RU2019124C1 - Device for examining ocular iris - Google Patents

Abstract

FIELD: medical engineering. SUBSTANCE: device has a means for obtaining the iris color image, which is an evidence of the condition of the patient's organism. The new in the device is that the means is a television camera connected with an electronic analyzer of the iris color image. The analyzer is incorporated into the device and has a video tape recorder, a video processor, a computer, and a video monitor. The video tape recorder input is electrically connected with the output of the TV camera. The video processor inputs are connected accordingly to the outputs of the TV camera and the video tape recorder. The input and output of the computer are connected accordingly to the output and input of the video processor. The video monitor is electrically connected with the TV camera and the video tape recorder. EFFECT: high accuracy of examining the iris. 7 cl, 5 dwg

Description

 The invention relates to medicine, namely to devices for examining the iris of the eye, and can be used in medicine for the diagnosis of various diseases (iridodiagnosis), mass screenings of the population (medical examination), and professional selection in various sectors of the economy: shift monitoring, control operator activity.

 Of great importance is the rapid assessment of the functional capabilities of the human body (patient) in accordance with the requirements arising in the process of his labor activity. One of the most effective methods for solving this problem is the use of the iridodiagnostic method based on the study of adaptive-trophic changes in the iris of the human eye.

 The main advantage of this method is its consistency. Iridodiagnostics allows you to assess the condition of the body as a whole, to compile a correct idea of the etilogy of the disease, to identify risk zones in the body that are not determined by clinical methods and subjectively. The comparative simplicity of the method, the painlessness and safety of information retrieval, the non-contact or non-invasiveness of information retrieval, the speed of preparation of the diagnosis, and the possibility of early preclinical diagnosis are also significant.

 In the practice of iridodiagnostics, there is known a device for examining the iris of the eye, containing a light source for illuminating the iris of the eye and installed on the path of the light stream reflected from the iris, means for obtaining a color image of the iris of the eye, which is used to judge the state of the patient's body.

 In the specified device, the means for obtaining a color image of the iris of the eye is made in the form of a microscope on which a microphotographic device is installed, with which the image of the iris is recorded on color slides. Subsequently, the received color image of the iris of the eye is analyzed by an iridologist for diagnosis.

 The disadvantage of this device is the low accuracy of the diagnosis, since the eye of the iridologist is psychologically unable to cover the entire field of the iris, and also can not make long-term observations and capture dynamic changes in the iris of the eye and perform an exact comparative analysis of the reference and investigated field of the iris lining of the eye for diagnostic purposes.

 In addition, when photographing or directly observing the iris field, very bright lighting is necessary, which irritates the patient under study and can lead to the appearance of “signs” that can be mistaken for signs of a pathological process.

 Thus, the iridologist judges the patient’s condition by a static image of the iris, which is less informative for a complete diagnosis.

 The disadvantage of this device is the short duration of storage of color slides, as long-term storage of color slides changes the color in the image of the iris, and the color of the iris contains a lot of information about the patient’s body condition.

 The basis of the invention is the task of improving the accuracy of diagnosis and the long-term storage and accumulation of iridological information.

 The problem is solved in that in the device for the study of the iris, containing means for obtaining a color image of the iris and a light source for illumination, according to the invention, the means for obtaining color images of the iris is made in the form of a television camera and is provided with a television camera electronic iris color analyzer containing a video recorder whose input is electrically connected to the output of the television cameras s, a video processor, the inputs of which are respectively connected to the outputs of the television camera and VCR, an analog-to-digital converter, the input and output of which are respectively connected to the output and input of the video processor, and a video monitor electrically connected to the television camera and VCR.

 The means for obtaining a color image of the iris is a color television camera, while the input of the VCR is directly connected to the output of the color television camera, and the inputs of the video monitor are directly connected to the outputs of the color television camera and VCR, respectively. The video monitor is connected to the output of the video processor with one input.

 The means for obtaining a color image of the iris of the eye consists of a black and white television camera with a set of filters installed with the possibility of rotation in the path of the light flux. Light filters can be installed in the path of the light flux reflected from the iris directly in front of the lens of a black and white television camera. It is advisable to install light filters in the path of the light flux directed directly to the iris of the eye.

 The device comprises a synchronization unit for operating a black-and-white camera with rotation of the light filters, the input of which is connected to the camera, and the output with an electric motor, on the shaft of which a set of light filters is installed.

 Thus, the proposed device can significantly improve the accuracy of diagnosis, as it increases the efficiency of the process of patient diagnosis by reducing the processing time of examination data, increases the reliability of diagnosis due to the fact that iridodiagnostic information is presented (fixed) in a dynamic form. In addition, using a cheap black-and-white camera, in a serial color television system, you can get not only a color television image, but also an image in different ranges of the visible spectrum.

 In addition, the proposed device allows for dynamic iridology, i.e. capture dynamic changes in the iris, which in turn allows you to register not only organic, but also functional changes in the body that have not yet passed into a chronic pathological form, by recording temporary changes in the iris that correspond to certain functional changes in the body that traditional iridology does not able to register.

 The proposed device allows you to quickly and non-invasively (non-contact) to assess the state of the human body as a whole, to draw up the correct understanding of the etiology of the disease, to identify risk zones in the body that are not determined by clinical methods and subjectively. In addition, this device allows the recorded video and iridological information to accumulate and store for any length of time for its computer processing.

 Figure 1 shows a block diagram of the proposed device for the study of the iris with a color camera; figure 2 is a block diagram of the proposed device with a black and white camera and filters; in FIG. 3 is a block diagram of the proposed device with the location of the filters; in FIG. 4 is a functional diagram of the video processor of the device of figure 1; figure 5 is a functional diagram of the video processor of the device in figure 2 and 3.

 The proposed device for studying the iris of the eye contains a source 1 (see FIGS. 1-3) of the light flux A for illuminating the iris 2 and a means 3 for obtaining a color image of the iris of the eye reflected from the iris of the eye 2, made in the form of a television camera connected to an electronic analyzer 4 of a color image of the iris, which is used to judge the state of the patient’s body.

 The electronic analyzer 4 of the color image of the iris according to all proposed embodiments of the proposed device (see Fig. 1-3) contains a video recorder 5, the input of which is electrically connected to the output of the television camera means 3, a video processor 6, the inputs 7 and 8 of which are respectively connected to the outputs of the television camera means 3 and the VCR 5, an analog-to-digital converter 9, the input and output of which are respectively connected to the output 10 and the input 11 of the video processor 6, and a color video monitor 12, electric and associated with the television camera means 3 and the VCR 5.

 The light source 1 includes a lamp 13 and a capacitor 14 mounted on the path of the light stream A, directing the light stream A to the iris of the eye 2.

 In an embodiment of the proposed device (see Fig. 1), a color television camera 15 is used as the television camera of means 3, while the input of the VCR 5 is directly connected to the output of the color television camera 15 and the inputs 16 and 17 of the video monitor 12 are directly connected to the output of the color television camera 15 and the output 18 of the VCR 5, respectively. To observe the intermediate processing results of the iris 2, the input 19 of the video monitor 12 is connected to the output 20 of the video processor 6.

 In another embodiment, the proposed device (see figure 2) to reduce the cost of equipment as a television camera means 3 used a black and white television camera 21, while the input of the video monitor 12 is electrically connected to the outputs of the black and white television camera 21 and the VCR 5, respectively through a video processor 6, the output of which 22 is connected to the input of the VCR 5.

 In this case, a set of filters 23 (R, G, B) is mounted on the disk 24, mounted to rotate in the direction of arrow C in the path of the light flux used to illuminate the iris 2. To prevent various kinds of contamination of the surfaces of the filters 23 the latter are installed in the path of the light flux A directed directly to the iris 2.

 To obtain a color television signal, the operation of the black-and-white television camera 19 is synchronized with the rotation of the filters 23 (R, G, B), for this purpose, the proposed device (see Fig. 2) has a synchronization unit 25, the input of which is connected to the black-and-white television camera 21, and the output is with an electric motor 26, on the output shaft 27 of which is fixed a disk 24 with filters 23.

An embodiment of the proposed device, presented in figure 3, is made similar to the proposed device in figure 2. The difference lies in the fact that the disk 24 (see Fig. 3) with light filters 23 is installed in the path of the light flux A ^I reflected from the iris 2 just in front of the lens 28 of the black and white television camera 21.

 In an embodiment of the proposed device (see FIG. 1), a television camera of the WV-F 15 type by PANASONIC (Japan) was used as a color television camera 15, and a video recorder of the AG-7450 type by PANASONIC or HR-D 530 MS as a video recorder 5 JVC (Japan), as a video monitor 12 - a video monitor KX-2910 from SONY (Japan), and as an analog-to-digital converter 9 - an electronic computer IBM PC / AT 386.

 As the video processor 6 (see Fig. 4), a Color FRAME QRABBER DT 2871 video processor (HSI) is used, comprising a decoder 29, the inputs of which are inputs 7 and 8 of the video processor 6 and are connected to the outputs of the video recorder 5 and color television camera 15, respectively, and the outputs (R, G, B) are connected to the inputs of the analog-to-digital converter 30, the input and output of which are connected respectively to the output and input of the random access memory 31, the output and input of which are output 10 and input 11 of the video processor 6 and are connected respectively to the input and out to the analog-to-digital converter 9. Another output of the RAM device 31 is connected to the input of the digital-to-analog converter 32, the other input of which is connected to one of the output of the analog-to-digital converter 30, and the outputs (R, G, B) are connected to the inputs of the encoder 33, the output of which is the output 20 of the video processor 6 and is connected to the input 19 of the video monitor 12.

 In an embodiment of the proposed device (see FIGS. 2 and 3), a well-known black-and-white television camera with a resolution of at least 250 lines and a signal-to-noise ratio ≥ 30 dB is used as a television camera 21.

 As a video recorder 5, a video recorder of the VM-12 Electronics type was used, a video monitor of the VK51Ts61 type was used as a video monitor 12, and a DVK-3 electronic computer was used as an analog-to-digital converter 9.

 As a video processor 6 (see Fig. 5), a VM video processor controller is used, comprising a decoder 34, the input of which is input 8 of the video processor 6 and connected to the video recorder 5, and the output is connected to the switch 35, the input of which is the input 7 of the video processor 6 and connected to a camera 21, and the outputs (R, G, B) of which are connected to the inputs of the analog-to-digital converters 36-38, the outputs of which are connected to a multiplexer 39, the output of which is connected to a random access memory 40, electrically connected to the analog-to-digital converter I eat 9 through the interface unit 41, one of the inputs and the output of which is the input 11 and the output 10 of the video processor 6, and the other output is connected to the multiplexer 39. The outputs of the RAM 40 are connected to the inputs of the digital-analog converters 42-44, the outputs (R, G , B) which are combined into one output, which is the output 29 of the video processor 6 connected to the video monitor 12, and connected respectively to the inputs of the encoder 45, the output of which is the output 22 of the video processor 6 and connected to the input of the video recorder 5.

 The principle of the proposed device for the study of the iris is as follows. The patient fixes his head so that his eye 2 (see figure 1) fell into the field of view of the lens 46 of the color television camera 15. After adjusting the light flux A, i.e. output with oblique lateral illumination of the flare outside the frame or on its peripheral areas, as well as adjusting the lens 46 of the camera 15, the image of the iris of each eye is recorded on the magnetic tape of the VCR 5. Simultaneously with the recording, the image of the iris of the eye 2 is displayed on the color video monitor 12.

 The video signal from the camera 15 through the input 7 of the video processor 6, and from the video recorder 5 through the input 8 is supplied to the decoder 29 (see Fig. 4) of the video signal PAL - >> RGB of the video processor 6. From the decoder 29, the signals R, G, B are digitized in real scale time in the analog-to-digital Converter 30 and served in the random access memory 31, which is connected to the analog-to-digital converter 9. The digitized image stored in the random access memory 31 (processed by the analog-to-digital converter 9 or unprocessed) is fed to digital Ogove converter 32, and then the encoder 33 RGB - >> PAL, the output of which is supplied for rendering a color image of the iris on the color video monitor 12 on which the judged condition of the patient.

 The principle of operation of the proposed device (see figure 2 and 3) is similar to the principle of operation of the device shown in figure 1.

The signal from the black-and-white television camera 21 (see FIGS. 2 and 3) is a sequence of R, G, B signals received using the light flux A and A ^I generated by source 1 and transmitted sequentially through R, G, B filters 23. The sequence of R, G-B signals is created as a result of rotation of the disk 24, in which the R, G, B filters are fixed 23. The rotation speed of the disk 24 of the filter 23 is synchronized with the operation of the camera 21 using the synchronization unit 25 and the electric motor 26, on the output shaft 27 of which disc 24 is installed.

 At the input 8 of the video processor 6, the signal from the output of the VCR 5 is supplied. The television signal is converted in the decoder 34 (Fig. 5) into R, G, B signals and through the switch 35 it enters the analog-to-digital converters 36-38 for each of the three colors R, G, B.

 The digitized signals R, G, B through the multiplexer 39 are sent to the random access memory 40. The digital information stored in the device 40 is converted into digital-to-analog converters 42-44 separately for each color R, G, B and is fed through the output 29 to render the color image rainbow shells of the eye on a color video monitor 12, which is used to judge the state of the patient’s body, and on encoder 45, in which R, G, B signals are converted into a full color television signal and, through output 22, are input to the video recorder 5.

 A television study of the iris opens up new prospects for the use of the proposed device, it becomes possible to assess the subtlest functional changes in the psychophysiological state of a person at any time. Such a study allows us to evaluate not only retrospectively, but also the perspective of a person's condition.

 Using the device is economically viable and practically advisable for preventive (outpatient) examinations of large groups of people in large industrial enterprises, as well as in remote and inaccessible areas.

Claims (7)

 1. DEVICE FOR RESEARCH OF THE IRIS OF THE EYE, containing means for obtaining a color image of the iris and a light source for illumination, characterized in that the means for obtaining a color image is made in the form of a television camera and it is provided with an electronic rainbow color analyzer connected to the television camera shell of the eye, containing a VCR, the input of which is electrically connected to the output of the television camera, a video processor, the inputs of which correspond are connected to the outputs of a television camera and a VCR, an analog-to-digital converter, the input and output of which are respectively connected to the output and input of a video processor, and a video monitor electrically connected to a television camera and a VCR.  2. The device according to claim 1, characterized in that a color television camera is used as a television camera, while the input of the VCR is directly connected to the output of the color television camera, and the inputs are to the outputs of the color television camera and VCR, respectively.  3. The device according to claim 2, characterized in that the video monitor is connected to the output of the video processor by one input.  4. The device according to claim 1, characterized in that a black and white television camera with a set of filters installed with the possibility of rotation in the path of the light stream is used as a television camera.  5. The device according to claim 4, characterized in that the filters are installed in the path of the light flux reflected from the iris directly in front of the lens of the black-and-white television camera.  6. The device according to claim 4, characterized in that the filters are installed in the path of the light flux directed directly to the iris.  7. The device according to claim 5 or 6, characterized in that it comprises a synchronization unit for operating a black and white camera with rotation of the light filters, the input of which is connected to the camera, and the output is with an electric motor, on the shaft of which a set of light filters is installed.

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