JP2006154772A - Liquid crystal display, liquid crystal driver, and its operating method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce the power consumption of a liquid crystal driver driving a liquid crystal display panel by inversion driving using a common constant driving method. <P>SOLUTION: A liquid crystal display apparatus of the present invention is composed of an LCD panel 1 including data lines 11, and an liquid crystal driver 2. The liquid crystal driver 12 includes: a positive drive circuit 23 outputting a positive data signal having positive polarity with respect to a ground level of the liquid crystal driver 2 to one of the data lines 11; and a negative drive circuit 24d outputting a negative data signal having negative polarity with respect to the ground level of the liquid crystal driver to another one of the data lines 11. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a liquid crystal display device, a liquid crystal driver, and an operation method thereof, and more particularly, to a liquid crystal driver that drives a liquid crystal display panel by inversion driving.

  The phenomenon that the life of the liquid crystal layer of each pixel is shortened when the pixels of the liquid crystal display panel are driven with a DC voltage is known as a burn-in phenomenon. A technique widely used to prevent this burn-in phenomenon is inversion driving (or AC driving). The inversion driving is a driving method that periodically inverts the polarity of the data signal supplied to each pixel. Inversion driving reduces the DC component of the voltage applied to the liquid crystal capacitance of the pixel and effectively prevents the occurrence of image sticking.

There are roughly two types of AC driving: a common constant driving method and a common inversion driving method. The common constant driving method is a driving method in which the potential of the common electrode (counter electrode) of the pixel (hereinafter referred to as “common potential V _COM ”) is kept constant and only the polarity of the data signal applied to the pixel is inverted. is there. On the other hand, the common inversion driving method is a driving method in which both the data signal and the common potential are inverted. The common constant driving method has an advantage that the potential stability of the common electrode is superior to the common inversion driving method. As widely known to those skilled in the art, the stability of the potential of the common electrode is important in terms of suppressing the occurrence of flicker. As will be described below, the present invention relates to a common constant drive method.

  One problem with the known common constant drive method is that it is necessary to operate a drive circuit for generating a data signal at a high power supply voltage. In a typical liquid crystal driver that employs the common constant driving method, it is necessary to supply a power supply voltage to the driving circuit that is at least twice the maximum voltage that can be applied to the liquid crystal capacitance. For example, when the maximum voltage that can be applied to the liquid crystal capacitor is 5V, it is necessary to supply a power supply voltage of 10V to the drive circuit.

  There are two disadvantages to operating the drive circuit at a high power supply voltage. One is the need to give a high breakdown voltage to the circuit elements constituting the drive circuit. Specifically, the circuit elements that constitute the drive circuit need to have a withstand voltage that is twice the maximum voltage that can be applied to the liquid crystal capacitance. The other is that the power consumption of the drive circuit increases. Since the power consumption of the drive circuit is approximately proportional to the power supply voltage, an increase in the power supply voltage causes an increase in power consumption.

A configuration of a liquid crystal driver for eliminating this disadvantage is disclosed in Patent Document 1. FIG. 1 is a block diagram showing a configuration of a known liquid crystal driver. The known liquid crystal driver separates a circuit system for generating a positive polarity data signal from a common potential V _COM and a circuit system for generating a negative polarity data signal by separating the circuit system described above. Addressing the problem.

  More specifically, the liquid crystal driver in FIG. 1 includes a polarity changeover switch group 101, a gradation voltage generation circuit 102, a positive side driver unit 103, a negative side driver unit 104, a polarity changeover switch group 105, and a polarity. A changeover switch control circuit 106 and a timing control circuit 107 are provided.

  The polarity switch group 101 is a circuit that transfers pixel data of each pixel to the positive driver unit 103 or the negative driver unit 104 in accordance with the polarity of the data signal supplied to the pixel.

Gradation voltage generating circuit 102, a positive-polarity gray scale potential (i.e., high gradation potential than the common potential V _COM) of the positive gradation voltage generation circuit 102a for generating a negative polarity gradation potential ( that, and a negative gradation voltage generating circuit 102b which generates a gradation voltage) lower than the common potential V _COM.

The positive side driver unit 103 is a circuit system for generating a positive polarity data signal using the grayscale potential supplied from the positive polarity grayscale potential generation circuit 102a with reference to the common potential _VCOM . For example, when the common potential V _COM is 5V and the maximum voltage applied to the liquid crystal capacitor is 5V, the positive driver unit 103 generates a data signal whose signal level is 5V to 10V. The positive side driver unit 103 includes a latch circuit 103a, a level shifter 103b, a D / A converter 103c, and a positive polarity drive circuit 103d. In order to generate a data signal having a signal level of 5V to 10V, a power supply voltage of 10V is supplied to the positive polarity drive circuit 103d. As the positive polarity drive circuit 103d, an operational amplifier is typically used.

The negative electrode side driver unit 104 uses the gray scale potential to be supplied from the negative gradation voltage generating circuit 102b, a circuit system for generating a negative polarity data signal to the common potential V _COM. For example, when the common potential V _COM is 5V and the maximum voltage applied to the liquid crystal capacitor is 5V, the negative side driver unit 104 generates a data signal whose signal level is 0V to 5V. The negative side driver unit 104 includes a latch circuit 104a, a level shifter 104b, a D / A converter 104c, and a negative polarity drive circuit 104d. In order to generate a data signal having a signal level of 0V to 5V, a power supply voltage of 5V is supplied to the negative polarity drive circuit 104d. An operational amplifier is typically used as the drive circuit 104d.

  The polarity switching switch group 105 is a circuit that outputs data signals generated by the positive driver unit 103 and the negative driver unit 104 to a desired output terminal 108. A data line of a liquid crystal display panel is connected to the output terminal 108, and a data signal is supplied to the data line via the output terminal 108.

The polarity changeover switch group 105 is provided with a switch 105a for precharging all output terminals 108 to a voltage that is ½ of the liquid crystal driving voltage _VLCD , that is, 5V.

  The liquid crystal driver of FIG. 1 is characterized by two circuit systems: a positive side driver unit 103 for generating a positive polarity data signal and a negative side driver unit 104 for generating a negative polarity data signal. It is to have. In this architecture, the power supply voltage supplied to the negative polarity drive circuit 104d of the negative side driver unit 104 is sufficient to be about the maximum voltage that can be applied to the liquid crystal capacitance; the negative polarity drive circuit 104d is applied to the liquid crystal capacitance. There is no need to apply a power supply voltage more than twice the maximum voltage that can be achieved. This effectively reduces the power consumption of the liquid crystal driver.

In addition, in this architecture, the circuit elements constituting the positive polarity driving circuit 103d of the positive polarity side driver unit 103 and the negative polarity driving circuit 104d of the negative polarity side driver unit 104 are the maximum that can be applied to the liquid crystal capacitance. Only a voltage about the voltage is applied. This is at the beginning of each horizontal period, because all of the output terminals 108 are precharged to 1/2 of the voltage of the liquid crystal drive voltage V _LCD by the switch 105a. The architecture of the liquid crystal driver in FIG. 1 can eliminate the necessity of giving a high breakdown voltage to the circuit elements constituting the positive polarity drive circuit 103d and the negative polarity drive circuit 104d.
Japanese Patent Laid-Open No. 10-62744

  However, according to the inventor's study, the liquid crystal driver disclosed in Patent Document 1 has room to further reduce power consumption. Certainly, the liquid crystal driver described above can reduce the power supply voltage supplied to the negative polarity drive circuit 104d, thereby reducing power consumption. However, the power supply voltage supplied to the positive polarity drive circuit 103d remains high.

  FIG. 2 is a diagram illustrating this using a specific example. For example, assume that the power supply voltage of the reference power supply of the liquid crystal driver is 3V, the common potential is 5V, and the maximum voltage that can be applied to the liquid crystal capacitance is 5V. In this case, the signal level of the data signal output from the negative polarity drive circuit 104d is in the range of 0V to 5V. Accordingly, the negative drive circuit 104d may be supplied with a power supply voltage of 5V by boosting the power supply voltage output from the reference power supply by a factor of 2, and regulating the boosted power supply voltage. On the other hand, the signal level of the data signal output from the positive side driver unit 103 is in the range of 5V to 10V. Therefore, it is necessary to supply the power supply voltage of 10V to the positive side drive circuit 103d by boosting the power supply voltage output from the reference power supply by four times and regulating the boosted power supply voltage. 1 reduces the power supply voltage supplied to the negative drive circuit 104d to 5V, but the power supply voltage supplied to the positive drive circuit 103d remains 10V. This is not preferable for reducing power consumption.

  Therefore, an object of the present invention is to further reduce the power consumption of a liquid crystal driver that drives a liquid crystal display panel by inversion driving using a common constant driving method.

  In order to solve the above problems, the present invention employs the means described below. In the description of technical matters constituting the means, in order to clarify the correspondence between the description of [Claims] and the description of [Best Mode for Carrying Out the Invention] Number / symbol used in the best mode for doing this is added. However, the added numbers and symbols should not be used for the interpretation of the technical scope of the invention described in [Claims].

  The liquid crystal display device according to the present invention includes a liquid crystal display panel (1) (1A) having a data line (11) and liquid crystal drivers (2) (2A). The liquid crystal driver (2) (2A) outputs a positive polarity data signal that is positive with respect to the ground potential of the liquid crystal driver (2) (2A) to one data line (11). And a negative side drive circuit (24d) for outputting a negative polarity data signal that is negative with respect to the ground potential to the other data line (11).

In the liquid crystal display device having such a configuration, the potential difference between the highest potential of the positive data signal and the ground potential of the liquid crystal driver (2) (2A), and the ground potential of the liquid crystal driver (2) (2A) Any potential difference from the lowest potential of the negative polarity data signal can be reduced to about the maximum voltage that can be applied to the liquid crystal capacitance (not twice the maximum voltage that can be applied to the liquid crystal capacitance). In other words, according to the above configuration, both the power supply voltage (V _DD ⁺ ) supplied to the positive side drive circuit (23d) and the power supply voltage (V _DD ⁻ ) supplied to the negative side drive circuit (24d). Ideally, it can be reduced to about the maximum voltage that can be applied to the liquid crystal capacitance. This effectively reduces the power consumption of the liquid crystal driver (2) (2A).

  The liquid crystal display device preferably includes precharge means (23e, 24e) for precharging the data lines of the liquid crystal display panels (1) (1A) to the ground potential. Such a configuration not only lowers the voltage applied to the circuit elements constituting the positive drive circuit (23d) and the negative drive circuit (24d), but also precharges the data line (11). Effectively reduce the required power. When the data line is precharged by electrically connecting the data line to a power supply line having a certain potential (typically a common potential), a current flows into the power supply line or a current flows out of the power supply line. In order to prevent the potential of the power supply line from fluctuating due to current flowing in and out, it is necessary to supply power to a circuit for maintaining the power supply line at the potential. However, the configuration of the liquid crystal display device of the present invention for precharging the data lines (11) of the liquid crystal display panels (1) and (1A) to the ground potential of the liquid crystal driver is for maintaining the power supply line at the precharged potential. No power is generated. Therefore, this configuration is suitable for reducing power consumption.

  The data lines of the liquid crystal display panel may be precharged by a diode element that connects the plurality of data lines to a ground terminal. Performing the precharge with a diode is effective for facilitating the timing control for the precharge operation and shortening the time required for the precharge. As the diode element, not only a general pn junction diode but also a transistor to which wiring is connected so as to function as a diode can be used.

  According to the present invention, it is possible to further reduce the power consumption of the liquid crystal driver that drives the liquid crystal display panel by inversion driving using the common constant driving method.

  Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description, the same components are referred to by the same or corresponding reference numerals. It should be noted that when it is necessary to distinguish the same component from each other, a suffix is added to the reference numeral, and the component is distinguished by this suffix.

1. First Embodiment (1) Overall Configuration of Liquid Crystal Display Device FIG. 3 is a diagram showing a configuration of a liquid crystal display device 10 according to a first embodiment of the present invention. The display device 10 includes a liquid crystal display panel 1 and a liquid crystal driver 2. The liquid crystal display panel 1 includes a data line 11, a gate line 12, and a pixel 13 provided at a position where the data line 11 and the gate line 12 intersect. The data line 11 is connected to the input terminal 16 and receives a data signal from the liquid crystal driver 2 via the input terminal 16. The gate line 12 is a signal line for selecting a row (line) of the pixels 13. When a data signal is written to the pixel 13, the gate line 12 corresponding to the selected line is activated. Each pixel 13 includes a TFT 13a, a pixel electrode 13b, and a common electrode 13c. Liquid crystal is filled between the pixel electrode 13b and the common electrode 13c, and the pixel electrode 13b and the common electrode 13c function as a liquid crystal capacitance. The potential of the common electrode 13c is maintained at the common potential _VCOM .

  The liquid crystal driver 2 is an integrated circuit that drives each pixel 13 of the liquid crystal display panel 1. The output terminal 3 of the liquid crystal driver 2 is connected to the input terminal 16 of the liquid crystal display panel 1 via the wiring 4. The data signal is supplied from the output terminal 3 of the liquid crystal driver 2 to the corresponding data line 11 via the wiring 4 and the input terminal 16, thereby driving the pixels 13 connected to the selected line.

  One feature of the present invention is that the liquid crystal driver 2 outputs a data signal having a positive polarity with respect to the ground potential of the liquid crystal driver 2 and a data signal having a negative polarity with respect to the ground potential to the data line 11. It is in the point where it is configured. Such a configuration makes it possible to lower the power supply voltage supplied to both the drive circuit that generates the positive polarity data signal and the drive circuit that generates the negative polarity data signal, as will be described in detail later. The power consumption of the liquid crystal driver 2 is effectively reduced. Hereinafter, a data signal having a positive polarity with respect to the ground potential of the liquid crystal driver 2 is referred to as a “positive polarity data signal”, and a data signal having a negative polarity with respect to the ground potential is simply referred to as a “negative polarity data signal”. There is a case.

(2) Configuration of Liquid Crystal Driver FIG. 4 outputs a positive data signal (which is positive with respect to the ground potential of the liquid crystal driver 2) and a negative data signal (which is negative with respect to the ground potential). It is a block diagram which shows the specific structure of the liquid crystal driver 2 for enabling.

  The liquid crystal driver 2 includes a polarity switching switch group 21, a gradation potential generation circuit 22, a positive side driver unit 23, a negative side driver unit 24, a polarity switching switch group 25, a polarity switching switch control circuit 26, A charge switch timing generation circuit 27, a timing control circuit 28, and an amplifier timing generation circuit 31 are provided.

  The polarity switch group 21 is a circuit that transfers pixel data of each pixel 13 to the positive driver unit 23 or the negative driver unit 24 in accordance with the polarity of the data signal to be supplied to the pixel 13. The polarity changeover switch group 21 is supplied with pixel data indicating the gradation of the pixel 13 of the selected line. The polarity changeover switch group 21 supplies pixel data of a pixel to be driven with a positive polarity data signal to the positive side drive circuit 23 out of the supplied pixel data, and a pixel to be driven with a negative polarity data signal. Are transferred to the negative side drive circuit 24.

  The gradation potential generation circuit 22 is a circuit that supplies gradation potentials corresponding to all gradation levels that a pixel can take to the positive driver section 23 and the negative driver section 24. The gradation voltage generation circuit 22 includes a positive gradation potential generation circuit 22a and a negative gradation potential generation circuit 22b. The positive gradation potential generation circuit 22 a supplies a gradation potential having a positive polarity with respect to the ground potential of the liquid crystal driver 2 to the positive driver section 23. On the other hand, the negative polarity gradation potential generation circuit 22 b supplies a gradation potential having a negative polarity to the negative side driver unit 24 with reference to the ground potential of the liquid crystal driver 2. The number of gradation potentials output from the positive gradation potential generation circuit 22a and the negative gradation potential generation circuit 22b is the same as the number of gradation levels that the pixel can take. When the number of gradation levels that a pixel can take is 64, the positive polarity gradation potential generation circuit 22a supplies 64 types of positive polarity gradation potentials to the positive side driver unit 23 to generate negative polarity gradation potentials. The circuit 22 b supplies 64 types of negative gradation potentials to the negative side driver unit 24.

  The positive side driver unit 23 is a circuit system that generates a positive polarity data signal in response to pixel data supplied thereto. The positive side driver unit 23 generates a positive data signal by using the positive gradation potential supplied from the positive gradation potential generation circuit 22a.

  Specifically, the positive side driver unit 23 includes a latch circuit 23a, a level shifter 23b, a D / A converter 23c, a positive side drive circuit 23d, and a precharge switch circuit 23e. The latch circuit 23a latches the pixel data received from the polarity changeover switch group 21 and outputs it to the level shifter 23b. The level shifter 23b converts the voltage level of the output of the latch circuit 23a so as to correspond to the input level of the D / A converter 23c.

  The D / A converter 23c performs D / A conversion on the pixel data received from the latch circuit 23a via the level shifter 23b, and outputs a gradation potential corresponding to the pixel data. More specifically, the D / A converter 23c selects and selects one of the positive gradation potentials supplied from the positive gradation potential generation circuit 22a in response to the pixel data received from the level shifter 23b. The gradation potential thus supplied is supplied to the positive electrode side drive circuit 23d.

  The positive side drive circuit 23d is a circuit for outputting a data signal corresponding to the pixel data; the positive side drive circuit 23d is a signal having a signal level corresponding to the gradation potential supplied from the D / A converter 23c. Is output to the output terminal 3 of the liquid crystal driver 2. An operational amplifier is typically used as the positive side drive circuit 23d. A signal output from the positive drive circuit 23 d is a positive data signal to be supplied to the data line 11.

  The precharge switch circuit 23 e is a circuit for precharging the data line 11 of the liquid crystal display panel 1 to the ground potential of the liquid crystal driver 2. The precharge switch circuit 23e precharges the data line 11 of the liquid crystal display panel 1 to the ground potential of the liquid crystal driver 2 when the precharge signal GND_SW sent from the precharge switch timing generation circuit 27 is activated. Precharging the data line 11 to the ground potential of the liquid crystal driver 2 means that the positive side drive circuit 23d has a high voltage (specifically, the maximum potential of the data signal having the positive polarity and the minimum potential of the data signal having the negative polarity. This is important in order to prevent the potential difference) from being applied.

  On the other hand, the negative side driver unit 24 is a circuit system that generates a negative polarity data signal in response to pixel data supplied thereto. The negative driver 24 generates a negative data signal using the grayscale potential supplied from the negative grayscale potential generation circuit 22b. The configuration of the negative side driver unit 24 is substantially the same as that of the positive side driver unit 23. The negative side driver unit 24 includes a latch circuit 24a, a level shifter 24b, a D / A converter 24c, a negative side driver circuit 24d, And a precharge switch circuit 24e. The main difference is that a negative gradation potential is supplied from the negative gradation potential generation circuit 22b to the D / A converter 24c, and the negative drive circuit 24d outputs a negative data signal.

The polarity changeover switch group 25 is a circuit for connecting the outputs of the positive-side driver unit 23 and the negative-side driver unit 24 to the output data line 11 of the data signal generated by them. For example, when a positive polarity data signal is to be output to the odd-numbered data lines 11 ₁ , 11 ₃ ..., The corresponding positive-side driver unit 23 outputs the odd-numbered data lines 11 ₁ , 11. ₃ ... are connected.

  The polarity changeover switch control circuit 26 is a circuit for instructing a connection relationship between the polarity changeover switch groups 21 and 25 and the polarity changeover switch group 21; the polarity changeover switch control circuit 26 supplies a polarity signal POL to the polarity changeover switch group 21. Thus, the connection relationship of the polarity changeover switch group 21 is switched so that the pixel data is transferred to the desired positive electrode side driver unit 23 and negative electrode side driver unit 24. In addition, the polarity changeover switch control circuit 26 supplies the switch control signal DOT_SW to the polarity changeover switch group 25 so that the data signal is output to the desired data line 11 so that the polarity changeover switch group 25 is connected. Switch.

  The precharge timing generation circuit 27 is a circuit for generating a precharge signal GND_SW for controlling the precharge switch circuits 23e and 24e.

  The amplifier timing generation circuit 31 is a circuit for controlling the operation timing of the positive side drive circuit 23d and the negative side drive circuit 24d, and generates an amplifier output control signal AMP_HIZ. When the amplifier output control signal AMP_HIZ is activated, the outputs of the positive side drive circuit 23d and the negative side drive circuit 24d are set to a high impedance state. When the amplifier output control signal AMP_HIZ is not activated, the positive side drive circuit 23d and the negative side drive circuit 24d output a data signal having a signal level corresponding to the pixel data.

  The timing control circuit 28 is a circuit that controls the operation timing of the polarity changeover switch group 21, the positive side driver unit 23, the negative side driver unit 24, and the polarity changeover switch group 25. Specifically, the timing control circuit 28 outputs a latch signal STB and controls the timing at which the latch circuits 23a and 23b latch pixel data. In addition, the timing control circuit 28 controls the polarity changeover switch circuit 26, the precharge timing generation circuit 27, and the amplifier timing generation circuit 31, and the polarity signal POL, the switch control signal DOT_SW, the precharge signal GND_SW, and the amplifier output The timing at which the control signal AMP_HIZ is switched is adjusted.

(3) Detailed Configuration of System for Outputting Data Signal FIG. 5 shows a positive side drive circuit 23d and a precharge switch circuit 23e of the positive side driver unit 23, and a negative side drive circuit 24d and a precharge switch of the negative side driver unit 24. 4 is a circuit diagram showing details of a circuit 24e and a polarity changeover switch group 25. FIG. In FIG. 5, only the portions related to the _two output terminals 3: output terminals 3 ₁ , 3 ₂ of the liquid crystal driver 2 are selectively illustrated, but the other portions have the same configuration. Will be readily understood by those skilled in the art.

The positive polarity drive circuit 23d includes a switch 23j and an amplifier 23k. The amplifier 23k functions as a voltage follower and generates a data signal having a signal level corresponding to the gradation potential supplied from the D / A converter 23c. The amplifier 23k is supplied with the positive power supply voltage V _DD ^+, and the amplifier 23k generates a positive data signal using the power supply voltage V _DD ⁺ . The power supply voltage V _DD ⁺ is typically 5V. The switch 23j is connected to the output of the amplifier 23k. The switch 23j is turned on / off in response to the amplifier output control signal AMP_HIZ. When the amplifier output control signal AMP_HIZ is activated, the switch 23j is turned off, and the output of the positive polarity drive circuit 23d is set to a high impedance state. When the amplifier output control signal AMP_HIZ is deactivated, the switch 23j is turned on, and the positive drive circuit 23d outputs a positive data signal.

Similarly, the negative drive circuit 24d includes a switch 24j and an amplifier 24k. The amplifier 24k functions as a voltage follower and generates a data signal having a signal level corresponding to the gradation potential supplied from the D / A converter 24c. The amplifier 24k is supplied with a negative power supply voltage V _DD ^−, and the amplifier 24k generates a negative data signal using the power supply voltage V _DD ⁻ . The power supply voltage V _DD ⁻ is typically −5V. The switch 24j is connected to the output of the amplifier 24k. The switch 24j is turned on / off in response to the amplifier output control signal AMP_HIZ. When the amplifier output control signal AMP_HIZ is activated, the switch 24j is turned off, and the output of the negative polarity drive circuit 24d is set to a high impedance state. When the amplifier output control signal AMP_HIZ is deactivated, the switch 23j is turned on, and the negative drive circuit 23d outputs a negative data signal.

The polarity switch group 25 includes switches 25a to 25d. Switch 25a is interposed between the output terminal of the output terminals 3 ₁ and the positive-side drive circuit 23d, the switch 25b is interposed between the output terminal of the output terminal 3 ₂ and the positive-side drive circuit 24d. On the other hand, the switch 25c is interposed between the output terminal of the output terminals 3 ₁ and the negative electrode side drive circuit 24d, the switch 25d is interposed between the output terminal of the output terminal 3 ₂ and the negative electrode side drive circuit 24d Yes. In response to the switch control signal DOT_SW sent from the polarity switching switch control circuit 26, the switches 25a to 25d switch the connection relationship between the output terminals 3 ₁ and 3 ₂ and the positive side drive circuit 23d and the negative side drive circuit 24d. . Specifically, when the switch control signal DOT_SW is activated, the output terminals 3 ₁ and 3 ₂ are connected to the positive side drive circuit 23d and the negative side drive circuit 24d, respectively. Such connection is used when a positive data signal and a negative data signal are output from the output terminals 3 ₁ and 3 ₂ to the data lines 11 ₁ and 11 ₂ , respectively. On the other hand, when the switch control signal DOT_SW is deactivated, the output terminals 3 ₁ and 3 ₂ are connected to the negative side drive circuit 24d and the positive side drive circuit 23d, respectively. Such a connection is used when a negative data signal and a positive data signal are output from the output terminals 3 ₁ and 3 ₂ to the data lines 11 ₁ and 11 ₂ , respectively.

  The precharge switch circuit 23e is composed of a switch 23f interposed between the output terminal of the positive drive circuit 23d and the ground terminal 23g. The switch 23f is turned on when the precharge signal GND_SW sent from the precharge switch timing generation circuit 27 is activated. Similarly, the precharge switch circuit 24e includes a switch 24f interposed between the output terminal of the negative side drive circuit 24d and the ground terminal 24g. The switch 24f is turned on when the precharge signal GND_SW sent from the precharge switch timing generation circuit 27 is activated. When the switches 23 f and 24 f are turned on, all the data lines 11 are precharged to the ground potential of the liquid crystal driver 2 regardless of the connection relationship of the polarity changeover switch group 25.

(4) Outline of Operation of Liquid Crystal Display Device of the Present Embodiment One feature of the liquid crystal display device 10 of the present embodiment is that the positive side driver unit 23 is positive with respect to the ground potential of the liquid crystal driver 2. The negative polarity data signal is generated, and the negative side driver unit 24 generates a negative polarity data signal that is negative with reference to the ground potential. Such an architecture makes it possible to reduce the power consumption of the liquid crystal driver 2. This is because, in this architecture, a high power supply voltage, specifically, a maximum that can be applied to the liquid crystal capacitance is applied to both the positive side drive circuit 23d and the negative side drive circuit 24d that generate the positive polarity data signal and the negative polarity data signal. This is because it is unnecessary to supply a power supply voltage that is twice or more the voltage.

For example, as shown in FIG. 6, for example, the power supply voltage of the reference power supply of the liquid crystal driver 2 is 3V, the common potential is 0V, and the maximum voltage that can be applied to the liquid crystal capacitance is 5V. Assume that In this case, since the signal level of the data signal output from the positive drive circuit 23d is in the range of 0V to 5V, the power supply voltage V _DD ⁺ to be supplied to the positive drive circuit 23d is 5V. On the other hand, since the signal level of the data signal output from the negative drive circuit 24d is in the range of −5V to 0V, the power supply voltage V _DD ⁻ to be supplied to the negative drive circuit 23d is −5V. As described above, in the liquid crystal display device 10 of the present embodiment, the power supply voltage (absolute value) supplied to both the positive polarity drive circuit 23d and the negative polarity drive circuit 23d is the maximum voltage that can be applied to the liquid crystal capacitance. In the known liquid crystal driver of FIG. 1, a power supply voltage more than twice the maximum voltage that can be applied to the liquid crystal capacitance is supplied to the drive circuit 103 d of the positive polarity driver unit 103. Note that there is a need. Since the power consumption of the positive electrode side drive circuit 23d and the negative electrode side drive circuit 24d is roughly proportional to the power supply voltage supplied thereto, eliminating the need to supply a high power supply voltage reduces the power consumption of the liquid crystal driver 2. It is effective for.

In the above-described operation, the common potential V _COM is selected to be the ground potential of the liquid crystal driver 2 or a potential close to the ground potential. Here, it should be noted that the common potential V _COM need not match the ground potential of the liquid crystal driver 2. Higher than the potential of the positive polarity data signal common potential V _COM, as long as the potential of the negative polarity data signal satisfies a common potential V condition that is lower than _COM, the common potential V _COM, identical to the ground potential of the liquid crystal driver 2 It is not limited to the potential. For example, when the potential range of the positive polarity data signal is 1.0 V to 5.0 V and the potential range of the negative polarity data signal is -5.0 V to -1.0 V, the common potential is V _COM can be −0.5V. The common potential V _COM being different from the ground potential of the liquid crystal driver 2 may be convenient for causing the pixel 13 to display a desired gradation. Specifically, by setting the common potential V _COM to a negative potential, when the gate line 12 is pulled down, the potential of the pixel electrode 13b becomes undesirably due to capacitive coupling between the gate line 12 and the pixel electrode 13b. Fluctuating effects can be canceled.

  Another feature of the liquid crystal display device 10 is that the data line 11 is precharged to the ground potential of the liquid crystal driver 2. Precharging is performed by the precharge switch circuits 23e and 24e. The precharge is important for preventing a high voltage from being applied to the elements constituting the positive electrode side drive circuit 23d and the negative electrode side drive circuit 24d. For example, when the data line 11 driven to a negative potential by the negative side drive circuit 24d is connected to the positive side drive circuit 23d, the element constituting the positive side drive circuit 23d is applied to the liquid crystal capacitance at the maximum. A voltage twice the maximum voltage that can be applied can be applied. However, if the data line 11 is precharged to the ground potential before connecting the data line 11 to the positive drive circuit 23d, a high voltage is not applied to the elements constituting the positive drive circuit 23d. The same applies to the negative side drive circuit 24d.

It is important that the potential at which the data line 11 is precharged is the ground potential of the liquid crystal driver 2 in order to reduce the power required for precharging; the common potential V _COM matches the ground potential of the liquid crystal driver 2. Note that even if not, the potential at which the data line 11 is precharged is the ground potential of the liquid crystal driver 2. As in the liquid crystal display device of FIG. 1, the data line is electrically connected to a power supply line having a certain potential (in the configuration of FIG. 1, ½ of the liquid crystal driving voltage or common potential V _COM ) that is not the ground potential. Accordingly, the configuration in which the data line is precharged needs to prevent the potential of the power supply line from fluctuating due to the current flowing into the power supply line at the time of precharging or the current flowing out of the power supply line. For this purpose, it is necessary to supply power to a circuit for maintaining the power supply line at the potential. On the other hand, the configuration of the liquid crystal display device 10 of the present embodiment that precharges the data line 11 of the liquid crystal display panel 1 to the ground potential of the liquid crystal driver 2 does not require power for maintaining the power supply line at the precharged potential. It is. The configuration of the present embodiment in which the data line 11 is precharged to the ground potential is effective for reducing power consumption.

(5) Specific Example of Operation of Liquid Crystal Display Device of the Present Embodiment FIG. 7 is a timing chart showing a preferred operation of the liquid crystal display device 10 of the present embodiment. In the operation of FIG. 7, dot inversion driving, that is, inversion driving in which the polarities of the data signals supplied to the pixels 13 adjacent in either the horizontal direction or the vertical direction are reversed is performed. It should be noted that in the dot inversion driving, the polarity of the data signal supplied to each data line 11 is inverted every horizontal period.

  When the m-th horizontal period starts, pixel data of pixels on the selected line is supplied to the polarity changeover switch group 21. In addition, the polarity signal POL and the switch signal DOT_SW are switched so that the connection relationship between the polarity switch groups 21 and 25 corresponds to the polarity of the data signal supplied to the data line 11 in the m-th horizontal period. Can be switched. Further, the latch signal STB is activated, and the pixel data is taken into the latch circuits 23 a and 24 a of the positive side driver unit 23 and the negative side driver unit 24.

  At the start of the m-th horizontal period, the precharge signal GND_SW is further activated. As a result, the switches 23f and 24f of the precharge switch circuits 23e and 24e are turned on, and all the data 11 are precharged to the ground potential of the liquid crystal driver 2. As described above, the data line 11 is precharged to the ground potential of the liquid crystal driver 2 in order to prevent a large voltage from being applied to the elements constituting the positive side drive circuit 23d and the negative side drive circuit 24d. is important.

After the precharge is completed, the positive electrode side drive circuit 23d and the negative electrode side drive circuit 24d are activated. When activated, the positive side drive circuit 23d and the negative side drive circuit 24d drive each data line 11 to a signal level corresponding to pixel data. In addition, the gate line 12 of the selected line is activated, and the driving voltage is written into the liquid crystal capacitance of the pixel 13 of the selected line. In the operation of FIG. 7, the data line 11 ₁ is driven in a positive polarity potential with respect to ground potential of the liquid crystal driver 2 in the m-th horizontal period.

  In the (m + 1) th horizontal period following the mth horizontal period, the data lines 11 are driven so that the polarity of each data line 11 in the (m + 1) th horizontal period is opposite to the polarity in the mth horizontal period. Specifically, the polarity signal POL and the switch signal DOT_SW are inverted at the start of the (m + 1) th horizontal period. As the polarity of the data signal supplied to the data line 11 is inverted, the data 11 is precharged to the ground potential of the liquid crystal driver 2, and the data constituting the positive side drive circuit 23d and the negative side drive circuit 24d is greatly increased. A voltage is prevented from being applied.

  In the operation of FIG. 7, the precharge signal GND_SW is activated at the start of each horizontal period and the data line 11 is precharged. However, when the polarity of the data signal supplied to the data line 11 is not inverted, The data line 11 does not need to be precharged. The fact that the data line 11 is not precharged when the polarity of the data signal supplied to the data line 11 is not inverted is rather effective in reducing the occurrence of extra power consumption.

For example, as shown in FIG. 8, in 2H inversion driving, that is, inversion driving in which the polarity of the data signal supplied to the pixels 13 is inverted in a cycle of 2 pixels in the vertical direction, in a cycle of 2 horizontal periods. The polarity of the data signal supplied to the data line 11 is inverted. Therefore, the data line 11 does not need to be precharged at the start of each horizontal period. For example, in the operation of FIG. 8, the data lines 11 _1, in the m-th horizontal period and the m + 1 horizontal period, either positive polarity data signal is supplied. In this case, precharging is not performed at the start of the (m + 1) th horizontal period. On the other hand, in the m + 2 horizontal period following the m + 1 horizontal period, the polarity of the data signal supplied to the data line 11 is inverted. At the start of the m + 2 horizontal period, the data line 11 is precharged, thereby preventing a large voltage from being applied to the elements constituting the positive side drive circuit 23d and the negative side drive circuit 24d.

  As shown in FIG. 9, V direction inversion driving, that is, inversion driving in which the polarities of data signals applied to the pixels 13 connected to the same data line 11 in the same frame period are the same. But the same is true. In the V direction inversion driving, the polarity of the data signal supplied to the data line 11 is not inverted in the middle of one frame period. Therefore, when V direction inversion driving is performed, after precharging is performed in the first horizontal period of a certain frame period, precharging is not performed in the remaining horizontal period of the frame period. Since the polarity of the data signal is inverted in the first horizontal period of the next frame period, precharge is performed at the start of the first horizontal period.

2. Second Embodiment (1) Configuration of Liquid Crystal Display Device in Present Embodiment FIG. 10A is a block diagram showing a configuration of a liquid crystal display device 10A in a second embodiment of the present invention. The basic configuration of the liquid crystal display device 10A of the present embodiment is the same as that of the liquid crystal display device 10 of the first embodiment; as shown in FIG. A positive polarity data signal is generated with reference to the ground potential of the liquid crystal driver, and the negative side driver unit 24 is configured to generate a negative polarity data signal with reference to the ground potential. Composed. As described above, such an architecture is effective in reducing the power consumption of the liquid crystal driver 2.

  The major difference is that time division driving is adopted in the second embodiment. Time-division driving is a driving method in which data signals are written to pixels in a time-division manner by sequentially selecting a plurality of data lines. Such time-division driving is a technique widely used in liquid crystal display devices because it can reduce the number of drive circuits that output data signals and can further reduce the number of wirings connecting the liquid crystal driver and the liquid crystal display panel. one of.

  With the adoption of time-division driving, the configuration of the liquid crystal display panel and the liquid crystal driver is changed from the first embodiment as follows: The liquid crystal display panel and the liquid crystal driver of the present embodiment whose configuration has been changed Hereinafter, they are described as a liquid crystal display panel 1A and a liquid crystal driver 2A.

In the present embodiment, the pixels 13 connected to the same data line 11 are associated with the same color. Specifically, the pixels 13 connected to the data lines 11 ₁ , 11 ₄ ,... Are associated with red (R) and connected to the data lines 11 ₂ , 11 ₅ ,. The pixel 13 is associated with green (G), and the pixel 13 connected to the data lines 11 ₃ , 11 ₆ ,... Is associated with blue (B). Pixel 13 associated with red is used to display red, pixel 13 associated with green is used to display green, and pixel 13 associated with blue is Used to display blue. Hereinafter, in order to clarify the correspondence between the pixels 13 and the colors, the pixels 13 associated with red, green, and blue may be referred to as R pixels 13, G pixels 13, and B pixels 13, respectively. is there.

In addition, the liquid crystal display panel 1A is provided with one input terminal 16 for each of the plurality of data lines 11. In the present embodiment, one input terminal 16 is provided for the three data lines 11. For example, in response to the data lines ₁₁ 1 to 11 ₃ are input terminals 16 ₁ provided, the data line ₁₁ 4-11 ₆ corresponding input terminals 16 ₂ are provided.

Further, a selector 17 is provided between the data line 11 and the input terminal 16 for selecting a desired data line from the three data lines 11 and connecting it to the corresponding input terminal 16. For example, the selector 17 ₁ connects a desired data line among the data lines 11 _{1 to} 11 ₃ to the input terminal 16 ₁ , and the selector 17 ₂ connects the desired data line among the data lines 11 _{4 to} 11 _6. and it is configured to be connected to the input terminal 16 _2. The selector 17 connects the desired data line 11 to the corresponding input terminal 16 in response to the control signals RSW, GSW, BSW supplied from the liquid crystal driver 2. Each selector 17 includes three switches: an R switch 18, a G switch 19, and a B switch 20, as shown in FIG. The R switch 18 is interposed between the data line 11 connected to the R pixel 13 and the input terminal 16, and is turned on when the control signal RSW sent from the liquid crystal driver 2A is activated. Similarly, the G switch 19 is interposed between the data line 11 connected to the G pixel 13 and the input terminal 16, and is turned on when the control signal GSW sent from the liquid crystal driver 2A is activated. . Further, the B switch 20 is interposed between the data line 11 connected to the B pixel 13 and the input terminal 16, and is turned on when the control signal BSW sent from the liquid crystal driver 2A is activated.

  Returning to FIG. 10, the liquid crystal driver 2 </ b> A of the second embodiment is different from the liquid crystal driver 2 of the first embodiment in the following points: First, the positive side driver unit 23 and the negative side driver unit 24. The configuration is changed so that data signals can be supplied to the pixels 13 connected to the plurality of data lines 11. Specifically, the configuration of the latch circuits 23 a and 24 a of the positive side driver unit 23 and the negative side driver unit 24 is changed so as to hold pixel data of pixels corresponding to the plurality of data lines 11. Furthermore, RGB selectors 23h and 24h for selecting pixel data held in the latch circuits 23a and 24a are provided in the positive driver 23 and the negative driver 24, respectively. The RGB selectors 23h and 24h supply pixel data corresponding to the data line 11 selected by the selector 17 to the D / A converters 23c and 24c via the level shifters 23b and 24b.

  Second, the liquid crystal driver 2A is additionally provided with an RGB switch timing generation circuit 29 and an RGB selector control circuit 30. The RGB switch timing generation circuit 29 is a circuit that generates control signals RSW, BSW, and GSW that are used to select the data line 11; the RGB switch timing generation circuit 29 has a desired data line 11 connected to the input terminal 16. Control signals RSW, BSW, and GSW are generated so as to be connected to each other. The RGB selector control circuit 30 is a circuit that controls the RGB selectors 23h and 24h; the RGB selector control circuit 30 supplies control signals to the RGB selectors 23h and 24h, and pixel data corresponding to the selected data line 11 Are selected by the RGB selectors 23h and 24h. The data signal is generated in response to the pixel data selected by the RGB selectors 23h and 24h.

(2) Overview of Operation of Liquid Crystal Display Device of the Present Embodiment In this embodiment, time-division driving and dot inversion driving are used together for driving the liquid crystal display panel 1A. That is, by sequentially selecting the three data lines 11 connected to the same input terminal 16, data signals are written to the pixels 13 in a time division manner. At this time, the data signal is written so that the polarity of the data signal written to the pixels 13 adjacent in the vertical direction and the horizontal direction is reversed. It should be noted that in the dot inversion driving, the potential generated in the adjacent data line 11 is reversed.

  In connection with the sequential selection of the data lines 11, in this embodiment, precharging is performed by a procedure different from that in the first embodiment. First, the precharge of the data line 11 is performed with all of the R switch 18, G switch 19 and B switch 20 turned on as shown in FIG. 11; in other words, all data In a state where the line 11 is connected to the corresponding input terminal 16, the switches 23g and 24g of the precharge switch circuits 23e and 24e are turned on. As a result, all the data lines 11 are simultaneously precharged to the ground potential of the liquid crystal driver 2A.

Precharging all the data lines 11 at the same time is advantageous for reducing noise for the following reason. In the dot inversion driving, the potentials generated on the adjacent data lines 11 are reversed, so that the charges on the two data lines among the data lines 11 connected to one input terminal 16 are almost canceled. . Therefore, the charges flowing into each of the precharge switch circuits 23e and 23e are only charges flowing from one data line 11 at most. For example, if the data lines ₁₁ 1, 11 ₃ are a positive potential is generated in a state where a negative potential to the data line 11 ₂ is generated, the precharging of the data lines ₁₁ 1 to 11 ₃ are performed, the data line 11 _1, 11 one charge of the _three, and the data line 11 _second charge, cancel substantially. Accordingly, the electric charge flowing into the ground terminal 23g of the precharge switch 23e is generally only the electric charge accumulated in one of the data lines 11 _{1 to} 11 ₃ . This suppresses fluctuations in the ground potential of the liquid crystal driver 2A and effectively reduces noise.

The second difference is that, in addition to the precharge of the data line 11, the input terminal 16 (and the wiring 4 connected thereto) of the liquid crystal display panel 1A is precharged. This is because in the second embodiment, the potential of the input terminal 16 needs to be inverted every time the data line 11 is switched. For example, a positive polarity data signal supplied through the input terminal 16 ₁ to the data line 11 _1, then, consider the case where negative data signals to the data lines 11 ₂ is supplied. After the positive polarity data signal to the data line 11 ₁ is supplied, the input terminal 16 ₁ is positive potential remaining. In a state where the potential of the positive input terminal 16 ₁ is left, connecting the input terminal 16 ₁ to the negative polarity driving circuit 24d, there is a possibility that a large voltage is applied to the element of the negative polarity driving circuit 24d. Accordingly, before connecting the input terminals 16 ₁ to the negative polarity driving circuit 24d, it is necessary to precharge the input terminals 16 ₁ to the ground potential of the LCD driver 2A. As shown in FIG. 12, the input terminal 16 is precharged in a state where all of the R switch 18, G switch 19 and B switch 20 are turned off, and the switches 23g and 24g of the precharge switch circuits 23e and 24e. Is done by turning on.

  In order to shorten the period necessary for sequentially driving all the data lines 11, the precharge time of the input terminal 16 is preferably shorter than the precharge time of the data line 11; The precharge time of the input terminal 16 refers to the time during which the input terminal 16 continues to be connected to the ground terminals 23g and 24g of the liquid crystal driver 2A in a state where the data line 11 is electrically disconnected from the input terminal 16. 11 is a time during which the data line 11 is continuously connected to the ground terminals 23g and 24g of the liquid crystal driver 2A. Certainly, the precharge time of the input terminal 16 needs only to be sufficient to precharge the input terminal 16 to the ground potential, but the precharge time of the input terminal 16 is the precharge time of the data line 11. It is not a problem in operation to be shorter. This is because the capacity of the input terminal 16 of the liquid crystal display panel 1 </ b> A and the wiring 4 connected to the input terminal 16 is extremely smaller than the capacity of the data line 11. Typically, the capacity of each data line 11 is several tens of pF, whereas the capacity of the input terminal 16 of the liquid crystal display panel 1A and the wiring 4 connected thereto is several pF in total. The fact that the precharge time of the input terminal 16 is made shorter than the precharge time of the data line 11 rather shortens the time required to drive all the data lines 11 sequentially, and thus the allowable minimum. This is preferable because the horizontal period can be reduced.

(3) Specific Example of Operation of Liquid Crystal Display Device of this Embodiment FIG. 13 is a timing chart showing a preferred operation of the liquid crystal display device 10A of this embodiment.
When the m-th horizontal period starts, pixel data of pixels on the selected line is supplied to the polarity changeover switch group 21. In addition, the polarity signal POL and the switch signal DOT_SW are switched. Thereby, the connection relationship of the polarity changeover switch group 21 is switched to correspond to the polarity of the data signal supplied to each data line 11 in the m-th horizontal period, and the connection relationship of the polarity changeover switch group 25 is changed to the mth. Switching is performed so as to correspond to the polarity of the data signal to be supplied to the data line 11 connected to the R pixel 13 in the horizontal period. Further, the latch signal STB is activated, and the pixel data is taken into the latch circuits 23 a and 24 a of the positive side driver unit 23 and the negative side driver unit 24.

  At the start of the m-th horizontal period, all of the precharge signal GND_SW and the control signals RSW, GSW, and BSW are activated. As a result, as shown in FIG. 11, the R switch 18, G switch 19, B switch 20 of all the selectors 17 and the switches 23f, 24f of the precharge switch circuits 23e, 24e are turned on, and all the data 11 is precharged to the ground potential of the liquid crystal driver 2. As described above, the data line 11 is precharged to the ground potential of the liquid crystal driver 2 in order to prevent a large voltage from being applied to the elements constituting the positive side drive circuit 23d and the negative side drive circuit 24d. is important.

  After the precharge is completed, the data signal is supplied to the data line 11 connected to the R pixel 13, and the data signal is written to the R pixel 13 of the selected line. Specifically, pixel data corresponding to the R pixel 13 is selected by the RGB selectors 23h and 24h, and the positive side drive circuit 23d and the negative side drive circuit 24d generate data signals corresponding to the selected pixel data. The polarity of the data signal generated by the positive side drive circuit 23d is positive with respect to the ground potential of the liquid crystal driver 2, and the polarity of the data signal generated by the negative side drive circuit 24d is equal to the ground potential of the liquid crystal driver 2. Note that this is negative. Further, as shown in FIG. 13, the control signal RSW is selectively activated, and the data line 11 connected to the R pixel 13 is connected to the input terminal 16; the control signals GSW and BSW are not Activated. Thereby, the data signal generated by the positive side drive circuit 23 d and the negative side drive circuit 24 d is supplied to the data line 11 connected to the R pixel 13. In addition, the gate line 12 corresponding to the selected line is activated, and a desired data signal is written to the R pixel 13 of the selected line.

  Subsequently, the data signal is written to the G pixel 13 of the selected line. Writing of a data signal to the G pixel 13 of the selected line is first started by precharging the input terminal 16. Specifically, the precharge signal GND_SW is activated in a state where all of the control signals RSW, GSW, and BSW are deactivated. Thus, as shown in FIG. 12, the input terminal 16 is connected to the ground terminal of the liquid crystal driver 2A in a state where the data line 11 is disconnected from the input terminal 16, and the input terminal 16 (and the input terminal 16 is connected thereto). The wiring 4) is precharged to the ground potential of the liquid crystal driver 2A. Note that in this precharge, the data line 11 is not precharged. As described above, the precharge time of the input terminal 16 is shorter than the precharge time of the data line 11.

  As shown in FIG. 13, during the precharge of the input terminal 16, the polarity signal POL and the switch signal DOT_SW are switched. Thereby, the connection relationship of the polarity changeover switch group 25 is switched so as to correspond to the polarity of the data signal to be supplied to the data line 11 connected to the G pixel 13 in the m-th horizontal period.

  Subsequently, a data signal is supplied to the data line 11 connected to the G pixel 13. Specifically, pixel data corresponding to the G pixel 13 is selected by the RGB selectors 23h and 24h, and the positive side drive circuit 23d and the negative side drive circuit 24d generate data signals corresponding to the selected pixel data. To do. Further, the control signal GSW is selectively activated, and the data line 11 connected to the G pixel 13 is connected to the input terminal 16. Thereby, the data signal generated by the positive side drive circuit 23 d and the negative side drive circuit 24 d is supplied to the data line 11 connected to the G pixel 13. In addition, the gate line 12 corresponding to the selected line is activated, and a desired data signal is written to the G pixel 13 of the selected line.

  Subsequently, the data signal is written to the B pixel 13 of the selected line. The procedure is that the pixel data corresponding to the B pixel 13 is selected by the RGB selectors 23h and 24h, and the control signal BSW is selectively activated, and the data signal is written to the G pixel 13 described above. Is the same.

  In other horizontal periods following the mth horizontal period, data signals are written in the same procedure.

  As described above, in the liquid crystal display device according to the second embodiment, the liquid crystal driver generates a data signal having a positive polarity with respect to the ground potential of the liquid crystal driver; And a negative polarity drive circuit that generates a data signal having a negative polarity with respect to the ground potential. Such an architecture effectively reduces the power consumption of the liquid crystal driver.

  Further, the data lines of the liquid crystal display panel are precharged to the ground potential of the liquid crystal driver. Such an architecture prevents a high voltage from being applied to the elements constituting the positive polarity drive circuit and the negative polarity drive circuit, and effectively reduces the power required for precharging.

  In the present embodiment, it is not necessary to precharge the input terminal 16 every time a data signal is written. It is also possible to precharge all data lines 11 and input terminals 16 only at the start of each horizontal period. In the operation in which precharging is performed only at the start of each horizontal period, all the data lines 11 are sequentially driven although the allowable breakdown voltage of the circuit elements constituting the positive side drive circuit 23d and the polarity changeover switch group 25 is somewhat higher. This is effective for shortening the period required for this purpose.

3. Third Embodiment FIG. 14 is a diagram showing a configuration of a liquid crystal driver 2B mounted on a liquid crystal display device according to a third embodiment of the present invention. The liquid crystal display device of the third embodiment has substantially the same configuration as the liquid crystal display device 10 of the first embodiment; the difference is that in the third embodiment, the positive-side driver unit 23, the negative electrode Instead of the precharge switch circuits 23e and 24e of the side driver unit 24, precharge diode circuits 41 and 42 are used.

  As shown in FIGS. 15A and 15B, the precharge diode circuit 41 includes a diode element 43 and a ground terminal 45. The cathode of the diode element 43 is connected to the node N1 connected to the output of the positive side drive circuit 23d, and the anode is connected to the ground terminal 45. Similarly, the precharge diode circuit 42 includes a diode element 44 and a ground terminal 46. The cathode of the diode element 44 is connected to the ground terminal 46, and the anode is connected to the node N2 connected to the output of the negative side drive circuit 24d.

  One feature of the liquid crystal display device of this embodiment is that the data line 11 and the input terminal 16 are precharged via the diode elements 43 and 44. The advantage of using the diode elements 43 and 44 for precharging is that the timing control becomes easy and the time required for precharging can be shortened. Hereinafter, advantages of using the diode elements 43 and 44 will be described in detail.

  Referring to FIG. 7, in the first embodiment, amplifier output control signal AMP_HIZ and precharge signal GND_SW are activated during precharge. Although FIG. 7 shows that both are activated simultaneously, strictly speaking, after the amplifier output control signal AMP_HIZ is activated first and the switches 23j and 24j are turned off, the precharge signal GND_SW is It must then be activated. This is because otherwise a high voltage can be applied to the output terminals of the amplifiers 23k and 24k. Furthermore, at the end of the precharge, after the precharge signal GND_SW is deactivated, the amplifier output control signal AMP_HIZ is deactivated and the switches 23j and 24j need to be turned on. Otherwise, the output terminals of the amplifiers 23k and 24k are electrically connected to the ground terminals 23g and 24g. As described above, in the liquid crystal display device of the first embodiment, it is necessary to appropriately control the timings of the amplifier output control signal AMP_HIZ and the precharge signal GND_SW.

  However, in order to appropriately control the timing of the amplifier output control signal AMP_HIZ and the precharge signal GND_SW, the time required for precharging (that is, until the amplifier output control signal AMP_HIZ is activated and then deactivated) Time). The long time required for precharging is particularly problematic when one horizontal period needs to be shortened, for example, when the number of lines of the liquid crystal panel 1 is large.

  The liquid crystal display device of this embodiment makes it unnecessary to generate the precharge signal GND_SW by using the diode elements 43 and 44 for precharging. Such a configuration facilitates timing control and effectively shortens the time required for precharging. Hereinafter, the operation of the liquid crystal display device of this embodiment will be described in detail.

Referring to FIG. 16, in the initial state, the polarity signal POL and the switch signal DOT_SW are inactivated, and the data lines 11 ₁ is driven to a negative potential, drive data lines 11 ₂ to a positive potential Suppose that it was done. In response to the switch signal DOT_SW is deactivated, polarity switching switches 25 connects the output of the positive-side drive circuit 23d of the positive polarity driving unit 23 to the data lines 11 _2, negative driver portion 24 connecting the output of the negative electrode side drive circuit 24d to the data line 11 _1.

  When the m-th horizontal period starts, the amplifier output control signal AMP_HIZ is activated. As a result, the switches 23j and 24j of the positive electrode side drive circuit 23d and the negative electrode side drive circuit 24d are turned off, and the output of the positive electrode side drive circuit 23d is set to a high impedance state.

  Further, the pixel data of the pixels on the selected line is supplied to the polarity changeover switch group 21. In addition, the polarity signal POL is switched. By inverting the polarity signal POL, the connection relationship of the polarity switching switch group 21 is switched so as to correspond to the polarity of the data signal supplied to the data line 11 in the m-th horizontal period. Further, the latch signal STB is activated, and the pixel data is taken into the latch circuits 23 a and 24 a of the positive side driver unit 23 and the negative side driver unit 24.

In addition, when the switch signal DOT_SW is activated, the connection relationship between the positive polarity driver unit 23 and the negative polarity driver unit 24 and the data lines 11 ₁ and 11 ₂ is switched. Specifically, as shown in Figure 15, polarity switching switch group 25 connects the data line 11 ₁ to the output of the positive-side drive circuit 23d of the positive-side driver 23, the data lines 11 ₂ negative The output is connected to the output of the negative side drive circuit 24d of the side driver unit 24.

By switching the connection relationship of the polarity changeover switch group 25, the data lines 11 ₁ and 11 ₂ are automatically precharged via the diode elements 43 and 44. Specifically, at the start of the m horizontal periods from the data line 11 ₁ has a negative potential, the diode element 43 by switching the connection of the polarity changeover switch group 25 is forward biased. Accordingly, the data lines 11 _1, is electrically connected to the ground terminal 45 via the diode element 43, the negative charge on the data lines 11 ₁ flows to the ground terminal 45 via the diode element 43. That is, the data lines 11 _1, to the ground potential, strictly speaking, are precharged to the potential -.phi _F. Here, phi _F is the forward voltage of the diode element 43.

Similarly, at the beginning of the m horizontal period data lines 11 ₂ because it has a positive potential, FIG. As shown in 15, the data line 11 by switching the connection of the polarity changeover switches 25 ₂ The diode element 44 connected between the ground terminal 46 and the ground terminal 46 is forward-biased. Accordingly, the data lines 11 ₂ is electrically connected to the ground terminal 46 through the diode element 44, the positive charge on the data lines 11 ₂ flows to the ground terminal 46 through the diode element 44. Accordingly, as shown in Figure 16, the data lines 11 _2, the ground potential, strictly speaking, it is precharged to the potential + phi _F. Here, phi _F is the forward voltage of the diode element 44.

  As described above, automatically precharging the data line 11 via the diode elements 43 and 44 is effective for shortening the time required for precharging.

After the precharge is completed, the positive electrode side drive circuit 23d and the negative electrode side drive circuit 24d are activated. Specifically, the amplifier output control signal AMP_HIZ is deactivated, and the positive side drive circuit 23d and the negative side drive circuit 24d start to drive the corresponding data line 11 to the signal level corresponding to the pixel data. In addition, the gate line 12 of the selected line is activated, and the driving voltage is written into the liquid crystal capacitance of the pixel 13 of the selected line. In the operation of FIG. 16, the data lines 11 _1, in the m-th horizontal period is driven to a potential which is positive with respect to the ground potential of the liquid crystal driver 2, the data lines 11 ₂ is a negative polarity with respect to ground potential Driven to potential.

  In the (m + 1) th horizontal period following the mth horizontal period, the data line 11 is operated in the same procedure except that the data line 11 is driven so that the polarity of each data line 11 is opposite to the polarity in the mth horizontal period. Is driven.

Specifically, the polarity signal POL and the switch signal DOT_SW are inverted at the start of the (m + 1) th horizontal period, and the amplifier output control signal AMP_HIZ is activated. Thus, as shown in FIG. 15B, the positive side driving circuit 23d, the output of the negative-side drive circuit 24d is set to high impedance, data line 11 ₁ to the anode of the diode 44, the data line 11 ₂ is electrically connected to the cathode of the diode 43. At the beginning of the (m + 1) -th horizontal period data line 11 ₁ has a positive potential, since the data lines 11 ₂ has a negative potential, the diode 43 is forward biased. Accordingly, the data lines 11 _1, is electrically connected to the ground terminal 46 through the diode element 44, the data lines 11 ₂ is electrically connected to the ground terminal 45 via the diode element 43, the data lines 11 ₁ , 11 ₂ are precharged. The potentials of the data lines 11 ₁ and 11 ₂ during the precharge are the potential + φ _F and the potential −φ _F , respectively.

After the precharge is completed, the positive electrode side drive circuit 23d and the negative electrode side drive circuit 24d are activated. Specifically, the amplifier output control signal AMP_HIZ is deactivated, and the positive side drive circuit 23d and the negative side drive circuit 24d start to drive the corresponding data line 11 to the signal level corresponding to the pixel data. In addition, the gate line 12 of the selected line is activated, and the driving voltage is written into the liquid crystal capacitance of the pixel 13 of the selected line. In the operation of FIG. 16, the data lines 11 _1, in the (m + 1) -th horizontal period is driven to a potential which is negative with respect to ground potential of the liquid crystal driver 2, the data lines 11 ₂ is a positive polarity with respect to ground potential Driven to potential.

  In other horizontal periods following the mth horizontal period, data signals are written in the same procedure.

  As described above, in the third embodiment, the data line is precharged by being connected to the ground terminal via the diode element. By using the diode element, the data line is automatically precharged, which makes it easy to control the operation timing during the precharge. This is effective for shortening the time required for precharging.

  Note that in the present embodiment, the term “diode element” is used to include not only a commonly used pn junction diode but also a transistor that functions as a diode. For example, as shown in FIG. 17, as the diode element 43, an N-channel MOS transistor 43A in which both the gate and the back gate (substrate terminal) are grounded can be used. In this case, the drain of the N-channel MOS transistor 43A is connected to the ground terminal 45, and the source is connected to the node N1 connected to the output of the positive drive circuit 23d. A parasitic diode between the substrate and the source of the N-channel MOS transistor 43A functions as a diode for precharging. As the diode element 44, a P-channel MOS transistor 43A in which both the gate and the back gate (substrate terminal) are grounded can be used. In this case, the drain of the P-channel MOS transistor 43A is connected to the ground terminal 46, and the source is connected to the node N2 connected to the output of the negative side drive circuit 24d. A parasitic diode between the source of the P-channel MOS transistor 44A and the substrate functions as a diode for precharging.

  If necessary, the N-channel MOS transistor 43A and the P-channel MOS transistor 44A in FIG. 17 can function as a switch for precharging instead of a diode. Specifically, if the gate of the N-channel MOS transistor 43A is set to the “High” level and the gate of the P-channel MOS transistor 44A is set to the “Low” level, the N-channel MOS transistor 43A and the P-channel MOS transistor 44A are turned on. The N channel MOS transistor 43A and the P channel MOS transistor 44A also function as switches for precharging the data line 11 to the ground potential. Here, it should be noted that the “Low” level at which the gate of the P-channel MOS transistor 44A is driven needs to be a negative potential.

Such an operation is effective for completely precharging the data line 11 to the ground potential. N-channel MOS transistor 43A, when the P-channel MOS transistor 44A functions as a diode, as described above, the data line 11 is not strictly a ground potential is precharged to the potential ± phi _F. By turning on N channel MOS transistor 43A and P channel MOS transistor 44A, data line 11 can be completely precharged to the ground potential when necessary.

4). Fourth Embodiment FIG. 18 is a block diagram showing a configuration of a liquid crystal driver 2C used in a liquid crystal display device according to a fourth embodiment of the present invention. The basic configuration of the liquid crystal display device of this embodiment is substantially the same as that of the liquid crystal display device 10 of the second embodiment; the positive side driver section 23 of the liquid crystal driver 2C is based on the ground potential of the liquid crystal driver 2. The negative driver unit 24 is configured to generate a positive polarity data signal having a positive polarity, and the negative side driver unit 24 is configured to generate a negative polarity data signal having a negative polarity with reference to the ground potential. Furthermore, like the liquid crystal driver 2A of the second embodiment, the liquid crystal driver 2C of this embodiment has a configuration corresponding to time-division driving.

  The difference is that, in the positive side driver unit 23 and the negative side driver unit 24, precharge diode circuits 51 and 52 are used instead of the precharge switch circuits 23e and 24e. However, in this embodiment, unlike the precharge diode circuits 41 and 42 of the third embodiment, the precharge diode circuits 51 and 52 operate in response to a pair of precharge signals GND_SWN and GND_SWP. I want to be. The precharge signals GND_SWN and GND_SWP are generated by the precharge timing generation circuit 27.

  Note that the precharge signals GND_SWN and GND_SWP have different signal level ranges. In the precharge signal GND_SWN, a predetermined positive potential (for example, + 5V) is defined as “High” level, and the ground potential of the liquid crystal driver 2C is defined as “Low” level. On the other hand, in the precharge signal GND_SWP, the ground potential of the liquid crystal driver 2C is defined as “High” level, and a predetermined negative potential (for example, −5 V) is defined as “Low” level.

  FIG. 19 is a circuit diagram showing a configuration of precharge diode circuits 51 and 52. The precharge diode circuit 51 includes an N channel MOS transistor 53 and a ground terminal 55. The N-channel MOS transistor 53 has its drain connected to the ground terminal 55 and its source connected to the node N1 connected to the output of the positive drive circuit 23d. The back gate (substrate terminal) of the N channel MOS transistor 53 is grounded. A precharge signal GND_SWN is supplied to the gate of the N channel MOS transistor 53.

The N-channel MOS transistor 53 of the precharge diode circuit 51 functions as an on / off switch for performing precharge in response to the precharge signal GND_SWN, and further functions as a diode for automatically performing precharge. When the precharge signal GND_SWN is set to a “High” level (for example, +5 V), the N-channel MOS transistor 53 is turned on, whereby the data line 11 is precharged to the ground potential. On the other hand, when the precharge signal GND_SWN is set to the “Low” level (that is, the ground potential), the N-channel MOS transistor 53 functions as a diode due to the presence of a parasitic diode between the source and the substrate. That is, when the potential of the node N1 becomes lower than the ground potential, a forward bias is applied to the parasitic diode, and the ground terminal 55 and the node N1 are electrically connected. Thus, the data line 11 to the ground potential, strictly are precharged to the potential -.phi _F.

  Similarly, the precharge diode circuit 52 includes a P-channel MOS transistor 54 and a ground terminal 56. The P channel MOS transistor 54 has its drain connected to the ground terminal 56 and its source connected to the node N2 connected to the output of the negative side drive circuit 24d. The back gate (substrate terminal) of the N channel MOS transistor 53 is grounded. A precharge signal GND_SWP is supplied to the gate of the P channel MOS transistor 54.

Similar to the N-channel MOS transistor 53, the P-channel MOS transistor 54 functions as an on / off switch for precharging in response to the precharge signal GND_SWP, and also serves as a diode for automatically performing precharging. Function. When the precharge signal GND_SWP is set to the “High” level (for example, +5 V), the P-channel MOS transistor 54 is turned on, whereby the data line 11 is precharged to the ground potential. On the other hand, when the precharge signal GND_SWP is set to the “Low” level (that is, the ground potential), the P-channel MOS transistor 54 functions as a diode due to the presence of a parasitic diode between the source and the substrate. That is, when the potential of the node N2 becomes higher than the ground potential, a forward bias is applied to the parasitic diode, and the ground terminal 56 and the node N2 are electrically connected. Thus, the data line 11 to the ground potential, strictly are precharged to the potential + phi _F.

  The liquid crystal display device of this embodiment is configured to cause the N-channel MOS transistor 53 and the P-channel MOS transistor 54 to function as both an on / off switch and a diode for the following technical reasons.

Precharging the data line 11 by causing the N-channel MOS transistor 53 and the P-channel MOS transistor 54 to function as diodes facilitates the timing control of the precharge operation as described in the third embodiment. There is an advantage of becoming. However, in the precharge via the diode, the data line 11 is not completely precharged to the ground potential; the data line 11 is precharged to the potential + φ _F or the potential −φ _F. This is not preferable for reducing the voltage applied to the circuit elements constituting the positive side drive circuit 23d, the negative side drive circuit 24d, and the polarity changeover switch group 25.

  Conversely, when the data line 11 is precharged by causing the N channel MOS transistor 53 and the P channel MOS transistor 54 to function as an on / off switch in response to the precharge signals GND_SWN and GND_SWP, the data line 11 is almost completely precharged to the ground potential. Charged. However, functioning the N-channel MOS transistor 53 and the P-channel MOS transistor 54 as an on / off switch is not suitable for controlling the operation timing during the precharge operation.

  The liquid crystal display device of this embodiment effectively utilizes both the function as an on / off switch and the advantage of the function as a diode. Specifically, when the data line 11 (and the input terminal 16) is precharged at the start of each horizontal period, the N-channel MOS transistor 53 and the P-channel MOS transistor 54 function as an on / off switch. On the other hand, when only the input terminal 16 is precharged in the middle of each horizontal period, the N-channel MOS transistor 53 and the P-channel MOS transistor 54 function as diodes. As described in the second embodiment, the time required for precharging only the input terminal 16 is shorter than the time required for precharging the data line 11. Therefore, severe operation timing control is required for precharging only the input terminal 16. Therefore, when only the input terminal 16 is precharged, the N channel MOS transistor 53 and the P channel MOS transistor 54 are operated so as to function as diodes. On the other hand, when the data line 11 is precharged, the N channel MOS transistor 53 and the P channel MOS transistor 54 are operated so as to function as an on / off switch, and the data line 11 and the input terminal 16 are substantially completely grounded. Is precharged. Hereinafter, the operation of the liquid crystal display device of this embodiment will be described in detail.

Referring to FIG. 20, in the initial state, the polarity signal POL and the switch signal DOT_SW are deactivated, and, the input terminal 16 ₁ is driven to a negative potential, the input terminal 16 ₂ is driven to a positive potential Suppose that it was done. In response to the switch signal DOT_SW is deactivated, polarity switching switches 25 connects the output of the positive-side drive circuit 23d of the positive polarity driving unit 23 to the input terminal 16 _2, negative driver portion 24 It is connected to the input terminal 16 ₁ to output the negative electrode side drive circuit 24d of.

  When the m-th horizontal period starts, the amplifier output control signal AMP_HIZ is activated. As a result, the switches 23j and 24j of the positive side drive circuit 23d and the negative side drive circuit 24d are turned off, and the outputs of the positive side drive circuit 23d and the negative side drive circuit 24d are set to a high impedance state.

  Further, the pixel data of the pixels on the selected line is supplied to the polarity changeover switch group 21. In addition, the polarity signal POL is switched. By inverting the polarity signal POL, the connection relationship of the polarity switching switch group 21 is switched so as to correspond to the polarity of the data signal supplied to the data line 11 in the m-th horizontal period. Further, the latch signal STB is activated, and the pixel data is taken into the latch circuits 23 a and 24 a of the positive side driver unit 23 and the negative side driver unit 24.

In addition, when the switch signal DOT_SW is activated, the connection relationship between the positive polarity driver unit 23 and the negative polarity driver unit 24 and the input terminals 16 ₁ and 16 ₂ is switched. Specifically, as shown in Figure 19, polarity switching switch group 25 connects the input terminals 16 ₁ to the output of the positive-side drive circuit 23d of the positive-side driver 23, the negative input terminal 16 ₂ The output is connected to the output of the negative side drive circuit 24d of the side driver unit 24.

  Further, as shown in FIG. 20, all of the control signals RSW, GSW, and BSW are activated, and the precharge signal GND_SWN is driven to the “High” level and the precharge signal GND_SWP is driven to the “Low” level. Is done. As a result, the R switch 18, G switch 19, B switch 20 of all the selectors 17 and the N channel MOS transistors 53 and P channel MOS transistors 54 of the precharge diode circuits 51 and 52 are turned on, and all the data 11 is liquid crystal. Precharged to the ground potential of the driver 2. As described above, the data line 11 is precharged to the ground potential of the liquid crystal driver 2 in order to prevent a large voltage from being applied to the elements constituting the positive side drive circuit 23d and the negative side drive circuit 24d. is important.

After the precharge is completed, the data signal is supplied to the data line 11 connected to the R pixel 13, and the data signal is written to the R pixel 13 of the selected line. Specifically, the precharge signal GND_SWN is returned to the “Low” level, the precharge signal GND_SWP is returned to the “High” level, and pixel data corresponding to the R pixel 13 is selected by the RGB selectors 23h and 24h. The positive side drive circuit 23d and the negative side drive circuit 24d generate a data signal corresponding to the selected pixel data; the polarity of the data signal generated by the positive side drive circuit 23d is relative to the ground potential of the liquid crystal driver 2. It should be noted that the polarity of the data signal generated by the negative side drive circuit 24 d is positive with respect to the ground potential of the liquid crystal driver 2. Further, the control signal RSW is selectively activated, and the data line 11 connected to the R pixel 13 is connected to the input terminal 16; the control signals GSW and BSW are deactivated. Thus, the positive electrode side drive circuit 23d, a data signal generated by the negative electrode side drive circuit 24d, respectively, are supplied to the data lines ₁₁ 1, 11 ₄ connected to the R pixel 13. In addition, the gate line 12 corresponding to the selected line is activated, and a desired data signal is written to the R pixel 13 of the selected line. After driving the R pixel 13, like the input terminal 16 ₁ is the positive potential, it is noted that the input terminal 16 ₂ is driven to a negative potential.

Subsequently, the data signal is written to the G pixel 13 of the selected line. Writing of a data signal to the G pixel 13 of the selected line is first started by precharging the input terminal 16. Specifically, in a state where all of the control signals RSW, GSW, and BSW are inactivated, the polarity signal POL and the switch signal DOT_SW are inverted, and the amplifier output control signal AMP_HIZ is activated. Thus, as shown in FIG 21A, the positive electrode side drive circuit 23d, the output of the negative-side drive circuit 24d is set to a high impedance, furthermore, the input terminal 16 ₁ is the source of the P-channel MOS transistor 54, input terminal 16 ₂ is electrically connected to the source of N-channel MOS transistor 53. Input terminals 16 ₁ at this point has a positive potential, from the input terminal 16 ₂ has a negative potential, the parasitic transistors of N-channel MOS transistor 53, P-channel MOS transistor 54 are both , Forward biased. Therefore, the input terminal 16 ₁ is connected to the electrically grounded terminal through the P-channel MOS transistor 54, input terminals 16 ₂ are electrically connected to the ground terminal through the N-channel MOS transistor 53, input terminal 16 _1, 16 ₂ are precharged. Input terminals ₁₆ 1, 16 ₂ of the potentials between which has been precharged, as shown in FIG. 20, respectively, potentials + phi _F, the potential -.phi _F.

Subsequently, a data signal is supplied to the data line 11 connected to the G pixel 13. Specifically, pixel data corresponding to the G pixel 13 is selected by the RGB selectors 23h and 24h, and the positive side drive circuit 23d and the negative side drive circuit 24d generate data signals corresponding to the selected pixel data. To do. Further, the control signal GSW is selectively activated, and the data line 11 connected to the G pixel 13 is connected to the input terminal 16. Thereby, the data signal generated by the positive side drive circuit 23 d and the negative side drive circuit 24 d is supplied to the data line 11 connected to the G pixel 13. In addition, the gate line 12 corresponding to the selected line is activated, and a desired data signal is written to the G pixel 13 of the selected line. After driving the G pixel 13, the input terminal 16 ₁ is a negative potential, we should be noted that the input terminal 16 ₂ is driven to a positive potential.

The data signal is written to the B pixel 13 of the selected line by the same procedure. In a state where all of the control signals RSW, GSW, and BSW are deactivated, the polarity signal POL and the switch signal DOT_SW are inverted, and further, the amplifier output control signal AMP_HIZ is activated. Thus, as shown in FIG. 21B, the cathode-side drive circuit 23d, the output of the negative-side drive circuit 24d is set to a high impedance, furthermore, the input terminal 16 ₁ is the source of the N-channel MOS transistor 53, input terminal 16 ₂ is electrically connected to the source of P-channel MOS transistor 54. This is a point input terminal 16 ₁ has a negative potential, since the input terminal 16 ₂ has a positive potential, the parasitic transistor of N-channel MOS transistor 53, P-channel MOS transistor 54, both , Forward biased. Therefore, the input terminal 16 _1, N-channel MOS transistor 53 is electrically grounded via the input terminal 16 ₂ is electrically grounded through the P-channel MOS transistor 54, input terminals ₁₆ 1, 16 ₂ Pre Charged. Input terminals ₁₆ 1, 16 ₂ of the potentials between which has been precharged, as shown in FIG. 20, respectively, potentials -.phi _F, the potential + phi _F.

  Subsequently, a data signal is supplied to the data line 11 connected to the B pixel 13. More specifically, pixel data corresponding to the B pixel 13 is selected by the RGB selectors 23h and 24h, and the positive side driving circuit 23d and the negative side driving circuit 24d generate data signals corresponding to the selected pixel data. To do. Further, the control signal BSW is selectively activated, and the data line 11 connected to the B pixel 13 is connected to the input terminal 16. Thereby, the data signal generated by the positive side drive circuit 23 d and the negative side drive circuit 24 d is supplied to the data line 11 connected to the B pixel 13. In addition, the gate line 12 corresponding to the selected line is activated, and a desired data signal is written to the B pixel 13 of the selected line.

  In other horizontal periods following the mth horizontal period, data signals are written in the same procedure.

  As described above, in the fourth embodiment, an N-channel MOS transistor and a P-channel MOS transistor that function as both an on / off switch and a diode are used for precharging. The precharge of the data line 11 at the start of each horizontal period is performed by causing the N channel MOS transistor and the P channel MOS transistor to function as an on / off switch. As a result, the data line 11 is substantially completely precharged to the ground potential. On the other hand, the precharging of the input terminal 16 is performed by causing the N channel MOS transistor and the P channel MOS transistor to function as diodes. As a result, the input terminal 16 can be precharged in a short time.

5. Fifth Embodiment FIG. 21 is a block diagram showing a configuration of a liquid crystal driver 2D used in a liquid crystal display device according to a fourth embodiment of the present invention. The basic configuration of the liquid crystal display device of the present embodiment is almost the same as that of the liquid crystal display device of the fourth embodiment; the positive side driver portion 23 of the liquid crystal driver 2D is positive with respect to the ground potential of the liquid crystal driver 2. The negative side driver unit 24 is configured to generate a negative polarity data signal having a negative polarity with reference to the ground potential. Further, like the liquid crystal driver 2C of the fourth embodiment, the liquid crystal driver 2D of this embodiment has a configuration corresponding to time-division driving.

  The difference is that the positive-side driver unit 23 and the negative-side driver unit 24 use precharge diode circuits 51A and 52A that are not controlled by the precharge signal. Accordingly, the precharge timing generation circuit 27 is not provided.

  As shown in FIGS. 22A and 22B, each of the precharge diode circuits 51A and 52A is a circuit that performs precharge with a diode element (not an on / off switch). Specifically, the precharge diode circuit 51A includes a diode element 53A and a ground terminal 55. The cathode of the diode element 53A is connected to the node N1 connected to the output of the positive side drive circuit 23d, and the anode is connected to the ground terminal 55. Similarly, the precharge diode circuit 52 </ b> A includes a diode element 54 and a ground terminal 56. The cathode of the diode element 54 is connected to the ground terminal 56, and the anode is connected to the node N2 connected to the output of the negative side drive circuit 24d.

  One feature of the liquid crystal display device of this embodiment is that the data line 11 and the input terminal are both precharged using the diode elements 53A and 54A. As described above, the advantage of using the diode elements 53A and 54A for precharging is that the timing control becomes easy and the time required for precharging can be shortened. It should be noted that also in the present embodiment, as the diode elements 53A and 54A, not only a commonly used pn junction diode but also a transistor functioning as a diode can be used. Hereinafter, the operation of the liquid crystal display device of the fifth embodiment will be described in detail.

Referring to FIG. 23, in the initial state, the polarity signal POL and the switch signal DOT_SW are deactivated, and, the input terminal 16 ₁ is driven to a negative potential, the input terminal 16 ₂ is driven to a positive potential Suppose that it was done. In response to the switch signal DOT_SW is deactivated, polarity switching switches 25 connects the output of the positive-side drive circuit 23d of the positive polarity driving unit 23 to the input terminal 16 _2, negative driver portion 24 It is connected to the input terminal 16 ₁ to output the negative electrode side drive circuit 24d of. Further, the odd-numbered data lines 11 ₁ , 11 ₃ ,... Are driven to a negative potential, and the even-numbered data lines 11 ₂ , 11 ₄ ,. To do.

  When the m-th horizontal period starts, the amplifier output control signal AMP_HIZ is activated. As a result, the switches 23j and 24j of the positive side drive circuit 23d and the negative side drive circuit 24d are turned off, and the outputs of the positive side drive circuit 23d and the negative side drive circuit 24d are set to a high impedance state.

  Further, the pixel data of the pixels on the selected line is supplied to the polarity changeover switch group 21. In addition, the polarity signal POL is switched. By inverting the polarity signal POL, the connection relationship of the polarity switching switch group 21 is switched so as to correspond to the polarity of the data signal supplied to the data line 11 in the m-th horizontal period. Further, the latch signal STB is activated, and the pixel data is taken into the latch circuits 23 a and 24 a of the positive side driver unit 23 and the negative side driver unit 24.

Further, as shown in FIG. 20, all of the control signals RSW, GSW, and BSW are activated, and the R switch 18, G switch 19, and B switch 20 of all the selectors 17 are turned on. Accordingly, the data lines ₁₁ 1 to 11 ₃ to the input terminal 16 _1, the data line ₁₁ 4-11 ₆ is connected to an input terminal 16 _2. Two of the three data lines 11 connected to the input terminal 16 ₁ is driven to a negative potential, since one is driven to a positive potential, the data lines 11 ₁ to 11 ₃ is an input terminal by being connected to the 16 _1, the potential of the input terminal 16 ₁ is negative. On the other hand, since _two of the three data lines 11 connected to the input terminal 162 are driven to a positive potential and one is driven to a negative potential, the data lines 11 _{4 to} 11 ₆ are driven. by being connected to the input terminal 16 _2, the potential of the input terminal 16 ₂ is positive.

In addition, when the switch signal DOT_SW is activated, the connection relationship between the positive polarity driver unit 23 and the negative polarity driver unit 24 and the input terminals 16 ₁ and 16 ₂ is switched. Specifically, as shown in Figure 22, polarity switching switch group 25 connects the input terminals 16 ₁ to the output of the positive-side drive circuit 23d, an input terminal 16 ₂ output of the negative-side drive circuit 24d Connect to. That is, the input terminals 16 ₁ and the data line 11 connected thereto is connected to the cathode of the diode 53A, the input terminals 16 ₂ and the data line 11 connected thereto is connected to the anode of the diode 54A.

Input terminal 16 ₁ has a negative potential, since the input terminal 16 ₂ has a positive potential, the diode 53A, the 54A, both a forward bias is applied. Therefore, the input terminal 16 ₁ and the data line 11 connected thereto, is electrically connected to the ground terminal 55 via the diode element 53A. Thus, the input terminals 16 ₁ and the data line 11 connected thereto, the ground potential, the more tightly is precharged to the potential -.phi _F. Input terminals 16 ₂ and the data line 11 connected thereto, is electrically connected to the ground terminal 56 via the diode element 54A. Thus, the input terminals 16 ₂ and the data line 11 connected thereto, the ground potential, the more tightly is precharged to the potential + phi _F. As described above, the data line 11 is precharged to the ground potential of the liquid crystal driver 2 in order to prevent a large voltage from being applied to the elements constituting the positive side drive circuit 23d and the negative side drive circuit 24d. is important.

After the precharge is completed, the data signal is supplied to the data line 11 connected to the R pixel 13, and the data signal is written to the R pixel 13 of the selected line. Specifically, pixel data corresponding to the R pixel 13 is selected by the RGB selectors 23h and 24h. The positive side drive circuit 23d and the negative side drive circuit 24d generate a data signal corresponding to the selected pixel data; the polarity of the data signal generated by the positive side drive circuit 23d is relative to the ground potential of the liquid crystal driver 2. It should be noted that the polarity of the data signal generated by the negative side drive circuit 24 d is positive with respect to the ground potential of the liquid crystal driver 2. Further, the control signal RSW is selectively activated, and the data line 11 connected to the R pixel 13 is connected to the input terminal 16; the control signals GSW and BSW are deactivated. Thus, the positive electrode side drive circuit 23d, a data signal generated by the negative electrode side drive circuit 24d, respectively, are supplied to the data lines ₁₁ 1, 11 ₄ connected to the R pixel 13. In addition, the gate line 12 corresponding to the selected line is activated, and a desired data signal is written to the R pixel 13 of the selected line. After driving the R pixel 13, like the input terminal 16 ₁ is the positive potential, it is noted that the input terminal 16 ₂ is driven to a negative potential.

Subsequently, the data signal is written to the G pixel 13 of the selected line. Writing of a data signal to the G pixel 13 of the selected line is first started by precharging the input terminal 16. Specifically, in a state where all of the control signals RSW, GSW, and BSW are inactivated, the polarity signal POL and the switch signal DOT_SW are inverted, and the amplifier output control signal AMP_HIZ is activated. Thus, as shown in FIG 24A, the positive electrode side drive circuit 23d, the output of the negative-side drive circuit 24d is set to a high impedance, furthermore, to the anode of the input terminal 16 ₁ is diode element 54A, an input terminal 16 ₂ is electrically connected to the cathode of the diode element 53A. Input terminals 16 ₁ at this point has a positive potential, from the input terminal 16 ₂ has a negative potential, the diode element 53A, the diode element 54A are both forward biased . Therefore, the input terminal 16 ₁ is connected to the electrically grounded terminal 56 via the diode element 54A, the input terminal 16 ₂ is electrically connected to the ground terminal through the diode element 53A, the input terminal ₁₆ 1, 16 ₂ are precharged. Input terminals ₁₆ 1, 16 ₂ of the potentials between which has been precharged, as shown in FIG. 23, respectively, potentials + phi _F, the potential -.phi _F.

Subsequently, a data signal is supplied to the data line 11 connected to the G pixel 13. Specifically, pixel data corresponding to the G pixel 13 is selected by the RGB selectors 23h and 24h, and the positive side drive circuit 23d and the negative side drive circuit 24d generate data signals corresponding to the selected pixel data. To do. Further, the control signal GSW is selectively activated, and the data line 11 connected to the G pixel 13 is connected to the input terminal 16. Thereby, the data signal generated by the positive side drive circuit 23 d and the negative side drive circuit 24 d is supplied to the data line 11 connected to the G pixel 13. In addition, the gate line 12 corresponding to the selected line is activated, and a desired data signal is written to the G pixel 13 of the selected line. After driving the G pixel 13, the input terminal 16 ₁ is a negative potential, it should be noted that the input terminal 16 ₂ is driven to a positive potential.

The data signal is written to the B pixel 13 of the selected line by the same procedure. In a state where all of the control signals RSW, GSW, and BSW are deactivated, the polarity signal POL and the switch signal DOT_SW are inverted, and further, the amplifier output control signal AMP_HIZ is activated. Thus, as shown in FIG. 21B, the cathode-side drive circuit 23d, the output of the negative-side drive circuit 24d is set to a high impedance, furthermore, the cathode of the input terminal 16 ₁ is diode element 53A, an input terminal 16 ₂ is electrically connected to the anode of the diode element 54A. Input terminals 16 ₁ at this point has a positive potential, from the input terminal 16 ₂ has a negative potential, the diode element 53A, 53B are both forward biased. Therefore, the input terminal 16 ₁ is electrically grounded through the diode element 53A, the input terminal 16 ₂ is electrically grounded through the diode element 54A, the input terminal ₁₆ 1, 16 ₂ are precharged. Input terminals ₁₆ 1, 16 ₂ of the potentials between which has been precharged, as shown in FIG. 26, respectively, potentials -.phi _F, the potential + phi _F.

  Subsequently, a data signal is supplied to the data line 11 connected to the B pixel 13. More specifically, pixel data corresponding to the B pixel 13 is selected by the RGB selectors 23h and 24h, and the positive side driving circuit 23d and the negative side driving circuit 24d generate data signals corresponding to the selected pixel data. To do. Further, the control signal BSW is selectively activated, and the data line 11 connected to the B pixel 13 is connected to the input terminal 16. Thereby, the data signal generated by the positive side drive circuit 23 d and the negative side drive circuit 24 d is supplied to the data line 11 connected to the B pixel 13. In addition, the gate line 12 corresponding to the selected line is activated, and a desired data signal is written to the B pixel 13 of the selected line.

  In other horizontal periods following the mth horizontal period, data signals are written in the same procedure.

  As described above, in the fifth embodiment, the data line 11 and the input terminal 16 are precharged by being connected to the ground terminal via the diode element. By using the diode element, the data line 11 and the input terminal 16 are automatically precharged, which makes it easy to control the operation timing during the precharge. This is effective for shortening the time required for precharging.

6). Summary As described above, in the above-described embodiment, the liquid crystal driver generates a data signal having a positive polarity with respect to the ground potential of the liquid crystal driver, and the ground potential. And a negative polarity driving circuit for generating a data signal having a negative polarity. Such an architecture effectively reduces the power consumption of the liquid crystal driver.

  In addition, in the above-described embodiment, the data line of the liquid crystal display panel is precharged to the ground potential of the liquid crystal driver. Such an architecture prevents a high voltage from being applied to the elements constituting the positive polarity drive circuit and the negative polarity drive circuit, and effectively reduces the power required for precharging.

  The configuration of the present invention should not be construed as being limited to the above-described embodiments; various modifications can be made to the embodiments of the present invention. For example, in the first and second embodiments, the switches 23f and 24f of the precharge switch circuits 23e and 24e are not the output terminals of the positive polarity drive circuit 23d and the negative polarity drive circuit 24d, but the liquid crystal driver 2 (or 2A). It is also possible to connect directly to the output terminal 3. In addition, in the second embodiment, the selector 17 for selecting the data line 11 can be provided not in the liquid crystal display panel 1A but in the liquid crystal driver 2A. Changes in the configuration of the liquid crystal display panel 1A and the liquid crystal driver 2A due to the provision of the selector 17 in the liquid crystal driver 2A will be obvious to those skilled in the art.

  Further, the polarity changeover switch group 25 can be provided not in the liquid crystal driver 2A but in the liquid crystal display panel 1A. The change of the configuration of the liquid crystal display panel 1A and the liquid crystal driver 2A accompanying the provision of the polarity changeover switch group 25 in the liquid crystal display panel 1A will be obvious to those skilled in the art.

FIG. 1 is a block diagram showing a configuration of a conventional liquid crystal driver. FIG. 2 is a diagram showing a relationship between a power supply voltage supplied to a positive electrode side drive circuit and a negative electrode side drive circuit mounted on a conventional liquid crystal driver, and a signal level of a data signal output therefrom. FIG. 3 is a block diagram showing the configuration of the liquid crystal display device according to the first embodiment of the present invention. FIG. 4 is a block diagram showing the configuration of the liquid crystal driver of the first embodiment. FIG. 5 is a detailed diagram illustrating a configuration of an output system portion that outputs a data signal in the liquid crystal driver according to the first embodiment. FIG. 6 is a diagram illustrating the relationship between the power supply voltage supplied to the positive electrode side drive circuit and the negative electrode side drive circuit and the signal level of the data signal output from them in the first embodiment. FIG. 7 is a timing chart showing a preferred operation of the liquid crystal driver of the first embodiment. FIG. 8 is a timing chart showing another preferable operation of the liquid crystal driver of the first embodiment. FIG. 9 is a timing chart showing still another preferred operation of the liquid crystal driver of the first embodiment. FIG. 10A is a block diagram illustrating a configuration of a liquid crystal display device according to a second embodiment of the present invention. FIG. 10B is a block diagram illustrating a configuration of a liquid crystal driver mounted in the liquid crystal display device of the second embodiment. FIG. 11 is a conceptual diagram showing an operation in which the liquid crystal driver of the second embodiment precharges the data lines. FIG. 12 is a conceptual diagram illustrating an operation in which the liquid crystal driver according to the second embodiment precharges the data lines. FIG. 13 is a timing chart showing a preferred operation of the liquid crystal driver of the second embodiment. FIG. 14 is a block diagram showing a configuration of a liquid crystal driver mounted on the liquid crystal display device according to the third embodiment of the present invention. FIG. 15A is a detailed diagram illustrating a configuration of an output system portion that outputs a data signal of the liquid crystal driver according to the third embodiment. FIG. 15B is a detailed diagram illustrating a configuration of an output system portion that outputs a data signal in the liquid crystal driver according to the third embodiment. FIG. 16 is a timing chart showing a preferred operation of the liquid crystal driver of the third embodiment. FIG. 17 is a diagram illustrating an example of a diode element mounted on the liquid crystal driver of the third embodiment. FIG. 18 is a block diagram showing a configuration of a liquid crystal driver mounted on the liquid crystal display device according to the fourth embodiment of the present invention. FIG. 19 is a detailed diagram illustrating a configuration of an output system portion that outputs a data signal of the liquid crystal driver according to the fourth embodiment. FIG. 20 is a timing chart showing a preferred operation of the liquid crystal driver of the fourth embodiment. FIG. 21A is a circuit diagram illustrating a preferred operation of the liquid crystal driver of the fourth embodiment. FIG. 21B is a circuit diagram illustrating a preferred operation of the liquid crystal driver of the fourth embodiment. FIG. 22 is a block diagram showing a configuration of a liquid crystal driver mounted on the liquid crystal display device according to the fifth embodiment of the present invention. FIG. 23 is a detailed diagram illustrating a configuration of an output system portion that outputs a data signal of the liquid crystal driver according to the fifth embodiment. FIG. 24 is a timing chart showing a preferred operation of the liquid crystal driver of the fifth embodiment. FIG. 25A is a circuit diagram illustrating a preferred operation of the liquid crystal driver of the fifth embodiment. FIG. 25B is a circuit diagram illustrating a preferred operation of the liquid crystal driver of the fifth embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1, 1A: Liquid crystal display panel 2, 2A: Liquid crystal driver 3, 3 ₁ , 3 ₂ : Output terminal 4, 4 ₁ , 4 ₂ : Wiring 10: Liquid crystal display device 11: Data line 12: Gate line 13: Pixel 13a: TFT
13b: Pixel electrode 13c: Common electrode 16: Input terminal 17: Selector 18: R switch 19: G switch 20: B switch 21: Polarity switching switch group 22: Gradation potential generating circuit 23: Positive side driver unit 24: Negative side Driver unit 23a, 24a: Latch circuit 23b, 24b: Level shifter 23c, 24c: D / A converter 23d: Positive side drive circuit 24d: Negative side drive circuit 23e, 24e: Precharge switch circuit 23f, 24f: Switch 23g, 24g: Ground terminals 23h, 24h: RGB selectors 23j, 24j: Switches 23k, 24k: Amplifiers 25: Polarity changeover switch group 26: Polarity changeover switch control circuit 27: Precharge timing generation circuit 28: Timing control circuit 29: RGB switcher Generation circuit 30: RGB selector control circuit 31: amplifier timing generation circuit 41, 42: precharge diode circuit 43, 44: diode element 43A: N channel MOS transistor 44A: P channel MOS transistor 45, 46: ground terminal 51, 52 , 51A, 51B: Precharge diode circuit 53: N channel MOS transistor 54: P channel MOS transistor 53A, 54A: Diode element 55, 56: Ground terminal

Claims (23)

A liquid crystal display panel having a plurality of data lines;
A liquid crystal driver,
The liquid crystal driver is configured to output a positive polarity data signal having a positive polarity with respect to the ground potential of the liquid crystal driver to one data line of the plurality of data lines, and the ground potential as a reference. A negative-side drive circuit that outputs a negative-polarity data signal having a negative polarity to the other data lines of the plurality of data lines. The liquid crystal display device according to claim 1,
Furthermore, precharge means for precharging the data line of the liquid crystal display panel to the ground potential is provided. The liquid crystal display device according to claim 2,
The positive drive circuit outputs the positive data signal to the first data line of the data lines of the liquid crystal display panel in a first horizontal period and a second horizontal period following the first horizontal period. ,
The negative drive circuit outputs the negative data signal to a second data line of the data lines of the liquid crystal display panel in the first horizontal period and the second horizontal period,
The precharge unit may be configured to output the liquid crystal display panel at a time before the positive data signal and the negative data signal are supplied to the first data line and the second data line, respectively, in the first horizontal period. The data line is precharged to the ground potential, and the data line of the liquid crystal display panel is not precharged to the ground potential in the second horizontal period. The liquid crystal display device according to claim 1,
Furthermore, precharge means for precharging the data line of the liquid crystal display panel is provided,
The precharge means includes a diode element that connects the plurality of data lines to a ground terminal. The liquid crystal display device according to claim 1,
Further, one of the output of the positive polarity side drive circuit and the output of the negative polarity drive circuit is provided to either the liquid crystal display panel or the liquid crystal driver as a first data line of the plurality of data lines. A polarity changeover switch circuit configured to electrically connect the other to a second data line of the plurality of data lines,
The liquid crystal driver is
A first diode element having a cathode connected to the output of the positive drive circuit and an anode connected to a ground terminal;
A liquid crystal display device comprising: a second diode element having an anode connected to the output of the negative side drive circuit and a cathode connected to a ground terminal. A liquid crystal display panel comprising a plurality of input terminals and a plurality of data lines connected to the pixels;
LCD driver,
A plurality of selectors provided in any of the liquid crystal display panel and the liquid crystal driver;
The plurality of input terminals include a first input terminal and a second input terminal;
The plurality of data lines are:
A plurality of first data lines provided corresponding to the first input terminals;
A plurality of second data lines provided corresponding to the second input terminal,
The plurality of selectors are:
A first selector for connecting a data line selected from the plurality of first data lines to the first input terminal;
A second selector for connecting a data line selected from the plurality of second data lines to the second input terminal;
The liquid crystal driver is
A positive-side drive circuit configured to be able to output a positive-polarity data signal that is positive with respect to the ground potential of the liquid crystal driver;
A negative side drive circuit configured to be capable of outputting a negative polarity data signal that is negative with respect to the ground potential;
And a selector control circuit that generates a control signal for controlling the plurality of selector circuits. The liquid crystal display device according to claim 6,
The liquid crystal driver further includes precharge means for precharging the plurality of input terminals to the ground potential. The liquid crystal display device according to claim 7,
In a first period of one horizontal period, the first selector connects all of the plurality of first data lines to the first input terminal, and the second selector includes the plurality of second data lines. Are connected to the second input terminal, and the precharge means precharges the first input terminal and the second input terminal to the ground potential,
In the second period after the first period in the horizontal period, the first selector selects one first selected data line selected from the plurality of first data lines as the first input terminal. And the second selector connects one second selected data line selected from the plurality of second data lines to the second input terminal, and the positive-side drive circuit includes: The positive data signal is output to one of the first input terminal and the second input terminal, and the negative drive circuit includes the first input terminal and the second input terminal. A liquid crystal display device that outputs the negative polarity data signal to the other side. The liquid crystal display device according to claim 8,
In the third period after the second period in the horizontal period, the first selector electrically disconnects all of the plurality of first data lines from the first input terminal, and the second selector Disconnects all of the plurality of second data lines from the second input terminal, and the precharge means precharges the first input terminal and the second input terminal to the ground potential,
In the fourth period after the third period in the horizontal period, the first selector selects another first selected data line selected from the plurality of first data lines as the first input. And the second selector connects another second selected data line selected from the plurality of second data lines to the second input terminal, and the positive drive circuit. Outputs the positive data signal to the other of the first input terminal and the second input terminal, and the negative side drive circuit includes the first input terminal and the second input terminal. And outputting the negative polarity data signal to the one of the liquid crystal display devices. The liquid crystal display device according to claim 9,
In the third period, the precharge means precharges the first input terminal and the second input terminal to the ground potential. In the first period, the precharge means performs the first input terminal and the second input terminal. 2. A liquid crystal display device shorter than a time for precharging two input terminals to the ground potential. The liquid crystal display device according to claim 6,
The liquid crystal driver further includes precharge means for precharging the plurality of input terminals,
The precharge means includes a diode element that connects the plurality of input terminals to a ground terminal. The liquid crystal display device according to claim 6,
Further, one of the output of the positive polarity side drive circuit and the output of the negative polarity drive circuit is provided to either the liquid crystal display panel or the liquid crystal driver as a first data line of the plurality of data lines. A polarity changeover switch circuit configured to electrically connect the other to a second data line of the plurality of data lines,
The liquid crystal driver is
An N-channel MOS transistor having a source connected to the output of the positive side drive circuit and a drain and a back gate grounded;
A liquid crystal display device comprising: a P-channel MOS transistor having a source connected to the output of the negative side drive circuit and a drain and a back gate grounded. The liquid crystal display device according to claim 12,
The liquid crystal driver further includes a precharge timing generation circuit for controlling the gate potential of the N-channel MOS transistor and the P-channel MOS transistor,
In a first period of one horizontal period, the first selector connects all of the plurality of first data lines to the first input terminal, and the second selector includes the plurality of second data lines. Are connected to the second input terminal, and the precharge timing generation circuit drives the gate of the N-channel MOS transistor to a predetermined positive potential and the P-channel MOS transistor to a predetermined negative potential,
In the second period after the first period in the horizontal period, the first selector selects one first selected data line selected from the plurality of first data lines as the first input terminal. And the second selector connects one second selection data line selected from the plurality of second data lines to the second input terminal, and the polarity changeover switch circuit includes: One output of the positive drive circuit and the negative drive circuit is connected to the first input terminal, and the other output is connected to the second input terminal. The positive drive circuit is connected to the second input terminal via the polarity changeover switch circuit. The liquid crystal display device, wherein the positive polarity data signal is output to a first input terminal, and the negative polarity side drive circuit outputs the negative polarity data signal to the second input terminal via the polarity changeover switch circuit. The liquid crystal display device according to claim 13,
In the third period after the second period in the horizontal period, the first selector disconnects all of the plurality of first data lines from the first input terminal, and the second selector All of the second data lines are disconnected from the second input terminal, and the precharge timing generation circuit drives the gates of the N-channel MOS transistor and the P-channel MOS transistor to the ground potential, and the polarity changeover switch circuit The one output of the positive drive circuit and the negative drive circuit is connected to the second input terminal, and the other output is connected to the first input terminal. The positive drive circuit and the negative drive The circuit is a liquid crystal display that sets its output to a high impedance state. The liquid crystal display device according to claim 6,
The liquid crystal driver is
A polarity changeover switch circuit that switches a connection relationship between the output of the positive drive circuit and the output of the negative drive circuit, and the first input terminal and the second input terminal;
A first diode element having a cathode connected to the output of the positive drive circuit and an anode connected to a ground terminal;
A liquid crystal display device comprising: a second diode element having an anode connected to the output of the negative side drive circuit and a cathode connected to a ground terminal. A liquid crystal driver used to drive a liquid crystal display panel,
A positive side drive circuit for outputting a positive data signal that is positive with respect to the ground potential of the liquid crystal driver to one of the data lines of the liquid crystal display panel;
A liquid crystal driver comprising: a negative side drive circuit for outputting a negative data signal that is negative with respect to the ground potential to another data line of the other data lines of the liquid crystal display panel. The liquid crystal driver according to claim 16, wherein
Furthermore,
A liquid crystal driver comprising precharge means for precharging the plurality of data lines to the ground potential. The liquid crystal driver according to claim 16, wherein
The positive drive circuit outputs the positive data signal to the first data line of the data lines of the liquid crystal display panel in a first horizontal period and a second horizontal period following the first horizontal period. ,
The negative drive circuit outputs the negative data signal to a second data line of the data lines of the liquid crystal display panel in the first horizontal period and the second horizontal period,
The precharge unit is configured to output the first data line and the second data line in the first horizontal period before the positive data signal and the negative data signal are supplied to the liquid crystal display panel, respectively. A liquid crystal driver that precharges the data line to the ground potential and does not precharge the data line of the liquid crystal display panel to the ground potential in the second horizontal period. The liquid crystal driver according to claim 16, wherein
Furthermore,
First and second output terminals for connection to any of the plurality of data lines;
A polarity changeover switch circuit configured to electrically connect one of the output of the positive drive circuit and the output of the negative drive circuit to the first output terminal and the other to the second output terminal;
A first diode element having a cathode connected to the output of the positive drive circuit and an anode connected to a ground terminal;
A liquid crystal driver comprising: a second diode element having an anode connected to the output of the negative side drive circuit and a cathode connected to a ground terminal. The liquid crystal driver according to claim 16, wherein
Furthermore,
First and second output terminals for connection to any of the plurality of data lines;
A polarity changeover switch circuit configured to electrically connect one of the output of the positive drive circuit and the output of the negative drive circuit to the first output terminal and the other to the second output terminal;
An N-channel MOS transistor having a source connected to the output of the positive side drive circuit and a drain and a back gate grounded;
A liquid crystal display device comprising: a P-channel MOS transistor having a source connected to the output of the negative side drive circuit and a drain and a back gate grounded. A driving method for driving a liquid crystal display panel by a liquid crystal driver,
Outputting a positive data signal that is positive with respect to the ground potential of the liquid crystal driver to one of the data lines of the liquid crystal display panel;
Outputting a negative data signal having a negative polarity with respect to the ground potential to another data line of the data lines of the liquid crystal display panel. The driving method according to claim 21, wherein
Furthermore,
A driving method comprising the step of precharging the data line of the liquid crystal display panel to the ground potential. The driving method according to claim 21, wherein
Furthermore,
A driving method comprising the step of connecting the data line of the liquid crystal display panel to a ground terminal via a diode.

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