KR102690479B1 - Touch panel liquid crystal display device - Google Patents

Abstract

The present invention particularly relates to an AIT touch panel liquid crystal display device that can save pins and packages of an MCU, and includes an MCU that provides register setting data, clock signals, and various control signals; A plurality of SR-ICs that receive the register setting data, clock signal, and various control signals from the MCU, and sequentially transmit touch sensing data to the MCU; The register setting data and various control signals are transmitted from the MCU to the plurality of SR-ICs in the touch non-sensing logic section of the touch synchronization signal (TSYNCN), and the touch sensing logic section of the touch synchronization signal (TSYNCN) is transmitted. a bidirectional data transmission line that sequentially transmits sensing data from the plurality of SR-ICs to the MCU; In addition, a clock transmission line is provided to transmit the clock signal in one direction from the MCU to each SR-IC.

Description

Touch panel liquid crystal display device}

The present invention relates to a touch panel liquid crystal display device, and particularly to an AIT (Advanced In-cell Touch) touch panel liquid crystal display device that can save MCU pins and packages.

With the development of multimedia, the importance of flat panel display devices is increasing. In response to this, flat panel displays such as liquid crystal displays, plasma displays, and organic light emitting displays are being commercialized.

Among these flat display devices, liquid crystal displays are widely used as portable flat display devices due to their excellent image quality, light weight, thinness, and low power consumption. In particular, they are widely used in laptops, computer monitors, and televisions.

Electrical characteristics such as resistance or capacitance change at a touch point where a hand or a stylus pen touches the liquid crystal display device, detecting the touch point, and outputting or calculating information corresponding to the touch point. A touch panel liquid crystal display device containing a stack of touch panels that performs the following is widely used.

Such a touch panel liquid crystal display device is one of the user interfaces, and its application range is expanding to small portable terminals, office equipment, mobile phones, etc.

However, this method of stacking a separate touch panel on a liquid crystal display device has limitations in making it thinner due to its increased thickness, the transmission efficiency of light decreases as it passes through the stacked panel, and the production cost is high. It has the same disadvantage as increasing.

To solve this problem, an AIT type touch panel liquid crystal display device in which a touch sensor is embedded in the pixel area of the liquid crystal display device has been proposed.

In this AIT type touch liquid crystal display device, the touch sensing unit is built into the SR-IC and the SR-IC and the MCU are separated from each other, so the MCU transmits image data, clock signals, and various control signals to the SR-IC. In order to transmit a touch sensing signal from the SR-IC to the MCU, an interface for transmitting and receiving data between the SR-IC and the MCU is required. SPI (Serial Peripheral Interface) is the most commonly used interface.

Figure 1 schematically shows the SR-IC and MCU in a conventional AIT type touch panel liquid crystal display device, and Figure 2 is a schematic configuration diagram of a conventional ROIC.

The MCU functions as a master and each SR-IC functions as a slave.

In the above, the SR-IC reads a touch sensing signal, converts it into a digital signal, and transmits it to the MCU through the interface. It receives a clock signal (ECLK) and various control signals from the MCU, and outputs an image from a timing controller. It includes an SDIC that receives data and drives the data line.

As shown in FIG. 2, the conventional ROIC includes a channel multiplexer (1) that receives touch signals from a plurality of touch sensing lines of the liquid crystal panel and selects and outputs one signal, and the channel multiplexer (1) A pre-amplifier (2) that pre-amplifies the touch signal output from the pre-amplifier, a S/H amplifier (3) that samples and holds and amplifies the pre-amplified touch signal, and a It is comprised of an A/D converter 4 that converts the touch signal output from the S/H amplifier 3 by a clock signal into a digital signal and provides it to the MCU through an SPI interface.

Although not shown in the drawing, the AIT type touch panel includes a plurality of gate lines and a plurality of data lines for displaying an image, and a plurality of touch sensing electrodes (S11, S12 in FIG. 2, S13, S21, S22, S23, S31, S32, S33) and a touch sensing line connecting them.

As shown in FIG. 1, a plurality of SR-ICs are mounted in the non-display area of the AIT type touch panel.

In order to interface with each of the plurality of SR-ICs, the MCU is provided with a plurality of SPI master blocks (MSPIO Mst ~ MSPI5 Mst) corresponding to the number of the plurality of SR-ICs, and each SPI master block (MSPIO Mst ~ MSPI5 Mst) and each SR-IC each has 4 pins (SSN, SCLK, MOSI, MISO).

At this time, the TTL transmission method is used between the MCU and each SR-IC. If there are 6 SR-ICs, the MCU must be equipped with 6 SPI master blocks (MSPIO Mst), so the MCU is basically 24 pins are required. In addition, the SR-IC reads the touch sensing signal, converts it into a digital signal, and transmits it to the MCU through the interface, so a separate clock signal is required to convert the touch sensing signal (analog signal) into a digital signal. . Accordingly, the MCU provides a clock signal (ECLK) for analog/digital conversion to the plurality of SR-ICs.

Therefore, in a conventional AIT type touch panel liquid crystal display device, when there are 6 SR-ICs, the MCU requires a total of 25 pins. Additionally, when there are six SR-ICs, each SR-IC has two ROICs, so 48 transmission lines (24×2) are required between the MCU and the six SR-ICs.

Such a conventional AIT type touch panel liquid crystal display device had the following problems.

First, it is a two-way communication in the form of TTL, and due to frequency limitations, the master (MCU) and each slave (SR-IC) are connected in a multi-point form. Therefore, in the case of a large-area, high-resolution display device, the SR-IC must be increased. Therefore, the number of transmission lines between the MCU and the plurality of SR-ICs rapidly increases.

Second, since the MCU must also have as many pins as the multiple points, not only does the number of pins increase as the display panel size increases and the number of SR-ICs increases, but also the package of the IC increases.

Third, the AIT type touch panel must have a LOG (Line On Glass) area, so the resistance value of each wire increases and space limitations occur.

Fourth, since two-way communication is performed using the TTL method, EMI (Electro Magnetic Interference) characteristics deteriorate.

Fifth, separately from the SPI clock, a clock (TTL) must be used to convert the touch sensing signal into a digital signal.

The present invention is intended to solve this problem, and provides multi-point LVDS (Low Voltage Differential signaling) between an algorithm processing unit (hereinafter referred to as “MCU”) and a source drive IC (hereinafter referred to as “SR-IC”). ) (hereinafter referred to as "MLVDS") topology is adopted as the basis, and AIT (AIT) can save the pins and package of the MCU by replacing the separate ADC clock with the MLVDS clock. The purpose is to provide an Advanced In-cell Touch (LCD) touch panel liquid crystal display device.

A touch panel liquid crystal display device according to the present invention for achieving the above object includes an MCU that provides register setting data, clock signals, and various control signals; A plurality of SR-ICs that receive the register setting data, clock signal, and various control signals from the MCU, and sequentially transmit touch sensing data to the MCU; The register setting data and various control signals are transmitted from the MCU to the plurality of SR-ICs in the touch non-sensing logic section of the touch synchronization signal (TSYNCN), and the touch sensing logic section of the touch synchronization signal (TSYNCN) is transmitted. It is characterized by having a bidirectional data transmission line for sequentially transmitting sensing data from the plurality of SR-ICs to the MCU; and a clock transmission line for unidirectionally transmitting the clock signal from the MCU to each SR-IC. .

Here, the MCU includes a data transmission buffer for transmitting the register setting data and various control signals to each SR-IC through the bidirectional data transmission line, and transmits the touch sensing data from each SR-IC in the bidirectional manner. It is characterized by comprising a data reception buffer for receiving data through a data transmission line, and a clock transmission buffer for transmitting the clock signal to each of the SR-ICs through the clock transmission line.

Each SR-IC includes a data reception buffer for receiving the register setting data and various control signals from the MCU through the bidirectional data transmission line, and a data reception buffer for receiving the touch sensing data from the MCU through the bidirectional data transmission line. It is characterized by comprising a data transmission buffer for transmission and a clock reception buffer for receiving the clock signal from the MCU through the clock transmission line.

The protocol for transmitting the register setting data and the various control signals to each SR-IC through the bidirectional data transmission line includes an instruction designating one or all of the plurality of SR-ICs and an address designating an internal register. Wow, it is characterized by being composed of data for setting the corresponding register.

The protocol for transmitting the touch sensing data from each SR-IC to the MCU through the bidirectional data transmission line is to transmit the plurality of SRs in a predetermined order in the touch sensing logic section of the touch synchronization signal (TSYNCN) without commands. -It is characterized by transmission from the IC at regular intervals.

If it is a non-touch sensing logic section of the touch synchronization signal, the MCU switches to the transmission mode and each SR-IC switches to the reception mode. If it is a touch sensing logic section of the touch synchronization signal, the MCU switches to the reception mode and the Each SR-IC is characterized by switching to transmit mode.

The touch panel liquid crystal display device according to the present invention having the above features has the following effects.

Since data is transmitted and received between the MCU and each SR-IC using the MLVDS interface, even when there are six SR-ICs, the MCU requires only four pins, and between the MCU and the six SR-ICs 24 transmission lines are required.

Therefore, since the number of pins of the MCU and the number of transmission lines between the MCU and the six SR-ICs are reduced, the package of the IC is also reduced, and the LOG (Line On Glass) area is not greatly required. A narrow panel bezel can be implemented and the width of each wiring can be increased, reducing wiring resistance and eliminating space constraints.

In addition, by using the MLVDS interface between the MCU and each SR-IC, EMI characteristics by the existing TTL method can be improved, and the transmission/reception buffer (Tx/Rx buffer) can be switched by utilizing the standard touch synchronization signal as is. Therefore, there is no need for separate pins or packets required for two-way communication.

In addition, the present invention can be applied not only to in-cell touch panels, but also to display devices using separate ROICs, such as out-cell/on-cell.

Figure 1 is a schematic diagram showing the SR-IC and MCU in a conventional AIT type touch panel liquid crystal display device.
Figure 2 is a schematic configuration diagram of a conventional ROIC.
Figure 3 is a configuration diagram schematically showing the SR-IC and MCU in the AIT type touch panel liquid crystal display device according to the present invention.
Figure 4 is a communication line configuration diagram between an MCU and a plurality of SR-ICs according to the present invention.
Figure 5 is a schematic configuration diagram of ROIC according to the present invention
Figure 6 is an example protocol for transmitting data from the MCU to each SR-IC in the touch panel liquid crystal display device according to the present invention.
Figure 7 is an example protocol for transmitting data from a plurality of SR-ICs to an MCU in a touch panel liquid crystal display device according to the present invention.

The touch panel liquid crystal display device according to the present invention having the above features will be described in more detail with reference to the attached drawings as follows.

Figure 3 is a diagram schematically showing the SR-IC and MCU in the AIT type touch panel liquid crystal display device according to the present invention, and Figure 4 is a diagram showing the communication line configuration between the MCU and a plurality of SR-ICs according to the present invention. .

First, although not shown in the drawing, an AIT type touch panel includes a plurality of gate lines and a plurality of data lines for displaying an image, a plurality of touch sensing electrodes for sensing a touch, and a touch sensing device connecting them. Provide a line.

As shown in FIG. 3, the AIT type touch panel liquid crystal display device according to the present invention has an MLVDS topology capable of bidirectional communication in the form of a bus (Multi-drop) between an MCU and a plurality of SR-ICs. is adopted as the basis, and the separate ADC clock is replaced with the MLVDS clock.

Therefore, the MCU has one master block (MSPI Mst), and the master block (MSPI Mst) transmits register setting signals and various control signals to each SR-IC, and receives touch signals from each SR-IC. It is provided with a pair of pins for receiving sensing data and a pair of pins for transmitting a clock signal to each of the SR-ICs. In other words, the master block (MSPI Mst) transmits register setting signals and various control signals to each SR-IC, and data transmission and reception buffers (Tx, Rx) for receiving touch sensing data from each SR-IC. and a clock transmission buffer (Tx) for transmitting the clock signal to each SR-IC. Therefore, the MCU has 4 pins.

In addition, the interface between the MCU and the plurality of SR-ICs includes a pair of data transmission lines (DTL) for transmitting the register setting signal, various control signals, and the touch sensing data in both directions, and the clock signal to the A pair of clock transmission lines (CTL) are provided for one-way transmission from the MCU to each SR-IC.

In addition, each SR-IC receives the register setting signal and various control signals from the MCU, a pair of pins for transmitting the touch sensing data to the MCU, and a pair for receiving the clock signal. Equipped with pins. In other words, each SR-IC receives the register setting signal and various control signals from the MCU, data transmission and reception buffers (Tx, Rx) for transmitting the touch sensing data to the MCU, and the clock signal to the MCU. It is equipped with a clock reception buffer (Rx) for receiving from the MCU. Accordingly, each SR-IC has four pins.

Each SR-IC receives image data from a timing controller and drives each data line.

Each of the SR-ICs according to the present invention includes an ROIC that reads a touch sensing signal, converts it into a digital signal, and transmits it to the MCU through the interface, receives the register setting signal and various control signals from the MCU, and a timing controller. It includes an SDIC that receives image data from and drives the data line.

Additionally, the MCU transmits a touch synchronization signal (TSYNCN) that defines a touch sensing section and an image data display section and a PWM signal (PWM_TX, PWM_DATA) for touch sensing to a plurality of SR-ICs.

Figure 5 is a schematic configuration diagram of ROIC according to the present invention.

As shown in FIG. 5, a channel multiplexer 11 receives touch signals from a plurality of touch sensing lines of the liquid crystal panel and selects and outputs one signal, and a touch signal output from the channel multiplexer 11. A pre-amplifier 12 that pre-amplifies, a S/H amplifier 13 that samples and holds and amplifies the pre-amplified touch signal, and the MCU through the clock transmission line (CTL). It is configured to include an A/D converter 14 that converts the touch signal output from the S/H amplifier 13 into a digital signal by a clock signal provided from and provides the digital signal to the MCU through the MLVDS interface.

The data transmission method of the touch panel liquid crystal display device according to the present invention configured as described above will be described as follows.

Figure 6 is an example protocol for transmitting data from the MCU to each SR-IC in the touch panel liquid crystal display device according to the present invention.

First, the transmission and reception mode of the MCU and each SR-IC is determined according to the touch synchronization signal (TSYNCN). That is, when the touch synchronization signal (TSYNCN) becomes a high section, the MCU switches to the transmission mode and each SR-IC switches to the reception mode. Conversely, when the touch synchronization signal (TSYNCN) is in the low section, the MCU switches to the reception mode and each SR-IC switches to the transmission mode.

Therefore, the protocol shown in FIG. 6 transmits from the MCU to each SR-IC through the pair of data transmission lines (DTL) in the high section of the touch synchronization signal (TSYNCN).

As shown in FIG. 6, the packet of the protocol for transmitting register setting signals and various control signals from the MCU to each SR-IC is a command designating one of the plurality of SR-ICs. ), an address that specifies an internal register, and data for setting the register. Accordingly, the packet is repeated to correspond to the number of SR-ICs.

For example, if the above command is “00”, it specifies the first SR-IC, if it is “01”, it specifies the second SR-IC,… If it is "05", it designates the last 6th SR-IC, and if it is "AA", it designates all SR-ICs.

Therefore, in order to individually transmit data to the plurality of SR-ICs, it consists of a packet including a command, an address, and data, and data common to all of the plurality of SR-ICs is transmitted. To transmit, it consists of a packet containing a command (“AA”), an address, and repeated data (Data).

Then, each SR-IC receives register setting data corresponding to its designated command through its receive buffer (Rx) and sets its register.

In this process, the order in which touch sensing data is transmitted is determined. For example, it is set to transmit touch sensing data in order from the first SR-IC to the last SR-IC.

Figure 7 is an example of a protocol for transmitting sensing data from a plurality of SR-ICs to an MCU in a touch panel liquid crystal display device according to the present invention.

The protocol for transmitting touch sensing data from each SR-IC to the MCU is as shown in FIG. 7.

As described above, the protocol shown in FIG. 7 transmits touch sensing data from each SR-IC to the MCU without a command in the low section of the touch synchronization signal ((TSYNCN)) through the pair of data transmission lines (DTL). is transmitted through.

That is, the MCU uses an internal counter to start transmitting touch sensing data shortly after the touch synchronization signal (TSYNCN) low signal (when digital conversion is completed in the A/D converter 14 of the ROIC), Preparations are made to receive the touch sensing data.

Meanwhile, as described in FIG. 5, the ROIC of each SR-IC is connected to the touch sensing electrodes (S11, S12, S13, S21, S22, S23, S31) at the low logic time of the touch synchronization signal (TSYNCN). , S32, S33) and convert it into a digital signal. Then, when the MCU is ready to receive touch sensing data, each SR-IC sequentially transmits touch sensing data through the data transmission line (DTL) with a certain delay time.

In Figure 7, Data(#1) is touch sensing data transmitted from the first SR-IC, Data(#2) is touch sensing data transmitted from the second SR-IC,... Data(#Last) is the touch sensing data transmitted from the last SR-IC.

In this way, data is transmitted and received between the MCU and each of the SR-ICs using an MLVDS interface through the pair of data transmission lines (DTL).

Therefore, even when there are six SR-ICs, only four pins are required for the MCU, and 24 transmission lines are required between the MCU and the six SR-ICs.

In addition, the clock transmission line (CTL) is provided between the MCU and the plurality of SR-ICs, so that the clock signal required when each SR-IC receives a touch signal and converts it into a digital signal is transmitted from the MCU to each of the plurality of SR-ICs. Provided for SR-ICs.

In this way, since the number of pins of the MCU and the number of transmission lines between the MCU and the six SR-ICs are reduced, the package of the IC is also reduced, and the LOG (Line On Glass) area is not greatly required. Since the width of each wiring can be increased, wiring resistance can be reduced and there are no space restrictions.

Additionally, EMI characteristics using the existing TTL method can be improved.

In addition, the present invention can be applied not only to in-cell touch panels, but also to display devices using separate ROICs, such as out-cell/on-cell.

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and it is commonly known in the technical field to which the present invention pertains that various substitutions, modifications, and changes can be made without departing from the technical spirit of the present invention. It will be clear to those who have the knowledge of.

Claims (11)

An MCU that provides a touch synchronization signal that defines the touch sensing section and the image data display section, a PWM signal for touch sensing, register setting data, clock signals, and various control signals;
The touch synchronization signal, the PWM signal, the register setting data, the clock signal, and the various control signals are received from the MCU, and image data is received from a timing controller during the image data display period according to the touch synchronization signal (TSYNCN). a plurality of SR-ICs that drive each data line and sequentially transmit touch sensing data to the MCU in the touch sensing section;
The register setting data and various control signals are transmitted from the MCU to the plurality of SR-ICs in the image data display section of the touch synchronization signal, and the touch sensing data is transmitted to the plurality of SR-ICs in the touch sensing section of the touch synchronization signal. A bidirectional data transmission line that sequentially transmits data from the SR-ICs to the MCU; and
A touch panel liquid crystal display device equipped with a clock transmission line for one-way transmission of the clock signal from the MCU to each SR-IC. According to claim 1,
The MCU is,
a data transmission buffer for transmitting the register setting data and the various control signals to each SR-IC through the bidirectional data transmission line;
a data data reception buffer for receiving the touch sensing data from each SR-IC through the bidirectional data transmission line;
A touch panel liquid crystal display device comprising a clock transmission buffer for transmitting the clock signal to each SR-IC through the clock transmission line. According to claim 1,
Each SR-IC above,
a data reception buffer for receiving the register setting data and various control signals from the MCU through the bidirectional data transmission line;
a data transmission buffer for transmitting the touch sensing data to the MCU through the bidirectional data transmission line;
A touch panel liquid crystal display device having a clock reception buffer for receiving the clock signal from the MCU through the clock transmission line. According to claim 1,
The protocol for transmitting the register setting data and the various control signals to each SR-IC through the bidirectional data transmission line includes an instruction designating one or all of the plurality of SR-ICs and an address designating an internal register. Wow, a touch panel liquid crystal display device consisting of data for setting the corresponding registers. According to claim 1,
The protocol for transmitting the touch sensing data from each SR-IC to the MCU through the bidirectional data transmission line is to transmit the plurality of SRs in a predetermined order in the touch sensing logic section of the touch synchronization signal (TSYNCN) without commands. -A touch panel liquid crystal display device that transmits data from IC at regular intervals. According to claim 1,
A touch panel liquid crystal display device in which the transmission and reception modes of the MCU and each SR-IC are switched by the touch synchronization signal. According to claim 6,
If it is a non-touch sensing logic section of the touch synchronization signal, the MCU switches to the transmission mode and each SR-IC switches to the reception mode. If it is a touch sensing logic section of the touch synchronization signal, the MCU switches to the reception mode and the Each SR-IC is a touch panel liquid crystal display device that switches to transmit mode. According to claim 1,
The MCU has one master block,
The master block transmits the register setting data and various control signals to each SR-IC, and a pair of pins for receiving touch sensing data from each SR-IC,
A touch panel liquid crystal display device having a pair of pins for transmitting the clock signal to each SR-IC. According to claim 1,
Each SR-IC receives the register setting data and various control signals from the MCU, and a pair of pins for transmitting the touch sensing data to the MCU,
A touch panel liquid crystal display device having a pair of pins for receiving the clock signal. According to claim 1,
Each SR-IC has an ROIC that reads the touch sensing signal, converts it into a digital signal, and transmits it to the MCU, receives the register setting data and various control signals from the MCU, and receives image data from the timing controller to provide data A touch panel liquid crystal display device that includes an SDIC that drives the lines. According to claim 10,
The ROIC is
a channel multiplexer that receives touch signals from a plurality of touch sensing lines of the display panel and selects and outputs one signal;
a pre-amplifier for pre-amplifying the touch signal output from the channel multiplexer;
a S/H amplifier that samples, holds, and amplifies the pre-amplified touch signal;
A touch panel including an A/D converter that converts a touch signal output from the S/H amplifier into a digital signal by a clock signal provided from the MCU through the clock transmission line and provides the digital signal to the MCU through the MLVDS interface. Liquid crystal display device.