PT107019B - SYSTEM FOR MEASURING THE INTERPULE DISTANCE USING A SCREEN WITH A SURFACE WITH TWO SPECIFICITY LEVELS - Google Patents

Abstract

The present invention is found in the technical field of optics and ophthalmology. The present invention is directed to a system that permits the measurement of the distal distance defined as the distance between the center of the left and the center of the right plexus, dispensing with any additional object or object on the face of the subject, and referring to a device CONVENTIONAL ELECTRONIC THAT COMPREHENSES A PROCESSOR AND A SCREEN WITH A SURFACE WITH TWO ZONES OF DIFFERENT SPECULARITY: A REFLECTIVE ZONE OF A HIGH REFLECTIVE ZONE OR OF HIGH SPECIFICITY (200) AND A LITTLE REFLECTIVE OR LOW SPECULARITY ZONE (202).

Description

The present invention is in the field of optics and optometry, and relates to the estimation of interpupillary distance by a contactless process.

In prescribing ophthalmic lenses it is necessary to have knowledge of various biometric data on the dimensions and shape of both the face and the visual system of the User, and the respective frames that will support the lens. With this data it is possible to obtain custom lenses that correct the user's vision problem. Among these biometric data, the most important is the Interpupillary Distance, which is defined as the distance between the pupil centers of the two eyes.

Interpupillary Distance is essential for lens prescription because it defines the distance of the optical axes of the two lenses to be placed on the frames. A correct measurement of this distance is crucial for a perfectly corrected vision. Otherwise, an incorrect measurement of more than one millimeter will cause misalignment of the lens relative to the eyes, resulting in imperfect vision and eye fatigue.

There are several commercial systems for measuring Interpupillary Distance, however these systems are complex, expensive and applied by specialized technicians, usually optometrists and ophthalmologists, performed in their own places such as shops, clinics or optical centers. These systems are generally rigorous, accurate to less than millimeter, and use specialized machines usually requiring an artifact or object placed on the patient's face or on the frame. The following are the most relevant and closest to the present invention.

(a) purely optical systems:

One of the most widely used classic systems is called a pupilometer, as described in FR1506352. The device, comprised of a lens assembly, contains three windows, two windows reproducing the glass frame of the lens that should be pressed against the patient's nose, and a window on the opposite side where the eye of the measuring observer is placed on the focus of a collimating lens. This lens allows the light source contained in the device to be placed at infinity, which corresponds to measuring far vision. The lens can be movable allowing to also measure the individual's interpupillary distance for near vision. The observer moves two moving markers so that they are aligned with the patient's two pupils, thus measuring the

Interpupillary Distance.

This type of system is time consuming, requires the active participation of the technician and is based on a device specifically designed for this purpose.

The present invention uses a different technological principle from this one, it does not require the participation of the technician and the User can calculate his own Interpupillary Distance using a device that is often accessible to him (a tablet, smartphone or laptop).

B)

Optical systems with artifacts on the face or frame:

More recently, a number of commercial systems have been disclosed that are based on an image sequence, such as the system described in WO 2011/042623. Its principle is based on a set of photographs of the face in different poses, where it is necessary to place an artifact with predefined marks on the face or frame. This artifact is essential for obtaining a metric for the measurements to be taken and for obtaining a geometric relationship between the various photographs.

The present invention, unlike this one, does not require any artifact on the patient's face.

User Motion Optical Systems:

The WO 2011/113936 system is also based on a set of photographs, in which the patient makes a predetermined movement, and, unlike the previous ones, does not require any face artifact or frame to measure Interpupillary Distance. This system applies a statistical calculation based on an iterative optimization algorithm for estimating camera distance, interpupillary distance, camera focal length, eyeball radius and pupil size, taking all images into account. of a sequence of photographs taken from the patient's movement. The results regarding the accuracy of the estimation of the multi-variable optimization problem involved are not known. In addition to the computational weight required, this system requires the patient to perform a pre-set motion and is dependent on automatic detection of the circle around the pupil, which may be difficult as it requires sophisticated detection methods and a large camera. resolution.

The present invention, unlike this system, does not require any patient movement or camera use.

d) There are other systems that locate the pupils three-dimensionally, using stereo vision systems (multi-camera or one-camera moving) or using active methods of detecting the patient from the system, such as the patented system. W02009 / 007731, or the case of structured light scanning systems such as CN101739717, or the case of the reflective surface and camera system subject to National Invention Patent No. 106430. These systems are quite metric accurate, but are devices with specific and calibrated hardware. They all use a stereoscopic system to calculate three-dimensional positions of the user's eyes.

The present invention uses a different technological principle from these systems as it does not dispense with the use of cameras and does not use triangulation processes to calculate the user's eye position.

In recent years, the online market for selling lenses and frames has been growing significantly. This has led to the need to obtain the Interpupillary User Distance remotely, ie without going to a specialized technician. Otherwise, if the User had to resort to a specialized technician, this would eliminate the main advantage of selling online which is to avoid the physical travel of the User. Thus, in order to obtain Interpupillary Distance, some online retailers ask their customers to apply rudimentary measurement techniques, based on objects placed on their face or based on direct ruler measurement. These techniques are based on approximate or empirical geometric principles and therefore produce approximate results, the measurement errors of which may exceed 3 millimeters and are generally discouraged by optometrists.

The first of these simpler systems corresponds to direct ruler measurement. Multiple measurement errors occur due to the distance the ruler has from the measured object. Errors are significant and difficult to quantify. When measuring in front of the mirror, the error will be even higher.

There are some stricter commercial systems that use exactly a camera and artifact with patient markings or measurements. Examples of such as credit cards or known face systems use artifacts with known sights placed on the patient's forehead or frames - such as the system proposed in US 2011/0267578. These systems assume that the artifact is co-planar with the pupil centers, which never happens.

Unlike the previous systems, the present invention does not require artifacts or rulers on the patient's face and the results obtained are not an approximation of reality.

General Description of the Invention

The system described in the present invention allows a User to measure Interpupillary Distance using a conventional device with the following requirements: having processing capability, having a screen with some reflective capability (200) and having a non-specular or non-specular zone in the center of the screen. low level of specularity (202). Devices of this type can be found on laptops, tablets, smartphones, PDAs and mobile phones. Said low specularity zone can be achieved at the expense of an object

mate physicist reducing the or drawing on the screen specularity of this an zone. zone white bright For the sake of clarity, zone not speculate or with low level of specularity as an zone in that the coefficient of specularity gives surface is very

reduced or null and its ability to function as a mirror is negligible. By contrast, specular zone or high specularity zone is defined as a zone in which the surface specularity coefficient is sufficient to function as a mirror.

The present invention, following the possible configuration of Figures 2 and 3, utilizes the screen surface specular property of device 200 which, acting as a mirror, allows the User to see his own reflection 201 throughout the screen, except in the non-specular zone (202). The User positions such that the left eye reflex (306) is on the left side of said non-specular zone and the right eye reflex (307) on the right side of said non-specular zone. By alternately looking at the left eye reflex (306) and the right eye reflex (307), the User aligns the slider (203) over the center of the left pupil reflex and the slider (204) over the center of the left reflex. right pupil. The interpupillary distance is given directly by the distance between the cursors 203 and 204.

The present invention has the following advantages or differences over existing systems:

a) The system can only be made by itself

User, dispensing the use of specialized material for the purpose or of a third person, as in the referred inventions FR1506352, WO 2011/042623, WO2009 / 007731;

b) The system does not require the use of rulers or any artifact on the face or frames, as in the inventions referred to WO 2011/042623, US 2011/0267578;

c) The system does not require the use of a camera and does not use any triangulation process between different points of view, as in the above-mentioned invention No. 106430.

d) The system is non-intrusive and easy to deploy on a high-consumption device, available to most people, such as laptops, tablets or smartphones.

e) 0 system is theoretically exactly when contrary in many systems that use methods empirical and feature results approximate, as US

2011/0267578.

Detailed Description of the Invention

The present invention is hereinafter described in detail, without limitation and by way of example, by way of a preferred embodiment shown in the accompanying drawing, in which Figures 2 and 3 are a simplified schematic representation of the system according to the invention. invention.

Figure 1 represents the general steps of the method.

Figure 2 represents the reflection of the user's face on the device screen.

Figure 3 represents a schematic perspective view.

The present invention corresponds to a measuring system, object of claim 1, comprising a processor-controlled device incorporating a high reflectivity display (200) except in a central zone of little or no specularity (202).

Most screens of conventional devices are reflective enough to be able to act as a mirror and see the reflection (201) of the user's face, particularly when the screen background is black and the face is adequately illuminated. . On the other hand, the non-specular zone in the center of the image makes it impossible to cross-view both eyes, ie the right eye (309) cannot see the reflection of the left eye (306), as shown in radius (305), just as the left eye cannot see the reflection of the right eye. Thus, when you see the reflection of your eyes, they will not be the perceived reflection (consisting of the stereoscopic fusion of the two views performed at the level of the visual cortex) but rather the actual reflection of the eyes. Thus, when the User sees the reflection (306), it truly corresponds to the reflection of the left eye (308). Similarly, when the User sees the reflection (307), it truly corresponds to the reflection of the right eye (309). In addition, the viewing rays 303 and 304 are parallel, so the interpupillary distance to be calculated will be equal to that measured if the eyes were looking at infinity.

Thus, one of the fundamental principles of the present invention is that there is a non-specular zone in the center of the screen allowing to occlude the cross vision of the user's eyes and thus inhibit the stereoscopic function of the user. This zone will have a typical width of 45mm which corresponds to the minimum interpupillary distance of an adult user, however it can be set to other widths. This non-specular zone can be constructed of a matt material glued or superimposed on the screen, but also of a high gloss material (a luminous surface) allowing not only to substantially reduce surface specularity but also to illuminate the person's face. In its preferred form, it is proposed to use the screen itself for the purpose of Claim 1 and 2. The high brightness of a white image drawn on the screen dramatically reduces the reflective ability of the screen, producing an inhibitory effect on the stereoscopic ability of the User. .

Interpupillary Distance can be determined by a computer-implemented method which will be explained below by presenting a method formed by a set of steps, shown in Figure 1 and object of claim 1:

(101) The first step is a positioning step in which the User stands in front of the system like a mirror, placing the left eye reflex (306) to the left of the zone (202) and the right eye reflex ( 307) to the right of zone (202).

(102) The second step is an alignment step of the left and right cursors or Markers (203) (204). Keeping the face still with respect to the device, the User looks at the left eye reflex and moves the Left Marker (203) to the center of the respective pupil reflex. The User then looks at the right eye reflex and moves the Right Marker (204) to the center of the respective pupil reflex.

(103) The third step is an interpupillary distance calculation step and is performed on the processor based on the location of the cursors 203 and 204 on the screen. The interpupillary distance is equal to the distance between said cursors, since the viewing rays (304) and (305) are parallel. Knowing the physical dimension of the screen pixel, we can convert the distance between the cursors in pixels to the Euclidean distance in millimeters by multiplying the distance in pixels with the pixel dimension in millimeters.

Claim 2 discloses the system adapted to perform the method of Claim 1, comprising a processor, memory, a keyboard, mouse or touch screen data entry system, and a flat screen displaying the images, covered by a reflective surface with a high level of specularity. Said data entry system is for moving the left and right Markers referred to in the method of Claim No. 1.

Claim 3 presents a possible embodiment for the low specular surface, which is to place a white zone on the screen that can be made at the expense of a white image drawn on the screen by the computer system itself. A white zone is a brighter zone, reducing the specular properties of the surface in that zone.

The use of the system, object of claim 4, can be found in any of the following applications:

(a) estimation of ophthalmic measurements for cutting and construction of monofocal or progressive ophthalmic lenses, whether in physical stores or online retail;

b) Three-dimensional survey of the frame to build custom frames, either in physical stores or online retail;

c) Collection of ophthalmic measures for choosing lenses and frames from a database or for aesthetic or medical advice of lenses or frames that best fit the User;

d) Collection of ophthalmic data for multimedia applications in physical store or online for viewing lenses and virtual frames on the user's face in the form of augmented reality;

e) The system is not limited to optometric applications only, but may extend to aesthetic, cosmetic and reconstructive medicine applications such as eyebrow, lip, hair, make-up, tattoos or for pre and postoperative analysis in aesthetic medicine. and reconstructive.

Lisbon, 5th August 2015

Claims (4)

1. Method for calculating Interpupillary Distance, defined as the distance between the center of a User's pupils (308) and (309), using a high specularity screen (201) and a low specularity zone (202) covering the central part of said screen, characterized by comprising the following steps: a) a positioning step (101) of the User's reflex such that the left eye reflex is to the left of said low specularity zone (202) and the right eye reflex is to the right of said zone; b) an alignment step (102) performed by the User, who, with his head still and assisting himself with his reflection on the screen (201), moves a Left Marker (203) to the center of the left pupil reflex and moves a Right Marker (204) to the center of the right pupil reflex; c) a step of calculating the Interpupillary Distance (103) which is simultaneous to the previous step and calculating the distance between the centers of said pupils from the distance between the positions of said left and right Markers, calculated on said Screen based on in metric knowledge of each screen pixel by multiplying the number of pixels between cursors by the pixel size in millimeters. Interpupillary Distance Measurement System, comprising a processor adapted to perform the method of claim 1, which controls all other features, by a flat screen (200) displaying images, covered by a high level reflective surface by a keyboard, mouse or touch screen surface data entry system that moves two Left and Right Markers on said Screen, characterized by a low specularity zone (202) covering the central part of the said screen, the configuration of which allows the User to see the left eye reflex (303) to the left of said zone (202) and the right eye reflex (304) to the right of said zone, said zone (202) making it impossible to left eye see right eye reflex and right eye see left eye reflex (305). System according to the preceding Claim, characterized in that said low specularity zone is a high brightness white zone, the preferred configuration of which is a white image drawn on the screen. 4. Use of the system and method of measurement and estimation of optometric measurements of the preceding claims characterized in that it is intended for any of the following applications: a) cutting and construction of monofocal or progressive ophthalmic lenses; b) construction of bespoke frames; c) selection of lenses and frames that best fit the User; d) multimedia applications for viewing lenses and virtual frames on the user's face in the form of augmented reality. Lisbon, September 14, 2015