JPH07182106A - Tablet device unified with display - Google Patents

Abstract

PURPOSE:To provide a tablet device unified with a display which applies an active matrix drive method to detect coordinates without deteriorating the display quality. CONSTITUTION:The switches 6-11 switch and select the Y and X coordinate signal generating parts 3 and 5 during the detection of coordinates. Each of both parts 3 and 5 contains a single pulse generating circuit. This pulse generating circuit includes a differentiator, an inverter and a waveform shaper and inputs a gate clock signal and the TFT output signal sent from a liquid crystal driving TFT to generate a coordinate detection scanning pulse having the width shorter than the ON mode delay time of the TFT. This scanning pulse is applied successively to the gate electrode G and the source electrode S of a display panel 1 to scan these electrodes. Thus it is possible to prevent such a case where the TFT is turned on by the Y coordinate detection scanning pulse applied to the electrode G. Then the coordinates can be detected with no deterioration of the display quality.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to improvements in an active matrix type display-integrated tablet device.

[0002]

2. Description of the Related Art Conventionally, there is a display device with a tablet function in which an X drive line and a Y drive line of a display device driven by an active matrix drive method are shared by a display electrode and a tablet electrode. -294919
Issue).

In the above-mentioned display device with tablet function, a display period and a coordinate detection period are provided, and the X drive line and the Y drive line are connected to the X driver and the Y driver during the display period as in a normal display device. Drive to display an image. On the other hand, in the coordinate detection period, the designated coordinates on the liquid crystal display are detected by the electrostatic coupling method as described below.

That is, first, pulses are sequentially applied to the X drive lines arranged in M lines by an X driver, and then applied to the X drive lines by an input pen having a detection electrode capacitively coupled to the X drive lines at the tip. Detected pulse. Then, the X coordinate on the liquid crystal display designated by the input pen is detected by the application timing and the detection timing of the pulse. Similarly, pulses are sequentially applied by the Y driver to the Y drive lines arranged in N lines, and the Y coordinate on the liquid crystal display designated by the input pen is detected based on the application timing and the detection timing of the pulses. Of.

[0005]

However, the display device with a tablet function by the active matrix driving method such as the above-mentioned conventional display device with a tablet function generally has the following problems.

(1) When a TFT (thin film transistor) is used as an active element, when a pulse is applied to the drive line connected to the gate of the TFT among the X drive line or the Y drive line in the coordinate detection period. The TFT turns on. Therefore, the voltage applied to the liquid crystal is changed and the display is adversely affected.

(2) Further, in the above-mentioned display device with tablet function, since one frame is time-divided into the display period and the coordinate detection period, all the coordinate detection operations described above are performed during the coordinate detection period. Need to be completed. Therefore, the scanning speed at the time of sequentially applying the pulse to the X drive line or the Y drive line to perform scanning becomes high.

At this time, as shown in FIG.
The scanning speed can be increased by making the trailing edge of the pulse applied to the (n-1) th line Y drive line and the trailing edge of the pulse applied to the nth line Y drive line at the same timing. However, when attention is paid to the scanning of the nth line, the detection electrode of the input pen located on the Y driving line of the nth line is also electrostatically coupled to the Y driving line of the (n-1) th line. Therefore, the voltage (indicated by a broken line in FIG. 10B) induced in the electrode of the input pen due to the rising of the pulse applied to the Y drive line of the nth line is the Y drive of the (n-1) th line. It is canceled by the voltage induced due to the trailing edge of the pulse applied to the line, and the voltage sufficient for coordinate detection is not induced as shown by the solid line in FIG. 10 (b). As a result, highly accurate coordinate detection cannot be performed.

(3) In addition, in the display device with a tablet function as described above, the drive line located below the X drive line or the Y drive line (for example, the Y drive line) is connected to the pixel electrode via the active element. , And a counter electrode facing the pixel electrode via the liquid crystal. Therefore, X
When a pulse for coordinate detection is applied to the drive line, the above Y
When the drive line or the counter electrode is open or has a high resistance in the circuit, electrostatic coupling occurs between the Y drive line or the counter electrode and the X drive line. As a result, a voltage is induced in the Y drive line and the counter electrode due to the pulse applied to the X drive line, and the voltage induced in the Y drive line and the counter electrode causes X in the detection electrode of the input pen. A voltage irrelevant to coordinate detection is induced and the original induced voltage signal for X coordinate detection (hereinafter,
Noise will be superimposed on the normal induced voltage signal. As a result, it becomes one of the causes of a decrease in accuracy in specifying the X coordinate of the tip of the input pen. Similarly, when a pulse for coordinate detection is applied to the Y drive line, a voltage is also induced in the X drive line and the counter electrode, and noise is generated in the normal induction voltage signal induced in the detection electrode of the input pen. It is superimposed.

Further, the counter electrode may be alternately driven for the purpose of lowering the breakdown voltage of the gate driver (eg, Y driver). At that time, a voltage is induced in the detection electrode of the input pen due to the alternating voltage applied to the counter electrode, noise is superimposed on the normal induction voltage signal, and the coordinate detection accuracy deteriorates. .

SUMMARY OF THE INVENTION An object of the present invention is to provide a display-integrated tablet device by the active matrix driving method which can detect coordinates with high accuracy without impairing the display quality.

[0012]

In order to achieve the above object, the invention according to claim 1 has a common display electrode in an active matrix type liquid crystal display device and a coordinate detection electrode in an electrostatic induction type tablet device. In a display-integrated type tablet device which is composed of a column electrode and a row electrode and which integrates the liquid crystal display device and the tablet device, an X coordinate detection signal having a pulse of a predetermined width is generated during a coordinate detection period. An X-coordinate detection signal generator for scanning the column electrodes by sequentially applying the generated X-coordinate detection signals with phase shifts to the column electrode group, and a Y-coordinate having a pulse of a predetermined width in the coordinate detection period. A Y-coordinate detection signal generator for generating a detection signal, sequentially shifting the phase of the generated Y-coordinate detection signal to the row electrode group, and scanning the row electrode; In the coordinate detection signal generation unit for applying the coordinate detection signal to at least the electrode connected to the control terminal of the active element used in the active matrix type liquid crystal display device in the coordinate detection signal generation unit and the Y coordinate detection signal generation unit. And a pulse generator circuit for generating a pulse signal having a pulse width shorter than the on-time delay time of the active element and outputting the generated pulse signal as the X coordinate detection signal or the Y coordinate detection signal. It is characterized by having.

According to a second aspect of the present invention, the display electrodes in the active matrix type liquid crystal display device and the coordinate detection electrodes in the electrostatic induction type tablet device are constituted by common column electrodes and row electrodes, and In a display-integrated tablet device in which a liquid crystal display device and a tablet device are integrated, an X-coordinate detection signal generation unit that generates an X-coordinate detection signal having a pulse of a predetermined voltage value in the coordinate detection period, and the coordinate detection period. In the Y coordinate detection signal generating section for generating a Y coordinate detection signal having a pulse of a predetermined voltage value, and the X coordinate detection signal generated by the X coordinate detection signal generating section, and then the captured X coordinate detection. An inverted X coordinate detection signal is generated by inverting the polarity of the pulse in the signal, and the X coordinate detection signal and the inverted X coordinate detection signal are alternately and And X coordinate detection signal output unit for scanning the column electrodes are sequentially applied to the column electrode group by shifting the phase of, Y generated by the Y-coordinate detection signal generating unit
By taking in the coordinate detection signal, an inverted Y coordinate detection signal is generated by inverting the polarity of the pulse in the taken in Y coordinate detection signal, and the Y coordinate detection signal and the inverted Y coordinate detection signal are alternately and the phase thereof is changed. It is characterized in that a Y-coordinate detection signal output section for scanning the row electrodes by sequentially applying them to the row electrode group by shifting them is provided.

According to a third aspect of the present invention, the display electrodes in the active matrix type liquid crystal display device and the coordinate detection electrodes in the electrostatic induction type tablet device are constituted by common column electrodes and row electrodes, and In a display-integrated type tablet device in which a liquid crystal display device and a tablet device are integrated, a counter electrode driving section for driving the counter electrode by applying an alternating voltage to the counter electrode in the active matrix liquid crystal display device, and the counter electrode. A counter electrode first switch, which is provided in a line that supplies an alternating voltage from the drive unit to the counter electrode and turns on / off the connection between the counter electrode drive unit and the counter electrode, and the counter electrode and a portion of a predetermined potential A second switch for the counter electrode, which is provided on the line to be connected and which turns on / off the connection of the counter electrode and the predetermined potential portion, and each of the column electrodes A plurality of column electrode switches, which are provided on each line that connects a location of a predetermined potential and turn on / off the connection between each of the column electrodes and a location of a predetermined potential, each row electrode and a location of a predetermined potential. A plurality of row electrode switches provided on each line to be connected to turn on / off the connection between each of the row electrodes and a predetermined potential location, and the counter electrode first switch is turned off during the coordinate detection period. Then, the second switch for the counter electrode is turned on, the switch for the column electrode or the row electrode corresponding to the scanning electrode in the column electrode and the row electrode is turned off, and the switch for the column electrode and the row electrode is corresponding to the non-scanning electrode in the column electrode and the row electrode. A switch control circuit for turning on the column electrode switch and the row electrode switch is provided.

According to a fourth aspect of the present invention, the display electrodes in the active matrix type liquid crystal display device and the coordinate detection electrodes in the electrostatic induction type tablet device are constituted by common column electrodes and row electrodes, and In a display-integrated tablet device in which a liquid crystal display device and a tablet device are integrated, an X coordinate detection signal and a Y coordinate detection signal having a pulse of a predetermined voltage value are generated in the coordinate detection period to generate the column electrode and the row electrode. A coordinate detection signal generating section for scanning the column electrodes and the row electrodes by sequentially applying a phase-shifted signal to each other, and comprising the pulse generating circuit in the display-integrated tablet device according to the first aspect of the present invention. A structural unit, the X-coordinate detection signal output section and the Y-coordinate in the display-integrated type tablet device of the invention according to claim 2. A second constituent unit consisting of an output signal output section, and the counter electrode first switch, counter electrode second switch, column electrode switch, row electrode switch in the display-integrated type tablet device according to the present invention. And at least two constituent units out of a third constituent unit composed of a switch control circuit.

[0016]

In the invention according to claim 1, during the coordinate detection period, the X coordinate detection signal generating section and the Y coordinate detection signal generating section generate the X coordinate detection signal and the Y coordinate detection signal having a pulse of a predetermined width. The phases are shifted and sequentially applied to the column electrode group and the row electrode group, and the column electrode and the row electrode are scanned. At that time, one of the X coordinate detection signal generating section and the Y coordinate detection signal generating section which applies the coordinate detection signal to at least the electrode connected to the control terminal of the active element used in the active matrix type liquid crystal display device The pulse generation circuit provided in the coordinate detection signal generation unit generates a pulse signal having a pulse width shorter than the on-time delay time of the active element to generate the X
It is output as a coordinate detection signal or a Y coordinate detection signal. Thus, the electrode scanning is executed without the active element operating due to the coordinate detection signal applied to the electrode connected to the control terminal of the active element in the active matrix type liquid crystal display device.

Further, in the invention according to claim 2, in the coordinate detection period, the X coordinate detection signal generating unit and the Y coordinate detection signal generating unit generate the X coordinate detection signal and the Y coordinate detection signal having a pulse of a predetermined voltage value. To be done. Then, the polarity of the pulse in the X coordinate detection signal is inverted by the X coordinate detection signal output unit to generate the inverted X coordinate detection signal, and the X coordinate detection signal and the inverted X coordinate detection signal are alternately and in phase. Are shifted and sequentially applied to the column electrode group to scan the column electrodes. On the other hand, the Y coordinate detection signal output section inverts the polarity of the pulse in the Y coordinate detection signal to generate an inverted Y coordinate detection signal, and the Y coordinate detection signal and the inverted Y coordinate detection signal are alternately and in phase. Are shifted and sequentially applied to the column electrode group to scan the row electrodes. Thus, in the coordinate detection period, the X coordinate detection signal and the Y coordinate detection signal having the pulses of opposite polarities are applied to the adjacent column electrodes and the adjacent row electrodes, and the electrode scanning is performed.

Further, in the invention according to claim 3, in the coordinate detection period, the first switch for the counter electrode is turned off by the switch control circuit so that the counter electrode drive section moves to the counter electrode of the active matrix type liquid crystal display device. The supply of alternating voltage is stopped. Further, the second switch for the counter electrode is turned on to connect the counter electrode to the predetermined potential portion, and the potential of the counter electrode is fixed to the potential of the predetermined potential portion. Further, the column electrode switch or the row electrode switch corresponding to the scanning electrode in the column electrode row and the row electrode column is turned off, and the scanning electrode is opened. Further, the column electrode switch and the row electrode switch corresponding to the non-scanning electrodes in the column electrodes and the row electrodes are turned on, and the potential of the non-scanning electrodes is fixed to the potential of the predetermined potential portion. Thus, in the coordinate detection period, all the electrodes other than the scanning electrodes are fixed to the potential of the predetermined potential portion, and noise is superimposed on the normal induction voltage signal due to the voltage fluctuation of the electrodes other than the scanning electrodes. Coordinate detection is carried out without doing so.

Further, in the invention according to claim 4, in the coordinate detection period, the coordinate detection signal generating section generates the X coordinate detection signal and the Y coordinate detection signal having the pulse of the predetermined voltage value to generate the column electrode group and the row. The column electrodes and the row electrodes are scanned by sequentially applying them to the electrode group with a phase shift. At that time, the first constituent unit including the pulse generating circuit in the display-integrated type tablet device of the invention according to claim 1 and the X-coordinate detection signal output unit in the display-integrated type tablet device of the invention according to claim 2. And a second structural unit consisting of a Y coordinate detection signal output section, and the counter electrode first switch, the counter electrode second switch, the column electrode switch, and the row in the display-integrated type tablet device of the invention according to claim 3. An active matrix liquid crystal display device, which is caused by the coordinate detection signal applied to the scan electrode by the operation of each constituent element in at least two constituent units of the third constituent unit including an electrode switch and a switch control circuit. The active elements in the circuit do not operate, the coordinate detection signal with the pulse of opposite polarity is applied to the adjacent electrodes, All of the electrodes other than the electrode are at least two of being fixed to the potential of a predetermined potential locations is performed.

[0020]

The present invention will be described in detail below with reference to the embodiments shown in the drawings.

<First Embodiment> FIG. 1 is a block diagram of a main part of a display-integrated type tablet device of the present embodiment. Figure 1
On the transparent TFT substrate that constitutes the display panel 1, m source electrodes S (S _{1 to} S _m ) extending in the column direction are arranged in parallel while extending in the row direction. The n gate electrodes G (G _{1 to} G _n ) are arranged in parallel. A TFT (not shown) is formed as a liquid crystal driving element at the intersection of each source electrode S and gate electrode G, and the gate of this TFT is connected to the gate electrode G, while the source is connected to the source electrode S. is doing. Further, a pixel electrode (not shown) arranged in a region surrounded by the gate electrode G and the source electrode S is connected to the drain. A common counter electrode (not shown) is arranged so as to face each pixel electrode.

A scanning pulse for image display is applied from the gate driver 2 to the gate electrode G in the display period, while a scanning pulse for coordinate detection is applied from the Y coordinate detection signal generator 3 in the coordinate detection period. Apply. Further, to the source electrode S, a display pulse is applied from the source driver 4 in the above display period, while a scanning pulse for coordinate detection is applied from the X coordinate detection signal generator 5 in the coordinate detection period. At this time, the selection of switching between the gate driver 2 and the Y coordinate detection signal generator 3 is made by the changeover switches 6, 7 and 8, and the selection of switching between the source driver 4 and the X coordinate detection signal generator 5 is made up of the changeover switches 9, 10. , 11 is performed.

In the display panel 1, the side on which the gate electrode G and the source electrode S are formed is the front side, and the side on which the counter electrode is formed is the back side. The detection pen is positioned on the front side where the gate electrode G and the source electrode S are formed, and is capacitively coupled to the gate electrode G and the source electrode S. By thus setting the counter electrode side as the back side, the distance between the gate electrode G or the source electrode S, which is the coordinate detection electrode, and the electrode of the detection pen becomes large, and the counter electrode serves as a shield. The G or source electrode S and the electrode of the detection pen are prevented from being capacitively coupled.

The pulse width setting of the scanning pulse for coordinate detection, which is a feature of this embodiment, will be described below.

When the input voltage having the waveform as shown in FIG. 2 (a) is input to the gate of the TFT for driving the liquid crystal, T
There is a time lag (on-time delay time t _α (on)) until the FT is turned on and the output voltage having the waveform as shown in FIG. 2B is output from the drain. That is, in order to turn on the TFT, it is necessary to continuously apply the input voltage for the on delay time t _α (on) or more. In view of this, in the present embodiment, the pulse width of the scanning pulse for coordinate detection is shown in FIG.
As shown in (c), it is set narrower than the on-delay time t _α (on). By doing so, when the scanning pulse is applied to the gate electrode G in the coordinate detection period,
Since the voltage is not applied to the gate of the FT for a time longer than the on-delay time t _α (on), the TFT does not turn on.

FIG. 3 shows the inside of the Y-coordinate detection signal generator 3 and the X-coordinate detection signal generator 5, and the on-time delay time t of the TFT based on a gate clock signal from the outside.
FIG. 4 is a block diagram of a single pulse generation circuit that generates a single pulse having a pulse width narrower than _α (on), and FIG. 4 is a timing chart of each signal in FIG.

In FIG. 3, a gate clock signal a as shown in FIG. 4A is input to the differentiator 15. And
Based on the input gate clock signal a, the differentiator 15, the inverter 16 and the waveform shaper 17 generate a pulse shorter than the ON delay time t _α (on) of the TFT as shown in FIG. 4D. _{That is,} the coordinate detection scanning pulse d having the width t _α is generated.

As described above, in the present embodiment, the above Y
Coordinate detection signal generator 3 and X coordinate detection signal generator 5
Is a liquid crystal driving T by the single pulse generating circuit.
Pulse width t _α narrower than FT18 on delay time t _α (on)
The coordinate detection scanning pulse d is generated and applied to the corresponding gate electrode G and each source electrode S.
Therefore, the T of the display panel is caused by the scanning pulse for coordinate detection applied to the gate electrode G in the coordinate detection period.
The FT does not turn on, and the coordinates can be detected without impairing the display quality.

The single pulse generating circuit is provided only on the Y coordinate detection signal generating section 3 side, and only the pulse width of the scanning pulse d of the Y coordinate detection signal applied to the gate electrode G is turned on in the liquid crystal driving TFT. It may be set to be narrower than the time delay time t _α (on).

<Second Embodiment> The basic structure of the display-integrated tablet device in this embodiment is the same as that of the display-integrated tablet device shown in FIG.

FIG. 5 is a diagram showing a scanning pulse generation circuit which is provided in the Y coordinate detection signal generating section 3 and the X coordinate detection signal generating section 5 in the present embodiment and generates a scanning pulse for coordinate detection. . Note that FIG. 5A shows an n-line scan pulse generation circuit, and FIG. 5B shows an (n + 1) -line scan pulse generation circuit.

The scanning pulse generating circuit for n lines is composed of a buffer 21, and as shown in FIG. 6B, an n line detection signal having a positive pulse generated based on a clock signal or the like is directly used for n lines. Output as a coordinate detection scan pulse. The (n + 1) -line scanning pulse generation circuit is composed of the exclusive OR gate 22 and becomes positive during the coordinate detection period and the (n + 1) -line detection signal having a positive pulse generated based on the clock signal or the like. As shown in FIG. 6C, the coordinate detection period signal is input and a (n + 1) line coordinate detection scanning pulse having a negative pulse is output.

By doing so, when the scanning pulse is applied to the gate electrode G or the source electrode S by the Y coordinate detection signal generator 3 or the X coordinate detection signal generator 5 in the coordinate detection period, as shown in FIG. For example, (n
-1) A negative scanning pulse is applied to the gate electrode G of the 1st line, a positive scanning pulse is applied to the gate electrode G of the nth line, and a negative scanning pulse is applied to the gate electrode G of the (n + 1) th line. For example, a pulse is applied, and a positive scanning pulse and a negative pulse are applied from a gate electrode (eg, G ₁ ) arranged on one side in a row of gate electrodes G toward a gate electrode (eg, G _n ) arranged on the other side. That is, the scanning pulse can be applied alternately to perform scanning.

In this embodiment, in order to increase the scanning speed, the end timing of the scanning pulse applied to the gate electrode G (source electrode S) on the (n-1) th line and the gate electrode G (on the nth line) When the start timing of the scan pulse applied to the source electrode S) is the same (that is, the phase difference of the scan pulse applied to the adjacent gate electrode G (source electrode S) is the same as the pulse width) Is the above (n
-1) While the scanning pulse rises at the timing of ending the scanning pulse applied to the gate electrode G (source electrode S) on the line, the scanning pulse applied to the gate electrode G (source electrode S) on the n-th line The scan pulse falls at the start timing. That is, the changing directions of the scanning pulse in the adjacent gate electrodes G (adjacent source electrodes S) are always the same at the same timing. Therefore,
The voltage induced in the electrode of the detection pen at the start of the scanning pulse applied to the gate electrode G (source electrode S) on the n-th line is applied to the gate electrode G (source electrode S) on the (n-1) -th line. It is not canceled by the voltage induced on the electrodes of the detection pen at the end of the applied scanning pulse.

As described above, according to this embodiment, in the coordinate detection period, the scanning pulse having the opposite polarity is applied to the adjacent gate electrode G (or the adjacent source electrode S). Therefore, when the phase difference of the scanning pulse applied to the adjacent gate electrode G (or the adjacent source electrode S) is made equal to the pulse width, the adjacent gate electrode G (or the adjacent source electrode S)
In the same timing, the changing direction of the scanning pulse is always the same, and the voltage induced in the electrode of the detection pen at the start of the scanning pulse applied to one gate electrode G (or source electrode S) is At the end of the scanning pulse applied to the gate electrode G (or the source electrode S), it is not canceled by the voltage induced in the electrode of the detection pen, and a voltage sufficient for coordinate specification is induced in the electrode of the detection pen. It Therefore, highly accurate coordinate detection can be performed.

<Third Embodiment> FIG. 7 is a block diagram showing a main part of a display-integrated type tablet device according to this embodiment. In the display-integrated type tablet device of this embodiment, as in the display-integrated type tablet device shown in FIG. 1, m source electrodes S extending in the column direction are formed on the TFT substrate 25 forming the display panel 1. (S _{1 to} S _m ) are arranged in parallel, while n gate electrodes G (G _{1 to} G _n ) extending in the row direction are arranged in parallel, and each source electrode S and gate electrode TFTs and pixel electrodes are formed at the intersections with G. Then, the changeover switch performs switching selection between the gate driver and the Y-coordinate detection signal generating section 3 or switching selection between the source driver and the X-coordinate detection signal generating section 5, and the image display and the above-described display period. Coordinate detection of the tip of the detection pen in the coordinate detection period is executed.
Incidentally, in FIG. 7, the TFT, the pixel electrode, the gate driver, the source driver and the changeover switch are omitted since they are not directly related to this embodiment.

An alternating voltage is applied from the counter electrode drive section 27 to the counter electrode 26 provided so as to face the TFT substrate 25 through the counter electrode first analog switch 28. Further, the counter electrode 26 is grounded through the counter electrode second analog switch 29. In addition, each gate electrode G has a gate electrode analog switch 30, 31, ...,
It is grounded via 32. Similarly, each source electrode S
Are source electrode analog switches 33, 34, ..., 35
Grounded through. Then, the first analog switch 28 for the counter electrode and the second analog switch 2 for the counter electrode
9, gate electrode analog switches 30, 31, ..., 3
2, source electrode analog switches 33, 34, ..., 35
Is controlled by an analog switch control circuit as shown in FIG. 8 to turn on / off.

FIG. 8 shows a gate electrode / counter electrode analog switch control circuit mounted on the Y coordinate detection signal generator 3. This analog switch control circuit is provided with NOR gates 37 corresponding to the number of inverters 36 and gate electrodes G,
38, 39, ... The coordinate detection period signal whose level is “H” during the coordinate detection period output from the control unit (not shown) which controls the display-integrated type tablet device is
The second analog switch control signal for the counter electrode is directly output to the second analog switch 29 for the counter electrode, while the level is inverted via the inverter 36 and the first analog switch control signal for the counter electrode is used for the first counter electrode. It is output to the analog switch 28. Further, a scanning pulse whose level becomes “H” at the time of scanning the gate electrode in the coordinate detection period is input to one input terminal of each NOR gate 37, 38, 39, ...
The output signal from 6 is input. And Noah Gate 3
The outputs from 7, 38, 39, ... Are input to the corresponding gate electrode analog switches 30, 31 ,.

FIG. 9 is a timing chart of the output signal from the analog switch control circuit. Below, FIG.
The operation of the analog switch control circuit will be described with reference to FIG.

First, during the display period, the level of the coordinate detection period signal is "L". Therefore, the level of the counter electrode second analog switch control signal becomes "L", and the counter electrode second analog switch 29 is turned off. On the other hand, the level of the counter electrode first analog switch control signal output from the inverter 36 becomes "H", and the counter electrode first analog switch 28 is turned on. Thus, in the display period, the counter electrode driving unit 2
An alternating voltage is applied from 7 to the counter electrode 26. A signal of level "H" is input from the inverter 36 to one input terminal of each NOR gate 37, 38, 39, .... Therefore, the level of the analog switch control signal for each gate electrode from each NOR gate 37, 38, 39, ... Is "L", all the gate electrodes G are open, and the applied gate signal voltage for display. Become.

Next, during the coordinate detection period, the level of the coordinate detection period signal becomes "H", so the levels of the counter electrode first analog switch control signal and the counter electrode second analog switch control signal are displayed. The opposite of the period. Therefore, the alternating voltage is not applied to the counter electrode 26, and it is grounded to the ground level. A signal of level "L" is input from the inverter 36 to one input terminal of each NOR gate 37, 38, 39, .... Therefore, only the NOR gate to which the scan pulse of level "H" is input outputs the analog switch control signal for gate electrode of level "L". Therefore, only the gate electrode G currently being scanned is opened, and other gate electrodes G are opened.
Is grounded to ground level.

The analog switch control circuit for the source electrode has a similar structure and operates in the same manner. as a result,
All the source electrodes S are opened during the display period. On the other hand, during the coordinate detection period, only the source electrode S that is being scanned is open, and the other source electrodes S are all grounded to the ground level.

As a result, for example, when scanning the gate electrode G in the coordinate detection period, the selected gate electrode G is scanned.
All the gate electrodes G, the source electrodes S, and the counter electrode 26 other than that are grounded to the ground level. Therefore, the source electrode S and the counter electrode 26 are not induced with a voltage that may cause noise in the normal induction voltage signal due to the scanning pulse applied to the selected gate electrode G. On the other hand, when scanning the source electrode S, the source electrode S other than the selected source electrode S, the gate electrode G, and the counter electrode 26 are grounded to the ground level. Therefore, a voltage that may cause noise in the normal induction voltage signal due to the scanning pulse applied to the selected source electrode S is not induced.

As described above, in this embodiment, each gate electrode G, each source electrode S, and the counter electrode 26 are grounded via the analog switch. Under the control of the analog switch control circuit, the non-selection electrode and the counter electrode 26 are grounded in the coordinate detection period, so that the voltage is applied to the non-selection electrode and the counter electrode 26 due to the scanning pulse applied to the selection electrode. It is possible to prevent the induction and accurately perform coordinate detection based on the normal induction voltage signal on which noise is not superimposed.

In the above embodiment, when the second analog switch 29 for the counter electrode, the analog switches 30 to 32 for the gate electrode and the analog switches 33 to 35 for the source electrode are turned on, each electrode is at the ground level. I am trying to become. However, the present invention is not limited to this, and may be set to another constant level such as the power supply voltage V _CC level. Further, in the above-described embodiment, in the coordinate detection period, the voltage signal induced in the detection electrode of the detection pen when the scanning pulse is applied to the gate electrode G or the source electrode S is used as the normal induction voltage signal, The detection pen tip coordinates are detected based on the induced voltage signal. However, the present invention is not limited to this, and the voltage induced in the gate electrode G or the source electrode S when a voltage is applied to the electrode of the input pen is detected as the normal induction voltage signal, and the normal induction voltage signal is detected. It is also applicable to a display-integrated type tablet device that detects the coordinates of the tip of the input pen based on a voltage signal. In addition, the first embodiment, the second embodiment and the third embodiment described above.
There is no problem even if two or more embodiments are combined and carried out.

[0046]

As is apparent from the above, in the display-integrated type tablet device according to the first aspect of the present invention, the predetermined width generated by the X coordinate detection signal generating section and the Y coordinate detection signal generating section in the coordinate detection period. When scanning the column electrodes and the row electrodes by the X-coordinate detection signal and the Y-coordinate detection signal having the pulse of, the X-coordinate detection signal generator and the Y-coordinate detection signal generator are used in at least the active matrix type liquid crystal display device. A pulse having a pulse width shorter than the on-time delay time of the active element by a pulse generation circuit provided in the coordinate detection signal generating section for applying the coordinate detection signal to the electrode connected to the control terminal of the active element. Since a signal is generated and output as the X coordinate detection signal or the Y coordinate detection signal, in the coordinate detection period , The electrode connected to the control terminal of the active element coordinate detection signal having a pulse shorter than the delay time when on the active element is applied. Therefore, the active element does not operate due to the coordinate detection signal applied to the scan electrode during the coordinate detection period, and the coordinate can be detected without impairing the display quality.

In the display-integrated tablet device according to the second aspect of the present invention, the X-coordinate detection signal output section and the Y-coordinate detection signal output section output the X-coordinate detection signal and the Y-coordinate detection signal during the coordinate detection period. An inverted X coordinate detection signal and an inverted Y coordinate detection signal in which the polarities of the pulses are inverted are generated, and the respective coordinate detection signals and the corresponding inverted coordinate detection signals are alternately and shifted in phase so that the column electrode group and the row electrode group are formed. Since the column electrodes and the row electrodes are scanned by sequentially applying the same to the column electrodes and the row electrodes adjacent to each other, coordinate detection signals having pulses of opposite polarities are applied to the adjacent column electrodes and the adjacent row electrodes.

Therefore, when the phase shift between the coordinate detection signal applied to the adjacent column electrode or the adjacent row electrode and the inverted coordinate detection signal is set to be the same as the pulse width, it is applied to the adjacent electrode. The changing directions of the voltage at the same timing in the pulse of the coordinate detection signal are the same. As a result, the voltage induced in the detection electrode of the detection pen due to the voltage change of the coordinate detection signal applied to one of the adjacent electrodes is the voltage of the coordinate detection signal applied to the other electrode. It is not canceled by the induced voltage caused by the change. That is, according to the present invention, it is possible to prevent the voltage drop of the normal induction voltage signal induced in the detection electrode of the detection pen and accurately detect the coordinates.

Further, in the display-integrated tablet device according to the third aspect of the present invention, during the coordinate detection period, the switch control circuit turns off the first counter electrode switch to turn off the counter electrode in the active matrix type liquid crystal display device. The application of the alternating voltage from the counter electrode driving unit is stopped, the second switch for the counter electrode is turned on to fix the potential of the counter electrode to a predetermined potential, and the switch for the column electrode or the row electrode corresponding to the scan electrode. Is turned off to open the scanning electrode, and the column electrode switch and the row electrode switch corresponding to the non-scanning electrode are turned on to fix the potential of the non-scanning electrode to a predetermined potential. The electric potentials of all the electrodes can be fixed to the above predetermined electric potential. Therefore, no voltage is induced in the non-scanning electrode and the counter electrode due to the voltage change of the scan electrode, and noise is superimposed on the normal induced voltage signal due to the voltage change of the electrodes other than the scan electrode. It is possible to prevent coordinates from being detected and to accurately detect coordinates.

A display-integrated tablet device according to a fourth aspect of the present invention includes a first structural unit including the pulse generating circuit in the display-integrated tablet device according to the first aspect, and a second aspect. A second constituent unit comprising the X coordinate detection signal output unit and the Y coordinate detection signal output unit in the display integrated tablet device of the invention, and the first counter electrode first in the display integrated tablet device of the invention according to claim 3. The switch, the second switch for the counter electrode, the switch for the column electrode, the switch for the row electrode, and the third constituent unit consisting of the switch control circuit, and at least two constituent units are provided. And claim 3
It is possible to provide a display-integrated tablet device that exhibits at least two effects of the effects of the display-integrated tablet device according to the invention.

[Brief description of drawings]

FIG. 1 is a block diagram of essential parts in a display-integrated tablet device of the present invention.

FIG. 2 is an explanatory diagram of a pulse width of a coordinate detection scanning pulse in the first embodiment.

FIG. 3 is a block diagram of a single pulse generation circuit that sets the pulse width shown in FIG.

FIG. 4 is a timing chart of each signal in the single pulse generation circuit shown in FIG.

FIG. 5 is a circuit diagram of a scan pulse generation circuit according to a second embodiment.

6 is a waveform diagram of coordinate detection scan pulses generated by the scan pulse generation circuit shown in FIG.

FIG. 7 is a block diagram of a main part of a display-integrated tablet device according to a third embodiment.

FIG. 8 is a circuit diagram of an analog switch control circuit that controls each analog switch shown in FIG.

9 is a timing chart of each analog switch control signal output from the analog switch control circuit shown in FIG.

FIG. 10 is a diagram showing a relationship between a conventional coordinate detection scanning pulse waveform and an induced voltage waveform.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Display panel, 3 ... Y coordinate detection signal generator, 5 ... X coordinate detection signal generator, 6-1
1 ... switch, 15 ... differentiator, 1
6 ... Inverter, 17 ... Waveform shaper, 26
... Counter electrode, 27 ... Counter electrode drive unit, 28
... 1st analog switch for counter electrodes, 29 ... 2nd analog switch for counter electrodes, 30-32 ... Analog switch for gate electrodes, 33-35 ... Analog switch for source electrodes.

Claims (4)

[Claims] 1. A display electrode in an active matrix type liquid crystal display device and a coordinate detection electrode in an electrostatic induction type tablet device are constituted by a common column electrode and row electrode, and the liquid crystal display device and the tablet device are combined. In the integrated display-integrated tablet device, an X coordinate detection signal having a pulse of a predetermined width is generated during the coordinate detection period, and the generated X coordinate detection signal is sequentially applied to the column electrode group while shifting the phase thereof. Then, an X-coordinate detection signal generator that scans the column electrodes and a Y-coordinate detection signal having a pulse of a predetermined width are generated in the coordinate detection period, and the phase of the generated Y-coordinate detection signal is shifted. In the Y-coordinate detection signal generating section and the X-coordinate detection signal generating section and the Y-coordinate detection signal generating section for sequentially applying to the row electrode group to scan the row electrode. The delay time when the active element is turned on is provided in at least the coordinate detection signal generating section for applying the coordinate detection signal to the electrode connected to the control terminal of the active element used in the active matrix type liquid crystal display device. A display-integrated type tablet device comprising a pulse generation circuit for generating a pulse signal having a shorter pulse width and outputting the generated pulse signal as the X coordinate detection signal or the Y coordinate detection signal. 2. A display electrode in an active matrix type liquid crystal display device and a coordinate detection electrode in an electrostatic induction type tablet device are constituted by a common column electrode and row electrode, and the liquid crystal display device and the tablet device are combined. In an integrated display-integrated tablet device, an X-coordinate detection signal generator that generates an X-coordinate detection signal having a pulse of a predetermined voltage value in the coordinate detection period, and a pulse of a predetermined voltage value in the coordinate detection period. And a Y-coordinate detection signal generator that generates a Y-coordinate detection signal and an X-coordinate detection signal generated by the X-coordinate detection signal generator, and inverts the polarity of the pulse in the captured X-coordinate detection signal. A reversed X-coordinate detection signal is generated, and the X-coordinate detection signal and the inverted X-coordinate detection signal are alternated and their phases are shifted. An X-coordinate detection signal output section for sequentially applying to the electrode group to scan the column electrodes, and a Y-coordinate detection signal generated by the Y-coordinate detection signal generation section are taken in to output the pulse of the taken-in Y-coordinate detection signal. An inverted Y-coordinate detection signal whose polarity is inverted is generated, and the Y-coordinate detection signal and the inverted Y-coordinate detection signal are alternately applied to the row electrode group alternately and with their phases shifted to scan the row electrode. A display-integrated tablet device comprising a coordinate detection signal output unit. 3. A display electrode in an active matrix type liquid crystal display device and a coordinate detection electrode in an electrostatic induction type tablet device are constituted by a common column electrode and row electrode, and the liquid crystal display device and the tablet device are combined. In an integrated display-integrated type tablet device, a counter electrode drive section for applying an alternating voltage to the counter electrode in the active matrix liquid crystal display device to drive the counter electrode, and a counter electrode drive section for alternating the counter electrode to the counter electrode. A counter electrode first switch that is provided on a line that supplies a voltage and that turns on / off the connection between the counter electrode driving unit and the counter electrode, and a line that connects the counter electrode and a portion of a predetermined potential are provided. To turn on the connection between the counter electrode and the predetermined potential
A second switch for the counter electrode that is turned on / off, and a plurality of lines that are provided on each line that connects each of the column electrodes and a portion of a predetermined potential to turn on / off the connection between each of the column electrodes and a portion of the predetermined potential. A column electrode switch, a plurality of row electrode switches provided on each line that connects each row electrode and a location of a predetermined potential, and a plurality of row electrode switches that turn on / off the connection between each row electrode and a predetermined potential location, In the coordinate detection period, the counter electrode first switch is turned off, the counter electrode second switch is turned on, and the column electrode switch or the row electrode switch corresponding to the scanning electrode in the column electrode and the row electrode is switched. And a switch control circuit for turning on the column electrode switch and the row electrode switch corresponding to the non-scanning electrodes in the column electrode and the row electrode. Integrated type tablet device. 4. A display electrode in an active matrix type liquid crystal display device and a coordinate detection electrode in an electrostatic induction type tablet device are constituted by a common column electrode and row electrode, and the liquid crystal display device and the tablet device are combined. In the integrated display-integrated tablet device, during the coordinate detection period, an X coordinate detection signal and a Y coordinate detection signal having a pulse of a predetermined voltage value are generated and sequentially applied to the column electrodes and the row electrodes with a phase shift. 3. A first structural unit comprising the pulse generation circuit in the display-integrated type tablet device according to claim 1, further comprising a coordinate detection signal generation part for scanning the column electrode and the row electrode.
The display-integrated type tablet device according to the second aspect, comprising the X-coordinate detection signal output section and the Y-coordinate detection signal output section.
And a third unit comprising the counter electrode first switch, the counter electrode second switch, the column electrode switch, the row electrode switch, and the switch control circuit in the display-integrated type tablet device according to claim 3. Of the constituent units,
A display-integrated tablet device comprising at least two constituent units.