RU2786087C1 - Backlight control circuit, its control method and display terminal - Google Patents

Abstract

FIELD: display technologies.

SUBSTANCE: invention relates to the field of display technologies and, in particular, to a backlight control circuit, a backlight control method and a display terminal. The effect is achieved in that the backlight driving circuit includes a driver circuit and a power conversion circuit. The driver circuit includes a feedback output pin and at least one channel port. The channel port is connected to the first output of the light string group. The driver circuit is configured to receive the voltage of each channel port and allow the feedback output pin to provide a current feedback signal based on the voltage Vch. The power conversion circuit is connected to the feedback output terminal and includes a voltage output terminal. The output voltage terminal is configured to provide a supply voltage for the second output of each group of light strings. The power conversion circuit is configured to convert the voltage over the input voltage and increase or decrease the supply voltage based on the current feedback signal.

EFFECT: lower power consumption of backlit displays.

22 cl, 13 dwg

Description

[0001] The present application claims priority based on Chinese Patent Application No. 201911055090.3, filed with the National Intellectual Property Office of China on October 31, 2019, entitled "BACKLIGHT CONTROL CIRCUIT, BACKLIGHT CONTROL METHOD, AND DISPLAY TERMINAL", which is hereby incorporated by reference in its entirety.

FIELD OF TECHNOLOGY TO WHICH THE INVENTION RELATES

[0002] The present invention relates to the field of display technologies, and more particularly to a backlight control circuit, a control method thereof, and a display terminal.

BACKGROUND OF THE INVENTION

[0003] Liquid crystal displays (liquid crystal display, LCD) are increasingly used in the field of high-performance displays due to characteristics such as small size, low power consumption, no radiation and relatively low manufacturing costs. The LCD display includes a liquid crystal display panel and a backlight used to provide a light source for the liquid crystal display panel. Compared with the edge-lit backlight unit, the direct backlight unit can perform local dimming and provide a better display effect.

[0004] At present, the direct backlight unit includes a plurality of light strings and a driver IC connected to the light strings. However, during the LCD display process, the forward voltage (VF) of the light strings, that is, the voltages corresponding to the rated current, change depending on the temperature. As a result, the voltage values of the ports that are in the driver IC and connected to the light strings change, and a phenomenon occurs that the voltage values of the ports are inconsistent. If the port voltage is relatively high, the power consumption of the driver IC is relatively high.

SUMMARY OF THE INVENTION

[0005] Embodiments of the present invention provide a backlight control circuit, a method for driving it, and a display terminal for reducing the difference between port voltages in a driver IC so that the driver IC operates in a proper operating range, thereby reducing power consumption and improving efficiency.

[0006] To achieve the above goal, the following technical solutions are used in this application.

[0007] According to one aspect of embodiments of the invention of the present application, a backlight control circuit is provided. The backlight control circuit is configured to drive at least one group of light strings. The light string group includes a plurality of light strings connected in parallel. In addition, the backlight driving circuit includes a driver circuit and a power conversion circuit. The driver circuit includes a feedback output pin and at least one channel port. The channel port is connected to the first output of the light string group. The driver circuit is configured to receive the voltage Vch of each channel port and allow the feedback output terminal to provide a current feedback signal based on the voltage Vch. The power conversion circuit is connected to the feedback output terminal and includes a voltage output terminal. The output voltage terminal is configured to provide a supply voltage for the second output of each group of light strings. The power conversion circuit is configured to convert the voltage over the input voltage and increase or decrease the supply voltage based on the current feedback signal. Thus, the voltage Vch of each channel port of the driver circuit can be maintained within a certain range. This avoids the abnormal brightness of the light string group caused by the voltage of the first terminal of the light string group is lower than the conduction threshold voltage or the breakpoint voltage of the channel port, or prevents the increase in power consumption of the driver circuit caused by the excessively high voltage of the first terminal of the light string group. Finally, on the one hand, in the backlight driving circuit provided in the embodiments of the present invention, a feedback output terminal that can provide a current feedback signal is located in the driver circuit, and the feedback output terminal is connected to the power conversion circuit. This may allow the driver circuit to provide a current feedback signal to the power conversion circuit based on the voltage Vch of each channel port of the driver circuit in real time. Based on this, the power conversion circuit can perform real-time, based on the current feedback signal, bi-directional adjustment of the supply voltage output by the voltage output terminal of the power conversion circuit, that is, increase the supply voltage or decrease the supply voltage. Thus, during the display process by the display terminal, the supply voltage received by the second terminal of the light string group can be adjusted within a certain range. This avoids that the Vch voltage of each channel port of the driver circuit remains in a relatively high or low state for a long time, reduces the difference between the Vch1 voltages of the channel ports of the driver circuit, and thus ultimately reduces the power consumption of the driver circuit. On the other hand, the feedback signal provided by the feedback output terminal which is the driver circuit and which is connected to the power conversion circuit is a current feedback signal. Compared with a voltage signal, the current signal is not affected by the distance between the driver circuit and the power conversion circuit, and therefore does not generate relatively large fluctuations, so that signal interference caused by cable noise can be reduced.

[0008] It is possible that the driver circuit is specifically configured to compare the voltage Vch of each channel port with the first predetermined voltage VL and the second predetermined voltage VH, while VL<VH. In addition, the driver circuit is specifically configured to: when the voltage Vch of any channel port is lower than the first predetermined voltage VL, to allow the feedback output terminal to provide the first current I1 as a current feedback signal, while the first current I1 is used for increasing the supply voltage; or when the voltages Vch of all channel ports are higher than the second predetermined voltage VH, allowing the feedback output terminal to provide the second current I2 as a current feedback signal, while the second current I2 is used to reduce the supply voltage. The first current I1 and the second current I2 have opposite directions. Finally, the feedback output terminal of the driver circuit may provide the first current I1 (that is, the sinking current) to increase the supply voltage outputted by the voltage output terminal of the power conversion circuit, and the feedback output terminal of the driver circuit may also provide the second current I2 (then present, source current) to lower the supply voltage output by the voltage output terminal of the power conversion circuit. Therefore, the backlight control circuit provided in the embodiments of the present application can perform bi-directional voltage adjustment of the second output of the light string group.

[0009] The driver circuit may include a comparator, a first current source, and a second current source. The input pin of the comparator is connected to the channel ports. The first output terminal of the comparator is connected to the control terminal of the first current source, and the second output terminal of the comparator is connected to the control terminal of the second current source. The comparator is configured to compare the voltage Vch of each channel port with the first predetermined voltage VL and the second predetermined voltage VH, while VL<VH. When the voltage Vch of any channel port is lower than the first predetermined voltage VL, the first output terminal outputs the first control signal. When the voltages Vch of all channel ports are higher than the second predetermined voltage VH, the second output terminal outputs the second control signal. The first electrode of the first current source is connected to the feedback output terminal, and the second electrode of the first current source is connected to the first voltage terminal. The first current source is configured to receive the first control signal, and the feedback output pin provides the first current I1. The first electrode of the second current source is connected to the second voltage terminal, and the second electrode of the second current source is connected to the feedback output terminal. The second current source is configured to receive the second control signal and the feedback output pin provides the second current I2. The first voltage terminal is configured to output the first voltage V1, and the second voltage terminal is configured to output the second voltage V2, wherein |V1| <|V2|. The feedback output terminal of the driver circuit may provide the first current I1 (ie, the sink current) and may also provide the second current I2 (ie, the source current). The technical effects are the same as those described above, and the details are not described here again.

[0010] It is possible that the power conversion circuit includes a first resistor that has a resistance value R1. The first terminal of the first resistor is connected to the voltage output terminal, and the second terminal of the first resistor is connected to the feedback output terminal.

[0011] It is possible that the backlight control circuit further includes a second resistor. The first terminal of the second resistor is connected to the second terminal of the first resistor, and the second terminal of the second resistor is connected to the feedback output terminal of the driver circuit. The second resistor is configured to match impedances at the second terminal of the first resistor and at the Feedback output terminal.

[0012] It is possible that the driver circuit is further configured to: when the voltage Vch of any channel port is lower than the first predetermined voltage VL for S successive times, to increase by the amount ΔI the change in current stepwise for S successive times of the first current I1 provided by the output feedback output, while S≥2, and S is a positive integer. In addition, the power conversion circuit is specifically further configured to increase, by a voltage change amount ΔV, each time based on the first current I1, the voltage outputted by the voltage output terminal. In this case, when the driver circuit can continuously detect the Vch voltages of all channel ports for each frame, and the driver circuit detects that the Vch voltage of any channel port is lower than the first specified voltage VL for S consecutive times (for example, the feedback output pin outputs the first current I1 once every two frames, and the duration S times is S × 2 frames, that is, the driver circuit detects that the voltage Vch of any channel port is lower than the first specified voltage VL for S × 2 consecutive frames), the first current I1 , provided by the feedback output pin, increases by the amount of current change ΔI in a stepwise manner for S successive times. Therefore, the current value of the first current I1 provided by the feedback output pin for the Sth time is S × ΔI. The power conversion circuit increases the voltage change amount ΔV each time based on the first current I1, the voltage output by the voltage output terminal. Therefore, the voltage output by the voltage output terminal Vout of the power conversion circuit for the Sth time increases by S × ΔV based on the original voltage. In addition, for the above magnitude of voltage change ΔV1 = |ΔI| × R1. Thus, the voltage change amount ΔV can be controlled by adjusting the resistance value of the first resistor.

[0013] It is possible that the driver circuit is further configured to: after the first current I1 provided by the feedback output terminal is increased by the current step change amount ΔI for S successive times, determining that the feedback output terminal is in the state high impedance when the Vch voltage of any channel port is lower than the first specified voltage VL. In a plurality of light string groups, there is a light string that is in an open circuit state. Therefore, no matter how the value of the supply voltage outputted by the voltage output terminal of the power conversion circuit increases, the voltage of the channel port to which the second terminal of the light string is connected in an open circuit state is still lower than the first predetermined voltage VL. In this case, the driver circuit may output an open circuit signal to the control system of the terminal with a display to detect the open circuit.

[0014] It is possible that the driver circuit is further configured to: when the voltages Vch of all channel ports are higher than the second predetermined voltage VH for N successive times, to reduce by the amount ΔI the change in current stepwise for N successive times, the second current I2 provided a feedback output terminal, wherein N≥2 and N is a positive integer. The power conversion circuit is specifically further adapted to reduce, by a voltage change amount ΔV, each time based on the second current I1, the voltage outputted by the voltage output terminal.

[0015] In this case, when the driver circuit can continuously detect the voltages Vch of all channel ports for each frame, and the driver circuit detects that the voltages Vch of all channel ports are higher than the second predetermined voltage VH for N successive times, the second current I2, provided by the feedback output terminal is reduced by the amount of current change ΔI in a stepwise manner N successive times. Therefore, the current value of the second current I2 provided by the feedback output pin in the Nth times is equal to N × ΔI. The power conversion circuit reduces the voltage change by ΔV each time based on the second current I2, the voltage output by the voltage output terminal. Therefore, the voltage output by the voltage output terminal Vout of the power conversion circuit by N times decreases by N × ΔV based on the original voltage. In addition, for the above magnitude of voltage change ΔV1 = |ΔI| × R1. The technical effects of the first resistor R1 are the same as described above, and the details are not described here again.

[0016] It is possible that the driver circuit further includes a plurality of gating ports and a power supply port that is connected to each gating port, and the power supply port is further connected to a voltage output terminal of the power conversion circuit. A plurality of groups of light strings are arranged in an array. The second terminals of the plurality of light string groups in one row are connected to one gate port. The first pins of the light string groups in one column are connected to one channel port of the driver circuit. Thus, one channel port can be separately connected to the first pins of the light string groups in the same column, thereby reducing the number of channel ports in the driver circuit.

[0017] It is possible that the voltage output terminal of the power conversion circuit is connected to the first terminal of each group of light strings. Thus, the voltage output terminal of the power conversion circuit can simultaneously supply voltage to the second terminals of the light string groups.

[0018] According to another aspect of the embodiments of the present application, a method for controlling a backlight control circuit is provided. The backlight control circuit is configured to drive at least one group of light strings. The light string group includes a plurality of light strings connected in parallel. The backlight driving circuit includes a driver circuit and a power conversion circuit. The driver circuit includes a feedback output pin and at least one channel port. The channel port is connected to the first output of the light string group. The power conversion circuit is connected to the feedback output terminal and includes a voltage output terminal. In addition, the control method includes: first, the driver circuit receives the channel port voltage Vch and enables the feedback output terminal to provide a current feedback signal based on the voltage Vch. Then, the power conversion circuit increases or decreases, based on the current feedback signal, the supply voltage outputted by the voltage output terminal. The backlight driving circuit driving method has the same technical effects as the backlight driving circuit driving methods provided in the above embodiments, and details are not described here again.

[0019] It is possible that the driver circuit receives the channel port voltage Vch and provides a current feedback signal, specifically includes: first, the driver circuit compares the voltage Vch of each channel port with the first predetermined voltage VL and the second predetermined voltage VH, wherein VL<VH. Then, when the voltage Vch of any channel port is lower than the first specified voltage VL, the feedback output terminal of the driver circuit provides the first current I1 as a current feedback signal, while the first current I1 is used to increase the supply voltage; or when the voltages Vch of all channel ports are higher than the second specified voltage, the feedback output terminal of the driver circuit provides the second current I2 as a current feedback signal, while the second current I2 is used to reduce the supply voltage. The first current I1 and the second current I2 have opposite directions. The feedback output pin of the driver circuit may provide the first current I1 (ie, the sink current) and may also provide the second current I2 (ie, the source current). The technical effects are the same as those described above, and the details are not described here again.

[0020] The driver circuit may include a comparator, a first current source, and a second current source. The input pin of the comparator is connected to the channel ports. The first output terminal of the comparator is connected to the control terminal of the first current source. The first electrode of the first current source is connected to the feedback output terminal, and the second electrode of the first current source is connected to the first voltage terminal. The second output terminal of the comparator is connected to the control terminal of the second current source. The first electrode of the second current source is connected to the second voltage terminal, and the second electrode of the second current source is connected to the feedback output terminal. The first voltage terminal is configured to output the first voltage V1, and the second voltage terminal is configured to output the second voltage V2, wherein |V1|<|V2|. Based on this, the driver circuit receives the channel port voltage Vch and outputs the current feedback signal, specifically includes: first, the comparator compares the Vch voltage of each channel port with the first preset voltage VL and the second preset voltage VH, while VL<VH . Then, when the voltage Vch of any channel port is lower than the first predetermined voltage V, the first output terminal of the comparator outputs the first control signal, the first current source receives the first control signal, and the feedback output terminal provides the first current I1; or when the voltages Vch of all channel ports are higher than the second predetermined voltage, the second output terminal of the comparator outputs the second control signal, the second current source receives the second control signal, and the feedback output terminal provides the second current I2. The feedback output terminal of the driver circuit may provide the first current I1 (ie, the sink current) and may also provide the second current I2 (ie, the source current). The technical effects are the same as those described above, and the details are not described here again.

[0021] It is possible that the power conversion circuit includes a first resistor that has a resistance value R1. The first terminal of the first resistor is connected to the voltage output terminal, and the second terminal of the first resistor is connected to the feedback output terminal. That the driver circuit receives the channel port voltage Vch and enables the feedback output pin to provide a current feedback signal based on the Vch voltage includes: when the Vch voltage of any channel port is lower than the first specified voltage VL for S consecutive times , the driver circuit increases by the amount of ΔI the current step change for S successive times the first current I1 provided by the feedback output terminal, while S≥2, and S is a positive integer. That the power conversion circuit increases or decreases, based on the current feedback signal, the supply voltage output by the voltage output terminal includes: the power conversion circuit increases each time by the amount of ΔV of the voltage change based on the first current I1, the voltage output through the voltage output. For the magnitude of the voltage change ΔV1 = |ΔI| × R1. The technical effects of the driver circuit, the power conversion circuit, and the first resistor are the same as described above, and the details are not described here again.

[0022] Optionally, the method further includes: first, after the first current I1 provided by the feedback output terminal of the driver circuit is increased by the current step change amount ΔI for S successive times, determining that the feedback output terminal the driver circuit connections in a high impedance state when the voltage Vch of any channel port is lower than the first predetermined voltage V; and then restoring the voltage output by the voltage output terminal of the power conversion circuit to the initial voltage. The technical effects of realizing open circuit detection using the above method are the same as those described above, and details are not described here again.

[0023] It is possible that the power conversion circuit includes a first resistor that has a resistance value R1. The first terminal of the first resistor is connected to the voltage output terminal, and the second terminal of the first resistor is connected to the feedback output terminal. That the driver circuit receives the channel port voltage Vch and turns on the feedback output pin to provide a current feedback signal based on the Vch voltage includes: when the Vch voltages at all channel ports are higher than the second specified voltage VH for N consecutive times, the driver circuit reduces by the amount of ΔI the current step change for N successive times the second current I2 provided by the feedback output terminal, where N≥2, and N is a positive integer. That the power conversion circuit increases or decreases based on the current feedback signal the supply voltage output by the voltage output terminal includes: the power conversion circuit reduces by the amount of ΔV of the voltage change based on the second current I1 the voltage output by the output terminal each time voltage. For the magnitude of the voltage change ΔV1 = |ΔI| × R1. The technical effects of the driver circuit, the power conversion circuit, and the first resistor are the same as described above, and the details are not described here again.

[0024] According to another aspect of embodiments of the present application, there is provided a display terminal including a liquid crystal display panel and a backlight unit configured to provide a light source for the liquid crystal display panel. The backlight unit includes a plurality of light string groups and a backlight control circuit. The light string group includes a plurality of light strings connected in parallel. Each light string includes a plurality of light emitting devices connected in series. In addition, the backlight driving circuit includes a driver circuit and a power conversion circuit. The driver circuit includes a feedback output pin and at least one channel port. The channel port is connected to the first outputs of the light string groups. The driver circuit is configured to receive the Vch voltage of each channel port and includes a feedback output pin to provide a current feedback signal based on the Vch voltage. The power conversion circuit is connected to the feedback output terminal and includes a voltage output terminal. The output voltage terminal is configured to provide a supply voltage for the second output of each group of light strings. The power conversion circuit is configured to increase or decrease, based on the current feedback signal, the supply voltage outputted by the voltage output terminal. The display terminal has the same technical effects as the backlight driving circuit provided in the above embodiments, and details will not be described here again.

[0025] It is possible that the liquid crystal display panel includes a plurality of sub-pixels arranged in an array. A plurality of groups of light strings are arranged in an array. The vertical projection onto the backlight block of the area in which the M × N subpixels are located overlaps the area in which one group of light chains is located, while M≥1, N≥1, and N and M are positive integers. Thus, one channel port of the driver circuit can control the brightness of at least one group of light strings, so that the brightness of each light string does not need to be adjusted separately. In addition, the area in which the light string group is located may correspond to the area in which the M×N sub-pixels are located on the liquid crystal display panel, thereby realizing local dimming for an image displayed by the display terminal.

[0026] It is possible that the driver circuit further includes a plurality of gating ports and a power supply port that is connected to each gating port, and the power supply port is further connected to a voltage output terminal of the power conversion circuit. The backlight unit further includes a plurality of second signal lines and a plurality of first signal lines. One second signal line is separately connected to one gate port and the second terminals of a plurality of light string groups in the same row. One first signal line is separately connected to one channel port of the driver circuit and the first pins of the light string groups that are in the same column. Thus, the power supply port of the driver circuit can supply the power supply to each gate port one by one. In addition, the plurality of first signal lines can separately transmit the voltage of the first terminal of each group of light strings in one row to each channel port row by row. In this case, the driver circuit may be configured to receive the voltage of each channel port and generate a current feedback signal based on the voltage value of each channel port. In addition, one channel port can be separately connected to the first pins of the light string groups in the same column, thereby reducing the number of channel ports in the driver circuit.

[0027] According to another aspect of embodiments of the invention of the present application, a driver circuit is provided. The driver circuit includes a feedback output pin and at least one channel port. The channel port is connected to the first output of the light string group. The driver circuit is configured to receive the Vch voltage of each channel port and allow the feedback output pin to provide a current feedback signal to the power conversion circuit based on the Vch voltage, so that the power conversion circuit increases or decreases the output voltage based on the current feedback signal. . The technical effects of the driver circuit are the same as described above, and the details are not described here again.

[0028] Perhaps the driver circuit is specifically configured to compare the voltage Vch of each channel port with the first predetermined voltage VL and the second predetermined voltage VH, while VL<VH. In addition, the driver circuit is specifically configured to: when the voltage Vch of any channel port is lower than the first predetermined voltage VL, to allow the feedback output terminal to provide the first current I1 as a current feedback signal, while the first current I1 is used for increasing the supply voltage; or when the voltages Vch of all channel ports are higher than the second predetermined voltage VH, allowing the feedback output terminal to provide the second current I2 as a current feedback signal, while the second current I2 is used to reduce the supply voltage. The first current I1 and the second current I2 have opposite directions. The technical effects of the first current I1 and the second current I2 are the same as described above, and the details are not described here again.

[0029] The driver circuit may include a comparator, a first current source, and a second current source. The input terminal of the comparator is connected to the channel ports, the first output terminal of the comparator is connected to the control terminal of the first current source, and the second output terminal of the comparator is connected to the control terminal of the second current source. The comparator is configured to compare the voltage Vch of each channel port with the first predetermined voltage VL and the second predetermined voltage VH, while VL<VH. When the voltage Vch of any channel port is lower than the first predetermined voltage VL, the first output terminal outputs the first control signal. When the voltages Vch of all channel ports are higher than the second predetermined voltage VH, the second output terminal outputs the second control signal. The first electrode of the first current source is connected to the feedback output terminal, and the second electrode of the first current source is connected to the first voltage terminal. The first current source is configured to receive the first control signal, and the feedback output pin provides the first current I1. The first electrode of the second current source is connected to the second voltage terminal, and the second electrode of the second current source is connected to the feedback output terminal. The second current source is configured to receive the second control signal, and the feedback output pin provides the second current I2. The first voltage terminal is configured to output the first voltage V1, and the second voltage terminal is configured to output the second voltage V2, wherein |V1|<|V2|. The feedback output terminal of the driver circuit may provide the first current I1 (ie, the sink current) and may also provide the second current I2 (ie, the source current). The technical effects are the same as those described above, and the details are not described here again.

BRIEF DESCRIPTION OF THE DRAWINGS

[0030] FIG. 1 is a schematic structural diagram of a display terminal according to an embodiment of the invention of the present application;

[0031] FIG. 2a is a schematic structural diagram of a plurality of light string groups according to an embodiment of the invention of the present application;

[0032] FIG. 2b is a schematic diagram of the correspondence between subpixels and light string groups shown in FIG. 2a;

[0033] FIG. 3a is a schematic diagram of the relationship between a backlight driving circuit and a plurality of light string groups according to an embodiment of the invention of the present application;

[0034] FIG. 3b is a schematic diagram of another connection relationship between a backlight driving circuit and a plurality of light string groups according to an embodiment of the invention of the present application;

[0035] FIG. 3c is a schematic diagram of another connection relationship between a backlight driving circuit and a plurality of light string groups according to an embodiment of the invention of the present application;

[0036] FIG. 4a is a schematic diagram of the relationship between temperature and forward voltage of a light string according to an embodiment of the invention of the present application;

[0037] FIG. 4b is a schematic diagram of the voltage values of the channel ports shown in FIG. 3a;

[0038] FIG. 5 is a flowchart of a method for controlling a backlight control circuit according to an embodiment of the invention of the present application;

[0039] FIG. 6 is a flowchart of the specific steps of S101 in FIG. five;

[0040] FIG. 7 is a schematic diagram of one connection between a driver circuit, a power conversion circuit, and a plurality of light string groups according to an embodiment of the invention of the present application;

[0041] FIG. 8 is a schematic diagram of another connection between a driver circuit, a power conversion circuit, and a plurality of light string groups according to an embodiment of the invention of the present application; as well as

[0042] FIG. 9 is a schematic diagram of voltages output by a voltage output terminal of a power conversion circuit in various phases according to an embodiment of the invention of the present application.

[0043] Legend in the accompanying drawings:

01: terminal with display; 10: liquid crystal display panel; 100: cell alignment substrate; 101: matrix substrate; 102: liquid crystal layer; 20: backlight unit; 201: reflector; 202: light emitting device; 203: optical film; 02: medium frame; 21: group of light chains; 200: light chain; 120: sub-pixel; 30: backlight control circuit; 301: driver circuit; 302: power conversion circuit; 323: light emission control current source; 311: comparator; 321: first current source; 322: second current source

DESCRIPTION OF EMBODIMENTS

[0044] The following describes the technical solutions in the embodiments of this application with reference to the accompanying drawings in the embodiments of the invention of the present application. Obviously, the described embodiments of the invention are only a part, and not all of the embodiments of the invention of the present application.

[0045] The following terms "first" and "second" are for description only and should not be understood as an indication or meaning of relative importance or an implicit indication of the number of specified technical characteristics. Therefore, a function limited to "first" or "second" may explicitly or implicitly include one or more functions. In the description of this application, unless otherwise indicated, "many of" means two or more than two.

[0046] In addition, in this application, orientation terms such as "top", "bottom", "left" and "right" may include, but are not limited to, orientations defined with respect to the orientations in which components are schematically placed on accompanying drawings. It should be understood that these orientation terms may be relative terms, used to describe and explain the term "relative" and may change depending on the change in orientation in which the components are placed in the accompanying drawings.

[0047] In this application, the term "communication" may mean a method of implementing an electrical connection for signal transmission. Unless otherwise expressly stated or limited, a "connection" may be a direct electrical connection or may be an indirect electrical connection through an intermediate medium.

[0048] An embodiment of the invention of the present application provides a terminal with a display. The display terminal includes, for example, a television, a mobile phone, a tablet computer, a personal digital assistant (personal digital assistant, PDA), or a vehicle-mounted computer. The specific shape of the display terminal is not particularly limited in this embodiment of the invention of the present application. A terminal with a display in any of the above forms includes an LCD display. In this case, as shown in FIG. 1, the display terminal 01 includes a liquid crystal display panel 10 and a backlight unit (BLU) 20 .

[0049] As shown in FIG. 1, the liquid crystal display panel 10 includes a cell alignment substrate 100 and a matrix substrate 101, which are opposed. Cell alignment is performed on the cell alignment substrate 100 and the matrix substrate 101 to form a liquid crystal cell. The liquid crystal display panel 10 further includes a liquid crystal layer 102 filled between the cell alignment substrate 100 and the matrix substrate 101 . The light transmittance obtained after the light emitted from the backlight unit 20 passes through the liquid crystal display panel 10 is controlled. Thus, the gray scale on the liquid crystal display panel 10 is adjusted.

[0050] As shown in FIG. 1, the backlight unit 20 includes a reflector 201, a plurality of light emitting devices 202 that are disposed on the reflector 201, and a plurality of optical film layers 203 disposed on the light emitting sides of the light emitting devices 202. The optical module 203 may be a diffusion film, a prism film, or the like. .P.

[0051] The light emitting device 202 may be a light emitting diode (LED). Based on this, a plurality of light emitting devices 202 can be connected in series to form a light string 200 shown in FIG. 2a. A plurality of light strings 200 may be connected in parallel to form a light string group 21. One light string group 21 can be used as a backlight control area capable of independent brightness control, thereby realizing local dimming (local dimming) of the backlight unit 20 and enhancing image contrast.

[0052] In some embodiments of the present invention, as shown in FIG. 2b, a plurality of subpixels 120 on the liquid crystal display panel 10 are arranged in an array. A plurality of light string groups 21 in the backlight unit 20 are also arranged in an array. Based on this, the vertical projection onto the backlight unit 20 of the area in which the M×N subpixels 120 are located overlaps the area in which one light string group 21 is located. That is, when the brightness of one light string group 21 is controlled, it is possible to control the display brightness of an area in which M×N subpixels 120 are arranged.

[0053] In M×N subpixels, M≥1, N≥1, and N and M are positive integers. Smaller values of M and N indicate a higher local dimming accuracy of the backlight unit 20 and a more complex control process. On the contrary, higher values of M and N indicate a lower local dimming accuracy of the backlight unit 20 and a simpler control process. The specific values of M and N in the present application are not limited.

[0054] It should be noted that, in order to facilitate the following description, in a plurality of groups 21 of light strings, which are arranged in an array and which are shown in FIG. 2a, a row of light string groups 21 arranged along the X direction is referred to as light string groups 21 in one row, and a column of light string groups 21 arranged along the Y direction is referred to as light string groups 21 in the same column.

[0055] In order to control the plurality of light string groups 21, the display terminal 01 provided in this embodiment of the present application further includes a backlight control circuit 30 shown in FIG. 3a. The backlight control circuit 30 includes a driver circuit 301 and a power conversion circuit 302. The backlight control circuit 30 may be located on the middle frame 02 (as shown in FIG. 1) on the side which is the backlight unit 20 and which is farthest from the liquid crystal display panel 10. The main board of the display terminal 01 is further disposed on the side which is in the middle frame 02 and faces away from the liquid crystal display panel 10 . In some embodiments of the invention of the present application, the backlight control circuit 30 may be integrated into the motherboard. Alternatively, in some other embodiments, the backlight control circuit 30 and the main board may be located independently on the middle frame 02. Alternatively, in some other embodiments, the backlight control circuit 30 may be integrated within the backlight unit 20.

[0056] In addition, the driver circuit 301 may be an IC (integrated circuit, IC) driver. The power conversion circuit 302 may be a direct current (DC) to direct current conversion circuit, that is, a DC power supply chip. An input terminal Vin (as shown in Fig. 3a) of the DC/DC power supply chip is configured to receive an input voltage and convert the input voltage to an output voltage.

[0057] For example, the battery voltage of the display terminal 01 or an output of another power supply circuit can be used as an input of the DC/DC power supply chip. In addition, the input of the DC/DC power supply chip must consider the load power consumption of the light string group 21 as a load, and the input of the DC/DC power supply chip must also meet the requirements of the transient response of the light string group 21. In this case, when the input voltage received by the power conversion circuit 302 has a relatively small amplitude, the power conversion circuit 302 can be used as a boost circuit to perform boost processing on the input voltage. Therefore, the power supply voltage VLED, which provides each light string 200 in the light string group 21 with normal light emission, can be output from the voltage output terminal Vout of the power conversion circuit 302.

[0058] Alternatively, when the input voltage has a relatively large amplitude, the power conversion circuit 302 can be used as a step-down circuit to perform step-down processing for the input voltage, so that the power supply voltage VLED is output from the voltage output terminal Vout of the power conversion circuit 302.

[0059] For example, one light emitting device 202 in the light string 200 requires a voltage of about 3 V when the light emitting device 202 emits light normally. When 10 light emitting devices 202 are connected in series in the light string 200, the supply voltage VLED required for the second terminal of the light string 200 is 30 V. In this case, the power conversion circuit 302 can convert the input voltage via the input terminal Vin to a supply voltage of 30 V.

[0060] In addition, as shown in FIG. 3a, the driver circuit 301 includes a feedback output (FBO) and at least one channel port (eg, CH1, CH2, and ... in FIG. 3a). One channel port is connected to the first terminal c of at least one light string group 21 (ie, to the cathode of each light string 200 in the light string group 21).

[0061] In this case, the light emission control current sources 323, which are shown in FIG. 3b, and which are associated with channel ports (eg, CH1, CH2, and ... in FIG. 3a), respectively, can be located within the driver circuit 301. The light control current source 323 can provide a constant source current for the channel CH port connected to the light control current source 323 . The source current is transmitted through the channel port CH to the light strings 200 connected in parallel in the light string group 21 to which the channel port is connected, so that each light string 200 in the light string group 21 can be driven to emit light.

[0062] It should be noted that the rated current flowing through the light string group 21 corresponds to the conduction threshold voltage or the knee voltage of the CH port. When the channel CH port voltage of the driver circuit 301 is lower than the conduction threshold voltage, the light emission control current source 323 connected to the channel CH port cannot provide the rated current for the light string group 21, and the light string group 21 cannot emit light normally. Therefore, in order for the light string group 21 to have normal brightness, the CH port voltage must be higher than the CH port conduction threshold voltage.

[0063] Based on this, a pulse width modulation (PWM) signal whose duty cycle is adjustable can be used to adjust the brightness of each light string 200. Based on the brightness requirement, the duty cycle of the PWM signal is adjusted. Thus, it is possible to control the effective duration of the current source provided by the light control current source 323 for the light string group 21 for a certain time, and therefore the brightness of the light string group 21 can be controlled.

[0064] Thus, one channel port of the driver circuit 301 can be associated with at least one group of light strings 21, so that each light string 200 does not need to be associated with one channel port. From the foregoing, it can be understood that the area in which the light string group 21 is located may correspond to the area in which M×N subpixels 120 are located on the liquid crystal display panel 10. Therefore, local dimming can be performed on the image displayed by the display terminal 01. It can be understood that each light string 200 may alternatively be associated with one channel port. In this case, the driver circuit 301 needs to provide more channel ports.

[0065] In addition, as shown in FIG. 3a, the power conversion circuit 302 in the backlight driving circuit 30 may be connected to the feedback output terminal FBO of the driver circuit 301. The power conversion circuit 302 includes a voltage output terminal Vout. The voltage output terminal Vout is configured to supply the supply voltage VLED to the second terminal a of each light string group 21 (that is, the anode of each light string 200 in the light string group 21).

[0066] In some embodiments of the invention of the present application, when the backlight unit 20 further includes a plurality of first signal lines SLc shown in FIG. 3a, the way to connect the ports (CH1, CH2 and ...) of the channels to the light string groups 21 can be as follows: one first signal line SLc is separately connected to the first terminals c of the light string groups 21 in the same column (Y direction) and one port CH channel circuit 301 driver.

[0067] In addition, the backlight unit 20 further includes a plurality of second signal lines SLa shown in FIG. 3a. The driver circuit 301 further includes a plurality of gating ports (SW1, SW2, and...) and a power supply Vps port connected to each gating port (SW1, SW2, and...). The power supply port Vps is also connected to the voltage output terminal Vout of the power conversion circuit 302, so that the voltage output terminal Vout of the power conversion circuit 302 can supply the power supply voltage VLED to the power supply port Vps of the driver circuit 301.

[0068] Based on this, the manner in which the power conversion circuit 302 provides the supply voltage VLED to the second terminals a of the light string groups 21 can be as follows: as shown in FIG. 3a, one second signal line SLa is separately connected to one gate port SW1 and the second terminals a of the plurality of light string groups 21 in one row (X direction).

[0069] Thus, the power supply port Vps of the driver circuit 301 can supply the power supply voltage VLED to the strobe ports (SW1, SW2, and...) one by one. In addition, the plurality of first signal lines SLc can separately transmit the voltages of the first terminals c of the light string groups 21 in one row (X direction) to the ports (CH1, CH2 and ...) of the channels row by row. In this case, the driver circuit 301 may be configured to receive the voltages (Vch1, Vch2, and...) of the channel ports (CH1, CH2, and...) and generate a current feedback signal based on the voltage values (Vch1, Vch2, and...). The current feedback signal may be provided by a feedback output terminal FBO of the driver circuit 301 to the power conversion circuit 302 .

[0070] Alternatively, in some other embodiments of the present invention, as shown in FIG. 3c, the method of connecting the channel ports (CH1, CH2 and ...) to the light string groups 21 may be that one first signal line SLc is connected to the first terminal of one light string group 21. In this case, compared to the structure shown in FIG. 3c in FIG. 3a, one channel CH port can be separately connected to the first terminals of the light string groups 21 in the same column (Y direction), thereby reducing the number of CH channel ports in the driver circuit 301.

[0071] In addition, when the connection method of the channel ports (CH1, CH2, and...) of the driver circuit 301 to the light string groups 21 is the connection method shown in FIG. 3c, the voltage output terminal Vout of the power conversion circuit 302 can be directly connected to the second terminals a of the light string groups 21 in each row. In this case, after the voltage output terminal Vout of the power conversion circuit 302 outputs the power supply voltage VLED, the driver circuit 301 can directly receive the voltages (Vch1, Vch2 and...) of the channels (CH1, CH2 and...) of the channels, and the output terminal FBO can reverse communication outputs a current feedback signal.

[0072] For ease of description, the backlight control circuit 30 will be described below using the structure shown in FIG. 3a as an example.

[0073] In addition, the forward voltage VF of the light string 200 in each light string group 21 decreases as the temperature of the light string 200 increases, as shown in FIG. 4a, while FIG. 4a is a graph of the forward voltage VF of the light string 200 as a function of the temperature of the light string 200 when the rated operating current IF of the light string 200 is 3 mA.

[0074] Since the brightness at different places of the image displayed by the display terminal 01 is different, the temperatures of the light string groups 21 at different positions are also different. As a result, the voltages (Vch1, Vch2, and...) of the channel ports (CH1, CH2, and...) of the driver circuit 301 are incompatible, as shown in FIG. 4b, with a large bar height in the histogram shown in FIG. 4b indicates the higher voltage value of the corresponding channel port.

[0075] Based on this, it can be learned from the above that the power conversion circuit 302 is connected to the FBO output terminal of the feedback circuit 301 of the driver. Therefore, after performing voltage conversion over the input voltage, the power conversion circuit 302 can be further configured to: based on the current feedback signal provided by the feedback output terminal FBO of the driver circuit 301, fine-adjust the voltage obtained after the conversion to obtain a voltage VLED supply and output voltage VLED supply through the voltage output Vout. In this way, the voltages are regulated at the second terminals of the groups 21 of the light chains.

[0076] In this case, after the voltages at the second terminals a of the light string groups 21 are adjusted, since the source current flowing through the light string groups 21 is fixed, the voltages at the second terminals a of the light string groups 21, that is, the voltages (Vch1, Vch2 and...) of the ports (CH1, CH2 and...) of the channels of the driver circuit 301 change along with the voltages of the second terminals a of the light string groups 21. Thus, the voltages of the first terminals c of the light string groups 21 are higher than the threshold voltage of the conduction ports of the CH channels of the driver circuit 301, thereby ensuring that the light string groups 21 can have normal brightness. In addition, the channel port voltages Vch of the driver circuit 301 can be maintained within a certain range. This ensures that the groups of 21 light strings are normally bright and reduces the power consumption of the driver circuit.

[0077] The forward voltage VF of the light string group 21 is the voltage difference between the voltage Va of the second terminal of the light string group 21 and the voltage Vc of the first terminal of the light string group 21, that is, VF=Va-Vc=VLED−Vch. Therefore, for example, when the forward voltage VF of the light string group 21 decreases and causes the voltage Vch of the port CH of the channel, which has the driver circuit 301 and which is connected to the first terminal c of the light string group 21, to increase, the driver circuit 301 provides one type of feedback signal current for the circuit 302 power conversion.

[0078] In this case, the power conversion circuit 302 may decrease, based on the current feedback signal, the supply voltage VLED outputted by the voltage output terminal Vout of the power conversion circuit 302. Since the amount of source current provided by the light driving current source 323 for the light string group 21 is fixed, the voltage at the second terminal a of the light string group 21, that is, the channel CH port voltage Vch which is from the driver circuit 301 and which is connected to the second terminal a group of 21 light strings, decreases accordingly.

[0079] Alternatively, for another example, when the forward voltage VF of the light string group 21 increases and causes the voltage Vch of the channel CH port which has the driver circuit 301 and which is connected to the first terminal c of the light string group 21 to decrease, the driver circuit 301 provides another type of current feedback signal for the power conversion circuit 302 .

[0080] In this case, the power conversion circuit 302 may increase, based on the current feedback signal, the power supply voltage VLED outputted by the voltage output terminal Vout of the power conversion circuit 302. Since the amount of source current provided by the light driving current source 323 for the light string group 21 is fixed, the voltage at the second terminal a of the light string group 21, that is, the voltage Vch of the channel CH port, that is, the driver circuit 301, and which is connected to the second terminal a a group of 21 light strings, increases accordingly.

[0081] Finally, on the one hand, in the backlight control circuit 30 provided in this embodiment of the present application, a feedback output terminal FBO that can provide a current feedback signal is located in the driver circuit 301, and the output terminal The feedback FBO is connected to the power conversion circuit 302 . This enables the driver circuit 301 to provide a current feedback signal to the power conversion circuit 302 based on the voltages (Vch1, Vch2 and...) of the channel ports (CH1, CH2 and...) of the driver circuit 301 in real time. Based on this, the power conversion circuit 302 can perform real-time, based on the current feedback signal, bi-directional adjustment of the power supply voltage VLED outputted by the voltage output terminal Vout of the power conversion circuit 302.

[0082] Thus, in the process of display by the display terminal 01, the power supply voltage VLED received by the second terminal of the light string group 21 can be adjusted within a certain range (for example, about 300 mV). This avoids the abnormal brightness of the light string group 21 caused by the Vch voltage of the CH port being lower than the conduction threshold voltage of the CH port, or avoiding the increase in power consumption of the driver circuit caused by the Vch voltage of the CH port being excessively high. In addition, it also avoids that the voltages (Vch1, Vch2, and...) of the channel ports (CH1, CH2, and...) of the driver circuit 301 remain in a relatively high or low state for a long time, reducing the difference between the voltages (Vch1, Vch2 and...) ports (CH1, CH2 and...) of the channels of the driver circuit 301 and thus ultimately reducing the power consumption of the driver circuit 301.

[0083] On the other hand, the feedback signal provided by the feedback output terminal FBO, which belongs to the driver circuit 301 and which is connected to the power conversion circuit 302, is a current feedback signal. Compared with the voltage signal, the current signal is not affected by the distance between the driver circuit 301 and the power conversion circuit 302, and therefore does not occur relatively large fluctuations, so that signal interference caused by cable noise can be reduced.

[0084] Based on the structure of the backlight driving circuit 30, an embodiment of the present application provides a method for driving the backlight driving circuit. As shown in FIG. 5, the method includes steps S101 and S102.

[0085] S101: The driver circuit 301 receives the voltages (Vch1, Vch2 and...) of the channel ports (CH1, CH2 and...) and enables the feedback output terminal FBO to provide a current feedback signal.

[0086] From the above, it can be understood that the driver circuit 301 is configured to perform step S101. S101 specifically includes steps S201-S203 shown in FIG. 6.

[0087] S201: The driver circuit 301 compares the voltages (Vch1, Vch2 and ...) of the channel ports (CH1, CH2 and ...) with the first predetermined voltage VL and the second predetermined voltage VH, with VL<VH.

[0088] It should be noted that when the channel port voltage Vch is in the range of VL to VH, the effect on the power consumption of the driver circuit 301 is relatively small and can be neglected. When the channel port voltage Vch is outside the range of VL to VH, for example, when the channel port voltage Vch is lower than the first predetermined voltage VL, the channel CH port voltage Vch tends to be lower than the channel CH port conduction threshold voltage. As a result, the brightness of the light string group 21 is abnormal. Alternatively, when the channel port voltage Vch is higher than the second predetermined voltage VH, the channel port voltage Vch has a relatively large effect on the power consumption of the driver circuit 301. In this case, the output terminal FBO of the feedback circuit 301 of the driver must provide a current feedback signal to the power conversion circuit 302 so that the power conversion circuit 302 can perform real-time bidirectional adjustment of the power supply voltage VLED output by the output terminal based on the current feedback signal. outputting the voltage Vout of the power conversion circuit 302, and finally adjusting the voltage of the CH port to be in the range of VL to VH. The values of the first predetermined voltage VL and the second predetermined voltage VH are not limited in the present application, and may be set based on the performance of the driver circuit 301 and the power consumption that can be tolerated by the driver circuit 301.

[0089] In order to be able to execute S201, the driver circuit 301 may include a comparator 311 as shown in FIG. 7. The input terminal of the comparator 311 is connected to each CH port of the channel. In addition, the comparator 311 further includes two reference voltage input terminals that are configured to input the first predetermined voltage VL and the second predetermined voltage VH to the comparator 311, respectively.

[0090] It should be noted that when the comparator 311 is connected to a plurality of channel ports CH, for example, the comparator 311 can be separately connected to each channel port and compare the voltage Vch of each channel port with the first predetermined voltage VL and the second predetermined voltage VH. The manner in which the comparator 311 compares the voltages of the plurality of CH ports associated with the comparator 311 is not limited here.

[0091] Thus, the comparator 311 can compare the voltages (Vch1, Vch2 and ...) of the channel ports (CH1, CH2 and ...) with the first predetermined voltage VL and the second predetermined voltage VH. In addition, the comparator 311 further includes a first output terminal O1 and a second output terminal O2.

[0092] When the comparison result of the comparator 311 is that the voltage Vch of any channel CH port is lower than the first predetermined voltage VL, that is, when any voltage Vch is lower than VL, the first output terminal O1 of the comparator 311 outputs a valid signal. This ensures that the currents transmitted by all the channel ports of the driver circuit 301 to the light string groups 21 are stable, so that the light emission characteristics of the light string groups 21 are stable, and therefore the light string groups 21 can emit light normally.

[0093] Alternatively, when the comparison result of the comparator 311 is that the voltages Vch of all the channel ports CH are higher than the second predetermined voltage VH, that is, when all the voltages Vch are higher than VH, the second output terminal O2 of the comparator 311 outputs a valid signal to reduce the power consumption of the driver circuit 301.

[0094] S202: When the voltage Vch of any channel CH port is lower than the first predetermined voltage VL, the feedback output terminal FBO of the driver circuit 301 provides the first current I1 as a current feedback signal.

[0095] It should be noted that from the above it can be understood that the driver circuit 301 enables the feedback output terminal FBO of the driver circuit 301 to provide a current feedback signal based on the voltages (Vch1, Vch2 and ...) of all channel ports. In this case, in some embodiments of the invention, when the driver circuit 301 executes S202, the comparator 311 of the driver circuit 301 may obtain the Vch voltages of all channel ports and then determine whether the Vch voltage of each channel port is lower than the first predetermined voltage VL. Then, based on the results of determining the voltages Vch of all the channel ports, the comparator 311 determines whether the voltage Vch of any port CH of the channel in the voltages Vch of all the channel ports is lower than the first predetermined voltage VL.

[0096] Alternatively, in some other embodiments of the invention, when the driver circuit 301 performs S202, the comparator 311 of the driver circuit 301 may sequentially determine, in accordance with the physical positions of the CH port locations, whether the channel port voltages Vch are lower than the first specified voltage VL. When the Vch voltage of one channel port is lower than the first predetermined voltage VL, the Vch voltage of any channel CH port is considered to be lower than the first predetermined voltage VL. The manner in which the driver circuit 301 determines that the voltage Vch of any port CH of the channel is lower than the first predetermined voltage VL is not limited in the present application.

[0097] In order to be able to implement S202, the driver circuit 301 may include a first current source 321 as shown in FIG. 7. The first current source 321 is configured to perform step S202.

[0098] For example, as shown in FIG. 7, the control terminal (Con) of the first current source 321 is connected to the first output terminal O1 of the comparator 311. The first electrode (for example, positive electrode "+") of the first current source 321 is connected to the feedback output terminal FBO of the driver circuit 301, the second electrode (for example , negative electrode "-") of the first current source 321 is connected to the first voltage terminal, and the first voltage terminal is configured to output the first voltage V1. For example, in some embodiments of the invention of the present application, the first voltage output may be a ground terminal GND, and the first voltage V1 is 0 V or low.

[0099] The "+" positive electrode of the first current source 321 is connected to the FBO output terminal of the feedback circuit 301 of the driver, and the "-" negative electrode of the first current source 321 is connected to the GND ground terminal. Therefore, the first current I1 generated by the first current source 321 may be a leakage current (sink) flowing to the driver circuit 301.

[00100] Based on this, when the comparison result of the comparator 311 is that the voltage Vch of any port CH of the channel is lower than the first predetermined voltage VL, the first output terminal O1 of the comparator 311 outputs a valid signal as the first control signal. When the first control signal is received, the control terminal (Con) of the first current source 321 starts to operate and generates the first current I1, which is used as a current feedback signal provided by the feedback output terminal FBO of the driver circuit 301.

[00101] It should be noted that in this embodiment of the present application, the comparator 311 of the driver circuit 301 can detect the voltages Vch of the CH ports for each frame, and the user can set the report time for the detection result of the comparator 311 as needed. For example, the detection result may be reported once for every frame or every two frames, and one frame may be calculated according to the refresh rate of the liquid crystal display panel 10. For example, when the refresh rate of the liquid crystal display panel 10 is 60 Hz, the duration T of one frame is 1/60 Hz.

[00102] After the comparator 311 of the driver circuit 301 each time reports the detection result (for example, once there may be two frames), when the driver circuit 301 obtains, based on the detection result reported by the comparator 311, that the Vch voltage of any channel port is lower, than the first predetermined voltage VL for S consecutive times (for example, S times is S×2 frames, where S≥2 and S is a positive integer), the first current I1 provided by the feedback output terminal FBO of the driver circuit 301 may increase by the amount ΔI of the current change each time in a stepwise manner.

[00103] It should be noted that the first current I1 provided by the feedback output terminal FBO of the driver circuit 301 increases by the current change amount ΔI in a step manner each time, which means that the value of the current of the first current I1 provided by the feedback output terminal FBO of the circuit 301 of the driver each time increases by the amount of current change ΔI based on the current value of the first current I1 supplied last.

[00104] Next, step S102 shown in FIG. five.

[00105] S102: The power conversion circuit 302 increases, based on the current feedback signal, the supply voltage VLED outputted by the voltage output terminal Vout.

[00106] It can be understood from the above that when the voltage Vch of any channel CH port is lower than the first predetermined voltage VL, the feedback output terminal FBO of the driver circuit 301 provides the first current I1 as a current feedback signal. In a circuit that includes a plurality of light string groups 21, a power conversion circuit 302, and a driver circuit 301, the first current I1 is the inflow current flowing into the driver circuit 301. Therefore, according to the characteristic of the current flowing from the high electric potential to the low electric potential, the supply voltage VLED output by the voltage output terminal Vout of the power conversion circuit 302 is increased based on the original voltage.

[00107] Based on this, when the voltage Vch of any channel port is lower than the first specified voltage VL for S consecutive times (for example, S times is S × 2 frames, while S≥2, and S is a positive integer) , the first current I1 provided by the feedback output terminal FBO of the driver circuit 301 increases each time by the current change amount ΔI in a stepwise manner. In this case, in a circuit that includes a plurality of light string groups 21, a power conversion circuit 302, and a driver circuit 301, the first current I1 is the inflow current flowing into the driver circuit 301. Therefore, in accordance with the characteristic of the current flowing from the high electric potential to the low electric potential, the power conversion circuit 302 increases each time by the voltage change amount ΔV based on the first current I1, the voltage output by the voltage output terminal Vout, that is, the power supply voltage VLED .

[00108] Thus, when the voltage Vch of any channel port is lower than the first predetermined voltage VL for S successive times, the power conversion circuit 302 increases each time by the same amount of voltage change ΔV based on the first current I1 each time the supply voltage VLED, output by the output terminal Vout, so that the power supply voltage VLED can increase evenly. In this case, the voltage (that is, the supply voltage VLED) of the second terminal a of the light string group 21 may increase evenly each time. The voltage of the first terminal c of the light string group 21, that is, the voltage of the channel CH port of the driver circuit 301, also increases uniformly each time and is in the range of VL to VH.

[00109] Based on this, in order to set the amount of voltage change ΔV as required, in some embodiments of the present invention, the power conversion circuit 302 may include a first resistor R1 shown in FIG. 8. For ease of description, the resistance value of the first resistor is also labeled R1. In addition, in the power conversion circuit 302, in order to enable the voltage output terminal Vout of the power conversion circuit 302 to normally output the power supply voltage VLED, a third resistor R3 that is connected in series with the first resistor R1 is further disposed in the power conversion circuit 302.

[00110] The first terminal of the third resistor R3, located away from the first resistor R1, is connected to the ground terminal GND. The voltage output by the voltage output terminal Vout is divided by the first resistor R1 and the third resistor R3 to obtain the FB node voltage. The voltage of the FB node may be input to an error determiner (not shown in the figure) of the power conversion circuit 302 for comparison with a reference voltage within the power conversion circuit 302, so that the voltage output terminal Vout outputs the normal power supply voltage VLED.

[00111] Based on this, the first terminal of the first resistor R1 is connected to the voltage output terminal Vout of the power conversion circuit 302, and the second terminal of the first resistor R1 is connected to the feedback output terminal FBO of the driver circuit 301. In this case, for the above voltage change ΔV, ΔV = |ΔI| × R1.

[00112] It should be noted that the resistance value of the first resistor R1 is not limited in the present application, and can be set based on the value of the first current I1 and the amount of voltage change ΔV used each time the power supply voltage VLED is finely adjusted. For example, in some embodiments of the invention of the present application, the first current I1 generated by the first current source 321 may be several hundred mA. The voltage change amount ΔV used in fine adjustment of the supply voltage VLED can be set to several hundred mV each time, such as 300 mV. In this case, the resistance value of the first resistor R1 may be less than 300 kΩ.

[00113] Based on this, in some embodiments of the invention of the present application, the backlight control circuit 30 may further include a second resistor R2, as shown in FIG. 8. The first terminal of the second resistor R2 is connected to the second terminal of the first resistor R1, and the second terminal of the second resistor R2 is connected to the output terminal FBO of the feedback circuit 301 of the driver. The second resistor is configured to perform impedance matching at the second terminal of the first resistor R1 and the feedback output terminal FBO of the driver circuit 301.

[00114] S203: When the voltages Vch of all the CH ports are higher than the second predetermined voltage VH, the feedback output terminal FBO of the driver circuit 301 provides the second current I2 as a current feedback signal.

[00115] In order to be able to perform step S203, the driver circuit 301 may include a second current source 322 as shown in FIG. 7. The second current source 322 is configured to perform step S203.

[00116] For example, as shown in FIG. 7, the control (Con) terminal of the second current source 322 is connected to the second output terminal O2 of the comparator 311. The first electrode (eg, positive electrode "+") of the second current source 322 is connected to the second voltage terminal VCC. The second voltage terminal VCC is configured to output the second voltage V2. In addition, the second electrode (for example, the negative electrode "-") of the second current source 322 is connected to the output terminal FBO of the feedback circuit 301 of the driver.

[00117] For example, in some embodiments of the invention of the present application, the second voltage V2 outputted by the second voltage terminal VCC may be at a high level. In this case, the voltage value of the first voltage V1 outputted by the first voltage terminal, for example, the ground terminal GND, is smaller than the voltage value of the second voltage V2 outputted by the second voltage terminal VCC, that is, |V1|˂|V2|.

[00118] In this case, when the comparison result of the comparator 311 is that the voltages Vch of all the CH ports of the channels are higher than the second predetermined voltage VH, the second output terminal O2 of the comparator 311 outputs a valid signal that can be specified as the second control signal . Upon receipt of the second control signal, the control terminal (Con) of the second current source 322 starts to operate and generates the second current I2, which is used as a current feedback signal provided by the feedback output terminal FBO of the driver circuit 301.

[00119] The "+" positive electrode of the second current source 322 is connected to the second voltage terminal VCC, and the "-" negative electrode of the second current source 322 is connected to the feedback output terminal FBO of the driver circuit 301. Therefore, the second current I2 generated by the second current source 322 may be the source current (source) flowing into the power conversion circuit 302. Based on this, the first current I1 and the second current I2 have opposite directions.

[00120] Then, the power conversion circuit 302 reduces, based on the current feedback signal, the supply voltage VLED outputted by the voltage output terminal Vout.

[00121] From the above, it can be understood that when the voltages Vch of all the channel CH ports are higher than the second predetermined voltage VH, the feedback output terminal FBO of the driver circuit 301 outputs the second current I2 as a current feedback signal. In a circuit that includes a plurality of light string groups 21, a power conversion circuit 302, and a driver circuit 301, the second current I2 is a source current flowing into the power conversion circuit 302. Therefore, in accordance with the characteristic of the current flowing from the high electric potential to the low electric potential, the supply voltage VLED output by the voltage output terminal Vout of the power conversion circuit 302 is reduced based on the original voltage.

[00122] Based on this, it can also be known that when the Vch voltages of all the CH ports are higher than the second predetermined VH voltage for N consecutive times (for example, once corresponds to two frames, and N times corresponds to N × 2 frames, where N≥2 and N is a positive integer), the second current I2 provided by the feedback output terminal FBO of the driver circuit 301 is stepped down by the current change amount ΔI each time. In a circuit that includes a plurality of light string groups 21, a power conversion circuit 302, and a driver circuit 301, the second current I2 is a source current flowing into the power conversion circuit 302. Therefore, in accordance with the characteristic of the current flowing from the high electric potential to the low electric potential, the power conversion circuit 302 reduces the voltage change amount ΔV each time based on the second current I2, the voltage output by the voltage output terminal Vout, that is, the power supply voltage VLED .

[00123] Thus, when the voltages Vch of all channel ports are higher than the second predetermined voltage VH for N successive times, the power conversion circuit 302 is reduced by the same amount of voltage change ΔV based on the second current I2 each time the voltage VLED power output by the output terminal Vout voltage, so that the power supply voltage VLED can decrease evenly. In this case, the voltage (that is, the supply voltage VLED) of the second terminal a of the light string group 21 may decrease evenly each time. Therefore, the voltage of the first terminal c of the light string group 21, that is, the voltage of the channel port CH of the driver circuit 301, decreases evenly each time and is in the range from VL to VH.

[00124] Finally, in FIG. 8, the comparator 311 of the driver circuit 301 can detect the voltages Vch of all the CH ports for each frame. The driver circuit 301 may provide the first current I1 (that is, a sink current) based on the detection result of the comparator 311 each time to raise the supply voltage VLED outputted by the voltage output terminal Vout of the power conversion circuit 302. Alternatively, the output terminal FBO of the feedback circuit 301 of the driver can also provide the second current I2 (that is, the source current) based on the detection result of the comparator 311 each time to reduce the supply voltage VLED output by the voltage output terminal Vout of the power conversion circuit 302 . Therefore, the backlight control circuit 30 provided in the embodiments of the present application can perform bi-directional voltage adjustment on the second terminal a of the light string group 21.

[00125] Based on the above method, for example, after turning on the backlight control circuit 30 in the first phase A shown in FIG. 9, the voltage output terminal Vout of the power conversion circuit 302 shown in FIG. 8 can provide the initial voltage Vref to the second terminals a of the light string groups 21 using the power supply port Vps of the driver circuit 301.

[00126] When the initial voltage Vref is relatively high, the comparator 311 of the driver circuit 301 can detect, after a predetermined time, for example, one frame (duration P), that the voltages Vch of all the CH ports are higher than the second predetermined voltage VH, and output a real control a signal to the control pin con of the second current source 322.

[00127] In this case, the second current source 322 generates the second current I2 (source current) as a current feedback signal provided by the feedback output terminal FBO. The power conversion circuit 302 reduces, based on the second current I2, the voltage output by the voltage output terminal Vout of the power conversion circuit 302, for example, reduces the voltage by the voltage change amount ΔV, so that the voltage output by the voltage output terminal Vout of the power conversion circuit 302, adjusted to the correct voltage.

[00128] In this case, after the second frame in the second phase B shown in FIG. 9, the voltage output terminal Vout of the power conversion circuit 302 can continuously output the correct supply voltage VLED to the second terminals a of the light string groups 21.

[00129] In addition, when some of the light emitting devices 202 in the plurality of light string groups 21 in the backlight unit 20 are damaged, causing a circuit break in the light string 200 in which the light emitting devices 202 are located, the control circuit backlight control method presented in the embodiments invention of the present application further includes a method for detecting an open circuit in the light string 200.

[00130] Specifically, the control method further includes the following steps.

[00131] S301: After the first current I1 (that is, the sinking current) provided by the feedback output terminal FBO of the driver circuit 301 is increased by the current change amount ΔI in a stepwise manner for S successive times, the feedback output terminal FBO of the circuit 301 the driver is in a high impedance state when the comparator 311 of the driver circuit 301 still determines that the voltage Vch of any port CH of the channel is lower than the first specified voltage VL, with S≥2, and S is a positive integer. In this case, it is considered that an open circuit condition exists in the light string groups 21, and at least one light string 200 in the light string groups 21 is damaged.

[00132] It should be noted that the fact that the feedback output terminal FBO is in a high impedance state means that the feedback output terminal FBO is completely cleared, so that the feedback output terminal FBO has a rather large impedance with respect to reference ground. , for example, may be several hundred kΩ, i.e. a high impedance state. In this case, the feedback output terminal FBO no longer affects the power conversion circuit 302 .

[00133] From the above, it can be understood that in a process in which the driver circuit 301 is configured to perform step S301, in the third phase C shown in FIG. 9, when the comparator 311 of the driver circuit 301 continuously determines the voltages Vch of all channel ports for each frame, and the comparator 311 of the driver circuit 301 determines that the voltage Vch of any channel port is lower than the first specified voltage VL for S consecutive times (for example, the output terminal The feedback FBO outputs the first current I1 once every two frames, and S times is S × 2 frames, that is, the comparator 311 detects that the voltage Vch of any channel port is lower than the first specified voltage VL for S × 2 consecutive frames), the first current I1 (ie, the sinking current) provided by the feedback output terminal FBO of the driver circuit 301 is increased by the current change amount ΔI in a stepwise manner for S successive times, for example, eight times. In this case, the current value of the first current I1 provided by the feedback output terminal FBO of the driver circuit 301 for the Sth time is 8Δ×I. The power conversion circuit 302 increases the voltage change amount ΔV each time based on the first current I1, the voltage output by output pin Vout voltage. The power supply voltage VLED outputted by the voltage output terminal Vout is increased by 8×ΔV at the Sth time based on the initial voltage.

[00134] However, in the plurality of light string groups 21, there is a light string 200 that is in an open circuit state. Therefore, no matter how the value of the supply voltage VLED outputted by the voltage output terminal Vout of the power conversion circuit 302 increases, the voltage Vch of the channel CH port to which the second terminal a of the light string 200 is connected, which is in the open circuit state, is still lower than the first given voltage VL.

[00135] Therefore, after the third phase C ends, the voltage output terminal Vout of the power conversion circuit 302 outputs a voltage with a final voltage value (VLED+S×ΔV) obtained after S times of boost. When the comparator 311 of the driver circuit 301 still determines that the voltage Vch of any port CH of the channel is lower than the first predetermined voltage VL, the feedback output terminal FBO of the driver circuit 301 is in a high impedance state. The driver circuit 301 can output an open circuit signal to the control system of the display terminal to prompt that the open circuit light string 200 exists in the plurality of light string groups 21 to achieve the purpose of detecting an open circuit.

[00136] S302: The voltage output by the voltage output terminal Vout of the power conversion circuit 302 is restored to the initial voltage Vref.

[00137] After the driver circuit 301 can output an open circuit signal to the control system of the display terminal, to prevent the power supply voltage VLED outputted by the voltage output terminal Vout of the power conversion circuit 302 from further increasing, and thus affect the other light circuit 200, the voltage output by the voltage output terminal Vout of the power conversion circuit 302 is restored to the initial voltage Vref.

[00138] In some embodiments of the invention of the present application, after completion of the third phase C, the process may directly proceed to the fifth phase E, shown in FIG. 9, and the voltage outputted by the voltage output terminal Vout of the power conversion circuit 302 is restored to the initial voltage Vref.

[00139] Alternatively, in some other embodiments of the invention of the present application, after the third phase C ends, the fourth phase D can be added between the third phase B and the fifth phase E. In the fourth phase D, the voltage output terminal Vout of the circuit 302 the power conversion continues to output the voltage with the voltage value (VLED + (S+1) × ΔV) obtained after S+1 times of boost. In this case, if the comparator 311 of the driver circuit 301 still determines that the voltage Vch of any port CH of the channel is lower than the first predetermined voltage VL after completion of the fourth phase D, the feedback output terminal FBO of the driver circuit 301 is in a high-impedance state. Thus, the fourth phase D is added to increase the number of times the CH port Vch voltages are determined to reduce the possibility that the CH port Vch voltages are incorrectly determined. The process may then proceed to the fifth phase E shown in FIG. 9, the voltage outputted by the voltage output terminal Vout of the power conversion circuit 302 is restored to the initial voltage Vref.

[00140] The duration of the fourth phase D in this application is not limited. For example, the fourth phase D may include three frames or two frames.

[00141] Thereafter, the feedback output terminal FBO of the driver circuit 301 is constantly in a high impedance state, and the voltage output terminal Vout of the power conversion circuit 302 continuously outputs the initial voltage Vref, so that each light string 200 in each light string group 21 operates at the initial voltage Vref.

[00142] In addition, after receiving the open circuit signal, the control system of the display terminal 01 can display alarm information to the user. The user can determine, based on the current display effect of the display terminal 01, whether the light string 200 needs to be repaired in an open circuit state.

[00143] It should be noted that the value of the initial voltage Vref is not limited in the present application. A person skilled in the art can make a preliminary judgment based on the forward voltage value VF of the light string 200. devices 202, the initial value of the operating voltage required for the light string group 21 in which the light string 200 is located, that is, the initial voltage Vref may be about 18 V (6×3 V).

[00144] The above description is only specific implementations of the present application, but is not intended to limit the scope of protection of the present application. Any modifications or substitutions within the limits disclosed in this application shall fall within the protection scope of this application. Therefore, the scope of protection of the present invention should be consistent with the scope of protection of the claims.

Claims (70)

1. A backlight control circuit, wherein the backlight control circuit is configured to drive a plurality of light string groups, each light string group comprising a plurality of light strings connected in parallel, and the backlight control circuit comprising: a driver circuit comprising a feedback output terminal and at least one channel port, wherein the channel port is connected to the first terminal of at least one of said plurality of light string groups, and the driver circuit is configured to receive the Vch voltage of each channel port and enable the output a feedback terminal to provide a current feedback signal based on the voltage Vch; and a power conversion circuit connected to the feedback output terminal and comprising a voltage output terminal, wherein the voltage output terminal is configured to provide a supply voltage to the second terminal of each group of light strings, and the power conversion circuit is configured to perform voltage conversion over the input voltage and increase or reducing the supply voltage based on the current feedback signal. 2. The backlight control circuit according to claim 1, wherein the driver circuit is specifically configured to: comparing the voltage Vch of each channel port with the first predetermined voltage VL and the second predetermined voltage VH, while VL<VH; and, when the voltage Vch of any channel port is lower than the first predetermined voltage VL, allowing the feedback output terminal to provide the first current I1 as a current feedback signal to increase the supply voltage; or, when the Vch voltages of all channel ports are higher than the second predetermined voltage VH, allowing the feedback output terminal to provide the second current I2 as a current feedback signal to reduce the supply voltage, while the first current I1 and the second current I2 have opposite directions. 3. The backlight control circuit of claim 2, wherein the driver circuit comprises a comparator, a first current source, and a second current source; the input terminal of the comparator is connected to the channel ports, the first output terminal of the comparator is connected to the control terminal of the first current source, and the second output terminal of the comparator is connected to the control terminal of the second current source; the comparator is configured to compare the voltage Vch of each channel port with the first predetermined voltage VL and the second predetermined voltage VH; and, when the voltage Vch of any channel port is lower than the first predetermined voltage VL, the first output terminal outputs the first control signal or, when the voltages Vch of all channel ports are higher than the second predetermined voltage VH, the second output terminal outputs the second control signal, while VL <VH; the first electrode of the first current source is connected to the feedback output terminal, the second electrode of the first current source is connected to the first voltage terminal, the first current source is configured to receive the first control signal, and the feedback output terminal provides the first current I1; the first electrode of the second current source is connected to the second voltage terminal, the second electrode of the second current source is connected to the feedback output terminal, the second current source is configured to receive the second control signal, and the feedback output terminal provides the second current I2; and the first voltage terminal is configured to output the first voltage V1, and the second voltage terminal is configured to output the second voltage V2, wherein |V1|<|V2|. 4. The backlight control circuit according to any one of paragraphs. 1-3, in which the power conversion circuit comprises a first resistor that has a resistance value R1, a first terminal of the first resistor is connected to a voltage output terminal, and a second terminal of the first resistor is connected to a feedback output terminal. 5. The backlight control circuit according to claim 4, wherein the backlight control circuit further comprises a second resistor; and the first terminal of the second resistor is connected to the second terminal of the first resistor, the second terminal of the second resistor is connected to the feedback output terminal of the driver circuit, and the second resistor is configured to perform impedance matching on the second terminal of the first resistor and the feedback output terminal. 6. The backlight control circuit according to claim 4, wherein the driver circuit is specifically further configured to: when the voltage Vch of any channel port is lower than the first predetermined voltage VL for S successive times, to increase by an amount

changing the current stepwise for S successive times of the first current I1 provided by the feedback output terminal, while S≥2 and S is a positive integer; and the power conversion circuit, in particular, is additionally made with the possibility of increasing by an amount

voltage changes based on the first current I1 each time the voltage output by the voltage output terminal, while for the amount of voltage change

7. The backlight control circuit according to claim 6, in which the driver circuit is particularly further configured to: after the first current I1 provided by the feedback output terminal is increased by an amount

stepping the current for S successive times, determining that the feedback output pin is in a high impedance state when the voltage Vch of any channel port is lower than the first predetermined voltage VL. 8. The backlight control circuit according to claim 4, in which the driver circuit is further configured to: when the voltages Vch of all channel ports are higher than the second predetermined voltage VH for N successive times, decrease by an amount

changing the current stepwise for N successive times of the second current I2 provided by the feedback output terminal, N≥2 and N is a positive integer; and the power conversion circuit, in particular, is further adapted to be reduced by an amount

voltage changes based on the second current I2 each time the voltage output by the voltage output terminal, while for the amount of voltage change

9. The backlight control circuit according to claim 1, wherein the driver circuit further comprises a plurality of gating ports and a power supply port that is connected to each gating port, and the power supply port is further connected to a voltage output terminal of the power conversion circuit; and the plurality of light string groups are arranged in an array, the second terminals of the plurality of light string groups in one row are connected to one gate port, and the first terminals of the light string groups in one column are connected to one channel port of the driver circuit. 10. The backlight control circuit according to claim 1, wherein the voltage output terminal of the power conversion circuit is connected to the first terminal of each group of light strings. 11. A method for driving a backlight driving circuit, wherein the backlight driving circuit is configured to drive a plurality of light string groups; wherein each group of light strings comprises a plurality of light strings connected in parallel; the backlight driving circuit includes a driver circuit and a power conversion circuit; the driver circuit includes a feedback output pin and at least one channel port; the channel port is connected to a first terminal of at least one of said plurality of light string groups; and the power conversion circuit is connected to the feedback output terminal and contains a voltage output terminal; and wherein the method comprises the steps: obtaining, by the driver circuit, a channel port voltage Vch, and allowing a feedback output terminal to provide a current feedback signal based on the voltage Vch; and increase or decrease by the power supply conversion circuit based on the current feedback signal of the supply voltage outputted by the voltage output terminal. 12. The method of driving the backlight control circuit of claim 11, wherein the driver circuit receives the channel port voltage Vch and provides a current feedback signal, specifically comprising: comparing, by means of a driver circuit, the voltage Vch of each channel port with the first predetermined voltage VL and the second predetermined voltage VH, while VL is VH; and, when the voltage Vch of any channel port is lower than the first predetermined voltage VL, allowing the feedback output terminal of the driver circuit to provide the first current I1 as a current feedback signal to increase the supply voltage; or, when the voltages Vch at all channel ports are higher than the second specified voltage, allowing the feedback output terminal of the driver circuit to provide the second current I2 as a current feedback signal to reduce the supply voltage, while the first current I1 and the second current I2 have opposite directions. 13. The method of controlling the backlight control circuit according to claim 12, wherein the driver circuit comprises a comparator, a first current source, and a second current source; the input terminal of the comparator is connected to the channel ports; the first output terminal of the comparator is connected to the control terminal of the first current source; the first electrode of the first current source is connected to the feedback output terminal and the second electrode of the first current source is connected to the first voltage terminal; the second output terminal of the comparator is connected to the control terminal of the second current source; the first electrode of the second current source is connected to the second voltage terminal and the second electrode of the second current source is connected to the feedback output terminal; and the first voltage terminal is configured to output the first voltage V1, and the second voltage terminal is configured to output the second voltage V2, while |V1|<|V2|; and receiving by the driver circuit of the voltage Vch of the channel port and providing a current feedback signal, in particular, contains: comparing, by means of a comparator, the voltage Vch of each channel port with the first predetermined voltage VL and the second predetermined voltage VH, while VL<VH; and, when the voltage Vch of any channel port is lower than the first predetermined voltage VL, outputting the first control signal by the first output terminal of the comparator, receiving the first control signal by the first current source, and providing through the feedback output terminal the first current I1; or, when the voltages Vch of all channel ports are higher than the second predetermined voltage VH, outputting the second control signal to the second output terminal of the comparator, receiving the second control signal to the second current source, and providing through the feedback output terminal the second current I2. 14. The method of driving the backlight control circuit according to claim 12 or 13, wherein the power conversion circuit comprises a first resistor having a resistance value R1, wherein the first terminal of the first resistor is connected to a voltage output terminal, and the second terminal of the first resistor is connected to a feedback output terminal. communications; the driver circuit receiving the channel port voltage Vch and allowing the feedback output pin to provide a current feedback signal based on the Vch voltage comprises: when the Vch voltage of any channel port is lower than the first specified voltage VL for S successive times, increase by the amount

changing the current stepwise for S successive times of the first current I1 provided by the feedback output terminal, while S≥2 and S is a positive integer; and increase or decrease by the power supply conversion circuit based on the current feedback signal of the power supply voltage output by the voltage output terminal, contains: increase by the power supply conversion circuit by the amount

voltage changes based on the first current I1 each time the voltage output by the voltage output terminal, while for the amount of voltage change

15. The method of controlling the backlight control circuit according to claim 14, wherein the method further comprises: after the first current I1 provided by the feedback output terminal of the driver circuit is increased by the amount

stepping current for S successive times, determining that a feedback output terminal of the driver circuit is in a high impedance state when the voltage Vch of any channel port is lower than the first predetermined voltage VL; and restoring the voltage outputted by the voltage output terminal of the power conversion circuit to the initial voltage. 16. The method of driving the backlight driving circuit according to claim 12 or 13, wherein the power conversion circuit comprises a first resistor having a resistance value R1, a first terminal of the first resistor is connected to a voltage output terminal, and a second terminal of the first resistor is connected to a feedback output terminal; the driver circuit receiving the channel port voltage Vch and allowing the feedback output terminal to provide a current feedback signal based on the Vch voltage comprises: when the Vch voltages of all channel ports are higher than the second specified voltage VH for N successive times, decrease by the amount

changing the current stepwise for N successive times of the second current I2 provided by the feedback output terminal, N≥2 and N being a positive integer; and increase or decrease by the power supply conversion circuit based on the current feedback signal of the supply voltage output by the voltage output terminal, comprises: decrease by the power supply conversion circuit by the amount

voltage changes based on the second current I2 each time the voltage output by the voltage output terminal, while for the amount of voltage change

17. A display terminal comprising a liquid crystal display panel and a backlight unit configured to provide a light source for the liquid crystal display panel; the backlight unit includes a plurality of light string groups and a backlight control circuit; each group of light strings contains a plurality of light strings connected in parallel; and each light string comprises a plurality of light emitting devices connected in series; and backlight control circuit contains: a driver circuit comprising a feedback output terminal and at least one channel port, wherein the channel port is connected to the first terminals of at least one of said plurality of light string groups, and the driver circuit is configured to receive the voltage Vch of each channel port and enable the output a feedback terminal to provide a current feedback signal based on the voltage Vch; and a power conversion circuit connected to the feedback output terminal and comprising a voltage output terminal, wherein the voltage output terminal is configured to provide a supply voltage to the second terminal of each group of light strings, and the power conversion circuit is configured to increase or decrease the supply voltage of the voltage output terminal based on the current feedback signal. 18. The display terminal of claim 17, wherein the liquid crystal display panel comprises a plurality of subpixels arranged in an array, and a plurality of light string groups arranged in an array; and vertical projection onto the backlight unit of the area in which the

subpixels, covers the area in which one group of light strings is located, while M≥1, N≥1 and N and M are positive integers. 19. The display terminal of claim 18, wherein the driver circuit further comprises a plurality of strobe ports and a power supply port that is connected to each strobe port, the power supply port is further connected to a voltage output terminal of the power conversion circuit, and a backlight unit further contains a plurality of second signal lines and a plurality of first signal lines; wherein the one second signal line is separately connected to one gate port and the second terminals of the plurality of light string groups in the same row; and one first signal line is separately connected to one channel port, the driver circuit port, and the first terminals of the light string groups, which are in the same column. 20. Driver circuit, wherein the driver circuit comprises a feedback output terminal and at least one channel port; the channel port is connected to the first output of the light string group; the driver circuit is configured to receive the Vch voltage of each channel port and allow the feedback output pin to provide a current feedback signal to the power conversion circuit based on the Vch voltage, so that the power conversion circuit increases or decreases, based on the current feedback signal, the output voltage the second output of the group of light chains. 21. The driver circuit according to claim 20, while the driver circuit is specifically configured to: comparing the voltage Vch of each channel port with the first predetermined voltage VL and the second predetermined voltage VH, while VL<VH; and, when the voltage Vch of any channel port is lower than the first predetermined voltage VL, allowing the feedback output terminal to provide the first current I1 as a current feedback signal to increase the supply voltage; or. when the Vch voltages of all channel ports are higher than the second predetermined voltage VH, allowing the feedback output terminal to provide the second current I2 as a current feedback signal to reduce the supply voltage, while the first current I1 and the second current I2 have opposite directions. 22. The driver circuit according to claim 21, wherein the driver circuit comprises a comparator, a first current source and a second current source; the input terminal of the comparator is connected to the channel ports, the first output terminal of the comparator is connected to the control terminal of the first current source, and the second output terminal of the comparator is connected to the control terminal of the second current source; the comparator is configured to compare the voltage Vch of each channel port with the first predetermined voltage VL and the second predetermined voltage VH; and, when the voltage Vch of any channel port is lower than the first predetermined voltage VL, the first output terminal outputs the first control signal, or, when the voltages Vch of all channel ports are higher than the second predetermined voltage VH, the second output terminal outputs the second control signal, wherein VL<VH; the first electrode of the first current source is connected to the feedback output terminal, the second electrode of the first current source is connected to the first voltage terminal, the first current source is configured to receive the first control signal, and the feedback output terminal provides the first current I1; the first electrode of the second current source is connected to the second voltage terminal, the second electrode of the second current source is connected to the feedback output terminal, the second current source is configured to receive the second control signal, and the feedback output terminal provides the second current I2; and the first voltage terminal is configured to output the first voltage V1, and the second voltage terminal is configured to output the second voltage V2, wherein |V1|<|V2|.

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