JP2005134910A - Driver circuit and method for providing reduced power consumption in driving flat-panel display - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a driver circuit and method for providing reduced power consumption in driving a flat-panel display. <P>SOLUTION: The invention relates to a source driver circuit and a method therefor for providing reduced power consumption in driving data lines of the flat-panel display, and a common voltage driver circuit and a method therefor for providing reduced power consumption in driving a common electrode of the flat-panel display. The source driver circuit and the method therefor for driving the data lines, and the common voltage driver circuit and the method therefor for driving the common electrode do not use only a completely boosted driving voltage to provide electric charge recycle by reducing the power consumption, but use each driving cycle intermediate reference voltage and the boosted driving voltage together. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a circuit and method for driving a flat panel display such as an LCD (Liquid Crystal Display), and more particularly to a source driver circuit and method for driving a data line of a flat panel display, and a common electrode of the flat panel display. The present invention relates to a common voltage driver circuit and method.

  Various types of flat panel displays such as LCDs, plasma display panels (PDP), and electroluminescent display panels have been developed to replace traditional CRT (Cathode Ray Tube). Such flat panel displays are suitable for devices and applications that require small size, light weight, and low power consumption. For example, since the LCD can be driven by a low voltage power source and consumes less power, it can be operated using an LSI (Large Scale Integration) driver. Accordingly, LCDs have been widely adopted in laptop computers, mobile phones, pocket computers, automobiles, color televisions and the like. That is, LCD features such as light weight, small size, and low power consumption allow LCDs to be used with portable devices.

  FIG. 1 is a schematic diagram illustrating a conventional display system. The display system 10 includes a display panel 11 such as an LCD and a plurality of components that drive and control the display panel 11, that is, a source driving IC 12, a gate driving IC 13, and a GRAM (Graphic Random Access Memory). 14 and a power generator 15. The controller 14 generates control signals for controlling the power generator 15, the source driving IC 12, and the gate driving IC 13.

The display panel 11 includes a plurality of data lines D _{1 to} D _n connected to the source driving IC 12 and a plurality of gate lines G 1 to Gm connected to the gate driving IC 13. The display panel 11 includes a plurality of pixels / subpixels arranged in a matrix of rows and columns. Pixels / subpixels arranged in any one row are commonly connected to any one gate line, and pixels / subpixels arranged in any one column are commonly connected to any one data line. . Depending on the application / design, one pixel / subpixel is configured at each intersection of the gate line and the data line.

  If the display panel 11 is a TFT (Thin Film Transistor) -LCD, the display panel 11 includes a TFT board including a plurality of pixels / subpixels arranged in a matrix form. As shown in FIG. 1, each pixel / subpixel unit includes a TFT, a liquid crystal capacitor Cp connected between the drain electrode of the TFT and the common electrode VCOM, and a thin film storage capacitor Cst connected in parallel with the liquid crystal capacitor Cp. including. The storage capacitor Cst stores charge so that the image on the display is maintained during the non-selected period. The liquid crystal capacitor Cp is formed by a common electrode VCOM of the color filter plate, a pixel electrode of the TFT, and a liquid crystal material between the electrodes. The source electrode of the TFT is connected to the data line, and the gate electrode of the TFT is connected to the gate line. The TFT serves as a switch for applying the source voltage on the data line to the pixel electrode when the gate driver signal VGH on the gate line is applied to the gate of the TFT.

  The power generator 15 includes a plurality of reference voltages, that is, a source driver power supply AVDD and a gamma reference voltage GVDD applied to the source driving IC 12, a high common electrode voltage VCOMH applied to the common voltage electrode VCOM of the panel 11, and a low common. An electrode voltage VCOML and a gate driver turn-on voltage VGH and a gate driver turn-off voltage VGOFF applied to the gate driving IC 13 to drive the selected gate line are generated.

  The controller 14 receives a plurality of drive data signals and drive control signals output from an image supply source (for example, a main board of a computer) as inputs. The drive data signal includes R, G, B data forming an image on the display panel 11. The drive control signal includes a vertical synchronization signal Vsync, a horizontal movement signal Hsync, a data enable signal DE, and a clock signal Clk. The controller 14 outputs a plurality of display data signals DDATA and source control signals corresponding to the R, G, and B data to the source driving IC 12. The controller 14 outputs a gate control signal to control the gate driving IC 13. The controller 14 controls the timing at which data and control signals are output from the source driving IC 12 and the gate driving IC 13. For example, in a predetermined operation mode, the controller 14 transmits the gate driver output signal VGH to each of the gate lines G1 to Gm in a continuous manner by the gate driving IC 13, and the data voltage is activated one by one in order. The source and gate control signals are generated so as to be selectively applied to each pixel / sub-pixel arranged in the array. In certain other operating modes, the pixels / subpixels may be charged by sequentially scanning the pixels / subpixels arranged in the first column and then scanning the pixels / subpixels arranged in the next column. .

The gate drive IC 13 includes a plurality of gate drivers that drive the corresponding gate lines G1 to Gm, respectively. Source driving IC 12 is to not a plurality of source driver circuits 12 for driving the corresponding data lines _D 1 to D _n includes a 12-n.

  FIG. 2 schematically shows a conventional source driver circuit 20. The source driver circuit 20 can be applied to the system 10 of FIG. 1 to drive the data lines of the display panel 11. In general, as shown in FIG. 2, the source driver circuit 20 includes a source driver 12-i for driving the corresponding data line Di and a gray scale voltage generator 23. The source driver circuit 20 of FIG. 2 shows the conventional structure of the source driver IC 12 of FIG. 1, where there is one source driver 12-i for each data line (or RGB channel). The output of the gray scale voltage generator 23 is applied in common to the source drivers 12-1 to 12-n of the source driver IC 12.

  In general, the source driver 12-i includes a polarity inversion circuit 21, a latch circuit 22, a gamma decoder 24, and a drive buffer 25. The source driver 12-i is controlled by a plurality of control signals, that is, a polarity control signal M, a latch control signal S_LATCH, a mode control signal GRAY_ON (gradient mode enable signal), and a BIN_ON (binary mode enable signal). The control signal is further described below. The source driver 12-i receives the gray scale reference voltage generated by the gray scale voltage generator 23 as an input.

  Source driver 12-i receives as input an n-bit block of display data DDATA for R, G, or B from GRAM 14. The polarity inversion circuit 21 receives the display data block DDATA and controls the polarity of the n-bit data in response to the polarity control signal M. For example, if the polarity control signal M is logic “0”, the polarity of the display data DDATA is kept the same. That is, the original display data (positive polarity) is maintained. On the other hand, if the polarity control signal M is logic “1”, the polarity of the display data DDATA is inverted to the negative polarity. In the embodiment of FIG. 2, the polarity inversion circuit 21 is implemented using an exclusive OR (ie, XOR) gate.

The latch circuit 22 latches the n-bit data block output from the polarity inversion circuit 21 in response to the latch control signal S_LATCH. In the embodiment of FIG. 2, the latch circuit 22 is implemented using a clocked n-bit latch. The latch circuit 22 outputs the latched display data block CD [n−1: 0] to the gamma decoder 24. The gray scale voltage generator 23 generates 2 ⁿ different gray scale reference voltages VG [2 ⁿ −1: 0] and outputs them to the gamma decoder 24. The gamma decoder 24 decodes the n-bit display data block CD [n−1: 0] output from the latch circuit 22, selects one grayscale voltage, and outputs it to the drive buffer 25. In each pixel (including RGB sub-pixels), the number of gray scales (or other colors) that can be generated for each pixel using an n-bit gray scale structure is 2 ⁿ (R) 2 ⁿ (G) 2 ⁿ (B) = 2 ³ⁿ .

The drive buffer 25 includes a first driver 26, a first driver output switch S 1, and a second driver 27. The first driver 26 buffers and amplifies the gray scale voltage output from the gamma decoder 24. The second driver 27 buffers and amplifies the MSB (Most Significant Bit) CD [n−1] of the latched display data CD [n−1: 0]. The drive buffer 25 generates a source driver output signal Sn for driving the corresponding data line Di. The source driver output signal Sn varies depending on the selected operation mode, that is, the binary mode (8-color mode) or the gradient mode ( ²³ⁿ color mode).

  In the gradient mode, the control signal GRAY_ON is enabled (logic “1”) to activate the switch S1, thereby allowing the first driver 26 to output a buffered grayscale voltage. In the gradient mode, the control signal BIN_ON applied to the second driver 27 is disabled (logic “0”) to deactivate the second driver 27. On the other hand, in the binary mode, the control signal GRAY_ON is disabled to deactivate the switch S1 (logic “0”), whereby the first driver 26 can output the buffered gray scale voltage as Sn. Is prevented. Then, the control signal BIN_ON is enabled to activate the second driver 27 (logic “1”).

  In the binary mode, the second driver 27 determines the source driver output voltage Sn of the source driver power supply voltage AVDD or the ground voltage AVSS for the source driver according to the logic level of the MSB of the latched display data CD [n−1: 0]. Is output.

  FIG. 3 is a timing diagram illustrating a binary operation mode of the source driver circuit of FIG. In FIG. 3, the resolution of the RGB data is 6 bits (ie n = 6) and has the values 00H (binary 000000), 3FH (binary 111111), 07H (binary 000111) and 19H (binary 011001). Assume that the latched display data CD [n−1: 0] are sequentially output from the latch 22. As shown in FIG. 3, in the binary mode, the control signal BIN_ON is fixed to logic “1”, and the control signal GRAY_ON is fixed to logic “0”. Accordingly, the switch S1 is opened and the second driver 27 is activated.

Also, as shown in FIG. 3, the latched display data CD [5: 0] having the value 00H before time T ₁ has the most significant bit CD [5] of logic “0”, and as a result. The second driver 27 outputs a source driver output signal Sn having a ground voltage AVSS for the source driver. The time _{T 1,} the display data CD by the latch control signal S_LATCH [5: 0] is the most significant bit CD [5] is the value 3FH of logic "1". In response to this, the source driver output signal Sn output from the second driver 27 transits from AVSS to the source driver power supply voltage level AVDD. The time _{T 2,} the display data CD by the latch control signal S_LATCH [5: 0] is the most significant bit CD [5] is the value 07H of logical "0". In response to this, the source driver output signal Sn output from the second driver 27 transits from AVDD to AVSS. At time T ₃ , the display data CD [5: 0] is set to the value 19H in which the most significant bit CD [5] is logic “0” by the latch control signal S_LATCH. In response to this, the source driver output signal Sn is maintained at AVSS.

  FIG. 4 is a timing diagram showing a gradient operation mode of the source driver circuit of FIG. In FIG. 4, the resolution of RGB data is 6 bits (ie, n = 6), and the values 00H (binary 000000), 3FH (binary 111111), 07H (binary 000111), and 19H (binary 011001). Assume that the latched display data CD [n−1: 0] is sequentially output from the latch 22. As shown in FIG. 4, in the binary mode, the control signal BIN_ON is fixed to logic “0” and the control signal GRAY_ON is fixed to logic “1”. Accordingly, the second driver 27 is deactivated and the switch S1 is activated, and the first driver 26 buffers and outputs the grayscale voltage selected by the decoder 24 as Sn.

In particular, as shown in the timing diagram of FIG. 4, before time T ₁ , the 00H latched display data CD [5: 0] causes the source driver output signal Sn to have the value VG [0].

The time _{T 1,} the display data CD by the latch control signal S_LATCH [5: 0] is the value 3FH, thereby Sn transitions to VG [63] from VG [0]. Then, the time _{T 2,} the display data CD by the latch control signal S_LATCH [5: 0] is the value 07H, thereby Sn transitions to VG [7] from VG [63]. At time T ₃ , the display data CD [5: 0] is set to the value 19H by the latch control signal S_LATCH, and thereby Sn changes from VG [7] to VG [25].

  FIG. 5 schematically illustrates a conventional common voltage driver circuit embodied in the system 10 of FIG. 1 for driving the common electrode VCOM of the display panel 11. In general, the common voltage driver includes first and second drivers 31 and 32, switches 33 and 34, and capacitors 35 and 36. The first driver 31 buffers and outputs the high common voltage VCOMH. Hereinafter, as will be described, the VCOMH voltage generator of the power supply generation circuit 15 generates VCOMH from the AVDD power supply. The capacitor 35 is connected to the output of the first driver 31 in order to stabilize the output voltage. The switch 33 is controlled by a control signal VCMH_ON to selectively connect the output of the first driver 31 to the VCOM node N and drive VCOM to the high common voltage VCOMH.

  The second driver 32 buffers and outputs the low common voltage VCOML. Hereinafter, as will be described, the VCOML voltage generator of the power supply generation circuit 15 generates VCOML from the VCL (−VCI) power supply. Capacitor 36 is coupled to the output of second driver 32 to stabilize the output voltage. The switch 34 is controlled by a control signal VCML_ON to selectively couple the output of the second driver 32 to the VCOM node N and drive VCOM to the low common voltage VCOML.

FIG. 6 is a timing diagram illustrating a conventional method of driving a common electrode using the circuit of FIG. Referring to FIG. 6, the polarity control signal M and the control signal VCMH_ON the time _{T 1} is enabled, the control signal VCML_ON is disabled. As a result, the switch 33 is activated, the switch 34 is deactivated, and VCOM is driven from VCOMH to VCOML by the first driver 31. The time _{T 2,} the polarity control signal M and the control signal VCMH_ON is disabled, the control signal VCML_ON is enabled. As a result, the switch 33 is deactivated, the switch 34 is activated, and VCOM is driven from VCOML to VCOMH by the second driver 32.

  When a display system such as an LCD panel is implemented in a small portable device, it is important to reduce the power consumption required to drive the display system to conserve battery power. In general, power required to drive a flat panel display is consumed mainly from a source driver and a VCOM driver. In particular, the voltage generated by the source driver to drive the data line is designed to have a relatively high level in order to improve the drive speed of the display (ie, to quickly charge the liquid crystal capacitor Cp). The However, if the drive voltage increases, power consumption increases in proportion to this. In addition, since the polarity of the common voltage is inverted every cycle, driving the common electrode is one of the important causes of power consumption.

  Generally, the source and the VCOM drive voltage are internal voltages generated by a predetermined voltage generator, and the voltage generator generates a drive voltage by boosting a voltage output from an intermediate reference voltage source. For example, FIG. 7 is a block diagram showing a conventional structure of the power generator 15 of FIG. In general, the power generator 15 generates a plurality of internal reference voltages using the intermediate reference voltage source VCI. In particular, the power supply generator 15 includes a first power supply generator 15-1 that generates the source driver power supply voltage AVDD by boosting the intermediate reference voltage VCI by a predetermined amount α. The AVDD voltage is applied to the source driver 12 and input to another power generator (not shown) to generate GVDD and VCOMH. The second power generator 15-2 receives the reference voltage AVDD as an input, and generates VGH by boosting AVDD by a predetermined amount β. The third power generator 15-3 receives the reference voltage VGH as an input and generates VGL (where VGL = −VGH). The fourth power generator 15-4 receives the intermediate reference voltage VCI as an input and generates VCL (where VCL = −VCI).

A problem with conventional source and VCOM driver circuits is the increased power consumption caused by using the boosted voltage to drive the data lines and VCOM. Referring to FIG. 2 in particular, the first and second drivers 26 and 27 of the driving buffer 25 use the boosted power supply AVDD to drive the data line. The boost power supply AVDD is used to generate VCOMH and drive the common electrode VCOM of the display panel 11. The power consumption P _AVDD is I _AVDD × AVDD, that is, α × I _AVDD × VCI with respect to _AVDD , and the drive current I _AVDD is supplied from the intermediate power supply VCI. The current consumption for the drive current I _AVDD is derived from the VCI power supply, but the actual power consumption based on the AVDD power supply is even greater when α is greater than 1. Therefore, the boosted power supplies AVDD and VCOMH for driving the data line and VCOM cause more power consumption for the same current consumption.

  The technical problem to be solved by the present invention is to provide a source driver circuit and a method for providing reduced power consumption in driving a data line of a flat panel display.

  Another technical problem to be solved by the present invention is to provide a common voltage driver circuit and method for providing reduced power consumption in driving a common electrode of a flat panel display.

  The preferred embodiment of the present invention to achieve the above technical problem does not use only a fully boosted drive voltage to reduce power consumption and provide charge recycling, and an intermediate reference in each drive cycle. Source driver circuits and methods that use both voltage and boosted drive voltage, and common voltage driver circuits and methods.

  In a preferred embodiment of the present invention, a source driving circuit for driving a data line of a display receives display data and generates a source driving voltage corresponding to the received display data, and the source driving voltage is displayed on the display. A source driver circuit for applying to the data line; a voltage generating circuit for generating an intermediate source driving voltage; and the source driving by the source driver circuit for driving the data line from the intermediate source driving voltage to the source driving voltage. And a control circuit for applying the intermediate source driving voltage to the data line to drive the data line to the intermediate source driving voltage before a voltage is applied to the data line.

  The control circuit selectively compares the received display data with the previously received display data to generate a comparison signal and the intermediate source driving voltage from the voltage generation circuit to the data line. A switch responsive to the comparison signal for applying is provided. The control circuit further comprises a latch for outputting the previously received display data to the comparator. The comparator compares the most significant bit of the received display data with the most significant bit of the previously received display data. The comparator generates a control signal to deactivate the switch when the most significant bit of the received display data is the same as the most significant bit of the previously received display data.

  In another preferred embodiment of the present invention, a circuit for driving a data line of the display receives an n-bit display signal and a polarity control signal, and changes the polarity of the n-bit display signal in response to the polarity control signal. A polarity control circuit that is inverted or maintained; a first latch that latches the n-bit display signal output from the polarity control circuit in response to a first latch control signal; and a plurality of gray scale references A decoder that receives as input a voltage and the n-bit display signal output from the first latch and decodes the n-bit display signal to selectively output one of the grayscale reference voltages; Source drive voltage is generated and applied to the data line of the display, before the first operation mode Responsive to the first mode control signal to generate the source driving voltage from the grayscale reference voltage output from the decoder, the n-bit display signal output from the first latch in the second operation mode. A buffer responsive to a second mode control signal to generate the source driving voltage based on the upper bits, a voltage generating circuit for generating an intermediate source driving voltage, and the data line from the intermediate source driving voltage to the source Before the source driving voltage is applied to the data line by the buffer circuit for driving with the driving voltage, the intermediate source driving voltage is applied to the data line to drive the data line with the intermediate source driving voltage. And a control circuit to be applied.

  In a preferred embodiment of the present invention, a common voltage driver circuit for driving a common electrode of a display includes a first driver circuit that outputs a high common voltage, a second driver circuit that outputs a low common voltage, and a first control signal. In response to the first switch selectively connecting the output of the first driver circuit to the common electrode of the display panel; and in response to a second control signal, selecting the output of the second driver circuit to the common electrode And an intermediate voltage output circuit for outputting one or more intermediate common voltages to the common electrode in response to one or more intermediate control signals. And

  The common voltage driver circuit drives the common electrode from the low common voltage to the high common voltage by driving the common electrode with the one or more intermediate common voltages before outputting the high common voltage. To drive. The common voltage driver circuit drives the common electrode from the high common voltage to the low common voltage by driving the common electrode with the one or more intermediate common voltages before outputting the low common voltage. To drive.

  The intermediate voltage output circuit includes one or more switching elements, each switching element corresponding to the intermediate control signal for selectively coupling a corresponding one of the intermediate common voltages to the common electrode. Respond to things.

  At least one of the intermediate common voltages is a ground voltage, and at least one of the intermediate common voltages is a voltage in a range of about 1/2 to about 3/4 of the high common voltage.

  For a full understanding of the invention and the operational advantages thereof and the objects achieved by the practice of the invention, reference should be made to the accompanying drawings and the accompanying drawings illustrating preferred embodiments of the invention. I have to do it.

  The source driver circuit and method and the common voltage driver circuit and method according to the present invention reduce power consumption.

  Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. The same reference numerals provided in each drawing denote the same members.

  FIG. 8 is a schematic diagram illustrating a source driving circuit according to a preferred embodiment of the present invention. The preferred embodiment shown in FIG. 8 is an extension of the source drive circuit 20 shown in FIG. 2, which significantly reduces the power consumed to drive the data lines of the display panel. In general, the source driving circuit 80 includes a source driver 81 for generating a source driver output signal Sn, a gray scale generator 23, and an intermediate voltage generator 90 to drive a corresponding data line Di. 8 shows a structure according to a preferred embodiment, and the source driver circuit 80 may be implemented in the source driver IC 12 in the display system of FIG. In the source driving circuit 80, one source driver 81 is assigned to each data line Di (or RGB channel), and the gray scale generator 23 and the intermediate voltage generator 90 are implemented in common for all source drivers. Is done.

  The source driver 81 is similar to the structure of the source driver 12-i in FIG. 2 in that the source driver 81 includes the polarity inversion circuit 21, the latch circuit 22, the gamma decoder 24, and the drive buffer 25. However, the source driver 81 further includes a comparison circuit 82 that compares the current most significant bit MSB with the previous most significant bit MSB and connects the data line Di to the intermediate voltage output from the intermediate voltage generator 90 according to the comparison result. . The intermediate voltage generator 90 outputs another intermediate voltage depending on the operation mode (binary or gradient).

  In particular, the comparison circuit 82 includes a latch circuit 83, an XOR circuit 84, an AND gate 85, and a switch element S2. In the preferred embodiment, the latch circuit 83 latches the most significant bit CD [n−1] of the currently latched block of display data stored in the latch 22 in response to the latch control signal PD_LATCH and has been previously latched. A 1-bit clocked D-type latch that outputs the most significant bit PD [n−1] of the display data is configured.

  The XOR circuit 84 has the most significant bits CD [n−1] of the current block of display data CD [n−1: 0] from the latch 22 and the most significant bits PD [n] of display data previously latched from the latch 83. -1] as an input. The XOR gate 84 outputs a logic “1” when the most significant bit CD [n−1] and the most significant bit PD [n−1] are different, and the most significant bit CD [n−1] and the most significant bit PD. When [n−1] is the same, logic “0” is output. The AND gate 85 is configured as a 2-input AND gate that receives the output of the XOR gate 84 and the control signal VCIR. The AND gate 85 serves as a gating circuit that transmits the output of the XOR gate 84 in response to the control signal VCIR in order to control the activation / deactivation of the switch S2. In the embodiment of the present invention, the switch S2 is activated when the output of the AND gate 85 is logic "1" (when the most significant bit CD [n-1] and the most significant bit PD [n-1] are different). The switch S2 is deactivated when the output of the AND gate 85 is logic “0” (when the most significant bit CD [n−1] and the most significant bit PD [n−1] are the same). Is done.

  When the switch S2 is activated, an intermediate voltage output from the intermediate voltage generator 90 is applied to drive the data line Di. The XOR gate 84 and the AND gate 85 can be replaced with other logic gates having the same function.

The intermediate voltage generator 90 may further include a capacitor 92 including a third driver 91 corresponding to an amplifier and a switch S3. The third driver 91 buffers and outputs one of the gray scale reference voltages VG output from the gray scale generator 23 using the VCI power supply. In the preferred embodiment, the third driver 91 receives the grayscale reference voltage VG [2 ^n-1 -1]. Here, the reference voltage VG [2 ^n-1 -1] is preferably lower than the VCI power supply. The switch S3 is connected to the first node N1 to which the first intermediate voltage VCI is applied in response to the voltage selection control signal BIN_FLAG, or is applied with the second intermediate voltage VG [2 ⁿ⁻¹ −1]. It is connected to the second node N2 (the output of the third driver 91). The capacitor 92 may be selectively coupled to the output of the third driver 91 to stabilize the output voltage.

  In the preferred embodiment of the present invention, the intermediate source drive voltage VCI is in the range of about 1/2 to 1/3 of the full swing voltage of the source drive voltage AVDD. For example, if AVDD is about 5-6 volts, VCI is about 2-3 volts and AVSS is about 0 volts.

In the binary mode, when the voltage selection control signal BIN_FLAG is logic “1”, S3 is connected to the first node N1, and the intermediate voltage VCI is transmitted to S2. In the gradient mode, when the voltage selection control signal BIN_FLAG is logic “0”, S3 is connected to the second node N2, and the intermediate voltage VG [2 ⁿ⁻¹ −1] is transmitted to S2. Each control signal M, S_LATCH, BIN_ON, GRAY_ON, VCIR, BIN_FLAG is generated by a controller such as controller 14 shown in FIG. As described above, the intermediate voltage generator 90 is commonly used by all the source drivers 81 in the source driver IC.

  FIG. 9 is a timing diagram illustrating a source driving method for driving a data line according to an exemplary embodiment of the present invention. For convenience of explanation, the method of FIG. 9 will be described with reference to the source driving circuit 80 of FIG. The method of FIG. 9 corresponds to the binary operation mode of the source driver circuit of FIG. In FIG. 9, the resolution of the RGB data is 6 bits (ie, n = 6), and the values 00H (binary 000000), 3FH (binary 111111), 07H (binary 000111), and 19H (binary 011001). Assume that the latched display data CD [n−1: 0] is sequentially output from the latch 22. In the binary mode, the control signal GRAY_ON is fixed to logic “0” (switch S1 is opened), and the control signal BIN_FLAG is fixed to logic “1” (switch S3 is connected to the node N1). Assume.

As shown in FIG. 9, the value 00H of the latched display data CD [5: 0] is output from the n-bit latch circuit 22 before time T ₁ . The most significant bit CD [5] of the latched display data CD [5: 0] is logic “0”. Further, the time _{T 1} before the control signal BIN_ON second driver 27 is turned on becomes logic "1". If the most significant bit CD [5] is logic “0”, the second driver 27 outputs the source driver output signal Sn of the ground voltage AVSS for the source driver to the data line Di. The latch control signal PD_LATCH activated before time T ₁ controls the 1-bit latch 83 to latch the most significant bit CD [5] = logic “0” of the display data 00H. As shown in FIG. 9, the latch control signal PD_LATCH is activated before the latch control signal S_LATCH is activated to latch the next block of display data.

Next, at time _{T 1,} the latch control signal S_LATCH is activated, whereby the latch 22 is the display data CD MSB CD [5] is a logic "1" [5: 0] value 3FH latches of Output. Also, after time _{T 1,} gating signal VCIR during period _{P 1} is the control signal BIN_ON been activated are inactivated. If the control signal BIN_ON is deactivated, the second driver 27 is turned off. When the gating signal VCIR is activated, the output of the XOR gate 84 is applied to the switch S2. Since the current most significant bit CD [n−1] and the previous most significant bit PD [n−1] are different (ie, CD [5] is 1 and PD [5] is 0), the AND gate 85 Becomes a logic "1", which activates the switch S2. If S2 is turned off is activated by the second driver, VCI power supply voltage for driving the AVSS data line Di with the source drive output signal Sn during the period P ₁ to the intermediate voltage VCI.

In time _{T 2,} VCIR is BIN_ON is deactivated is activated, whereby switch S2 is open (expires VCI from the data line Di) second driver 27 is turned on. If the current most significant bits CD [5] is a logic "1", the second driver 27 drives the VCI output signal Sn during the period _{T 2} to AVDD. PD_LATCH is activated in the last part of the period P ₂ , whereby the 1-bit latch 83 latches the most significant bit CD [5] = logic “1” of the display data 3FH and PD [5] = logic “1”. "Is output.

Followed by time _{T 3,} S_LATCH is activated, whereby n- bit latch 22 is display data CD MSB CD [5] is a logic "0" [5: 0] values 07H and latches Output. Further, during a period _{P 3} after _{T 3,} VCIR is BIN_ON been activated are inactivated. If the control signal BIN_ON is deactivated, the second driver 27 is turned off. When the gating signal VCIR is activated, the output of the XOR gate 84 is applied to the switch S2. Because the current most significant bit CD [n−1] and the previous most significant bit PD [n−1] are different (ie, CD [5] is 0 and PD [5] is 1), the AND gate 85 Becomes a logic "1", which activates the switch S2. When S2 is activated, the data line Di is connected to the VCI power supply, thereby discharging the source driver output signal Sn from AVDD to the intermediate voltage VCI.

Followed by time _{T 4,} VCIR is BIN_ON is deactivated is activated. As a result, the switch S2 is opened (that is, VCI is disconnected from the data line Di), and the second driver 27 is turned on. If CD [5] is 0, the second driver 27 drives the Sn from VCI to AVSS during the interval _{P 4.} Is PD_LATCH is activated in the last part of the period _{P 4,} whereby 1-bit latch 83 is the most significant bit of the display data 07H CD [5] = logic "0" is latched PD [5] = logic "0 "Is output.

Then the S_LATCH activation time _{T 5,} whereby n- bit latch 22 is display data CD MSB CD [5] is a logic "0" [5: 0] values 19H and latches the output of the To do. Further, during a period _{P 5} after _{T 5,} VCIR is BIN_ON been activated are inactivated. If the control signal BIN_ON is deactivated, the second driver 27 is turned off. When the gating signal VCIR is activated, the output of the XOR gate 84 is applied to the switch S2. Since the current most significant bit CD [n−1] and the previous most significant bit PD [n−1] are identical (ie, CD [5] is 0 and PD [5] is 0), AND The output of the gate 85 becomes a logic “0”, which keeps the switch S2 inactive. If S2 is deactivated, the source driver output signal Sn is maintained at AVSS (ie, not charged to VCI). After the time _{T 6,} VCIR is BIN_ON is deactivated is activated. If CD [5] is 0, the second driver 27 maintains Sn at AVSS.

  FIG. 10 is a timing diagram illustrating a source driving method for driving a data line according to another exemplary embodiment of the present invention. For convenience of explanation, the method of FIG. 10 will be described with reference to the source driving circuit 80 of FIG. The method of FIG. 10 corresponds to the gradient operation mode of the source driver circuit of FIG. In FIG. 10, the resolution of RGB data is 6 bits (ie, n = 6), and the values 00H (binary 000000), 3FH (binary 111111), 07H (binary 000111), and 19H (binary 011001). Assume that latched display data CD [n−1: 0] having the following are sequentially output from the latch 22. In the gradient mode, the control signal BIN_ON is fixed to logic “0” (the second driver 27 is deactivated), and the control signal BIN_FLAG is fixed to logic “0” (the switch S3 is connected to the third driver 91). It is assumed that the node N2 is connected to the output.

As shown in FIG. 10, the value 00H of the latched display data CD [5: 0] is output from the n-bit latch circuit 22 before the time T ₁ . The most significant bit CD [5] of the latched display data CD [5: 0] is logic “0”. Further, before time _{T 1,} the control signal GRAY_ON is the switch S1 becomes a logic "1" is short-circuited. Accordingly, the first driver 26 drives the data line Di having the source driver output signal Sn to the gray scale voltage VG lower than the intermediate voltage VG [31]. The latch control signal PD_LATCH activated before the time T ₁ is such that the 1-bit latch 83 latches the most significant bit CD [5] = logic “0” of the display data 00H and PD [5] = logic “0”. To output "". As shown in FIG. 10, the latch control signal PD_LATCH is activated before the latch control signal S_LATCH is activated to latch the next block of display data.

Next, at time T ₁ , the latch control signal S_LATCH is activated, whereby the latch 22 latches the value 3FH of the display data CD [5: 0] whose most significant bit CD [5] is logic “1”. Output. Also, after time _{T 1,} gating signal VCIR during period _{P 1} is the control signal GRAY_ON been activated are inactivated. If the control signal GRAY_ON is deactivated, the switch S1 is opened. When the gating signal VCIR is activated, the output of the XOR gate 84 is applied to the switch S2. Since the current most significant bit CD [n−1] and the previous most significant bit PD [n−1] are different (ie, CD [5] is 1 and PD [5] is 0), the AND gate 85 Becomes a logic "1", which activates the switch S2. If S2 is opened is S1 is activated, the third driver 91 is driven from VG [0] data lines Di having a source drive output signal Sn during the period _{P 1} to the intermediate voltage VG [31].

In time _{T 2,} VCIR is GRAY_ON is deactivated is activated, whereby the switch S2 is open (the output from the data line Di to the third driver 91 expires) switch S1 is short-circuited. CD [5: 0] is if 3FH, first driver 26 drives the output signal Sn during a period _{T 2} from VG [31] to VG [63]. PD_LATCH is activated in the last part of the period P ₂ , whereby the 1-bit latch 83 latches the most significant bit CD [5] = logic “1” of the display data 3FH and PD [5] = logic “1”. "Is output.

Next, at time T ₃ , S_LATCH is activated, whereby the n-bit latch 22 latches and outputs the value 07H of the display data CD [5: 0] whose most significant bit CD [5] is logic “0”. To do. Further, during a period _{P 3} after _{T 3,} VCIR is GRAY_ON been activated are inactivated. If the control signal GRAY_ON is deactivated, the switch S1 is opened, and if the gating signal VCIR is activated, the output of the XOR gate 84 is applied to the switch S2. Because the current most significant bit CD [n−1] and the previous most significant bit PD [n−1] are different (ie, CD [5] is 0 and PD [5] is 1), the AND gate 85 Becomes a logic "1", which activates the switch S2. When S2 is activated, the data line Di is connected to the node N2, whereby the driver 91 discharges the source driver output signal Sn from VG [63] to the intermediate voltage VG [31].

Followed by time _{T 4,} VCIR is GRAY_ON is deactivated is activated. Thereby, the switch S2 is opened (that is, the node N2 is disconnected from the data line Di), and the switch S1 is short-circuited. CD [5: 0] is if 07H, the first driver 26 drives the Sn during the interval _{P 4} from VG [31] In VG [7]. Is PD_LATCH is activated in the last part of the period _{P 4,} whereby 1-bit latch 83 is the most significant bit of the display data 07H CD [5] = logic "0" is latched PD [5] = logic "0 "Is output.

Next, at time _{T 5,} S_LATCH is activated, whereby n- bit latch 22 is display data CD MSB CD [5] is a logic "0" [5: 0] values 19H and latches Output. Further, during a period _{P 5} after _{T 5,} VCIR is GRAY_ON been activated are inactivated. If the control signal GRAY_ON is deactivated, the switch S1 is opened, and if the gating signal VCIR is activated, the output of the XOR gate 84 is applied to the switch S2. Since the current most significant bit CD [n−1] and the previous most significant bit PD [n−1] are identical (ie, CD [5] is 0 and PD [5] is 0), AND The output of the gate 85 becomes a logic “0”, which keeps the switch S2 inactive. If S2 is deactivated, the source driver output signal Sn is maintained at VG [7] During the period _{P 5} (i.e., not be charged to the VG [31]). After the time _{T 6,} VCIR is GRAY_ON is deactivated is activated. If CD [5: 0] is 19H, the first driver 26 drives Sn to VG [25].

The source drive circuit and method described with reference to FIGS. 8, 9, and 10 significantly reduce power consumption compared to the conventional circuit and method described with reference to FIGS. . In particular, the use of VCI power to partially drive the data line Di with period P ₁ in FIG. 9, the conventional method of FIG. 3 the boosted power supply (AVDD) is used to drive the data line Compared with power consumption. Further, by using the VCI power to drive the data lines in the section P _3, charge recycling operation is induced due to the "negative" current to VCI power.

In addition, the gradient operation mode in FIG. 10 uses a VCI power supply for the third driver 91, thereby greatly reducing power consumption compared to the conventional method of FIG. In particular, in FIG. 10, the third driver 91 uses a non-boosted VCI power source to drive the data line with VG [31], thereby reducing power consumption in the interval P ₁ and VCI in the interval P ₃ . Negative current to the power supply triggers charge recycling behavior.

For example, it is assumed that I _D is the total drive current from AVSS to AVDD, the drive current in section P ₁ is I _D1 , the drive current in section P ₂ is I _D2 , and I _D = I _D1 + I _D2. . Then, assuming that AVSS is 0 volts and AVDD is α × VCI, according to the method of the present invention of FIG. 9 where the VCI power supply is partially used to drive the data line, the interval P ₁ , the total drive power consumption P in P ₂ is determined by the following equation.

P = I _D1 × (VCI−AVSS) + I _D2 × (AVDD−VCI)
= I _D1 × VCI + {I _D2 × (VCI × α) −I _D2 × VCI}}
= VCI × (I _D1 −I _D2 + α × I _D2 )

In contrast, according to the conventional method of FIG. 3, the total driving power consumption P ′ in the sections P ₁ and P ₂ is obtained by the following equation.
P ′ = _ID × (AVDD−AVSS)
= I _D × AVDD
= I _D × (α × VCI)
= VCI × (α × I _D1 + α × I _D2 )

  Assuming that the total drive current is the same for the conventional method and the present invention, when α is greater than 1, the total drive power consumption P 'by the conventional method is greater than the total drive power consumption P by the method of the present invention. That is, the power consumption is reduced in the method according to the invention compared to the conventional method.

Therefore, according to the preferred method of the present invention of FIGS. 9 and 10, using the VCI power source during the interval P ₁ consumes 1 / α of power compared to the conventional method. Also, as described above, due to the negative current in a period P ₃ for VCI power charge recycling occurs.

  FIG. 11 illustrates a common voltage driver circuit 40 according to a preferred embodiment of the present invention. The common voltage driver circuit 40 is similar to the driver circuit 30 of FIG. 5 in that it includes first and second drivers 31 and 32, switches 33 and 34, and capacitors 35 and 36. The common voltage driver circuit 40 includes an intermediate voltage output circuit 41 that outputs one or more intermediate common voltages to the common electrode VCOM node N in response to one or more intermediate control signals.

  In particular, in the preferred embodiment shown in FIG. 11, the intermediate voltage output circuit 41 includes a third driver 42 that buffers and outputs the reference voltage VCI, and a switch 43 controlled by the intermediate voltage control signals VCIR and VSSR, 44. Switch 43 is controlled to couple the output of driver 42 to VCOM node N, and switch 44 is controlled to couple VCOM node N to ground voltage AVSS. In the preferred embodiment of the present invention, VCOMH is about 4 volts, VCI is about 2-3 volts, AVSS is 0 volts, and VCOML is about -1 volts.

As described below with reference to FIG. 12, the method of driving the common electrode using the driver circuit 40 of FIG. 11 significantly reduces power consumption compared to the drive circuit 30 of FIG.
FIG. 12 is a timing diagram illustrating a method of driving a common electrode according to a preferred embodiment of the present invention. In particular, FIG. 12 shows an operation mode of the common voltage driver 40 of FIG. Referring to FIG. 12, when the polarity control signal M is at a logic "0" at time _{T 1} before the interval, the control signal VCML_ON is enabled (switch 34 is short-circuited) control signal VCMH_ON, VCIR, and VSSR Is disabled (switches 33, 43, and 44 are opened). Therefore, the common electrode VCOM is driven by VCOML by the second driver 32.

In time _{T 1,} the polarity control signal M is changed to a logic "1" to invert the display data, VCML_ON switch 34 is disabled is opened. Then, the control signal VSSR is enabled, whereby the switch 44 is short-circuited and the VCOM node N is connected to the intermediate voltage AVSS (that is, the ground voltage). During the time period _{P 1,} VCOM is driven from VCOML to AVSS. Then, the time _{T 2,} VSSR is open switch 44 is disabled and, VCIR is shorted is enabled switch 43, and, VCOM node N is connected to the output of the third driver 42. Thus, during the period _{P 2,} VCOM is driven from AVSS using VCI supply to an intermediate voltage VCI. Next, at time _{T 3,} VCIR is open switch 43 is disabled and the control signal VCMH_ON are short-circuited is enable switch 33, and the output of the first driver 31 is connected to the VCOM node N. Therefore, during a period _{P 3,} VCOM is driven VCOMH from the intermediate voltage VCI by the first driver 31.

Next, at time _{T 4,} the polarity control signal M is changed to a logic "0" indicating the display data having a positive polarity, VCMH_ON switch 33 is disabled is opened. Then, the control signal VCIR is enabled, whereby the switch 43 is short-circuited and the VCOM node N is connected to the output of the third driver 42. Therefore, during a period _{P 4,} VCOM is driven VCI from VCOMH by the driver 42. Next, at time _{T 5,} VCIR is open switch 43 is disabled and, VSSR are short switch 44 is enabled, and, VCOM node N is connected to the ground AVSS. Therefore, during a period _{P 5,} VCOM is driven from the VCI to VSS. Next, at time T ₆ , VSSR is disabled, switch 44 is opened, control signal VCML_ON is enabled, switch 34 is shorted, and VCOM node N is coupled to the output of second driver 32. Therefore, during a period _{P 6,} VCOM is driven from the intermediate voltage AVSS to VCOML.

The common voltage drive circuit and method of FIGS. 11 and 12 significantly reduce power consumption compared to the conventional common voltage drive circuit and method of FIGS. For example, the interval _{P 1,} the VCOM VCOML (i.e., -1 volt) to AVSS (i.e., 0 volts) power is not consumed by the use of ground to drive the. Moreover, the interval _{P 2,} power consumption as described above is decreased as 1 / alpha the VCOM using VCI power instead of the step-up power supply AVDD by driving the AVSS (ground) to the VCI. Moreover, the interval P _4, charge recycling operation due to the negative current supply occurs for VCI power. Further, the interval _{P 5,} power is not consumed by sinking the VCI to AVSS using ground.

  In the foregoing, the best embodiment has been disclosed in the drawings and specification. Although specific terms are used herein, they are merely used for the purpose of describing the present invention and limit the scope of the present invention as defined in the meaning and claims. It was not used for that purpose. Accordingly, those skilled in the art will appreciate that various modifications and other equivalent embodiments are possible. Therefore, the true technical protection scope of the present invention must be determined by the technical idea of the claims.

  The source driver circuit and method and the common voltage driver circuit and method according to the present invention can be used for driving LCDs, PDPs, and electroluminescent displays.

It is the schematic which shows the conventional display system. It is the schematic which shows the conventional source driver circuit. FIG. 3 is a timing diagram illustrating a binary operation mode of the source driver circuit of FIG. 2. FIG. 3 is a timing diagram showing a gradient operation mode of the source driver circuit of FIG. 2. It is the schematic which shows the conventional common electrode VCOM driver circuit. FIG. 6 is a timing chart showing an operation mode of the common electrode VCOM driver of FIG. 5. It is a block diagram which shows the conventional structure of the power generator of FIG. 1 is a schematic diagram illustrating a source driving circuit according to a preferred embodiment of the present invention. FIG. 9 is a timing diagram illustrating a binary operation mode of the source driving circuit of FIG. 8 according to a preferred embodiment of the present invention. FIG. 9 is a timing diagram illustrating a gradient operation mode of the source driving circuit of FIG. 8 according to an exemplary embodiment of the present invention. FIG. 3 is a schematic diagram illustrating a common electrode VCOM driver circuit according to a preferred embodiment of the present invention. FIG. 12 is a timing chart showing an operation mode of the common electrode VCOM driver of FIG. 11.

Explanation of symbols

21 polarity inversion circuit 22 n-bit latch circuit 23 gray scale generator 24 gamma decoder 25 drive buffer 26 first driver 27 second driver 80 source drive circuit 81 source driver 82 comparison circuit 83 latch circuit 84 XOR circuit 85 AND gate 90 intermediate Voltage generator 91 Third driver 92 Capacitor AVDD Source driver power supply voltage AVSS Source driver ground voltage Di Data line M, BIN_ON, GRAY_ON, BIN_FLAG Control signal N1 First node N2 Second node S_LATCH, PD_LATCH Latch control signals S1, S2, S3 Switch element Sn Source driver output signal VCI Intermediate source drive voltage VCIR Gating signal

Claims (53)

In the source drive circuit that drives the data line of the display,
A source driver circuit for receiving display data, generating a source driving voltage corresponding to the received display data, and applying the source driving voltage to a data line of the display;
A voltage generating circuit for generating an intermediate source driving voltage;
Driving the data line to the intermediate source drive voltage before the source drive voltage is applied to the data line by the source driver circuit to drive the data line from the intermediate source drive voltage to the source drive voltage And a control circuit for applying the intermediate source driving voltage to the data line. The control circuit includes:
A comparator that compares the received display data with previously received display data to generate a comparison signal;
The source driving circuit according to claim 1, further comprising: a switch responsive to the comparison signal for selectively applying the intermediate source driving voltage from the voltage generating circuit to the data line. The control circuit includes:
The source driving circuit of claim 2, further comprising a latch that outputs the previously received display data to the comparator.   The source driving circuit of claim 2, wherein the comparator compares the most significant bit of the received display data with the most significant bit of the previously received display data.   The comparator generates a control signal to deactivate the switch when the most significant bit of the received display data is the same as the most significant bit of the previously received display data. The source drive circuit according to claim 4.   The source of claim 4, wherein the comparator comprises an exclusive OR gate that receives as input the most significant bit of the received display data and the most significant bit of the previously received display data. Driving circuit. The control circuit includes:
The source driving circuit according to claim 2, further comprising a gate circuit responsive to a gate control signal to selectively apply the comparison signal to the switch.   The source driver circuit is enabled by a first control signal to apply the source driving voltage to the data line, and the control circuit is enabled by a second control signal to apply the intermediate source driving voltage to the data line. The first and second control signals are exclusively activated so that the intermediate source driving voltage is applied to the data line before the source driving voltage is applied to the data line. The source drive circuit according to claim 1.   The source driving circuit according to claim 1, wherein the intermediate source driving voltage output from the voltage generator is a gray scale reference voltage.   The source driving circuit of claim 1, wherein the intermediate source driving voltage is in a range of about 1/2 to about 1/3 of a full swing voltage of the source driving voltage. In the circuit that drives the data line of the display,
a polarity control circuit that receives an n-bit display signal and a polarity control signal and inverts or maintains the polarity of the n-bit display signal in response to the polarity control signal;
A first latch for latching the n-bit display signal output from the polarity control circuit in response to a first latch control signal;
The n-bit display for receiving a plurality of gray scale reference voltages and the n-bit display signal output from the first latch as an input and selectively outputting one of the gray scale reference voltages. A decoder for decoding the signal;
Responsive to a first mode control signal to generate and apply a source driving voltage to a display data line and to generate the source driving voltage from the grayscale reference voltage output from the decoder in a first operation mode; A buffer responsive to a second mode control signal to generate the source driving voltage based on the most significant bit of the n-bit display signal output from the first latch in a second operation mode;
A voltage generating circuit for generating an intermediate source driving voltage;
Driving the data line to the intermediate source driving voltage before the buffer circuit applies the source driving voltage to the data line to drive the data line from the intermediate source driving voltage to the source driving voltage; And a control circuit for applying the intermediate source driving voltage to the data line. The control circuit includes:
A comparator that compares the most significant bit of the n-bit display signal with the most significant bit of the previously received n-bit display signal to generate a comparison signal;
12. The driving circuit according to claim 11, further comprising a switch responsive to the comparison signal to selectively apply the intermediate source driving voltage to the data line. The control circuit includes:
The driving circuit of claim 12, further comprising a 1-bit latch that latches and outputs the most significant bit of the previously received n-bit display signal to the comparator.   The driving circuit according to claim 12, wherein the comparator comprises an exclusive OR gate.   13. The driving circuit according to claim 12, further comprising a gate circuit responsive to a gate control signal for selectively outputting the comparison signal to the switch.   The comparison signal deactivates the switch when the received n-bit display signal and the most significant bit of the previously received n-bit display signal are the same. 12. The drive circuit according to 12.   The buffer circuit is enabled by a first or second mode control signal to apply the source driving voltage to the data line, and the control circuit is controlled by a control signal to apply the intermediate source driving voltage to the data line. Enabled and the control signal is exclusive to the first or second mode control signal such that the intermediate source drive voltage is applied to the data line before the source drive voltage is applied to the data line. The drive circuit according to claim 11, wherein the drive circuit is activated.   12. The driving circuit of claim 11, wherein the intermediate source driving voltage is in a range of about [1/2] to about [1/3] of a full swing voltage of the source driving voltage.   The driving circuit according to claim 11, wherein the first mode is a gradient mode and the second mode is a binary mode. The voltage generation circuit includes:
An intermediate voltage driver;
Comprising a switch controlled by a switch control signal to connect to the first node or the second node;
The driving circuit of claim 11, wherein the first node is connected to an intermediate voltage power source, and the second node is connected to an output of the intermediate voltage driver.   The driving circuit of claim 20, further comprising a capacitor connected between the second node and the ground.   The voltage generation circuit outputs a first voltage generated by the intermediate voltage power source as the intermediate source driving voltage in the second operation mode, and the voltage generation circuit outputs the intermediate voltage as the intermediate source driving voltage in the first operation mode. 21. The driving circuit according to claim 20, wherein the driving circuit outputs a second voltage generated by the voltage driver.   The driving circuit according to claim 22, wherein the intermediate voltage driver operates using the first voltage generated by the intermediate voltage power source.   24. The driving circuit of claim 23, wherein the intermediate voltage driver buffers and outputs a gray scale reference voltage as the second voltage used as an intermediate source driving voltage.   25. The source driving circuit of claim 24, wherein the intermediate source driving voltage is in a range of about [1/2] to about [1/3] of a full swing voltage of the source driving voltage. A liquid crystal display panel including a plurality of thin film transistors (TFTs), a plurality of gate lines connected to the gate electrodes of the TFTs, and a plurality of data lines connected to the source electrodes of the TFTs;
A gate driver including a plurality of gate driver circuits each driving a corresponding gate line of the liquid crystal display panel;
A source including a plurality of source driver circuits driving a corresponding data line of the liquid crystal display panel by generating a source driving voltage corresponding to the received display data and applying the source driving voltage to the data line. A driver,
A voltage generating circuit for generating an intermediate source driving voltage applied in common to the source driver circuit,
Each of the source driver circuits has the corresponding data line before the source drive voltage is applied to the data line by the source driver circuit to drive the data line from the intermediate source drive voltage to the source drive voltage. A liquid crystal display device comprising: a control circuit that applies the intermediate source driving voltage to the corresponding data line in order to drive the intermediate source driving voltage to the intermediate source driving voltage. The control circuit includes:
A comparator that compares the received display data with previously received display data to generate a comparison signal;
27. The liquid crystal display device according to claim 26, further comprising: a switch responsive to the comparison signal for selectively applying the intermediate source driving voltage from the voltage generation circuit to the data line. The control circuit includes:
28. The liquid crystal display device of claim 27, further comprising a latch for outputting the previously received display data to the comparator.   28. The liquid crystal display device of claim 27, wherein the comparator compares the most significant bit of the received display data with the most significant bit of the previously received display data.   The comparator generates a control signal to deactivate the switch when the most significant bit of the received display data is the same as the most significant bit of the previously received display data. 30. The liquid crystal display device according to claim 29, wherein:   30. The liquid crystal of claim 29, wherein the comparator comprises an exclusive OR gate that receives as input the most significant bit of the received display data and the most significant bit of the previously received display data. Display device. The control circuit includes:
28. The liquid crystal display device of claim 27, further comprising a gate circuit responsive to a gate control signal to selectively apply the comparison signal to the switch.   The source driver circuit is enabled by a first control signal to apply the source driving voltage to the data line, and the control circuit is enabled by a second control signal to apply the intermediate source driving voltage to the data line. The first and second control signals are exclusively activated so that the intermediate source driving voltage is applied to the data line before the source driving voltage is applied to the data line. The liquid crystal display device according to claim 26.   27. The liquid crystal display device of claim 26, wherein the intermediate source driving voltage output from the voltage generator is a gray scale reference voltage.   27. The liquid crystal display device of claim 26, wherein the intermediate source driving voltage is in a range of about [1/2] to about [1/3] of a full swing voltage of the source driving voltage. In a method of driving a data line of a display,
Generating a source driving voltage corresponding to the received display data;
Generating an intermediate source drive voltage; and
Applying the intermediate source drive voltage to the data line to drive a data line to the intermediate source drive voltage;
Applying the source driving voltage to the data line to drive the data line from the intermediate source driving voltage to the source driving voltage. In a common voltage driver circuit for a display panel,
A first driver circuit that outputs a high common voltage;
A second driver circuit that outputs a low common voltage;
A first switch that selectively couples an output of the first driver circuit to a common electrode of the display panel in response to a first control signal;
A second switch that selectively couples the output of the second driver circuit to the common electrode in response to a second control signal;
An intermediate voltage output circuit for outputting one or more intermediate common voltages to the common electrode in response to one or more intermediate control signals.   The common voltage driver circuit drives the common electrode from the low common voltage to the high common voltage by driving the common electrode with the one or more intermediate common voltages before outputting the high common voltage. The common voltage driver circuit according to claim 37, wherein the common voltage driver circuit is driven.   The common voltage driver circuit drives the common electrode from the high common voltage to the low common voltage by driving the common electrode with the one or more intermediate common voltages before outputting the low common voltage. The common voltage driver circuit according to claim 37, wherein the common voltage driver circuit is driven.   The intermediate voltage output circuit includes one or more switching elements, each switching element corresponding to the intermediate control signal for selectively coupling a corresponding one of the intermediate common voltages to the common electrode. 38. The common voltage driver circuit of claim 37, responsive to the one.   38. The common voltage driver circuit of claim 37, wherein at least one of the intermediate common voltages is a ground voltage.   38. The common voltage driver circuit of claim 37, wherein at least one of the intermediate common voltages is in the range of about [1/2] to about [3/4] of the high common voltage. A liquid crystal display panel including a plurality of TFTs, a plurality of gate lines connected to the gate electrodes of the TFTs, a plurality of data lines connected to the source electrodes of the TFTs, and a common electrode;
A gate driver including a plurality of gate driver circuits each driving a corresponding gate line of the liquid crystal display panel;
A source including a plurality of source driver circuits driving a corresponding data line of the liquid crystal display panel by generating a source driving voltage corresponding to the received display data and applying the source driving voltage to the data line. A driver,
A common voltage driver circuit,
The common voltage driver circuit includes:
A first driver circuit that outputs a high common voltage;
A second driver circuit that outputs a low common voltage;
A first switch that selectively couples an output of the first driver circuit to a common electrode of the display panel in response to a first control signal;
A second switch that selectively couples the output of the second driver circuit to the common electrode in response to a second control signal;
And an intermediate voltage output circuit for outputting one or more intermediate common voltages to the common electrode in response to one or more intermediate control signals.   The common voltage driver circuit drives the common electrode from the low common voltage to the high common voltage by driving the common electrode with the one or more intermediate common voltages before outputting the high common voltage. 44. The liquid crystal display device according to claim 43.   The common voltage driver circuit drives the common electrode from the high common voltage to the low common voltage by driving the common electrode with the one or more intermediate common voltages before outputting the low common voltage. 44. The liquid crystal display device according to claim 43.   The intermediate voltage output circuit includes one or more switching elements, each switching element corresponding to the intermediate control signal for selectively coupling a corresponding one of the intermediate common voltages to the common electrode. 44. The liquid crystal display device according to claim 43, which is responsive to the object.   44. The liquid crystal display device according to claim 43, wherein at least one of the intermediate common voltages is a ground voltage.   44. The liquid crystal display device of claim 43, wherein at least one of the intermediate common voltages is in a range of about [1/2] to about [3/4] of the high common voltage. In a method of driving a common electrode of a display panel,
Generating a high common voltage; and
Generating a low common voltage; and
Generating one or more intermediate common voltages;
Driving the common electrode from the low common voltage to the high common voltage by outputting the one or more intermediate common voltages to the common electrode before outputting the high common voltage. A common electrode driving method.   Driving the common electrode from the high common voltage to the low common voltage by outputting the one or more intermediate common voltages to the common electrode before outputting the low common voltage. 50. The common electrode driving method according to claim 49, wherein the driving method is a common electrode driving method.   50. The common electrode driving method of claim 49, wherein the driving comprises sequentially activating a plurality of switch control signals to sequentially output the one or more intermediate common voltages. Method.   The common electrode driving method according to claim 49, wherein at least one of the intermediate common voltages is a ground voltage. 50. The method of claim 49, wherein at least one of the intermediate common voltages is in a range of about [1/2] to about [3/4] of the high common voltage.

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