BG2974U1 - System for producing 3d digital tooth models - Google Patents

Abstract

The system finds application in dental medicine, particularly in aesthetic dental prosthetics. The system allows personal face features, temperament and personal preferences of patient to be transmitted in natural-looking digital tooth forms in relation with psycho-dentofaccial harmony of the personality. The system consists of photo camera (1), connected to a unit for facial analysis (2), connected to the input of a unit for two dimensional dental design (4), connected to a unit for assessment of the psychological profile (3) and with a unit for design of three dimensional digital tooth models (7), connected to a three dimensional printer (8). The unit for design of three dimensional digital tooth models (7) is connected separately with a three dimensional scanner (5) and with a unit for adding of data for additional criteria of the design (6).

Description

The utility model refers to a system for the production of three-dimensional digital dental models, which is used in dentistry, in particular, in aesthetic dentures.

BACKGROUND OF THE INVENTION

Systems for the production of three-dimensional digital dental models are known, but none use an integrated methodology to convey the patient's personal features, temperament and personal preferences in natural-looking digital three-dimensional dental shapes in accordance with the psychodontofacial harmony of the personality.

Such systems are: DSD by Ch. Coachman, Smile Designer Pro, Digital Smile System, 3 Shape Dental System, CEREC Dentsply Sirona, Zirkonzhan, Amann Girrbach.

A system for the production of two-dimensional digital dental models described in [1] is known. This well-known system uses an integrated methodology through which the patient's personal features, temperament and personal preferences are conveyed in natural-looking digital dental forms in accordance with the psychodontofacial harmony of a person.

The system includes a digital camera whose output is connected to the input of a facial analysis unit, which comprises an image upload unit, a face and unit recognition unit, an image calibration unit, a database unit, and a classifier unit. The input of the image upload unit is the input of the facial analysis unit, and the output of the image upload unit is connected simultaneously to the input of the face recognition unit and its elements and to the input of the image calibration unit. The face recognition unit and its elements consist of a parallel contour unit for determining the facial contour, a unit for determining the contour of the eyes, a unit for determining the contour of the nose and eyebrows and a unit for determining the contour of the mouth, whose inputs are connected simultaneously to the input of the input of the face recognition unit and its elements, and their outputs are connected simultaneously to the output of the face recognition unit and its elements. The second input of the face recognition unit and its elements is connected to the output of the image calibration unit. The output of the database block and the output of the face recognition block and its elements, separately, are connected to the two inputs of the classifier block, the output of which is the output of the facial analysis block and is connected to the input of a two-dimensional dental design block. a second input is connected to the output of a block for determining a psychological profile. The psychological profile determining unit comprises a block for entering data from a questionnaire, the output of which is connected to the first input of an analysis unit, the second input of which is connected to the output of a second database block. The output of the analysis block is the output of the block for determining a psychological profile. The two-dimensional dental design unit comprises a design frame building unit, the first and second inputs of which are the first and second inputs of the two-dimensional dental design unit, and its output is connected to a two-dimensional dental arch generating unit whose second input is connected. to the output of a block for selection of tooth shapes, the first input of which is connected to the output of the block for determining a psychological profile, and its second input is connected to the output of a third block of databases. The output of the block for generating a two-dimensional dental arch is the output of the block for two-dimensional dental design and is connected to a two-dimensional printer.

The known system is designed for the production of two-dimensional digital dental models and provides a two-dimensional image-template (tooth contour), which serves as follows:

- as an important reference point for dental technicians in the planning of prosthetic structures, providing information about the tooth proportions, inclinations, line of the cutting edges of the front teeth, tooth shapes, etc .;

- as an important reference point for the dental contour and can be used when working with other concepts for digital smile design;

- as an important reference point in the virtual CAD / CAM planning of prosthetic structures;

- as a tool to assist the clinician in the process of planning and creating a treatment plan.

2614 Descriptions to certificates for registration of utility models № 08.2 / 31.08.2018

A disadvantage of the known system for the production of two-dimensional digital tooth models is that it does not provide the possibility to convert the two-dimensional graphic tooth configurations into their corresponding realistic three-dimensional tooth shapes.

Technical essence of the utility model

The task of the utility model is to create a system for the production of three-dimensional digital dental models, which uses an integrated methodology through which the personal features, temperament and personal preferences of the patient are transmitted in their corresponding realistic three-dimensional dental shapes with psychodentofacial harmony. the personality.

This task is solved by a system for the production of three-dimensional digital dental models, which includes a digital camera whose output is connected to the input of a block for facial analysis, which contains a block for uploading an image, a block for recognizing the face and its elements, a block for image calibration, database block and classifier block. The input of the image upload unit is the input of the facial analysis unit. The output of the image upload unit is connected simultaneously to the input of the face recognition unit and its elements and to one input of the image calibration unit. The output of the database unit together with the output of the image calibration unit, separately, are connected to the two inputs of the classifier unit, the output of which is the output of the facial analysis unit and is connected to the first input of a two-dimensional dental design unit. The second input of the two-dimensional dental design unit is connected to the output of a psychological profile determination unit, which contains a block for entering data from a questionnaire, the output of which is connected to the first input of an analysis unit, the second input of which is connected to the output of the analysis unit. second database block. The output of the analysis block is the output of the block for determining a psychological profile. The two-dimensional dental design unit comprises a design frame building unit, the first and second inputs of which are the first and second inputs of the two-dimensional dental design unit, and its output is connected to a two-dimensional dental arch generating unit whose second input is connected. to the output of a block for selection of tooth shapes, the first input of which is connected to the output of the block for determining a psychological profile, and its second input is connected to the output of a third database block. The output of the block for generating a two-dimensional dental arch is the output of the block for two-dimensional dental design and is connected to a printer. According to the utility model, the output of the face recognition unit and its elements is connected to the second input of the image calibration unit, the output of which is connected to the second input of the classifier unit. The output of the block for generating a two-dimensional dental arch is connected to the printer, which is three-dimensional, through a block for design of three-dimensional digital dental models. The first input of a 3D dental model design unit is connected to the output of the 3D arc generating unit, its second input is connected to the output of a 3D scanner, and its third input is connected to the output of a data input unit with additional design criteria. The design block of three-dimensional digital dental models consists of a fourth database block, the output of which is connected to the first input of a block for selection and sizing of three-dimensional files, the second input of which is connected to the output of the block for generating two-dimensional dental arch. The output of the block for selection and sizing of three-dimensional files is connected to the fourth input of a block for generating a three-dimensional dental arch, whose output is connected to the input of a block of three-dimensional digital editor, whose output is the block for design of three-dimensional digital tooth models.

An advantage of the system for the production of three-dimensional digital dental models, according to the utility model, is that it uses an integrated methodology by which the personal features, temperament and personal preferences of the patient are transmitted in natural-looking digital dental forms in accordance with psychodontofacial harmony of personality, which is very easy to apply, which allows the dentist to make very complex three-dimensional digital dental models. Therefore, this will allow every clinician, at every level, to start working with three-dimensional digital dental models at a very high professional level, due to the fact that the system is, in fact, a digital laboratory that converts by applying algorithms for calculate the two-dimensional design in three-dimensional, and immediately create a three-dimensional digital

2615 Descriptions to certificates for registration of utility models № 08.2 / 31.08.2018 dental models. The three-dimensional design uses an integrated methodology through which the patient's personal features, temperament and personal preferences can be conveyed in natural-looking three-dimensional digital tooth shapes, by applying algorithms to calculate the optimal combination of incisal silhouette, tooth axes, tooth proportions and the combination of individual tooth shapes.

Explanation of the attached figure

The utility model is illustrated in the attached figure 1, which is a block diagram of a system for the production of three-dimensional digital dental models.

Examples of implementation of the utility model

The system for the production of three-dimensional digital dental models includes a digital camera 1, the output of which is connected to the input of a facial analysis unit 2, which contains an image upload unit 2.1, a face recognition unit and its elements 2.2, an image calibration unit 2.3, first database block 2.4 and classifier block 2.5. The input of the image upload unit 2.1 is the input of the face analysis unit 2. The output of the image upload unit 2.1 is connected simultaneously to the input of the face recognition unit and its elements 2.2 and to the input of the image calibration unit 2.3 . The output of the database block 2.4, together with the output of the image calibration block 2.3, are separately connected to the two inputs of the classifier block 2.5, whose output is the output of the face analysis block 2, and is connected to the input of the two-dimensional block dental design 4, the second input of which is connected to the output of a block for determining psychological profile 3, which contains a block for data entry from questionnaire 3.1, the output of which is connected to the first input of analysis unit 3.3, the second input of which is connected to the output of the second block of databases 3.2. The output of the analysis unit 3.3 is the output of the psychological profile determination unit 3. The two-dimensional dental design unit 4 comprises a design frame building unit 4.1, the first and second inputs of which are, respectively, the first and second inputs of the two-dimensional dental unit. dental design 4, and its output is connected to a block for generating a two-dimensional dental arch 4.4, the second input of which is connected to the output of a block for selection of dental shapes 4.3, whose first input is connected to the output of the block for determining psychological profile 3 , and its second input is connected to the output of the third database block 4.2. The output of the block for generating a two-dimensional dental arch 4.4 is the output of the block for two-dimensional dental design 4 and is connected to a printer 8. The utility model is characterized by the fact that the output of the block for recognizing face and its elements 2.2 is connected to the other input of the image calibration block 2.3, the output of which is connected to the second input of the classifier block 2.5. The output of the unit for generating a two-dimensional dental arch 4.4 is connected to the printer 8, which is three-dimensional, through a unit for design of three-dimensional digital dental models 7. The first input of the unit for design of three-dimensional digital dental models 7 is connected to the output of the unit for generating a two-dimensional dental arch 4.4, its second input is connected to the output of a three-dimensional scanner 5, and its third input is connected to the output of a data input unit with additional design criteria 6. The design unit of three-dimensional digital dental models 7 is made up of a fourth database block 7.1, the output of which is connected to the first input of a block for selection and sizing of three-dimensional files 7.2, the second input of which is connected to the output of the block for generating a two-dimensional dental arch 4.4. The output of the block for selection and sizing of three-dimensional files 7.2 is connected to the fourth input of a block for generating a three-dimensional dental arc 7.3, whose output is connected to the input of a block of three-dimensional digital editor 7.4, whose output is the block of design for three-dimensional digital dental models 7.

Using the utility model

The system for the production of three-dimensional digital dental models works as follows. The digital camera 1, with manual mode settings, uses a macro lens and flash to capture the patient's face with a wide smile and visible teeth. The image is provided to the image upload unit 2.1, which is able to accept the image as input, store it and provide it as needed. The facial analysis unit 2 performs type classification

2616 Descriptions to certificates for registration of utility models № 08.2 / 31.08.2018 person. The face recognition unit and its elements 2.2 perform fundamental face recognition, biometric measurements, facial analysis, description of the shape of the face - characteristic points that determine facial features, as well as their coordinates, head position, smile state detection , the presence of visible teeth. Examples of such a block are Kairos Face Recognition, Betaface Face Recognition. The image calibration unit 2.3 calibrates the image. The image and data about the face and its elements are obtained as input data. The image calibration unit 2.3 uses the data on the location of the pupils on the image, performs transformations on the image - positioning, scaling and rotation so that the calibration condition is met, and returns the calibrated image. The condition for calibration is the following: the line passing through the two pupils should be located parallel to the horizon, the distance between the pupils should be equal to a constant and the pupils should be located at certain points. The data from the training of classification algorithm - classification model are stored in the first block of the database 2.4. Classifier 2.5, using the description of the person, the data for the calibration of the person and the data from the training of the classification algorithm, determines the type of person.

The types of faces are pre-visually determined by a specialist on the principle of cephaloscopy and are as follows:

• strong (choleric): a rectangular face, formed by clearly defined angles, vertical and horizontal lines around the forehead and mouth, sunken eyes;

• dynamic (sanguine): angular face formed by sloping lines around the eyes and forehead, distinctly convex nose and wide mouth;

• delicate (melancholic): close-set eyes and an oval face with features that are either rounded or shaped by thin lines;

• calm (phlegmatic): round or square face, protruding lower lip and heavy eyelids.

Based on these data, mathematical models are built, defining each of the types - face cards. By using training data representing a set of persons and their corresponding classifications, Classifier 2.5 is trained to classify the type of person with the same result as the specialist. Examples of classifiers are the well-known Weka C4.5, IBM SPSS Modeler C5.1, Weka J48, IBM SPSS Modeler Bayesian Network. The psychological profile unit 3 determines the patient's profile. According to an adapted psychological test questionnaire, data from a questionnaire are entered in the data entry block 3.1. The second test database 3.2 stores a test verification key. Data analysis unit 3.3 determines the psychological type of the patient using the completed questionnaire and the key to test the test, as well as the combination of the main types as follows: strong (choleric), dynamic (sanguine), sensitive (melancholic), calm (phlegmatic) . Two-dimensional dental design is made in the block for two-dimensional dental design 4. First, the design framework is built in the block for building design 4.1, which calculates for the upper jaw excision projection, the axes of inclination of the teeth and the proportions. The calculation is performed according to the following rules:

• incisal projection (the line according to which the cutting edges of the upper front teeth are arranged) - of the type of face, as follows: straight - strong, calm; inclined - dynamic, delicate; line - strong, dynamic; rainbow - calm, delicate;

• axes of inclination of the teeth - of the type of face, as follows: straight - strong, calm; sloping dynamic, delicate;

• proportionality - of the type of person, as follows: strongly - strong; moderately pronounced dynamic, delicate; weakly expressed - calm.

The obtained data are stored in the third block of database 4.2, which also contains a digital two-dimensional dental library, representing the different tooth shapes of the front teeth, as follows: rectangular (strong), triangular (dynamic), oval (delicate), square ( calm). The third block of the database also stores data on the incisal projection - angles of inclination, the axes of inclination of the teeth - angles of inclination, proportionality - dimensions. The block for selection of tooth shapes

2617 Descriptions to certificates for registration of utility models № 08.2 / 31.08.2018

4.3 calculates the shapes of the front teeth for the upper jaw. The calculation is performed according to the following rules:

• dental shapes of the central and lateral incisors - from the psychological test - the main type of temperament, as follows: rectangular - strong, triangular - dynamic, oval - delicate, square - calm;

• dental shapes of canine teeth - from the psychological test - an additional type of temperament, as follows: rectangular - strong, triangular - dynamic, oval - delicate, square - calm.

The block for generating a two-dimensional dental arch 4.4, combining the data from the block for building the design 4.1 and from the block for selecting tooth shapes 4.3, generates a complete two-dimensional dental arch and provides it in the form of a two-dimensional graphic image accompanied by a text description. The three-dimensional scanner 5, which can be an intraoral medical three-dimensional scanner or a laboratory dental scanner, reproduces the shape of the jaw in the form of a three-dimensional model - STL file. For example, I TERO, 3Shape TRIOS, 3Shape D1000.

The block for entering additional design criteria 6 provides the possibility to enter data - additional design criteria, as follows:

• list of teeth involved in the design - from the upper jaw, • text description, • additional photographs, • contour of the incisal edge, • incisal embrasures, • surface texture, • buccal corridors.

The design block of three-dimensional digital dental models 7 stores the results in the fourth database 7.1, which is a digital three-dimensional dental library. Sets of 14 digital three-dimensional dental shapes, designed by a dental specialist, are available. Their shapes and textures are based on the most important aesthetic parameters for the different dental shapes of the front teeth, as follows: rectangular (strong), triangular (dynamic), oval (delicate), square (calm). The fourth database also stores data on the proportions and angles when arranging the teeth in a three-dimensional dental arch, as well as on the possible shapes of the dental arch. The three-dimensional dental arch when viewed from above is mathematically represented as a polynomial of the fourth degree, and the shapes of the dental arch determine the coefficients in the polynomial, the main shapes are four and correspond to the shape of the face - strong, calm, dynamic, delicate. The operator can change the shape of the dental arch, during which it is rearranged. The block for selection and sizing of three-dimensional files 7.2, using the obtained data for the complete two-dimensional dental arch from the block for generating two-dimensional dental arch 4.4, the final design and selection of digital three-dimensional shapes from the fourth block database 7.1 of teeth, automatically converts them into individualized three-dimensional libraries. In this way, a three-dimensional model of the individual teeth is created, whose frontal projection has the same characteristics as the two-dimensional design. The 3D arc generating unit 7.3, combining the data from the 2D arc generating unit 4.4, the 3D file selection and sizing unit 7.2, the 3D scanner 5 and the additional design criteria input unit 6, together with its own database , generates a complete three-dimensional dental arch and provides it in the form of a three-dimensional geometric object, consisting of three-dimensional tooth shapes, organized spatially in a strictly individual order for each individual case generated by the system. The block for generating a three-dimensional dental arch 7.3 arranges the teeth on the contour of the arch from the center to the periphery, taking into account the points of contact. Starting from the central incisors, which touch the center of the arch, then the lateral incisors, which touch the central incisors, then the canine teeth, which touch the lateral incisors, and similarly for the other teeth, to the arrangement of all selected teeth. In this arrangement, the three-dimensional dental arch generating unit 7.3 adheres to the already defined two-dimensional dental design, which, in this case, is a front view of the three-dimensional dental arch. The block is a three-dimensional digital editor

2618 Descriptions to certificates for registration of utility models № 08.2 / 31.08.2018

7.4 allows the editing of the tooth shapes, performs transformations on the three-dimensional dental arch - positioning, scaling and rotation, so that the condition for calibration is fulfilled. Block 7.4 also works with the complex geometry of the teeth, which has many points. The operator can select a point on the surface of the object and then slide the point inward or outward, thus changing the shape of the tooth. After the edits, the finished product can be saved as a file in STL, OBJ or other format and output from the system to the 3D printer 8 or to a 3D cutter - for example, FormLabs, Stratasys, CEREC.

Claims (1)

Claims A system for producing three-dimensional digital dental models, comprising a digital camera whose output is connected to the input of a facial analysis unit, which comprises an image upload unit, a face recognition unit and its elements, an image calibration unit , a database unit and a classifier unit, the input of the image upload unit being the input of the facial analysis unit, wherein the output of the image upload unit is connected simultaneously to the input of the face recognition unit and its elements and to one input of the image calibration unit, wherein the output of the database unit and the output of the image calibration unit are connected, respectively, to the two inputs of the classifier block, the output of which is the output of the facial analysis unit and is connected to the input of a block for two-dimensional dental design, the second input of which is connected to the output of a block for determining a psychological profile, which contains a block for entering data from a questionnaire whose output is connected to the first input of an analysis unit, whose second input is connected to the output of a second database unit, and the output of the analysis unit is an output of the psychological profile determination unit, and the two-dimensional dental design unit contains a block for building a design frame, the first and second inputs of which are, respectively, the first and second inputs of the block for two-dimensional dental design, and its output is connected to a block for generating a two-dimensional dental arch, the second input of which is connected to the output of a block for selection of dental shapes, the first input of which is connected to the output of the block for determining a psychological profile, and its second input is connected to the output of a third block of databases, the output of the block for generating a two-dimensional dental arch is the output of the block for two-dimensional dental design and is connected to a printer, characterized in that the output of the face recognition unit and its elements (2.2) is connected to the other input of the image calibration unit (2.3), the output of which is connected to the second input of the classifier block (2.5), wherein the output of the block for generating a two-dimensional dental arc (4.4) is connected to the printer (8), which is three-dimensional, through a block for design of three-dimensional digital dental models (7), the first input of which is connected to the output of the block for generating a two-dimensional dental arch (4.4), its second input is connected to the output of a three-dimensional scanner (5) and its third input is connected to the output of a data input unit with additional design criteria (6), wherein the design unit of three-dimensional digital dental models (7) is composed of a fourth database unit (7.1), the output of which is connected to the first input of a selection unit and dimensioning of three-dimensional files (7.2), the second input of which is connected to the output of the block for generating a two-dimensional dental arch (4.4), where the output of the block for selection and sizing of three-dimensional files (7.2) is connected to the fourth input of block for generating a three-dimensional dental arch (7.3) , the output of which is connected to the input of a block of a three-dimensional digital editor (7.4), the output of which is the output of the block for design of three-dimensional digital gear models (7).