This application claims priority to and the benefit of Korean Patent Application No. 2010-52240, filed Jun. 3, 2010, the disclosure of which is incorporated herein by reference in its entirety.
1. Field of the Invention
The present invention relates to a display driving circuit, and more particularly, to a display driving circuit which exhibits excellent output characteristics due to improved performance and has excellent reliability.
2. Discussion of Related Art
In general, it is difficult to diversely integrate circuits for driving pixels in a liquid crystal display (LCD) panel employing amorphous silicon (a-Si) thin-film transistors (TFTs) due to low mobility, unlike an LCD panel employing low-temperature polysilicon TFTs.
To solve this problem, active attempts to integrate regions capable of operating at a low frequency in a panel have been made lately. Among the attempts, integrating a gate driver circuit in a panel is considered the most efficient technique, and also the resultant product has been put on the market. Multiple LCD driving circuits in which a gate driver circuit is integrated according to conventional art are disclosed in Korean Patent Registration No. 705628 filed by the present Applicant, and so on.
To overcome low mobility, a gate driver circuit integrated in an LCD panel increases the width of a TFT and forms a shift register circuit using a bootstrap effect.
Referring to
At this time, since the voltage raised by the bootstrap effect is applied to the gate node of an output TFT T11, large current can flow through the output TFT T11, and the clock signal is output to an output node without significant loss of a rise/fall delay time. A signal delay of one horizontal time occurs between the input signal and the output signal, and thus the shift register circuit can normally operate.
Next, Korean Patent Registration No. 705628 filed by the present Applicant will be described as an example of a driving circuit in which a gate driver circuit is embedded according to conventional art.
Referring to
An output signal X of the inverter circuits T5 and T6 is applied to the TFT gate nodes of the pull-down portions T2 and T4. At this time, an increase in gate voltage leads to improvement in circuit performance, but deteriorates the TFTs due to stress caused by gate node bias voltage, which results in deterioration of reliability. In general, when the TFTs of pull-down portions T2 and T4 are turned off, a gate-source voltage (Vgs) of the TFTs is frequently 0 V or more, and in this case, there is leakage current.
Further, when the threshold voltage Vth is low and a mobility increasing factor, such as high temperature, occurs in the high-level section of an output of a gate driver integrated as a circuit leakage current component in the circuit of the pull-down portions T2 and T4, the output of the gate driver is attenuated and output.
The present invention is directed to providing a display driving circuit which exhibits excellent output characteristics due to improved performance and has excellent reliability.
One aspect of the present invention provides A display driving circuit, in which a gate driver including a plurality of shifter register stages for shifting and outputting an input signal is embedded, including: an input portion receiving a pulse input signal consisting of a high-level signal and a low-level signal and transferring the pulse input signal to a boosting node; an inverter portion connected with the input portion, and inverting the pulse input signal to output the inverted signal; and a pull-up/pull-down portion consisting of a pull-up portion connected to the input portion, receiving a boosting voltage from the boosting node, and outputting a pull-up output signal, and a pull-down portion connected to the inverter portion, receiving the inverted signal and outputting a pull-down output signal. Here, the inverter portion outputs a signal having a lower level than the low-level signal for a predetermined time period in which the pull-up output signal is high.
Here, the inverter portion may output an overshoot for a predetermined time period in which the pull-down output signal is output.
Another aspect of the present invention provides A display driving circuit, in which a gate driver including a plurality of shifter register stages for shifting and outputting an input signal is embedded, including first and second blocks. The first block includes: a first input portion receiving and transferring a pulse input signal consisting of a high-level signal and a low-level signal to a first boosting node; an inverter portion connected with the first input portion, and inverting the pulse input signal to output the inverted signal; and a first pull-up/pull-down portion consisting of a first pull-up portion connected to the first input portion, receiving a boosting voltage from the first boosting node, and outputting a first pull-up output signal, and a first pull-down portion connected to the inverter portion, receiving the inverted signal, and outputting a first pull-down output signal. The second block includes: a second input portion receiving and transferring an output signal of the first block to a second boosting node; and a second pull-up/pull-down portion consisting of a second pull-up portion receiving a boosting voltage from the second boosting node and outputting a second pull-up output signal and a second pull-down portion sharing the inverter portion to receive the inverted signal and output a second pull-down output signal. Here, the inverter portion outputs a signal having a lower level than the low-level signal for a predetermined time period in which the pull-up output signal is output.
The above and other objects, features and advantages of the present invention will become more apparent to those of ordinary skill in the art by describing in detail exemplary embodiments thereof with reference to the attached drawings, in which:
Hereinafter, exemplary embodiments of the present invention will be described in detail. However, the present invention is not limited to the embodiments disclosed below, but can be implemented in various forms. The following embodiments are described in order to enable those of ordinary skill in the art to embody and practice the present invention.
Exemplary embodiments of the present invention can be applied to all kinds of Display apparatus which employ TFT (Thin Film Transistor) as switching device, for example, electronic paper displays or electrophoretic displays (EPDs) or general liquid crystal displays (LCDs) or AMOLED (Active Matrix Organic Light Emitting Diode) (e.g., LCDs employing an amorphous silicon (a-Si) thin-film transistor (TFT)).
Here, an EPD is a flat panel display that can be comfortably “read” without stress, like an e-book, e-paper, etc. The EPD is a non-self-light-emitting display based on an electrophoretic phenomenon, which influences charged particles suspended in a solvent.
Such an EPD generally includes one pair of separated substrates that face each other, and electrodes present in the pair of substrates respectively. Here, at least one of the electrodes is transparent. Also, an electrophoretic device is present between the pair of confronting substrates, and a dielectric solvent and charged particles distributed in the dielectric solvent are included in the electrophoretic device.
Thus, when different voltages are applied through the electrodes present in the substrates, charged particles move to a substrate having a polarity opposite to the charged polarity due to gravity. In this case, a color seen from the substrate including the transparent electrode is determined by the colors of the dielectric solvent and the charged particles, the arrangement of the charged particles in the dielectric solvent, and so on.
The EPD applies a selection signal and a data signal to a pixel region, in which a plurality of scanning lines and a plurality of data lines intersect, through the scanning lines and data lines respectively, so that a plurality of pixels can display an image in grayscale. In this case, the EPD has a transistor device to control a data signal applied to each pixel, and the transistor device generally consists of a TFT.
<First Exemplary Embodiment>
Referring to
Here, the input portion 210 receives and transfers a pulse input signal having a high level VGH and a low level VGL to a boosting node (bootstrap node) P-node, and the inverter portion 220 is connected with the input portion 210, inverts a pulse input signal, and outputs the inverted signal to an X-node.
The pull-up/pull-down circuit portion 240 includes a pull-up portion 240a that is connected to the input portion 210, receives a boosting voltage from the boosting node P-node and outputs a pull-up output signal, and a pull-down portion 240b that is connected to the inverter portion 220, receives the inverted signal and outputs a pull-down signal.
Here, the inverter portion 220 outputs a signal having a lower level LVGL than the low level VGL of the pulse input signal input to the input portion 210 for a predetermined time period in which the pull-up output signal is output. An LVGL voltage may be lower than a VGL voltage by about 3 V to 6 V.
The input portion 210 may have an input switch in the form of a diode using a saturation mode TFT. A signal input is applied when the input signal is in the high level VGH, and is interrupted when the input signal is in the low level VGL. After a signal is input, the input portion 210 functions to maintain a floating state.
The pull-up portion 240a uses a clock signal as a power source for generating a high-level voltage of a gate output waveform. The voltage level of the clock signal has a high or low level of a gate driving voltage, that is, one of the two levels VGH and VGL. The duty ratio of a clock waveform is about 20% to 50%, and a 2-phase signal or 4-phase signal can be used according to a driving method as mentioned above.
Referring to
The exemplary embodiment is different from conventional art in that the TFT T23 is added. The gate terminal of the TFT T23 is connected to the bootstrap node P-node, and the source terminal is connected to the lower level LVGL than the voltage level VGL of the source terminal. Also, the voltage Vbias to which the drain of the TFT T21 is connected is set to have a voltage level (about 4 V to 5 V) so that the TFT T21 for maintaining an X-node output signal at an off level can have an appropriate voltage level for normal operation.
Unlike an inverter circuit outputting the voltage level VGL using only an input voltage as a control signal according to conventional art, the inverter portion 220 uses the bootstrap node P-node as a control signal. The inverter portion 220 causes the output of the inverter circuit to have lower electric potential than the voltage level VGL using the lower VGL (LVGL) signal, and causes gate-source voltages (Vgs) of TFTs in a pull-down function portion to be negative numbers to reduce leakage current, thereby removing a circuit destabilizing factor such as high temperature and reduction in a threshold voltage Vth.
The display driving circuit of
Here, the drain terminal and gate terminal of the first transistor T31 are connected in common to an output terminal of an (N−1)th or (N−2)th gate line.
The drain terminal of the second transistor T32 is connected with the source terminal of the first transistor T31 to form a P-node P, and the source terminal is connected to a VGL terminal.
A clock signal CLK is applied to the first electrode of the first capacitor C31, and the second electrode is connected to the P-node P.
The gate terminal of the third transistor T33 is connected to the P-node P, an inverted signal CLKB of the clock signal CLK is applied to the drain terminal, and the source terminal is connected to an N-th gate line.
The gate terminal of the fourth transistor T34 is connected with the gate terminal of the second transistor T32 to form an X-node, the drain terminal is connected to the N-th gate line, and the source terminal is connected to the VGL terminal.
The gate terminal and drain terminal of the fifth transistor T35 are connected in common to a Vbias terminal, and the source terminal is connected to the X-node.
The sixth transistor T36 is connected between the X-node and the VGL terminal, and the gate terminal is connected to the drain terminal of the first transistor T31.
The second capacitor C32 is connected between the X-node and the gate terminal of the sixth transistor T36.
The display driving circuit of
Also, the seventh transistor T37 and the eighth transistor T38 may be added for a reset function. The gate terminal of the seventh transistor T37 is connected to an (N+1)th gate line, and the seventh transistor T37 is connected between the P-node P and the VGL terminal in parallel with the second transistor T32. The gate terminal of the eighth transistor T38 is connected to the (N+1)th gate line, and the eighth transistor T38 is connected between the Vbias terminal and the X-node.
The disposition of
Referring to
Referring to
For convenience, only states of the P-node and the X-node at the G1 block are illustrated in the timing diagram. Thus, timings of the P-node and the X-node are shifted by one period per block at the following blocks such as the second block and the third block.
Operation of the display driving circuit constituted as described above will be described in detail below.
Referring to
When the output signal of the (N−1)th circuit, which is an input signal from the viewpoint of an N-th circuit that is the driving circuit, is input through the first transistor T31, the clock signal CLK is also input in synchronization with the input signal.
When the input signal is in the high level VGH, the first transistor T31 and the sixth transistor T36 are turned on, the P-node has a positive level, and a voltage becomes an electric potential (VGH−a) calculated by subtracting the threshold voltage of the first transistor T31 from a voltage of the high level VGH.
Meanwhile, an output signal is maintained at the low level VGL because the X-node has the high level VGH and the third transistor T33 is kept turned off. The second capacitor C32 is charged.
Here, the input signal is switched to the low level VGL, the first transistor T31 and the sixth transistor T36 are turned off, the third transistor T33 is turned on by a voltage of the high-level VGH of the P-node, the inverted clock signal CLKB is at the high level VGH, and thus the output signal is in the high level VGH.
Meanwhile, the gate terminal of the ninth transistor T39 is connected to the P-node, and the source terminal is connected to the lower voltage level LVGL than the low level VGL. Due to such a constitution, the X-node can have a profile as shown in
When the output signal of an (N+1)th circuit is applied as a reset signal to the seventh transistor T37 and the eighth transistor T38, the P-node has a low level, and the X-node has high voltage due to the fifth transistor T35. Thus, the second transistor T32 and the fourth transistor T34 can be kept turned on, and it is possible to maintain the off voltage of an output waveform.
Here, a capacitance Cap of the second capacitor C32 is intended to maintain and stabilize an electric potential level at the X-node, and the capacitance of the first capacitor C31 is intended to stabilize off-level characteristics of an output signal Output.
Meanwhile, a bootstrap capacitor C33 may be selectively removed when a driving voltage is sufficiently high and a sufficient bootstrap for driving the third transistor T33 can happen.
In the disposition of
First, an STP_O signal is input to N−1 (input) of
Likewise, the G2 block outputs a gate output signal Gout(2) in response to an STP_E signal in the same way as the G1 block.
Meanwhile, the respective odd-numbered blocks such as the G1 block, the G3 block, and a G5 block are connected with each other, receive an input signal from the preceding blocks, and output a reset signal to the preceding blocks. This is the same for the even-numbered blocks such as the G2 block, a G4 block, and a G6 block.
For convenience, only states of the P-node and the X-node at the G1 block are illustrated in the timing diagram. Thus, timings of the P-node and the X-node are shifted by one period per block at the second block and the following blocks.
Meanwhile, in the similar disposition of
Referring to
<Second Exemplary Embodiment>
In a driving circuit according to a second exemplary embodiment of the present invention, a part controlling the X-node in the above-described first exemplary embodiment is shared by two stages to reduce the number of TFTs controlling the X-node, thereby effectively reducing dead space on the both sides of a display panel.
In this structure, a first block 1 Block and a second block 2 Block are repeatedly and successively formed on one side of a substrate, and connected in sequence to odd-numbered gate lines respectively. Also, the first block 1 Block and the second block 2 Block are repeatedly and successively formed on the opposite side of the substrate, and connected in sequence to even-numbered gate lines respectively.
It is assumed below that the first block 1 Block and the second block 2 Block are connected to an N-th gate line and an (N+2)th gate line respectively.
In the second exemplary embodiment, stages outputting two output waveforms are combined and used. Thus, it is difficult to use 2-phase driving, and basically 4-phase driving is used. Since the first block and the second block perform a reset operation using an (N+3)th output waveform, an undesired waveform may be output by 2-phase driving.
To be specific, the inverter portion of an N-th stage shift register is shared with an (N+2)th stage. The X-node in the first block is shared with the next block, and a reset is received through an (N+3)th signal, so that three TFTs controlling the voltage of the X-node can be removed. Thus, it is possible to reduce a circuit area and effectively reduce power consumption.
Referring to
In this constitution, two blocks constitute one group, share an X-node, and are reset at the same time. Also, after a gate output signal of a second block in one group is output, a reset signal is input later than a X-signal. For example, the gate output signal of a G4 block is input as a reset signal to the G1 and G3 blocks, and the gate output signal of a G5 block is input as a reset signal to the G2 and G4 blocks.
Also, a second block in each group (two blocks) uses a first gate output in the same block as an input signal, and a first block in each group (two blocks) uses the gate output signal of a stage preceding by one gate line as an input signal. The G5 block uses the gate output signal of the G4 block as an input signal, and a G6 block uses the gate output signal of the G5 block as an input signal.
First, when the STP_O signal is input, a P-node in the G1 block is precharged. Then, a clock signal CLK(O) is switched to a high level, and a gate output signal Gout(1) is output. Subsequently, when the G3 block is precharged and an inverted clock signal CLKB(O) is switched to a high level, a gate output signal Gout(3) is output. Meanwhile, the G1 and G3 blocks are reset using a gate output signal Gout(4) as a reset signal.
When an STP_E signal is input, a P-node in the G2 block is precharged. Then, a clock signal CLK(E) is switched to a high level, and a gate output signal Gout(2) is output. Subsequently, when the G4 block is precharged and an inverted clock signal CLKB(E) is switched to a high level, a gate output signal Gout(4) is output. The G2 and G4 blocks are reset using a gate output signal Gout(5) as a reset signal.
For convenience, only states of the P-node, a P′-node and the X-node in the first block G1 are illustrated in the timing diagram. Thus, timings of the P-node and the X-node are shifted by one period per block at the second block and the following blocks.
The constitution of the first and second blocks 1 Block and 2 Block will be described in detail below.
Referring to
Connection of the first block 1 Block is as follows: the first, second, fourth, fifth, sixth and ninth transistors T41, T42, T44, T45, T46 and T49 have the same connection and operate in the same way as the first, second, fourth, fifth, sixth and ninth transistors T31, T32, T34, T35, T36 and T39 of the above-described first exemplary embodiment, and thus the description will not be reiterated.
The gate terminal of the third transistor T43 is connected to the P-node, the clock signal CLK is applied to the drain terminal, and the source terminal is connected to an N-th gate line.
The first capacitor C41 is connected to the gate terminal and source terminal of the third transistor T43.
Connection of the second block 2 Block is as follows: the drain terminal and gate terminal of the tenth transistor T51 are connected in common to the source terminal of the third transistor T43 of the first block 1 Block.
The drain terminal of the eleventh transistor T52 is connected with the source terminal of the tenth transistor T51 to form the P′-node, the source terminal is connected to a VGL terminal, and the gate terminal is connected with the gate terminals of the second and fourth transistors T42 and T44 of the first block 1 Block to form the X-node together.
The gate terminal of the twelfth transistor T53 is connected to the P′-node, the inverted clock signal CLKB which is the clock signal CLK shifted by two phases is applied to the drain terminal, and the source terminal is connected to the (N+2)th gate line.
The gate terminal of the thirteenth transistor T54 is connected with the gate line of the eleventh transistor T52 to form the X-node together with the gate terminals of the second and fourth transistors T42 and T44 of the first block 1 Block, the drain terminal is connected to the (N+2)th gate line, and the source terminal is connected to the VGL terminal.
The gate terminal of the fourteenth transistor T55 is connected to an (N+3)th gate line, the drain terminal is connected to the P′-node, and the source terminal is connected to the VGL terminal.
The gate terminal of the fifteenth transistor T56 is connected to the P′-node, the drain terminal is connected to the X-node, and the source terminal is connected to an LVGL terminal having a lower voltage level than the VGL terminal.
The driving circuit consisting of the first and second blocks 1 Block and 2 Block as described above may be applied to LCDs employing an a-Si TFT, but the application is not limited to the LCDs and applicable to all kinds of displays which are manufactured using Thin Film Transistor. For example, the driving circuit can be also applied to EPDs, AMOLED, and so on.
Here, an LCD and an EPD show a difference in driving voltage. For example, a basic mobile LCD has driving voltages such as Vbias of 5 V, VGL of −10 V, LVGL of −13 V and VGH of 15 V, and an EPD has driving voltages such as Vbias of 4 V, VGL of −20 V, LVGL of −24 V and VGH of 22 V. Due to the difference in driving voltages, an EPD has some superior aspects to an LCD.
To be specific, noise of an output waveform is reduced when the second and fourth transistors T42 and T44 are turned on to lower the voltages of the P-node and the output waveform to an off voltage. To this end, a difference between the high voltage of the X-node and the voltage of the VGL terminal needs to be sufficiently larger than a threshold voltage Vth so that the second and fourth transistors T42 and T44 can be driven into saturation.
The voltage of the X-node is determined by voltage distribution of the fifth, sixth and ninth transistors T45, T46 and T49 of an inverter stage. An EPD has a larger voltage difference between Vbias and VGL than an LCD, and thus a range in which the voltage of the X-node can be controlled increases.
Under a low-temperature reliability condition, the threshold voltage Vth is shifted to a positive voltage. Here, in the case of an LCD, the second and fourth transistors T42 and T44 show a waveform that cannot reach a saturation state.
On the other hand, in the case of an EPD, a sufficient voltage to overcome the threshold voltage Vth is applied by the VGL voltage, which is lower than that of an LCD. Thus, the second and fourth transistors T42 and T44 are driven with no problem and can be robust to noise of the P-node and the output waveform.
For this reason, the fourteenth transistor T55 and the fifteenth transistor T56 can be additionally removed from a structure to be described later according to a third exemplary embodiment of the present invention, as shown in
Operation of a part of the display driving circuit constituted as described above according to the second exemplary embodiment of the present invention will be described below. A case in which the first block 1 Block and the second block 2 Block are connected to an N-th gate line and an (N+2)th gate line respectively will be described as an example.
To this end, the fifteenth transistor T56 is added to the second block 2 Block, thereby lowering the voltage of the X-node X to an LVGL level in response to a bootstrap voltage of the P′-node when a clock signal is applied to the second block 2 Block.
The driving period of a group consisting of the first and second blocks is 4 H, and the voltage of the X-node is overshot to the LVGL level during 1 H twice in response to respective clock signals. Thus, the overshoot is applied in synchronization of each clock signal during 1 H, that is, 2 H in total.
In addition to three TFTs corresponding to the transistors T45, T46 and T48 of the first block, a bootstrap capacitor corresponding to the first capacitor C41 of the first block can be removed from the second block 2 Block. Since the voltage of the X-node is maintained by the first capacitor C41 in the first block 1 Block, a bootstrap capacitor in the second block 2 Block can be removed.
However, since the output waveform of the second block 2 Block is slightly unstable, a VGL voltage needs to be lowered by about 2 V to −12 V compared to a conventional VGL voltage, and the first capacitor C41 having a slightly larger capacitance than a conventional bootstrap capacitor is used. These cause the eleventh and thirteenth transistors T52 and T54 to be placed in an operation state for sure, thereby stabilizing the output waveform.
In the second exemplary embodiment of the present invention, an input and reset are received differently than the above-described structure according to the first exemplary embodiment. The first block 1 Block receives an (N−1)th input, and the output of the first block 1 Block is received and used as the input of the second block 2 Block. Also, the reset operation is performed by the first block 1 Block and the second block 2 Block at the same time, and thus an (N+3)th output from the viewpoint of the first block 1 Block is used for reset.
Operation of the display driving circuit will be described in sequence with reference to
The output signal of an N-th circuit, that is, the first block 1 Block, is input through the drain terminal of the tenth transistor T51 in the second block 2 Block. When the output signal of the N-th circuit is input through the tenth transistor T51, the clock signal CLK is also input in synchronization with the input signal.
When the input signal is in the high level VGH, the tenth transistor T51 is turned on, the P-node has a positive level, and a voltage becomes an electric potential (VGH−a) calculated by subtracting the threshold voltage of the tenth transistor T51 from the VGH voltage.
Meanwhile, an output signal is maintained at a low level because the X-node has a low level and the third transistor T43 is kept turned off. Here, the input signal is switched to the low level VGL, the tenth transistor T51 is turned off, and the twelfth transistor T53 is turned on by the high-level voltage of the P-node.
As shown in
Meanwhile, the gate terminal of the fifteenth transistor T56 is connected to the P-node, and the source terminal is connected to the lower voltage level LVGL than the voltage VGL. Due to such a constitution, the X-node can maintain a low level once again as shown in
When the output signal of an (N+3)th circuit is applied as a reset signal to the seventh transistor T47 and the eighth transistor T48 in the first block 1 Block, the P-nodes have a low level, and the X-node has high voltage due to the fifth transistor T45. Thus, the second transistor T42 and the fourth transistor T44 can be kept turned on, and it is possible to maintain the off voltage of an output waveform.
Here, a capacitance Cap of the first capacitor C41 is intended to intensify a bootstrap and maintain and stabilize an electric potential level at the X-node.
In comparison with
Meanwhile,
<Third Exemplary Embodiment>
Referring to
As described above, additional removal of the fourteenth transistor T55 and the fifteenth transistor T56 in the second block 2 Block is intended not to use a reset TFT. Here, the output waveform of the second block 2 Block may be weakened by noise, but can be maintained as close to itself as possible by the second and fourth transistors T42 and T44.
It can be seen from
The above-described display driving circuit according to an exemplary embodiment of the present invention generates the output waveform of an inverter portion applied to the gate node of a TFT in a pull-down function portion of a shift register in the form of an overshoot to reduce the bias stress voltage of the gate node, thereby increasing the life.
Further, a leakage current component is removed from the display driving circuit, and thus excellent output characteristics can be obtained without attenuation of a gate output waveform even when a TFT leakage current increasing factor, such as high temperature or low threshold voltage, occurs.
While the invention has been shown and described with reference to certain exemplary embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.
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