Source: https://patents.google.com/patent/KR20060097819A/en
Timestamp: 2020-08-08 18:57:02
Document Index: 201854340

Matched Legal Cases: ['art\n500', 'art 400', 'art 400', 'art 400', 'art 560', 'art 570', 'art 550', 'art 570']

KR20060097819A - Shift register and display device having the same - Google Patents
KR20060097819A
KR20060097819A KR1020050018552A KR20050018552A KR20060097819A KR 20060097819 A KR20060097819 A KR 20060097819A KR 1020050018552 A KR1020050018552 A KR 1020050018552A KR 20050018552 A KR20050018552 A KR 20050018552A KR 20060097819 A KR20060097819 A KR 20060097819A
KR1020050018552A
2005-03-07 Application filed by 삼성전자주식회사 filed Critical 삼성전자주식회사
2005-03-07 Priority to KR1020050018552A priority Critical patent/KR20060097819A/en
2006-09-18 Publication of KR20060097819A publication Critical patent/KR20060097819A/en
238000006542 no. of reaction stages Methods 0.000 claims 2
239000004973 liquid crystal related substances Substances 0.000 description 8
E05Y2800/412—Protection against friction
Disclosed are a shift register for improving reliability and a display device having the same. The first pull-up unit outputs the first gate signal of the current stage based on the first gate signal and the first clock signal of the previous stage. The pull-down unit pulls down the first gate signal to the power supply voltage based on the second clock signal. The first holding part maintains the first gate signal as a power supply voltage based on the first clock signal. The second pull-up part outputs the second gate signal of the current stage based on the first gate signal and the third clock signal. The second holding part maintains the second gate signal at the power supply voltage based on the first and second clock signals. Accordingly, the driving reliability of the optical sensor included in the touch display device may be improved by outputting two gate pulses using three clock signals.
Optical Sensors, Sensing Display Panels, Gate Pulses, Shift Registers
SHIFT REGISTER AND DISPLAY DEVICE HAVING THE SAME}
1 is a schematic block diagram of a display device according to an exemplary embodiment of the present invention.
FIG. 2 is an equivalent circuit diagram of a unit pixel of the display panel illustrated in FIG. 1.
FIG. 3 is a detailed block diagram illustrating the sensing gate driver shown in FIG. 1.
4 is an internal circuit diagram of each stage of the shift register shown in FIG.
5A to 5H are timing diagrams for input signals and output signals of the stage shown in FIG.
100: display panel 200: data driver
300: gate driver 400: lead-out part
500: sensing gate driver
510: first pull-up unit 520: first pull-up control unit
530: second pull-down control unit 540: first pull-down unit
550: first holding unit 560: first output unit
570: second pull-up unit 580: second holding unit
590: second output unit
The present invention relates to a shift register and a display device having the same, and more particularly, to a shift register for improving driving reliability of an optical sensor and a display device having the same.
In general, the touch screen panel is an input device which is disposed on the liquid crystal display and inputs data through an object such as a hand or an object. The liquid crystal display is used as a display and input device by implementing the liquid crystal display by disposing the touch display panel on the liquid crystal display panel.
Recently, a display panel in which the touch screen panel and the liquid crystal display panel are integrated has been developed. An integrated display panel uses the display panel as a display device and an input device by forming an optical sensor using a thin film transistor such as a-Si / Poly-Si in an active area where an image is displayed.
In general, the optical sensor is formed of a photo thin film transistor. The conventional photo thin film transistor driving method is driven by applying a predetermined level of DC voltage to the gate electrode. However, if the DC voltage is continuously applied to the gate electrode of the photo thin film transistor as described above, there is a problem of lowering the driving reliability due to deterioration of the photo thin film transistor.
Accordingly, the technical problem of the present invention is to solve such a conventional problem, and an object of the present invention is to provide a shift register for improving the driving reliability of the optical sensor.
Another object of the present invention is to provide a display device having the shift register.
In a shift register in which a plurality of stages are connected in a cascade according to an embodiment for realizing the object of the present invention, each stage includes a first pull-up unit, a pull-down unit, a first holding unit, a second pull-up unit, and a second holding unit Include. The first pull-up unit outputs the first gate signal of the current stage based on the first gate signal and the first clock signal of the previous stage. The pull-down unit pulls down the first gate signal to a power supply voltage based on a second clock signal. The first holding part maintains the first gate signal at a power supply voltage based on the first clock signal. The second pull-up part outputs a second gate signal of the current stage based on the first gate signal and the third clock signal. The second holding part maintains the second gate signal at the power supply voltage based on the first and second clock signals.
Preferably, the first clock signal has a first period, the second clock signal is a signal whose phase is inverted with respect to the first clock signal, and the third clock signal has a second period shorter than the first period. Have
The shift register may include a pull-up control unit configured to apply a control signal to the first pull-up unit when a first gate pulse output from a previous stage is applied, and the off voltage to the pull-down unit when a first gate pulse output from a subsequent stage is applied. It includes a pull-down control unit for applying a.
The second pull-up part includes a switching element connected to an output terminal of the first pull-up part, a first current electrode is connected to an input end of the third clock signal, and a second current electrode is connected to the second holding part. do.
The second holding part may include a first switching element in which a control electrode is connected to an input terminal of the first clock signal, a first current electrode is connected to an input terminal of the off voltage, and a second current electrode is connected to an output terminal of the second pull-up unit. And a control electrode is connected to an input terminal of the second clock signal, a first current electrode is connected to an input terminal of the off voltage, and a second current electrode includes a second switching element connected to an output terminal of the second pull-up unit. .
Another object of the present invention is to include a display panel, a sensing gate driver, and a display gate driver. The display panel includes a first switching element formed in a unit pixel area having a pixel electrode, a second switching element for providing sensed external light to the first switching element, and a third switching element for driving the pixel electrode. do. The sensing gate driver outputs a first gate pulse for activating the first switching element and a second gate pulse for activating the second switching element. The display gate driver outputs a third gate pulse to the third switching device.
The display panel includes a sensing display area for displaying an image and sensing external light and a peripheral area surrounding the sensing display area, and the sensing gate driver is a shift register formed of a plurality of stages in the peripheral area.
Each stage includes a first pull-up part that outputs a first clock signal as a first gate pulse of a current stage based on a first gate pulse of a previous stage, and turns off the first gate pulse based on the second clock signal. A pull-down part for pulling down to a voltage; a first holding part for holding the first gate pulse at an off voltage based on the first clock signal; and a third clock signal based on the first gate pulse; A second pull-up part which outputs two gate pulses, and a second holding part which holds the second gate pulse at an off voltage based on the first and second clock signals.
The first clock signal has a first period, the second clock signal is a signal whose phase is inverted with respect to the first clock signal, and the third clock signal has a second period shorter than the first period.
The second pull-up part includes a control electrode connected to an output terminal of the first pull-up part, a first current electrode is connected to an input terminal of the third clock signal, and a second current electrode includes a transistor connected to the second holding part. .
The second holding part may include a first transistor connected to a control electrode of an input terminal of the first clock signal, a first current electrode to an input terminal of the off voltage, and a second current electrode of an output terminal of the second pull-up part; A control electrode is connected to an input terminal of the second clock signal, a first current electrode is connected to an input terminal of the off voltage, and the second current electrode includes a second transistor connected to an output terminal of the second pull-up unit.
According to the shift register and the display device having the same, driving reliability of the optical sensor can be improved by generating two gate pulses using three clock signals.
Referring to FIG. 1, the display device includes a display panel 100, a data driver 200, a gate driver 300, a readout unit 400, and a sensing gate driver 500.
The display panel 100 includes an array substrate 110, a color filter substrate 120, and a liquid crystal layer (not shown) interposed between the array substrate 110 and the color filter substrate 120.
The array substrate 110 includes a sensing display area SDA and first to third peripheral areas PA1, PA2, and PA3. The sensing display area SDA is an area in which an optical sensor is integrally formed on the display panel, and the first switching elements for driving the pixel electrode and the optical sensors for sensing a location where an event occurs are formed.
The data driver 200 and the lead-out unit 400 are mounted in a chip form in the first peripheral area PA1, respectively. The gate driver 300 formed of an amorphous silicon thin film transistor is integrated in the second peripheral area PA2, and the sensing gate driver 500 formed of an amorphous silicon thin film transistor is integrated in the third peripheral area PA3.
The data driver 200 and the gate driver 300 display an image by driving a plurality of first switching elements formed on the display panel 100. In detail, the data driver 200 converts a digital data signal into an analog data signal and outputs the digital data signal to the current electrode of the first switching device. The data driver 200 receives an input signal 102 including a data control signal, a reference gray voltage, and a digital data signal. The data driver 200 converts the digital data signal into an analog data signal based on the reference gray voltage and outputs the analog data signal to the display panel 100.
A gate control signal 103 including a vertical start signal, an off voltage, a first clock signal, and a first inversion clock signal is input to the gate driver 300, and the first gate pulse is input to the display panel 100 using the gate control signal 103. ) The first gate signal is applied to the control electrode of the first switching element.
The readout unit 400 and the sensing gate driver 500 drive out the optical sensors formed on the display panel 100 to read out the sensing signal. In detail, the readout unit 400 converts the sensing signal detected from the optical sensors formed on the display panel 100 into the digital sensing signal 404 based on the control signal 104 and outputs the sensing signal.
The sensing gate driver 500 receives a sensing control signal 105 including a vertical start signal, an off voltage, a first clock signal, a first inverted clock signal, and a second clock signal. And a third gate pulse to the display panel 100.
The optical sensor includes a second switching device for transmitting a sensing signal to the lead-out unit 400 and a third switching device for sensing external light. The sensing gate driver 500 includes second and third gate signals applied to control electrodes of the second and third switching devices.
1 and 2, the unit pixel includes first to third switching elements. The first switching element TFT1 is electrically connected to the first gate line GL1 and the first data line DL1. A first gate signal output from the gate driver 300 is applied to the first gate line GL1, and a first data signal output from the data driver 200 is applied to the first data wire DL1. do. The first switching element TFT1 is electrically connected to the liquid crystal capacitor CLC and the storage capacitor CST. The first common voltage Vcom is applied to the liquid crystal capacitor CLC, and the second common voltage Vst is applied to the storage capacitor CST.
The second switching element TFT2 is electrically connected to the second gate line GL2 and the second data line DL2. A second gate signal output from the sensing gate driver 500 is applied to the second gate line GL2. The second data line DL2 is an output line electrically connected to the readout part 400 to transfer a sensing signal to the readout part 400.
The third switching element TFT3 is electrically connected to a third gate line GL3 and the first data line DL1. The third switching element TFT3 is a photo thin film transistor and senses external light. A third gate signal output from the sensing gate driver 500 is applied to the third gate line GL3. The third switching element TFT3 is electrically connected to the second switching element TFT2, and the sensing signal sensed by the third switching element TFT3 is read through the second switching element TFT2. It is delivered to the out part 400.
Preferably, the unit pixels shown in FIG. 2 are formed to be uniformly distributed among the plurality of pixels formed in the display panel. All of the plurality of pixels may be formed as the unit pixel shown, or only some of the plurality of pixels may be formed as the unit pixel shown.
Referring to FIG. 3, the sensing gate driver is one shift register including a plurality of unit stages.
Specifically, the shift register includes N stages SRC1, SRC2, SRC3, which output N second and third gate signals (or scan signals) G11 G12, G21 G22,..., GN1 GN2. And a dummy stage SRCN + 1 for outputting the SRCN and the dummy gate signal DG. The dummy stage SRCN + 1 outputs the dummy gate signal DG to deactivate the front stage SRCN.
Each stage includes first to third clock terminals CK1 to CK3, a power supply terminal VSS, first and second control terminals IN1 and IN2, and first and second output terminals OUT1 and OUT2. Include. The first to third clock terminals CK1 to CK3 have a first clock signal CK1 having a first period, a first inverted clock signal CKB1 inverted to the first clock signal, and a second period having a second period. Two clock signals CK2 are applied, respectively. A gate off voltage Voff is applied to the power supply terminal VSS to set an off level of the gate signal.
A vertical start signal STV and a second gate signal output from the first output terminal OUT1 of the previous stage are applied to the first control terminal IN1 to activate an operation. A second gate signal output from the first output terminal OUT1 of the next stage is applied to the second control terminal IN2 to deactivate the operation.
A second gate signal for controlling the second switching element is output to the first output terminal OUT1, and a third gate signal for controlling the third switching element is output to the second output terminal OUT2.
In detail, the first clock signal CK1, the second inverted clock signal CKB1, and the second clock signal CK2 are respectively applied to the first to third clock terminals CK1 to CK3 of the first stage SRC1. The off voltage Voff is applied to the power supply terminal VSS. Since the vertical start signal STV is applied to the first control terminal IN1, the first stage SRC1 is activated to receive the first and second gate signals G12 and G13 from the first and second output terminals. Output to OUT1, POT2).
The second gate signal G12 output to the first output terminal OUT1 of the first stage SRC1 is applied to the first control terminal IN1 of the second stage SRC2, so that the second stage SRC2 is The action is activated.
The second second gate signal G22 output from the first output terminal OUT1 of the second stage SRC2 is applied to the second control terminal IN2 of the first stage SRC1 that is the previous stage, so that the second The operation of the first stage SRC1 is inactivated and applied to the first control terminal IN1 of the third stage SRC3, which is the next stage, to activate the operation of the third stage SRC3.
In this manner, the plurality of stages that are mutually connected to each other may operate to output second and third gate signals to second and third switching elements, which are optical sensors formed on the display panel.
4 is an internal circuit diagram of each stage of the shift register shown in FIG. 5A to 5H are timing diagrams for input signals and output signals of the stage shown in FIG.
4 and 5A to 5H, each stage includes a first pull-up unit 510, a pull-up control unit 520, a pull-down control unit 530, a first pull-down unit 540, and a first holding unit 550. , A second pull-up part 560 and a second holding part 570. The following describes only the nth stage (specific stage) among the plurality of stages.
The first pull-up unit 510 has a gate electrode connected to the node t1 and controlled by the control signal CT, a drain electrode receives the first clock signal CK1, and a source electrode receives the first output unit 560. ) Includes a first transistor TR1. In addition, a first capacitor Cbs is formed between the gate electrode and the source electrode of the first transistor TFT1.
The pull-up control unit 520 includes a second transistor TFT2 to which a drain electrode and a gate electrode are commonly connected to receive the first gate pulse Gn-1 of the n-th stage, and the input first gate. The control signal CT is output to the node t1 by the pulse Gn-1. Here, when the n-th stage is the first stage, the start signal STV is input to the second transistor TFT2 of the first pull-up control unit 520.
The pull-down control unit 530 is provided with a gate electrode of the first gate pulse Gn + 1 output from the n + 1 stage, and a drain electrode of the pull down controller 530 connected to the gate electrode of the first transistor TFT1. The source electrode includes a third transistor TFT3 to which a power supply voltage Voff is applied. When the first gate pulse Gn + 1 output from the n + 1 stage is applied to the gate electrode to turn on the third transistor TFT3, the power supply voltage Voff is provided to the node t1.
The pull-down unit 540 includes a sixth transistor TFT6. The gate electrode of the sixth transistor TFT6 receives the first inverted clock signal CKB1, the source electrode receives the power supply voltage Voff, and the drain electrode of the first transistor TFT1 of the pull-up unit 510. It is connected to the source electrode and the first output unit 560. When the first inversion clock signal CKB1 is applied to the gate electrode, the sixth transistor TFT6 pulls down the first gate pulse Gn to the low level Voff.
That is, the first pull-up unit 510 outputs a first gate pulse Gn synchronized with the first clock signal CK1 under the control of the pull-up control unit 520, and the pull-down control unit 530. According to the control of the pull-down unit 540 pulls down the first gate pulse (Gn) output from the first pull-up unit 510 to the level of the power supply voltage (Voff).
The first holding part 550 includes a fifth transistor TFT5, a fourth transistor TFT4, and a second capacitor Cc. The gate electrode of each of the fifth transistor TFT5 and the fourth transistor TTF4 is connected to the node t2, and a source voltage Voff is applied to the source electrode. One end of the second capacitor Cc is connected to the first clock signal CK1.
Gate electrodes of the fifth and fourth transistors TFT5 and TFT4 are connected to the drain electrodes of the node t2 and the seventh transistor TFT7. When the seventh transistor TFT7 is turned on, the fifth transistor TFT5 and the fourth transistor TFT4 are turned off by the power supply voltage Voff. When the seventh transistor TFT7 is turned off, the signal applied to the node t2 has the same waveform as the first clock signal CK1 charged in the second capacitor Cbs. This is because the fourth transistor TFT4 and the fifth transistor TFT5 are turned on at the same period as the first clock signal CK1 to thereby convert the first gate pulse Gn, which is an output signal of the node t1 and the first output unit 560. Keep it low level. In addition, when the first clock signal CK1 is low, the first inverted clock signal CKB1 becomes high to turn on the sixth transistor TFT6 to output the first gate pulse to the first output unit 560. Keep (Gn) at a low level.
As such, the first clock signal CK1 and the first inverted clock signal CKB1 alternately maintain the first gate pulse Gn at the low level Voff, thereby preventing signal distortion due to various couplings.
In the second pull-up unit 560, a gate electrode is connected to an output terminal of the first pull-up unit 510, a second clock signal CK2 is input to a drain electrode, and a source electrode is a ninth and tenth transistor ( And an eighth transistor TFT8 connected to the TFT9 and TFT10. When the first gate pulse Gn is output from the first pull-up unit 510, the first gate pulse Gn is applied to the gate electrode of the eighth transistor TFT8, and the eighth transistor TFT8 is turned on. As a result, the second clock signal CK2 applied to the drain electrode of the eighth transistor TFT8 is output to the output terminal of the second pull-up unit 560. That is, the second clock signal CK2 is output as the second gate pulse Gn1.
The second holding part 570 includes ninth and tenth transistors TFT9 and TFT10. The gate electrode of the ninth transistor TFT9 is connected to the node t2, the source electrode is connected to the power supply voltage Voff, and the drain electrode is connected to the output terminal of the second pull-up unit 560. In the tenth transistor TFT10, the first inverted clock signal CKB1 is input to the gate electrode, the source electrode is connected to the power supply voltage Voff, and the drain electrode is connected to the output terminal of the second pull-up unit 560. When the first gate pulse Gn is not output from the first pull-up unit 510, the eighth transistor is turned off and the second output unit 590 is powered by the ninth or tenth transistors TFT9 and TFT10. (Voff) is output. The node t2 and the first inverted clock signal CKB1 are applied to the gate electrodes of the ninth and tenth transistors TFT9 and TFT10, respectively, and as shown in FIGS. 5A and 5F, the first inverted clock signal CKB1. The signals applied to and node t2 are inverted signals.
Accordingly, when the ninth transistor TFT9 is turned off, the power supply voltage Voff is applied to the output terminal of the second pull-up unit 560 through the tenth transistor TFT10, and when the tenth transistor TFT10 is turned off. The power supply voltage Voff is applied to the second pull-up unit 560 through the ninth transistor TFT9. Therefore, the second gate pulse Gn1 output from the second pull-up unit 560 is maintained at a low level.
As described above, according to the present invention, the unit stage of the shift register outputs two gate pulses by using three clock signals. As a result, a gate pulse is applied to an optical sensor formed on the display panel, that is, a gate electrode of the photo thin film transistor and the switching thin film transistor.
Therefore, the power consumption can be relatively reduced compared to the conventional driving method of applying a DC voltage to the photo thin film transistor.
In addition, it is possible to prevent a decrease in reliability due to deterioration of the photo thin film transistor, which is a problem of the conventional driving method by applying a DC voltage to the photo thin film transistor.
In a shift register in which multiple stages are cascaded,
A first pull-up unit configured to output a first gate signal of the current stage based on the first gate signal and the first clock signal of the previous stage;
A pull-down unit configured to pull down the first gate signal to a power supply voltage based on a second clock signal;
A first holding part which maintains the first gate signal at the power supply voltage based on the first clock signal;
A second pull-up unit configured to output a second gate signal of a current stage based on the first gate signal and a third clock signal; And
And a second holding part for holding the second gate signal at the power supply voltage based on the first and second clock signals.
The shift register of claim 1, wherein the first clock signal has a first period, and the second clock signal is a signal whose phase is inverted with respect to the first clock signal.
3. The shift register according to claim 2, wherein the third clock signal has a second period shorter than the first period.
The pull-up control unit of claim 1, further comprising: a pull-up control unit applying a control signal to the first pull-up unit when a first gate signal output from a previous stage is applied; and
And a pull-down control unit configured to apply the power supply voltage to the pull-down unit when the first gate signal output from the stage is applied.
The method of claim 1, wherein the second pull-up part
A control electrode is connected to an output terminal of the first pull-up part, a first current electrode is connected to an input terminal of the third clock signal, and a second current electrode includes a switching element connected to the second holding part; Shift register.
The method of claim 1, wherein the second holding portion
A first switching element connected to an input terminal of the first clock signal, a first current electrode connected to an input terminal of the power supply voltage, and a second current electrode connected to an output terminal of the second pull-up unit; And
The control electrode is connected to the input terminal of the second clock signal, the first current electrode is connected to the input terminal of the power supply voltage, the second current electrode includes a second switching element connected to the output terminal of the second pull-up unit Shift register.
A pull-up control unit which outputs a control signal when the first gate signal output from the previous stage is applied:
A first pull-up unit configured to output a first gate signal of a current stage based on the control signal and the first clock signal;
A pull-down control unit outputting a power supply voltage when the first gate signal output from the stage is applied;
A pull-down unit configured to pull down the first gate signal to the power supply voltage provided from the pull-down control unit based on a second clock signal;
8. The method of claim 7, wherein the first clock signal has a first period, and the second clock signal is a signal whose phase is inverted with respect to the first clock signal.
And the third clock signal has a second period shorter than the first period.
A display panel including a first switching element formed in a unit pixel area having a pixel electrode, a second switching element providing sensed external light to the first switching element, and a third switching element driving the pixel electrode;
A sensing gate driver configured to output a first gate pulse for activating the first switching element and a second gate pulse for activating the second switching element; And
And a display gate driver configured to output a third gate pulse for activating the third switching element.
The display panel of claim 9, wherein the display panel includes a sensing display area for displaying an image and sensing external light, and a peripheral area surrounding the sensing display area.
The sensing gate driver is a shift register formed of a plurality of stages in the peripheral area.
The method of claim 10, wherein each stage is
A first pull-up unit configured to output a first gate pulse of the current stage based on the first gate pulse and the first clock signal of the previous stage;
A pull-down unit configured to pull down the first gate pulse to a power supply voltage based on a second clock signal;
A first holding part which maintains the first gate pulse at a power supply voltage based on the first clock signal;
A second pull-up unit configured to output a second gate pulse of a current stage based on the first gate pulse and a third clock signal; And
And a second holding part for holding the second gate pulse at a power supply voltage based on the first and second clock signals.
KR1020050018552A 2005-03-07 2005-03-07 Shift register and display device having the same KR20060097819A (en)
KR1020050018552A KR20060097819A (en) 2005-03-07 2005-03-07 Shift register and display device having the same
KR20060097819A true KR20060097819A (en) 2006-09-18
ID=37629374
KR (1) KR20060097819A (en)
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