KR20170064643A - Apparatus for Transmitting and Receiving Data and Display Device Having The Same - Google Patents

Abstract

The data transmitting and receiving apparatus according to the present invention includes a master, first and second slaves. The master transmits the SCLK through the first channel and the MOSI signal including the Address and Command through the second channel. The first slave responds to the MOSI from the second channel and sends MISO1 corresponding to the Command to the master via the third channel. The second slave responds to the MOSI from the second channel and sends MISO2 corresponding to the Command to the master via the fourth channel. The first slave transmits MISO1 during the first period. The second slave counts the SCLK to determine the elapsed time of the first period, and transmits the MISO2 during the second period after the first period elapses.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a data transmission / reception device,

The present invention relates to a data transmission / reception device and a touch sensor built-in display device including the same.

A Serial Peripheral Interface (SPI) is a protocol for serial communication between an MCU and a peripheral device. The SPI allows full duplex communication and allows easy control of transmit and receive bits. And the advantage is that the interface is simple. The SPI also allows one MCU to communicate with multiple slaves. However, in order for one MCU to communicate with a plurality of slaves, the communication channel between the MCU and the slave must be individually made, or the address and the command must be separately transmitted to each slave. It is inconvenient to redesign the MCU in order to individually communicate between the MCU and the slave. Or a method of separately transmitting an address and a command to each slave requires a long communication time.

SPI communication is also applied to a display device. For example, the SPI communication is used as a communication protocol between an SRIC for acquiring touch data and an MCU for calculating touch coordinates in a touch sensing built-in display device.

The SRIC acquires the touch data from the touch sensors and transmits it to the MCU through SPI communication. As the display panel becomes larger, the number of touch sensors of the display panel also increases, and accordingly, the number of SRICs that drive touch sensors and acquire touch data is also increasing. As the SRIC increases, it is necessary to set the communication path between the MCU and the SRIC. To do so, it is necessary to redesign the communication channel or individually input an address and a command to each SRIC. That is, if the SPI communication is to be used in response to the increasing SRIC, the MCU must be redesigned or the communication time consuming method should be used.

An object of the present invention is to provide a data transmission / reception device and a touch sensor built-in type display device in which one MCU can perform SPI communication with a plurality of slaves without reducing the communication time without redesigning the MCU.

In order to achieve the above object, a data transmitting and receiving apparatus according to the present invention includes a master, first and second slaves. The master transmits the SCLK through the first channel and the MOSI signal including the Address and Command through the second channel. The first slave responds to the MOSI from the second channel and sends MISO1 corresponding to the Command to the master via the third channel. The second slave responds to the MOSI from the second channel and sends MISO2 corresponding to the Command to the master via the fourth channel. The first slave transmits MISO1 during the first period. The second slave counts the SCLK to determine the elapsed time of the first period, and transmits the MISO2 during the second period after the first period elapses.

In the touch sensor built-in type display device according to the present invention, the MCU can perform SPI communication with two or more SRICs using one address and a command. Therefore, it is possible to reduce the time required to input Address and Command to each SRIC. The present invention can simultaneously communicate with two or more SRICs using a conventional MCU without changing the design of the MCU.

1 is a view showing a data transmitting and receiving apparatus according to the present invention;
2 shows a communication protocol between the master and the first and second slaves shown in Fig. 1; Fig.
3 is a view showing a touch sensor built-in display device according to the present invention.
Fig. 4 is an enlarged view of a part of the pixel array in Fig. 3; Fig.
5 is a diagram showing a communication relationship between the MCU and the SRIC according to the present invention;
6 is a diagram showing an example of first and second SRIC addresses;
7 and 8 are views showing a reading process in an SPI communication between the MCU and the first and second SRICs.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. Like reference numerals throughout the specification denote substantially identical components. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS In the following description, a detailed description of known technologies or configurations related to the present invention will be omitted when it is determined that the gist of the present invention may be unnecessarily obscured. In addition, the component names used in the following description may be selected in consideration of easiness of specification, and may be different from the parts names of actual products.

FIG. 1 shows a data transmitting and receiving apparatus according to the present invention, and FIG. 2 is a timing chart of signals used by the data transmitting and receiving apparatus shown in FIG.

1 and 2, the data transmitting / receiving apparatus according to the present invention includes a master, a first slave SLAVE1, and a second slave SLAVE2.

The master MASTER simultaneously transmits SCLK to the first slave SLAVE1 and the second slave SLAVE2 via the first channel 1 and transmits MOSI through the second channel 2. [ Then, the master transmits the SSN to the first slave SLAVE1 and the second slave SLAVE2 via the fifth channel 5. The first channel 1 to the third channel 3 are signal transmission lines having directional lines through which signals are transmitted from the master to the first slave SLAVE1 and the second slave SLAVE2.

SCLK is a synchronous clock. MOSI includes Address and Command. SSN is a signal to select a slave.

The first slave SLAVE1 transmits MISO1 to the master in response to MOSI from the second channel 2. [ The first slave SLAVE1 transmits MISO1 for a first period of time through the third channel 3. The MISO1 includes first data corresponding to a command transmitted by the master (MASTER).

The second slave SLAVE2 transmits the MISO2 to the master in response to the MOSI from the second channel 2. [ The second slave SLAVE2 transmits the MISO2 for a second period of time via the third channel 3. The second slave SLAVE2 counts the SCLK to determine the elapsed time point of the first period and transmits the MISO2 during the second period after the first period has elapsed.

3 is a view showing a touch sensor built-in display device according to the present invention. 4 is a view showing pixels included in a touch sensor, and FIG. 5 is a diagram showing a driving signal applied to each signal line. In FIGS. 3 and 5, although the touch sensors and the sensing lines are individually designated by reference numerals, the touch sensor TC and the sensing line TW I will explain.

3 to 5, a touch sensor built-in display device according to the present invention includes a display panel 100, a host system 105, a timing controller 110, a data driver 120, a gate driver 130, an ROIC (200) and an MCU (300).

In the display panel 100, the pixels P and the touch sensors TC are disposed. The display panel 100 includes an upper substrate and a lower substrate opposed to each other with the liquid crystal layer LC therebetween. The pixel array of the display panel 100 includes the data lines DL, the gate lines GL, the thin film transistors TFT formed at the intersections of the data lines DL and the gate lines GL, A pixel electrode 5 connected to the pixel electrode 5, and a storage capacitor Cst connected to the pixel electrode 5, and the like. The thin film transistor TFT is turned on in response to the gate pulse from the gate line GL to supply the data voltage applied to the pixel electrode 5 through the data line DL. The liquid crystal layer LC is driven by a voltage difference between a data voltage charged in the pixel electrode 5 and a common voltage Vcom applied to the touch common electrode 7 to control the amount of light transmitted.

The touch sensor TC is connected to a plurality of pixels and is implemented as a capacitance type to sense a touch input. A plurality of pixels P are coupled to each touch sensor TC. FIG. 4 shows a case where nine pixels P arranged in a 3x3 matrix are assigned to one touch sensor TC. The common electrode 7 is divided into units of touch sensors TC so that the area occupied by the common electrode 7 can be referred to as a touch sensor TC. Each of the touch sensors TC is connected to the sensing lines TW one by one. For example, a sensing line TW [1,1] of one row and one column is connected to the touch sensor TC [1,1] of one row and one column, ) Are connected to the sensing lines TW [1,2] of one row and two columns.

The common electrode 7 receives the common voltage Vcom, which is a reference voltage of the pixels during the display period, and receives the touch driving voltage during the touch sensing period.

The timing controller 110 inputs a timing signal such as a vertical synchronization signal Vsync, a horizontal synchronization signal Hsync, a data enable signal DE and a main clock MCLK input from the host system 105 And synchronizes the operation timings of the data driver included in the SRIC and the gate driver 130 with each other. The gate timing control signal includes a gate start pulse (GSP), a gate shift clock, a gate output enable signal (GOE), and the like. The data timing control signal includes a source sampling clock (SSC) and a source output enable (SOE) signal.

The host system 105 may be implemented as any one of a television system, a set-top box, a navigation system, a DVD player, a Blu-ray player, a personal computer (PC), a home theater system, and a phone system. The host system 105 converts the digital video data RGB of the input image into a format suitable for display on the display panel DIS, including a system on chip (SoC) with a built-in scaler. The host system 105 transmits timing signals (Vsync, Hsync, DE, MCLK) to the timing controller 110 together with the digital video data. In addition, the host system 105 executes an application program associated with coordinate information (Txy) of touch data input from the MCU 300. [

The data driver 120 receives image data from the timing controller, converts the image data into a positive / negative gamma compensation voltage, and outputs a positive / negative data voltage. The data voltage is supplied to the data lines DL.

The gate driver 130 sequentially supplies gate pulses to the gate lines GL under the control of the timing controller. The gate pulse output from the gate driver is synchronized with the data voltage. The gate driver may be formed on the lower substrate of the display panel 100 together with the pixel array in a gate in panel (GIP) process.

The ROIC 200 stores the touch data (Tdata) obtained by driving the touch sensor (TC) in the buffer memory. Then, the ROIC 200 reads the previous touch data from the buffer memory and transmits the touch data (Tdata) to the MCU 40.

The MCU 40 executes a preset touch recognition algorithm. Any known algorithm for the touch recognition algorithm is possible. The touch recognition algorithm compares the touch primitive data input from the sensing unit 34 with a predetermined threshold value, and determines that the touch primitive data exceeding the threshold value is the touch input data obtained from the touch sensors at the touch input position. The touch recognition algorithm assigns an identification code to each of the touch input data of a threshold value or more and calculates coordinates of each of the touch input positions. The MCU 40 transmits the identification code of each touch input data and the touch coordinate information Txy to the host system 105. [

5 is a diagram illustrating a process of an MCU receiving touch data according to an embodiment of the present invention. FIG. 5 illustrates a display device of FIG. 3 using an SRIC incorporating a data driver and an ROIC. 5 shows a display panel in which 80 touch sensors TC are arranged in the horizontal direction and 45 are arranged in the column direction

Referring to FIG. 5, the SRIC unit 210 includes first to eighth SRICs (SRIC1 to SRIC8). The first to eighth SRICs (SRIC1 to SRIC8) acquire touch data (Tdata) of the touch sensors (TC) arranged in ten columns, respectively. For example, the first SRIC 211 acquires the touch data (Tdata) of the 10 × 45 'touch sensors (TC) arranged in the first column (C1) to the tenth column (C10).

The first SRIC 211 includes 50 9: 1 multiplexers. Each of the multiplexers is connected to the touch sensors TC arranged in the same column as the same row in each of the first to ninth touch groups GR1 to GR9. As a result, the first SRIC 211 acquires 50 touch data (Tdata) at a time. For example, the first SRIC 211 acquires the first touch data of the 50 touch sensors TC belonging to the first touch group GR1, and sequentially acquires the first touch data of the first touch group GR1 belonging to the second to ninth touch groups GR2 to GR9 And acquires second to ninth touch data belonging to the same.

The second SRIC 212 similarly acquires the second touch data. That is, although not shown in FIG. 5, the second SRIC 212 acquires touch data (Tdata) of '10 × 45' touch sensors (TC) arranged in the 11th to 20th columns.

  Then, the first to eighth SRICs (SRIC1 to SRIC8) transmit the obtained touch data to the MCU 300.

 The first to eighth SRICs SRIC1 to SRIC8 drive the touch sensor TC through the SPI communication with the MCU 300 and acquire touch data and transmit the touch data to the MCU 300. [

The MCU 300 includes first to fourth masters (MASTER), and each master performs SPI communication concurrently with a pair of SRICs. Hereinafter, the SPI communication between the MCU 300 including the first master and the first SRIC 211 and the second SRIC 212 will be described.

6 is a diagram showing an example of an address of a buffer memory and a register of the first SRIC and the second SRIC.

A process of acquiring the touch data by the first SRIC 211 and the second SRIC 212 in response to an instruction of the MCU 300 will be described below. The SM input pin of the first SRIC 211 is fixed to '0' and the SM input pin of the second SRIC 212 is fixed to '1'. In the process of transmitting the MISO to the MISO receiving terminal of the MCU 300, the first SRIC 211 and the second SRIC 212 determine the MISO transmission order according to the first SM input pin and the second SM input pin information. The present invention describes an embodiment in which the first SRIC 211 first transmits MISO1 and the second SRIC 212 transmits MISO2.

The MCU 300 simultaneously transmits the SCLK to the first SRIC 211 and the second SRIC 212 via the first channel 1 and transmits the MOSI through the second channel 2. Then, the MCU 300 transmits the SSN to the first SRIC 211 and the second SRIC 212 through the fifth channel 5. The SSN maintains a low level during the first period PE1 and the second period PE2.

The address of the first SRIC 211 register and the address of the second SRIC 212 include the common address '300'. In order to designate the first SRIC 211 and the second SRIC 212 at the same time in the process of issuing the write operation, the address of MOSI includes '300'. And MOSI's Command includes "Write Command".

The first SRIC 211 responds to the common address value of the MOSI and drives the touch sensors TC in response to the " write command " included in the command to acquire the first touch data Tdata. Then, the first SRIC 211 stores '50' touch data in the first buffer memory SBUF1 shown in FIG. Similarly, the second SRIC 212 responds to the common address value of the MOSI, drives the touch sensors TC of the second touch group GR2 in response to the " write command " included in the command, (Tdata). The second SRIC 212 stores the second touch data Tdata in the second buffer memory SBUF.

In order to operate only the second SRIC 212, the MCU can designate '1300' as the address.

 8 is a schematic diagram showing that the first SRIC 211 and the second SRIC 212 transmit the first touch data Tdata and the second touch data, respectively. A process of receiving the first touch data Tdata1 and the second touch data Tdata2 from the first SRIC 211 and the second SRIC 212 by the MCU 300 will be described. The MCU 300, the first SRIC 211 and the second SRIC 212 use the SPI communication protocol shown in FIG.

The first SRIC 211 and the second SRIC 212 have an ALIGNED SBUF of '0000'. The ALIGNED SBUF is an address that can designate the first SRIC 211 and the second SRIC 212 at the same time.

The MCU 300 simultaneously transmits the SCLK to the first SRIC 211 and the second SRIC 212 via the first channel 1 and transmits the MOSI through the second channel 2. Then, the MCU 300 transmits the SSN to the first SRIC 211 and the second SRIC 212 through the fifth channel 5. The SSN maintains a low level during the first period PE1 and the second period PE2.

In order for the MCU 300 to receive touch data from both the first SRIC 211 and the second SRIC 212, the address of the MOSI includes an ALIGNED SBUF '0000' Command '.

The first SRIC 211 responds to the ALIGNED SBUF and transmits the first data stored in the first buffer memory SBUF1 through the MISO1 in response to the 'read command' included in the command. The first SRIC 211 transmits the first touch data Tdata to the MCU 300 during the first period PE1.

The second SRIC 212 responds to the ALIGNED SBUF and transmits the second data stored in the second buffer memory SBUF2 through the MISO2 in response to the 'read command' included in the command. The second SRIC 212 transmits the second touch data Tdata to the MCU 300 during the second period PE2. The second SRIC 212 counts the SCLK to determine the elapsed time of the first period PE1. The second SRIC 212 floats the MISO2 output during the first period PE1 and then transmits the second touch data during the second period PE2.

The MCU 300 of the present invention can designate a specific SRIC so that only the corresponding SRIC can retransmit the touch data. Generally, all the touch sensors TC are driven the same number of times, but the number of times of sensing can be increased in a region where the sensing sensitivity is lowered as in the case of the outside of the display panel 100. 9, the MCU 300 designates the address '1100' of the buffer memory of the second SRIC 212 as the address of the MOSI in the case of attempting to re-receive the touch data only from the second SRIC 212 do.

The second SRIC 212 transmits the second touch data Tdata in the MISO 2 (MISO 2) in response to the '1100' address.

As described above, the MCU according to the present invention can perform SPI communication with a plurality of SRICs without decoding an address for each SRIC. Conventionally, in order to perform two or more SRIC and SPI communication, one MCU must communicate with each SRIC individually, and the address and command must be separately transmitted to each SRIC.

On the other hand, the present invention can perform SPI communication with two or more SRICs using one Address and Command. Therefore, it is possible to reduce the time required to input Address and Command to each SRIC. In addition, the present invention can simultaneously communicate with two or more SRICs using a conventional MCU without changing the design of the MCU.

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.

5: pixel electrode 7: common electrode
TC: Touch sensor TW: Sensing line
105: Host 110: Timing controller
120: Data driver 130: Gate driver
200: ROIC 300: MCU

Claims (10)

A master transmitting SCLK through a first channel and transmitting an MOSI signal including an Address and a Command via a second channel;
A first slave transmitting, in response to the MOSI from the second channel, MISO1 corresponding to the Command to the master via a third channel; And
And a second slave transmitting, in response to the MOSI from the second channel, the MISO2 corresponding to the Command to the master via a fourth channel,
The first slave transmits the MISO1 for a first period,
Wherein the second slave counts the SCLK to determine an elapsed time of the first period and transmits the MISO2 during a second period after the first period elapses. The method according to claim 1,
Wherein the master outputs an SSN selecting the first slave or the second slave through a fifth channel, and transmits the SSN at a low level during the first and second periods. The method according to claim 1,
Wherein the first slave includes a first SM input pin and transmits the MISO1 during the first period according to a preset operation of a first SM input pin,
Wherein the second slave includes a second SM input pin and transmits the MISO2 during the second period according to a preset operation of the second SM input pin. A first SRIC for driving a first touch sensor group to acquire first touch data;
A second SRIC for driving a second touch sensor group to acquire second touch data; And
And an MCU receiving the first touch data and the second touch data and calculating touch input coordinates in the first and second touch sensor groups,
The MCU transmits an SCLK through a first channel, an MOSI including an Address and a command through a second channel to the first and second SRICs,
Wherein the first SRIC transmits the first touch data to the MCU in response to the MOSI,
Wherein the second SRIC transmits the first touch data to the MCU in response to the MOSI,
The first SRIC transmits the touch data during a first period,
Wherein the second SRIC counts the SCLK to determine an elapsed time of the first period and transmits the second touch data to the MCU during a second period after the first period elapses, . 5. The method of claim 4,
The MCU outputs an SSN for selecting the first SRIC or the second SRIC through the fifth channel, and transmits the SSN at a low level during the first and second periods. 5. The method of claim 4,
Wherein the first SRIC includes a first SM input pin and transmits the first touch data during the first period according to a preset operation of a first SM input pin,
Wherein the second SRIC includes a second SM input pin and transmits the second touch data during the second period according to an operation setting of a second SM input pin set in advance. 5. The method of claim 4,
Wherein the first SRIC comprises a first register having a first register Address,
The second SRIC comprising a second register having a second register Address,
Wherein the first SRIC acquires the first touch data in response to a first register address included in the MOSI,
And the second SRIC acquires the second touch data in response to a second register address included in the MOSI. 8. The method of claim 7,
The first and second registers Address include a common register Address,
Wherein the first and second SRICs acquire touch data of the first and second touch sensor groups, respectively, in response to the common register address included in the MOSI. 5. The method of claim 4,
Wherein the first SRIC includes a first buffer memory for storing the first touch data,
The second SRIC includes a second buffer memory for storing second touch data,
The first SRIC transmits the first touch data to the MCU in response to the address of the first buffer memory included in the MOSI,
And the second SRIC transmits the second touch data to the MCU in response to an address of the second buffer memory included in the MOSI. 10. The method of claim 9,
Wherein the first buffer memory and the second buffer memory include an alignment buffer Address having the same value,
Wherein the first and second SRIC sequentially transmit the first touch data and the second touch data to the MCU in response to the aligned address included in the MOSI.

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