FR2929722A1 - Plastic solar filter cutting method for spectacle lens, involves superimposing image of superposed trace with displayed image of frame using Nonuniform Rational Beta splines, and cutting filter by cutting apparatus along trace - Google Patents

Abstract

The method involves acquiring an image of a frame of spectacle using a web camera, and displaying the acquired image of the frame. Points used for calculating a curve of a cutting trace of a solar filter are marked on the displayed image of the frame. The cutting trace of the filter is calculated from the points. An image of the superposed trace is superimposed with the displayed image of the frame using Nonuniform Rational Beta splines. The filter is cut by a cutting apparatus along the trace.

Description

The invention relates to a method for cutting solar filters intended to be fixed superimposed on glasses of spectacles. The sunscreens referred to in the present invention are in particular colored plastic solar filters, made for example of tri-acetate, which have polarizing properties of light or not, and which are adaptable to a pair of glasses, for example by means of ties.

Today, there is no simple and economical way to make solar filters on demand. In practice, there is no simple known method that allows, for example an optician, to immediately meet the demand of a customer who would like to adapt filters to a pair of glasses. In view of the foregoing, a problem to be solved by the invention is to define a simple method of producing sunscreens adaptable to a pair of glasses.

The solution of the invention to this problem relates to a method of cutting a plastic solar filter to be fixed superimposed on spectacle lenses, characterized in that it comprises the following steps: - acquisition of an image of a spectacle frame; displaying the acquired image of said frame; positioning, on the displayed image of the frame, points that are useful for calculating a cutting plot curve of the filter, said points being displayed in the displayed frame image; calculating a cutting plot of the filter from said points, and superimposing an image of said plot on the displayed frame image; and - cutting said filter by a cutting apparatus according to said pattern. Thus, in just a few steps, with image acquisition means that are likely to be rudimentary, it is possible to obtain sunscreens adaptable to a given pair of glasses, in a limited time. Advantageously: the acquired image of the spectacle frame is an image acquired by means of a webcam; the acquired image of the spectacle frame is a two-dimensional image; the number of points is between about 7 and about 30; each of the points is weighted with a weight p equal to 1 or greater; the calculation of the cutting plot takes into account the position of the points as well as the weighting of said points; the calculation of the cutting plot is carried out using adjustment curves called "Splines" or "NURBS"; the cutting path is corrected according to the three-dimensional configuration of the spectacle frame; the method is implemented by means of software installed on a computer of the personal type; and - the pilot software Cutting by the cutting apparatus by transmitting to said apparatus, cutting commands according to the cutting plot.

The invention will be better understood on reading the description which follows, written with reference to the appended drawings, in which: FIG. 1 shows the different steps of the method according to the invention; and FIGS. 2A, 2B and 2C illustrate different views in the production of a solar filter according to the method of the invention. The method of the invention comprises a series of steps. These steps, presented in FIG. 1, notably include the acquisition of an image of a spectacle frame; the display 2 of the acquired image of said frame; positioning, on the displayed image of the frame, points useful for calculating a filter cut plot curve, said points being displayed in the displayed frame image; the possible weighting of these points; calculating a cut-off plot of the filter from said possibly weighted points and displaying an image of said plot superimposed on the displayed frame image; the correction of this line; and cutting 7 of said filter by a cutting apparatus according to said pattern. The terms eyeglass frames will have to be considered, in the present description, in a broad sense, including in particular eyeglass frames whose lenses are not rimmed or half-rimmed, in particular the frames of said glasses, rimless, which include only branches and a nose. The acquisition 1 of the image of the frame is made for example by means of a webcam, that is to say a camera whose usual use relates to the acquisition of images to be transmitted in a network of the Internet type. The webcam is therefore a device that has limited hardware resources - including optical - and whose purchase and use costs are low. Acquired images are two-dimensional images. They are intended to shape the contour to be modeled without concern for the exact dimensions of the actual frame at this stage of the process.

The display 1 of the acquired image of the frame is made in a window of a screen of a computer, for example of a personal type. This window 10 is shown in FIG. 2A. As it appears in this figure, the image 11 of the frame is a front view of this frame having a main body 12 of said frame, circling the lenses 13, and a nose bridge 14. Branches 15 of the frame are deployed or not. For the implementation of the invention, it does not matter that the dimensions of the presented image of the frame 11 are equal to the actual dimensions thereof. Indeed, as will be described further in the following description of the invention, a correction is made for cutting. The window of Figure 2A shows framing elements. These elements comprise in particular a vertical axis OY dividing the window into two substantially equal parts: a left part and a right part. They further comprise a median horizontal axis OX of the window 10. They may further comprise a bottom grid. as well as various elements such as for example inclined bottom lines intended to materialize the inclination of the rising parts of the nasal bridge 14. Thanks, in particular, to these framing elements, a user can adjust the position of the image of the mount 11 in the window 10, and in particular center this image on the intersection O of the vertical axis OY and the horizontal axis OX. It should be noted that positioning the image on the screen amounts to centering it so that it is perfectly symmetrical right-left.

For this purpose, an interlaced centering aid system of the half-image right side and the inverted symmetrical of the. left half-image can be implemented. This help system can display on the right part of the screen an interlacing of lines, a line on two coming from the real image and a line on two being displayed by symmetry of the left part with respect to the axis Y central. The software, which manages the steps of the method according to the invention, then defines at least a first point and, preferably, a second point corresponding to the cutting plot of the solar filter that is to be defined. The first point, noted Pl, is automatically positioned by the software near the cross O of the vertical axes. OY and horizontal OX framing, left part of the window 10. The second point P2 is disposed substantially below the point Pl, shifted slightly to the left, according to a probable curve that describes the nasal bridge 14. To define the outline of the filter, the user moves the points Pi and P2 by clicking by means of a pointer such as a computer mouse and manually points, directly on the image displayed on the screen, additional points P3, P4, P5, P6, P7, PN using said pointer, and clicking on the desired position of each point, successively. The shape of the filter is thus directly defined with respect to the image of the mount 11. This step is illustrated in FIG. 2B. In practice, the number N of points is between about 7 and about 30. However, it can be much greater. Nevertheless, below 7 points, the filter layout will not be sufficiently precise and, above 30 points, the filter resulting from the trace may have defects in aspects to the cut, materialized by unsightly angles of the filter.

Note that the curve does not go through the points positioned according to the invention. It is only, as it were, attracted by these points, more or less strong, according to their weighting, as will be explained in the remainder of this description.

When points are practically aligned, the curve passes close to each of them. The more they form an important angle, the more the curve moves away from it. So we do not point the contour directly but only attracting points.

The points P are weighted. The base weight of a newly clicked point P is a weight equivalent to two units. In practice, we have imagined putting all the weights to 1 unit. However, we then realized that the drawing was less easy, the curve is then a little too "loose" compared to its attractors. In practice, the difference is not noticeable, but the weighting of 2 units proved to be the most practical in use.

By clicking on a button represented on the screen and referenced 16, it is possible to assign to a point P, a weight of a value greater than its basic weight, it is possible to reduce the weight of each point by clicking on that same button. Note, however, that the final weight assigned to a point will never be less than the base weight (one unit). The weighting is from 1 to 10. By default, it is equal to 2. The weighting of the points P is particularly useful when the profile of the frame describes a curve with a small radius of curvature, for example, at the upper and lower corners. of the mount. The mount 11 having a bilateral symmetry, its image, in two dimensions, has an axis of symmetry, which is the vertical axis OY, when said image is centered in the window 10. Similarly, the filter that one wishes to obtain has a bilateral symmetry which follows the overall drawings of the body shape 12 of the mount 11. Thus, it is not necessary for the user, who defines the position and the weight of the points P1 to PN for the realization of the path of the filter outline, define the points on one side (the left side) of the window and on the other side (the right side) of the window. It is also preferable that these points are defined only on one side for the symmetry of the filter cut is perfect. The plot of the right part of the filter (in front view) is therefore deduced from the outline of its left part (always in front view) - see Figure 2B.

The calculation of the plot 17 from the weighted points positioned by the user is an essential step of the method according to the invention. The user can not position a large number of points without losing time. Consequently, the cutting plot 17 must be defined with a minimum of points and must be smooth, that is to say do not generate angles, which would constitute appearance defects in the cut filter. The curve is constantly recalculated and superimposed on the acquired image. The calculation of the cutting plot takes into account the position of the N points P as well as the weighting of said points P. It is carried out by means of generalizations of the Béziers curves called p Splines or NURBS (Non-Uniform Rational Beta Splines).

Preferably, it is carried out by means of Splines adjustment curves which make a better plot in this specific case of the definition of a contour of solar filters contour. It is possible according to the invention to visualize the filter 18 whose plot has been calculated. Such a representation is shown in Figure 2C. Note that the software allows correction of the plot after pointing by displacement, deletion, addition or weighting of the points, in order to improve the final plot 30 after the gross drawing phase and calculation of the final trajectory of the cutting tool given the offsetting correction related to the radius of the latter. In addition, as mentioned above, the plotting of the plot is outside actual dimensions, simply modeled on the acquired image. Then the plot is scaled with both X and Y dimensions requested before machining or printing. Also, a correction must be made on the plot reproduced on the screen so that it is adjusted to the actual dimensions of the spectacle frames. To make this adjustment, two values are entered in the software. The first value is the value of the distance between the attachment point of one branch and the point of attachment of the other branch. The second value is the highest height of the frame, taken at the level of a glass. The correction takes into account that the mount, just like the filter that needs to be defined, is not flat but curved, not only from left to right, but from bottom to top. The cutting path is thus corrected according to the three-dimensional configuration of the spectacle frame. Once the plot is corrected, the software initiates the cut. This cutting is performed by a specific device called router. This router includes a strawberry. In a first embodiment of the invention, this cutter is controlled directly by the software. In a second embodiment of the invention, the router comprises a memory, in which is stored a file corresponding to the plot of the cut and performs cutting according to the stored file. The software can also transmit to a simple memory key which will then be transported to the machine, it may be provided with an optional housing for driving from this memory key. In this case, the software only indirectly controls the machine. Both configurations are proposed, direct control if the computer is located near the machine, or well indirect control via a memory key and an optional control box if the computer is remote.

Of course, the invention is not limited to the embodiments described above and those skilled in the art can, by routine operations, adapt these embodiments.

Claims (10)

REVENDICATIONS1. A method of cutting a plastic solar filter to be fixed superimposed on spectacle lenses, characterized in that it comprises the following steps. acquiring (1) an image of a spectacle frame (11); displaying (2) the acquired image of said mount; positioning, on the displayed image of the frame, points useful for calculating a filter cut plot curve, said points being displayed in the displayed frame image; computing (5) a plot (17) of cutting the filter from said points, and superimposing an image of said plot superimposed on the displayed frame image; and cutting (7) said filter by a cutting apparatus according to said pattern. 2. Method according to claim 1, characterized in that the acquired image of the frame (11) of the glasses is an image acquired by means of a webcam. 3. Method according to one of claims 1 or 2, characterized in that the acquired image of the spectacle frame is a two-dimensional image. 30 4. Method according to one of claims 1, 2 or 3, characterized in that the number of points is between about 7 and about 30. 5. Method according to one of the preceding claims, characterized in that each of the points is weighted with a weight p equal to 1 or greater. 6. Method according to one of the preceding claims, characterized in that the calculation (5) of the cutting plot takes into account the position of the points and the weighting of said points. 7. Method according to one of the preceding claims, characterized in that the calculation of the plot (17) of cutting is performed by means of curves called p Splines or NURBS. 8. Method according to one of the preceding claims, characterized in that the tracing (17) is corrected cutting according to the three-dimensional configuration of the spectacle frame. 9. Method according to one of the preceding claims, characterized in that it is implemented by means of software installed on a computer of the personal type. 10. Method according to claim 9, characterized in that the software controls cutting by the cutting apparatus by transmitting to said apparatus, cutting commands according to the cutting plot.