Method for designing and producing a customized device, the shape of which is adapted to the user's morphology

Abstract

A method for manufacturing a customized apparatus with a shape adapted to a specific user's morphology, or a mold for such an apparatus, includes obtaining a description of a generic apparatus, or of the mold for such an apparatus, the generic apparatus being adapted to a generic morphology. A description of the generic morphology and a description of the specific user's morphology is obtained. The descriptions of the generic morphology and of the specific user's morphology are processed to identify a geometric transformation mapping together the generic morphology and the specific user's morphology. The geometric transformation is applied to the description of the generic apparatus, or the description of the mold for such apparatus, in order to define the description of the customized apparatus or the mold therefor. The customized apparatus is then manufactured.

Claims

1. A method for manufacturing a customized apparatus with a shape adapted to a specific user's morphology or a mold for the customized apparatus, the method comprising the following steps: receiving data relating to a 3D digital model of a generic apparatus or a physical mold for the generic apparatus, the generic apparatus being adapted to a generic morphology; receiving data relating to a 3D digital model of the generic morphology; receiving data relating to a 3D digital model of the specific user's morphology; analyzing the data relating to the 3D digital model of the generic morphology and the data relating to a 3D digital model of the specific user's morphology using a computer to determining a geometric transformation mapping the generic morphology to the specific user's morphology; applying the determined geometric transformation to the data relating to the 3D digital model of the generic apparatus or the mold for the generic apparatus and generating a 3D digital model of the customized apparatus or a mold for the customized apparatus; and manufacturing the customized apparatus or the mold for the customized apparatus.

2. The method of claim 1, wherein receiving data relating to a 3D digital model of the specific user's morphology comprises measuring at least a portion of a body of the user.

3. The method of claim 1, wherein the data relating to each of the 3D digital models comprises at least one of computer code in a 3D object description language, a 3D mesh, a volume image, or a plurality of 2D images.

4. The method of claim 1, wherein the data relating to the 3D digital model of the generic apparatus or the mold of the generic apparatus is associated with data relating to local stiffness information, and wherein applying the determined geometric transformation to the data relating to the 3D digital model of the generic apparatus or the mold for the generic apparatus comprises locally modulating the application of the geometric transformation using the data relating to local stiffness information when creating the 3D digital model of the customized apparatus or the mold for the customized apparatus.

5. The method of claim 4, wherein manufacturing the customized apparatus or the mold for the customized apparatus comprises using an additive manufacturing process or a machining process.

6. The method of claim 4, wherein: the method comprises a method for manufacturing a mold for a customized apparatus having a shape adapted to a specific user's morphology; receiving data relating to the 3D digital model of the generic apparatus or of the mold for the generic apparatus comprises receiving data relating to the 3D digital model of the mold for the generic apparatus; applying the determined geometric transformation to the data relating to the 3D digital model of the generic apparatus or the mold for the generic apparatus and generating a 3D digital model of the customized apparatus or the mold for the customized apparatus comprises applying the determined geometric transformation to the data relating to the 3D digital model of the mold for the generic apparatus and generating a 3D digital model of the mold for the customized apparatus; and manufacturing the customized apparatus or the mold for the customized apparatus comprises manufacturing the mold for the customized apparatus.

7. The method of claim 6, wherein manufacturing the mold for the customized apparatus comprises using an additive manufacturing process or a machining process.

8. A computer system configured under control of a program to perform the following processes: receive and store a 3D digital model of a generic apparatus or a mold for the generic apparatus, the generic apparatus being adapted to a generic morphology; receive and store a 3D digital model of the generic morphology receive and store a 3D digital model of a specific user's morphology; analyze the 3D digital model of the generic morphology and of the 3D digital model of the specific user's morphology to determine a geometric transformation mapping the generic morphology to the specific user's morphology; and apply the determined geometric transformation to the 3D digital model of the generic apparatus; or the mold for the generic apparatus, to define a 3D digital model of a customized apparatus or a mold therefor.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Other characteristics and advantages of the disclosure will emerge from the detailed description hereunder while referring to the accompanying figures wherein:

(2) FIG. 1 schematically shows the steps of a method in accordance with the present disclosure; and

(3) FIGS. 2A to 2D show an exemplary embodiment of the method of FIG. 1.

DETAILED DESCRIPTION

(4) According to a first aspect, the disclosure relates to a method for designing a customized apparatus, or a mold for such an apparatus, i.e., an apparatus having a shape adapted to a specific user's morphology. It should be noted that this apparatus may be an orthosis or a prosthesis that the deter mined user wishes to equip himself/herself with.

(5) For the purposes of this description, the term design refers to the steps of making a sufficient description of a device (apparatus, mold, etc.), as needed, to enable the representation thereof, for example, in graphical form using computer processing and visualization means or to enable the production thereof. Reference can be made to the general book Warping & Morphing of Graphical Objects by J. Gomes, The Morgan Kaufmann Series in Computer Graphics, Morgan Kaufmann, 1998, for a detailed discussion of the well-known methods of description and manipulation of objects.

(6) The disclosure is not limited to a particular form of description of the apparatus, a mold for this apparatus and/or a user's morphology and these descriptions can be formed using an object description language (such as VRML, STL or STEP). They can also be formed by decomposition into finite elements (3D mesh) of the surfaces that define same. They can also be described by a volume image, i.e., composed of points, called voxels, identified in a three-dimensional space and associated with at least one numerical value that can represent a grayscale or a color. The descriptions of an apparatus or a morphology can also be formed by a plurality of 2D images (composed of pixels) making it possible to reset the object described in its volume.

(7) A description of an apparatus, a mold, or a morphology can be hybrid, i.e., combine different forms of description such as those just presented. These different forms may relate to identical or complementary parts of the described object.

(8) Whatever the form(s) chosen to describe an object, its description can be materialized by a computer file containing the language elements and/or the pixels, voxels, and/or mesh points that it/they is/are made of.

(9) To design the customized apparatus, this disclosure is based on the availability of a description of a generic device or a mold for this apparatus. The generic apparatus has a form adapted to a user's generic morphology. This generic morphology is itself the subject of a description, referred to in this application as the description of the generic morphology.

(10) Generic morphology refers to a morphology representative of a class of users. Only one generic morphology and the description thereof can be available, and this morphology can then constitute an average and simplified morphology of a human body. Alternatively, a plurality of generic morphologies (and the descriptions thereof) may be available, for example, a male generic morphology and a female generic morphology. In all cases, a generic morphology and the description thereof form a representative, albeit simplified, version of the class of users it represents. It should be noted that it is not necessary for the description of the generic morphology to represent an entire human body. This may be the most relevant part of this body relative to the apparatus under consideration.

(11) A generic morphology, and the representation thereof, is associated with a description of a generic apparatus, or a description of a mold for such an apparatus. The generic apparatus is precisely adapted to the generic morphology, i.e., the surfaces that will be, in operation, in contact with the user complying with the generic morphology. Of course, the generic morphology and the apparatus generic are described in the same starting space, which makes it possible to associate the same with each other, to identify the same relative to each other, and to ensure that they are well tailored to each other.

(12) Since the generic morphology is generally a simplified representation of a real morphology, it is clear that this generic apparatus or the mold thereof are easily described.

(13) To design the customized apparatus, the disclosure is also based on the availability of a description of the determined user's morphology to whom the customized apparatus is intended for.

(14) As seen above, this description can take multiple and hybrid forms, but advantageously the description results from a measurement system of the I.R.M. type, or from an X-ray scanner for computed axial tomography, or from an ultrasonic measurement device. These means make it possible to obtain very directly a volume image of the user's morphology. Alternatively, the description can be obtained from a measurement system to obtain a plurality of 2D images of the user. It can be an X-ray device. In yet another alternative embodiment, the description can be obtained from a skin surface measurement system. It can be a depth camera or laser scanning.

(15) The description of the specified user's morphology or a complete description of this user's body need not be complete, and only the part of his/her body most relevant to the apparatus to be produced may be sufficient.

(16) FIG. 1 schematically shows the steps of a method in accordance with a first embodiment of the disclosure. The method includes a first series of steps consisting in, without any imposed order, obtaining the representation of an apparatus having a shape that is adapted to a generic morphology, obtaining a description of this morphology and obtaining a description of the determined user's morphology. Descriptions of the generic apparatus and generic morphology can be derived from, and chosen from, one previously constituted library. In the event that one does not have a description of the determined user's morphology, this sequence of steps can include or be preceded by a step aiming at making this representation. This may be, for example, but not exclusively, one of the measurement techniques presented above.

(17) In a subsequent step, the method according to the disclosure includes a step of processing the description of the generic morphology and the description of the identified user's morphology. Such processing identifies the geometric transformation of the space by matching the generic morphology, defined and described in a starting space, and the determined user's morphology, defined and described in an end space.

(18) Such processing operations are well known to the person in the art, as shown in J. Gomes' book cited above. Reference may also be made to the review articles by M. A. Audette, F. P. Ferrie, and T. M. Peters (2000), An algorithmic overview of surface registration techniques for medical imaging, Medical image analysis, 4(3), 201-217; or O. Van Kaick, H. Zhang, G. Hamarneh, and D. Cohen-Or (2011, September), A survey on shape correspondence, in Computer Graphics Forum (Vol. 30, No. 6, pp. 1681-1707), Blackwell Publishing Ltd., for a detailed overview of existing algorithms and techniques that can be applied.

(19) In a very general way, this processing comprises determining the transformation of the space that best matches the elements defining a first description of an object in a first position with elements defining a second description of that object in a second position. This processing is generally considered as an optimization problem, the solving of which uses known function-minimizing techniques, for example, derived from a gradient method. This disclosure uses known object description-matching algorithms to identify the geometric transformation matching the generic morphology with the determined user's morphology.

(20) This geometric transformation can be indifferently applied to the representation of the generic morphology to obtain the determined user's morphology. Conversely, it may be the one applied to the description of the determined user's morphology to obtain a morphology best matching that of the generic morphology. In this last case, great care is taken to reverse the geometric transformation before applying it in accordance with the next step of the design method, the description of which is given hereunder.

(21) The geometric transformation can be determined as a combination of translation, rotation, homothety, etc.

(22) More generally, the geometric transformation can be a deformation field associating, for example, each point of the starting space with a point of the end space; or associating a displacement to be applied in the X, Y and Z directions at each point of the starting space to determine the point of the end space.

(23) In a subsequent step of the method according to the disclosure, the geometric transformation identified with the description is applied to the generic apparatus to make the description of the customized apparatus.

(24) By applying the same transformation to the description of the generic apparatus as those matching the generic morphology and the specific user's morphology, the customized apparatus is assuredly adapted to the specific user's morphology. As the transformation applies to the space containing the apparatus as a whole (e.g., by applying the identified deformation field, as previously specified), it is not necessary to combine several parts together to make the description of the customized apparatus. The need for manually editing the description of the customized apparatus is thus limited, or even eliminated.

(25) In a particular embodiment of the disclosure, the step of applying the geometric transformation is implemented concurrently with the step of determining the geometric transformation.

(26) According to a particularly advantageous embodiment, the description of the generic apparatus is associated to local information on rigidity. This information specifies which areas of the generic apparatus can be freely transformed or deformed, those that must not be transformed or deformed, or those that must undergo a lower degree of transformation or deformation. The application of the geometric transformation to the generic apparatus can thus be locally modulated. This may have the advantage of preserving, in the adapted apparatus, portions that have not fully undergone geometric transformation and can, therefore, preserve, at least in part, the original geometry thereof. These may be functional portions of the apparatus, such as a joint, that could be rendered inoperative by a poorly controlled transformation.

(27) Following the implementation of the design method just presented, a description of the appropriate apparatus is, therefore, available. This description, in particular, when it takes the form of a computer file, may be used as such by processing and/or visualization devices, for example, to constitute objects integrated in an animated sequence.

(28) FIGS. 2A to 2D represent an exemplary application of a method in accordance with the disclosure to the design of a leg orthosis.

(29) FIG. 2A represents, in a starting space materialized by the grid 1, a generic morphology 2 of a user's limb and the generic orthosis 3 associated with such limb. A functional, rigid, part 3a of the orthosis has also been represented, which must not be transformed. The representation of the morphology and the orthosis was obtained from their descriptions, which define these objects in three dimensions. This description also defines the degree of rigidity of the functional part 3a, as described above. One could have chosen to represent the orthosis and morphology from another angle, or to represent them separately. The descriptions that both representations are based on may have been specifically designed or extracted from a pre-existing library.

(30) FIG. 2B shows, from the same angle of view as the one used in FIG. 2A, a morphology 4 of a specific user's limb, for example, obtained by a 3D scanning technique. Similar to the comments applying to FIG. 2A, the representation of the determined user's morphology was obtained from the description thereof, which defines this object in three dimensions.

(31) FIG. 2C represents the geometric transformation applied to the generic morphology 2 to match it with the determined user's morphology 4. This transformation is notably materialized by the deformation of the grid 1, defining the deformation field applying to the starting space to ensure this correspondence. It can be seen that the morphology 2 shown in this figure is very similar to the determined user's morphology 4 shown in FIG. 2B.

(32) This FIG. 2C also shows the generic orthosis 3, which the same transformation field has been applied to as the one applied to the generic morphology, to form the transformed generic orthosis 3. This transformed orthosis 3 defines the orthosis adapted to the particular user, which is represented in FIG. 2D.

(33) According to a second embodiment of the present disclosure, the design method aims at creating a mold for the customized apparatus rather than the apparatus itself.

(34) The implementation of the mold design method is entirely similar to the one described in relation to the first embodiment. For the sake of conciseness, this description is therefore not repeated, but applies in full.

(35) In the case of this second embodiment, the method includes a step of obtaining a description of the mold used to make the generic apparatus.

(36) Then, the geometric transformation of the space that matches the generic morphology with the determined user's morphology is applied to the mold for the generic apparatus in order to obtain the description of the mold for the customized apparatus.

(37) Once manufactured, this mold makes it possible to produce, for example, by thermoforming, the customized apparatus.

(38) The design method according to the disclosure is intended to be implemented by a computer, through a computer program consisting of instructions adapted to implement at least each of the steps of this method.

(39) According to another aspect of the disclosure, the description of the customized apparatus is used to produce the customized apparatus as such or the mold thereof, so that it can equip the determined user. According to this other aspect, the disclosure thus relates to a method for producing a customized apparatus or its mold. It also relates to the customized apparatus obtained using this method.

(40) Advantageously, the customized apparatus or its mold is obtained by additive production, particularly well adapted to the manufacture of a single object, as is the case for a user-tailored apparatus. It can also be manufactured by machining.