KR101131768B1 - Multi touch screen for high speed sampling - Google Patents

Abstract

PURPOSE: A multi-touch screen capable of high speed sampling is provided to enable a camera having low frame rate to sense quick touch by successively photographing images at high speed. CONSTITUTION: A screen(10) receives the touch of a user and displays an image. An infrared ray light source(20) is embedded on a screen. Infrared cameras(31-33) are installed from the screen and photographs the image of the screen. A control unit(40) successively operates the infrared cameras from images which are obtained from the infrared cameras.

Description

Multi touch screen for high speed sampling}

The present invention relates to a multi-touch screen capable of high speed sampling capable of accurately detecting a touch position of a screen even if a user's touch speed is high.

In general, a touch screen is a screen equipped with a special input device for detecting the position of a user's hand or an object when it touches a character or a specific position on the screen. (Resistive / Pressure sensitive), voltage (Capacitive / Electrostatic), and infrared (Infrared).

In the decompression method, a point made of plastic is located between two layers, and when a pressure is applied, an electric signal flows, and the electric signal is recognized to know a touched position. However, since the decompression method can measure only one signal at a time, multi-touch is impossible, and since it can be pressed by other than the hand, unwanted manipulation may occur.

In the voltage method, when the screen is touched using a finger or a conductor, the voltage is changed by interrupting the flow of electricity flowing on the screen, and the position of the touch is recognized by recognizing the change in the flow of electricity. However, although the voltage method can be multi-touch, the manufacturing cost is high.

In the infrared method, when a touch is made by arranging a sensor on and around a screen composed of a lattice, the sensor recognizes an infrared ray to know a touched position. However, the infrared method is expensive and may not detect even if a touch is made due to the infrared rays emitted from the surroundings.

Recently, as the demand for convenience of the user increases, the demand of the touch screen is greatly increased, and in the past, input has been recognized at a single point. It is done.

Such a technique of detecting multi-touch includes Frustrated Total Inetrnal Reflection. When total incident light enters a dense medium having a large refractive index and a small refractive index medium, when the incident angle is more than a certain angle, the boundary surface Refers to the phenomenon in which all light is reflected. Therefore, when the finger touches the screen through which infrared light flows, the light is diffusely reflected downward, and the reflected light is recognized by the infrared camera. As described above, patent technologies using frustrated total reflection include Korean Patent Publication No. 2009-0060283 and US Publication No. 2006-0227120.

However, since a conventional multi-touch device using frustrated total reflection captures light reflected shapes through a single camera, when a camera having a low shooting speed, that is, a low frame rate, is used, It is difficult to recognize the touch at a high speed, and thus there is a problem in that operation reliability and use sensitivity are lowered.

The present invention has been made to solve the above problems of the prior art, the object of the present invention is to provide a multi-touch screen capable of high-speed sampling that can accurately detect the multi-touch through frustrated total reflection even if the user touches quickly There is this.

The present invention is a screen that the user's touch is input, the image is illuminated; At least one infrared light source embedded in the screen and configured to allow infrared light to flow inside the screen by total reflection; A plurality of infrared cameras installed at a predetermined distance from the screen and configured to capture an image of the screen; And a controller configured to sequentially drive the infrared cameras at a speed faster than the frame rates of the infrared cameras, and to calculate coordinates touched from the images obtained from the infrared cameras. Provides a multi-touch screen capable of sampling.

In addition, in the present invention, the infrared light source is an infrared light emitting diode (Infra-red light emitting diode), the screen includes a front of the user's touch input, the back of the image is illuminated, the screen when the screen touch From the front of the camera is characterized in that the infrared light emitted through the back to obtain.

The control unit may assign a trigger signal to sequentially operate the infrared cameras.

The multi-touch screen capable of high-speed sampling according to the present invention configured as described above uses a low-cost camera having a slow frame rate because a plurality of cameras sequentially shoot a multi-touch image based on frustrated total reflection at a higher speed than the frame rate of the cameras. Even if the user can quickly detect the user's touch, not only increases the operation reliability but also has the advantage of increasing the use sensitivity.

1 is a diagram illustrating a configuration of a multi-touch screen capable of high speed sampling according to the present invention.
FIG. 2 is a diagram illustrating an image of a touch moment captured by an infrared camera of a multi-touch screen capable of high speed sampling according to the present invention; FIG.

Hereinafter, with reference to the accompanying drawings for the present embodiment will be described in detail. However, the scope of the inventive idea of the present embodiment may be determined from the matters disclosed by the present embodiment, and the inventive idea of the present embodiment may be implemented by adding, deleting, or modifying components to the proposed embodiment. It will be said to include variations.

1 is a diagram illustrating a configuration of a multi-touch screen capable of high speed sampling according to the present invention, and FIG. 2 is a diagram illustrating an image of a touch moment captured by an infrared camera of a multi-touch screen capable of high speed sampling according to the present invention. to be.

The multi-touch screen capable of high-speed sampling according to the present invention is based on Frustrated Total Inetrnal Reflection, as shown in FIG. 1, and is limited to that provided in a display type project input device.

In detail, the multi-touch screen capable of high speed sampling includes a screen 10, an infrared light source 20, a plurality of infrared cameras 31, 32, and 33, a control unit 40, a beam projector 50, It is configured to include a computer 60.

The screen 10 includes an acrylic plate 11 having a user's touch on the front surface thereof, and a film-shaped projection paper 12 attached to the rear surface of the acrylic plate 11. At this time, the acrylic plate 11 is formed of an acrylic material to enter the infrared light, but may be used as other suitable materials, general glass is not preferably applied because of low light transmittance. Of course, a glass product such as a general monitor or panel may be provided between the acrylic plate 11 and the projection paper 12, and a screen composed of the acrylic plate 11 and the projection paper 12 may be placed on the general glass product. Can be mounted. In this case, the screen 10 is configured to display an image projected from the beam project 50.

The infrared light source 20 allows infrared light to flow inside the acrylic plate 11 while total reflection occurs, and the frame 21 mounted around the acrylic plate 11 and the frame 21 are mutually different. It consists of a plurality of infrared light emitting diodes (Infra-red light emitting diodes) 22 installed side by side in the opposite direction. Of course, as the infrared light emitting diodes 22 are used, there are cost reduction effects including energy saving.

 The cameras 31, 32, and 33 are installed perpendicularly to the back of the screen 10 at regular intervals in the rear direction of the screen 10. The screen 10 is installed to photograph the entire back. Preferably, the cameras 31, 32, and 33 may use a relatively inexpensive webcam or a similar camera, and may have a low shooting speed, that is, a low frame rate. However, the cameras 31, 32, 33 should be set or set to be controlled by the controller 40.

The controller 40 generates a trigger signal and assigns the trigger signal to the cameras 31, 32, and 33, and sequentially sequentially moves the cameras 31, 32, and 33 according to the signal at a higher speed than the frame rate. To shoot with the camera. At this time, the trigger signal is a signal that gives the start of the operation to the circuit built in the cameras (31, 32, 33), most of the waveform of the pulse state. Of course, the cameras 31, 32, and 33 may be controlled by software included in themselves, but in the present invention, the control unit 40 assigns and controls a trigger signal to the cameras 31, 32, and 33. It is limited to that. In addition, the controller 40 receives images captured by the cameras 31, 32, and 33, and then transfers the images to the computer 60.

The beam projector 50 is installed on the rear surface of the screen 10 to project an image onto the screen 10, and the computer 60 outputs an image signal to the beam projector 50. Is connected to the beam projector 50 so as to. That is, when an image signal is transmitted from the computer 60 to the beam projector 50, the beam projector 50 projects the image on the screen 10. In addition, the computer 50 detects coordinates touched on the screen 10 through the captured image received from the controller 40, and operates to function as the detected touch coordinates. Of course, the computer 60 may be configured to include the functions of the controller 40.

Looking at the operation of the multi-touch screen capable of high-speed sampling configured as described above, as follows.

First, the infrared light emitting diodes 22 emit infrared light, and infrared light enters the acrylic plate 11, and then total internal reflection occurs. Normally, light is refracted depending on the angle of incidence when it encounters a low refractive index medium, but when the angle of incidence is above a certain angle (critical angle), the total reflection of light at its interface is called total reflection.

In addition, the beam projector 50 converts an image signal sent from the computer 60 and then illuminates the image on the screen 10. In this case, the user may touch a desired position in the image reflected on the screen 10, and may simultaneously touch several positions or at a high speed.

Therefore, when the acrylic plate 11 is touched by a user's hand or a tool, the phenomenon that the infrared light is totally reflected inside the acrylic plate 11 is frustrated. Accordingly, the acrylic plate 11 penetrates the acrylic plate 11 and is mostly straight. Are dispersed in the direction. In this case, the controller 40 repeats a process of sequentially photographing the back surface of the acrylic plate 11 by allocating a trigger signal to the cameras 31, 32, and 33.

For example, if the frame rate of the cameras 31, 32, 33 is 30 ms, the controller 40 allocates a trigger signal to sequentially photograph the three cameras 31, 32, 33 at 10 ms intervals. Of course, one camera captures images at 30ms intervals, so you cannot detect your touch between 30ms intervals, but three cameras 31, 32, and 33 capture images at 10ms intervals. The shooting time interval can be shortened to more accurately detect the user's touch.

As described above, the image photographing the rear surface of the screen 10 is transferred to the computer 60, and when such an image is determined to have a user's touch as shown in FIG. 2, the coordinates on the screen 11 are displayed. Will be calculated and the function will be activated at the corresponding coordinates.

10 screen 11: acrylic
12: projection 20: infrared light source
21: light source frame 22: infrared light emitting diode
31, 32, 33: camera 40: control unit
50: beam projector 60: computer

Claims (3)

A screen on which a user's touch is input and an image is displayed;
At least one infrared light source embedded in the screen and configured to allow infrared light to flow inside the screen by total reflection;
A plurality of infrared cameras installed at a predetermined distance from the screen and configured to capture an image of the screen; And,
And a controller configured to sequentially drive the infrared cameras at a speed faster than the frame rates of the infrared cameras, and calculate touched coordinates from the images obtained from the infrared cameras. 2 multi-touch screens available.
The method of claim 1,
The infrared light source is an infrared light emitting diode,
The screen includes a front surface on which a user's touch is input and a rear surface on which an image is illuminated.
And the cameras acquire infrared light from the front of the screen through the back when the screen is touched.
The method according to claim 1 or 2,
The control unit assigns a trigger signal to sequentially operate the infrared cameras.

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