KR20110053165A - Apparatus for multi touch and proximated object sensing using sensing array - Google Patents

Abstract

PURPOSE: A multi touch and object sensing apparatus which uses a sensing array is provided to reduce the thickness of the apparatus and to arrange a sensing array in the lower part of the diffuse plate. CONSTITUTION: A diffusing plate(420) projects invisible light. A visible light source(430) locates in the lower part of the diffusing plate and radiates the visible light is radiated to the diffusing plate. A sensing array(470) is located in the lower part of the diffuse plate and senses the non-visible light. An invisible light source(451) is located in the upper part of the diffuse plate and radiates the invisible light which senses a touch or target image. The touch or the target image is generated to the object.

Description

Multi-touch and proximity object sensing device using sensing array {APPARATUS FOR MULTI TOUCH AND PROXIMATED OBJECT SENSING USING SENSING ARRAY}

The present invention relates to a multi-touch sensing device capable of sensing a touch image or a target image using a sensing array.

Recently, with the development of display technology, the interest of technology for identifying the position of an object touching the display is increasing. In implementing a display that responds to a touch or a sketch, when a touch sensor is coupled to an existing LCD display attached to a backlight unit that provides flat white light, non-uniformity of plane light may occur.

In the related art, a structure has been proposed in which a diffuser plate is removed and an IR sensor is sensed to sense an object located on an LCD display. In this structure, the path of the IP light source can be secured, but there is a problem that the quality of the image output from the LCD display is deteriorated and the touch sensor existing at the bottom of the LCD display is exposed.

Accordingly, there is a need for a touch and proximity object sensing device capable of variously modifying a position of a light source for detecting a touch of an object and a shape of an object while outputting a high quality image. In addition, since a display panel that can be touched by a user is used in a portable device, a structure capable of reducing the thickness of the touch sensing device is also required.

The sensing device includes a diffuser plate in which invisible light is projected, a visible light source positioned above the diffuser plate, and positioned below the diffuser plate to emit visible light to the diffuser plate, and positioned below the diffuser plate, and projected by the diffuser plate. It may include a sensing array for sensing.

The display apparatus may further include an invisible light source disposed on the diffuser plate and emitting the invisible light for sensing the touch image or the target image generated by the object.

The light guide may further include a light guide positioned on the diffuser plate and totally reflecting the invisible light emitted from the invisible light source. In this case, the invisible light source may emit invisible light in the light guide or in the object. Here, the object may be located at a predetermined distance from the upper portion of the light guide or the upper portion of the light guide. Then, the sensing array may sense invisible light reflected by the object.

In addition, the sensing array may sense a position at which total reflection is disturbed by the object when the invisible light emitted from the invisible light source is totally reflected inside the light guide.

In addition, the invisible light source may emit invisible light for sensing the touch image to the diffuser while being spaced apart from the diffuser by a predetermined distance. In this case, the invisible light source may emit invisible light perpendicular to the diffuser plate or at a predetermined angle with the diffuser plate.

In addition, the visible light source is located below the perpendicular to the diffuser plate, it can emit visible light directly to the diffuser plate.

In addition, the visible light source is located at the lower edge with respect to the diffuser plate, can reflect the visible light through the wave guide to emit visible light to the diffuser plate.

The sensing device may include a diffuser plate on which invisible light is projected, and a sensing array positioned under the diffuser plate to sense invisible light projected by the diffuser plate.

The display apparatus may further include an invisible light source positioned above the diffuser plate and emitting the invisible light for sensing a touch image or a target image generated by an object.

In addition, the invisible light source may emit invisible light perpendicular to the diffuser plate or at a predetermined angle with the diffuser plate.

The sensing device may include organic light emitting diodes (OLEDs) for emitting visible light, and a sensing array positioned under the OLED panel provided with the OLEDs and sensing invisible light projected onto the OLED panel.

The thickness of the multi-touch sensing device can be reduced by disposing a visible light source and a sensing array under the diffuser to display an image and sense a touch image.

In addition, since the sensing array is disposed under the diffuser plate, the visible light source is not affected by the sensing array, thereby improving image quality.

In addition, the touch image may be sensed only by a specific number of sensing arrays disposed under the diffusion plate, thereby reducing the cost of the multi-touch sensing device.

1 is a diagram illustrating a sensing device using a multi-touch multi-touch and a proximity object having an invisible light source disposed at an edge thereof.
2 and 3 are views illustrating a multi-touch sensing device in which invisible light sources are spaced apart from each other.
FIG. 4 is a diagram illustrating a configuration of a sensing device using a multi-touch and a proximity object using a wave guide.
5 and 6 are views illustrating the configuration of a multi-touch sensing device using wave guides.
7 and 8 illustrate a configuration of a sensing device using a multi-touch and a proximity object using a plurality of invisible light sources.
FIG. 9 is a diagram illustrating a configuration of a multi-touch sensing device using invisible light around an object.

Hereinafter, with reference to the contents described in the accompanying drawings will be described in detail an embodiment according to the present invention. However, the present invention is not limited to or limited by the embodiments. Like reference numerals in the drawings denote like elements.

1 is a diagram illustrating a sensing device using a multi-touch and proximity object in which an invisible light source is disposed at an edge.

Referring to FIG. 1, the sensing device 100 using the multi-touch and proximity objects includes a display panel 110, a diffuser plate 120, a visible light source 130, an invisible light source 140, and a light guide 150. , And the sensing array 160.

The display panel 110 is disposed on the top of the multi-touch sensing device 100 to display an image. In this case, the display panel may be an LCD panel.

The diffuser 120 is disposed under the display panel to diffuse, spread out, and scatter visible light incident from the visible light source 130 to emit visible light in a planar form. In this case, the diffuser 120 may receive visible light or invisible light emitted from the visible light source 130 or the invisible light source 140.

In addition, the diffuser plate 120 may emit visible light incident from the visible light source 130 in a planar shape. In this case, a pattern may be formed in the diffusion plate 120 to remove hot spots while maintaining uniformity of incident light. Here, the hot spot may be generated by concentrating visible light on a specific portion of the diffusion plate 120 due to the visible light source 130 representing the point light source or the linear light source.

   The visible light source 130 is disposed below and perpendicular to the diffuser plate 120 to emit visible light. That is, the visible light source 130 may be disposed in a direct type with respect to the diffusion plate 120. In this case, the visible light source 130 may directly emit visible light for displaying an image on the display panel 110 to the diffuser plate 120. As a result, in FIG. 1, the backlight unit is removed from the display panel 110, and the diffuser plate 120 and the visible light source 130 may perform the functions of the backlight unit. By removing the backlight unit, the thickness of the multi-touch sensing device 100 may be reduced.

For example, the visible light source 130 may be in the form of a linear light source (CCFL), a point light source (LED). The visible light emitted from the visible light source 130 may be changed into light having a planar shape through the diffuser plate 120.

The invisible light source 140 may be disposed on the diffusion plate 120 to emit invisible light for sensing a touch image or a target image generated by the object. In this case, the object may be positioned at a predetermined distance from the upper portion of the light guide 150 or the upper portion of the light guide.

For example, as shown in FIG. 1, the invisible light source 140 may emit invisible light to an object 800 located in proximity to the upper portion of the light guide. Invisible light can also be infrared (IR) or ultraviolet (UV) light.

More specifically, when the object 200 is located on the upper surface of the light guide 150, the invisible light source 140 is the display panel 110 by the object 200 located on the upper surface of the display panel 110 Invisible light for sensing the touch image or the target image displayed on the rear surface may be emitted. Here, the target image may be an image corresponding to the position of the reflected light having an object shape by being reflected by an object near the top of the light guide 150 among the images displayed on the rear surface of the display panel 110.

In this case, the invisible light source 140 is located at a position for emitting light to the inside of the light guide 150 located on the upper surface of the display panel 110 and to the object 800 spaced a predetermined distance from the top of the light guide 150. Can be deployed. For example, the invisible light source 140 may be disposed at an edge of the upper portion of the display panel 110.

The light guide 150 totally reflects invisible light emitted from the invisible light source 140 (TIR). For example, the light guide 150 may be made of a transparent material such as acrylic or polycarbonate plate. In this case, when an object such as a user's hand or a stick is positioned on the display panel 110, total reflection generated inside the light guide 150 may be disturbed by the object (FTIR).

The sensing array 160 may be disposed under the diffuser plate 120 to sense invisible light projected from the invisible light source 140 to the diffuser plate 120.

For example, when the object 200 is located on the upper surface of the light guide 150, the sensing array 160 identifies the position of the invisible light reflected by the object 200 and projected onto the diffuser plate 120, The touch image corresponding to the identified position may be sensed.

In addition, when the object 800 is located at a distance from the light guide 150, the sensing array 160 reflects the position of the invisible light that is reflected by the object 800 and is directly projected or transmitted to the diffuser plate 120. The target image corresponding to the identified position may be sensed.

For example, the target image may be a reflected light image of an object shape that is projected or transmitted through the expansion plate 120. In this case, the object may be located close to the light guide 150 so that the invisible light is emitted from the invisible light source 140 to the object.

In addition, the sensing array 160 may sense a touch image corresponding to a position identified by identifying a position where total reflection of invisible light is disturbed in the light guide 150. Here, the sensing array 160 may be composed of one or more invisible light sensors that can sense invisible light.

In this case, the invisible light sensor may be a photo diode or a photo transistor. The invisible light sensor may be arranged in the form of a matrix in the sensor array 160 to read a voltage or a current that varies according to the amount of invisible light emitted from the invisible light source 140. The invisible light sensor may provide invisible light intensity of the touch image based on the 2D coordinates based on the read voltage or current.

For example, the visible light source 130 may be controlled by pre-defined control information according to the image data acquired by the sensing array 160 and may be turned on or off or light amount may be adjusted. Here, the control information may include a touch to the light guide, the shadow of the invisible light projected onto the diffuser plate, and the movement of the invisible light source.

More specifically, when a touch is generated using the object as the light guide 150, the visible light source 130 may adjust the amount of visible light illuminating an area corresponding to the touch of the object according to the touch intensity. In addition, the visible light source 130 may be turned on or off according to the movement of the touch.

In this case, the visible light source 130 may adjust the amount of visible light by using the shadow of the invisible light projected on the diffuser plate 120 or the movement of the invisible light source 140 spaced apart from the diffuser plate 120 by a predetermined distance.

For example, when an object such as a user's hand or a laser pointer is moved up, down, left, right, or diagonally on the diffuser plate 120, the visible light amount may be adjusted, that is, the display panel ( The brightness of the image displayed on 120 may be adjusted.

Through this, a function of the user input device may be performed by transmitting the pointing position and the motion information of the object to a device for controlling the information of the LCD. Here, the device for controlling the information of the LCD may be a PC, and the user input device may be a mouse or a keyboard.

In this case, the image data may be obtained by sensing the invisible light reflected by the sensing array 160 or the shadow of the object or the invisible light directly irradiated onto the diffuser plate 120.

2 and 3 are views illustrating a multi-touch sensing device in which invisible light sources are spaced apart from each other.

Referring to FIG. 2, the multi-touch sensing device 100 may include a display panel 110, a diffusion plate 120, a visible light source 130, an invisible light source 140, and a sensing array 160. have.

The display panel 110 may be disposed on the top of the multi-touch sensing device to display an image.

The diffuser 120 may be disposed under the display panel to diffuse visible light emitted from the visible light source 130 in a planar shape.

The visible light source 130 may be disposed below and perpendicular to the diffuser plate 120 to emit visible light. That is, the visible light source 130 may be directly below the diffuser plate 120. In this case, the visible light source 130 may directly emit visible light for displaying an image on the display panel 110 to the diffuser plate 120.

The invisible light source 140 may radiate invisible light to the diffuser plate 120 to sense the touch image at a position spaced apart from the diffuser plate 120 by a predetermined distance. In this case, the invisible light source 140 may emit invisible light perpendicular to the upper part of the diffusion plate 120 as shown in FIG. 2, and as shown in FIG. 3, form an invisible light at a predetermined angle with the upper part of the diffusion plate 120. It can radiate. For example, the invisible light source 140 may be a lamp or a laser pointer.

The sensing array 160 is disposed under the diffuser plate 120 and senses invisible light projected from the invisible light source 140 to the diffuser plate 120.

In one example, the sensing array 160 identifies the location of the light reflected by the invisible light reflected by the object 200 and projected onto the diffuser plate 120 to sense a touch image corresponding to the identified location. Here, since the sensing array 160 is the same as the sensing array 160 of FIG. 1, a redundant description will be omitted.

In addition, the sensing array 160 may sense the invisible light projected by the diffuser plate 120 to obtain the coordinates of the invisible light source 140.

If the laser pointer is used as the invisible light source 140, the sensing array 160 may acquire the coordinates pointed at the laser pointer by sensing the projected invisible light at a predetermined angle with the diffuser plate 120. .

FIG. 4 is a diagram illustrating a configuration of a sensing device using a multi-touch and a proximity object using a wave guide. 5 and 6 are views illustrating the configuration of a multi-touch sensing device using wave guides. That is, FIGS. 4 to 6 are diagrams in which a wave guide is added to each of the multi-touch sensing devices of FIGS. 1 to 3. Hereinafter, detailed descriptions of components overlapping with the components of FIGS. 1 to 3 will be omitted.

First, referring to FIG. 4, the sensing device 400 using the multi-touch and proximity objects includes a display panel 410, a diffuser plate 420, a visible light source 430, a wave guide 440, and an invisible light source 450. ), A light guide 460, and a sensing array 470.

The display panel 410 is disposed on the top of the multi-touch sensing device to display an image.

The diffuser 420 may be disposed under the display panel to emit visible light emitted from the visible light source 430 as visible light in a planar form.

The visible light source 430 may be disposed at a lower edge of the diffuser plate 120 to emit visible light. For example, the visible light source 430 may emit visible light for displaying an image on the display panel 410 to the diffuser plate 220 through the wave guide 440. In this case, the visible light source 430 may be disposed in an edge type with respect to the diffusion plate 420.

The wave guide 440 may be disposed under the diffuser plate 420 to reflect the visible light emitted from the visible light source 430 to the diffuser plate 220. For example, as the wave guide 440, a wedge type having a different thickness of an edge to be viewed may be used. In addition, a reflective pattern may be engraved on a plate type having the same thickness to be used as the wave guide 440. Through this, not only the visible efficiency of the radiation to the diffuser plate 420 may be improved, but also the reflection pattern may be differently adjusted according to the distance from the light source located at the edge for uniform plane light.

The invisible light source 450 may be disposed on the diffusion plate 420 to emit invisible light for sensing a touch image or a target image generated by the object.

The light guide 460 may allow total internal reflection (TIR) of the invisible light emitted by the invisible light source 450.

The sensing array 470 may be disposed under the wave guide 440 and may sense invisible light projected from the invisible light source 450 to the diffuser plate 420.

That is, when the object 200 is located on the upper surface of the light guide 460, the sensing array 470 identifies and identifies the position of the light in which the invisible light is reflected by the object 200 and projected onto the diffuser plate 420. The touch image corresponding to the position may be sensed. In this case, the sensing array 470 may identify a location where total reflection of invisible light is disturbed in the light guide 460 and sense a touch image corresponding to the identified location.

In addition, when the object 800 is located at a distance from the light guide 460, the sensing array 470 identifies a position of invisible light that is reflected by the object and is directly projected or transmitted through the diffuser plate 420. The target image corresponding to the identified position may be sensed.

5 and 6, the multi-touch sensing device 400 includes a display panel 410, a diffuser plate 420, a visible light source 430, a wave guide 440, an invisible light source 450, and Sensing array 470.

The display panel 410 may be disposed on the top of the multi-touch sensing device to display an image.

The diffuser 420 may be disposed below the display panel to emit and scatter visible light emitted from the visible light source 430 in a planar shape.

The visible light source 430 is disposed at the lower edge of the diffuser plate 420 to emit visible light. In this case, the visible light source 430 may emit visible light to the diffuser plate 420 through the wave guide 440.

The wave guide 440 may be disposed under the diffuser plate 420 to reflect the visible light emitted from the visible light source 430 to the diffuser plate 420. Then, the visible light emitted from the visible light source 430 may be reflected through the wave guide 440 to be incident perpendicularly to the diffuser plate 420. That is, the visible light source 430 may be disposed in an edge shape with respect to the diffuser plate 420.

The invisible light source 450 may radiate invisible light for sensing the touch image or the target image to the diffuser plate 420 at a position spaced apart from the diffuser plate 420 by a predetermined distance. In this case, the invisible light source 450 may emit invisible light perpendicular to the upper portion of the diffusion plate 420 as shown in FIG. 5, and as shown in FIG. 6, the invisible light is formed at an angle with the upper portion of the diffusion plate 420. Can emit.

The sensing array 470 may be disposed under the wave guide 440 and may sense invisible light projected from the invisible light source 450 to the diffuser plate 420.

In addition, the sensing array 470 may acquire the pointing coordinates of the invisible light source 450 by sensing the invisible light projected by the diffuser plate 420.

For example, when the laser pointer is used as the invisible light source 450, the sensing array 470 may sense the projected invisible light at an angle with the diffuser plate 420 to obtain coordinates pointing at the laser pointer. have.

As another example, when the LED pointer is used as the invisible light source 450, the sensing array 470 may acquire the pointing coordinates by sensing the invisible light emitted vertically downward from the LED pointer and projected onto the diffuser plate 420. have.

In the above, the case where there is only one invisible light source has been described. However, as illustrated in FIGS. 7 and 8, the sensing array 470 uses a plurality of invisible light sources 451 and 453 to use a touch image, a target image, and a diffusion plate ( The non-visible light projected on 420 may be sensed. That is, the sensing array 470 may sense the touch image or the target image by using the light reflected by the upper surface of the light guide 150 or the object located near the top of the light guide 150. When the laser pointer is the invisible light source 450, the sensing array 470 may acquire the coordinates to which the laser pointer is pointing.

In addition, the sensing array 470 may sense the touch image by using a shadow generated by the invisible light around the object 200 in addition to the invisible light reflected by the object 200. That is, as illustrated in FIG. 9, the sensing array 470 may sense the touch image by sensing the shadow 910 generated by the invisible light surrounding the object 200 in the diffuser plate 420. At this time, the invisible light source 140 may include a lamp (Lamp), sunlight.

Until now, when the LCD panel is used as the display panel, the sensing device using the multi-touch and proximity objects touching the touch image or the target image projected by the diffusion plate has been described. However, the OLED panel may be used as the display panel. have. In this case, OLED (Organic Light Emitting Diodes) may be used as the visible light source.

For example, when the OLED is used as the visible light source, the diffusion plate 120 may be removed from the sensing device 100 using the multi-touch and proximity objects. Then, the sensing array may be positioned under the OLED panel to sense invisible light projected onto the OLED panel.

As described above, the present invention has been described by way of limited embodiments and drawings, but the present invention is not limited to the above embodiments, and those skilled in the art to which the present invention pertains various modifications and variations from such descriptions. This is possible.

Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined not only by the claims below but also by the equivalents of the claims.

110: display panel
120: diffuser plate
130: visible light source
140: invisible light source
150: light guide
160: sensing array

Claims (22)

A diffuser plate on which invisible light is projected;
A visible light source positioned below the diffusion plate and emitting visible light to the diffusion plate; And
A sensing array positioned under the diffusion plate and configured to sense invisible light projected onto the diffusion plate
Sensing device comprising a. The method of claim 1,
An invisible light source positioned on the diffusion plate and emitting the invisible light for sensing a touch image or a target image generated by an object;
Sensing device further comprising. The method of claim 2,
A light guide positioned on the diffusion plate and totally reflecting the invisible light emitted from the invisible light source;
Further comprising:
The invisible light source,
And a sensing device that emits invisible light in the light guide or in the object. The method of claim 2,
The object is located at a distance from the top of the diffusion plate or the top of the diffusion plate,
The sensing array,
And a sensing device which senses invisible light reflected by the object. The method of claim 3,
The sensing array,
And a position where total reflection is interrupted by the object when the invisible light emitted from the invisible light source is totally reflected inside the light guide. The method of claim 2,
The invisible light source,
A sensing device for emitting an invisible light for sensing the touch image to the diffusion plate while being spaced apart from the diffusion plate by a predetermined distance. The method of claim 6,
The invisible light source,
Sensing apparatus for emitting invisible light perpendicular to the diffusion plate or at an angle with the diffusion plate. The method of claim 1,
The visible light source,
And a sensing device positioned below and perpendicular to the diffuser plate to emit visible light directly to the diffuser plate. The method of claim 1,
The visible light source,
A sensing device positioned at a lower edge of the diffuser plate to reflect visible light through a wave guide to emit visible light to the diffuser plate. The method of claim 1,
The sensing array,
And sensing the coordinates of the invisible light source which is pointed by sensing the invisible light projected on the diffusion plate. The method of claim 1,
The sensing array,
And a non-visible light shielded by the object to detect a position of a shadow generated inside the diffusion plate. The method of claim 1,
The visible light source,
The sensing device is turned on or off or the amount of light is controlled based on the image data sensed through the sensing array. A diffuser plate on which invisible light is projected; And
A sensing array positioned under the diffusion plate and configured to sense invisible light projected onto the diffusion plate
Sensing device comprising a. The method of claim 13,
An invisible light source positioned on the diffusion plate and emitting the invisible light for sensing a touch image or a target image generated by an object;
Sensing device further comprising. The method of claim 14,
The invisible light source,
Totally reflects invisible light into the light guide,
The sensing array,
And a position where total reflection is interrupted by the object when the invisible light emitted from the invisible light source is totally reflected inside the light guide. 16. The method of claim 15,
The object is located above the light guide or a predetermined distance from the top of the light guide,
The sensing array,
And a sensing device which senses invisible light reflected by the object. The method of claim 14,
The invisible light source,
A sensing device for emitting an invisible light for sensing the touch image to the diffusion plate while being spaced apart from the diffusion plate by a predetermined distance. The method of claim 14,
The invisible light source,
Sensing apparatus for emitting invisible light perpendicular to the diffusion plate or at an angle with the diffusion plate. The method of claim 14,
Visible light source for emitting visible light in a planar shape through the diffusion plate
Sensing device further comprising. The method of claim 19,
The visible light source,
And a sensing device positioned below and perpendicular to the diffuser plate to emit visible light directly to the diffuser plate. The method of claim 19,
The visible light source,
A sensing device positioned at a lower edge of the diffuser plate to reflect visible light through a wave guide to emit visible light to the diffuser plate. Organic light emitting diodes (OLED) for emitting visible light; And
A sensing array positioned under the OLED panel provided with the OLED and sensing invisible light projected onto the OLED panel.
Sensing device comprising a.

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