KR20140065867A - Bidirectional touch sensing system - Google Patents

Abstract

The present invention relates to a bi-directional touch sensing system. The touch sensing system includes: a display panel; a first and second touchscreen separately arranged with a cathode of the display panel therebetween; a display panel driving unit to input image data to the display panel; and a touchscreen panel driving unit which supplies a driving signal to the first and second touchscreen to detect a touch input.

Description

Bidirectional Touch Sensing System [0001]

The present invention relates to a bi-directional touch sensing system.

A user interface (UI) enables a user (a user) to communicate with various electric or electronic devices, allowing the user to easily control the device as desired. Representative examples of the user interface include a keypad, a keyboard, a mouse, an on-screen display (OSD), a remote controller having infrared communication or radio frequency (RF) communication functions. User interface technology has been developed to enhance the user's sensibility and ease of operation. Recently, the user interface has evolved into a touch UI, a voice recognition UI, a 3D UI, and the like.

Touch UI is becoming a necessity for portable information devices and is being applied to household appliances. The touch sensing system of the capacitive type has advantages in that the structure of the touch screen is higher in durability and sharpness than the conventional resistive film type, and can be applied to various applications because multi-touch recognition and proximity touch recognition are possible.

Various methods for combining a touch screen with an organic light emitting display device, which has been attracting attention as a next generation display device following a liquid crystal display device, have been introduced. The pixels of the organic light emitting display include organic light emitting diodes (OLEDs). The organic light emitting display device has advantages such as high response speed and no backlight compared to the liquid crystal display device, so that it is possible to realize power efficiency and thinner. Such an organic light emitting display device will be applied to mobile devices and soon become a display device of television.

The organic light emitting display device is also being developed as a transparent display or a flexible display. Since the transparent display simultaneously displays transparent images at the front and back of the display panel, the bidirectional touch UI is effective when implementing the touch UI. However, since the organic light emitting display device (hereinafter referred to as "transparent organic light emitting display device") implemented with a transparent display can not implement a bidirectional touch UI due to its structural problem, It is not easy.

1 is a schematic view illustrating a touch screen formed on a display panel of a transparent organic light emitting display device. In the display panel 100 of the transparent organic light emitting display, a cathode 101 of an OLED and an anode are formed. The cathode 101 is formed as a single film over the pixel array, and is connected to a ground voltage source to supply a ground voltage GND. The touch screen 200 may be implemented as capacitive touch sensors. Such a touch screen judges the touch sensors having a large capacity change before and after touch as a touch sensor in which a touch input is generated. The cathode 101 of the display panel 100 forms a ground surface in front of the touch screen 100 when the touch screen 200 is viewed from behind the display panel 100. [ Due to the ground surface, when a finger or another conductor touches the back of the display panel 100, the capacity of the touch sensors can not be changed. Therefore, the transparent organic light emitting display device as shown in FIG. 1 can not realize the bidirectional touch UI because it can not recognize the touch input inputted from the rear side of the display panel 100.

The present invention provides a bi-directional touch sensing system capable of realizing a bidirectional touch UI in a transparent organic light emitting diode display device.

A bidirectional touch sensing system of the present invention includes: a display panel; First and second touch screens separated and disposed across the cathode of the display panel; A display panel driver for writing image data on the display panel; And a touch screen driver for sensing a touch input by supplying a driving signal to the first and second touch screens.

According to another aspect of the present invention, there is provided a bi-directional touch sensing system comprising: first and second display panels arranged rearward of each other; A first touch screen formed on the first display panel or embedded in the first display panel; A second touch screen formed on the second display panel or embedded in the second display panel; The background image of the first display panel captured by the second camera is written to the first display panel in combination with the first image data and the background image of the second display panel captured by the first camera is recorded in the second A display panel driver for writing in the second display panel in combination with image data; And a touch screen driver for sensing a touch input by supplying a driving signal to the first and second touch screens.

The present invention can implement a bidirectional touch UI in a transparent organic light emitting diode display device by disposing first and second touch screens with a cathode of a display panel interposed therebetween.

1 is a schematic view illustrating a touch screen formed on a display panel of an OLED display.
2 is a diagram illustrating a bi-directional touch sensing system according to an embodiment of the present invention.
3 is a cross-sectional view illustrating an example of a cross-sectional structure of the display panel shown in FIG.
FIG. 4 is a view showing driving units of the display panel and the touch screen shown in FIG. 2. FIG.
5 is a diagram illustrating a bi-directional touch sensing system according to another embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings. Like reference numerals throughout the specification denote substantially identical components. In the following description, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

Referring to FIGS. 2 and 3, the bidirectional touch sensing system of the present invention includes first and second touch screens TSP1 and TSP2 that are disposed with a display panel DPNL therebetween.

The display panel DPNL is a bidirectional transparent display panel that emits light of an image displayed on the pixel array forward and backward. The display panel DPNL includes data lines, scan lines (or gate lines) intersecting with the data lines, and a pixel array in which pixels are arranged in a matrix form. The pixels include an OLED, a driving element for adjusting the current flowing in the OLED according to the data voltage, a pixel driving circuit for controlling the driving element, and the like. In the OLED, a hole injection layer (HIL), a hole transport layer (HTL), an emission layer (EML), an electron transport layer (ETL), and an electron injection layer (Electron Injection layer, EIL) are stacked. The pixel driving circuit includes one or more switch TFTs (Thin Film Transistor) and a capacitor, and can be implemented by any known circuit. A color filter may be formed on the display panel DPNL for color implementation.

The first touch screen TSP1 senses a touch input generated on the front surface of the display panel DPNL and the second touch screen TSP2 senses a touch input generated on the back surface of the display panel DPNL. The touch screens TSP1 and TSP2 include a plurality of touch sensors and wires for applying driving signals to the touch sensors. The touch sensors may include a capacitance. The touch screens TSP1 and TSP2 may be implemented by a touch screen of self capacitance or mutual capacitance.

A cathode of the OLED is disposed between the first and second touch screens TSP1 and TSP2. The first touch screen TSP1 may be formed on the front substrate 11 of the display panel DPNL or may be embedded in the display panel DPNL between the front substrate 11 and the cathode 13. [ The second touch screen TSP2 may be formed on the rear substrate 19 of the display panel DPNL or may be embedded in the display panel DPNL between the rear substrate 19 and the cathode 13. [ The front substrate 11 and the rear substrate 19 of the display panel DPNL may be made of a transparent glass substrate or a transparent film. The transparent film can be made of PET (poly ethylene terephthlate) film.

3 shows an example in which the first touch screen TSP1 is formed on the front substrate 11 and the second touch screen TSP2 is embedded in the display panel DPNL between the cathode 13 and the rear substrate 19 The bi-directional touch screen structure of the present invention is not limited to Fig. For example, when the first touch screen TSP1 is embedded in the display panel DPNL between the front substrate 11 and the cathode 13 and the second touch screen TSP2 is formed on the rear substrate 19 It is possible. However, the cathode 13 should be disposed between the first and second touch screens TSP1 and TSP2 so that the bidirectional touch input is not blocked due to the cathode 13. [

3, a first transparent insulating film 18 is formed on a rear substrate 19, and a second touch screen TSP2 is formed thereon. A second transparent insulating film 17 is formed on the second touch screen TSP2, and a TFT array 16 is formed thereon. The first and second transparent insulation films 17 and 18 may be formed of an organic transparent insulation material or an inorganic transparent insulation material. For example, the first and second transparent insulation films 17 and 18 may be formed of polyimide. The TFT array 16 includes data lines, scan lines, driving elements of pixels, and a pixel driving circuit. An anode 15, an OLED 14 and a cathode 13 are laminated on the TFT array 16 and a transparent passivation layer 12 is formed on the cathode 13. The anode 15 and the cathode 13 may be formed of a transparent conductive material such as ITO (indium tin oxide) or a semi-transparent metal film formed of a thin metal film so that light can be transmitted. The transparent protective film is formed of an organic insulating material or an inorganic insulating material. A front substrate 11 is formed on the transparent protective film 12, and a first touch screen TSP1 is bonded thereon.

Light generated by the light emission of the OLED 14 passes through the cathode 13, the transparent protective film 12, the front substrate 11 and the first touch screen TSP1 and is emitted forward of the display panel DPNL. At the same time, the light generated by the light emission of the OLED 14 passes through the anode 15, the transparent insulating film 17, the second touch screen TSP2, the transparent insulating film 18 and the rear substrate 19, As shown in Fig. Accordingly, the display panel DPNL and the bi-directional touch screen of the present invention can realize a bidirectional transparent organic light emitting display device. The user can touch and input a finger or a conductive material to the touch screens TSP1 and TSP2 arranged on the front and rear sides of the display panel DPNL in both directions of the display panel DPNL.

FIG. 4 is a view showing driving parts of the display panel DPNL and the touch screens TSP1 and TSP2 shown in FIG.

Referring to FIG. 4, the display panel driving unit includes a timing controller 120 and a panel driving circuit 130. The panel driving circuit 130 includes a data driving circuit, a scan driving circuit, and the like, and writes the input image data to the display panel DPNL.

The data driving circuit converts the digital video data of the input image input from the timing controller 120 into an analog positive / negative gamma compensation voltage to output a data voltage. The data voltage output from the data driving circuit is supplied to the pixels through the data lines of the display panel DPNL. The scan driver circuit sequentially supplies the gate signal to the gate lines to select a line of the display panel DPNL into which the data voltage is written. The gate signal may include, but is not limited to, a scan signal synchronized with the data voltage, a light emission control signal for controlling the light emission timing of the OLED, and an initialization signal for initializing the pixels.

The timing controller 120 rearranges the digital video data of the input image input from the host system 110 according to the pixel arrangement of the display panel DPNL and transmits the digital video data to the data driving circuit. The timing controller 120 receives timing signals, such as a vertical synchronization signal, a horizontal synchronization signal, a data enable signal, and a main clock, input from the host system 110, and controls operation timings of the data driving circuit and the scan driving circuit.

The host system 110 transmits timing signals to the timing controller 120 together with the digital video data of the input image. The host system 110 executes an application program associated with the coordinate information XY of the touch input input from the algorithm executing unit 220. [

The touch screen driver includes a sensing circuit 210 and an algorithm executing unit 220. The sensing circuit 210 simultaneously supplies driving signals to the first and second touch screens TSP1 and TSP2 to sense the voltage change of the touch sensors and transmit coordinate information of the touch input position to the algorithm executing unit 220 . The sensing circuit 210 synchronizes the voltage of the touch sensor received from the first and second touch screens TSP1 and TSP2 with an analog-to-digital converter (ADC) And outputs the touch raw data. When the touch sensor is touched before and after the touch, the capacitance value (C) of the touch sensor decreases at Q (charge) = C (capacitance) × V (voltage). Accordingly, the charge change amount of the touch sensor in which the touch input is generated is larger than that of the touch sense in which there is no touch input, so that the presence or absence of the touch input can be determined based on the difference in the charge variations. The sensing circuit 210 may be integrated into a read-out integrated circuit (ROIC).

The algorithm executing unit 220 executes a preset touch recognition algorithm and compares the touch raw data received from the sensing circuit 210 with a preset threshold value. Any known algorithm for the touch recognition algorithm is possible. The touch recognition algorithm detects touch primitive data above a threshold value. The touch primitive data exceeding the threshold value is determined as touch data obtained from the touch sensors in which the touch input is generated. The algorithm executing unit 220 executes a touch recognition algorithm to determine each of the touch data that is equal to or larger than the threshold value as a touch input, assigns an identification number to the touch inputs, and calculates coordinates. The algorithm executing unit 220 transmits the touch screen identification code indicating which touch screen is touched and the identification number and coordinate information of each touch input having a threshold value or more to the host system 110. The algorithm executing unit 220 may be implemented as an MCU (Micro Controller Unit).

5 is a diagram illustrating a bi-directional touch sensing system according to another embodiment of the present invention.

5, the bidirectional touch sensing system of the present invention includes first and second display panels DPNL1 and DPNL2 which are back to back, a first touch screen TSP1 formed on the front surface of the first display panel DPNL1, And a second touch screen TSP2 formed on the front surface of the second display panel DPNL2.

The first and second display panels DPNL1 and DPNL2 are display panels of the OLED display. The rear substrate of the first and second display panels DPNL1 and DPNL2 may be applied as an opaque substrate or a high reflectance substrate. The front substrate of the first and second display panels DPNL1 and DPNL2 may be made of a transparent glass substrate or a transparent film. Light from the first display panel DPNL1 is transmitted through the first touch screen TSP1 and emitted toward the front of the first display panel DPNL1. Light from the second display panel DPNL2 is transmitted through the second touch screen TSP2 and emitted toward the front of the second display panel DPNL2. The first and second display panels DPNL1 and DPNL2 display a background image captured by the cameras CAM1 and CAM2. Accordingly, the first and second display panels DPNL1 and DPNL2 and the first and second touch screens TSP1 and TSP2 implement a bidirectional transparent organic light emitting display device.

The first touch screen TSP1 detects the touch input generated on the front surface of the first display panel DPNL1 and the second touch screen TSP2 senses the touch input generated on the front surface of the second display panel DPNL2 do. The touch screens TSP1 and TSP2 include a plurality of touch sensors and wires for applying driving signals to the touch sensors. The touch sensors may include capacitance.

The first touch screen TSP1 may be formed on the front substrate of the first display panel DPNL1 or may be embedded in the first display panel DPNL1 between the front substrate and the cathode. The second touch screen TSP2 may be formed on the front substrate of the second display panel DPNL2 or may be embedded in the second display panel DPNL2 between the front substrate and the cathode.

The display panel driving unit includes first and second timing controllers 121 and 122, and first and second panel driving circuits 131 and 132. Each of the panel driving circuits 131 and 132 includes a data driving circuit, a scan driving circuit, and the like. The first panel drive circuit 131 writes the first image data to the first display panel DPNL1 under the control of the first timing controller 121. [ The second panel drive circuit 132 writes the second image data to the second display panel DPNL2 under the control of the second timing controller 122. [

The first timing controller 121 rearranges the digital video data of the first image input from the host system 111 according to the pixel arrangement of the display panel DPNL and transmits the rearranged digital video data to the data driving circuit. The first timing controller 121 receives a timing signal such as a vertical synchronizing signal, a horizontal synchronizing signal, a data enable signal, and a main clock input from the host system 111 and outputs the timing signals to the data driving circuit 131 of the first panel driving circuit 131 And the timing of operation of the scan driving circuit. The second timing controller 122 rearranges the digital video data of the second video input from the host system 111 according to the pixel arrangement of the display panel DPNL and transmits the rearranged digital video data to the data driving circuit. The second timing controller 122 receives a timing signal such as a vertical synchronizing signal, a horizontal synchronizing signal, a data enable signal, and a main clock inputted from the host system 111 and supplies the timing signal to the data driving circuit 132 of the second panel driving circuit 132 And the timing of operation of the scan driving circuit.

The host system 111 combines the background image data captured by the cameras CAM1 and CAM2 with the first and second input image data to output first and second image data that can obtain a transparent effect. The host system 111 transmits the first image data and the timing signals synchronized with the image data to the first timing controller 121. The host system 111 transmits the second image data and the timing signals synchronized with the image data to the second timing controller 122. The host system 111 synchronizes the first and second timing controllers 121 and 122. In addition, the host system 111 executes an application program associated with the coordinate information (XY) of the touch input input from the coordinate transformation unit 231 of the touch screen driver.

The first camera CAM1 picks up the front image of the first display panel DPNL1, that is, the background image of the rear of the second display panel DPNL2. The host system 111 transmits the background image received from the first camera CAM1 to the second timing controller 122 in combination with the second image data. Therefore, the second display panel DPNL2 displays a background image obtained by the first camera CAM1, and thus can display an image such as a transparent display panel.

The second camera CAM2 picks up a front image of the second display panel DPNL2, that is, a back background image of the first display panel DPNL1. The host system 111 transmits the background image received from the second camera (CAM2) to the first timing controller 121 in combination with the first image data. Therefore, the first display panel DPNL1 displays a background image obtained by the second camera CAM2, and thus can display an image such as a transparent display panel.

The touch screen driver includes a sensing circuit 211, an algorithm executing unit 221, and a coordinate conversion unit 231. The sensing circuit 211 simultaneously supplies a driving signal to the first and second touch screens TSP1 and TSP2 to sense the voltage change of the touch sensors and transmits coordinate information of the touch input position to the algorithm executing unit 221 . The sensing circuit 211 converts the voltage of the touch sensor received from the first and second touch screens TSP1 and TSP2 into digital data through the ADC in synchronization with the driving signal to output the touch primitive data.

The algorithm executing unit 221 executes a preset touch recognition algorithm and compares the touch raw data received from the sensing circuit 211 with a preset threshold value. Any known algorithm for the touch recognition algorithm is possible. The touch recognition algorithm detects touch primitive data above a threshold value. The touch primitive data exceeding the threshold value is determined as touch data obtained from the touch sensors in which the touch input is generated. The algorithm executing unit 221 executes the touch recognition algorithm to determine each of the touch data equal to or larger than the threshold value as a touch input, assigns an identification number to the touch inputs, and calculates coordinates. The algorithm executing unit 221 transmits the touch screen identification code indicating which touch screen is touched and the identification number and coordinate information of each touch input having a threshold value or more to the coordinate conversion unit 231.

The first and second display panels DPNL1 and DPNL2 face their display surfaces in opposite directions with the back surface facing each other. Therefore, when any one of the first and second touch screens TSP1 and TSP2 is touched, the coordinate of the touch input position is directly reflected on the opposite-layer touch screen, and the virtual touch input position on the opposite side from the actual touch input position is different Therefore, a coordinate conversion process is required. The coordinate transformation unit 231 transforms coordinates of the actual touch input into coordinates of the opposite touch screen so that the touch input positions obtained when one touch screen is touched can be seen at the same position on the other touch screen, . For example, in FIG. 5, when the coordinate of the actual touch input generated in the first touch screen TSP1 is F (x, y), if there is no coordinate conversion process, the virtual touch input position of the second touch screen TSP2 is 1 touch screen (TSP1). The coordinate transformation unit 231 transforms the x coordinate from the coordinate F (x, y) of the actual touch input and outputs the virtual touch input coordinate B (x ', y') corresponding to the actual touch input coordinate F (x, y) . The host system 111 executes an application program in which the actual touch input, the coordinate information, and the virtual touch input are associated with the coordinate information.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification, but should be defined by the claims.

DPNL, DPNL1, DPNL2: Display panel TSP1, TSP2: Touch screen
120 to 122: Timing controller 130 to 132:
210, 211: sensing circuit 220, 221: algorithm executing section
231:

Claims (4)

Display panel;
First and second touch screens separated and disposed across the cathode of the display panel;
A display panel driver for writing image data on the display panel; And
And a touch screen driver for sensing a touch input by supplying a driving signal to the first and second touch screens. The method according to claim 1,
Wherein the first touch screen is formed on a front substrate of the display panel or is embedded in the display panel between the front substrate and the cathode,
Wherein the second touch screen is formed on a rear substrate of the display panel or is embedded in the display panel between the rear substrate and the cathode. First and second display panels disposed rearward of each other;
A first touch screen formed on the first display panel or embedded in the first display panel;
A second touch screen formed on the second display panel or embedded in the second display panel;
The background image of the first display panel captured by the second camera is written to the first display panel in combination with the first image data and the background image of the second display panel captured by the first camera is recorded in the second A display panel driver for writing in the second display panel in combination with image data; And
And a touch screen driver for sensing a touch input by supplying a driving signal to the first and second touch screens. The method of claim 3,
Wherein the first touch screen is formed on the front substrate of the first display panel or is embedded in the first display panel between the front substrate and the cathode of the first display panel,
Wherein the second touch screen is formed on the front substrate of the second display panel or is embedded in the second display panel between the front substrate and the cathode of the second display panel.

Images