KR102610936B1 - Skin Elasticity Measuring Method and Skin Elasticity Measuring Device - Google Patents

Abstract

The present invention relates to a method for measuring skin elasticity and a device for measuring skin elasticity. The skin elasticity measuring method for measuring skin elasticity according to an embodiment of the present invention involves applying sound pressure of a preset magnitude to the target skin for a preset time. Measuring the skin deformation length for each angle; and the average of the deformation length for each angle ( ) or standard deviation ( ) and calculating the skin elasticity index based on the skin elasticity index.

Description

{Skin Elasticity Measuring Method and Skin Elasticity Measuring Device}

The present invention relates to a skin elasticity measurement method and a skin elasticity measurement device. More specifically, a skin elasticity measurement method and skin elasticity measurement method that can provide an elasticity index by calculating the skin deformation length and the difference between diagonals in a desired three-dimensional aspect after applying negative pressure It is about an elasticity measuring device.

As skin ages, its elasticity decreases, so improving this can be said to be one of the important efficacy characteristics of cosmetics. Therefore, measuring skin elasticity is important in evaluating product efficacy, and various measuring devices are being developed and researched for this purpose.

As an example, in the case of Patent Document 1, it was disclosed to measure skin elasticity by placing a pressure container on the skin surface, forming positive or negative pressure inside the pressure container, and measuring the recovery speed of the skin over time.

However, the skin has a three-dimensional shape, and skin elasticity is also based on three-dimensional characteristics. However, in the case of Patent Document 1, there was a problem in that the elasticity characteristics of the skin could not be reflected from all angles, and accordingly, the elasticity characteristics varied depending on the angle or position of the skin. There was a problem that the results were different and consistent results were not obtained.

Meanwhile, as a prior art to reflect the three-dimensionality of the skin, there was a method of confirming skin elasticity by inducing deformation of the skin by applying a certain negative pressure to the skin. As an example, referring to Figure 1, there is CutiScan ^® (Courage + Khazaka electronic GmbH, Germany), a device that measures skin deformation at each angle and calculates the elongation/contraction curve of the skin. CutiScan ^® The elasticity index (V3=V2/V1Х100) was calculated as the ratio of the extension length (V1) and contraction length (V2) of the skin through skin deformation.

However, because the extension length (V1), contraction length (V2), and elasticity index (V3) are calculated for each angle, there is ambiguity in verifying product efficacy using them in practice.

In particular, when comparing the elasticity index (V3) at arbitrarily designated angles, there is a limitation in that it does not reflect all angles, and there is a problem that the value varies depending on the angle at which it is measured.

In addition, after measurement, intuitive understanding was possible through images and graph trends output through the device's program, but comparison through quantitative numerical data was not possible.

KR10-0969503 B1

The present invention is intended to solve the above-mentioned problems, and provides a skin elasticity measurement method and a skin elasticity measurement device that can accurately and precisely measure the elasticity characteristics of the skin by calculating the skin deformation length at all angles and the difference between diagonals. The purpose is to provide

In addition, skin elasticity measurement can provide elasticity characteristics as quantitative numerical results, the difference in numerical values is clearly distinguished, and the same or similar results can be obtained even if performed repeatedly, providing meaningful evaluation values before and after product application. The purpose is to provide a method and a device for measuring skin elasticity.

A skin elasticity measurement method for measuring skin elasticity according to an embodiment of the present invention includes the steps of applying sound pressure of a preset magnitude to target skin for a preset time to measure the length of skin deformation at each angle; and the average of the deformation length for each angle ( ) or standard deviation ( ) and calculating the skin elasticity index based on the skin elasticity index.

The average length of skin deformation for the angle j ( ) or standard deviation ( ) can be calculated according to [Equation 1] below.

[Equation 1]

Here, n is the number of measurements, is the deformation length at time i of angle j, and i is a value from 0 to a preset time t.

The first elasticity index (Z) can be calculated by calculating the average of the deformation length for a preset angle range.

The first elasticity index (Z) is calculated by averaging the deformation length for 360°, and can be calculated according to [Equation 2] below.

[Equation 2]

The skin deformed by applying the negative pressure is divided into four sections at 90° each, and the average value of the first diagonal difference (B) and the average value of the second diagonal difference (C) are calculated in each of the diagonal sections, A second elasticity index (Y) can be calculated according to the difference between the average value (B) of the first diagonal difference and the average value (C) of the second diagonal difference.

The second elasticity index (Y) can be calculated according to [Equation 3] below.

[Equation 3]

The skin deformed by applying the negative pressure is divided into four sections at 90° each, and the standard deviation (B') of the first diagonal difference and the standard deviation (C') of the second diagonal difference are calculated in the sections diagonal to each other. Thus, the third elasticity index (Y') can be calculated according to the difference between the standard deviation (B') of the first diagonal difference and the standard deviation (C') of the second diagonal difference.

The third elasticity index (Y') can be calculated according to [Equation 4] below.

[Equation 4]

A skin elasticity measuring device for measuring skin elasticity according to another embodiment of the present invention includes a negative pressure generator that forms a negative pressure of a preset size on target skin; A skin deformation measuring device connected to the negative pressure generator and measuring the length of skin deformation for each angle on the target skin by applying negative pressure for a preset time; And according to the skin deformation length for each angle measured, the average of the skin deformation length for each angle ( ) or standard deviation ( ) and calculates the skin elasticity index.

In the processor, the average length of skin deformation for each angle ( ) or standard deviation ( ) can be calculated according to [Equation 1] below.

[Equation 1]

Here, n is the number of measurements, is the deformation length at time i of angle j, and i is a value from 0 to a preset time t.

In the processor, the first elasticity index (Z) may be calculated by calculating the average of the deformation length for a preset angle range.

In the processor, the skin deformed by applying the sound pressure is divided into four sections at 90° intervals, and the average value of the first diagonal difference (B) and the average value of the second diagonal difference (C) are calculated in the sections diagonal to each other. By calculating , a second elasticity index (Y) can be calculated according to the difference between the average value (B) of the first diagonal difference and the average value (C) of the second diagonal difference.

In the processor, the skin deformed by applying the sound pressure is divided into four sections at 90° intervals, and the standard deviation of the first diagonal difference (B') and the standard deviation of the second diagonal difference (C) are calculated in the sections diagonal to each other, respectively. '), the third elasticity index (Y') can be calculated according to the difference between the standard deviation (B') of the first diagonal difference and the standard deviation (C') of the second diagonal difference.

According to one embodiment of the present invention, the elasticity characteristics of the skin can be measured accurately and precisely by calculating the skin deformation length at all angles and the difference between diagonals to quantitatively derive elasticity characteristics that reflect the three-dimensional characteristics of the skin. An elasticity measurement method and a skin elasticity measurement device can be provided.

In addition, according to one embodiment of the present invention, it is possible to provide results of elasticity characteristics that reflect the sides and symmetry of all angles of three-dimensional skin, the differences in values are clearly distinguished, and the same or similar results are obtained even when performed repeatedly. Therefore, it is possible to provide a skin elasticity measurement method and a skin elasticity measurement device that can provide meaningful evaluation values before and after product application.

Figure 1 is a graph showing the extension/contraction curve of skin due to negative pressure.
Figure 2 is a flowchart schematically showing a method for measuring skin elasticity according to an embodiment of the present invention.
Figure 3 is a flowchart showing the elasticity index calculation steps according to an embodiment of the present invention.
Figure 4 is a diagram schematically showing a skin elasticity measuring device according to an embodiment of the present invention.
Figure 5 is a three-dimensional diagram showing skin changes caused by sound pressure measured according to an embodiment of the present invention.
Figure 6 is a graph showing a comparison of the first elasticity index before and after application of cosmetics measured according to an embodiment of the present invention.
Figure 7 is a graph comparing the second elasticity index before and after application of cosmetics measured according to an embodiment of the present invention.
Figure 8 is a graph showing a comparison of the third elasticity index before and after application of cosmetics measured according to an embodiment of the present invention.
Figure 9 is a graph comparing R ₂ values before and after application of cosmetics measured according to the prior art.

Since these embodiments can be subjected to various transformations and have various embodiments, specific embodiments will be described in detail by illustrating them in the drawings. However, this is not intended to limit the scope to specific embodiments, and should be understood to include all transformations, equivalents, and substitutes included in the disclosed spirit and technical scope. In describing the embodiments, if it is determined that detailed description of related known technologies may obscure the point, the detailed description will be omitted.

In an embodiment, a 'module' or 'unit' performs at least one function or operation, and may be implemented as hardware or software, or as a combination of hardware and software. In addition, a plurality of 'modules' or a plurality of 'units' are integrated into at least one module and implemented by at least one processor (not shown), except for 'modules' or 'units' that need to be implemented with specific hardware. It can be.

Hereinafter, the embodiment will be described in detail with reference to the accompanying drawings. In the description with reference to the accompanying drawings, identical or corresponding components will be assigned the same drawing numbers and overlapping descriptions thereof will be omitted.

Figure 2 is a flowchart schematically showing a method for measuring skin elasticity according to an embodiment of the present invention.

Referring to FIG. 2, the skin elasticity measurement method for measuring skin elasticity according to an embodiment of the present invention includes the steps of measuring the skin deformation length at each angle by applying sound pressure of a preset magnitude to the target skin for a preset time ( S1), and the average of the deformation length for each angle ( ) or standard deviation ( ) and calculating the skin elasticity index based on (S2).

According to one embodiment of the present invention, in the step (S1) of measuring the skin deformation length for each angle, the skin deformation length for each angle may be measured by applying sound pressure of a preset magnitude to the target skin for a preset time.

According to one embodiment, negative pressure may be induced through a known negative pressure generator on the target skin. Additionally, CutiScan ^® (Courage + Khazaka electronic GmbH, Germany) can be used to measure the length of skin deformation at each angle. Through CutiScan ^® , the length of skin deformation at each angle can be measured by measuring the extension length (V1) and contraction length (V2) of the deformed skin at each angle.

Then, the average of the deformation length values for each angle ( ) or standard deviation ( ) Based on this, the skin elasticity index can be calculated (S2).

Through the average or standard deviation of the deformation length for each angle, elasticity indices can be calculated by identifying the average or distribution characteristics of the deformation length within a preset angle range (preferably all angle ranges of 360°).

Figure 3 shows a step (S1) of calculating a elasticity index according to an embodiment of the present invention, and is specifically a flowchart showing the steps of calculating a first elasticity index, a second elasticity index, and a third elasticity index.

In the case of FIG. 3, it is shown that the first elasticity index, the second elasticity index, and the third elasticity index are all calculated, but this is not necessarily limited, and of course, they may be calculated individually or in combination with one or more of them.

More specifically, the first elasticity index, second elasticity index, and third elasticity index can be calculated through the following process.

First, the average of the deformation length for angle i ( ) and standard deviation ( ) can be calculated as [Equation 1] below (S21).

[Equation 1]

Here, n is the number of measurements, is the deformation length at time i at angle j, i means the time when sound pressure is applied, and has a value from 0 to a preset time t.

According to one embodiment, the Can be measured using pixel units, and the time t during which sound pressure is applied can be, for example, 4 seconds. However, it is not necessarily limited to this, and of course it can be set to various times.

The average of the deformation lengths for each angle j ( ) is calculated by measuring the deformation length measured during the time the sound pressure is applied and finding the average, and the average of the deformation length for angle j ( ) or standard deviation ( ) can be calculated together.

The first elasticity index (Z) is an index that means the average of the deformation length for a preset angle range, and can preferably be derived by calculating the average of the deformation length for all angles (i.e., 360°) (S23 ). In the past, if the elasticity index was calculated by considering only the skin deformation length for a specific angle, according to an embodiment of the present invention, the average of the skin deformation lengths within a preset angle range, preferably the average of the skin deformation lengths within all angles, is calculated. It can be calculated. In other words, the elasticity characteristics of the skin can be calculated considering the roughness characteristics within a preset angle range or at all angles.

According to one embodiment, the first elasticity index (Z) is calculated by averaging the deformation length for 360°, and can be calculated according to [Equation 2] below.

[Equation 2]

Here, the range of angle j can be from 0 to 359 to derive the average of the deformation length for 360°. However, it is not necessarily limited to this, and only values within a specific angle range may be applied.

Meanwhile, in the case of products with elastic efficacy, when measured before and after application, the deformation length at all angles of the output image increases overall, and the asymmetric structure tends to be alleviated.

Therefore, the value of the first elasticity index (Z) increases as the overall length of skin deformation increases. That is, when the value of the first elasticity index (Z) increases, it means that elasticity is improved. Therefore, the elasticity characteristics of the skin can be compared through the increase or decrease of the first elasticity index (Z), and further, it is possible to check whether the elasticity characteristics are improved before and after application of the elasticity product.

Meanwhile, the second elasticity index (Y) is an index indicating asymmetry based on the average of the average deformation length for each angle, and can be calculated through steps S21, S24, S25, and S26 of FIG. 3.

Specifically, the average or standard deviation of the deformation length for each angle can be calculated (S21), and the target skin can be divided into four sections at 90° each (S24). More specifically, it can be divided into a first section from 0° to 89°, a second section from 90° to 179°, a third section from 180° to 269°, and a fourth section from 270° to 359°.

In addition, the average value (B) of the first diagonal difference in the first and third sections that are diagonal to each other and the average value (C) of the second diagonal difference in the second section and the fourth section can be calculated. (S25).

And, a second elasticity index (Y) can be calculated according to the difference between the average value (B) of the first diagonal difference and the average value (C) of the second diagonal difference (S26).

More specifically, the second elasticity index (Y) can be calculated according to [Equation 3] below.

[Equation 3]

The second elasticity index (Y) is an index indicating asymmetry in skin deformation in response to negative pressure, and when its value decreases, it means that the asymmetric structure has been alleviated. Therefore, when the value of the second elasticity index (Y) decreases, it means that elasticity is improved. In other words, this means that the skin deformation length is evenly distributed for each angle and the asymmetric structure is alleviated.

Likewise, the elasticity characteristics can be compared through the second elasticity index (Y), and it is possible to check whether the elasticity characteristics are improved before and after application of the elasticity product.

In addition, the third elasticity index (Y') is an index indicating asymmetry based on the standard deviation of the deformation length for each angle, and can be calculated through steps S21, S24, S27, and S28 of FIG. 3.

Specifically, the average or standard deviation of the deformation length for each angle can be calculated (S21), and the target skin can be divided into four sections at 90° each (S24). More specifically, it can be divided into a first section from 0° to 89°, a second section from 90° to 179°, a third section from 180° to 269°, and a fourth section from 270° to 359°.

Then, the difference between the standard deviations in the first section and the third section that are diagonal to each other and the difference in the standard deviations in the second section and the fourth section that are diagonal to each other are calculated, and the first section and the third section are calculated. The standard deviation (B') of the first diagonal difference in and the standard deviation (C') of the second diagonal difference in the second and fourth sections can be calculated (S27).

Afterwards, the third elasticity index (Y') can be calculated through the difference between the standard deviation (B') of the first diagonal difference and the standard deviation (C') of the second diagonal difference (S28).

Specifically, the third elasticity index (Y') can be calculated according to [Equation 4] below.

[Equation 4]

The third elasticity index (Y') is also an indicator of asymmetry in skin deformation in response to negative pressure, and a decrease in its value means that the asymmetric structure has been alleviated. Therefore, if the value of the third elasticity index (Y') decreases, it means that elasticity has improved. In other words, this means that the skin deformation length is evenly distributed for each angle, and the asymmetric structure is alleviated.

Likewise, through the third elasticity index (Y'), elasticity characteristics can be compared and it is possible to check whether elasticity characteristics are improved before and after application of the elasticity product.

According to one embodiment, the first elasticity indicator (Z), the second elasticity indicator (Y), and the third elasticity indicator (Y') can be calculated separately or together, and each indicator is divided into sections to grade elasticity. Can be classified.

For example, after calculating each of the three indicators, if there is a significant difference in one or more of the indicators or the change rate is more than 5% through statistical comparison, the elasticity can be judged to be excellent.

In addition, the significance of the above-described elasticity indicators according to the present invention is that a meaningful evaluation can be obtained compared to conventional indicators that do not detect changes in skin elasticity. In addition, other elasticity values may vary depending on the measured skin angle, but the present invention is significant in that it can produce consistent results because it considers the skin deformation length within all angle ranges.

Figure 4 is a diagram schematically showing a skin elasticity measuring device according to an embodiment of the present invention.

The above-described method of measuring skin elasticity can be performed using a skin elasticity measuring device according to an embodiment of the present invention. Accordingly, information about the skin elasticity measurement method can also be applied to the skin elasticity measuring device. The opposite is also true.

Referring to Figure 4, the skin elasticity measuring device for measuring the elasticity of the skin according to an embodiment of the present invention includes a negative pressure generator 10 that forms a negative pressure of a preset size on the target skin T, and the negative pressure generator A skin deformation measuring device (20) connected to (10), which measures the skin deformation length for each angle on the target skin by sound pressure for a preset time, and according to the measured skin deformation length for each angle, the skin deformation length for each angle. average( ) or standard deviation ( ) and a processor 30 that calculates the skin elasticity index.

The negative pressure shaper 10 may be provided with various devices known in the art for inducing negative pressure to the skin.

A device capable of measuring the length of skin deformation at each angle while negative pressure is applied may be used as the skin deformation measuring device 20, and an example may be CutiScan ^® (Courage + Khazaka electronic GmbH, Germany).

In the processor 30, the average length of skin deformation for each angle ( ) or standard deviation ( ) can be calculated according to [Equation 1] below.

[Equation 1]

Here, n is the number of measurements, is the deformation length at time i of angle j, and i is a value from 0 to a preset time t.

The processor 30 calculates the average length of skin deformation for each angle ( ) or standard deviation ( ), it is possible to calculate elasticity indices that reflect elasticity characteristics within a rough or all angle range within a preset angle range.

Specifically, the processor 30 may calculate the first elasticity index (Z) by calculating the average of the deformation length for a preset angle range.

In addition, the processor 30 divides the skin deformed by applying the negative pressure into four sections at 90° angles, and calculates the average value (B) of the first diagonal difference and the average value (B) of the second diagonal difference in the diagonal sections. By calculating the average value (C), a second elasticity index (Y) can be calculated according to the difference between the average value (B) of the first diagonal difference and the average value (C) of the second diagonal difference.

And, in the processor 30, the skin deformed by applying the negative pressure is divided into four sections at 90° each, and the standard deviation (B') of the first diagonal difference and the second diagonal difference are calculated in the sections diagonal to each other. By calculating the standard deviation (C') of the first diagonal difference (B') and the standard deviation (C') of the second diagonal difference, the third elasticity index (Y') is calculated. You can.

According to the skin elasticity measuring method or skin elasticity measuring device according to various embodiments of the present invention described above, the elasticity characteristic index reflecting the three-dimensional characteristics of the skin can be calculated by calculating the skin deformation length at all angles and the difference between diagonals. there is. And, since these elasticity indicators are quantitative results, users can make accurate and precise comparisons through them. In other words, it can be used to compare or evaluate the elasticity efficacy of different elasticity products before and after application of the elasticity product.

In addition, the above-mentioned elasticity indices can reflect the symmetry in skin characteristics and elasticity at all angles, so they can provide more consistent and reliable results compared to results that measure elasticity only at a random angle. In other words, when elasticity is measured only at a random angle, the value may change depending on the angle set, but in the case of one embodiment of the present invention, since all angles are reflected, the same or similar results can be obtained even if performed repeatedly. there is. Accordingly, it is possible to provide a skin elasticity measurement method and a skin elasticity measurement device that can provide meaningful evaluation values for elasticity efficacy before/after application of an elasticity product or for different elasticity products.

For 10 adults, three-dimensional images were measured by applying negative pressure to the forearm, and the first elasticity index (Z), second elasticity index (Y), and third elasticity index (Y') were calculated.

After washing the measurement area (forearm) with a face wash, it was left to wait for 15 minutes under constant temperature and humidity conditions (22 ± 2°C, 45 ± 5% RH (Relative Humidity)). Negative pressure of 400 mbar was applied to the subject's forearm using Cutiscan ^® (suction/relaxation time 2s, 2 cycles) and skin changes in the area were measured.

For statistical analysis, the SPSS ^® Statistics 20 program was used, paired T-test was used, and the significant difference was set at p<0.05.

By applying the first cosmetic with elasticity effect to the forearm area, the extension length (V1), contraction length (V2), and elasticity index (V3) for each angle calculated by CutiScan ^® are converted into vector values by applying Mat-lab algorithms. It is shown in three dimensions. Deformed images for each angle before and after application of the first cosmetic were calculated, and they were as shown in Figure 5.

Figures 5 (a) and (b) show deformation images at each angle before application of the first cosmetic, and Figures 5 (b) and (c) show the first cosmetic at the same angle as (a) and (b). It shows the deformed image for each angle after applying cosmetics.

Referring to Figure 5, it was confirmed that after application of the first cosmetic, the deformation length for each angle increased overall and the asymmetric structure was alleviated. However, it was difficult to confirm quantitative information on the extent to which it had increased and to what extent the asymmetric structure had been alleviated.

In addition, the surface area and volume based on vector values did not show consistently meaningful results depending on the measurement, and although intuitive understanding was possible, comparison through quantitative numerical data was difficult.

Figure 6 is a graph showing the calculation and comparison of the first elasticity index (Z) before (a) and after (b) applying the first cosmetic.

To calculate the first elasticity index (Z) before and after applying cosmetics, calculate the average of the deformation length for 4 seconds for each angle, then calculate the average of the deformation length over 360° to obtain the first elasticity index (Z). Calculated.

Referring to Figure 6, it can be seen that the first elasticity index (Z) increased by approximately 22.4% after applying the first cosmetic material compared to before applying the first cosmetic material. It has increased significantly by more than 5%, and it can be quantitatively confirmed that the deformation length for each angle has increased by 22.4% overall.

Figure 7 is a graph showing the calculation and comparison of the second elasticity index (Y) before (a) and after (b) applying the first cosmetic.

To calculate the second elasticity index (Y) before and after applying cosmetics, calculate the average of the deformation length for 4 seconds for each angle, divide it into sections of 90° (0-89°; 90-179°) ; 180-269°; 270-359°) and then the diagonal difference was calculated. Specifically, the average of the diagonal differences in the diagonal sections (0-89°; 180-269°) and the average of the diagonal differences in the diagonal sections (90-179°; 270-359°) After calculating the average, the difference was calculated to calculate the second elasticity index (Y).

Referring to Figure 7, it can be seen that the average before and after application of the first cosmetic decreased by approximately 44.8%. Since it decreased by more than 5%, it was significantly reduced, and it can be confirmed that the asymmetric structure was alleviated by application of the first cosmetic.

Figure 8 is a graph showing the calculation and comparison of the third elasticity index (Y') before (a) and after (b) applying the first cosmetic.

To calculate the third elasticity index (Y') before and after applying cosmetics, the standard deviation of the deformation length for 4 seconds for each angle was calculated. Then, after dividing sections by 90° (0-89°; 90-179°; 180-269°; 270-359°), the difference in standard deviation on the diagonal was calculated. That is, the standard deviation of the difference in standard deviations in diagonal sections (0-89°; 180-269°) and the difference in standard deviations in diagonal sections (90-179°; 270-359°) After calculating the standard deviation, the difference was calculated to calculate the third elasticity index (Y').

Referring to Figure 8, it can be seen that the average before and after application of the first cosmetic decreased by approximately 17.7%. Since it decreased by more than 5%, it was significantly reduced, and it can be confirmed that the asymmetric structure was alleviated by application of the first cosmetic.

Meanwhile, to verify the results, the R ₂ values before and after applying the first cosmetic were compared using Cutometer ^® , which is used to measure elasticity. R ₂ is a value representing the ratio of the total skin recovery length during a preset time to the total skin deformation length after the action of negative pressure.

Figure 9 is a graph comparing R ₂ values calculated with Cutometer ^® before (a) and after (b) applying the first cosmetic.

Referring to Figure 9, it was confirmed that the elasticity index R ₂ before and after application of the first cosmetic increased by approximately 2.0%.

According to an embodiment of the present invention, it can be seen that the first elasticity index increases by approximately 22.4%, and the second and third elasticity indicators decrease by approximately 44.8% and approximately 17.7%, respectively. However, these are the values calculated with Cutometer ^® . It can be seen that the values are larger than the R ₂ value. That is, according to one embodiment of the present invention, the elasticity efficacy, which was difficult to accurately compare in the past, can be compared more accurately and precisely because the difference in value is large. In other words, it can help users understand product efficacy through more intuitive efficacy verification.

In addition, in the case of R ₂ calculated with Cutometer ^® , the concept of angle was not included, but according to one embodiment of the present invention, it reflects the deformation length for the entire angle and reflects the asymmetry of the skin with three-dimensionality. By considering elasticity characteristics, more in-depth results can be provided.

10: Negative pressure generator
20: Skin strain meter
30: processor

Claims (13)

As a skin elasticity measurement method for measuring skin elasticity,
A skin deformation measuring device measuring the length of skin deformation at each angle by applying sound pressure of a preset magnitude to the target skin through a negative pressure generator for a preset time;
The processor, based on the skin deformation length for each angle measured by the skin deformation measuring device, averages the deformation length for each angle ( ) calculating; and
The average of the deformation length for each calculated angle ( ), including calculating the elasticity index of the skin through,
In the step of calculating the elasticity index of the skin, the skin deformed by applying the negative pressure is divided into four sections at 90° each,
Calculate the average value (B) of the first diagonal difference and the average value (C) of the second diagonal difference in sections that are diagonal to each other,
A method for measuring skin elasticity, characterized in that calculating a second elasticity index (Y) according to the difference between the average value (B) of the first diagonal difference and the average value (C) of the second diagonal difference.
According to claim 1,
In the processor, the average of the skin deformation length for angle j ( ) and standard deviation ( ) is a skin elasticity measurement method characterized in that it is calculated according to [Equation 1] below.
[Equation 1]

Here, n is the number of measurements, is the deformation length at time i of angle j, and i is a value from 0 to a preset time t.
According to claim 2,
A method of measuring skin elasticity, characterized in that the processor calculates the first elasticity index (Z) by calculating the average of the deformation length for a preset angle range.
According to claim 3,
The first elasticity index (Z) is calculated by averaging the deformation length for 360°, and is calculated according to [Equation 2] below.
[Equation 2]

delete According to claim 1,
A method of measuring skin elasticity, wherein the second elasticity index (Y) is calculated according to [Equation 3] below.
[Equation 3]

According to claim 1,
The average of the deformation length for each angle ( ) In the step of calculating, the average of the deformation length for each angle based on the skin deformation length for each angle measured by the skin deformation measuring device ( ) and standard deviation ( ), and
In the step of calculating the elasticity index of the skin, the skin deformed by applying the negative pressure is divided into four sections at 90° each,
Calculate the standard deviation (B') of the first diagonal difference and the standard deviation (C') of the second diagonal difference in sections that are diagonal to each other,
A method of measuring skin elasticity, characterized in that calculating a third elasticity index (Y') according to the difference between the standard deviation (B') of the first diagonal difference and the standard deviation (C') of the second diagonal difference.
According to claim 7,
The third elasticity index (Y') is a method of measuring skin elasticity, characterized in that calculated according to [Equation 4] below.
[Equation 4]

A skin elasticity measuring device that measures the elasticity of the skin,
A negative pressure generator that forms a negative pressure of a preset size on the target skin;
A skin deformation measuring device connected to the negative pressure generator and measuring the length of skin deformation at each angle on the target skin while negative pressure is applied for a preset time; and
Based on the skin deformation length for each angle measured above, the average of the skin deformation length for each angle ( ) and a processor that calculates the elasticity index of the skin,
In the processor, the skin deformed by applying the negative pressure is divided into four sections at 90°,
Calculate the average value (B) of the first diagonal difference and the average value (C) of the second diagonal difference in sections that are diagonal to each other,
A skin elasticity measuring device, characterized in that calculating a second elasticity index (Y) according to the difference between the average value (B) of the first diagonal difference and the average value (C) of the second diagonal difference.
According to clause 9,
In the processor, the average length of skin deformation for each angle ( ) and standard deviation ( ) is a skin elasticity measuring device, characterized in that calculated according to [Equation 1] below.
[Equation 1]

Here, n is the number of measurements, is the deformation length at time i of angle j, and i is a value from 0 to a preset time t.
11. The method of claim 10, wherein the processor:
A skin elasticity measuring device characterized in that the first elasticity index (Z) is calculated by calculating the average of the deformation length for a preset angle range.
delete 10. The method of claim 9, wherein the processor:
Based on the skin deformation length for each angle measured by the skin deformation measuring device, the average of the skin deformation length for each angle ( ) and standard deviation ( ), and
Divide the skin deformed by applying the negative pressure into four sections at 90° each,
Calculate the standard deviation (B') of the first diagonal difference and the standard deviation (C') of the second diagonal difference in sections that are diagonal to each other,
A skin elasticity measuring device, characterized in that calculating a third elasticity index (Y') according to the difference between the standard deviation (B') of the first diagonal difference and the standard deviation (C') of the second diagonal difference.

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