KR20120094455A - Virtual touch apparatus and method without pointer on the screen - Google Patents

Abstract

PURPOSE: A virtual touch apparatus and method thereof are provided to enable a user to rapidly control electronic apparatuses without using a pointer in a display unit. CONSTITUTION: A three dimensional coordinate calculation apparatus(10) extracts the three dimensional coordinate data of a user body. A touch position calculation unit(21) calculates tangent coordinate data using a first and a second space coordinate received from the three dimensional coordinate calculation apparatus A virtual touch processing unit(22) inputs a command code to the main control unit of an electronic apparatus by creating the command code corresponding to the tangent coordinate data.

Description

Virtual touch apparatus and method without pointer on the screen}

The present invention relates to an apparatus and method for remotely manipulating an electronic device, and to a virtual touch device and a method for accurately controlling an electronic device remotely without displaying a pointer on an electronic device display display surface.

Recently, electronic devices having a touch panel such as a smart phone have been used a lot. This touch panel technology does not need to display a 'pointer' on the display when compared to an electronic device such as a computer that can be operated with an existing mouse. The user moves the finger over the icon and performs the operation by touching it without moving the pointer (the cursor of the computer) to the corresponding position (e.g., the program icon) in order to operate the electronic device. In this touch panel technology, it is unnecessary to move the 'pointer' necessary for the conventional electronic device control means, thereby enabling quick operation of the electronic device.

However, the touch panel technology has a disadvantage in that it can not be used remotely because the user has to directly touch the display surface in spite of the above convenience. Therefore, even an electronic device employing a touch panel technology can not but rely on a device such as a conventional remote control for remote operation.

Recently, as a remote electronic control device, a device capable of generating a pointer at an accurate point, such as touch panel technology, that is, a straight line of the user's eyes and fingers is displayed from the captured image after photographing the front of the display using two cameras. Although a technique for generating a pointer at the point of meeting is disclosed in the published patent application [Document 1], a 'pointer' must be generated as a preliminary measure for controlling an electronic device (with a pointer control unit). It is very inconvenient in performing an operation by comparing a user's gesture with a previously stored pattern for a specific operation control.

Document 1 Publication 2010-0129629 December 9, 2010

The present invention is to provide a convenient user interface, such as touching the surface of the touch panel even when the user remotely operates the electronic device. To this end, the present invention provides a method capable of operating an electronic device without using a pointer on the display surface of the electronic device, and precisely selecting an area such as precisely touching a specific part of the touch panel.

According to one aspect of the present invention, there is provided a virtual touch device comprising: a device for remotely controlling an electronic device including a display having a display surface, the three-dimensional coordinate calculating device configured to calculate three-dimensional coordinate data of a user's body; And a touch position that calculates contact coordinate data where a straight line connecting the first spatial coordinates and the second spatial coordinates meets the display surface by using the first spatial coordinates and the second spatial coordinates received from the 3D coordinate calculator. And a controller including a virtual touch processor configured to generate a command code for performing an operation set to correspond to the contact coordinate data received from the touch position calculator, and input the command code to a main controller of the electronic device.

In an embodiment of the present invention, the three-dimensional coordinate calculation apparatus may calculate the three-dimensional coordinate data of the user's body using a time of flight measurement (Time of Flight).

In an embodiment of the present invention, the first spatial coordinate is a three-dimensional coordinate of any one of the end of one of the user's fingers, the end of the pointer held by the user with the finger, and the second spatial coordinate is the It may be formed of three-dimensional coordinates of the center point of either eye of the user.

In another embodiment of the present invention, the first spatial coordinates are three-dimensional coordinates of two or more fingertips of the user's fingers, and the second spatial coordinates are formed as three-dimensional coordinates of a center point of one eye of the user. Can be.

In another embodiment of the present invention, the first spatial coordinates are three-dimensional coordinates of the tips of one or more fingers respectively presented by two or more users, and the second spatial coordinates are the one eye of the two or more users. It may be formed of three-dimensional coordinates of the center point of.

In an embodiment of the present invention, the virtual touch processing unit determines whether there is a change in the contact coordinate data for a set time or more from a time at which initial contact coordinate data is calculated, and if there is no change in the contact coordinate data for a set time or more, the contact coordinate data. A command code for performing an operation set to correspond to the control unit may be generated and input to the main controller of the electronic device.

In another embodiment of the present invention, the virtual touch processing unit determines whether there is a change in the contact coordinate data for a set time or more from a time at which initial contact coordinate data is calculated, and if there is no change in the contact coordinate data for a set time or more, the first touch point. When the distance change over the set distance occurs by determining whether there is a distance change over the set distance between the spatial coordinates and the second spatial coordinates, a command code for performing a set operation corresponding to the contact coordinate data is generated to generate the main code of the electronic device. It may be configured to input to the control unit.

In a preferred embodiment of the present invention, if it is determined that the variation of the contact coordinate data is within a range of a setting area of the display, it may be regarded that there is no variation of the contact coordinate data.

The virtual touch device and method according to the present invention have the following effects.

The virtual touch device and method according to the present invention enable fast manipulation of electronic devices by not using a pointer in a display. Therefore, the present invention proposes an apparatus and method that can apply the advantages of the above-described touch panel to the field of electronic device remote control. In general, an electronic device such as a computer or a digital TV can be manipulated by creating a pointer in a corresponding area using a control method and then performing a specific additional operation. In addition, until now, numerous technologies such as how to set the position of the display pointer at high speed, how to select the speed of the pointer on the display, how to use one or more pointers, and how to control the pointer by the remote control, etc. It has been developed with limited to technology.

In addition, the user may precisely point a specific area of the display surface of the electronic device.

In the present invention, in order to precisely point the display surface of the electronic device, the principle that 'only the fingertip and one eye can be used to accurately point the position of the object' is adopted. show). By employing such a method in the present invention, the user can point at a menu on the screen in detail as if using a touch panel remotely.

1 is a block diagram of a virtual touch device according to a preferred embodiment of the present invention.
In FIG. 2A the user selects a screen menu displayed on the display.
In FIG. 2B, the electronic device display submenu is displayed.
In FIG. 2C the user selects a submenu displayed on the display.
In FIG. 3A, a user maintains a first spatial coordinate and a second spatial coordinate for a predetermined time.
In FIG. 3B, the user moves the fingertip in the initial contact coordinate direction.
In FIG. 3C, the user moves the fingertip in the direction of the second spatial coordinate.
In FIG. 4, a user performs a touch operation using two fingertips.
In FIG. 5, two users each use a fingertip to perform a touch operation.
6 is a flowchart illustrating a virtual touch method according to the present invention.

Other objects, features and advantages of the present invention will become apparent from the detailed description of the embodiments with reference to the accompanying drawings.

A preferred embodiment of a virtual touch device that does not use a pointer according to the present invention will be described with reference to the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but can be implemented in various different forms, only the embodiments to complete the disclosure of the present invention and complete the scope of the invention to those skilled in the art. It is provided to inform you. Therefore, the embodiments described in the present specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and are not intended to represent all of the technical ideas of the present invention. Therefore, various equivalents There may be water and variations.

1 is a block diagram showing a virtual touch device according to an embodiment of the present invention.

Referring to FIG. 1, the virtual touch device 1 includes a 3D coordinate calculating apparatus 10 and a controller 20 for extracting 3D coordinate data of a user's body.

The three-dimensional coordinate calculation apparatus 10 may calculate three-dimensional coordinates of the user's body by using various three-dimensional coordinate extraction methods known in the art. Representative methods of such three-dimensional coordinate extraction can be divided into optical triangulation method and time delay measurement method. The active three-dimensional information acquisition technique using structured light, which is one of the optical triangulation techniques, projects a pattern image coded continuously using a projector and acquires an image of a scene where the structure light is projected through a camera, This is a method of estimating the position.

In addition, the time delay measurement method is a technique of obtaining 3D information by converting the time difference between the ultrasonic wave generated from the transmitter and the receiver to the receiver by dividing the time of flight by the traveling speed of the ultrasonic wave. In addition, various methods of calculating three-dimensional coordinates using a time of flight measurement method exist in the past, and a description thereof will be omitted since it can be easily implemented by those skilled in the art.

In addition, the three-dimensional coordinate calculation apparatus 10 according to the present invention may be configured to include an illumination assembly 11, the image acquisition unit 12 and the spatial coordinate calculation unit (13). The lighting assembly 12 includes a light source 111 and a diffuser 112 to project the speckle pattern onto the user's body. The image acquisition unit 12 includes an image sensor 121 and a lens 122 to capture a speckle pattern on the user projected by the lighting assembly. In general, the image sensor 121 may be a CCD or CMOS based image sensor. In addition, the spatial coordinate calculator 13 calculates the 3D coordinate data of the user's body by processing the image obtained by the image acquisition unit 12.

The controller 20 includes a touch position calculator 21 and a virtual touch calculator 22.

The touch position calculator 21 may include a straight line connecting the first spatial coordinates and the second spatial coordinates using the first spatial coordinates and the second spatial coordinates received from the 3D coordinate calculator 10. It calculates contact point coordinate data.

In general, a finger is the only part of a person's body that allows for sophisticated and delicate manipulations. In particular, when using either one of the thumb or index finger among the fingers, or when using two fingers together, precise pointing can be performed. Therefore, it is very effective to use the tip of the thumb and / or index finger as the first spatial coordinates in the present invention.

In addition, in the same context, instead of the tip of the finger serving as the first spatial coordinate, a pointed tip (eg, a pen tip) held by the finger may be used. The use of such a pointer has the advantage that the portion covering the display from the user's field of view is smaller than the tip of the finger, and the pointed end of the pointer can accurately point even the smallest portion of the display.

In addition, the present invention uses only the center point of one eye of the user. For example, if a user places an index finger in front of both eyes and looks at the index finger, the index finger will appear as two. This phenomenon occurs because the shape of the index finger viewed by both eyes of the user is different (due to the angle difference between the eyes). However, if you look at your index finger with only one eye, your index finger will be clearly visible. Also, even if you do not sense one eye, your index finger will be clearly visible even if you are consciously looking at one eye. It is the same principle to close and close one eye for sports events that require a high degree of accuracy in aiming, such as shooting and archery.

The present invention adopts the principle that the shape of the fingertip can be clearly recognized when looking at the fingertip (first spatial coordinate) with only one eye. In this way, the user must be able to see the first spatial coordinates accurately to point to a specific area of the display that matches the first spatial coordinates.

In the present invention, when the user of 1 uses any one of the fingers, the first spatial coordinate is a three-dimensional coordinate of any one of the end of the finger of the user's finger, the end of the pointer held by the user with the finger, The second spatial coordinate will be the three-dimensional coordinates of the center point of either eye of the user.

In addition, when a single user uses two or more of the fingers, the first spatial coordinates are three-dimensional coordinates of the ends of one or more fingers respectively presented by the two or more users, and the second spatial coordinates are the two. It may be formed of three-dimensional coordinates of the center point of either eye of the user.

In addition, when used by two or more users, the first spatial coordinates are three-dimensional coordinates of the tips of one or more fingers respectively presented by two or more users, and the second spatial coordinates are the one eye of the two or more users. It may be formed of three-dimensional coordinates of the center point of.

In the present invention, the virtual touch processing unit 22 determines whether there is a change in the contact coordinate data for a set time or more from a time at which initial contact coordinate data is calculated, and if there is no change in the contact coordinate data for a set time or more, the contact coordinate data. It may be configured to generate a command code for performing the operation set to correspond to the input to the main control unit 31 of the electronic device. The virtual touch processing unit 22 can be processed in a similar manner by two fingers of one user or two or more users.

Further, in the present invention, the virtual touch processing unit 22 determines whether there is a change in the contact coordinate data for a set time or more from a time at which initial contact coordinate data is calculated, and if there is no change in the contact coordinate data for a set time or more, the first touch point. When the distance change over the set distance occurs by determining whether there is a distance change over the set distance between the spatial coordinates and the second spatial coordinates, a command code for performing the operation set to correspond to the contact coordinate data is generated to generate the main code of the electronic device. It may be configured to input to the control unit 31. The virtual touch processing unit 22 can be processed in a similar manner by two fingers of one user or two or more users.

On the other hand, if it is determined that the variation of the contact coordinate data is within the range of the setting area of the display 30, the contact coordinate data may be formed to be regarded as no change in the contact coordinate data. That is, when the user points the display to the tip of the finger or the tip of the pointer, it is very difficult for the user to keep the contact coordinates as the body or finger naturally has some movement or tremor. Therefore, when the contact coordinate data value is within the range of the setting area of the display, it is assumed that there is no change in the contact coordinate data, and a command code for performing the set operation may be generated and input to the main controller 31 of the electronic device. .

Digital TVs are representative of electronic devices that are subject to remote control according to the present invention. In general, a digital television receiver includes a broadcast signal receiver, an image signal processor, a system controller, and the like, but these components are extremely obvious to those skilled in the art, and thus detailed descriptions thereof will be omitted. Other electronic devices that are subject to remote control according to the present invention include home appliances such as lighting appliances, gas appliances, heating appliances, and method appliances, and various electronic appliances may also be remotely controlled by the present invention. Can be.

The virtual touch device 1 according to the present invention may be inserted and installed on the top of an electronic device frame to be remotely controlled, or may be installed separately from the electronic device.

2A is a diagram in which a user selects a specific icon on the electronic device display 30 according to an embodiment of the present invention. The user selects the 'music' icon on the display 30 while looking at the fingertip with one eye. The three-dimensional coordinate calculation apparatus 10 generates three-dimensional spatial coordinates of the user's body, and the touch position calculator 21 of the controller 20 controls the three-dimensional coordinate data (X1, Y1, Z1) and one eye of the fingertip. The three-dimensional coordinate data (X2, Y2, Z2) of the center point of is processed to calculate the contact coordinates (X, Y, Z) with the display display surface. Thereafter, the virtual touch processor 22 generates a command code for performing an operation set to correspond to the contact coordinate data X, Y, and Z, and inputs the command code to the main controller 31 of the electronic device. The main controller 31 controls the display 30 to display a result of performing the command code. In FIG. 2A, a 'music' icon menu is selected.

FIG. 2B illustrates a screen in which a user displays a sub-menu for a song song name that appears after the user selects the 'music' icon menu in FIG. 2A. 2C is a screen in which a user selects a specific song from a music sub menu.

3A to 3C, the touch position calculator 21 of the controller 20 includes three-dimensional coordinate data (X1, Y1, Z1) of the fingertip and three-dimensional coordinate data (X2, Y2, Z2) of the center point of one eye. The main control unit 31 of the electronic device generates a command code for performing an operation that is set to correspond to the contact coordinates (X, Y, Z) with the display display surface only when a certain condition (change in Z coordinate value) is met. Shows how to type.

3A illustrates that the touch position calculator 21 determines whether there is a change in the contact coordinate data for a set time or more from a time at which initial contact coordinate data is calculated, and thus the contact coordinate only when there is no change in the contact coordinate data for a set time or more. A command code for performing an operation set to correspond to data is generated and input to the main controller 31 of the electronic device.

In FIGS. 3B and 3C, the virtual touch processor 22 determines whether there is a change in the contact coordinate data for a set time or more from a time at which initial contact coordinate data is calculated, and thus changes in the contact coordinate data for a set time or more (X and Y coordinates). Value), it is determined whether there is a change in distance greater than or equal to the set distance between the first spatial coordinate and the second spatial coordinate, and when a distance change (change in Z coordinate value) greater than or equal to the set distance occurs, A command code for performing an operation is generated and input to the main controller 31 of the electronic device. 3B illustrates a case where the distance between the first spatial coordinates and the second spatial coordinates is far from each other, and FIG. 3C illustrates a case where the distance between the first spatial coordinates and the second spatial coordinates approaches each other.

Fig. 4 shows a case where one user has two contact coordinates, (Xa, Ya, Za) and (Xb, Yb, Zb) on an electronic device display display surface using two fingertips. An example in which the user controls the operation of the electronic device while having two contact coordinates on the display surface will be common in games. It will also be very useful when the user manipulates (move, rotate, zoom, zoom, etc.) the image on the display screen when using two fingertips.

Fig. 5 shows a case where two users each have two contact coordinates, (Xa, Ya, Za) and (Xb, Yb, Zb) on an electronic device display display surface using one fingertip. An example in which two users have two contact coordinates on a display surface and controls electronic device operation, respectively, will be common in games.

6 is a flowchart illustrating a virtual touch method according to an embodiment of the present invention.

As shown, the illumination assembly 11 projects the speckle pattern to the user (S510).

The image acquisition unit 12 captures the speckle pattern on the user projected by the lighting assembly 11 (S520).

The spatial coordinate calculation unit 13 processes the image of the speckle pattern to calculate the three-dimensional spatial coordinates of the user's body (S530).

The first touch position calculating unit 21 is a three-dimensional coordinates of any one of the end of the finger of the user finger received from the three-dimensional coordinate calculation device 10, the end of the pointer held by the user finger Contact coordinate data where a straight line connecting the first spatial coordinates and the second spatial coordinates meets the display surface is calculated using the spatial coordinates and the second spatial coordinates of the center point of one eye of the user (S540). ),

The virtual touch processor 22 generates a command code for performing an operation set to correspond to the contact coordinate data received from the touch position calculator 21, and inputs the command code to the main controller 31 of the electronic device (S550). .

In another embodiment of the present invention, in step S550, the virtual touch processor 22 determines whether there is a change in the contact coordinate data more than a preset time from the time at which the initial contact coordinate data is calculated, and thus, the time of the contact coordinate data for more than a preset time. If there is no change, a command code for performing an operation set to correspond to the contact coordinate data may be generated and input to the main controller 31 of the electronic device.

In another embodiment of the present invention, in step S550, the virtual touch processing unit 22 determines whether there is a change in the contact coordinate data for a set time or more from a time at which initial contact coordinate data is calculated, and then the contact coordinate data for a set time or more. If there is no change, the command code for determining whether there is a distance change of more than a set distance between the first spatial coordinates and the second space coordinates, and if a distance change of more than a set distance occurs, the command code for performing the operation set to correspond to the contact coordinate data May be generated and input to the main controller 31 of the electronic device.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It will be apparent to those skilled in the art that various modifications may be made without departing from the scope of the present invention. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

10 3-D coordinate calculation device 20 Control unit
30 Display

Claims (16)

An apparatus for remotely controlling a display without displaying a pointer on said display surface of an electronic device comprising a display having a display surface, said apparatus comprising:
A three-dimensional coordinate calculator for extracting three-dimensional coordinate data of the user's body; And
Calculating touch position that calculates contact coordinate data where a straight line connecting the first spatial coordinates and the second spatial coordinates meets the display surface by using the first spatial coordinates and the second spatial coordinates received from the 3D coordinate calculating apparatus. And a controller including a virtual touch processor configured to generate a command code for performing an operation set to correspond to the contact coordinate data received from the touch position calculator, and input the command code to a main controller of the electronic device. Virtual touch device. The method of claim 1,
The three-dimensional coordinate calculation device is configured to obtain the three-dimensional coordinate data by using a time of flight measurement (Time of Flight). The method according to claim 1 or 2,
The first spatial coordinate is a three-dimensional coordinate of any one of the end of one finger of the user finger, the end of the pointer held by the user with the finger, and the second spatial coordinate is the center point of one eye of the user. Virtual touch device, characterized in that formed in three-dimensional coordinates. The method of claim 3, wherein
The virtual touch processor determines whether there is a change in the contact coordinate data for a predetermined time or more from a time at which initial contact coordinate data is calculated, and performs a set operation to correspond to the contact coordinate data if there is no change in the contact coordinate data for a preset time. The virtual touch device, characterized in that for generating a command code to be input to the main control unit of the electronic device. The method of claim 3, wherein
The virtual touch processor determines whether there is a change in the contact coordinate data for a predetermined time or more from a time at which initial contact coordinate data is calculated, and if there is no change in the contact coordinate data for a preset time, between the first spatial coordinate and the second spatial coordinate. When the distance change is greater than or equal to the set distance is determined to determine whether there is a change in the distance or more than the set distance to generate a command code for performing the operation set to correspond to the contact coordinate data is formed to be input to the main control unit of the electronic device Virtual touch device. The method of claim 4, wherein
And if it is determined that the variation of the contact coordinate data is within a range of a setting area of the display, the virtual touch device is configured to consider that the variation of the contact coordinate data is free. The method according to claim 1 or 2,
And the first spatial coordinates are three-dimensional coordinates of two or more fingertips of the user's fingers, and the second spatial coordinates are formed in three-dimensional coordinates of a center point of one eye of the user. The method of claim 7, wherein
The virtual touch processing unit connects the two or more first spatial coordinates and the second spatial coordinates by using the two or more first spatial coordinates and the second spatial coordinates received from the 3D coordinate calculator. The electronic device generates a touch position calculator for calculating two or more pieces of contact coordinate data where a straight line meets the display surface, and generates a command code for performing an operation set to correspond to the contact coordinate data received from the touch position calculator. The virtual touch device, characterized in that the input to the main control unit of the device. The method of claim 8,
The virtual touch processor determines whether there is a change in the contact coordinate data for a predetermined time or more from a time at which initial contact coordinate data is calculated. The virtual touch device, characterized in that it is generated to generate a command code to perform the input to the main control unit of the electronic device. The method of claim 8,
The virtual touch processor determines whether there is a change in the contact coordinate data for a set time or more from a time at which initial contact coordinate data is calculated, and if there is no change in the contact coordinate data for a set time or more, the first spatial coordinates and the second space. It is determined to generate a command code for performing a set operation corresponding to the contact coordinate data when the distance change over the set distance occurs by determining whether there is a distance change over the set distance between the coordinates and input the input to the main control unit of the electronic device. Virtual touch device, characterized in that. The method of claim 9,
And if it is determined that the variation of the contact coordinate data is within a range of a setting area of the display, the virtual touch device is configured to consider that there is no variation of the contact coordinate data. The method according to claim 1 or 2,
The first spatial coordinates are three-dimensional coordinates of the end of one or more fingers respectively presented by two or more users, and the second spatial coordinates are formed of three-dimensional coordinates of the center point of one eye of the two or more users. Virtual touch device, characterized in that. 13. The method of claim 12,
The virtual touch processor may include one or more first spatial coordinates received for each user and one or more first spatial coordinates received by the user from the three-dimensional coordinate calculator and the one or more second spatial coordinates. A touch position calculating unit for calculating two or more contact coordinate data meeting the display surface with a straight line connecting one second spatial coordinate, and corresponding contact point data received from the touch position calculating unit for each user; And generating a command code to perform a set operation and inputting the command code to a main controller of the electronic device. The method of claim 13,
The virtual touch processor determines whether there is a change in the contact coordinate data for a predetermined time or more from a time at which initial contact coordinate data is calculated for each user, and if there is no change in the contact coordinate data for a preset time, the contact coordinate data for each user. And generating a command code for performing an operation set to correspond to the electronic device and inputting the command code to the main controller of the electronic device. The method of claim 13,
The virtual touch processor determines whether there is a change in the contact coordinate data for a predetermined time or more from a time at which initial contact coordinate data is calculated for each user, and if there is no change in the contact coordinate data for a set time or more, the first space for each user. If the distance change is greater than or equal to the set distance between the coordinates and the second spatial coordinates is determined, and if a distance change is greater than or equal to the set distance, a command code for performing a set operation corresponding to the contact coordinate data is generated for each user. The virtual touch device, characterized in that the input to the main control unit of the electronic device. 15. The method of claim 14,
And if it is determined that the variation of the contact coordinate data is within a range of a setting area of the display, the virtual touch device is configured to consider that there is no variation of the contact coordinate data.

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