FR2971929A1 - Measuring device for use in optical store to measure e.g. lens centering parameters required to fabricate spectacles, has measuring element comprising measuring unit for measuring positioning of optical axes along height direction - Google Patents

Abstract

The device has a measuring element (1) placed on a face of an individual and having shape of a beam maintained in front of eyebrows of the individual by two branches (11, 12) perpendicular to the element. The element comprises a measuring unit for measuring precise positioning of optical axes of a capturing device along width direction. The element comprises a checking unit for checking alignment with respect to a horizontal line of the element during capturing, and another measuring unit for measuring positioning of the optical axes along height direction corresponding to pupillary height.

Description

Method and device for measuring the parameters necessary for the manufacture of spectacles adapted to the morphology of a given individual.

The invention relates to a method for facilitating and securing the taking of measurements relating to the morphological characteristics of a given individual. It applies to equipment specifically designed and made to carry out this measurement as to the method itself.

It is known that the realization of glasses perfectly adapted to the morphology of a given individual requires knowledge of the characteristic parameters of the face, parameters which differ substantially from one individual to another, and which can be grouped into two categories. On the one hand, the parameters necessary for centering the lenses in the frame and, on the other hand, the parameters necessary for the fitting of the frame to the spectacle wearer.

For the correct centering of the glasses on the frame, the essential parameters are the pupillary half-distances (between the visual axis and the median of the points of support of the telescope on the sides of the nose) and the pupillary height which will determine the height. mounting (between the visual axis and the bottom of the glass). To determine the visual axis, the optician takes either the geometric center of the pupil (which geometric center moves slightly when the opening changes, depending on the brightness), or the corneal reflection which has the advantage of remaining fixed and to be more easily detectable, but that is displaced about 0.25mm nasal side relative to the pupil center. The pupillary distance is generally between 56mm and 70mm for an adult, it is at its maximum in infinite vision and is reduced to near vision (convergence of the eyes). For progressive lenses, the pupillary distance is measured in infinite vision. An error of 2mm for diopter corrective lenses 2.00 will reduce the field of view by more than 40%, in near vision. The pupillary height (between the center of the pupil or the corneal reflection, and the bottom of the glass) must be measured in primary position, horizontal gaze and relaxed posture.

For the proper adaptation of a frame to the face, we must take into account the dimensions, orientations and shapes of the face and nose, but also the temples and ears. For the facial face and the nose the important parameters are, in particular, 2s -2- the front angles (of the order of 25 ° to 20 °, between the tangents to the sides of the nose and the vertical, in the plan of the mount, in front view), the hunting angles (of the order of 22 ° to 25 °, between the walls of the nose and the vertical median plane of the face, seen from above), the nasal width ( of the order of 10 to 6 mm, in the plane of the mount at the height of the line of the canthus which passes through the commissures of the eyelids) and the nasal height (of the order of 4 to 2 mm, between the intersection of the back of the nose and the plane of the mount, and the line of the canthus), the inclination of the mounting plane (of the order of 10 °, with respect to the vertical, value characterized by the pantoscopic angle), and the distance glass-eye. With regard to the temples, the important parameters are the width of the temples at the level of the face (sphenoidal gap of the order of 120 mm to 110 mm), and at the level of the ears (superauricular difference of the order of 150 mm at 140mm). Also imports their shape: which can be straight, hollow, or curved. The supraauricular groove at the junction of the ear and the skull is characterized by its height relative to the line of the canthus, and by its distance from the mounting plane (of the order of 100mm to 90mm).

Finally, we can also take into account the shape and position of the eyebrows and cheekbones, knowing that this shape and position have more impact on an aesthetic than on a functional level.

In general, in store the only parameters measured are the centering parameters, on the other hand the good adaptation of a frame is simply noted - at best after a slight adjustment of the nose pads or even the curvature of the ends of the branches. Devices dedicated to these measurements are available in optical stores. The devices and methods according to the invention are applicable to remote measurement, in the case of carriers or customers who can not or do not want to go to a store, and preferring to choose and order glasses from their home by via the internet network. It will be seen in the following description that the devices and methods according to the invention allow to assemble with great ease -3- without the direct intervention of an optician, very quickly, and with great precision all the information necessary for the manufacture a pair of glasses perfectly adapted to a given individual. Consequently, these devices and methods lend themselves not only to the trade of personalized glasses by correspondence, with a phase of taking measurements by Internet, but also to the realization of measuring centers and instant manufacture of glasses adapted to the morphology, to the tastes and medical requirements of each individual, which measurement and manufacturing centers can for example be integrated in spaces of small dimensions, for example cabins having approximately the dimensions of the cabins used for the realization pictures of identities and placed in places or shopping malls. This type of implantation in such a small space is only possible thanks to the precision of the devices and methods according to the invention. The measurements obtained by this device are indeed reliable enough to drive ls directly on the one hand the cutting of glasses at the sight of the wearer and their robotic mounting on the frames chosen by the latter, on the other hand the selection and adaptation even the machining of frames perfectly adapted to the wearer's face. One of the applications of the devices and methods according to the invention is thus also to allow the realization of measurement and fabrication cabins, from a collection of mounts and unadjusted glasses contained in the cabin, of custom glasses, the entire process of taking measurements and manufacturing for less than five minutes.

It is known to make these measurements of pupillary gap prior to the making of glasses adapted to a given individual by taking a picture of the face of this individual and taking measurements on the photos obtained. In a manner also known and usual, is placed in the field of the shooting at least a template of known dimensions, so as to have a frame on the picture. The dimensions are then calculated by comparison with those of the template 30 appearing on the same scale in the photo. To make this template it has been proposed to use a ruler or to print a ruler and to ask the wearer to place it. such an object against his forehead and to get caught or to have his picture taken. It has also been proposed that the subject should stand in front of a mirror and note the graduations. Other distance references may be used, such as a coin or a sheet of paper of known format.

Such measurement methods lead to significant inaccuracies, without the possibility to evaluate or correct them, especially if the camera is not placed perfectly in front of the customer, if the customer's face is tilted forwards or backwards or io oriented to the right or left, or if the template which by definition is located at a distance from the eye is not perfectly perpendicular to the axis of view. And when the measurement is made by fixing a template on an existing pair of glasses of the wearer, the measurement is tainted by an additional error related to the deviation of the light rays caused by the optical and curved surfaces of the corrective lenses on the glass distance -ceil.

Thus, we can evaluate these inaccuracies between 5 to 100/0 on half pupillary gaps generally between 28mm and 35mm - much more than the 0.5mm regarded as the maximum acceptable absolute error for a good measure. Regarding the height of the pupils in relation to the bottom of the glasses, the measurement depends on the size of the frame, and also on the manner in which the wearer wears his glasses: this implies on the face of having the frame on the nose . However, a wearer or customer making the choice or the purchase of glasses on the internet or in a dedicated cabin does not materially dispose of the frame he wishes to obtain. One option would be to send the selected frame (s) for testing and to take measurements with these frames - but this option entails significant costs (postal charges, entry & exit of the stock with cleaning and re-fitting of the frames, and increase of the necessary stock ). Then comes the difficulty of the measurement: this measure is very variable depending on the wearing of the head. Indeed, it must be taken with a head port in primary position. If the client 2971929 -s- lowers too much or raises too much head, it will compensate for this inclination by raising or kissing the eyes so that the measurement will be distorted.

Finally, beyond measures for the proper centering of lenses, there is still a significant problem. In a process of distance selling, the customer chooses a priori the frame that he likes, for example according to photo. If it appears, following the previous measurements, that the mount is not well suited to the wearer, no current method can advise the wearer on the choice of another frame better adapted. However, in case of poor adaptation of the frame, it will be returned by the customer, significant logistical costs are expected, and even if it is actually possible to recycle the frame, the glasses will be lost.

In store, the problem of the mount does not arise since the customer has already chosen his mount (equipped with non-corrective lenses), the proper adaptation has been checked, and the frame was eventually adjusted; in addition, the optician can give instructions on the wearing of head and posture. Several solutions have been proposed to solve the specific difficulties involved in taking the measures necessary to manufacture spectacles adapted to the morphology of an individual without it being necessary for the latter to go to a point of sale. In particular, the use of rules or pupillometers which make it possible to take the measurements manually is known. It has also been proposed: FR2620927 filed in the name of Briot in 1987. This text proposes to measure pupillary distance and height as a function of positioning and detection, by image analysis of the relative position of the pupils and the extremities of Frame. This method assumes the perfect perpendicularity of the plane of the face with respect to the optical axis of the means of shooting, without, however, proposing the means of obtaining this perpendicularity. FR2690832 filed in the name of the Essilor Company in 1992. This text recommends to make a picture of the face with glasses and to calculate the interpupillary distance and the height according to the known dimensions of the frame. He also suggests to determine the inclination in the vertical plane of the mount by comparison of the image with the actual shape. -6- FR2690833 filed in the name of Essilor-VideoCentron in 1992. This patent mentions the parallax error due to the distance glass / eye and proposes to use sensors arranged laterally for the measurement of the exact pantoscopic angle FR2719463 & EP6807222A1 filed in the name of Essilor in 1994. This text proposes solutions, including the use of light gradients, for the determination of the exact position of the corneal reflection by signal processing. FR2829842 (filed in the name of Sayag Sean-Philippe / ACEP in 200. This text provides for using a three-dimensional template attached to the frame for measuring with greater accuracy the inclination and / or orientation of the face io FR2860417 filed at Sayag Sean-Philippe / ACEP in 2003. This text proposes ways to measure the glass-eye distance using one or more mirrors placed on the sides of a removable device that can be attached to existing glasses. filed in the name of JPChauveau / Essilor in 2006 proposes the measurement 15 in the space of the horizontal and vertical orientation of the head of the wearer thanks to a reference structure placed on the telescope and the correction of the measurements of the interpupillary distance and A fixed camera must be placed in the visual plane The texts FR2914173 filed in the name of JPChauveau / Essilor in 2007 WO2006106248A1 (Essilor-CRO), FR2915290 (JPChauveau / E ssilor, 2007) WO20070362288 specify and confirm these proposals, in particular as regards the measurements of the pantoscopic angle, including the use of an inclinometer to evaluate the differences in orientation of the face with respect to the ideal orientation. FR2860887 (Thomet / IVS, 2003) proposes to take a series of photos of the wearer who looks at the lens by turning his head from left to right and vice versa and automatically determine the position with the best orientation to measure the Interpupillary distance taking into account that, when the wearer is looking at the objective but his head is turned to one side, the eyeballs compensate by pivoting towards the other side and inversely, when the head initially turned to the right approaches the axis, the interpupillary half distance of the right eye increases while the half distance between pupillary left eye decreases. This text is specified by FR2892529 (Thomet / IVS, 2005) which recommends placing a reference structure on the bezel usually worn by the wearer, the said structure comprising vertical and horizontal horns facilitating measurements of the dimensions taking into account account of the orientation in the space. US7322697B2 (Pentax, 2005) This text recommends the use of a structure of known dimensions placed on the glasses, the measurement of distance between the camera and the wearer, and a mean distance between the glass. and the eyeball making it possible to calculate the interpupillary distance even when the wearer is not facing the objective. These various proposals represent significant improvements in the measurement conditions and provide elements of solution. The fact remains that, necessarily associated with a mount previously chosen and verified that it was well adapted, they are not directly transferable to the distance selling - on the 3 criteria of the precision of the measurement , costs associated with this measure and the guarantee of good adaptation of the chosen frame, as we have explained previously.

The invention proposes to solve the difficulties and shortcomings described above by means of an element not placed on an existing but autonomous pair of glasses. This element makes it possible to provide a dimensional and positional reference, in particular because it is provided with means for detecting, with respect to the axis of view, a possible rotation of the face to the right or to the left as well as to a possible inclination of the vertical or lateral head. This element also makes it possible to simulate the port of the mount chosen so as to ensure that the centering parameters correspond exactly to those which would have been measured with this mount once it is correctly positioned on the face. This element also makes it possible to measure physiological parameters, in particular the angles and dimensions of the nose, so as to make it possible, if necessary, to provide frames that are better adapted to the wearer's face. The processing of the information provided by the slides and methods according to the invention will be operated by computer hardware and software means. The device and method for measuring the morphological characteristics of the face of an individual according to the invention can be used remotely via the internet network, or at the point of sale, in a specially equipped cabin.

The device and the method for measuring the morphological characteristics of the face of an individual according to the invention can be used remotely via the internet network, or at the point of sale, in a specially equipped cabin.

They comprise an element intended to be placed on the face of the individual, a camera placed horizontally approximately in front of the wearer's face at eye level and the software means for analyzing the images obtained.

The invention will be better understood with reference to the drawings below:

FIG. 1 represents a perspective view of the device according to the invention, device intended to be worn, instead of eyeglasses, by the wearer during measuring operations prior to the manufacture of spectacles in accordance with FIG. his choices and adapted to his morphology. FIGURE 2 represents a front view of the device according to the invention. FIG. 3 represents a partial side view of the piece supporting the device according to the invention by pressing on the nose of the subject.

FIG. 1 shows that the element (1) intended to be placed on the face of the individual is in the form of a beam, held approximately in front of the eyebrows of the individual by two branches (11 and 12) perpendicular to said element (1) and can be placed on the ears, and placed on the nose by a support piece (8). This element (1) is symmetrical with respect to its reference axis (4) and it comprises at least: the means for accurately measuring the positioning in width of the optical axes corresponding to the two interpupillary half-gaps the means for measuring possible deviations between the reference axis (4) of the element intended to be placed on the face and the optical axis of the camera (angles of heading and pitch); . the means for verifying the alignment with respect to the horizontal of the element (1) placed on the wearer's face at the time of each shot (roll angle). the means for measuring the height positioning of the optical axes corresponding to the pupillary height, by reproducing the wearing of the chosen frame and in particular the zone of contact with the nose, and of checking that the positioning of this frame will be correct and allow a good adaptation. the means for measuring the parameters necessary for a good adaptation of the frame to the face, if the frame initially chosen was not adapted to the face. the means of verifying that the measurements are taken under normal conditions, that is to say with a head port and a positioning of the measuring device which does not induce distortion of the measurements made.

Advantageously, the means for accurately measuring the two half inter-pupillary gaps will be constituted by calculating the ratio between these distances measured on the image and the known width of the element (1) placed on the wearer's face. corrected according to the difference measured between the reference axis (4) of the element placed on the wearer's face and the optical axis of the camera.

Preferably, the means for measuring possible deviations between the reference axis (4) of the element (1) placed on the face and the optical axis of the camera will be constituted by at least two non-planar reflective surfaces (2 and 3) disposed on the exposed portion of the camera (1) on the wearer's face. In an advantageous embodiment, these non-planar reflective surfaces will be portions of spheres covered with a silver coating. The center of these elements will be marked and it will coincide with the reflection of the flash of the camera in the case where the reference axis (4) of the element (1) will coincide with the optical axis of the camera and if and only if the face is tilted up or down or tilted to the right -10- or to the left. In other words, any position other than the strictly neutral position for shooting will be detected by a slight difference between the center of one or the other of the non-plane reflective elements and the reflection of the flash of the camera. view of these elements. The curvature of the non-planar elements being known and memorized, the measurement of the distances between each center and the point of reflection of the light of the flash on the corresponding non-plane element, will allow, by a simple calculation to deduce and to calculate precisely any possible angular deviation of the wearer's head and / or the attached device at the time of shooting. Thus, the means for verifying the alignment with respect to the horizontal of the element (1) placed on the wearer's face at the time of each shot will also consist of at least two reflecting surfaces (2 and 3). non-planes (which may be the same as above) arranged on the portion exposed to the camera of the element placed on the wearer's face In a complementary manner, for example in case of unavailability of the flash, the means To measure possible deviations between the reference axis (4) of the element (1) intended to be placed on the face and the optical axis of the camera will be constituted by an outgrowth (5) perpendicular to the element intended to be placed on the face, said protrusion being centered on the reference axis (4) of said element (1) and being dimensioned and positioned so that its end is beyond the vertical passing by the end of the nasal appendix of the wearer using the device. The image of this growth on the photo will determine the orientation of the face. Advantageously, for greater accuracy and ease of reading, the protrusion (5) perpendicular to the element (1) intended to be placed on the face will present in top view and from below a triangular or trapezoidal shape. two inclined faces (6 and 7) of this form being visible in front view and having graduations and / or a coating capable of reflecting light. The number of visible graduations and / or the reflection of the image of the flash on one or the other of the faces (6) or (7) will make it possible to measure the possible rotation of the face of the wearer and therefore of the element (1) with respect to the optical axis of the camera. In a variant, this protrusion (5) may have the shape of an elongated cone, which will also make it possible to detect a head port inclined upwards or downwards.

In a complementary manner, the invention comprises the means for determining, according to each category of spectacles that may be chosen by the individual concerned, the positioning in height of the optical axes of the lenses to be used with respect to at least one point. reference of the definitive frames. These means consist of a support piece (8) connected to the element (1) intended to be placed on the face, the said support piece (8) having an opening (9) of known shape in such a way that it allows to simulate and evaluate what will be the precise positioning of the chosen frame belonging to a given category, and thus to guarantee at the same time a good measurement of the lens centering parameters - Io in particular the height , and a good adaptation of the mount. In a preferred embodiment, the support piece (8) rigidly but removably attaches to the element (1) intended to be placed on the face.

Advantageously, the invention also comprises the means of determining the necessary parameters for a good adaptation of the frame, and its use will make it possible to propose other frames, if the frame initially chosen was not suitable. Thus we can provide different support pieces (8), in size and shape, which can be used according to the categories of frame so as to find the one that best suits the client's face. Preferably, this support member (8) may consist of two sliding parts (19 and 20) on the element 1 - which we will call slides, may deviate or approach according to the nasal width. This setting can be automated by equipping it with a spring or a return elastic. On each of these sliders the parts (21 and 22) in contact with the nose in the plane of the frame - which we will call platelets - 25 may be both separable so as to fit perfectly to the front angles of the nose of the nose. carrier, and adjustable so as to adapt perfectly to the hunting angles of the wearer's nose, while remaining in the mounting plane. Spacing and orientation can be obtained by equipping each plate with a ball joint, or a combination of joints, or by providing a weak point facilitating deformation, at the junction with the sliding portion. Again, in the case of the ball joint and joints the adjustment can be automated with a spring or a return elastic. Once the wearer has considered that the element placed on his face is worn in a natural and pleasant manner, and knowing the geometry of the plates, the shooting will measure their position and their orientation, so that to deduce the nasal width and height, the front and flush angles corresponding to an optimal positioning, and thus to make accurately and reliably, either the pre-adjustment or the manufacture of the frame. The force of the springs or elastics will be determined according to the weight of the measuring element which will rest on the super-auricular furrows and on the nose, and will take into account the friction of the plates on the nose thus of the material used.

Also advantageously branches (11 and 12) may be equipped with bubble levels or a balance or other means for measuring the inclination relative to the horizontal, as well as landmarks of known geometry. These branches may be made of a flexible material capable of undergoing stable deformation mas reversible so as to reproduce the curvature of the branches of the chosen frame. The front view and the comparison with the element 1 of known geometry and orientation will make it possible to measure the sphenoidal distance and the super-auricular difference as well as the shape of the temples, and the inclination with respect to the horizontal. A side view will make it possible to measure the height of the super-auricular groove with respect to the line of the canthus, its distance from the mounting plane, the inclination with respect to the horizontal of the measuring device, the pantoscopic angle as well as the glass-eye distance and thus to complete the determination of the parameters necessary for the adjustment or the manufacture of a frame perfectly adapted to the morphology and the attitude of the wearer. It will be understood that the information relating to the wearing of the head and positioning of the device on the face should be available in the front view. To obtain a result, one will choose to equip each of the lateral branches of articulated inverted T-shaped pendulums (13 and 14) approximately in the middle of the branches (11 and 12) and equipped with lateral returns at the front (15 and 16). ) and back (17 and 18). In a preferred manner, the potentially visible portions in front view of these lateral returns will be colored in different colors depending on whether they are returns placed at the front or rear of the articulated devices. These lateral returns will have identical dimensions. Thus, the visualization of the only front part of the lateral returns on a front view, -13- the rear lateral returns being entirely masked by the front lateral returns will allow to conclude that the head port is horizontal and that the positioning of the measuring device on the face is correct. Conversely, the appearance of all or part of the rear lateral returns on a photograph taken in front view will conclude that the port of head is not strictly vertical and correct the measurements based on this information. The subject will then be asked to take a side shot without changing the positioning of the device on his face. In this side view, a possible parallelism defect between the lateral branches of the device and the lower bar of the beam (13 or 14) visible can be detected and measured. The combination of information relating to the positioning of the articulated rockers obtained in front and profile photographs made without modification of the port of the device will provide all the information necessary for the evaluation of the actual conditions of measurements, and therefore of make any necessary corrections. The data from the images can be used in real time or in a very short time, in combination with wishes expressed and / or data introduced by the user, to propose and / or manufacture glasses adapted to the needs of the user. visual correction and user tastes, under optimized cost and time conditions.

In a suitable embodiment, the means necessary for the implementation of the device as well as all the means necessary for the storage of the constituent elements of pairs of glasses and the other means all necessary means 25 to the automated manufacture of pairs of glasses according to the information collected by means of the device will be combined into one is even place, this one and the same place may be for example a photo booth type cabin or the like located in a shopping mall.

Claims (3)

CLAIMS 1- Device for measuring the morphological characteristics of the face of an individual, usable at the point of sale, in a specially arranged cabin or remotely via the Internet network of the type comprising an element intended to be placed on the face of the individual, a camera placed horizontally approximately in front of the wearer's face at the level of the eyes and the software means for analyzing the images obtained, characterized in that the element (1) intended to be placed on the face of the individual has the shape of a beam held approximately in front of the eyebrows of the individual by two branches perpendicular to said element (1) and can be placed on the ears and in that said element comprises: the means for accurately measuring the positioning in width of the optical axes, corresponding to the two interpupillary half-distances, the means of measuring the nual pitch deviations. roll and cap between the reference axis (4) of the element intended to be placed on the face and the optical axis of the camera. - The means of checking the alignment with respect to the horizontal of the element (1) placed on the wearer's face at the time of each shot. The means for measuring the height positioning of the optical axes corresponding to the pupillary height. - 2- Device for measuring the morphological characteristics of the face of an individual, usable at the point of sale, in a specially equipped cabin or remotely via the internet network of the type comprising an element intended to be placed on the face of the individual, a camera and the software means for analyzing the images obtained, according to claim 1, characterized in that the means for accurately measuring the two half interpupillary gaps are constituted by the calculation of the ratio between these distances measured in the image and the known width of the element (1) placed on the face of the corrected carrier as a function of the difference measured between the reference axis (4) of the element placed on the the wearer's face and the optical axis of the camera. 16-3- Device for measuring the morphological characteristics of the face of an individual, usable at the point of sale, in a specially equipped cabin or remotely via the internet network of the type comprising an element intended to be placed on the face of the individual, a camera and the image analysis software obtained according to claims 1 and 2, characterized in that the means for checking and measuring any deviations between the reference axis (4) of the element (1) placed on the face and the optical axis of the camera are constituted by at least two reflecting surfaces (2 and 3) non-planes disposed on the portion exposed to the camera of the element (1) placed on lo the face of the wearer. -4- Device for measuring the morphological characteristics of the face of an individual, usable at the point of sale, in a specially arranged cabin or remotely via the Internet network of the type comprising an element intended to be placed on the face of the individual, a camera and the image analysis software obtained according to claim 1, characterized in that the means for checking and measuring the alignment with respect to the horizontal of the element (1) placed on the wearer's face at the time of each shot are constituted by at least two non-planar reflecting surfaces (2 and 3) disposed on the portion exposed to the camera of the viewer. element placed on the wearer's face. -5- Device for measuring the morphological characteristics of the face of an individual, usable at the point of sale, in a specially arranged cabin or remotely via the internet network of the type comprising an element intended to be placed on the face of the individual, a camera and the image analysis software obtained according to Claims 1 and 2, characterized in that the means for verifying and measuring any differences between the reference axis ( 4) of the element (1) placed on the face and the optical axis of the camera are constituted by an outgrowth (5) perpendicular to the element (1) intended to be placed on the face said protrusion (5) being centered on the reference axis (4) of said element (1) and being dimensioned and positioned in such a way that its end is beyond the vertical passing through the end of the nasal appendix of the using the device. -6- Device for measuring the morphological characteristics of the face of an individual, usable at the point of sale, in a specially arranged cabin or remotely via the internet network of the type comprising an element intended to be placed on the face of the individual, a camera and the image analysis software obtained according to claim 5, characterized in that the protrusion (5) perpendicular to the element intended to be placed on the face io presented in top view and from below a triangular or trapezoidal shape, the two inclined faces (6 and 7) of this form being visible in front view and having graduations and / or a coating capable of reflecting light. 7 Device for measuring the morphological characteristics of the face of an individual, usable at the point of sale, in a specially equipped cabin or remotely via the Internet, of the type comprising an element intended to be placed on the face of the individual, a camera and the image analysis software obtained according to claim 1, characterized by a support piece (8) connected to the element (1) to be placed on the face allowing to determine, according to each category of glasses likely to be chosen by the individual concerned, the optimal positioning in height of the optical axes of the glasses to be used with respect to at least one reference point of the definitive frames the said support piece (8) having an opening (9) designed such that it allows to prejudge what will be the precise positioning on the nose of a frame of glasses belonging to a given category, provided that these glasses are worn, instead of the device, by the individual concerned .. -8- Device for measuring the morphological characteristics of the face of an individual, usable in point of sale, in a specially arranged cabin or remotely via the internet network of the type comprising an element intended to be placed on the face of the individual, a camera and the software for analyzing images obtained according to claim 7, characterized in that the support piece (8) rigidly but removably attaches to the element (1) intended to be placed on the face, and in that different support pieces (8) having different forms of openings (9) can be used depending on the choice of the category of mount chosen and / or the shape of the nose of the individual concerned. -9- A device for measuring the morphological characteristics of the face of an individual, usable at point of sale, in a specially equipped cabin or remotely via the Internet network of the type comprising an element intended to be placed on the face of . the individual, a camera and the image analysis software obtained according to claim 1, characterized in that the means for measuring the height positioning of the optical axes corresponding to the pupillary height comprise a piece support member (8) of known geometry, said support piece (8) being composed of four parts (19,20, 21 and 22) that are separable and orientable as a function of the nasal width and of the front and flush angles. -10- A device for measuring the morphological characteristics of the face of an individual, usable at the point of sale, in a specially arranged cabin or remotely via the internet network of the type comprising an element intended to be placed on the face of the individual, a camera and the image analysis software obtained according to claims 1 and 2, characterized in that the branches (11 and 12) are equipped with bubble levels or rocker or any other means for measuring the inclination with respect to the horizontal, as well as markers of known geometry, such that a side view makes it possible to measure the height of the super-auricular groove relative to the line canthus, its distance from the mounting plane, the pantoscopic angle and the glass-eye distance, the angle from the horizontal and thus to complete the determination of the parameters required. pre-adjustment or the manufacture of a pre-adjusted frame or the manufacture of a frame perfectly adapted to the morphology and attitude of the wearer.