KR102049040B1 - Apparatus for diagnosing biometric roughness - Google Patents

Abstract

The present invention provides a device for diagnosing roughness of a skin of a living body, comprising: a main body (10) connecting a cone (15) to a lower side of a center band (11); Detection means for detecting light reflected from a plurality of lamps arranged inside the main body (10) with a CCD camera (36); And a controller 40 for inputting a signal of the detection means and outputting a roughness calculation value by a set algorithm.
Accordingly, it is effective to reduce the influence of disturbance light while maintaining a soft contact in response to body parts that are difficult to mechanically fix based on an optical method, thereby improving convenience and accuracy of skin roughness diagnosis.

Description

Apparatus for diagnosing biometric roughness}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a biological diagnostic apparatus, and more particularly, to a roughness diagnostic apparatus for a living body, which detects information on skin of a specific body part of a subject in an imaged manner.

In general, the skin roughness of the subject is usually examined by visual observation or palpation, and more precisely, the USB objective microscope is used, but it is largely dependent on the subjective judgment of the inspector. In addition, the stylus method of converting the stylus movement into an electrical signal by scratching the skin requires a direct contact, so it is difficult to apply to a smooth surface, and the inconvenience and cost burden to secure hygiene are accompanied.

As the prior art documents related to skin diagnosis, Korean Patent Publication No. 1206622, Korean Patent Publication No. 0834865, and the like are known.

In the former, observing the rate at which keratinocytes occurred in the stratum corneum from the observation result of the electron scanning microscope, classifying them to quantify the roughness of the stratum corneum; After applying the cosmetic, performing the following steps to quantify the roughness of the stratum corneum layer; and the like. Therefore, the general public expects the effect of making it easier to understand the evaluation results of skin moisturizing power of cosmetics.

The latter two cameras for superimposing the skin surface; A laser module scanning a baseline for matching the captured image; A calibration module for correcting a device error of the camera; It includes a connection module for three-axis rotatable connection between the two cameras and the calibration module. Thus, it is expected to quantitatively and visually determine the improvement effect before and after skin care.

However, according to the above-mentioned prior document, there is a possibility that the convenience and accuracy of the measurement may be deteriorated when the skin of the body part, which is difficult to mechanically fix, may be deteriorated.

Korean Patent Publication No. 1206622 "Method of Evaluating Skin Moisturizing Power of Cosmetics by Measuring Roughness of Skin Keratin Layer" (Publication date: September 20, 2007) Korean Registered Patent Publication No. 0834865 "3D Skin Measurement Apparatus and Method" (Published Date: 2007.06.13.)

An object of the present invention for improving the conventional problems as described above, based on the optical method to detect the roughness of the skin while reducing the effect of the disturbance light while maintaining a soft contact corresponding to the body parts difficult to mechanically fix The present invention provides a roughness diagnosis apparatus for a living body that can be quantified.

In order to achieve the above object, the present invention provides a device for diagnosing the roughness of the skin of the living body: a main body connecting the cone to the lower side of the center; Detection means for detecting light reflected from a plurality of lamps arranged inside the main body with a CCD camera; And a controller for inputting a signal of the detecting means and outputting a roughness calculation value by a set algorithm.

As a variant of the present invention, the main body is characterized in that to maintain a conical structure by wrapping a cone divided into a flexible sheet.

As a detailed configuration of the present invention, the detecting means is characterized in that it comprises an upper lamp for irradiating downward from the center belt, the side lamp for irradiating laterally from the cone.

As another modification of the present invention, the detecting means further comprises a moisture sensor for detecting the moisture state of the skin.

As a detailed configuration of the present invention, the controller sequentially calculates the brightness of the reflected light image by the upper lamp, the side lamp of one side, the side lamp of the other side, and corrects the error due to the light difference through the calibration, using a mean function It is characterized by calculating the surface roughness by the arithmetic mean.

As described above, according to the present invention, it is possible to reduce the influence of disturbance light while maintaining a soft contact in response to a body part that is difficult to fix mechanically, thereby improving convenience and accuracy of diagnosing skin roughness.

In addition, it can be used as an objective basis when evaluating the efficacy of various drugs, cosmetics, procedures, etc., and aims at measuring roughness in materials or fields that are difficult to measure in a normal manner as well as the human body.

1 is a block diagram showing an apparatus according to the invention as a whole
2 is a configuration diagram showing a modification of the device according to the present invention;
3 is a block diagram showing the main circuit connections of the device according to the invention.
4 is a flow chart showing a control algorithm of the apparatus according to the present invention.

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

The present invention proposes a technique for employing a device for diagnosing roughness of skin of a living body, in particular, a non-contact optical method. Conventional optical roughness measuring methods include optical cleavage and optical interference. The photocleavage method uses a microscope to measure optically cut the surface by irradiating light in a certain direction, and the microscope should be applied to a fixed small material. Optical coherence is measured by magnifying a light interference pattern generated by superposition of light reflected by the reference reflecting surface and the measured surface under a microscope. It can be used only on a surface that reflects light well and is sensitive to vibration. All of these methods are not suitable for measuring the roughness of the body skin.

The main body 10 according to the present invention has a structure in which the cone 15 is connected to the lower side of the center bar 11. The main body 10 has a center band 11 at the vertex position of the cone 15 in the form of a flat hat. In measuring the roughness of the body with a lot of flexion, the bottom diameter 3cm and the height 3cm of the cone 15 are advantageous in terms of blocking external light, but are not limited to these dimensions. The inner surface of the cone 15 is preferably coated with a material that absorbs the reflected light therein.

As a variation of the present invention, the main body 10 is characterized in that to maintain a conical structure by wrapping the cone (15) divided into a plurality of flexible sheets (16). 2 illustrates the state in which the cone 15 is divided into four and fixed to the center plate 11 while the cone 15 is entirely wrapped in the flexible sheet 16 to form a solid hat. The flexible sheet 16 uses a material that absorbs the reflected light from the inside and is in close contact with the skin at the bottom to block external light, which is advantageous for blocking disturbance light that interferes with the measurement.

Meanwhile, referring to FIG. 2, the arc pad 21 or the binding band 25 is used in a narrow and curved portion such as a finger. Arc pad 21 is thick in the center and is coupled to the cone 15 through the fitting groove (23). The binding band 25 is configured by combining the Velcro tape and the like at two points opposite from the lower end of the cone 15. Thus, the arc pad 21 blocks the inflow of external light, and the binding band 25 suppresses the shaking of the main body 10.

Further, according to the present invention, the detection means detects the light reflected from the lamps disposed in the plurality of the main bodies 10 with the CCD camera 36. The detection means includes a plurality of lamps for irradiating light to the target TG set on the skin and a CCD camera 36 for acquiring an image by the light reflected from the target TG. The CCD camera 36 is provided above the through hole 12 formed in the bottom surface of the center stand 11.

As a detailed configuration of the present invention, the detection means is characterized in that it comprises an upper lamp 31 for irradiating downward from the center stand 11, the side lamp 32 for irradiating laterally from the cone 15. . The upper lamp 31 is arranged in a plurality of distribution or a single ring shape around the through hole 12 at the bottom of the central stage (11). The side lamp 32 is disposed opposite to the slightly elevated position at the lower end of the cone 15, and is oriented so that light does not directly enter the CCD camera 36 on the upper side. The upper lamp 31 and the side lamp 32 may use an LED. As an example of the design, the side lamp 32 installs a 3 mm diameter LED at a height of 3 mm from the bottom of the cone 15.

In another variant of the invention, the detection means is characterized in that it further comprises a moisture sensor 34 for detecting the moisture state of the skin. The moisture detector 34 is preferably a near-infrared spectroscopy method that can be installed in a non-contact manner in the center band 11, but may be configured as a capacitive method using a contact electrode and a dielectric constant sensor. In the latter case, an electrode is disposed at the lower end of the cone 15 so that disturbance light does not occur. The use of the moisture detector 34 is because the moisture content is a factor that affects the roughness of the skin.

In addition, according to the present invention, the controller 40 inputs a signal of the detection means and outputs a roughness calculation value with a set algorithm. The controller 40 can be configured in the form of a computer that can be operated independently or a cable connected to the center stage 11 of the main body 10. In any case, the controller 40 is composed of a microcomputer circuit equipped with a storage unit 42, an I / O unit 44, and a display unit 46 based on a microprocessor. The storage unit 42 stores an algorithm for calculating the roughness of the skin, and the display unit 46 calculates the roughness of the skin and displays it numerically and graphically.

As a detailed configuration of the present invention, the controller 40 sequentially calculates the brightness of the reflected light image by the upper lamp 31, the side lamp 32 on one side, and the side lamp 32 on the other side, and performs brightness through calibration. It is characterized by calculating the surface roughness by arithmetic mean using the mean function and correcting the error due to the difference.

An example of the operation by the controller 40 will be described using the flow chart of FIG. 4, and the center 1 cm x 1 cm area is the target TG with the above-described 3 cm diameter cone 15.

At the start of the operation, the upper lamp 31 is turned on to irradiate the target vertically, and the shooting is performed at the same time, and the second shooting is performed simultaneously with the lighting of one side lamp 32 successively, and the other side of the lamp 32 is consecutively At the same time the third shot is taken and the image is acquired. Brightness (alpha) (beta) (gamma) information by three images is processed into digital data using the color and brightness value for each pixel coordinate as a variable.

The surface roughness equation of the first step is calculated as shown in Equation 1 below. The difference between the pixel value of the upper lamp 31 and the pixel value of the two side lamps 32 is assumed to be roughness, and is corrected by adding both values.

[Equation 1] θ = Σ {| αi-βi | + | αi-γi | }-k

When the two side lamps 32, which are symmetric about the measurement target, are used for the brightness value, the error caused by the difference in the luminance according to the distance during the irradiation of the one side lamp 32 is eliminated. The constant (k) is determined by calibration using a reference plate (not shown) with standard roughness and color. By using the difference with the image value by the vertical upper lamp 31, the effect of the brightness difference by the color difference is canceled out.

The surface roughness formula of the second step is calculated as shown in [Equation 2] below. As a method of making the difference value relative to the overall mean roughness, mean (Δ) = mean (α) -mean (β + γ), and assuming that the surface does not have roughness, Σ {αi- (βi + γi )} = [Formula 2] is applied because mean (Δ) is established.

[Equation 2] θ = Σ | αi- (βi + γi)-mean (Δ) |

The processed data is displayed on the screen of the controller 40 or on a display capable of independent operation. The graph shows the change of illuminance according to the sequential irradiation and makes the part that deviates from the linear value as roughness.

On the other hand, it is possible to implement different colors of the upper lamp 31 and the side lamp 32 to be used according to the color of the target, as well as the roughness as well as the numerical value of the skin tone using the deviation of the color value for each pixel can do. After shooting with the white upper lamp 31, the inspection is progressed by selecting the optimal light source according to the state or color of the surface of the specimen. The degree of bundling by comparing the brightness of the image by the upper lamp 31 with respect to the standard sample for each color It can be measured.

Of course, the present invention can be applied to in vitro precision semiconductor surface inspection and the like. In either case, the principle of comparing the values that vary with the change of illumination in the unit of fixed coordinates is the same.

It is apparent to those skilled in the art that the present invention is not limited to the described embodiments and that various modifications and changes can be made without departing from the spirit and scope of the present invention. Therefore, such modifications or variations will have to belong to the claims of the present invention.

10: main body 11: center stand
12: through 15
16: Flexible Sheet 21: Arc Pad
23: fitting groove 25: binding band
31: upper lamp 32: side lamp
34: moisture sensor 36: CCD camera
40: controller 42: storage unit
44: I / O section 46: display section

Claims (5)

In the device for diagnosing the roughness of the skin of the living body:
A main body 10 connecting the cone 15 to the lower side of the center bar 11;
Detection means for detecting light reflected from a plurality of lamps arranged inside the main body (10) with a CCD camera (36); And
And a controller 40 for inputting a signal of the detection means and outputting a roughness calculation value by a set algorithm.
The main body 10 is wrapped around the pliers 15 divided into a flexible sheet 16 to maintain a conical structure,
The flexible sheet 16 is made of a material that absorbs the reflected light inside and is in close contact with the skin at the bottom,
The detection means is provided with an upper lamp 31 for irradiating downward from the center stand 11, a side lamp 32 for irradiating laterally from the cone 15,
The detecting means further comprises a moisture detector 34 for detecting the moisture state of the skin,
The controller 40 sequentially calculates the brightness of the reflected light image by the upper lamp 31, the side lamp 32 on one side, and the side lamp 32 on the other side, and corrects an error due to the light difference through calibration. A roughness diagnostic apparatus for a living body, characterized in that for calculating a surface roughness as an arithmetic mean using a mean function. delete delete delete delete

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