KR102165145B1 - Method for Authenticating Stamp Touch a Coupled Sound Signal - Google Patents

Abstract

The present invention relates to a painting touch authentication method linked to a sound signal, comprising a program provided in a user's wireless terminal equipped with a capacitive touch screen and a sound input unit, and an operation of communicating with a program of the wireless terminal through a designated path In the painting touch authentication method linked with a sound signal executed in conjunction with a server, wherein the program includes a plurality of touch points touched through a plurality of capacitive touch units provided in a designated touch painting using the capacitive touch screen. Recognizing the stamp touch, the program recognizes the sound signal input through the sound input unit based on the time when the stamp touch is recognized, the program checks the code value corresponding to the recognized sound signal, and the The program compares and authenticates the code value corresponding to the sound signal, and the program provides component values for the plurality of touch points corresponding to the painting touch and the code value corresponding to the sound signal through a designated path. The method authentication result is transmitted, and the operation server receives the digital method authentication result for the component values for the plurality of touch points corresponding to the painting touch and the code value corresponding to the sound signal via a designated path, The operation server checks the geometric positional relationship on the design of the plurality of touch units of the designated touch coating for authenticating the geometrical positional relationship of the plurality of touch points, and the operation server confirms the geometrical positional relationship of the plurality of touch points. Authenticate whether it matches the geometric position relationship of the designed design within the tolerance range, and the operation server authenticates the analog method authentication result for the geometric position relationship of the plurality of touch points and the digital method for the code value corresponding to the sound signal The result is combined to determine and transmit the final stamp touch authentication result using the touch stamp, and the program receives the stamp touch authentication result.

Description

Method for Authenticating Stamp Touch a Coupled Sound Signal {Method for Authenticating Stamp Touch a Coupled Sound Signal}

The present invention is a seal touch linked with a sound signal executed by interlocking a program provided in a user's wireless terminal equipped with a capacitive touch screen and a sound input unit and an operation server communicating with the program of the wireless terminal through a designated path. In the authentication method, the program recognizes a paint touch including a plurality of touch points touched through a plurality of capacitive touch units provided on a designated touch paint using the capacitive touch screen, and the program recognizes the paint touch Based on the recognized time point, a sound signal input through the sound input unit is recognized, the program checks a code value corresponding to the recognized sound signal, and the program compares and authenticates the code value corresponding to the sound signal And, the program transmits the digital method authentication results for the component values for the plurality of touch points corresponding to the painting touch and the code value corresponding to the sound signal through the designated path, and the operation server designated path Through receiving the component values for the plurality of touch points corresponding to the painting touch and the digital method authentication result for the code value corresponding to the sound signal, the operation server determines the geometric positional relationship of the plurality of touch points Check the geometric positional relationship of the design for the plurality of touch parts of the designated touch coating for authentication, and the operation server matches the geometrical positional relationship of the plurality of touch points within the geometrical positional relationship and the tolerance of the identified design Authentication, and the operation server combines the digital method authentication result for the code value corresponding to the sound signal and the analog authentication result for the geometric positional relationship of the plurality of touch points, and the painting touch authentication result using the touch stamp The final determination and transmission, and the program relates to a seal touch authentication method linked with a sound signal to receive the seal touch authentication result.

Touch coating used as an authentication means or identification means for providing various services by providing a plurality of touch units made of a conductive material on a painted object, and by touching them on a capacitive touch screen to authenticate the geometric positional relationship formed by the plurality of touch units The service is started.

Conventional capacitive touch screens are designed to use a touch by a user's finger as an input means, and are also optimized to do so. That is, the capacitive touch screen provided in a wireless terminal such as a recently activated smartphone or tablet PC is designed and manufactured to be used as an input means for touch input, but it is technically difficult to use it as an authentication means or identification means. It has a difficult problem.

In order to use the geometric positional relationship of a plurality of touch units provided in the touch coating as an authentication means or identification means, a plurality of touch units provided in at least two or more different touch coatings are formed by different geometrical positional relationships and all kinds of electrostatic It must have a recognizable cognition on the touch screen. However, conventional capacitive touch optimized as an input means using a finger only needs to detect the point indicated by the capacitive touch touched on the capacitive touch screen, and the capacitive touch itself using a finger is basically relatively wide. Since it has a contact area, it is an analog method that calculates the approximate midpoint of a large contact area and detects it as a point indicated by the capacitive touch. Therefore, even if the same position of the capacitive touch screen is touched capacitively using the same finger, the points detected for each touch are detected differently. It is technically very difficult to use the capacitive touch optimized as an input means using a finger as an identification means or an authentication means.

An object of the present invention for solving the above problems is to provide a program provided in a user's wireless terminal equipped with a capacitive touch screen and a sound input unit, and an operation server that communicates with the program of the wireless terminal through a designated path. In the painting touch authentication method linked to a sound signal executed in conjunction, the painting touch including a plurality of touch points touched through a plurality of capacitive touch units provided in a designated touch painting using the capacitive touch screen A first step of recognizing and a second step of recognizing a sound signal input through the sound input unit based on the time when the stamp touch is recognized by the program, and a code value corresponding to the recognized sound signal by the program The third step of checking and the fourth step of comparing and authenticating the code value corresponding to the sound signal by the program, and the component values and the sound for a plurality of touch points corresponding to the painting touch through a path designated by the program The fifth step of transmitting the digital method authentication result for the code value corresponding to the signal and the component values for the plurality of touch points corresponding to the painting touch through the designated path by the operation server and corresponding to the sound signal The sixth step of receiving the digital method authentication result for the code value, and the operation server confirming the geometric positional relationship on the design of the plurality of touch units of the designated touch coating for authenticating the geometrical positional relationship of the plurality of touch points. Step 7 and the operation server verifying whether the geometrical positional relationship for the plurality of touch points is matched within a tolerance with the geometrical positional relationship on the identified design, and the operation server performs geometrical position of the multi-touch points The ninth step of combining the analog authentication result for the relationship and the digital method authentication result for the code value corresponding to the sound signal to finally determine and transmit the painting touch authentication result using the touch painting, and the program Including a tenth step of receiving the touch authentication result It is to provide a painting touch authentication method linked to a sound signal.

The painting touch authentication method linked with a sound signal according to the present invention includes a program provided in a user's wireless terminal equipped with a capacitive touch screen and a sound input unit, and an operating server communicating with the program of the wireless terminal through a designated path. In the painting touch authentication method linked with a sound signal executed in conjunction with, the program comprising a plurality of touch points touched through a plurality of capacitive touch units provided in a designated touch painting using the capacitive touch screen A first step of recognizing a touch and a second step of recognizing a sound signal input through the sound input unit based on the time when the stamp touch is recognized by the program, and a code value corresponding to the recognized sound signal A third step of confirming and a fourth step of comparing and authenticating a code value corresponding to the sound signal by the program, and component values for a plurality of touch points corresponding to the painting touch through a path designated by the program, and the The fifth step of transmitting the digital method authentication result for the code value corresponding to the sound signal, and the operation server responds to the component values and the sound signal for a plurality of touch points corresponding to the painting touch via a designated path The sixth step of receiving the digital method authentication result for the code value and confirming the geometric positional relationship of the design for the plurality of touch units of the designated touch coating for the operation server to authenticate the geometrical positional relationship of the plurality of touch points. The seventh step and the operation server verifying whether the geometrical positional relationship for the plurality of touch points is matched within the checked geometrical positional relationship and an allowable error range, and the operation server performs the geometrical positional relationship of the plurality of touched points. A ninth step of combining the analog authentication result for the positional relationship and the digital authentication result for the code value corresponding to the sound signal to finally determine and transmit the seal touch authentication result using the touch seal, and the program 10th step of receiving the stamp touch authentication result It characterized in that it comprises a.
In the painting touch authentication method linked to the sound signal according to the present invention, the program further comprises the step of confirming a result of recognizing a plurality of touch points corresponding to the number of designated touch parts of the designated touch painting, and the third step And recognizing a sound signal input through the sound input unit when a plurality of touch points corresponding to the designated number of touch units are recognized.
In the painting touch authentication method linked with a sound signal according to the present invention, an analog authentication result for the geometric location relationship of the plurality of touch points using a geometric location relationship in a design for a plurality of touch parts of the touch painting designated with the program The step of confirming further comprises recognizing a sound signal input through the sound input unit when the geometric positional relationship of the plurality of touch points is authenticated.
In the seal touch authentication method associated with a sound signal according to the present invention, the third step comprises the steps of, by the program, reading the sound signal to check numbers or characters encoded in the sound signal according to DTMF coding rules, and the And generating a code value included in the sound signal by combining the numbers or letters by a program.
In the seal touch authentication method linked to a sound signal according to the present invention, the third step comprises the steps of, by the program, reading the sound signal to check the bit stream encoded in the sound signal according to a sound code encoding rule, and the And extracting a code value encoded in the sound signal by reading the bit stream by a program.
In the painting touch authentication method linked with a sound signal according to the present invention, the third step includes: the program recognizing a sound pattern of the sound signal, and the program calculating a code value based on the recognized sound pattern. It characterized in that it comprises the step of generating.
In the painting touch authentication method linked to the sound signal according to the present invention, in the fourth step, the program generates a unique code provided in the electronic module of the touch painting or painting use place and a unique code corresponding to the sound signal. It characterized in that it comprises a digital method of validity authentication for comparison authentication.
In the painting touch authentication method linked to the sound signal according to the present invention, in the fourth step, the program is a one-time code generated through an electronic module of the touch painting or painting use place, and a one-time code corresponding to the sound signal. It characterized in that it comprises a digital authentication method of comparing and authenticating.
The painting touch authentication method linked with a sound signal according to the present invention includes a program provided in a user's wireless terminal equipped with a capacitive touch screen and a sound input unit, and an operation server communicating with the program of the wireless terminal through a designated path. A painting touch authentication method linked to a sound signal executed in conjunction, wherein the program includes a plurality of touch points touched through a plurality of capacitive touch units provided in a designated touch painting using the capacitive touch screen A first step of recognizing a touch, a second step of recognizing a sound signal input through the sound input unit based on the time when the stamp touch is recognized, and the program corresponding to the recognized sound signal A third step of checking a code value, a fourth step of verifying the validity of the code value corresponding to the sound signal by the program, and a plurality of touch points corresponding to the painting touch through a path designated by the program A fifth step of transmitting a sound authentication result for a component value and a code value corresponding to the sound signal, and a plurality of touch stamps in which geometric positional relationships for multiple touch points are specified in the operation server through a path designated by the program And a sixth step of receiving a final determined stamp touch authentication result by combining a positional relationship authentication result that has been verified to match a design geometrical positional relationship with respect to the touch unit and a sound authentication result for a code value corresponding to the sound signal. .

According to the present invention, the method for authenticating a painting touch in connection with the sound signal includes component values for a plurality of touch points corresponding to the painting touch and a code value corresponding to the sound signal through a path designated by the operation server. Step 5-1 of receiving the sound authentication result for the operation server, and a fifth step of confirming the geometric positional relationship of the design for the plurality of touch units of the designated touch painting for the operation server to authenticate the geometrical positional relationship of the plurality of touch points. Step 2, Step 5-3 of the operation server to verify that the geometrical positional relationship of the plurality of touch points is matched with the geometrical positional relationship of the identified design, and the operation server is the geometrical positional relationship of the plurality of touched points Step 5-4 of finally determining a seal touch authentication result using the touch stamp by combining the location relationship authentication result for and the sound authentication result for the code value corresponding to the sound signal, and the operation server designating a designated path. It may further include a 5-5 step of transmitting the painting touch authentication result through.

According to the present invention, the step 5-3 is the operation server to verify whether the geometrical positional relationship for the plurality of touch points is matched with the geometrical positional relationship in the design for the plurality of touch units of the designated touch coating within a specified tolerance. It may include an analog type of validation.

According to the present invention, the method of authenticating a seal touch in connection with the sound signal further includes the step of confirming a result of recognizing a result of recognizing a plurality of touch points corresponding to a specified number of touch portions of the touch paint designated by the program, and the third step May recognize a sound signal input through the sound input unit when a plurality of touch points corresponding to the designated number of touch units are recognized.

According to the present invention, the method for authenticating a seal touch in connection with the sound signal is a result of authenticating a positional relationship for a geometrical positional relationship of the plurality of touched points using a geometrical positional relationship in a design for a plurality of touch units of a touch paint designated with the program. The step of confirming, wherein the third step may recognize a sound signal input through the sound input unit when the geometric positional relationship of the plurality of touch points is authenticated.

According to the present invention, the third step comprises the steps of the program reading the sound signal to check the number or character coded in the sound signal according to the DTMF coding rule, and the program combining the number or character to generate the sound It may include generating a code value included in the signal.

According to the present invention, the third step comprises the steps of the program reading the sound signal to check a bit stream encoded in the sound signal according to a sound code coding rule, and the program reading the bit stream to determine the sound signal. It may include the step of extracting the code value encoded in.

According to the present invention, the third step may include recognizing, by the program, a sound pattern of the sound signal, and generating, by the program, a code value based on the recognized sound pattern.

According to the present invention, the sound signal may be generated through at least one of an electronic module of the touch coating, an electronic module provided to mount the touch coating, and a terminal device at a destination using the touch coating.

According to the present invention, the code value corresponding to the sound signal may include a unique code given to the use of the touch painting or painting, or a disposable code generated through the electronic module of the touch painting or painting use.

According to the present invention, the fourth step may include digital validity authentication in which the program compares and authenticates a unique code provided in an electronic module of the touch painting or painting user and a unique code corresponding to the sound signal. have.

According to the present invention, the fourth step may include digital authentication in which the program compares and authenticates the one-time code generated through the electronic module of the touch painting or painting user and the one-time code corresponding to the sound signal. have.

According to the present invention, by capacitively touching a user's wireless terminal with a touch coating having a plurality of capacitive touch units, various services designated to be provided to the user at a painting location using the touch coating are provided to the user's wireless terminal. It has the advantage of providing real-time through.

According to the present invention, when the geometrical positional relationship formed by a plurality of touch units provided in the touch coating is used as an authentication means or an identification means, the limited touch area of the touch coating (that is, the touch area of the coating cannot be larger than the touch screen area) There is an advantage of deriving an infinite number of cases by solving the limitation on the number of touch units derived from the inside and the limitation on the number of tooth relation cases that can be formed corresponding thereto through a sound signal.

According to the present invention, a geometric positional relationship formed by a plurality of touch units provided in the touch coating is used as an authentication means (eg, a password concept) and a sound signal is used as an identification means (eg, a unique ID concept), or a touch By using the geometrical positional relationship formed by the plurality of touch parts provided in the painting as an identification means and at the same time using a sound signal as an authentication means, the number of cases is infinitely increased and the time required for painting touch authentication is innovatively reduced. There is an advantage.

1 is a diagram showing a schematic diagram of a system configuration for providing a seal touch authentication associated with sound according to an implementation method of the present invention.
2A to 2F are diagrams showing the structure of a touch coating according to an exemplary method of the present invention.
3 is a diagram showing a configuration of an electronic module according to an embodiment of the present invention.
4 is a diagram showing a functional configuration of a wireless terminal and a program according to an exemplary method of the present invention.
5 is a diagram showing the configuration of an operation server according to an embodiment of the present invention.
6 is a diagram illustrating a process of registering a painting touch authentication condition of a touch painting according to an implementation method of the present invention.
7 is a diagram showing a process of registering a stamp usage destination of a touch coating according to an implementation method of the present invention.
8 is a diagram illustrating a process of recognizing a painting touch using a touch painting in a program of a wireless terminal according to an implementation method of the present invention.
9 is a diagram illustrating a process of authenticating a code value corresponding to a sound signal according to an exemplary method of the present invention.
10 is a diagram illustrating a process of authenticating a geometric positional relationship for N touch points according to an exemplary method of the present invention.
11 is a diagram illustrating a process of determining a painting touch authentication result by combining a location relationship authentication result and a sound authentication result according to an implementation method of the present invention.

Hereinafter, the operating principle of a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings and description. However, the drawings and the description to be described below are for a preferred implementation method among various methods for effectively describing the features of the present invention, and the present invention is not limited to the following drawings and description. For example, the configuration unit provided on the server side may be implemented on the terminal side, or conversely, the configuration unit provided on the terminal side may be implemented on the server side.

In addition, in the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. In addition, terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to the intention or custom of users or operators. Therefore, the definition should be made based on the contents throughout the present invention.

As a result, the technical idea of the present invention is determined by the claims, and the following examples are a means for efficiently explaining the technical idea of the present invention to those of ordinary skill in the art to which the present invention belongs. Only.

1 is a diagram showing a schematic diagram of a system configuration for providing a painting touch authentication associated with sound according to an implementation method of the present invention.

In more detail, FIG. 1 shows a touch coating 200 having a plurality of capacitive touch units 250 made of a rubber-elastic conductive material on the capacitive touch screen 405 provided on the user's wireless terminal 400. When a plurality of touch points corresponding to the plurality of touch units 250 of the touch coating 200 are recognized by touching, a time point at which the plurality of touch points are recognized by the program 415 of the wireless terminal 400 The code value corresponding to the sound signal input through the sound input unit 407 is checked and authenticated, but the component values for the plurality of touch points and the sound authentication result for the code value corresponding to the sound signal are assigned to a designated path. When transmitted to the operation server 500 on the network through the operation server 500, after the operation server 500 authenticates the geometric positional relationship of the plurality of touch points, the positional relationship authentication result and the sound signal for the geometrical positional relationship of the plurality of touch points It schematically shows the configuration of a system for finally authenticating a painting touch using the touch painting 200 by combining sound certification results for a code value corresponding to. However, for convenience, the embodiment of the present invention shows an embodiment in which a sound signal is linked to a painting touch authentication, but the present invention is not limited thereto, and in addition to the sound signal, an NFC-based radio frequency signal and/or a short-range wireless The communication-based radio frequency signal can be processed in connection with the painting touch authentication, and the present invention also includes an embodiment of linking an NFC-based radio frequency signal and/or a short-range wireless communication-based radio frequency signal with the painting touch authentication. I have to make it clear.

The system of the present invention includes a touch coating 200 in which a plurality of touch units 250 made of a conductive material are arranged and fixed in a pre-designed geometrical positional relationship, and a plurality of touch units 250 provided in the touch coating 200 It comprises a wireless terminal 400 having a capacitive touch screen 405 to be touched. The wireless terminal 400 is possessed by a user who will be provided with a service using the touch seal 200. The touch stamp 200 is provided (or sold) to a stamp user (eg, an affiliate store or a stamp buyer that provides a service using a stamp touch) to provide a service to the user. Therefore, in the present invention, the touch painting 200 is used as a means for identifying or authenticating the use of the painting. Preferably, the use of the painting may be provided with a cradle 105 for mounting the touch painting 200, or a terminal device 100 to provide a service using the touch painting 200.

According to the implementation method of the present invention, the painting touch using the touch painting 200 is authenticated in connection with sound. Preferably, the sound associated with the painting touch is the electronic module 300 provided in the touch painting 200, the electronic module 300 provided in the mounting of the painting usage place, and the terminal device 100 of the painting usage location. ) (Or the electronic module 300 embedded in the terminal device 100), and is input to the sound input unit 407 of the wireless terminal 400.

The wireless terminal 400 recognizes a plurality of touch points corresponding to the number of the plurality of capacitive touch units 250 provided in the touch coating 200 provided at the painting location through the capacitive touch screen 405, and , And a program 415 for checking component values of the recognized plurality of touch points.

The program 415 of the wireless terminal 400 recognizes a sound signal input through the sound input unit 407 at a designated time point during or after the plurality of touch points are recognized, and a code value corresponding to the recognized sound signal And, by authenticating the validity of the code value corresponding to the sound signal, a sound authentication result for the code value corresponding to the sound signal is determined.

According to an embodiment of the present invention, the code value corresponding to the sound signal is determined by reading the sound signal input through the sound input unit 407 of the wireless terminal 400 according to the DTMF coding rule It may include a code value generated by combining. The code value corresponding to the sound signal may include a code value extracted from the identified bit string by reading the sound signal input through the sound input unit 407 of the wireless terminal 400 according to a specified sound code coding rule. I can. Alternatively, the code value corresponding to the sound signal may include a code value generated by recognizing a sound pattern of a sound signal input through the sound input unit 407 of the wireless terminal 400. Preferably, the code value corresponding to the sound signal is generated through the touch stamp 200 or a unique code given to the stamp use place, or the touch stamp 200 or the electronic module 300 of the stamp using place. It may include a disposable code. Therefore, in the present invention, the validity authentication for the code value corresponding to the sound signal is the validity of the digital method of comparing and authenticating the unique code given to the touch stamp 200 or the stamp using place and the unique code corresponding to the sound signal. It may include authentication, or digital authentication of comparing and authenticating the one-time code generated through the touch seal 200 or the electronic module 300 of the paint use place with the one-time code corresponding to the sound signal.

The program 415 of the wireless terminal 400 transmits component values for a plurality of touch points corresponding to the painting touch and a sound authentication result for a code value corresponding to the sound signal through a designated path, and the The component values of the plurality of touch points and the sound authentication result are transmitted to the designated operation server 500 via a designated path. The designated path may include a relay path for relaying communication between the wireless terminal 400 and the operation server 500 via the relay server 110, or a communication path between the wireless terminal 400 and the operation server 500. have.

The operation server 500 receives component values for a plurality of touch points corresponding to the painting touch and a sound authentication result for a code value corresponding to the sound signal through a designated path, and the geometrical of the plurality of touch points After confirming the geometrical positional relationship in the design for the plurality of touch units 250 of the designated touch coating 200 for authenticating the positional relationship, the geometrical positional relationship of the plurality of touch points is matched with the geometrical positional relationship in the identified design. Is verified to determine the positional relationship authentication result for the geometrical positional relationship of the plurality of touch points, and a sound authentication result for the positional relationship authentication result for the geometrical positional relationship of the plurality of touchpoints and a code value corresponding to the sound signal In combination, the result of the stamp touch authentication using the touch stamp 200 is finally determined and transmitted through a designated path, and the stamp touch authentication result is received by the program 415 of the wireless terminal 400.

According to the implementation method of the present invention, the authentication of the positional relationship for the geometric positional relationship of the plurality of touch points is performed on the design of the plurality of touch units 250 of the touch coating 200 in which the geometrical positional relationship for the plurality of touch points is designated It includes an analogue method of validity authentication that verifies that the geometrical positional relationship and matching within a specified tolerance range. That is, the painting touch authentication result of the present invention is characterized in that it is finally determined by a combination of an analog type validity authentication for a geometric positional relationship at a plurality of touch points and a digital type validity authentication for a code value corresponding to a sound signal.

Hereinafter, for convenience, the characteristics of the present invention will be described by referring to the number of touch units 250 provided in the touch coating 200 as N, but N is N≥2, N≥3, N≥4, N≥ 5, ..., etc. are all possible, and the number N of the touch units 250 is not limited to a specific number or more.

2A to 2F are diagrams showing the structure of a touch coating 200 according to an exemplary method of the present invention.

In more detail, FIG. 2A is a diagram illustrating a cut surface of the side surface in a state where the touch coating 200 is erected on the floor in order to explain the internal structure of the touch coating 200, and FIG. It is a diagram illustrating the flat plate portion 245 and the touch portion 250 visible on the bottom. For those of ordinary skill in the art to which the present invention belongs, various implementation methods for the structure of the touch coating 200 by referring to and/or modifying this Figure 2 (eg, some components are omitted or subdivided, or , Or a combined implementation method) may be inferred, but the present invention includes all the inferred implementation methods, and the technical features are not limited only by the implementation method shown in FIG.

The touch coating 200 of the present invention includes a handle part 205 formed to be gripped by a human hand, N touch parts 250 made of a rubber-elastic conductive material, and N touch parts at a designed position on a flat area. A flat plate part 245 fixing the part 250, and N touch parts 250 and a handle part fixed to the flat part 245 while physically connecting the handle part 205 and the flat part 245 It includes an adapter unit 215 electrically connecting the 205. According to an exemplary method of the present invention, the touch coating 200 may further include a housing part 225 that protects the touch part 250 and the flat part 245. The housing part 225 includes a guide part 220 for guiding the adapter part 215 and/or the flat plate part 245 in a vertical direction while the touch coating 200 is erected as shown in FIG. 2A, and the flat plate A spring part 210 may be provided to maintain the touch part 250 fixed to the part 245 so as to float above a certain height on the floor. Depending on the implementation method, the guide part 220 and the spring part 210 may be omitted, and in this case, the N touch parts 250 fixed to the flat part 245 are exposed to the outside of the housing part 225 Can be.

The handle part 205 is made of a conductive material capable of receiving the capacitance of the human body, or is coated or plated with a conductive material. The conductive material of the handle part 205 is electrically connected to the N touch parts 250. The handle part 205 may be manufactured in a variety of designs according to the request of a painting user using the touch painting 200.

The touch unit 250 is a generic term for a component forming one touch point when the touch coating 200 is touched on the capacitive touch screen 405, and is made of a rubber-elastic conductive material. For example, the touch part 250 may be made of a conductive rubber material or a conductive plastic material.

The touch unit 250 is designed and manufactured to have a contact surface 265 in the shape of a designated figure (eg, polygonal or circular). The contact surface 265 of the touch unit 250 has a contact area calculated by design so as to effectively touch the capacitive touch screen 405. The contact area is based on the capacitance of the human body transmitted to the handle part 205, and one effective capacitive touch using the touch part 250 on the plurality of capacitive touch screens 405 included in the touch target. It is calculated as an area greater than or equal to the area corresponding to the touch sensitivity that can be recognized as a touch point. When designing the touch unit 250 of the touch coating 200 to touch different types of capacitive touch screens 405, if the touch sensitivity of each capacitive touch screen 405 is different, the touch unit ( 250) is calculated as an area greater than or equal to a larger area (that is, an area corresponding to a smaller touch sensitivity) among areas corresponding to each touch sensitivity that can be recognized by each capacitive touch screen 405. desirable. For example, the contact area of the touch unit 250 may be calculated as an area greater than or equal to 25 mm 2, an area greater than or equal to 28 mm 2, an area greater than or equal to 36 mm 2, an area greater than or equal to 38 mm 2, etc. have. Calculating the contact area of the touch unit 250 based on the area corresponding to the touch sensitivity of the capacitive touch screen 405 of the designated device, so that the touch unit 250 is recognized as one effective touch point. At the same time, it is to calculate the maximum number of cases in which each touch unit 250 is provided at different locations within a limited area of the flat plate area.

The contact surface 265 of the touch unit 250 is manufactured in a shape corresponding to the calculated contact area. For example, the contact surface 265 of the touch unit 250 may be manufactured in a 5mm*5mm square shape forming a contact area of 25mm2. Alternatively, the contact surface 265 of the touch unit 250 may be manufactured in a circular shape having a diameter of 6 mm forming a contact area larger than 28 mm 2. Alternatively, the contact surface 265 of the touch unit 250 may be manufactured in a 6mm*6mm square shape forming a contact area of 36mm2. Alternatively, the contact surface 265 of the touch unit 250 may be manufactured in a circular shape having a diameter of 7 mm forming a contact area larger than 38 mm 2.

The side structure of the touch unit 250 is manufactured in a'T' shape in which the touch implementation unit 260 is formed at the center of the buried plate 255 as shown in Fig. 2c, or a part of the buried plate 255 as shown in Fig. 2d. It may be manufactured in a'Г' shape in which the touch implementation unit 260 is formed biased toward the side. The flat plate part 245 supports the buried plate 255 of the touch part 250, and the upper plate part 230 electrically connecting the handle part 205 and the touch part 250, and the touch part 250 are embedded. It is composed of a middle plate part 235 into which the plate 255 is embedded and a lower plate part 240 exposing the touch implementation part 260 of the touch part 250 to the outside as shown in FIG. 2B. The buried plate 255 of the touch unit 250 is embedded in the middle plate unit 235 and supported by the upper plate unit 230, and the touch implementation unit 260 of the touch unit 250 forms a groove of the lower plate unit 240. Is exposed to the outside through. The thickness of the buried plate 255 is formed to have the same thickness as the thickness of the middle plate part 235, and the height of the touch implementation part 260 is formed larger than the thickness of the lower plate part 240 so that the contact surface of the touch part 250 ( 265 is manufactured to be exposed to the outside of the lower plate part 240.

The touch unit 250 is made of a flexible (for example, soft, semi-soft, or semi-rigid) conductive material so that an error does not occur in the geometric touch position relationship of each touch point or a minimum error occurs within the calculated range. As shown in Fig. 2C or Fig. 2D, the center part of the contact surface 265 maintains the designated shape shape and is manufactured by round processing in a structure that protrudes convexly at a predetermined curvature above the boundary line of the shape shape. When the touch unit 250 manufactured as described above is touched on the capacitive touch screen 405, the capacitive touch screen 405 is first formed from the central portion of the contact surface 265 of the touch unit 250 that protrudes convexly at a predetermined curvature. ) Is touched, and when a certain pressing force is applied to the touch unit 250 in this state, the central part is retracted by the pressing force, and as a result, the entire contact surface 265 of the touch unit 250 is calculated. While forming an area, the capacitive touch screen 405 is touched. The midpoint (=touch point) of the touch surface touched on the capacitive touch screen 405 by the touch unit 250 corresponds to or at least calculates the central portion of the contact surface 265 formed on the touch unit 250 It corresponds to the central portion of the contact surface 265 within the specified error range.

The touch unit 250 forms an empty space inside the flexible conductive material as shown in Fig. 2c or 2d in order to further reduce the error in the calculated range or not cause an error in the geometric touch position relationship of each touch point. Can be made. The empty space inside the touch unit 250 provides a space in which the central portion of the contact surface 265 protruding convexly at a predetermined curvature is constricted by a pressing force and can be contracted into the touch unit 250. Since the touch coating 200 is touched on the capacitive touch screen 405 while being held in the hand of a person, the pressure applied to the touch unit 250 by the hand of the person is applied to the capacitive touch screen ( Not only the vertical direction component of 405) exists, but also the horizontal direction component. In this case, in the empty space inside the touch unit 250, even if the horizontal direction component is present in the pressing force, the contact surface 265 of the touch unit 250 is not distorted in either direction by the horizontal direction component and is in the vertical direction. It is induced to contract into the interior of the touch unit 250 by the component. If the contact surface 265 of the touch unit 250 is distorted to either side of the horizontal direction component, as a result, the midpoint of the touched surface on the capacitive touch screen 405 is moved in the distorted direction. So the error increases. An empty space inside the touch unit 250 prevents or minimizes such an error.

The flat plate part 245 is manufactured to have a figure shape designed to fix the N touch parts 250 and a flat plate area. The same type of touch coating 200 means a coating in which the same flat plate part 245 and the same number of touch parts 250 are provided. According to an exemplary embodiment of the present invention, N touch units 250 are fixed to the flat region of the flat plate 245 according to a predesigned geometric positional relationship.

According to the present invention, the geometrical positional relationship in the design of the N touch units 250 is used as a touch authentication condition for authenticating a painting touch using the touch painting 200. Therefore, the N touch portions 250 fixed to the flat plate portions 245 of each painting should have uniqueness that forms a different geometrical positional relationship for each painting. However, since the flat surface area of the flat plate part 245 is finite, and the N touch parts 250 fixed thereon also have a contact area calculated by design, the N touch parts 250 are arranged in different geometric shapes. The number of cases that can be fixed due to the positional relationship is limited. According to the present invention, in the process of designing a location for fixing the N touch units 250 to the flat plate 245, the N touch units 250 may be fixed in different geometrical positional relationships on a finite flat surface area. The minimum discrimination recognition distance is set in order to derive the maximum number of possible cases.

When two or more touch units 250 are touched on the capacitive touch screen 405, the minimum discrimination recognition distance refers to a touch point by two or more touch units 250 on the corresponding capacitive touch screen 405. It includes the minimum separation distance that can be distinguished by For example, if the distance between two touch points multi-touched on the capacitive touch screen 405 is less than 6 mm, two touch points are recognized as one touch point, and if the distance is more than 7 mm, two touch points are recognized. When distinguishing and recognizing by different touch points, the minimum discrimination recognition distance is preferably 7 mm. On the other hand, if there are two or more capacitive touch screens 405 corresponding to objects to be touched with the touch coating 200, the minimum distinguishing recognition distance distinguishes between two touch points multi-touched on two or more capacitive touch screens 405 Among the recognizable minimum separation distances, a larger separation distance may be set.

According to an exemplary embodiment of the present invention, the minimum discrimination recognition distance is a value correlated with the contact area of the touch unit 250. That is, the minimum discrimination recognition distance may be a value set on the capacitive touch screen 405, but is a value experimentally obtained based on an allowable error. For example, even with the same capacitive touch screen 405, if the contact area of the touch unit 250 is 25 mm2 (for example, the contact surface 265 manufactured in a square shape of 5 mm * 5 mm) The minimum discrimination recognition distance may be different from the minimum discrimination recognition distance when the contact area of the touch unit 250 is greater than 38 mm 2 (eg, a contact surface 265 manufactured in a circular shape having a diameter of 7 mm). Therefore, the minimum discrimination recognition distance is preferably set based on experimental data for a plurality of capacitive touch screens 405 based on the contact area of the touch unit 250. In this case, the minimum discrimination recognition distance is set as a distance between the central portion and the central portion of the contact surface 265 of the touch unit 250, or of a figure that implements the contact surface 265 of the touch unit 250. It can be set as the distance between the outline and the outline.

According to the implementation method of the present invention, when the number of the touch coating 200 is to be produced more than the maximum number that can calculate the geometrical positional relationship, only the geometrical positional relationship is applied to the paintwork using the touch coating 200. May not be able to maintain its uniqueness. In order to solve this problem, in addition to the geometrical positional relationship of the N touch units 250, a chip provided in the touch coating 200 and a sound signal transmitted through a speaker (or buzzer) or a sound signal provided in the touch coating 200 A radio frequency signal transmitted through an NFC (Near Field Communication) chip and an antenna may be used as an additional means for maintaining the uniqueness of the touch coating 200. The sound signal can be recognized through the microphone of the wireless terminal 400 having the capacitive touch screen 405 to which the touch seal 200 is touched, and if the NFC module 411 is connected to the wireless terminal 400 If provided, it is possible to recognize the radio frequency signal of the NFC chip provided on the touch coating 200. In this case, the uniqueness of the touch seal 200 may be maintained by a combination of a geometric position relationship formed by the N touch units 250 and a sound signal, or a combination of the geometric position relationship and a radio frequency signal of an NFC chip. have. The sound signal may include a unique code stored in the chip or a disposable code dynamically generated through an algorithm designated by the chip in the form of a Dual Tone Multi-Frequency (DTMF) signal or a sound code. The radio frequency signal of the NFC chip may include a unique code stored in the NFC chip or a disposable code dynamically generated through an algorithm designated by the NFC chip according to the NFC standard.

According to the present invention, different geometrical positional relationships for the N touch units 250 provided in each of the same type of touch coating 200 can be identified as different geometrical positional relationships even if they touch the capacitive touchscreen 405. Must have a distinctiveness. The touch to the capacitive touch screen 405 is a surface touch, not a point touch, and the operating system of the wireless terminal 400 equipped with the capacitive touch screen 405 calculates the center of the touch surface as a touch point, and a specified distance It is calculated that the midpoint has moved only when the abnormal touch surface has moved. Therefore, in the process of designing a location for fixing the N touch units 250 to the flat panel 245, different geometric positional relationships for the N touch units 250 are touched on the capacitive touch screen 405. In order to be identified by different geometric positional relationships in the state, a minimum identification distance is set.

The minimum identification distance is designed with different geometrical positional relationships so that the N touch units 250 fixed to the flat panel 245 are identified by different geometrical positional relationships while being touched on the capacitive touch screen 405 For this purpose, it includes a distance at which the N touch units 250 provided on different flat plate portions 245 must be separated. For example, if the capacitive touch screen 405 detects that the center point has moved when the touch surface of the same area is moved by 3 mm or more, the minimum identification distance may be set to a value greater than or equal to 3 mm.

According to an exemplary method of the present invention, the minimum identification distance may be a value set on the capacitive touch screen 405, but is a value experimentally obtained based on an allowable error. On the other hand, if there are two or more capacitive touch screens 405 corresponding to the object to be touched with the touch coating 200, the minimum identification distance can detect movement of the center of the touch surface on the two or more capacitive touch screens 405. It may be set as the larger of the minimum separation distance.

According to the present invention, even if the N touch units 250 provided on the touch coating 200 are touched in any direction on the capacitive touch screen 405, they must have readability that can be read. Such readability is achieved by a rule of determining any one of the N touch units 250 as a reference point even if the N touch units 250 are touched in any direction on the capacitive touch screen 405. Can be secured.

According to an embodiment of the present invention, the N touch units 250 provided on the flat plate 245 include n touch units 250 provided at n (n<N) calculated positions and at least one designated It includes a designated touch unit 250 provided at a location, and the N touch units 250 (or at least n touch units 250) form a predesigned geometric positional relationship on the flat surface.

According to an embodiment of the present invention, in the process of designing a position for fixing the N touch units 250 to the flat panel 245 in order to secure the readability of the N touch units 250, the flat panel ( The flat area of the 245 is divided into n divided areas 270 by design (however, the divided areas 270 exist by design, and the flat area may not be displayed). One touch unit 250 is fixed to each of the n divided areas 270 at a position calculated by design to form a geometric positional relationship, and any one designated area 275 among the n divided areas 270 One touch unit 250 corresponding to a reference point is fixed at a location designated by design. That is, one touch unit 250 is fixed to each of (n-1) divided areas 270 among the n divided areas 270, and two touch units 250 are fixed to one designated area 275. Is fixed. Preferably, the designated location may be designated at a location in contact with the outline of the figure in the flat area or at a location of the edge of the outline of the figure.

When touching the capacitive touch screen 405 by fixing the N touch units 250 to the n divided areas 270 as described above, the touch authentication system includes n number of touch units 250. Matching the divided area 270 to N touch points to identify a designated area 275 in which two touch points are recognized among the n divided areas 270, and a designated position on the identified designated area 275 The touch points provided in may be determined as reference points of the N touch points. And when the coordinates rotate based on the identified reference point, even if the N touch units 250 are touched in any direction on the capacitive touch screen 405, it is possible to compare the geometric position relationship of the previously registered touch authentication condition. .

FIG. 2E illustrates a state in which the flat area of the flat part 245 is divided into four divided areas 270 by design. Referring to FIG. 2E, a certain margin may exist between each divided area 270 and the divided area 270. Preferably, the blank space preferably includes an interval equal to the minimum discrimination recognition distance, and in this case, even if the touch unit 250 is provided at any position on each divided area 270, it is fixed to each divided area 270. The touch units 250 are always maintained at a distance of more than the minimum discrimination recognition distance. On the other hand, as shown in FIG. 2E, when the space between the divided regions 270 is fixed, the area of the flat plate for calculating the position where the touch unit 250 is to be fixed is reduced by that amount. In order to prevent this, after omitting the margin illustrated in Fig. 2e and dividing the divided area 270, each touch unit 250 is separated by more than the minimum discrimination recognition distance in the process of calculating the position where the touch unit 250 is to be fixed. Can be calculated.

Referring to Fig. 2f, each position to fix one touch unit 250 is calculated in each divided area 270, and one touch unit 250 is designated by designating any of the divided areas 270. The position to further fix is designated. As shown in Fig. 2f, by fixing one touch unit 250 at a calculated position on each divided region 270 and fixing one designated touch unit 250 at a designated position on the designated region 275, N number of A flat plate portion 245 to which the touch portion 250 is fixed is manufactured.

3 is a diagram showing the configuration of an electronic module 300 according to an exemplary method of the present invention.

In more detail, this drawing 3 is provided in the touch painting 200, or provided on at least one of the cradle 105 of the painting location and the terminal device 100 where the painting is used, and a plurality of touch units of the touch painting 200 ( 250), which shows the configuration of the electronic module 300 that outputs a predetermined signal for authenticating a code value to be linked to authentication of geometrical position relations for 250), and those of ordinary skill in the art to which the present invention belongs, Various implementation methods for the function of the electronic module 300 may be inferred by referring to and/or modifying FIG. 3, but the present invention includes all of the inferred implementation methods, and the implementation shown in FIG. The technical characteristics are not limited only by the method. For convenience, the embodiment of FIG. 3 shows and describes the electronic module 300 in the form of a standalone module, but the electronic module 300 includes electronic devices such as a touch seal 200, a cradle 105, and a terminal device 100. It is possible to implement in a spherical form in the configuration part, and the present invention is clearly to include all examples that can be modified as described above.

Referring to FIG. 3, the electronic module 300 includes a control unit 305 and a memory unit 320, and is connected to the geometric positional relationship authentication for the plurality of touch units 250 of the touch coating 200. A sound output unit 310 for outputting a sound signal for code value authentication and a battery 340 for supplying operation power are provided, and a screen output unit 325 for screen output and a user control unit 330 for user manipulation It may be further provided. Meanwhile, according to another implementation method of the present invention, the code value can be output in the form of a radio frequency signal other than a sound signal, and for this purpose, it will be linked with geometric positional relationship authentication for the plurality of touch units 250 of the touch seal 200. An NFC communication unit 315 and/or a short distance communication unit 335 for outputting a radio frequency signal for code value authentication may be provided.

The controller 305 is a generic term for controlling the operation of the electronic module 300 and may be implemented through a logic circuit or may be implemented in a form including at least one processor and an execution memory. Hereinafter, for convenience, the control unit 305 includes a processor and an execution memory, loads at least one program code into the execution memory, calculates, and outputs the result through a designated output unit 370 or a communication unit. Hereinafter, for convenience, a program 350 corresponding to a program code for generating a signal for authenticating a code value to be linked with the geometric positional relationship authentication of the plurality of touch units 250 of the touch coating 200 is shown in the controller 305. I will explain. However, it should be clear that the method of implementing the electronic module 300 is not limited to the embodiment of FIG. 3, and the configuration illustrated by the configuration of the program 350 in FIG. 3 can also be implemented in the form of a logic circuit. It is a bar.

The memory unit 320 is a generic term for a nonvolatile memory provided in the electronic module 300, and includes at least one program code executed through the control unit 305 and at least one data set used by the program code. Save and keep. The program code includes a program code corresponding to a program 350 implemented for the operation of the present invention, a system program code and a system data set corresponding to the operating system of the electronic module 300, and the electronic module 300. It includes communication program code and communication data set that handles various communication.

According to the implementation method of the present invention, the code value of the code value authentication to be linked with the geometric positional relationship authentication for the plurality of touch units 250 of the touch stamp 200 is given to the touch stamp 200 or the place where the painting is used. It may include a unique code, or a disposable code generated through the touch coating 200 or the electronic module 300 of the use of the painting.

According to an exemplary embodiment of the present invention, when the code value is a unique code, the memory unit 320 may store a unique unique code assigned to the touch stamp 200 or the painting location.

According to another embodiment of the present invention, when the code value is a one-time code, the memory unit 320 may store one or more static seed values to be substituted into a designated code generation algorithm to dynamically generate a one-time code. Preferably, the static seed value is a unique serial code uniquely assigned to the touch coating 200, a space identification code that identifies a space (eg, a store, a building, a store, etc.) in which the touch coating 200 is used, It may include various identification codes, including a use identification code for identifying a purpose in which the touch coating 200 is used.

On the other hand, when the code value corresponds to a sound signal, the memory unit 320 may recognize a sound pattern (for example, a designated voice (for example, a segmental sound uttered by a speaker)), a sound source (for example, a sheet music) that can be recognized through a designated pattern recognition algorithm. According to this, pattern information corresponding to at least one sound pattern) among music played through an instrument and a speaker uttered according to a score) may be stored.

The sound output unit 310 is composed of a sound output unit such as a speaker or a buzzer provided in the electronic module 300 and a driving module that drives the same, and is connected to the control unit 305 by a bus. Among various calculation results, sound data corresponding to the calculation result corresponding to sound output is decoded, converted into a sound signal, and then output through the sound output device.

The NFC communication unit 315 is a generic term for processing NFC communication using a radio frequency signal at a close distance of about 10 cm using an antenna, and preferably according to the NFC (Near Field Communication) standard using a 13.56Mz frequency band. Handles two-way NFC communication.

The screen output unit 325 is composed of a screen output unit (eg, LCD (Liquid Crystal Display), electronic paper, etc.) provided in the electronic module 300 and a driving module driving the same, and various types of the control unit 305 Among the calculation results, the calculation result corresponding to the screen output is output to the screen output device.

The user control unit 330 is composed of a user input device provided in the electronic module 300 and a driving module that drives the same, and receives commands for commanding various operations of the control unit 305 or the control unit 305 It receives the data necessary for the operation of.

The short-range communication unit 335 is a short-range communication module that connects a communication session using a radio frequency signal as a communication medium within a certain distance, and preferably supports Wi-Fi communication, Bluetooth communication (for example, Bluetooth Smart after Bluetooth 4.0 standard). Bluetooth communication) and public wireless communication. The short-range communication unit 335 may access a communication network through an access device (eg, a wireless access point (AP)) located in a short distance (eg, within 10 m).

When the code value authentication to be linked with the geometric positional relationship authentication for the plurality of touch units 250 of the touch seal 200 corresponds to a sound signal, the program 350 of the electronic module 300 may include the memory unit ( A storage unit 355 for storing the unique code designated in 320, an encoding unit 365 for generating sound data by encoding the unique code according to a designated sound coding rule, and the sound output unit 310 An output unit 370 for outputting sound data encoded with a code value including a unique code may be provided.

The storage unit 355 stores a unique code of a designated code system in the memory unit 320. Preferably, the unique code is a time when the electronic module 300 is manufactured, a time when the electronic module 300 is mounted on a device (for example, touch painting 200, cradle 105, etc.) The electronic module 300 may be stored in the memory unit 320 at at least one of the times initially set to be used in a designated painting location.

According to the first code storage method of the present invention, the electronic module 300 may be manufactured in a state in which the unique code is stored in the memory unit 320 at the time the electronic module 300 is manufactured, and the storage unit 355 is During the manufacturing process of the module 300, the unique code may be stored in the memory unit 320.

According to the second code storage method of the present invention, the unique code may be stored in the memory unit 320 when the electronic module 300 is mounted on the device where the painting is used, and the storage unit 355 ) Receives or inputs a unique code to be stored in the memory unit 320 from the outside through at least one of the NFC communication unit 315, the user operation unit 330, and the short range communication unit 335, and the received or input unique The code may be stored in the memory unit 320.

According to the third code storage method of the present invention, the unique code may be stored in the memory unit 320 when the electronic module 300 is initially set, and the storage unit 355 includes the NFC communication unit ( 315), receiving or inputting a unique code to be stored in the memory unit 320 from the outside through at least one of the user manipulation unit 330, and the short-range communication unit 335, and storing the received or input unique code in the memory unit Can be stored in (320).

The encoder 365 generates sound data obtained by encoding a code value including the unique code according to a specified sound encoding rule. The sound coding rule may include at least one of a DTMF coding rule and a sound code coding rule.

The DTMF encoding rule is a generic term for encoding '1' to '9', '0','#','*', etc., used for a phone button into a sound signal of an audible frequency band, and preferably in a low frequency region ( For example, by combining the sound frequency of 697Hz, 770Hz, 852Hz, 941Hz) and the sound frequency of the high frequency range (e.g., 1209Hz, 1336Hz, 1477Hz, 1633Hz), '1' to '9', '0','#', '*', etc. are encoded. If the code value is encoded as a DTMF signal, it is preferable that the code value has a designated code structure that can be represented by '1' to '9', '0','#','*', and the like.

The sound code encoding rule is a generic term for encoding rules for inserting a bit string of specified data into a specified bit string of sound data encoded according to a specified sound encoding rule, and preferably the specified according to a data encoding rule matching the sound encoding rule. The data is encoded to generate a sound spreading code applicable to the sound encoding rule, and the generated sound spreading code is encoded into sound data according to the sound encoding rule to generate a sound code encoded with the designated data. It is preferable that the sound spreading code is encoded in a pseudo noise region, whereby the sound spreading code cannot be recognized by the sound recognition ability perceived by ordinary humans.

When sound data encoded with the code value is generated through the encoding unit 365, the output unit 370 outputs the generated sound data through the sound output unit 310. The sound data may be periodically output or may be repeatedly output a specified number of times at a specified time interval. Repeating the output of the sound data a specified number of times at a specified time interval is to increase the probability that the wireless terminal 400 recognizing the sound data recognizes a code value encoded in the sound data.

When the code value authentication to be linked with the geometric positional relationship authentication for the plurality of touch units 250 of the touch seal 200 corresponds to a sound signal, the program 350 of the electronic module 300 may include the memory unit ( A storage unit 355 for storing the sound pattern designated in 320 and an output unit 370 for outputting sound data encoded with the sound pattern through the sound output unit 310 may be provided.

The storage unit 355 stores the designated sound pattern in the memory unit 320. Preferably, the sound pattern is a time when the electronic module 300 is manufactured, a time when the electronic module 300 is mounted on the device where the painting is used, and the electronic module 300 is used in a painting location. It may be stored in the memory unit 320 at at least one of the initially set time points.

According to the first sound pattern storage method of the present invention, when the electronic module 300 is manufactured, the sound pattern may be manufactured in a state in which the sound pattern is stored in the memory unit 320, and the storage unit 355 is During the manufacturing process of the electronic module 300, the sound pattern may be stored in the memory unit 320.

According to the second sound pattern storage method of the present invention, the sound pattern may be stored in the memory unit 320 when the electronic module 300 is mounted on the touch seal 200, and the storage unit ( 355) receives or inputs a sound pattern to be stored in the memory unit 320 from the outside through at least one of the NFC communication unit 315, the user manipulation unit 330, and the short range communication unit 335, and the received or input The sound pattern may be stored in the memory unit 320.

According to the third sound pattern storage method of the present invention, the sound pattern may be stored in the memory unit 320 at the time when the electronic module 300 is initially set, and the storage unit 355 is the NFC communication unit. 315, receiving or inputting a sound pattern to be stored in the memory unit 320 from the outside through at least one of the user manipulation unit 330 and the short-range communication unit 335, and the received or input sound pattern to the memory unit Can be stored in (320).

The output unit 370 outputs sound data including the sound pattern through the sound output unit 310. The sound data may be periodically output or repeatedly output a specified number of times at a specified time interval. Repeating the output of the sound data a specified number of times at a specified time interval is to increase the probability that the wireless terminal 400 that recognizes the sound data recognizes the sound pattern encoded in the sound data.

When the code value authentication to be linked with the geometric positional relationship authentication for the plurality of touch units 250 of the touch stamp 200 corresponds to a sound signal, the program 350 of the electronic module 300 is a designated code generation rule A generator 360 for dynamically generating a one-time code having a structure designated according to the method, an encoding unit 365 for generating sound data by encoding the generated one-time code according to a designated sound coding rule, and the sound output unit 310 ) May be provided with an output unit 370 for outputting sound data encoded with a code value including the disposable code.

The storage unit 355 stores at least one static seed value to be used to dynamically generate the disposable code in the memory unit 320. Preferably, the static seed value is a time when the electronic module 300 is manufactured, a time when the electronic module 300 is mounted on the touch coating 200, and the electronic module 300 is used at a painting location. It may be stored in the memory unit 320 at at least one of the time points initially set for this purpose.

According to the first seed storage method of the present invention, the static seed value may be stored in the memory unit 320 when the electronic module 300 is manufactured, and the storage unit 355 During the manufacturing process of the electronic module 300, the static seed value may be stored in the memory unit 320.

According to the second seed storage method of the present invention, the static seed value may be stored in the memory unit 320 when the electronic module 300 is mounted on the touch coating 200, and the storage unit ( 355 receives or inputs a static seed value to be stored in the memory unit 320 from the outside through at least one of the NFC communication unit 315, the user manipulation unit 330, and the short range communication unit 335, and the reception or input The generated static seed value may be stored in the memory unit 320.

According to the third seed storage method of the present invention, the static seed value may be stored in the memory unit 320 at the time when the electronic module 300 is initially set, and the storage unit 355 is the NFC communication unit. (315), receiving or inputting a static seed value to be stored in the memory unit 320 from the outside through at least one of the user manipulation unit 330 and the short-range communication unit 335, and the received or input static seed value It can be stored in the memory unit 320.

The generation unit 360 includes a code generation algorithm for dynamically generating the disposable code according to a specified code generation rule, and is selected from among the stored one or more static seed values and dynamically determined dynamic seed values by periodic or designated events. One or more seed values are substituted into a designated code generation algorithm (eg, MD4, MD4, SHA, etc.) to dynamically generate a one-time code of a designated structure (eg, code length, number of digits, code structure, etc.). Preferably, the code generation rule may include at least one of a time synchronization method code generation rule and a challenge-response method code generation rule.

According to the first dynamic seed determination method of the present invention, the generation unit 360 checks a time value through a timer (not shown) built in the electronic module 300 and determines the time value (or the time value). A value processed in the form of a value) may be determined as the dynamic seed value.

According to the second dynamic seed determination method of the present invention, the generation unit 360 uses the NFC communication unit 315 to provide a designated device (e.g., a POS terminal, a computer, a wireless terminal 400, etc.) around the touch seal 200. ) May be determined as a dynamic seed value by receiving a seed value transmitted through NFC communication. Preferably, the seed value determined using the NFC communication may include at least one of a time value, a challenge value, and a dynamically generated value.

According to the third dynamic seed determination method of the present invention, the generation unit 360 may receive a seed value transmitted from a designated device or server through the short-range communication unit 335 and determine the dynamic seed value. Preferably, the seed value determined using the short-range communication unit 335 may include at least one of a time value, a challenge value, and a dynamically generated value.

The encoder 365 generates sound data obtained by encoding a code value including the generated disposable code according to a specified sound encoding rule. The sound coding rule may include at least one of a DTMF coding rule and a sound code coding rule.

The DTMF encoding rule is a generic term for encoding '1' to '9', '0','#','*', etc., used for a phone button into a sound signal of an audible frequency band, and preferably in a low frequency region ( For example, by combining the sound frequency of 697Hz, 770Hz, 852Hz, 941Hz) and the sound frequency of the high frequency range (e.g., 1209Hz, 1336Hz, 1477Hz, 1633Hz), '1' to '9', '0','#', '*', etc. are encoded. If the code value is encoded as a DTMF signal, it is preferable that the code value is generated in a designated code structure that can be represented as '1' to '9', '0','#','*', and the like.

The sound code encoding rule is a generic term for encoding rules for inserting a bit string of specified data into a specified bit string of sound data encoded according to a specified sound encoding rule, and preferably the specified according to a data encoding rule matching the sound encoding rule. The data is encoded to generate a sound spreading code applicable to the sound encoding rule, and the generated sound spreading code is encoded into sound data according to the sound encoding rule to generate a sound code encoded with the designated data. It is preferable that the sound spreading code is encoded in a pseudo noise region, whereby the sound spreading code cannot be recognized by the sound recognition ability perceived by ordinary humans.

When sound data encoded with the code value is generated through the encoding unit 365, the output unit 370 outputs the generated sound data through the sound output unit 310. The sound data may be periodically output or may be repeatedly output a specified number of times at a specified time interval. Repeating the output of the sound data a specified number of times at a specified time interval is to increase the probability that the wireless terminal 400 recognizing the sound data recognizes a code value encoded in the sound data.

When the code value authentication to be linked with the geometric positional relationship authentication for the plurality of touch units 250 of the touch stamp 200 corresponds to a radio frequency signal based on short-range wireless communication, the program 350 of the electronic module 300 A storage unit 355 for storing the unique code designated in the memory unit 320 and a transmission unit for transmitting a code value including the unique code to the wireless terminal 400 through the short-range communication unit 335 (375) may be provided.

The storage unit 355 stores a unique code of a code system designated through at least one of the first to third code storage methods in the memory unit 320.

The transmission unit 375 transmits the code value including the unique code to the wireless terminal 400 through the short-range communication unit 335. The code value may be transmitted periodically or may be repeatedly transmitted a specified number of times at a specified time interval. Repeating the transmission of the code value a specified number of times at a specified time interval is to increase the probability that the wireless terminal 400 recognizing the code value will recognize the unique code included in the code value.

When the code value authentication to be linked with the geometric positional relationship authentication for the plurality of touch units 250 of the touch stamp 200 corresponds to a radio frequency signal based on short-range wireless communication, the program 350 of the electronic module 300 The code value including the generated one-time code through the generation unit 360 and the generated one-time code through the short-range communication unit 335 is dynamically generated according to the designated code generation rule to the wireless terminal 400. A storage unit 355 may be provided that includes a transmission unit 375 for transmitting and stores at least one static seed value for dynamically generating the disposable code in the memory unit 320.

The storage unit 355 stores in the memory unit 320 at least one static seed value to be used to dynamically generate the disposable code through at least one of the first to third seed storage methods.

The generation unit 360 includes a code generation algorithm for dynamically generating the disposable code according to a specified code generation rule, and is selected from among the stored one or more static seed values and dynamically determined dynamic seed values by periodic or designated events. One or more seed values are substituted into a designated code generation algorithm (eg, MD4, MD4, SHA, etc.) to dynamically generate a one-time code of a designated structure (eg, code length, number of digits, code structure, etc.). The generator 360 may determine the dynamic seed value through at least one of the first to third dynamic seed determination methods. Preferably, the code generation rule may include at least one of a time synchronization method code generation rule and a challenge-response method code generation rule.

The transmission unit 375 transmits the code value including the disposable code to the wireless terminal 400 through the short-range communication unit 335. The code value may be transmitted periodically or may be repeatedly transmitted a specified number of times at a specified time interval. Repeating the transmission of the code value a specified number of times at a specified time interval is to increase the probability that the wireless terminal 400 recognizing the code value recognizes the one-time code included in the code value.

When the code value authentication to be linked with the geometric positional relationship authentication for the plurality of touch units 250 of the touch seal 200 corresponds to an NFC-based radio frequency signal, the program 350 of the electronic module 300, A storage unit 355 for storing the unique code designated in the memory unit 320, and a transmission unit 375 for transmitting a code value including the unique code to the wireless terminal 400 through the NFC communication unit 315 ), and may further include an activity check unit 380 for checking whether the NFC communication is activated according to an implementation method.

The storage unit 355 stores a unique code of a code system designated through at least one of the first to third code storage methods in the memory unit 320.

The transmission unit 375 transmits the code value including the unique code to the wireless terminal 400 through the NFC communication unit 315. The code value may be transmitted periodically or may be repeatedly transmitted a specified number of times at a specified time interval. Repeating the transmission of the code value a specified number of times at a specified time interval is to increase the probability that the wireless terminal 400 recognizing the code value will recognize the unique code included in the code value.

In order to transmit a unique code at the time when NFC communication is activated between the electronic module 300 and the wireless terminal 400, the activation confirmation unit 380 is a frequency matching the radio frequency signal of the NFC communication unit 315 It is checked whether a radio field is formed around the electronic module 300 by the radio frequency signal of the band. Preferably, the activity check unit 380 may recognize whether a radio field is formed around the electronic module 300 by recognizing the magnitude or change of the radio frequency signal received through the antenna of the NFC communication unit 315.

If the electronic module 300 is provided with the activity check unit 380, the transmission unit 375 is the unique code at the time when NFC communication is activated between the electronic module 300 and the wireless terminal 400 A code value including a may be transmitted, and after transmitting the code value at a time when the NFC communication is activated, it may be repeatedly transmitted a specified number of times at a specified time interval.

When the code value authentication to be linked with the geometric positional relationship authentication for the plurality of touch units 250 of the touch seal 200 corresponds to an NFC-based radio frequency signal, the program 350 of the electronic module 300, A generating unit 360 dynamically generating a one-time use code having a designated structure according to a designated code generation rule, and transmitting a code value including the generated one-time code to the wireless terminal 400 through the NFC communication unit 315 A storage unit 355 is provided with a transmission unit 375 and storing at least one static seed value for dynamically generating the disposable code in the memory unit 320, and the NFC communication is activated according to an implementation method. It may be provided with one or more checks of the activity check unit 380 to check whether it is.

The storage unit 355 stores in the memory unit 320 at least one static seed value to be used to dynamically generate the disposable code through at least one of the first to third seed storage methods.

The generation unit 360 includes a code generation algorithm for dynamically generating the disposable code according to a specified code generation rule, and is selected from among the stored one or more static seed values and dynamically determined dynamic seed values by periodic or designated events. One or more seed values are substituted into a designated code generation algorithm (eg, MD4, MD4, SHA, etc.) to dynamically generate a one-time code of a designated structure (eg, code length, number of digits, code structure, etc.). The generator 360 may determine the dynamic seed value through at least one of the first to third dynamic seed determination methods. Preferably, the code generation rule may include at least one of a time synchronization method code generation rule and a challenge-response method code generation rule.

The transmission unit 375 transmits the code value including the disposable code to the wireless terminal 400 through the NFC communication unit 315. The code value may be transmitted periodically or may be repeatedly transmitted a specified number of times at a specified time interval. Repeating the transmission of the code value a specified number of times at a specified time interval is to increase the probability that the wireless terminal 400 recognizing the code value recognizes the one-time code included in the code value.

In order to transmit a one-time code at the time when NFC communication is activated between the electronic module 300 and the wireless terminal 400, the activity confirmation unit 380 is a frequency matched with the radio frequency signal of the NFC communication unit 315 It is checked whether a radio field is formed around the electronic module 300 by the radio frequency signal of the band. Preferably, the activity check unit 380 may recognize whether a radio field is formed around the electronic module 300 by recognizing the magnitude or change of the radio frequency signal received through the antenna of the NFC communication unit 315.

When the electronic module 300 is provided with the activity check unit 380, the transmission unit 375 is the one-time code when NFC communication is activated between the electronic module 300 and the wireless terminal 400 A code value including a may be transmitted, and after transmitting the code value at a time when the NFC communication is activated, it may be repeatedly transmitted a specified number of times at a specified time interval.

FIG. 4 is a diagram showing the functional configuration of the wireless terminal 400 and the program 415 according to the method of the present invention.

In more detail, FIG. 4 shows a touch coating 200 having a plurality of capacitive touch units 250 made of a rubber-elastic conductive material on the capacitive touch screen 405 provided on the user's wireless terminal 400. When a plurality of touch points corresponding to the plurality of touch units 250 of the touch coating 200 are recognized by touching, the sound signal input through the sound input unit 407 is applied based on the time point at which the plurality of touch points are recognized. The corresponding code values are checked and authenticated, but the component values for the plurality of touch points and the sound authentication results for the code values corresponding to the sound signals are transmitted to the operation server 500 on the network through a designated path for authentication. It shows the functional configuration of the program 415 to be configured and the configuration of the wireless terminal 400 in which the program 415 operates, and those of ordinary skill in the art to which the present invention pertains, refer to this Figure 4. And/or modified to be able to infer various implementation methods for the functional configuration of the wireless terminal 400 and the program 415 (for example, some components are omitted, or subdivided, or combined implementation method). The invention is made including all the inferred implementation methods, and the technical features are not limited only by the implementation method shown in FIG. 4. Preferably, the wireless terminal 400 of FIG. 4 may include at least one of various smart phones capable of wireless communication, various tablet PCs, various PDAs, and various mobile phones.

Referring to FIG. 4, the wireless terminal 400 includes a control unit 401, a memory unit 414, a key input unit 402, a screen output unit 403, a touch input unit 404, and a sound output unit 406. And a sound input unit 407, a short-range wireless communication module 409, a wireless network communication module 410, an NFC module 411, a location positioning module 412, and a USIM reader unit 413, and A battery 408 is provided. The USIM for wireless communication of the wireless terminal 400 is detached from the USIM reader unit 413. The wireless terminal 400 may include at least one portable device of a smart phone, a mobile phone, and a tablet PC having a capacitive touch screen 405.

The control unit 401 is a generic term for controlling the operation of the wireless terminal 400. The controller 401 includes at least one processor and an execution memory in hardware, and is connected to each component of the wireless terminal 400 through a bus. The control unit 401 software loads the program code provided in the memory unit 414 of the wireless terminal 400 into the execution memory through the processor and calculates it, and transfers the result to each component unit through a bus. The operation of the wireless terminal 400 is controlled, and data required for calculation may be transmitted from each component as needed.

The memory unit 414 is a generic term for a nonvolatile memory provided in the wireless terminal 400, and includes at least one program code executed through the control unit 401 and at least one data set used by the program code. Save and keep. The memory unit 414 stores a program 415 implemented in the form of a program code. As the program 415 is driven or activated, the program 415 is loaded and calculated by the control unit 401.

The key input unit 402 includes one or more components of a key button, a keypad, and a keyboard provided in the wireless terminal 400. The key input unit 402 may generate a key event for driving or activating the program 415. Alternatively, the key input unit 402 may generate a key event for activating the capacitive touch screen 405 so that the painting touch is possible.

The screen output unit 403 includes a display (eg, a liquid crystal display (LCD)) provided in the wireless terminal 400 and a driving module for driving the display in the wireless terminal 400. The screen output unit 403 outputs an execution screen or an authentication result of the program 415.

The touch input unit 404 includes a capacitive touch panel made of a transparent material that shares a coordinate plane with the screen output unit 403 and a driving module for driving the capacitive touch panel inside the wireless terminal 400. Done. The capacitive touch screen 405 is implemented by combining the capacitive touch panel made of the transparent material and the display of the screen output unit 403.

The sound output unit 406 includes a speaker provided in the wireless terminal 400 and a driving module for driving the speaker inside the wireless terminal 400, and the sound input unit 407 is It comprises a microphone provided in the terminal 400 and a driving module for driving the microphone inside the wireless terminal 400. When the touch seal 200 has a function of outputting a sound signal, the sound input unit 407 receives the sound signal and transmits data encoded in the sound signal to the program 415.

The wireless network communication module 410 and the short-range wireless communication module 409 are communication resources provided in the wireless terminal 400, and the wireless network communication module 410 accesses a wireless communication network through a base station, and The wireless communication module 409 accesses a communication network through a short-range communication device or a wireless AP (Access Point) located in a short distance.

The NFC module 411 transmits and receives a radio frequency signal at a close distance of about 10 cm in accordance with the NFC standard using a 13.56Mz frequency band among the wireless communication standards of the ISO 18000 series standard. When an NFC chip is provided in the touch seal 200, the NFC module 411 receives a radio frequency signal transmitted through the NFC chip of the touch seal 200, and is encoded in the NFC-based radio frequency signal. Data can be transferred to the program 415.

The position positioning module 412 includes a GPS module for positioning the moving position of the wireless terminal 400. The location positioning module 412 is location information for measuring the location of the wireless terminal 400 at a time when the touch coating 200 having N touch units 250 on the capacitive touch screen 405 is touched. Can be transferred to the program 415.

According to the present invention, the program 415 can be downloaded to the wireless terminal 400 and installed in the wireless terminal 400 through a designated program providing server (eg, Apple's App Store, etc.) (however, the wireless terminal If the manufacturer of (400) installed the program 415 by default, it is omitted). The program 415 may be manually driven or activated by a user, or driven or activated by a depth of push notification. Hereinafter, for convenience, a functional component of the program 415 that is implemented in the form of a program code on the program 415 and is loaded into the control unit 401 to be functionalized by operation is shown in the control unit 401 to describe the features of the present invention. I will do it.

Referring to Figure 4, the program 415 of the wireless terminal 400, the functional authentication condition operating unit 420 for storing the painting touch authentication condition including the code value authentication condition to be authenticated through the program 415 It is equipped with.

According to the implementation method of the present invention, the painting touch authentication condition is stored in the form of a program code on the program 415, or data from the operation server 500 operating the storage medium 510 for storing the painting touch authentication condition. It may be received in a form and stored in the memory unit 414. When the stamp touch authentication condition is stored in the memory unit 414 in the form of data, the authentication condition operation unit 420 is used for the touch stamp 200 to be authenticated through the program 415 from the operation server 500. The stamp touch authentication condition is received, and the received stamp touch authentication condition is stored in a storage area on the memory unit 414 managed by the program 415. Meanwhile, according to the implementation method, the painting touch authentication condition is not stored in the memory unit 414, but is operated in a form referring to the painting touch authentication condition stored in the storage medium 510 at the time when the touch painting 200 is touched. I can.

Referring to Figure 4, the program 415 of the wireless terminal 400, a touch coating 200 having N touch units 250 made of a rubber elastic conductive material on the capacitive touch screen 405. Functionally provided with a touch recognition unit 425 for recognizing the N touch points touched.

The touch recognition unit 425 reads the touch event generated through the operating system of the wireless terminal 400 at least once, and transfers the N touch units 250 provided in the touch coating 200 to the capacitive touch screen 405. Recognizes N touch points touched. Typically, a touch event generated through an operating system does not distinguish between a multi-touch by a human finger and a painting touch by the touch stamp 200. Meanwhile, since the touch coating 200 of the present invention includes N touch units 250 according to a pre-designed pattern, it has a touch characteristic according to a pre-designed rule, and based on this, it is distinguished from multi-touch by a human finger. A touch of the touch coating 200 by the touch coating 200 may be recognized.

The touch recognition unit 425 selectively selects at least one of a simultaneous touch condition, a fixed touch condition, a static touch condition, a dynamic touch condition, and a sequential touch condition in order to clearly determine the touch of the touch coating 200 according to the designed rule. As an additional application, or a combination of two or more conditions may be additionally applied.

The simultaneous touch condition is a condition for determining whether the N touch units 250 provided in the touch coating 200 touch the capacitive touch screen 405 at the same time. The simultaneous touch condition is that the N touch units 250 provided in the flat area of the touch coating 200 are designed and manufactured at the same height (or similar height within the permitted range), and the thus produced touch coating 200 It may be applied when the touch unit 250 is touched on the flat-type capacitive touch screen 405.

When N touch points are recognized by applying the simultaneous touch condition, the touch recognition unit 425 reads the touch event and touches two or more touch points in a state in which the touch points are not touched through the capacitive touch screen 405. It is checked whether the number of touched points is N at the time point is touched. If the number of the identified touch points is N, the touch recognition unit 425 converts the N touch points into touch points that are touched using a touch seal 200 designed and manufactured to satisfy the simultaneous touch condition. I can judge.

Alternatively, when N touch points are recognized by applying the simultaneous touch condition, the touch recognition unit 425 reads the touch event and checks whether two or more touch points are recognized through the capacitive touch screen 405. If two or more touch points are recognized through the capacitive touch screen 405, the touch recognition unit 425 determines the two or more touch points touched on the capacitive touch screen 405 based on the touch event at a designated time. Recognize repeatedly at intervals. The touch recognition unit 425 checks whether the number of touch points touched by the two or more touch points within a predetermined time (or a predetermined number of repeated recognition) from the initial touch recognition time is N. If the number of identified touch points within the predetermined time (or the predetermined number of repetitive recognition) is N, the touch recognition unit 425 applies the N touch points to the touch coating designed and manufactured to satisfy the simultaneous touch condition ( 200) can be used to determine the touch point.

The fixed touch condition is a condition for determining whether a person touches the touch stamp 200 on the capacitive touch screen 405 based on the behavior habit of the person who paints the stamp. In general, in the case of imprinting on paper with a stamp on the stamp, a person who has experienced this behavior will have a habit of keeping the stamp in contact with the paper for a certain period of time until the stamp on the stamp is sufficiently printed on the paper. . Such behavioral habits may be expressed inertia even when the touch coating 200 is touched on the capacitive touch screen 405 without padding.

When N touch points are recognized by applying the fixed touch condition, the touch recognition unit 425 reads the touch event and checks whether N touch points are recognized through the capacitive touch screen 405. If N touch points are recognized through the capacitive touch screen 405, the touch recognition unit 425 determines the N touch points touched on the capacitive touch screen 405 based on the touch event at a designated time. Recognize repeatedly at intervals. The touch recognition unit 425 checks whether the number of touch points repeatedly recognized for a predetermined time (or a predetermined number of repeated recognition) is N. If the number of touch points repeatedly checked for a certain period of time (or a certain number of repeated recognition) is N, the touch recognition unit 425 touches the touch stamp 200 according to the behavior habit of stamping the N touch points. It can be judged by one touch point.

Alternatively, when N touch points are recognized by applying the fixed touch condition, the touch recognition unit 425 reads the touch event and checks whether N touch points are recognized through the capacitive touch screen 405. If N touch points are recognized through the capacitive touch screen 405, the touch recognition unit 425 determines the N touch points touched on the capacitive touch screen 405 based on the touch event at a designated time. Recognize repeatedly at intervals. The touch recognition unit 425 repeatedly checks the positions of the N touch points that have been repeatedly recognized, and compares the positions of the repeatedly identified N touch points for each touch point to see if the positions of the N touch points are not changed. Confirm. If the location of the N touch points is not changed, the touch recognition unit 425 may determine that the touch point touched the touch stamp 200 according to a habit of stamping the N touch points.

The static touch condition is a condition for determining whether the N touch units 250 provided in the touch coating 200 do not move while being touched on the capacitive touch screen 405 and maintain a static state. The static touch condition may be applied when the N number of touch units 250 provided in the touch coating 200 are designed and manufactured so as not to move.

When N touch points are recognized by applying the static touch condition, the touch recognition unit 425 reads the touch event and checks whether N touch points are recognized through the capacitive touch screen 405. If N touch points are recognized through the capacitive touch screen 405, the touch recognition unit 425 determines the N touch points touched on the capacitive touch screen 405 based on the touch event at a designated time. Recognize repeatedly at intervals. The touch recognition unit 425 repeatedly checks the positional relationship of the N touch points that are repeatedly recognized, and compares the positional relationship of the N touch points that have been repeatedly identified, so that the positional relationship of the N touch points is an allowable error range. Make sure it remains static and unchanged within. If the position of the N touch points maintains a static state, the touch recognition unit 425 touches the N touch units 250 fixedly mounted on the touch seal 200 by touching the N touch points. It can be determined by the touch point.

The dynamic touch condition is a condition for determining whether the N touch units 250 provided in the touch coating 200 move according to a rule specified on the capacitive touch screen 405. The dynamic touch condition may be applied when the N touch units 250 provided in the flat area of the touch coating 200 are designed and manufactured to move by a force (= pressure force) to apply a seal. For example, the design and fabrication structure of the touch coating 200 touches the touch coating 200 on the capacitive touch screen 405 while the pressure in the vertical direction (that is, the vertical direction with the touch screen 405). When an attractive force is applied, the dynamic touch condition is applied when at least one of the N touch units 250 is manufactured to slide in a designated direction on the flat surface by a slider that is inclined with the vertical direction. can do.

When N touch points are recognized by applying the dynamic touch condition, the touch recognition unit 425 reads the touch event and checks whether N touch points are recognized through the capacitive touch screen 405. If N touch points are recognized through the capacitive touch screen 405, the touch recognition unit 425 determines the N touch points touched on the capacitive touch screen 405 based on the touch event at a designated time. Recognize repeatedly at intervals. The touch recognition unit 425 repeatedly checks the positions of the repeatedly recognized N touch points, compares the positions of the repeatedly confirmed N touch points, and changes the positional relationship of the N touch points according to a specified rule. Make sure it is dynamic. If the position gap of the N touch points is in a dynamic state in which the positional boundaries of the N touch points are changed according to a specified rule, the touch recognition unit 425 is designed and manufactured to move the N touch points according to a specified rule. It may be determined as a touch point touched by using the touch coating 200 provided with.

The sequential touch condition is a condition for determining whether the N touch units 250 provided in the touch coating 200 are sequentially touched according to a rule designated on the capacitive touch screen 405. The sequential touch condition is that the N number of touch units 250 are electrostatically applied by the force of stamping by varying the height of one or more of the N touch units 250 provided in the flat area of the touch coating 200. It can be applied when it is designed and manufactured to sequentially touch the expression touch screen 405. For example, five touch units 250 made of a rubber-elastic conductive material are provided in a flat area of the flat plate part 245 provided in the touch coating 200, and if the 5 touch parts based on the flat area If one of the touch parts 250 is 5 mm high, the two touch parts 250 are 3.5 mm high, and the two touch parts 250 are 2 mm high, the pressing force at the point of touch As a result, the touch unit 250 having a height of 5 mm among the five touch units 250 is touched first, and the touch unit 250 having a height of 3.5 mm is then touched, and finally, the touch unit 250 having a height of 2 mm is touched. A total of five touch units 250 are touched by being touched, and the sequential touch condition may be applied to the touch coating 200 designed and manufactured to be touched sequentially.

Alternatively, when N touch points are recognized by applying the sequential touch condition, the touch recognition unit 425 reads the touch event and starts at a point when at least one touch point is recognized through the capacitive touch screen 405. The touch points touched on the capacitive touch screen 405 are repeatedly recognized at specified time intervals, and the number of touch points and the location of the touch points are repeatedly checked while the touch points are repeatedly recognized. The touch recognition unit 425 checks a change in the number of touch points during the repetition recognition, and repeatedly checks the position of the touch point according to the change in the number of touch points. Preferably, since the number of touch points increases by the force of a person pressing the touch coating 200, the number of touch points to be changed increases to the designed N, but should not be reduced in the middle. In addition, as the number of touch points increases, the location of additionally identified touch points should be fixed without being changed. The touch recognition unit 425 checks whether the change in the number of repeatedly checked touch points and the location of the touch points have the characteristics of the sequential touch condition as described above, so that the N touch points are sequentially touched according to a specified rule. Confirm. If the N touch points are sequentially touched according to a specified rule, the touch recognition unit 425 includes N touch units 250 designed and manufactured to sequentially touch the N touch points according to a specified rule. It may be determined as a touch point touched by using the touch coating 200. However, since the stamping force or the stamping speed is different for each person who takes the touch stamp 200, it is preferable not to specify a time difference for sequentially touching in the sequential touch condition.

Referring to Fig. 4, the program 415 of the wireless terminal 400 reads the component values for the N touch points touched by using a touch seal 200 having N touch units 250 A touch reading unit 430 is functionally provided.

When N touch points touched on the capacitive touch screen 405 using the touch coating 200 are recognized, the touch reading unit 430 uses N to check the geometric positional relationship formed by the N touch points. The component values for the touch points are extracted. The component values for the N touch points may be composed of at least one or a combination of two or more of a coordinate value, a scalar value, and a vector value on a designated coordinate system. The coordinate system for extracting the component values may include a Cartesian coordinate system applied to the capacitive touch screen 405, while the designated coordinate system includes the N touch points in addition to the coordinate system applied to the capacitive touch screen 405 It is possible to include other coordinate systems defined to interpret the positional relationship to. For example, the component value is a coordinate value in a specified coordinate system such as A(41, y1), B(42, y2), C(43, y3), D(44, y4), E(45, y5), etc. It may include. Alternatively, the component value is a line segment value such as segment AB, segment AC, segment AD, segment AE, etc. calculated based on the coordinate value on the coordinate system, and ∠BAC, ∠BAD, ∠BAE, ∠CAD, ∠CAE, ∠DAE, etc. It may include a scalar value including at least one of the same angle values. Alternatively, the component value may include a vector value calculated based on a reference point or a reference line on the coordinate system. The reference point for calculating the vector value may be an origin on a coordinate system or any one of the N touch points.

Referring to FIG. 4, the program 415 of the wireless terminal 400 may include a location checking unit 435 that checks the location information of the wireless terminal 400.

The positioning unit 435 is the position information of the wireless terminal 400 positioned through the positioning module 412 at any point before, during, and after the N touch points are touched on the capacitive touch screen 405 Check. Preferably, the positioning unit 435 is the wireless terminal 400 positioned through the positioning module 412 at a point in time when component values for N touch points are read through the touch reading unit 430 You can check the location information of.

4, the program 415 of the wireless terminal 400 recognizes a sound signal input through the sound input unit 407, and a sound recognition unit that checks a code value corresponding to the sound signal ( 440), and a signal for recognizing a radio frequency signal input through the NFC module 411 or the short-range wireless communication module 409 according to an implementation method, and confirming a code value corresponding to the radio frequency signal A recognition unit 445 may be provided.

When the electronic module 300 shown in FIG. 3 outputs a sound signal, the sound recognition unit 440 reads the component values for the N touch points through the touch reading unit 430 ( For example, when N touch points corresponding to the number of touch units 250 of the touch seal 200 are recognized), the sound input unit 407 is activated at a certain point in the middle or later through the sound input unit 407 An input sound signal is checked, and a code value corresponding to the sound signal is generated by reading the sound signal or a code value encoded in the sound signal is extracted.

According to the first sound reading method of the present invention, the electronic module 300 may output a sound signal obtained by encoding a code value (eg, a unique code or a one-time code) according to a DTMF coding rule. In this case, the sound recognition The unit 440 may read the input sound signal through a DTMF coding rule to check a number or character coded in the sound signal, and generate a code value included in the sound signal by combining the number or character. have.

According to the second sound reading method of the present invention, the electronic module 300 may output a sound signal obtained by encoding a bit stream corresponding to a code value according to a sound code encoding rule. In this case, the sound recognition unit 440 ) Reads the input sound signal through a sound code encoding rule to check the bit stream encoded in the sound signal, and reads the bit stream to extract a code value encoded in the sound signal.

According to the third sound reading method of the present invention, the electronic module 300 may output a sound signal including a sound pattern (eg, voice, a signal sound of a specific frequency band, etc.) corresponding to a code value. The sound recognition unit 440 may generate a code value corresponding to the sound signal by applying a specified sound pattern recognition rule (eg, a voice recognition algorithm) to the input sound signal.

On the other hand, when the electronic module 300 shown in FIG. 3 outputs an NFC-based radio frequency signal or a short-range wireless communication-based radio frequency signal, the signal recognition unit 445 may include the positioning unit 435 Before the component values for the N touch points are read through the touch reading unit 430 (e.g., when N touch points corresponding to the number of touch units 250 of the touch stamp 200 are recognized), At some point in the middle or later, the NFC module 411 or the short-range wireless communication module 409 is activated to check the radio frequency signal received through the NFC module 411 or the short-range wireless communication module 409, and the wireless The code value transmitted from the electronic module 300 may be extracted by reading the frequency signal.

Referring to FIG. 4, the program 415 of the wireless terminal 400 includes the N touch units 250 provided in the touch painting 200 using the painting touch authentication condition. A code value authentication unit 450 for authenticating the validity of a code value corresponding to the sound signal input through the sound input unit 407 of the wireless terminal 400 at the time when the capacitive touch screen 405 is touched. do.

When the code value corresponding to the sound signal according to the first code value embodiment of the present invention includes a unique code stored in the electronic module 300, the code value authentication unit 450 The code value corresponding to the sound signal and the unique code to be compared are checked, and the validity of the code value corresponding to the sound signal digitally is determined by comparing the code value corresponding to the sound signal with the unique code of the code value authentication condition. By authenticating, the sound authentication result for the code value corresponding to the sound signal is determined. The sound authentication result may include an authentication error result or an authentication success result.

According to the second code value embodiment of the present invention, when the code value corresponding to the sound signal includes a one-time code dynamically generated through the electronic module 300, the code value authentication unit 450 authenticates the code value. From the condition, a code generation rule for dynamically generating a one-time code to be compared with a code value corresponding to the sound signal is checked, a one-time code is dynamically generated using the code generation rule, and then a code value corresponding to the sound signal By comparing the generated one-time code with and digitally verifying the validity of the code value corresponding to the sound signal, a sound authentication result for the code value corresponding to the sound signal is determined. The sound authentication result may include an authentication error result or an authentication success result.

Referring to Fig. 4, the program 415 of the wireless terminal 400 includes component values for N touch points touched on the capacitive touch screen 405 and a code value corresponding to the sound signal. It includes an information transmission unit 455 for processing the sound authentication result to be transmitted to the designated operation server 500 by transmitting through a designated path.

The information transmission unit 455 checks the component values for the N touch points read through the touch reading unit 430, and transmits the component values for the N touch points according to a specified data exchange protocol. And, the component values for the N touch points are received to the operation server 500 through a designated path.

The information transmission unit 455 checks the sound authentication result for the code value corresponding to the sound signal, transmits the sound authentication result for the code value corresponding to the sound signal according to a designated data exchange protocol, and the sound The authentication result is received to the operation server 500 through a designated path. Depending on the implementation method, the information transmission unit 455 may transmit a signal authentication result for the code value identified through the signal recognition unit 445 instead of the code value corresponding to the sound signal.

The information transmission unit 455 can check the location information of the wireless terminal 400 checked through the location check unit 435, and transmit the location information of the wireless terminal 400 according to a designated data exchange protocol, and , The location information of the wireless terminal 400 is received to the operation server 500 through a designated path.

Referring to Figure 4, the program 415 of the wireless terminal 400 is a sound for a position relationship authentication result for the geometric position relationship of the N touch points and a code value corresponding to the sound signal through a designated path. It includes an authentication result receiver 460 for receiving a painting touch authentication result using the touch painting 200 finally determined by combining the authentication results.

After the operation server 500 authenticates the geometric positional relationship of the N touch points, the positional relationship authentication result for the geometrical positional relationship of the N touch points and the sound authentication result for the code value corresponding to the sound signal After the final determination of the painting touch using the touch painting 200 by combining them, the painting touch using the touch painting 200 is transmitted through a designated path, and the authentication result receiving unit 460 is the operation server through the designated path. Receives the stamp touch authentication result transmitted from 500. The program 415 of the wireless terminal 400 is a service corresponding to the stamp touch authentication using the touch stamp 200 when the stamp touch using the touch stamp 200 is finally authenticated (for example, a value accumulation service , Value use service, etc.).

Figure 5 is a diagram showing the configuration of the operation server 500 according to the implementation method of the present invention.

In more detail, FIG. 5 is a touch coating 200 designed and manufactured according to a rule in which the N touch points are designated by reading the geometric positional relationship of the N touch points touched on the capacitive touch screen 405 of the wireless terminal 400. ) Shows the configuration of a system for authenticating whether or not the N touch units 250 are touched, and those of ordinary skill in the art to which the present invention belongs, refer to and/or modify this Figure 5 Various implementation methods for the configuration of the operation server 500 (e.g., some components are omitted, or subdivided, or combined implementation method) may be inferred, but the present invention includes all the inferred implementation methods. It is made, and the technical features are not limited only by the implementation method shown in FIG.

The operation server 500 of this figure 5 is a server that communicates with the program 415 of the wireless terminal 400 shown in FIG. 4 and a designated path, or the program 415 of the wireless terminal 400 and a designated path It is a generic term for a program code configuration implemented in software on a server that communicates through.

Referring to FIG. 5, the operation server 500 is an authentication condition storage unit for storing a painting touch authentication condition including a geometrical positional relationship in design for the N touch units 250 provided in the touch painting 200. It has 505.

According to an embodiment of the present invention, N touch parts 250 are provided on the flat part 245 of the touch coating 200, and the N touch parts 250 include at least one designated touch part 250 and n (n<N) touch units 250 are provided. Depending on the implementation method, the touch coating 200 may include two or more designated touch units 250, whereby the present invention is not limited. The designated touch part 250 is a touch part 250 provided at a designated position on the flat part 245 of the touch coating 200 and wirelessly transmits the N touch parts 250 provided in the flat part 245. A touch unit 250 corresponding to a reference point for reading N touch points recognized by touching the capacitive touch screen 405 of the terminal 400. The n number of touch units 250 are the remaining touch units 250 excluding the designated touch unit 250 among the touch units 250 provided on the flat unit 245 of the touch coating 200, and the flat unit 245 ) Is provided at the calculated position on the top.

According to the implementation method of the present invention, the position of mounting the n number of touch units 250 on the flat portion 245 of the touch coating 200 is calculated by a designated design device (not shown), preferably The calculated position is based on the area of the area where the touch unit 250 can be mounted on the flat panel 245, the contact area of each touch unit 250, and the minimum discrimination recognition distance (and/or minimum identification distance). It is preferable that each flat portion 245 of each touch coating 200 is calculated at a different position within the calculated maximum number of cases. The design device is designed to mount at least one touch unit 250 of the N touch units 250 at a designated position (eg, a corner portion) on the flat plate unit 245. The manufacturing apparatus (not shown) manufactures a flat plate part 245 to have n touch parts 250 at a calculated position designed by the design device and at least one designated touch part 250 at a designated position. , N touch units 250 are mounted at the designated and calculated positions of the fabricated flat plate unit 245.

According to the implementation method of the present invention, the design device divides the flat area of the flat part 245 into n divided areas 270 by design, and each divided area 270 includes one touch unit 250. It is desirable to design so that) is provided. In this case, the calculated position at which the n number of touch units 250 are provided is limited to the position on the divided area 270. The design device designates at least one of the n divided areas 270 divided by design as a designated area 275 having a designated touch unit 250, and a designated position on the designated area 275 The designation touch unit 250 is designed to be provided at. If any one of the n divided regions 270 is designated as the designated region 275 and one designated touch unit 250 is provided at any designated position on the designated region 275, the design device Of the n divided areas 270, (n-1) divided areas 270 are each provided with one touch unit 250, and the one designated area 275 includes a designated touch unit 250 It is designed so that two touch units 250 are provided.

The authentication condition storage unit 505 checks the geometrical positional relationship on the design formed by the N touch units 250 provided on the flat panel 245 of the touch coating 200 designed as described above, and The painting touch authentication condition including the positional relationship is stored in the designated storage medium 510. Preferably, the authentication condition storage unit 505 is designed to have N number of touch units 250 on the flat plate 245 in the process of designing or manufacturing the flat plate 245 of the touch coating 200 After confirming the geometrical positional relationship corresponding to the calculated position of the image and the designated position, inputting it from a designated terminal, or receiving it from a design device, the painting touch authentication condition including the geometrical positional relationship of the design is specified in a designated storage medium ( 510). Meanwhile, since at least one of the calculated positions in which n number of touch units 250 are mounted is designed differently within the number of allowed cases for each of the flat parts 245 of each touch coating 200, the geometrical It is preferable that the positional relationship has a different relationship for each flat portion 245 of each touch coating 200 within the number of cases described above.

According to the implementation method of the present invention, the geometrical positional relationship in the design includes the relative coordinate values of the N touch units 250 provided on the flat panel 245 of the touch coating 200 based on a preset designated coordinate system. Including a coordinate relationship and/or a distance relationship between the N touch units 250 and a reference point on the designated coordinate system based on a coordinate value on the designated coordinate system (for example, a touch of any one of the N touch units 250 An angular relationship formed by each of the touch units 250 may be included based on a point corresponding to the coordinate value of the unit 250, an origin on the designated coordinate system, or an arbitrary reference point on the designated coordinate system. The angular relationship is an angle formed by a line segment connecting the reference point and the two touch units 250 or an angle formed by the reference point and each touch unit 250 based on a reference line passing through the reference point. Can include. Here, the designated coordinate system is a coordinate system that serves as a reference for analyzing the geometric positional relationship formed by the N touch units 250, and is preferably composed of metrological units (eg, µm, ㎜, ㎝) or designated logical units in the real world. It is preferable to include a coordinate system. However, depending on the implementation method, it is possible to include the coordinate system of the touch screen 405 of the wireless terminal 400. Preferably, the geometrical positional relationship in the design is preferably set based on the midpoint of each touch unit 250.

According to the implementation method of the present invention, each of the touch units 250 provided on the flat portion 245 of the touch coating 200 has a constant contact area, and the capacitive touch screen 405 of the wireless terminal 400 Since the midpoint of the touched touch point is calculated based on the touched surface, noise generated in the touch recognition process of the capacitive touch screen 405 or the contamination state of the touch screen 405 The geometric positional relationship formed by the N touch points recognized by touching the touch units 250 on the capacitive touch screen 405 and the N touch units provided on the flat plate 245 of the touch coating 200 ( 250) may not always match. Accordingly, the design geometrical positional relationship includes design error information corresponding to a design tolerance (eg, within a 95% coincidence range of a Gaussian probability distribution) for authenticating the geometrical positional relationship of the N touch points. It is preferably set. The authentication condition storage unit 505 checks (or determines) design error information for the geometric positional relationship in the design, and stores a designated seal touch authentication condition including the geometrical positional relationship and design error information in the design. It can be stored in the medium 510. If the actual measurement position relationship is not confirmed, the painting touch authentication condition may be used for authentication.

According to the implementation method of the present invention, the painting touch authentication condition may include an authentication condition for a minimum identification recognition distance and/or a minimum identification distance for the touch painting 200. If the electronic module 300 shown in FIG. 3 is provided in the place where the paint is used (or the touch device of the place where the paint is used, the cradle 105, the terminal device 100, etc.), it outputs a sound signal corresponding to the code value. In case (or outputting an NFC-based radio frequency signal, or outputting a radio frequency signal based on short-range wireless communication, etc.), the painting touch authentication condition is for authenticating the validity of the code value corresponding to the sound signal. A code value authentication condition may be further included. If the code value corresponding to the signal output from the electronic module 300 is a unique code of a designated code system, the code value authentication condition may include a unique code to be compared with a code value corresponding to the signal. Or, in case the code value corresponding to the signal output from the electronic module 300 is dynamically generated one-time code, the code value authentication condition is a code for dynamically generating a one-time code to be compared with the code value corresponding to the signal A generation rule (eg, a code generation algorithm, a fixed seed value, a rule for determining a dynamic seed value (eg, time or challenge), etc.) may be included.

On the touch coating 200 (or a device linked to the touch coating 200 (e.g., the cradle 105 of the touch coating 200, the terminal device 100 of an affiliated store operating the touch coating 200, etc.)) When a function for outputting a sound signal or an NFC chip is provided, the painting touch authentication condition may further include an authentication condition for authenticating a unique code or a disposable code encoded in the sound signal or the NFC-based radio frequency signal.

Meanwhile, according to the implementation method of the present invention, the flat portion 245 of the touch coating 200 is divided by design into n divided areas 270, and each of the calculated positions on the n divided areas 270 When the touch unit 250 is provided and one designated touch unit 250 is designed to be provided in any one designated area 275 among the n divided areas 270, the authentication condition storage unit 505 Check the geometric positional relationship in the design corresponding to the distance relationship and the angular relationship formed by one designated touch unit 250 and n number of touch units 250 designed on the flat plate part 245, and the confirmed geometric position on the design A painting touch authentication condition including the relationship and information on the divided areas 270 for the n divided areas 270 may be configured and stored in a designated storage medium 510.

According to the implementation method of the present invention, the geometrical positional relationship in design for the touch coating 200 having at least one designated touch part 250 and n number of touch parts 250 is designated touch based on a preset designated coordinate system. Including a coordinate relationship including relative coordinate values for the unit 250 and the n touch units 250, and/or the designated touch unit 250 and each of the n touch units ( The distance relationship between 250) and the angular relationship formed by the n number of touch units 250 based on the designated touch unit 250 on the designated coordinate system may be included.

When the flat plate part 245 designed as described above is manufactured, the authentication condition storage unit 505 checks the serial code given to the flat plate part 245 provided with the N touch parts 250, or a designated terminal After receiving input from or provided from a manufacturing apparatus, the painting touch authentication condition and serial code may be mapped and stored in a designated storage medium 510.

According to the implementation method of the present invention, after the touch coating 200 is designed and manufactured as described above, the geometrical positional relationship of the design for the touch coating 200 and the flat part 245 of the touch coating 200 A procedure of verifying whether a geometric positional relationship when the provided N touch units 250 are touched on the capacitive touch screen 405 is matched within a specified tolerance range may be performed. In this case, the authentication condition storage unit 505 includes N touches repeatedly touched more than a specified number of times on a capacitive touch panel provided in a designated device to register a geometric positional relationship with the touch unit 250 of the touch coating 200. Check the component value for a point, match the repeatedly touched component value with the geometric positional relationship on the design, and compare it within a specified error tolerance (e.g., within a 95% match range of the Gaussian probability distribution) ), it is determined whether the N touch points are touched. If the repeatedly touched component value coincides with or is close to the geometric positional relationship of the design within a specified error tolerance, the authentication condition storage unit 505 provides actual measurement error information based on the repeatedly touched component value. After calculating and generating a geometrical positional relationship including the geometrical positional relationship on the design and the calculated actual measurement error information, the painting touch authentication condition including the generated geometrical positional relationship may be stored. On the other hand, when the value of the repeatedly touched component and the geometrical position of the design exist within a specified error tolerance, the actual measurement error is included in the design error, and the authentication condition storage unit 505 It is possible to store a painting touch authentication condition to be used for authentication, including geometric positional relationship and the design error information.

According to the implementation method of the present invention, the authentication condition storage unit 505 receives a serial code assigned to the flat panel 245 of the touch seal 200 to be registered from a device designated for registration, and the received serial code Check the geometric positional relationship in the design to calculate error information using. The authentication condition storage unit 505 checks the component value repeatedly touched more than a specified number of times on the capacitive touch panel of the registration device through the touch point verification unit 520 below, and the following touch point authentication unit ( In connection with 530), it is checked whether the mutual positional relationship of the identified touch points is valid, and in connection with the following reference point identification unit 535 and the positional relationship calculation unit 540, the N touch points repeatedly touched The relationship between the actual measurement location and the distance relationship and angle relationship included in the actual measurement location relationship, and the distance relationship and angle relationship included in the geometrical location relationship in the design corresponding to the painting touch authentication condition confirmed through the serial code It is checked whether the actual measurement position relationship exists within a specified error tolerance based on the design geometric position relationship. If the actual measurement position relationship is out of the specified error tolerance range, the flat plate portion 245 of the manufactured touch coating 200 is error-corrected to fall within the specified error tolerance range, or a procedure of remanufacturing after disassembly is performed. Preferably, for this purpose, the authentication condition storage unit 505 outputs information necessary for error correction or remanufacturing of the flat part 245 of the manufactured touch coating 200 and instructs the work accompanying it. I can. On the other hand, if the component value repeatedly touched on the capacitive touch screen 405 of the registration device is within a specified error tolerance, the authentication condition storage unit 505 provides error information based on the repeatedly touched component value ( For example, after checking actual measurement error information or design error information), generating a geometric positional relationship including the geometrical positional relationship in the design and the identified error information, and then touching the stamp including the generated geometrical positional relationship Authentication conditions can be saved.

On the other hand, when the produced touch stamp 200 is supplied to a stamp use place (eg, an affiliate store that provides a designated service using the touch stamp 200) in a specific location (or region), the authentication condition storage unit 505 receives the serial code of the touch stamp 200 and location area information (eg, address information, area information, etc.) of the user destination from the terminal device 100 provided at the user destination, and the serial code Based on, the painting touch authentication condition corresponding to the touch painting 200 provided to the user is checked. If the stamp touch authentication condition mapped with the serial code is not confirmed, the authentication condition storage unit 505 sends a non-registration error for the touch stamp 200 corresponding to the authentication code to the terminal device 100 of the user. Transmit. On the other hand, when the stamp touch authentication condition mapped with the serial code is confirmed, the authentication condition storage unit 505 may map the checked stamp touch authentication condition and the location area information of the use destination and store it in the storage medium 510. have.

According to the implementation method of the present invention, the authentication condition storage unit 505 provides the code value authentication condition among the painting touch authentication conditions stored in the storage medium 510 to the program 415 of the wireless terminal 400. The program 415 of the wireless terminal 400 stores the code value authentication condition in the memory unit 414, and then recognizes it at the time when N touch points are touched on the capacitive touch screen 405 It can be used to authenticate the code value corresponding to the sound signal. Meanwhile, according to an implementation method, the code value authentication condition may be referenced through the program 415 of the wireless terminal 400 in a state stored in the storage medium 510.

Referring to Figure 5, the operation server 500, the sound authentication result for the component values for the N touch points transmitted from the program 415 of the wireless terminal 400 and the code value corresponding to the sound signal An information receiving unit 515 for receiving a signal through a designated path may be provided, and a location information checking unit 525 may be provided to check the location information of the wireless terminal 400.

The touch coating 200 including a plurality of capacitive touch units 250 made of rubber elastic conductive material is touched on the capacitive touch screen 405 provided in the wireless terminal 400 of the user, and the touch coating 200 ), when a plurality of touch points corresponding to the plurality of touch units 250 are recognized, input through the sound input unit 407 based on a time point at which the plurality of touch points are recognized in the program 415 of the wireless terminal 400 The code value corresponding to the sound signal to be verified and authenticated, but the component value for the plurality of touch points and the sound authentication result for the code value corresponding to the sound signal are transmitted through a designated path to the operation server 500 on the network. When transmitted to, the information receiving unit 515 receives component values for the N touch points and a sound authentication result for code values corresponding to the sound signals through a designated path.

According to the implementation method of the present invention, the program 415 of the wireless terminal 400 transmits the sound authentication result for the component values for the N touch points and the code value corresponding to the sound signal. After, at a specified time point, the location information of the wireless terminal 400 can be checked and transmitted. In this case, the location information checking unit 525 is transmitted from the program 415 of the wireless terminal 400 through a designated path. The location information of the wireless terminal 400 can be received. On the other hand, when the program 415 of the wireless terminal 400 does not transmit the location information of the wireless terminal 400, the location information checking unit 525 is a base station or a base station in which a wireless section is formed with the wireless terminal 400 Location information of the wireless terminal 400 can be checked based on cell-based location information corresponding to a location calculated using the wireless AP.

Referring to Figure 5, the operation server 500, the N touch units 250 provided in the touch coating 200 touched on the capacitive touch screen 405 of the wireless terminal 400 It includes a touch point check unit 520 to check the component value for the touch point.

The touch point checking unit 520 checks the component values of the N touch points touched on the capacitive touch screen 405 of the wireless terminal 400. If the component value includes the coordinate value of the touch screen 405 coordinate system, the touch point check unit 520 converts the component value to a coordinate system corresponding to the geometric positional relationship included in the painting touch authentication condition. You can convert the coordinates. Meanwhile, the coordinate conversion may be performed by the following touch point authentication unit 530, a reference point identification unit 535, or a position relationship calculation unit 540.

Referring to Fig. 5, the operation server 500 reads the mutual positional relationship between each of the N touch points using the component values for the N touch points, and the read mutual positional relationship is designed and manufactured. A touch point authentication unit 530 for authenticating whether a positional relationship that can be formed by touching the touch unit 250 of the touch coating 200 on the capacitive touch screen 405 is included.

The touch point authentication unit 530 reads the component value checked through the touch point check unit 520, and the N touch points provided on the flat surface 245 of the touch seal 200 are effective. It is authenticated whether it is a touch point touched by the unit 250.

According to the implementation method of the present invention, the touch point authentication unit 530 calculates the distance between the N touch points, and the calculated distance between the touch points is less than the minimum discrimination recognition distance set for the effective touch stamp 200. By reading whether they are greater than or equal to each other, it is possible to verify whether the N touch points are touch points of the effective touch coating 200 designed and manufactured according to the design method according to the present invention. The distance comparison is compared based on a coordinate distance on the same coordinate system, and coordinate transformation may be performed for this. If any one of the distances between the touch points is smaller than the set minimum discrimination recognition distance within a specified tolerance range, it may be determined that the N touch points are not valid touch points of the touch coating 200. If the N touch parts 250 provided on the flat part 245 of the touch coating 200 are composed of at least one designated touch part 250 and n touch parts 250, the touch point authentication part 530 calculates the distance between the n touch units 250, and compares the distance between the n touch units 250 to the minimum discrimination recognition distance, and the N touch points are touches of the effective touch coating 200 designed and manufactured according to the design method according to the present invention. You can verify whether it is a point.

According to an exemplary method of the present invention, the touch point authentication unit 530 sets and maintains an N-angle structure condition formed by a line segment connecting N touch points. If the N touch parts 250 provided on the flat part 245 of the touch coating 200 are composed of at least one designated touch part 250 and n touch parts 250, the N-shaped structure condition (N-1) of the n divided areas 270 that divide the flat area of the flat part 245 of the effective touch coating 200, (n-1) divided areas 270 have one touch part 250 having a designated contact area. ) Is provided, and one or more conditions for reading the geometrical characteristics of the N-angle due to the two touch units 250 including the designated touch units 250 are provided in any one designated area 275 do. For example, the N-gonal structure condition is formed based on a contact area size of the touch unit 250, a minimum discrimination recognition distance, a minimum discrimination distance, a method of dividing a flat area, and a blank area that is not used on the flat area. Conditions for geometric properties for possible N-gons, and/or conditions for non-formable geometric properties may be included. When the N-gonal structure condition is set, the touch point authentication unit 530 connects the N touch points to form an N-angle, and reads the geometric characteristics of the formed N-gonal structure through the set N-gonal structure condition. , It is possible to authenticate whether the N touch points are touch points of the effective touch coating 200 designed and manufactured according to the design method according to the present invention.

When the component value is converted to the coordinates in the designated coordinate system, it is preferable that the touch point authentication unit 530 reads the mutual positional relationship between the N touch points by using a value set as information on the designated coordinate system. If the component value is in a state in which the coordinate is not converted to the designated coordinate system, the touch point authentication unit 530 may coordinate the component value to the designated coordinate system and read the mutual positional relationship.

Referring to Figure 5, the operation server 500, a reference point identification unit 535 for identifying a reference point for reading the geometric positional relationship of the N touch points, and between each touch point based on the reference point Authenticate by matching and comparing the geometrical positional relationship of the stamp touch authentication condition stored through the authentication condition storage unit 505 and the geometrical positional relationship to be authenticated. A touch authentication processing unit 545 is provided. If the N touch parts 250 provided on the flat part 245 of the touch coating 200 are composed of at least one designated touch part 250 and n touch parts 250, the operation server 500 ) Is a reference point identification unit for identifying a designated touch point provided at a designated position of the designated region 275 by reading the component value through information of the divided region 270 for the n divided regions 270 (535), a location relationship calculation unit 540 for calculating an authentication target geometrical positional relationship between the identified designated touch point and each of the n touch points, and the stamp touch authentication stored through the authentication condition storage unit 505 And a touch authentication processing unit 545 for matching and comparing the geometrical positional relationship of the condition and the geometrical positional relationship to be authenticated between the calculated designated touch points and each of the n touch points. Hereinafter, for convenience, based on an embodiment in which the N touch units 250 provided on the flat panel 245 of the touch coating 200 are composed of at least one designated touch unit 250 and n touch units 250, the A technical feature for authenticating the geometric positional relationship of the N touch points will be described. However, the technical features of the present invention are not limited to the following embodiments, and any method of authenticating the geometrical positional relationship with respect to the N touch points by determining a reference point is clearly revealed to be included in the scope of the present invention.

The reference point identification unit 535 stores the component value verified through the touch point identification unit 520 or the component value authenticated through the touch point authentication unit 530 to the n divided areas 270. Matched with information of the divided region 270 for. If the divided area 270 information is set as coordinate area information on the designated coordinate system, the reference point identification unit 535 matches the component value converted to the designated coordinate system with the divided area 270 information. The component value is a state in which the coordinates are converted into the designated coordinate system through the touch point identification unit 520 or the touch point authentication unit 530, or the reference point identification unit 535 converts the coordinates to the designated coordinate system. Coordinates can be converted.

According to the first reference point identification method of the present invention, the reference point identification unit 535 virtually designates any one of the N touch points in order to match the information of the divided area 270 and the component value. After determining as a touch point, matching the virtual designated touch point and the divided area 270 information, and then performing a process of coordinate rotation of n touch points based on the virtual designated touch point at least once, It is possible to check whether two touch points exist on the designated area 275 in which the virtual designated touch point is located among the divided areas 270 and one touch point exists in each of the remaining (n-1) divided areas 270. If two touch points exist in the designated area 275 where the virtual designated touch point is located, and one touch point exists in each of the remaining (n-1) divided areas 270, the virtual designated touch point is determined according to the present invention. It can be identified by a designated touch point provided at a designed designated location.

According to an exemplary method of the present invention, the reference point identification unit 535 is an N-shaped geometric characteristic formed by the N touch points in order to shorten the process of matching the information of the divided area 270 and the component value. Based on, a touch point having a high probability of being a designated touch point among the N touch points may be predicted, and a process of first determining and matching a virtual designated touch point from the predicted touch point may be performed. For example, the reference point identification unit 535 may predict a touch point on both sides of the corresponding vertex as a virtual designated touch point when there is a vertex greater than 180° among the inner angles of the N-shaped vertices. have.

According to the second reference point identification method of the present invention, the reference point identification unit 535 matches the design virtual origin and the divided area 270 information, and designates any one of the N touch points as a virtual origin reference. After matching to the touch point position, two touch points exist in the designated area 275 among the n divided areas 270 by performing the process of coordinate rotation of the N touch points based on the virtual origin at least once. And it is possible to check whether one touch point exists in each of the remaining (n-1) divided regions 270. If two touch points exist in the designated area 275 and one touch point exists in each of the remaining (n-1) divided areas 270, a virtual designated touch point is provided at a designated location designed according to the present invention. It can be identified by a designated touch point.

When a designated touch point is identified among the N touch points, the location relationship calculation unit 540 determines the distance relationship between the identified designated touch point and the n number of touch points provided in the n divided areas 270 and the identification. An authentication target geometrical positional relationship between the designated touch point and each of the n touch points, including an angular relationship formed by the n touch points, is calculated based on a designated designated touch point.

The distance relationship includes a coordinate distance on a designated coordinate system. The coordinate distance includes a relative coordinate distance calculated through a coordinate value based on a designated coordinate system, and may be expressed as a vector value further including a specific direction on the designated coordinate system according to an implementation method.

The angular relationship includes a coordinate angle on a designated coordinate system. The coordinate angle includes an angle on a coordinate system formed by two touch points among n touch points, using the designated touch point as a reference point, or the designated touch point and each n touch points based on a specific reference line on the designated coordinate system. The angle formed by the connected line segments may be included.

According to an exemplary method of the present invention, it is preferable that the positional relationship calculation unit 540 calculates an authentication target geometric positional relationship between the designated touch point and each of n touch points based on a coordinate value on a designated coordinate system.

When the authentication target geometric position relationship between the designated touch point and each of the n touch points is calculated, the touch authentication processing unit 545 includes the geometric position relationship of the stamp touch authentication condition stored by the authentication condition storage unit 505 and the After matching the calculated geometric positional relationship to be authenticated between the calculated designated touch points and each of the n touch points, the distance and angle are compared to check whether they match or are close within the specified error range. If the calculated geometrical positional relationship to be authenticated and the geometrical positional relationship of the painting touch authentication condition coincide with each of the matched touch points or close within a specified error range, the component identified through the touch point identification unit 520 The value is authenticated by a touch by the touch coating 200 having the N touch units 250 corresponding to the matching or adjacent coating touch authentication condition.

When the stamp touch authentication condition stored in the storage medium 510 and the location area information of the touch stamp 200 are mapped and stored, and the location information of the wireless terminal 400 is confirmed, the touch authentication processing unit 545 ) Checks the comparison target stamp touch authentication condition mapped with the location area information matching the received location information among the stamp touch authentication conditions stored in the storage medium 510, and the geometric position relationship of the comparison target stamp touch authentication condition By comparing whether the calculated geometrical positional relationship to be authenticated matches or is close within a predetermined error range, the calculated geometrical positional relationship to be authenticated and the stamp touch authentication for each touch stamp 200 stored in the storage medium 510 It is possible to shorten the time required to compare and authenticate the geometrical positional relationship of the condition.

The touch authentication processing unit 545 includes a design geometrical positional relationship and a specified tolerance range for the N touch units 250 of the touch coating 200 in which a geometric positional relationship corresponding to the component values of the N touch points is specified. A positional relationship authentication result for the geometrical positional relationship of the N touch points verified to be matched in is determined. The location relationship authentication result for the geometric location relationship of the N touch points may include an authentication error result or an authentication success result.

Referring to Figure 5, the operation server 500, by combining the position relationship authentication result for the geometric position relationship of the N touch points and the sound authentication result for the code value corresponding to the sound signal, the touch coating ( An authentication result determination unit 550 for finally determining a result of the painting touch authentication using 200), and an authentication result transmission unit 555 for transmitting a result of authentication of the painting touch using the touch stamp 200 through a designated path. .

The authentication result determination unit 550 checks the positional relationship authentication result for the geometrical positional relationship of the N touch points determined through the touch authentication processing unit 545, and the code value authentication unit 450 determines the After confirming the sound authentication result for the code value corresponding to the sound signal, the touch is made by combining the position relationship authentication result for the geometric positional relationship of the N touch points and the sound authentication result for the code value corresponding to the sound signal. The result of the painting touch authentication using the painting 200 is finally determined.

According to the implementation method of the present invention, the authentication result determination unit 550 includes the authentication success result of the positional relationship authentication result for the geometric positional relationship of the N touch points, and the code value corresponding to the sound signal When the sound authentication result includes the authentication success result, it may be determined that the painting touch using the touch painting 200 is finally authenticated.

The authentication result transmission unit 555 transmits the stamp touch authentication result using the touch stamp 200 determined by the authentication result determination unit 550 through a specified path, and the stamp touch authentication result is transmitted through a specified path. It is received by the program 415 of the wireless terminal 400. On the other hand, according to the implementation method, when the stamp touch authentication result includes an authentication success result, the stamp touch authentication result is converted or replaced with service provision information using the touch stamp to be used as the program 415 of the wireless terminal 400. In this case, the program 415 of the wireless terminal 400 can immediately receive a service according to the success of the painting touch authentication using the touch painting 200. If the stamp touch authentication result is provided by the program 415 of the wireless terminal 400, the program 415 of the wireless terminal 400 reads the stamp touch authentication result and, if authentication succeeds, the touch stamp It is possible to request and receive a service according to the success of the painting touch authentication using 200.

6 is a diagram showing a process of registering a painting touch authentication condition of the touch painting 200 according to an implementation method of the present invention.

In more detail, FIG. 6 shows the process of storing the geometrical positional relationship and error information on the design of the N touch units 250 provided in the touch painting 200 in the operation server 500 in the painting touch authentication condition. As shown, for those of ordinary skill in the art to which the present invention belongs, various implementation methods for the process of registering the painting touch authentication condition by referring and/or modifying this Figure 6 (e.g., some steps are omitted, Alternatively, the implementation method in which the order has been changed) may be inferred, but the present invention includes all the inferred implementation methods, and the technical features are not limited only by the implementation method shown in FIG. 6.

Referring to Figure 6, the operation server 500 is a design geometrical for the N touch parts 250 provided in the flat plate part 245 in the process of designing and manufacturing the flat part 245 of the touch coating 200. The positional relationship is checked 600, and a design geometrical positional relationship is stored for the N touch units 250 (605), and the geometrical positional relationship may include design error information. If the actual measurement verification is not performed on the geometrical positional relationship in the design, a stamp touch authentication condition including the geometrical positional relationship in the design and the design error information is generated (625), and the generated stamping touch authentication condition and The serial code of the touch stamp may be mapped and stored in the storage medium 510 (630).

On the other hand, if the actual measurement verification for the geometrical position relationship in the design is performed, the operation server 500 designates the N touch units 250 provided in the touch coating 200 on the designated capacitive touch screen 405. Check the relationship of the actual measurement position repeatedly touched more than a number of times (610). If the actual measurement position relationship with respect to the N touch units 250 is confirmed, the operation server 500 checks whether the actual measurement position relationship exists within an error tolerance of the geometrical position relationship in the design (615). If the actual measurement position relationship does not exist within the tolerance range, the operation server 500 performs a procedure of correcting the N touch units 250 provided on the flat panel 245 of the touch coating 200. Or (620), or a procedure of re-manufacturing the flat portion 245 of the touch coating 200 is performed (620).

On the other hand, if the actual measurement position relationship exists within the error tolerance range, the operation server 500 performs stamp touch authentication including design geometrical positional relationship and error information for the flat part 245 of the touch painting 200 A condition is generated (625), and the serial code of the touch stamp 200 and the stamp touch authentication condition are mapped and stored in the storage medium 510 (630). The painting touch authentication condition includes at least one of the divided area 270 information, the minimum identification recognition distance, and the minimum identification distance in common, or the operation server 500 is a touch unit of the touch coating 200 ( 250) can be linked to be used to authenticate N touch points.

FIG. 7 is a diagram showing a process of registering a location of use of a touch coating 200 according to an implementation method of the present invention.

In more detail, Figure 7 shows the geometrical positional relationship and error information on the design of the N touch units 250 provided in the touch painting 200 in the operation server 500, after storing the painting touch authentication condition, the touch As showing a process of registering and storing the location area information of the stamp usage destination from the terminal device 100 of the painting usage destination provided with the painting 200, those of ordinary skill in the technical field to which the present invention belongs, With reference to and/or modification of this Figure 7, it is possible to infer various implementation methods (for example, implementation methods in which some steps are omitted or the order is changed) for the registration process for the use of the painting, but the present invention All implementation methods are included, and technical features thereof are not limited only by the implementation method illustrated in FIG. 7.

Referring to FIG. 7, the operation server 500 receives the serial code of the touch stamp 200 and the location area information of the stamp use destination from the terminal device 100 of the stamp use destination provided with the touch stamp 200. Do (700). The operation server 500 checks the stamp touch authentication conditions mapped with the received serial code among the stamp touch authentication conditions registered in the storage medium 510 (705).

If the seal touch authentication condition mapped with the serial code is not confirmed, the operation server 500 configures and transmits unregistered error information for the touch seal 200 to the terminal device 100 (710). On the other hand, when the stamp touch authentication condition mapped with the serial code is confirmed, the operation server 500 maps the checked stamp touch authentication condition and the location area information of the received stamp use destination and stores it in the storage medium 510. Do (715). According to an implementation method of the present invention, it is preferable that the painting touch authentication condition further includes a code value authentication condition for code value authentication associated with the painting touch.

The operation server 500 converts the painting touch authentication condition including the code value authentication condition corresponding to the sound signal to be output through the electronic module 300 of the painting use place to the program 415 of the wireless terminal 400 It can be provided (or embedded on the program 415) (720).

FIG. 8 is a diagram showing a process of recognizing a painting touch using the touch painting 200 in the program 415 of the wireless terminal 400 according to an embodiment of the present invention.

In more detail, FIG. 8 shows a program of the wireless terminal 400 when the touch coating 200 having N touch units 250 is touched on the capacitive touch screen 405 of the wireless terminal 400 ( At 415), a process of recognizing a painting touch using the touch painting 200, recognizing a sound signal output through the electronic module 300 of the painting location, and confirming a code value, to which the present invention belongs. For those of ordinary skill in the art, various implementation methods for the process of processing the painting touch recognition and authentication result by referring and/or modifying this figure 8 (e.g., some steps are omitted or the order is changed) ) May be inferred, but the present invention includes all the inferred implementation methods, and the technical features are not limited only by the implementation methods shown in FIG. 8.

Referring to Figure 8, as the program 415 is driven or activated (800), the wireless terminal 400 checks a touch event for a touch point touched on the capacitive touch screen 405 (805), and the touch By reading the event, it is checked whether the painting touch that touched the N touch units 250 provided in the touch painting 200 is recognized (810). The painting touch may be a touch in which N touch points were touched on the capacitive touch screen 405, or a touch to which one or more of a fixed touch condition, a static touch condition, a dynamic touch condition, and a sequential touch condition is additionally applied.

If the painting touch is recognized, the program 415 of the wireless terminal 400 reads the component values for the N touch points corresponding to the N touch units 250 provided in the touch painting 200 Do (815). When the location information of the wireless terminal 400 is used for authentication of the N touch points, the program 415 of the wireless terminal 400 can check the location information of the wireless terminal 400 (820). ).

As the program 415 of the wireless terminal 400 recognizes the N touch points or reads component values for the N touch points, the sound input unit 407 of the wireless terminal 400 is used as a starting point. After activation (825), a sound signal input through the sound input unit 407 is checked (830). If the sound signal is confirmed, the program 415 of the wireless terminal 400 reads the sound signal and checks the code value corresponding to the sound signal (835).

9 is a diagram illustrating a process of authenticating a code value corresponding to a sound signal according to an exemplary method of the present invention.

In more detail, FIG. 9 is a sound input unit of the wireless terminal 400 at a point in time when N touch points are recognized on the capacitive touch screen 405 of the wireless terminal 400 in the program 415 of the wireless terminal 400 ( 407), which shows a process of digitally authenticating a code value corresponding to a sound signal input through, and for those of ordinary skill in the technical field to which the present invention belongs, refer to and/or modify this Figure 9 Various implementation methods for the code value authentication process corresponding to the sound signal (for example, some steps are omitted or the order is changed) may be inferred, but the present invention includes all the inferred implementation methods. It is made, and the technical features are not limited only by the implementation method shown in FIG. 9.

Referring to Figure 9, the program 415 of the wireless terminal 400 is the wireless terminal at the time when N touch points are recognized on the capacitive touch screen 405 of the wireless terminal 400 through the process shown in Figure 8. A code value corresponding to the sound signal input through the sound input unit 407 of 400 is checked (900).

The program 415 of the wireless terminal 400 is a code included in the painting touch authentication condition for the touch painting 200 corresponding to the N touch points touched on the capacitive touch screen 405 of the wireless terminal 400 A value authentication condition is checked (905), and validity of a code value corresponding to the sound signal is authenticated using the checked code value authentication condition (910).

If the validity of the code value corresponding to the sound signal is not authenticated, the program 415 of the wireless terminal 400 generates a sound authentication result including an authentication error result for the code value corresponding to the sound signal. Do (915).

On the other hand, if the validity of the code value corresponding to the sound signal is authenticated, the program 415 of the wireless terminal 400 generates a sound authentication result including a result of authentication success for the code value corresponding to the sound signal. (920).

The program 415 of the wireless terminal 400 transmits the component values for the N touch points and the sound authentication result for the code value corresponding to the sound signal through the designated path (925), and Accordingly, the location information of the wireless terminal 400 is further transmitted (925), and a sound authentication result for the component values for the N touch points and a code value corresponding to the sound signal, and/or the wireless terminal 400 The location information of is received to the operation server 500 through a designated path.

Meanwhile, when the code value corresponding to the sound signal is not authenticated, the program 415 of the wireless terminal 400 is a result of sound authentication for the component values for the N touch points and the code values corresponding to the sound signal. It is okay to not transmit (that is, the validity of the component values for the N touch points is considered to be unauthenticated), and the present invention is not limited thereby.

FIG. 10 is a diagram illustrating a process of authenticating a geometric positional relationship for N touch points according to an exemplary method of the present invention.

In more detail, FIG. 10 shows a process of authenticating the geometric positional relationship of the N touch points touched on the capacitive touch screen 405 of the wireless terminal 400 in the operation server 500 in an analog manner, For those of ordinary skill in the art to which the present invention belongs, various implementation methods for the geometric positional relationship authentication process for the N touch points by referring and/or modifying this drawing 10 (e.g., some steps are omitted or , Or the implementation method in which the order has been changed) may be inferred, but the present invention includes all the inferred implementation methods, and the technical features are not limited only by the implementation method shown in FIG.

Referring to Fig. 10, the operation server 500 corresponds to the component values for the N touch points and the sound signal transmitted to the program 415 of the wireless terminal 400 through the process in Fig. 9 through a designated path. The sound authentication result for the code value and/or the location information of the wireless terminal 400 is received, and the geometrical positional relationship of the N touch points touched on the capacitive touch screen 405 of the wireless terminal 400 In order to authenticate, component values for the N touch points touched on the capacitive touch screen 405 of the wireless terminal 400 are checked (1000). The operation server 500 reads the mutual positional relationship for the N touch points based on the component values for the N touch points, so that N touch points corresponding to the component values are effectively designed and manufactured. It is authenticated whether it is a touch point of the touch coating 200 (1005). If the N touch points are not valid touch points of the touch stamp 200, the operation server 500 generates a location relationship authentication result including an authentication error result for the N touch points (1035).

If the N touch points are valid touch points of the touch coating 200, the operation server 500 includes n divided areas 270 applied in design in the process of manufacturing the flat portion 245 of the touch coating 200. ) To identify a designated touch point corresponding to the touch unit 250 provided at a designated position on the designated area 275 among n divided areas 270 by reading the component values through the divided area 270 information Do (1010). If the designated touch point is not identified, the operation server 500 generates a location relationship authentication result including the authentication error result for the N touch points (1035).

If a designated touch point among the N touch points is identified, the operation server 500 calculates a geometrical positional relationship to be authenticated between the identified designated touch point and each of the n touch points (1015). On the other hand, if the touch authentication condition and the location area information of the painting destination are mapped through the process shown in FIG. 2, the operation server 500 checks the location information of the wireless terminal 400, and the wireless terminal 400 ) By comparing the location information of the touch authentication condition with the location area information of the touch authentication condition to check at least one comparison target touch authentication condition to be compared with the calculated geometrical positional relationship to be authenticated among a plurality of touch authentication conditions stored in the storage medium 510, and In step 1020, the geometric positional relationship of the comparison target touch authentication condition and the calculated geometrical positional relationship to be authenticated are matched and compared (1025). If the touch authentication condition is not matched with the location area information of the stamp use destination, a process of comparing the geometric positional relationship with the entire touch authentication condition stored in the storage medium 510 may be performed.

The operation server 500 checks a touch authentication condition including a geometrical positional relationship that matches the authentication target geometrical positional relationship or is close within a specified tolerance range (1030). If a touch authentication condition that matches the authentication target geometrical position relationship or includes a geometrical positional relationship that is close within a specified tolerance range is confirmed, the operation server 500 displays the stamp touch corresponding to the authentication target geometrical positional relationship. It can be authenticated by touching the touch stamp 200 corresponding to the checked touch authentication condition.

If the authentication target geometrical positional relationship is not authenticated, the operation server 500 generates a positional relationship authentication result including an authentication error result for the N touch points (1035).

On the other hand, when the authentication target geometrical positional relationship is authenticated, the operation server 500 generates a positional relationship authentication result including the authentication success result for the N touch points (1040).

11 is a diagram illustrating a process of determining a painting touch authentication result by combining a location relationship authentication result and a sound authentication result according to an implementation method of the present invention.

In more detail, FIG. 11 shows the sound authentication result for the code value corresponding to the sound signal determined through the process shown in FIG. 9 in the operation server 500 and the geometry of the N touch points determined through the process shown in FIG. It shows the process of determining the final authentication result for the painting touch using the touch painting 200 by combining the location relation authentication results for the location relationship, and those of ordinary skill in the technical field to which the present invention belongs, the present invention With reference to and/or modification of FIG. 11, various implementation methods for the process of determining the result of the painting touch authentication (e.g., some steps are omitted, or the order is changed) may be inferred, but the present invention All implementation methods are included, and the technical features are not limited only by the implementation method shown in FIG.

Referring to FIG. 11, the operation server 500 checks the location relationship authentication result for the geometric location relationship of the N touch points determined through the process shown in FIG. 10 (1100), and through the process shown in FIG. After confirming the sound authentication result for the code value corresponding to the sound signal determined through the program 415 of the wireless terminal 400 (1105), the positional relationship authentication result and the sound signal for the geometric positional relationship of the N touch points It is checked whether the sound authentication result for the code value corresponding to is including the mode authentication success result (1110).

If any one of the authentication error result for the positional relationship authentication result for the geometrical positional relationship of the N touch points and the sound authentication result for the code value corresponding to the sound signal includes an authentication error result, the operation server 500 A painting touch authentication result including an authentication error result for a painting touch using the touch painting 200 of the user is finally determined (1115).

On the other hand, if the location relationship authentication result for the geometric position relationship of the N touch points and the sound authentication result for the code value corresponding to the sound signal include the mode authentication success result, the operation server 500 The painting touch authentication result including the authentication success result for the painting touch using the touch painting 200 of is finally determined (1120).

The operation server 500 transmits the stamp touch authentication result for the stamp touch using the touch stamp 200 through a designated path (1125), and the stamp touch authentication result is transmitted to the wireless terminal 400 through a designated path. It is received by program 415.

100: terminal device 105: cradle
220: touch coating 300: electronic module
310: sound output unit 400: wireless terminal
405: capacitive touch screen 407: sound input unit
415: program 500: operation server

Claims (12)

To the seal touch authentication method linked to a sound signal executed by interlocking a program provided in a user's wireless terminal equipped with a capacitive touch screen and a sound input unit and an operation server communicating with the program of the wireless terminal through a designated path. In,
A first step of recognizing, by the program, a painting touch including a plurality of touch points touched by a plurality of capacitive touch units provided on a designated touch coating using the capacitive touch screen;
A second step of recognizing, by the program, a sound signal input through the sound input unit based on a point in time when the stamp touch is recognized;
A third step of checking, by the program, a code value corresponding to the recognized sound signal;
A fourth step in which the program compares and authenticates a code value corresponding to the sound signal;
A fifth step of transmitting, by the program, a digital method authentication result for a code value corresponding to the sound signal and a component value for a plurality of touch points corresponding to the painting touch through a designated path;
A sixth step of receiving, by the operation server, a digital method authentication result for a plurality of touch points corresponding to the painting touch and a code value corresponding to the sound signal via a designated path;
A seventh step of confirming, by the operation server, a geometrical positional relationship on a design for a plurality of touch units of a designated touch coating for authenticating the geometrical positional relationship of the plurality of touch points;
An eighth step of authenticating, by the operation server, whether the geometrical positional relationship with respect to the plurality of touch points matches the geometrical positional relationship of the identified design within an allowable error range;
The operation server combines the analog authentication result for the geometric positional relationship of the plurality of touch points and the digital method authentication result for the code value corresponding to the sound signal, and finally determines the painting touch authentication result using the touch painting. A ninth step of transmitting; And
The painting touch authentication method linked to the sound signal comprising a; tenth step of the program receiving the stamp touch authentication result.
delete delete The method of claim 1,
The program further comprises the step of confirming a result of recognizing a plurality of touch points corresponding to the designated number of touch units of the designated touch coating,
In the third step, when a plurality of touch points corresponding to the designated number of touch units are recognized, a sound signal input through the sound input unit is recognized.
The method of claim 1,
Further comprising the step of confirming an analog authentication result of the geometrical positional relationship of the plurality of touch points using a geometrical positional relationship in design for the plurality of touch units of the touch coating designated by the program,
In the third step, when the geometrical positional relationship of the plurality of touch points is authenticated, a sound signal input through the sound input unit is recognized.
The method of claim 1, wherein the third step,
Reading, by the program, the sound signal to check numbers or characters coded in the sound signal according to DTMF coding rules; And
And generating, by the program, a code value included in the sound signal by combining the numbers or characters.
The method of claim 1, wherein the third step,
Reading, by the program, the sound signal and checking a bit stream encoded in the sound signal according to a sound code coding rule; And
And extracting a code value encoded in the sound signal by reading the bit stream by the program.
The method of claim 1, wherein the third step,
Recognizing, by the program, a sound pattern of the sound signal; And
And generating, by the program, a code value based on the recognized sound pattern.
delete delete The method of claim 1, wherein the fourth step,
The seal associated with the sound signal, characterized in that the program comprises a digital method of validity authentication that compares and authenticates a unique code provided in the electronic module of the touch painting or painting user and a unique code corresponding to the sound signal. Touch authentication method.
The method of claim 1, wherein the fourth step,
The seal associated with the sound signal, characterized in that the program comprises a digital authentication method of comparing and authenticating the one-time code generated through the touch seal or the electronic module of the seal user and the one-time code corresponding to the sound signal. Touch authentication method.

Images