KR102499864B1 - Customizing progressive lens design device and method - Google Patents

Abstract

The present invention provides a designing device for a customized progressive lens and a designing method for the same, capable of obtaining accuracy and efficiency of a design process and improving satisfaction of a user. According to an embodiment of the present invention, the designing device for a customized progressive lens includes: a photographing unit photographing a user state of wearing glasses or not wearing the glasses; a three-dimensional image generating unit generating a three-dimensional image by rendering the image photographed by the photographing unit; a feature data extracting unit extracting feature data from the three-dimensional image generated by the three-dimensional image generating unit or an image photographed by the photographing unit; a recommended glasses frame determining unit determining at least one or more recommended glasses frames by matching the feature data extracted by the feature data extracting unit to glasses database stored in advance; and a progressive lens designing unit designing the progressive lens by calculating distance information between pupils and the lenses of the recommended glasses frame based on the feature data extracted by the feature data extracting unit.

Description

User-customized progressive lens design device and its progressive lens design method {CUSTOMIZING PROGRESSIVE LENS DESIGN DEVICE AND METHOD}

The present invention relates to a user-customized progressive lens design device and a progressive lens design method thereof, and more particularly, to design a progressive lens customized for the user by creating a three-dimensional image of a photographed image of the user, and designing a progressive lens customized thereto. An apparatus for designing a progressive lens for a user and a method for designing a progressive lens thereof, which can increase user satisfaction as well as obtain accuracy and efficiency in a design process because a suitable spectacle frame can be determined.

In the case of a normal person's eye, the origin of the eye is infinity and the near point is about 25 cm.

By the way, some people suffer from ophthalmotropia, which has difficulty seeing both near and far distances due to reduced accommodative power at the near and far points. They can correct their eyesight by wearing progressive lenses (hereinafter referred to as "progressive lenses") .

In order to manufacture such a progressive lens, it is necessary to consider lens wearer's unique physical characteristics and viewing habits, such as distance or near gaze position or direction, pupillary distance, face facial structure, pupil rotation angle, and facial tilt.

For example, according to Korean Patent Registration No. 10-1300670 (Title of Invention: Eyeball rotation angle measurement device for setting the length of the progressive zone of progressive lenses and its method), behavior patterns such as reading habits of glasses wearers are measured and Disclosed is a method in which a user-customized progressive zone length can be set, and through which a progressive lens is manufactured.

However, in the conventional progressive lens design device, since the front face was mainly used, the accuracy and recognition rate were low, and since the glasses were matched to the width of the face without accurate information on the size, there was also a limit to the accuracy of the progressive lens design. . In addition, in the prior art, since the progressive lenses and spectacle frames were manufactured by separate devices, the manufacturing process was somewhat complicated.

Therefore, it is required to develop an apparatus and method for designing a progressive lens with a new configuration capable of realizing a progressive lens customized to the user by utilizing a 3D image instead of a 2D image while designing a progressive lens and a spectacle frame at the same time. am.

The embodiment of the present invention creates a three-dimensional image of a photographed image of a user, designs a progressive lens customized for the user, and determines a spectacle frame suitable for the user, so that accuracy and efficiency of the design process can be obtained, as well as user satisfaction. An apparatus for designing a user-customized progressive lens capable of increasing , and a method for designing a progressive lens thereof are provided.

The problem to be solved by the present invention is not limited to the above-mentioned problem (s), and another problem (s) not mentioned will be clearly understood by those skilled in the art from the following description.

An apparatus for designing a progressive lens for a user according to an embodiment of the present invention includes a photographing unit for photographing a user wearing glasses or not wearing glasses, and a three-dimensional image generating a three-dimensional image by rendering the image photographed by the photographing unit. A dimensional image generating unit, a feature data extracting unit extracting feature data from an image captured by the photographing unit or the 3D image generated by the 3D image generating unit, and extracted by the feature data extracting unit A recommendation spectacle frame determination unit for determining at least one recommended spectacle frame by matching the obtained feature data to a pre-stored spectacle frame database and a distance between the lens and the pupil of the recommended spectacle frame based on the feature data extracted by the feature data extraction unit. It may include a progressive lens design unit for designing a progressive lens by calculating the information.

In addition, the photographing unit according to an embodiment of the present invention includes a first photographing unit for photographing the face of the user in a non-wearing glasses state and a second photographing unit for photographing the face of the user in a glasses wearing state. The second photographing unit may photograph the position of the pupil moving in the vertical direction in the user's wearing glasses.

In addition, the photographing unit according to an embodiment of the present invention may further include a calibration unit for calibrating an image when photographing a two-dimensional image.

In addition, the photographing unit according to an embodiment of the present invention may be a plurality of cameras arranged at regular intervals with the user as the center.

In addition, the feature data extraction unit according to an embodiment of the present invention includes a first extractor for extracting feature data from the image of the user not wearing glasses, and the lenses and pupils of the spectacle frame from the image of the user wearing glasses. It may include a second extraction unit for extracting location data between.

Also, the recommended eyeglass frame determining unit according to an embodiment of the present invention may include a virtual fitting unit that virtually fits the determined eyeglass frame to the user's 3D image.

In addition, the progressive lens design unit according to an embodiment of the present invention may design a progressive lens using positional information between the pupil and the lens according to the movement of farsightedness or nearsightedness.

In addition, in the progressive lens design apparatus according to an embodiment of the present invention, an image photographed by the photographing unit displays a 3D image rendered by the 3D image generation unit or the recommendation determined by the recommendation spectacle frame determination unit. It may further include a display unit displaying an image of the spectacle frame or displaying an image of the progressive lens designed by the progressive lens design unit.

On the other hand, a progressive lens design method of a user-customized progressive lens design device according to an embodiment of the present invention includes a photographing step of photographing an image of a user wearing or not wearing glasses by a photographing unit, and photographing by the photographing unit. A 3D image generating step of generating a 3D image by rendering the 3D image by a 3D image generating unit, and an image captured by the photographing unit or generated by the 3D image generating unit using a feature data extraction unit. a feature data extraction step of extracting feature data from the 3D image; a recommended spectacle frame determining step of determining at least one recommended spectacle frame by using a recommended spectacle frame decision unit to correspond the feature data to a pre-stored spectacle frame database; and the feature data and a progressive lens designing step of designing a progressive lens by calculating distance information between the lens of the recommended spectacle frame and the pupil using a progressive lens designing unit based on the feature data extracted by the extraction unit.

In addition, the photographing step according to an embodiment of the present invention, the first photographing step of photographing the face of the user in a non-wearing glasses state by the first photographing unit of the photographing unit and the second photographing unit of the photographing unit and a second photographing step of photographing the face of the user in a state of wearing glasses, wherein the second photographing step may photograph the position of the pupil moving vertically in the state of wearing glasses of the user by the second photographing unit. .

In addition, the photographing step according to an embodiment of the present invention may further include a calibration step of calibrating the image through a calibration unit provided in the photographing unit when capturing a two-dimensional image.

In addition, during the photographing step according to an embodiment of the present invention, the user may be photographed using a plurality of cameras of the photographing unit provided at regular intervals centering on the user.

In addition, the feature data extracting step according to an embodiment of the present invention includes a first extracting step of extracting feature data from an image of the user in a non-wearing state of glasses through a first extracting unit of a feature data extracting unit and the feature data extracting unit A second extraction step of extracting positional data between the lens of the spectacle frame and the pupil from the image of the user wearing glasses through a second extraction unit of .

In addition, the step of determining the recommended eyeglass frame according to an embodiment of the present invention may include a virtual fitting step of virtually fitting the recommended eyeglass frame determined by the recommended eyeglass frame determination unit to the 3D image of the user by a virtual fitting unit. there is.

In addition, in the step of designing the progressive lens according to an embodiment of the present invention, the progressive lens may be designed by calculating the position between the pupil and the lens according to the motion of the hyperopia or myopia by the progressive lens design unit.

Meanwhile, a method for designing a progressive lens of a user-customized progressive lens design device according to an embodiment of the present invention includes a first photographing step of photographing an image of a user not wearing glasses by a photographing unit, and a photographed image by the photographing unit. A 3D image generating step of generating a 3D image by rendering an image by a 3D image generating unit, and an image captured by the photographing unit or generated by the 3D image generating unit using a feature data extraction unit. A feature data extraction step of extracting feature data from a 3D image; a recommended spectacle frame determining step of determining at least one recommended spectacle frame by using a recommended spectacle frame decision unit to correspond the feature data to a previously stored spectacle frame database; A second photographing step of photographing an image of a state in which glasses are worn by a photographing unit; a positional data extraction step of extracting positional data of the lenses and pupils of the recommended spectacle frame in relation to the movement of the pupils of the user; and a lens and pupil of the spectacle frame. It may include a progressive lens designing step of designing a progressive lens by calculating distance information of .

According to an embodiment of the present invention, it is possible to design a progressive lens customized for the user by generating a 3D image of a photographed image of the user and determine a spectacle frame suitable for the user, so that accuracy and efficiency of the design process can be obtained, as well as user satisfaction can be increased.

1 is a diagram schematically illustrating the configuration of an apparatus for designing a user-customized progressive lens according to an embodiment of the present invention.
FIG. 2 is a flowchart of a progressive lens design method of the progressive lens design apparatus of FIG. 1 .
3 is a flowchart of a progressive lens designing method of a progressive lens designing apparatus according to another embodiment of the present invention.

Advantages and/or features of the present invention, and methods of achieving them, will become apparent with reference to the following detailed description of the embodiments taken in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below and will be implemented in various forms different from each other, only these embodiments make the disclosure of the present invention complete, and common knowledge in the art to which the present invention pertains. It is provided to completely inform the person who has the scope of the invention, and the present invention is only defined by the scope of the claims. Like reference numbers designate like elements throughout the specification.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a diagram schematically illustrating the configuration of an apparatus for designing a user-customized progressive lens according to an embodiment of the present invention.

Referring to FIG. 1 , an apparatus for designing a user-customized progressive lens according to an embodiment of the present invention 100 includes a photographing unit 110, a 3D image generating unit 120, and a feature data extraction unit 130. and a recommended spectacle frame determining unit 140, a progressive lens designing unit 150, and a display unit (not shown).

With this configuration, it is possible to design a progressive lens customized for the user and to determine a spectacle frame.

In the conventional case, visual acuity is tested by an optometry device, progressive lenses are designed based on two-dimensional image information, and glasses to which progressive lenses are applied are provided after a user separately determines a spectacle frame. In the present embodiment, the user's face is Since a recommended spectacle frame is determined based on the 3D image information and progressive lenses are designed, the process can be simplified compared to the prior art, and glasses with progressive lenses optimized for the user can be provided.

Describing each configuration, first, the photographing unit 110 of the present embodiment captures the user's face wearing glasses and the user's face not wearing glasses.

As shown in FIG. 1 , the photographing unit 110 includes a first photographing unit 111 for photographing the user's face without glasses, and a second photographing unit 113 for photographing the user's face while wearing glasses. ) may be included.

Here, the second photographing unit 113 may obtain data for designing a progressive lens by capturing the position of the pupil moving in the vertical direction while the user is wearing glasses.

In addition, the photographing unit 110 of this embodiment, as shown in Figure 1, may further include a calibration unit 115 for image calibration (calibration) in addition to the photographing units. The calibration unit 115 calibrates each of the 2D images acquired by the photographing units 111 and 113 .

On the other hand, although not shown, the photographing unit 110 of this embodiment includes a plurality of cameras constituting the first photographing unit 111 and the second photographing unit 113 as described above, and the plurality of cameras focus on the user. can be arranged at regular intervals. In other words, for example, a plurality of cameras may be arranged in a circle with the user at the center.

In other words, a total of three shots may be taken, for example, by the shooting unit 110 of this embodiment. In the first shooting, for example, a plurality of cameras, which are provided in total of nine, take a picture of the user's face at each location.

In addition, the second and third shots are taken using some of the nine cameras, for example, the front, side, and back of the user's face, which is performed by the above-described second capture unit 113 and is used for myopia or astigmatism. It may be a shooting for obtaining information about.

Meanwhile, referring to FIG. 1 , the 3D image generating unit 120 of this embodiment may generate a 3D image by rendering an image captured by the photographing unit 110 .

As described above, a plurality of images can be obtained by the photographing unit 110 having a plurality of cameras, and the three-dimensional image generating unit 120 renders these two-dimensional images to generate a three-dimensional image. will be.

On the other hand, the feature data extraction unit 130 of the present embodiment, as shown in FIG. 1, features data from an image captured by the photographing unit 110 or a 3D image generated by the 3D image generating unit 120. can be extracted.

The feature data extraction unit 130 includes a first extraction unit 131 that extracts feature data from an image of the user not wearing glasses and positional data between the lens of the eyeglass frame and the pupil in the image of the user wearing glasses. It may include a second extraction unit 135 for extraction.

The feature data extraction unit 130 extracts feature data of the wearing or non-wearing state of glasses by the first extracting unit 131 and the second extracting unit 135, through which a database for determining spectacle frames and designing progressive lenses is built. make it possible

Meanwhile, referring to FIG. 1 , the recommended spectacle frame determining unit 140 according to the present embodiment may determine at least one recommended spectacle frame by matching the feature data extracted by the feature data extraction unit 130 with a pre-stored spectacle frame database. .

In other words, the feature data extracted by the feature data extraction unit 130 is data on the characteristics of the user's face, for example, information on the width of the face, interpupillary distance between the two eyes, and the shape of the nose. Data of the stored spectacle frame database is matched to determine a recommended spectacle frame optimized for the user.

The recommended spectacle frame determining unit 140 may include a virtual fitting unit that virtually fits the determined recommended spectacle frame to the user's 3D image. Through this, a customized recommended eyeglass frame can be provided to the user in consideration of a design suitable for the shape of the face, a length of the temples, a size, an angle, and the like.

Meanwhile, referring to FIG. 1 , the progressive lens design unit 150 of the present embodiment calculates the distance between the lens of the recommended spectacle frame and the pupil based on the feature data extracted by the feature data extraction unit 130 to calculate the progressive lens can be designed.

The progressive lens design unit 150 may design a progressive lens using positional information between the pupil and the lens according to movement of the farsightedness or myopia.

Based on the information obtained and calculated by the operation of the progressive lens design unit 150 and the aforementioned units, it is possible to determine whether the user has astigmatism or myopia, and the progressive lens can be designed accordingly. For example, it is possible to design the thickness of the lens, whether it is multifocal or not, and even the color.

Meanwhile, although not shown in FIG. 1 , the apparatus 100 for designing a progressive lens according to this embodiment may further include a display unit for displaying each process in designing a progressive lens. The display unit displays, for example, a 3D image obtained by rendering an image captured by the photographing unit 110 by the 3D image generating unit 120 or an image of a recommended spectacle frame determined by the recommended spectacle frame determination unit 140. or an image of the progressive lens designed by the progressive lens design unit 150 may be displayed.

Meanwhile, a method for designing a progressive lens of the aforementioned progressive lens design apparatus will be described below with reference to FIG. 2 .

FIG. 2 is a flowchart of a progressive lens design method of the progressive lens design apparatus of FIG. 1 .

As shown in this, the progressive lens design method of this embodiment includes a photographing step (S100), a 3D image generating step (S200), a feature data extraction step (S300), a recommended spectacle frame determining step (S400), A lens design step (S500) may be included.

First, in the photographing step (S100) of the present embodiment, as described above, an image of the user wearing glasses or not wearing glasses may be photographed by the photographing unit 110.

In this photographing step (S100), the first photographing step of photographing the user's face in a non-wearing glasses state by the first photographing unit 111 and the user's glasses-wearing face by the second photographing unit 113 A second photographing step of photographing is included. Here, in the second photographing step, the position of the pupil moving vertically in the user's wearing glasses may be photographed by the second photographing unit 113 .

In addition, the photographing step ( S100 ) may further include a calibration step of calibrating the image through the calibration unit 115 when capturing the two-dimensional image.

In the 3D image generating step (S200) of the present embodiment, a 3D image may be generated by rendering the image captured by the photographing unit 110 by the 3D image generating unit 120.

On the other hand, in the feature data extraction step (S300) of the present embodiment, the image captured by the photographing unit 110 using the feature data extraction unit 130 described above or the three images generated by the 3D image generating unit 120 Feature data can be extracted from dimensional images.

The feature data extraction step (S300) includes the first extraction step of extracting feature data from the image of the user not wearing glasses through the first extraction unit 131, and the user's glasses through the second extraction unit 135. A second extraction step of extracting positional data between the lens of the spectacle frame and the pupil from the image of the wearing state may be included.

Meanwhile, in the recommended spectacle frame determining step (S400) of the present embodiment, at least one recommended spectacle frame may be determined by using the recommended spectacle frame determining unit 140 to correspond feature data to a pre-stored spectacle frame database.

The recommended spectacle frame determining step ( S400 ) may include a virtual fitting step of virtually fitting the recommended spectacle frame determined by the recommended spectacle frame determining unit 140 to the user's 3D image using a virtual fitting unit.

On the other hand, in the progressive lens design step (S500) of the present embodiment, based on the feature data extracted by the feature data extraction unit 130, the distance information between the lens of the recommended spectacle frame and the pupil is obtained using the progressive lens design unit 150. Calculations can be made to design progressive lenses.

In the step of designing the progressive lens (S500), the progressive lens can be designed by calculating the position between the pupil and the lens according to the movement of the far or myopia by the progressive lens design unit 150.

As described above, according to an embodiment of the present invention, it is possible to design a progressive lens customized for the user by generating a 3D image of a photographed image of the user and determine a spectacle frame suitable for the user, so that accuracy and efficiency of the design process can be obtained. Of course, it can increase user satisfaction.

Meanwhile, in the following, a progressive lens design method according to another embodiment of the present invention will be described, but descriptions of substantially the same parts as the above-described embodiment will be omitted.

3 is a flowchart of a progressive lens designing method of a progressive lens designing apparatus according to another embodiment of the present invention.

As shown in this, the progressive lens design method of this embodiment includes a first photographing step (S10), a 3D image generating step (S20), a feature data extraction step (S30), a recommended spectacle frame determining step (S40), , a second photographing step (S50), a location data extraction step (S60), and a progressive lens design step (S70) may be included.

In the first photographing step (S10), an image of the user not wearing glasses is photographed by the photographing unit 110, and then in the 3D image generating step (S20), the image photographed by the photographing unit 110 is captured by the third image. A three-dimensional image may be generated by rendering by the dimensional image generating unit 120 .

Next, in the feature data extraction step (S30), the image captured by the photographing unit 110 using the feature data extraction unit 130 or the feature in the 3D image generated by the 3D image generating unit 120 Data is extracted, and then, in the step of determining a recommended eyeglass frame (S40), at least one recommended eyeglass frame may be determined by using the recommended eyeglass frame determining unit 140 to correspond feature data to a previously stored eyeglass frame database.

Thereafter, in the second photographing step (S50), an image of the user wearing glasses is captured by the photographing unit 110, and then in the position data extraction step (S60), the lens of the recommended eyeglass frame for the movement of the user's eyes. After extracting the position data of the eyeglasses and the pupil, in the step of designing the progressive lens (S70), the progressive lens may be designed by calculating distance information between the lens of the eyeglass frame and the pupil.

Although specific embodiments according to the present invention have been described so far, various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments and should not be defined, but should be defined by not only the scope of the claims to be described later, but also those equivalent to the scope of these claims.

As described above, the present invention has been described by the limited embodiments and drawings, but the present invention is not limited to the above embodiments, and those skilled in the art in the field to which the present invention belongs can make various modifications and transformation is possible Therefore, the spirit of the present invention should be grasped only by the claims described below, and all equivalent or equivalent modifications thereof will be said to belong to the scope of the spirit of the present invention.

100: user-customized progressive lens design device
110: shooting unit
111: first shooting unit
113: second shooting unit
115: calibration unit
120: 3D image generating unit
130: feature data extraction unit
131: first extraction unit
135: second extraction unit
140: recommended glasses frame determination unit
150: progressive lens design unit

Claims (16)

a photographing unit for photographing a user wearing glasses or not wearing glasses;
a 3D image generating unit generating a 3D image by rendering the image captured by the photographing unit;
a feature data extracting unit extracting feature data for features of the face of the user from the image captured by the photographing unit or the 3D image generated by the 3D image generating unit;
a recommendation spectacle frame determining unit which compares the feature data extracted by the feature data extracting unit with data of a spectacle frame database stored in advance to determine at least one recommended spectacle frame; and
a progressive lens design unit for designing a progressive lens by calculating distance information between the lens of the recommended spectacle frame and the pupil based on the feature data extracted by the feature data extraction unit;
Including,
The recording unit,
a first photographing unit for photographing the user's face in a non-wearing state; and
A second photographing unit for photographing the user's face in a state of wearing glasses;
The second shooting unit,
A user-customized progressive lens design device, characterized in that for photographing the position of the pupil moving in the vertical direction in the user's wearing glasses.
delete According to claim 1,
The recording unit,
A user-customized progressive lens design device further comprising a calibration unit for calibrating an image when a two-dimensional image is captured.
According to claim 1,
The user-customized progressive lens design device, characterized in that the photographing unit is a plurality of cameras arranged at regular intervals centered on the user.
According to claim 1,
The feature data extraction unit,
a first extractor for extracting feature data for facial features of the user from an image of the user not wearing glasses; and
and a second extraction unit for extracting positional data between the lens of the spectacle frame and the pupil from the image of the user wearing the glasses.
According to claim 1,
The recommended spectacle frame determination unit,
and a virtual fitting unit for virtually fitting the determined spectacle frame to the user's three-dimensional image.

According to claim 1,
The progressive lens design unit designs a progressive lens for a user, characterized in that the progressive lens is designed using positional information between the pupil and the lens according to the movement of farsightedness or myopia.
According to claim 1,
The image captured by the photographing unit displays a 3D image rendered by the 3D image generating unit, displays the image of the recommended spectacle frame determined by the recommended spectacle frame determination unit, or displays a progressive lens designed by the progressive lens design unit. User-customized progressive lens design device further comprising a display unit for displaying an image of the lens.
A photographing step of photographing an image of a user wearing or not wearing glasses by a photographing unit;
a 3D image generating step of generating a 3D image by rendering the image captured by the photographing unit by a 3D image generating unit;
a feature data extraction step of extracting feature data for a feature of the user's face from an image photographed by the photographing unit or a 3D image generated by the 3D image generating unit using a feature data extracting unit;
a recommended spectacle frame determining step of comparing the feature data with data of a pre-stored spectacle frame database using a recommended spectacle frame determining unit to determine at least one recommended spectacle frame; and
a progressive lens designing step of designing a progressive lens by calculating distance information between the lens of the recommended spectacle frame and the pupil using a progressive lens designing unit based on the feature data extracted by the feature data extraction unit;
Including,
The shooting step,
a first photographing step of photographing the face of the user in a non-wearing state by a first photographing unit of the photographing unit; and
And a second photographing step of photographing the face of the user wearing glasses by a second photographing unit of the photographing unit,
In the second photographing step, the position of the vertically moving pupil in the user's wearing glasses is photographed by the second photographing unit.
delete According to claim 9,
The shooting step,
The method of designing a progressive lens of a user-customized progressive lens design device, further comprising a calibration step of calibrating the image through a calibration unit provided in the photographing unit when capturing a two-dimensional image.
According to claim 9,
In the photographing step, the user is photographed using a plurality of cameras of the photographing unit provided at regular intervals centered on the user.
According to claim 9,
The feature data extraction step,
a first extraction step of extracting feature data for facial features of the user from an image of the user not wearing glasses through a first extraction unit of a feature data extraction unit; and
and a second extraction step of extracting position data between the lens of the spectacle frame and the pupil from the image of the user wearing the glasses through the second extraction unit of the feature data extraction unit. A method for designing a progressive lens of a device.
According to claim 9,
The step of determining the recommended eyeglass frame,
and a virtual fitting step of virtually fitting the recommended spectacle frame determined by the recommended spectacle frame determination unit to the user's three-dimensional image by means of a virtual fitting unit.

According to claim 9,
In the step of designing the progressive lens, a progressive lens design method of a user-customized progressive lens design device, characterized in that the progressive lens is designed by calculating the position between the pupil and the lens according to the movement of the farsightedness or myopia by the progressive lens designing unit. .
A first photographing step of photographing an image of a user not wearing glasses by a photographing unit;
a 3D image generating step of generating a 3D image by rendering the image captured by the photographing unit by a 3D image generating unit;
a feature data extraction step of extracting feature data for a feature of the user's face from an image photographed by the photographing unit or a 3D image generated by the 3D image generating unit using a feature data extracting unit;
a recommended spectacle frame determining step of comparing the feature data with data of a pre-stored spectacle frame database using a recommended spectacle frame determining unit to determine at least one recommended spectacle frame;
a second photographing step of photographing, by a photographing unit, an image of the user wearing the glasses wearing the glasses frame determined by the recommendation glasses frame determination unit;
a positional data extraction step of extracting positional data of the pupil and the lens of the recommended spectacle frame with respect to the movement of the user's pupil; and
a progressive lens design step of designing a progressive lens by calculating distance information between the lens of the spectacle frame and the pupil;
A progressive lens design method of a user-customized progressive lens design device comprising a.

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