WO2020103313A1 - Display device and display device load testing method - Google Patents

Abstract

A display device (10) and a display device (10) load testing method. By means of a timing controller (11) receiving and executing an eye pattern enlarging instruction output by an inner integrated circuit bus controller (13) to correspondingly output an eye pattern enlarging drive signal to a driving chip (14), influence on the determination of a load testing result due to the serious attenuation of a drive signal during the load testing of the display device (10) is avoided, thereby improving the accuracy of the load testing of the display device (10).

Description

Display device and method for on-load test of display device Technical field

The present application relates to the field of display technology, and in particular, to a display device and a method for on-load testing of a display device.

Background technique

After the display device is completed, it is necessary to judge the accuracy of the mass production code burned in the flash memory of the printed circuit board (Printed Circuit Board Assembly, PCBA) by the printing company. The mass production code includes various control circuits (timing on the printed circuit board) Control circuit, programmable gamma correction buffer circuit and digital power management integrated circuit, etc.) The data information required for operation. When judging the mass production code, you need to use a jumper to transmit the test signal output by the test equipment to the control circuit on the printed circuit board for processing, and the control circuit needs to run the mass production code to be in a working state to process the test signal. The test signal is transmitted to the drive circuit of the display panel, the drive circuit converts the processed test signal to light the display panel, and the accuracy of the mass production code is judged by the screen point of the display device, that is, the amount is judged by the method of on-load testing The accuracy of the production code.

However, as the resolution of the display device becomes higher and higher, the data transmission rate required by the display device also becomes higher and higher. When the actual application needs to be simulated to judge the accuracy of the mass production code, the test signal is transmitted to the printed circuit board The data transmission rate of the control circuit is the same as the actual application. When the test signal transmission rate is too high, the impedance of the jumper leads to serious signal attenuation, which will cause the drive signal transmitted to the drive circuit to be seriously attenuated, making the load The test failed to light up the picture smoothly, which affected the accuracy of mass production code judgment.

Therefore, it is necessary to propose a technical solution to solve the problem that the accuracy judgment of mass production codes is affected due to signal attenuation during load testing.

technical problem

The purpose of the present application is to provide a display device and a method for on-load testing of a display device, to solve the problem that the accuracy of mass production codes is affected due to signal attenuation during on-load testing.

Technical solution

A display device includes a timing controller, a flash memory chip, a driving chip, an internal integrated circuit bus controller, and a display panel, the timing controller and the flash memory chip, the driving chip, and the internal integrated circuit, respectively A bus controller is connected, the display panel is electrically connected to the driving chip,

The internal integrated circuit bus controller is used to output an eye diagram increase instruction to the timing controller;

The timing controller is used to read the mass production code required for the operation of the timing controller from the flash memory chip and run the mass production code required for the operation of the timing controller to be in a working state The timing controller is further used to receive and execute the eye diagram increase instruction to correspondingly output a drive signal with increased eye diagram to the drive chip;

The driving chip is used to convert the driving signal with the increased eye pattern to light up the display panel.

In the above display device, the timing controller includes:

An eye diagram increasing instruction receiving unit, configured to receive the eye diagram increasing instruction;

The eye diagram increasing instruction execution unit is configured to modify the code of the eye diagram register in the timing controller according to the eye diagram increasing instruction to increase the eye diagram code, and process the input image according to the eye diagram increasing code The test signal of the timing controller correspondingly outputs the driving signal for increasing the eye diagram, and the mass production code required for the operation of the timing controller includes the code of the eye diagram register.

In the above display device, the test signal is an image signal or a video signal.

In the above display device, the internal integrated circuit bus controller includes:

Detection unit for detecting high level;

The output unit is used for outputting the eye diagram increasing command through the internal integrated circuit bus after the detection unit detects a high level.

In the above display device, the display device further includes a power supply module, and the power supply module is used to output the high level to the detection unit.

In the above display device, the flash memory chip and the timing controller are connected through a serial peripheral device interface bus.

In the above display device, the driving signal with an increased eye pattern is a micro-swing differential signal with an increased eye pattern.

In the above display device, the micro-swing differential signal with the increased eye pattern has an eye pattern amplitude of 600-700 millivolts.

In the above display device, the micro-swing differential signal with the increased eye pattern has an eye pattern amplitude of 650 mV.

A method for on-load testing of a display device. The display device includes a timing controller, a flash memory chip, a driving chip, an internal integrated circuit bus controller, and a display panel. The timing controller is separately connected to the flash memory chip and the driver A chip and the internal integrated circuit bus controller are connected, the display panel is electrically connected to the driving chip, and the method for on-load testing of the display device includes the following steps:

After the display device is powered on, input a test signal to the timing controller through a jumper;

The timing controller reads from the flash memory chip the mass production code required for the timing controller to work and runs the mass production code required for the timing controller to operate in a working state;

The timing controller in the working state receives and executes the eye diagram increase instruction output by the internal integrated circuit bus controller to correspondingly output a drive signal with an increased eye diagram to the drive chip;

The driving chip converts the driving signal with the increased eye pattern to light up the display panel.

In the above method for on-load testing of a display device, the timing controller in the working state receives and executes an eye diagram increase instruction output by the internal integrated circuit bus controller to correspond to a driving signal for increasing the output eye diagram It includes the following steps:

The timing controller in the working state receives the eye diagram increasing instruction;

The timing controller modifies the code of the eye diagram register in the timing controller according to the eye diagram increasing instruction to obtain an eye diagram increasing code;

The timing controller processes the test signal according to the code for increasing the eye diagram to correspondingly output a driving signal for increasing the eye diagram;

Wherein, the mass production code required for the operation of the timing controller includes the code of the eye diagram register.

In the above method for on-load testing of a display device, the test signal is an image signal or a video signal.

In the above method for on-load testing of a display device, the method further includes the following steps: after the internal integrated circuit bus controller detects a high level, the eye pattern increase command is output to the internal integrated circuit bus via the internal integrated circuit bus The timing controller.

In the above method for on-load testing of a display device, the display device further includes a power supply module, and the power supply module outputs the high level to the internal integrated circuit bus controller.

In the above method for on-load testing of a display device, the flash memory chip and the timing controller are connected through a serial peripheral device interface bus.

In the above method for on-load testing of a display device, the driving signal with an increased eye pattern is a micro-swing differential signal with an increased eye pattern.

In the above method for on-load testing of a display device, the amplitude of the micro-swing differential signal with an increased eye diagram is 600-700 millivolts.

In the above method for on-load testing of a display device, the amplitude value of the micro-swing differential signal with an increased eye diagram is 650 mV.

Beneficial effect

The present application provides a display device and a method for on-load testing of a display device. The timing controller receives and executes an eye diagram increase command output by an internal integrated circuit bus controller to correspondingly output a drive signal with an increased eye diagram to the drive chip. It is avoided that the drive device is seriously attenuated when the on-load test is performed on the display device, which affects the judgment of the on-load test result, thereby improving the accuracy of the on-load test of the display device.

BRIEF DESCRIPTION

FIG. 1 is a display device according to an embodiment of the application;

FIG. 2 is a schematic flow chart of the display device shown in FIG. 1 performing on-load testing.

Embodiments of the invention

The technical solutions in the embodiments of the present application will be described clearly and completely in conjunction with the drawings in the embodiments of the present application. Obviously, the described embodiments are only a part of the embodiments of the present application, but not all the embodiments. Based on the embodiments in the present application, all other embodiments obtained by those skilled in the art without making creative work fall within the protection scope of the present application.

Please refer to FIG. 1, which is a display device 10 according to an embodiment of the present application. The display device 10 includes a timing controller 11, a flash memory chip 12, a driving chip 14, an internal integrated circuit bus controller 13 and a display panel 15. The timing controller 11 It is connected to the flash memory chip 12, the driving chip 14 and the internal integrated circuit bus controller (I ² C-bus Control, Inter-Integrated Circuit Bus Control) 13, and the display panel 15 is electrically connected to the driving chip 14,

The internal integrated circuit bus controller 13 is used to output the eye diagram increase command to the timing controller 11;

The timing controller 11 is used to read the mass production code required for the operation of the timing controller 11 from the flash memory chip 12 and run the mass production code required for the operation of the timing controller 11 to be in the working state, and the timing controller 11 in the working state It is also used to receive and execute the eye diagram increasing instruction to correspondingly output the driving signal for increasing the eye diagram to the driving chip;

The driving chip is used to convert the driving signal of the increased eye pattern to light up the display panel 15.

What needs to be understood is that for digital signals, there are multiple sequence combinations of high-level and low-level changes. In terms of timing, enough sequences are aligned at a certain reference point, and then the waveforms of the sequences are superimposed to form an eye. Figure.

The driving chip is composed of a source driving chip 142 and a gate driving chip 141. The driving chip is located on a flip chip (not shown). The flip chip is connected to the display panel 15 through an anisotropic conductive adhesive. The printed circuit board with the timing controller 11 is connected.

The above-mentioned display device receives and executes the eye diagram increase command output by the internal integrated circuit bus controller through the timing controller to correspondingly output the drive signal with the increased eye diagram to the drive chip, to avoid serious attenuation of the drive signal during the on-load test of the display device And it affects the judgment of the load test result, thereby improving the accuracy of the load test of the display device.

Further, the timing controller 11 includes:

The eye diagram increasing instruction receiving unit is used to receive an eye diagram increasing instruction;

The eye diagram increase instruction execution unit is used to modify the code of the eye diagram register in the timing controller 11 according to the eye diagram increase instruction to increase the eye diagram code, and process the test input to the timing controller 11 according to the increased eye diagram code The signal corresponds to the drive signal for increasing the output eye diagram, and the mass production code required for the operation of the timing controller 11 includes the code of the eye diagram register.

When the timing controller 11 reads the mass production code required for the operation to be in the working state, the code of the eye diagram register in the timing controller 11 is modified according to the eye diagram increase instruction to store the code for increasing the eye diagram in the eye diagram register, namely When the timing controller 11 is in the working state, modify the code in the eye diagram register to obtain a code that can increase the eye diagram. When the timing controller 11 processes the test signal according to the modified code, it can increase the driving signal output by the timing controller Eye diagram to overcome the problem of drive signal attenuation.

This application takes into account that the purpose of on-load testing is to test the correctness of the mass production code in the flash memory chip 12 of the display device 10, and the mass production code in the flash memory chip 12 has been verified by multiple tests and proved to be a reasonable code, directly modifying the flash memory The production code of the chip 12 to increase the eye diagram of the drive signal will cause the display device to fail the Electromagnetic Interference (EMI) test, so the production code of the flash memory chip 12 cannot be directly modified to increase the eye diagram of the drive signal . This application modifies the code in the eye diagram register in the timing controller 11 online when the timing controller 11 reads the mass production code required for its work to be in the working state to obtain the enlarged eye diagram code. This modification will not affect To the judgment of the mass production code in the flash memory chip 12.

Further, the internal integrated circuit bus controller 13 includes:

Detection unit for detecting high level;

The output unit is used to output an eye diagram increase command through the internal integrated circuit (Inter-Integrated Circuit, I ² C) bus after the detection unit detects a high level.

In this application, the high level is a switch signal designed specifically for the on-load test of the display device 10. When the internal integrated circuit bus controller 13 receives the high level, the internal integrated circuit bus controller 13 sends a signal to the timing controller 11 Output the eye diagram increase instruction to modify the code in the eye register of the timing controller 11 online to achieve the purpose of increasing the eye diagram; when the display device 10 is powered off, the integrated circuit bus controller 13 cannot receive the high level , The code in the eye diagram register is restored to the unmodified code.

Furthermore, the display device 10 further includes a power module (not shown), which is used to output a high level to the detection unit.

Further, the flash memory chip 12 and the timing controller 11 are connected through a serial peripheral interface (Serial Peripheral Interface, SPI) bus.

Further, the test signal is an analog signal such as an image signal or a video signal, and is input to the timing controller 11 through a corresponding interface on the printed circuit board. The test signal may also be other analog voltage signals, which is not specifically limited in this application.

Further, the driving signal with increased eye diagram is a reduced swing differential signal (RSDS) with increased eye diagram, and the timing controller 11 outputs the RSDS signal with increased eye diagram to the source driver chip 142, Specifically, the RSDS signal with an increased eye pattern has an eye pattern amplitude of 600-700 mV, for example, the RSDS signal with an increased eye pattern has an eye pattern amplitude of 650 mV.

As shown in FIG. 2, it is a schematic flow chart of the on-load test of the display device 10 shown in FIG. 1. The display device 10 includes a timing controller 11, a flash memory chip 12, a driving chip 14, an internal integrated circuit bus controller 13 and a display panel 15. The timing controller 11 is respectively connected to the flash memory chip 12, the driving chip 14 and the internal integrated circuit bus controller 13, the display panel 15 is electrically connected to the driving chip 14, and the display device 10 on-load test method includes the following steps:

S20: After the display device 10 is powered on, input a test signal to the timing controller 11 through a jumper;

S21: The timing controller 11 reads the mass production code required for the operation of the timing controller 11 from the flash memory chip 12 and runs the mass production code required for the operation of the timing controller 11 to be in a working state;

S22: The timing controller 11 in the working state receives and executes the eye diagram increase instruction output by the internal integrated circuit bus controller 13 to correspondingly output the drive signal with the increased eye diagram to the drive chip 14;

S23: The driving chip 14 converts the driving signal with an increased eye pattern to light up the display panel 15.

Further, the timing controller 11 in the working state receives and executes the eye diagram increase instruction output by the internal integrated circuit bus controller 13 to correspond to the output driving signal of the increase in the eye diagram, including the following steps:

The timing controller 11 in the working state receives the eye diagram increasing instruction;

The timing controller 11 modifies the code of the eye diagram register in the timing controller 13 according to the eye diagram increasing instruction to obtain the code for increasing the eye diagram;

The timing controller 11 processes the test signal according to the code for increasing the eye pattern to correspond to the drive signal for increasing the output eye pattern;

Wherein, the mass production code required for the operation of the timing controller 11 includes the code of the eye diagram register.

Further, the above method further includes the following steps: after the internal integrated circuit bus controller 13 detects a high level, an eye diagram increase instruction is output to the timing controller 11 through the internal integrated circuit bus.

Furthermore, the above display device 10 further includes a power supply module (not shown), and the power supply module outputs a high level to the internal integrated circuit bus controller 13.

Further, the flash memory chip 12 and the timing controller 11 are connected through a serial peripheral device interface bus.

Further, the test signal is an analog signal such as an image signal or a video signal, and is input to the timing controller 11 through a corresponding interface on the printed circuit board. The test signal may also be other analog voltage signals, which is not specifically limited in this application.

Further, the driving signal with an increased eye diagram is a micro-swing differential signal with an increased eye diagram, and the timing controller 11 outputs the RSDS signal with an increased eye diagram to the source driver chip 142. Specifically, the increased eye diagram The amplitude of the eye pattern of the RSDS signal is 600-700 mV. For example, the amplitude of the eye pattern of the RSDS signal with an increased eye pattern is 650 mV.

The above-mentioned display device on-load test method receives and executes the eye diagram increase command output by the internal integrated circuit bus controller through the timing controller to correspondingly output the drive signal with increased eye diagram to the drive chip, to avoid the display device performing on-load test Because the driving signal is severely attenuated, the judgment of the on-load test result is affected, thereby improving the accuracy of the on-load test of the display device.

The descriptions of the above embodiments are only used to help understand the technical solutions and core ideas of the present application; those of ordinary skill in the art should understand that they can still modify the technical solutions described in the foregoing embodiments or some of the technologies Features are equivalently replaced; and these modifications or replacements do not deviate from the scope of the technical solutions of the embodiments of the present application of the essence of the corresponding technical solutions.

Claims (18)

1. A display device, wherein the display device includes a timing controller, a flash memory chip, a driving chip, an internal integrated circuit bus controller, and a display panel, the timing controller and the flash memory chip, the driving chip, and the The internal integrated circuit bus controller is connected, the display panel is electrically connected to the driving chip,

   The internal integrated circuit bus controller is used to output an eye diagram increase instruction to the timing controller;

   The timing controller is used to read the mass production code required for the operation of the timing controller from the flash memory chip and run the mass production code required for the operation of the timing controller to be in a working state The timing controller is further used to receive and execute the eye diagram increase instruction to correspondingly output a drive signal with increased eye diagram to the drive chip;

   The driving chip is used to convert the driving signal with the increased eye pattern to light up the display panel.
2. The display device according to claim 1, wherein the timing controller comprises:

   An eye diagram increasing instruction receiving unit, configured to receive the eye diagram increasing instruction;

   The eye diagram increasing instruction execution unit is configured to modify the code of the eye diagram register in the timing controller according to the eye diagram increasing instruction to increase the eye diagram code, and process the input image according to the eye diagram increasing code The test signal of the timing controller correspondingly outputs the driving signal for increasing the eye diagram, and the mass production code required for the operation of the timing controller includes the code of the eye diagram register.
3. The display device according to claim 2, wherein the test signal is an image signal or a video signal.
4. The display device according to claim 1, wherein the internal integrated circuit bus controller comprises:

   Detection unit for detecting high level;

   The output unit is used for outputting the eye diagram increasing command through the internal integrated circuit bus after the detection unit detects a high level.
5. The display device according to claim 4, wherein the display device further comprises a power supply module for outputting the high level to the detection unit.
6. The display device according to claim 1, wherein the flash memory chip and the timing controller are connected through a serial peripheral interface bus.
7. The display device according to claim 1, wherein the driving signal with an increased eye pattern is a micro-swing differential signal with an increased eye pattern.
8. The display device according to claim 7, wherein the micro-swing differential signal with the increased eye pattern has an eye pattern amplitude of 600-700 mV.
9. The display device according to claim 8, wherein the micro-swing differential signal with the increased eye pattern has an eye pattern amplitude of 650 mV.
10. A method for on-load testing of a display device, wherein the display device includes a timing controller, a flash memory chip, a driving chip, an internal integrated circuit bus controller, and a display panel, the timing controller and the flash memory chip, respectively The driving chip and the internal integrated circuit bus controller are connected, the display panel is electrically connected to the driving chip, and the display device on-load test method includes the following steps:

    After the display device is powered on, input a test signal to the timing controller through a jumper;

    The timing controller reads from the flash memory chip the mass production code required for the timing controller to work and runs the mass production code required for the timing controller to operate in a working state;

    The timing controller in the working state receives and executes the eye diagram increase instruction output by the internal integrated circuit bus controller to correspondingly output a drive signal with an increased eye diagram to the drive chip;

    The driving chip converts the driving signal with the increased eye pattern to light up the display panel.
11. The method for on-load test of a display device according to claim 10, wherein the timing controller in the working state receives and executes an eye diagram increase instruction output by the internal integrated circuit bus controller to correspond to the output eye The driving signal of the enlarged figure includes the following steps:

    The timing controller in the working state receives the eye diagram increasing instruction;

    The timing controller modifies the code of the eye diagram register in the timing controller according to the eye diagram increasing instruction to obtain an eye diagram increasing code;

    The timing controller processes the test signal according to the code for increasing the eye diagram to correspondingly output a driving signal for increasing the eye diagram;

    Wherein, the mass production code required for the operation of the timing controller includes the code of the eye diagram register.
12. The method for on-load testing of a display device according to claim 11, wherein the test signal is an image signal or a video signal.
13. The method for on-load testing of a display device according to claim 10, wherein the method further comprises the step of: after the internal integrated circuit bus controller detects a high level, the eye The graph increase instruction is output to the timing controller.
14. The method for on-load testing of a display device according to claim 13, wherein the display device further comprises a power supply module, and the power supply module outputs the high level to the internal integrated circuit bus controller.
15. The method for on-load testing of a display device according to claim 10, wherein the flash memory chip and the timing controller are connected through a serial peripheral interface bus.
16. The method for on-load testing of a display device according to claim 10, wherein the driving signal with an increased eye pattern is a micro-swing differential signal with an increased eye pattern.
17. The method for on-load testing of a display device according to claim 16, wherein the micro-swing differential signal with the increased eye pattern has an eye pattern amplitude of 600-700 mV.
18. The method for on-load testing of a display device according to claim 17, wherein the amplitude value of the micro-swing differential signal with an increased eye diagram is 650 mV.