Patent Description:
At present, the liquid crystal display regional backlight brightness control scheme for televisions and other display fields is taking LED (Light Emitting Diode) array as a light source, coordinating with the system to matrix-divide the image signal and calculate the data corresponding to the grayscale values of different matrix addresses through communication protocols such as SPI and control equipment such as multi-region matrix controller, and controlling the matrix controller to output the corresponding PWM signal to control the brightness and darkness of each LED to achieve the control of the brightness and darkness of the backlight in different regions, so as to achieve the purpose of multi-region local dimming to reduce screen light leakage and improve dynamic contrast.

However, with the continuous improvement of liquid crystal display resolution, <NUM>, <NUM> and other display technologies continue to mature, the market demand continues to expand, the number of backlight LED lights, the complexity of the design of the multi-region matrix controller, the maximum number of controllable regions, heat dissipation, the main controller scheme and other aspects are limited. The multi-region backlight technology still cannot achieve pixel-level control, and cannot achieve smaller area brightness changes and higher contrast.

<CIT> provides a display including a color panel, an achromatic panel, a backlight, and a panel controller configured to generate color panel and achromatic panel drive values. The panels may be LCD panels. The color panel drive values dynamically compensating for variations in the color of light transmitted by the achromatic panel due to varying drive conditions of the achromatic panel. The invention includes a system, method, or controller for generating or providing color panel drive values (and optionally also achromatic panel drive values) for a dual panel display in accordance with any embodiment of the method), and optionally also storing the drive values in an look-up table, and a computer readable medium which stores code for implementing any embodiment of the method.

<CIT> provides a display apparatus, an electronic device including the same, and a method of operating the same are provided. The electronic device includes a display including a first region and a second region, a first driving module configured to generate processing information corresponding to a first image to be displayed in the first region of the display, and a second driving module configured to receive the processing information from the first driving module, and to compensate for a second image to be displayed in the second region of the display, based on the processing information.

<CIT> provides a direct-view display apparatus including a transparent substrate, an internal light source, a plurality of light modulators coupled to the transparent substrate, and a controller for controlling the states of the plurality of light modulators and the internal light source. The controller is configured to cause the display to transition from one of a transmissive, reflective and transflective mode, to a second of said modes.

The main object of the present application is to provide a multi-region backlight control system, a multi-region backlight control method, a television and a readable storage medium, aiming to solve the technical problems that the multi-region backlight technology in the prior art cannot achieve smaller regional brightness changes and higher contrast.

In order to achieve the above object, the present application provides a multi-region backlight control system according to the independent claim <NUM>.

Preferably, the main controller includes a signal decoder, a signal displayer, a signal encoder, an image collecter, a signal processor and a control outputer; the signal decoder, the signal displayer, the signal encoder and the first driver are connected in sequence; the signal displayer, the image collecter, the signal processor, the control outputer and the second driver are connected in sequence.

Preferably, the multi-region backlight control system further includes a light sensor, where the main controller further includes an interface; the light sensor is connected with the interface, and the interface is connected with the signal processor; the light sensor is configured to detect change of ambient light around a television to obtain detection data, and the light sensor is configured to send the detection data to the signal processor through the interface; the signal processor is configured to process the detection data after receiving the detection data.

The present application further provides a multi-region backlight control method, which is applied to a television according to independent claim <NUM> and corresponding independent claim <NUM>. The television includes the multi-region backlight control system described above.

Preferably, the main controller includes a signal decoder, a signal displayer and a signal encoder; the signal decoder, the signal displayer, the signal encoder and the first driver are connected in sequence; where the step of in response to receiving an image signal, processing, by the main controller, the image signal to obtain image data, sending, by the main controller, the image data to the first driver and the second driver synchronously includes:.

Preferably, the main controller further includes an image collecter, a signal processor and a control outputer; the signal displayer, the image collecter, the signal processor, the control outputer and the second driver are connected in sequence; where the step of converting, by the second driver, the received image data into a control signal, and driving, by the second driver, the non-color liquid crystal display screen to adjust light transmittance based on the control signal includes:.

Preferably, the step of sending, by the signal processor, the adjustment result to the second driver through the control outputer includes:
saving, by the signal encoder, image data of a previous frame, optimizing and adjusting, by the signal processor, the image data to obtain the adjustment result, sending, by the signal processor, the adjustment result to the control outputer, processing, by the control outputer, the adjustment result to obtain the second processing result, and sending, by the control outputer, the first processing result to the second driver.

Preferably, the multi-region backlight control system further includes a light sensor, and the main controller further comprises an interface; the light sensor is connected with the interface, and the interface is connected with the signal processor; where the step of subsequent to receiving the image data, converting, by the second driver, the image data into the control signal further includes:.

In addition, in order to achieve the above object, the present application further provides a readable storage medium according to claim <NUM>.

In this application, a non-color liquid crystal display screen is set between a color liquid crystal display screen and a constant backlight source. When receiving an image signal, a main controller processes the image signal to obtain image data and sends the image data to a first driver and a second driver synchronously. The first driver converts the image data into a display signal, and drives the color liquid crystal display screen to output a display image. Meanwhile, the second driver converts the image data into a control signal, and drives the non-color liquid crystal display screen to adjust light transmittance of each pixel of the non-color liquid crystal display screen, and cooperates with the constant backlight source to drive the color liquid crystal display screen to display image. It is realized that in a certain state, the main controller may simultaneously control the rotation angle of the liquid crystal molecules of the color liquid crystal display screen and the non-color liquid crystal display screen, so that lights of different brightness are transmitted through different pixels, thereby achieving the purpose of controlling the brightness and darkness of the multi-region backlight. In this application, the display signal and the control signal are synchronously output to ensure the synchronization of the control of the non-color liquid crystal display screen and the color liquid crystal display screen. At the same time, different regional brightnesses and darknesses in the display signal are output by the main controller to the color liquid crystal display screen to synchronize the control of the switching angle of the liquid crystal molecules in the corresponding region of the non-color liquid crystal display screen to achieve dimming in different regions and improve the display contrast of the screen. The local backlight brightness and darkness is adjusted to improve the dynamic contrast of the display, which greatly reduces light leakage and alleviates the eye fatigue caused by watching the television for a long time. The viewer's eyes gain comfort and the user experience is improved.

The purposes, functional features and advantages of this application will be further described in conjunction with the embodiments and with reference to the drawings.

It should be understood that the specific embodiments described herein are only used to explain the present application, and are not used to limit the present application.

As shown in <FIG> is a schematic hardware structure diagram of a television according to an embodiment of the present application.

As shown in <FIG>, the television may include: a processor <NUM>, such as a CPU, a network interface <NUM>, a user interface <NUM>, a memory <NUM>, and a communication bus <NUM>. The communication bus <NUM> is configured to implement connection communication between these components. The user interface <NUM> may include a display, an input unit such as a keyboard, and optionally the user interface <NUM> may further include a standard wired interface and a wireless interface. The network interface <NUM> may optionally include a standard wired interface and a wireless interface (such as a WI-FI interface). The memory <NUM> may be a high-speed RAM memory or a stable memory (non-volatile memory), such as a disk memory. The memory <NUM> may optionally be a storage device independent of the foregoing processor <NUM>.

Optionally, the television may further include a camera, an RF (Radio Frequency) circuit, a sensor, an audio circuit, a WiFi module, and so on. Certainly, the television may also be equipped with other sensors such as gyroscopes, barometers, hygrometers, thermometers, and infrared sensors, which will not be repeated here.

Those skilled in the art may understand that the structure of the television shown in <FIG> does not constitute a limitation on the television, and more or less components than those illustrated may be included, or certain components may be combined, or different components may be arranged.

As shown in <FIG>, the memory <NUM> as a computer storage medium may include an operating system, a network communication module, a user interface, and a multi-region backlight control program.

In the television shown in <FIG>, the network interface <NUM> is mainly configured to connect to the back-end server and perform data communication with the back-end server; the user interface <NUM> is mainly configured to connect to the client (user end) and perform data communication with the client; and the processor <NUM> may be configured to call the multi-region backlight control program stored in the memory <NUM> and implement the following operations:.

Further, the processor <NUM> may call the multi-region backlight control program stored in the memory <NUM>, and further implements the following operations:.

Further, the processor <NUM> may call the multi-region backlight control program stored in the memory <NUM>, and further implements the following operations:
saving, by the signal encoder, image data of a previous frame, optimizing and adjusting, by the signal processor, the image data to obtain the adjustment result, sending, by the signal processor, the adjustment result to the control outputer, processing, by the control outputer, the adjustment result to obtain the first processing result, and sending, by the control outputer, the first processing result to the second driver.

Referring to <FIG>, <FIG> is a block schematic diagram of a multi-region backlight control system according to a first embodiment of this application; and <FIG> is a light flow diagram of the multi-region backlight control system according to the first embodiment of this application.

In the first embodiment, the multi-region backlight control system includes a color liquid crystal display screen <NUM>, a non-color liquid crystal display screen <NUM>, a first driver <NUM>, a second driver <NUM>, a constant backlight source <NUM>, and a main controller <NUM>. The color liquid crystal display screen <NUM> and the non-color liquid crystal display screen <NUM> are sequentially fixed on the constant backlight source <NUM>, and the non-color liquid crystal display screen <NUM> is disposed between the color liquid crystal display screen <NUM> and the constant backlight source <NUM>. The main controller <NUM> is respectively connected with the first driver <NUM>, the second driver <NUM> and the constant backlight source <NUM>, the first driver <NUM> is electrically connected with the color liquid crystal display screen <NUM>, and the second driver <NUM> is electrically connected with the non-color liquid crystal display screen <NUM>.

In response to receiving an image signal, the main controller <NUM> is configured to process the image signal to obtain image data, the main controller <NUM> is configured to send the image data to the first driver <NUM> and the second driver <NUM> synchronously and control the constant backlight source <NUM> to be turned on. The first driver <NUM> is configured to convert the received image data into a display signal and drive the color liquid crystal display screen <NUM> to output a display image based on the display signal. The second driver <NUM> is configured to convert the received image data into a control signal and drive the non-color liquid crystal display screen <NUM> to adjust light transmittance of each pixel of the non-color liquid crystal display screen <NUM> based on the control signal.

The color liquid crystal display screen <NUM> is a liquid crystal display screen with a color filter, that is, the liquid crystal display screen currently used in liquid crystal display products such as televisions, which may output color images. The non-color liquid crystal display screen <NUM> is a liquid crystal display without a color filter, which only includes filters, TFTs and liquid crystals, etc. TFT (Thin Film Transistor) may only output black and white images. The constant backlight source <NUM> may be in the form of a direct array of LED lights, or may be an edge-lit linear arrangement, and may also be other types of backlight sources. This system may be applied to a variety of backlight source solutions. The color liquid crystal display screen <NUM> is the main display screen and the outermost image display of the entire displayer <NUM>. The non-color liquid crystal display screen <NUM> is designed between the color liquid crystal display screen <NUM> and the constant backlight source <NUM>, which is used as the light transmittance controller of the backlight control system and configured to adjust the light transmittance by controlling the rotation angle of the liquid crystal molecules. The main controller <NUM> outputs the display signal to the color liquid crystal display screen <NUM> and the control signal to the non-color liquid crystal display screen <NUM> synchronously, that is, in a certain state, the main controller <NUM> controls the rotation angles of the liquid crystal molecules of the color liquid crystal display screen <NUM> and the non-color liquid crystal display screen <NUM> simultaneously. After the constant backlight source <NUM> passes through the non-color liquid crystal display screen <NUM>, lights of different brightnesses are transmitted through different pixels to achieve the purpose of controlling the brightness and darkness of the multi-region backlight.

The main controller <NUM> may output the display signal and the control signal synchronously, which may be realized by setting a synchronization processor <NUM> in the main controller. The synchronization processor <NUM> may be implemented by a clock signal. For example, when the display signal is output and the clock signal is detected to be converted from low to high, the control signal is controlled to be output, so that the synchronous output of the display signal and the control signal is realized. The synchronous output of the display signal and the control signal is realized by the synchronization processor <NUM>, so that the effect of this control mode is more favorable. This application has been proved by experiments that, even if the synchronization processor <NUM> is not provided, the difference between the output of the display signal and the output of the control signal is only a few milliseconds, and the human eye cannot perceive it when viewing the display image, which does not affect the viewing effect. The main controller <NUM> outputs the display signal and the control signal synchronously to ensure the synchronization of control of the non-color liquid crystal display screen and the color liquid crystal display screen. Different regional brightnesses and darknesses in the display signal output by the main controller to the color liquid crystal display screen are calculated through a specific algorithm, so as to synchronously control the switching angle of the liquid crystal molecules in the corresponding region of the non-color liquid crystal display screen to achieve dimming in different regions and improve screen contrast.

In this application, a non-color liquid crystal display screen <NUM> is set between a color liquid crystal display screen <NUM> and a constant backlight source <NUM>. When receiving an image signal, a main controller <NUM> processes the image signal to obtain image data and sends the image data to a first driver <NUM> and a second driver <NUM> synchronously. The first driver <NUM> converts the image into a display signal, and drives the color liquid crystal display screen <NUM> to output a display image. Meanwhile, the second driver <NUM> converts the image data into a control signal, and drives the non-color liquid crystal display screen <NUM> to adjust light transmittance of each pixel of the non-color liquid crystal display screen, and cooperates with the constant backlight source <NUM> to drive the color liquid crystal display screen <NUM> to display image. It is realized that in a certain state, the main controller <NUM> may simultaneously control the rotation angle of the liquid crystal molecules of the color liquid crystal display screen <NUM> and the non-color liquid crystal display screen <NUM>, so that lights of different brightness are transmitted through different pixels, thereby achieving the purpose of controlling the brightness and darkness of the multi-region backlight. In this application, the display signal and the control signal are synchronously output to ensure the synchronization of the control of the non-color liquid crystal display screen <NUM> and the color liquid crystal display screen <NUM>. At the same time, different regional brightnesses and darknesses in the display signal are output by the main controller <NUM> to the color liquid crystal display screen to synchronize the control of the switching angle of the liquid crystal molecules in the corresponding region of the non-color liquid crystal display screen <NUM> to achieve dimming in different regions and improve the display contrast of the screen. The local backlight brightness and darkness is adjusted to improve the dynamic contrast of the display, which greatly reduces light leakage and alleviates the eye fatigue caused by watching the television for a long time. The viewer's eyes gain comfort and the user experience is improved.

Preferably, the main controller <NUM> includes a signal decoder <NUM>, a signal displayer <NUM>, a signal encoder <NUM>, an image collecter <NUM>, a signal processor <NUM> and a control outputer <NUM>. The signal decoder <NUM>, the signal displayer <NUM>, the signal encoder <NUM> and the first driver <NUM> are connected in sequence. The signal displayer <NUM>, the image collecter <NUM>, the signal processor <NUM>, the control outputer <NUM> and the second driver <NUM> are connected in sequence.

The signal decoder <NUM> decodes the input image signal, and then the decoded signal is encoded according to the output signal standard through the signal displayer <NUM> and the signal encoder <NUM> to output, so as to obtain image data signal and clock signal such as VBO (V-By-One), LVDS to drive the color liquid crystal display screen <NUM> for display. The image signal collecter collects the decoded display signal and adjusts and optimizes the display signal through software algorithms in signal processing to achieve the intended purpose. The adjusted and optimized signal, that is, the adjustment result, is encoded by the control outputer <NUM> and output to the second driver <NUM>, thus the purpose of controlling the non-color liquid crystal display screen <NUM> is achieved. The signal processor <NUM> may use the image data collected in the previous frame for statistics and processing to obtain the corresponding adjustment result, and then re-encode and output the adjustment result through the control outputer <NUM>. A new image signal obtained by the second driver <NUM> is applied in the image display of the next frame, so that the dynamic control of the backlight in different pixel regions of the non-color liquid crystal display screen <NUM> is realized.

Preferably, the multi-region backlight control system further includes a light sensor <NUM>, where the main controller further includes an interface <NUM>. The light sensor <NUM> is connected with the interface <NUM>, and the interface <NUM> is connected with the signal processor <NUM>. The light sensor <NUM> is configured to detect change of ambient light around a television to obtain detection data, and the light sensor <NUM> is configured to send the detection data to the signal processor <NUM> through the interface <NUM>. The signal processor <NUM> is configured to process the detection data after receiving the detection data.

As shown in <FIG>, the light sensor <NUM> detects changes in ambient light around the television and transmits the detection data to the main controller <NUM> in real time. The main controller <NUM> converts the collected image signals to perform dynamic compensation adjustment according to the changes in ambient light to enhance or reduce the light transmittance of the backlight in the non-color liquid crystal display screen <NUM>, so as to achieve the enhancement or reduction of the grayscale value displayed by the non-color liquid crystal display screen <NUM>, thereby achieving the purpose of overall enhancement and reduction of the backlight. For example, when the ambient light is different, the detected data is A1 to An, where the ambient light corresponding to An is the brightest and the ambient light corresponding to A1 is the darkest. The software uses the formula L=aA<NUM>+bA+C and the algorithm to set the brightness value of the output signal corresponding to A1 as L1 and set the brightness value of the output signal corresponding to An as Ln, where L1 to Ln correspond to gray-scale brightness change curve of the output signal. This curve may be used to calculate the brightness value L through software algorithm and certain formula and set different modes according to the different scenes of the screen, so as to achieve the purpose of using non-color liquid crystal glass to control the light transmittance to strengthen and reduce the backlight.

Referring to <FIG> is a schematic flowchart of a multi-region backlight control method according to the first embodiment of this application.

In the first embodiment, the multi-region backlight control method includes:
Step S10: in response to receiving an image signal, processing, by the main controller, the image signal to obtain image data, sending, by the main controller, the image data to the first driver and the second driver synchronously, and controlling, by the main controller, the constant backlight source to be turned on.

In this embodiment, the first driver and the second driver may convert the image data signals and clock signals such as VBO, LVDS, etc. output by the main controller into line field control signals that can be recognized by the liquid crystal display screen. The distortion degree of liquid crystal molecules is changed by TFT operation in the control panel of the line field control signal, thereby changing the light transmittance of each pixel, and driving the liquid crystal display screen to display images in cooperation with the backlight.

Step S20: converting, by the first driver, the received image data into a display signal, and driving, by the first driver, the color liquid crystal display screen to output a display image based on the display signal.

In this embodiment, the first driver converts the received image data into the display signal, and drives the color liquid crystal display screen to output the display image based on the display signal. When the image signal is received, the signal decoder decodes the image signal to obtain image information. The signal decoder sends the image information to the signal displayer, and the signal displayer processes the image information to obtain image data. The signal displayer sends the image data to the signal encoder, and the encoder encodes according to the output signal standard, and outputs the encoding result to the first driver, so as to convert the encoding result into a display signal, and the first driver drives the color liquid crystal display screen to output the display image based on the display signal.

Step S30: converting, by the second driver, the received image data into a control signal, and driving, by the second driver, the non-color liquid crystal display screen to adjust light transmittance based on the control signal.

In this embodiment, the second driver converts the received image data into the control signal, and drives the non-color liquid crystal display screen to adjust the light transmittance based on the control signal. The main controller may output the display signal and the control signal synchronously, which may be realized by setting a synchronization processor in the main controller. The synchronization processor may be implemented by a clock signal. For example, when the display signal is output and the clock signal is detected to be converted from low to high, the control signal is controlled to be output, so that the synchronous output of the display signal and the control signal is realized. The synchronous output of the display signal and the control signal is realized by the synchronization processor, so that the effect of this control mode is more favorable. This application has been proved by experiments that, even if the synchronization processor is not provided, the difference between the output of the display signal and the output of the control signal is only a few milliseconds, and the human eye cannot perceive it when viewing the display image, which does not affect the viewing effect. The main controller outputs the display signal and the control signal synchronously to ensure the synchronization of control of the non-color liquid crystal display screen and the color liquid crystal display screen. Different regional brightnesses and darknesses in the display signal output by the main controller to the color liquid crystal display screen are calculated through a specific algorithm, so as to synchronously control the switching angle of the liquid crystal molecules in the corresponding region of the non-color liquid crystal display screen to achieve dimming in different regions and improve screen contrast. The first driver drives the color liquid crystal display screen to output the display image according to the display signal. At the same time, the second driver drives the non-color liquid crystal display screen to adjust its light transmittance according to the control signal, and the main controller controls the constant backlight source to be turned on. In order to output the display signal and the control signal synchronously, the signal processor in the main controller may use the image data collected in the previous frame for statistics and processing to obtain the corresponding adjusted image signal, and then re-encode and output the image signal through the control outputer. The new image signal obtained by the second driver is applied to the image display of the next frame to realize the dynamic control of the backlight in different pixel regions of the non-color liquid crystal display screen. In addition, the signal encoder in the main controller may also store the image data of the last frame, and wait for the image collecter, the signal processor and control outputer to process, encode and output the collected signal, and then output at the same time, so that the first driver and the second driver may simultaneously acquire one frame of signal display data. thereby eliminating the display image distortion caused by scene switching.

In this application, a non-color liquid crystal display screen is set between a color liquid crystal display screen and a constant backlight source. When receiving an image signal, a main controller processes the image signal to obtain image data and sends the image data to a first driver and a second driver synchronously. The first driver converts the image data into a display signal, and drives the color liquid crystal display screen to output a display image. Meanwhile, the second driver converts the image data into a control signal, and drives the non-color liquid crystal display screen to adjust light transmittance of each pixel of the non-color liquid crystal display screen, and cooperate with the constant backlight source to drive the color liquid crystal display screen to display image. It is realized that in a certain state, the main controller may simultaneously control the rotation angle of the liquid crystal molecules of the color liquid crystal display screen and the non-color liquid crystal display screen, so that lights of different brightness are transmitted through different pixels, thereby achieving the purpose of controlling the brightness and darkness of the multi-region backlight. In this application, the display signal and the control signal are output synchronously to ensure the synchronization of control of the non-color liquid crystal display screen and the color liquid crystal display screen. At the same time, different regional brightnesses and darknesses in the display signal are output by the main controller to the color liquid crystal display screen, so as to synchronously control the switching angle of the liquid crystal molecules in the corresponding region of the non-color liquid crystal display screen to achieve dimming in different regions and improve screen contrast.

Based on the first embodiment, a second embodiment of the multi-region backlight control method of the present application is provided. The main controller includes a signal decoder, a signal displayer, and a signal encoder. The signal decoder, the signal displayer, the signal encoder, and the first driver are connected in sequence. Referring to <FIG>, step S10 includes:.

In this embodiment, the first driver and the second driver may convert the image data signals and clock signals such as VBO (V-By-One) (digital interface standard), LVDS (Low Voltage Differential Signal), etc. output by the main controller into line field control signals that can be recognized by the liquid crystal display screen. The distortion degree of liquid crystal molecules is changed by TFT operation in the control panel of the line field control signal, thereby changing the light transmittance of each pixel, and driving the liquid crystal display screen to display images in cooperation with the backlight. The signal decoder decodes the input image signal, and then the decoded signal is encoded according to the output signal standard through the signal displayer and the signal encoder to output, so as to obtain image data signal and clock signal such as VBO (V-By-One), LVDS to drive the color liquid crystal display screen <NUM> for display.

Based on the second embodiment, a third embodiment of the multi-region backlight control method of the present application is provided. The main controller further includes an image collecter, a signal processor and a control outputer. The signal displayer, the image collecter, the signal processor, the control outputer and the second driver are connected in sequence. Please refer to <FIG>, step S30 includes:.

In this embodiment, the control signal is controlled by the image collecter, the signal processor and the control outputer. The control outputer may encode the adjustment result to obtain image data signal and clock signal such as VBO (V-By-One) and LVDS, and the image data signal and the clock signal are output to the second driver to realize the synchronous output of the control signal and the display signal. The signal processor may use the image data collected in the previous frame for statistics and processing to obtain the corresponding adjustment result, and then re-encode and output the adjustment result through the control outputer. A new image signal obtained by the second driver is applied in the image display of the next frame, so that the dynamic control of the backlight in different pixel regions of the non-color liquid crystal display screen is realized.

Further, step S33 includes:
saving, by the signal encoder, image data of a previous frame, optimizing and adjusting, by the signal processor, the image data to obtain the adjustment result, sending, by the signal processor, the adjustment result to the second driver through the control outputer.

In this embodiment, the signal encoder may store the image data of the last frame, and wait for the image collecter, the signal processor and control outputer to process, encode and output the collected signal, and then output at the same time, so that the first driver and the second driver may simultaneously acquire one frame of signal display data to eliminate the display image distortion caused by scene switching.

Based on the third embodiment, a fourth embodiment of the multi-region backlight control method of the present application is provided. The multi-region backlight control system further includes a light sensor, the light sensor is connected with an interface, and the interface is connected with the signal processor. Please refer to <FIG>, step S30 further includes:.

In this embodiment, the light sensor obtains detection data after detecting changes in ambient light around the television, and the light sensor sends the detection data to the signal processor through the interface. After receiving the detection data, the signal processor performs dynamic compensation adjustment on the adjustment result to obtain a compensation signal. The signal processor sends the compensation signal to the control outputer, and the control outputer processes the compensation signal to obtain a second processing result and send the second processing result to the second driver. After receiving the second processing result, the second driver converts the second processing result into a control signal and drives the non-color liquid crystal display screen to adjust the light transmittance based on the control signal. As shown in <FIG>, the light sensor <NUM> detects changes in ambient light around the television and transmits the detection data to the main controller <NUM> in real time. The main controller <NUM> converts the collected image signals to perform dynamic compensation adjustment according to the changes in ambient light to enhance or reduce the light transmittance of the backlight in the non-color liquid crystal display screen <NUM>, so as to achieve the enhancement or reduction of the grayscale value displayed by the non-color liquid crystal display screen <NUM>, thereby achieving the purpose of overall enhancement and reduction of the backlight. For example, when the ambient light is different, the detected data is A1 to An, where the ambient light corresponding to An is the brightest and the ambient light corresponding to A1 is the darkest. The software uses the formula L=aA<NUM>+bA+C and the algorithm to set the brightness value of the output signal corresponding to A1 as L1 and set the brightness value of the output signal corresponding to An as Ln, where L1 to Ln correspond to gray-scale brightness change curve of the output signal. This curve may be used to calculate the brightness value L through software algorithm and certain formula and set different modes according to the different scenes of the screen, so as to achieve the purpose of using non-color liquid crystal glass to control the light transmittance to strengthen and reduce the backlight.

In addition, an embodiment of the present application further provides a readable storage medium on which a multi-region backlight control program is stored, and when the multi-region backlight control program is executed by a processor, the steps of the multi-region backlight control method described above are implemented.

The specific embodiments of the readable storage medium of the present application are basically the same as the various embodiments of the multi-region backlight control system described above, and are not repeated here.

It should be noted that in this article, the terms "comprise", "include" or any other variant thereof are intended to cover non-exclusive inclusion, so that a process, method, article or device that includes a series of elements includes not only those elements, but also other elements that are not explicitly listed, or include elements inherent to such processes, methods, objects, or devices. Without more restrictions, the element defined by the sentence "comprise a. " does not exclude that there are other identical elements in the process, method, article or device that includes the element.

The sequence numbers of the above embodiments of the present application are for description only, and do not represent the advantages and disadvantages of the embodiments.

Through the description of the above embodiments, those skilled in the art can clearly understand that the methods in the above embodiments can be implemented by means of software plus a necessary general hardware platform, and of course, can also be implemented by hardware, but in many cases the former is the better. Based on this understanding, the technical solution of the present application can be embodied in the form of a software product in essence or part that contributes to the existing technology, and the computer software product is stored in a storage medium as described above (such as a ROM/RAM, a magnetic disk, an optical disk), including several instructions to enable a device (which may be a mobile phone, computer, server, air conditioner, or network equipment, etc.) to perform the method described in each embodiment of the present application.

Claim 1:
A multi-region backlight control system, comprising a color liquid crystal display screen (<NUM>), a non-color liquid crystal display screen (<NUM>) set between the color liquid crystal display screen (<NUM>) and a constant backlight source (<NUM>), a first driver (<NUM>), a second driver (<NUM>), the constant backlight source (<NUM>), and a main controller (<NUM>); wherein the color liquid crystal display screen (<NUM>) and the non-color liquid crystal display screen (<NUM>) are sequentially fixed on the constant backlight source (<NUM>), and the non-color liquid crystal display screen (<NUM>) is disposed between the color liquid crystal display screen (<NUM>) and the constant backlight source (<NUM>); the main controller (<NUM>) is respectively connected with the first driver (<NUM>), the second driver (<NUM>) and the constant backlight source (<NUM>), the first driver (<NUM>) is electrically connected with the color liquid crystal display screen (<NUM>), and the second driver (<NUM>) is electrically connected with the non-color liquid crystal display screen (<NUM>); wherein, in response to receiving an image signal, the main controller (<NUM>) is configured to process the image signal to obtain image data, send the image data to the first driver (<NUM>) and the second driver (<NUM>) synchronously and control the constant backlight source (<NUM>) to be turned on; the first driver (<NUM>) is configured to convert the received image data into a display signal and drive the color liquid crystal display screen (<NUM>) to output a display image based on the display signal; the second driver (<NUM>) is configured to convert the received image data into a control signal and drive the non-color liquid crystal display screen (<NUM>) to adjust light transmittance of each pixel of the non-color liquid crystal display screen (<NUM>) based on the control signal, the main controller (<NUM>) is further configured to convert the collected image signals to perform dynamic compensation adjustment according to changes in ambient light to enhance or reduce the light transmittance of the backlight in the non-color liquid crystal display screen (<NUM>), and the main controller (<NUM>) is configured to output different regional brightnesses and darknesses in the display signal of the color liquid crystal display screen (<NUM>), and synchronously control the switching angle of liquid crystal molecules in the corresponding region of the non-color liquid crystal display screen (<NUM>).