JP3183773B2 - Display integrated tablet device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a display-integrated tablet device in which a display function and a tablet function used in a laptop computer, a word processor and the like are integrated.

[0002]

2. Description of the Related Art Conventionally, for example, Japanese Patent Application No. 5-104100
FIG. 6 shows a display-integrated tablet device having both a display function by an active matrix method and a tablet function, which has already been filed in the content of the above-mentioned application.

Referring to FIG. 6, this display-integrated tablet device includes an active matrix type liquid crystal display panel (hereinafter referred to as a display panel) 1, a row electrode driving circuit 2 for driving the display panel 1, and a column electrode driving IC. A column electrode driving circuit 3 which receives a display data signal and a synchronization signal from the outside, and supplies a display control signal to the row electrode driving circuit 2 and the column electrode driving circuit 3; A detection control circuit 5 for supplying a detection control signal to the circuit 3; a coordinate detection circuit 7 for receiving a signal from the electronic pen 6 to detect the coordinates of the tip of the electronic pen 6 on the display panel 1; And a control circuit 9 that controls the switching circuit 8 and the coordinate detection circuit 7 to execute the image display operation and the coordinate detection operation. That.

[0004] The display panel 1 comprises a transparent TFT substrate 1.
0, a plurality of row electrodes G1, G arranged in parallel on the inner surface of
, G480 (hereinafter, an arbitrary row electrode is described as G), and a plurality of column electrodes S1, S2, S3,. S64
0 (hereinafter, an arbitrary column electrode is described as S). Further, a thin film transistor (hereinafter, referred to as a TFT) 11 is disposed at the intersection of each row electrode G and each column electrode S. It is connected. The pixel electrode 1 is connected to the drain electrode of each TFT 11.
2 are connected to each other. Each picture element electrode 12 is arranged in a matrix in a region surrounded by each row electrode G and each column electrode S.

[0005] A counter substrate 13 is disposed on the back side of the TFT substrate 10 so as to face the TFT substrate 10, and a counter electrode 14 having substantially the same area as the TFT substrate 10 is interposed on the inner surface of the counter substrate 13. To form a picture element matrix.

The power supply circuit 1 is connected to the counter electrode 14.
6 and the counter electrode drive circuit 15 supply a bias voltage.

The row electrode drive circuit 2 sequentially applies scanning pulses of row electrode scanning signals g 1 to g 480 (hereinafter, an arbitrary row electrode scanning signal is referred to as g) to each row electrode G on the display panel 1. The row electrode G is scanned. Further, the column electrode drive circuit 3 in synchronization with the scanning of the row electrodes G, the column electrode driving signals s ₁ 1 to s ₁ 640 having a voltage level corresponding to the picture elements of a display grayscale of the row electrode G ( hereinafter, applying the arbitrary column electrode driving signals to as s ₁₎ to the column electrode S. Further, independently of the scanning of the row electrodes G, the column electrode scanning signal s ₂ 1 to s ₂ 640 (hereinafter, an arbitrary column electrode scanning signal s ₂
) Is sequentially applied to each column electrode S to scan the column electrode S.

Here, the scanning pulse generated by the row electrode driving circuit 2 and the driving pulse and the scanning pulse generated by the column electrode driving circuit 3 are generated by a bias voltage from the power supply circuit 16.

The electronic pen 6 has, at its tip, a detection electrode (not shown) having a high input impedance, which is coupled to the row electrode G and the column electrode S on the display panel 1 by a stray capacitance. G scanning pulse or column electrode S
An induced voltage is induced in the detection electrode due to the scanning pulse applied to the detection electrode. The coordinate detection circuit 7 detects the generation timing of the induced voltage generated on the detection electrode of the electronic pen 6 based on the coordinate detection timing signal from the control circuit 9 and detects the tip coordinates of the electronic pen 6.

When the coordinates of the tip of the electronic pen 6 are detected by the coordinates detection circuit 7, an x-coordinate signal and a y-coordinate signal representing the coordinates of the tip are output from the coordinates detection circuit 7.
Further, based on the x-coordinate signal and the y-coordinate signal, the display data signal for displaying a point image at the tip position of the electronic pen 6 on the display panel 1 is generated by a display data signal generating means (not shown). Is input to the display control circuit 4. As a result, the switching operation of the switching circuit 8 based on the control of the control circuit 9 and the operations of the display control circuit 4, the row electrode driving circuit 2 and the column electrode driving circuit 3 cause the tip of the electronic pen 6 on the display panel 1 to move. A point image will be displayed.

In this manner, characters, symbols, pictures, and the like can be written on the display panel 1 by the electronic pen 6 as if we were writing a picture with a writing instrument. At the same time, an input character or an input signal can be recognized by a recognition unit (not shown) from the change in the x-coordinate signal and the y-coordinate signal, and a document creation or control instruction can be performed using the recognition result. Of course, it can also be used as a response unit to the icon displayed on the display panel 1.

FIG. 7 is a diagram showing the operation timing of the conventional display-integrated tablet device. As shown in FIG. 7, one cycle T _V of the vertical synchronization signal V, which is one of the synchronization signals, is divided into a display period (y-coordinate detection period) T1 of one screen and an x-coordinate detection period T2. Coordinate detection period T2
Are assigned to the vertical blanking period Tb. Further, the division of the display period (y-coordinate detection period) T1 and the x-coordinate detection period T2 is performed by the switching circuit 8 using the display control circuit 4.
Alternatively, it is performed by switching selection of the detection control circuit 5.

FIG. 8 is a timing chart of various signals in the operation of the conventional display-integrated tablet device. Hereinafter, the operation of the conventional display-integrated tablet device will be described with reference to FIG.

As shown in FIG. 8, the display control circuit 4,
The synchronization signals input to the detection control circuit 5 and the control circuit 9 include a horizontal synchronization signal H in addition to the vertical synchronization signal V. The vertical synchronization signal V has a period T corresponding to one screen display period.
Has a _V, also the horizontal synchronizing signal H has a period T _H corresponding to one horizontal screen display period. Furthermore, in this embodiment, 525 cycles of the horizontal synchronization signal H correspond to one cycle of the vertical synchronization signal V. That is, 1T _V =
It is a 525T _H.

One cycle T _V (= 52) of the vertical synchronizing signal V
5T _H ), 480 T _H is a display period (y-coordinate detection period) T 1, and the remaining 45 T _H is a vertical blanking period Tb (x-coordinate detection period T 2) that does not contribute to image display.
It is.

[0016] The display period (y-coordinate detection period) T1, said row electrode driving circuit 2, TF every row at a period T _H
Row electrode scanning signals g1 to g480 having a scanning panel for turning on T11 are sequentially output to the row electrodes G1 to G480. In this display-integrated tablet device, the TFT1
1. The scanning pulse for "ON" is also used as a scanning pulse for y-coordinate detection. On the other hand, the column electrode driving circuit 3
Is a TFT 1 connected to a row electrode G selected by a scanning pulse from the row electrode drive circuit 2 and in an “ON” state.
1, a column electrode drive signal s1 having a drive pulse of a level corresponding to the display density applied to the picture element electrode 12 is output.

The vertical blanking period Tb (x
The coordinate detection period T2), the column electrode driving circuit 3 sequentially output to scan the column electrodes S1~S640 the column electrode scanning signal s ₂ having a scan pulse for detecting the x coordinate.

At this time, the output of the column electrode drive signal s ₁ performed in the display period T 1 by the column electrode drive circuit 3 and the output of the column electrode scan signal s ₂ performed in the vertical blanking period Tb are respectively It is controlled by the display control circuit 4 and the detection control circuit 5.

Here, during the vertical blanking period Tb in which the column electrode drive circuit 3 outputs the column electrode scanning signal s2 to the column electrode S, the row electrode G
No signal is output to all TFT1s.
1 is in the "off" state. Therefore, during the vertical blanking period Tb, the pixels of the display panel 1 are not turned on by the scanning of the column electrodes S.

Further, since the continuously applied DC voltage to the liquid crystal liquid crystal deteriorates, one period T _V of the vertical synchronizing signal V
Each time, the polarity of the output voltage of the column electrode drive circuit 3 with respect to the output voltage of the row electrode drive circuit 2 is inverted.

[0021]

However, the above-mentioned conventional display-integrated tablet device has the following problems.

First, considering the timing chart shown in FIG. 8 in consideration of the time factor, the frequency of the vertical synchronizing signal V is normally set to 60 Hz, and therefore, the period T
_V is about 31.8 μsec (= 16.7 msec / 52)
5).

Here, it is assumed that the column electrode scanning for detecting the x coordinate is performed during one period T _H of the horizontal synchronizing signal H. Now, it is assumed that the number of pulses output from the column electrode driving circuit 3 in one column electrode scanning is a total of 800 pulses of 640 pulses in a period for actually scanning the column electrodes and 160 pulses in a horizontal blanking period. Then,
The period τ _S of the column electrode scanning signal s ₂ is about 39.8 nsec (3
1.8 μsec / 800).

In this case, since the frequency of the column electrode scanning signal is too high, it is very difficult to specify the x coordinate of the tip of the electronic pen 6 based on the dielectric voltage generated at the detection electrode of the electronic pen 6. It becomes difficult and the detection accuracy becomes low.

In order to cope with the above problem, it is conceivable to extend the period τ _S by dividing the frequency of the horizontal synchronization signal H in the vertical blanking period Tb. In that case, the maximum value of the period τ _{S of} the column electrode scanning signal s ₂ is 1.70 because the vertical blanking period Tb is 45 T _H at the maximum.
μsec (39.8 nsec × 45).

By the way, in the column electrode S, which is a load of the column electrode drive circuit 3, the resistance of the column electrode S itself, the cross capacitance between the column electrode S and the row electrode G, and other influences cause the column electrode drive circuit 3 to lose its load. At the farthest tip, the column electrode scanning signal s ₂
Transmission is delayed. Further, the delay time has a variation of 2 μsec to 5 μsec depending on the size of the display panel 1 or variation in manufacturing.

As described above, the delay in the transmission of the column electrode scanning signal s ₂ in the column electrode S causes the x coordinate detection accuracy to decrease as will be described in detail below.

FIG. 9 is a schematic configuration diagram for explaining the transmission delay of the column electrode scanning signal in the display-integrated tablet device of FIG. 6, and FIG. 10 shows that the period of the scanning pulse is "τ".
Upon application of an column electrode scanning signal s ₂ is _S "in the column electrode S, a timing chart of the potential changes that occur at each point in the display panel 1 shown in FIG.

9 and 10, each column electrode S
_n-1, S _n, S input end side of a point of the column electrode scanning signal s ₂ at n _{+ 1,} b point potential change occurring in the point c, the period of the predetermined row electrode scanning signal s ₂ tau _S It occurs with only a phase difference. Therefore, the detection accuracy of the x-coordinate of the column electrode S on the side of the column electrode drive circuit 3 in the display panel 1 can be a normal accuracy, so that there is no problem.

However, the potential change occurring at the point a 'on the tip side of the column electrode _Sn-1 is caused by the column electrode scanning signal s.
_{Due to} the transmission delay of ₂ , it occurs after a delay time τ _p from the point a. Here, assuming that the period τ _S of the column electrode scanning signal s ₂ is 1.8 μsec, which is the maximum value that can be taken as described above, and the delay time τ _p is 3 μsec, the electronic pen 6 is positioned at the point a ′. In this case, the time when the dielectric voltage is generated at the detection electrode is longer than the time when it should be generated by the delay time τ _p = 3
The time is delayed by μsec. On the other hand, the electronic pen 6
The time during which the induced voltage is generated at the detection electrode of the electronic pen 6 when it is positioned at the point is a time delayed by the period τ _S = 1.8 μsec of the column electrode scanning signal s ₂ from the case when it is positioned at the point a. , The time when the induced voltage is generated at the point c is longer than that at the point a by τ _S × 2 = 3.6 μs.
This is a time delayed by ec.

That is, when the electronic pen 6 is positioned at the point a ', the time during which the induced voltage is generated at the detection electrode of the electronic pen 6 is two-thirds of the time between the points b and c from the point b. It will be the same time as when it is located at As a result, the coordinates of the point a ′, which should be the same x-coordinate as the point a, are determined as the x-coordinates at a position ｂ of the point b between the points b and c.

Such an erroneous determination is based on the column electrode scanning signal s ₂
Occurs because the value of the period τ _S is substantially equal to the value of the delay time τ _p . Therefore, if the effect of the delay time τ _p can be removed from the time at which the dielectric voltage is generated at the detection electrode of the electronic pen 6, the correct electronic pen can be determined based on the time until the dielectric voltage is generated at the detection electrode of the electronic pen 6. 6 can be detected.

The present invention solves the above-mentioned conventional problems, and provides a display-integrated tablet device capable of accurately detecting the coordinates of the tip of the electronic pen even if the transmission of the column electrode scanning signal is delayed. The purpose is to:

[0034]

A display-integrated tablet device according to the present invention comprises a plurality of picture element electrodes arranged in a matrix on a display panel for writing an image during a display period; A plurality of connected column electrodes;
A plurality of column electrode driving units provided so as to respectively drive a plurality of these column electrodes, a position indicating member which is electrostatically coupled to an arbitrary column electrode and outputs a predetermined signal, and a display on a display panel. Outside the period, a first column electrode scanning signal is applied to each column electrode from each column electrode driving unit, and a column electrostatically coupled to the position indicating member based on a signal output from the position indicating member. A drive unit detection unit that detects a column electrode drive unit that drives an electrode, and outside the display period after the column electrode drive unit is detected by the drive unit detection unit, from each column electrode drive unit to each column electrode, The period of the second column electrode scanning signal applied to the column electrode from the column electrode driving unit detected by the driving unit detection unit is changed from the other column electrode driving unit to the column electrode. The period of the applied second column electrode scanning signal. Control means for applying in a state where the second column electrode scanning signal is longer than the period of the first column electrode scanning signal, and the second column electrode scanning signal is supplied from each column electrode driving unit by the drive control means. When applied to each, the column electrode electrostatically coupled to the position indicating member,
And a coordinate detecting means for detecting based on a signal output from the position indicating member, whereby the object is achieved.

The display-integrated tablet device according to the present invention includes a plurality of pixel electrodes arranged in a matrix on a display panel for writing an image during a display period, and a switching element connected to each of the pixel electrodes. A plurality of column electrodes and row electrodes that are connected to each other and orthogonal to each other, a plurality of these column electrodes, a plurality of column electrode driving units provided so as to respectively drive the plurality of column electrodes, and the plurality of row electrodes. A row electrode driving unit to be driven; a position indicating member that is electrostatically coupled to an arbitrary column electrode and a row electrode to output a predetermined signal; and Applying a first column electrode scanning signal,
A driving unit detecting unit that detects a column electrode driving unit that drives a column electrode electrostatically coupled to the position indicating member based on a signal output from the position indicating member; Outside the display period after the section is detected, the second column electrode scanning signal is applied to each column electrode from each column electrode drive section, and the column electrode drive section detected by the drive section detection means is applied to the column electrode. The period of the applied second column electrode scanning signal is longer than the period of the second column electrode scanning signal applied to the column electrode from another column electrode driving unit, or the first column electrode scanning is performed. A drive control unit for applying the signal in a state longer than the signal period, and when the second column electrode scanning signal is applied to each column electrode from each column electrode drive unit by the drive control unit, Place the electrostatically coupled column electrode on the position finger. Coordinate detecting means for detecting based on a signal output from the member, and for detecting the row electrode electrostatically coupled to the position indicating member based on an output signal from the position indicating member during the display period, Which achieves the above object.

Further, the display-integrated tablet device of the present invention comprises a plurality of picture element electrodes arranged in a matrix on a display panel for writing an image during a display period, and a plurality of picture element electrodes respectively connected to each picture element electrode. A plurality of column electrodes, a plurality of these column electrodes, a plurality of column electrode driving units provided to respectively drive the column electrodes, and a position indicating member that is electrostatically coupled to an arbitrary column electrode and outputs a predetermined signal. Outside the display period of the display panel, a first column electrode scanning signal is applied to each column electrode from each column electrode driving section, and the position indicating member is statically applied based on a signal output from the position indicating member. A driving unit detecting unit for detecting a column electrode driving unit for driving the electrically coupled column electrode, and detecting by the driving unit detecting unit outside a display period after the column electrode driving unit is detected by the driving unit detecting unit. Columns Only from the pole drive unit, a drive control means for sequentially applying a second column electrode scanning signal to each of the column electrodes, the from the column electrode driving unit by the drive control means 2
Are applied to the column electrodes, respectively.
Coordinate detecting means for detecting a column electrode electrostatically coupled to the position indicating member based on a signal output from the position indicating member, thereby achieving the object described above. Further, the display-integrated tablet device of the present invention is connected to a plurality of picture element electrodes arranged in a matrix on a display panel for writing an image during a display period, and each of the picture element electrodes is connected via a switching element. A plurality of column electrodes and row electrodes that are orthogonal to each other, a plurality of these column electrodes, a plurality of column electrode driving units provided to respectively drive the plurality of column electrodes, and a row for driving the plurality of row electrodes. An electrode driving unit, a position indicating member that is electrostatically coupled to an arbitrary column electrode and a row electrode and outputs a predetermined signal, and a first electrode driving unit that outputs a predetermined signal from each column electrode driving unit to each column electrode outside a display period of the display panel. Applying a column electrode scanning signal, based on a signal output from the position indicating member,
A driving unit detecting unit that detects a column electrode driving unit that drives a column electrode that is electrostatically coupled to the position indicating member, and the driving unit detecting unit detects the column electrode driving unit outside the display period after the column electrode driving unit is detected. Drive control means for sequentially applying a second column electrode scanning signal to each column electrode only from the column electrode drive section detected by the drive section detection means, and a second drive from each column electrode drive section by the drive control means. When a column electrode scanning signal is applied to each of the column electrodes, a column electrode that is electrostatically coupled to the position indicating member is detected based on a signal output from the position indicating member. And coordinate detecting means for detecting a row electrode electrostatically coupled to the position indicating member based on an output signal from the position indicating member, thereby achieving the object described above. Preferably, the plurality of column electrode driving units apply a second column electrode scanning signal to each column electrode at the same timing for each column electrode driving unit when the column electrode driving unit is detected by the driving unit detection unit. In addition, the application timing of the second column electrode scanning signal is shifted for each column electrode driving unit.

[0037]

With the above arrangement, in the display period, the row electrodes are driven by the row electrode driving means in order to write an image on the liquid crystal. At this time, based on a signal from a position indicating member such as an electronic pen that is electrostatically coupled to the row electrode, the coordinate detecting means detects the y coordinate representing the input position of the position indicating member. On the other hand, outside the display period, coordinates are read based on signals from a position indicating member electrostatically coupled to the column electrodes when the column electrodes are scanned by the column electrode scanning signals from the column electrode driving units. The x-coordinate representing the input position by the position indicating member is detected by the detecting means.

As described above, when detecting the x coordinate,
The column electrode scanning signal is output from the plurality of column electrode driving units, and the input position by the position indicating member is scanned by the column electrode scanning signal output from any of the plurality of column electrode driving units. The column electrode driving unit having the position indicating member is specified by roughly detecting whether the column electrode is a column electrode, and further, only the column electrode scanning signal sequentially applied from the specified column electrode driving unit is slowed down in frequency. Driving, the period τ _S is longer than the conventional period even if the transmission of the column electrode scanning signal in the column electrode is delayed, and the period τ _S
And the delay time τ _P are not substantially the same value, and a correct x coordinate of the tip of the position indicating member can be obtained without erroneous determination.

When detecting the x-coordinate, a column electrode driving unit such as a column electrode driving IC applies a column electrode scanning signal to all the column electrodes to which the column electrode scanning signal is applied at the same timing, and a position indicating member. Of the plurality of column electrode driving units detects a column electrode being scanned by a column electrode scanning signal applied from a plurality of column electrode driving units, and detects a column electrode driving position of a column electrode driving unit. In this case, the column electrode scanning signal is applied to all the column electrodes to which the column electrode scanning signal is applied in the unit of the column electrode driving unit at the same timing, and the column electrode scanning signal is sequentially applied to each column electrode driving unit. Is applied to the column electrodes, so that the time for specifying the column electrode driving unit having the position indicating member is shortened, and the period for outputting the column electrode scanning signal for lowering the frequency can be lengthened accordingly. More correct x coordinates can slower the frequency of the issue scanning signal is obtained.

[0040]

Embodiments of the present invention will be described below.

FIG. 1 is a block diagram showing a main part of a display-integrated tablet device according to an embodiment of the present invention. Components having the same functions as those of the components of the conventional display-integrated tablet device shown in FIG. 6 are denoted by the same reference numerals, and description thereof is omitted. Further, the display control circuit 4, the switching circuit 8, the TFT substrate 10, the TFT 1 shown in FIG.
1, the picture element electrode 12, the counter substrate 13, the counter electrode 14, the counter electrode circuit 15, and the power supply circuit 16 are not directly related to the present invention, and thus are omitted here.

In FIG. 1, an electronic pen 6 serving as a position indicating member for indicating a position by being electrostatically coupled with an arbitrary one of a plurality of column electrodes is connected to a switching circuit 21. The switching circuit 21 detects coordinates. The circuit 22 is connected to an IC detection circuit 23 as a drive unit detection unit. The IC detection circuit 23 is connected to a detection control circuit 24 as drive control means.
It is connected to a column electrode drive circuit 25 having a plurality of column electrode drive ICs as column electrode drive units. The synchronization signal is input to the detection control circuit 24 and the control circuit 26, and the output terminal of the control circuit 26 is connected to the switching circuit 21, the coordinate detection circuit 22, and the IC detection circuit 23, respectively.

The control circuit 26 receives an external synchronization signal and controls the IC detection circuit 23, the coordinate detection circuit 22 and the switching circuit 21 to control the IC detection operation and the coordinate detection operation. 21 is switched between an IC detection operation and a coordinate detection operation.

In this IC detection operation, the IC detection circuit 23 receives the signal from the electronic pen 6 and scans the column electrode on the display panel 1 where the tip of the electronic pen 6 is located. It detects which one of ic1 to ic8 is the column electrode driving IC, and sends out this detection pulse to the detection control circuit 24.

The detection control circuit 24 receives a synchronization signal from the outside and a data signal as a detection pulse from the IC detection circuit 23, and supplies a detection control signal to the column electrode drive circuit 25.

Further, the column electrode driving circuit 25
In synchronization with the scanning of the column electrodes, a column electrode driving signal _S1 having a voltage level corresponding to the display density of the picture element of each row electrode G is applied to the column electrodes S.
Is applied. Further, independently of the scanning of the row electrodes G, the column electrode scanning signals _S31 to _S3 640 (hereinafter, an arbitrary column electrode scanning signal is described as _S3 ) and _S41 to _S4 640 (hereinafter, referred to as _S3 ).
A scanning pulse of an arbitrary column electrode scanning signal is described as _S4 ) is sequentially applied to each column electrode S to scan the column electrode S.

Here, for example, the column electrode driving IC is
Assuming that R, G, and B have one output and have 80 outputs, the column electrode drive circuit 25 includes eight column electrode drive I
Ic8 as C, and ic1 of the column electrode driving IC is a column electrode S
1 to S80, ic2 of the column electrode driving IC is a column electrode S81.
, 160,..., Ic8 of the column electrode driving IC scans the column electrodes S561 to S640, respectively.

Hereinafter, the column electrode drive circuit 25 will be described as having eight column electrode drive ICs having the above-mentioned output of 80 outputs.

FIG. 2 is a diagram showing operation timings in the vertical blanking period of the display-integrated tablet device of FIG. Since the vertical blanking period is the same as the vertical blanking period Tb in the conventional display-integrated tablet device shown in FIG. 7, the same numbers are given and the description is omitted. The display period (y coordinate detection period)
Since it is not directly related to the present invention, it is omitted here.

In FIG. 2, the vertical blanking period Tb
Has an IC detection period T3 and an x coordinate detection period T4. That is, the vertical blanking period Tb is equal to the IC detection period T.
3 and an x-coordinate detection period T4.
This is implemented by selecting the switching of.

FIG. 3 shows an IC in the vertical blanking period shown in FIG.
FIG. 4 is a timing chart of various signals in the operation during the x-coordinate detection period of the vertical blanking period of FIG. 2 during the detection period. However, here, the case where ic3 of the column electrode driving IC is selected by the IC detection circuit 23 is shown.

Hereinafter, referring to FIGS. 3 and 4, FIG.
The operation of the display-integrated tablet device will be described in detail.
Note that the synchronization signal input to the detection control circuit 24 and the control circuit 26 is the same as the horizontal synchronization signal H in the conventional display-integrated tablet device shown in FIG. I do.

[0053] With this configuration, the vertical blanking period Tb of this embodiment is 45T _H, column electrode driving IC 8
Because it is individual, 8T _H is an IC detection period T3, 37
_TH is the x-coordinate detection period T4. At this time, during the vertical blanking period Tb, the column electrode drive circuit 25 columns the column electrode scanning signal s ₃ having the scanning pulse for detecting the IC and the column electrode scanning signal s ₄ having the scanning pulse for detecting the x coordinate. Scanning is performed by sequentially outputting the signals to the electrodes S1 to S640. At that time,
The vertical blanking period Tb by the column electrode driving circuit 25
The column electrode scanning signal s ₃ and the output of the column electrode scanning signal s ₄ are controlled by the detection control circuit 23 and the control circuit 26.

[0054] In the IC detection period T3, the column electrode scanning for one column electrode driving IC detection between one period T _H of the horizontal synchronizing signal H column electrode scanning for IC detection of the horizontal synchronization signal H 1 During the period T _H, the column electrodes (8
0). Therefore, 8T _H for one column electrode scanning
Output 640 pulses from ic1 to ic8 from the column electrode drive circuit 25. Furthermore, selecting an IC by detection pulse of the electronic pen 6 is detected what number of T _H by IC detection circuit 23. As described above, the detection control circuit 23 receives a signal from the electronic pen 6 and detects a column electrode driving unit that scans a column electrode on the display panel 1 where the tip of the electronic pen 6 is located.

In the x-coordinate detection period T4, column electrode scanning for x-coordinate detection is performed for one cycle T of the horizontal synchronizing signal H.
Scanning one column electrode driving IC portion of column electrodes (80 pieces) between _H but as shown in FIG. 4, in 80 pulse by 30T _H column electrode driving IC which is detected by the IC detection period T3 The scanning is performed while the detection period is extended, and output from the column electrode drive circuit 25. That is, upon receiving a detection data signal from the IC detection circuit 23 and an external synchronization signal, the specific electrode driving IC detected by the IC detection circuit 23 among the eight electrode driving ICs is sequentially applied to each column electrode. Only the column electrode scanning signal to be driven is driven with a lower frequency (a lower frequency per unit time or a longer period). Then, the period τ _S of the column electrode scanning signal s ₃ during the x coordinate detection period is about 11.925 μsec (3
1.8 μsec × 30/80), and even if the transmission of the column electrode scanning signal s _{3 at} the column electrode S is delayed, the period τ _S is longer than in the conventional case, and the period τ _S and the delay time τ _P are substantially equal. The value does not become the same, and the correct x coordinate of the tip of the electronic pen 6 can be obtained without erroneous determination.

As described above, according to the display-integrated tablet device of this embodiment, when detecting the x coordinate, the column electrode scanning signal is output from the plurality of column electrode driving ICs by the column electrode driving circuit 25. Have been. Therefore, there is a plurality of column electrode driving ICs in which the input position by the electronic pen 6 is plural.
Of the column electrode driving ICs, the column electrode driving IC with the electronic pen 6 is specified by roughly detecting which column electrode scanning IC is output from which column electrode scanning signal. Further, since the column electrode driving circuit 25 drives only the column electrode scanning signal sequentially applied from the specified column electrode driving IC with a lower frequency, it is necessary to increase the period τ _{S of the} detection portion as compared with the related art. As a result, the correct x coordinate can be obtained, and even if the transmission of the column electrode scanning signal is delayed, the tip coordinate of the electronic pen can be accurately detected without erroneous determination.

FIG. 5 is a timing chart of various signals showing the operation of the display-integrated tablet device according to another embodiment of the present invention. The present embodiment is the same as the circuit configuration of FIG. 1, but the method of signal control is different from that of FIGS. Further, the detection control circuit 24 and the control circuit 2
The synchronization signal input to 6 is the same as the horizontal synchronization signal H in the conventional display-integrated tablet apparatus shown in FIG.

[0058] As shown in FIG. 5, a vertical blanking period Tb of this embodiment is 45T _H, at 1T _H is IC detection period T3, 44T _H is x-coordinate detection period T4. At this time, during the vertical blanking period Tb, the column electrode driving circuit 2
5 has a scanning pulse for column electrode scanning signal s ₃ to the column electrodes S1～S640 (output 80 present simultaneously) sequentially output in one column electrode drive IC unit and x-coordinate detection having a scanning pulse for detection IC column electrode scanning signal s ₄ and sequentially output to the column electrode detected by the IC detection circuit (80 pieces) scans.
At this time, the output of the column electrode scanning signal s ₃ and the output of the column electrode scanning signal s ₄ performed during the vertical blanking period Tb by the column electrode driving circuit 25 are detected by the detection control circuit 24 and the control circuit 2.
6.

[0059] In the IC detection period T3, and outputs the 8 pulses in IC detection period a column electrode scanning in one period T _H of the horizontal synchronizing signal H for the IC detection from the column electrode driving circuit 25. Further, the IC is selected by detecting the pulse number of the detection pulse of the electronic pen 6 by the IC detection circuit 23.

In the x coordinate detection period T4, the column electrode drive circuit 25 outputs the column electrode scanning signal s for x coordinate detection.
_3, and outputs 80 pulse by the column electrode driving IC is detected in 44T _H above IC detection period T3. Then, the period τ _S of the column electrode scanning signal s ₃ during the x coordinate detection period is about 17.49 μsec (31.8 μsec × 44/80)
Thus, even if the transmission of the column electrode scanning signal s _{3 at} the column electrode S is delayed, the correct x coordinate of the tip of the electronic pen 6 can be obtained.

As described above, according to the display-integrated tablet device of the present embodiment, when detecting the x coordinate, the column electrode scanning signal is output from the plurality of column electrode driving ICs by the column electrode driving circuit 25. I have. The column electrode driving I
It is assumed that C is an IC that can apply the column electrode scanning signal to all the column electrodes to which the column electrode scanning signal is applied at the same timing. Therefore, by detecting the input position of the electronic pen 6 from a plurality of column electrode driving ICs, the column electrode being scanned by a column electrode scanning signal applied from which column electrode driving IC, the electronic position is detected. The column electrode driving IC having the pen 6 is specified. At this time, the column electrode driving circuit 25 applies the column electrode scanning signal to the column electrodes in order for each column electrode driving IC in column electrode driving IC units. Drive. That is, the column electrode scanning signal is applied at the same timing to all the column electrodes to which the column electrode scanning signal is applied for each column electrode driving IC. Further, the column electrode driving circuit 25 drives only the selected column electrode driving IC. However, the column electrode driving IC sequentially applies the column electrode scanning signal to the column electrodes.
Therefore, the time for specifying a certain column electrode driving IC of the electronic pen 6 is shortened, and the period for outputting the column electrode scanning signal for lowering the frequency can be increased by that much, and the frequency of the column electrode scanning signal can be further reduced. A more accurate x coordinate is obtained.
This makes it possible to more accurately detect the tip coordinates of the electronic pen even if transmission of the column electrode scanning signal is delayed.

[0062]

As described above, according to the present invention, a column electrode driving section having a position indicating member is specified from a plurality of column electrode driving sections, and the column electrodes sequentially applied from the specified column electrode driving section. Since only the scanning signal is driven with a lower frequency, even if the transmission of the column electrode scanning signal is delayed, the period τ _{S of the} detection portion can be increased as compared with the conventional method, and the position can be indicated accurately without erroneous determination. The tip coordinates of the member can be detected.

Further, since the driving is performed so that the column electrode scanning signal is sequentially applied to the column electrodes for each column electrode driving section, the time for specifying the column electrode driving section having the position indicating member can be shortened.
The period during which the column electrode scanning signal for lowering the frequency is output is taken longer by that amount, and the period of the column electrode scanning signal output from the column electrode driving unit having the position indicating member is longer, so that a more correct x coordinate can be obtained. Therefore, even if the transmission of the column electrode scanning signal is delayed, the tip coordinates of the position indicating member can be detected with higher accuracy.

[Brief description of the drawings]

FIG. 1 is a block diagram illustrating a main part of a display-integrated tablet device according to an embodiment of the present invention.

FIG. 2 is an operation timing chart in a vertical blanking period in the display-integrated tablet device of FIG. 1;

3 is a timing chart of a column electrode scanning signal in an example of an IC detection operation in a vertical blanking period of the display-integrated tablet device in FIG.

4 is a timing chart of a column electrode scanning signal in an example of an x-coordinate detection operation in a vertical blanking period of the display-integrated tablet device in FIG. 1;

FIG. 5 is a timing chart of various signals in an operation during a vertical blanking period of the display-integrated tablet device in an embodiment different from FIGS. 3 and 4;

FIG. 6 is a block diagram of a conventional display-integrated tablet device.

7 is an operation timing chart of the display-integrated tablet device of FIG.

8 is a timing chart of various signals in the operation of the display-integrated tablet device in FIG.

9 is a schematic configuration diagram for explaining a transmission delay of a column electrode scanning signal in the display-integrated tablet device of FIG.

10 is a waveform diagram of a column electrode scanning signal transmitted to points a, a ', b, and c in FIG.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Display panel 2 Row electrode drive circuit 6 Electronic pen 21 Switching circuit 22 Coordinate detection circuit 23 IC detection circuit 24 Detection control circuit 25 Column electrode drive circuit 26 Control circuit

Continuation of the front page (58) Field surveyed (Int.Cl. ⁷ , DB name) G06F 3/033-3/037 G02F 1/13-1/137 G06F 3/03

Claims (5)

(57) [Claims] A plurality of pixel electrodes arranged in a matrix on a display panel for writing an image during a display period; a plurality of column electrodes connected to each of the pixel electrodes; A plurality of column electrode driving units provided so as to be driven respectively, a position indicating member which is electrostatically coupled to an arbitrary column electrode and outputs a predetermined signal, and A column for applying a first column electrode scanning signal to each column electrode from a column electrode driving unit and for driving a column electrode electrostatically coupled to the position indicating member based on a signal output from the position indicating member A driving unit detecting unit that detects an electrode driving unit; and a second column electrode from each column electrode driving unit to each column electrode outside a display period after the column electrode driving unit is detected by the driving unit detecting unit. The scanning signal is supplied to the driving unit detecting means. The period of the second column electrode scanning signal applied to the column electrode from the column electrode driver detected by the above is longer than the period of the second column electrode scanning signal applied to the column electrode from the other column electrode driver. A drive control means for applying the voltage in a long state or in a state longer than the period of the first column electrode scanning signal; and the drive control means applies a second column electrode scanning signal from each column electrode driving section to the column electrode. A coordinate detecting means for detecting a column electrode electrostatically coupled to the position indicating member based on a signal output from the position indicating member when the voltage is applied, respectively; 2. A plurality of picture element electrodes arranged in a matrix on a display panel for writing an image during a display period, and a plurality of picture element electrodes connected to each picture element electrode via a switching element and orthogonal to each other. A plurality of column electrodes, a plurality of column electrodes provided to drive each of the plurality of column electrodes, and a plurality of row electrode driving units each of which drives the plurality of row electrodes. A position indicating member that is electrostatically coupled to the column electrode and the row electrode and outputs a predetermined signal; and applying a first column electrode scanning signal to each column electrode from each column electrode driving unit outside the display period of the display panel. A driving unit detecting unit that detects a column electrode driving unit that drives a column electrode electrostatically coupled to the position indicating member based on a signal output from the position indicating member; Outside the display period after the column electrode drive section is detected, a second column electrode scan signal is applied to each column electrode from each column electrode drive section by the column electrode drive section detected by the drive section detection means. The period of the second column electrode scanning signal applied to the column electrode is longer than the period of the second column electrode scanning signal applied to the column electrode from another column electrode driver, or A drive control unit for applying the voltage in a state longer than the cycle of the column electrode scanning signal; and the position control is performed when a second column electrode scanning signal is applied to the column electrode from each column electrode driving unit by the drive control unit. The column electrode that is electrostatically coupled to the pointing member is detected based on a signal output from the position pointing member, and the display period is based on a signal output from the position pointing member. Coordinate detection to detect electrostatically coupled row electrodes And a display unit. 3. A plurality of picture element electrodes arranged in a matrix on a display panel for writing an image during a display period, a plurality of column electrodes connected to each picture element electrode, and A plurality of column electrode driving units provided so as to be driven respectively, a position indicating member which is electrostatically coupled to an arbitrary column electrode and outputs a predetermined signal, and A column for applying a first column electrode scanning signal to each column electrode from a column electrode driving unit and for driving a column electrode electrostatically coupled to the position indicating member based on a signal output from the position indicating member A driving unit detecting unit that detects an electrode driving unit, and outside the display period after the column electrode driving unit is detected by the driving unit detecting unit, only from the column electrode driving unit detected by the driving unit detecting unit, Column electrode
Drive control means for sequentially applying the column electrode scanning signals of the above, and when the drive control means applies a second column electrode scanning signal to each of the column electrodes from each column electrode drive unit, the position indicating member is And a coordinate detecting means for detecting the coupled column electrodes based on a signal output from the position indicating member. 4. A plurality of picture element electrodes arranged in a matrix on a display panel for writing an image during a display period, and a plurality of picture element electrodes connected to each picture element electrode via a switching element and orthogonal to each other. A plurality of column electrodes, a plurality of column electrodes provided to drive each of the plurality of column electrodes, and a plurality of row electrode driving units each of which drives the plurality of row electrodes. A position indicating member that is electrostatically coupled to the column electrode and the row electrode and outputs a predetermined signal; and applying a first column electrode scanning signal to each column electrode from each column electrode driving unit outside the display period of the display panel. A driving unit detecting unit that detects a column electrode driving unit that drives a column electrode electrostatically coupled to the position indicating member based on a signal output from the position indicating member; Outside the display period after the detection of the column electrode drive section, the second column electrode drive section detects only the column electrode drive section detected by the drive section detection section and applies the second
Drive control means for sequentially applying the column electrode scanning signals of the above, and when the drive control means applies a second column electrode scanning signal to each of the column electrodes from each column electrode drive unit, the position indicating member is The coupled column electrode was detected based on a signal output from the position indicating member, and was also electrostatically coupled to the position indicating member based on an output signal from the position indicating member during the display period. A display integrated tablet device comprising: a coordinate detection unit configured to detect a row electrode. 5. A method according to claim 1, wherein the plurality of column electrode driving units apply a first column electrode scanning signal to each column electrode at the same timing for each column electrode driving unit when the column electrode driving unit is detected by the driving unit detecting means. 5. The display-integrated tablet device according to claim 1 , wherein the application timing of the first column electrode scanning signal is shifted for each column electrode drive unit. 6.