KR20130084765A - Display controller and display controlling method - Google Patents

Abstract

PURPOSE: A display controller and a display controlling method are provided to insert a middle porch among display regions when an external device is expected to operate, thereby enabling design of the external device without consideration for display noise. CONSTITUTION: A display controlling method in a display system comprises the steps of: inputting image data and a display signal; increasing frequency of a clock based on operation information of a display device; and outputting display data corresponding to the image data using the clock having the increased frequency. At least one middle porch (MP) is inserted among display regions that output the display data based on the display signal. The at least one middle porch is inserted between a front porch (FP) and a back porch (FP).

Description

Display controller and display control method {DISPLAY CONTROLLER AND DISPLAY CONTROLLING METHOD}

The present invention relates to a display controller and a display control method.

Display devices included in data processing devices (eg, mobile terminals) continue to be enlarged due to the development of communication speeds and demands for a variety of functions (eg, web browsing, etc.). In particular, in order to increase the display area within a predetermined size, there is a method of embedding a keypad or a direction key in the display unit. For this, a touch screen panel is required.

In general, in the case of a mobile terminal, a host controller, which may be referred to as a baseband processor or an application processor, may separately use a touch screen controller and a display drive IC. To control. In general, in the case of a mobile terminal, each component must be designed to be strong against display noise.

SUMMARY OF THE INVENTION An object of the present invention is to provide a display controller and display control method capable of designing a device without having to consider display noise.

It is an object of the present invention to provide a display controller for providing a middle porch and a display control method thereof.

A display control method of a display system according to an exemplary embodiment of the present invention includes receiving image data and a display signal; Increasing the frequency of the clock based on operation information of the at least one device; Outputting display data corresponding to the image data using the clock having the increased frequency; And inserting at least one middle porch between display regions for outputting the display data based on the display signal.

In an embodiment, the display signal is a vertical synchronization signal.

The front porch may be inserted at the front end of the display signal and the back porch may be inserted at the rear end of the display signal.

In an embodiment, inserting the at least one middle porch may include: generating a redundancy porch by removing or reducing the back porch; And inserting a middle porch in response to an interrupt INT or a command CMD.

In one embodiment, the at least one device is a touch screen.

The method may further include receiving an interrupt or a command CMD from the at least one device.

The method may further include increasing the frequency of the clock in response to the interrupt INT or command CMD.

The inserting the at least one middle porch may include: determining whether the middle porch may be inserted into a current frame in response to the interrupt (INT) or command (CMD); And when it is difficult to insert the middle porch into the frame, inserting the middle porch into the next frame.

In an embodiment, the at least one middle porch includes a plurality of middle porches, and the plurality of middle porches are inserted at equal intervals.

In an embodiment, the at least one middle porch includes a plurality of middle porches, each of the plurality of middle porches being inserted in a predetermined section according to a corresponding device.

In one embodiment, the at least one middle porch is inserted asynchronously with the frame frequency.

The display system may include a display controller configured to receive image data and the display signal and output the display data, wherein the at least one middle porch is inserted between the displays areas in the controller.

The display system may include a host configured to output image data and the display signal, and a display controller configured to receive the image data and the display signal output to the host and output the display data. The middle porch of is inserted between the display regions at the host.

According to an embodiment of the present disclosure, a display controller may include: at least one frame memory configured to store image data in a frame unit and to output the image data in response to a read clock; A frame memory controller configured to receive the image data, a data activation signal, and at least one display signal and transmit the image data to the frame memory; A source driver for receiving image data output from the at least one frame memory and outputting the image data as display data in response to the read clock; A register file that stores the image data and the data activation signal and stores operation information related to an operation start and time of at least one device; A timing controller for generating control signals in response to the at least one display signal and a command output from the register file; A gate driver which receives a control signal output from the at least one timing controller and outputs a gate control signal in response to the read clock; An oscillator for generating a clock; An oscillator controller for controlling the oscillator according to the control of the timing controller; A clock controller that receives the clock from the oscillator and generates the read clock in response to control signals output from the timing controller, wherein the timing controller includes instructions related to the operation information output from the register file; The control signal to increase the frequency of the read clock in response to an interrupt (INT) input from the outside and to insert at least one middle porch between display regions for outputting the display data based on the at least one display signal. Occurs.

The at least one frame memory may include: a first frame memory configured to store a current frame; And a second frame memory for storing a previous frame, and comparing the image data stored in the first frame memory with the image data stored in the second frame memory in response to the read clock to calculate a response time of the liquid crystal panel. And a liquid crystal response time accelerator for compensating the calculated response time by using a liquid crystal response time table.

As described above, the display controller and the display control method according to the present invention can design the external device without considering the display noise by inserting the middle porch when the operation of the external device is predicted.

1 illustrates a general vertical sync signal, a display porch, and a display area.
2 is a diagram generally illustrating a display control method for avoiding display play noise.
3 is a view for explaining an asymmetric sensing period.
4 is a view for conceptually explaining a display control method according to the present invention.
5 is a display timing diagram exemplarily illustrating a distribution of a porch section and a display area when one frame is displayed according to the present invention.
6 is a diagram illustrating a display controller according to an exemplary embodiment of the present invention.
7 is a diagram illustrating a display system having a display controller without a frame memory according to an exemplary embodiment of the present invention.
8 is a view showing a first embodiment of the insertion form of the middle porch according to the present invention.
9 is a view showing a second embodiment of the insertion form of the middle porch according to the present invention.
10 is a view showing a third embodiment of the insertion form of the middle porch according to the present invention.
FIG. 11 is a diagram illustrating an exemplary standby state for receiving an interrupt INT or a command CMD by increasing the display clock speed.
FIG. 12 is a diagram illustrating that a middle porch is inserted when an interrupt INT or a command CMD is generated.
FIG. 13 is a diagram for inserting a middle porch when a sudden interrupt (INT) or a command request is received while performing a normal display.
14 exemplarily shows a processing method when sufficient middle porch time is not secured.
15 is a block diagram exemplarily illustrating a first embodiment of a display controller according to the present invention.
16 is a block diagram exemplarily illustrating a second embodiment of a display controller according to the present invention.
17 is a block diagram illustrating a method of inserting a middle porch in a host.
18 is a block diagram exemplarily illustrating a structure for indicating a middle porch section while performing direct communication between a display controller and a device affected by display noise.
19 is a block diagram illustrating a data processing system in accordance with an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings so that those skilled in the art can easily carry out the technical idea of the present invention.

The present invention avoids display noise by stopping at least one signal related to a display (hereinafter, a display signal) for a predetermined time with respect to at least one external device operation. A display system and a display control method thereof can be reduced. Since the display system and its display method according to the present invention can avoid or reduce display noise, it is possible to design an external device without considering display noise.

In the following, stopping the display signal for a predetermined time will be referred to as a display porch. In other words, display porch is called display blacking. In the following description, it is assumed that the display signal is a vertical synchronization signal (VSYNC) for convenience of description. However, the display signal of the present invention will not be limited to the vertical sync signal VSYNC. The display signal of the present invention may be a horizontal synchronization signal (HSYNC).

1 is a diagram illustrating a general vertical sync signal VSYNC, a display porch FP and a BP, and a display area. The vertical synchronizing signal VSYNC is a signal for controlling the display panel and is a signal defining a period for scanning one frame. The display porch includes a front porch (FP) and a back porch (BP) and is a section not displayed on the display panel. The display region DR is a section displayed on the display panel.

In summary, the display porches FP and BP are areas in which display data are not output based on the vertical sync signal VSYNC, and the display areas are in which display data are output based on the vertical sync signal VSYNC. Area.

2 is a diagram generally illustrating a display control method for avoiding display play noise. Referring to FIG. 2, porch sections are increased to avoid display noise. By the increased porch interval, the operation (eg, sensing) time of the touch screen controller is secured.

Although the above-described method is an effective method for avoiding display noise, it is difficult to sense at a frequency exceeding the display frequency since the sensing interval is the same as the display frequency in the time axis. If the sensing time is short and two or more times are sensed in the porch section, the non-sensing section is increased because the time of the display area DR is relatively long. Therefore, symmetry of the sensing period is not secured.

3 is a view for explaining an asymmetric sensing period. Referring to FIG. 3, the lengths of the sensing region of the front stage and the sensing region of the rear stage are different from each other.

According to the present invention, a display control method includes increasing a clock speed for outputting image data and inserting at least one middle porch between display regions for outputting display data corresponding to the image data; Increase the front porch and back porch sections.

4 is a view for conceptually explaining a display control method according to the present invention. Referring to FIG. 4, a middle porch MP is inserted between the display regions DR. In other words, the middle porch MP is inserted between the front porch FP and the back porch BP.

The display control method of the present invention inserts at least one middle porch MP between display regions for outputting display data based on a display signal (eg, VSNC). In the inserted middle porch MP, the output of the display data is cut off, and the operation of any one external device will be performed. Therefore, the external device can be designed without considering display noise.

5 is a display timing diagram exemplarily illustrating a distribution of a porch section and a display area when one frame is displayed according to the present invention. Referring to Fig. 5, a conventional display area 11 and a display area 12 according to the present invention are shown. A and C are porch sections when only the display is considered without considering the insertion of the middle porch MP. B and D are porch sections considering insertion of a middle porch (MP) and increase of the porch section. The porch sections B and D may be set to allow an external device (eg, a touch screen) to be designed without considering display noise in consideration of an operation time. In the present invention, the display area DR is reduced (11 → 12) for one frame time, and the porch section is increased (A → B, C → D).

The display control method according to the present invention is embedded in a display controller such as a display driver IC (DDI) or a touch screen controller (TCON), or a graphic card or video for transmitting a display signal to the DDI or TCON. It may be embedded in a host such as a video driver.

6 is a block diagram illustrating a display controller 100 in accordance with the present invention. Referring to FIG. 6, the display controller 100 includes a frame memory controller 110, a frame memory 120, and a display signal controller 130. The display controller 100 shown in FIG. 6 may be a DDI or a TCON.

The frame memory controller 110 receives image data, a data activation signal DE, a vertical synchronization signal VSYNC, and a horizontal synchronization signal HSYNC, and outputs image data and control signals CTLS. .

The frame memory 120 receives image data and control signals CTLS and outputs image data. The frame memory 120 stores image data in frame units.

The display signal controller 130 receives image data output from the frame memory 120 and outputs display data for display in response to the read clock RCLK. The display signal controller 130 may be, for example, a source driver or a gate driver.

In an embodiment, the display controller 100 may operate asynchronously with an external input. Since the display controller 100 operates asynchronously, the middle porch may occur internally. For example, by increasing the frequency of the clock of the display controller 100 and the read clock RCLK provided to the frame memory 120, the time delay due to the middle porch insertion may be compensated. That is, the display controller 100 reads image data from the frame memory 120 and outputs display data from the display signal controller 130 in response to a read clock RCLK having an increased frequency when the middle porch is inserted.

The display controller 100 according to the present invention may internally generate a middle porch.

The display controller 100 shown in FIG. 6 includes a frame memory 120. However, the present invention is not necessarily limited to the display controller having the frame memory. The display control method according to the present invention is applicable to a display system having a display controller without a frame memory.

7 is a diagram showing a display system 10 having a display controller without a frame memory according to the present invention. Referring to FIG. 7, the display system 10 includes a host 200 and a display controller 300.

The host 200 may be any one device related to an image, such as a graphic driver, a video driver, an application processor, and the like. The host 200 includes a display IP 220. The display IP 220 generates image data and control signals CTLS. The display IP 220 generates a middle porch and inserts the generated middle porch between the display regions based on the display signal.

The display controller 300 includes a timing controller 320. The timing controller 320 receives image data and control signals CTLS and outputs display data to display. The timing controller 320 receives a middle porch generated from the display IP 220. Thus, the display controller 300 can be designed without considering the middle porch.

The display system 10 according to the present invention generates a middle porch at the host 200.

The display method according to the present invention may insert the middle porch in various forms to avoid or reduce display noise of at least one device. The following describes the various insertion forms for the middle porch (MP).

8 is a view showing a first embodiment of the insertion form of the middle porch (MP) according to the present invention. Referring to FIG. 8, middle porches are generated at equal intervals for an apparatus requiring a constant interval of operation time. In FIG. 8, three middle porches MP1, MP2, and MP3 are shown for convenience of description, but the number of middle porches of the present invention will not be limited thereto. Devices generating the middle porch (eg, the display controller 100 of FIG. 6 and the display IP 220 of FIG. 7) may be configured to display the middle pores MP1 based on operation information related to the start or time of operation of the device. Will cause (mp2, mp3).

The display control method of the present invention can be used to reduce or avoid display noise of a plurality of adjacent devices.

9 is a view showing a second embodiment of the insertion form of the middle porch according to the present invention. Referring to FIG. 9, a middle porch corresponding to each of the devices A, B, and C is generated for the devices A, B, and C that require different operating times.

In the case of devices A and B, a middle porch may be generated according to a set value.

In the case of the device C, a middle porch may be randomly generated in response to an interrupt INT or a command CMD. That is, at least one middle porch may be generated according to the interrupt INT.

In summary, the middle porch of the present invention may be generated according to at least one value set based on the operation information, the response of the interrupt INT or the command CMD.

In FIGS. 8 and 9, the middle porch is generated in synchronization with the frame period. However, the middle porch of the present invention does not necessarily need to be generated in synchronization with the frame period.

10 is a view showing a third embodiment of the insertion form of the middle porch according to the present invention. Referring to FIG. 10, middle pores MP1, MP2, and MP3 are inserted into one frame at a predetermined interval, and the middle porch MP is inserted into another frame. That is, the middle porches MP1, MP2, MP3, and MP4 are generated at regular intervals regardless of the frame period.

In an embodiment, when a plurality of horizontal synchronization signal HSUNC counters are provided and the number of horizontal synchronization signals HSYNC set in the reservoir is input, middle porch insertion is started and the number of horizontal synchronization signals HSYNC set in the reservoir is set. Middle porch is generated.

The middle porch according to the present invention may be inserted by an interrupt INT or a command CMD. In FIG. 11 to FIG. 14, the middle porch is inserted by the interrupt INT or the command CMD.

11 is capable of receiving interrupt (INT) or command (CMD) by increasing the frequency of the display clock (eg, read clock (RCLK) shown in FIG. 5) (in other words, by increasing the clock speed). A display timing diagram illustrating an exemplary standby state. Referring to FIG. 11, the frequency of the display clock is increased, and the back porch BP of the vertical synchronizing signal VSYNC is removed or reduced, thereby ensuring extra time. As a result, the original DR 21 may be reduced and a redundant porch (RP) may be secured. The new DR 22 will be formed by outputting the display data according to the display clock with the increased frequency.

12 is a display timing diagram exemplarily illustrating that a middle porch is inserted when an interrupt INT or a command CMD is input. Referring to FIG. 12, a first new DR 32 is formed by outputting display data in response to a display clock having a raised frequency, a middle porch MP is inserted, and then a display clock having a raised frequency. In response, the second new DR 33 is formed by outputting the display data. As the front porch FP and the back porch BP are extended as a whole, and the middle porch MP is inserted, the first DR 32 and the second new DR 33 will be made smaller in the original DR 31. .

Referring back to FIG. 12, a middle porch MP is inserted between the first new DR 32 and the first new DR 33 when the interrupt INT or command CMD is input, and the inserted middle porch MP is inserted. ) Ensures stable operating time of other devices. According to the middle porch insertion method of the present invention, when the interrupt INT or the command CMD is input, the middle porch is inserted to secure a safe operation time of another device.

The middle porch insertion method of the present invention described above is applicable to both a device that operates periodically or a device that operates aperiodically.

FIG. 13 is a display timing diagram exemplarily illustrating insertion of a middle porch when a sudden interrupt (INT) or command (CMD) request is received while performing a normal display. Referring to FIG. 13, if enough display time remains to secure the operation time of another device, the middle porch MP may be immediately inserted by increasing the frequency of the display clock.

The DR 42 will be formed by outputting the display data in response to the display clock having the original speed until the interrupt INT or command CMD is input. Thereafter, the middle abandonment MP is inserted and the display data is output in response to the display clock having the raised frequency so that a new DR 43 is formed.

On the other hand, when the interrupt INT or the command CMD is input late, the middle porch may be inserted in consideration of the time until the next frame.

14 is a display timing diagram illustratively showing a processing method when sufficient middle porch time is not secured. Referring to FIG. 14, when the interrupt INT or the command CMD is input late in the previous frame N, the middle porch MP is inserted in consideration of the time until the next frame N + 1. will be.

In the previous frame (Frame N), the DR 51 is formed by outputting the display data in response to the display clock having the original speed.

In the current frame Frame N + 1, the middle porch MP is inserted, and display data is output in response to a display clock having an increased frequency, thereby forming a new DR 62. The new DR 62 is smaller than the original DR 61 as the pores FP and BP are extended and the middle porch MP is inserted.

15 is a block diagram illustrating a first embodiment of a display controller 400 according to the present invention. Referring to FIG. 15, the display controller 400 includes a frame memory controller 410, a frame memory 420, a source driver 430, a gate driver 435, a register file 440, a timing controller 450, and an oscillator. Controller 460, oscillator 470, and clock controller 480.

The frame memory controller 410 receives image data, a data activation signal, and at least one display signal and transmits the image data to the frame memory 420. The frame memory 420 stores image data in frame units and outputs image data in response to the read clock RCLK. The source driver 430 receives image data output from the frame memory 420 and outputs the display data in response to the read clock RCLK. The gate driver 435 receives the gate control signal from the timing controller 450 and outputs the gate control signal GCS in response to the read clock RCLK.

The register file 440 stores image data and data activation signals, and stores operation information related to operation start and time of at least one device.

The timing controller 450 generates control signals in response to the at least one display signal and the command CMD output from the register file 440. In particular, the timing controller 450 controls the control signals to increase the frequency of the read clock RCLK in response to a command CMD related to the operation information output from the register file 440 or an interrupt INT input from the outside. Occurs.

In an embodiment, the timing controller 450 may include at least one input port 451 for receiving an interrupt INT. The interrupt INT may be output from a host or a touch driver, and the host or touch driver may include a status register or an output port for outputting an interrupt.

The oscillator controller 460 controls the oscillator 470 according to the control of the timing controller 450. The oscillator 470 generates a clock CLK under the control of the oscillator controller 460. The clock controller 480 receives the clock CLK output from the oscillator 470 and generates a read clock RCLK in response to control signals output from the timing controller 450.

Hereinafter, the insertion and extension operations of the middle porch of the display controller 400 will be described.

When an interrupt (INT) or a command (CMD) is requested to insert a porch externally, the display controller 400 synchronizes the oscillator 470 according to the synchronization of the horizontal synchronizing signal HSYNC and the vertical synchronizing signal VSYNC for stable display. Adjust the frequency of).

The timing controller 450 generates at least one middle porch based on operation information of devices related to display noise stored in the register file 440. When it is time to insert the middle porch, the timing controller 450 stops the read clock RCLK and the read enable signal for reading data of the frame memory 420, and also operates the source driver 430 and the gate driver 435. Stop it.

The horizontal synchronizing signal (HSYNC) counter (not shown) included in the timing controller 450 may check an operation time of a preset device. The timing controller 450 displays the signal and the read clock RCLK to the frame memory 420, the source driver 430, and the gate driver 435 again when the operation time of the device ends.

The display controller 400 of the present invention may be divided into a write clock domain and a read clock domain as shown in FIG. 15. The operation up to storing image data from the frame memory controller 410 to the frame memory 420 is performed in response to the write clock WCLK. Meanwhile, the operation of reading image data from the frame memory 120 and outputting the image data from the source driver 430 to the display data is performed in response to the read clock RCLK.

The display controller 400 of the present invention raises the frequency of the read clock RCLK when the middle porch is inserted.

In general, the response time of a liquid crystal (hereinafter referred to as "LC") has a large effect on image quality. The faster the display clock is, the shorter the voltage application time according to gray scale for each pixel. If the LC response time is not secured and the voltage application is stopped, the image quality may be degraded because the proper gray scale is not expressed. The display controller of the present invention may further include a compensation circuit for reducing the LC response time in order to prevent image degradation due to insertion of the middle porch and expansion of the vertical sync signal (HSYNC) porch.

16 is a block diagram illustrating a second embodiment of the display controller 500 according to the present invention. 16 illustrates a frame memory controller 510, a first frame memory 521, a second frame memory 522, a source driver 530, a gate driver 535, a register file 540, a timing controller 550, Oscillator Controller 560, Oscillator 570, Clock Controller 580, LC Response Time Table 591 and LC Response Time Accelerator 592. The LC response time compensation circuit may be implemented with an LC response time table 591 and an LC response time accelerator 592.

In an embodiment, the timing controller 550 may include at least one input port 451 for receiving an interrupt INT.

The position of the compensation circuit is disposed between the frame memory 522 and the source driver 530.

The first frame memory 521 stores the current frame, and the second frame memory 522 stores the previous frame.

The LC response time table 591 may include a look up table (“LUT”) measuring the LC response time of the liquid crystal panel. If there is no compensation circuit without the LC response time table 591 shown in Fig. 16, the response time should be able to be calculated by the equation.

The LC response time accelerator 592 calculates the LC response time by comparing the image data stored in the first frame memory 521 and the image data stored in the second frame memory 522 in response to the read clock RCLK. Compensated LC response time with reference to LC response time table 591.

As shown in FIG. 16, the display controller 500 separates the write clock domain and the read clock domain. By completely separating the clock domains, additional porch insertion may be possible by speeding up the read clock RCLK.

When the timing controller 500 receives an interrupt INT or a command CMD for middle porch insertion, the frequency of the oscillator 570 is increased by using the oscillator controller 560. Accordingly, the read clock RCLK input to the first frame memory 521 and the read clock input to the second frame memory 522, the LC response time accelerator 592, the source driver 530, the gate driver 535, and the like. (RCLK) is faster.

The display controller 500 according to the present invention compensates for the LC response time in order to prevent deterioration of image quality due to the middle porch insertion.

17 is a block diagram illustrating a method of inserting a middle porch in a host. Referring to FIG. 17, the display system 20 includes a host 700, a display controller 800, and a touch controller 900. A middle porch is generated at the host 700.

When the device sensitive to display noise informs the host 700 of the operation time and time, and transmits an interrupt (INT) or a command (CMD), the display IP 720 of the host 700 ensures the safe operation of the device. Raise the middle porch. This method can insert the middle porch even if there is no frame memory inside the display controller 800.

The touch controller 900 is a device related to display noise. The touch controller 900 may receive signals related to display noise such as a horizontal sync signal HSYNC, a vertical sync signal VSYNC, and a common voltage signal VCOM of the display controller 800 in order to know a safer operation time. Alternatively, the host 700 may receive a signal related to the synchronization signal and the display noise directly.

18 is a block diagram exemplarily illustrating a structure for indicating a middle porch section while performing direct communication between a display controller and a device affected by display noise. Referring to FIG. 18, the display system 30 includes a host 701, a display controller 801, and a touch controller 901. Here, the display controller 801 and the touch controller 901 communicate directly.

When the touch controller 901 informs the display controller 801 of the operation time and time, and transmits an interrupt INT or a command CMD, the display controller 801 generates a middle porch to ensure safe operation.

The display controller 801 outputs a signal to the touch controller 901 indicating a valid region of an operation without display noise based on the generated middle porch.

In the display system 30 according to the present invention, the display controller 801 and the touch controller 901 communicate directly to generate a middle porch.

19 is a block diagram illustrating an example of a data processing system 1000 according to an example embodiment. Referring to FIG. 19, the data processing system 1000 includes a host controller 1100, a display driver integrated circuit 1200, a touch screen controller 1300, and an image processor 1400. Inside the data processing system 1000, the display driver integrated circuit 1200 is implemented to provide display data 1004 to the display 1500, and the touch screen controller 1300 is connected to a touch panel that overlaps the display 1500. In addition, the touch panel 1600 may be implemented to receive the sensing data 1005 from the touch panel 1600. The display driver integrated circuit 1200 according to an exemplary embodiment of the inventive concept may be implemented by the middle porch method described with reference to FIGS. 1 to 18.

Meanwhile, details of the data processing system 1000 will be described in US published patent US 2010-0241957, filed by Samsung Electronics and incorporated by reference in this application.

The data processing system 1000 of the present invention is applicable to mobile phones (Galaxy S, iPhone, etc.), tablet PCs (Galaxy Tab, iPad, etc.).

In the display control method according to the present invention, by generating a middle porch, it is possible to secure safe operation time of at least one external device, thereby improving performance of the entire product.

Embodiments of the present invention are software, firmware, application specific integrated circuit (ASIC) stored by at least one microchip or integrated circuit, hardware logic, memory device interconnected by using a motherboard, and executed by a microprocessor. Or as a field programmable gate array (FPGA), or by any combination thereof.

While the invention has been shown and described with reference to certain preferred embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made therein without departing from the spirit and scope of the invention. Therefore, the scope of the present invention should not be limited to the above-described embodiments, but should be determined by the equivalents of the claims of the present invention as well as the claims of the following.

10, 20, 30: display system
100, 400, 500: display controller
200, 700: host
110: frame memory controller
120: frame memory
130: display controller

Claims (10)

In the display control method of the display system:
Receiving image data and a display signal;
Increasing the frequency of the clock based on operation information of the at least one device;
Outputting display data corresponding to the image data using the clock having the increased frequency; And
And inserting at least one middle porch between display regions on which the display data is output based on the display signal. The method of claim 1,
The display signal is a vertical synchronization signal,
And a front porch at a front end of the display signal and a back porch at a rear end of the display signal. 3. The method of claim 2,
Inserting the at least one middle porch,
Generating a redundancy porch by removing or reducing the back porch; And
And inserting a middle porch in response to an interrupt or command. The method of claim 1,
And receiving an interrupt or a command from the at least one device. 5. The method of claim 4,
And increasing the frequency of the clock in response to the interrupt or command. The method of claim 5, wherein
Inserting the at least one middle porch,
Determining whether a middle porch can be inserted into a current frame in response to the interrupt or command; And
If it is difficult to insert a middle porch into the frame, inserting a middle porch into a next frame. The method of claim 1,
The at least one middle porch comprises a plurality of middle porches,
And a plurality of middle porches are inserted at equal intervals. The method of claim 1,
The at least one middle porch comprises a plurality of middle porches,
And each of the plurality of middle porches is inserted in a predetermined section according to a corresponding device. At least one frame memory for storing image data in frame units and outputting the image data in response to a read clock;
A frame memory controller configured to receive the image data, a data activation signal, and at least one display signal and transmit the image data to the frame memory;
A source driver for receiving image data output from the at least one frame memory and outputting the image data as display data in response to the read clock;
A register file that stores the image data and the data activation signal and stores operation information of at least one device;
A timing controller for generating control signals in response to the at least one display signal and a command output from the register file;
A gate driver which receives the control signals from the timing controller and outputs a gate control signal in response to the read clock;
An oscillator for generating a clock;
An oscillator controller for controlling the oscillator according to the control of the timing controller;
A clock controller which receives the clock from the oscillator and generates the read clock in response to control signals output from the timing controller,
The timing controller increases the frequency of a read clock in response to a command related to the operation information output from the register file or an interrupt or command input from an external device, and outputs the display data based on the at least one display signal. And display the control signals to insert at least one middle porch between display regions. The method of claim 9,
The timing controller further comprises at least one input port for receiving the interrupt.

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