WO2018126768A1 - 触控显示基板及其触控检测方法 - Google Patents
触控显示基板及其触控检测方法 Download PDFInfo
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- WO2018126768A1 WO2018126768A1 PCT/CN2017/107750 CN2017107750W WO2018126768A1 WO 2018126768 A1 WO2018126768 A1 WO 2018126768A1 CN 2017107750 W CN2017107750 W CN 2017107750W WO 2018126768 A1 WO2018126768 A1 WO 2018126768A1
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Definitions
- the present disclosure relates to the field of touch display substrates, and in particular, to a touch display substrate and a touch detection method thereof.
- the touch function can be implemented in an external or in-line manner.
- the touch structure may be disposed on the inner side of the cover or a cathode as a pattern of the touch structure.
- the external type is simple to make, the metal wire is more obvious, and the visual reflection is more obvious.
- the in-line type needs to divide the cathode, which will cause inconsistency in loading.
- the OLED current drive is more obvious, and the resistance voltage drop is very high. It cannot be used to make a large-size touch screen (more than 2 inches display is difficult to guarantee).
- the manner in which the touch function is implemented in the existing touch screen is either easy to reflect or not suitable for a large touch screen.
- Some embodiments of the present disclosure provide a touch display substrate and a touch detection method thereof, which are used to solve the problem that the existing touch screen is either easily reflective or not suitable for a large size touch screen.
- An embodiment of the present disclosure provides a touch display substrate, including: a substrate substrate, a photosensitive touch member and an OLED device sequentially disposed on the substrate.
- the photosensitive touch component includes: a touch electrode layer, a photosensitive material layer, an insulating layer, and an ITO layer which are sequentially disposed.
- the touch electrode layer is closer to the base substrate than the photosensitive material layer.
- the insulating layer is disposed on the touch electrode layer In the gap of the case, and in the gap of the pattern of the photosensitive material layer.
- the ITO layer is a one-layer structure.
- the touch electrode layer includes a plurality of touch electrodes; the touch electrodes are mutual capacitance electrodes or self capacitance electrodes.
- the touch electrode is a self-capacitance electrode; and the touch sensing area is an area where the touch electrode is located.
- the pattern of photosensitive material layers is a plurality of squares arranged in a matrix. In one implementation, each square has a size of 5 mm x 5 mm.
- the touch electrodes are mutual capacitance electrodes
- the touch electrodes include a driving electrode and a sensing electrode
- a touch node is formed between each of the driving electrodes and each of the sensing electrodes.
- the touch sensing area is an area where the touch node is located.
- the OLED device comprises a cathode and an anode.
- the cathode is a translucent electrode material
- the anode is a reflective electrode material.
- the OLED device includes an anti-circular polarizing layer disposed on a side of the OLED device remote from the substrate.
- the touch display substrate further includes: a TFT structure disposed between the photosensitive touch member and the OLED device.
- the TFT structure is a top gate type structure.
- the OLED device includes: a plurality of sub-pixels.
- the orthographic projection of each of the photosensitive material layers on the substrate substrate covers an orthographic projection of a plurality of sub-pixels on the substrate.
- Some embodiments of the present disclosure provide a touch detection method for any of the above touch display substrates, including:
- the photosensitive touch component determines a position where the touch occurs by sensing the light reflected by the finger.
- determining whether there is a finger on the touch display substrate performs a touch operation according to the following manner:
- Determining whether there is a finger on the touch display substrate performs a touch operation according to a difference between the received square wave signal and the originally transmitted square wave signal.
- the photosensitive touch component detects the light reflected by the finger The location where the touch occurs, including:
- the touch display substrate provides a reference voltage for the ITO layer and the touch electrode layer in the photosensitive touch component to enable the photosensitive material layer to work normally;
- the photosensitive material layer converts the optical signal into an electrical signal after sensing the light reflected by the finger, and transmits the generated electrical signal to the corresponding touch sensing area;
- the electrical signals in all the touch sensing regions are read, and the touch sensing region where the touch occurs is determined according to the difference between the read electrical signals and the reference voltage.
- Some embodiments of the present disclosure may achieve at least one of the following beneficial effects and/or other benefits:
- a photosensitive touch member capable of implementing a touch function is disposed between the base substrate and the OLED device, and the original display substrate is not changed.
- the order of each film layer is made, and since the photosensitive touch member is disposed under the OLED device, it does not affect the light emission of the touch display substrate, and is suitable for making a large-sized touch screen.
- FIG. 1 is a schematic diagram of a basic structure of a touch display substrate according to an embodiment of the present disclosure
- FIG. 2 is a schematic top plan view of a photosensitive touch member in which a touch electrode is a self-capacitance electrode according to an embodiment of the present disclosure
- FIG. 3 is a detailed structural diagram of a touch display substrate according to an embodiment of the present disclosure.
- FIG. 4 is a flowchart of a method for determining whether a finger performs a touch operation according to an embodiment of the present disclosure
- FIG. 5 is a flowchart of a method for determining a location where a touch occurs, according to an embodiment of the present disclosure.
- a touch display substrate is mainly provided for a display substrate that needs to be touched.
- a touch can be added between the base substrate and the OLED device.
- Functional photosensitive touch components The touch display substrate does not need to change the order of fabrication of the respective film layers in the original display substrate, and since the photosensitive touch member is disposed under the OLED device, it does not affect the light emission of the touch display substrate.
- the structure described in the present disclosure can be employed as long as the display substrate can project the light reflected by the finger onto the photosensitive touch member, and the structure described in the present disclosure is suitable for making a large-sized touch screen. The specific structure of the touch display substrate will be described in detail below.
- FIG. 1 is a schematic diagram of a basic structure of a touch display substrate according to an embodiment of the present disclosure.
- the touch display substrate may include a base substrate 101, a photosensitive touch member 102 and an OLED device 103 sequentially disposed on the base substrate 101.
- the photosensitive touch component 102 can include a touch electrode layer 1021, a photosensitive material layer 1022, an insulating layer 1023, and an ITO layer 1024 disposed in sequence.
- the touch electrode layer 1021 is closer to the base substrate 101 than the photosensitive material layer 1022.
- the orthographic projection of the touch sensing region in the touch electrode layer 1021 on the substrate 101 completely covers the orthographic projection of the pattern of the photosensitive material layer 1022 on the substrate 101, and is located on the substrate 101 on the ITO layer. Inside the orthographic projection.
- the insulating layer 1023 is disposed in the slit of the pattern of the touch electrode layer 1021 and is disposed in the slit of the pattern of the photosensitive material layer 1022.
- the touch display substrate provided in some embodiments of the present disclosure is not easy to be reflective or is not suitable for a large-size touch screen.
- a photosensitive touch member 102 is added between the base substrate 101 and the OLED device 103 to implement a touch function. It not only does not change the order of fabrication of the various layers in the original display substrate, but also does not affect the illumination of the touch display substrate because the photosensitive touch member is disposed under the OLED device. Suitable for making large-size touch screens.
- the photosensitive touch component 102 can sense the light reflected by the finger to the photosensitive material layer 1022 when the finger touches, and then determine the specific position of the finger touch through the sensed reflected light.
- the photosensitive touch component 102 can include a plurality of film layers, and mainly includes: a touch electrode layer 1021, a photosensitive material layer 1022, an insulating layer 1023, and an ITO layer 1024 disposed in sequence.
- the photosensitive touch member 102 and the OLED device can be bonded by the optical adhesive 104.
- the touch electrode layer 1021, the photosensitive material layer 1022, the insulating layer 1023, and the ITO layer 1024 are sequentially arranged, and the touch electrode layer 1021 is closest to the base substrate 101. Since the photosensitive material layer 1022 requires a certain voltage to operate normally, the photosensitive material layer 1022 can be disposed between the touch electrode layer 1021 and the ITO layer 1024. In order to isolate the respective electrodes in the touch electrode layer 1021 and the pattern in the photosensitive material layer 1022, the insulating layer 1023 is disposed in the slit of the pattern of the touch electrode layer 1021 and disposed in the slit of the pattern of the photosensitive material layer 1022.
- each of the film layers constituting the photosensitive touch member 102 has a specific pattern, and the touch sensing area in the touch electrode layer 1021 is a touch sensing area, and the touch sensing area in the touch electrode layer 1021.
- the size and location must be completely covered by the pattern in the layer of photosensitive material 1022 to better receive the electrical signals generated by the layer of photosensitive material 1022. That is, as shown in FIG. 1 , the orthographic projection of the touch sensing region on the base substrate 101 in the touch electrode layer 1021 completely covers the orthographic projection of the pattern of the photosensitive material layer 1022 on the substrate 101 .
- the ITO layer is a one-layer structure. That is, as shown in FIG. 1 , the orthographic projection of the touch sensing region on the base substrate 101 in the touch electrode layer 1021 is located in the orthographic projection of the ITO layer on the substrate 101 .
- the ITO layer may also be provided as a separate structure, for example, a structure similar to the pattern of the photosensitive material layer, but it must be ensured that all of the ITO patterns in the ITO layer can be simultaneously at the same potential.
- the touch electrode layer disposed in the photosensitive touch component 102 includes a plurality of touch electrodes, and the type of the touch electrodes can be set as needed.
- the touch electrode layer includes a plurality of touch electrodes; the touch electrodes are self-capacitance electrodes or mutual capacitance electrodes. The following is a detailed introduction.
- the touch electrode is a self-capacitance electrode.
- the touch sensing area is the area where the touch electrode is located.
- each touch electrode itself is The touch sensing area, that is, the touch sensing area is the area where the touch electrode is located.
- FIG. 2 is a schematic top plan view of a photosensitive touch member in which a touch electrode is a self-capacitance electrode according to an embodiment of the present disclosure.
- the ITO layer 1024 in the figure is a one-layer structure.
- the touch electrode layer 1021 includes a plurality of touch electrodes arranged in a matrix, and the touch electrodes are self-capacitance electrodes.
- the pattern of the photosensitive material layer 1022 is a plurality of squares arranged in a matrix.
- each square has a size of 5 mm x 5 mm.
- the dotted square in the figure is the pattern of the photosensitive material layer.
- the shape and size of the photosensitive material layer pattern can be set according to actual needs and the shape and size of the touch electrodes.
- the touch electrodes When the touch electrodes are mutual capacitance electrodes, the touch electrodes include a driving electrode and a sensing electrode, and a touch node is formed between each of the driving electrodes and each of the sensing electrodes.
- each touch node is a touch sensing area, that is, the touch sensing area is an area where the touch node is located.
- the touch electrode may be a double-layer mutual-capacitance electrode structure, or may be configured as a single-layer mutual-capacitance electrode according to requirements.
- the touch electrode is a self-capacitance electrode, and the orthographic projection of the touch node on the base substrate must be satisfied, and the orthographic projection of the pattern of the photosensitive material layer on the substrate substrate is completely covered.
- the signal line 1025 on the touch electrode may be formed in the same layer when the touch electrode is fabricated, or may be a separately formed metal line, as long as the signal transmission on the touch electrode can be realized.
- FIG. 3 is a detailed structural diagram of a touch display substrate according to an embodiment of the present disclosure.
- OLED device 103 can include a number of sub-pixels 1031.
- the orthographic projection of each of the photosensitive material layers 1022 on the substrate substrate covers an orthographic projection of the plurality of sub-pixels 1031 on the substrate.
- each of the photosensitive material layers 1022 may cover two sub-pixels 1031, that is, may correspond to at least two slits. In a specific implementation, it is also possible to provide three or more sub-pixels 1031 for each of the photosensitive material layers 1022 as needed.
- the structure of the display substrate portion in the touch display substrate may not be Limited, no need to change the original film layer production sequence.
- the above embodiment is based on the existing OLED display substrate, and the photosensitive touch member is externally attached to the bottom of the OLED display substrate, so that the touch function can be realized on the basis of a small change design. Specifically, as long as the light reflected by the finger can be transmitted to the bottom of the display substrate, the conventional display substrate can transmit light through the slit, and in order to better realize the photosensitive touch, a feasible method is described below.
- the touch display shows the structure of the display substrate portion in the substrate.
- the display substrate portion in the touch display substrate mainly includes an OLED device.
- OLED device 103 can include a cathode 1032 and an anode 1033.
- Cathode 1032 is a translucent electrode material and anode 1033 is a reflective electrode material.
- the cathode 1032 of the translucent electrode material can transmit light reflected by the finger, and can generally be made of materials such as magnesium or aluminum.
- the anode 1033 is a reflective electrode material, so the light reflected by the finger can only be transmitted from the slit between the anodes.
- the OLED device 103 may further include: an anti-circular polarizing layer 1034 disposed on a side of the OLED device away from the substrate.
- the polarizing layer 1034 can be configured to prevent the light reflected by the metal from entering the anti-circular polarizing layer of the human eye, and further eliminating the need to provide a black matrix or the like that blocks the TFT structure.
- the light reflected by the finger can be directly transmitted through the polarizing layer, and transmitted through the slit between the anodes in the OLED device and the region where the TFT structure is not disposed to the photosensitive touch member, so that the photosensitive touch member can sense the finger touch. Specific location.
- the display substrate portion in the touch display substrate may further include a TFT structure. Since the current embodiment employs an anti-circular polarizing layer, a black matrix or the like for shielding the TFT structure is not provided.
- the touch display substrate further includes: a TFT structure disposed between the photosensitive touch member and the OLED device. Among them, the TFT structure is a top gate type structure. If a bottom gate type TFT structure is to be used, it is necessary to separately provide a black matrix or the like that blocks the TFT structure.
- the touch display substrate may be configured as an external touch display substrate as shown in FIG. 1 and FIG. 3 , or the photosensitive touch component may be embedded in the display substrate as needed. As long as it does not affect the normal operation of the display panel.
- a touch detection method for a touch display substrate is provided for use in a touch display substrate provided by any one of the above embodiments of the present disclosure.
- the touch detection method can be implemented by the following steps:
- the photosensitive touch member passes The light reflected by the sensing finger determines the position at which the touch occurs.
- the touch detection method can sense the light reflected by the finger through the photosensitive touch component, thereby determining the specific location where the touch occurs.
- FIG. 4 is a flowchart of a method for determining whether a finger performs a touch operation according to an embodiment of the present disclosure. In an embodiment, the method may be specifically implemented by the following steps:
- Step 401 When the OLED device in the touch display substrate is normally displayed, send a square wave signal to the cathode in the OLED device, and receive the returned square wave signal;
- Step 402 Determine, according to the difference between the received square wave signal and the originally transmitted square wave signal, whether there is a finger on the touch display substrate to perform a touch operation.
- the cathode in the OLED device may be used to determine whether a finger performs a touch operation.
- a square wave signal can be transmitted to the cathode and the returned square wave signal can be received through the same signal line. Since the square wave signal is fixed, when a finger performs a touch operation, the capacitance on the cathode increases, and the number of square waves and the delay time of the returned square wave signal change, and thus can be based on the received square wave signal. A difference between the originally transmitted square wave signal is used to determine whether a finger is on the touch display substrate for a touch operation.
- FIG. 5 is a flowchart of a method for determining a location where a touch occurs, according to an embodiment of the present disclosure.
- the method may be specifically implemented by the following steps:
- Step 501 The touch display substrate provides a reference voltage for the ITO layer and the touch electrode layer in the photosensitive touch component to enable the photosensitive material layer to work normally.
- Step 502 the photosensitive material layer converts the optical signal into an electrical signal after sensing the light reflected by the finger, and transmits the generated electrical signal to the corresponding touch sensing area;
- Step 503 Read electrical signals in all touch sensing regions, and determine a touch sensing region where the touch occurs according to a difference between the read electrical signals and the reference voltage.
- a voltage difference needs to be formed between the ITO layer and the touch electrode layer in the photosensitive touch member.
- the ITO layer is set to a fixed potential, and all the touch electrodes in the touch electrode layer are set to the same potential, thereby forming a voltage difference between the ITO layer and the touch electrode layer.
- the photosensitive touch member After the light emitted by the OLED device is reflected by the finger, the region between the anodes in the OLED device and the region where the TFT structure is not disposed is transmitted to the photosensitive touch member. After sensing the light reflected by the finger, the photosensitive material layer in the photosensitive touch component converts the optical signal into an electrical signal (voltage or current), and transmits the generated electrical signal to the corresponding setting. Touch sensing area.
- the electrical signals in the touch sensing area of all the touch electrodes are read.
- the electrical signals of the touch sensing area are read. affected. Since the reference voltage applied by each touch sensing area is the same, the touch sensing area where the touch occurs can be determined according to the difference between the read electrical signal and the reference voltage.
- some embodiments of the present disclosure provide a touch display substrate and a touch detection method thereof.
- a photosensitive touch component capable of implementing a touch function between the base substrate and the OLED device, not only the order of fabrication of the respective film layers in the original display substrate is changed, but also the photosensitive touch member is disposed under the OLED device. Therefore, it does not affect the light emission of the touch display substrate.
- the embodiment is suitable for making a large size touch screen.
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Abstract
Description
Claims (14)
- 一种触控显示基板,包括:衬底基板,依次设置在所述衬底基板上的光敏触控部件和有机发光二极管OLED器件;所述光敏触控部件包括:依次设置的触控电极层,光敏材料层,绝缘层,以及氧化铟锡ITO层;其中,所述触控电极层比所述光敏材料层靠近所述衬底基板;所述触控电极层中的触控感测区域在所述衬底基板上的正投影,完全覆盖所述光敏材料层的图案在所述衬底基板上的正投影,且位于所述ITO层在所述衬底基板上的正投影内;所述绝缘层设置在所述触控电极层图案的缝隙中、且设置在所述光敏材料层图案的缝隙中。
- 如权利要求1所述的触控显示基板,其中,所述ITO层为一整层的结构。
- 如权利要求1所述的触控显示基板,其中,所述触控电极层包括多个触控电极;所述触控电极为自电容电极或互电容电极。
- 如权利要求3所述的触控显示基板,其中,所述触控电极为自电容电极;所述触控感测区域为所述触控电极所在的区域。
- 如权利要求4所述的触控显示基板,其中,所述光敏材料层的图案为呈矩阵排列的多个正方形。
- 如权利要求5所述的触控显示基板,其中,每个正方形的尺寸为5mm×5mm
- 如权利要求3所述的触控显示基板,其中,所述触控电极为互电容电极,所述触控电极包括驱动电极和感应电极,且每条驱动电极和每条感应电极之间均形成触控节点;其中,所述触控感测区域为所述触控节点所在的区域。
- 如权利要求1所述的触控显示基板,其中,所述OLED器件包括:阴极和阳极;其中,所述阴极为半透明电极材料,所述阳极为反射电极材料。
- 如权利要求1所述的触控显示基板,其中,所述OLED器件包括:设置在所述OLED器件上远离所述衬底基板一侧的防反圆偏光层。
- 如权利要求9所述的触控显示基板,其中,所述触控显示基板还包括:设置在所述光敏触控部件和所述OLED器件之间的TFT结构;其中,所述TFT结构为顶栅型结构。
- 如权利要求1-10任一项所述的触控显示基板,其中,所述OLED器件包括:若干个子像素;其中,所述光敏材料层中的每个图案在所述衬底基板上的正投影,均覆盖多个子像素在所述衬底基板上的正投影。
- 一种用于如权利要求1-11中任一项所述的触控显示基板的触控检测方法,包括:当确定所述触控显示基板上有手指进行触控操作时,所述光敏触控部件通过感测手指反射的光线确定触控发生的位置。
- 如权利要求12所述的方法,其中,根据下列方式确定所述触控显示基板上是否有手指进行触控操作:当所述触控显示基板中的OLED器件正常显示时,向所述OLED器件中的阴极发送方波信号,并接收返回的方波信号;根据接收到的方波信号与原发送的方波信号之间的差异,确定所述触控显示基板上是否有手指进行触控操作。
- 如权利要求12所述的方法,其中,所述光敏触控部件通过感测手指反射的光线确定触控发生的位置,包括:所述触控显示基板分别为所述光敏触控部件中的ITO层以及所述触控电极层提供能够使所述光敏材料层正常工作的参考电压;所述光敏材料层在感测到手指反射的光线后将光信号转换为电信号,并将产生的电信号传输给对应的触控感测区域;读取所有触控感测区域中的电信号,并根据读取到的电信号与所述参考电压之间的差异,确定触控发生的触控感测区域。
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CN109426388B (zh) | 2017-09-01 | 2021-05-25 | 京东方科技集团股份有限公司 | 显示基板、显示装置及其控制方法 |
CN108564885B (zh) * | 2018-01-11 | 2020-08-25 | 上海天马微电子有限公司 | 柔性显示面板及其制作方法和柔性显示装置 |
CN108807715B (zh) * | 2018-05-31 | 2020-09-01 | 武汉华星光电半导体显示技术有限公司 | 触控显示面板 |
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CN112947787A (zh) * | 2021-02-23 | 2021-06-11 | 北京京东方显示技术有限公司 | 触控面板、显示装置、显示系统及触控方法 |
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