beam 3, the object is observed through the illuminated end of the plate. As a result of multiple reflections of light as it passes through the plate, a complete symmetrization of the radiation directivity in azimuth is achieved, visualization of contour lines of the surface relief is achieved, and also reflections from the shiny surface of the object are eliminated.

FIG. Figure 2 shows the formation of light and shadow when two objects are illuminated parallel to the surface of the plate and inclined to it, when the object is illuminated by a slidable beam (Fig. 2a) and a paraxial (Fig. 26) beam. When illuminated at a small sliding angle of 90-70 °, the inclined element 4 is illuminated with the pitch of the parallel element 5, which provides the required counterpart. When illuminated by paraxial beam

(0–20 °) the oblique element is illuminated less than parallel, which provides the required contrast (with dark contour lines).

Claims (2)

Claim 1. A method of obtaining images of embossed objects by illuminating an object and observing it in reflected light, characterized in that, in order to visualize the contour lines of the surface relief of an object and improve image quality, the object is illuminated through a fiber-optic plate superimposed by one end on the object while observing the object is conducted through the second end of the plate, 2. A method according to claim 1, characterized in that the object is illuminated by a beam falling on the second end of the plate at an angle lying in the range of 90-70 ° or 0-20 ° FIG. Hh but FIG. 2 V M 1 M f 1 G J