TW201911280A - Image Display Method and Display System - Google Patents

Abstract

An image display method includes acquiring a data clock signal, generating a backlight driving signal according to the data clock signal, and a display system displaying an image according to at least the data clock signal and the backlight driving signal. The data clock signal includes a first data square wave and a second data square wave. The first data square wave and the second data square wave are periodically transmitted by using a data period. The backlight driving signal includes a first backlight square wave and a second backlight square wave. The first backlight square wave and the second backlight square wave are periodically transmitted by using a backlight period. The data period is greater than the backlight period.

Description

Method and display system for displaying images

The present invention describes a method and display system for displaying images, and more particularly to a method and display system for displaying images that prevent flickering of a picture.

Liquid crystal display (LCD) and Organic Light Emitting Diode (OLED) display devices have been widely used in multimedia players due to their advantages of thinness, power saving, and no radiation. , mobile phones, personal digital assistants, computer monitors, or flat-panel TVs and other electronic products.

When a conventional display displays an image, the pulse modulation signal is used to drive the backlight to generate a backlight signal, and the backlight signal is continuously turned on or off. Therefore, the user can easily feel the flickering of the screen while viewing the screen and reduce the visual quality. Moreover, when the display displays an image, since the backlight signal generated by the backlight device matches the clock frequency of the image data, when the clock frequency of the image data is low, the frequency of the backlight signal generated by the backlight device also decreases. However, too low a backlight signal frequency will be difficult to trigger the visual persistence mechanism of the human eye. In other words, when the human eye is watching a display with a low backlight signal frequency, there is a visual experience of flickering the picture. The phenomenon of flickering the screen will also have a bad influence on the human eye.

An embodiment of the present invention provides a method for displaying an image, comprising: acquiring a data clock signal; generating a backlight driving signal according to the data clock signal; and displaying, by the display system, the image according to at least the data clock signal and the backlight driving signal. The data clock signal includes a first data square wave and a second data square wave. The first data square wave and the second data square wave are transmitted in the data cycle. The backlight driving signal includes a first backlight square wave and a second backlight square wave. The first backlight square wave and the second backlight square wave are transmitted in a backlight cycle. The data period is greater than the backlight period.

Another embodiment of the present invention provides a display system including a processing device, a pixel array, an image driving device, a backlight module, and a backlight driving device. The processing device is configured to obtain a data clock signal and generate a backlight driving signal according to the data clock signal of the data. A pixel array is used to generate an image. The image driving device is coupled to the processing device and the pixel array for controlling the pixel array according to the data clock signal. The backlight module is used to emit a backlight signal. The backlight driving device is coupled to the processing device and the backlight module for controlling the backlight module according to the backlight driving signal. The data clock signal includes a first data square wave and a second data square wave. The first data square wave and the second data square wave are transmitted in the data cycle. The backlight driving signal includes a first backlight square wave and a second backlight square wave. The first backlight square wave and the second backlight square wave are transmitted in a backlight cycle. The data period is greater than the backlight period.

1 is a block diagram of an embodiment of a display system 100 of the present invention. The display system 100 includes a processing device 10, a video driving device 11, a pixel array 12, a backlight driving device 13, and a backlight module 14. Processing device 10 can be any form of computing component, such as a processing chip (Scalar), a central processing unit, a microprocessor, a programmable control unit, and the like. The image driving device 11 is coupled to the processing device 10 for generating a voltage required to drive the pixel array 12. The backlight driving device 13 is coupled to the processing device 10 for generating a voltage required to drive the backlight module 14. The image driving device 11 can be any type of scanning line/data line driving device or a driving device including a shift register. The image driving device 11 can drive the pixel array 12 using a column drive mode (Row by Row). The pixel array 12 can be any component having a display color function. The backlight driving device 13 can be any driving device that drives the backlight module 14 according to Pulse Width Modulation (PWM). The backlight module 14 can be any device having a light emitting function. For example, the backlight module 14 can be at least one string of Light-Emitting Diodes (LEDs). In the display system 100, the processing device 10 is configured to generate a data clock signal and generate a backlight driving signal according to the data clock signal. The data clock signal can be a pulse modulation signal having a predetermined or custom frequency, such as 60 Hertz (Hz). The image driving device 11 can adjust the polarity of the liquid crystal of the sub-pixels in the pixel array 12 according to the data clock signal and the image data input from the outside to generate an image. The backlight driving device 13 can control the backlight module 14 according to the backlight driving signal to generate a backlight signal. A method of displaying an image by the display system 100 will be described later.

FIG. 2 is a schematic diagram showing the data clock signal DK and the backlight driving signal BL in the system 100. The data clock signal DK can be a periodic square wave signal. For example, the frequency of the data clock signal DK can be 60 Hz. The data clock signal DK may include a plurality of square wave signals, such as a first data square wave D1 and a second data square wave D2. The first data square wave D1 and the second data square wave D2 may be square waves having the same width. In other words, the widths of the first data square wave D1 and the second data square wave D2 correspond to the first time interval T1. Moreover, the first data square wave D1 and the second data square wave D2 are separated by a blanking time interval BLK. The first data square wave D1 and the second data square wave D2 can be transmitted using one data period DP. The data period DP can be defined as the rising time of the first data square wave D1 to the rising time of the second data square wave D2. When the frequency of the data clock signal DK is 60 Hz, the length of the data period DP is (1/60) seconds. The backlight driving signal BL can be a Pulse Width Modulation (PWM) composed of a plurality of square wave signals. For example, the backlight driving signal BL may include a first backlight square wave B1 and a second backlight square wave B2. The width of the first backlight square wave B1 corresponds to the second time interval T2. The width of the second backlight square wave B2 corresponds to the third time interval T3. The second time interval T2 corresponding to the first backlight square wave B1 is within the first time interval T1, and the third time interval T3 corresponding to the second backlight square wave B2 is within the blank time interval BLK. The first backlight square wave B1 and the second backlight square wave B2 may be transmitted using one backlight period BP. The definition of the backlight period BP may be the rising edge time of the first backlight square wave B1 to the rising edge time of the second backlight square wave B2. Also, the data period DP is greater than the backlight period BP. For example, the aforementioned data period DP may be (1/60) seconds in length, and the backlight period BP may be (1/120) seconds in length. If the length of the backlight period BP is (1/120) seconds, the frequency of the backlight driving signal BL is equivalent to 120 Hz. However, the present invention is not limited by the frequency of the data clock signal DK being 60 Hz and the frequency of the backlight driving signal BL being 120 Hz. For example, the frequency of the backlight driving signal BL may be N times the data clock signal DK, and N is a positive integer greater than 1. In the second figure, since the frequency of the backlight driving signal BL is larger than the frequency of the data clock signal DK, in the time interval visible to the human eye, in a data period DP, in addition to the third time interval When T3 sees the image, it can also see the image in the second time interval T2. Therefore, the visual persistence mechanism of the human eye will be activated to prevent the visual experience of flickering of the picture.

FIG. 3 is a schematic diagram showing the width and height of the first backlight square wave B1 and the second backlight square wave B2 in the display system 100. For the sake of description simplification, the following description will be made with the corresponding first backlight square wave B1 and second backlight square wave B2 in one data period DP. However, it should be understood that the paired backlight square waves in the backlight driving signal BL have the same characteristics. In FIG. 3, the height of the second backlight square wave B2 is set to the first value V1, and the width of the second backlight square wave B2 is set to the second value V2. The height of the first backlight square wave B1 is set to a third value V3, and the width of the first backlight square wave B1 is set to a fourth value V4. The first value V1, the second value V2, the third value V3, and the fourth value V4 are positive numbers greater than zero. Moreover, the first value V1, the second value V2, the third value V3, and the fourth value V4 can determine the image brightness per unit time (for example, within one data period DP). For example, when the image brightness is L, L can be expressed as (V1 × V2) + (V3 × V4). In other words, the image brightness L per unit time is the sum of the areas of the first backlight square wave B1 and the second backlight square wave B2. Moreover, in the display system 100 of the present invention, in a data period DP, each of the light-emitting elements in the backlight module 14 (for example, an LED lamp) is in the second time interval T2 (as shown in FIG. 2). The first value V4) corresponding to the first backlight square wave B1 and the third time interval T3 (as shown in FIG. 2, corresponding to the second value V2 of the second backlight square wave B2) are simultaneously turned on, and each time One of the light-emitting elements is simultaneously turned off outside the second time interval T2 and the third time interval T3. Therefore, in one data period DP, the time interval visible by the human eye is related to the second value V2 of the second backlight square wave B2 and to the fourth value V4 of the first backlight square wave B1. As shown in FIG. 3, the time interval in which the human eye of the second backlight square wave B2 is visible is the second value V2. However, since the time interval corresponding to the second backlight square wave B2 is within the blank time interval BLK, when the backlight module 14 is turned on according to the second backlight square wave B2, the image seen by the human eye is the liquid crystal of the pixel array 12. The polarity has changed to a steady state image. In contrast, the time interval in which the human eye of the first backlight square wave B1 is visible is the fourth value V4. Since the time interval corresponding to the first backlight square wave B1 is within the first time interval T1 of the first data square wave D1, when the backlight module 14 is turned on according to the first backlight square wave B1, the image seen by the human eye is The liquid crystal polarity of the pixel array 12 is a transient image. In order to reduce the time of the unstable image seen by the human eye in one data period DP, the first value V1, the second value V2, the third value V3, and the fourth value V4 are also adjusted according to the image brightness L. The rules for adjustment are described below.

4 is a schematic diagram showing the width and height of the first backlight square wave B1 and the second backlight square wave B2 when the image brightness L is set higher than the set value in the display system 100. As mentioned above, when the backlight module 14 is turned on according to the first backlight square wave B1, the image seen by the human eye is an image in which the liquid crystal polarity of the pixel array 12 is transient. When the backlight module 14 is turned on according to the second backlight square wave B2, the image seen by the human eye is an image in which the liquid crystal polarity of the pixel array 12 has become a steady state. Therefore, when the image brightness L is set higher than the set value, for example, when the image brightness L is higher than 50% of the maximum image brightness, the display system 100 preferentially maximizes the width and height of the second backlight square wave B2, and then left The lower image brightness L corresponds to the first backlight square wave B1. For example, the display system 100 preferentially sets the first value V1 (height) of the second backlight square wave B2 to the square wave height setting maximum value MAXV1, and the second value V2 (width) of the second backlight square wave B2. Set to the width setting maximum value MAXV2. Here, the square wave height setting maximum value MAXV1 is substantially equal to the maximum height setting value in the corresponding blank time interval BLK. The square wave width setting maximum value MAXV2 is substantially equal to the maximum width setting value in the corresponding blank time interval BLK. When both the width and the height of the second backlight square wave B2 are set to the maximum value, the third value V3 (height) and the fourth value V4 (width) of the first backlight square wave B1 will conform to (V3×V4)= L-(MAXV1×MAXV2). In other words, the third value V3 and the fourth value V4 of the first backlight square wave B1 may be based on the image brightness L, the first value V1 (this embodiment is equal to the square wave height setting maximum value MAXV1), and the second value V2 (this The embodiment is equal to the square wave width setting maximum value MAXV2). Further, in the condition of (V3 × V4) = L - (MAXV1 × MAXV2), in order to minimize the unstable time of the human visual image, the display system 100 will assign the third value V3 and the fourth value V4. The third value V3 is preferentially maximized to reduce the demand of the fourth value V4, and the function of shortening the unstable time of the visible image is achieved. For example, the fourth value V4 can be expressed as [L - (MAXV1 × MAXV2)] / V3. When the third value V3 is set to the maximum value of the square wave height, the fourth value V4 will be reduced. Finally, the backlight module 14 driven by the first backlight square wave B1 and the second backlight square wave B2 will emit a backlight signal conforming to the image brightness L, and the image can maintain good stability.

Fig. 5 is a view showing the width and height of the first backlight square wave B1 and the second backlight square wave B2 when the image brightness L is set lower than the set value in the display system 100. As mentioned above, when the backlight module 14 is turned on according to the first backlight square wave B1, the image seen by the human eye is an image in which the liquid crystal polarity of the pixel array 12 is transient. When the backlight module 14 is turned on according to the second backlight square wave B2, the image seen by the human eye is an image in which the liquid crystal polarity of the pixel array 12 has become a steady state. Therefore, when the image brightness L is set lower than the set value, for example, when the image brightness L is lower than 50% of the maximum image brightness, the display system 100 avoids all the energy required for the image brightness L to be allocated to the second backlight square wave B2. . The reason for this is that when all the energy required for the image brightness L is assigned to the second backlight square wave B2, the first backlight square wave B1 is substantially absent (no area). Therefore, the frequency of the backlight driving signal BL will be halved, causing the image to flicker. Therefore, even when the setting of the image brightness L is lower than the set value, the display system 100 maintains the existence of the first backlight square wave B1 and the second backlight square wave B2. In order to ensure the existence of the first backlight square wave B1 and the second backlight square wave B2, the display system 100 adjusts the first value V1 (height) of the second backlight square wave B2 to a height lower than the maximum value of the square wave height setting. The set value is denoted here as V1'. The display system 100 adjusts the second value V2 (width) of the second backlight square wave B2 to a width setting value that is lower than the square wave width setting maximum value, herein denoted as V2'. When the width and height of the second backlight square wave B2 are both set, the third value V3 (height) and the fourth value V4 (width) of the first backlight square wave B1 will conform to (V3×V4)=L- (V1' x V2'), and (V3 x V4) > 0. Since (V3×V4)>0, it indicates that the first backlight square wave B1 exists (the area is a positive number), and the backlight driving signal BL can maintain a high frequency to avoid the phenomenon that the image flickers. Similarly, in order to minimize the unstable time of the human visual image, the display system 100 preferentially maximizes the third value V3 when assigning the third value V3 and the fourth value V4 to reduce the demand of the fourth value V4. , to achieve the function of shortening the unstable time of the visible image. Finally, the backlight module 14 driven by the first backlight square wave B1 and the second backlight square wave B2 will emit a backlight signal conforming to the image brightness L. The first value V1 and the third value V3 in the above embodiment may be the voltage or power of the corresponding square wave. The second value V2 and the fourth value V4 may be the length of time corresponding to the rising edge time of the square wave to the falling edge time.

The above-mentioned image brightness L can be a user-defined picture preset brightness. For example, the user can adjust the brightness of the picture to be displayed by using the on-screen adjustment function (eg, On Screen Display, OSD). Alternatively, the user can also directly set the preset brightness of the screen by using the remote control. However, the image brightness L can also be the brightness of the screen automatically adjusted by the system or the preset screen brightness. For example, when the display has a function of automatically adjusting the brightness of the screen according to the external ambient light, the image brightness L can be automatically adjusted by the display. Any manner of setting the image brightness L is within the scope of the present invention.

FIG. 6 is a flow chart showing a method of displaying an image in the display system 100. The method of displaying an image includes steps S601 to S603. Any reasonable step changes are within the scope of the present invention. Steps S601 to S603 are described below:

The detailed description of steps S601 to S603 has been described in the foregoing, and thus will not be described again. The data clock signal DK includes a first data square wave D1 and a second data square wave D2. The first data square wave D1 and the second data square wave D2 are transmitted in the data period DP. The backlight driving signal BL includes a first backlight square wave B1 and a second backlight square wave B2. The first backlight square wave B1 and the second backlight square wave B2 are transmitted in a backlight period BP, and the data period DP is greater than the backlight period BP.

In summary, the present invention describes a method and display system for displaying images. The display system utilizes a backlight drive signal that is greater than the frequency of the data clock signal to prevent unpleasant image flicker. Moreover, in order to further increase the stability of the image when viewed, the display system optimizes the waveform of the backlight driving signal. When the image brightness setting is higher than the set value, the display system will maximize the square wave area of the backlight driving signal in the corresponding blank time interval, so that the visible image in each data period remains stable. When the brightness setting of the image is less than the set value, the display system limits the square wave area of the backlight driving signal in the corresponding blank time interval, so that the square wave of the backlight driving signal in the square wave time corresponding to the data clock signal still exists. Therefore, the frequency of the backlight driving signal can be prevented from being lowered. In the case that the frequency of the backlight driving signal can be maintained greater than the frequency of the data clock signal, the phenomenon that the image flickers can be avoided. Thus, the display system of the present invention provides a good visual experience regardless of any image brightness. The above are only the preferred embodiments of the present invention, and all changes and modifications made to the scope of the present invention should be within the scope of the present invention.

100‧‧‧Display system

10‧‧‧Processing device

11‧‧‧Image Drive

12‧‧‧ pixel array

13‧‧‧Backlight drive

14‧‧‧Backlight module

DK‧‧‧ data clock signal

BL‧‧‧Backlight drive signal

D1‧‧‧First data square wave

D2‧‧‧Second data square wave

B1‧‧‧First Backlit Square Wave

B2‧‧‧Second backlit square wave

T1‧‧‧ first time interval

T2‧‧‧ second time interval

T3‧‧‧ third time interval

BLK‧‧‧ blank time interval

DP‧‧‧ data cycle

BP‧‧‧ backlight cycle

V1‧‧‧ first value

V2‧‧‧ second value

V3‧‧‧ third value

V4‧‧‧ fourth value

MAXV1‧‧‧ square wave height setting maximum

MAXV2‧‧‧ square wave width setting maximum

V1’‧‧‧ height setting

V2’‧‧‧Width setting

Figure 1 is a block diagram of an embodiment of a display system of the present invention. Figure 2 is a schematic diagram of the data clock signal and the backlight driving signal in the display system of Figure 1. Fig. 3 is a view showing the width and height of the first backlight square wave and the second backlight square wave in the display system of Fig. 1. Fig. 4 is a view showing the width and height of the first backlight square wave and the second backlight square wave when the image brightness setting is higher than the set value in the display system of Fig. 1. Fig. 5 is a view showing the width and height of the first backlight square wave and the second backlight square wave when the image brightness setting is lower than the set value in the display system of Fig. 1. Fig. 6 is a flow chart showing a method of displaying an image in the display system of Fig. 1.

Claims (18)

A method for displaying an image, comprising: obtaining a data clock signal; generating a backlight driving signal according to the data clock signal; and displaying, by the display system, an image according to at least the data clock signal and the backlight driving signal; The data clock signal includes a first data square wave and a second data square wave, and the first data square wave and the second data square wave are transmitted in a data period, the backlight driving signal includes a first backlight square wave and a second The backlight square wave, the first backlight square wave and the second backlight square wave are transmitted in a backlight cycle, and the data period is greater than the backlight period. The method of claim 1, wherein a frequency of the backlight driving signal is N times the clock signal of the data, and N is a positive integer greater than 1. The method of claim 1, wherein the frequency of the data clock signal is 60 Hz, and the frequency of the backlight driving signal is 120 Hz. The method of claim 1, wherein the first data square wave and/or the second data square wave correspond to a first time interval, and the first data square wave and the second data square wave are separated by a blank time interval. And the first backlight square wave corresponds to one of the second time intervals in the first time interval, and the second backlight square wave corresponds to one of the third time intervals in the blank time interval. The method of claim 4, further comprising: setting a height of the second backlight square wave to a first value according to an image brightness setting, and setting a width of the second backlight square wave to a second a value, the height of the first backlight square wave is set to a third value, a width of the first backlight square wave is set to a fourth value, and the first value, the second value, the third The value and the fourth value are positive numbers greater than zero. The method of claim 5, wherein the third value and the fourth value are determined by a preset luminance, the first value, and the second value. The method of claim 6, wherein when the first value and the second value are two maximum set values, the second value is equal to a square wave width setting maximum value in the blank time interval, and the first The value is equal to the square wave height setting maximum value in the blank time interval. The method of claim 6, wherein when the third value and the fourth value are allocated, the third value is first set to a maximum value of a square wave height to reduce the fourth value, so that the second backlight The square wave and the first backlight square wave conform to the preset brightness of the picture. The method of claim 5, wherein if the image brightness setting is higher than a set value, the first value is a maximum value of a square wave height, and the square wave height setting maximum value is equal to the blank time interval. The maximum setting value; if the image brightness setting is lower than a set value, the first value is a height setting value lower than a maximum value of the square wave height setting, and/or the second value is lower than a square wave Width sets one of the maximum width settings. The method of any one of claims 4 to 9, further comprising: each of the light-emitting element arrays in a backlight module being simultaneously turned on in the second time interval and the third time interval, And each of the light-emitting elements is simultaneously turned off outside the second time interval and the third time interval. A display system comprising: a processing device for generating a data clock signal, and generating a backlight driving signal according to the data clock signal; a pixel array for generating an image; and an image driving device coupled The processing device and the pixel array are configured to control the pixel array according to the data clock signal; a backlight module for emitting a backlight signal; and a backlight driving device coupled to the processing device and The backlight module is configured to control the backlight module according to the backlight driving signal; wherein the data clock signal comprises a first data square wave and a second data square wave, the first data square wave and the second data square wave The backlight driving signal includes a first backlight square wave and a second backlight square wave. The first backlight square wave and the second backlight square wave are transmitted in a backlight cycle, and the data period is greater than the backlight period. . The system of claim 11, wherein the first data square wave and/or the second data square wave correspond to a first time interval, and the first data square wave and the second data square wave are separated by a blank time interval. And the first backlight square wave corresponds to one of the second time intervals in the first time interval, and the second backlight square wave corresponds to one of the third time intervals in the blank time interval. The system of claim 12, wherein a height of the second backlight square wave is a first value, and a width of the second backlight square wave is a second value, and the first backlight square wave The height is a third value, a width of the first backlight square wave is a fourth value, and the first value, the second value, the third value, and the fourth value are positive numbers greater than zero. The system of claim 13, wherein the third value and the fourth value are determined by a preset luminance, the first value, and the second value. The system of claim 14, wherein when the first value and the second value are two maximum set values, the second value is equal to a square wave width setting maximum value in the blank time interval, and the first The value is equal to the square wave height setting maximum value in the blank time interval. The system of claim 14, wherein when the third value and the fourth value are assigned, the third value is first set to a maximum value of a square wave height to reduce the fourth value, so that the second backlight The square wave and the first backlight square wave conform to the preset brightness of the picture. The system of claim 13, wherein if the image brightness setting is higher than a set value, the first value is a maximum value of a square wave height, and the square wave height setting maximum value is equal to the blank time interval. The maximum setting value; if the image brightness setting is lower than a set value, the first value is a height setting value lower than a maximum value of the square wave height setting, and/or the second value is lower than a square wave Width sets one of the maximum width settings. The system of any one of claims 12 to 17, wherein each of the light-emitting element arrays of the backlight module is simultaneously turned on in the second time interval and the third time interval, and the Each of the light-emitting elements is simultaneously turned off outside the second time interval and the third time interval.