SU34302A1 - V-Sensitometer - Google Patents

Description

The invention is a wedge-based densitometer with a constant HIeqe of photometric fields, in which the intensity of the compared fluxes (in comparison measure) does not depend on the measured density, i.e., is constant.

In FIG. 1 shows a diagram of one of the densitometroe already known, and FIG. 2-scheme of the proposed densito. meters., V

As is known, densitometers of various designs are used to determine optical densities, based on comparing (subjective or objective) two light fluxes, one of which passes through the test density, and the other through a particular photometric device, which allows to vary the intensity of this flow. Most of the existing structures are prone to the disadvantage that for each test density, a comparison occurs between conditions due to the fact that the intensity of the compared fluxes varies depending on the density to be measured. This circumstance is highly undesirable for both objective and subjective photometry, making it difficult to calculate and reduce their accuracy.

FIG. 1 drawing is given a schematic representation of a typical existence (124)

design wedge densitometer; where we test the density (plate) 7 and the photometric wedge 2 under, are compared by comparison with the eye 6 by the photometric Lummer-Brodhun cube 5. Illumination of the test density and the wedge is made by the light sources 5 and #. In such a design, during densitometry, equalities of two visible fields adjacent to the ocular are equalized, from which the strength of one is determined by the test density, and the brightness of the other can be arbitrarily changed by moving the photometric wedge. It is obvious that the brightness of the photometric fields will vary depending on the values of 1 of the test density, and the comparison will occur under unequal conditions.

The author offers a densitometer design that is free of the indicated | i.ext, based on the principle that the light beam that passes through a certain constant reference density is subjected to comparison, and the light beam that passes through both the test density and the photometric device, allowing arbitrary change the intensity of the light flux. Thus, the photometry in the "proposed conditions" consists in comparing a certain reference density and the total density

test, density and photo fixture (more precisely: equivalent to „density of photometric fixture); the desired density is determined by the difference: this; The density minus is equivalent to the density of the photometric device.

The implementation of this principle in relation to the design of the densitometer shown in FIG. 1 is schematically shown in FIG. 2, where the location of the test density (plate) 7, photometric gray wedge 2, light sources 3 vi 4, photometric cube 5, ocular 6 and some / standard standing density (plate) 7 is shown.

In the absence of the test density / photometric fields will have the same brightness when the section of the wedge 2 under the cube 5 will be its density equal to the reference density 7. If you now enter the test density 7, as shown in FIG. 2, then for the brightness equation of the fields you need to move the LIN 2 by an amount so that the sum of the density of the wedge 2 (dice 5) and the test density 7 is still equal to the reference density 7. Obviously, the desired test density value 7 is determined, as usual, with wedge drive. On the other hand, it is obvious that the brightness of the photometric field will always be the same at the time of comparison, whatever the density to be measured. This fulfills the requirement of photometric measurement always in equal conditions (i.e., with constant brightness of the photometric fields) corresponding to the optimal conditions of contrasting eye sensitivity or sensitivity of an objective photometric device, which ensures the maximum achievable measurement accuracy.

The subject matter of the invention.

A wedge densitometer, characterized in that the reference plate 7 with a constant density is set to the rays from one light source 3, and a test plate 7 and a gray wedge 2 are located along the path of the rays from another light source 4.

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