FR2966038A1 - Method for measuring pupillary deviation of person to determine location of optical center of glass with respect to frame of spectacles during mounting of glass by e.g. optician, involves calculating real value of pupillary deviation - Google Patents

Abstract

The method involves measuring a distance (E') representing pupillary deviation (E) of a person in a terminal (16) e.g. computer or portable telephone, where the distance is expressed in the form of a number of pixels. The number of pixels is transmitted to a remote server from the terminal via a communication network i.e. Internet. A real value of the pupillary deviation is calculated from the number of pixels. A distance between a digital camera (11) of the terminal, a focal distance and the person is measured by a direct measurement unit e.g. laser or infra-red pointer. An independent claim is also included for a device for measuring pupillary deviation of a person, comprising a remote server.

Description

METHOD FOR MEASURING THE PUPILLARY GAP OF A PERSON AND ASSOCIATED DEVICE The invention relates to a method for determining the pupillary distance of a person, as well as an associated device. By pupillary distance, we mean the distance separating the two pupils of a person, from center to center. This value is unique to each person. When mounting a spectacle lens, this value of the pupillary distance is used to determine the location of the optical center of the lens relative to the spectacle frame. The optical center of the glass is a value necessary to cut the glass, with the shape of the frame. There are currently several categories of methods for measuring the pupillary distance of a person. A first method consists in measuring the pupillary distance directly on the person concerned, using a measuring means. This measuring means may be a specific eyeglass frame, a binocular device, such as a pupillometer or a graduated ruler. Measuring means making a direct measurement of the pupillary distance are for example described in documents EP 1 763 695 or FR 2 921 817. These measurements are generally carried out by an optician, who then transmits them to the manufacturer of spectacle lenses. . The measurement thus made is up-to-date and accurate, but it requires traveling to an optician. As a variant of this first method, the person concerned may be required to carry out the measurement himself, for example in front of a mirror using a graduated ruler, and then send this measurement himself to a manufacturer of lenses. glasses. There are indeed today several websites that offer this service.

This avoids having to move to the optician. However, this requires measuring the pupillary gap itself, which can lead to measurement errors. A second method is to perform a measurement away from the pupillary distance of the person concerned. For this, the person concerned can take a photograph, which also includes a marking whose size is well known. This marking may be a coin, or any means provided by the spectacle lens manufacturer itself. The photograph is then sent to the spectacle lens manufacturer, who then measures the pupillary distance by a simple rule of three, knowing the exact size of the mark. For example, document EP 1 450 201 may be cited and note that, again, many websites offer this service. In this way, the person is not obliged to travel to an optician and does not have to carry out the measurement of the pupillary gap, which makes it possible to limit the errors of measured. Nevertheless, the manufacturer can still make a measurement error on the photograph sent to him, the person concerned not being at his side. Finally, a third method consists in making no measurement of the pupil distance, either directly on the person concerned or at a distance from it. It is then based on measurements made in the past, which can for example be present in the medical file of this person. The person can then transmit this data to the spectacle lens manufacturer, who is based on the data provided to him. The data transmitted to the spectacle lens manufacturer may, however, be dated and no longer accurate.

Moreover, in most cases, these data are not available. This process can therefore only be implemented for a limited number of people. An object of the invention is to propose a method with which a manufacturer of spectacle lenses or any interested person can have access to a measure at the same time up-to-date and precise of the pupillary distance of the person whose knowledge is sought. pupillary distance, without any individual having to directly measure this pupillary distance. By individual, we mean in particular the manufacturer of spectacles glasses, the optician or the person whose pupil gap is sought to be known. Another objective is to propose a device for measuring the pupillary distance of this person, capable of implementing this method. To achieve at least one of these objectives, the invention provides a method for measuring the pupil distance E of a person, characterized in that it comprises the following steps: (a) measuring at least one distance E ', E'1, E'2, E'11, E'21 representative of the pupillary distance in a terminal, which is situated on the place of presence of the person, this distance being expressed in the form of a number of pixels; (b) transmitting this number of pixels to a remote server of the terminal; then (c) the actual value of the pupillary distance E is calculated from this number of pixels. The method may also have at least one of the following features, taken alone or in combination: step (a) further comprises a step of measuring the distance D between a digital camera of the terminal, focal length f, and the person; Distance D is measured by the person himself; the distance D is measured by the camera, which comprises a variable focal length f; the distance D is measured by means for directly measuring this distance, for example a laser or infrared pointer, preferably located in the plane of the camera; step (c) consists in calculating the real value of the pupillary distance E, by s the relation E = E '. [(D / f) -1], taking into account the number of pixels representing E', the actual size of a pixel being known; step (a) further comprises a step in which the size T'1, T'2, T'3 is measured in the form of a number of pixels of a known real size element TI, T2 , T3, located in the plane of the person's face; it is a method in which: the known real-size element is an object of real known size TI, for example a coin or a sheet of paper in A4 format; or 15 - the known real-size element is a part of the face or body of the person whose actual size T2 is statistically determined; or - the known real-size element is an object whose actual size T3 is measured by the person himself. Step (c) is to calculate the actual value of the pupillary distance E by the relation E = E '(T / T') where T is one of the known actual sizes TI, T2, T3 of the known real-size element and T 'is one of the measured sizes in pixels T'1, T'2, T'3 of this same element; step (a) comprises the following substeps: (a1) moving a light marker horizontally on a screen of the terminal; (a2) identifying a first position PI for which the axis of gaze of the person on the light marker is perpendicular to the plane of the screen; 30 (a3) identifying a second position P2 for which the axis of gaze of the person on the light marker is perpendicular to the plane of the screen; (a4) measuring the distance E 'representative of the pupillary distance, by counting the number of pixels separating the two positions P1 and P2. step (c) consists in calculating the real value of the pupillary distance E by the relation E = E ', taking into account the number of pixels representing E', the real size of a pixel being known; step (a) comprises the following sub-steps: (garl) a first distance E'l representative of the perceived pupillary distance E1 is measured by a digital camera of focal length fi of the terminal, this distance E'1 being expressed in the form of a number of pixels; (a12) the focal length of the camera (11) is changed to the value f2; (a) measuring a second distance E'2 representative of the perceived pupil distance E2 by the camera (11) of focal length f2, this distance E'2 being expressed in the form of a number of pixels. step (c) consists in calculating the real value of the pupillary distance E by the relation E = (1-fl / f 2) / [(fl / f 2) / E'l-1 / E'2], in taking into account the number of pixels representing the distances E'l and E'2, the actual size of a pixel being known; step (a) comprises the following substeps: (a21) two luminous points P3, P4 are displayed on a screen of the terminal, these two points being separated by a distance d expressed in the form of a number of pixels ; (a22) measuring a first distance E'Il, corresponding to the distance separating two points of a pattern as perceived by a digital camera of the terminal located in the plane of the screen, when the pattern is in a position, said initial position, of contact with the face of the person, this distance E'Il being expressed in the form of a number of pixels; (a23) the target is moved towards the screen until the target is positioned at the intersection of the two axes defined by one (OG, OD) of the person's eyes and a luminous point (P3 , P4) displayed on the screen, this position being called the final position of the target; and (a24) measuring a second distance E'21, corresponding to the distance separating the two points of the test pattern in its final position, as perceived by the camera, this distance E'21 being expressed in the form of a number of pixels. step (c) consists in calculating the real value of the pupillary distance E by the relation E = da / (1-a) with a = E'11 / E'21 such that 0 <a <1, taking count the number of pixels representing the distance d, the actual size of a pixel being known. To achieve at least one of these objectives, the invention also proposes a device for measuring the pupillary distance of a person comprising a terminal, a server remote from the terminal and a communication network connecting the terminal and the remote server. , characterized in that it comprises: means for measuring at least a distance E 'representative of the pupillary distance at the place of presence of the person, these means comprising a digital camera belonging to the terminal and making it possible to express this distance E 'in the form of a number of pixels and an eye detection software of the person belonging to the remote server; calculation means belonging to the remote server, capable of calculating the real value of the pupillary distance E from this number of pixels. Moreover, the communication network may be the Internet network. The invention will be better understood and other objects, advantages and characteristics thereof will appear more clearly on reading the description which follows and which is made with reference to the appended drawings, in which: FIG. device for measuring the pupillary distance of a person; FIG. 2 is a diagram showing the part of the device of FIG. 1 situated close to the person whose pupillary distance is to be known, for the implementation of a first method of measuring this pupillary distance; FIG. 3 is an optical diagram of the device represented in FIG. 2; FIG. 4 is a diagram showing the part of the device of FIG. 1 located near the person whose pupillary distance is to be known, for the implementation of a second method of measuring this pupillary distance; FIG. 5 is a diagram showing the part of the device of FIG. 1 located near the person whose pupillary distance is to be known, for the implementation of a third method of measuring this pupillary distance; FIG. 6 comprises FIGS. 6 (a) and 6 (b), which respectively represent a first optical scheme for which the camera has a first focal length of the device and a second optical scheme for which the camera has a second focal length of device for covering a fourth method of measuring the pupillary distance; FIG. 7 is a diagram showing the part of the device of FIG. 1 located near the person whose pupillary distance is to be known, for the implementation of a fifth method of measuring this pupillary distance. A device 1 for measuring the pupillary distance E of a person according to the invention, as represented in FIG. 1, comprises a terminal 16 connected to a server 12, remote from the terminal 16, the terminal 16 and the server 12 being connected by a communication network 15, for example the Internet network. The device 1 comprises in particular a means 10 for measuring at least a distance E 'representative of the pupillary distance E at the place of presence of the person. This means 10 more precisely comprises a digital camera 11, belonging to the terminal 16, making it possible to express the distance E 'in the form of a number of pixels and a software 13 for detecting the eyes of the person belonging to the remote server. 12. The software 13 is facial recognition software, used to detect the person's eyes. There are many software programs on the market that can be used in the context of the invention. Examples include: FaceSDK from Luxand available on www.luxand.com, OpenCV (free software), FaceAPl available from www.seeingmachines.com, BiolD® available from www.bioid .com, or face recognition software offered by the site 15 www.pittpatt.com. The device 1 also comprises a calculation means 14, belonging to the remote server 12, capable of calculating the real value of the pupillary distance E, from this number of pixels. The terminal 16 may be a computer comprising a digital camera 11. In a variant, the terminal 16 may be a mobile phone incorporating a digital camera, this phone being capable of being connected to the remote server 12 by a communication network such as the Internet network or another type of communication network. The device 1 may further include a direct measurement means (not shown) of the distance between the camera 11 and the person. This means may for example be a laser pointer or infrared installed in the plane of the camera. Furthermore, the camera 11 may have a variable focal length. The method for measuring the pupillary distance E then comprises the following steps: (a) measuring at least a distance E ', E'1, E'2, E'11, E'21 representative of the pupillary distance in the terminal 16, which is located on the place of presence of the person, this distance being expressed in the form of a number of pixels; (b) this number of pixels is transmitted to the server 12 remote from the terminal 16, and (c) the real value of the pupillary distance E is calculated from this number of pixels. The implementation of this method can be carried out according to different variants, hereinafter called methods 1 to 5. In all cases, step (a) uses the software 13 to detect the person's eyes.

Method 1 This first method is presented in support of FIGS. 2 and 3. According to this method, step (a) measures at least a distance E 'representative of the pupillary distance within the terminal 16, 20 expressed as a number of pixels. This step (a) further comprises a step in which the distance D between a camera 11 of the terminal 16, of focal length f, and the person is measured within the terminal 16. The distance D can be measured by the person himself. As a variant, the distance D can be measured by the camera 11, which comprises a variable focal distance f. According to another variant, the distance D is measured by a direct measurement means (not shown) of this distance, for example a laser or infrared pointer located in the plane of the camera. At the end of step (a), the value in pixels of the distance E 'has thus been determined, the distance D, the focal length f being known from the device 1. In fact, the focal length the camera is known by the terminal 16 by means of the driver ("driver" in English) for the installation of this camera. In step (b), this number of pixels, as well as the distance D, are then transmitted to the remote server 12, via the communication network 15. In step (c), the calculation means 14 of the remote server 12 then calculates the real value of the pupillary distance E by the relation E = E '. [(D / f) - 1], taking into account the number of pixels representing E', the actual size of the a pixel being known from the device 1 because it is intrinsic to the device 1 o used. The lens manufacturer thus automatically obtains the pupillary distance from the person without having to carry out a measurement himself.

Method 2 This second method is described in support of FIG. 4. According to this method, during step (a) at least one distance E 'representative of the pupillary distance within the terminal 16 is measured. distance E 'being expressed as a number of pixels.

This step (a) further comprises a step in which the size T'1, T'2, T'3 is measured in the terminal 16 in the form of a number of pixels, a element 17 of known real size TI, T2, T3, located in the plane of the face of the person. The element 17 may be a known actual size object TI, for example a coin, an A4 size paper sheet or the like. A coin is shown in Figure 3. Alternatively, the element 17 may be a part of the face or body of the person whose actual size is statistically determined. It may for example be the size T2 of the iris. In addition, the person may be asked to specify one or more additional parameters relating to him, such as sex, age or size. According to another variant, the known real size element is an object whose actual size T3 is measured by the person himself. At the end of step (a), the value in pixels of the distance E ', the value in pixels T' of the known real-size element 17 has been determined. Note that T 'represents one of the sizes measured in pixels T'1, T'2, T'3 of the element 17 and, T represents one of the known actual sizes TI, T2, T3 of the same element 17. At the step (b), these numbers of pixels are then transmitted to the remote server 12, via the communication network 15. In step (c), the calculation means 14 of the remote server 12 then calculates the real value pupillary distance E by the relation E = E '. (T / T'). For this, one can take into account the number of pixels representing E 'and T' respectively, the actual size of a pixel being known. However, it should be noted that the actual value of the pupillary distance E can be calculated by the preceding relation without involving the actual size of a pixel.

Method 3

This third method is described in support of FIG. 5. According to this method, the distance E 'representative of the pupil distance in the terminal 16 is measured, this distance E' expressed in the form of a number of pixels. according to the following sub-steps (a,) to (a4): A light marker 18 is moved horizontally on a screen 19 of the terminal 16, which is arranged in front of the person. In FIG. 5, the screen 19 is that of a computer 16. The characteristics of the light marker 18 (direction of movement, speed, etc.) are managed by the remote server 12. A first identification is then identified (a2). PI position for which the axis of the gaze of the person on the light marker 18 is perpendicular to the plane of the screen 19. This identification is performed by the means 10, namely by the camera 11 which is connected to the software 13 for detecting the person's eyes. For this purpose, the camera 11 is in the plane of the screen 19 of the computer 16. The means 10 of the device 1 considers that the axis of the gaze of the person is perpendicular to the screen 19 when the size of the the iris of the person he perceives is at his maximum. In the same way, we identify (a3) a second position P2 for which the axis of gaze of the person on the light marker 18 is also perpendicular to the plane of the screen 19 of the terminal 16. The position P2 is distinct from the PI position. Finally, measure (a4) the distance E 'representative of the pupillary distance, by counting the number of pixels separating the two positions PI and P2. At the end of step (a), the value in pixels of the distance E 'was thus determined. In step (b), this number of pixels is then transmitted to the remote server 12, via the communication network 15. In step (c), the calculation means 14 of the remote server 12 then calculates the number of pixels. actual value of the pupillary distance E by the relation E = E ', taking into account the number of pixels representing E', the real size of a pixel being known from the device 1 because it is intrinsic to the device used.

Method 4

This fourth method is described in support of Figure 6, which includes Figures 6 (a) and 6 (b). According to this method, step (a) comprises the following sub-steps (a ') to (a13): A first distance E' 1 representative of the pupil distance perceived E1 by the digital camera 11 is measured (garl). , of focal length fi, belonging to the terminal 16, this distance E'l being expressed in the form of a number of pixels.

Then, we modify (a12) the focal distance of the camera 11 to the value f2. The camera 11 thus has a variable focal length. Measuring (a13) then a second distance E'2 representative of the perceived pupil distance E2 by the camera 11, of focal length f2, this distance E'2 being expressed in the form of a number of pixels. At the end of step (a), the value in pixels of the distances E '1 and E' 2 has been determined, the focal lengths f 1 and f 2 being known from the device 1.

In step (b), these numbers of pixels are then transmitted to the remote server 12, via the communication network 15. In step (c), the calculation means 14 of the remote server 12 then calculates the actual value of the pupillary distance E by the relation E _ (1-fi / f2) / [(fi / f2) / E'l-1 / E'2], taking into account the number of pixels representing E ' 1 and E'2, the actual size of a pixel being known from the device 1 because it is intrinsic to the device used. It is therefore understood that the distances E'1 and E'2 are representative of the pupillary distance E.

Method 5

Here is described a fifth method for measuring the pupil distance of a person with the device described above in support of Figure 1.

This fifth method is described in support of FIG. 7. In this method, step (a) comprises the following sub-steps (a21) to (a24). Two luminous points P3, P4 are displayed (a21) on the screen 19 of the terminal 16, these two points being separated by a distance d expressed in the form of a number of pixels.

The actual distance d is thus known from the device 1, by the knowledge of the number of pixels between the points P3 and P4, the actual size of a pixel being intrinsic to the device 1. The person whose pupil gap is sought to be known. s must be placed in front of the screen 19 and the camera 11, the camera 11 being situated in the plane of the screen 19. This person is then brought to position a sight 20 between his eyes, as close as possible to these last. The target 20 can thus be brought into contact with the person's face and extend vertically between the two eyes. This position is called the initial position of the target 20. This target 20 may be a finger, a pencil or any other equivalent means. Preferably, this test pattern is fine, for example the size of a pencil lead, in order to obtain an accurate measurement. In this initial position, we measure (a22) in the terminal 16, the distance E'Il separating two points (not shown) of the target 20, this distance being expressed in the form of a number of pixels. These two points may correspond to two marks made on the target 20. In a variant, these two points may correspond to the two ends of the target 20, the distance E'I1 then coinciding with the height of this target 20. When the target 20 is a finger of the person, for example his index finger, these two points may correspond to two well-identified points of that finger. The distance E 'It is that which is perceived by the camera 11 of the terminal 16. For this purpose, the software 13 also makes it possible to identify, according to the case considered, the two marks of the pattern 20, the two ends of the pattern 20 or two points of a finger. Then, the person moves (a23) the target 20 towards the screen 19 until the target 20 is positioned at the intersection of the two axes defined by an eye and a light point of the screen 19 (FIG. Left eye OG with right hand P4 of screen 19; right eye OD with left hand point P3 of screen 19). Once this position is reached, the target 20 then hides at the right eye OD the left point P3 of the screen 19 and also hides at the left eye OG the right point P4 of the screen 19. This position is called position In this final position, we measure (a24) in the terminal 16, the distance E'21 separating the two points distant from the target 20 mentioned above, this distance E'21 being also expressed in the form a number of pixels. In step (b), the values in pixels of the distances E'11 and E'21 are then transmitted to the remote server 12. In step (c), the computing means 14 of the remote server 12 then calculate the actual value of the pupil distance E of the person by the relation E = da / (1- a) with a = E'11 / E'21 such that 0 <a <1, taking into account the number of pixels representing the distance d, the real size of a pixel being known from the device 1. From this relation, it is understood that the distances E'11 and E'21 are representative of the pupillary distance E. As represented in FIG. it should be noted that if the distance D is the distance between the camera 11 and the person, the distance aD 25 is the distance between the camera 11 and the target 20 in its final position and, the distance (1-a) .D is the distance between the sight 20 in its final position and the person. For example, if the size perceived by the device 1 of the pattern 20 increases in a ratio two between the initial (E'11) and final (E'21) positions of the target 20, then it can be determined that the target 20 is located, in its final position, halfway between the camera 11 and the person (a = 1/2).

The invention therefore makes it possible to perform a precise, automatic and remote real-time measurement of the pupillary distance of a person, by means of the device 1 described above. This facilitates the steps of a person looking to change glasses, because it no longer needs to travel to an optician, many people with a terminal such as a computer or a mobile phone with a digital camera, this terminal being able to be connected to the Internet network. This also limits the risk of measurement errors in the pupillary distance, since no individual has to directly measure this pupillary distance.

Claims (17)

REVENDICATIONS1. A method for measuring pupil distance E of a person, characterized in that it comprises the following steps: (a) measuring at least a distance E ', E'1, E'2, E'11, E Representative of the pupillary distance in a terminal (16), which is located on the place of presence of the person, this distance being expressed in the form of a number of pixels; (b) transmitting this number of pixels to a server (12) remote from the terminal (16); then (c) the actual value of the pupillary distance E is calculated from this number of pixels. 15 The method according to claim 1, wherein step (a) further comprises a step of measuring the distance D between a digital camera (11) of the terminal (16), of focal length f, and the nobody. 20 3. Method according to the preceding claim, wherein the distance D is measured by the person himself. The method of claim 2, wherein the distance D is measured by the camera (11), which includes a variable focal length. 5. The method according to claim 2, wherein the distance D is measured by direct measuring means of this distance, for example a laser or infrared pointer, preferably located in the plane of the camera (11). 6. Method according to one of claims 2 to 5, wherein step (c) consists in calculating the real value of the pupillary distance E, by the relation E = E '. [(D / f) - 1 ], taking into account the number of pixels representing E ', the actual size of a pixel being known. The method according to claim 1, wherein step (a) further comprises a step in which the size TI, T'2, T'3 is measured as a number of pixels of one element (17) of known real size TI, T2, T3, located in the plane of the person's face. 8. Method according to the preceding claim, wherein: the known real-size element (17) is an object of known real size TI, for example a coin or a sheet of A4 paper; or the known real-size element (17) is a part of the face or body of the person whose actual size T2 is statistically determined; or the known real-size element (17) is an object whose actual size T3 is measured by the person himself. 9. Method according to one of claims 7 or 8, wherein step (c) consists of calculating the real value of the pupillary distance E, by the relation E = E '. (T / T') where T is one of the known actual sizes TI, T2, T3 of the known real-size element (17) and T 'is one of the measured sizes in pixels T'1, T'2, T'3 of this same element (17). The method of claim 1, wherein step (a) comprises the following substeps: (a1) moving a light marker (18) horizontally on a screen (19) of the terminal (16); (a2) identifying a first position P1 for which the axis of gaze of the person on the light marker (18) is perpendicular to the plane of the screen (19); (a3) identifying a second position P2 for which the axis of gaze of the person on the light marker (18) is perpendicular to the plane of the screen (19); (a4) measuring the distance E 'representative of the pupillary distance, by counting the number of pixels separating the two positions P1 and P2. 11. Method according to the preceding claim, wherein step (c) consists of calculating the real value of the pupillary distance E by the relation E = E ', taking into account the number of pixels representing E', the size real of a pixel being known. The method according to claim 1, wherein step (a) comprises the following sub-steps: (a11) measuring a first distance E'1 representative of the perceived pupil distance E1 by a digital camera (11) of focal length f1 of the terminal (16), this distance E'1 being expressed in the form of a number of pixels; (a12) the focal length of the camera (11) is changed to the value f2; then (a13) measuring a second distance E'2 representative of the perceived pupil distance E2 by the camera (11) of focal length f2, this distance E'2 being expressed in the form of a number of pixels. 13. Method according to the preceding claim, wherein step (c) consists of calculating the real value of the pupillary distance E by the relation E = (1-f1 / f2) / [(f1 / f2) / E ' 1 - 1 / E'2], taking into account the number of pixels representing the distances E'1 and E'2, the actual size of a pixel being known. The method according to claim 1, wherein step (a) comprises the following sub-steps: (a21) two luminous points P3, P4 are displayed on a screen (19) of the terminal (16), these two points being separated by a distance d expressed as a number of pixels; (a) measuring a first distance E'11, corresponding to the distance separating two points of a pattern (20) as perceived by a digital camera (11) of the terminal (16) located in the plane of the screen (19), when the target (20) is in a position, called initial position Zo, of contact with the face of the person, this distance E'11 being expressed in the form of a number of pixels; (a23) the pattern (20) is moved towards the screen (19) until the pattern (20) is positioned at the intersection of the two axes defined by the one (OG, OD) of the eyes of the person and a light point (P3, P4) displayed on the screen (19), this position being called the final position of the target (20); and (a24) measuring a second distance E'21, corresponding to the distance separating the two points of the pattern (20) in its final position, as perceived by the camera (11), this distance E'21 20 being expressed as a number of pixels. 15. Method according to the preceding claim, wherein step (c) consists of calculating the real value of the pupillary distance E by the relation E = da / (1-a) with a = E'11 / E'21. such that 0 <a <1, taking into account the number of pixels representing the distance d, the actual size of a pixel being known. 16. Device (1) for measuring the pupillary distance of a person comprising a terminal (16), a server (12) remote from the terminal (16) and a communication network (15) connecting the terminal (16) and the remote server (12), characterized in that it comprises: means (11, 13) for measuring at least a distance E 'representative of the pupillary distance on the place of presence of the person, these means (11 , 13) comprising a digital camera (11) belonging to the terminal (16) and making it possible to express this distance E 'in the form of a number of pixels and a software (13) for detecting the eyes of the person belonging to the server remote (12); calculation means (14) belonging to the remote server (12) capable of calculating the real value of the pupillary distance E from this number of pixels. 17. Device according to the preceding claim, wherein the communication network (15) is the Internet network.