KR102238935B1 - Method for Authenticating Capacitive Touch - Google Patents

Abstract

The present invention relates to a capacitive touch authentication method and system, and in the capacitive touch authentication method executed through a system interlocking with a capacitive touch screen supporting multiple touches, Check or receive information on a plurality of touch points recognized by multi-touching a plurality of touch units provided in a touch unit manufactured by arranging in a unique design geometric positional relationship including an angular relationship on a capacitive touch screen, By reading the relationship between the plurality of touch points, among a plurality of touch units arranged in a unique geometric positional relationship previously designed on the touch unit, a designated touch point corresponding to a designated touch unit fixedly disposed at a predetermined position on the design is identified, Coordinate rotation of the plurality of touch points based on the reference point identified through the designated touch point so as to be able to match the geometric position relationship in the designated design, and the geometric touch position relationship with the coordinate rotated plurality of touch points is registered in advance Processed to be matched and compared with one or more geometrical positional relationships on the design.

Description

Method for Authenticating Capacitive Touch {Method for Authenticating Capacitive Touch}

The present invention relates to a capacitive touch authentication method executed through a system interlocking with a capacitive touch screen that supports multiple touches, in which a plurality of touch units are pre-designed, including a pre-designed relative distance relationship and an angular relationship. Touch by multi-touching a plurality of touch units provided in a touch unit manufactured in relation to each other on a capacitive touch screen to check or receive information on a plurality of recognized touch points, and to read the relationship between the plurality of touch points. Identify a designated touch point corresponding to a designated touch part fixedly disposed at a pre-designated position among a plurality of touch parts arranged in a unique geometric positional relationship previously designed in the unit, and identify a reference point identified through the designated touch point. Coordinate rotation of the plurality of touch points as a reference so as to be able to match the geometrical positional relationship of a designated design, and matching and comparing the geometrical touch positional relationship of the plurality of rotated coordinates with the geometrical positional relationship of one or more previously registered designs It relates to a capacitive touch authentication method that is processed to be processed.

A service is disclosed in which a touch unit includes a plurality of touch units made of an electrostatic change inducing material and simultaneously touches the capacitive touch screen to use the geometrical positional relationship formed by the plurality of touch units as various authentication means or identification means.

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. In the case of a recently released smartphone, the capacitive touch screen supports multi-touch and is designed to use multiple touches using a finger as an input means (eg, pinch-to-zoom, etc.).

Meanwhile, in order to use the geometrical positional relationship of a plurality of touch units provided in the touch unit as an authentication means or an identification means, the geometrical positional relationship of a plurality of touch units provided in different touch units must have different uniqueness. Even if the touch parts of the capacitive touch screen are touched in any position or in any direction, the user should always have the convenience of recognizing and authenticating. However, it is difficult to provide the uniqueness and convenience of a touch unit to be used as an authentication means or an identification means using only the multi-touch method optimized with the conventional input means.

An object of the present invention for solving the above problems is, in a capacitive touch authentication method executed through a system interlocking with a capacitive touch screen supporting multiple touches, a pre-designed relative distance relationship between a plurality of touch units and Check or receive information on a plurality of touch points recognized by multi-touching a plurality of touch units provided in a touch unit manufactured by arranging in a unique design geometric positional relationship including an angular relationship on a capacitive touch screen, By reading the relationship between the plurality of touch points, among a plurality of touch units arranged in a unique geometric positional relationship previously designed on the touch unit, a designated touch point corresponding to a designated touch unit fixedly disposed at a predetermined position on the design is identified, Coordinate rotation of the plurality of touch points based on the reference point identified through the designated touch point so as to be able to match the geometric position relationship in the designated design, and the geometric touch position relationship with the coordinate rotated plurality of touch points is registered in advance It is to provide a capacitive touch authentication method for processing to be matched and compared with one or more geometrical positional relationships on the design.

In the capacitive touch authentication method according to the present invention, in the capacitive touch authentication method executed through a system interlocking with a capacitive touch screen supporting multiple touches, a plurality of touch units are pre-designed relative distance relations and angle relations. A first step of confirming or receiving information on a plurality of touch points recognized by multi-touching a plurality of touch units provided in a touch unit manufactured by arranging in a geometrical positional relationship on a unique design that includes multiple touches on a capacitive touch screen; and A device for reading the relationship between the plurality of touch points and identifying a designated touch point corresponding to a designated touch part fixedly disposed at a predetermined position in the design among a plurality of touch parts arranged in a unique geometric positional relationship previously designed on the touch unit. Step 2 and a third step of coordinate rotation of the plurality of touch points based on the reference point identified through the designated touch point to match the geometrical positional relationship on the designated design, and the coordinates of the plurality of rotated touch points And a fourth step of processing the touch position relationship to be matched and compared with one or more previously registered geometric positional relationships on the design.
In the capacitive touch authentication method according to the present invention, the geometrical positional relationship is one or more of a distance relationship and an angular relationship between the designated touch unit and the remaining touch units, or between a preset reference point and a plurality of touch units. It is characterized in that it comprises at least one of a distance relationship and an angle relationship.
In the capacitive touch authentication method according to the present invention, the distance relationship includes a coordinate distance in a coordinate system corresponding to the geometric position relationship in the design.
In the capacitive touch authentication method according to the present invention, the angular relationship is a coordinate angle in a coordinate system corresponding to the geometric position relationship in the design, or a center point of each touch unit on a coordinate system corresponding to the geometric position relationship in the design. It is characterized in that it comprises a coordinate angle formed by a line segment or a coordinate angle formed by a center point of each touch unit based on a reference line on a coordinate system corresponding to the geometrical positional relationship in the design.
In the capacitive touch authentication method according to the present invention, the first step further comprises converting the coordinates of the plurality of touch points into a coordinate system corresponding to the geometrical positional relationship in the design.
In the capacitive touch authentication method according to the present invention, it is characterized in that it further comprises the step of authenticating whether it is included in the range of an effective geometrical positional relationship in a design that can be mounted on the touch unit by reading the mutual positional relationship between the touch points .
In the capacitive touch authentication method according to the present invention, the geometrical positional relationship in the design includes a relationship of arranging a specified number of touch units in n (n≥4) divided areas, and the second step includes the n Characterized in that the relationship between the plurality of touch points is read based on the design divided area information for the n divided areas, and a designated touch point corresponding to a designated touch unit disposed in any one designated area among the n divided areas is identified. It is done.
In the capacitive touch authentication method according to the present invention, the geometrical positional relationship in the design is that a specified number of touch units are arranged in n (n≥4) divided areas, and the plurality of the plurality of touch units are arranged in any one of the n divided areas. And a relationship of arranging a designated touch unit among the touch units of, and the second step is to read the relationship between the plurality of touch points based on the divided area information on the design for the n divided areas, and the n number of It is characterized in that a designated touch point corresponding to a designated touch unit disposed in any one designated region of the divided regions is identified.
In the capacitive touch authentication method according to the present invention, the geometrical positional relationship in the design is that a designated number of touch units are arranged in n (n≥4) divided areas, but a designated position on any one designated area among the n divided areas And a relationship of arranging a designated touch unit among the plurality of touch units, and the second step is to read the relationship between the plurality of touch points based on the design divided area information for the n divided areas. A designated touch point corresponding to a designated touch unit disposed at a designated position on any one designated region among the n divided regions is identified.
In the capacitive touch authentication method according to the present invention, when identifying the designated touch point, the method further comprises converting the designated touch point and the remaining touch points into a coordinate system corresponding to the geometrical positional relationship on the design. It is characterized.
In the capacitive touch authentication method according to the present invention, the fourth step further includes checking the geometrical touch positional relationship and a geometrical positional relationship close to within a specified error range among geometrical positional relations on one or more designs previously registered. It characterized in that it is made by doing.
In the capacitive touch authentication method according to the present invention, the fourth step includes the step of checking the geometrical positional relationship between the geometrical touch positional relationship and the geometrical positional relationship matched within a specified error range among geometrical positional relationships on one or more designs previously registered. It characterized in that it comprises more.
In the capacitive touch authentication method according to the present invention, the fourth step further comprises checking a geometric positional relationship closest to the geometrical touch positional relationship among geometrical positional relationships on one or more designs previously registered. It is characterized.
In the capacitive touch authentication method according to the present invention, in the capacitive touch authentication method executed through a system interlocking with a capacitive touch screen to which a touch unit having a plurality of capacitive touch units is touched, n (n≥4) (N) touched through a touch unit having one touch unit in each of the calculated positions on (n-1) divided areas, and having two touch units at the calculated position and the designated position on a designated area. A first step of storing a touch authentication condition for authenticating the geometrical touch position relationship of +1) touch points, a second step of checking (n+1) touch point information touched through the capacitive touch screen, and , A third step of reading the (n+1) touch point information through the divided region information for the n divided regions to identify a designated touch point provided at a designated position of the designated region, and the identified designation And a fourth step of calculating a geometrical touch position relationship between the touch point and each of the n touch points, and a fifth step of matching and comparing the calculated touch position relationship with the touch position relationship of the touch authentication condition to authenticate.

According to the present invention, the touch position relationship may include a distance relationship between a designated touch point and each of n touch points, and an angular relationship between each of n touch points with respect to the designated touch point. Meanwhile, the distance relationship may include a coordinate distance calculated on a specific coordinate system. In addition, the angular relationship is a coordinate angle formed by two touch points out of n touch points on a specific coordinate system based on 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 specific coordinate system. It may include a coordinate angle formed by a connected line segment.

According to the present invention, the first step includes checking and storing a design geometrical touch position relationship with respect to the (n+1) touch points, and designating the touch unit through a capacitive touch screen of the registration device. Checking the actual measurement position relationship for the (n+1) touch points identified by repeatedly touching more than a number of times, and confirming whether the actual measurement position relationship exists within a specified error tolerance of the geometric touch position relationship in the design. And storing a touch authentication condition including a geometric touch position relationship on the design and an authentication touch position relationship including an error tolerance range when the actual measurement position relationship exists within the error tolerance range. I can.

According to the present invention, the (n+1) touch point information may be composed of a coordinate value of a device-side coordinate system set in a device having the capacitive touch screen.

According to the present invention, the capacitive touch authentication method may further include converting the identified (n+1) touch point information into a designated coordinate system corresponding to the touch position relationship of the touch authentication condition. .

According to the present invention, the capacitive touch authentication method may further include the step of authenticating whether a touch point was touched by a valid touch unit by reading a mutual positional relationship between the identified (n+1) touch points. have.

According to the present invention, the mutual location relationship may include a distance between touch points for comparison with a minimum discrimination recognition distance set for an effective touch unit.

According to the present invention, the mutual positional relationship may include a distance between touch points for comparison with a maximum separation distance at which each of the touch units can be separated from each other on a flat area of a flat plate provided in an effective touch unit.

According to the present invention, the mutual position relationship is (n+1) by dividing the flat area of the flat part provided in the effective touch unit into n and providing (n+1) touch parts having a designated contact interview in each area. It may include a geometric characteristic of a (n+1) square formed by a line segment connecting two touch points.

According to the present invention, in the third step, after matching any one of the identified (n+1) touch points with virtual designated touch points and division area information, n number of Including the step of reading whether two touch points exist on a designated area among n divided areas and one touch point exists in each of the remaining (n-1) divided areas by performing a process of rotating the touch point at least once. can do.

According to the present invention, in the third step, the virtual origin on the design and the divided area information are matched, and any one of the identified (n+1) touch points is matched with the designated touch point position based on the virtual origin, Coordinate rotation of (n+1) touch points based on the virtual origin is performed at least once, so that two touch points exist on a designated area among n divided areas, and the remaining (n-1) divided areas are It may include reading whether there is one touch point each.

According to the present invention, the first step further comprises the step of mapping and storing the touch authentication condition with location area information of a location where the touch unit is operated, and the second step comprises the (n+1) ) Further comprising the step of checking the location information touched by the touch points, wherein the fifth step is a touch location relationship between a location area information corresponding to the identified location information and a mapped touch authentication condition, and the calculated touch location relationship You can compare and authenticate.

According to the present invention, in the first step, the touch authentication conditions are grouped according to geometric characteristics of (n+1) squares that connect (n+1) touch units provided in a flat area of a flat panel provided in an effective touch unit. The fifth step further comprises a step of storing, and the fifth step includes a touch position relationship of a touch authentication condition belonging to a group matching a geometric characteristic of an (n+1) square corresponding to the calculated touch position relationship and the calculated touch position Relationships can be compared and authenticated.

According to the present invention, the touch unit may be made of an electrostatic change inducing material, and may include a contact surface of a designated shape to be touched on the capacitive touch screen. Meanwhile, the contact surface includes a contact area calculated to be recognized as an effective touch point of the capacitive touch screen, and the central portion of the contact area may be convexly rounded over the boundary line of the figure shape according to a predetermined curvature. have. The contact area may include an area calculated from an area equal to or greater than an area corresponding to the lowest touch sensitivity that can be recognized based on the capacitance of a human body in the capacitive touch screen.

According to the present invention, the calculated position is calculated to provide at least one touch unit among n touch units at different positions for each flat unit on a flat area of a flat unit provided in each of the same type of touch units, and thus a changeable position is provided. Can include.

According to the present invention, the calculated position is a touch unit provided in at least one of the n divided areas in which the flat area of the flat panel provided in each of the same type of touch units is divided into n at different locations for each flat panel. It may include a position that can be changed and calculated to have.

According to the present invention, the designated position may include a fixed position designated to provide one designated touch unit at the same position on a flat region of a flat plate provided in each touch unit of the same type.

According to the present invention, the designated location may be designated as an area on the flat area of the flat panel provided in each touch unit of the same type and in contact with the outline of the shape of the flat area.

According to the present invention, the designated position may be designated as a corner area in contact with the outline of a figure of the flat area on a flat area of a flat surface provided in each touch unit of the same type.

According to the present invention, the capacitive touch authentication system may be implemented in software in a device having the capacitive touch screen, or in a server that communicates with the device having the capacitive touch screen through a communication network. .

In the capacitive touch authentication system according to the present invention, in the capacitive touch authentication system interlocking with a capacitive touch screen to which a touch unit having a plurality of capacitive touch units is touched, ( (n+1) touches touched through a touch unit that has one touch unit at each calculated position on n-1) divided areas and has two touch units at the calculated position and designated position on one designated area An authentication condition storage unit that stores a touch authentication condition for authenticating the geometric touch position relationship of a point, a touch point identification unit that checks information of (n+1) touch points touched through the capacitive touch screen, and the n A touch point identification unit that reads the (n+1) touch point information through the divided region information on the divided regions to identify a designated touch point provided at a designated position of the designated region, and the identified designated touch point And a location relationship calculation unit that calculates a geometrical touch position relationship between each of the n touch points, and a touch authentication processing unit that matches and compares the calculated touch position relationship with the touch position relationship of the touch authentication condition to authenticate.

According to the present invention, the capacitive touch authentication system further includes a touch point authentication unit for authenticating whether a touch point was touched by a valid touch unit by reading the mutual positional relationship between the identified (n+1) touch points. can do.

According to the present invention, in the case of touching a capacitive touch screen of a touch unit having a plurality of touch units in a flat area of a designated area, the touch unit is aligned in a specific position or direction on the capacitive touch screen, without the need to touch Even if it touches freely, there is an advantage of authenticating the geometric touch position relationship formed by each touch point.

According to the present invention, there is an advantage of deriving the maximum number of cases in which a specified number of touch units can be provided within a limited area of a flat panel provided in a touch unit.

1 is a diagram showing the configuration of a touch authentication system according to an embodiment of the present invention.
2 is an illustration of the external appearance of a touch unit designed and manufactured according to an implementation method of the present invention.
3 illustrates a divided area according to an exemplary method of the present invention.
4 illustrates a divided area and a designated area according to an exemplary method of the present invention.
5 illustrates a minimum discrimination recognition distance according to an exemplary method of the present invention.
6 illustrates a minimum identification distance according to an exemplary method of the present invention.
7 illustrates the maximum possible separation distance according to an exemplary method of the present invention.
8 illustrates geometric characteristics of an (n+1) square according to an exemplary method of the present invention.
9 illustrates a distance relationship according to an exemplary method of the present invention.
10 illustrates an angular relationship according to an exemplary method of the present invention.
11 is a diagram illustrating a process of storing a touch authentication condition according to an exemplary method of the present invention.
12 is a diagram illustrating a touch authentication process according to an exemplary method of the present invention.
13 is a diagram showing an embodiment of a user's wireless terminal corresponding to a device having a capacitive touch screen according to an embodiment of the present invention.
14 is a diagram illustrating an embodiment in which a touch authentication system is implemented in a server on a network according to an exemplary embodiment of the present invention.
15 is a diagram illustrating an embodiment in which a touch authentication system is implemented in a server on a network according to another embodiment 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, a component provided on the server side may be implemented on the device side, or conversely, a component provided on the device side may be implemented on the server side.

In addition, in the following description of the present invention, when it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, a 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 overall contents of 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 pertains. Only.

1 is a diagram showing the configuration of a touch authentication system 100 according to an embodiment of the present invention.

In more detail, FIG. 1 shows the touch when a touch unit 200 having a specified number of touch units 220 made of an electrostatic change inducing material is touched on the capacitive touch screen 1310 of the designated device 1300. Even if the unit 200 is aligned to a specific position or a specific direction on the capacitive touch screen 1310 and freely touched without the need to touch, the geometric touch position relationship formed by each touch point is determined with the touch position relationship of the previously registered touch authentication condition. It shows a configuration in which authentication is performed by matching and comparing. For those of ordinary skill in the art to which the present invention belongs, various implementation methods for the touch authentication system 100 by referring to and/or modifying this Figure 1 (for example, some components are omitted or subdivided, 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. 1.

The touch unit 200 to be touched on the capacitive touch screen 1310 of the present invention includes a handle part 205 formed to be gripped by a human hand, a designated number of touch parts 220 made of a material inducing electrostatic change, and , Comprising a frame unit 210 that connects the handle unit 205 and the designated number of touch units 220 to fix the designated number of touch units 220 to the flat region 305 of a designated shape. . When the capacitance of the human body is transmitted to each of the touch units 220, the handle unit 205 and the touch unit 220 are electrically connected via the frame unit 210. To this end, at least one side of the handle part 205 (eg, a part in contact with a person's hand) and at least one side of the frame part 210 (eg, a handle part 205 and the touch part 220) are connected. Part) is made of a conductive material or is coated (or plated) with a conductive material.

The frame unit 210 includes a flat area 305 of a designated figure shape, a flat plate part 215 on which a designated number of touch parts 220 are fixed or formed, and the touch part 220 is attached to a handle part 205 ) And a connection part connected to it. The flat plate portion 215 may include a flat plate region 305 in a shape such as a square, a rectangle, a pentagon to a T (T>5) square. Alternatively, the flat plate portion 215 may include a flat plate region 305 in a shape such as a circle or an ellipse. The flat plate part 215 may have any geometrical structure as long as it has a fixed area that can be divided and an outline 300 that at least one touch part 220 can contact.

The touch unit 220 is a generic term for a component that forms one touch point when the touch unit 200 is touched on the capacitive touch screen 1310 of the designated device 1300. However, a plurality of touch units 220 are provided in the flat panel 215 provided on the frame unit 210 of the touch unit 200, and the present invention provides a plurality of touch units provided on the flat panel 215 ( 220) has a characteristic that the geometric touch position relationship of each touch point formed by multi-touching the capacitive touch screen 1310 of the designated device 1300 is used as an authentication condition. Therefore, the touch unit 220 is recognized as one effective touch point on the capacitive touch screen 1310 of the designated device 1300, and at the same time, within a limited area on the flat area 305 implemented by the flat unit 215 Induces the maximum number of cases for the calculated position 410 to effectively distinguish each touch point in, and no error occurs in the geometric touch position relationship of each touch point, or the minimum error is within the calculated range. It must be designed and manufactured to occur.

The touch unit 220 is designed and manufactured to have a contact area calculated to be recognized as one effective touch point when it is touched on the capacitive touch screen 1310 of the designated device 1300. The calculated contact area includes an area greater than or equal to an area corresponding to the lowest touch sensitivity that can be recognized based on the capacitance of the human body on the capacitive touch screen 1310 of the designated device 1300. If the touch unit 220 of the touch unit 200 is designed to touch the capacitive touch screen 1310 of two or more different designated devices 1300, the capacitive touch screen of each designated device 1300 ( If the touch sensitivity of 1310) is different, the contact area of the touch unit 220 is the larger of the areas corresponding to the lowest touch sensitivity that can be recognized by the capacitive touch screen 1310 of each designated device 1300 ( That is, it is preferable to calculate an area larger than or equal to an area corresponding to a smaller minimum touch sensitivity). For example, the contact area of the touch unit 220 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 220 based on the area corresponding to the lowest touch sensitivity for the capacitive touch screen 1310 of the designated device 1300 is that the touch unit 220 has one effective touch. This is to calculate the maximum number of cases in which each touch unit 220 is provided at different locations within a limited area of the flat area 305 while being recognized as a dot.

The touch unit 220 is manufactured to have a contact surface in the form of a designated figure for implementing the calculated contact area. For example, the contact surface of the touch unit 220 may be manufactured in a 5mm*5mm square shape to form a contact area of 25mm2. Alternatively, the contact surface of the touch unit 220 may be manufactured in a circular shape having a diameter of 6 mm for a contact area larger than 28 mm 2. Alternatively, the contact surface of the touch unit 220 may be manufactured in a 6mm*6mm square shape for a contact area of 36mm2. Alternatively, the contact surface of the touch unit 220 may be manufactured in a circular shape having a diameter of 7 mm for a contact area larger than 38 mm 2.

The touch unit 220 induces electrostatic change corresponding to at least one of soft, semi-soft, or semi-rigid 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. It is made of a material, and is manufactured by round processing in a structure in which the central part of the contact surface convexly protrudes above the boundary line of the figure shape according to a predetermined curvature while maintaining the designated figure shape. When the touch unit 220 manufactured as described above is touched on the capacitive touch screen 1310 of the designated device 1300, the capacitive touch first from the center part protruding convexly at a certain curvature among the contact surfaces of the touch unit 220 The screen 1310 is touched, and when a certain pressing force is applied to the touch unit 220 in this state, the central portion is constricted by the pressing force, and as a result, the entire contact surface of the touch unit 220 is calculated. While forming an area, the capacitive touch screen 1310 is touched. The midpoint (= touch point) of the touch surface touched on the capacitive touch screen 1310 by the touch unit 220 corresponds to the center portion of the contact surface formed on the touch unit 220 or at least a calculated error range Corresponds to the central part of the contact surface within.

In the embodiment of the present invention, the term including the'pressing force'or'pressingforce' is a term applied when the touch unit 200 is a painting-type object or a module mounted on a painting-type object. , If the touch unit 200 is not a painted object or is not mounted on a painted object, it may not be applied.

The touch unit 220 is made of an electrostatic change inducing material corresponding to at least one of soft, semi-soft, or semi-rigid in order to further reduce an error within the calculated range or no error in the geometrical touch position relationship of each touch point. It can be manufactured by forming an empty space inside. The empty space inside the touch unit 220 provides a space in which the central portion of the contact surface protruding convexly at a predetermined curvature is constricted by a pressing force and can be contracted into the touch unit 220. Since the touch unit 200 touches the capacitive touch screen 1310 of the designated device 1300 in a state held in the hand of the person, a pressing force applied to the touch part 220 by the hand of the person In addition, not only the vertical direction component of the capacitive touch screen 1310 exists, but also the horizontal direction component. In this case, the empty space inside the touch unit 220 is not distorted by the horizontal direction component and the contact surface of the touch unit 220 is not distorted by the vertical direction component even if the horizontal component is present in the pressing force. It induces to contract into the inside of the touch part 220. If the contact surface of the touch unit 220 is distorted to one of the horizontal components due to the pressing force of the contact surface of the touch unit 220, as a result, the midpoint of the surface touched by the capacitive touch screen 1310 also moves in the distorted direction, resulting in an error. Will increase. An empty space inside the touch unit 220 prevents or minimizes such an error.

The flat portion 215 of the touch unit 200 includes n (n≥4) touch units 220 among the touch units 220 designed and manufactured as described above at the calculated position 410 , One touch unit 220 is further provided at a designated location 405, and as a result, a total of (n+1) touch units 220 are provided on the flat panel 215 of the touch unit 200. The flat plate portion 215 provided in each touch unit 200 of the same type has a flat plate area 305 having the same flat surface area, and a flat area of the flat plate portion 215 provided in each touch unit 200 of the same type 305 is made of the same figure shape forming the same flat surface area, and as a result, the flat area 305 of the flat plate portion 215 provided in each touch unit 200 of the same type has the same figure outline 300 do. Accordingly, the same type of touch unit 200 includes the same number of touch units 220 on the flat surface 215 having the same flat area of the same figure shape, even if the shape of the handle unit 205 is different.

The flat area 305 of the flat part 215 is divided into n divided areas 310 in the design process to provide the n number of touch units 220 at the calculated position 410, and each divided area One touch unit 220 is provided at each calculated position 410 on the 310, and one designated touch at a designated position 405 on any one designated area 400 among the n divided areas 310 The unit 220 is further provided. The designated location 405 with respect to the designated touch part 220 is to place one designated touch part 220 at the same location on the flat area 305 of the flat part 215 provided in each touch unit 200 of the same type. It is a fixed position designated by design in order to be provided, and the n calculated positions 410 for the n touch units 220 are a flat area of the flat unit 215 provided in each touch unit 200 of the same type ( It is a changeable position calculated by design in order to provide at least one touch unit 220 among the n number of touch units 220 at different positions for each flat unit 215 on 305 ).

According to the embodiment of the present invention, the designated position 405 is a figure of the flat area 305 corresponding to the flat portion 215 of the touch unit 200 in which (n+1) touch units 220 are provided. It may be designated as an area in contact with the outline 300. Preferably, the designated position 405 is preferably designated in a corner area in contact with the figure outline 300 of the flat area 305. Meanwhile, according to another embodiment of the present invention, the designated position 405 may be designated as a central portion of the flat plate part 215. That is, the designated location 405 is a location in which one designated touch part 220 is always designated and provided at the same location with respect to the flat area 305 of the flat part 215 provided in the same type of touch unit 200. Includes.

According to the embodiment of the present invention, the calculated positions 410 are n divided areas 310 obtained by dividing the flat areas 305 of the flat portions 215 provided in each touch unit 200 of the same type into n. In order to provide the touch unit 220 provided in one or more of the divided regions 310 at different positions for each of the flat surfaces 215, a changeable position calculated by design is included.

The n divided areas 310 that divide the flat area 305 include areas that are logically set to calculate positions on the flat area 305 where the n number of touch units 220 are to be provided. Therefore, even if the n divided regions 310 are not implemented in the actually manufactured flat plate 215, the n divided regions 310 are actually It may be displayed or divided into the displayed area.

The division type and division method for the division area 310 may be applied in various ways. For example, when the shape of the flat area 305 has a square shape, the divided area 310 has a grid shape of 4 square areas in which the rectangular flat area 305 is divided into 4, and a grid shape divided into 6 It may include 6 rectangular areas, 8 rectangular areas in the form of a grid divided into 8 areas, and the like. Alternatively, the divided area 310 may include 4 sectors divided by a 90° angle from the center point of the flat area 305 as an origin, 6 sectors divided by a 60° angle, and 8 sectors divided by a 45° angle. And the like.

Each of the divided regions 310 is provided with one touch unit 220 at a position 410 calculated in advance for design. Here, the position 410 calculated by design is the minimum discrimination recognition distance 500 set by design such that n number of touch units 220 provided on the same flat plate 215 provided in the same touch unit 200 are provided apart from each other. And, provided in the same divided area 310 for each divided area 310 divided by the same rule by dividing the flat area 305 of the different flat parts 215 provided in each of the different touch units 200 This is a position that satisfies the minimum identification distance 600 set in the design so that the touch units 220 are provided apart from each other.

When two or more touch points are multi-touched on the capacitive touch screen 1310 of the designated device 1300, the minimum discrimination recognition distance 500 is determined by the corresponding device 1300 (or the capacitive touch screen 1310). It includes a minimum separation distance that can be recognized by distinguishing two or more multi-touched touch points as different touch points. For example, if the distance between two touch points multi-touched on the designated device 1300 (or capacitive touch screen 1310) is within 6 mm, the two touch points are recognized as one touch point, and In this case, if two touch points are distinguished and recognized as different touch points, it is preferable that the minimum discrimination recognition distance 500 includes 7 mm. On the other hand, if there are two or more designating devices 1300 (or capacitive touch screen 1310) corresponding to a target to which the touch unit 200 is to be touched, the minimum discrimination recognition distance 500 is two or more designating devices 1300 (Or the capacitive touch screen 1310) may be set to a larger separation distance among the minimum recognizable separation distances for distinguishing two touch points multi-touched on the capacitive touch screen 1310.

According to an exemplary embodiment of the present invention, the minimum discrimination recognition distance 500 is a value that correlates with the contact area of the touch unit 220. That is, the minimum discrimination recognition distance 500 may be a value set in the designated device 1300 (or the capacitive touch screen 1310), but is a value obtained experimentally. For example, even with the same device 1300 (or capacitive touch screen 1310), the contact area of the touch unit 220 is 25 mm2 (e.g., manufactured in a square shape of 5 mm * 5 mm). The minimum discrimination recognition distance 500 in the case of a contact surface) and the minimum discrimination recognition when the contact area of the touch unit 220 is greater than 38 mm2 (eg, a contact surface manufactured in a circular shape with a diameter of 7 mm) Distance 500 can be different. Therefore, the minimum discrimination recognition distance 500 is preferably set based on experimental data for a plurality of devices 1300 (or capacitive touch screen 1310) based on the contact area of the touch unit 220. . In this case, the minimum discrimination recognition distance 500 is set as a distance between a central portion and a central portion of the contact surface of the touch unit 220, or an outline of a figure that implements the contact surface of the touch unit 220 It can be set as the distance between the outlines.

According to the present invention, n touch units 220 provided one by one in the n divided regions 310 are provided at any position within each divided region 310 (however, touch within the divided regions 310 is The position where the unit 220 is to be provided may be calculated based on the minimum identification distance 600), but is provided spaced apart by the minimum identification recognition distance 500 or more within the flat area 305.

The minimum identification distance 600 is, when touching one area on the capacitive touch screen 1310 of the designated device 1300 two or more times and moving little by little while touching at different locations, the two or more touch points are different from each other. It contains the minimum separation distance that can be identified by the touch point. For example, a first touch point is touched on a coordinate value (x1, y1) corresponding to an area on the capacitive touch screen 1310 of the specified device 1300, and a second touch point is applied to the coordinate value (x2, y2). When the touch point is touched and the third touch point is touched on the coordinate values (x3, y3), the device 1300 (or the capacitive touch screen 1310) changes the coordinate values (x1, y1) and the coordinate values ( If the touch point of x2, y2) is recognized as the same touch point, whereas the touch point of the coordinate value (x1, y1) and the coordinate value (x3, y3) is recognized as different touch points, the coordinate values (x1, y1) ) And the coordinate values (x2, y2) corresponds to a separation distance smaller than the minimum identification distance 600, and the distance between the coordinate values (x1, y1) and the coordinate values (x3, y3) is the minimum identification distance (600). It corresponds to a separation distance greater than or equal to ).

According to an exemplary method of the present invention, the minimum identification distance 600 may be a value set in the designated device 1300 (or the capacitive touch screen 1310), but is a value obtained experimentally. For example, the minimum identification distance 600 is repeatedly touched while moving the designed and manufactured touch unit 220 by 0.1 mm to any one area on the capacitive touch screen 1310 of one or more designated devices 1300 It may be determined based on the information on the obtained touch point. On the other hand, if there are two or more designating devices 1300 (or capacitive touch screen 1310) corresponding to a target to which the touch unit 200 is to be touched, the minimum identification distance 600 is two or more designating devices 1300 ( Alternatively, the capacitive touch screen 1310 may be set to a larger separation distance among the minimum separation distances capable of identifying two or more touch points that have been touched twice or more in one area.

According to the present invention, the touch unit 220 provided in at least one of the n touch units 220 provided in each of the n divided areas 310 is provided in another touch unit 200 Of the divided areas 310 of the other flat plate parts 215 divided by the same rule, the touch unit 220 provided in the same divided area 310 and the minimum identification distance 600 are separated from each other. It is equipped. Accordingly, the n number of touch units 220 provided on the flat portions 215 of different touch units 200 are provided with at least one touch unit 220 at different positions, and the flat portions of each touch unit 200 The geometrical touch positional relationship between the n number of touch units 220 provided in 215 is identified by different geometrical touch positional relationships within the calculated number range.

One designated area 400 of the n divided areas 310 obtained by dividing the flat area 305 of the flat part 215 further includes one designated touch part 220. Preferably, the designated touch part 220 is provided in an area in contact with the figure outline 300 implementing the figure shape of the flat region 305, and as a result, two touch parts 220 are provided in the designated region 400. ) Is provided.

The designated touch part 220 is provided at a designated location 405 (ie, an area in contact with the figure outline 300 of the flat area 305) irrespective of the minimum identification distance 600, and n touch parts ( 220) is preferably provided with a minimum discrimination recognition distance 500 or more.

The (n+1) touch units 220 provided on the flat plate part 215 designed and manufactured as described above are each n touch units provided on the same plate based on the midpoint of one designated touch unit 220 The geometric touch position relationship including the distance relationship 900 and the angular relationship 1000 with the midpoints of the unit 220 has unique characteristics. In this way, a unique serial code may be assigned to the flat plate part 215 designed and manufactured to have uniqueness in the geometrical touch positional relationship between the one designated touch part 220 and each of the n touch parts 220.

The touch unit 200 of the present invention is manufactured by connecting the frame portion 210 having the flat portion 215 uniquely designed and manufactured as described above with the handle portion 205, and the handle portion 205 and The flat plate part 215 is connected through a connection part provided in the frame part 210.

The touch authentication system 100 of the present invention is installed in a designated device 1300 having a capacitive touch screen 1310 to be touched by a touch unit 200 having a flat plate part 215 designed and manufactured as described above. It may be implemented in the form of software to be implemented, or may be implemented through the server 1400 on a network that directly or indirectly communicates with the designated device 1300.

Referring to Figure 1, the touch authentication system 100, one of each of the calculated positions 410 on (n-1) divided areas 310 among n (n≥4) divided areas 310 Touched through the touch unit 200 including the touch unit 220 and having two touch units 220 at the calculated position 410 and the designated position 405 on one designated area 400 (n An authentication condition storage unit 105 is provided for storing touch authentication conditions for authenticating the geometrical touch positional relationship of +1) touch points.

The authentication condition storage unit 105 includes a designated touch point corresponding to the midpoint of one designated touch unit 220 provided in the flat unit 215 of the touch unit 200 and the flat unit of the touch unit 200. The distance relationship 900 between the n touch points corresponding to the midpoints of the n touch units 220 provided in 215 and the geometric touch position relationship in the design corresponding to the angular relationship 1000 are checked, and the designated touch A touch authentication condition including a design geometrical touch position relationship for a point and n touch points is stored.

According to the implementation method of the present invention, the geometric touch position relationship in the design is to design or manufacture the flat plate part 215 having the (n+1) touch parts 220 in the form of a coordinate value on a preset designated coordinate system. Includes a coordinate relationship including the coordinate values of the designated touch points determined in the process and the relative coordinate values for n touch points, and/or between the designated touch point and each of n touch points based on the coordinate values on the designated coordinate system. It includes a distance relationship 900 and an angular relationship 1000 formed by n touch points based on a designated touch point on a designated coordinate system. Here, the designated coordinate system is a coordinate system that serves as a reference for analyzing the geometric touch position relationship between the designated touch point and n touch points, and is preferably composed of metrological units (e.g., µm, mm, cm) 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 a device-side coordinate system.

When the touch authentication system 100 is implemented on the server 1400 according to the first implementation method of the present invention, the authentication condition storage unit 105 includes the (n+1) touch units 220 In the process of designing or manufacturing one flat plate part 215, the calculated position 410 and designated position 405 in the design for providing (n+1) touch parts 220 on the flat plate part 215 A corresponding geometric touch position relationship may be checked or input from a designated terminal, and a touch authentication condition including the design geometric touch position relationship may be stored in the designated storage medium 110.

According to the implementation method of the present invention, the authentication condition storage unit 105 checks design error information corresponding to a design tolerance range with respect to the design geometric touch position relationship, and the design geometric touch position relationship Touch authentication conditions including design error information may be stored in the designated storage medium 110. If the actual measurement position relationship is not confirmed, the touch authentication condition may be used for authentication.

According to an implementation method of the present invention, the authentication condition storage unit 105 checks the serial code given to the flat plate unit 215 having the (n+1) touch units 220, and the touch authentication condition And the serial code may be mapped and stored in the designated storage medium 110.

According to an exemplary method of the present invention, the authentication condition storage unit 105 includes each of the touch units 200 based on a geometric characteristic of an (n+1) square formed by connecting the (n+1) touch points. Each touch authentication condition may be classified and grouped by two or more geometric characteristics, and the grouped touch authentication condition may be classified and stored for each group. Preferably, the storage medium 110 may store group identification information for identifying a group to which the touch authentication condition belongs.

The authentication condition storage unit 105 is repeatedly touched more than a specified number of times on the capacitive touch panel provided in the device 1300 designated to register the geometric touch position relationship with the touch unit 220 of the touch unit 200 ( Check the information of n+1) touch points, match the information of the repeatedly touched (n+1) touch points with the geometric touch position relationship in the design, and compare them to within a specified error tolerance (e.g., Gaussian (Gaussian) ) Determine whether (n+1) touch points are touched within the 95% coincidence range of the probability distribution). If the repeatedly touched (n+1) touch point information coincides with or is close to the geometric touch position relationship in the design within a specified error tolerance, the authentication condition storage unit 105 receives the repeatedly touched (n+1) touch point information. After calculating actual measurement error information based on +1) touch point information, generating an authentication touch position relationship including the geometric touch position relationship on the design and the calculated actual measurement error information, the generated touch position It is possible to store a touch authentication condition including a relationship. On the other hand, if the repeatedly touched (n+1) touch point information and the geometric touch position relationship in the design exist within a specified error tolerance, the actual measurement error is included in the design error, so the authentication condition storage unit Reference numeral 105 may store a touch authentication condition to be used for authentication, including the geometric touch position relationship on the design and error information on the design.

According to the implementation method of the present invention, the authentication condition storage unit 105 receives the serial code given to the flat panel 215 of the touch unit 200 to be registered from the device 1300 designated for registration, and the reception Using the generated serial code, check the geometric touch position relationship in the design to calculate the error information. The authentication condition storage unit 105 checks information on (n+1) touch points repeatedly touched more than a specified number of times on the capacitive touch panel of the registration device 1300 through the touch point confirmation unit 115 below. And, in connection with the touch point authentication unit 120 below, it is checked whether the mutual positional relationship of the identified touch points is valid, and in connection with the touch point identification unit 125 and the positional relationship calculation unit 130 below Check the actual measurement position relationship for the repeatedly touched (n+1) touch points, the distance relationship 900 and the angle relationship 1000 included in the actual measurement location relationship, and the touch identified through the serial code By comparing the distance relationship 900 and the angular relationship 1000 included in the geometric touch position relationship in the design corresponding to the authentication condition, the actual measurement position relationship is within a specified error tolerance based on the geometric touch position relationship in the design. Make sure it is. If the actual measurement position relationship is out of the specified error tolerance range, the fabricated touch unit 200 (or the flat panel portion 215 having (n+1) touch portions 220) allows the specified error. It is preferable that an error correction or a procedure of remanufacturing after disassembly is performed to fall within the range, and for this purpose, the authentication condition storage unit 105 includes the manufactured touch unit 200 (or (n+1) touch units. It is possible to output information necessary for error correction or remanufacturing of the flat plate unit 215 provided with 220 and instruct the accompanying work. On the other hand, if (n+1) touch point information repeatedly touched on the capacitive touch screen 1310 of the registration device 1300 is within a specified error tolerance, the authentication condition storage unit 105 An authentication touch that checks error information (eg, actual measurement error information or design error information) based on the (n+1) touch point information, and includes the geometric touch position relationship in the design and the confirmed error information After the location relationship is created, a touch authentication condition including the generated touch location relationship may be stored.

According to the second embodiment of the present invention, when the touch authentication system 100 is implemented in a designated device 1300 having a capacitive touch screen 1310, the authentication condition storage unit 105 includes the designated device ( 1300) stores the touch authentication condition to be used for authentication in the form of an operation code on the program 1330, and/or the touch authentication condition to be used for authentication in the form of a file referenced by the program 1330 It can be stored in the memory unit 1328 of 1300.

It is preferable that the touch authentication condition to be used for authentication in the second implementation method includes a design touch position relationship and specified error information (eg, actual measurement error information or design error information). The touch authentication condition to be used for the authentication is in the form of an operation code on the program 1330 provided in the device 1300 and/or in the form of a file referenced by the program 1330 in the memory unit 1328 of the device 1300. Can be saved. If the touch authentication condition to be used for the authentication is stored in the memory unit 1328 of the device 1300 in the form of a file, the touch authentication condition to be used for the authentication is on the server 1400 according to the first implementation method. The generated touch authentication condition may be stored in the memory unit 1328 of the device 1300 in a form distributed to the device 1300 having the program 1330 through a communication network.

When the touch authentication system 100 is implemented on the server 1400 according to the first implementation method of the present invention, the authentication condition storage unit 105 includes each touch including the touch position relationship for authentication and a serial code. Touch authentication conditions for each unit 200 may be stored in the designated storage medium 110. On the other hand, when the manufactured touch unit 200 is supplied to a user at a specific location (or region) (e.g., an affiliate store that provides a designated service using the touch unit 200), the authentication condition storage unit ( 105) may check the location area information (eg, address information, area information, etc.) of the use place of the touch unit 200, map it to the touch authentication condition, and store it in the storage medium 110.

According to the second embodiment of the present invention, when the touch authentication system 100 is implemented in a designated device 1300 having a capacitive touch screen 1310, the authentication condition storage unit 105 includes the designated device ( The program 1330 stores at least one authentication touch position relationship to be used in the corresponding program 1330 in the form of an operation code on the program 1330 provided as 1300, or in the form of a file referenced by the program 1330 At least one authentication touch position relationship to be used in may be stored in the memory unit 1328 of the corresponding device 1300.

Referring to FIG. 1, the touch authentication system 100 includes a touch point identification unit 115 that checks (n+1) touch point information touched through the capacitive touch screen 1310 of the designated device 1300. ).

When the touch authentication system 100 is implemented on the server 1400 according to the first implementation method of the present invention, the touch point identification unit 115 is the capacitive touch screen 1310 of the designated device 1300 The (n+1) number of touch points 220 provided on the flat portion 215 of the touch unit 200 are touched to receive information about (n+1) number of touch points recognized. The server 1400 may receive (n+1) touch point information from the designated device 1300 or through the designated relay server 1500.

The (n+1) touch point information is a device-side coordinate system set on the capacitive touch screen 1310 of the device 1300 touched by the touch unit 200 (e.g., a pixel coordinate system corresponding to the touch screen 1310). ), and the coordinate value information for the (n+1) touch points recognized as the reference, and the touch point identification unit 115 includes the device-side coordinate system together with the (n+1) touch point information. It is possible to receive the coordinate system identification information that can identify the.

According to an exemplary method of the present invention, the touch point identification unit 115 includes the (n+1) touch point information and the touch unit 200 touched from the device 1300 to which the touch unit 200 was touched. It is desirable to receive device information about the device 1300 (for example, information that uniquely identifies the device 1300 touched by the touch unit 200 or identifies the model or manufacturer of the device 1300). In this case, the device information may be used as the coordinate system identification information. To this end, information for identifying a device-side coordinate system using device information is provided on the server 1400.

According to an embodiment of the present invention, the touch point identification unit 115 receives the (n+1) touch point information from the device 1300 touched by the touch unit 200 while the touch unit 200 Location information about the touched device 1300 (for example, information obtained through a GPS module provided in the device 1300, information capable of confirming the location of a base station connected to the device 1300, etc.) may be received. .

When the (n+1) touch point information and the device-side coordinate system are confirmed, the touch point confirmation unit 115 provides the (n+1) touch point information consisting of coordinate values on the device-side coordinate system as the touch authentication condition. Coordinates can be converted into coordinate values on a designated coordinate system corresponding to. If the device 1300 that recognizes the (n+1) touch points converts and transmits the (n+1) touch point information to the designated coordinate system, or the following touch point authentication unit 120 or When the coordinate conversion procedure is performed by the touch point identification unit 125 or the location relationship calculation unit 130, the touch point identification unit 115 may not perform the coordinate conversion procedure.

When the touch authentication system 100 is implemented in a designated device 1300 having a capacitive touch screen 1310 according to the second embodiment of the present invention, the touch point identification unit 115 is ) Of (n+1) touch points recognized by touching (n+1) touch units 220 provided on the flat panel 215 of the touch unit 200 on the capacitive touch screen 1310 Check. If the device-side coordinate system that recognizes the (n+1) touch points and the designated coordinate system of the touch authentication condition are different, the touch point identification unit 115 stores (n+1) touch point information as the touch authentication condition. It is possible to perform a procedure of converting coordinates into coordinate values on a designated coordinate system corresponding to. On the other hand, when the touch authentication condition stored in the device 1300 is set and stored in accordance with the device-side coordinate system, coordinate conversion for (n+1) touch point information may be omitted as described below.

Referring to FIG. 1, the touch authentication system 100 reads the mutual positional relationship between the identified (n+1) touch points, and authenticates whether a touch point of the touch unit 200 is valid. It has 120.

The touch point authentication unit 120 reads (n+1) touch point information checked through the touch point identification unit 115, and an effective touch unit 200 designed and manufactured according to the design method according to the present invention. ), it is verified whether it is a touch point touched by the (n+1) touch units 220 provided on the flat panel 215 of ).

According to an implementation method of the present invention, the touch point authentication unit 120 calculates the distance between the n touch points or the distance between (n+1) touch points, and the calculated distance between the touch points is a valid touch unit By reading whether it is greater than or equal to the minimum discrimination recognition distance 500 set for 200, the (n+1) touch points are effective touch points of the touch unit 200 designed and manufactured according to the design method according to the present invention. Recognition can be verified. 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 less than the set minimum discrimination recognition distance 500 within a specified tolerance, it is determined that the (n+1) touch points are not valid touch points of the touch unit 200. I can.

According to an embodiment of the present invention, the touch point authentication unit 120 includes (n+1) touch units 220 provided in each divided area 310 on the flat area 305. The maximum possible distance 700 that can be provided apart from the top is set and maintained (or referenced). In this case, the touch point authentication unit 120 calculates the distance between (n+1) touch points, and reads whether the calculated distance between the touch points is less than or equal to the set maximum separation distance 700, the It is possible to authenticate whether (n+1) touch points are valid touch points of the touch unit 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 larger than the set maximum distance 700 within a specified tolerance, it is determined that the (n+1) touch points are not valid touch points of the touch unit 200. I can.

According to an exemplary method of the present invention, the touch point authentication unit 120 sets and maintains a (n+1) square structure condition formed by a line segment connecting (n+1) touch points. Here, the (n+1) polygonal structure condition is (n-1) of (n-1) divided areas (n-1) of the n divided areas 310 obtained by dividing the flat area 305 of the flat part 215 of the effective touch unit 200 310) is provided with one touch unit 220 having a designated contact area, and two touch units 220 including the designated touch unit 220 are provided in any one designated area 400, so that the (n +1) contains one or more conditions for reading the geometric properties that the square will have. For example, the (n+1) polygonal structure condition is a method of dividing the contact area size of the touch unit 220, the minimum discrimination recognition distance 500, the minimum discrimination distance 600, and the flat area 305, and It may include a condition for a geometric characteristic of an (n+1) square that can be formed based on a blank area that is not used on the flat plate region 305 and/or a geometric characteristic that cannot be formed. When the (n+1) square structure condition is set, the touch point authentication unit 120 connects the (n+1) touch points to form an (n+1) square, and the set (n+1) ) By reading the geometric characteristics of the (n+1) polygon formed through the polygonal structure condition, the (n+1) touch points are touches of the effective touch unit 200 designed and manufactured according to the design method according to the present invention. You can verify whether it is a point.

When the (n+1) touch point information is coordinately converted to the designated coordinate system, the touch point authentication unit 120 uses a value set as the information on the designated coordinate system, between (n+1) touch points. It is desirable to read the mutual positional relationship. If the (n+1) touch point information has not been coordinate converted to the designated coordinate system, the touch point authentication unit 120 coordinates the (n+1) touch point information to the designated coordinate system, and then The mutual positional relationship can be read. Meanwhile, according to another implementation method of the present invention, if the information set to read the (n+1) touch point information is set as information on the coordinate system of each device, the touch point authentication unit 120 performs ( It is possible to read the mutual positional relationship between n+1) touch points.

Referring to FIG. 1, the touch authentication system 100 reads the (n+1) touch point information through information on the divided areas 310 for the n divided areas 310, and the designated area ( A touch point identification unit 125 for identifying a designated touch point provided at the designated location 405 of 400), and a location relationship calculation unit for calculating a geometric touch position relationship between the identified designated touch point and each of the n touch points (130) and a touch authentication processing unit 135 for matching and comparing the calculated geometric touch position relationship between the calculated designated touch points and each of the n touch points and the touch position relationship of the touch authentication condition to be authenticated.

The touch point identification unit 125 is divided corresponding to the coordinate area of the divided area 310 obtained by dividing the flat area 305 of the flat part 215 of the effective touch unit 200 into n divided areas 310. Area 310 information is set and maintained, and (n+1) touch point information verified through the touch point verification unit 115 or (n+1) information authenticated through the touch point authentication unit 120 ) Touch point information is matched with the divided area 310 information. If the divided area 310 information is set as coordinate area information on the designated coordinate system, the touch point identification unit 125 converts (n+1) touch point information into the designated coordinate system as the divided area. (310) Matching with information, and the (n+1) touch point information is a state in which the coordinates are converted to the designated coordinate system through the touch point identification unit 115 or the touch point authentication unit 120, or the touch The coordinates may be converted into the designated coordinate system by the point identification unit 125. If the divided area 310 information is set as coordinate area information on each device-side coordinate system, the touch point identification unit 125 may convert the (n+1) touch point information into the divided area 310 without coordinate conversion. ) Can be matched with information.

According to the first designated touch point identification method of the present invention, the touch point identification unit 125 matches the divided area 310 information with (n+1) touch point information, the (n+1) After determining any one of the three touch points as a virtual designated touch point, matching the virtual designated touch point and the divided area 310 information, coordinate rotation of n touch points based on the virtual designated touch point By performing the process at least once, two touch points exist on the designated area 400 in which a virtual designated touch point is located among the n divided areas 310, and each of the remaining (n-1) divided areas 310 is You can check whether there is one touch point. If two touch points exist in the designated area 400 where the virtual designated touch points are located, and one touch point exists in each of the remaining (n-1) divided areas 310, the virtual designated touch points are 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 touch point identification unit 125 includes the (n+1) touch points in order to shorten the process of matching the divided area 310 information and (n+1) touch point information. A touch point with a high probability of being a designated touch point among the (n+1) touch points is predicted based on the geometric characteristic of the (n+1) polygon formed by the point, and a virtual designation takes precedence from the predicted touch point. A process of matching by selecting a touch point may be performed. For example, the touch point identification unit 125 virtually designates touch points on both sides of the vertex when there is a vertex greater than 180° among the inner angles of each vertex of the (n+1) square. It can be predicted by points.

According to the second designated touch point identification method of the present invention, the touch point identification unit 125 matches the virtual origin on the design with the divided area 310 information, and determines any one of the (n+1) touch points. A designated area among the n divided areas 310 by performing a process of coordinate rotation of (n+1) touch points based on the virtual origin after matching with the location of the designated touch point based on the virtual origin. It can be checked whether two touch points exist in 400 and one touch point exists in each of the remaining (n-1) divided regions 310. If two touch points exist in the designated area 400 and one touch point exists in each of the remaining (n-1) divided areas 310, 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+1) touch points, the positional relationship calculation unit 130 determines the distance between the identified designated touch point and each n touch points provided in the n divided areas 310 A geometric touch position relationship between the designated touch point and each of the n touch points, including a relationship 900 and an angular relationship 1000 formed by the n touch points based on the identified designated touch points, is calculated. .

The distance relationship 900 includes a coordinate distance on a specific coordinate system. The coordinate distance includes a relative coordinate distance calculated through a coordinate value based on a specific coordinate system, and may be expressed as a vector value further including a specific direction on the specific coordinate system according to an implementation method.

The angular relationship 1000 includes a coordinate angle on a specific 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 specific coordinate system. The angle formed by the connected line segments may be included.

According to an exemplary method of the present invention, the specific coordinate system may be a designated coordinate system corresponding to the positional relationship of the touch position relationship of the touch authentication condition, or may be a device-side coordinate system. When the calculated distance relationship 900 of the touch position relationship and the coordinate system corresponding to the angular relationship 1000 and the coordinate system corresponding to the location relationship of the touch authentication condition are different, the location relationship calculation unit 130 It is possible to perform a procedure for converting the coordinates of the coordinate system of to the coordinate system of another side.

According to the implementation method of the present invention, it is preferable that the location relationship calculation unit 130 calculates a geometric touch location relationship between the designated touch point and each of n touch points based on a coordinate value on a designated coordinate system. The (n+1) touch point information may be coordinate converted into coordinate values on the designated coordinate system, or may be coordinate converted by the location relationship calculation unit 130. If the touch location relationship of the touch authentication condition is provided for each device-side coordinate system, the coordinate conversion may be omitted, and the touch location relationship may be calculated based on a coordinate value on each device-side coordinate system.

When the geometric touch position relationship between the designated touch point and each of the n touch points is calculated, the touch authentication processing unit 135 includes the touch position relationship of the touch authentication condition stored by the authentication condition storage unit 105 and the calculated designation. After matching the geometrical touch position relationship between the touch point and each of the n touch points for each touch point, the distance and angle are compared to determine whether they match or are close within the specified error range. If the calculated geometrical touch position relationship and the touch position relationship of the touch authentication condition coincide with each of the matched touch points or are close within a specified error range, the (n+1) checked through the touch point identification unit 115 ) Touch point information is authenticated as a touch by the touch unit 200 having (n+1) touch units 220 corresponding to the matching or adjacent touch authentication condition.

When the touch authentication conditions stored in the storage medium 110 on the server 1400 according to the first embodiment of the present invention are grouped and stored by (n+1) polygonal geometric characteristics, the touch authentication processing unit 135 Check the geometric characteristic of the (n+1) square corresponding to the geometric touch position relationship between the calculated designated touch point and each of the n touch points, and match the geometric characteristic among the touch authentication conditions stored in the storage medium 110. By comparing whether the touch position relation of the touch authentication condition belonging to the group and the geometric touch position relation between the calculated designated touch point and each of n touch points are matched or approached within a predetermined error range, the calculated touch position relation and the It is possible to shorten the time required for matching and authenticating the touch position relationship of the touch authentication condition for each touch unit 200 stored in the storage medium 110.

According to the first embodiment of the present invention, the touch authentication condition stored in the storage medium 110 on the server 1400 and the location area information of the user of the touch unit 200 are mapped and stored, and the ( When n+1) touch point information is received and the location information of the designated device 1300 that recognizes the (n+1) touch points is received, the touch authentication processing unit 135 is the storage medium 110 Among the touch authentication conditions stored in the touch position relationship between the location area information matched with the received position information and the mapped touch authentication condition, and the geometric touch position relationship between the calculated designated touch point and each of the n touch points, the error is preferentially designated. By comparing whether they match or close within a range, it is possible to shorten the time required to compare and authenticate the calculated touch position relationship and the touch position relationship of the touch authentication condition for each touch unit 200 stored in the storage medium 110. .

When the touch authentication system 100 is implemented on the server 1400 according to the first implementation method of the present invention, the touch authentication processing unit 135 authenticates the (n+1) touch point information ( For example, an authentication error result or an authentication success result) is generated, and the generated touch authentication result is transmitted in the reverse direction of the path where the (n+1) touch point information is received. The touch authentication result is output through the designated device 1300 or used as an authentication value for providing a designated service to the designated device 1300.

According to the second embodiment of the present invention, when the touch authentication system 100 is implemented in a designated device 1300 having a capacitive touch screen 1310, the touch authentication processing unit 135 performs the (n+1) ) A result of authenticating touch point information is generated, the generated touch authentication result is output, or a designated service is initiated based on the touch authentication result.

FIG. 2 is an illustration of the external appearance of a touch unit 200 designed and manufactured according to an implementation method of the present invention.

In more detail, the drawing 2 shows a handle part 205 formed to be gripped by a person's hand, a designated number of touch parts 220 made of an electrostatic change inducing material, the handle part 205 and a designated number of touch parts. A frame unit 210 is provided to connect 220 to fix the designated number of touch units 220 to a flat area 305 of a designated shape, and the frame unit 210 is a flat area of a designated graphic shape. As an example of the external appearance of the touch unit 200 including the 305 and including the flat plate portion 215 on which the specified number of touch units 220 are fixed or formed, common knowledge in the technical field to which the present invention pertains. If a person has, it is possible to infer various embodiments of the external appearance of the touch unit 200 by referring and/or modifying this drawing 2, but the present invention includes all the inferred implementation methods, and the present invention It is not limited only to the appearance illustrated in FIG. 2. For convenience of explanation, in the embodiment of the present invention, the touch unit 200 will be illustrated and described as a painted object, but the structural features of the touch unit 200 of the present invention are not limited thereto, and the present invention The touch unit 200 of is manufactured in the form of a module including a touch unit, excluding some components necessary for maintaining the painting form, and is mounted/embedded in various items (eg, cards, accessories, etc.) that can be held or carried in the hand. It is clear that it can be carried out in the form of various objects that can be held in the hand or carried in addition to objects in the form of stamps or stamps.

According to the first touch part implementation method of the present invention, the touch part 220 may be manufactured using a conductive material having rubber elasticity of at least one of a conductive rubber material, a conductive plastic material, and a conductive silicone material. It may be manufactured to have a pre-designed hardness (eg, 80 or less based on a Shore A hardness tester) and electrical resistance (eg, a measurement resistance value of 300 Ω or less between a touched part and a part electrically connected to the human body). For example, when the touch part 220 of the first touch part embodiment is made of a conductive rubber material, the conductive rubber is mixed with conductive carbon (eg, including conductive carbon or metal powder) and rubber in a calculated ratio. It may be manufactured, and hardness and electrical resistance may be determined according to the mixing ratio of the rubber and conductive carbon.

According to the second touch unit implementation method of the present invention, the touch unit 220 may be manufactured using a metallic material, and the metal material has high electrical conductivity (eg, touched Any material may be used as long as the measured resistance value between the part and the part electrically connected to the human body is less than 1Ω). Meanwhile, when the touch unit 220 is made of a metallic material, the touch screen may be damaged at the time of touching the touch screen made of a glass material. Accordingly, a touch film made of a material capable of buffering the amount of impact (for example, 90 or less based on the Shore A hardness tester) may be formed between the touch part 220 of the metallic material and the touch screen. have. The touch film is manufactured in a form that is individually attached to each touch part 220, a designated number of touch parts 220 are attached to the touch film, or is spaced apart from each touch part 220 at a predetermined interval. Then, it may be manufactured in a structure in which the touch unit 220 and the touch film come into contact with each other at the point of touch. Preferably, the touch layer is preferably made of an opaque material.

According to the third method of implementing the touch unit of the present invention, the touch unit 220 may be manufactured by plating a metallic material on a non-conductive material. If the non-conductive material has a hardness such as to damage the touch screen (e.g., 90 or more based on the Shore A hardness tester), the touch film is formed on the touch part 220 plated with a metallic material on the non-conductive material. I can.

According to the fourth touch part implementation method of the present invention, the touch part 220 may be manufactured by forming a metallic film made of a metallic material on the outside of a buffer material made of an elastic material. The cushioning material may be made of a foamable material such as sponge or polyurethane, and the metal film may be manufactured by plating a metallic material on the cushioning material and/or using a metallic material as yarn or cotton yarn. For example, the touch part 220 manufactured by forming a metal film of the buffer material may have a structure of a gasket for EMI shielding.

According to the fifth method of implementing the touch part of the present invention, the touch part 220 may be manufactured using a carbon fiber material including a carbon nanotube material or a single-wall carbon nanotube material, and preferably has a pre-designed hardness ( For example, it may be manufactured with a Shoa A hardness tester standard of 80 or less).

According to the sixth method of implementing the touch unit of the present invention, the touch unit 220 may be manufactured using a dielectric material in a solid form or a dielectric material in a liquid form, and a dielectric material including a container storing the same. Dielectric material is a generic term for materials in which polarization occurs by a voltage or electric field and constrained charges are generated on the surface.Polarization is generated by a voltage or electric field applied to the surface of the touch screen, and constrained charges that can induce electrostatic change It is preferable to contain a ferroelectric material (eg, barium titanate or Rossel salt, etc.) having a dielectric constant to be generated.

On the other hand, the embodiment of the touch unit 220 of the present invention is by no means limited to the case of the first to sixth touch unit embodiments, and is made of a material that is electrically connected to the human body and induces electrostatic change of the capacitive touch screen. If so, it is clearly stated that any material falls within the scope of the present invention.

3 illustrates a divided area 310 according to an exemplary method of the present invention.

In more detail, FIG. 3 is an exemplary diagram of an implementation method of dividing the flat area 305 of the flat portion 215 provided in the touch unit 200 into n (n = 4) pieces of information used for touch authentication. As such, a person of ordinary skill in the art to which the present invention pertains will be able to infer various implementation methods for the divided region 310 by referring and/or modifying this drawing 3, but the present invention is the analogy. It includes all the implementation methods, and the technical features are not limited only by the implementation method shown in FIG. 3.

The example of FIG. 3A is an illustration of the flat area 305 formed on the bottom of the flat portion 215 of the touch unit 200, and the flat area 305 illustrated in FIG. A figure outline 300 formed in a fine shape with a certain curvature and forming a certain area while maintaining the figure shape is provided.

The example of FIG. 3B illustrates that the flat area 305 illustrated in FIG. 3A is divided into four divided areas 310. Since the flat area 305 of FIG. 3A has a basic quadrangular shape, in the example of FIG. 3B, the flat area 305 is divided into four divided areas 310. If the shape of the flat area 305 has a pentagonal shape, the divided area 310 may be divided into 5 divided areas 310 including 5 triangular areas based on a central area. Alternatively, if the shape of the flat area 305 has a hexagonal shape, the divided area 310 may be divided into 6 divided areas 310 including 6 triangular areas. On the other hand, if the shape of the flat area 305 has a rectangular shape, the divided area 310 will be divided into 6 divided areas 310 including 6 rectangular areas dividing the short side into two and the long side divided into three. I can. It is preferable that each of the divided regions 310 has the same area. However, the present invention is by no means limited thereto, and each divided area 310 may have a different area according to an implementation method.

An example of FIG. 3C illustrates an implementation method of dividing the flat area 305 illustrated in FIG. 3A into four divided areas 310, but with a certain margin. In this case, the space between the divided areas 310 may always be less than the minimum discrimination recognition distance 500 no matter where the touch units 220 provided in each divided area 310 are provided at any position of each divided area 310. It is preferable to include a margin of the minimum discrimination recognition distance 500 designated so as to be.

4 illustrates a divided area 310 and a designated area 400 according to an exemplary method of the present invention.

In more detail, FIG. 4 shows that the calculated positions 410 on the three divided areas 310 of the four divided areas 310 divided into four as shown in FIG. 3B are the flat area 305 of FIG. 3A. One touch unit 220 is provided at a designated position 405 on one designated area 400 and at the same time, one touch unit 220 is provided at one calculated position 410. 220) is an exemplary diagram for an implementation method including, for those of ordinary skill in the art to which the present invention belongs, various implementation methods for the divided area 310 are described with reference to and/or modification of this FIG. 4. Although it may be inferred, the present invention includes all of the above inferred implementation methods, and the technical features thereof are not limited only by the implementation method shown in FIG. 4.

4A and 4B use the lower left area of the flat area 305 illustrated in FIG. 3A into 4 divided areas 310 as shown in FIG. 3B as the designated area 400, An example in which the remaining three areas are used as the divided area 310 is illustrated.

According to the example of FIG. 4A, the designated area 400 at the lower left of the four divided areas 310 is set to a designated position 405 at the lower left corner of the flat area 305 in contact with the figure outline 300. , The calculated location 410 is set in the remaining area on the designated area 400 excluding the area in which the designated location 405 is set. In addition, one calculated position 410 is set for the remaining three divided regions 310 of the four divided regions 310 except for the designated region 400.

According to the example of FIG. 4B, a designated touch unit 220 is provided at a designated location 405 of the designated area 400 at the lower left of the four divided areas 310, and the calculated location 410 of the designated area One touch unit 220 is provided in the unit. In addition, one touch unit 220 is provided at the calculated positions 410 on the remaining three divided areas 310 of the four divided areas 310 except for the designated area 400.

5 illustrates a minimum discrimination recognition distance 500 according to an exemplary method of the present invention.

In more detail, FIG. 5 is an exemplary view of the minimum discrimination recognition distance 500 among information used for touch authentication, and those of ordinary skill in the art to which the present invention pertains, refer to FIG. 5 and/ Alternatively, various implementation methods of the minimum discrimination recognition distance 500 for each direction on the flat area 305 may be inferred, but the present invention includes all the inferred implementation methods. The technical features are not limited only by the implementation method shown in FIG.

The example of FIG. 5A is an illustration of setting the distance between the contact surface and the contact surface of the touch unit 220 having a designated contact area as the minimum discrimination recognition distance 500, and specifically, the flat area illustrated in FIG. 3A. It is an example of setting the distance between the contact surface and the contact surface of the touch unit 220 as the minimum discrimination recognition distance 500 based on the upper side of the horizontal direction of 305.

The example of FIG. 5B is an illustration of setting the distance between the midpoint and the midpoint of the touch unit 220 having a designated contact area as the minimum discrimination recognition distance 500. Specifically, the flat plate illustrated in FIG. 3A It is an example of setting the distance between the midpoint and the midpoint of the touch unit 220 as the minimum discrimination recognition distance 500 based on the upper side of the region 305 in the horizontal direction.

According to an implementation method extending from the present invention, a combination of the examples of FIGS. 5A and 5B, for example, the distance between the contact surface of one touch unit 220 and the midpoint of the other touch unit 220 It may be set as the minimum discrimination recognition distance 500.

According to the present invention, even if the touch units 220 provided on the flat area 305 are provided in any divided area 310, each of the touch units 220 must be provided at a distance of more than the set minimum discrimination recognition distance 500. . Preferably, the minimum discrimination recognition distance 500 is a distance applied in each horizontal and vertical direction on a two-dimensional plane corresponding to the flat area 305.

Figure 6 illustrates a minimum identification distance 600 according to an embodiment of the present invention.

In more detail, FIG. 6 is an exemplary view of the minimum identification distance 600 among information used for touch authentication, and those of ordinary skill in the art to which the present invention pertains, refer to FIG. 6 and/or By modifying, various implementation methods of the minimum identification distance 600 for each direction on the flat area 305 may be inferred, but the present invention includes all the inferred implementation methods, and is shown in FIG. The technical characteristics are not limited only by the method of implementation.

In the example of FIG. 6, the flat area 305 of the flat part 215 provided in different touch units 200 is the same as the flat area 305 illustrated in FIG. 3A, and the flat area 305 is shown in FIG. 3B. In the case of dividing into four divided areas 310 in the same manner, the calculated positions 410 of the designated area 400 of each touch unit 200, the upper left divided area 310, and the upper right divided area 310 Is the same, but the calculated position 410 of the lower right divided area 310 is separated by a minimum identification distance 600 in the horizontal direction of the exemplary reference of FIG. 6.

According to the present invention, among the touch units 220 provided on different flat areas 305, the touch units 220 provided in one or more of the same divided areas 310 are separated by more than the set minimum identification distance 600. By being provided, the relationship of the touch positions of the touch units 220 provided in each of the flat regions 305 is different so that one or more touch positions can be identified from each other. Preferably, the minimum identification distance 600 is a distance applied in each horizontal and vertical direction on a two-dimensional plane corresponding to the flat plate area 305.

Meanwhile, the designated positions 405 of the designated area 400 in which the designated touch unit 220 is provided with respect to the same type of touch unit 200 are the same. Even if the flat area 305 of the flat part 215 and the divided area 310 are the same, if the designated location 405 where the designated touch part 220 is to be provided is different, it may be classified as a different type of touch unit 200. .

7 illustrates the maximum possible separation distance 700 according to an exemplary method of the present invention.

In more detail, FIG. 7 is an exemplary view of the maximum possible separation distance 700 among information used for touch authentication, and those of ordinary skill in the art to which the present invention pertains, refer to this FIG. 7 and/ Alternatively, it is possible to infer various implementation methods of the maximum possible separation distance 700 that can be implemented with respect to the shape shape of the various flat plate regions 305 by modification, but the present invention includes all the inferred implementation methods, and the present invention The technical features are not limited only by the implementation method shown in FIG. 7.

The example of FIG. 7 illustrates the maximum possible separation distance 700 that can be implemented on the flat area 305 illustrated in FIG. 3A. Among the divided areas 310 illustrated in FIG. 3B, the lower left corner as in the example of FIG. 3B. The maximum possible distance 700 calculated on the upper right divided area 310 based on the designated touch unit 220 provided at the designated location 405 on the designated area 400 of is illustrated. The (n+1) touch points touched by each touch unit 200 having the same flat area 305 cannot be separated by more than the maximum possible separation distance 700.

Fig. 8 illustrates the geometric characteristics of an (n+1) square according to an exemplary method of the present invention.

In more detail, FIG. 8 is an illustration of the limitations of the geometric characteristics of the (n+1) square formed by connecting (n+1) touch points among the information used for touch authentication. For those of ordinary skill in the relevant technical field, refer to and/or modify this Figure 8 to have a (n+1) square according to the shape of the various flat plate regions 305 and the divided regions 310 and contact areas. It is possible to infer various implementation methods of the geometrical characteristics, but the present invention includes all the inferred implementation methods, and the technical characteristics are not limited only by the implementation method shown in FIG. 8.

In the example of FIG. 8, the flat area 305 illustrated in FIG. 3A is divided into four divided areas 310 to have a margin corresponding to the minimum discrimination recognition distance 500 as in the example of FIG. 3C, and FIG. 3C In the case where the lower left divided area 310 is designated as the designated area 400 and the designated touch unit 220 is provided in the lower left corner area as in the example of (n+1) touch units 220 or touch points It is an illustration of the areas where the focus of the can not exist and the areas that can exist. For convenience, areas where the center cannot exist are indicated in dark gray, areas that can exist are indicated in light gray, and the error range for each area is omitted. For reference, the (n+1) square will be formed based on the touch point, but this figure 8 illustrates the touch unit 220 for convenience in order to aid understanding.

According to the present invention, the flat area 305, the divided area 310, and the touch unit 220 include a designated figure shape and a certain area, and are formed on n divided areas 310 by dividing the flat area 305. The center point of the touch unit 220 provided in must exist in an area that can exist as shown in FIG. 8. As described above, while an area in which the center cannot exist and an area that can exist, two touch units 220 are provided in the designated area 400 of the n divided areas 310, and each of the touch units 220 is at least It is formed by connecting (n+1) touch points to be separated from each other by a distinct recognition distance (500) or more, since the touch units 220 of the other touch units (200) and a minimum identification distance (600) or more must be identified. The (n+1) square that becomes, will have the specified geometric properties. For example, the spacing between the focal points must be separated from each other by a distance corresponding to the minimum discrimination recognition distance 500, and the spacing between the focal points must exist within the maximum possible separation distance 700. The spacing is a characteristic provided in the same designated area 400, and the like. Such geometric characteristics can be expressed as a function of the distance and angle of each side constituting the (n+1) square, and the shape of the flat area 305, the divided area 310, and the touch unit 220, etc. Of the number of areas 310, the minimum discrimination recognition distance 500 set by design, the maximum separation distance 700, and the minimum identification distance 600, (n+1) can be customized according to one or more conditions limiting the formation of a square. I can.

9 illustrates a distance relationship 900 according to an exemplary method of the present invention.

In more detail, FIG. 9 illustrates a distance relationship 900 between n touch points based on a designated touch point among information used for touch authentication, and those of ordinary skill in the art to which the present invention belongs , It is possible to infer various implementation methods for the distance relationship 900 by referring to and/or modifying this figure 9, but the present invention includes all the inferred implementation methods, and the implementation shown in this figure 9 The technical characteristics are not limited only by the method.

The example of FIG. 9 shows four angles based on the designated touch points corresponding to the designated touch unit 220 provided in the corner area of the designated area 400 at the lower left of the divided areas 310 of FIG. 3B or 3C. The distance relationship 900 between four touch points corresponding to each touch unit 220 provided at the calculated position 410 on the divided area 310 is illustrated. For reference, the distance relationship 900 is calculated and compared based on the touch point, but this drawing 9 illustrates the touch unit 220 for convenience of understanding.

The distance relationship 900 included in the touch location relationship of the touch authentication condition and the distance relationship 900 of the touch location relationship calculated based on (n+1) touch points are compared after matching each touch point, and the distance In order to match the relationship 900, a unique identifier may be assigned to each touch point. For example, as shown in the example of FIG. 9, identifiers such as'A','B','C', and'D' may be assigned to touch points in a specific direction based on the designated touch point. The distance relationship 900 included in the touch location relationship of the touch authentication condition for each touch point corresponding to, and the distance relationship 900 of the touch location relationship calculated based on (n+1) touch points are matched. If the distances of each of the matched identifiers are compared and approximate within a specified error range (eg, within a 95% match range of a Gaussian probability distribution), the match may be considered. Even if the compared distances are close within the specified error range, if the distances corresponding to different identifiers are close, it is considered to be inconsistent.

Fig. 10 illustrates an angular relationship 1000 according to an exemplary method of the present invention.

In more detail, FIG. 10 illustrates an angular relationship 1000 formed by n touch points based on a designated touch point among information used for touch authentication, and provides general knowledge in the technical field to which the present invention belongs. If a person has, it is possible to infer various implementation methods for the angular relationship 1000 by referring and/or modifying this figure 10, but the present invention includes all of the above inferred implementation methods, and The technical features are not limited only by the illustrated implementation method.

Examples of FIGS. 10A and 10B are based on a designated touch point corresponding to a designated touch unit 220 provided in the corner area of the lower left designated area 400 of the divided area 310 of FIG. 3B or 3C. The angular relationship 1000 formed by four touch points corresponding to each touch unit 220 provided at the calculated position 410 on each of the four divided regions 310 is illustrated. For reference, the angular relationship 1000 is calculated and compared based on the touch point, but this drawing 10 illustrates the touch unit 220 for convenience of understanding.

The example of Fig. 10a is an illustration of the angular relationship 1000 in the coordinate system between two touch points among n touch points with a designated touch point as a reference point, and the example of Fig. 10b is a virtual origin based on a virtual origin on the coordinate system and a reference line. The angular relationship 1000 formed by a line segment connecting (n+1) touch points is illustrated. The virtual origin illustrated in FIG. 10B may exist within a designated touch point.

The angular relationship 1000 included in the touch position relationship under the touch authentication condition and the angular relationship 1000 of the touch position relationship calculated based on (n+1) touch points are compared after matching each touch point. In order to match the relationship 1000, a unique identifier may be assigned to each touch point. For example, as in the example of this drawing 10, identifiers such as'A','B','C','D', and'E' may be assigned to a touch point in a specific direction based on a designated touch point. For each touch point corresponding to each identifier, the angular relationship 1000 included in the touch position relationship of the touch authentication condition and the angular relationship 1000 of the touch position relationship calculated based on (n+1) touch points are matched. do. If the angles of each of the matched identifiers are compared and approximate within a specified error range (eg, within a 95% match range of a Gaussian probability distribution), the match may be considered. Even if the compared angles are close within the specified error range, if the distances corresponding to different identifiers are close, it is considered to be inconsistent.

11 is a diagram illustrating a process of storing a touch authentication condition according to an exemplary method of the present invention.

In more detail, FIG. 11 is a calculation on (n-1) divided areas 310 among n divided areas 310 obtained by dividing the flat area 305 of the flat part 215 provided in the touch unit 200. (N It shows a process of storing a touch authentication condition for authenticating the geometric touch position relationship of +1) touch points, and if a person of ordinary skill in the art to which the present invention belongs, refer to Fig. 11 and/or By modifying, various implementation methods for the storage process of the touch authentication condition (e.g., an implementation method in which some steps are omitted or the order is changed) may be inferred, but the present invention includes all the inferred implementation methods. The technical features are not limited only by the implementation method illustrated in FIG. 11.

Referring to FIG. 11, the touch authentication system 100 is designed and manufactured in a form in which n number of touch units 220 and one designated touch unit 220 are provided in the flat area 305 of the flat unit 215. Check the geometric touch position relationship in design for (n+1) touch points corresponding to each touch point of the touch unit 200 (1100), and design geometric touch for the (n+1) touch points The positional relationship is stored in the designated storage medium 110 (1105). Meanwhile, according to an implementation method, the touch authentication system 100 checks design error information for the (n+1) touch points, and touch authentication conditions including the geometric touch position relationship and design error information on the design. Can be stored (1105). If the touch unit 220 of the touch unit 200 is designated for quality control of the touch unit 220 of the designed and manufactured touch unit 200, the capacitive touch screen 1310 of the registration device 1300 is designated. ), the stored touch authentication condition may be used for authentication if the procedure for registering by repeatedly touching the number specified in) is not performed.

The touch authentication system 100 repeatedly touches the touch unit 200 designed and manufactured in response to the touch authentication condition on the capacitive touch screen 1310 of the designated registration device 1300 for more than a specified number of times (n+ 1) Check the relationship of the actual measurement positions for the touch points (1110). If the actual measurement position relationship with respect to the (n+1) touch points repeatedly touched is confirmed, the touch authentication system 100 determines the actual measurement position relationship repeatedly checked more than the specified number of times. It is checked whether it exists within a specified error tolerance of the design geometrical touch position relationship with respect to the touch point (1115).

If the actual measurement position relationship, which has been repeatedly checked more than the specified number of times, does not exist within the specified error tolerance range of the geometric touch position relationship in the design, the touch authentication system 100 includes the (n+1) touch units 220 The (n+1) touch units 220 provided in the touch unit 200 having an error are corrected to fall within the error tolerance range, or a procedure of remanufacturing after disassembly is performed (1120).

On the other hand, if the actual measurement position relationship, which has been repeatedly checked more than the specified number of times, exists within the specified error tolerance range of the geometric touch position relationship on the design, the touch authentication system 100 is in the geometric touch position relationship and the error tolerance range on the design. A touch authentication condition including corresponding error information (eg, design error information or actual measurement error information) is stored in a designated storage medium 110 that stores a touch authentication condition to be used for authentication (1125).

12 is a diagram illustrating a touch authentication process according to an exemplary method of the present invention.

In more detail, FIG. 12 shows the (n+1) number of touch units (n+1) when the (n+1) number of touch units 220 provided in the touch unit 200 are touched through the capacitive touch screen 1310 ( 220) shows a process of matching and comparing the positional relationship of (n+1) touch points corresponding to (n+1) touch points with the touch positional relationship of the touch authentication condition registered through the process shown in FIG. Those of ordinary skill in the relevant technical field can infer various implementation methods for the touch authentication process (e.g., implementation methods in which some steps are omitted or the order is changed) by referring and/or modifying this Figure 12. Although it may be possible, the present invention includes all of the above inferred implementation methods, and the technical features are not limited only by the implementation method shown in FIG. 12.

Referring to FIG. 12, the touch authentication system 100 touches (n+1) touch units 220 provided in the touch unit 200 to the capacitive touch screen 1310, and (n+1) touches. Check the point information (1200). According to an implementation method, the touch authentication system 100 may perform a coordinate conversion procedure for the identified (n+1) touch points.

The touch authentication system 100 reads the mutual positional relationship between the identified (n+1) touch points and authenticates whether or not a touch point has been touched by a valid ceramic (1205). According to an implementation method, the touch authentication system 100 may perform a coordinate conversion procedure for the (n+1) touch points in order to read the mutual positional relationship. The coordinate transformation may be performed once and then no longer performed.

If the (n+1) touch points are not valid touch points of the touch unit 200, the touch authentication system 100 performs authentication error result processing on the (n+1) touch points, and the ( A procedure of discarding n+1) touch point information may be performed (1210).

On the other hand, if the (n+1) touch points are valid touch points of the touch unit 200 as a result of reading the mutual positional relationship, the touch authentication system 100 includes a flat plate part 215 provided in the touch unit 200. A designated touch point provided at a designated location 405 of the designated region 400 by reading the (n+1) touch point information through the divided region 310 information corresponding to the n divided regions 310 for To identify (1215). According to an implementation method, the touch authentication system 100 may perform a coordinate conversion procedure for the (n+1) touch points to identify the designated touch points. The coordinate transformation may be performed once and then no longer performed. According to an embodiment of the present invention, the designated touch point matches the coordinate system of the divided area 310 information with the coordinate system of (n+1) touch points, and then the (n+1) Whether two touch points match each of the divided regions 310 of the divided region 310 information may be identified through a coordinate rotation procedure.

If the designated touch point is not identified through the divided area 310 information, the touch authentication system 100 performs authentication error result processing on the (n+1) touch points, and the (n+1) touch points A procedure of discarding) touch point information may be performed (1210).

Meanwhile, when the designated touch point is identified through the divided area 310 information, the touch authentication system 100 calculates a geometric touch position relationship between the identified designated touch point and each of the n touch points (1220). According to an implementation method, the touch authentication system 100 may perform a coordinate conversion procedure for the (n+1) touch points to identify the designated touch points. The coordinate transformation may be performed once and then no longer performed.

The touch authentication system 100 includes available touch authentication conditions (e.g., all touch authentication conditions, touch authentication conditions mapped to a specific location, touch authentication belonging to a specific group) among touch authentication conditions stored through the process shown in FIG. Condition, etc.) and the calculated touch position relationship (1225), the touch position relationship of the matched touch authentication condition and the calculated touch position relationship are compared and authenticated to match, or Alternatively, it is verified whether it is close to the specified error range (1230).

The matching comparison authentication process is preferably performed for all available touch authentication conditions, and if the touch location relationship is not authenticated even after performing the authentication procedure for all available touch authentication conditions, the touch authentication system 100 An authentication error result processing may be performed on (n+1) touch points, and a procedure of discarding the (n+1) touch point information may be performed (1210).

Meanwhile, during or after performing an authentication procedure for all available touch authentication conditions, if the touch position relationship is authenticated, the touch authentication system 100 processes authentication success results for the (n+1) touch points. Perform (1235). A service corresponding to the touch authentication may be started by processing the authentication success result.

13 is a diagram showing an embodiment of a user's wireless terminal 1300 corresponding to the device 1300 having the capacitive touch screen 1310 according to an embodiment of the present invention.

In more detail, FIG. 13 is a first implementation of the configuration of the program 1330 of the wireless terminal 1300 interworking with the touch authentication system 100 implemented on the server 1400 according to the first implementation method of the present invention. As an example, a second embodiment is shown in which the touch authentication system 100 shown in Fig. 1 is implemented in the form of a program 1330 mounted on the wireless terminal 1300 according to the second embodiment of the present invention. , If a person of ordinary skill in the art to which the present invention belongs, it is possible to infer various implementation methods for the function of the wireless terminal 1300 by referring and/or modifying this figure 13, but the present invention is the analogy It includes all the implementation methods, and the technical features are not limited only by the implementation method shown in FIG. 13. Preferably, the wireless terminal 1300 of FIG. 13 may include at least one of various smart phones capable of wireless communication, various tablet PCs, various PDAs, and various mobile phones.

13, the wireless terminal 1300 includes a control unit 1302, a memory unit 1328, a screen output unit 1306, a key input unit 1308, a sound output unit 1312, and a sound input unit 1314. And a camera unit 1304, a wireless network communication unit 1322, a short-range wireless communication unit 1320, a proximity wireless communication unit 1316, a location positioning unit 1324, a USIM reader unit 1326, and a USIM, and supply power. It is provided with a battery 1318 for.

The controller 1302 is a generic term for a configuration that controls the operation of the wireless terminal 1300, and includes at least one processor and an execution memory, and each component and a bus provided in the wireless terminal 1300 ( BUS). According to the present invention, the control unit 1302 loads at least one program code provided in the wireless terminal 1300 into the execution memory through the processor and calculates, and calculates the result of at least one configuration through the bus. It is transmitted to the unit and the operation of the wireless terminal 1300 is controlled. Hereinafter, for convenience, a configuration of the program 1330 implemented in software in the wireless terminal 1300 according to the first embodiment or the second embodiment will be described by showing in the control unit 1302.

The memory unit 1328 is a generic term for a nonvolatile memory corresponding to a storage resource of the wireless terminal 1300, and includes at least one program code executed through the control unit 1302 and at least one program code used by the program code. Save and maintain the dataset. The memory unit 1328 basically includes a system program code and a system data set corresponding to the operating system of the wireless terminal 1300, a communication program code and a communication data set for processing wireless communication connection of the wireless terminal 1300, and at least One application program code and application data set are stored, and a program code and data set corresponding to the program 1330 of the present invention are also stored in the memory unit 1328.

The screen output unit 1306 is composed of a screen output unit (for example, a liquid crystal display (LCD)) corresponding to the output resource of the wireless terminal 1300 and a driving module that drives the screen output unit 1300, and interlocks with the control unit 1302 As a result, an operation result corresponding to a screen output among various operation results of the control unit 1302 is output to the screen output device.

The key input unit 1308 is composed of one or more user input devices (eg, buttons, keypads, touch panels, etc.) corresponding to the input resources of the wireless terminal 1300 and a driving module that drives them, and the control unit 1302 and Interlockingly, a command for commanding various operations of the control unit 1302 is input, or data required for calculation of the control unit 1302 is input.

According to the present invention, the key input unit 1308 implements the capacitive touch screen 1310 by interlocking with the capacitive touch panel provided in the screen output unit 1306, and the flat part 215 of the touch unit 200 ) Provided in (n+1) touch units 220 are capacitively touched on the capacitive touch screen 1310.

The sound output unit 1312 is composed of a speaker corresponding to the output resource of the wireless terminal 1300 and a driving module that drives it, and is interlocked with the control unit 1302 to generate sound among various calculation results of the control unit 1302. The calculation result corresponding to the output is output through the speaker. The driving module decodes sound data to be output through the speaker and converts it into a sound signal.

The sound input unit 1314 includes a microphone corresponding to an input resource of the wireless terminal 1300 and a driving module that drives the microphone, and transmits sound data input through the microphone to the control unit 1302. The driving module encodes and encodes a sound signal input through the microphone.

The camera unit 1304 is composed of an optical unit corresponding to the camera resource of the wireless terminal 1300, a charge coupled device (CCD), and a driving module that drives the same, and in the form of a bitmap input to the CCD through the optical unit. Acquire image data or image data. The data acquired through the camera unit 1304 may include image data in the form of a still image or video data in the form of a moving image.

The wireless network communication unit 1322 and the short-range wireless communication unit 1320 are generic terms of communication resources for connecting the wireless terminal 1300 to a designated communication network. Preferably, the wireless terminal 1300 may include a wireless network communication unit 1322 as a basic communication resource, and may include one or more short-range wireless communication units 1320.

The wireless network communication unit 1322 is a generic term for communication resources for connecting the wireless terminal 1300 to a wireless communication network via a base station, and an antenna for transmitting and receiving a radio frequency signal of a specific frequency band, an RF module, a baseband module, and a signal. It is configured to include at least one processing module, and is connected to the control unit 1302 to transmit an operation result corresponding to wireless communication among various operation results of the control unit 1302 through a wireless communication network or receive data through a wireless communication network. Then, the data is transmitted to the control unit 1302 and at the same time, the wireless communication access, registration, communication, and handoff procedures are performed. According to the present invention, the wireless network communication unit 1322 may connect the wireless terminal 1300 to a telephone communication network including a call channel and a data channel through an exchange, and in some cases, a packet It is possible to connect to a data network that provides communication-based wireless network data communication (eg, the Internet).

According to the implementation method of the present invention, the wireless network communication unit 1322 performs at least one of access to a mobile communication network, location registration, call processing, call connection, data communication, and handoff according to CDMA/WCDMA/LTE standards. Includes composition. Meanwhile, according to the intention of a person skilled in the art, the wireless network communication unit 1322 may further include a portable Internet communication configuration that performs at least one access to the mobile Internet, location registration, data communication, and handoff according to IEEE 802.16 related standards. It should be clearly understood that the present invention is not limited by the wireless communication configuration provided by the wireless network communication unit 1322. That is, the wireless network communication unit 1322 is a generic term for a configuration unit that connects to a wireless communication network through a cell-based base station regardless of a frequency band of a radio section, a type of communication network, or a protocol.

The short-range wireless communication unit 1320 is a generic term for communication resources for connecting a communication session using a radio frequency signal as a communication medium within a certain distance (e.g., 10m) and connecting the wireless terminal 1300 to a communication network. , Preferably, the wireless terminal 1300 may be connected to a communication network through at least one of Wi-Fi communication, Bluetooth communication, public wireless communication, and UWB. According to an exemplary embodiment of the present invention, the short-range wireless communication unit 1320 may be implemented in an integrated or separate form with the wireless network communication unit 1322. According to the present invention, the short-range wireless communication unit 1320 connects the wireless terminal 1300 to a data network providing packet communication-based short-range wireless data communication through a wireless AP.

The proximity wireless communication unit 1316 is a communication that processes one or more proximity wireless communication among two-way proximity wireless communication, full-duplex proximity wireless communication, and half-duplex proximity wireless communication by using a radio frequency signal as a communication medium at a close distance (for example, within 10 cm). As a generic term for resources, it is possible to process proximity wireless communication preferably according to the NFC (Near Field Communication) standard of the 13.56Mz frequency band. Alternatively, the proximity wireless communication unit 1316 may process proximity wireless communication according to the ISO 18000 series standard, and in this case, may process proximity wireless communication for a frequency band other than the 13.56Mz frequency band. For example, the proximity wireless communication unit 1316 may operate in a reader mode, a tag mode, or a two-way communication mode. Meanwhile, the proximity wireless communication unit 1316 may be included in a communication resource for connecting the wireless terminal 1300 to a communication network according to a communication target in proximity.

The location positioning unit 1324 is a generic term for positioning resources for positioning the location of the wireless terminal 1300, and preferably, a terminal method positioning using a Global Positioning System (GPS), a network positioning method using a network resource, and the terminal method. The location of the wireless terminal 1300 may be located through a positioning technology in which at least one or a combination of two or more of a hybrid method in which a network method and a network method are mixed. Terminal method positioning is a technology that precisely locates the location of the wireless terminal 1300 through a GPS module (or a module with a GPS function) built in the wireless terminal 1300, and a location signal sent from a GPS satellite is transmitted to the wireless terminal. A-GPS (Assisted-GPS) method that (1300) reads and informs the base station, and DGPS (Differential GPS) method that corrects an error in a position signal received from a satellite by receiving a correction signal from a ground reference receiver. have. Network-based positioning is a positioning technology that uses network resources that can be interlocked with the wireless terminal 1300, and is a cell ID method that identifies the location of the wireless terminal 1300 through the service cell ID of the base station, and between the base station and the terminal in the cell ID method. Enhanced CellID method that improves accuracy by adding distance information of the terminal, AOA (Angle Of Arrival) method that uses the difference in signal reception angles from three base stations that received the signal from the terminal, between one base station and two neighboring base stations The hybrid method may include one or more of a TOA (Time Of Arrival) method using a difference in signal arrival time and a TDOA (Time Difference Of Arrival) method of measuring signal delays of neighboring base stations based on a base station signal. It includes E-OTD (Enhanced Observed Time Difference), which measures the difference in time when more than one base station sends a radio wave to a terminal and returns the radio wave again, positioning the location of the radio terminal 1300 by a network method or a hybrid method. In this case, the location of the wireless terminal 1300 is positioned through a separate positioning server, and the location positioning unit 1324 is connected to the wireless network communication unit 1322 or the short-range wireless communication unit 1320 through a positioning server. After performing the operation of positioning the wireless terminal 1300, a result of measuring the location of the wireless terminal 1300 may be provided from the positioning server.

The USIM reader 1326 is a generic term for exchanging at least one data set with a Universal Subscriber Identity Module mounted or detached from the wireless terminal 1300 based on the ISO/IEC 7816 standard. As a result, the data set is exchanged in a half-duplex communication method through an Application Protocol Data Unit (APDU).

The USIM is a SIM type card equipped with an IC chip according to the ISO/IEC 7816 standard, an input/output interface including at least one contact connected to the USIM reader 1326, and at least one IC chip program code And an IC chip memory for storing a data set, and the IC chip program code is calculated or the data set is extracted (or processed) according to at least one command transmitted from the wireless terminal 1300 by being connected to the input/output interface. It includes a processor that transmits to the input/output interface.

The program 1330 of the present invention is downloaded from a program providing server (eg, Apple's App Store, etc.) through a data network to which the communication resource is accessible, and stored in the memory unit 1328. The downloaded program 1330 may be manually driven by a user, or automatically driven (or activated) after user confirmation or automatically by receiving a message. Meanwhile, a separate program 1330 may be running in advance to automatically drive the program 1330 after user confirmation or automatically, and the present invention is not limited thereto.

Referring to Figure 13, the program 1330 of the wireless terminal 1300 connects to a designated server 1400 through a data network to which the communication resource is accessible, and subscribes a user as a member or authenticates the user's membership. A member registration/authentication unit (not shown) to receive and a program authentication unit (not shown) for authenticating the validity of the program 1330 through at least one communication network accessible through the communication resource.

The program 1330 includes communication connection macro information for accessing the designated server 1400 through a data network to which the communication resource is accessible, and the membership registration/authentication unit registers a user through the screen output unit 1306. Outputs an interface for inputting user information (e.g., name, social security number, etc.) and a member account to be subscribed to, and transmits the user information and member account input through the interface to the designated server 1400 through the data network. Sign up the user as a member.

Meanwhile, the user's membership subscription may be subscribed through a separate user terminal other than the wireless terminal 1300. Therefore, when the user is already registered as a member or has been subscribed as a member through the user terminal, the member registration/authentication unit outputs an interface for inputting the user's member account, and a server designated through the data network ( 1400), the member account inputted through the interface is transmitted to authenticate whether the user is a member.

The program authentication unit authenticates the validity of the program 1330 to the designated server 1400 through at least one of a data network and a telephone communication network to which the communication resource is accessible. According to the implementation method of the present invention, the process of authenticating the validity of the program 1330 performs an encryption/decryption communication process agreed in advance between the program 1330 and the server 1400, and for convenience, the encryption/decryption process A detailed description of will be omitted.

According to the first program authentication method of the present invention, the program 1330 is downloaded through the program providing server in a state in which a unique key value for identifying that the program is operated by the designated server 1400 is set. In this case, In the program authentication unit, by transmitting the unique key value to the designated server 1400, it is possible to authenticate that the program 1330 is a program operated by the designated server 1400. Meanwhile, the program authentication unit transmits at least one unique information stored in the wireless terminal 1300 or allocated to a communication network together with the unique key value in the process of transmitting the unique key value to the designated server 1400, It is possible to simultaneously authenticate that the program 1330 is a program operated by the designated server 1400 and that the program 1330 is running in the wireless terminal 1300.

According to the second program authentication method of the present invention, after the program 1330 is downloaded through the program providing server, an app identification value that uniquely identifies the program 1330 on the data network according to a predetermined procedure (e.g., A device token, etc. allocated by APNS of Apple Inc.) may be allocated, and in this case, the program authentication unit transmits the app identification value to the designated server 1400, so that the program 1330 is assigned to the designated server 1400. It is possible to certify that the program is operated by Meanwhile, the program authentication unit transmits at least one unique information stored in the wireless terminal 1300 or allocated to a communication network together with the app identification value in the process of transmitting the app identification value to the designated server 1400, It is possible to simultaneously authenticate that the program 1330 is a program operated by the designated server 1400 and that the program 1330 is running in the wireless terminal 1300.

According to the third program authentication method of the present invention, in the program 1330, at least one key value, a key exchange protocol, and an encryption/decryption rule are set, and an authentication procedure for authenticating the program 1330 is defined using this. The certificate can be downloaded through the program providing server in a loaded state, and in this case, the program authentication unit includes at least one key value set in the certificate, key exchange protocol, and encryption/decryption according to the authentication procedure defined in the certificate. By selectively using a rule, it is possible to certify that the program 1330 is a program operated by the designated server 1400. Meanwhile, the program authentication unit further uses at least one unique information stored in the wireless terminal 1300 or allocated to the communication network in the process of using the certificate for the authentication procedure, so that the server 1400 to which the program 1330 is designated. It is possible to simultaneously authenticate that the program 1330 is running in the wireless terminal 1300 as well as the program operated by.

According to the fourth program authentication method of the present invention, the wireless terminal 1300 inputs the received authentication number when the authentication number sent from the designated server 1400 is received through the message exchange protocol of the telephone communication network. By receiving and transmitting it to the designated server 1400 through the data network, it is possible to authenticate that the program 1330 is a program operated by the designated server 1400. Meanwhile, the program authentication unit transmits at least one unique information stored in the wireless terminal 1300 or allocated to a communication network together with the authentication number in the process of transmitting the authentication number to the designated server 1400, the program ( It is possible to simultaneously authenticate that 1330 is a program operated by the designated server 1400 and that the program 1330 is running in the wireless terminal 1300.

According to the fifth program authentication method of the present invention, the program authentication unit checks the validity of the program 1330 from the designated server 1400 through an authentication method in which at least one of the first to fourth program authentication methods is selectively combined. It is possible to authenticate, whereby the present invention is not limited.

Referring to Figure 13 according to the first embodiment of the present invention, the program 1330 of the wireless terminal 1300 recognizes (n+1) touch points touched through the capacitive touch screen 1310. A touch point recognition unit 1335 and a touch point transmission unit 1340 that processes the recognized (n+1) touch point information to be transmitted to the server 1400 in which the touch authentication system 100 is implemented, An authentication result receiving unit 1345 for receiving a touch authentication result for the (n+1) touch points from the touch authentication system 100, and when the (n+1) touch points are authenticated, the (n+1) touch points 1) A service processing unit 1350 that processes a service corresponding to one touch point is provided.

The touch point recognition unit 1335 checks the number of touch points touched through the capacitive touch screen 1310 and checks whether a specified number of touch points is recognized. If (n+1) touch points are recognized through the capacitive touch screen 1310, the touch point recognition unit 1335 is acquired based on a device-side coordinate system corresponding to the capacitive touch screen 1310. (N+1) touch point information corresponding to the coordinate value is generated.

The touch point transmission unit 1340 processes (n+1) touch point information generated through the touch point recognition unit 1335 to be transmitted to the server 1400 in which the touch authentication system 100 is implemented. The touch point transmission unit 1340 connects a communication channel with the server 1400 on which the touch authentication system 100 is implemented, and the (n+1) touches to the server 1400 through the connected communication channel. Point information can be transmitted. Alternatively, the touch point transmission unit 1340 checks the relay server 1500 connected to the server 1400 on which the touch authentication system 100 is implemented, and the (n+1) touches with the relay server 1500 Point information may be transmitted, and the relay server 1500 relays the (n+1) touch point information to the server 1400 in which the touch authentication system 100 is implemented.

According to an exemplary method of the present invention, the touch point transmission unit 1340 checks coordinate system identification information capable of identifying a device-side coordinate system corresponding to the identified (n+1) touch point information, and/or Check device information available as the coordinate system identification information, and touch the identified coordinate system identification information (or device information) through a designated path (e.g., a directly connected communication channel or a relay channel using the relay server 1500) The authentication system 100 may be processed to be transmitted to the implemented server 1400.

According to an exemplary method of the present invention, the touch point transmission unit 1340 is the (n+1) through the location positioning unit 1324 (or the wireless network communication unit 1322, or the short-range wireless communication unit 1320, etc.). Before, during, and after the touch points are touched, the location of the wireless terminal 1300 is determined through the location information (e.g., GPS-based location information obtained from GPS, a base station (or wireless AP) connected to the wireless terminal 1300). Server in which the touch authentication system 100 is implemented through a designated path (e.g., a communication channel directly connected or a relay channel using the relay server 1500), and the identified location information is checked. It can be processed to be transmitted to (1400).

When the touch authentication system 100 generates a touch authentication result obtained by authenticating the (n+1) touch points and transmits the (n+1) touch point information in the reverse direction, the authentication result receiving unit 1345 ) Receives the touch authentication result.

If an authentication success result is included in the received touch authentication result, the service processing unit 1350 starts a designated service using the authentication success result as an authentication value. The designated service may include various services according to a designated service type to use a touch of the touch unit 200 having the (n+1) touch units 220 as an authentication value, and is not limited to a specific service. Does not.

Referring to Figure 13 according to the second embodiment of the present invention, the program 1330 of the wireless terminal 1300 is a flat portion 215 of the touch unit 200 to be touched on the capacitive touch screen 1310. An authentication condition storage unit 105 that stores touch authentication conditions to be used for authentication with respect to the n touch units 220 provided in, and (n+1) touches touched through the capacitive touch screen 1310 Between the touch point recognition unit 1335 for recognizing a point, the touch point identification unit 115 for checking the recognized (n+1) touch point information, and the identified (n+1) touch points The touch point authentication unit 120 that reads the mutual positional relationship and authenticates whether it is a valid touch point of the touch unit 200, and the flat portion 215 of the touch unit 200 to be touched on the capacitive touch screen 1310. The (n+1) touch point information is read through the information on the (n+1) touch points for n divided areas 310 in which the flat area 305 is divided into n, and the designated position of the designated area 400 ( A touch point identification unit 125 for identifying a designated touch point provided in 405, a positional relationship calculation unit 130 for calculating a geometrical touch position relationship between the identified designated touch point and each of the n touch points, and the A touch authentication processing unit 135 that matches and compares and authenticates the geometric touch position relationship between the calculated designated touch point and each of the n touch points and the touch position relationship of the touch authentication condition, and the (n+1) touch points are authenticated. In a case, a service processing unit 1350 is provided to process services corresponding to the (n+1) touch points.

The authentication condition storage unit 105, the touch point identification unit 115, the touch point authentication unit 120, the touch point identification unit 125, the location relationship calculation unit 130, and the touch authentication processing unit 135 are shown in the drawing. It operates as described in 1, and the touch point recognition unit 1335 and the service processing unit 1350 operate as in the first embodiment.

FIG. 14 is a diagram showing an embodiment in which the touch authentication system 100 is implemented in the server 1400 on the network according to an exemplary method of the present invention.

In more detail, FIG. 14 is a touch authentication system shown in FIG. 1 to a server 1400 on a network that communicates with a user's wireless terminal 1300 corresponding to a device 1300 having a capacitive touch screen 1310. It shows an embodiment in which (100) is implemented, and for those of ordinary skill in the art to which the present invention belongs, a touch authentication system ( 100) may be inferred various implementation methods (e.g., implementation methods in which some components are omitted, subdivided, or combined) with respect to the embodiment in which 100) is implemented, but the present invention includes all of the inferred implementation methods. However, the technical features are not limited only by the implementation method illustrated in FIG. 14.

Referring to FIG. 14, the server 1400 in which the touch authentication system 100 is implemented includes the configuration of the touch authentication system 100 shown in FIG. 1, and includes (n+1) touch units 220 ) And a design/manufacturing management unit 1405 that manages the design and manufacture of the touch unit 200 having a ).

The design/manufacturing management unit 1405 divides the flat area 305 of the flat panel 215 provided in the touch unit 200 into n divided areas 310, and divides n divided areas 310 into n The touch unit 220 is manufactured by calculating the position where the touch units 220 are to be provided, and the touch unit 220 of (n+1) is provided at the calculated position 410 and a predetermined position 405 do. Various information generated by the design/production management unit 1405 is used to generate a touch authentication condition by the authentication condition storage unit 105 of the touch authentication system 100.

Referring to FIG. 14, the server 1400 in which the touch authentication system 100 is implemented includes a member management unit 1410 that subscribes and manages a user of the wireless terminal 1300 as a member, and the wireless terminal 1300. (N+1) touch points from the program management unit 1415 for authenticating and managing the program 1330 provided in the device, and the program 1330 provided in the wireless terminal 1300 according to the first embodiment of the present invention. An information receiving unit 1420 receiving information, and a touch authentication result obtained by authenticating the (n+1) touch points in the touch authentication system 100 are checked and provided to the program 1330 of the wireless terminal 1300 Among the authentication result providing unit 1425 and the service providing unit 1430 processing to provide a designated service through the program 1330 of the wireless terminal 1300 when the (n+1) touch points are authenticated. , Having one or more components.

The member management unit 1410 receives and manages the user of the wireless terminal 1300 as a member by interlocking with the member registration/authentication unit provided in the program 1330 of the wireless terminal 1300, and manages the user of the wireless terminal 1300 as a member, and the program management unit 1415 Is interlocked with a program authentication unit provided in the program 1330 of the wireless terminal 1300 to authenticate and manage the program 1330 provided in the wireless terminal 1300.

The information receiving unit 1420 receives (n+1) touch point information touched through the capacitive touch screen 1310 of the wireless terminal 1300 from the program 1330 of the wireless terminal 1300 accordingly. Receive. Preferably, the information receiving unit 1420 may receive coordinate system identification information capable of identifying a device-side coordinate system corresponding to (n+1) touch point information and/or device information usable as the coordinate system identification information. . Alternatively, the information receiving unit 1420 may provide location information at a specified time before, during, and after the (n+1) touch points are touched through the capacitive touch screen 1310 (e.g., GPS-based location information obtained from GPS). , Information for confirming the location of the wireless terminal 1300 through a base station (or wireless AP) connected to the wireless terminal 1300 may be received.

The touch authentication system 100 authenticates (n+1) touch points using the information received through the information receiving unit 1420, and the authentication result providing unit 1425 is the touch authentication system 100 A touch authentication result obtained by authenticating (n+1) touch points may be checked and provided to the program 1330 of the wireless terminal 1300. Meanwhile, the service provider 1430 reads the touch authentication result at some point before, during, and after the touch authentication result is provided to the program 1330 of the wireless terminal 1300, and the touch authentication system 100 Through this, it is checked whether the (n+1) touch points are authenticated. If the (n+1) touch points are authenticated, the service provider 1430 uses the authentication result for the (n+1) touch points as an authentication value, and the program 1330 of the wireless terminal 1300 is ) To provide the designated service. The provision of the service may replace the result of the touch authentication.

FIG. 15 is a diagram illustrating an embodiment in which the touch authentication system 100 is implemented in the server 1400 on the network according to another embodiment of the present invention.

In more detail, FIG. 15 is an embodiment in which a relay server 1500 is provided between the user's wireless terminal 1300 corresponding to the device 1300 having a capacitive touch screen 1310 and the touch authentication system 100 As shown, if a person of ordinary skill in the technical field to which the present invention pertains, referring to and/or modifying this Figure 15, the touch authentication system 100 is implemented in the server 1400 on the network. Various implementation methods (eg, some components are omitted, subdivided, or combined implementation method) may be inferred, but the present invention includes all the inferred implementation methods, and is shown in FIG. 15. The technical features are not limited only by the implementation method.

Referring to Fig. 15, a relay server 1500 is provided between the user's wireless terminal 1300 and the touch authentication system 100, and the relay server 1500 is a member management unit 1410 shown in Fig. 14. , A program management unit 1415, an authentication result providing unit 1425, and a service providing unit 1430, including at least one component, and a program 1330 of the wireless terminal 1300 according to the first embodiment of the present invention. ), and an information relay unit (not shown) for relaying (n+1) touch point information received from the touch authentication system 100 to the touch authentication system 100. The information relay unit may further relay coordinate system identification information capable of identifying a device-side coordinate system corresponding to the (n+1) touch point information and/or device information usable as the coordinate system identification information. Alternatively, the information relay may further relay location information of the user's wireless terminal 1300.

100: touch authentication system 105: authentication condition storage unit
110: storage medium 115: touch point confirmation unit
120: touch point authentication unit 125: touch point identification unit
130: location relationship calculation unit 135: touch authentication processing unit

Claims (26)

In the capacitive touch authentication method executed through a system interlocking with a capacitive touch screen supporting multiple touches,
A plurality of touch units recognized by multi-touching a plurality of touch units provided in a touch unit manufactured by arranging a plurality of touch units in a unique design geometric position relationship including a pre-designed relative distance relationship and an angular relationship A first step of checking or receiving information on a touch point;
A device for reading the relationship between the plurality of touch points and identifying a designated touch point corresponding to a designated touch part fixedly disposed at a predetermined position in the design among a plurality of touch parts arranged in a unique geometric positional relationship previously designed on the touch unit. Step 2;
A third step of coordinate rotation of the plurality of touch points based on a reference point identified through the designated touch point so as to be matched with a geometric positional relationship on a designated design; And
The capacitive touch authentication method comprising: a fourth step of processing a geometrical touch positional relationship with respect to the plurality of coordinate rotated touch points to be matched and compared with a geometrical positional relationship of at least one previously registered design.
The method of claim 1, wherein the geometrical positional relationship is
At least one of a distance relationship and an angular relationship between the designated touch unit and the remaining touch units, or
A capacitive touch authentication method comprising at least one of a distance relationship and an angular relationship between a preset reference point and a plurality of touch units.
The method of claim 2, wherein the distance relationship,
The capacitive touch authentication method comprising a coordinate distance in a coordinate system corresponding to the geometric position relationship in the design.
The method of claim 2, wherein the angular relationship,
A coordinate angle in a coordinate system corresponding to the geometrical positional relationship in the design, or
A coordinate angle formed by a line segment connecting the center point of each touch unit on a coordinate system corresponding to the geometrical positional relationship in the design, or
The capacitive touch authentication method comprising a coordinate angle formed by a center point of each touch unit based on a reference line on a coordinate system corresponding to the geometrical positional relationship in the design.
The method of claim 1, wherein the first step,
And converting the coordinates of the plurality of touch points into a coordinate system corresponding to the geometrical positional relationship on the design.
The method of claim 1,
The capacitive touch authentication method, further comprising: reading a mutual positional relationship between each touch point and verifying whether it is included in a range of an effective geometrical positional relationship in a design that can be mounted on the touch unit.
The method of claim 1,
The geometrical positional relationship in the design includes a relationship of arranging a specified number of touch units in n (n≥4) divided areas,
In the second step, a relationship between the plurality of touch points is read based on the design divided area information for the n divided areas to correspond to a designated touch unit disposed in any one of the n divided areas. Capacitive touch authentication method, characterized in that identifying a designated touch point.
The method of claim 1,
The geometrical positional relationship in the design is a relationship of arranging a designated number of touch units in n (n≥4) divided areas, but disposing one designated touch unit among the plurality of touch units in any designated area among the n divided areas. Including,
In the second step, a relationship between the plurality of touch points is read based on the design divided area information for the n divided areas to correspond to a designated touch unit disposed in any one of the n divided areas. Capacitive touch authentication method, characterized in that identifying a designated touch point.
The method of claim 1,
In the geometrical positional relationship of the design, a designated number of touch units is arranged in n (n≥4) divided areas, and any one of the plurality of touch units is designated at a designated position on any one of the n divided areas. Includes the relationship to be placed,
In the second step, a designation touch unit disposed at a designated position on any one of the n divided regions by reading a relationship between the plurality of touch points based on design partition information for the n divided regions Capacitive touch authentication method, characterized in that identifying a designated touch point corresponding to the.
The method of claim 1,
When identifying the designated touch point,
And converting the coordinates of the designated touch point and the remaining touch points into a coordinate system corresponding to the geometrical positional relationship on the design.
The method of claim 1, wherein the fourth step,
The capacitive touch authentication method further comprising the step of checking the geometrical touch positional relationship among the geometrical positional relationships of one or more previously registered design geometrical positional relationships and the geometrical positional relationship close to within a specified error range.
The method of claim 1, wherein the fourth step,
The capacitive touch authentication method further comprising the step of checking the geometrical positional relationship between the geometrical touch positional relationship and the geometrical positional relationship matched within a specified error range among the geometrical positional relations of one or more previously registered designs.
The method of claim 1, wherein the fourth step,
The capacitive touch authentication method further comprising the step of checking a geometrical positional relationship closest to the geometrical touch positional relationship among one or more previously registered geometrical positional relationships on the design.

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