EP3894948A1 - Procédé de génération de données géométriques d'une monture de lunettes individualisée - Google Patents

Procédé de génération de données géométriques d'une monture de lunettes individualisée

Info

Publication number
EP3894948A1
EP3894948A1 EP19842859.1A EP19842859A EP3894948A1 EP 3894948 A1 EP3894948 A1 EP 3894948A1 EP 19842859 A EP19842859 A EP 19842859A EP 3894948 A1 EP3894948 A1 EP 3894948A1
Authority
EP
European Patent Office
Prior art keywords
adaptation
polygon model
data
model
polygon
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Pending
Application number
EP19842859.1A
Other languages
German (de)
English (en)
Inventor
Daniel DZABO
Dominik Kolb
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
You Mawo GmbH
Original Assignee
You Mawo GmbH
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by You Mawo GmbH filed Critical You Mawo GmbH
Publication of EP3894948A1 publication Critical patent/EP3894948A1/fr
Pending legal-status Critical Current

Links

Classifications

    • GPHYSICS
    • G06COMPUTING; CALCULATING OR COUNTING
    • G06TIMAGE DATA PROCESSING OR GENERATION, IN GENERAL
    • G06T17/00Three dimensional [3D] modelling, e.g. data description of 3D objects
    • G06T17/20Finite element generation, e.g. wire-frame surface description, tesselation
    • GPHYSICS
    • G02OPTICS
    • G02CSPECTACLES; SUNGLASSES OR GOGGLES INSOFAR AS THEY HAVE THE SAME FEATURES AS SPECTACLES; CONTACT LENSES
    • G02C13/00Assembling; Repairing; Cleaning
    • G02C13/003Measuring during assembly or fitting of spectacles
    • GPHYSICS
    • G02OPTICS
    • G02CSPECTACLES; SUNGLASSES OR GOGGLES INSOFAR AS THEY HAVE THE SAME FEATURES AS SPECTACLES; CONTACT LENSES
    • G02C13/00Assembling; Repairing; Cleaning
    • G02C13/003Measuring during assembly or fitting of spectacles
    • G02C13/005Measuring geometric parameters required to locate ophtalmic lenses in spectacles frames
    • GPHYSICS
    • G06COMPUTING; CALCULATING OR COUNTING
    • G06TIMAGE DATA PROCESSING OR GENERATION, IN GENERAL
    • G06T19/00Manipulating 3D models or images for computer graphics
    • G06T19/20Editing of 3D images, e.g. changing shapes or colours, aligning objects or positioning parts
    • GPHYSICS
    • G06COMPUTING; CALCULATING OR COUNTING
    • G06TIMAGE DATA PROCESSING OR GENERATION, IN GENERAL
    • G06T2219/00Indexing scheme for manipulating 3D models or images for computer graphics
    • G06T2219/20Indexing scheme for editing of 3D models
    • G06T2219/2021Shape modification

Definitions

  • the invention relates to a method for generating geometric data of an individualized object, in particular for further processing into manufacturing data for the manufacture of the object. It also relates to a computer program and a storage medium.
  • Spectacle frames made to measure and for the manufacture of such objects by additive manufacturing processes are known in principle.
  • US 9,810,927 B1 (3-D Frame Solutions) describes a method for generating a product specification for an adapted spectacle frame.
  • a library with fully parameterized standard models is accessed.
  • the models can be adapted using adaptation values, which include biometric data of the future carrier.
  • the product specification for manufacturing e.g. B. generated using a 3D printer.
  • FR 3 044 430 B1 discloses a method for producing an eyeglass frame with flat nose pads. First of all, spatial data of the face of the future wearer are recorded, a three-dimensional model of the spectacle frame is generated on this basis, and finally the frame is manufactured using an additive manufacturing process. When creating the three-dimensional model This is compared with a three-dimensional model of the face so that flattenings can be created as nose pads at the correct location.
  • US 9,470,91 B2 (Bespoke, Inc.) relates to systems and methods for the production of customized products.
  • an anatomical model of the user is first created based on a scan and / or measurement data.
  • a computer provides an adaptable product model and enables the preview as well as automatic or user-controlled adaptation of the product model.
  • the model can finally be sent to a manufacturer.
  • the product model can be represented by a surface grid or a solid-state model which has elements or features which, for. B. polygons, curved elements or the like.
  • US 2015/0127132 A1 (West Coast Vision Labs Inc.) describes a system and a method for producing customized eyeglass frames, the geometry generated being usable for modeling, manufacturing and printing.
  • a template with predetermined dimensions is assumed. These can then be adapted based on multidimensional data of the wearer's head and several identified orientation points of this data.
  • the geometry is represented by a polygon model. The adaptation is done through a morphing process.
  • the design of the eyeglass frame is essentially known at the beginning of the process.
  • the adjustments made concern the fit of the glasses on the wearer's head.
  • US 2017/0038767 A 1 (Materiaiise NV) relates to the adaptation of the geometry of objects, e.g. B. glasses frames or wristwatches, which are produced by means of 3d printing techniques.
  • the adaptation by the users takes place within the limits specified by the manufacturers. The limits can in particular differ Factors arise that affect the printability of an adapted geometry.
  • the adjustment tools are adapted to the object to be manufactured. For this purpose, customizable zones are defined as part of the basic model and graphic operating elements (e.g. sliding bars) are assigned for the corresponding adjustments. As part of the design of a basic model, the corresponding adjustment options are defined. In addition to the actual product design, the designer must always identify and implement the possible adjustments. This generates additional workload and requires additional knowledge and skills or the involvement of a specialist if more complex adjustments are to be made possible.
  • the object of the invention is to create a method belonging to the technical field mentioned at the beginning for generating geometric data of an individualized object, which enables the simple creation of new, flexibly parametrically adaptable designs of the individualized object.
  • the method for generating geometric data of an individualized object comprises the following steps:
  • the polygon model comprising a network formed from network elements, the network elements being discrete points,
  • edges and surfaces that represent a geometric initial shape of the object; wherein the polygon model comprises local attributes which are assigned to at least some of the network elements and relate to at least one belonging to one of several adaptation groups or parameters for a deformation process;
  • fitting tools are defined in such a way that when they are applied to the network, a topology of the network is retained and that when they are used, the local attributes of the network elements of the area are evaluated in order to determine a measure of local deformation; and c) fitting the polygon model using the fitting tools.
  • the process is a computer-aided or computer-implemented process, which is carried out by appropriate software on suitable computers and machines.
  • the invention accordingly comprises a computer program which is adapted such that it carries out the method according to the invention, and a (non-volatile) storage medium comprising such a computer program.
  • the computer program can comprise several modules, which are executed on different devices, which are geographically spaced from one another and are connected to one another via a data network.
  • the polygon model represents the geometry of a physical product, especially with regard to its manufacture after customization (customization), e.g. B. by automated manufacturing processes (additive manufacturing, subtractive manufacturing).
  • customization e.g. B. by automated manufacturing processes (additive manufacturing, subtractive manufacturing).
  • adapted polygon model can also form the basis for semi-automated or manual manufacturing processes.
  • the object is represented by a network of polygons formed from network elements.
  • these elements can represent the polygon model or they can be derived directly and clearly from the stored data.
  • Basic information such as position, orientation and neighboring elements are assigned to each individual element.
  • At least some of the network elements are also assigned additional data fields which relate to at least one of several adaptation groups or parameters for a deformation process. There may thus be network elements which are not local Attributes are assigned as well as those to which at least one local attribute is assigned.
  • the assigned attribute can belong to at least one of several adaptation groups, parameters for a deformation process or other attributes.
  • a network element can be provided with attributes for belonging as well as for the deformation process.
  • a plurality of network elements are preferably provided with attributes for belonging and several network elements with attributes for the deformation process, some of these network elements being assigned both attributes.
  • the polygon model thus defines - including attributes - a parametric shape of the object whose geometry data are to be generated.
  • Polygon models are known in particular from 3D computer graphics, such as those used for. B. is used in the context of computer game software for real-time creation of animated graphics. Hardware components that specifically support corresponding processing steps are commercially available (e.g. corresponding graphics chips).
  • Model parameters are set to specified values.
  • adjustment steps are carried out from a set of predefined adjustment tools.
  • defined functions which calculate the deformation of the polygon model for a desired parameter change, correspond to the several adaptation tools provided in the set and the adaptation steps carried out therewith.
  • the changes in the polygon model and thus the object geometry caused by the adjustment tools are constant.
  • the parameters of the adaptation tools can preferably be set as precisely as desired and not only in discrete steps.
  • the topology of the mesh is matched to the subsequent procedures that change the mesh, especially the deformations that are caused by the fitting tools.
  • the adjustment tools that act on certain areas of the object expect them to have a certain polygon topology structure.
  • the position of the elements of the mesh is read, deformed by the function and then saved again.
  • the attributes stored for each mesh element are included to calculate the respective deformation.
  • the combination of a polygon model with local attributes and predefined adaptation tools enables a completely automated and data-controlled assignment of the relation of model areas or elements to deformation procedures. This means that in addition to the definition of the adaptation tools and certain local attributes, there is no explicit definition of the
  • model parameters are adjusted proportionally to one another - unless a change in the overall shape is to be brought about specifically - in order to best preserve the overall shape of the object.
  • Topology of a polygon model is understood here to mean the number and mutual arrangement of the elements of the polygon network (nodes, edges and surfaces).
  • the polygon model is only deformed, no elements are added or removed. Accordingly, only the position data of the elements of the polygon mesh have to be adjusted. This considerably reduces the computational effort for the adjustment and enables adjustment in real time.
  • Structures of the object e.g. receiving openings, connecting elements, etc.
  • structures of the object often have a precisely predetermined geometry, so that these elements are adapted makes little sense anyway in the context of the adjustment process. This would mean that the geometry of the structures would be incorporated into the adaptation process as a fixed default or that further adjustments would be necessary after the actual adaptation process in order to ensure the correct geometry of the structures for the interaction. It is therefore easier and more efficient to do this
  • the method according to the invention is suitable for generating geometry data of different individualized objects, e.g. B. glasses, hearing aid cases, shoes, wristwatches, insoles, prostheses, orthoses, etc.
  • a polygon model on the one hand and a set of predefined adaptation tools, on the other hand, enables a platform solution in which basic models for certain object types can be provided as part of a design component. These each include a polygon model and the associated set of predefined fitting tools.
  • a designer can create a product design based on a selected basic model without having to worry about the adaptation tools. Thanks to the assigned, unchanged adaptation tools, the result is automatically available as a parametrically adaptable object and can therefore be used in an adaptation component of the platform for individual adaptation without further measures.
  • Once a basic model has been defined with the associated adaptation tools, it can be used for a large number of designs of a certain object type. Designers can independently create parametrically changeable product designs within the scope of the method according to the invention.
  • the geometry data can be processed further into production data for the production of the object.
  • the production data define the geometry of the individualized object in accordance with the result of the adaptation process and, if appropriate, of further elements of a product which comprises the object, in particular those further elements which can be produced automatically.
  • the manufacturing data are intended in particular for the subsequent additive manufacturing.
  • the manufacturing data also include data that are intended for different manufacturing processes (e.g. CNC milling, grinding, etc.).
  • Additive manufacturing (3D printing, e.g. laser sintering) enables the automated production of moldings from different materials and, if necessary, with complex shapes.
  • Devices for additive manufacturing are available in various price and quality classes and can be operated decentrally. Prerequisites for their function are essentially access to the required manufacturing data and the provision of the required raw materials.
  • the manufacturing data can also include further data for other manufacturing steps. Only a subset of the manufacturing data is therefore required for additive manufacturing.
  • the system can obtain data in industry-typical formats for storing polygon networks such as STL, OBJ or PLY from the polygon model and / or refined polygon models derived from it.
  • the system can also advantageously generate and export spline curves and surfaces from the polygon model and / or refined polygon models derived therefrom, which are suitable for production systems that require such representation models for objects.
  • instruction data sets for producing the 3D model e.g. B. machine-specific G-code for the control of 3D printers or milling.
  • the various export options make it possible to manufacture individualized objects in different materials that require different production processes and therefore different data exchange formats.
  • the manufacturing dates are digitally forwarded to the hardware that produces the object for the production process, in particular via a computer network (WAN or LAN).
  • the system has interfaces to save the production data generated in a customer portal or to transmit it directly to the manufacturing partner via a corresponding program interface.
  • system can automatically output dimensioned technical drawings that document the adjustment process and support the production process.
  • the manufacturing data are based on the fully adapted polygon model. Are they used as part of an interactive process to issue a physical prototype, e.g. B. for trying on by the end customer, they can be based on a partially adapted polygon model.
  • the following steps are preferably carried out to provide the polygon model: a 1) Providing a basic polygon model for an object type of the individualized object, at least some network elements of the
  • Polygon basic model are assigned local attributes that indicate belonging to one of several adaptation groups; a2) Provision of the set of predefined adaptation tools assigned to the basic polygon model for deforming the polygon model derived from the basic polygon model, the adaptation tools being adapted to the object type and at least some of the adaptation tools evaluating the local attributes when used, which indicate the affiliation to the adaptation groups ; a3) Modeling the basic polygon model in order to obtain the polygon model, wherein a topology of the basic polygon model remains unchanged, the local attributes being changed as necessary, while maintaining a set and definition of the several adaptation groups. In this way, the polygon model can be obtained, which forms the starting point for the subsequent adaptation steps for generating the geometry data of the individualized object.
  • the basic polygon model represents a general template (template, blueprint), which has the basic topology of the object type.
  • template blueprint
  • a possible polygon basic model for the "glasses frame” type of object has elements which represent two glass receptacles, a web connecting them and cheeks arranged on the outside of the glass receptacles for fastening hinges for eyeglass temples.
  • a different basic model is provided for glasses with a double bridge.
  • the mesh on which the basic polygon model is based is optimized in such a way that it comprises a sufficient number but not unnecessary points, edges and surfaces to represent the conceivable geometries of the object according to the object type and to cover all required deformations.
  • Network elements of the basic polygon model are already assigned local attributes. These are at least partially also initialized with input values, e.g. B. with semantic assignments, especially to adaptation groups.
  • the local attributes thus indicate, for example, to which functional component of an object certain sub-areas of the geometry belong. This information can later be used in the adaptation, e.g. B. to - as described in more detail below - to limit the impact of certain adjustment tools on predetermined components of the object.
  • the aesthetic shaping or the adaptation to the individualization of the object follows only in the later step of modeling, after the provision of the adaptation tools.
  • object type glasses, implant, orthosis, prosthesis, shoe, etc.
  • very few basic polygon models and associated sets of adjustment tools are required.
  • the modeling can be done with common design tools and can be carried out, for example, by a specialist (designer).
  • the design tools include, for example, procedures for automatically smoothing, distributing and aligning the existing polygon topology.
  • tools can be made available within the scope of the method according to the invention which are tailored to the needs of the object type. These can be based on tools from the set of predefined fitting tools, or can be provided specifically for modeling. In general, there are more degrees of freedom in modeling than in the subsequent adjustment to individualize the object.
  • Modeling is intended to create an aesthetically appealing and ergonomically advantageous shape. This step enables a large number of product designs to be derived from a single basic polygon model.
  • the assignments of the network elements of the basic model to adaptation groups and any other local attributes can usually be retained. They can also be taken into account in the modeling process if, for example, B. only an area of the three-dimensional shape is to be adapted.
  • local attributes can also be adapted or other network elements can be provided with local attributes. For example, a desired rounding of an edge can be changed as part of the modeling if a rounder or more angular shape is desired.
  • the changeability of the local attributes and the types of the attributes that can be added are defined in such a way that the adaptation tools assigned to the basic polygon model can work with the polygon models that are generated during the modeling process. H. interpret all attributes correctly and take them into account when applying them to the polygon model. As a rule, the same set of adjustment tools can be applied to every polygon model that results from the same basic polygon model. The designer does not have to worry about the adjustment tools, but can focus on the actual design process.
  • the designer works on the polygon mesh of the basic polygon model. If the possibility of a Given a virtual preview, this can also be used during modeling so that the designer can check the result of all adjustments that are made later in the course of the further process steps. In this way, he can easily ensure that the adapted polygon models also meet his design and functional ideas.
  • the modeling process does not necessarily have to be based on a basic polygon model, it can also be based on a polygon model that has already been modeled, because the topology of this polygon model corresponds to that of the basic polygon model, the adjustment tools are the same, and there are no irreversible transformations in the context of modeling.
  • the adjustment of the polygon model can be done fully automatically, based on input data. Based on the current polygon model (including local and global attributes) and the input data mentioned, the adaptation tools are therefore applied to the polygon model fully automatically, so that an adapted polygon model results.
  • the individual adaptation of the geometry of an object can take place at any time, regardless of the availability of expert personnel. If the combination of adaptation of the polygon model and preparation of image data can be done in a few seconds or faster, so to speak in real time, a virtual try-on is required during the adaptation process up to the definition of the perfectly fitting geometry, e.g. B. possible based on the feedback from the future user or carrier.
  • Process steps that require the aesthetic evaluation by a user are therefore preferably semi-automated in that the user provides inputs and makes decisions, which, however, are supported and partially automated by the computing means as well as possible.
  • the input data preferably comprise processing data which are obtained from geometric information relating to a counterpart of the object. This enables a fully or partially automatic adaptation of the object geometry with regard to an aesthetic appearance of the combination of the object and the counterpart and / or with regard to a good fit of the object, that is to say the best possible ergonomics.
  • the geometry information is obtained in particular from a three-dimensional image of a body region of a person.
  • a three-dimensional image of a body region of a person For example, an image of the head of the person is used when adapting an eyeglass frame, an image of the ear region when adapting a hearing device housing and an image of the person's feet when adapting shoes.
  • a three-dimensional image of the body region means an accurate image of the corresponding surface, including depth information.
  • the three-dimensional image can be captured directly by using an imaging technology that can directly capture the three-dimensional shape.
  • the detection can also be done indirectly, e.g. B. by appropriately offsetting several two-dimensional images from different perspectives.
  • the detection can also consist of receiving raw data for generating the three-dimensional image or data already obtained or prepared three-dimensionally from an external source via a suitable interface.
  • Suitable technologies for obtaining three-dimensional images are known in principle. For example, runtime-based systems (TOF cameras), stereoscopic systems or triangulation or interferometric systems exist for direct acquisition. Light field cameras can also be used. The indirect calculation can be based on raw data from common (digital) cameras.
  • TOF cameras runtime-based systems
  • stereoscopic systems or triangulation or interferometric systems exist for direct acquisition.
  • Light field cameras can also be used.
  • the indirect calculation can be based on raw data from common (digital) cameras.
  • images of the same region can be captured and processed, e.g. B. multiple frames of a video recording. This increases the precision that can be achieved.
  • images can also be recorded which show different facial expressions - to ensure that the individualized object (e.g. glasses) fits in different situations and looks aesthetic. If a foot is detected, it can be detected in various positions of the foot (flat, on ten tips, etc.) in order to obtain additional physiological information with regard to the fitting of a shoe.
  • a plurality of orientation points on the body region of the person are preferably identified and their position is stored.
  • the orientation points are identified on the basis of the image, after identification they are transferred to the three-dimensional polygon model, marked and saved.
  • the body region of the person is thereby measured, and features relevant for the adaptation of the object are made available for the further automated processing of the data. They are used in particular for automatic positioning and orientation of the three-dimensional image and the subsequent automated adaptation of the polygon model.
  • program libraries or SDKs software development kits
  • the processing data are preferably obtained from the geometry information using a process based on machine learning.
  • Such processes machine learning, ML
  • ML machine learning
  • the automatic processing e.g. classification
  • the quality of processing is continuously increased.
  • the use of the ML process allows the iterations required to be continuously reduced until the polygon model represents the object geometry desired by the user.
  • the ML process can be used on the one hand to recommend an initial design that fits the physiognomy of the future wearer, and on the other hand to automatically adapt the shape and positioning of the polygon model to the physiognomy during the subsequent modeling, e.g. B. based on the identified landmarks.
  • Suitable ML algorithms are based, for example, on Support Vector Machines (SVM) or artificial neural networks.
  • SVM Support Vector Machines
  • ML processes based on supervised learning are likely to be used.
  • the ML process is advantageously based on a large number of training data from three-dimensional images of a large number of people and associated, adapted polygon models.
  • the data required for the application of the corresponding ML process are thus obtained from the three-dimensional images of the first data (e.g. the orientation points) (and possibly second data, if available and useful) and the polygon models ultimately generated, i.e. H. the model parameter values which represent these adapted models.
  • Other data sources are possible - for example, available photographs that show the counterpart of the object together with the object (e.g. the face of people with glasses on) and in which the object geometry of people or a suitable algorithm is judged to match the counterpart , are used as training data. It is also possible to use "negative" training data, which represent poor adaptation of an object.
  • the initial training data are preferably based on a manual or semi-automatic adaptation of objects of the corresponding object type, e.g. B. in the context of a computer-aided adjustment process with a virtual try-on, but the adjustment of the model was carried out manually by an operator. Only the parameters of accepted models are used for training the ML algorithm. If there is a sufficient number of assignments between 3D images and accepted polygon models (e.g. at least 100, preferably at least 500), the trained ML algorithm can already significantly improve the adaptation process. Under certain circumstances, it is then even possible to carry out the adaptation without feedback on the content of the user as part of a virtual try-on, i.e. without the output of image data from an overlay of the adapted and refined polygon model with a view of the counterpart, because there is a sufficiently high level of certainty that the fully automatically adjusted object fits perfectly.
  • a sufficient number of assignments between 3D images and accepted polygon models e.g. at least 100, preferably at least 500
  • the machine learning process is furthermore advantageously based on property data of the person, in particular an age, a gender, an ethnic origin and / or preference details of the person. Based on this, the person can be assigned to a target group. From the training data it is known which preferences in relation to the individualized object and, if necessary, the adaptation the corresponding target group has. Accordingly, the selection of the basic model and / or the automated adaptation of the polygon model can be adapted according to these preferences.
  • Belonging to the adaptation group can in particular indicate belonging to a spatial area of the polygon model, that is to say to a three-dimensional area.
  • Adaptation tools can make deformation of network elements dependent, in particular, on whether they are assigned to this spatial area. For example, an adaptation tool can selectively influence only those network elements that belong to a specific aesthetic and / or functional subunit of the object.
  • the set of predefined adaptation tools advantageously comprises at least one local adaptation tool, the application of which to the polygon model only influences a local area of the model and leaves all areas outside of this local area unaffected.
  • a local adjustment tool affects in particular only a specific element of the object.
  • the localization of the adjustment tools can be achieved by assigning the elements of the polygon network to belonging to one or more groups.
  • the groups can be assigned as a binary bit field (0: not part of the group; 1: part of the group) to every element of the mesh.
  • the groups thus serve as masks in order to limit the deformations to certain regions of the mesh in the adaptation process.
  • Belonging to the adaptation group can in particular indicate belonging to a guide curve of the polygon model, that is to say to a two-dimensional (connected) line.
  • Such guidance curves place conditions on the adjustment steps carried out in the course of the adjustment process with the appropriate adjustment tools, for example the curvature or the position of an inflection point of the guidance curve should (largely) be retained within the scope of such an adjustment.
  • the adaptation tools are preferably predefined and are used in such a way that predetermined guide curves of the model are retained as best as possible. As a result, the transition to the surrounding areas of the modeled object is always automatically adapted as part of each local deformation.
  • the guidance curves can also be used as part of a user guidance: For example, a user can influence the geometry represented by the polygon model by specifically influencing parameters such as curvatures or positions of turning points or other reference points along a guidance curve. It may also be possible to display two-dimensional projections on levels in which the main curves run. Correspondingly, changes can be made to the geometry in the context of the representation of such projections. Similarly, guide curves can also be used for the automatic adaptation of the polygon model.
  • Guide curves can also be used if the polygon model is to be refined by doing this fully automatically so that the refined polygon model follows the guide curve of the starting polygon model.
  • Fine adjustment is carried out in particular after the geometry of the object has been adapted as part of the adaptation process. It is based in particular on knowledge of the properties of the algorithms used for the subdivision steps. Remaining degrees of freedom, in particular with regard to the positioning of the polygon nodes, can be used to select positions within the framework of the polygon model that lead to an advantageous local geometry of the polygon mesh in the subsequent subdivision.
  • Belonging to the adaptation group can in particular also show a reference point of the polygon model.
  • Such reference points can be assigned fixed positions, for example, or they correspond to known positions of the counterpart to which the geometry of the object is to be adapted.
  • Such reference points also impose conditions on the adaptation steps carried out as part of the adaptation process using the appropriate adaptation tools, for example the position of a reference point should remain unchanged.
  • the parameter for the deformation process can in particular indicate a radius for an edge rounding or a deformation weight.
  • the corresponding values are taken into account by the adaptation tools when defining the deformations to be carried out.
  • At least one of the adaptation tools can thus determine a degree of deformation.
  • the extent can be determined absolutely or relative to other variables, or lower and / or upper limits for the deformation are derived.
  • Several local and / or global attributes can be used to define the extent of the deformation for each network element. If necessary, local attributes are also used which are assigned to other network elements (e.g. in the vicinity of the network element directly affected). However, a definition of is preferred local attributes and the adaptation tools such that, in addition to the global attributes, only the local attributes assigned to the network element concerned have to be included.
  • the at least one adaptation tool limits a maximum deformation for network elements which belong to a guide curve of the polygon model or form a reference point of the polygon model.
  • the restriction means that the permissible deformation is in particular smaller than for other network elements in the area.
  • the limitation can be relative (compared to other deformations) or absolute. It can also make certain adjustments to affected network elements entirely impossible, as mentioned above in connection with reference points.
  • the local attributes which are assigned to a network element of the polygon model, can advantageously indicate the affiliation to several adaptation groups, in particular the affiliation to several spatial areas of the polygon model.
  • the local attributes can indicate the affiliation to several adaptation groups of the same class (e.g. guide curve or spatial area).
  • z. B. enables areas to overlap and intersect guiding curves, which increases the flexibility with regard to the possible specifications for the geometry and enables the definition of different affiliations for different adaptation tools.
  • the definition and combination of overlapping adaptation groups creates relationships between the individual sub-areas of an object. These are used in the data-controlled, automated adaptation of all areas of the object, in that the adaptation tools automatically take into account the interaction of influencing areas of the polygon network in the deformation calculations during the deformation.
  • an adaptation tool for a network element that belongs to several adaptation groups determines a first partial deformation due to belonging to a first of the adaptation groups and a second partial formation due to belonging to a second of the adaptation groups, and a deformation applied to the network element becomes from the first Partial deformation and the second partial deformation derived.
  • a Adaptation tool which acts on several adaptation groups, also performs the desired deformation in overlapping areas.
  • the derivation can be carried out in different ways, so the deformations can be carried out in the manner of a convolution (if necessary with a predetermined order) or the deformation represents an average of the two partial deformations.
  • the adaptation steps are preferably carried out using the adaptation tools from the set of predefined adaptation tools according to predefined rules and with predefined priorities.
  • the predetermined priorities result from a predetermined sequence and / or are determined by a predetermined decision scheme depending on input parameters.
  • the method according to the invention for generating geometric data of an individualized object can be used in particular in a method for generating production data for an individualized object for a person, which comprises the following steps: a) acquiring at least one three-dimensional image of a body region of a person; b) generating input data from the three-dimensional image; c) providing the polygon model and the set of predefined fitting tools according to the method according to the invention; d) adapting the polygon model based on the input data; e) outputting image data of an overlay of the adapted polygon model with a view of the body region of the person; and f) outputting the production data generated from the adapted polygon model.
  • a system for generating production data for producing an individualized object for a person accordingly preferably comprises a) a camera for taking one or more images of a body region of the person; b) a first processing module for generating a three-dimensional image of the body region from the one or more images;
  • a second processing module for generating input data from the three-dimensional image
  • a modeling module for providing a polygon model for the object to be manufactured
  • an adaptation module for automatically generating adaptation data for the modeling module on the basis of the input data
  • an image output module for outputting image data of an overlay of the model with the one or more images of the body region of the person
  • an output device for receiving and displaying the output image data
  • a third processing module for generating manufacturing data from the polygon model
  • the camera can be a still or video camera, the term "camera” including all conceivable image capture devices.
  • the camera is part of a mobile device (e.g. smartphones or tablets). It preferably has the ability to directly capture three-dimensional images, e.g. B. based on integrated infrared sensors for depth measurement. This means that there is no need for dedicated additional recording devices; the customer or a service provider can use an existing device or one that is commercially available without further and relatively inexpensive.
  • the edges of the object can be rounded after adaptation. The rounding takes place depending on the angle of the adjacent surfaces of the edges to be rounded.
  • the polygon model is then positioned appropriately in relation to the image or images of the body region.
  • the output of the image data can directly include the display on an output device, but as a rule the image data (in a form suitable for immediate output or as precursor data that can be further processed to image data) are transmitted to a terminal device arranged at a distance and displayed there. This transmission takes place in particular via a computer network (WAN or LAN).
  • the images can ultimately be output statically or in motion (video overlay).
  • Steps d) and e) of the method and the manual input of data are preferably carried out in a cycle until the user accepts the current model and releases it for production.
  • the manufacturing data are then generated.
  • the cycle can include other steps. In this way, a sample of the item can be produced and tried on. Depending on the result of the try-on, this can in turn result in second data which are incorporated into the further adjustment.
  • the adaptation process can in particular be carried out fully automatically, as a result of which the configuration and ordering of an individualized object can take place at any time, regardless of the availability of skilled personnel. Because the combination of parameter adjustment and preparation of the image data can take place in a few seconds or faster, i.e. in real time, so to speak, the virtual try-on during the ordering process and the execution of several iterations up to the definition of the perfectly matching item are based on the feedback from the future wearer or user, easily possible.
  • the method according to the invention can be completely supported by the customer on state-of-the-art devices such as smartphones or tablets, wherein a specific app or a web-based application in the browser can be used.
  • the method according to the invention is preferably controlled and the system according to the invention is so blanked out that the following steps can take place in a fully automated manner and do not require any manual actions on the part of the service provider:
  • a system for producing an individualized object for a person preferably comprises the described system for generating production data and a first device for additively producing the at least one element of the object to be produced using the output production data.
  • the polygon model is preferably provided and adapted with a first density of a polygon mesh.
  • the polygon model is then transformed by at least a first subdivision step into a first refined polygon model with a second density of the polygon mesh, the second density being higher than the first density, and for outputting the production data, the polygon model is then transformed by at least a second Subdivision step transformed into a second refined polygon model with a third density of the polygon mesh, the third density being equal to or higher than the second density.
  • the image data for output are thus generated from the original, partially or completely adapted polygon model, preferably in real time, i.e. H. so that adjustments made are updated without any additional request from the user and without any noticeable delay in the display of the individualized object with the view of the body region of the person.
  • the system preferably comprises a transformation module for transforming the polygon model into a first refined polygon model with a second density of the polygon mesh, the second density being higher than the first density and for transforming the polygon model into a second refined polygon model having a third density of the mesh, the third density being equal to or higher than the second density.
  • the polygon model is initially provided with the first density.
  • the image output module is then based on the first refined polygon model, the third processing module is based on the second refined polygon model.
  • the manufacturing data encode additive manufacturing using several different materials.
  • the materials can differ from one another in terms of material parameters, colors and / or additives.
  • the different materials can preferably be used in the same additive manufacturing process. This enables the production of homogeneous objects "from a single source” that have heterogeneous material properties. This makes it possible, for example, to implement hinge solutions not only on a geometric basis, but also through material distribution in the object. The possibilities of multi-material printing can be taken into account when parameterizing the object during the adaptation process.
  • an assignment step is preferably carried out automatically in order to assign different materials to different areas of the object to be produced.
  • This enables a fully automatic and efficient generation of the manufacturing data.
  • Information about a different materialization and / or about different manufacturing processes can be obtained solely through the assignment step, or they are already coded in whole or in part in the local attributes of the polygon model.
  • the method advantageously includes the further step of manually entering further input data, these further input data being used when adapting the polygon model.
  • Such manual entries can be made, for example, directly from the future wearer or user of the individualized item or from a consulting service provider or a specialist (e.g. an optician, a hearing aid mechanic, a shoemaker, etc.) who is with the person or live with them communicates (e.g. via a video chat).
  • the manually entered further input data relate, for example, to preferences (fashion style, color, material, price range) in relation to the item to be manufactured or to additional information which is required for generating the manufacturing data.
  • Additional input data can also be based on the fact that certain dimensions of the body region are first determined using special instruments. Core parameters can then be obtained from this. This detection represents an alternative to the extraction from the processing data. However, the dimensions can also be used to calibrate the recorded 3D image or the processing data generated therefrom, as a result of which the manufacturing precision can be increased considerably.
  • An alternative is the simultaneous image recording of the body region with a reference object (eg a measuring tape). Certain devices and methods are also able to take absolute distance or position measurements without such additional measures.
  • the further input data can preferably be entered after the image data has been output, after which steps d) and e) are dependent on the further input data run again.
  • the future carrier or the consulting service provider (or another person) can thus provide feedback on the current design of the individualized object in accordance with the current polygon model. This can consist of a simple YES / NO answer or several YES / NO answers to various questions, but it can also contain specific influencing parameters - for example, the person entering the item can select and influence elements of the object using a graphical user interface.
  • User interface can provide, for example, that the user can "pull” on elements of the object in order to directly influence their dimensioning and / or shape.
  • sliders can be provided with which the user can influence certain aspects (dimensions, fillets, colors, etc.). From this, input data are generated that correspond to an adaptation of a parameter of the polygon model.
  • second data are recorded manually both before and after the first display.
  • the first entry concerns general preferences and
  • the other entries concern feedback on the current status of the adjustment.
  • another person e.g. on the part of the consulting service provider or the manufacturer
  • the set of predefined adjustment tools preferably comprises several of the adjustment tools described below by way of example: a. an adaptation tool for changing at least one dimension of a nose bridge of the glasses to be produced.
  • Such an adjustment tool can influence one or more of the following properties:
  • Bridge width The width of the nose bridge is increased or decreased.
  • the frame thickness does not change.
  • the total width of the frame front is reduced by the amount of change in the nose bridge, so the overall width of the glasses front remains unchanged.
  • Depth of the nose bridge The depth of the nose bridge is increased or decreased. The remaining thickness of the frame is not changed.
  • Width of the nose bridge in the lower part This can be increased or decreased separately. This changes the angle of the nose pad. The entire width of the nose bridge remains unchanged and the width of the frame front does not change as a result.
  • an adaptation tool for changing at least one overall dimension of the glasses front e.g. the front width and / or front height
  • the shape of the glass opening and thus the shape of the lens adapt accordingly.
  • the width of the nose bridge does not change and the design of the glasses is retained.
  • the depth of the frame can optionally be changed.
  • an adjustment tool for influencing a base curve The base curve relates to the curvature of the lens glass and thus also the geometry of the frame.
  • the base curve corresponds to a projection of the spectacle frame onto spheres with defined ones
  • Radii for the different base curves The center of the sphere that is being projected is positioned in the optical center of the lens.
  • the base curve can be increased or decreased with the adjustment tool.
  • the strength of the frame is retained.
  • the width of the eyeglass frame is also retained since the projection is realized by shearing the shape into the depth of the sphere.
  • an adaptation tool for changing a geometry of a glass groove for receiving a lens glass The glass groove fixes the lens in the frame. Their geometry can be either round or pointed.
  • the groove depth can also be changed.
  • the temple Since the temple is connected to the cheek by a hinge, this results in a change in the angle of the temple relative to the front of the glasses. On the one hand, the angle of the ironing step can be changed. Only the cheek of the glasses frame is changed. The glasses front remains unchanged.
  • the inclination can be increased and decreased.
  • the front of the glasses is rotated around a point on the glasses cheek.
  • the eyeglass temples remain unchanged.
  • the overall shape, height, depth and angle of the nose pad can be changed. All other dimensions of the frame are not affected.
  • the nose pad can also be changed so that there is no more pad on the frame. In this case, holes are provided in the lower area of the nose bridge, which make it possible to attach metal bars with silicone nose pads after production.
  • the length of the bracket can be increased or decreased.
  • the version remains unaffected.
  • the bracket can be bent at the end of the bracket. You can do this with another adjustment tool
  • Position of the bend, the bend angle and the radius of the bend can be influenced.
  • the version remains unaffected.
  • the rounding of the eyeglass frame in the lower frame area from nose bridge to eyeglass cheek can be increased with a further adjustment tool. This is necessary for the stability of certain glasses models.
  • the order of the adjustment tools can be specified, for example, as follows: width of the bridge - depth of the bridge - frame size - width of the bridge in the lower part - modification of the upper, inner part of the glass opening - radius shaped glass - base curve - glass groove - bracket angle - inclination - rounding glasses frame - nose pad - temple length - temple crease. This ensures that the effects of a subsequent adjustment step in the corresponding iteration do not require (renewed) adjustments with an adjustment tool previously used in this iteration, regardless of the adjustments made.
  • the method according to the invention preferably comprises the additional step of defining openings for attaching further elements in the polygon model.
  • these openings are used, for example, for fastening a hinge or the fastening elements of a metal / silicone nose pad.
  • the other elements are advantageously simulated together with the object, so that the adjustment process and the definition of the openings result in correct alignment and positioning of the further elements in the assembled object.
  • Figure 1 is a schematic representation of the process phases of a method according to the invention for generating geometry data and for further processing to manufacturing data and the corresponding data model.
  • 2 shows a schematic representation of an overall system according to the invention for generating geometry and production data and for producing an individualized object;
  • 3 shows a schematic representation of a system according to the invention for the manufacture of custom-made glasses;
  • FIG. 4 shows a flowchart for the schematic representation of the sequence of a method according to the invention for the manufacture of custom-made glasses
  • 5A-F are schematic representations of the orientation points and the definition of the world coordinate system used
  • Spectacle frame 10 is a flowchart of the parameter adjustment process; Fig. 1 1-20 representations of the glasses frame to explain the parameter adjustment functions; and
  • Polygon mesh in a refined polygon mesh for the display and a refined and further processed polygon mesh for the additive manufacturing.
  • FIG. 1 is a schematic representation of the process phases of a process according to the invention for generating geometry data and for further processing to manufacturing data and the corresponding data model.
  • FIG. 2 is a schematic illustration of an overall system according to the invention for generating geometry and production data and for producing an individualized object.
  • a basic polygon model 61 which corresponds to the object type of the individualized object to be produced, and a set of adaptation tools 71 assigned to the basic polygon model 61 are provided.
  • the basic polygon model 61 includes, for example, network elements 62.1, 62.2, ..., 62.5 and assigned local attributes 63.1.1, 63.3.2.
  • the set of adaptation tools 71 comprises several adaptation tools 71.1, 71.2 etc.
  • the adaptation tools 71.1, 71.2 are adapted to the basic polygon model 61 in such a way that the data of the network elements 62.1 ... 5 can be processed depending on the local attributes 63 and further input data .
  • Tools 95 for modeling the basic polygon model 61 are also provided. These tools include both standard tools 95.1, 95.2, 95.3, e.g. B. for smoothing, distributing or aligning or for generic changes in shape, as well as tools specifically aligned to the polygon basic model 61 of the object type 95.4, 95.5. There is also an interface to the adaptation tools 71 .1, 71.2 of the set of adaptation tools 71, so that these tools (or some of them) or derivations that use these tools are also used by the designer as part of the modeling on the basic polygon model 61 can be.
  • a first service provider 80 provides one or more basic polygon models, the assigned sets of adaptation tools, the tools 95 and the storage in a database 81.
  • a designer 82 Based on the basic polygon model 61 from the database 81, a designer 82 creates an initial polygon model 64 (modeling process 91) by changing the network elements 65.1 ... 5, in particular the position of the individual network nodes, by means of common tools in order to achieve a desired shape of the represented object. He can also add or adjust local attributes 66.3.1, 66.4.1, e.g. B. to determine the desired edge rounding or to change the affiliation of certain sections of the polygon mesh to adjustment areas. Further local attributes 66.1.1, 66.3.2 are identical to those of the basic polygon model 61. The associated set of adjustment tools 71 remains unchanged.
  • the initial polygon model 64 is stored in a database 83.
  • this database 83 comprises a whole series of polygon models which represent different design variants (models) of an object of a certain type. All of these design variants have the same adaptation tools in common, whereby certain adaptation tools are at most ineffective for a specific variant due to the appropriate setting of local and / or global attributes, because they are intended, for example, to process an optional element that is missing in the variant concerned or because the corresponding one Degree of freedom from designer 82 is deliberately not released, e.g. B. because through appropriate adjustments the basic character of the design variant would be lost.
  • the adaptation of the polygon model 64 takes place in an adaptation process 92.
  • This is described in more detail below in connection with a system and method for producing a pair of custom-made glasses.
  • a polygon model 64 with the desired look and / or functionality is first selected and loaded from the database 83.
  • the adaptation tools 71 are then used to adapt the network elements 65.1 ... 5 of the selected polygon model 64, in particular to change the positions of the network nodes.
  • Local attributes 66.3.2 can also be changed selectively, e.g. B. affect an edge rounding to make edges rounder or more angular.
  • the adaptation of the polygon model 64 is based, on the one hand, on input data, which are derived from a three-dimensional image 75 of a counterpart (e.g. a body region of a future bearer or user) can be obtained by a machine learning process 93, on the other hand on input data 76, which additionally flow into the adaptation process, e.g. B. manually entered feedback from the carrier or user or another operator.
  • the user receives a virtual preview of the object according to the current adaptation. This advantageously also shows the counterpart (e.g. a body region) to which the object is to be adapted.
  • a server 100 of a service provider communicates with a computer 200 which is arranged at a distance from the server 100, e.g. B. at the future wearer or user or in the business premises of a provider (e.g. an optician, a hearing aid or shoe store).
  • the computer 200 has a keyboard 201 (and further input devices) and a screen 202. It is also connected to a 3D-capable camera 210 and a local 3D printer 220 for producing test prints.
  • the computer 200 and thus the peripheral devices connected to it communicate with the server 100 via a suitable interface of the computer 200, a data network (for example the Internet, via a connection secured, for example, with TLS) and an interface of the server 100.
  • the computer 200 with keyboard 201 (or other input device) and screen 202 on the one hand and the 3D-capable camera 210 can be integrated in the same terminal, in particular a tablet computer or a smartphone.
  • Manufacturing data 68 can then be obtained from this by means of a processing step 94. These primarily represent the shape of the object according to the network elements of the polygon model 67. As described further below, however, the resolution can be refined compared to the polygon model used for the adaptation process 92, i. H. there are more network elements.
  • the manufacturing data 68 are then transmitted to one or more manufacturers 300. Ultimately, these deliver the manufactured product directly or indirectly to the wearer or user of the individualized object.
  • FIG. 3 is a schematic illustration of a system according to the invention for the production of made-to-measure glasses. Are shown in favor of an improved overview only the data connections between the individual elements, the physical transports are only apparent from the descriptive text.
  • the system comprises a server 100 of a service provider, which includes common computer hardware. Functionally, it comprises a database 101, an interface module 102 and at least the following function modules:
  • a processing module 1 10 for generating input data from a three-dimensional image of a head of a person obtained;
  • a modeling module 1 1 5 for providing a model for a spectacle frame
  • an adaptation module 120 for generating adaptation data and for making adaptations to the mentioned model
  • a transformation module 122 for transforming a mesh into a refined mesh
  • an image output module 125 for outputting image data of an overlay of the model with one or more images of the head of the person;
  • a data output module 135 for outputting the manufacturing data.
  • the modules communicate with the database 101 and the interface module 102. Their functioning and interaction is described in more detail below in connection with a method according to the invention.
  • the system comprises the computer 200 described above, which communicates with the server 100 via the interface of the computer 200, a data network and the interface module 102 of the server 100.
  • the computer 200 with the keyboard 201 (or other input device) and the screen 202 on the one hand and the 3D-capable camera 210 can be integrated in the same terminal, in particular a tablet computer or a smartphone.
  • the devices of the different manufacturers comprise - as shown for the first manufacturer 310.1 of the first group and the first manufacturer 320.1 of the second group - each via computer 311, 321 with suitable interfaces for communication with the interface module 102 of the server 100 (again preferably via a secure one Internet connection) and via appropriate manufacturing facilities, e.g. B. a machine 312 for additive manufacturing or an automatic grinder 322 for processing lens blanks.
  • FIG. 4 shows the sequence of a method according to the invention schematically as a flowchart.
  • a customer who wants new glasses goes to the business premises of the optician whose company is integrated in the system according to the invention or cooperates with the system according to the invention.
  • the optician determines the optical properties that the glasses should have, in particular with regard to the spherical and cylindrical correction values, the axis position of the cylinder, prismatic values and base positions as well as the apex distance. In the case of multifocal glasses or free-form glasses, further data must be collected.
  • the general parameters for the desired glasses are acquired via the computer 200 and the keyboard 201, guided via the screen 202, and forwarded to the server 100 of the service provider (step 10).
  • the general parameters include a (first) selection from various basic models. These are physically available from the optician so that the customer can take them in hand and put them on for testing. For many customers, this later simplifies the virtual fitting, because the relationship between the glasses put on a screen and the physical object represented is much different can be made easier.
  • the general parameters also include, among other things, the specification of the material or materials, the desired color, a temple inscription, etc. It is also possible to enter certain preferences in relation to the geometry of the frame, z. B. a (relative) glass size or a base curve. The scope and permissible ranges of the adjustable parameters can vary depending on the basic model.
  • a three-dimensional image of the customer's head is captured using camera 210 (step 12).
  • the picture includes at least the entire face, the forehead with hairline, the temples and the ears.
  • the three-dimensional image data are in turn transmitted to the server 100.
  • the detection can be done with commercially available products, e.g. B. with modern tablet computers or smartphones that have cameras that can (usually infrared-based) capture depth information. As a rule, it makes sense to take several pictures from different angles and then combine them into a 3D model. Appropriate applications and library functions are available. They can be run directly on the device used.
  • First input data are then generated on the server in the processing module 110 from the three-dimensional image data by identifying predetermined orientation points using image recognition and storing their position on the customer's head in the database 101 (step 14).
  • the result is a 3D polygon model with the associated texture.
  • elements of the mouth, nose, eyes, eyebrows, ears and face contour serve as orientation points.
  • the landmarks are first identified on the 2-dimensional image and then projected onto the 3D polygon model. This results in the 3-dimensional location information. With their help, the head can be oriented in the room (pupils on one axis, nasal root at a fixed position in the room, etc ).
  • the glasses model is then always positioned so that the lower back of the nose bridge in the world coordinate system is positioned at the coordinate origin (0/0/0) (FIG. 5B).
  • the glasses front is aligned parallel to the X world axis (FIGS. 5C, 5E, 5F).
  • the temples are aligned parallel to the Z world axis ( Figures 5D-F).
  • the 3D head scan is first rotated accordingly so that the orientation points of the pupils are aligned parallel to the X axis (FIG. 5C).
  • the 3D scan is then positioned so that the point of orientation of the root of the nose sits on the origin of the coordinate (FIG. 5B).
  • the 3D scan is then rotated around the point of orientation of the nasal root in such a way that the point of orientation of the ear lies below the temple ( Figure 5B).
  • a polygon model for an eyeglass frame with the desired basic properties is also provided in the modeling module 115 (step 16).
  • This polygon model comprises a polygon mesh, i.e. a mesh of discrete elements consisting of points, edges and polygon surfaces. Each individual element has basic information such as position, orientation and adjacent neighboring elements as well as additional data fields such as group membership and attributes that define the parametric form.
  • the group membership is automatically specified. These are binary bit fields (0: not part of the group; 1: part of the group).
  • the groups can represent areas, lines, so-called leading curves (e.g. the upper front curve or the upper return curve), or points, namely reference points (e.g. the nasal posterior point or the front cheek corner) by binary bit fields.
  • FIG. 6A shows two reference points of the socket bridge as an example
  • FIG. 6B shows the front, upper guide curve of the socket
  • FIG. 6C shows the area "socket bridge".
  • the reference points mark important points on the model, such as turning points of the leading curves.
  • the groups i.e. areas, guide curves and reference points, serve as masks to limit the deformations to certain regions of the polygon mesh in the subsequent adjustment process.
  • the definition and combination of overlapping groups of the different polygon mesh elements creates relationships between the individual sub-areas of an object. This automatically leads to the fact that - in particular in the case of the data-controlled, automated adaptation of the Object geometry - the adaptation procedures during the deformation automatically take into account the interaction of influencing polygon mesh areas in the deformation calculations.
  • the guiding curves and reference points can also be linked to conditions that must be complied with during the adaptation. So z. B. a radius of curvature along a guide curve or at a reference point within certain limits, or the position of an inflection point of a guide curve should be in a certain range.
  • FIG. 7 shows an example of the numerical values that are used to control the inclination (pantoscopic angle). These are values from an i. W. continuous spectrum (e.g. between 0 and 1), based on which the influence by a deformation process (deformation weight) can be controlled quantitatively. Similarly, such quantitative values may e.g. B. specify the radius of the fillet.
  • the polygon model also includes global attributes, in particular semantic information relating to the type of the object represented (eg "glasses front", “glasses temple” etc.) and design variants (in the case of a glasses front eg “standard") "," Double bridge “,” upper bridge “etc.).
  • Two basic topologies are sufficient for the basic models provided within the framework of the system shown, namely for glasses with a single bridge (FIG. 8A) and glasses with a double bridge (FIG. 8B).
  • the mesh topologies are optimized to include the required minimum of points, edges and surfaces in order to represent all basic models and to cover all required deformations in the adaptation process.
  • the basic models include data fields, which have relevant properties of the basic model, e.g. B. the presence or absence of a double web, and the related groups and attributes represent.
  • Parameter priorities automatically generate an output parameter configuration. For example, the width of the eyeglass nose bridge is determined based on the width of the scanned nose, and the length of the temple is calculated based on the distance from the root of the nose and the beginning of the auricle.
  • the initial parameter configuration refers to an initial model with a minimum number of polygon mesh elements to represent the respective shape of the glasses. It defines the mesh geometry for the following one
  • Adaptation process and includes all data required on the elements of the network.
  • the corresponding polygon model (control polygon model) is first loaded into the working memory of the executing system. This is followed by preprocessing with a view to adapting, previewing and generating the production data.
  • the results of this preprocessing are saved in such a way that they can be called up with the least possible computing and time expenditure. Furthermore, more computationally intensive procedures of the adaptation component - as far as possible - are already being carried out, so that subsequently, during the actual adaptation, real-time operation is guaranteed even with moderate computing power.
  • the preprocessing includes, for example, the creation of geometry for the edge rounding for the nose pad or the shaped lens disk (see below). Several preprocessed objects are kept in parallel in the working memory and can be called up when necessary.
  • a machine learning is based on the existing data, namely the mentioned parameters and the three-dimensional image including orientation points. Algorithm applied (step 18). This provides adaptation values for the subsequent parameter adaptation (step 20) in the adaptation module 120, which is described in detail below.
  • the machine learning algorithm was trained with existing 3D scans and assigned, customized glasses.
  • the training data are supplemented with each newly adapted model, the data of the ML algorithm is updated periodically.
  • the machine learning algorithm in particular correlates the orientation points with the measurement glasses parameters, i. H. Based on the orientation points of the face, the trained person can predict parameters for the custom-made glasses configuration. Through this process, information and statistics about the measurement glasses parameters and the corresponding wearer can be obtained, which provide information about the adjustment needs of the wearer regarding his age, gender, ethnic origin, etc. This information can then be used for future glasses design for specific target groups.
  • the polygon mesh of the adapted model is first refined using the transformation module 122 using a Catmull-Clark subdivision algorithm (step 21).
  • the image data of the head are superimposed on this refined polygon network in the image output module 125 of the server 100 and transmitted to the computer 200 of the optician via the data network.
  • There the image can be displayed on the screen 202 (virtual try-on), compare FIG. 9A-D (step 22). The customer thus gets an impression of the fit and the aesthetic effect of the future glasses.
  • the viewing angle on the image can be changed without further ado so that the aesthetic effect can be fully appreciated.
  • the spectacle lens can also be displayed with the corresponding reflections or even the influences of the refractive power.
  • the representation can be made on the 3D model or superimposed on a live video stream of the customer.
  • the same orientation points or a subset thereof are determined in real time on the basis of the video data, so that the virtual spectacle frame can be positioned correctly and immediately follows the movement of the head or a differently chosen viewing angle.
  • the front camera of a tablet computer or smartphone can be used to record the live video stream.
  • the display of the spectacle frame can be supported accordingly by existing "augmented reality" functions of this local terminal.
  • the customer or an attending specialist of the optician can now use the keyboard 201 (and / or further input devices) to provide feedback on the current model (step 24). If further adjustments are necessary, these can be specified to a certain extent (e.g. by using sliders for the glass size, the width of the bridge, the glass frame in different areas or by selecting another type of glasses from a list) .
  • the new input data is processed together with the data previously recorded (unless these are overwritten or replaced by the new data) in a next step of the adaptation process, i. H. first the machine learning algorithm is used again (step 18), followed by the further steps described.
  • manufacturing data for a test copy are provided in the processing module 130 and transmitted to the optician's computer 200.
  • the molded glass is created for each pair of glasses.
  • a so-called clip-on can be created on request, a surface that fits the front of the glasses and has the same lens openings. The clip-on is provided with darkening sun glasses and can later be clipped onto the glasses with a hook. Shaped lens, clip-on and tag are attached to the glasses during manufacture using an eyelet.
  • the unique identification in the form of three-dimensional geometry is projected into the bracket.
  • the cavities for the hinges are also projected into the temples and the front of the glasses, with additional polygon mesh elements generally being produced.
  • the density of the polygon mesh is now increased again using the Catmull-Clark subdivision algorithm, it being possible to start with the data already available for the display, which are further refined with a further iteration (step 27). This smoothes the surface of the glasses. It is only in this phase that the network topology is changed.
  • test copy is produced in a few minutes using the local 3D printer 220 (step 28). It is a copy of the eyeglass frame with the exact geometry, but without surface finishing and possibly made of a different material.
  • step 30 the customer or the supervising specialist can in turn provide feedback as to whether the model fits or whether further adjustments are necessary (step 30).
  • this new information is fed back into the cyclic process, followed by a next step of applying the machine learning algorithm (step 18) - again applied to the polygon model without smoothing, ie with the polygon model of lower density.
  • an assignment step step 34
  • different sets of manufacturing data are generated (step 36), again including generation of the tag and further elements and a previous smoothing by means of Catmull-Clark subdivision (Step 35). From this and from the optical data for the lenses already fed in by the optician, the necessary work for the production of the complete glasses results.
  • step 38 the server 100 using corresponding software interfaces (API) computers from manufacturers 310.1, 310.2, 310.3 of the first group for additive manufacturing of the spectacle frame, manufacturers 320.1, 320.2,
  • Contact 330.3 of the third group for the manufacture of further elements in particular hinges, separate metal bars with silicone nose pads for attachment to the nose bridge, etc.
  • the customer can now - again via the optician's computer 200 - select the preferred offer (step 40).
  • the manufacturing data for the glasses are then output to the corresponding manufacturer 320.1 (step 42) and the manufacturing data for the eyeglass frame (eyeglass front, temple) as well as for the other components (hinges etc.) and the order for assembly with the necessary information to the corresponding manufacturer 310.1, 330.1 or service provider 340.1 transmitted (step 44).
  • the system according to the invention can save the 3D polygon model in industry-typical formats for the storage of polygon networks such as STL, OBJ, PLY for additive or subtractive production.
  • the system can also generate and export spline curves and surfaces from the polygon model, which are suitable for production systems that require such representation models for objects.
  • the system can output standardized OMA data for the control of automatic lens grinding machines for the production of the lens discs.
  • the different export options make it possible to manufacture glasses in different materials that require different production processes and therefore different data exchange formats.
  • the manufacturing data is usually encrypted and given an access restriction. On the one hand, it can be ensured that no unauthorized third parties can use this data, on the other hand, a remuneration model can be established in which the individual manufacturing processes for the same spectacle frame are invoiced individually.
  • the optician needs information on the production of glasses, which must be in the form of physical objects instead of digital data.
  • One such example is the shape of the lens disc, which an optician sometimes cannot transmit in digital form to an automatic grinding machine because the shape must be scanned by the machine from a physical object.
  • the system supports the possibility of displaying physical templates, such as a shaped lens disk, which is also produced in the production process.
  • the system can automatically output dimensioned technical drawings that document the adaptation process and support the production process.
  • Manufacturers 310.1, 320.1, 330.1 manufacture the components ordered, possibly with downstream processes such as dyeing, grinding or coating, and send them to service provider 340.1. There they are assembled and finally sent to the optician. The finished glasses can then be tried on there. Since it was made to measure based on the 3D measurement, there is usually no need for further adjustments. At most, common adjustment steps (e.g. in relation to the shape of the ear hook) are still carried out by the optician. In addition, the corrective properties of the lens glasses are checked in relation to the customer's eyes.
  • the data exchange can take place entirely via a platform operated by the service provider on the server 100, on which all parties involved (employees of the service provider, customer, optician, manufacturer, assembly service provider, logistics company) etc.) can access. Only those data that the respective party needs are released for read or write access. Access can be via APIs, applications (apps) or Internet browsers, for example.
  • the data can be made available via a blockchain infrastructure.
  • the platform also enables later access, so that if the glasses are lost or damaged, the required components can be reordered automatically.
  • Each order (and the resulting partial orders) is assigned unique identification information.
  • the physically manufactured components are marked with this information, e.g. B. by an appropriate engraving, an imprint, a machine-readable tag (RFID tag) or a label.
  • RFID tag machine-readable tag
  • the parameter adjustment mentioned (step 20) is described below.
  • the adaptation process is carried out by a sequence of defined functions that calculate the deformation of the glasses model for a specific parameter change.
  • the mesh topologies are defined in such a way that the same adaptation steps are carried out for all basic models, whereby the adaptation functions can act differently depending on the basic topology of the model.
  • the corresponding data fields of the model are evaluated.
  • certain functions can provide additional deformations in the area of the double web when a double web is present. All functions carry out their calculations on the basis of the control polygon network in a data-controlled manner.
  • the functions react on the one hand to the attributes of the individual polygon mesh elements and on the other hand to the parameters that are transferred to the system from outside by an actor.
  • This actor can be either a human or a machine - for example a machine learning model.
  • the position of the elements of the polygon mesh is read, deformed by a function and then saved again.
  • the attributes stored for each mesh element point, edge, polygon area
  • no generation takes place while the glasses are being adjusted additional mesh elements instead.
  • the adjustment process takes place exclusively through deformation. Only to generate the manufacturing data is the density of the polygon mesh - as described below - increased.
  • the operations on the polygon mesh elements are parallelized on several computing cores, which speeds up the calculation considerably.
  • All of the parameters discussed below - apart from the inclination and certain dimensions of the temple - are relative values in millimeters and angles (degrees) that relate to the model dimensions of the standard glasses models.
  • the parameters of the polygon model do not necessarily have to be changed in each of the steps.
  • the corresponding adjustment value can be zero.
  • the network topology of the polygon model is coordinated with the procedures described below, which deform or change the topology (create new components of the design). Conversely, procedures that affect certain areas of the object expect that they have a certain structure of the network topology.
  • step 20.1 the bridge width is adjusted in step 20.1 (FIG. 1 1).
  • the nose bridge 51 is increased or decreased in width.
  • the thickness of the frame 50 does not change.
  • the entire width of the frame front increases or decreases by the amount of change in the nose bridge 51.
  • the depth of the nose bridge 51 is increased or decreased (FIG. 12).
  • the remaining thickness of the frame is not changed.
  • the glass width is increased or decreased (step 20.3; Figure 13).
  • the entire front of the glasses adapts accordingly.
  • the glass height is adjusted proportionally to the glass width.
  • the width of the nose bridge 51 does not change, the design of the glasses is retained.
  • the thickness of the frame 50 can optionally be changed in depth.
  • the width of the nose bridge 51 is increased or decreased separately in the lower part (FIG. 14). This changes the angle of the nose pad 52. The entire width of the nose bridge 51 remains unchanged and the width of the frame front does not change as a result.
  • the upper, inner part of the glass opening of the frame 50 can be pulled down by 1 mm. With some shapes this is necessary for a better fit of the glass in the frame.
  • the radius of the above-mentioned shaped glass (or shaped lens disk, the template which is used to mold the glass shape for cutting the correction lens) can be increased in a next step 20.6.
  • Some shapes require an increase in the shape glass radius so that the correction lens, which is created on the basis of the shape glass template, sits more firmly in the frame of the glasses.
  • the base curve can be increased or decreased.
  • the base curve corresponds to a projection of the spectacle frame onto a sphere with defined radii for the different base curves.
  • the center of the sphere that is being projected is positioned in the optical center of the lens. From this position, the center of the base curve is tilted 6 ° towards the Z axis and 9.5 ° towards the Y axis. This gives the glasses a standard inclination of 9.5 °.
  • the strength of the frame is retained.
  • the width of the eyeglass frame is also retained since the projection is realized by shearing the shape into the depth of the sphere.
  • the glass groove that fixes the correction lens in the glasses frame can also be adjusted (step 20.8).
  • the groove can have both a round and an acute geometry.
  • the groove depth can also be determined.
  • step 20.9 the angle of the ironing step is increased (FIG. 15). Only the jaw 53 of the spectacle frame is changed. The glasses front remains unchanged.
  • step 20.10 The front of the spectacle frame is rotated about a point on the jaw 53 of the spectacle frame ( Figure 16).
  • the eyeglass temples remain unchanged.
  • step 20.1 1 the rounding of the spectacle frame can be increased in the lower frame area from the nose bridge to the spectacle cheek. This is necessary for the stability of certain glasses models.
  • the subsequent step 20.12 enables the nose pad 52 to be changed in height, depth and angle (FIGS. 17-19). All other dimensions of the frame are not affected.
  • the nose pad 52 can also be changed so that there is no more pad on the frame.
  • 51 holes are provided in the lower area of the nose bridge, which make it possible to attach metal bars with silicone nose pads after production, as is customary in classic glasses production and as is desired by some customers.
  • the length of the bracket 54 can be increased or decreased (FIG. 20).
  • the spectacle frame remains unaffected.
  • the bracket 54 can be bent at the end of the bracket.
  • the position of the stirrup bend, the stirrup bend angle and the radius of the stirrup bend can be influenced in step 20.14.
  • the spectacle frame remains unaffected.
  • the torsion of the jaw can be changed in a further step.
  • the functions are defined in such a way that the visual character of the glasses is preserved as best as possible when they are used. This means that u. a.
  • the proportions of the individual areas of the glasses and the curvature of the guide curves are preserved as far as possible. This is implemented using the attribute data of the polygon mesh, for example by analyzing the guide curves and reference points before the deformation, which in turn influences the interdependency of individual partial areas of an eyeglass model during the deformation.
  • the edges of the glasses are rounded (step 20.15).
  • the rounding takes place depending on the angle of the adjacent surfaces of the edges to be rounded.
  • the glasses model is positioned so that the lower, rear edge of the nose bridge lies on the world coordinate origin (see above and FIG. 5B). Due to the previous parameter adjustments, this positioning may need to be adjusted.
  • the above-mentioned parameters and deformation functions for customizing glasses are designed in such a way that the frame can be adjusted without significantly changing the design of the shape (round glasses remain round and do not become oval, etc.). All important proportions of the glasses model are preserved and areas such as the glasses cheek remain unchanged despite the transformation.
  • the above process is optimized for production using materials with homogeneous material properties. This means, for example, 3D printing with one material.
  • FIGS. 21 A-C are illustrations of a section of the temple that is adjacent to the front of the glasses.
  • FIG. 21A shows the original polygon mesh that is used in the adaptation process (polygon mesh of the control polygon model);
  • FIG. 21 B shows a refined polygon mesh for the representation,
  • FIG. 21 C shows a further refined and further processed polygon mesh for additive manufacturing.
  • the refined polygon mesh according to FIG. 21B was created by the multiple application of the Catmull-Clark subdivision algorithm to the original polygon mesh. Its area is approximately four times larger than that of the original network. The resulting resolution is sufficient for the practically photo-realistic graphic representation of the glasses.
  • the further refined polygon mesh according to FIG. 21 C was created by the repeated application of the Catmull-Clark subdivision algorithm to the refined polygon mesh according to FIG. 21 B. Its area is approximately 16 times larger than that of the original network. After the second iteration of the subdivision, openings (continuous and blind-hole-like) with a given geometry were inserted into the polygon mesh for additive manufacturing. They serve to accommodate a hinge element and other fastening elements.
  • the invention is not restricted to the exemplary embodiment shown. This means that the customer's process does not necessarily have to take place at an optician or another specialist, but can easily take place at the customer's home or on the go using the existing devices.
  • a consultant e.g. an optician or an employee of the service provider
  • the computers and production devices can also be localized in a wide variety of ways.
  • a 3D printer is not mandatory at the optician (or at the customer's home).
  • This can, for example, be located in the optician's premises along with an automatic grinding machine, so that the components can be manufactured directly by the optician and assembled by the optician to form the finished glasses. Additional elements can be used that do not have to be manufactured individually, but are available from the optician (e.g. hinge parts).
  • the distribution of the processing tasks among the various computers can differ from that in the exemplary embodiment.
  • the end device by means of which the 3D scan is carried out can also already carry out first processing steps, possibly including the assignment of the orientation points.
  • first processing steps possibly including the assignment of the orientation points.
  • all computing steps can be carried out on the server, so that the local end devices are only used for data acquisition and display (e.g. via a browser interface).
  • the manufacturing method according to the invention can also be used independently of a 3D scan.
  • the basic glasses models can be adapted on the basis of measurement data, which is recorded, for example, by an optician and entered into the system.
  • the machine learning algorithm can also be easily used in this variant if a correspondence can be established between the input data of the ML algorithm (e.g. the position of the orientation points) and the measurement data of the optician.
  • the adjustment process can also be designed differently. It can make sense to provide additional deformation options for other glasses, especially those that change the actual shape. Additional procedures for automatically smoothing, distributing and aligning existing polygon topology can also be provided and carried out if required.
  • Individual input data which in the exemplary embodiment shown result from automatic processes, can also be entered manually by the end customer, an optician or an operator on the service provider side. Conversely, it is possible to obtain certain input data manually collected in the exemplary embodiment from additional automatic processes.
  • the system is also generally suitable for 3D manufacturing processes in which two or more different materials are processed at the same time.
  • the assignment takes place during the corresponding process step in that, in addition to the assignment to a production process, an assignment to a sub-process is also made.
  • This enables the production of one-piece objects that have heterogeneous, i.e. continuously changing, material properties. This makes it possible, for example, to implement hinge solutions not only on a geometric basis, but also through material distribution in the object.
  • the invention creates a method for generating geometric data of an individualized object, which enables the simple creation of new, flexible, parametrically adaptable designs of the individualized object.

Landscapes

  • Physics & Mathematics (AREA)
  • Engineering & Computer Science (AREA)
  • General Physics & Mathematics (AREA)
  • Software Systems (AREA)
  • Computer Graphics (AREA)
  • Theoretical Computer Science (AREA)
  • Geometry (AREA)
  • Health & Medical Sciences (AREA)
  • Ophthalmology & Optometry (AREA)
  • Optics & Photonics (AREA)
  • Architecture (AREA)
  • General Engineering & Computer Science (AREA)
  • Computer Hardware Design (AREA)
  • Processing Or Creating Images (AREA)
  • Eyeglasses (AREA)

Abstract

Dans le cadre d'un procédé de génération de données géométriques d'un objet individualisé, notamment de traitement ultérieur pour obtenir les données de fabrication aux fins de fabrication d'un objet, un modèle polygonal (64) de l'objet est fourni, le modèle polygonal comprenant un réseau formé d'éléments de réseau (65.1...5), les éléments de réseau (65.1...5) comportant des points, des arêtes et des surfaces discret-es qui représentent une forme initiale de l'objet. Le modèle polygonal (64) comprend des attributs locaux (66.1.1, 66.3.1, 66.3.2, 66.4.1) qui sont affectés à au moins certains des éléments de réseau (65.1, 65.3, 65.4) et qui concernent au moins une appartenance à un groupe d'une pluralité de groupes d'adaptation ou de paramètres pour une opération de déformation. En outre, l'invention fournit un jeu (71) d'outils d'adaptation (71.1, 71.2) prédéfinis destinés à la déformation d'une zone du réseau de modèles polygonaux (64), les outils d'adaptation (71.1, 71.2) étant définis de manière telle que, lors de leur application sur le réseau, une topologie du réseau est conservée et que, lors de leur application, les attributs locaux (66.1.1, 66.3.1, 66.3.2, 66.4.1) des éléments de réseau (65.1, 65.3, 65.4) de la zone sont évalués afin de déterminer une dimension d'une déformation locale. Le modèle polygonal (64) est adapté par l'application des outils d'adaptation (71.1, 71.2).
EP19842859.1A 2018-12-13 2019-12-05 Procédé de génération de données géométriques d'une monture de lunettes individualisée Pending EP3894948A1 (fr)

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
DE102018009811.8A DE102018009811A1 (de) 2018-12-13 2018-12-13 Verfahren zum Generieren von Herstellungsdaten zur Herstellung einer Brille für eine Person
PCT/DE2019/000316 WO2020119843A1 (fr) 2018-12-13 2019-12-05 Procédé de génération de données géométriques d'une monture de lunettes individualisée

Publications (1)

Publication Number Publication Date
EP3894948A1 true EP3894948A1 (fr) 2021-10-20

Family

ID=69172566

Family Applications (1)

Application Number Title Priority Date Filing Date
EP19842859.1A Pending EP3894948A1 (fr) 2018-12-13 2019-12-05 Procédé de génération de données géométriques d'une monture de lunettes individualisée

Country Status (4)

Country Link
US (1) US20220148262A1 (fr)
EP (1) EP3894948A1 (fr)
DE (1) DE102018009811A1 (fr)
WO (2) WO2020119843A1 (fr)

Families Citing this family (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
DE102021109381A1 (de) 2021-04-14 2022-10-20 YOU MAWO GmbH Individualisierte brillenfassung und verfahren zum erzeugen von deren geometriedaten
DE102021004077A1 (de) 2021-08-07 2023-02-09 Caddent Gmbh lndividualisierte Otoplastiken und Brillen
IT202100030014A1 (it) * 2021-11-26 2023-05-26 Luxottica Group S P A Procedimento interamente virtuale per misurazioni di grandezze optometriche.
WO2023242205A1 (fr) * 2022-06-17 2023-12-21 Telefonaktiebolaget Lm Ericsson (Publ) Procédé basé sur des règles pour déformation de maillage 3d
DE102023000840A1 (de) 2023-03-07 2024-09-12 Caddent Gmbh Otoplastiken und Brillen

Family Cites Families (12)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO2001088654A2 (fr) * 2000-05-18 2001-11-22 Visionix Ltd. Systeme d'adaptation de lunettes et procedes d'adaptation correspondants
KR20040097200A (ko) * 2002-03-26 2004-11-17 김소운 3차원 안경 시뮬레이션 시스템 및 방법
US9047704B2 (en) * 2012-03-27 2015-06-02 IntegrityWare, Inc. Method for filleting 3D mesh edges by subivision
NL2010009C2 (en) * 2012-12-19 2014-06-23 Sfered Intelligence B V Method and device for determining user preferred dimensions of a spectacle frame.
US9429773B2 (en) * 2013-03-12 2016-08-30 Adi Ben-Shahar Method and apparatus for design and fabrication of customized eyewear
KR101821284B1 (ko) 2013-08-22 2018-01-23 비스포크, 인코포레이티드 커스텀 제품을 생성하기 위한 방법 및 시스템
US20150127363A1 (en) * 2013-11-01 2015-05-07 West Coast Vision Labs Inc. Method and a system for facilitating a user to avail eye-care services over a communication network
US9810927B1 (en) 2014-03-19 2017-11-07 3-D Frame Solutions LLC Process and system for customizing eyeglass frames
ES2912600T3 (es) 2014-04-30 2022-05-26 Mat Nv Sistemas y procedimientos para la personalización de objetos en la fabricación aditiva
US11086148B2 (en) * 2015-04-30 2021-08-10 Oakley, Inc. Wearable devices such as eyewear customized to individual wearer parameters
FR3044430B1 (fr) 2015-11-26 2018-03-23 Ak Optique Procede de fabrication d'une monture de lunettes munie d'appuis nasaux a meplat
EP3410178A1 (fr) * 2017-06-01 2018-12-05 Carl Zeiss Vision International GmbH Procédé, dispositif et programme d'ordinateur destinés à l'adaptation virtuelle d'une monture de lunettes

Also Published As

Publication number Publication date
WO2020119843A1 (fr) 2020-06-18
US20220148262A1 (en) 2022-05-12
WO2020119842A1 (fr) 2020-06-18
DE102018009811A1 (de) 2020-06-18

Similar Documents

Publication Publication Date Title
EP3649505B1 (fr) Procédé, dispositif et programme d'ordinateur destinés à l'adaptation virtuelle d'une monture de lunettes
WO2020119843A1 (fr) Procédé de génération de données géométriques d'une monture de lunettes individualisée
EP3631570B1 (fr) Procédé, dispositif et programme d'ordinateur destinés à l'adaptation virtuelle d'une monture de lunettes
EP3642670B1 (fr) Procédé, dispositif et programme d'ordinateur destinés à l'adaptation virtuelle d'une monture de lunettes
CN105637512B (zh) 用于创造定制产品的方法和系统
DE69807479T2 (de) Erzeugung eines Bildes eines dreidimensionalen Objekts
EP2691934B1 (fr) Images "identikit" avec base de donnees
KR20040097349A (ko) 3차원 안경 시뮬레이션 시스템 및 방법
Oliveira-Santos et al. 3D face reconstruction from 2D pictures: first results of a web-based computer aided system for aesthetic procedures
DE102021129171B3 (de) Verfahren, system und computerprogramm zur virtuellen voraussage eines realen sitzes eines realen brillengestells am kopf einer person mit individueller kopfgeometrie
EP3851903A1 (fr) Procédé et système pour fournir une monture de lunettes
DE102020131580B3 (de) Computerimplementiertes Verfahren zum Bereitstellen und Platzieren einer Brille sowie zur Zentrierung von Gläsern der Brille
EP4006628A1 (fr) Procédé mis en oeuvre par ordinateur pour fournir et positionner des lunettes et pour centrer les verres des lunettes
DE102022208561A1 (de) Accessoire-erkennung und bestimmung für avatar-registrierung
EP4323833A1 (fr) Monture de lunettes individualisée et procédé de génération de données géométriques de celle-ci
DE202007008176U1 (de) Virtuelle Ankleide

Legal Events

Date Code Title Description
STAA Information on the status of an ep patent application or granted ep patent

Free format text: STATUS: UNKNOWN

STAA Information on the status of an ep patent application or granted ep patent

Free format text: STATUS: THE INTERNATIONAL PUBLICATION HAS BEEN MADE

PUAI Public reference made under article 153(3) epc to a published international application that has entered the european phase

Free format text: ORIGINAL CODE: 0009012

STAA Information on the status of an ep patent application or granted ep patent

Free format text: STATUS: REQUEST FOR EXAMINATION WAS MADE

17P Request for examination filed

Effective date: 20210707

AK Designated contracting states

Kind code of ref document: A1

Designated state(s): AL AT BE BG CH CY CZ DE DK EE ES FI FR GB GR HR HU IE IS IT LI LT LU LV MC MK MT NL NO PL PT RO RS SE SI SK SM TR

DAV Request for validation of the european patent (deleted)
DAX Request for extension of the european patent (deleted)
STAA Information on the status of an ep patent application or granted ep patent

Free format text: STATUS: EXAMINATION IS IN PROGRESS

17Q First examination report despatched

Effective date: 20240207