JP2002311909A - Active matrix type display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce power consumption of an active matrix type display device. SOLUTION: A holding circuit 110 for holding a video signal every pixel is arranged, and a normal operation mode and a memory operation mode are switched to each other for displaying. In the memory operation mode, an output of a booster circuit 200 arranged in a panel is used as a reference voltage of the holding circuit, and also a selection circuit is changed over. The power consumption is reduced by halting the operation of a booster circuit of an external circuit board and a driver circuit in the panel. In the normal operation mode, the booster circuit 200 is halted.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to an active matrix display device, and more particularly to an active matrix display device provided with a plurality of holding circuits corresponding to pixels.

[0002]

2. Description of the Related Art In recent years, a display device is a portable display device,
For example, portable televisions, portable telephones and the like are required as market needs. In response to such demands, research and development have been actively conducted to reduce the size, weight, and power consumption of the display device. Each display pixel has a static memory (Static
A liquid crystal display device having a random access memory (SRAM) and displaying a still image is disclosed in JP-A-2000-28216.
No. 8.

FIG. 5 shows a conventional liquid crystal display (Liquid).
1 shows a circuit configuration diagram of a crystal display (LCD). In the liquid crystal display panel 100, a plurality of pixel electrodes 17 are arranged on the insulating substrate 10 in a matrix. A plurality of gate signal lines 51 connected to a gate driver 50 for supplying a gate signal are arranged in one direction, and a plurality of drain signal lines 61 are arranged in a direction crossing the gate signal lines 51. I have.

A drain signal line 61 is connected to sampling transistors SP1, SP2, SP2 in accordance with the timing of a sampling pulse output from a drain driver 60.
, SPn are turned on, and the data signal (analog video signal or digital video signal) of the data signal line 62 is supplied.

[0005] A gate driver 50 selects a certain gate signal line 51 and supplies a gate signal thereto. A data signal is supplied from the drain signal line 61 to the pixel electrodes 17 in the selected row.

Hereinafter, a detailed configuration of each pixel will be described. In the vicinity of the intersection between the gate signal line 51 and the drain signal line 61, a circuit selection circuit 40 including a P-channel circuit selection TFT 41 and an N-channel circuit selection TFT 42 is provided. Both drains of the circuit selection TFTs 41 and 42 are connected to a drain signal line 61, and both gates thereof are connected to a circuit selection signal line 88. One of the circuit selection TFTs 41 and 42 is turned on in response to the selection signal from the selection signal line 88. Further, a circuit selection circuit 43 is provided in a pair with the circuit selection circuit 40 as described later. In the circuit selection circuits 40 and 43, the transistors only need to operate complementarily, and the P channel and the N channel may be reversed.

As a result, an analog video signal display (corresponding to a full-color moving image) in a normal operation mode and a digital video display (low power consumption,
(Corresponding to a still image). Further, a pixel selection circuit 70 including an N-channel type pixel selection TFT 71 and an N-channel type TFT 72 is disposed adjacent to the circuit selection circuit 40. Pixel selection TFT
71 and 72 are circuit selection TFs of the circuit selection circuit 40, respectively.
T41 and 42 are connected in cascade, and a gate signal line 51 is connected to their gates. Pixel selection T
Both of the FTs 71 and 72 are configured to be turned on simultaneously according to a gate signal from the gate signal line 51.

An auxiliary capacitor 85 for holding an analog video signal is provided. One electrode of the storage capacitor 85 is connected to the source of the pixel selection TFT 71.
The other electrode is connected to a common auxiliary capacitance line 87, and is supplied with a bias voltage Vsc. Also, pixel selection TFT
The source of 71 is the circuit selection TFT 44 and the contact 16
Is connected to the pixel electrode 17 via the. When the gate of the pixel selection TFT 71 is opened by the gate signal, the analog video signal supplied from the drain signal line 61 is input to the pixel electrode 17 via the contact 16 and drives the liquid crystal as a pixel voltage. The pixel voltage must be held for one field period from the time when the selection of the pixel selection TFT 71 is released to the time when the pixel selection TFT 71 is again selected. Not sufficiently maintained for a period. Then, the decrease in the pixel voltage appears as display unevenness, and good display cannot be obtained. Therefore, an auxiliary capacitor 85 is provided to hold the pixel voltage for one field period.
The auxiliary capacitor 85 is constituted by a pair of electrodes having a predetermined area and facing each other.
A semiconductor layer integrated with 1 and the other electrode are auxiliary capacitance lines 87. The auxiliary capacitance lines 87 are connected by a plurality of pixels in the row direction, and the voltage _VSC is applied.

A P-channel type TFT 44 of the circuit selection circuit 43 is provided between the auxiliary capacitance 85 and the pixel electrode 17, and is turned on and off simultaneously with the circuit selection TFT 41 of the circuit selection circuit 40. Circuit selection TFT4
The operation mode in which 1 is turned on and an analog signal is supplied as needed to drive the liquid crystal is called a normal operation mode or an analog operation mode.

A holding circuit 110 is provided between the TFT 72 of the pixel selection circuit 70 and the pixel electrode 17. The holding circuit 110 includes two positively fed-back inverter circuits and a signal selection circuit 120, and forms an SRAM that holds digital binary values.

The signal selection circuit 120 is a circuit for selecting a signal in accordance with signals from two inverters, and includes two N-channel TFTs 121 and 122. Complementary output signals from the two inverters are applied to the gates of the TFTs 121 and 122, respectively, so that the TFTs 121 and 122 are turned on and off complementarily.

Here, when the TFT 121 is turned on, the counter electrode signal VCOM (signal A) of a DC voltage is selected, and the TFT 121 is turned on.
When the switch 122 turns on, an AC drive signal (signal B) for driving the liquid crystal, which is an AC voltage centered on the counter electrode signal VCOM, is selected.
5, is supplied to the liquid crystal pixel electrode 17 via the contact 16. When the circuit selection TFT 42 is turned on, the holding circuit 11
An operation mode in which a display is performed based on the data held in 0 is called a memory mode or a digital operation mode.

To summarize the above configuration, a circuit (analog display circuit) including a pixel selection TFT 71 as a pixel selection element and an auxiliary capacitor 85 for holding an analog video signal.
And a circuit (digital display circuit) including a TFT 72 as a pixel selection element and a holding circuit 110 for holding a binary digital video signal are provided in one display pixel.
A circuit selection circuit 40 for selecting these two circuits,
43 are provided.

Next, peripheral circuits of the liquid crystal panel 100 will be described. An external circuit board 90 separate from the insulating substrate 10 of the liquid crystal panel 100 has a drive signal generation circuit 9
1, a boosting circuit 92 and a voltage generating circuit 93 are provided. A battery 95 is connected to the external circuit board 90.

The battery 95 outputs a battery voltage VB, the boosting circuit 92 boosts the voltage to a higher boosted voltage VVDD, and the voltage generating circuit 93 outputs a predetermined voltage to the wiring connected to each part of the LCD panel 100. I do. The boost VVDD is used, for example, as a positive driving voltage of the gate driver 50. The boosted negative voltage VVEE is used as a driving negative voltage of the gate driver. The reference voltage VSS is usually ground. Signals A and B are voltages that are selected by the data held in the holding circuit 110 and applied to the liquid crystal. PCG and PCD are signals for precharging the drain signal line 61. Also, the vertical start signal STV is supplied from the drive signal generation circuit 91.
Is input to the gate driver 50, and the horizontal start signal S
TH is input to the drain driver 60. Further, a video signal is input to the data line 62.

Next, a method of driving the display device having the above-described configuration will be described. (1) In the case of the normal operation mode (analog operation mode) When the analog display mode is selected according to the mode signal, the drive signal generation circuit 91 is set to a state of supplying an analog signal to the data signal line 62 and , The potential of the circuit selection signal line 88 becomes L (low), and the circuit selection circuit 4
The P-channel circuit selection TFTs 41 and 44 of 0 and 43 are turned on, and the N-channel circuit selection TFTs 42 and 45 are turned off.

The sampling transistor SP according to a sampling signal based on the horizontal start signal STH.
, SPn are sequentially turned on, and the analog video signal of the data signal line 62 is supplied to the drain signal line 61.

A gate signal is supplied to the gate signal line 51 based on the vertical start signal STV. When the pixel selection TFT 71 is turned on in response to the gate signal, the analog video signal An. Sig is transmitted to the pixel electrode 17 and held in the auxiliary capacitance 85. A video signal voltage applied to the pixel electrode 17 is applied to the liquid crystal, and the liquid crystal is oriented according to the voltage, whereby a liquid crystal display can be obtained.

Since the drain signal line 61 is connected to many transistors, it has a large capacity and it is difficult to apply a video signal instantaneously. Therefore, the precharge transistors PCT1, PCT2,.
Thus, a precharge signal PCD of a predetermined voltage is supplied to each drain signal line 61. The precharge transistor is turned on every horizontal retrace period by the precharge signal PCG.

In this analog display mode, the liquid crystal is driven at any time in accordance with an analog signal input as needed, which is suitable for displaying a full-color moving image. However,
The drive signal generation circuit 91 of the external circuit board 90 and the drivers 50 and 60 constantly consume power to drive them. (2) In the case of the memory operation mode (digital display mode) When the digital display mode is selected according to the mode signal, the drive signal generation circuit 91 converts the digital signal obtained by digitally converting the video signal and extracting the upper 1 bit. The output is set to the data signal line 62, and the potential of the circuit selection signal line 88 becomes high, so that the circuit selection circuits 40 and 43 are output.
The circuit selection TFTs 41 and 44 are turned off, and the circuit selection TFTs 42 and 45 are turned on, and the holding circuit 110 is enabled.

Further, start signals STV and STH are input to the gate driver 50 and the drain driver 60 from the drive signal generation circuit 91 of the external circuit board 90, respectively. Sampling signals are sequentially generated in response thereto, and sampling transistors SP1, SP2,... Sig is sampled and supplied to each drain signal line 61.

Next, the holding circuit 110 will be described. First, the pixel selection TFT 72 of each display pixel connected to the gate signal line 51 is turned on for one horizontal scanning period by the gate signal G1. Focusing on the display pixels in the first row and first column, the digital video signal S11 sampled by the sampling signal SP1 is input to the drain signal line 61.
When the pixel selection TFT 72 is turned on by the gate signal, the digital signal D.D. Sig is the holding circuit 11
0 and held by two inverters.

The signal held by the inverter is input to a signal selection circuit 120, and the signal selection circuit 120
To select the signal A or the signal B, the selected signal is applied to the pixel electrode 17, and the voltage is applied to the liquid crystal.

By scanning from the gate signal line in the first row to the gate signal line in the last row in this manner, one screen (1
(Field period), that is, all dot scans are completed, and one screen is displayed.

Here, when one screen is displayed, the supply of voltage to the gate driver 50, the drain driver 60, and the drive signal generation circuit 91 of the external substrate is stopped, and the driving thereof is stopped. The holding circuit 110 is always driven by supplying the boosted voltage VVDD and the reference voltage VSS as the reference voltage, and the signals A and B are supplied to the selection circuit 1 using the common electrode voltage as the common electrode.
20.

That is, VVDD and VSS for driving the holding circuit 110 are supplied to the holding circuit 110, the common electrode voltage VCOM is applied to the common electrode, and the liquid crystal display panel 100 is normally white (NW). Applies an AC drive voltage of the same potential as the counter electrode voltage to the signal A, and applies an AC voltage (for example, 60 Hz 30H) for driving the liquid crystal to the signal B.
Only z) is applied. By doing so, one screen can be held and displayed as a still image.
In addition, no voltage is applied to the other gate driver 50, drain driver 60, and drive signal generation circuit 91.

At this time, when “H (high)” is input to the holding circuit 110 as a digital video signal to the drain signal line 61, the first TFT is selected in the signal selection circuit 120.
Since a row is to be input to 121, the first TF
T121 is turned off, and high is input to the other second TFT 122, so that the second TFT 122 is turned on. Then, the signal B is selected, and the voltage of the signal B is applied to the liquid crystal. That is, since the AC voltage of the signal B is applied and the liquid crystal rises by the electric field, the display can be observed as a black display on the NW display panel.

When low is input to the holding circuit 110 as a digital video signal to the drain signal line 61, high is input to the first TFT 121 in the signal selection circuit 120. The second TFT 122 is turned off, and a row is input to the other second TFT 122, so that the second TFT 122 is turned off. Then, the signal A is selected, and the voltage of the signal A is applied to the liquid crystal. That is, since the same voltage as that of the counter electrode is applied,
Since no electric field is generated and the liquid crystal does not rise, it can be observed as white display on the NW display panel.

As described above, a still image can be displayed by writing and holding one screen, but in this case, each of the drivers 50 and 60 and the drive signal generation circuit 9
1 is stopped, so that power consumption can be reduced accordingly.

[0030]

However, in the conventional active matrix type display device with a holding circuit, the voltage for operating the holding circuit in the memory operation mode is as follows.
There are disadvantages in that the number of power supplies and control signals supplied from the external circuit board 90 in the memory operation mode is large, and the number of terminals of the panel 100 is large.

In the memory operation mode, the boosted voltage VVDD is used as the power supply voltage. Therefore, it is necessary to keep operating the booster circuit of the external circuit board 90, and the power consumption in the memory operation mode is large. .

Accordingly, the present invention is to reduce the number of power supplies and control signals used in a memory operation mode in an active matrix display device having a holding circuit, thereby simplifying and further reducing power consumption. Aim.

[0033]

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and has a plurality of gate signal lines arranged in one direction on a substrate and a plurality of gate signal lines arranged in a direction intersecting the gate signal lines. And a plurality of pixel electrodes that are selected by a scanning signal from the gate signal line and to which a video signal is supplied from the drain signal line, and that stores data corresponding to the video signal that is arranged corresponding to the pixel electrode. An active matrix having a normal operation mode in which a pixel voltage corresponding to a video signal input as needed is displayed as needed, and a memory operation mode displaying in accordance with data stored in the holding circuit. In the type display device, the display device has a booster circuit for boosting an externally supplied power supply voltage, and the holding circuit operates using an output of the booster circuit in a memory operation mode. That is an active matrix type display device.

Further, a plurality of gate signal lines arranged in one direction on the substrate, a plurality of drain signal lines arranged in a direction intersecting the gate signal lines, and a scanning signal from the gate signal lines are selected. A plurality of pixel electrodes to which a video signal is supplied from a drain signal line, and a holding circuit that is arranged corresponding to the pixel electrode and stores data corresponding to the video signal. A power supply voltage externally supplied to the display device in an active matrix type display device having a normal operation mode in which display is performed by applying a pixel voltage as needed, and a memory operation mode in which display is performed according to data stored in the holding circuit. An active matrix display device having a switching circuit for switching between a normal operation mode and a memory operation mode in accordance with the output of a booster circuit for boosting the voltage.

Further, the voltage supply to the booster circuit is stopped in the normal operation mode.

Further, the booster circuit includes a charge pump to which a power supply voltage is supplied, an output of the charge pump, and a selection circuit for selecting and outputting a first voltage lower than the output of the charge pump. The selection circuit selects and outputs the first voltage in the normal operation mode, and selects and outputs the output of the charge pump in the memory operation mode.

[0037]

DESCRIPTION OF THE PREFERRED EMBODIMENTS A display device according to an embodiment of the present invention will be described. FIG. 1 shows a circuit configuration diagram when the display device of the present invention is applied to a liquid crystal display device. The pixel portion of the display device of the present embodiment is almost the same as the conventional one. That is, in this embodiment, the selection TF is selected by the circuit selection circuits 40 and 43.
By switching between the analog operation circuit having T71 and the storage capacitor 85 and the memory operation circuit having the holding circuit 110, the normal operation mode and the memory operation mode are switched and displayed. The same components as those in the related art are denoted by the same reference numerals, and detailed description is omitted.

The display device of the present embodiment is an LCD panel 1
00, a booster circuit 200, an oscillator 300, a ground switch 401, and a ground switch 402 are provided. The holding circuit is similar to the conventional display device in that two types of reference voltages, high and low, are input. However, in the present application, the output C1 of the boosting circuit 200 is supplied as the higher reference voltage. Is different from the past. The lower reference voltage is the reference potential VSS as usual, and is usually the ground potential.

First, the booster circuit 200 will be described.
FIG. 2 is a diagram showing the booster circuit 200 in more detail. The boosting circuit 200 includes a charge pump 201 supplied with the battery voltage VB and the reference voltage VSS, a first switching circuit 202 supplied with a switching signal, a second switching circuit 203 supplied with the boosted voltage VVDD, and a transistor 204. Have.

The charge pump 201 is supplied with a power supply voltage VB, boosts the power supply voltage VB, and outputs a predetermined voltage LVDD. The first switching circuit 202 receives a switching signal input to the gate electrodes of the P-channel transistor and the N-channel transistor, and outputs the output LVDD of the charge pump in response to the switching signal.
And a negative voltage VVEE to output a first control signal C1. The second switching circuit 203 receives VVDD at the gate electrodes of the P-channel transistor and the N-channel transistor, and outputs the output LVDD of the charge pump and the negative voltage VV according to VVDD.
EE and outputs the second control signal C2.

The first control signal C1 of the booster circuit 200 is
It is supplied as a gate voltage of the circuit selection circuits 40 and 43 and as a high voltage side reference voltage of the holding circuit 110. The second control signal C2 is supplied as a gate voltage of each transistor of the oscillation unit 300, the ground switch 401, and the ground switch 402.

Next, the oscillation section 300 will be described. FIG.
FIG. 3 is a diagram showing the oscillation unit 300 in more detail. Oscillator 3
Reference numeral 00 includes a transmitting circuit 301, a frequency dividing circuit 302, and a plurality of inverters. The transmission circuit 301 outputs a rectangular wave having a period of, for example, 120 Hz. The dividing circuit 302 includes the transmitting circuit 3
01 is divided by 4 and a rectangular wave having a cycle of 30 Hz is output. The output of the frequency dividing circuit 302 is output from inverters 307 and 30
After being inverted twice at 8, the signal is output as a first AC signal via the first output transistor 303. The output of the frequency dividing circuit 302 is output from inverters 307, 309, 310
After being inverted three times, the signal is output as a second AC signal via the second output transistor 304. The first and second AC signals are rectangular waves inverted from each other.

Next, the operation of this embodiment will be sequentially described with reference to FIG. 4 for three cases. FIG. 4 illustrates the booster circuit 200 and the oscillation unit 300 in detail. For simplification of the drawing, only one pixel is illustrated and other pixels are omitted. ing.

(1) Normal Operation Mode First, in the normal operation mode, the booster circuit 92 of the external circuit board 90 is operating, and a predetermined voltage VVDD is output as the driving positive voltage of the gate driver 50. In the normal operation mode, the gate driver 50 and the drain driver 60 operate based on various timing signals output from the drive signal generation circuit 91. The switching signal is high, and the first switching circuit 202 of the booster circuit 200
The low voltage VVEE is selected and output as the first control signal C1, the P-channel circuit selection TFTs 41 and 44 are turned on, and
The channel circuit selection TFTs 42 and 45 are turned off. Thus, when the pixel selection TFT 71 is turned on in response to the gate signal, the analog video signal A is output from the drain signal line 61.
n. Sig is transmitted to the pixel electrode 17 and the storage capacitor 85 to perform display.

At this time, since the first control signal C1 is supplied to the high-voltage reference voltage of the holding circuit 110, the holding circuit 110 has stopped its operation because the held contents have been erased.
Since the holding circuit 110 is unnecessary in the normal operation mode, the signal is shared with the gate electrodes of the circuit selection circuits 40 and 43, and the space in the pixel is saved. Further, the transistor 204 that supplies the battery voltage VB, which is the power supply to the charge pump 201, is turned off in response to the switching signal.
The operation of the charge pump 201 is also stopped, and the operation current of the charge pump 201 is reduced, including the leakage current of the circuit.
Can be reduced.

Further, since VVDD is high, the second switching circuit 203 also selects the low voltage VVEE and outputs the second control signal C2
And the first output transistor 3 of the oscillation unit 300
03, second output transistor 304, ground switch 40
1. Each transistor of the ground switch 402 is turned off.
The transistor 3 that supplies power to the oscillator 301
Since the switch 05 is turned off, the oscillator 301 stops operating, and the operating current of the oscillator 301 can be reduced. on the other hand,
Since the third output transistor 306 is turned on, a predetermined voltage VSC is applied to the electrode of the storage capacitor SC85.

The oscillating unit 300 is used in a memory operation mode described later, and is not used in a normal operation mode. However, simply turning off the transistors 303 and 304 causes a part of the circuit elements included in the oscillator 300 to be in a floating state, and the operation of peripheral circuits fluctuates the potential of some of those circuits, causing unexpected noise in display. There is a risk of carrying it. Therefore, in the present embodiment, a pair of P-channel transistors 311, 312 whose gates receive the second control signal C2 are provided. Transistor 31
1 and 312 are turned on in the normal operation mode, and the oscillation unit 300
Is grounded to prevent the influence of unexpected noise. The transistor 311 and the transistor 312 are connected to the circuit constituting the oscillating unit 300. If the transistor 311 and the transistor 312 are floating at the time of the normal operation mode, the effect can be obtained by grounding the transistor. The connection between the output transistors 308 and 310 and the output transistors 303 and 304 of the oscillating unit 300 can prevent the influence of noise most reliably.

(2) Holding Circuit Writing Mode Next, in the holding circuit writing mode, the booster circuit 92 of the external circuit board 90 is operating, and a predetermined voltage VVDD is output as the driving positive voltage of the gate driver 50. ing. The gate driver 50 and the drain driver 60
It operates based on various timing signals. The switching signal switches to low. As a result, the transistor 204 of the booster circuit 200 turns on, and the charge pump 201 operates. Then, the first switching circuit 202 outputs the output of the charge pump 201 as a first control signal, the P-channel circuit selection TFTs 41 and 44 are turned off, and the N-channel circuit selection TFTs 42 and 45 are turned on. Since the reference voltage of the holding circuit 110 is also turned on, the holding circuit 110 operates, and data based on the video signal is sequentially written to the holding circuit 110 of each pixel under the control of the gate driver 50 and the drain driver 60.

In the holding circuit write mode, since VVDD is output from the booster circuit 92, the booster circuit 200
Output from the second control signal C2 remains low.
Therefore, the transistors 303, 304,
305 remains off.

(3) Memory Operation Mode When the memory operation mode is set, the external circuit board 9
The 0 drive signal generation circuit 91 and the booster circuit 92 stop operating. Therefore, the driving voltage VVDD of the gate driver 50
Becomes low, and the gate driver 50 and the drain driver 60 also stop operating. Since the switching signal remains high, the circuit selection circuits 40 and 43 select the holding circuit 110, and the display device performs display according to the video data held in the holding circuit 110.

In the present embodiment, in the memory operation mode, the drive signal generation circuit 91 and the booster circuit 92 disposed on the external circuit board 90 completely stop operating and do not perform any output. Only the battery voltage VB supplied from the battery 95 is directly supplied to the liquid crystal display panel 100. The reference voltage to be supplied to the holding circuit 110 is obtained by boosting the battery voltage VB by the boosting circuit 200 disposed inside the liquid crystal display panel 100 and using the same. Therefore, voltage supply to the external circuit board 90 can be completely stopped, and power consumption in the memory operation mode is greatly reduced as compared with the conventional case.

When the external booster circuit 92 stops operating, VVDD goes low, and the second selector circuit 203 of the booster circuit 200 selects the output of the charge pump 201 and outputs it as the second control signal C2. Switch to Accordingly, the transistor 305 that supplies power to the oscillator 301 is turned on, and the oscillator 301 operates. The output of the oscillator 301 is frequency-divided by a frequency dividing circuit 302, inverted by inverters 307 to 310, and output via transistors 303 and 304. at the same time,
The transistor 306 is turned off. Transistor 303
Is called a first AC signal, and the output of the transistor 304 is called a second AC signal. The first and second AC signals have waveforms whose phases are shifted from each other by 180 degrees. Holding circuit 110
Turns on one of the transistors 121 and 122 and turns off the other in accordance with the video data.
When the transistor 122 is on, a first AC signal is supplied to the liquid crystal, and when the transistor 122 is on, a second AC signal is supplied to the liquid crystal. The second AC signal is also supplied to a counter electrode (not shown) as a counter electrode signal VCOM. Therefore, transistor 1
In the pixel where 22 is selected, the liquid crystal is not driven, and in the case of normally black, “black” is displayed.

When the voltage VSC supplied to the common electrode in the normal operation mode is floating in the memory operation mode, the transistor 306 does not need to be provided. However, VSC is supplied from the external circuit board 90,
Since the wiring is connected to the external circuit board 90, the wiring may pick up noise and hinder the operation.
Therefore, it is more preferable that the transistor 306 be provided.

In the present embodiment, in the memory operation mode, the drive signal generation circuit 91 and the booster circuit 92 arranged on the external circuit board 90 completely stop operating, and the voltage applied to the liquid crystal is It is created using the battery voltage VB by the oscillation unit 300 arranged inside the panel 100. Therefore, voltage supply to the external circuit board 90 can be completely stopped, and power consumption in the memory operation mode is greatly reduced as compared with the conventional case.

Next, the output potential of the booster circuit 200 will be described. The output of the booster circuit 200 is set to be higher than the highest potential that the output of the oscillation unit 300 can take. The output of the oscillating unit 300 is input to the pixel electrode 17 via the data output transistor 121 or 122 and the transistor 45 of the circuit selection circuit 43 in order. At this time, when the gate potentials of the circuit selection transistor 45 and the data output transistors 121 and 122 are lower than the potential of the oscillation unit 300, the transistors 45, 121, and 12
2 cannot be reliably turned on. Therefore, the gate voltages of the transistors 45, 121, and 122 need to be higher than the maximum voltage output from the oscillation unit 300. In the case of the present embodiment, the gate voltage of the circuit selection transistor 45 is the output voltage of the boosting circuit 200, and the gate voltage when turning on the data output transistors 121 and 122 is the high reference voltage of the holding circuit 100, that is, the boost voltage. The output voltage of the circuit 200. Therefore, the output potential of the booster circuit 200 is set to be higher than the highest potential of the output of the oscillation section 300 by the transistors 45 and 1.
If the thresholds 21 and 122 are set higher, the transistor 45 can be reliably turned on.

The output amplitude of the oscillation section 300 depends on the battery voltage VB. Since the voltage applied to the liquid crystal is determined by the amplitude of the oscillating unit 300, if the display is performed with the output amplitude obtained only from the battery voltage VB and the ON / OFF contrast ratio cannot be sufficiently obtained, the oscillator 301 is used. It is necessary to insert a booster circuit between the transistor and the transistor 305 to increase the voltage. In the present embodiment, the battery voltage VB
Is set to 3V, a sufficient contrast ratio can be obtained, and it is not necessary to insert a booster circuit between the oscillator 301 and the transistor 305.

The circuit elements on the liquid crystal display panel 100 are formed by using polysilicon obtained by crystallizing amorphous silicon with a laser or the like. Since the crystallinity of the polysilicon varies due to variations in the output of the crystallization laser and the like, the variation in characteristics is larger than that of a circuit element formed on a semiconductor wafer. For that reason,
Oscillator 301 may lose the duty of the output signal, that is, the balance between high and low. When the duty balance is lost, a DC component voltage is applied to the liquid crystal, which causes deterioration of the liquid crystal. On the other hand, according to the present embodiment, the output of the oscillator 301 is frequency-divided by the frequency dividing circuit 302 and output, so that the output duty of the oscillator 301 can be corrected and an output of a waveform with a uniform duty can be obtained. . Although the first and second AC signals are exemplified at 30 Hz, it is sufficient that the first and second AC signals are inverted at a cycle that does not cause deterioration of the liquid crystal, and the cycle is slower than the operation cycle of the gate driver 50 and the like. It is. In order to output such a slow-period AC output directly by the oscillator 301, the oscillator 30
1 and the number of inverter stages must be increased, and a large circuit area is required. In this embodiment, the output of the high-frequency oscillator 301 is divided by the frequency dividing circuit 302. Since the frequency division is performed, the capacitance and resistance of the oscillator 301 can be reduced, and the number of inverter stages can be reduced.

Next, the inverters 308 and 310 will be described. The output of the frequency dividing circuit 302 is applied to the liquid crystal via the transistors 121 and 122, respectively. The frequency dividing circuit 302 is arranged around the pixel portion and is supplied to each pixel by wiring. This wiring is thin and long. Further, since each pixel has a liquid crystal capacitance and a line cross capacitance, it can be said that the output destination of the frequency dividing circuit is a large load. When the output of the inverter 307 is supplied to such a large load, the output waveform of the inverter 307 is distorted. If the output waveform of the inverter becomes blunt, a through current will flow until the output is completely inverted, resulting in an increase in power consumption. By increasing the size of the inverter 307,
Although the output waveform can be sharpened to some extent, this leads to an increase in circuit area. Therefore, the inverter 30
By arranging 8, 310, the current driving capability can be enhanced, the output waveform can be sharpened, and the through current can be reduced. The more such inverters are arranged, the smaller the through current can be. In the present embodiment, the on-resistances of the transistors 303 and 304 are set to be somewhat larger than the on-resistances of the transistors constituting the inverter, so that the through current is reduced. In the present embodiment, the length of the transistors 303 and 304 /
When the width ratio was set to 1/40 and when the width ratio was set to 1/20, the through current was smaller when the width ratio was set to 1/20, and power consumption in the memory operation mode could be reduced. By intentionally setting the on-resistances of the transistors 303 and 304 to be large, the inverter 3
08 and 310 are minimized, and the increase in circuit area is suppressed as much as possible. The inverters 308 and 310 can be omitted as long as the through current can be sufficiently reduced by increasing the on-resistance of the transistors 303 and 304 and the output waveform can be absorbed. In the present embodiment, although not shown, 5 to 10 inverters 308 and 310 are arranged respectively.

Next, the ground transistors 401 and 402 will be described. In the memory operation mode, since the gate driver 50 and the drain driver 60 are stopped,
Since the gate line gate signal line 51 and the drain line drain signal line 61 are floating, capacitive coupling occurs with each circuit element in the pixel. Therefore, the potentials of the gate line gate signal line 51 and the drain line drain signal line 61 fluctuate, and the transistors 41, 71, and 72 in the pixel, which should be turned off, may be turned on. On the other hand, in the present embodiment, since the second control signal C2 is input to the gates of the ground transistors 401 and 402, they are turned on in the memory operation mode. Thereby, the gate line gate signal line 51,
The drain line and the drain signal line 61 are grounded to prevent a malfunction caused by a change in potential. In the present embodiment, VSS which is the ground potential is input before the ground transistors 401 and 402. However, the present invention is not limited to this.
Any potential may be used as long as the transistor 41, 71, 72 in the pixel is connected to an arbitrary voltage lower than the threshold voltage so as not to be turned on.

In the above embodiment, the holding circuit 110 holds only one bit. Of course, if the holding circuit 110 is multi-bit, gray scale display can be performed in the memory operation mode, and the holding circuit 110 can hold the analog signal. If a memory for storing values is used, full-color display in a memory operation mode can be performed.

As described above, according to the embodiment of the present invention, the normal operation mode (analog display mode) in which one liquid crystal display panel 100 displays a full-color moving image,
It is possible to cope with two types of display, that is, a memory operation mode for performing digital gradation display with low power consumption (in the case of a digital display mode).

In the above embodiment, if a reflection type LCD is used in which the pixel electrode is a reflection electrode, the holding circuit 110 and the like can be arranged below the pixel electrode.
, And the transparent pixel electrode and the holding circuit can be arranged so as to overlap each other. However, in a transmissive LCD, the area where the metal wiring is arranged is shielded from light, so that a decrease in the aperture ratio is inevitable. Further, when a holding circuit is arranged below a pixel electrode in a transmissive LCD, there is a possibility that a transistor of the holding circuit or a selection circuit may malfunction due to transmitted light, and thus a light-shielding film needs to be provided on the gates of all the transistors. . Therefore, it is difficult to increase the aperture ratio in a transmissive LCD. On the other hand, the reflection type LCD does not affect the aperture ratio regardless of what circuit is arranged below the pixel electrode. Furthermore, unlike a transmissive liquid crystal display device, there is no need to use a so-called backlight on the side opposite to the observer side, so that power for turning on the backlight is not required. Since the primary purpose of the LCD with the holding circuit is to reduce power consumption, it is preferable that the display device of the present invention is a reflective LCD that does not require a backlight and is suitable for low power consumption.

Although the above embodiment has been described using a liquid crystal display device, the present invention is not limited to this, and can be applied to various display devices such as an organic EL display device and an LED display device. it can.

[0064]

As described above, in the active matrix display device of the present invention, the holding circuit operates using the output of the booster circuit 200 provided in the display device in the memory operation mode. Since the wiring is shorter and can be arranged closer to the holding circuit than using the booster circuit 92 provided on the attached circuit board, the load on the wiring is lighter and the external booster circuit 9 is used.
2, the power consumption of the booster circuit 200 can be reduced, and the power consumption in the memory operation mode can be reduced.

A switching circuit 4 for switching a circuit used in a normal operation mode and a memory operation mode of the pixel portion.
Since 0 and 43 are switched in accordance with the output of the booster circuit 200 provided in the display device, there is no need to input a switching signal from the external circuit board 90, and the booster circuit 92 of the external circuit board 90 is switched. By stopping the operation, power consumption in the memory operation mode can be reduced.

In any of the above, by using the booster circuit 200 which operates in the memory operation mode,
Since an optimum voltage is supplied only to circuit elements used in the memory operation mode, and no extra voltage is supplied to circuit elements not used in the memory operation mode, power consumption in the memory operation mode can be reduced.

Further, since the voltage supply to booster circuit 200 is stopped in the normal operation mode, power consumption in the normal operation mode can be reduced.

Further, the booster circuit 200 selects and outputs a charge pump to which a power supply voltage (battery voltage VB in the embodiment) is supplied, and an output of the charge pump and a first voltage lower than the charge pump. It has a selection circuit. Then, the selection circuit selects and outputs the first voltage in the normal operation mode. Therefore, in the normal operation mode, the holding circuit 1
10 can be stopped to reduce the power consumption in the normal operation mode. In addition, since it becomes low in the normal operation mode and high in the memory operation mode, the switching circuit 4
0 and 43 can be appropriately switched. Therefore, there is no need to supply a dedicated signal for switching the switching circuits 40 and 43 from the external circuit board 90, and the number of connection terminals between the display device and the external circuit board 90 can be reduced.

[Brief description of the drawings]

FIG. 1 is a circuit diagram showing an active matrix display device according to an embodiment of the present invention.

FIG. 2 is a circuit diagram showing a booster circuit of the present invention.

FIG. 3 is a circuit diagram showing an oscillation unit according to the present invention.

FIG. 4 is a circuit diagram showing an embodiment of the present invention.

FIG. 5 is a circuit diagram showing a conventional active matrix type display device.

[Explanation of symbols]

 17 Pixel electrode 40, 43 Circuit selection circuit 51 Gate signal line 61 Drain signal line 70 Pixel selection circuit 85 Auxiliary capacitance 110 Holding circuit 200 Boosting circuit 201 Charge pump 202, 203 Selection circuit 300 Oscillator 301 Oscillator 302 Divider circuit

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) G09G 3/20 611 G09G 3/20 611A 612 612D 612G 624 624B F-term (Reference) 2H093 NA16 NA46 NA79 NC23 NC26 NC34 ND08 ND39 ND42 5C006 AF68 AF69 BB16 BC03 BC06 BC13 BF46 EC13 FA42 FA45 FA47 5C080 AA10 BB05 DD23 DD26 JJ02 JJ03 KK07 5C094 AA22 BA03 BA43 CA19 EA04 EA07

Claims (4)

[Claims] 1. A plurality of gate signal lines arranged in one direction on a substrate, a plurality of drain signal lines arranged in a direction intersecting with the gate signal lines, and a plurality of drain signal lines selected by a scanning signal from the gate signal lines. And a plurality of pixel electrodes to which a video signal is supplied from the drain signal line, and a holding circuit which is arranged corresponding to the pixel electrode and stores data corresponding to the video signal, and is inputted as needed. A normal operation mode in which a pixel voltage according to a video signal is applied at any time and displayed,
An active matrix display device having a memory operation mode in which a display is performed in accordance with data stored in the holding circuit, including a booster circuit for boosting a power supply voltage externally supplied to the display device; An active matrix display device which operates using an output of the booster circuit in a memory operation mode. 2. A plurality of gate signal lines arranged in one direction on a substrate, a plurality of drain signal lines arranged in a direction intersecting with the gate signal lines, and selection by a scanning signal from the gate signal lines. And a plurality of pixel electrodes to which a video signal is supplied from the drain signal line, and a holding circuit which is arranged corresponding to the pixel electrode and stores data corresponding to the video signal, and is inputted as needed. A normal operation mode in which a pixel voltage according to a video signal is applied at any time and displayed,
In an active matrix display device having a memory operation mode in which a display is performed in accordance with data stored in the holding circuit, a booster circuit for boosting a power supply voltage externally supplied to the display device is provided. And a switching circuit for switching between a normal operation mode and a memory operation mode. 3. The active matrix display device according to claim 1, wherein the supply of the power supply voltage to the booster circuit is stopped in a normal operation mode. 4. The booster circuit includes a charge pump to which a power supply voltage is supplied, a selection circuit that selects and outputs an output of the charge pump and a first voltage lower than the output of the charge pump. 2. The device according to claim 1, wherein the selection circuit selects and outputs the first voltage in a normal operation mode, and selects and outputs an output of the charge pump in a memory operation mode. 3. 3. The active matrix display device according to 2.