WO2021148530A1

WO2021148530A1 - Method for comparing standardized body-size- and/or body-shape-dependent products with a body part of a user of the product

Info

Publication number: WO2021148530A1
Application number: PCT/EP2021/051323
Authority: WO
Inventors: Christian BRÜGMANN; Niklas Stefan Konrad VON WEIHE; Tobias Günter ZIMMERER
Original assignee: Match And Fit Ct Gmbh
Priority date: 2020-01-23
Filing date: 2021-01-21
Publication date: 2021-07-29
Also published as: DE102020101538A1

Abstract

Method for comparing standardized body-size- and/or body-shape-dependent products with a body shape of a user of the product, wherein the method is substantially described by the following steps: stipulation of at least a body-part basic state and a fit parameter set consisting of a fit parameter of the product and a fit parameter of the body part, measurement of the product and of the body part in the body-part basic state and digital capture of the measurement data, neutralization of the measurement data of the product and comparison of the fit parameters of the body part with the fit parameters of the product in the neutralized data of the product.

Description

Method for comparing standardized body size and / or body shape-dependent products with a body part of a user of the product

Description:

Technical area:

The present invention relates to a method for comparing standardized body size and / or body shape-dependent products with a body part of a user of the product. In particular, the present invention relates to a method for determining the accuracy of fit of a product produced in different sizes and models in relation to a predetermined body part of a user.

State of the art:

In the manufacture of body size and / or body shape-dependent products such as clothing, shoes, technical devices, furniture and other objects that are used by people, standardized manufacturing methods are usually used. For this purpose, certain basic models that correspond to a shape of a human body part are selected and scaled to different sizes. The corresponding products are then produced and offered in a limited number of different sizes.

This standardized production method offers the manufacturer the possibility of producing a certain product in a given design in different sizes efficiently and inexpensively, but at the expense of the personal fit and the individual comfort of use of the user. It is known that people have very different physiques, which means that not every basic model selected by a manufacturer corresponds to the physique of a user.

Each manufacturer defines a certain size grid for the products it offers. In practice, however, there are a large number of people who have a body part size that deviates from the size grid selected by a manufacturer and / or that is between two sizes specified by a manufacturer. This is particularly problematic with shoes, because shoes that do not fit properly can lead to discomfort while running. To determine the conformity of the fit, size tables or dimensions of the product are given. Some size tables are partly very old and go back to historical dimensions. Above all, these size tables are hardly comprehensible or comprehensible for the user. Therefore, the correct or suitable size can often only be determined by trying on the products. Once a user has found the size of a size chart for a piece of clothing or a shoe that is suitable for him, he can use this known size to make a preselection of pieces of clothing or shoes that might fit him, especially in the clothing and shoe industry, when making further purchases with the help of this known size.

However, there are different size tables in the shoe industry and in the clothing industry, which also differ nationally. In the clothing industry, the size tables also differ in some cases for the individual pieces of clothing. After all, when producing standardized products, the individual producers assume different basic shapes or master models, so that even with identical sizes, one manufacturer's model fits and the other does not.

As a result, the user, despite knowing his or her clothing or shoe size, often cannot make a selection of a suitable product without actually trying it on. While most adults just find trying on a nuisance, there are cases in which even trying it on sometimes does not lead to a suitable selection. When buying shoes, small children in particular are unable or barely able to judge whether the shoe fits or not. With regard to e-commerce, the need to try them on has the consequence that the user often orders items of clothing or shoes that do not fit and then have to be sent back to the retailer.

Since the individual producers want to address different customer groups with different body shapes, non-standardized fits are particularly desired by the clothing and shoe industries. Some producers specifically target tall and slim people, while other producers want to serve small and corpulent people. The basic models of both manufacturers will therefore always differ significantly.

The original forms, for example in the form of patterns for clothing or lasts for shoes, are particularly valuable for the relevant manufacturers and are usually kept secret. There is a desire to improve the current situation for the user and to provide a method with the help of which it is possible to select a suitable product without actually trying it on, whereby the manufacturers should still be able to keep their original forms secret to keep.

In particular, there is a desire to be able to reliably purchase a suitable product online, in particular in order to significantly reduce returns due to non-suitable products, while at the same time the original forms or samples from the manufacturer are kept secret in a very secure manner.

Archetypes or samples are understood to mean all the forms that are used to reproduce a product. The original forms can be present, for example, in the form of the lasts of a shoe, a pattern of an item of clothing or a negative form of a technical device.

Presentation of the invention:

It is therefore the object of the present invention to provide a method that enables a user to select a suitable body size or body shape-dependent product without trying it on; in particular, it is the object of the present invention to provide a method that enables a user to do so without knowledge of the specific basic model of the body size or body shape-dependent product and to select a suitable body size or body shape-dependent product without trying it on, so that the manufacturers can keep their original samples very securely secret.

The object is achieved with a method for comparing standardized body size and / or body shape-dependent products with a body part of a user of the product according to claim 1.

The method is based on standardized products such as clothing, shoes, pieces of furniture or technical devices, which interact with at least one part of the user's body when used as intended, in particular bear against this part of the body and / or surround this part of the body, and which due to the different body sizes and Human body shapes are offered in different sizes and models. The product has a product use state and the body part a body use state, the product in the product use state having at least one product complementary area which is complementary to at least one part of the body part, and wherein the product in the product use state and the body part in the body part use state interact with one another.

In this method, a basic body condition is defined in a first method step. The basic body state is preferably a state in which the body part can be measured easily and reproducibly.

Subsequently, at least one set of fit parameters consisting of a fit parameter of the body part and a fit parameter of the product corresponding to the fit parameter of the body part is established.

A fit parameter set is a parameter set with the help of which a dimension of a part of the body can be compared with a dimension of the product. The fit parameter of the body part and the fit parameter of the product are mutually corresponding sizes. The fit parameter of the body part is usually a characteristic size of a body part, which can differ for the individual users and for which the fit of the product is relevant. A fit parameter of a body part therefore always has a corresponding fit parameter on the product. If the fit parameters of a body part and the fit parameters of a product have the same values within a predetermined tolerance, then the body part and product fit at least with regard to this fit parameter.

To determine the fit parameter or at least one auxiliary parameter for determining the fit parameter of the body part, at least that part of the body part is measured in the basic state which interacts or comes into contact with the product when used as intended and which is used to determine the fit parameter of the body part or the at least one auxiliary parameter is suitable for determining the fit parameter of the body part. The measurement data are recorded digitally and made available in a corresponding body part data set for the body part. In addition, the value of the fit parameter and / or of the at least one auxiliary parameter for the fit parameter of the body part is determined.

Furthermore, at least a part of the contour of the product is detected in the product usable state, the detected sub-area comprising areas that enable a determination of the fit parameter of the Enable product or at least one auxiliary parameter for determining the fit parameter of the product. The data is provided in a digital product data set. The fit parameter of the product and / or the at least one auxiliary parameter for determining the fit parameter of the product are identified or determined in the digital product data set.

In the next step, the preferably three-dimensionally recorded product data are transferred to a neutralized, preferably two-dimensional comparison model, the fit parameter and / or the at least one auxiliary parameter for determining the fit parameter being transferred true to scale from the product data set to the neutralized comparison model. The product data are thus neutralized in the comparison model, so that preferably no conclusions can be drawn about the product data from the data of the comparison model, but the fit parameters of the product can still be determined.

Neutralization is understood here as the transfer of original data, i.e. the recorded product data, into comparative data of the comparative model, so that, if the manufacturer so wishes, the original data cannot be reconstructed even if the comparative data of the comparative model is known. For example, the information density of the original data can differ from the comparison data. It is not an encryption of data in the usual sense, in which the data is provided with a code. If required, the comparison data can also be encrypted, i.e. provided with a code.

The fit parameter of the product in the neutralized comparison model is then compared with the fit parameter of the body part. On the basis of the degree of correspondence between the values of the fit parameters, it can be concluded whether the product fits the user or not.

In the context of the method described, it does not matter in which order the basic body condition and the product are measured. In this way, the product can be measured at the same time as the basic body condition or it can already have been measured before the basic body condition was measured. As a rule, the basic body condition and the product are recorded or measured independently of one another. This is particularly useful if the original form on which the product is based is to be kept secret. It goes without saying that, for better determination of the accuracy of fit, several sets of fit parameters can be present, each set of fit parameters having a fit parameter of the product and a fit parameter of the body part.

The method described has the advantage that it can be determined by means of measurement data from the body part whether a product is suitable for a user or not. Trying on the product is not absolutely necessary. It is not necessary for the user to know the master models or templates of the products in order to identify a suitable product, since the body part is compared with a comparison model and not with the actual product. Manufacturers do not have to fear that master models or master samples that have previously been kept secret will become known through the use of the process.

The provision of the actual, preferably three-dimensional product data for the creation of the comparison model can take place with the help of the manufacturer, in that at least a part of the contour of the product in the product usage state is recorded with the help of a basic model such as a master model or strips. This type of detection can be useful, for example, for detecting the contour of the interior of shoes, since the contour of a last with subsequent consideration of soles is easier to determine than to measure the contour of the interior of the shoe itself.

Alternatively, at least part of the contour of the product in the product usage state can be recorded directly by measuring the product. In the case of items of clothing, the item of clothing can also be measured, for example, by means of a dressmaker's dummy, which wears the item of clothing with an accurate fit. This recording of the product data can also be carried out without the assistance of the manufacturer. Image analysis methods such as tomography or digital measuring methods, possibly also analog measuring methods, are suitable as measuring methods.

In a preferred embodiment, at least part of the body part is measured in the defined basic body state by means of at least one of the following methods: image analysis, digital measuring method, analog measuring method. For example, a body part can be imaged using a camera. Basic body condition data and / or fit parameters can be provided via a corresponding image analysis. In some cases it may also be sufficient to measure a part of the body manually with a ruler. The body part is preferably measured at predefined intervals, these data being stored in the digital data record of the body. Depending on the selected measurement method, the measurement effort for the user can be reduced to a very low level. In addition, a predefined selection of measuring points at predetermined intervals enables a good starting point for a comparison with the corresponding product, in which measuring points are likewise recorded at predefined intervals. Ideally, the distances between the measuring points in the product in the product used condition are equal to the distances between the measuring points in the basic body condition.

For example, when recording the basic state of the body with the help of image analysis, there is a risk that the recorded data of the body part in a body part data set do not indicate the absolute dimensions of the body part but only the relative dimensions of the body part due to undesired reduction or enlargement effects. In this case, in particular, it makes sense to provide reference variables in order to be able to easily and clearly compare the fit parameters of the basic body condition with the fit parameters of the product. In order to be able to make the simplest possible comparison of the fit parameter of the product in the neutralized comparison model with the at least one fit parameter of the body part in this case, it is therefore preferred that the fit parameter of the body part and / or the at least one auxiliary parameter for determining the fit parameter of the body part are recorded as a function of a first reference variable and the fit parameter of the product and / or the at least one auxiliary parameter for determining the fit parameter of the product in the comparison model is recorded as a function of a second reference variable, the first and second reference variable being the reference variable for comparing the fit parameter of the product is with the fit parameter of the body part.

It is advantageous here that the first and second reference variables are the same and the second reference variable does not change during the transition from the three-dimensionally recorded product data set to the comparison model.

In a first embodiment of the method, the useful body state and the basic body state differ from one another. In order to determine the shape of a handle for a product, it can be useful, for example, to define an outstretched hand as the basic body state, while the state of use for the body is a curved hand to encompass a handle.

In a further embodiment of the method, it is provided that the body part is deformed during the transition from the basic body state to the useful body state, in particular is compressed or stretched in sections. The method is used, for example, in determining the accuracy of fit of shoes, in which a foot standing on the ground is the basic body condition and the body condition is a foot in a shoe with a heel. In this case, the sole of the foot is partially compressed and stretched when it is converted from the basic state into the use state. With the help of this method, products which lead to the body part being deformed during intended use can generally be assigned to a specific suitable product.

In order to record the deformation of the body part during the transition from the basic body state to the useful body state when selecting the product that is suitable for a user, it is advantageous that the at least one fit parameter of the body part and / or the at least one auxiliary parameter for determining the fit parameter of the body part change during the transition from the basic state of the body to the state of use.

In a preferred embodiment of the method, the data of the product in the product state of use and the data of the body part in the basic body state are recorded, the comparison model being created from the data of the product state of use. This method is comparatively simple, the comparison model can be determined directly from the product data of the actually available product or from the actually available master sample.

In a further embodiment of the method, the data of the product in the product state of use and the data of the body part in the basic body state are recorded, the data of the product state of use being converted into data of a basic product state and the comparison model being created from the data of the basic product state. The conversion of the data of the product usage status into data of a product basic status is done purely virtually.

The basic product state is understood to mean, in particular, the state which corresponds to the state in which the product is complementary to the body part in the basic body state or interacts with it. However, the product state can also be another state that is different from the product use state.

This has the advantage that in the case in which the basic product state corresponds to the state of use for the body, the accuracy of fit of the product selected by a user is very high, since the deformation of the body part between the basic state of the body and the state of use is taken into account. Furthermore, it becomes great for an unauthorized third party difficult to draw conclusions about the product data from the comparative model obtained in this way.

When transferring the preferably three-dimensionally recorded product data into a neutralized, preferably two-dimensional comparison model, different methods can be used depending on the requirements, such as application and deformation logic, computer-aided deep learning, artificial intelligence with regard to movement sequences, deformation of objects and bodies.

In a preferred development of the method, which is particularly suitable for applications in which the data of the product in the product state of use and the data of the body part in the basic body state are recorded, the data of the product state of use being converted into data of a basic product state and the comparison model from the data of the Basic product condition is created, the three-dimensional product is transferred to a neutralized, two-dimensional comparison model using the following steps:

First, a curved section of the product is selected from the captured product data. This curved section is divided into predetermined measuring points, in particular measuring points. The measuring points are preferably arranged equidistantly. Measurement vectors are then positioned at the specified measuring points perpendicular to the curved sections. The next step is to define a flat base section onto which the curved section is projected. Then the measuring point with the smallest distance to the base section is determined. The base section is preferably placed in such a way that at least one measuring point is already on the base section. Starting from the measuring point with the smallest distance to the base section, the respectively neighboring measurement vectors are successively shifted onto the flat base section until each measurement vector is perpendicular to the base section.

The methods described so far are suitable both for body parts that change during the transition from the basic state to the useful body state, in particular are compressed or stretched in sections, as well as for body parts that have the same shape in the useful body state as in the basic body state. Brief description of the drawings:

Preferred embodiments are explained in more detail with reference to the accompanying drawings, in which:

Fig. 1 is a pictorial representation of a digitized foot,

2 shows a graphic representation of measurement parameters of the foot,

3 shows a pictorial representation of a digitized shoe last,

4 shows a schematic representation of measurement vectors in the digital shoe last,

5 shows a graphical representation of width and flea parameters of the shoe last,

6 shows a comparison of the digitized shoe last with a foot on the basis of the measurement data

7 shows a comparison of the digitized shoe last with a foot on the basis of a pictorial representation.

Ways to carry out the invention and industrial applicability:

In connection with FIGS. 1 to 7, a method for comparing a shoe with the foot of a user is described in order to determine the accuracy of fit of the shoe. The shoe is a shoe with a heel, such as a pump.

A foot in a pump is deformed compared to a bare foot on the floor. In the following, the bare foot standing on the floor is referred to as the unloaded foot and the foot in a pump is referred to as the loaded foot.

For example, the sole of a foot in a pump is stretched compared to an unloaded foot, so that the sole of the foot in a pump is slightly longer than that of an unloaded foot. The same applies to the width of the ball of the foot. This is slightly wider in the loaded state than in the unloaded foot. If the width of the ball of the foot or the length of the sole of the foot is measured on the unloaded foot and then compared with the width of the ball of the foot and the length of the sole of the shoe provided in the pumps, the user will find that the shoe does not fit properly. A direct comparison of the width of the ball of the foot or the length of the sole of the foot on the unloaded foot with the width of the ball of the shoe and the length of the shoe sole in a shoe with a heel does not lead to a satisfactory selection of suitable shoes. In order to be able to carry out a direct comparison between the foot and the shoe, the foot would have to be measured in the same position as it is in the shoe. However, this is not practical.

In the method described below for determining the accuracy of fit of a shoe for a given foot, the deformations of the foot in a shoe with a heel, such as a pump, are taken into account.

In the first step, a set of fit parameters with a fit parameter for the foot and with a fit parameter for the shoe is established. The fit parameter of the foot should change during the transition from the unloaded foot to the loaded foot and be directly related to a corresponding fit parameter on the shoe. The fit parameter of the shoe should therefore also be a measure of the size and shape of a shoe. In the present case, the length of the sole of the foot and the width of the ball of the foot are suitable as fit parameters for the foot, and in the shoe they each have a corresponding associated fit parameter of the shoe in terms of the sole length and the ball of the foot. The fit parameters that complement each other are thus the sole length or the sole length and the ball of the foot and the ball of the shoe width. The sole length or sole length and ball of the foot width and shoe ball width each form a fit parameter set.

In the next step, a basic body state is determined in which the body part is measured. The unloaded foot is chosen as the basic body state, since easily reproducible measurement results can be obtained here.

A user's foot is now measured. In the specific case, the contour of the entire foot is recorded by means of a 3-D scanner (see FIG. 1). The width, fleas and length of the foot are given in defined concrete measuring points. In Fig. 2, the measuring points are shown in a coordinate system: The fleas of the foot is plotted on the Y-axis as a function of the length of the foot and the width of the foot is indicated accordingly on the Z-axis. The fit parameters of the foot, namely the ball of the foot and the length of the sole of the foot, are determined from the recorded measurement data. The sole length can be simply determine the length of the foot and also determine the ball width from the measurement data relating to the width of the foot.

A shoe that is suitable for a user is essentially predetermined by the shape of the interior space. The shoe ball width and the sole length must therefore be determined in the interior of the shoe.

Measuring the interior of a shoe is generally not as simple as measuring a user's foot.

The basic shape of the interior is given by the strips used (see Fig. 3). However, the actual interior differs from the last in that the finished shoe still contains soles. By means of corresponding known methods, however, it is possible, with knowledge of the contour of the last and the soles used, to determine the contour of the interior volume of a shoe. The disadvantage of this method is that data must be available for the last. Alternatively, however, a shoe can also be measured by means of tomography, for example.

The method is therefore based on a digital data record which reproduces the contour of the interior of a shoe. However, which measuring method was used in detail to obtain the data is irrelevant for this method. It is essential that contour data relating to the interior of the shoe are available which are suitable for determining the selected fit parameters, namely sole length and shoe ball width.

These fit parameters are identified in the digital data set of the interior of the shoe by means of specific measurement points. These measurement points are auxiliary variables or auxiliary parameters for determining the fit parameters of the shoe. These measuring points are in turn marked in order to be able to determine the sole length and the ball width of the shoe in the comparison model as stated below.

In order to be able to compare the interior of the shoe with the unloaded foot, the measurement data of the interior volume are corrected for deformation, stretching and stretching. In addition, the measurement data of the shoe are neutralized and transferred to a comparison model. The neutralization of the measurement data of the shoe and transfer to a comparison model also ensures, among other things, that it is no longer possible to transfer the comparison model back into a real shoe model. The deformation, stretching and stretching of the measurement data of the shoe is corrected in that, as can be seen in FIG. 4, measurement vectors are provided which are arranged perpendicular to the outsole. The above-mentioned auxiliary variables or auxiliary parameters are also represented by measurement vectors. The measurement vectors are located at regular intervals on the outsole, preferably the measurement intervals are equidistant.

A base area is assigned to the last, which essentially corresponds to a fictitious running surface. The outsole is now mapped on the base surface in that, starting from the deepest measuring point, i.e. the measuring point that has the smallest distance to the base surface, the respective neighboring vectors are transferred or mapped onto the base surface until they are perpendicular to the base surface. The distance between the measuring points is left unchanged during this process. This creates a neutralized running surface that has been cleared of the compressions and expansions of the deformation (see FIG. 5).

The auxiliary parameters for determining the fit parameters are identified in the comparison model, and the two fit parameters of the shoe are determined therefrom.

The fit parameters of the shoe determined in this way, namely the length of the shoe sole and the width of the ball of the shoe, are compared with the parameters of the fit of the foot, namely the length of the sole of the foot and the width of the ball of the ball. As shown in FIGS. 6 and 7, this can be done graphically or in the form of a model representation. If the fit parameter of the foot is within a tolerance range of the corresponding fit parameter of the shoe, the shoe is a perfect fit for the foot.

Since undesired reduction or enlargement effects can occur when the foot is captured using image analysis methods, a further variant of the method provides that a reference variable is provided which is present in both the foot and the shoe and which changes when the three-dimensionally captured product data transition in the comparison model does not change. Alternatively, a scale can be recorded together with the foot.

Instead of the entire foot or the entire shoe, it is also possible to capture only part of the contour of the foot or the shoe. With the help of the recorded contour, however, it should be possible to identify the selected fit parameter sets. Within the scope of the invention, all known measurement methods can be used to record the dimensions of the foot, which lead to the fact that the defined fit parameters can be determined on the foot. Analog or digital measuring methods can be used for this.

The invention has been described, by way of example, in connection with shoes. However, the method according to the invention can also be used to find a suitable item of clothing, furniture such as an armchair or chair or a technical device that is manufactured as a function of body size or body shape.

In the case of items of clothing, for example, a tailor's dummy can be used to determine the product usage status, which wears the item of clothing with a precise fit.

In particular when determining the fit of an item of outer clothing with the aid of the method according to the invention, the case may arise that the basic state of the body part is the same as the state of use of the product. In this case, the measurement data of the body part could be compared directly with the measurement data of the product. However, this has the disadvantage that conclusions can then be drawn about the basic model of the product. In order to avoid this, it is also provided in this case that the recorded product data are neutralized and transferred into a preferably two-dimensional comparison model.

In summary, the method described relates to a method for comparing standardized body size and / or body shape-dependent products with a body part of a user of the product in order to determine the fit of a product without trying on the product, the method being essentially described by the following steps: Determination At least one basic body part state and at least one set of fit parameters consisting of a fit parameter of the product and a fit parameter of the body part, measurement of the body part in the basic state of the body part and of the product and subsequent digital acquisition of the measurement data of the product and the body part, neutralization of the measurement data of the product and comparison of the fit parameters of the body part with the fit parameters of the product in the neutralized data of the product. The conversion of the product data into neutralized data enables on the one hand to measure a body part in a body position that does not correspond to the body position when the product is used as intended, and on the other hand it can prevent data on the reproduction of the product from getting into unauthorized hands .

Claims

Patent claims:

1. A method for comparing standardized body size and / or body shape-dependent products with a body part of a user of the product, the product having a product use state and the body part having a body use state, the product in the product use state having at least one product complementary area that is complementary to at least part of the Body part is formed, and the product in the product state of use and the body part in the body part state of use interact with one another,

Defining a basic body state,

Definition of at least one set of fit parameters consisting of a fit parameter of the body part and a fit parameter of the product corresponding to the fit parameter of the body part,

Measuring at least a part of the body part in the defined basic body state, the recorded sub-area comprising areas to which the product is designed to be complementary and which enables the fit parameter to be determined,

Provision of the recorded measurement data of the body part in a digital body part data set of the body part,

Determining the value of the fit parameter of the body part and / or at least one auxiliary parameter for the fit parameter of the body part,

Detection of at least part of the contour of the product in the product use state, the detected sub-area comprising areas that enable the fit parameters of the product to be determined,

Provision of the recorded data of the product in a digital product data set, identification or determination of the fit parameter of the product and / or at least one auxiliary parameter for determining the fit parameter of the product,

Transferring the three-dimensionally recorded product into a neutralized comparison model, the fit parameter of the product or the at least one auxiliary parameter for determining the fit parameter of the product being transferred true to scale from the product data set to the neutralized comparison model.

- Comparison of the fit parameter of the product in the neutralized comparison model with the fit parameter of the body part.

2. The method according to claim 1, characterized in that the neutralized comparison model is a two-dimensional model.

3. The method according to any one of the preceding claims, characterized in that the detection of at least part of the contour of the product in the product use state takes place by measuring the product and / or with the help of a basic model.

4. The method according to any one of the preceding claims, characterized in that the measurement of at least part of the body part in the defined basic body state and / or the measurement of at least part of the contour of the product in the product use state is carried out by means of at least one of the following methods: image analysis, digital measurement method , analog measuring method.

5. The method according to any one of the preceding claims, characterized in that the body part is measured at predefined intervals and these data are stored in the digital data set of the body part.

6. The method according to any one of the preceding claims, characterized in that the fit parameter of the body part and / or the at least one auxiliary parameter for determining the fit parameter of the body part are recorded as a function of a first reference variable and the fit parameter of the product and / or the at least one auxiliary parameter to determine the fit parameter of the product as a function of a second reference variable, the first and second reference variable being the reference variable for comparing the fit parameters and / or auxiliary parameters of the body part and the product.

7. The method according to claim 6, characterized in that the first and second reference variables are the same and the second reference variable does not change during the transition from the three-dimensionally recorded product data set to the comparison model.

8. The method according to any one of the preceding claims, characterized in that the body state of use and the basic body state differ.

9. The method according to any one of the preceding claims, characterized in that the body part is deformed during the transition from the basic body state to the useful body state, in particular is compressed or stretched in sections.

10. The method according to claim 8 or 9, characterized in that the at least one fit parameter or the at least one auxiliary parameter for determining the The fit parameters of the body part changes during the transition from the basic body state to the useful body state.

11. The method according to any one of claims 8 to 10, characterized in that the data of the product in the product state of use and the data of the body part in the basic body state are recorded, the comparison model being created from the data of the product state of use.

12. The method according to any one of claims 8 to 10, characterized in that the data of the product in the product state of use and the data of the body part in the basic body state are recorded, the data of the product state of use being converted into data of a basic product state and the comparison model from the data of the basic product state is created.

13. The method according to any one of the preceding claims, characterized in that the transfer of the three-dimensionally recorded measurement data into a neutralized comparison model takes place by means of one of the following methods: application and deformation logic, computer-aided deep learning, artificial intelligence with regard to movement sequences, deformation of objects and Bodies.

14. The method according to any one of the preceding claims, characterized in that the conversion of the three-dimensionally recorded product data into a neutralized, two-dimensional comparison model takes place by means of the following steps:

Selection of a curved section of the product from the recorded product data,

Division of the curved section into specified measuring points,

Positioning of measurement vectors at the specified measuring points perpendicular to the curved section,

Define a planar base section onto which the curved section will be projected,

Determine the measuring point with the smallest distance to the base section,

- Starting from the measuring point with the smallest distance to the base section, successive mapping of the respective adjacent measurement vector onto the flat base section, so that the measurement vector is perpendicular to the base section.

15. The method according to any one of the preceding claims, characterized in that the shape of the body part in the useful body state is the same as the shape of the basic body state.

16. The method according to any one of the preceding claims, characterized in that the product is an item of clothing, a shoe, an item of furniture or a technical device.