The present disclosure relates generally to a field of display technologies, and more particularly, to a gamma voltage generator, a source driver including a gamma voltage generator, and a display apparatus.
The display apparatus includes a display panel and a driver. The display panel includes scan lines, data lines, and pixels. The driver may include a gate driver and a source driver. Each pixel may transmit light with brightness corresponding to a data voltage supplied through a corresponding data line in response to a gate signal supplied through a corresponding gate line. The gamma voltage generator in the source driver (e.g., included in a source driver integrated circuit (IC)) may generate a plurality of gamma voltages respectively corresponding to a plurality of gray scale values based on gamma reference voltages, and may use respective gamma voltages to convert gray scale values of display data into data voltages, so that each pixel displays based on a corresponding data voltage.
Therefore, it is very important to rapidly settle and stabilize respective gamma voltages used for generating the data voltages to ensure a display effect.
According to one aspect of the present disclosure, there is provided a gamma voltage generator, connected with a plurality of channel circuits and used for outputting a predetermined number of gamma voltages, each channel circuit selecting at least one gamma voltage according to input display data to generate a corresponding data voltage, wherein, the gamma voltage generator includes: a gamma voltage generating circuit, having a plurality of first voltage input end nodes, a plurality of second voltage input end nodes, and a plurality of voltage output end nodes; a plurality of basic buffers, each basic buffer having an input end for receiving a corresponding gamma reference voltage, and an output end connected to a corresponding first voltage input end node; and a plurality of dynamic buffers, each dynamic buffer having an input end for receiving a corresponding gamma reference voltage, and an output end connected to a corresponding second voltage input end node, wherein each dynamic buffer is configured to operate in a first mode or a second mode, and wherein, each dynamic buffer does not output a buffer voltage when operating in the first mode, and outputs the buffer voltage to a second voltage input end node which the dynamic buffer is connected to when operating in the second mode, and wherein, at least a part of dynamic buffers of the plurality of dynamic buffers switch from the first mode to the second mode based on update or change of the display data.
According to another aspect of the present disclosure, there is further provided a gamma voltage generator, and the gamma voltage generator includes: a gamma voltage generating circuit, having a plurality of voltage input end nodes and a plurality of voltage output end nodes, the plurality of voltage output end nodes outputting a predetermined number of gamma voltages based on input voltages from the plurality of voltage input end nodes; and a plurality of buffers, respectively electrically coupled to the plurality of voltage input end nodes, wherein, the gamma voltage generating circuit includes a plurality of resistor units connected in series; a connection node of adjacent resistor units is coupled to one voltage output end node; and each resistor unit is configured to have a second resistance when operating in the second mode less than a first resistance when operating in the first mode.
According to another aspect of the present disclosure, there is further provided a source driver, including: the gamma voltage generator as described above; and a plurality of channel circuits, connected with the gamma voltage generator and used for generating respective data voltages corresponding to input display data by using gamma voltages output by the gamma voltage generator.
According to another aspect of the present disclosure, there is further provided a display apparatus, including a display panel; and the source driver as described above, used for driving the display panel.
By introducing dynamic buffers and/or variable resistor units, the gamma voltage generator according to the embodiment of the present disclosure may reduce an offset of the generated gamma voltages relative to the expected gamma voltages when it is necessary to settle (establish) and stabilize the gamma voltages again (e.g., when it is necessary to update or change the display data), may improve driving capability of the gamma voltages output by the gamma voltage generating circuit, and meanwhile, may accelerate the process of settling and stabilizing the gamma voltage, so as to ensure a display effect. Besides, by changing an operation mode of the dynamic buffers only when the display data changes, overall power consumption may be saved. In addition, in a case where a plurality of source driver circuits drive a same display panel, the plurality of source driver circuits all use the gamma voltage generator according to the embodiment of the present disclosure, which may reduce a display chromatic difference and thus improve a display effect.
The accompanying drawings are included to provide further understanding of the present disclosure, and the accompanying drawings are incorporated into the specification and form a part of the specification. The accompanying drawings illustrate the embodiments of the present disclosure and are used for explaining principles of the present disclosure together with the description.
It should be understood that other embodiments may be utilized and structural changes may be made without departing from the scope of the present disclosure. In addition, it should be understood that the wording and terms used herein are for descriptive purposes and should not be considered limitative. The use of “comprising”, “including” or “having” and variations thereof herein is intended to cover items listed thereafter and equivalents thereof as well as additional items. Unless otherwise limited, the term “connection” and variations thereof herein are used in a broad sense and cover direct and indirect connections, and may include electrical or physical connections. Likewise, terms such as “a” “an” or “the” do not denote a limitation of quantity, but denote the presence of at least one. An expression in singular may include an expression in plural, and an expression in plural may also include an expression in singular, unless defined in the context clearly.
As shown in
The display apparatus 10 may display an image in units of frames. Time required to display one frame may be referred to as a vertical cycle, and the vertical cycle may be determined by a frame rate of the display apparatus 10. During one vertical cycle, the gate driver 21 may sequentially scan the plurality of gate lines G1 to Gm. Time for the gate driver 21 to scan each gate line among the plurality of gate lines G1 to Gm is referred as to a horizontal cycle. During one horizontal cycle (an interval between pulses of two horizontal synchronization signals (Hsync)), the source driver 22 may input data voltages to pixels PX on the respective data lines Si to Sn. Each data voltage may be a voltage output by the source driver 22 based on the display data, and brightness of each pixel PX may be determined by a data voltage corresponding thereto.
The processor used for sending the display data to the display driving apparatus 20 may be an Application Processor (AP) in a case of a mobile apparatus, or may also be a Central Processing Unit (CPU) or a System on Chip (SoC) in a case of a desktop computer, a laptop computer, a television, etc. In detail, the processor may be understood as a processing apparatus having an arithmetic function. The processor may generate the display data to be displayed by the display apparatus 10, or receive the display data from a memory, a communicating module, etc., and send the display data to the display driving apparatus 20.
Referring to
The gamma voltage generator 201 generates a plurality of gamma voltages (VGs) and supplies the plurality of gamma voltages (VGs) to each channel circuit CH. The gamma voltage generator 201 may determine the number of the plurality of gamma voltages (VGs) based on the number of bits of the display data. For example, when the display data is 8-bit data, the number of the plurality of gamma voltages VG may be 256 or less; and when the display data is 10-bit data, the number of the plurality of gamma voltages VG may be 1024 or less. In other words, when the display data is n-bit data, the plurality of gamma voltages (VGs) may have at most 2n different voltage values. It should be understood that specific number of the plurality of gamma voltages (VGs) may be selected according to actual situations.
After the shift register 210 receives the corresponding display data (RGB) and captures the same according to timing; the latch circuit 220 may sample and hold the display data according to a shift sequence of the shift register 210. The latch circuit 220 may output the latched display data (RGB) to the digital-analog converter (DAC) 230.
A digital-analog converter (DAC) 230 in each channel circuit CH may generate a data voltage (Vdata) from the plurality of gamma voltages (VGs). The digital-analog converter (DAC) 230 may select at least one of the plurality of gamma voltages (VGs) in response to the latched display data (RGB) from the latch circuit 220, and may output the selected voltage as the data voltage (Vdata). The digital-analog converter (DAC) 230 may include a plurality of switching elements for selecting the at least one of the plurality of gamma voltages. For example, the digital-analog converter (DAC) 230 may output data voltage Vdata corresponding to a gray scale value by using a separate lookup table that defines a relationship between gray scale values and the plurality of gamma voltages, or by performing logical processing on the gray scale value. For example, the data voltage Vdata may have 256 voltage levels corresponding to an 8-bit gray scale value. A data voltage (Vdata) corresponding to each gray scale value may be on a gamma curve. More specifically, the digital-analog converter (DAC) 230 may output the data voltages (Vdata) corresponding to the gamma curve through logic processing on the plurality of gamma voltages in a linear relationship. Or, in some situations, the data voltage may be generated based on more than two selected gamma voltages.
A source buffer 240 in each channel circuit CH may be coupled to one corresponding data line provided in the display panel. The source buffer 240 may receive and amplify the data voltage (Vdata) from the digital-analog converter (DAC) 230, and may apply the amplified data voltage (Vdata) to the corresponding data line. The data voltage Vdata mentioned hereinafter refers to the amplified data voltage Vdata.
As shown in
The gamma reference voltage circuit 310 provides a plurality of gamma reference voltages for generating gamma voltages. Each buffer has an input end for receiving a gamma reference voltage, and an output end for outputting a buffer voltage to the gamma voltage generating circuit 312. The gamma voltage generating circuit 312 generates a plurality of gamma voltages based on a plurality of buffer voltages output by the plurality of buffers. Each buffer may be implemented by an Operational Amplifier (OP), for example, one input end of the operational amplifier is coupled to an output end thereof, and the other input end is coupled to the gamma reference voltage circuit 310 for receiving a corresponding gamma reference voltage.
As an example, the gamma reference voltage circuit 310 may adopt a form of resistor string (which may be referred to as a source resistor string) composed of a plurality of resistors connected in series, to divide an input voltage which is input to two ends of the resistor string, so as to obtain the plurality of gamma reference voltages. Similarly, the gamma voltage generating circuit 312 may also adopt a form of resistor string (which may be referred to as a gamma resistor string) to divide an input voltage which is input to two ends of the resistor string, so as to generate a plurality of gamma voltages. The plurality of buffer voltages output by the plurality of buffers are respectively supplied to a part of connection nodes of adjacent resistors of the gamma resistor string, and at least a part of connection nodes of the gamma resistor string may be coupled to or serve as output end nodes (also referred to as “end points” or “nodes”, etc. for connection) of the gamma voltage generating circuit 312. It should be noted that one resistor symbol shown in the diagram may represent a plurality of resistors.
As described above, rapid settlement and stabilization of respective gamma voltages is crucial to ensure a display effect, so corresponding solutions are needed. For example, in a case of a high frame rate display operation, display time allocated to each frame is relatively short, resulting in high requirements for time for settling the gamma voltages, and respective stable gamma voltages are also favorable for generating accurate data voltages.
In addition, with an increasing size of the display panel, it may be necessary to use two or more source driver circuits (e.g., source driver integrated circuits (ICs)) to drive same display panel. However, due to limitations of fabrication and design process, there may be differences in the gamma voltages generated by the gamma voltage generators respectively included in the two or more source driver circuits driving the same display panel, which may cause non-uniformity of display of the display panel. For example, there is an evident chromatic difference between display areas controlled by different source driver circuits.
In this regard,
As shown in
At least one power transmission terminal P of the first source driver circuit 31 (IC1) is electrically coupled to at least one corresponding power transmission terminal P′ of the second source driver circuit 32 (IC2), to form an electrical connection between the source driver circuit 31 (IC1) and the source driver circuit 32 (IC2). The number of electrical connections between the power transmission terminals of the first source driver circuit 31 (IC1) and the second source driver circuit 32 (IC2) is determined according to design needs, and the present disclosure is not limited to specific number of the electrical connections.
According to the embodiment of the present disclosure, the first source driver circuit 31 (IC1) serves as a master circuit, and the second source driver circuit 32 (IC2) serves as a slave circuit. All buffers in the second source driver circuit 32 (IC2) may be turned off, or, according to the circuit structure (e.g., the connection manner of the source resistor string and the gamma resistor string), all buffers except the buffers that supply a maximum gamma reference voltage and a minimum gamma reference voltage (the same as the maximum gamma reference voltage and the minimum gamma reference voltage in the first source driver) to the second gamma voltage generating circuit are turned off. In such a situation, the at least one power transmission terminal P included in the first source driver circuit 31 (IC1) that serves as an output terminal of the first source driver circuit 31 (IC1) may supply, via the electrical connection(s) between the power transmission terminals of the first source driver circuit 31 (IC1) and the second source driver circuit 32 (IC2), a buffer voltage output from an output end of at least one buffer inside the first source driver circuit 31 (IC1) to the at least one power transmission terminal P′ serving as an input terminal of the second source driver circuit 32 (IC2), so as to supply the buffer voltage to the gamma voltage generator inside the second source driver circuit 32 (IC2); and vice versa.
As shown in
In the gamma voltage generator in
Therefore, a gamma voltage generator capable of rapidly settling and stabilizing the gamma voltages to ensure the display effect of the display panel is needed. In addition, it is also expected that even when two or more source driver circuits (which correspondingly include two or more gamma voltage generators) drive a same display panel, a uniform display effect of the display panel may still be guaranteed based on such gamma voltage generators.
As shown in
The gamma voltage generating circuit 410 has a plurality of first voltage input end nodes IN1, a plurality of second voltage input end nodes IN2, and a plurality of voltage output end nodes O, and the plurality of voltage output end nodes are used for outputting a predetermined number of gamma voltages. Optionally, the gamma voltage generating circuit 410 may be a gamma resistor string composed of a plurality of resistors connected in series, each connection node between resistors in the gamma resistor string may be taken as or coupled to a voltage output end node, and each input end node of the plurality of first voltage input end nodes IN1 and the plurality of second voltage input end nodes IN2 may act as or be connected to a corresponding voltage output end node O, so that a buffer voltage may be output from the corresponding voltage output end node O (and each buffer voltage may be taken as a gamma voltage). For the purpose of illustration, the plurality of first voltage input end nodes IN1 and the plurality of second voltage input end nodes IN2 are shown separately from the voltage output end nodes O respectively corresponding thereto in
The input end of each of the plurality of basic buffers 420 receives a corresponding gamma reference voltage (e.g., the input end is connected to one corresponding output terminal of the gamma reference voltage circuit), and the output end thereof is connected to a corresponding first voltage input end node of the plurality of first voltage input end nodes. The input end of each of the plurality of dynamic buffers 430 receives a corresponding gamma reference voltage (e.g., the input end is connected to one corresponding output terminal of the gamma reference voltage circuit), and the output end thereof is connected to a corresponding second voltage input end node of the plurality of second voltage input end nodes, and each dynamic buffer 430 is configured to operate in the first mode or the second mode. Each dynamic buffer 430 does not output a buffer voltage when operating in the first mode, and outputs the buffer voltage to a connected second voltage input end node when operating in the second mode.
For example, for the dynamic buffer 430-1, in the first mode, the dynamic buffer 430-1 is turned off, and a voltage at the input end thereof will not be output to the output end thereof, so the output end will not supply a buffer voltage to the second voltage input end node IN2 connected therewith; in the second mode, the dynamic buffer 430-1 is turned on, and the voltage at the input end thereof will be output to the output end thereof, so the output end will supply the buffer voltage to the second voltage input end node IN2 connected therewith. Other dynamic buffers also operate synchronously with the dynamic buffer 430-1, so in the first mode, the dynamic buffers may be regarded as not operating.
In this way, in a case where the gamma voltage generator 400 is not connected with other gamma voltage generators, or the gamma voltage generator 400 needs to output buffer voltages to other gamma voltage generators (e.g., the gamma voltage generator 400 serves as a master circuit in a case of more than two source driver circuits as described later), the gamma voltage generator 400 may output a plurality of gamma voltages VGM at the plurality of voltage output end nodes O based on the buffer voltages of the plurality of basic buffers and optionally the buffer voltages of the plurality of dynamic buffers. Moreover, in a case where the gamma voltage generator 400 is connected with other gamma voltage generators but does not need to output buffer voltages to other gamma voltage generators (e.g., the gamma voltage generator 400 serves as a slave circuit in a case of more than two source driver circuits as described later), the plurality of basic buffers are not be turned on or only two basic buffers supplying the maximum gamma reference voltage and the minimum gamma reference voltage are turned on.
For example, the first mode is a standby mode, and the second mode is a boost mode. The boost mode is applicable to a period before the predetermined number of generated gamma voltages are stabilized (i.e., a plurality of buffer voltages need to be continued to be provided in order to settle and stabilize the plurality of gamma voltages at the output end nodes of the gamma voltage generator), and the standby mode is applicable to a period after the predetermined number of generated gamma voltages are stabilized.
Therefore, based on the gamma voltage generator 400 shown in
In addition, in some embodiments, when it is necessary to settle and stabilize the gamma voltages, only some of the plurality of dynamic buffers may operate in the second mode, without all dynamic buffers operating in the second mode. For example, in one embodiment, with respect to a specific image mode, only dynamic buffers that output gamma voltages with a lower value are turned on. In addition, although the dynamic buffers and the basic buffers are alternately arranged in
As described with reference to
Therefore, the update or change of the display data mentioned in the context of the present disclosure may refer to the update or change of pixel data loaded into one or some channel circuits. For example, after the scanning cycle of the current row of pixels ends, the display data for the next row of pixels is loaded into the plurality of channel circuits, for the plurality of channel circuits to output a plurality of data voltages (the number of which is the same as that of the plurality of channel circuits) to the next row of pixels on the panel. For each channel circuit, the display data (i.e., pixel data) for the pixel loaded into the channel circuit is updated (the value of the pixel data may also change). That is, the update of display data may refer to switching between two pieces of pixel data for two adjacent pixels on the same column loaded into any channel circuit, regardless of whether the two pieces of pixel data have changed. Moreover, the change of display data may refer to the switching between two pieces of pixel data for two adjacent pixels on the same column loaded in any channel circuit, and the two pieces pixel data have changed, for example, the two gray values corresponding to the two pieces of pixel data have changed.
During display process, if the display data changes, data voltages output from one or more channel circuits change. Because the plurality of channel circuits are connected with the voltage output end nodes of the gamma voltage generator, so the plurality of gamma voltages output by the gamma voltage generator will be affected by the change of the data voltages, for example, the channel circuits need to draw current from the gamma resistor string that generates the plurality of gamma voltages, so the plurality of gamma voltages will be interfered; and when the display data updates but does not change, the plurality of gamma voltages output by the gamma voltage generator may not be affected.
That is to say, when the display data changes, that is, when the pixel data applied to any channel circuit changes (which will cause the data voltage to change, thus the plurality of gamma voltages will be affected), it is necessary to rapidly settle and stabilize the plurality of gamma voltages output by the gamma voltage generator again. Therefore, with respect to the gamma voltage generator shown in
As shown in
For example, such an implementation is very favorable for the Always On Display (AOD) mode. In the AOD mode, only a small portion of screen displays an AOD image, and when data are written into the pixels in the remaining region displaying no image, it may be considered that there is no change in the two pieces of display data for two adjacent pixels on the same column in the region, so the plurality of dynamic buffers keep operating in the first mode during these scanning cycles corresponding to these pixels in the region, which can save the overall power consumption.
Therefore, the dynamic buffers may operate in the second mode to output the buffer voltages only when the display data changes, which saves overall power consumption; because with respect to a case where the display data does not change (e.g., for large-area black images), the dynamic buffers operate in the first mode without outputting the buffer voltages.
In addition, in some cases, even if the display data changes, the plurality of gamma voltages output by the gamma voltage generator may be less affected, and it may not be necessary to settle and stabilize the plurality of gamma voltages again. In these cases, it may be determined whether the plurality of dynamic buffers need to operate in the second mode according to a difference between actual values and expected values of some gamma voltages. For example, since the gamma reference voltage circuit is capable of supplying accurate voltage values (expected values) at the input ends of the plurality of buffers, at least a part of dynamic buffers among the plurality of dynamic buffers may be configured to switch to operate in the second mode, in response to a voltage at an input end of any one dynamic buffer being different from a voltage at a connected second voltage input end node IN2 (which is also an output actual gamma voltage at a voltage output end node), and switch to operate in the first mode after a predetermined period, or in response to voltages at the input ends of these dynamic buffers are the same as the voltages at the plurality of second voltage input end nodes IN2.
In addition, in other implementations, in order to more easily control mode switching of the plurality of dynamic buffers, the plurality of dynamic buffers may be made switch from the first mode to the second mode according to the update of the display data, that is to say, as long as the display data is updated, even if it does not change, the plurality of dynamic buffers (or a part thereof) may also perform mode switching. The update of the display data is synchronized with the shift of the Horizontal synchronization signal (Hsync) or the scan signal, that is, the update cycle of the display data is the same as the scanning cycle.
As shown in
In this case, since the update of the display data is synchronized with the shift of the Horizontal synchronization signal (Hsync) or the scan signal, mode switching of the plurality of dynamic buffers may be controlled according to the Horizontal synchronization signal (Hsync) or the scan signal.
In this embodiment, switching from the first mode (the standby mode) to the second mode (the boost mode) is completed before the update time of the display data, to settle and stabilize the required gamma voltages in advance. It should be noted that since the update of the display data may involve the change of values of the display data, and then cause transition of data voltages, and the transition of data voltages may have great impact on the plurality of gamma voltages, the predetermined duration of the second mode preferably overlaps with the time for the transition of data voltages corresponding to the update or change of the display data, that is, the predetermined duration of the second mode lasts at least until completion of the transition of data voltages.
In the embodiment shown in
Hereinafter, several exemplary structures of the dynamic buffer will be introduced in conjunction with
In some implementation modes, each dynamic buffer includes a buffer and a switching module. Components included in the same dynamic buffer can be regarded as corresponding to each other. Each switching module is configured to forbid a corresponding buffer from outputting a buffer voltage in the first mode and allow a corresponding buffer to output a buffer voltage in the second mode.
Optionally, the buffer included in the dynamic buffer may have a same structure as a general buffer, and also have a same structure as a basic buffer, for example, it is composed of an operational amplifier, but is not limited thereto.
In
In
In
In addition, as described above, in a case where the dynamic buffer may switch from the first mode to the second mode in response to a voltage of an input end of any dynamic buffer being different from a voltage at a second voltage input end node that the dynamic buffer is connected to (i.e., at a voltage output end node), the dynamic buffer may further include a voltage difference detecting module in addition to the buffer (e.g., the operational amplifier) and the switching module. Optionally, the voltage difference detecting module may include a comparator.
As shown in
Each switching module is configured to allow in the second mode or forbid in the first mode, an output end of its corresponding operational amplifier to output the buffer voltage to the second voltage input end node that the corresponding dynamic buffer is connected to, based on the switching control signal of the corresponding voltage difference detecting module or a switching control signal of another voltage difference detecting module.
For example, if a voltage difference detecting module in any one or more dynamic buffers detects that input voltages of two input ends of the voltage difference detecting module are different, for example, a voltage difference exceeds a predetermined threshold (0 or other value), it indicates that the plurality of gamma voltages generated by the gamma voltage generating circuit may be inaccurate, and at this time, it is necessary to settle and stabilize gamma voltages again; and therefore, the voltage difference detecting module may output a switching control signal, so as to control these dynamic buffers or some of these dynamic buffers to jointly operate in the second mode, to settle and stabilize the gamma voltages again.
In
In this way, the voltage difference detecting module controls mode switching of the dynamic buffer by detecting a difference between the actual gamma voltages and the expected gamma voltages. Therefore, a duration of the second mode (e.g., ON time of the switch SW in
Optionally, although a structure of each dynamic buffer in each source driver circuit is the same in many situations, it is not required so in other situations, as long as these dynamic buffers are capable of performing mode switching synchronously. For example, it is not necessary for all the dynamic buffer to include the voltage difference detecting module; but some dynamic buffers may adopt the structure as described in
The gamma voltage generator as described above with reference to
The above-described embodiments of introducing the dynamic buffers may be considered as increasing the driving capability of the gamma voltages output by the gamma voltage generating circuit, which may also be implemented equivalently by reducing the resistance of the resistor string in other embodiments of the gamma voltage generating circuit including the resistor string.
As shown in
The gamma voltage generating circuit 1210 has a plurality of voltage input end nodes IN and a plurality of voltage output end nodes O. The plurality of voltage output end nodes are used for outputting a predetermined number of gamma voltages based on input voltages from the plurality of voltage input end nodes IN. In some embodiments where the gamma voltage generating circuit is a gamma resistor string (which includes a plurality of resistor units connected in series according to this embodiment), each voltage input end node may be connected to a corresponding voltage output end node, and each voltage input end node and its corresponding voltage output end node may be a same end node, for example, may be a connection node between adjacent resistor units in the gamma resistor string.
The plurality of buffers 1220 (1220-1, 1220-2, . . . , 1220-N) are respectively electrically connected to the plurality of voltage input end nodes IN. In this way, in a case where the gamma voltage generator 1200 is not connected with other gamma voltage generators, or the gamma voltage generator 1200 needs to output buffer voltages to other gamma voltage generators (e.g., the gamma voltage generator 1200 serves as a master circuit in a case of more than two source driver circuits as described later), the gamma voltage generator 1200 may output a plurality of gamma voltages at the plurality of voltage output end nodes O based on buffer voltages of the plurality of buffers. Moreover, in a case where the gamma voltage generator 1200 is connected with other gamma voltage generators and does not need to output buffer voltages to other gamma voltage generators (e.g., the gamma voltage generator 1200 serves as a slave circuit in a case of more than two source driver circuits as described later), the plurality of buffers may not be turned on or only two buffers that supply the maximum reference voltage and the minimum reference voltage may be turned on.
In order to improve the driving capability of the gamma voltages, the gamma voltage generating circuit includes a plurality of resistor units RVA connected in series, and a connection node of adjacent resistor units RVA is connected to or taken as a voltage output end node. Each resistor unit is configured to have a first resistance in the first mode, have a second resistance in the second mode, and the second resistance is less than the first resistance. The diagram schematically shows a combination of multiple resistor units RVA with a resistor symbol RS. The number of resistor units RVA connected in series represented by each resistor symbol RS may be determined according to the number of gamma voltages that need to be output and not limited to the shown quantity.
In this way, a first time length required for the gamma voltage generating circuit to output the predetermined number of gamma voltages when each resistor unit RVA has the first resistance is greater than a second time length required for the gamma voltage generating circuit to output the predetermined number of gamma voltages when each resistor unit RVA has the second resistance.
Corresponding to the first mode and the second mode of the foregoing dynamic buffer, with respect to the resistor unit according to this embodiment, the first mode is also the standby mode, and the second mode is the boost mode. For example, when it is necessary to settle and stabilize the gamma voltages output by the gamma voltage generator again, the resistor units operate in the boost mode, and after the gamma voltages output by the gamma voltage generator are settled and stabilized, that is, it is not necessary to settle and stabilize the gamma voltages any more, the resistor units operate in the standby mode.
In this way, in the boost mode (the second mode), each resistor unit RVA in the gamma voltage generating circuit may be configured to have a smaller resistance, so that more current may rapidly flow through the plurality of resistor units connected in series, to rapidly settle and stabilize the gamma voltages. In the standby mode (the first mode), each resistor unit RVA may be configured to have a greater resistance, thereby reducing overall power consumption.
Optionally,
As shown in
Optionally, similar to the contents as described above with reference to
For example, when the display data input to the plurality of channel circuits is updated, the plurality of resistor units connected in series may switch to operate in the second mode to rapidly settle and stabilize the gamma voltages again, and the plurality of resistor units connected in series may return to operate in the first mode after a predetermined period.
Alternately, as described above, the display data input to the plurality of channel circuits is periodically updated (e.g., based on the horizontal synchronization signal Hsync or the scan signal), so at a time point with a predetermined time length prior to a start point of each update cycle, the plurality of resistor units connected in series may switch to operate in the second mode to rapidly settle and stabilize the gamma voltages again, and the plurality of resistor units connected in series return to operate in the first mode after a predetermined period.
Alternately, as described above, when the display data input to the plurality of channel circuits changes, the plurality of resistor units switch to operate in the second mode, and after a predetermined period, the plurality of resistor units return to operate in the first mode. In this way, overall power consumption may be further reduced. In some embodiments, a processor inside the source driver may determine change of the display data.
Therefore, in the gamma voltage generator as described with reference to
According to some other embodiments, the plurality of dynamic buffers and the plurality of resistor units having a variable resistance as described above may be jointly combined into a same gamma voltage generator. For example, as shown in
Therefore, in the second mode, the plurality of dynamic buffers, together with the basic buffers, may be connected to the gamma voltage generating circuit 1210 (including a plurality of resistor units connected in series), meanwhile, the plurality of resistor units included in the gamma voltage generating circuit 1210 may have a relatively small resistance (e.g., the bypass switches are turned on). In this way, the solution of combining the dynamic buffers and the resistor units having a variable resistance may further reduce time for settling and stabilizing the gamma voltages, and improve driving capability of the gamma voltages output by gamma voltage generator. Such an implementation may allow the display apparatus to operate at an ultra-high frame rate.
According to another aspect of the present disclosure, there is provided a source driver, and the source driver may include one gamma voltage generator as described above (e.g., referring to
In addition, in some other application scenarios, for example, for folding mobile phones equipped with a flexible display screen, the display screen has an increasing size, so the source driver may include more than two source driver circuits (each including a gamma voltage generator) to drive a same display panel, for example, as shown in
When the source driver may include more than two source driver circuits, a gamma voltage generator in at least one of the source drivers may adopt the structure of the gamma voltage generator as described with reference to
For example, in the solution based on the dynamic buffers, as shown in
At least one of the gamma voltage generator 1400-1 (the first gamma voltage generator) included in the first source driver circuit (IC1) and the second gamma voltage generator 1400-2 included in the second source driver circuit (IC2) may adopt the structure of the gamma voltage generator 400 as described with reference to
Therefore, as an example, when the first gamma voltage generator 1400-1 and the second gamma voltage generator 1400-2 both adopt the structure of the gamma voltage generator as described with reference to
The structure of the second gamma voltage generator 1400-2 is also the same as that of the first gamma voltage generator 1400-1, and includes: a second gamma voltage generating circuit 1412, a plurality of basic buffers (i.e., a second set of basic buffers) and a plurality of dynamic buffers (i.e., a second set of dynamic buffers). Wherein, the second gamma voltage generating circuit 1412 has a second set of first voltage input end nodes, a second set of second voltage input end nodes, and a second set of voltage output end nodes. The second set of basic buffers have input ends respectively receive corresponding gamma reference voltages, and have output ends respectively connected to the second set of first voltage input end nodes. The second set of dynamic buffers have input ends respectively receive corresponding gamma reference voltages, and have output ends respectively connected to the second set of second voltage input end nodes, and are configured to operate in the first mode or the second mode synchronously with the plurality of dynamic buffers in the first gamma voltage generator 1400-1. It should be noted that the expression of the “second set” of certain elements in present application is used to distinguish it from the expression of the plurality of corresponding elements (i.e., regarded as the “first set” of certain elements) included in the first gamma voltage generating circuit 1411.
The second set of first voltage input end nodes of the second gamma voltage generating circuit 1412 included in the second gamma voltage generator 1400-2 receive the first group of buffer voltages from the first gamma voltage generator 1400-1; the second set of dynamic buffers output the second group of buffer voltages to the second set of second voltage input end nodes in the second mode, and do not output the second group of buffer voltages in the first mode; and the second gamma voltage generating circuit 1412 outputs the second predetermined number of gamma voltages at the second set of voltage output end nodes of the second gamma voltage generator 1400-2, based on the first group of buffer voltages and the second group of buffer voltages (in the second mode) or based on the first group of buffer voltages (in the first mode).
That is to say, in a case where it is necessary to settle and stabilize the gamma voltages again, (all or some (which is set according to system requirements) of) the dynamic buffers in the first gamma voltage generator 1400-1 and the second gamma voltage generator 1400-2 operate in the second mode, to output the buffer voltages. The first group of buffer voltages output by the basic buffers of the first gamma voltage generator 1400-1 are supplied to the second gamma voltage generator 1400-2, so that the second gamma voltage generator 1400-2 may generate gamma voltages based on the second group of buffer voltages output by the dynamic buffers included by itself and the first group of buffer voltages from the first gamma voltage generator 1400-1, and thus the second gamma voltage generator 1400-2 may speed up the settlement and stabilization of the gamma voltages to a certain extent, as compared with the case where only the first group of buffer voltages from the first gamma voltage generator 1400-1 are taken as basis, so the two source driver circuits may be close in terms of settlement and stabilization time of gamma voltages, which may reduce a display chromatic difference, and improve a display effect.
For another example, in the solution based on the resistor units having a variable resistance, at least one of the gamma voltage generator 1500-1 (the first gamma voltage generator) included in the first source driver circuit (IC1) and the second gamma voltage generator 1500-2 included in the second source driver (IC2) may adopt the structure of the gamma voltage generator 201 as described with reference to
Similarly, as described above, the first gamma voltage generator 1500-1 and the second gamma voltage generator 1500-2 may adopt the same structure of gamma voltage generator out of consideration of display effect, production costs, and design complexity.
Therefore, as an example, when the first gamma voltage generator 1500-1 and the second gamma voltage generator 1500-2 both adopt the structure of the gamma voltage generator as described with reference to
The second gamma voltage generator 1500-2 has a same structure as that of the first gamma voltage generator 1500-1, and includes: a second gamma voltage generating circuit, and a second set of buffers, wherein, the second gamma voltage generating circuit has a second set of voltage input end nodes and a second set of voltage output end nodes. The second set of buffers have input ends respectively receive corresponding gamma reference voltages, and have output ends respectively connected to the second set of first voltage input end nodes. The second set of voltage input end nodes receive the buffer voltages from the first gamma voltage generator 1500-1. The second gamma voltage generating circuit 1500-2 includes a second set of resistor units connected in series, and a connection node of adjacent resistor units is connected to or taken as a voltage output end node. Each resistor unit of the second set of resistor units is configured to switch between the first mode and the second mode synchronously with the resistor units in the first gamma voltage generator 1500-1.
That is to say, in a case where it is necessary to settle and stabilize the gamma voltages again, the resistor units in the second gamma voltage generator 1500-2 operate in the second mode, to generate the gamma voltages based on the buffer voltages from the first gamma voltage generator 1500-1 in a case of the resistor units having a smaller resistance, so that the second gamma voltage generator 1500-2 may speed up the settlement and stabilization of the gamma voltages to a certain extent, as compared with a case where the resistor units having a variable resistance are not provided, so the two source driver circuits may be close in terms of settlement and stabilization time of gamma voltages, which may reduce a display chromatic difference, make display more uniform, and improve a display effect.
In addition, it should be noted that although it is exemplarily described in
In addition, if a gamma voltage generator inside each source driver circuit is fast enough to settle and stabilize gamma voltages, the difference in time between the gamma voltage generators of the source driver circuits to settle and stabilize the gamma voltages is also small, and may be regarded as consistent. Therefore, when the source driver may include at least two source driver circuits, each source driver circuit may randomly adopt any one of the solution based on dynamic buffers (e.g.,
It should be understood that the source driver may further include other circuit; and the other circuit is configured to cooperate with the gamma voltage generator of each source driver circuit in the source driver to generate gamma voltages and drive the display panel. Those skilled in the art will understand the structure and operation of other circuit as shown in
Those skilled in the art will understand that various modifications and changes may be made to the structure of the disclosed embodiments without departing from the scope or spirit of the present disclosure. In view of the foregoing contents, it is hoped that the present disclosure will cover modifications and changes to the present disclosure within the scope of the appended claims and equivalents thereof.
Number | Date | Country | Kind |
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202310272342.8 | Mar 2023 | CN | national |
112111675 | Mar 2023 | CN | national |
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63325152 | Mar 2022 | US |