RU2361271C1 - Anamorphotic system for reading papillary patterns of outermost phalanges and method of using said system - Google Patents

Abstract

FIELD: physics; alarm.

SUBSTANCE: invention relates to reading and transferring images of papillary patterns of outermost phalanges and can be used in automated biometric information systems for person identification. The said anamorphotic system for reading papillary patterns comprises monochromated radiation sources (RS) and additional sources (AS) of radiation, an optical system (OS) with an objective lens provided with an aperture diaphragm and an optical element (OE) for applying the outermost phalanx and a multielement photodetector (MP). One of the surfaces of the optical element is reflective, spherical and cambered outwards. The multielement photodetector is connected to a controller and inclined with respect to the optical axis. The radiation source and additional radiation source are embodied such that they are hardware-device-controlled and make it possible to receive radiation with uniform illumination and contrast of images. The direction of radiation during passage through the optical element to optical system on the surface with papillary patterns is projected on the multielement photodetector on an area where a papillary line directly contacts the working surface of the optical element, thereby initiating a signal intensity which is greater than that of the area devoid of a direct contact. The additional radiation source and radiation source are periodically actuated.

EFFECT: increase in quality of initial data, input into the person identification system; increase in uniformity of illumination and contrast of different images of papillary patterns; reduction of polychromatic distortions and cost of the system.

15 cl, 14 dwg

Description

Technical field

The proposed device and method relates to the reading and transmission of images of papillary patterns of the extreme phalanges of the fingers used in automated biometric information identification systems.

State of the art

Analogs to the proposed device can be considered:

1. Fingerprint reader for identification, US patent No. 5222152 according to MKI G06K 09/00, op. 22.6.1993, including a light source, an optical system containing, including, an optical element for applying a finger, and a fingerprint image recorder.

2. Device for registering a papillary pattern, RF patent No. 2185096 according to MKI A61B 5/117, op. 07.20.2002, including a light source, an optical system, including, inter alia, an optical element for applying a finger, and a system of photodetector elements connected to the image processing unit.

The disadvantages of the analogues are: insufficiently high quality of the initial data over the entire contact area of the papillary drawings of the extreme phalanges of the fingers with the working surface of the optical element entering the identification system, insufficiently uniform contrast of various images of the papillary patterns due to different characteristics of the presented papillary patterns and lighting characteristics of the optical element, which is applied papillary drawing of the extreme phalanges of the fingers.

The closest in technical essence the prototype for the proposed device and method is "Anamorphic system for reading papillary drawings and the method of its use", RF patent No. 2298222 according to MKI G06K 09/00, op. 04/27/2007, including a light source, an optical system, including, inter alia, an optical element for applying a finger, and a multi-element photodetector in the form of a CCD array.

The disadvantages of the prototypes are the insufficient quality of the source data over the entire contact area of the papillary drawings of the extreme phalanges of the fingers with the working surface of the optical element entering the personality identification system, insufficiently uniform contrast and illumination of various images of the papillary patterns due to various characteristics of the presented papillary patterns and the lighting characteristics of the optical element, to which a papillary drawing of the extreme phalanges of the fingers is applied.

SUMMARY OF THE INVENTION

The geometric dimensions of the scanner optical system are reduced by “compressing” the image of the papillary pattern transmitted to the multi-element photodetector, subjecting it to anamorphy and deanamorphization to obtain the desired undistorted image. Moreover, in order to improve the quality of images transmitted to the personality identification system, it is necessary to ensure a sufficiently high contrast and uniformity of illumination of the working surface in the system, to which papillary drawings of the extreme phalanges of the fingers are applied.

The objective of the invention is to improve the quality of the source data entering the identification system, increasing the contrast and uniformity of illumination of various images of papillary patterns, reducing the cost of the system, reducing polychromatic distortions.

Technical results of the invention:

1) improving the quality of the source data entering the system of personal identification;

2) increasing the contrast of various images of papillary patterns;

3) increasing the uniformity of illumination of various images of papillary patterns;

4) reducing the cost of the system;

5) reduction of polychromatic distortion.

Technical results are achieved by the fact that the anamorphic reading system of papillary drawings of the extreme phalanges of the fingers contains a radiation source, an optical system including, among other things, an optical element for applying a surface with a papillary pattern, and a multi-element photodetector located in the housing, one of the surfaces of the optical element is made reflecting, spherical, convex outward, correcting perspective or trapezoidal distortions of the surface with a papillary pattern applied to the working surface of the optical element, the optical element is made of a substance with a refractive index in the range of 1.2 to 1.8 with a dihedral angle in the range of 60 ° to 87 ° between the working surface of the optical element and the plane passing through at least part of the contour the reflecting surface of the optical element, between the working and refracting faces in the range from 81 ° to 109 °, the multi-element photodetector is connected to the controller and tilted to the optical axis, forming an optical dihedral angle between the multi-element photodetector and by the flickering face of the optical element in the range of angles from 1 ° to 29 °, the radiation source is made in the form that allows to obtain illumination of the working face close to uniform, software-hardware-controlled, the optical system includes an additional at least one hardware-software a controlled radiation source, and the direction of radiation reflected from the applied extreme phalanx of the finger with a papillary pattern, from an additional radiation source or from a radiation source to the optical element, allows to obtain projections when passing through an optical system with distortions eliminated onto the multi-element photodetector of the places of direct contact of the papillary lines with the working face of the optical element, causing a greater intensity of the electric signal on the corresponding elements of the multi-element photodetector compared to places free of direct contact, and the optical system includes a lens with aperture diaphragm. In this case, anamorphization is carried out in only one direction, and the anamorphization coefficient lies in the range from 1.3 to 1.7, the radiation source is located on the side of the opposite working face of the optical element, it emits in the wavelength range from 0.8 μm to 0, 9 μm, additional radiation sources are arranged in such a way that they illuminate the four angular regions of the working face of the optical element, emit in the wavelength range from 0.8 μm to 0.9 μm and are monochromatized with the radiation source.

The term “working face” of an optical element should be understood as a face to which a surface with a papillary pattern of the extreme phalanx of the fingers is applied.

The term "refracting face" of a reflective prism should be understood as the face to which the objective of the optical system is directed.

Monochromatization of radiation sources reduces polychromatic distortion and allows the use of a single-lens instead of a multi-lens while ensuring the same image quality, which affects the overall cost of the device.

An anamorphic reading system of papillary patterns can be performed with the location of additional radiation sources from the side opposite the working face of the optical element. This implementation of the system allows to improve the quality of the source data entering the personality identification system by increasing the uniformity of illumination of the working face.

Anamorphic reading system of papillary patterns can be performed with the location of additional radiation sources from the sides adjacent to the working face of the optical element. This implementation of the system allows to improve the quality of the source data entering the personality identification system by increasing the uniformity of illumination of the working face.

An anamorphic reading system for papillary patterns can be performed with monochromatization of additional radiation sources with a radiation source by selection according to the radiation characteristics by wavelengths. This implementation of the system allows to improve the quality of the source data entering the personality identification system by reducing polychromatic distortions.

An anamorphic reading system for papillary patterns can be performed with a multi-element photodetector containing microlenses for each element. This embodiment of the system allows to improve the quality of the initial data entering the personality identification system by focusing the image parts on the working parts of the photocells of the multi-element photodetector.

An anamorphic reading system for papillary drawings may contain an optical axis that changes its direction, for example, by mirrors or prisms. This embodiment of the system allows to increase its compactness by reducing the distance between the optical element and the multi-element photodetector.

An anamorphic reading system for papillary drawings may contain an immersion lens. This embodiment of the system allows to increase its compactness by reducing the distance between the reflective prism and a multi-element photodetector.

The lens may contain at least one, for example, an aspherical lens. This embodiment of the lens allows you to get the desired undistorted image of the papillary pattern of the extreme phalanx of the finger.

The lens may contain a remote aperture diaphragm. This embodiment of the lens improves the image quality of the papillary pattern of the extreme phalanx of the finger.

A multi-element photodetector of an anamorphic papillary pattern reading system can be made in the form of a CCD matrix (charge-coupled device) or a CMOS structure (silicon-metal-oxide-semiconductor).

The way to use the anamorphic system is to use the standby modes for contacting the surface of the papillary pattern of the extreme phalanx of the finger with the working surface of the optical element and analyzing the surface applied to the working surface of the optical element, adjusting the rational illumination of the working surface of the optical element, adjusting the rational contrast of the optical system, additional analysis of the surface applied to the working surface of the optical element, and transmission of digitized on the image of the papillary pattern of the extreme phalanx of the finger in the computer memory or on the storage medium if the criterion for the correspondence of the surface attached to the working surface of the optical element of the finger with the papillary pattern of the extreme phalanx of the finger to papillary patterns with features inherent in the applied surfaces, in which the radiation source and additional radiation sources activate periodically with periods close to those necessary for successive stages of radiation source and additional sources to the accumulation of the maximum possible change in electrical parameters when changing the conditions of illumination of the element from complete absence to maximum illumination acting on the element for a duration that guarantees the end of transient processes on at least one element of the multi-element photodetector, adjusting the rational illumination of the working surface of the optical element , rational contrast settings, additional analysis of the surface applied to the working surface of the optical element, and the transmission of the digitized image of the papillary pattern of the extreme phalanx of the finger in the computer's memory or on the storage medium. During the stage of waiting for the surface of the papillary pattern of the extreme phalanx of the finger to contact the working surface of the optical element and analyzing the surface applied to the working surface of the optical element, the changes in the electrical parameters generated by the radiation in the optical system are taken into account linearly, taking into account the discreteness of the elements of the multi-element photodetector, radiation source and additional radiation sources of initial duration, part of the total duration necessary to obtain the maximum possible change in the electrical parameter when changing the conditions of illumination of the element from complete absence to maximum illumination, acting on the element for a duration that guarantees the end of transients at least on one of the elements of a multi-element photodetector, and sum proportionally increased or decreased, for example , according to the power law, the difference in the values of changes in electrical parameters in adjacent linearly located elements of a multi-element instant photodetector, activate the radiation source and additional radiation sources with a shorter duration, which is part of the initial duration, and sum the proportionally increased or decreased, for example, according to a power law, the difference in the values of changes in electrical parameters in neighboring linearly arranged elements of the multi-element photodetector and compare the obtained values with the criterion value proportionally increased or decreased, for example, according to a power law, the difference of values changes in electrical parameters in neighboring linearly arranged elements of a multi-element photodetector, determined empirically for surfaces with a papillary pattern of the extreme phalanges of the fingers, and if the comparison conditions are satisfied, they proceed to the steps of adjusting the rational illumination of the working surface of the optical element and adjusting the rational contrast of the anamorphic system for additional analysis of the surface applied to the working surface of the optical element, and in case of unsatisfaction lzhayut use standby contact surface papillary pattern phalanx at the working surface of the optical element and surface analysis applied to the working surface of the optical element. During the stage of adjusting the rational illumination of the working surface of the optical element, the radiation source and additional radiation sources are activated with a partial duration that is part of the total duration necessary to obtain the maximum possible change in the electrical parameter when changing the illumination conditions of the element from complete absence to maximum illumination acting on the element with a duration of guaranteeing the end of transients on the elements of a multi-element photodetector the receiver, which is discretely increased until the full duration is reached, and while the radiation source and additional radiation sources are activated or in the active state, the values of changes in the electrical parameters of the linearly arranged elements of the multi-element photodetector are summed up with the value of these parameters exceeding 80% of the maximum possible change in the electrical parameter when changing the lighting conditions of the element from complete absence to maximum illumination acting on the element lasts with the power guaranteeing the end of transient processes, and the values of the sums and corresponding values of the partial duration are stored both at the radiation source and at additional radiation sources, upon reaching the full duration, the value of the partial duration is selected at which rational illumination of the working surface of the optical element is ensured. During the stage of adjusting the rational contrast of the optical system, the radiation source and additional radiation sources are activated with a partial duration, which is part of the total duration necessary to obtain the maximum possible change in the electrical parameter when changing the lighting conditions of the element from complete absence to maximum illumination, affecting the element with a duration guaranteeing the end transients at least on one of the elements of a multi-element phot receiver, which is discretely increased until the full duration is reached, and while the radiation source and additional radiation sources are activated or in an active state, the values of changes in the electrical parameters of the linearly arranged elements of the multi-element photodetector are summed up with the value of these parameters exceeding 80% of the maximum possible change in the electrical parameter when changing lighting conditions of the element from complete absence to maximum illumination acting on the element Call duration guaranteeing termination transients, and stored values of the sum and the corresponding value of the partial length, on reaching the full length of the partial length value is selected at which the contrast is provided a rational optical system; during the stage of additional analysis of the surface applied to the working surface of the optical element, activate a radiation source with a duration that ensures rational contrast of the optical system in the range from 0.8 μm to 0.9 μm, activate the mode of transferring the digitized image of the papillary pattern of the extreme phalanx of the finger to the computer's memory or to a storage medium in the process of which changes in the electrical parameters of each element of a multi-element photodetector generated by radiation are taken into account optical system.

One of the possible applications of a multi-element photodetector to solve the problems of the present invention is to use semiconductor sensors, the elements of which are supplied with a blocking voltage during operation, and when illuminated, the current in the element circuit increases due to a decrease in resistance due to the formation of charge carriers. Measurements of changes in electrical parameters automate the recognition of papillary patterns.

In the method of using the anamorphic system, a proportional increase or decrease in the difference in the values of changes in the electrical parameters in neighboring linearly arranged elements of the multi-element photodetector can be performed according to the quadratic law.

In the method of using the anamorphic system, a multi-element photodetector can be controlled by a computer.

In the method of using the anamorphic system, a multi-element photodetector can be controlled by a microprocessor.

Information confirming the possibility of carrying out the invention

The possibility of practical implementation of the invention is illustrated by drawings and examples of actions that make up the elements of a method for recognizing a papillary pattern.

Figure 1 presents a diagram of anamorphic system.

Figure 2 presents the spatial diagram of the anamorphic system with refracted mirrors by the optical axis and the location of the multi-element photodetector in the plane of the circuit board.

Figure 3 presents the spatial diagram of the change in illumination depending on the distance from the radiation source to the working surface when placing the latter near the center of the face, the opposite working face of the optical element (size 18 × 24 mm).

Figure 4 presents the spatial diagram of the change (compared with figure 3) during the joint operation of the radiation source and one of the additional radiation sources.

Figure 5 presents the options for accounting for the generated radiation in the optical system of electrical parameters linearly, taking into account the discreteness of the elements of the multi-element photodetector: 5a, 5b - axial; 5c, 5d - parallel to the axes; 5d - inclined; 5e - diagonally, 5g - spline; 5c - along a fragment of a circle.

Figure 6 presents a diagram of the activation of an additional radiation source in standby mode of contact of the surface of the papillary pattern with the working surface of the optical element and analysis of the surface applied to the working surface of the optical element.

Figure 7 presents a diagram of the activation of radiation sources in the setting mode of rational illumination and rational contrast of the optical system.

The diagrams in Fig.6, 7 are presented without detailing the transients when the radiation source is turned on and off with conditional images of the gaps during which the changes in the electrical parameters of the elements of the multi-element photodetector generated by the radiation in the optical system are taken into account.

The anamorphic reading system of papillary patterns contains a radiation source 1, an optical system including a lens 2 with an aperture diaphragm 3 and an optical element 4 for applying a surface with a papillary pattern of the extreme phalanx of finger 5, and a multi-element photodetector 6. Optical element 4 with dihedral angles 7 and 8 between the working surface 9 of the optical element and the plane passing through at least part of the contour of the reflecting surface 10 of the optical element 4 between the working 9 and the refracting surfaces 11 Accordingly, the multi-element photodetector 6 is connected to the controller 12 and is inclined to the optical axis 13, forming an optical dihedral angle 14 between the multi-element photodetector 6 and the refractive face 11 of the optical element 4. The anamorphic reading system of papillary patterns also contains additional radiation sources 15. The optical system may contain refractive optical axis 13 of the mirror 16.

The manufacture of an optical element can be carried out by known methods from materials used in optics, for example glass, and by spraying on the reflective surface of the optical element of the reflective layer, for example, from metal.

The manufacture of the remaining elements of the system can be carried out by known methods.

The way to use the anamorphic system is as follows.

Use the standby mode of contact of the surface of the papillary pattern 5 with the working surface 9 of the optical element 4 and analysis of the surface applied to the working 9 surface of the optical element 4, while activating an additional radiation source 14 periodically software and hardware with a period of duration T (see Fig.6) close to that which is necessary for sequentially carrying out the radiation stages by an additional source 15 until the maximum charge value is accumulated on at least one element of a multi-element photodetector, rational contrast settings, additional analysis of the surface applied to the working surface of the optical element, and transmission of the digitized image of the papillary pattern to the computer memory or to the storage medium.

During activation of the additional radiation source 14, the electrical parameters generated by the radiation in the optical system are taken into account linearly (lines are indicated by 17 in FIG. 5), taking into account the discreteness of the elements of the multi-element photodetector 6, while the additional radiation source 15 is activated with an initial duration T2, which is part the total duration T1 necessary to obtain the maximum possible change in electrical parameters when changing the lighting conditions of the element from full about absence to maximum illumination, acting on the element for a duration, guaranteeing the end of transients, at least on one of the elements of the multi-element photodetector 6, and the proportionally increased or decreased, for example, according to a power law, the difference in the values of changes in electrical parameters in adjacent linearly located 17 elements of a multi-element photodetector, activate an additional radiation source 15 with a shortened duration of T3, which is part of the initial duration T2, and summarize the proportionally increased or decreased, for example, according to a power law, the difference in the values of changes in electrical parameters in the neighboring linearly located 17 elements of the multi-element photodetector 6 and compare the obtained values with the value of the criterion proportionally increased or decreased, for example, according to the power law, the difference of values changes in electrical parameters in adjacent linearly located 17 elements of the multi-element photodetector.

When the surface of the papillary pattern is in contact with the working surface of the optical element, the rational contrast and rational illumination settings of the optical system are used. In this case, an additional radiation source 15 or radiation source 1 is activated with a partial duration T4, which is part of the total duration T1, which is discretely increased until the full duration T1 is reached (see Fig. 7). For an additional radiation source 15 or radiation source 1, the duration of the periods of their activation to ensure rational contrast may be different.

During the stage of additional analysis of the surface applied to the working surface of the optical element, the radiation source 1 is activated with a duration of rational contrast and rational illumination of the optical system, the transmission mode of the digitized image of the papillary pattern in the computer memory or storage medium is activated, during which changes in the electrical parameters of each element of a multi-element photodetector generated by radiation in an optical system.

In the method of using the anamorphic system, a proportional increase or decrease in the difference in the values of changes in electrical parameters in neighboring linearly arranged elements of the multi-element photodetector 6 can be carried out according to a quadratic law.

In the method of using the anamorphic system, a multi-element photodetector 6 can be controlled by a computer.

In the method of using the anamorphic system, a multi-element photodetector 6 can be controlled by a microprocessor.

Thus, the use of system data and the method of its use allows to improve the quality of the initial data entering the personality identification system, the contrast of various images of papillary patterns of the extreme phalanges of the fingers, and the recognition accuracy of papillary patterns of the extreme phalanges of the fingers to reduce polychromatic distortion and the cost of the system.

Claims (15)

1. Anamorphic reading system of papillary drawings of the extreme phalanges of the fingers, containing a radiation source, an optical system including an optical element for applying a surface with a papillary pattern, and a multi-element photodetector located in the housing, one of the surfaces of the optical element is made reflective, spherical and convex outward, correcting perspective or trapezoidal distortions of the surface with a papillary pattern applied to the working surface of the optical element, the optical element is made laminated from a substance with a refractive index of 1.2 to 1.8 with a dihedral angle of 60 to 87 ° between the working surface of the optical element and the plane passing through at least part of the contour of the reflecting surface of the optical element, and from 81 to 109 ° between the working and refracting faces, the multi-element photodetector is connected to the controller and tilted to the optical axis, forming an optical dihedral angle between the multi-element photodetector and the refracting face of the optical element in the range of angles from 1 to 29 °, the radiation source is it is filled with software-hardware-controlled and with the possibility of providing illumination of the working face close to uniform, the optical system includes at least one software-hardware-controlled radiation source, and the direction of radiation reflected from the applied extreme phalanx of the finger with a papillary pattern, from an additional radiation source or from a radiation source into the optical element, allows not passing through the optical system with eliminated distortion projection places not mediocre contact of the papillary lines with the working face of the optical element on the multi-element photodetector, causing a greater intensity of the electric signal on the corresponding elements of the multi-element photodetector compared to places free from direct contact, and the optical system includes a lens with an aperture diaphragm, characterized in that the anamorphic is performed only by one direction, and the anamorphic coefficient lies in the range from 1.3 to 1.7, the radiation source is positioned on the side of the opposite working face of the optical element and is configured to emit in the wavelength range from 0.8 to 0.9 μm, additional radiation sources are arranged in such a way that they illuminate the four angular regions of the working face of the optical element, are monochromatized with radiation source and emit in the wavelength range from 0.8 to 0.9 microns. 2. Anamorphic system according to claim 1, characterized in that the additional radiation sources are located on the side of the opposite working face of the optical element. 3. Anamorphic system according to claim 1, characterized in that the additional radiation sources are located on the side of the faces adjacent to the working face of the optical element. 4. Anamorphic system according to claim 1, characterized in that the additional radiation sources are monochromatized with the radiation source by selection according to the radiation characteristics by wavelengths. 5. Anamorphic system according to claim 1, characterized in that the multi-element photodetector is made with microlenses for each element. 6. Anamorphic reading system for papillary drawings according to any one of claims 1 to 5, characterized in that in the optical system the optical axis is configured to change direction. 7. Anamorphic reading system of papillary drawings according to any one of claims 1 to 5, characterized in that the lens is immersion. 8. Anamorphic reading system for papillary drawings according to any one of claims 1 to 5, characterized in that the lens contains an aspherical lens. 9. Anamorphic reading system of papillary drawings according to any one of claims 1 to 5, characterized in that the aperture diaphragm is remote. 10. Anamorphic reading system for papillary drawings according to any one of claims 1 to 5, characterized in that the multi-element photodetector is made in the form of a CCD matrix. 11. Anamorphic reading system for papillary drawings according to any one of claims 1 to 5, characterized in that the multi-element photodetector is made in the form of a CMOS structure. 12. The method of using the anamorphic system, in which the surface of the papillary pattern of the extreme phalanx of the finger is expected to contact the working surface of the optical element and the surfaces of the papillary pattern of the extreme phalanx of the finger applied to the working surface of the optical element are analyzed, rational illumination of the working surface of the optical element, rational contrast of the optical system are adjusted , additionally analyze the surface of the papillary pattern of the extreme phalanx of the finger attached to the working the surface of the optical element, and transfer the digitized image of the papillary pattern of the extreme phalanx of the finger to the computer memory or the storage medium if the surface of the papillary pattern of the extreme phalanx of the finger matches the papillary patterns with the features inherent in the applied surface of the extreme phalanx of the fingers, in which the radiation source and additional radiation sources activate with periods close to those necessary for sequentially conducting the stages of radiation by the source and additional sources to the accumulation of the maximum possible change in electrical parameters when changing the illumination conditions of the element from complete absence to maximum illumination acting on the element for a duration that guarantees the end of transients on at least one element of the multi-element photodetector, adjusting the rational illumination of the working surface of the optical element, for rational contrast settings, for additional analysis of the surface of papillary pattern and for the extreme phalanx of the finger attached to the working surface of the optical element and for transferring the digitized image of the papillary pattern of the extreme phalanx of the finger to the computer memory or storage medium, during the stage of waiting for the surface of the papillary pattern of the extreme phalanx of the finger to contact the working surface of the optical element and its analysis electrical parameters generated by radiation in an optical linear ramp system taking into account the discreteness of the arrangement of elements of a multi-element photodetector and, at the same time, the radiation source and additional radiation sources are activated with an initial duration that is part of the total duration necessary to obtain the maximum possible change in the electric parameter when changing the lighting conditions of the element from complete absence to maximum illumination, affecting the element with a duration guaranteeing the end of transient processes, at least on one of the elements of a multi-element photodetector, and proportionally enlarged or optionally reduced, for example, according to the power law law of the difference in the values of electrical parameters in neighboring linearly arranged elements of the multi-element photodetector, activate the radiation source and additional radiation sources with a shorter duration, which is part of the initial duration, and sum proportionally increased or proportionally reduced, for example, according to the power law of the difference values of changes in electrical parameters in neighboring linearly arranged elements of many an element photodetector and compare the obtained values with a criterion proportionally increased or decreased, for example, according to the power law of the difference in the values of changes in electrical parameters in neighboring linearly arranged elements of a multi-element photodetector, determined empirically for surfaces with a papillary pattern of the extreme phalanges of the fingers, and if the comparison condition is satisfied proceed to the steps of adjusting the rational illumination of the working surface of the optical element and the rational the contrast of the anamorphic system for additional analysis of the surface of the papillary pattern of the extreme phalange of the finger applied to the working surface of the optical element, and in case of unsatisfaction, they continue to use the standby mode of contact of the surface of the papillary pattern of the extreme phalange of the finger with the working surface of the optical element and its analysis; during the stage of adjusting the rational illumination of the working surface of the optical element, the radiation source and additional radiation sources are activated with a partial duration that is part of the total duration necessary to obtain the maximum possible change in the electrical parameter when changing the lighting conditions of the element from complete absence to maximum illumination acting on the element with a duration of guaranteeing the end of transients on the elements of a multi-element photodetector the receiver, which is discretely increased until the full duration is reached, and while the radiation source and additional radiation sources are activated or in the active state, the values of changes in the electrical parameters of the linearly arranged elements of the multi-element photodetector are summed up with the value of these parameters exceeding 80% of the maximum possible change in the electrical parameter when changing the lighting conditions of the element from complete absence to maximum illumination acting on the element lasts power, guaranteeing the end of transient processes, and store the values of the sums and corresponding values of the partial duration both at the radiation source and at additional radiation sources; upon reaching the full duration, the value of the partial duration is selected at which rational illumination of the working surface of the optical element is ensured; during the stage of adjusting the rational contrast of the optical system, the radiation source and additional radiation sources are activated with a partial duration that is part of the total duration necessary to obtain the maximum possible change in the electrical parameter when changing the lighting conditions of the element from complete absence to maximum illumination acting on the element with a duration guaranteeing the end transients at least on one of the elements of a multi-element phot receiver, which is discretely increased until the full duration is reached, and while the radiation source and additional radiation sources are activated or in an active state, the values of changes in the electrical parameters of the linearly arranged elements of the multi-element photodetector are summed up with the value of these parameters exceeding 80% of the maximum possible change in the electrical parameter when changing lighting conditions of the element from complete absence to maximum illumination acting on the element Call duration guaranteeing termination transients and storing the sum value and the corresponding value of the partial length, on reaching the full length of partial duration selected value, at which the contrast is provided a rational optical system; during the stage of additional analysis of the surface, the papillary pattern of the extreme phalange of the finger, applied to the working surface of the optical element, the radiation source is activated for a duration that provides rational contrast of the optical system from 0.8 to 0.9 μm, the transmission mode of the digitized image of the papillary pattern of the extreme phalange of the finger is activated in the computer memory or on the storage medium, during which the changes in the electrical parameters of each element of the multi-element photodetector are taken into account radiation generated in the optical system. 13. The method of using the anamorphic system according to 14, characterized in that the proportional increase or proportional decrease in the difference in the values of changes in electrical parameters in neighboring linearly arranged elements of the multi-element photodetector is carried out according to a quadratic law. 14. The method of using the anamorphic system according to claim 12 or 13, characterized in that the multi-element photodetector is controlled by a computer. 15. The method of using the anamorphic system according to claim 12 or 13, characterized in that the multi-element photodetector is controlled by a microprocessor.

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