CN109215603B - Brightness adjusting method and system of display system and display system - Google Patents

Abstract

The invention relates to a brightness adjusting method of a display system, which is used for adjusting the brightness of a display panel penetrating through glasses, wherein the display panel is lightened by a backlight module, the glasses comprise a first lens and a second lens, the display panel comprises a plurality of blocks, and the backlight module comprises a plurality of light-emitting elements; the brightness adjusting method of the display system comprises the following steps: writing a first driving signal into the display panel, and simultaneously controlling the first lens to be opened; when the time for writing the first driving signal into the display panel reaches the preset time, controlling each light-emitting element of the backlight module to be simultaneously started; adjusting a first on time of each light emitting element; writing a second driving signal into the display panel, and simultaneously controlling the second lens to be opened; when the time for writing the second driving signal into the display panel reaches the preset time, controlling each light-emitting element of the backlight module to be simultaneously started; the second on time of each light emitting element is adjusted.

Description

Brightness adjusting method and system of display system and display system

Technical Field

The invention relates to the technical field of liquid crystal display, in particular to a brightness adjusting method and system of a display system and the display system.

Background

The brightness displayed by the liquid crystal panel is controlled by the mutual matching of the backlight module, the signal driving module and the glasses driving module. The backlight module is composed of a plurality of light-emitting elements which are arranged according to a certain mode, the light-emitting elements are used for lightening the blocks of the liquid crystal panel, and the average backlight brightness of each block of the liquid crystal panel is different due to the difference of manufacturing processes of the light-emitting elements; the liquid crystal panel and the liquid crystal glasses need to be driven for a certain time to output stable penetration rate due to the physical characteristics of liquid crystal; if the liquid crystal glasses are started synchronously with the writing of the liquid crystal panel driving signal and the starting of the backlight module, the penetration response of the liquid crystal glasses, the penetration response of the liquid crystal panel and the backlight average brightness of each block of the liquid crystal panel are acted together to enable the penetration response of the liquid crystal glasses corresponding to each block of the liquid crystal panel, the product of the penetration response of the liquid crystal panel and the backlight average brightness of each block of the liquid crystal panel to be unequal, and therefore the brightness of each block of the liquid crystal panel penetrating through the liquid crystal glasses is uneven.

Disclosure of Invention

Therefore, it is necessary to provide a brightness adjustment method, a brightness adjustment system and a display system for a display system, which aim at the problem that the transmittance response of the liquid crystal glasses corresponding to each block of the liquid crystal panel, the product of the transmittance response of the liquid crystal panel and the backlight average brightness of each block of the liquid crystal panel are not equal due to the combined action of the transmittance response of the liquid crystal glasses, the transmittance response of the liquid crystal panel and the backlight average brightness of each block of the liquid crystal panel, so that the brightness of each block of the liquid crystal panel passing through the liquid crystal glasses is not uniform.

A brightness adjusting method of a display system is used for adjusting the brightness of a display panel penetrating through glasses, the display panel is lightened by a backlight module, the glasses comprise a first lens and a second lens, the display panel comprises a plurality of blocks, and the backlight module comprises a plurality of light-emitting elements; the brightness adjusting method of the display system comprises the following steps:

writing a first driving signal into the display panel, and simultaneously controlling the first lens to be opened;

when the time for writing the first driving signal into the display panel reaches the preset time, controlling each light-emitting element of the backlight module to be simultaneously started;

adjusting a first on time of each light emitting element;

writing a second driving signal into the display panel, and simultaneously controlling the second lens to be opened;

when the time for writing the second driving signal into the display panel reaches the preset time, controlling each light-emitting element of the backlight module to be simultaneously started;

the second on time of each light emitting element is adjusted.

In one embodiment, the writing the first driving signal into the display panel and the controlling the first mirror to be turned on further includes:

writing a first driving signal into the display panel, controlling the first lens to be opened and controlling each light-emitting element of the backlight module to be opened;

detecting the penetration rate of each block of the display panel along with the change of time and recording the response time of the penetration rate;

and comparing the penetration rate to obtain the preset time according to the response time.

In one embodiment, the drive current for each light emitting element is equal.

A brightness adjusting system is used for adjusting the brightness of a display panel through glasses, the display panel is lightened by a backlight module, the glasses comprise a first lens and a second lens, the display panel comprises a plurality of blocks, and the backlight module comprises a plurality of light-emitting elements;

the brightness adjusting system comprises a signal driving module, a glasses driving module and a control module;

the signal driving module is used for writing a first driving signal into the display panel; the glasses driving module is used for controlling the first lens to be opened; the control module is used for controlling the signal driving module to write a first driving signal into the display panel, and the time for controlling the glasses driving module to open the first lens is consistent with the time for controlling the glasses driving module to open the first lens;

the control module is also used for controlling each light-emitting element of the backlight module to be simultaneously started when the time for writing the first driving signal into the display panel reaches the preset time;

the control module is further used for adjusting the first opening time of each light-emitting element;

the signal driving module is also used for writing a second driving signal into the display panel; the glasses driving module is also used for controlling the opening of the second lens; the control module is also used for controlling the time for writing the second driving signal into the display panel by the signal driving module to be consistent with the time for controlling the second lens to be opened by the glasses driving module;

the control module is further configured to adjust a second on time of each light emitting element.

In one embodiment, the device further comprises a penetration rate detector; the penetration rate detector is used for detecting the penetration rate of each block of the display panel along with the change of time and recording the response time of the penetration rate when the signal driving module writes a first driving signal into the display panel, the glasses driving module controls the first lens to be started and the control module controls each light-emitting element of the backlight module to be started; the penetration rate detector is also used for transmitting the penetration rate and the response time to the control module; the control module is further used for comparing the penetration rate to obtain the preset time according to the response time.

In one embodiment, the drive current for each light emitting element is equal.

In one embodiment, the plurality of light emitting elements form a backlight source, the backlight source is a single-side lateral light source, the number of the light emitting elements is N, the blocks correspond to the light emitting elements one to one, and each light emitting element is used for lighting a corresponding block.

In one embodiment, the plurality of light emitting elements form a backlight source, the backlight source is a bilateral lateral light source, the number of the light emitting elements is 2N, every two light emitting elements correspond to one block, and every two light emitting elements light up one block.

In one embodiment, the plurality of light emitting elements form a backlight source, the backlight source is a direct-type light source, the number of the light emitting elements is N × M, the light emitting elements are arranged in a matrix of N rows and M columns, the M light emitting elements in each row correspond to one block, and the M light emitting elements in each row illuminate the corresponding block.

A display system comprises a display panel and the brightness adjusting system.

According to the brightness adjusting method, the brightness adjusting system and the display system of the display system, on the premise that the plurality of light emitting elements of the backlight module are simultaneously started, the first lens is controlled to be started while the driving signal is written into the display panel, when the time for writing the first driving signal into the display panel reaches the preset time, each light emitting element of the backlight module is controlled to be simultaneously started, the penetration rate of each block of the display panel tends to be equal, the penetration rate of glasses corresponding to each block tends to be equal, and therefore the brightness of each block of the display panel passing through the glasses tends to be uniform.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present application, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a flow chart of a method for adjusting brightness of a display system in one embodiment;

FIG. 2 is a diagram illustrating a single-sided lateral-entry light source and a block mapping according to an embodiment;

FIG. 3 is a diagram illustrating a correspondence between dual edge lateral light sources and blocks in an embodiment;

FIG. 4 is a diagram of a direct light source and a block according to an embodiment;

FIG. 5 is a timing diagram illustrating the transmittance of the display panel, the transmittance of the glasses and the backlight brightness during a display period according to an embodiment;

FIG. 6 is a timing diagram of the transmittance of the display panel, the transmittance of the glasses and the backlight brightness in one display period according to another embodiment;

FIG. 7 is a timing diagram illustrating the transmittance of the display panel, the transmittance of the glasses and the backlight brightness in one display period according to another embodiment;

FIG. 8 is a timing diagram illustrating the transmittance of the display panel, the transmittance of the glasses and the backlight brightness in one display period according to another embodiment;

FIG. 9 is a flowchart of a brightness adjustment method of a display system according to another embodiment;

fig. 10 is a functional block diagram of a brightness adjustment system in one embodiment.

Detailed Description

Please refer to fig. 1, which is a flowchart illustrating a brightness adjusting method of a display system according to a preferred embodiment of the present application. It should be noted that the method of the present application is not limited to the order of the following steps, and in other embodiments, the method of the present application may include only a part of the following steps, or a part of the steps may be deleted. In addition, in other embodiments, one step may be divided into a plurality of steps, or a plurality of steps may be combined into one step.

The brightness adjusting method of the display system is used for adjusting the brightness of a display panel penetrating through glasses, the display panel is lightened by a backlight module, the glasses comprise a first lens and a second lens, the display panel comprises a plurality of blocks, the backlight module comprises a plurality of light-emitting elements, and the backlight source is formed by the light-emitting elements; the driving signals include a first driving signal and a second driving signal. The brightness adjusting method of the display system comprises the following steps:

in step S1, the first driving signal is written into the display panel and the first mirror is controlled to be turned on.

In one embodiment, the glasses are 3D liquid crystal glasses, and the display panel is a 3D liquid crystal display panel.

The backlight may be a side-entry light source or a direct-illumination light source. The lateral light source comprises a single-side lateral light source and a double-side lateral light source. The control module controls each light-emitting element of the backlight module to be turned on simultaneously. In one display period, the driving signals include a first driving signal and a second driving signal.

As shown in fig. 2, in one embodiment, the lateral light source is a single-side lateral light source, the light emitting elements are LEDs and are N in number, the blocks correspond to the LEDs one by one, and each LED is used for lighting a corresponding block, for example, LED1 lights block BL1, LED2 lights block BL 2.

As shown in fig. 3, in one embodiment, the lateral light source is a double-sided lateral light source, the number of the light emitting elements is 2N, each two LEDs correspond to one block, and each two LEDs light one block, for example, LED1A and LED1B light block BL1, LED2A and LED2B light block BL 2.

The lateral light source uses a small number of light-emitting elements, which is beneficial to reducing the weight of the product.

In one embodiment, as shown in fig. 4, the backlight source is a direct-lit light source. The number of the light-emitting elements is N × M, the light-emitting elements are arranged in a matrix of N rows and M columns, M LEDs in each row correspond to one block, M LEDs in each row are lighted to correspond to one block, and the light-emitting elements are LEDs. The LEDs 1A, LEDs 1B, …, LED1M make up a first row of LED backlight units LEDs 1; LED2A, LED2B, …, LED2M make up a second row of LED backlight units, LEDs 2; …, LEDNA, LEDNB, …, LEDNM constitute the Nth row of LED backlight units LEDN. Each row of LED backlight units is configured to illuminate a corresponding one of the blocks, for example, the LED1 illuminates the block BL1, the LED2 illuminates the block BL 2.

The direct light source can make the brightness of each block of the display panel more uniform.

The light emitting element may also be a CCFL (Cold Cathode Fluorescent Lamp).

In step S2, when the time for writing the first driving signal into the display panel reaches a preset time, each light emitting element of the backlight module is controlled to be turned on simultaneously.

When the time for writing the first driving signal into the display panel reaches the preset time, the penetration rate response of the display panel is stable and tends to be consistent, and the penetration rate response of the glasses is stable and tends to be consistent.

The brightness of each block of the display panel passing through the liquid crystal glasses is the product of the transmittance of the display panel, the transmittance of the glasses and the average backlight brightness of the display panel. The average backlight luminance of the display panel is the average backlight luminance for lighting the display panel, and the luminance of the display panel is the luminance displayed by the display panel. Because of the physical characteristics of liquid crystal response, the display panel and the glasses need to be driven for a certain time to output stable penetration rate, the average backlight brightness of a plurality of blocks of the display panel are different from each other, and if the driving signals are written into the display panel and the glasses are started synchronously with the backlight module, the penetration rate of each block of the display panel, the penetration rate of the glasses corresponding to each block and the product of the average backlight brightness of each block of the display panel are different. Therefore, the transmittance of each block of the display panel tends to be equal through the adjustment of the sequence and time of writing the driving signals into the display panel, the opening of the glasses and the opening of the backlight module, and further the product of the transmittance of each block of the display panel, the transmittance of the glasses corresponding to each block and the backlight average brightness of each block of the display panel tends to be equal, so that the brightness of each block of the display panel passing through the liquid crystal glasses tends to be uniform. The average luminance of the backlight of each block corresponds to the average luminance of the light emitting elements of each block. The transmittance of the glasses corresponding to each zone is the transmittance of the glasses corresponding to the light-emitting element corresponding to each zone.

This application is in under the prerequisite that a plurality of light emitting component of backlight module opened simultaneously, through writing into the first lens of the simultaneous control of display panel with drive signal and opening, when the time that first drive signal wrote into display panel reached preset time, every light emitting component of backlight module was opened simultaneously again in the control, at this moment, the transmissivity of every block of display panel tends to equal and the transmissivity of the glasses that every block corresponds tends to equal to make the luminance that each block of display panel saw through liquid crystal glasses tend to be even.

In step S3, the first turn-on time of each light emitting element is adjusted.

The first turn-on time is the turn-on time of each light emitting element corresponding to the writing of the first driving signal and the turning on of the first mirror in one display period of the display panel.

The application also adjusts the backlight average brightness of each block of the display panel by adjusting the starting time of each light-emitting element, so that the product of the penetration rate of each block of the display panel, the penetration rate of the glasses corresponding to each block and the backlight average brightness of each block of the display panel is equal, and the brightness of each block of the display panel penetrating through the liquid crystal glasses is uniform.

It should be noted that, in one display period of the display panel, the first driving signal is written into the display panel, and the turn-on time of each light emitting element reaches the corresponding first turn-on time and then is turned off.

In step S4, the second driving signal is written into the display panel and the second mirror is controlled to be turned on.

In step S5, when the time for writing the second driving signal into the display panel reaches a preset time, each light emitting element of the backlight module is controlled to be turned on simultaneously.

Step S6, adjusting the second turn-on time of each light emitting element.

The second turn-on time is the turn-on time of each light emitting element corresponding to the writing of the second driving signal and the turning on of the second mirror in one display period of the display panel.

In addition, in one display period of the display panel, the second driving signal is written into the display panel, and the on time of each light emitting element is turned off after reaching the corresponding second on time.

The drive current of each light emitting element is equal. The driving current is used for driving the light-emitting element to emit light.

To better illustrate the method of the present application, a detailed description is given below with reference to fig. 5 to 8. Referring to fig. 5, the turn-on time of each light emitting element is t1, t 2.. and tN, i.e., the lighting time of each corresponding block is t1, t 2.. ton, t1 ═ t2 … ═ tN ═ t, where t is the preset time. Curve 1 is the first driving signal written into the display panel. Curve 2 is the first lens transmittance of the first lens corresponding to each light emitting device, and the first lens transmittance of the first lens corresponding to each light emitting device is L _ T _1, L _ T _2, …, L _ T _ N, respectively. "Δ" of the first half of the display period of fig. 5 is the first panel transmittance corresponding to the on-time of each light emitting element for each tile, and the first panel transmittance corresponding to the on-time of each light emitting element for each tile is OC _ TL _1, OC _ TL _2, …, OC _ TL _ N, respectively.

The first half of the display period of fig. 5 is represented by rectangles for each block, the average luminance of the block BL1 is BL _ ave _1, the average luminance of the block BL2 is BL _ ave _2. Due to the difference in the manufacturing process of the backlight module, BL _ ave _1 ≠ BL _ ave _2 ≠ … ≠ BL _ ave _ N. At this time, the luminance BL _ ave _1 _ OC _ TL _1 _ L _ T _1 ≠ BL _ ave _2 _ OC _ TL _2 _ L _ T _2 ≠ … ≠ BL _ ave _ N _ OC _ TL _ N _ L _ T _ N of each block of the display panel viewed by the user through the first mirror, i.e., the luminance of each block of the display panel through the first mirror is not uniform.

Curve 3 is the second driving signal written into the display panel. The curve 4 is the second glasses transmittance of the second lens corresponding to each light emitting device, and the second glasses transmittance of the second lens corresponding to each light emitting device is R _ T _1, R _ T _2, …, R _ T _ N, respectively. "Δ" in the second half of the display period of fig. 5 is the second panel transmittance corresponding to the on-time of each light emitting element for each block, and the second panel transmittance corresponding to the on-time of each light emitting element for each block is OC _ TR _1, OC _ TR _2, …, OC _ TR _ N, respectively. The second half of fig. 5 shows a periodic rectangle representing the average backlight luminance of each block, the average luminance of the block BL1 is BL _ ave _1, the average luminance of the block BL2 is BL _ ave _2. Due to differences in manufacturing processes of the backlight modules, BL _ ave _1 ≠ BL _ ave _2. At this time, the luminance BL _ ave _1 × OC _ TR _1 × R _ T _1 ≠ BL _ ave _2 × OC _ TR _2 _ R _ T _2 ≠ … ≠ BL _ ave _ N × OC _ TR _ N × R _ T _ N of each block of the display panel viewed by the user through the second mirror, i.e., the luminance of each block of the display panel through the second mirror is not uniform.

Referring to fig. 6 to 8, the driving signal is written into the display panel while the first mirror is turned on, and when the time for writing the driving signal into the display panel reaches a preset time, each light emitting element of the backlight module is controlled to be turned on simultaneously, and the turn-on time of each light emitting element is adjusted, so as to adjust the backlight average brightness of each block of the display panel, wherein the turn-on time of each light emitting element is adjusted from t1, t2,. and tN to the first turn-on time tL1, tL2,. such, tLN and the second turn-on time tR1, tR2,. tRN, respectively. Corresponding to the first on-time of each light emitting element, the average luminance of the block BL1 is changed from BL _ ave _1 to BL _ ave _ L1 ', the average luminance of the block BL2 is changed from BL _ ave _2 to BL _ ave _ L2 ', and the average luminance of the block BLN is changed from BL _ ave _ N to BL _ ave _ LN '. The first panel transmittance of each zone corresponding to the on-time of each light emitting element is changed from OC _ TL _1, OC _ TL _2, …, OC _ TL _ N to OC _ TL _1 ', OC _ TL _ 2', …, OC _ TL _ N ', OC _ TL _ 1' ≈ OC _ TL _2 '… ≈ OC _ TL _ N', respectively. The first lens penetration rate of the first lens corresponding to each light emitting element is changed from L _ T _1, L _ T _2, …, L _ T _ N to L _ T _1 ', L _ T _ 2', …, L _ T _ N ', L _ T _ 1' ≈ L _ T _2 '… ≈ L _ T _ N', respectively. At this time, the luminance BL _ ave _ L1 ' × OC _ TL _1 ' × L _ T _1 ' ═ BL _ ave _ L2 ' × OC _ TL _2 ' × L _ T _2 ' ═ BL _ ave _ LN ' × OC _ TL _ N ' × L _ T _ N ' of each block of the display panel seen by the user through the first mirror is uniform.

Corresponding to the second on time of each light emitting element, the average luminance of the block BL1 is changed from BL _ ave _1 to BL _ ave _ R1 ', the average luminance of the block BL2 is changed from BL _ ave _2 to BL _ ave _ R2 ', and the average luminance of the block BLN is changed from BL _ ave _ N to BL _ ave _ R N '. The second glasses penetration rate of the second lens corresponding to each light emitting element is changed from R _ T _1, R _ T _2, …, R _ T _ N to R _ T _1 ', R _ T _ 2', …, R _ T _ N ', R _ T _ 1' ≈ R _ T _2 '… ≈ R _ T _ N', respectively. The second panel transmittance of each patch corresponding to the on-time of each light emitting element is changed from OC _ TR _1, OC _ TR _2, …, OC _ TR _ N to OC _ TR _1 ', OC _ TR _ 2', …, OC _ TR _ N ', OC _ TR _ 1' ≈ OC _ TR _2 '… ≈ OC _ TR _ N', respectively. At this time, the luminance BL _ ave _ R1 ' × OC _ TR _1 ' × R _ T _1 ' ═ BL _ ave _ R _2 ' × OC _ TR _2 ' × R _ T _2 ' ═ … ═ BL _ ave _ R N ' × OC _ TR _ N ' × R _ T _ N ' of each block of the display panel viewed by the user through the first mirror is uniform in luminance through the second mirror.

Referring to fig. 9, in an embodiment, step S1 is preceded by the steps of:

step S10, writing the first driving signal into the display panel, controlling the first lens to turn on and controlling each light emitting element of the backlight module to turn on.

Step S20, detecting the penetration rate of each block of the display panel changing with time and recording the response time of the penetration rate.

And step S30, comparing the penetration rate to obtain the preset time according to the response time.

To sum up, according to the brightness adjustment method of the display system of the present application, on the premise that the plurality of light emitting elements of the backlight module are simultaneously turned on, the first lens is controlled to be turned on by writing the driving signal into the display panel, and when the time for writing the first driving signal into the display panel reaches the preset time, each light emitting element of the backlight module is controlled to be turned on simultaneously, at this time, the penetration rate of each block of the display panel tends to be equal, and the penetration rate of the glasses corresponding to each block tends to be equal; and the average backlight brightness of each block of the display panel is further adjusted by adjusting the on-time of each light-emitting element, so that the product of the penetration rate of each block of the display panel, the penetration rate of the glasses corresponding to each block and the average backlight brightness of each block of the display panel is equal, and the brightness of each block of the display panel penetrating through the liquid crystal glasses is uniform.

The following describes in detail a brightness adjustment method of a display system provided in an embodiment of the present application with reference to fig. 10. It should be noted that, the brightness adjustment system shown in fig. 10 is used for executing the method of the embodiment shown in fig. 1 of the present application, and for convenience of description, only the portion related to the embodiment of the present application is shown, and details of the technology are not disclosed, please refer to the embodiment shown in fig. 1 of the present application.

Referring to fig. 10, the brightness adjusting system is used for adjusting the brightness of a display panel through glasses, the display panel is lighted by a backlight module, the glasses include a first lens and a second lens, the display panel includes a plurality of blocks, the backlight module includes a plurality of light emitting elements, and the plurality of light emitting elements form a backlight source. The backlight source is a side-in light source. The brightness adjusting system comprises a signal driving module, a glasses driving module and a control module.

The signal driving module is used for writing a first driving signal into the display panel; the glasses driving module is used for controlling the first lens to be opened. The control module is used for controlling the time of the signal driving module for writing the first driving signal into the display panel to be consistent with the time of the glasses driving module for controlling the first lens to be opened. The control module is further used for controlling each light-emitting element of the backlight module to be simultaneously started when the time for writing the first driving signal into the display panel reaches the preset time. The control module is further used for adjusting the first opening time of each light-emitting element;

the signal driving module is further used for writing a second driving signal into the display panel. The glasses driving module is also used for controlling the second lens to be opened. The control module is further used for controlling the time for writing the second driving signal into the display panel by the signal driving module to be consistent with the time for controlling the second lens to be opened by the glasses driving module. The control module is further configured to adjust a second on time of each light emitting element.

According to the brightness adjusting system, on the premise that the plurality of light emitting elements of the backlight module are simultaneously started, the driving signal is written into the display panel and the first lens is controlled to be started, when the time for writing the driving signal into the display panel reaches the preset time, each light emitting element of the backlight module is controlled to be simultaneously started, and at the moment, the penetration rate of each block of the display panel tends to be equal and the penetration rate of glasses corresponding to each block tends to be equal; and the average backlight brightness of each block of the display panel is further adjusted by adjusting the on-time of each light-emitting element, so that the product of the penetration rate of each block of the display panel, the penetration rate of the glasses corresponding to each block and the average backlight brightness of each block of the display panel is equal, and the brightness of each block of the display panel penetrating through the liquid crystal glasses is uniform.

The application also provides a display system, which comprises a display panel and the brightness adjusting system.

The display panel of the embodiment of the invention can be any one of the following: a liquid crystal display panel, an OLED display panel, a QLED display panel, a Twisted Nematic (TN) or Super Twisted Nematic (STN) type, an In-Plane Switching (IPS) type, a Vertical Alignment (VA) type, a curved panel, or other display panels.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (6)

1. A brightness adjusting method of a display system is used for adjusting the brightness of a display panel penetrating through glasses, the display panel is lightened by a backlight module, the glasses comprise a first lens and a second lens, the display panel comprises a plurality of blocks, and the backlight module comprises a plurality of light-emitting elements; the brightness adjusting method of the display system is characterized by comprising the following steps of:

writing a first driving signal into the display panel, controlling the first lens to be started and controlling each light-emitting element of the backlight module to be started, wherein the driving current of each light-emitting element is equal;

detecting the penetration rate of each block of the display panel along with the change of time and recording the response time of the penetration rate;

comparing the penetration rate to obtain preset time according to the response time;

writing a first driving signal into the display panel, and simultaneously controlling the first lens to be opened;

when the time for writing the first driving signal into the display panel reaches the preset time, controlling each light-emitting element of the backlight module to be simultaneously started;

adjusting a first on time of each light emitting element;

writing a second driving signal into the display panel, and simultaneously controlling the second lens to be opened;

when the time for writing the second driving signal into the display panel reaches the preset time, controlling each light-emitting element of the backlight module to be simultaneously started, wherein the driving current of each light-emitting element is equal;

the second on time of each light emitting element is adjusted.

2. A brightness adjusting system is used for adjusting the brightness of a display panel through glasses, the display panel is lightened by a backlight module, the glasses comprise a first lens and a second lens, the display panel comprises a plurality of blocks, and the backlight module comprises a plurality of light-emitting elements; it is characterized in that the preparation method is characterized in that,

the brightness adjusting system comprises a signal driving module, a glasses driving module, a control module and a penetration rate detector;

the signal driving module is used for writing a first driving signal into the display panel; the glasses driving module is used for controlling the first lens to be opened; the control module is used for controlling the signal driving module to write a first driving signal into the display panel, and the time for controlling the glasses driving module to open the first lens is consistent with the time for controlling the glasses driving module to open the first lens;

the control module is further used for controlling each light-emitting element of the backlight module to be simultaneously started when the time for writing the first driving signal into the display panel reaches the preset time, and the driving current of each light-emitting element is equal;

the control module is further used for adjusting the first opening time of each light-emitting element;

the signal driving module is also used for writing a second driving signal into the display panel; the glasses driving module is also used for controlling the opening of the second lens; the control module is also used for controlling the time for writing the second driving signal into the display panel by the signal driving module to be consistent with the time for controlling the second lens to be opened by the glasses driving module;

the control module is further used for controlling each light-emitting element of the backlight module to be simultaneously started when the time for writing the second driving signal into the display panel reaches the preset time, and the driving current of each light-emitting element is equal;

the control module is further used for adjusting the second opening time of each light-emitting element;

the penetration rate detector is used for detecting the penetration rate of each block of the display panel along with the change of time and recording the response time of the penetration rate when the signal driving module writes a first driving signal into the display panel, the glasses driving module controls the first lens to be started and the control module controls each light-emitting element of the backlight module to be started; the penetration rate detector is also used for transmitting the penetration rate and the response time to the control module; the control module is further used for comparing the penetration rate to obtain the preset time according to the response time.

3. The system of claim 2, wherein the plurality of light emitting elements form a backlight source, the backlight source is a single-side edge type light source, the number of the light emitting elements is N, the blocks correspond to the light emitting elements one to one, and each light emitting element is configured to illuminate a corresponding block.

4. The system of claim 2, wherein the plurality of light emitting elements constitute a backlight source, the backlight source is a bilateral lateral light source, the number of the light emitting elements is 2N, each two light emitting elements correspond to one block, and each two light emitting elements illuminate a corresponding block.

5. A brightness adjusting system according to claim 2, wherein the plurality of light emitting elements constitute a backlight source, the backlight source is a direct-type light source, the number of light emitting elements is N × M, and the light emitting elements are arranged in a matrix of N rows and M columns, M light emitting elements in each row correspond to one block, and M light emitting elements in each row illuminate a corresponding block.

6. A display system comprising a display panel and a brightness adjustment system according to any one of claims 2 to 5.

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