1. Field of the Invention
The present invention relates to a gate signal line driving circuit and a display device using the same.
2. Description of the Related Art
In known display devices, such as liquid crystal display devices, a method is often adopted in which a gate signal line driving circuit including plural shift register basic circuits, which output to plural gate signal lines gate signals that have a high voltage in order, is formed on the same substrate as a thin film transistor (hereinafter, referred to as a TFT) disposed in a display unit, example. A gate signal line driving circuit in the related art is disclosed in JP 2010-113247A.
For example, in a shift register basic circuit disclosed in JP 2010-113247A, an OFF voltage is applied to a switch of a gate line high voltage application circuit (transistors 93 and 94), which is turned on in a high signal period to apply a high voltage to a gate signal line, after the high signal period by an internal signal of a shift register basic circuit located at the subsequent stage. Accordingly, the gate line high voltage application circuit is turned off.
In addition, the shift register basic circuit provided in the gate signal line driving circuit may further include a gate line low voltage application circuit which is turned on in a low signal period (a period other than the high signal period) to apply a low voltage to the gate signal line so that the low voltage is stably output to the gate signal line during the low signal period. In this case, it is necessary to control a switch of the gate line low voltage application circuit similarly.
In order to do so, a control circuit which controls voltages applied to the switch of the gate line high voltage application circuit and the switch of the gate line low voltage application circuit, respectively, is required, and it is necessary to acquire a control signal for controlling the control circuit from the outside of the shift register basic circuit. This increases the circuit size of the shift register basic circuit.
The invention has been made in view of such a problem, and it is an object of the invention to provide a gate signal line driving circuit capable of improving the voltage quality of a gate signal output to a gate signal line while suppressing an increase in the circuit size and a display device using the gate signal line driving circuit.
In order to solve the above-described problem, according to a first aspect of the invention, a gate signal line driving circuit includes: plural shift register basic circuits each of which outputs to a corresponding gate signal line a gate signal which has a high voltage during a high signal period of one screen display period and has a low voltage during a low signal period that is a period other than the high signal period. Each of the shift register basic circuits includes: a gate line high voltage application circuit which is turned on in accordance with the high signal period to apply the high voltage to the corresponding gate signal line; a gate line low voltage application circuit which is turned on in accordance with the low signal period to apply the low voltage to the corresponding gate signal line; and a second gate line low voltage application circuit which is turned on to apply the low voltage to the corresponding gate signal line in at least a part of a period until the gate line low voltage application circuit is turned on after the gate line high voltage application circuit is turned off.
According to a second aspect of the invention, in the gate signal line driving circuit according to the first aspect of the invention, a gate signal at a subsequent stage may be input to a switch of the second gate line low voltage application circuit of each of the shift register basic circuits.
According to a third aspect of the invention, in the gate signal line driving circuit according to the first aspect of the invention, each of the shift register basic circuits may further include a high voltage application OFF control circuit which applies an OFF voltage to a switch of the gate line high voltage application circuit in accordance with a timing at which a control voltage applied to a switch of the gate line low voltage application circuit of the shift register basic circuit at a preceding stage changes from OFF voltage to ON voltage.
According to a fourth aspect of the invention, in the gate signal line driving circuit according to the first aspect of the invention, each of the shift register basic circuits may further include a low voltage application ON control circuit which increases a control voltage, which is applied to a switch of the gate line low voltage application circuit, to an ON voltage at a timing at which two-phase clock signals with different phases are input at a predetermined period and one of the two-phase clock signals changes from the low voltage to the high voltage, and the other clock signal of the two-phase clock signals may be input to the gate line high voltage application circuit.
According to a fifth aspect of the invention, in the gate signal line driving circuit according to any one of the first to fourth aspects of the invention, each of the shift register basic circuits may include a high voltage application driving OFF control circuit which applies an OFF voltage to a switch of the gate line high voltage application circuit in an ON state and a low voltage application driving OFF control circuit which applies an OFF voltage to a switch of the gate line low voltage application circuit in an ON state.
According to a sixth aspect of the invention, in the gate signal line driving circuit according to the fifth aspect of the invention, in each of the shift register basic circuits, when the shift register basic circuit is not driven for the switch of the high voltage application driving OFF control circuit and the switch of the low voltage application driving OFF control circuit, an intermediate voltage higher than the low voltage and lower than the high voltage may be applied to turn on the high voltage application driving OFF control circuit and the low voltage application driving OFF control circuit.
According to a seventh aspect of the invention, in the gate signal line driving circuit according to the sixth aspect of the invention, the intermediate voltage may be a ground voltage.
According to an eighth aspect of the invention, in the gate signal line driving circuit according to the fifth aspect of the invention, in each of the shift register basic circuits, the high voltage application driving OFF control circuit and the low voltage application driving OFF control circuit are turned off together in at least a part of a blanking period, for which all voltages of the plural gate signal lines are the low voltage, of one screen display period and are turned on in the other period when the shift register basic circuit is not driven.
According to a ninth aspect of the invention, in the gate signal line driving circuit according to the fifth aspect of the invention, each of the shift register basic circuits may further include a switching control circuit which supplies an ON voltage to the switch of the high voltage application driving OFF control circuit and the switch of the low voltage application driving OFF control circuit.
According to a tenth aspect of the invention, in the gate signal line driving circuit according to the ninth aspect of the invention, an intermediate voltage higher than the low voltage and lower than the high voltage is applied to a switch of the switching control circuit of each of the shift register basic circuits to turn on the switching control circuit.
According to an eleventh aspect of the invention, in the gate signal line driving circuit according to the ninth aspect of the invention, when the shift register basic circuit is not driven, the switching control circuit of each of the shift register basic circuits may supply an OFF voltage in at least a part of a blanking period, for which all voltages of the plural gate signal lines are the low voltage, of one screen display period and supply an ON voltage in the other period.
According to a twelfth aspect of the invention, in the gate signal line driving circuit according to the tenth aspect of the invention, in each of the shift register basic circuits, the high voltage may be input to the switching control circuit when the switching control circuit supplies an ON voltage.
According to a thirteenth aspect of the invention, a display device includes the gate signal line driving circuit according to any one of the first to twelfth aspects of the invention.
According to the aspects of the invention, there are provided a gate signal line driving circuit, which suppresses noise in a gate signal while suppressing an increase in the circuit size, and a display device using the gate signal line driving circuit.
A display device according to a first embodiment of the invention is an IPS (In-Plane Switching) liquid crystal display device 1, for example. As shown in an overall perspective view of the liquid crystal display device 1 according to the present embodiment shown in
A display unit 27, a driver IC 21, a gate signal line driving circuit 22, an RGB selection circuit 24, a precharge circuit 25, and a detection circuit 26 are provided on the TFT substrate 12. The gate signal line driving circuit 22 is disposed at each of both sides of the display unit 27. In
Plural shift register basic circuits SR are provided in the gate signal line driving circuit 22 so as to correspond to the plural gate signal lines 105. For example, when 854 gate signal lines 105 are present, 854 shift register basic circuits SR are similarly provided in the gate signal line driving circuit 22. According to control signals input from the driver IC 21, each shift register basic circuit SR outputs to the corresponding gate signal line 105 a gate signal which has a high voltage during a corresponding high signal period of 1 frame period TF (one screen display period), which is a period for which one screen is displayed, and has a low voltage during a low signal period which is the other period in the frame period TF.
In addition, although the driver IC 21 controls the plural shift register basic circuits SR provided in the gate signal line driving circuit 22 with control signals 115 output from the driver IC 21 herein, the control is not limited to this example. For example, a shift register control circuit may be provided in the gate signal line driving circuit 22 and this shift register control circuit may control the plural shift register basic circuits SR according to control signals that are output. In this case, control signals from the outside are input to the shift register control circuit through the FPC 20, and the shift register control circuit generates control signals output to the plural shift register basic circuits SR.
In addition, plural video signal lines 107 connected to the RGB selection circuit 24 extend in a vertical direction in the drawing at equal distances therebetween. In addition, display dots arrayed in a grid shape are divided by the gate signal lines 105 and the video signal lines 107. In addition, common signal lines 108 extend in the horizontal direction in the drawing so as to be parallel to the corresponding gate signal lines 105, respectively. Alternatively, the common signal lines 108 may extend in the vertical direction in the drawing, similar to the video signal line 107.
A TFT 109 is formed in the corner of each display dot divided by the gate signal lines 105 and the video signal lines 107, and is connected to the video signal line 107 and a pixel electrode 110. In addition, a gate electrode of the TFT 109 is connected to the gate signal line 105. In each display dot, a common electrode 111 is formed so as to face the pixel electrode 110.
In the circuit configuration described above, a reference voltage COM is applied to the common electrode 111 of each display dot through the common signal line 108. In addition, a gate signal is output from the gate signal line driving circuit 22 to the corresponding gate signal line 105, and a voltage of the gate signal is applied to gates of the plural TFTs 109 connected to the gate signal line 105. The plural TFTs 109 to which the high voltage of the gate signal is applied are in an ON state, and the voltage of a video signal supplied from the driver IC 21 to the corresponding video signal line 107 through the RGB selection circuit 24 is applied to the corresponding pixel electrode 110 through the TFT 109 in the ON state. In addition, an operation of supplying the voltage of a video signal to the pixel electrode 110 is referred to as “writing video data in a display dot”. Then, a potential difference occurs between the pixel electrode 110 and the common electrode 111, and this controls the orientation of liquid crystal molecules and the like. Accordingly, the degree of blocking light from the backlight 13 is controlled to display an image.
In
In the gate signal line driving circuit 22 according to the present embodiment, the first to 854-th shift register basic circuits SR output to the corresponding gate signal lines 105 gate signals which have a high voltage in order from the top in 1 frame period TF. That is, a first gate signal G1, a second gate signal G2, a third gate signal G3, and an 854-th gate signal G854 continue a high signal period, for which they have a high voltage in this order, in the 1 frame period TF. Assuming that this is forward driving, the gate signal line driving circuit 22 according to the present embodiment can perform forward driving.
As shown in
The control signals 115 input from the driver IC 21 to the gate signal line driving circuit 22 include two-phase clock signals VCK1 and VCK2, a low voltage power line VGL, a buffered voltage power line VDD, and a start signal VRES as a trigger of one screen (frame) display.
Here, m-phase clock signals will be described generally. The m-phase clock signals are clock signals with different phases at predetermined periods T. Assuming that the period of a clock signal is T, one period T can be subdivided into periods of T/m in the case of m-phase clock signals. Assuming that the period of T/m is one clock, one period T has m clocks. The m-phase clock signals are set to have a high voltage in order. Assuming that a certain clock is a first clock, a clock signal which changes to have a high voltage at the first clock is set as a clock signal VCK1. The clock signal VCK1 changes to have a high voltage at the first clock, but has a low voltage at other clocks. In a period of the certain 1 period T, clock signals VCK1, VCK2, VCK3, and VCKm have high voltages in order at first, second, third, and m-th clocks, respectively. Here, a period for which two adjacent clock signals have a low voltage may be present in a period for which either of the two adjacent clock signals has a high voltage. That is, one clock for which a certain clock signal has a high voltage, may include a period for which the clock signal has a low voltage in part. In addition, a low voltage of each clock signal is set to the same voltage as the low voltage power line VGL, and a high voltage of each clock signal is set to the same voltage as a high voltage power line VGH (not shown).
Next, input terminals and output terminals of each shift register basic circuit SR will be described. The n-th shift register basic circuit SRn has four input terminals IN1, IN2, IN3, and IN4 and three output terminals OUT1, OUT2, and OUT3. In addition, one of the two-phase clock signals VCK1 and VCK2 input to the n-th shift register basic circuit SRn is expressed as Vn, and the other one is expressed as Vn+1. Generally, “Vn+m=Vn=Vn−m” is satisfied when m-phase clock signals are input. Therefore, in the gate signal line driving circuit 22 according to the present embodiment, “Vn+2=Vn=Vn−2, Vn+1=Vn−1” is satisfied since the two-phase (m=2) clock signals VCK1 and VCK2 are input.
A gate signal Gn is output from the output terminal OUT1 of the n-th shift register basic circuit SRn, a node NBn to be described later is output from the output terminal OUT2, and a node NCn to be described later is output from the output terminal OUT3. The output terminal OUT1 is connected to the corresponding gate signal line 105. In addition, an (n+1)-th gate signal Gn+1 output from the (n+1)-th shift register basic circuit SRn+1 is input to the input terminal IN1 of the n-th shift register basic circuit SRn, nodes NBn−1 and NCn−1 respectively output from the output terminals OUT2 and OUT3 of the (n−1)-th shift register basic circuit are respectively input to the two input terminals IN2 and IN3, and the start signal VRES is input to the input terminal IN4.
In general, for the n-th shift register basic circuit SRn in order of the forward direction among the plural shift register basic circuits SR which output high-voltage gate signals, the preceding shift register basic circuit SR indicates an (n−1)-th shift register basic circuit SRn−1 and the subsequent shift register basic circuit SR indicates an (n+1)-th shift register basic circuit SRn+1.
The clock signal VCK1 is input to the Vn of the odd-numbered shift register basic circuit SR, and the clock signal VCK2 is input to the Vn+1. On the other hand, the clock signal VCK2 is input to the Vn of the even-numbered shift register basic circuit SR, and the clock signal VCK1 is input to the Vn+1. That is, Vn is the clock signal VCK1 and Vn+1 is the clock signal VCK2 when n is an odd number, and Vn is the clock signal VCK2 and Vn+1 is the clock signal VCK1 when n is an even number.
In addition, the dummy circuit SR0 is disposed before the first shift register basic circuit SR1. The start signal VRES is input to the input terminal IN2 of the dummy circuit SR0. The input terminals IN1, IN3, and IN4 and the output terminal OUT1 do not necessarily need to be provided in the dummy circuit SR0, and may be omitted.
As shown in
In addition, transistors shown in
The n-type TFT is turned on when the gate potential becomes higher than the source potential by a voltage more than a threshold voltage VTH. The voltage which turns on the n-type TFT is an ON voltage. Similarly, the voltage which turns off the n-type TFT is an OFF voltage. In addition, although the transistor according to the present embodiment is described as an n-type TFT herein, the invention may also be applied to a p-type TFT. However, the p-type TFT is turned on when the gate potential becomes lower than the source potential by a voltage more than the threshold voltage VTH. This voltage may be called an ON voltage, and the voltage which turns off the p-type TFT may be called an OFF voltage similarly.
The invention is characterized in that the shift register basic circuit SR includes a second gate line low voltage application circuit (transistor T10) which outputs a low voltage to the output terminal OUT1 in an ON state. In the n-th shift register basic circuit SRn, the gate line high voltage application circuit (transistor T1) applies a high voltage to the output terminal OUT1 during a high signal period. Then, in at least a part of a period until the gate line low voltage application circuit (transistor T9) is turned on after the gate line high voltage application circuit is turned off, the second gate line low voltage application circuit is in an ON state and applies a low voltage to the output terminal OUT1. Accordingly, since a low voltage is stably applied to the output terminal OUT1 during a period for which the second gate line low voltage application circuit is in an ON state, the n-th shift register basic circuit SRn can output the gate signal Gn with higher quality.
Next, the circuit configuration of the n-th shift register basic circuit SRn of the gate signal line driving circuit 22 according to the present embodiment shown in
A transistor T1 is a gate line high voltage application circuit. The clock signal Vn which is one of the two-phase clock signals VCK1 and VCK2 is input to the input side of the transistor T1, and the output terminal OUT1 is connected to the output side of the transistor T1. The voltage applied to the gate of the transistor T1 is the node NAn. During the high signal period, the node NAn is an ON voltage. When the node NAn is an ON voltage, the transistor T1 is in an ON state. Accordingly, the transistor T1 applies the input clock signal Vn to the output terminal OUT1. Since the clock signal Vn has a high voltage during the high signal period, the gate signal Gn output from the output terminal OUT1 has a high voltage during the high signal period.
A transistor T2 is a voltage buffer circuit, and serves to buffer a rapid voltage change. A buffered voltage which is a voltage of the buffered voltage power line VDD is applied to the gate of the transistor T2. Here, the buffered voltage is a voltage between a high voltage and a low voltage, and is a sufficient voltage for turning on a transistor compared with the low voltage. For example, when the high voltage is +10 V and the low voltage is −7 V, an appropriate voltage higher than −7 V and lower than +10 V is preferably selected as the buffered voltage. For example, the buffered voltage is +5 V. In addition, if a ground voltage GND (=0 V) is set as the buffered voltage, it is possible to reduce the power consumption since a voltage source is not required in particular.
The transistor T2 is disposed between the input terminal IN2 and the node NAn. Here, for the sake of convenience, it is assumed that the input side of the transistor T2 is connected to the input terminal IN2 and the output side of the transistor T2 is connected to the node NAn. Accordingly, when the node NAn is a low voltage, the transistor T2 is turned on by the buffered voltage. When a higher voltage than the buffered voltage is input to the input terminal IN2, the transistor T2 drops the higher voltage so that the buffered voltage is applied to the node NAn. That is, the ON voltage of the node NAn is as high as the buffered voltage. Moreover, the node NAn may have a higher voltage than the normal ON voltage due to the bootstrap effect, as will be described later. In this case, however, the transistor T2 suppresses “the voltage of the input terminal IN2 becomes higher than the buffered voltage”.
An output side of a transistor T8 is connected to the input side of the transistor T2 in parallel with respect to the input terminal IN2. The transistor T8 is a high voltage application OFF control circuit. The low voltage power line VGL is connected to the input side of the transistor T8, and the input terminal IN3 is connected to a gate of the transistor T8. Accordingly, when the ON voltage is applied to the input terminal IN3, the transistor T8 is turned on. Then, the transistor T8 applies a low voltage (OFF voltage) of the low voltage power line VGL to the input side of the transistor T2. In this case, since the transistor T2 is in an ON state by the buffered voltage of the buffered voltage power line VDD applied to the gate of the transistor T2, the transistor T2 applies an OFF voltage to the node NAn. That is, in the ON state, the transistor T8 is a high voltage application OFF control circuit which applies an OFF voltage to the node NAn.
Transistors T14 and T3 are a next stage control signal output circuit. The clock signal Vn is input to the input side of the transistor T14, and the node NAn is connected to a gate of the transistor T14. The input side and the gate of the transistor T3 are connected to the output side of the transistor T14 as diode connection. The output terminal OUT2 is connected to the output side of the transistor T3. Accordingly, when the node NAn becomes an ON voltage, the transistor T14 is turned on, similar to the transistor T1. As a result, the transistor T14 outputs the input clock signal Vn from the output side. Since the clock signal Vn has a high voltage during a high signal period as described above, the transistor T3 is in an ON state during the high signal period. Accordingly, the transistor T3 applies the high voltage of the clock signal Vn to the output terminal OUT2. In addition, the voltage of the output terminal OUT2 is the node NBn. In addition, since the transistor T3 is diode-connected, the transistor T3 is turned off when the voltage at the output side of the transistor T3 is higher than the voltage at the input side.
A transistor T9 is a gate line low voltage application circuit. The low voltage power line VGL is connected to the input side of the transistor T9, and the output terminal OUT1 is connected to the output side of the transistor T9. A voltage applied to a gate of the transistor T9 is the node NCn, and the node NCn is applied to the output terminal OUTS. When the node NCn is an ON voltage, the transistor T9 is in an ON state. Accordingly, the transistor T9 applies a low voltage of the low voltage power line VGL to the output terminal OUT1.
A transistor T7 is a low voltage application OFF control circuit which applies an OFF voltage to the node NC in the ON state. The low voltage power line VGL is connected to the input side of the transistor T7, the node NCn is connected to the output side of the transistor T7, and the input terminal IN2 and the output side of the transistor T8 are connected to a gate of the transistor T7. Accordingly, when the input terminal IN2 has a high voltage, the transistor T7 is in an ON state. Then, the transistor T7 applies a low voltage (OFF voltage) of the low voltage power line VGL to the node NCn. In addition, when the transistor T8 is turned on and the low voltage (OFF voltage) is applied to the gate of the transistor T7, the transistor T7 is turned off.
A low voltage application ON control circuit 29 is configured to include transistors T4, T5, and T6 and a capacitor C1, and is a booster circuit which boosts the node NC to the ON voltage.
The input side and the gate of the transistor T4 are connected to the clock signal Vn+1 as diode connection. The transistor T5 is disposed between the output side of the transistor T4 and the input side of the transistor T6. The transistor T5 is a voltage buffer circuit similar to the transistor T2, and the buffered voltage power line VDD is connected to a gate of the transistor T5. The capacitor C1 is disposed between a gate and the input side of the transistor T6. The clock signal Vn is input to the gate of the transistor T6, and the output side of the transistor T6 is connected to the node NCn. In addition, it is assumed that an upper electrode of the capacitor C1 in
When the clock signal Vn has a low voltage and the clock signal Vn+1 has a high voltage, the transistor T4 is turned on and the output side of the transistor T4 has a high voltage. In this case, a voltage drop occurs due to the transistor T5 in an ON state, and the output side of the transistor T5 has a buffered voltage (ON voltage) of the buffered voltage power line VDD. Accordingly, the input side of the transistor T6 and the first electrode of the capacitor C1 have an ON voltage. In addition, since the gate of the transistor T6 and the second electrode of the capacitor C1 have a low voltage, the transistor T6 is turned off and the capacitor C1 is charged so that the first electrode becomes higher than the second electrode.
Then, the clock signal Vn+1 changes from high voltage to low voltage. Then, the clock signal Vn changes from low voltage to high voltage. When the clock signal Vn+1 changes from high voltage to low voltage, the transistor T4 is turned off. In addition, when the clock signal Vn changes from low voltage to high voltage, the second electrode of the capacitor C1 has a high voltage, and the voltage of the first electrode of the capacitor C1 rises due to coupling of the capacitor C1. As a result, since the transistor T6 is turned on and a positive charge stored in the first electrode of the capacitor C1 moves to the node NCn through the transistor T6 in an ON state, the voltage at the node NCn rises. That is, the low voltage application ON control circuit 29 boosts the node NCn to the ON voltage at the timing at which the clock signal Vn changes from low voltage to high voltage.
Then, the clock signal Vn changes from high voltage to low voltage. Then, the clock signal Vn+1 changes from low voltage to high voltage. As a result, the transistor T6 is turned off, and the capacitor C1 is charged again. By repeating this, the node NCn maintains an ON voltage.
A transistor T10 is a second gate line low voltage application circuit. Similar to the transistor T9, the low voltage power line VGL is connected to the input side of the transistor T10, and the output terminal OUT1 is connected to the output side of the transistor T10. That is, the transistor T10 is disposed in parallel with the transistor T9 with respect to the output terminal OUT1. The input terminal IN1 is connected to a gate of the transistor T10. When the ON voltage is applied to the input terminal IN1, the transistor T10 is in an ON state. Accordingly, the transistor T10 applies a low voltage of the low voltage power line VGL to the output terminal OUT1.
A transistor T11 is a reset circuit. An input terminal IN4 is connected to the input side and a gate of the transistor T11 as diode connection. In addition, the start signal VRES is input to the input terminal IN4. In addition, the node NCn is connected to the output side of the transistor T11. The start signal VRES has an ON voltage at the start of the 1 frame period TF and has an OFF voltage in the other period. Accordingly, when the start signal VRES has an ON voltage, the transistor T11 of each shift register basic circuit SR to which the start signal VRES is input is turned on all at once, and the ON voltage is applied to the node NC of each shift register basic circuit SR. As a result, not only by the low voltage application ON control circuit 29 but also by the transistor T11, the ON voltage is stably maintained at the node NCn during a low signal period, and the transistor T9 which is turned on applies a low voltage to the output terminal OUT1 stably.
The node NBn−1 of the (n−1)-th shift register basic circuit SRn−1 is input to the input terminal IN2 of the n-th shift register basic circuit SRn. Similarly, the node NCn−1 is input to the input terminal IN3 of the n-th shift register basic circuit SRn. In addition, the start signal VRES is input to the input terminal IN4 of each shift register basic circuit SR.
As shown in
Then, in the period P1, the node NAn−1 is an ON voltage and the node is an OFF voltage (low voltage). In addition, in the period P1, the (n−1)-th gate signal Gn−1 has a low voltage, and the node NBn−1 is a low voltage as will be described later.
Here, driving in the n-th shift register basic circuit SRn will be described. In the period P1, the node NBn−1 input to the input terminal IN2 is a low voltage and the node NCn−1 input to the input terminal IN3 is an OFF voltage and accordingly, the transistor T8 is turned off. Therefore, the input side of the transistor T2 is a low voltage (OFF voltage), and the node NAn maintains an OFF voltage through the transistor T2 in the ON state. Since the node NAn is an OFF voltage, the transistors T1 and T14 are turned off. Accordingly, the node NBn maintains a low voltage. In addition, the node NCn maintains an ON voltage through the low voltage application ON control circuit 29.
At time t1, the clock signal Vn−1 changes from low voltage to high voltage. According to the change of the gate signal Gn−1 from low voltage to high voltage, the node NBn−1 changes from low voltage to high voltage. As a result, the node NAn changes from OFF voltage to ON voltage through the transistor T2 in the ON state. In addition, the transistor T8 maintains an OFF state. In addition, since the gate of the transistor T7 changes from low voltage to high voltage, the transistor T7 is turned on and the node NCn changes from ON voltage to OFF voltage.
As described above, in the period P2, the node NAn is an ON voltage and the node NCn is an OFF voltage. In addition, since the node NAn is an ON voltage, the transistors T1 and T14 are turned on. In the period P2, however, the clock signal Vn has a low voltage. Accordingly, since the transistor T1 applies a low voltage of the clock signal Vn to the output terminal OUT1, the gate signal Gn maintains a low voltage. Moreover, similarly, the transistor T14 applies a low voltage to the gate and the input side of the transistor T3 and accordingly, the transistor T3 is turned off. Therefore, the node NBn maintains a low voltage similar to the gate signal Gn, as will be described later.
In the period P3 (except for a part), the clock signal Vn has a high voltage. During a period for which the clock signal Vn has a high voltage, the transistor T1 in the ON state applies a high voltage of the clock signal Vn to the output terminal OUT1. That is, a period for which the clock signal Vn has a high voltage in the period P3 is a high signal period. During the high signal period, the gate signal Gn output from the output terminal OUT1 has a high voltage. Similarly, during the high signal period, the transistor T14 in the ON state outputs a high voltage of the clock signal Vn, and the node NBn which is a voltage applied to the output terminal OUT2 becomes a high voltage through the transistor T3 in the ON state.
In practice, in the period P2, the node NAn is an ON voltage which is a voltage lower than the high voltage of the clock signal Vn. In the period P3, this voltage is not sufficient to turn on the transistor T1 completely. However, the transistor T1 is formed so that the parasitic capacitance C (not shown) is generated between the gate and the output side of the transistor T1. In the period P2, the voltage of the node NAn becomes an ON voltage, and the parasitic capacitance C is charged with this voltage. At the start time of the period P3, the node NAn maintains an ON voltage and the transistor T1 maintains an ON state. The clock signal Vn with a high voltage is input to the input side of the transistor T1 in the ON state, and this increases an output-side voltage of the transistor T1. In this case, the node NAn is increased to a voltage, which is obtained by adding the voltage of the parasitic capacitance C to the output-side voltage, by capacitive coupling of the parasitic capacitance C. This is called a bootstrap effect. Then, since the transistor T1 is turned on, the gate signal Gn output from the output terminal OUT1 is increased to approximately the same voltage as a high voltage of the input clock signal Vn.
Even if the node NAn is increased to a voltage higher than the ON voltage by the bootstrap effect, the voltage of the input terminal IN2 becomes an ON voltage since the transistor T2 in the ON state drops to a buffered voltage. That is, the node NBn−1 connected to the input terminal IN2 is an ON voltage during the period P3.
At time t2, the clock signal Vn−1 changes from low voltage to high voltage. Then, the node NCn−1 changes from OFF voltage to ON voltage by the low voltage application ON control circuit 29 of the (n−1)-th shift register basic circuit SRn−1. Then, the gate of the transistor T8 connected to the input terminal IN3 to which the node NCn−1 is connected changes from OFF voltage to ON voltage, and the transistor T8 is turned on. Then, the transistor T8 applies a low voltage (OFF voltage) of the low voltage power line VGL to the input side of the transistor T2. Through the transistor T2 in the ON state, the node NAn changes from ON voltage to OFF voltage. That is, the OFF voltage is applied to the node NAn by the transistor T8 which is turned on at a timing at which the node NCn−1 changes from OFF voltage to ON voltage. Accordingly, the transistors T1 and T14 are turned off. At the same time, since the gate of the transistor T7 changes from ON voltage to OFF voltage by the transistor T8 in the ON state, the transistor T7 is turned off. Accordingly, during the period P4, the node NAn is an OFF voltage, and the transistors T1 and T14 are turned off. In addition, during the period P4, the clock signal Vn is a low voltage, and the transistor T6 is in an OFF state. Accordingly, the node NCn maintains an OFF voltage. In addition, the transistor T9 maintains an OFF state.
Thus, since both the transistors T1 and T9 are in the OFF state during the period P4, the output terminal OUT1 is in a float state if there is no transistor T10. However, since the (n+1)-th gate signal Gn+1 is input to the input terminal IN1 connected to the gate of the transistor T10 and the gate signal Gn+1 changes from low voltage to high voltage at time t2, the transistor T10 is turned on. Accordingly, during the high signal period of the (n+1)-th gate signal Gn+1, the transistor T10 is in an ON state, and the transistor T10 applies the low voltage of the low voltage power line VGL to the output terminal OUT1.
Although the node NCn maintains an OFF voltage during the period P4 in
After the clock signal Vn−1 changes from high voltage to low voltage, the clock signal Vn changes from low voltage to high voltage and the node NCn changes from OFF voltage to ON voltage by the low voltage application ON control circuit 29 at time t3. Accordingly, during the period P5, the node NCn becomes an ON voltage. Even after the period P5, the low voltage application ON control circuit 29 boosts the node NCn to the ON voltage periodically (every two clocks), so that the node NCn maintains an ON voltage.
In addition, at time t2, the transistor T8 is turned on when the node NCn−1 changes from OFF voltage to ON voltage, and the transistor T8 applies a low voltage of the low voltage power line VGL to the input side of the transistor T2 and the input terminal IN2. Accordingly, the node NBn−1 of the (n−1)-th shift register basic circuit SRn−1 connected to the input terminal IN2 changes from ON voltage to low voltage (OFF voltage). Then, since the node NCn−1 maintains an ON voltage, the node NBn−1 maintains a low voltage in the meantime.
Similarly, at time t3, the node NCn changes from OFF voltage to ON voltage and accordingly, the node NBn changes from ON voltage to low voltage (OFF voltage). Then, the node NBn maintains a low voltage. In addition, when the node NCn changes from ON voltage to OFF voltage at time t1, the transistors T8 of the (n+1)-th shift register basic circuit SRn+1 is turned off. However, a low voltage is maintained at the input terminal IN2 of the (n+1)-th shift register basic circuit SRn+1 during the period P2 and accordingly, the node NBn maintains a low voltage similarly. Accordingly, the node NBn becomes equal to or higher than the ON voltage during the periods P3 and P4. This period is equal to the period for which the node NAn+1 is an ON voltage.
Here, it is assumed that the node NBn−1 is input to the input terminal IN2 of the n-th shift register basic circuit SRn. Accordingly, the n-th gate signal Gn is not directly influenced by voltage changes of the (n+1)-th (next-stage) input terminal IN2, and this improves the quality of the gate signal Gn. However, in the case of driving only in the forward direction like the gate signal line driving circuit 22 according to the present embodiment, the (n−1)-th (preceding-stage) gate signal Gn−1 may be input to the node NBn−1. In this case, in order to suppress the influence of the voltage output from the transistor T8 or the voltage of the node NAn to the (n−1)-th gate signal Gn−1, it is necessary to provide the transistor T3 between the input terminal IN2 and the input side of the transistor T2 (output side of the transistor T8). In this case, since it is not necessary to newly provide the transistor 114, the circuit size is reduced.
In addition, clock signals input to the gate signal line driving circuit 22 herein are the two-phase clock signals VCK1 and VCK2. Using the two-phase clock signals VCK1 and VCK2, the low voltage application ON control circuit 29 boosts the node NCn to the ON voltage every two clocks. Therefore, as shown in
In addition, clock signals input to the gate signal line driving circuit 22 are not limited to the two-phase clock signals VCK1 and VCK2. In general, m-phase (m is 2 or more) clock signals may be input to the gate signal line driving circuit 22. In each shift register basic circuit SR, preferably, when there is a period (a time difference occurs) between the timing at which the node NA changes from ON voltage to OFF voltage and the timing at which the low voltage application ON control circuit 29 boosts the node NC, the second gate line low voltage application circuit (transistor T10) is turned on at least in a part of the period so that the second gate line low voltage application circuit applies a low voltage to the output terminal OUT1.
In addition, the transistors T8 and T11 may not be provided in the dummy circuit SR0 shown in
A display device according to a second embodiment of the invention has basically the same configuration as the display device according to the first embodiment. The main difference between the display device according to the second embodiment and the display device according to the first embodiment is that the gate signal line driving circuit 22 according to the present embodiment can perform bidirectional driving so that either forward driving or reverse driving can be selectively performed.
In the gate signal line driving circuit 22 according to the first embodiment, both the gate signal line driving circuit 22R shown at the right side of
Moreover, for example, when there are 854 gate signal lines 105, each of the gate signal line driving circuit 22R which performs forward driving and the gate signal line driving circuit 22L which performs reverse driving includes 854 shift register basic circuits SR.
The block diagram of the plural shift register basic circuits SR shown in
In addition, in the gate signal line driving circuit 22L which performs reverse driving, nodes NBn+1 and NCn+1 output from the output terminals OUT2 and OUT3 of the (n+1)-th shift register basic circuit SRn+1 are input to the input terminals IN2 and IN3 of the n-th shift register basic circuit SRn, respectively. In addition, the (n−1)-th gate signal Gn−1 is input to the input terminal IN1 of the n-th shift register basic circuit SRn. In general, for the n-th shift register basic circuit SRn in order of the reverse direction among the plural shift register basic circuits SR which output high-voltage gate signals, the preceding shift register basic circuit SR indicates an (n+1)-th shift register basic circuit SRn+1 and the subsequent shift register basic circuit SR indicates an (n−1)-th shift register basic circuit SRn−1. In addition, a dummy circuit SR855 is disposed before the 854-th shift register basic circuit SR854, and the start signal VRES is input to the input terminal IN2 similar to the dummy circuit SR0 shown in
The main difference between the n-th shift register basic circuit SRn according to the first embodiment shown in
A transistor T12 is a high voltage application driving OFF control circuit which is turned on when the driving direction is different in order to apply an OFF voltage to the node NA. The driving direction control line VDR is connected to the gate of the transistor T12, the low voltage power line VGL is connected to the input side of the transistor T12, and the output side of the transistor T12 is connected to the input side of the transistor T2.
Similarly, a transistor T13 is a low voltage application driving OFF control circuit which is turned on when the driving direction is different in order to apply an OFF voltage to the node NC. The driving direction control line VDR is connected to the gate of the transistor T13, the low voltage power line VGL is connected to the input side of the transistor T13, and the node NCn is connected to the output side of the transistor T13.
The driving direction control line VDR(R) connected to the gate signal line driving circuit 22R which performs forward driving has a low voltage at the time of forward driving and has an intermediate voltage VM when performing reverse driving. That is, the driving direction control line VDR has an OFF voltage when the driving direction selected from two directions is the same as a driving direction of a gate signal line driving circuit connected to the driving direction control line VDR and has an intermediate voltage VM when the driving direction selected from two directions is different from the driving direction of the gate signal line driving circuit connected to the driving direction control line VDR.
Here, the intermediate voltage VM is a voltage between a high voltage and a low voltage and is a sufficient voltage for turning on a transistor compared with the low voltage, similar to the buffered voltage which is a voltage of the buffered voltage power line VDD. For example, when the high voltage is +10 V and the low voltage is −7 V, an appropriate voltage higher than −7 V and lower than +10 V is preferably selected as the intermediate voltage VM. If the intermediate voltage VM is set to be the same as the buffered voltage of the buffered voltage power line VDD, it is possible to reduce power consumption without requiring a new voltage source in order to generate a voltage of the driving direction control line VDR. In addition, if the intermediate voltage VM is set as the ground voltage GND, it is possible to further reduce power consumption.
Since the driving direction control line VDR(R) has a low voltage at the time of forward driving, a low voltage (OFF voltage) is applied to each gate of the transistors T12 and T13. As a result, both the transistors T12 and T13 maintain an OFF state. Since the driving direction control line VDR(R) has an intermediate voltage VM at the time of reverse driving, the intermediate voltage VM which is an ON voltage is applied to each gate of the transistors T12 and T13. As a result, both the transistors T12 and T13 maintain an ON state.
Since the transistor T12 in the ON state applies the low voltage of the low voltage power line VGL to the input side of the transistor T2, the node NAn maintains an OFF voltage through the transistor T2 in the ON state. That is, when the transistor T12 is turned on, the OFF voltage is applied to the node NAn. In this case, since the transistor T1 maintains an OFF state, the transistor T1 does not apply the clock signal Vn to the output terminal OUT1. Since the transistor T14 maintains an OFF state, the node NBn output from the output terminal OUT2 does not become a high voltage. Similarly, since the transistor T13 in the ON state applies the low voltage (OFF voltage) of the low voltage power line VCL to the node NCn, the transistor T9 maintains an OFF state.
In contrast, the start signal VRES(L) and the clock signals VCK1(L) and VCK2(L) connected to the gate signal line driving circuit 22L which performs reverse driving maintain a low voltage, and the driving direction control line VDR(L) maintains the intermediate voltage VM. Here, a case where the intermediate voltage VM is the ground voltage GND is shown.
As described above, when the driving direction control line VDR(L) maintains the intermediate voltage VM, the transistors T12 and T13 in each shift register basic circuit SR of the gate signal line driving circuit 22L which performs reverse driving are turned on. Accordingly, since both the nodes NA and NC maintain an OFF voltage, each shift register basic circuit SR does not contribute to the output to the output terminal OUT1 at all.
In addition, when the gate signal line driving circuit 22 according to the present embodiment performs reverse driving, the start signal VRES(L), the clock signals VCK1(L) and VCK2(L), and the driving direction control line VDR(L), which are connected to the gate signal line driving circuit 22L which performs reverse driving, perform the same driving as the start signal VRES(L), the clock signals VCK1(R) and VCK2(R), and the driving direction control line VDR(R) shown in
For example, in the case of performing forward driving as shown in
A display device according to a third embodiment of the invention has basically the same configuration as the display device according to the second embodiment. Similar to the gate signal line driving circuit 22 according to the second embodiment, a gate signal line driving circuit 22 according to the present embodiment can perform bidirectional driving so that either forward driving or reverse driving can be selectively performed. In addition, the main difference between the display device according to the third embodiment and the display device according to the second embodiment is the configuration of the shift register basic circuit SR.
A transistor T15 is a switching control circuit, and supplies a control voltage to a switch (gate) of the high voltage application driving OFF control circuit (transistor T12) or the low voltage application driving OFF control circuit (transistor T13). The buffered voltage power line VDD is connected to the gate of the transistor T15, so that an ON voltage is applied to the gate of the transistor T15. The driving direction control line VDR is connected to the input side of the transistor T15, and the output side of the transistor T15 is connected to the gates of the transistors T12 and T13. The voltage of the driving direction control line VDR is applied to the gates of the transistors T12 and T13 as a control voltage through the transistor T15 in the ON state. In addition, when the voltage of the driving direction control line VDR is higher than the buffered voltage of the buffered voltage power line VDD, the voltage of the driving direction control line VDR drops to the buffered voltage due to the transistor T15, and this voltage becomes a control voltage.
The start signal VRES(L) and the clock signals VCK1(L) and VCK2(L) connected to the gate signal line driving circuit 22L which performs reverse driving maintain a low voltage, as in
By repeating a high voltage and a low voltage as a voltage of the driving direction control line VDR similar to the clock signal, it is possible to generate the driving direction control line VDR using a voltage source required to generate the two-phase clock signals VCK1 and VCK2 and a new voltage source is not required.
As shown in
In addition, as shown in
In addition, when the gate signal line driving circuit 22 according to the present embodiment performs reverse driving, the start signal VRES(L), the clock signals VCK1(L) and VCK2(L), and the driving direction control line VDR(L), which are connected to the gate signal line driving circuit 22L which performs reverse driving, perform the same driving as the start signal VRES(R), the clock signals VCK1(R) and VCK2(R), and the driving direction control line VDR(R) shown in
For example, in the case of performing forward driving as shown in
By applying a low voltage to the gates of the transistors T12 and T13 in at least a part of the blanking period TB of the 1 frame period TF in order to turn off the transistors T12 and T13, the shift of the threshold voltage VTH of the transistors T12 and T13 to the negative side is further suppressed, compared with that when the transistors T12 and T13 have an ON state for a long time. This improves the reliability of the gate signal line driving circuit 22.
Here, although the voltage of the driving direction control line VDR is set to repeat a high voltage and a low voltage, the voltage of the driving direction control line VDR is not limited to this. Using the intermediate voltage VM instead of a high voltage as in the second embodiment, the voltage of the driving direction control line VDR may also be set to repeat the intermediate voltage VM and a low voltage. In addition, the intermediate voltage VM may be set to be the same as the buffered voltage of the buffered voltage power line VDD, and the intermediate voltage VM may be set as the ground voltage GND.
In addition, in the second embodiment, the voltage of the driving direction control line VDR connected to the plural shift register basic circuits SR which are not driven is maintained as the intermediate voltage VM. However, the voltage of the driving direction control line VDR may also be set as a low voltage in at least a part of the blanking period TB of the 1 frame period TF, as in the third embodiment. In this case, since the shift of the threshold voltage VTG of the transistors T12 and T13 to the negative side is further suppressed compared with that when the transistors T12 and T13 have an ON state for a long time, the reliability of the gate signal line driving circuit 22 is improved.
A display device according to a fourth embodiment of the invention is an IPS liquid crystal display device 1, for example, and includes the gate signal line driving circuit 22 according to any one of the first to third embodiments. In addition, the configuration of the TFT substrate 12 of the liquid crystal display device 1 according to the present embodiment is the same as the block diagram shown in
As described above, the voltage of a video signal is supplied to each of the plural display dots of the display unit 27 by dot inversion driving. For example, pixels aligned horizontally in one row are assumed to be first, second, third, and fourth pixels in order from the left. As described above, in each pixel, three display dots of red, green, and blue colors are aligned in this order. Accordingly, the first pixel is formed by a first R display dot, a first G display dot, and a first B display dot, and this is the same for other pixels. In a certain frame period TF, when the voltage sign of a video signal supplied from the driver IC 21 to the first R display dot is positive, the voltage sign of a video signal supplied to the first G display dot is negative by dot inversion driving. In this case, in order from the first R display dot and in the left direction, the signs of voltages of video signals are positive, negative, positive, and negative, which are alternately different.
The precharge circuit 25 includes plural switching elements (transistors) disposed corresponding to the plural video signal lines 107 (not shown). An odd-numbered precharge control line PRG1 is connected to a gate of an odd-numbered transistor from the left, and an even-numbered precharge control line PRG2 is connected to a gate of an even-numbered transistor from the left. In addition, a precharge voltage line PRN is connected to the input side of each switching element.
The output side of each switching element is connected to the corresponding video signal line 107. Accordingly, in the ON state, each switching element supplies the precharge voltage of the precharge voltage line PRN to the first R display dot, the first G display dot, the first B display dot, the second R display dot, the second G display dot, and the second B display dot, in order from the left. Since output-side terminals of switching elements are connected to the video signal lines 107 corresponding to the first R display dot, the first G display dot, the first B display dot, the output-side terminals of the switching elements are expressed as DR1, DG1, DB1,
When the odd-numbered precharge control line PRG1 or the even-numbered precharge control line PRG2 has an ON voltage, the ON voltage is applied to gates of plural transistors connected thereto. Through the transistor in the ON state, the precharge voltage of the precharge voltage line PRN is supplied to the pixel electrode 110 of a corresponding display dot.
As described later, in the liquid crystal display device 1 according to the present embodiment, precharge driving is performed before a video signal is supplied for a display dot, in which the voltage sign of the supplied video signal is positive, among display dots which perform writing of video data in a high signal period (horizontal period H) of each gate signal. Therefore, the voltage of either the odd-numbered precharge control line PRG1 or the even-numbered precharge control line PRG2 becomes an ON voltage corresponding to the pixel electrode 110 of a display dot in which the voltage sign of a video signal becomes positive at the start of a high signal period (horizontal period H) of each gate signal, that is, according to the start of the high signal period. Then, the ON voltage is applied to the gates of the plural corresponding transistors. Through the transistor in the ON state, a precharge voltage of the precharge voltage line PRN is supplied to the pixel electrode 110 of the corresponding display dot. The precharge voltage is a much lower voltage than the minimum value of the voltage of a video signal supplied to the corresponding video signal line 107. In addition, the minimum value of the voltage of the video signal is a voltage when the sign of the voltage of the video signal is negative and the absolute value of the voltage of the video signal with respect to the reference voltage becomes a maximum.
The RGB selection circuit 24 includes plural switching elements (transistors) disposed corresponding to the plural video signal lines 107. Using two pixels (six display dots) as one set, a first switch control line ASW1 is connected to gates of first and fourth transistors (for red display dots) from the left, a second switch control line ASW2 is connected to gates of second and fifth transistors (for green display dots), and a third switch control line ASW3 is connected to gates of third and sixth transistors (for blue display dots). In addition, a first data voltage supply line SIG1 (odd-numbered data voltage supply line) is connected to the input sides of the first, third, and fifth (odd-numbered) transistors, and a second data voltage supply line SIG2 (even-numbered data voltage supply line) is connected to the input sides of the second, fourth, and sixth (even-numbered) transistors.
In the 1 frame period TF, a high signal period (horizontal period H) of a gate signal output from the gate signal line driving circuit 22 to the corresponding gate signal line 105 is a period for which the video data is written into each of pixels which are aligned in one row and are connected to the corresponding gate signal line 105. During one horizontal period H, the first switch control line ASW1, the second switch control line ASW2, and the third switch control line ASW3 have an ON voltage in order, and the video data is written sequentially in corresponding display dots through the transistors in the ON state.
As described above, the liquid crystal display device 1 according to the present embodiment performs dot inversion driving. Accordingly, the voltage signs of video signals supplied to adjacent display dots are different. For example, the voltage sign of a video signal supplied to each display dot of the first pixel is positive, negative, and positive in order of the first R display dot, the first G display dot, and the first B display dot. Display dots in which the voltage signs of video signals are positive during a certain 1 horizontal period H are assumed to be a first R display dot, a first B display dot, and a second G display dot. In addition, these display dots are assumed to be odd-numbered display dots. On the other hand, display dots in which the voltage signs of video signals are negative during this 1 horizontal period H are assumed to be a first G display dot, a second R display dot, and a second B display dot, and these display dots are assumed to be even-numbered display dots.
Among display dots of the first and second pixels, three odd-numbered display dots are connected to the first data voltage supply line SIG1, which is an odd-numbered data voltage supply line, through a corresponding transistor and three even-numbered display dots are connected to the second data voltage supply line SIG2, which is an even-numbered data voltage supply line, through a corresponding transistor.
Since the RGB selection circuit 24 has such a configuration, the voltage signs of video signals supplied from each data voltage supply line to three display dots, which write video data in each horizontal period H, are the same. Accordingly, the load on the driver IC 21 when supplying the video signals to the three display dots in each horizontal period H is reduced.
The detection circuit 26 includes plural switching elements (transistors) disposed corresponding to plural data voltage supply lines. A switching element connected to the odd-numbered data voltage supply line is assumed to be an odd-numbered switching element (odd-numbered transistor), and a switching element connected to the even-numbered data voltage supply line is assumed to be an even-numbered switching element (even-numbered transistor). A first detection voltage supply line QDS1 (odd-numbered detection voltage supply line) is connected to the input side of an odd-numbered transistor (odd-numbered transistor) from the left, and a second detection voltage supply line QDS2 (even-numbered detection voltage supply line) is connected to the input side of an even-numbered transistor (even-numbered transistor) from the left. In addition, a detection control line QDG is connected to a gate of each switching element.
The detection circuit 26 is used for performance test of the TFT substrate 12 or for detection of the yield of the TFT substrate 12 after manufacturing the TFT substrate 12 of the liquid crystal display device 1 according to the present embodiment. When performing such detection test, a control signal is output to the gate signal line driving circuit 22 so as to perform forward driving, for example. The gate signal line driving circuit 22 outputs a gate signal in a high signal period in order of the forward direction. During each horizontal period H, an ON voltage is supplied to the detection control line QDG to turn on each switching element of the detection circuit 26. In addition, a detection voltage (for example, a voltage of video data of the maximum gradation value) for the corresponding display dot is supplied to each of the first and second detection voltage supply lines QDS1 and QDS2. Then, the detection voltage is supplied to the pixel electrode 110 of the corresponding display dot through each switching element in the ON state.
In this case, the first switch control line ASW1, the second switch control line ASW2, and the third switch control line ASW3 have an ON voltage in order during each horizontal period H, such that the detection voltage is applied to the three corresponding display dots through each data voltage supply line in each horizontal period H. Accordingly, the detection voltage is supplied to the pixel electrodes 110 of the corresponding display dots in order through plural transistors of the RGB selection circuit 24 in the ON state.
Since the liquid crystal display device 1 performs image display by dot inversion driving as described above, all signs of detection voltages which are supplied to three display dots through each data voltage supply line during each horizontal period H become equal by making the detection circuit 26 and the RGB selection circuit have the above-described configuration. As a result, the detection voltage is supplied to the three display dots in each horizontal period H.
The driving characteristic of the liquid crystal display device 1 according to the present embodiment is that precharge driving is performed for a display dot, in which the voltage sign of a video signal becomes positive, before the video signal is supplied. In
In a certain frame period TF, in first and second pixels aligned in the n-th row in order of a forward direction, all signs of voltages of video signals supplied to the first R display dot, the first B display dot, and the second G display dot connected to the first data voltage supply line SIG1 are negative, and all signs of voltages of video signals supplied to the first R display dot, the first B display dot, and the second G display dot aligned in the (n+1)-th row are positive. Accordingly, the voltage sign of a video signal supplied to the first data voltage supply line SIG1 is negative in a horizontal period Hn, which is shown at the left side in
Accordingly, in the horizontal period Hn, the voltage sign of the video signal supplied to the first data voltage supply line SIG1 is negative, and the odd-numbered precharge control line PRG1 maintains an OFF voltage. Then, in the horizontal period Hn+1, the voltage sign of the video signal is positive. At the start of the horizontal period Hn+1 (at a timing corresponding to the start of the horizontal period Hn+1), the odd-numbered precharge control line PRG1 has an ON voltage.
In
As described above, the precharge voltage applied to the precharge voltage line PRN is a much lower voltage than the minimum value of the voltage of a video signal supplied to the video signal line 107. When the odd-numbered precharge control line PRG1 has an ON voltage, an odd-numbered transistor from the left in
Then, GND precharge driving 42 is performed. Since the liquid crystal display device 1 according to the present embodiment performs dot inversion driving to perform display, the voltage signs of video signals supplied to the pixel electrodes 110 of adjacent display dots are different. Moreover, when the voltage sign of the video signal supplied to the pixel electrode 110 of a certain display dot is negative (positive) in a certain horizontal period H, the voltage sign of the video signal supplied to the pixel electrode 110 of the display dot in a subsequent horizontal period H is positive (negative). If the voltage applied to the video signal line 107 connected to the display dot is changed from negative to positive (from positive to negative) by the driver IC 21, the load on the driver IC 21 becomes large.
Accordingly, the GND precharge driving 42 is performed for all display dots in one row connected to the gate signal line 105 with a high-voltage gate signal, and the voltages of the plural video signal lines 107 and the pixel electrode 110 of display dots in the corresponding row are changed to the ground voltage GND. Specifically, the driver IC 21 makes all of the first to third switch control lines ASW1, ASW2, and ASW3 have an ON voltage, and supplies the ground voltage GND to all of the plural data voltage supply lines.
In this case, it is assumed that the GND precharge driving 42 is performed in each horizontal period H unlike the PRN precharge driving 41. In
After performing the GND precharge driving 42, the video data is written in each display dot. As described above, the first switch control line ASW1, the second switch control line ASW2, and the third switch control line ASW3 have an ON voltage in order, and the video data is written in corresponding display dots through the transistors in the ON state. Here, the video data is written in odd-numbered display dots of the first and second pixels through the first data voltage supply line SIG1. The voltage of a video signal is applied to the pixel electrode 110 through the first data voltage supply line SIG1 in order of the first R display dot, the second G display dot, and the first B display dot.
In addition, the video data is written in even-numbered display dots through the second data voltage supply line SIG2. Accordingly, the voltage sign of the video signal supplied to the second data voltage supply line SIG2 is always different from the voltage sign of the video signal supplied to the first data voltage supply line SIG1. Moreover, in each horizontal period H, the voltage of a video signal is applied to the pixel electrode 110 in order of the second R display dot, the first G display dot, and the second B display dot.
The voltage applied to the video signal line 107 of the first R display dot connected to the first data voltage supply line SIG1 is schematically shown at the bottom in
In a horizontal period Hn−1 (not shown) for which the (n−1)-th gate signal Gn−1 has a high voltage, the voltage of a video signal is supplied to odd-numbered display dots of the first and second pixels aligned in the (n−1)-th row through the first data voltage supply line SIG1, and the sign of the corresponding voltage is positive. Accordingly, the sign of the voltage applied to the video signal line 107 is positive.
In the horizontal period Hn, the voltage sign of a video signal supplied to odd-numbered display dots aligned in the n-th row is negative. Therefore, since the PRN precharge driving 41 is not performed for the corresponding display dots, the voltage applied to the video signal line 107 is a voltage of a video signal of odd-numbered display dots aligned in the (n−1)-th row as shown in
Then, the GND precharge driving 42 is performed. As a result, the voltage applied to the first data voltage supply line SIG1 and the connected three video signal lines 107 becomes the ground voltage GND. In addition, the video data is written in each display dot, but the voltage sign of the video signal supplied to odd-numbered display dots aligned in the n-th row is negative. Accordingly, as shown in
In the horizontal period Hn+1, the voltage sign of a video signal supplied to odd-numbered display dots aligned in the (n+1)-th row is positive. Accordingly, the PRN precharge driving 41 is performed for the corresponding display dots. As shown in
Then, similar to the horizontal period Hn, the voltage applied to the first data voltage supply line SIG1 and the connected video signal line 107 becomes the ground voltage GND by the GND precharge driving 42. In addition, by writing the video data in the corresponding display dots, the voltage applied to the video signal line 107 is shown in
In the above, driving of the liquid crystal display device 1 according to the present embodiment has been described. In the case where the display device performs display using a dot inversion method, the voltage sign of a video signal applied to the video signal line 107 in each horizontal period H of the 1 frame period TF changes. That is, the sign of the voltage applied to the video signal line 107 changes to repeat positive and negative signs. Between the video signal line 107 and the common signal line 108, there is capacitive coupling. Accordingly, as the voltage applied to the video signal line 107 changes, the reference voltage applied to the common signal line 108 (common electrode 111) changes due to the capacitive coupling.
A change of the common signal line 108 occurring when the voltage applied to the video signal line 107 changes in the negative direction and a change of the common signal line 108 occurring when the voltage applied to the video signal line 107 changes in the positive direction are assumed to be the same and symmetrical. In this case, in the frame period TF, the voltage applied to the video signal line 107 changes from negative to positive (in the positive direction) in a certain horizontal period H and then changes from positive to negative (in the negative direction) in the next horizontal period H. Accordingly, it is thought that the influence of changes of the common signal line 108 is negated in the 1 frame period TF. In addition, the signs of voltages applied to adjacent video signal lines are different. For this reason, in a certain horizontal period H, when the voltage applied to a certain video signal line 107 changes from negative to positive (in the positive direction), the voltage applied to an adjacent video signal line 107 changes from positive to negative (in the negative direction). Accordingly, it is thought that the influence of changes of the common signal line 108 is negated.
However, if the PRN precharge driving 41 is executed before writing in which the voltage sign of a video signal is negative, the common signal line 108 changes in the positive direction since the precharge voltage is lower than the minimum value of the voltage of a video signal. Accordingly, even at the time of writing in which the voltage sign of a video signal is positive, the common signal line 108 changes in the positive direction. As a result, the influence of changes of the common signal line 108 is not negated.
The inventors have found out through the study that it is possible to negate the influence of changes of the common signal line 108 by executing the PRN precharge driving 41 before the writing, in which the voltage sign of a video signal is positive, after the writing in which the voltage sign of a video signal is negative. Accordingly, driving shown in
As described above, the driving characteristic of the liquid crystal display device 1 according to the present embodiment is that the PRN precharge driving 41 is performed for a display dot, in which the voltage sign of a video signal becomes positive, before the video signal is supplied. As shown in
A display device according to a fifth embodiment of the invention has basically the same configuration as the display device 1 according to the fourth embodiment. A difference between the liquid crystal display device 1 according to the present embodiment and the liquid crystal display device 1 according to the fourth embodiment is the structure of the precharge circuit 25, the RGB selection circuit 24, and the detection circuit 26.
In the RGB selection circuit 24 according to the fourth embodiment shown in
As described above, in a certain horizontal period H, the voltage signs of video signals, which are supplied from the driver IC 21 to two adjacent display dots of three display dots connected to each data voltage supply line are different. Also in such a case, when there is a sufficient driving capability in the driver IC 21, the circuit size can be reduced by using the RGB selection circuit 24 shown in
The detection circuit 26 according to the present embodiment shown in
Also in this case, abnormal display is suppressed by performing the PRN precharge driving 41 for a display dot, in which the voltage of a supplied video signal becomes positive, before the video signal is supplied, similar to the driving in the fourth embodiment shown in
The detection circuit 26 is disposed every video signal line 107 connected to plural display dots aligned in each row. Each of three display dots of each pixel and a switching element (transistor) are connected to each other through the corresponding video signal line 107. The detection control line QDG is connected to a switch (gate) of each switching element (transistor). In addition, the first detection voltage supply line QDS1, the second detection voltage supply line QDS2, and the third detection voltage supply line QDS3 are connected to the input sides of plural switching elements (transistors) in order of red, green, and blue.
Also in this case, abnormal display is similarly suppressed by performing the PRN precharge driving 41 for a display dot, in which the voltage sign of a supplied video signal becomes positive, through the video signal line 107 before the video signal is supplied to the corresponding video signal line 107.
A display device according to a sixth embodiment of the invention has basically the same configuration as the display device according to the fourth embodiment. The liquid crystal display device 1 according to the fourth embodiment performs image display by dot inversion driving, while the liquid crystal display device 1 according to the present embodiment performs image display by line inversion driving.
Here, the line inversion driving refers to driving in which the voltage signs of video signals supplied to plural display dots provided in the display unit 27 are different between display dots adjacent to each other in the vertical direction shown in
Unlike the TFT substrate 12 shown in
The equalizing circuit 35 includes plural transistor elements (transistors), and two switching elements (transistors) disposed in parallel are disposed for each video signal line 107 (not shown). An equalizing control line EQG is connected to a gate of one transistor, and a reference voltage COM supplied to the common signal line 108 is input to the input side. A discharge control line VSS is connected to a gate of the other transistor, and a discharge voltage line DIS is connected to the input side.
When the equalizing control line EQG has an ON voltage, the reference voltage COM supplied to the common signal line 108 is applied to the plural video signal lines 107 through the transistors in the ON state. Then, equalizing driving 43 is performed as will be described later.
In addition, the discharge control line VSS always has an OFF voltage at the time of driving of the liquid crystal display device 1, but changes to an ON voltage when a supply source of the liquid crystal display 1, such as a battery, is detached. Accordingly, the voltage of the discharge voltage line DIS is applied to the plural video signal lines 107 through the transistors in the ON state. The voltage of the discharge voltage line DIS is the ground voltage GND, for example. Then, discharge driving is performed to discharge electric charges collected in the display unit 27 of the liquid crystal display device 1.
Assuming that display dots aligned in one row in the horizontal direction are the first R display dot, the first G display dot, the first B display dot, the second R display dot, the second G display dot, and the second B display dot in order from the left, the output side of each switching element is connected to the corresponding video signal line 107. In
The characteristic of the driving of the liquid crystal display device 1 according to the present embodiment is that equalizing driving is performed at the start of each horizontal period H. In
As described above, the equalizing driving 43 is performed at the start of each horizontal period H. Accordingly, both at the start of the horizontal period H, and at the start of the horizontal period Hn+1, the equalizing control line EQG has an ON voltage, so that the equalizing driving 43 is performed.
At the start of the horizontal period Hn, the reference voltage COM supplied to the common signal line 108 changes from the negative voltage to the positive voltage. Accordingly, if the equalizing driving 43 is not performed, the voltage applied to the video signal line 107 changes in the positive direction due to capacitive coupling. As a result, the voltage applied to the video signal line 107 is changed to the positive reference voltage COM by the equalizing driving 43.
After the equalizing driving 43, the video data is written in each display dot similar to the driving shown in
At the start of the horizontal period Hn+1, the reference voltage COM changes from the positive voltage to the negative voltage. Accordingly, if the equalizing driving 43 is not performed, the voltage applied to the video signal line 107 changes in the negative direction due to capacitive coupling. As a result, the voltage applied to the video signal line 107 is changed to the negative reference voltage COM by the equalizing driving 43. After the equalizing driving 43, the video data is similarly written in each display dot.
In the liquid crystal display device 1 according to the present embodiment, the RGB selection circuit 24 and the equalizing circuit 35 may be provided in the driver IC 21 as in
As the display devices according to the embodiments of the invention, the IPS liquid crystal display device has been described in the above as shown in
While there have been described what are at present considered to be certain embodiments of the invention, it will be understood that various modifications may be made thereto, and it is intended that the appended claims cover all such modifications as fall within the true spirit and scope of the invention.
Number | Date | Country | Kind |
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2011-013512 | Jan 2011 | JP | national |
This application is a continuation of U.S. application Ser. No. 14/805,134 filed on Jul. 21, 2015, which, in turn, is a continuation of U.S. application Ser. No. 13/356,700 (now U.S. Pat. No. 9,123,274) filed on Jan. 24, 2012. Further, this application claims priority from Japanese application No. 2011-013512 filed on Jan. 25, 2011, the contents of which are hereby incorporated by reference into this application.
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Number | Date | Country | |
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20170076686 A1 | Mar 2017 | US |
Number | Date | Country | |
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Parent | 14805134 | Jul 2015 | US |
Child | 15361785 | US | |
Parent | 13356700 | Jan 2012 | US |
Child | 14805134 | US |