FR2570206A1 - Apparatus for detecting and classifying the characteristics of skin surface shapes - Google Patents

Abstract

a. Apparatus for detecting and classifying the characteristics of skin surface shapes. b. Apparatus characterised in that it uses a data processing device 5, 6, 7, 8, 9, 10, 11, 12, 13, at least one illumination device 2X, 2Y intended to illuminate the surface of the skin or a reproduction of this surface, a device for producing a group of digital signals representing a surface image of the skin, memory means intended to store these digital signals, means of calculating continuous lengths corresponding to a predetermined level of the digital signal relating to this surface image, and means of calculating different statistical quantities allowing classification of the distributions of these continuous-level lengths. c. The invention relates to an apparatus for detecting and classifying the characteristics of skin surface shapes.

Description

Apparatus for detecting and classifying features
skin surface shapes
the invention relates to an apparatus for detecting and classifying the characteristics of skin surface shapes, and more specifically to an apparatus for analyzing fine forms of the skin surface to extract configuration information therefrom serving as markers for classifying #; t # distinguish the nature and quality of the skin. A device of this type can be used for the care and diagnosis of the skin for hygienic purposes and the use of cosmetics.

 On the surface of the skin, we can see a certain number of fine grooves called skin grooves, small approximately rectangular eminences formed by the skin furrows and called skin eminences, as well as fine relief configurations (figures skin) formed by skin pores or the like, the shape of these elements reflecting skin metabolism and other physiological functions. Consequently, the fact of analyzing a fine shape of the surface of the skin to determine the characteristics of this one makes it possible to obtain the elements of knowledge of the nature and the quality of the skin, essential for the care, the diagnosis and the use of cosmetics; this analysis is therefore important.

 In the past, various means have been used to determine the characteristics of the skin from the patterns formed on the surface thereof. However, the decision on the quality of the skin is generally made subjectively and experimentally on the basis of the readings carried out by the observer and the synthesis of what are called characteristics of skin figures such as the size and number of the pores. , the density, the diameter, the depth and the direction of the furrows of the skin, and the size and the shape of the eminences of the skin.

 The fine shape of the skin surface was expressed quantitatively. For example, in a first method, a skin reproduction surface (in which the surface shape of the skin is reproduced by pressure in a suitable material) is scanned by a sensor (read tip) of a roughness measuring device. surface, and the amplitude of the signal obtained is processed by a computer allowing digital information to be obtained (Nippon Keshohin Cijyutsusha Kaishi "Vol. 13, n0 2, pages 44 to 49). In a second method, a number is used of images obtained by varying the conditions of illumination of a photographic light source, so as to classify zones lying in predetermined lighting and darkness ranges. In a third method, a powerful computer is used and quick to analyze and process the data by a complicated figure processing program, so as to extract the characteristic information.

 However, in these methods, it is not possible to obtain a good correspondence between the results obtained by subjective and experimental procedures, where periods of time are excessively long, very high costs and very significant professional experience are necessary. to implement them, which makes them impractical.

 The object of the invention is to remedy these drawbacks by creating a device for detecting and classifying the surface shape characteristics of the skin which is small, inexpensive, simple to operate, and well suited to conventional subjective and experimental results.

 To this end, the invention relates to an apparatus for detecting and classifying the characteristics of shapes of skin surfaces, apparatus characterized in that it uses an information processing device comprising, for the detection and analysis of the shapes of the surface of the skin, at least one lighting device intended to illuminate the surface of the skin or a reproduction of this surface, a device for producing a group of digital signals representative of a surface image of the skin or d '' a reproduction of this illuminated by the lighting device, memory means intended for storing these digital signals, means for calculating continuous lengths corresponding to a predetermined level of the digital signal relating to this surface image, and means for calculating different statistical quantities allowing the classification of the distributions of these lengths at a continuous level.

 The essential characteristic of the invention is based on the fact that the shape information of the images of the surface of the skin is processed to be expressed in the form of a certain number of limited levels, that the distribution of suitable characteristics, such as that continuity is obtained from these levels, and that the shape of the skin surface is intended to be characterized by the classification of these forms of distribution. As parameters of these distributions, one can use the average values, the standard deviation, the number of picture elements above a determined level, and others, but when one uses as parameter the increasing difference of the data between positions relating to variable data configurations, it is possible to further improve the accuracy of extracting the characteristics.

the invention will be described in detail with reference to the accompanying drawings in which
- Figure 1 is a block diagram showing an embodiment of an apparatus for detecting and classifying surface characteristics of the skin, according to the invention
- Figure 2 shows an example of binary image of the skin;
- Figure 3a shows an example of a binary image of the skin with regularly distributed skin figures
- Figure 3b shows the horizontal scanning direction; and
- Figure 3c shows a graph showing the relationship between the continuous number of black data and the frequency of the latter.

 In the following description, Figure 1 shows a block diagram of an embodiment of the apparatus for detecting and classifying skin surface shape characteristics according to the invention. In FIG. 1, the reference 1 designates the skin to be analyzed or a reproduction thereof. References 2X and 2Y designate illumination light sources preferably designed so that their amounts of light can be varied. Although two illumination devices are shown in the figure, it will be noted that the use of three illumination sources offset by 1200 would make it possible to choose suitable lighting conditions. It will also be noted that in order to simplify the device, you can use a single light source, and if you use an optical fiber and a reflecting mirror together, it is convenient to adjust the amounts of light and the angle of incidence of light when mounts the light source itself.

 As the above does not constitute the main subject of the invention, no further description will be given thereof.

 Reference 3 designates an enlarged optical system in which a low magnification microscope or a contact lens is used to obtain a predetermined magnification image (approximately 1.0 to 2.0). The reference 4 designates a scanning and conversion device intended to scan an optical image to produce an electrical signal whose amplitude varies according to the intensity of the light in the various parts of the image, and one can use a a suitable imaging device such as a color camera, a monochromatic camera or a CCD (charge coupled component) camera.

 In the present embodiment, only the case where only black and white information is used will be described. It is however possible to add color information to obtain different characteristics of the skin, and the comparison of the amplitudes and the continuity between the components of three primary colors is particularly important, but this will not be described in more detail for the this is beyond the main scope of the invention.

Reference 5 designates a front amplifier intended to regulate the output levels of the scanning and conversion device, this amplifier being placed to ensure adaptation with an A / D converter (Analog /
Digital) 6.

 In the simplest case, the A / D converter can be replaced by a simple threshold circuit. In this case, the converter can be designed so that the threshold can be modified by hand or by a signal from an information processing device 10.

 In the A / D converter 6, the devices necessary for the A / D conversion are associated with a sampling device.

 if necessary, the output of the A / D converter 6 can be stored in a system memory 7 intended for the initial recording of the data.

However, this system memory 7 can be deleted.

 The reference 8 designates an interface device of the A / D converter 6 or of the system memory, and the information processing device 10 can, if necessary, include an interface device of a projection monitor d monochrome image 9 intended to monitor # the signals before their entry into the information processing device 10.

 The information processing device 10 operates at least in main memory to perform arithmetic and logical operations, as well as in working and control memory.

 The main memory is used to store the signals converted by the A / D converter. The arithmetic and logic operations function selectively and systematically performs the arithmetic and logic operations necessary to process the data by the control function. The working memory function temporarily stores the intermediate results and the final result of the operation. The control function is conveniently carried out by what is called a program control system which triggers the functions necessary to control the functions indicated above at the required times. A small calculator called a personal calculator can be applied to the information processing device equipped with these functions.

 The arithmetic and logical operations, relating to the essential characteristics of the invention require at least the function capable of calculating the parameters such as for example the standard deviations representing the comparison between large and small arithmetic sums, the average values and constants, and the dispersion distributions of analyzed data.

 Reference 11 designates an external memory used to store the various information and constants necessary for operation. Reference 12 designates a color or monochrome cathode ray tube display device, and reference 13 designates a printer.

 We will now describe the operating principle of the device, starting with the case where the A / D converter is binary, that is to say by the case where the operation can be ensured by a simple threshold circuit, which will then allow to deduce the principle of a more complicated operation. First of all, the skin or the reproduction of the skin 1 is illuminated by the light sources 2X and 2Y. An image of the skin or of the reproduction thereof 1 is enlarged by the optical enlargement system 3. The scanning and conversion device 4 scans this enlarged image to produce electrical signals whose amplitude varies according to the light intensity in the different parts.

 This signal is sampled by the A / D converter 6, as indicated above, via the front amplifier 5, then transformed into binary information of 1 bit taking the value "1", when the illumination is less than a predetermined value, and the value o when the illumination is greater than the above value, for each of the picture elements, and this information is temporarily stored in the system memory 7. The binary image stored in the system memory 7 is read at a suitable time and produced in the information processing device 10 via the interface device 8. On the other hand, the other output of the interface device 8 is added to the monochrome projected image monitor 9 to enable monitoring of the binary image. An example of this binary image is shown in FIG. 2. The binary image data introduced into the information processing device 10, are stored under the form of a signal corresponding to "1" or to "O" above, together with position information provided on the surface of the binary image by the operation of the main memory of the processing device information 10.

 An example of data processing will be described below. The data stored by the control function and the main memory function of the information processing device are read relative to the initial binary image surface, this reading corresponding to the horizontal scanning in four directions forming angles between them. 450 as shown in Figure 3b given by way of example. This can be replaced by binary data obtained by rotating the reproduction 1 of the skin by 450.

 The column of data obtained by scanning in each of these directions is a column of signals "1" and O, and among these signals, the length for which one obtains "1" is calculated by an operation of arithmetic logic, and the length for which a "1" is obtained, as well as the frequency at which this length occurs, with respect to the respective scanning directions, are stored by the working memory.

 These memories are read to calculate an average value of lengths which is preserved with respect to the scanning direction, with the standard deviation of the frequency with respect to the lengths preserved, with the total number of "1" etc .... These results are arranged and stored in other areas of the working memory. In addition, the average value of the lengths kept, with respect to the respective directions, is obtained by averaging these lengths, then arranged and stored in yet other areas of the working memory.

 The "1" thus obtained in four scanning directions, the average value of the lengths conserved, the standard deviation and the total number of "1", corresponding to the skin or to the reproduction thereof, can be used below. after as benchmarks reflecting the characteristics of the skin. Of course, these classifications are given as examples, and if other parameters are used, more classifications can be made.

(1) The value (S1) obtained by calculating the average value of the length kept in the four scanning directions, can be used for the discrimination and the classification of relatively large pores and smaller pores
(2) The value (S2) for which, among the average values of lengths kept, with respect to the four scanning directions, an orthogonal scanning pair is formed to obtain a ratio of respective average values taking into account a larger absolute value coming out of the two reports above, can be used for: the discrimination and the classification of the values for which the master plan of the figures of the skin, i.e. the furrows of the skin, is relatively dispersed, and values for which the skin grooves are oriented in the same direction
(3) The value (S3) of the total number of 1 can be used for: the discrimination and the classification of the values for which the furrows of the skin are small and the eminences short (rough), and values for which there are many skin furrows; and
(4) The value (54) for which the whole surface of an image is divided into meshes (for example 256 meshes of 13 x 13 points each) to obtain the number of "1" of each mesh so as to establish a coefficient variable, can be used for: discrimination and classification of # values for which the eminences of the skin are small, and values for which the eminences of the skin are large or indeterminate.

 The above discrimination and classification will be described in detail using the value (S2). FIG. 3a represents a binary image presenting uniformly distributed skin figures, different from those of FIG. 2. When the main memory containing the 1 and the O of the binary image, is read by the horizontal scanning in the four directions ( 1), (2), (3) and (4) of Figure 3b, we obtain data columns comprising the i and the "O", but these data columns are different according to the directions (1), (2 ), (3) and (4).

 FIG. 3c is a graph re-presenting the continuous number of "1" and the frequency thereof by considering these columns of data. On the graph, the references (1), (2), (3) and (4) correspond to the scanning directions (1), (2), (3) and (4) of FIG. 3b, which are respectively curves representing the distribution of continuity. It will easily be understood that in the case of (3), the continuity of the "1", that is to say the continuous length of a black part swept in the direction (3) of FIG. 3a, is most often short, and its frequency is that shown in Figure 3c. It will also be understood that the distribution in the direction of (4) orthogonal to that of (3), is also that indicated in FIG. 3c.

As described above, the ratio of the mean values of the continuous number of the distributions (3) and (4) of FIG. 3c, deviates from 1.

 The distributions (1) and (2) have practically similar curves, and the ratio of the mean values of the number of continuous lengths is approximately equal to 1. However, the ratio of the mean values of the number of continuous lengths in two orthogonal scanning sets neighbors of 1, will not be used here.

 Considering this fact in the skin figures in which the black part is regularly distributed radially in FIG. 2-, it will be said that the ratio of the mean values of the number of continuous lengths obtained by orthogonal scanning, is close to 1. Consequently, it becomes possible to carry out the discrimination and classification described in (2). The discrimination and classification of (1), (3) and # 84) will not be described in more detail, because they are easily understood.

 In the detection and classification of the characteristics of the surface shape of the skin, the values Sl, S2, S3 and S4 above are divided quantitatively into Sl ~ l, S1 ~ 2, S1 ~ 3 sS2-1 S2- 2 'S2-3 # 2-3 S4 lux S4 2 S4 3 ... and these values can be used in composition as discrimination benchmarks. By the classification carried out on the basis of the above elements, it is possible to obtain a very precise coincidence with the classification carried out by the critical examination of skin experts on the basis of the size of the pores, the shape of the grooves of the skin, the size of the eminence of the skin, and others.

 The results thus obtained can be published and disseminated, if necessary, in the form of data or digital figures, on a cathode ray tube display device 12 and on a printer 13, by the main memory function, the working memory function, and the control function. If necessary, it is possible to store the results in the external memory 11, so as to be able to compare the new and old results.

 If a small computer is used in the information processing device 10, there is no difficulty in integrating special hardware, and one can use the very diverse data processing possibilities of a computer to make more complicated analysis and discrimination possible. In addition, the input data, the interrogation data and the observation data can be introduced from other measuring devices, to obtain diagnoses by combining these data.

 In the case where the small computer is used, this can be used to initialize the outputs of the A / D converter and to provide additional buffer means to make the word length of the number of bits equal to the length word calculator.

 As described above, the apparatus according to the invention can be manufactured in very small form and at very low cost, and objective benchmarks can be obtained very quickly by anyone.

The apparatus can suitably be put on sale in establishments such as small hospitals, pharmacies, perfumeries and other shops of utilities.

Claims (6)

 10) Apparatus for detecting and classifying the characteristics of shapes of skin surfaces, apparatus characterized in that it uses an information processing device (5, 6, 7, 8, 9, 10, 11, 12, 13) comprising, for the detection and analysis of the shapes of the skin surface, at least one device (2X, 2Y) for lighting intended to illuminate the surface of the skin or a reproduction of this surface, a device for producing a group of digital signals representative of a surface image of the skin or of a reproduction of the latter illuminated by the lighting device, memory means intended for storing these digital signals, means for calculating continuous lengths corresponding to a predetermined level of the digital signal relating to this surface image, and means for calculating different statistical quantities allowing the classification of the distributions of these lengths at a continuous level.  20) A detection and classification apparatus according to claim 1, characterized in that the means for calculating the continuous lengths corresponding to a predetermined level of the digital signal relating to the surface image, comprise means for scanning information in two dimensions in four directions separated from each other by 450, to calculate the frequencies of continuous lengths corresponding to a predetermined level in each direction, and the length thereof.  30) Detection and classification apparatus according to any one of claims 1 and 2, characterized in that the means for calculating the different statistical quantities allowing the classification of distributions of these lengths at continuous level, include means for calculating an average value of continuous lengths at this predetermined level.  40) detection and classification apparatus according to any one of claims 1 and 2, characterized in that the means for calculating the different statistical quantities, comprise means for calculating a ratio of mean values of continuous lengths corresponding to a level predetermined, for an orthogonal scan among the four directions, so as to calculate the largest of these ratios.  50) Detection and classification apparatus according to claim 1, characterized in that the means for calculating the different statistical quantities allowing the classification of distributions of these lengths at continuous level, comprise means for calculating the total sum corresponding to a point having a predetermined level.  60) Detection and classification apparatus according to claim 1, characterized in that the means for calculating the continuous lengths corresponding to a predetermined level of the digital signal relating to the surface image, and the means for calculating the different statistical quantities allowing the classification of the distributions of these lengths at continuous level, include means for dividing the entire surface of a mesh image making it possible to count the points having predetermined levels for each mesh, and means for calculating a variable coefficient corresponding to these counting points.