JP2007206531A - Display driving device and display device with same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To suppress occurrence of horizontal tailing caused by fluctuation in a power supply voltage during sampling operation and to improve display quality. <P>SOLUTION: A display driving device includes a data register 12 to fetch display data and an output unit comprising a data latch 14, a multiplexer 16, a digital-analog converter (DAC) 18, a buffer amplifier 20 and a demultiplexer 22 so as to output pixel data based on the display data fetched by the data register 12, and controls in such a manner that in one horizontal scanning period, the fetching operation of display data by the data register 12 does not overlap the output operation of pixel data by the output unit. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a display driving device for driving a display panel corresponding to an active matrix driving method, and a display device including such a display panel and a display driving device.

  In recent years, as a display device (display) for displaying images, character information, etc. in imaging devices such as digital video cameras and digital still cameras, which are remarkably popular, and portable devices such as mobile phones and personal digital assistants (PDAs), Liquid crystal displays (LCDs) that are thin, lightweight, low power consumption, and have excellent display image quality as monitors and displays for information devices such as computers and video equipment such as televisions. Is frequently used.

  Hereinafter, a conventional display device will be briefly described with reference to FIGS. FIG. 5A is a block diagram showing a schematic configuration of a display device having a thin film transistor (TFT) type display pixel in the prior art, and FIG. 5B is a main configuration of a liquid crystal display panel in the prior art. It is an equivalent circuit diagram which shows an example.

  As shown in FIGS. 5A and 5B, a liquid crystal display device 100P according to the prior art is roughly a liquid crystal display panel (display) in which display pixels Px are two-dimensionally arranged (for example, arranged in n rows × m columns). Panel) 110P, a gate driver (scan driver) 120P that sequentially scans the display pixel Px group in each row of the liquid crystal display panel 110P and sets the selected state, and a display pixel Px group in the selected row. Source drivers (data drivers) 130P that collectively output display signal voltages based on video signals, and control signals (horizontal control signals, vertical control signals, etc.) for controlling operation timing in the gate drivers 120P and the source drivers 130P Generate and output LCD controller 150P and various timing signals (horizontal synchronization signal, vertical synchronization signal, control signal from video signal) A display signal generation circuit 160P that generates display data including luminance signals and outputs the display data to the source driver 130P, and a polarity inversion signal generated by the LCD controller 150P. A common signal driving amplifier (driving amplifier) 170P for applying a common signal voltage Vcom having a predetermined voltage polarity to the counter electrode provided in common to each display pixel Px of the liquid crystal display panel 110P based on FRP; It is comprised.

  Here, the liquid crystal display panel 110P includes, for example, a plurality of scanning lines SL and a plurality of data lines DL arranged between the opposing transparent substrates so as to be orthogonal to each other in the matrix direction, as shown in FIG. 5B, for example. And a plurality of display pixels (liquid crystal display pixels) Px arranged in the vicinity of each intersection of the scanning line SL and the data line DL. Each display pixel Px includes a pixel transistor TFT composed of a thin film transistor having a source-drain (current path) connected between the pixel electrode and the data line DL, and a gate (control terminal) connected to the scan line SL, and a pixel electrode. And a pixel capacitor (liquid crystal capacitor) Clc composed of liquid crystal molecules filled and held between the counter electrode and the pixel electrode provided in common to all display pixels Px, and a pixel capacitor Clc. And an auxiliary capacitor (storage capacitor) Cs for holding the signal voltage applied to the pixel capacitor Clc.

  Note that the scanning line SL and the data line DL provided on the liquid crystal display panel 110P are connected to the gate driver 120P and the source driver 130P provided separately from the liquid crystal display panel 110P via the connection terminals TMg and TMs, respectively. Configured to be connected. Further, an electrode (auxiliary electrode) on the other end side of the auxiliary capacitor Cs is configured to be applied with a predetermined voltage Vcs (for example, a common signal voltage Vcom) via a common connection line CL.

  In the liquid crystal display device 100P having such a configuration, display data corresponding to display pixels for one row of the liquid crystal display panel 110P supplied from the display signal generation circuit 160P is supplied from the LCD controller 150P. Are sequentially captured and held by the source driver 130P. On the other hand, based on a vertical control signal supplied from the LCD controller 150P, a scanning signal is sequentially applied to each scanning line SL disposed on the liquid crystal display panel 110P by the gate driver 120P, and the display pixels Px group in each row are selected. Set to The source driver 130P supplies the display signal voltages based on the held display data to the display pixels Px simultaneously through the data lines DL in synchronization with the selection timing of the display pixels Px group in each row. By repeating such a series of operations for each row for one screen, desired image information based on the video signal is displayed on the liquid crystal display panel 110P.

In such a liquid crystal display device, in recent years, high definition of the liquid crystal display panel 110P has been achieved in order to improve display image quality. In order to suppress the increase in the circuit scale and power consumption of the source driver 130P due to this higher definition, for example, as disclosed in Patent Document 1, each data line DL is divided into, for example, RGB, A configuration for time-division driving is known. In such a source driver 130P, normally, the operation of taking display data from the display signal generation circuit 160P (sampling) and the operation of supplying the display signal voltage to each data line DL of the liquid crystal display panel 110P are performed in parallel. Has been done.
JP 2005-227513 A

  In the source driver 130P as described above, the power supply voltage may vary depending on the operating current during the sampling operation. In this case, if the configuration is such that the sampling operation and the display signal voltage supply operation are performed simultaneously in parallel as disclosed in Patent Document 1, the output voltage level of the display signal is caused by such a fluctuation in the power supply voltage. May fluctuate. As a result, a horizontal line called tailing may occur on the screen.

  Here, a case will be described in which a plurality of source drivers as described above are provided and the liquid crystal display panel 110P is time-division driven by applying a conventional driving method to each source driver.

  FIG. 6 is a diagram showing the timing of the data fetching operation and the driving operation of each source driver when the display panel is time-division driven by applying the conventional driving method as it is to each source driver. FIG. 7 is a diagram illustrating the timing of the data fetching operation and the driving operation of each source driver when the driving operation timing of each source driver is controlled in common and the time division driving is performed.

  As shown in FIG. 6, when the configuration of time-division driving in the case of one source driver as disclosed in Patent Document 1 is applied as it is, a plurality of display data supply periods in one horizontal scanning period are displayed. Each of the source drivers simultaneously takes in the RGB display data and supplies the display signal voltage. For this reason, the horizontal tailing as described above occurs due to the fluctuation of the output voltage level of the display signal due to the fluctuation of the power supply voltage during the sampling operation.

  Therefore, as shown in FIG. 7, when the output timing of the display signal voltage of each source driver is controlled in common, the sampling operation and the output period can be partially shifted. However, since the period during which the display data is captured and the display signal voltage is supplied in parallel remains in part, the horizontal tailing on the screen still remains in part.

  The present invention has been made in view of the above points, and a display driving device capable of improving the display quality by suppressing the occurrence of horizontal tailing caused by fluctuations in the power supply voltage during the sampling operation, and the same An object of the present invention is to provide a display device including

  One aspect of the display driving device of the present invention is a display driving device for driving a display panel having a plurality of display pixels arranged in a matrix in the vicinity of intersections of a plurality of scanning lines and a plurality of signal lines. Data capturing means for capturing a plurality of display data corresponding to the plurality of display pixels, and output means for outputting display signal voltages based on the plurality of display data captured by the data capturing means to the plurality of signal lines; Control means for controlling such that the period during which the plurality of display data is fetched into the data fetching means and the period during which the display signal voltage is output from the output means are different from each other. It is characterized by.

  One embodiment of the display device according to the present invention includes a display panel in which a plurality of display pixels are arranged in a matrix in the vicinity of intersections of a plurality of scanning lines and a plurality of signal lines, and at least the plurality of the display panels. A display comprising: data fetching means for fetching a plurality of display data corresponding to display pixels; and output means for outputting display signal voltages based on the plurality of display data fetched by the data fetching means to the plurality of signal lines. A driving device, a period for performing the operation of capturing the plurality of display data to the data capturing unit in the display driving device in one horizontal scanning period, and a period for performing the operation of outputting the display signal voltage from the output unit. And a control means for controlling the timings to be different from each other.

  According to the present invention, in a display driving device for driving a display panel and a display device having the display panel, a period during which display data is fetched into the data fetching means and an output operation of the display signal voltage from the output means to the signal line The display drive voltage does not overlap with each other and the timing is different, so even if the power supply voltage of the display drive device fluctuates during the display data capture operation, it affects the voltage level of the display signal voltage. There is no. Accordingly, there is provided a display driving device capable of improving the display quality without causing a horizontal line called tailing due to fluctuations in power supply voltage on the screen, and a display device including the display driving device. Can do.

  The best mode for carrying out the present invention will be described below with reference to the drawings.

  FIG. 1A is a schematic configuration diagram illustrating an overall configuration of a display device to which a display driving device according to an embodiment of the present invention is applied, and FIG. 1B illustrates a main configuration of the display device. FIG. Here, a liquid crystal display device using an active matrix liquid crystal display panel will be described as the display device. 1 (A) and 1 (B), the same reference numerals are given to the same constituent elements as those in the prior art shown in FIGS. 5 (A) and 5 (B), and the description thereof will be simplified. In the present embodiment, the configuration includes four source drivers as described below. However, the present invention is not limited to this and may include other numbers of source drivers.

  As shown in FIGS. 1A and 1B, the display device 100 according to the present embodiment is roughly similar to the above-described conventional technique (see FIG. 5A), and includes a plurality of scanning lines SL and a plurality of scanning lines SL. A scanning signal is sequentially applied to the liquid crystal display panel 110 in which a plurality of display pixels Px are arranged two-dimensionally (n rows × m columns) in the vicinity of the intersection of the data lines (signal lines) DL and each scanning line SL at a predetermined timing. Gate driver 120, first to fourth source drivers 131 to 134 for applying display signal voltages based on display data to each data line DL, and control to be supplied to at least gate driver 120 and source drivers 131 to 134, respectively. LCD controller 150 that generates and outputs signals (vertical control signal, horizontal control signal), and source driver 131 from an externally input video signal A display signal generation circuit 160 that generates display data to be supplied to 134 and a timing signal to be supplied to the LCD controller 150, and a common electrode provided in common to all the display pixels Px have a predetermined voltage polarity. And a common voltage driving amplifier 170 that applies a common signal voltage Vcom having the same. Note that the above-described liquid crystal display panel 110 has a configuration equivalent to the configuration shown in the prior art (the liquid crystal display panel 110P shown in FIG. 5B), and thus detailed description thereof is omitted. Here, the liquid crystal display panel 110 has, for example, 1920 data lines DL, and the source drivers 131 to 134 drive 480 data lines in the display panel, respectively, and the source drivers 131 to 134 use the liquid crystal display panel. 110 (480 × 4 =) 1920 data lines DL are driven.

  FIG. 2 is a diagram showing a configuration of one source driver in the display driving apparatus of the present embodiment, and FIG. 3 shows timings of data fetching operation and driving operation of each source driver in the display driving apparatus of the present embodiment. FIG. In the following description, the source drivers 131 to 134 drive 480 data lines in the display panel, and the display data is composed of 6-bit digital signals. This is an example. Needless to say, this configuration is not restrictive. Each source driver 131 to 134 has a configuration in which the data line is divided into three and time-division driven in the same manner as the configuration shown in the prior art. However, the present invention is not limited to this and is not limited to this. Time division driving may be performed with division or other division numbers of four or more divisions.

  Each of the source drivers 131 to 134 in the display driving device includes a shift register 10, a data register 12, a data latch 14, a multiplexer 16, 160 digital-analog converters (DAC) 18, 160 buffer amplifiers 20, and a demultiplexer. It consists of a multiplexer 22.

  The shift register 10 is a 160-bit shift register, and is supplied with a start signal STH and a clock signal CLK from the outside. The shift register 10 is configured to shift the input start signal STH by 1 bit every clock and to sequentially supply output signals to the data register 12.

  The data register (data capturing means, data capturing unit) 12 is a data register having a 6-bit × 480 set configuration, and display data of a plurality of systems, for example, a red component (R), a green component (G), which constitutes image information, Display data Rdata (D00 to D05), Gdata (D10 to D15), and Bdata (D20 to D25) of 6 bits (64 gradations) of three systems each including the blue component (B) are supplied in parallel from the outside. . The data register 12 is configured to fetch sixty-bit display data Rdata, Gdata, and Bdata in parallel in 160 sets in accordance with the output timing of the shift register 10, respectively.

  The data latch (data holding unit) 14 is a 6-bit × 480-set data latch, and is supplied with a latch control signal STB from the outside. The data latch 14 simultaneously latches and outputs the contents of the data register 12, that is, the display data fetched in the previous horizontal scanning period, at the falling edge of the latch control signal STB.

  The multiplexer (first switch means) 16 is for converting parallel data into serial data, and is supplied with multiplexer control signals APnR, APnG, APnB from the outside. The multiplexer 16 is a system of serial data in which the 6-bit display data Rdata, Gdata, and Bdata held in the data latch 14 are time-divisionally arranged based on multiplexer control signals APnR, APnG, and APnB. (Pixel data).

  A DAC 18 is provided for each output of the multiplexer 16. The predetermined 64 levels of voltages V1, V2,..., V64 are supplied, and the pixel data (R, G, B) output from the multiplexer 16 is converted into analog signals having voltage levels corresponding to the values. Convert to

  The buffer amplifier 20 is provided corresponding to each DAC 18 and amplifies an analog signal analog-converted by the DAC 18 to a predetermined signal level and outputs it as a display signal voltage. Here, the DAC 18 and the buffer amplifier 20 constitute display signal voltage generation means in the present invention.

  The demultiplexer (second switch means) 22 is connected in parallel to the output terminal of the buffer amplifier 20, and is connected to, for example, display pixels corresponding to RGB colors of the display panel (in units of three). Each of the output terminals Y1 to Y3, Y4 to Y6,..., Y478 to Y480 has a configuration including a switching element. Each switching element is ON / OFF controlled according to the above-described multiplexer control signals APnR, APnG, APnB. Thus, the display signal voltage amplified by the buffer amplifier 20 is supplied to the corresponding data line for each of RGB. Here, the multiplexer 16, the DAC 18, and the demultiplexer 22 constitute an output unit and an output unit in the present invention.

  The display data Rdata (D00 to D05), Gdata (D10 to D15), and Bdata (D20 to D25) supplied to the data register 12 are continuous for each horizontal scanning period. However, there is a period during which invalid data is applied. This is the so-called blanking period.

  Next, the operation of the first source driver 131 in the display driving device having the above structure will be described with reference to a timing chart in FIG.

  That is, the latch control signal STB is input in accordance with the start timing of one horizontal scanning period (1H), and accordingly, the data latch 14 is captured in the data register 12 and is captured in the previous horizontal scanning period. Latch display data. Accordingly, the display data latched in the data latch 14 by the latch control signal STB is the display data of the previous horizontal scanning period. Then, after the blanking period, the start signal STH is input in accordance with the timing at which valid data is applied ((valid) display data supply period), from which the shift register 10 operates, and the data register 12 is supplied accordingly. Display data is taken in sequentially.

  The display data latched by the data latch 14 is output from the output terminals Y1 to Y480 as follows in accordance with the multiplexer control signals APnB, APnG, APnB.

  That is, as shown in FIG. 3, during the operation of fetching display data into the data register 12 (for 160 clocks), the multiplexer control signals APnR, APnG, APnB (in this case, the first source driver, AP1R, AP1G , AP1B) is not output (low level). Therefore, the output terminals Y1 to Y480 are high impedance (HiZ).

  After the capturing operation is completed, the multiplexer control signal AP1R is input (becomes high level), so that the multiplexer 16 supplies 160 R pixel data among the display data latched by the data latch 14 to the DAC 18. Are converted into analog signals, amplified by the buffer amplifiers 20 and supplied to the demultiplexer 22. At this time, since the demultiplexer 22 also contains the multiplexer control signal AP1R, the corresponding switching element is turned on, and the output terminals Y1, Y4,..., Y478 corresponding to the data line of the R pixel of the display panel are turned on. A display signal voltage corresponding to the R pixel data is output.

  Thus, for example, after outputting R pixel data for 160 clocks, the multiplexer control signal AP1R is switched to the multiplexer control signal AP1G (the multiplexer control signal AP1G becomes high level). Then, the multiplexer 16 supplies 160 G pixel data among the display data latched by the data latch 14 to the DAC 18 and converts it into analog signals, which are amplified by the buffer amplifiers 20 to be supplied to the demultiplexer 22. Supply. At this time, since the demultiplexer 22 also contains the multiplexer control signal AP1G, the corresponding switching element is turned on, and the output terminals Y2, Y5,..., Y479 corresponding to the data lines of the G pixels of the display panel are turned on. A display signal voltage corresponding to the G pixel data is output.

  Then, after outputting G pixel data for 160 clocks, the multiplexer control signal AP1G is switched to the multiplexer control signal AP1B (the multiplexer control signal AP1B becomes high level). Then, the multiplexer 16 supplies 160 B pixel data of the display data latched by the data latch 14 to the DAC 18 and converts it into analog signals, which are amplified by the buffer amplifiers 20 and then sent to the demultiplexer 22. Supply. At this time, since the demultiplexer 22 also contains the multiplexer control signal AP1B, the corresponding switching element is turned on, and the output terminals Y3, Y6,..., Y480 corresponding to the data lines of the B pixels of the display panel are turned on. A display signal voltage corresponding to the B pixel data is output.

  In this way, the RGB data is sequentially applied to the DAC 18 via the multiplexer 16 to perform parallel-to-serial conversion, and the output of the DAC 18 is applied to the buffer amplifier 20, and the output of the buffer amplifier 20 is Via the demultiplexer 22, the output terminals Y1 to Y3, Y4 to Y6,..., Y478 to Y480 are sequentially distributed and output in order. That is, serial-to-parallel conversion is performed.

  As described above, in the display driving device according to the present embodiment, the control sequence of the multiplexer control signals APnR, APnG, APnB is changed so that the sampling operation and the output period do not overlap. Even if it fluctuates, it does not affect the output voltage level of the display signal. Therefore, a horizontal line called tailing does not occur on the screen, and display quality can be improved.

  Next, operations of the first to fourth source drivers 131 to 134 in the display device 100 will be described with reference to the timing chart of FIG.

  In this case, the overflow output of the shift register 10 of the first source driver 131 is supplied to the shift register 10 of the second source driver 132 as the start signal STH. Similarly, the overflow output of the shift register 10 of the second source driver 132 is the start signal STH to the shift register 10 of the third source driver 133, and the overflow output of the shift register 10 of the third source driver 133 is the output of the fourth source driver 134. Each is supplied to the shift register 10 as a start signal STH.

  Further, the horizontal control signals from the LCD controller 150 are sent to the source drivers 131 to 134 as the clock signal CLK, the latch control signal STB, the multiplexer control signals APnR, APnG, APnB as shown in FIG. , N = 1 to 4) and 6-bit display data Rdata (D00 to D05), Gdata (D10 to D15), and Bdata (D20 to D25) are supplied as display data from the display signal generation circuit 160. .

  In the display device having such a configuration, the LCD controller 150 is based on the timing signal from the display signal generation circuit 160 at the start timing of one horizontal scanning period (1H) as shown in FIG. In addition, the latch control signal STB is supplied to each of the source drivers 131 to 134. In response, the data latch 14 of each of the first to fourth source drivers 131 to 134 receives the display data captured in the previous horizontal scanning period, which is captured in the data register 12 of each of the source drivers 131 to 134. Latch. Accordingly, the display data latched in the data latch 14 of each of the first to fourth source drivers 131 to 134 by the latch control signal STB is the display data of the previous horizontal scanning period.

  Then, in the (valid) display data supply period after the blanking period, the control of the LCD controller 150 causes the display data to be taken into the source drivers 131 to 134 and the liquid crystal display panel 110 to be Display data is output to each data line. Hereinafter, each operation of the first to fourth source drivers 131 to 134 will be described in more detail.

<Intake period into first source driver 131>
As shown in FIG. 3, the LCD controller 150 matches the timing ((valid) display data supply period) when valid data after the blanking period is applied based on the timing signal from the display signal generation circuit 160. The start signal STH is supplied to the first source driver 131 among the four source drivers 131 to 134. As a result, the shift register 10 of the first source driver 131 operates, and display data from the display signal generation circuit 160 is taken into the data register 12 of the first source driver 131 accordingly.

  The LCD controller 150 does not output the multiplexer control signals AP1R, AP1G, AP1B (low level) during the operation of fetching display data into the data register 12 of the first source driver 131 (for 160 clocks). Accordingly, the output terminals Y1 to Y480 of the first source driver 131 are high impedance (HiZ). On the other hand, during the period, the multiplexer control signal AP2B is supplied to the second source driver 132, the multiplexer control signal AP3G is supplied to the third source driver 133, and the multiplexer control signal AP4R is supplied to the fourth source driver 134. Supply.

  Accordingly, the multiplexer 16 of the second source driver 132 supplies 160 B pixel data among the display data latched in the data latch 14 of the second source driver 132 by the supply of the multiplexer control signal AP2B. The analog signal is supplied to the DAC 18 of the source driver 132, amplified by the buffer amplifier 20 of the second source driver 132, and supplied to the demultiplexer 22 of the second source driver 132. At this time, since the demultiplexer 22 also contains the multiplexer control signal AP2B, the corresponding switching element is turned on to correspond to the data line of the B pixel among the 481st to 960th data lines of the display panel. A display signal voltage corresponding to the B pixel data is output from the output terminals Y3, Y6,..., Y480 of the second source driver 132.

  Further, the multiplexer 16 of the third source driver 133 supplies 160 G pixel data among the display data latched by the data latch 14 of the third source driver 133 by supplying the multiplexer control signal AP3G. The analog signal is supplied to the DAC 18 of the source driver 133, amplified by the buffer amplifier 20 of the third source driver 133, and supplied to the demultiplexer 22 of the third source driver 133. At this time, since the demultiplexer 22 also contains the multiplexer control signal AP3G, the corresponding switching element is turned on and corresponds to the G pixel data line among the 961st to 1440th data lines of the display panel. Display signal voltages corresponding to G pixel data are output from the output terminals Y2, Y5,..., Y479 of the third source driver 133.

  Also, the multiplexer 16 of the fourth source driver 134 supplies 160 R pixel data among the display data latched by the data latch 14 of the fourth source driver 134 by the supply of the multiplexer control signal AP4R. The analog signal is supplied to the DAC 18 of the source driver 134, amplified by the buffer amplifier 20 of the fourth source driver 134, and supplied to the demultiplexer 22 of the fourth source driver 134. At this time, since the demultiplexer 22 also contains the multiplexer control signal AP4R, the corresponding switching element is turned on and corresponds to the R pixel data line among the 141st to 1920th data lines of the display panel. A display signal voltage corresponding to the R pixel data is output from the output terminals Y1, Y4,..., Y478 of the fourth source driver 134.

  In this way, during the operation of fetching display data into the data register 12 of the first source driver 131, the display signal voltage corresponding to the B pixel data from the second source driver 132 corresponds to the G pixel data from the third source driver 133. The display signal voltage corresponding to the R pixel data is output from the fourth source driver 134 to the corresponding data line of the liquid crystal display panel 110.

<Intake period into second source driver 132>
Next, when the operation of fetching display data into the data register 12 of the first source driver 131 is completed, an overflow output is supplied from the shift register 10 of the first source driver 131 to the shift register 10 of the second source driver 132 as a start signal STH. Is done. As a result, the shift register 10 of the second source driver 132 operates, and display data from the display signal generation circuit 160 is taken into the data register 12 of the second source driver 132 accordingly.

  When the operation of fetching display data into the data register 12 of the second source driver 132 is started, the LCD controller 150 switches the output of the multiplexer control signal AP2R supplied to the second source driver 132 to a low level. . Accordingly, during the operation of fetching display data into the data register 12 of the second source driver 132 (for 160 clocks), the multiplexer control signals AP2R, AP2G, AP2B are not output (low level), and the second source driver 132 The output terminals Y1 to Y480 have high impedance (HiZ).

  In contrast, during this period, the first source driver 131 is supplied with the multiplexer control signal AP1R, the third source driver 133 is supplied with the multiplexer control signal AP3B, and the fourth source driver 134 is supplied with the multiplexer control signal AP4G. The multiplexer control signals to the respective source drivers 131, 133, and 134 are switched and output so as to supply.

  Therefore, the multiplexer 16 of the first source driver 131 supplies 160 R pixel data among the display data latched in the data latch 14 of the first source driver 131 by the supply of the multiplexer control signal AP1R. The analog signal is supplied to the DAC 18 of the source driver 132, amplified by the buffer amplifier 20 of the first source driver 131, and supplied to the demultiplexer 22 of the first source driver 131. At this time, since the demultiplexer 22 also contains the multiplexer control signal AP1R, the corresponding switching element is turned on and corresponds to the data line of the R pixel among the first to 480th data lines of the display panel. Display signal voltages corresponding to the R pixel data are output from the output terminals Y1, Y4,..., Y478 of the first source driver 131.

  Further, the multiplexer 16 of the third source driver 133 supplies the 160 B pixel data among the display data latched by the data latch 14 of the third source driver 133 by the supply of the multiplexer control signal AP3B. The analog signal is supplied to the DAC 18 of the source driver 133, amplified by the buffer amplifier 20 of the third source driver 133, and supplied to the demultiplexer 22 of the third source driver 133. At this time, since the demultiplexer 22 also contains the multiplexer control signal AP3B, the corresponding switching element is turned on to correspond to the data line of the B pixel among the 961st to 1440th data lines of the display panel. A display signal voltage corresponding to the B pixel data is output from the output terminals Y3, Y6,..., Y480 of the third source driver 133.

  Also, the multiplexer 16 of the fourth source driver 134 supplies 160 G pixel data among the display data latched by the data latch 14 of the fourth source driver 134 by the supply of the multiplexer control signal AP4G. The analog signal is supplied to the DAC 18 of the source driver 134, amplified by the buffer amplifier 20 of the fourth source driver 134, and supplied to the demultiplexer 22 of the fourth source driver 134. At this time, since the demultiplexer 22 also contains the multiplexer control signal AP4G, the corresponding switching element is turned on to correspond to the G pixel data line among the 1441st to 1920th data lines of the display panel. Display signal voltages corresponding to the G pixel data are output from the output terminals Y2, Y5,..., Y479 of the fourth source driver 134.

  In this way, during the operation of fetching display data into the data register 12 of the second source driver 132, the display signal voltage corresponding to the R pixel data from the first source driver 131 corresponds to the B pixel data from the third source driver 133. A display signal voltage corresponding to the G pixel data is output from the fourth source driver 134 to a corresponding data line of the liquid crystal display panel 110.

<Intake period into third source driver 133>
Next, when the operation of fetching display data into the data register 12 of the second source driver 132 is completed, an overflow output is supplied from the shift register 10 of the second source driver 132 to the shift register 10 of the third source driver 132 as a start signal STH. Is done. As a result, the shift register 10 of the third source driver 133 operates, and accordingly, the display data from the display signal generation circuit 160 is taken into the data register 12 of the third source driver 133.

  When the operation of fetching display data into the data register 12 of the third source driver 133 is started, the LCD controller 150 switches the output of the multiplexer control signal AP3B supplied to the third source driver 133 to a low level. . Therefore, during the operation of fetching display data into the data register 12 of the third source driver 133 (for 160 clocks), the multiplexer control signals AP3R, AP3G, AP3B are not output (low level), and the third source driver 133 The output terminals Y1 to Y480 have high impedance (HiZ).

  In contrast, during that period, the first source driver 131 is supplied with the multiplexer control signal AP1G, the second source driver 132 is supplied with the multiplexer control signal AP2R, and the fourth source driver 134 is supplied with the multiplexer control signal AP4B. The multiplexer control signals to the respective source drivers 131, 132, and 134 are switched and output so as to supply.

  Accordingly, the multiplexer 16 of the first source driver 131 supplies 160 G pixel data among the display data latched by the data latch 14 of the first source driver 131 by supplying the multiplexer control signal AP1G. The analog signal is supplied to the DAC 18 of the source driver 132, amplified by the buffer amplifier 20 of the first source driver 131, and supplied to the demultiplexer 22 of the first source driver 131. At this time, since the demultiplexer 22 also contains the multiplexer control signal AP1G, the corresponding switching element is turned on and corresponds to the G pixel data line among the first to 480th data lines of the display panel. Display signal voltages corresponding to G pixel data are output from the output terminals Y2, Y5,..., Y479 of the first source driver 131.

  In addition, the multiplexer 16 of the second source driver 132 supplies 160 R pixel data among the display data latched by the data latch 14 of the second source driver 132 by supplying the multiplexer control signal AP2R. The analog signal is supplied to the DAC 18 of the source driver 132, amplified by the buffer amplifier 20 of the second source driver 132, and supplied to the demultiplexer 22 of the second source driver 132. At this time, since the demultiplexer 22 also contains the multiplexer control signal AP2R, the corresponding switching element is turned on and corresponds to the R pixel data line among the 481st to 960th data lines of the display panel. A display signal voltage corresponding to the R pixel data is output from the output terminals Y1, Y4,..., Y478 of the second source driver 132.

  Further, the multiplexer 16 of the fourth source driver 134 supplies 160 B pixel data among the display data latched in the data latch 14 of the fourth source driver 134 by the supply of the multiplexer control signal AP4B. The analog signal is supplied to the DAC 18 of the source driver 134, amplified by the buffer amplifier 20 of the fourth source driver 134, and supplied to the demultiplexer 22 of the fourth source driver 134. At this time, since the demultiplexer 22 also contains the multiplexer control signal AP4B, the corresponding switching element is turned on to correspond to the data line of the B pixel among the 1441st to 1920th data lines of the display panel. A display signal voltage corresponding to the B pixel data is output from the output terminals Y3, Y6,..., Y480 of the fourth source driver 134.

  In this way, during the operation of fetching the display data into the data register 12 of the third source driver 133, the display signal voltage corresponding to the G pixel data from the first source driver 131 corresponds to the R pixel data from the second source driver 132. A display signal voltage corresponding to the B pixel data is output from the fourth source driver 134 to a corresponding data line of the liquid crystal display panel 110.

<Upload period to the fourth source driver 134>
When the operation of fetching display data into the data register 12 of the third source driver 133 is completed, an overflow output is supplied from the shift register 10 of the third source driver 133 to the shift register 10 of the fourth source driver 134 as a start signal STH. Is done. As a result, the shift register 10 of the fourth source driver 134 operates, and the display data from the display signal generation circuit 160 is taken into the data register 12 of the fourth source driver 134 accordingly.

  When the operation of capturing display data into the data register 12 of the fourth source driver 134 is started, the LCD controller 150 switches the output of the multiplexer control signal AP4B supplied to the fourth source driver 134 to a low level. . Therefore, during the operation of fetching display data into the data register 12 of the fourth source driver 134 (for 160 clocks), the multiplexer control signals AP4R, AP4G, AP4B are not output (low level), and the fourth source driver 134 The output terminals Y1 to Y480 have high impedance (HiZ).

  In contrast, during this period, the first source driver 131 is supplied with the multiplexer control signal AP1B, the second source driver 132 is supplied with the multiplexer control signal AP2G, and the third source driver 133 is supplied with the multiplexer control signal AP3R. The multiplexer control signals to the respective source drivers 131 to 133 are switched and output so as to supply.

  Accordingly, the multiplexer 16 of the first source driver 131 supplies 160 B pixel data among the display data latched by the data latch 14 of the first source driver 131 by supplying the multiplexer control signal AP1B. The analog signal is supplied to the DAC 18 of the source driver 132, amplified by the buffer amplifier 20 of the first source driver 131, and supplied to the demultiplexer 22 of the first source driver 131. At this time, since the demultiplexer 22 also contains the multiplexer control signal AP1B, the corresponding switching element is turned on and corresponds to the data line of the B pixel among the first to 480th data lines of the display panel. Display signal voltages corresponding to B pixel data are output from the output terminals Y3, Y6,..., Y480 of the first source driver 131.

  In addition, the multiplexer 16 of the second source driver 132 supplies 160 G pixel data among the display data latched by the data latch 14 of the second source driver 132 by the supply of the multiplexer control signal AP2G. The analog signal is supplied to the DAC 18 of the source driver 132, amplified by the buffer amplifier 20 of the second source driver 132, and supplied to the demultiplexer 22 of the second source driver 132. At this time, since the demultiplexer 22 also contains the multiplexer control signal AP2G, the corresponding switching element is turned on and corresponds to the G pixel data line among the 481st to 960th data lines of the display panel. A display signal voltage corresponding to the G pixel data is output from the output terminals Y2, Y5,..., Y479 of the second source driver 132.

  Also, the multiplexer 16 of the third source driver 133 supplies 160 R pixel data among the display data latched in the data latch 14 of the third source driver 133 by the supply of the multiplexer control signal AP3R. The analog signal is supplied to the DAC 18 of the source driver 133, amplified by the buffer amplifier 20 of the third source driver 133, and supplied to the demultiplexer 22 of the third source driver 133. At this time, since the demultiplexer 22 also contains the multiplexer control signal AP3R, the corresponding switching element is turned on to correspond to the R pixel data line among the 961st to 1440th data lines of the display panel. Display signal voltages corresponding to the R pixel data are output from the output terminals Y1, Y4,..., Y478 of the third source driver 133.

  In this way, during the operation of fetching display data into the data register 12 of the fourth source driver 134, the display signal voltage corresponding to the B pixel data from the first source driver 131 corresponds to the G pixel data from the second source driver 132. The display signal voltage corresponding to the R pixel data is output from the third source driver 133 to the corresponding data line of the liquid crystal display panel 110.

  As described above, in the display device according to this embodiment, the control order of the multiplexer control signals APnR, APnG, and APnB is changed so that the sampling operation and the output period of the source drivers 131 to 134 do not overlap. Even if the power supply voltage fluctuates during the sampling operation, it does not affect the output voltage level of the display signal. Therefore, a horizontal line called tailing does not occur on the screen, and display quality can be improved.

  Next, FIG. 4 is a diagram illustrating another example of the timing of the data capturing operation and the driving operation of each source driver in the display device of this embodiment.

  In the above description, the LCD controller 150 individually controls the multiplexer control signals APnR, APnG, and APnB (n = 1 to 4) for the source drivers 131 to 134. As shown in FIG. AP3G and AP4R have the same timing, AP1R and AP3B and AP4G have the same timing, AP1G and AP2R and AP4B have the same timing, and AP1B and AP2G and AP3R have the same timing. Therefore, these signals having the same timing may be supplied in common. In other words, the LCD controller 150 provides the four types of signals shown in FIG. 4 (first signals corresponding to AP2B, AP3G, and AP4R, first signals for AP1R, AP3B, and AP4G as multiplexer control signals to the source drivers 131 to 134. 2 signal, a third signal for AP1G, AP2R, AP4B, a fourth signal for AP1B, AP2G, AP3R) may be output and supplied as a multiplexer control signal corresponding to each source driver 131-134. . According to this, the number of control signal lines output from the LCD controller 150 can be reduced.

  Although the present invention has been described above based on the embodiments, the present invention is not limited to the above-described embodiments, and various modifications and applications are naturally possible within the scope of the gist of the present invention.

  For example, in the above-described embodiment, the display data is input to the data register 12 in parallel with RGB. However, the present invention is not limited to this. That is, display data Rdata, Gdata, Bdata may be input serially.

  In the above embodiment, the output timing of the display signal voltage corresponding to the R, G, and B pixel data from the remaining three source drivers that are not in the display data capturing operation is the source driver that is performing the display data capturing operation. However, the present invention is not limited to this. That is, it is sufficient that the sampling operation and the output period do not overlap in one source driver, and it corresponds to the output timing from other source drivers that are not in the display data capturing operation, and R, G, B pixel data. The output period of the display signal voltage to be set is arbitrarily set.

  In the above embodiment, in the first to fourth source drivers 131 to 134, the display signal voltages corresponding to the pixel data output from the remaining three source drivers that are not in the display data capturing operation are R, G, Although B is set not to overlap, it may be overlapped. That is, any order may be used as long as all display signal voltages corresponding to R, G, and B pixel data are output from each source driver during one horizontal scanning period.

FIG. 1A is a schematic configuration diagram illustrating an entire configuration of a display device according to an embodiment of the present invention, and FIG. 1B is a detailed diagram illustrating a main configuration of the display device. FIG. 2 is a diagram illustrating a configuration of a display driving device according to an embodiment of the present invention. FIG. 3 is a diagram illustrating an example of the timing of the data capturing operation and the driving operation of each source driver in the display device according to the embodiment of the present invention. FIG. 4 is a diagram illustrating another example of the timing of the data capturing operation and the driving operation of each source driver in the display device according to the embodiment of the present invention. FIG. 5A is a block diagram showing a schematic configuration of a display device having a thin film transistor (TFT) type display pixel in the prior art, and FIG. 5B is a main configuration of a liquid crystal display panel in the prior art. It is an equivalent circuit diagram which shows an example. FIG. 6 has a plurality of source drivers, and shows the timing of the data fetching operation and the driving operation of each source driver when the display panel is time-division driven by applying the conventional driving method to each source driver. FIG. FIG. 7 shows a data acquisition operation and a drive operation of each source driver when a plurality of source drivers are provided and the display panel is time-division driven by commonly controlling the drive operation timing of each source driver. It is a figure which shows a timing.

Explanation of symbols

    DESCRIPTION OF SYMBOLS 10 ... Shift register, 12 ... Data register, 14 ... Data latch, 16 ... Multiplexer, 18 ... Digital-analog converter (DAC), 20 ... Buffer amplifier, 22 ... Demultiplexer, 100 ... Display apparatus, 110 ... Liquid crystal display panel 120 ... Gate driver 131-134 Source driver 150 ... LCD controller 160 ... Display signal generation circuit 170 ... Common voltage drive amplifier Rdata, Gdata, Bdata ... Display data, APnR, APnG, APnB, Multiplexer control signal.

Claims (14)

In a display driving device for driving a display panel having a plurality of display pixels arranged in a matrix in the vicinity of intersections of a plurality of scanning lines and a plurality of signal lines,
at least,
Data capturing means for capturing a plurality of display data corresponding to the plurality of display pixels;
Output means for outputting display signal voltages based on the plurality of display data captured by the data capturing means to the plurality of signal lines;
Control means for controlling the period for performing the operation for capturing the plurality of display data to the data capturing means and the period for performing the operation for outputting the display signal voltage from the output means;
A display driving device comprising: The data capturing means includes a plurality of data capturing units that capture the display data corresponding to a predetermined number of signal lines in the plurality of signal lines connected in cascade.
The output means corresponds to each of the plurality of data capture units, and outputs a display signal voltage based on the display data captured by the corresponding data capture unit to the predetermined number of signal lines. The display driving apparatus according to claim 1, wherein: The control means includes
The display data fetching operation in any one specific data fetching unit in the plurality of data fetching units, and the output unit other than the output unit corresponding to the specific data fetching unit in the plurality of output units The display driving device according to claim 2, wherein the display signal voltage is controlled to be performed in parallel with the output operation of the display signal voltage. The control means includes
The control unit is configured to control the output terminal of the output unit corresponding to the data capturing unit to be in a high impedance state during a period in which the display unit captures the plurality of display data. 3. The display driving device according to 2. Each of the plurality of output units is
A data holding unit for holding the display data captured in the corresponding data capturing unit in parallel corresponding to the predetermined number of signal lines;
Display signal voltage generating means for generating the display signal voltage based on the display data held in the data holding unit;
Time-division driving means for dividing the predetermined number of signal lines into a plurality of signal line groups and sequentially applying the display signal voltage to the signal line groups in a time-division manner in one horizontal scanning period;
The display driving apparatus according to claim 2, further comprising: The control means includes
The other than the output unit corresponding to the specific data capturing unit in the plurality of output units and the operation of capturing the plurality of display data in any one specific data capturing unit in the plurality of data capturing units 6. The display signal voltage application operation to at least one of the plurality of signal line groups in the time-division driving unit of the output unit is controlled to be performed in parallel. Display drive device. The time-division driving means is
First switch means for sequentially selecting the display data corresponding to each of the signal line groups in the plurality of display data held in parallel in the data holding unit according to the timing of the time division;
A second one for sequentially supplying the display signal voltage generated by the display signal voltage generating means based on the display data selected by the first switch means to each of the signal line groups in accordance with the time division timing; Switch means;
The display driving apparatus according to claim 5, further comprising: A display panel in which a plurality of display pixels are arranged in a matrix in the vicinity of each intersection of a plurality of scanning lines and a plurality of signal lines;
At least a data capturing unit that captures a plurality of display data corresponding to the plurality of display pixels of the display panel, and a display signal voltage based on the plurality of display data captured by the data capturing unit to the plurality of signal lines. An output means for outputting, a display driving device comprising:
In one horizontal scanning period, the period during which the plurality of display data is fetched into the data fetching means in the display driving device is different from the period during which the display means voltage is outputted from the output means. Control means for controlling
A display device comprising: The plurality of signal lines in the display panel are divided into a plurality of predetermined lines,
The data capturing means in the display driving device includes a plurality of data capturing units that capture the display data corresponding to the predetermined number of signal lines connected in cascade.
The output means corresponds to each of the plurality of data capture units, and outputs a display signal voltage based on the display data captured by the corresponding data capture unit to the predetermined number of signal lines. The display device according to claim 8, further comprising: The control means includes
The display data fetching operation in any one specific data fetching unit in the plurality of data fetching units, and the output unit other than the output unit corresponding to the specific data fetching unit in the plurality of output units The display device according to claim 9, wherein the display signal voltage is controlled to be performed in parallel with the display signal voltage output operation. The control means includes
The control unit is configured to control the output terminal of the output unit corresponding to the data capturing unit to be in a high impedance state during a period in which the display unit captures the plurality of display data. 9. The display device according to 9. Each of the plurality of output units is
A data holding unit for holding the display data captured in the corresponding data capturing unit in parallel corresponding to the predetermined number of signal lines;
Display signal voltage generating means for generating the display signal voltage based on the display data held in the data holding unit;
Time-division driving means for dividing the predetermined number of signal lines into a plurality of signal line groups and sequentially applying the display signal voltage to the signal line groups in a time-division manner in one horizontal scanning period;
The display device according to claim 9, further comprising: The control means includes
The other than the output unit corresponding to the specific data capturing unit in the plurality of output units and the operation of capturing the plurality of display data in any one specific data capturing unit in the plurality of data capturing units 13. The display signal voltage application operation to at least one of the plurality of signal line groups in the time division drive unit of the output unit is controlled to be performed in parallel. Display device. The time-division driving means is
First switch means for sequentially selecting the display data corresponding to each of the signal line groups in the plurality of display data held in parallel in the data holding unit according to the timing of the time division;
A second one for sequentially supplying the display signal voltage generated by the display signal voltage generating means based on the display data selected by the first switch means to each of the signal line groups in accordance with the time division timing; Switch means;
The display device according to claim 12, comprising:

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