RU97839U1 - DEVICE FOR PREPARING IMAGES OF IRIS OF THE EYES - Google Patents

Abstract

 A device for acquiring images of human irises (ROGs) comprising RAG illumination means in one or more spectral ranges close to the visible range, a means for registering a signal reflected from the eyes, and a means for processing received images, including a detection unit on the image of eye pupil centers, a determination unit eye coordinates relative to a given center of reference and the construction of a baseline that connects the centers of the pupils, the image processing unit HRO in a normalized coordinate grid segmentation and allocation information areas, codes forming unit and storage unit.

Description

The utility model relates to techniques for protecting various objects from access by unauthorized persons by identifying a person by the image of her iris (ROG) and can be used to diagnose the state of organs and functional systems of the body by the ROG.

Various technological processes and devices are known in order to identify a person by the totality of special, inherent only signs that are present on the iris of the eye (see US 4641349 [1]).

A device for identifying a person by his iris (HORN) is known, which is a means for registering an HORN in the form of a video camera with a lens and a processing unit for receiving information connected to it (see JP 10137223 [2]). The information processing unit is connected to means of transmitting information to a person whose identity must be identified. This tool is made in the form of a loudspeaker, which informs the identifiable person about the need to change his location in order to obtain the optimal HOG for image recognition. A disadvantage of the known system is its relative complexity, which consists in the fact that the system for obtaining information on the Horn should carry out its fairly quick analysis, identify deficiencies (for example, image clarity) and, through a rather sophisticated sound notification system, indicate to the identifiable person the need for certain movements regarding fixation means HORN.

A device for identifying a person according to the image of her iris is provided, which comprises means for registering images of Horn of people in the form of a television camera, a means of illuminating the Horn of an identifiable person, which is used as a semiconductor radiation source (see JP 10137220 [3]), and a means of forming they are based on a database, which is then used to identify an individual. At the same time, in the process of registering an Horn image, the eye is illuminated by optical radiation in a narrow spectral range. Each image before being placed in the database is processed in a computer using special software and stored as a specific code. To carry out the process of identifying a person, an image of its Horn is registered, the captured image is processed and compared with those stored in the database.

A disadvantage of the known device for identifying a person is its relatively low accuracy since one set of characteristic features is used to identify a person, i.e. one code.

Closest to the claimed is a known device for identifying a person by the image of her iris, which contains a means of recording images. It was found that the use of backlighting in the same spectral range due to differences in the color of the HOG pigment in some cases does not allow us to accurately determine the boundary between the protein and the iris, and in addition, some of the characteristic features of the HOG are not detected due to poor contrast when using backlight whose wavelength is close to the color of these elements. Therefore, in the known device there are several illuminators with different wavelengths of emitted radiation. The eye of the identifiable person is first illuminated with light close to infrared, the color of the Horn pigment is detected, and depending on this, the wavelength of the optical radiation source used to illuminate the Horn is selected at the time of recording its image. As a result of image processing, a code corresponding to it is generated, which is stored in a database and used for comparison with the current value of the code created by re-registering an HOR image of an identifiable person (JP 2006031185 [4]).

A disadvantage of the known device for identifying a person, despite the fact that the resulting codes carry information about a greater number of characteristic elements, is its relatively low accuracy since one set of characteristic features is used to identify a person, i.e. one code. In addition, the device has a relatively complex design, is difficult to operate, and requires a sufficiently long time to obtain HOR images because of the need to select the optimal radiation length to obtain the high-quality image necessary for identification. The process of creating a code for putting it into a database and for identifying a person by comparing the re-received code with the existing ones also requires quite a lot of time and can lead to errors due to the fact that the identifiable person at the moment of fixing the images required for this can tilt its head, as a result, the image obtained under such conditions may coincide with the HOR images of other previously identified individuals obtained by “normal” placement of the face in the field of view of the recording mouth royals. In addition, when forming the identification code, the angle of inclination of the head and, accordingly, the rotation of the Horn within certain limits are not taken into account due to the physically ambiguous approach of the identifiable person to the field of view of the means of fixing the Horn image, which significantly increases the identification time due to enumeration of the tilt angles of the obtained Horn image with simultaneous comparison with those stored in database.

Declared as a useful model, a device for obtaining images of the iris of the eye (ROG) of a person is aimed at simplifying the design, operating conditions and the possibility of simultaneously obtaining several sets of characteristic features, i.e. multiple codes, which provides increased accuracy and speed of identification.

This result is achieved by the fact that the device for obtaining images of the iris of the eye (ROG) of a person includes means for illuminating the ROG in one or more spectral ranges close to the visible range, a means for recording the signal reflected from the eyes, and a means for processing the obtained images, including a detection unit on the image of the centers pupils of the eyes, a unit for determining the coordinates of the eyes relative to a given center of reference and building a baseline that connects the centers of the pupils, the image processing unit HORN in a normalized coordinate grid with segmentation and allocation of information areas, a block for generating codes and a block for storing them.

Providing the device with an ROG illumination means in one or several spectral ranges close to the visible range allows one to obtain several images of the same ROG in which characteristic points (image elements) will have different locations in the same coordinate grid. At the same time, characteristic features that have low contrast in one color spectrum and / or when illuminated by radiation of one wavelength may not be taken into account by the image recognition and processing system, are more contrasted in another color spectrum and / or when illuminated by radiation of a corresponding other length the waves. This in turn allows you to generate identification codes for each of the images, while each code is strictly individual and belongs only to this person. Therefore, identification carried out immediately by several codes, greatly increases the accuracy of identification of a person, since a person is considered uniquely established when all the codes obtained during processing of several images coincide.

The use of optical radiation illumination, the spectral range of which is close to visible light, during the registration of the HOGs increases the accuracy of identification, since, on the one hand, it allows one to obtain a color image of Horns with virtually no distortion in the spectral characteristics of its elements, and, on the other hand, select a sufficiently large number spectra (or spectral lines, or spectral ranges) in which this image can be processed.

Providing the device with a means of recording the signal reflected from the eyes allows you to capture the image of the Horn for further processing of the obtained images and their storage.

The supply of the device with a means of processing the obtained images is necessary in order to generate identification codes based on them.

Providing the means for processing the obtained images with a detection unit on the image of the centers of the pupils of the eyes and a unit for determining the coordinates of the eyes relative to a given reference center and constructing a baseline that connects the centers of the pupils can significantly accelerate both the formation of codes for storage and their comparison with the codes of the person currently identifiable, and also to increase the accuracy of identification even if radiation from one long wavelength (monochrome) is used for illumination. Indeed, if we take into account that the identifiable person at the moment of fixing the images required for this can tilt his head, as a result of which the image obtained under such conditions can coincide with the HOR images of other previously identified individuals obtained by “normal” placement of the face in the field of view , then the construction of a baseline that connects the centers of the pupils allows you to determine (restore) the "normal" position of the face and thereby avoid mistakes. Accordingly, the construction of a baseline that connects the centers of the pupils allows it to be used as the basis for the formation of a normalized coordinate grid, in which the location of characteristic elements of the ROG is calculated, and identification codes are generated. And carrying out calculations in a normalized coordinate grid reduces the time for the formation of identification codes.

As a means of illumination, any known monochromatic or close to them (with a narrow spectral range) radiation sources — incandescent lamps with corresponding light filters, LEDs, etc. can be used.

As a means of image registration, any of the known ones can be used - video cameras, digital cameras, etc., but in order for the captured image to be easily digitized and subjected to processing (analysis, encryption, recognition) using a computer it is advisable to use CCD or CMOS matrices as such.

As a means of processing the obtained images, including a detection unit on the image of the centers of the pupils of the eyes, a unit for determining the coordinates of the eyes relative to a given center of reference and constructing a baseline that connects the centers of the pupils, a block for processing HOG images in a normalized coordinate grid with segmentation and selection of information areas, a code generation unit and a storage unit may use a personal computer equipped with appropriate software. For example, a set of such programs as: a program for determining the coordinates of the eyes relative to a given center of reference; a program for constructing a basal straight line connecting the centers of the pupils; a program for processing HOR images in a normalized coordinate grid with segmentation and allocation of information areas; code generation program; database for storing codes.

The essence of the claimed device is illustrated by an example of its implementation and a drawing, which shows in a most general form a schematic diagram of a device for registering an HORN.

A device for acquiring an Horn image in the most general case comprises a means 1 for illuminating the Horn in one or more spectral ranges close to the visible range, means 2 for recording a signal reflected from the eyes, which is in the field of view of the optical projection system 3, which constructs an image of the registered Horn in the plane of the photosensitive elements of the CCD matrix and means 4 for processing the obtained images. The means 1 for illuminating the Horn, the means 2 for recording the signal reflected from the eyes and the optical projection system 3 can be placed in a common housing (not shown in the drawing)

The processing means 4, which can be used as a personal computer, includes a block 5 for detecting the centers of the pupils of the eyes on the image, a block 6 for determining the coordinates of the eyes relative to a given reference center and constructing a baseline that connects the centers of the pupils, a block 7 for processing ROG images in a normalized coordinate grid with segmentation and allocation of information areas, block 8 forming codes and block 9 storing codes.

The device is used as follows. An identifiable person is placed in the field of view of the optical projection system 3, which builds an image of the registered ROG in the plane of the photosensitive elements of the registration means 2 (CCD matrix), which allows to obtain a high-quality image of the ROG. Moreover, in the process of registering an image of the Horn, it is highlighted with optical radiation from sources 1 with different spectral ranges or wavelengths. For this purpose, known radiation sources can be used, for example, LEDs of a certain luminance range or other sources. The resulting image is converted into digital form and transmitted to the means 4 for processing the obtained images (personal computer equipped with appropriate software). In accordance with the image processing programs, in the detection unit 5 on the image of the centers of the eye pupils, the location of the centers of the eye pupils is calculated, and then in the block 6, the coordinates of the eyes are determined relative to a given reference center and the construction of a baseline that connects the centers of the pupils. As a predetermined center of reference, for example, the center of the left pupil can be selected. Then the abscissa axis is laid off along the straight line connecting the centers of the pupils of the eyes, and is directed towards the right eye. Another option for choosing the center of coordinates is the middle of the segment connecting the centers of the pupils of both eyes. The abscissa axis is oriented along this segment.

In block 7 of the processing of HOR images in a normalized coordinate grid, information areas are selected, then their quality is improved due to digital filtering algorithms, and useful information is converted into a form suitable for comparison. At the stage of selecting information areas, a visual interference (eyelashes, eyelids and glare) is searched for in the frame. The information area of the eye is the entire area of the iris, except for the area occupied by visual interference. Digital filtering is necessary to reduce the noise level in the frame, to highlight the differences in color intensity in different spectral ranges. At the stage of translating the prepared image into a code, the image is compressed into a data array (code) in such a way that a measure of similarity of these codes can be introduced in order to identify or verify a person’s personality.

Based on the isolation and analysis of the HOG images, codes of each of them are generated, which are stored in the database as reference. Subsequently, when there is a problem of identification of a person with the purpose of permitting his access or passage, for example, to a protected area, some storehouse, when crossing the borders of the state, the procedure described above is repeated, except that the codes obtained from this identification they are compared with those already stored in the database, and if the codes of the identified identity match, access or passage is allowed.

Claims (1)

A device for acquiring images of human irises (ROGs) comprising RAG illumination in one or more spectral ranges close to the visible range, a means for registering a signal reflected from the eyes, and a means for processing received images, including a detection unit in the image of eye pupil centers, a determination unit eye coordinates relative to a given center of reference and the construction of a baseline that connects the centers of the pupils, the image processing unit HRO in a normalized coordinate grid segmentation and allocation information areas, codes forming unit and storage unit.