JP2986286B2 - 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 used for a personal computer, a word processor and the like.

[0002]

2. Description of the Related Art As a means for inputting handwritten characters and figures into a computer or word processor, for example, a liquid crystal display and an electrostatic induction type tablet are stacked, and the characters and figures are statically written as if we were writing on paper with a writing instrument. 2. Description of the Related Art A tablet device integrated with a display unit capable of inputting to an electric induction type tablet has been put to practical use. However, in this display unit integrated type tablet device, since the reflectance and the transmittance are different between the portion with and without the electrodes, the electrodes can be seen in a grid pattern on the display screen, causing a deterioration in the quality of the liquid crystal display. I have.

The present inventor has recently proposed a tablet device integrated with a display as shown in FIG. 10 as a tablet which has eliminated such disadvantages (Japanese Patent Application No. Hei 3-467).
No. 51). This display-integrated tablet device serves both as a display electrode of a liquid crystal display and a coordinate detection electrode of a capacitance-type tablet device. Then, as shown in FIG. 11, a coordinate detection period for detecting designated coordinates on the tablet and a display period for displaying an image are provided during one frame period, and coordinate detection and image display are performed in a time-division manner. I have.

In FIG. 10, a liquid crystal panel 1 has common electrodes Y _{1 to} Y _n (hereinafter, an arbitrary common electrode is referred to as Y) and segment electrodes X _{1 to} X arranged orthogonally to each other.
_m (hereinafter, an arbitrary segment electrode is described as X) and a liquid crystal is interposed therebetween, and each pixel is formed in a region where each common electrode Y and the segment electrode X intersect. . That is, the liquid crystal panel 1 has pixels of n × m dots arranged in a matrix.

[0005] This display-integrated tablet device has the advantage that the grid-like electrode pattern is eliminated and is easier to see than the above-described liquid crystal display in which a capacitance type tablet is laminated. Since the electrode and the drive circuit are also used as the capacitive tablet, there is an advantage that the cost can be reduced and the size and weight can be easily reduced.

The display-integrated tablet device operates as follows. That is, the common drive circuit 2 for driving the common electrode Y and the segment drive circuit 3 for driving the segment electrode X are provided with a switching circuit 4
Are connected to the display control circuit 5 and the detection control circuit 6 via the. The switching circuit 4 is controlled by the control circuit 7 to output an output signal from the display control circuit 5 to the common drive circuit 2 and the segment drive circuit 3 during the display period, and to output the detection control circuit 6 during the coordinate detection period. Are output to the common drive circuit 2 and the segment drive circuit 3. In FIG. 10, the switching circuit 4, the display control circuit 5, the detection control circuit 6, and the control circuit 7 are represented by being divided into respective blocks. However, in an actual circuit, each of the above circuits is implemented as an LSI (Large Scale Integrated Circuit), and cannot be strictly divided into blocks as described above in terms of form.

During the display period, the shift data s is output from the shift data output terminal S of the display control circuit 5, the inverted signal fr is output from the inverted signal output terminal FR, and the clock signal cp1 is output from the clock output terminal CP1. The clock signal cp2 is output from the clock output terminal CP2.
There is output, the display from the data output terminal D0~D3 data D ₀ to D ₃ is output.

The clock signal cp1 is a clock signal having a period of displaying one row of pixels as a cycle. The clock signal cp1 is output to the clock input terminal YCK of the common drive circuit 2 via the output terminal CP10 of the switching circuit 4 as the clock signal cp1o. It is input to the latch pulse input terminal XLP of the segment drive circuit 3. The shift data s, which is a pulse signal for selecting a specific common electrode Y, is supplied to the shift data input terminal DIO1 of the common drive circuit 2 as the shift data so via the output terminal SO of the switching circuit 4, and the clock signal cp1o. Input in synchronization with.

When the shift data so is input to the common drive circuit 2, the pulse position of the shift data so is shifted by the shift register in synchronization with the clock signal cp1o, and the output of the common drive circuit 2 corresponding to the shift position is output. driving pulses of common electrode drive signal is applied to the common electrode Y ₁ to Y _n from the terminal O1 to on. This common electrode drive signal is supplied from a bias power supply V supplied from the DC power supply circuit 12.
It is generated based on ₀ ~V _5.

The clock signal cp2 is a clock signal whose period is a period obtained by dividing a period for displaying pixels of one row into several parts, and is output as a clock signal cp2o via the output terminal CP2O of the switching circuit 4 to the segment driving circuit 3. Is input to the clock input terminal XCK.

The display data D _{0 to} D ₃ are supplied to a switching circuit 4.
Display data D ₀ through the output terminal D0O~D3O of o~D
Input terminal XD0-XD of segment drive circuit 3 as ₃ o
3 and sequentially taken into a register in the segment drive circuit 3 in synchronization with the clock signal cp2o. And
When all the display data corresponding to the pixels of one row is captured, the captured display data is latched at the timing of the clock signal cp1o input to the latch pulse input terminal XLP, and the segment corresponding to each display data is obtained. driving pulses of the electrode driving signal is applied from the output terminal of the segment driving circuit 3 O1 to Om to the segment electrode X ₁ to X _m. The segment drive signal is also generated based on the bias power supply V ₀ ~V ₅ supplied from the DC power supply circuit 12.

The inversion signal fr is a signal for periodically inverting the direction of application of the voltage applied to the liquid crystal during the display period to prevent the liquid crystal from being deteriorated due to electrolysis.
The inverted signal input terminal Y of the common drive circuit 2 is output as the inverted signal fro via the inverted signal output terminal FRO of the switching circuit 4.
FR and inverted signal input terminal XFR of segment drive circuit 3
Entered as

Thus, the pixel matrix of the liquid crystal panel 1 is driven in accordance with the row order by the operation of the common drive circuit 2 and the segment drive circuit 3, and an image corresponding to the display data D _{0 to} D ₃ is displayed on the liquid crystal panel 1. It is done.

On the other hand, during the coordinate detection period, the shift data sd is output from the shift data output terminal Sd of the detection control circuit 6, and the inverted signal f is output from the inverted signal output terminal FRd.
rd is output, the clock signal cp1d is output from the clock output terminal CP1d, the clock signal cp2d is output from the clock output terminal CP2d, and the data output terminals D0d to D0d are output.
Drive data D ₀ d~D ₃ d is output from the 3d.

The clock signal cp1d is a clock signal having a period of a scanning period for scanning one common electrode Y, and is output as a clock signal cp1o via the output terminal CP10 of the switching circuit 4 to the clock input terminal of the common drive circuit 2. YCK and the latch pulse input terminal XLP of the segment drive circuit 3 are input. The shift data sd, which is a pulse signal for selecting a specific common electrode Y, is supplied to the shift data input terminal DIO1 of the common drive circuit 2 as the shift data so via the output terminal SO of the switching circuit 4, and the clock signal cp1d. Input in synchronization with.

Then, as in the above-described display period, the pulse position of the shift data so is shifted by the shift register of the common drive circuit 2 in synchronization with the clock signal cp1o, and the output terminal O1 corresponding to the shift position is shifted.
To the common electrodes Y ₁ to Y _{n from} the common electrode scanning signal y.
₁ ~y _n (hereinafter referred to as y any of the common electrode scanning signal) scan pulse is sequentially applied. The common electrode scanning signal y is generated based on the bias power supply V ₀ ~V ₅ supplied from the DC power supply circuit 12. The above clock signal cp
2d is a clock signal whose cycle is a scanning period for scanning the segment electrode X.
The clock signal cp2o is input to the clock input terminal XCK of the segment drive circuit 3 via P2O.

The drive data D ₀ d to D ₃ d are supplied to the drive data D ₀ o to D ₃ via output terminals D ₀ O to D _{3 O} of the switching circuit 4.
D ₃ o as an input terminal of the segment driving circuit 3 XD0～X
The signal is input to D3, and is sequentially taken into a register in the segment drive circuit 3 in synchronization with the clock signal cp2o. Then, scanning pulses of the segment electrode scanning signals x _{1 to} x _m (hereinafter, an arbitrary segment electrode scanning signal is referred to as x) corresponding to the drive data are output from the output terminals O 1 to Om of the segment driving circuit 3 to the segment electrodes X. is output to ₁ to X _m. The segment electrode scanning signal x is also supplied to the DC power supply circuit 12.
It is generated based on the bias power supply V ₀ ~V ₅ supplied from.

FIG. 12 is a timing chart of each scanning signal in the coordinate detection period of the display-integrated tablet device. The coordinate detection period is the x coordinate detection period followed by y
In the x-coordinate detection period, the segment electrode scanning signal x, which is a pulse voltage signal, is sequentially applied to the segment electrodes X. In the y-coordinate detection period, the common electrode Y, which is a common pulse voltage signal, is applied. Electrode scanning signal y
Are sequentially applied.

By applying the pulse voltage signal, the segment electrode X or the common electrode Y and the designated coordinate detecting pen
A voltage is induced in the detection pen 8 by a stray capacitance between the detection pen 8 (hereinafter, simply referred to as a detection pen) and the tip electrode. The induced voltage generated in the detection pen 8 is amplified by the amplifier 9 and input to the x-coordinate detection circuit 10 and the y-coordinate detection circuit 11.
The x coordinate detection circuit 10 and the y coordinate detection circuit 11
Based on the output signal from the amplifier 9 and the timing signal from the control circuit 7, the time from the application of the pulse voltage signal to the time when the induced voltage reaches the maximum value is detected. Detects the x coordinate or the y coordinate of the position indicated by.

FIG. 13 is a diagram showing the liquid crystal panel 1, the common drive circuit 2 and the segment drive circuit 3 in FIG. 10 in further detail. In FIG. 13, the liquid crystal panel 1
A common substrate 1U such as glass having transparent common electrodes Y arranged on its surface and a segment substrate 1L made of glass having transparent segment electrodes X arranged on its surface are opposed to each other with an interval of several microns.

The common drive circuit 2 includes the substrates CTAB1,
The common drive circuit LSI chip (C-LSI) is formed on the CTAB2 and CTAB3, and is mounted on each of the substrates. Similarly, the segment drive circuit 3 is also composed of substrates STAB1 to STAB4 on which a segment drive LSI chip (S-LSI) is mounted.

The output terminals of the chips C-LSI and S-LSI of the respective driving LSIs are connected to the respective substrates CTAB and S-LSI.
A region S indicated by hatching in TAB is connected to the common electrode Y and the introduction terminal of the segment electrode X on the common substrate 1U or the segment substrate 1L, respectively.
In the case of FIG. 13, the display area 1 'formed by the segment electrode X and the common electrode Y is a square A
It is a BCD, and the detection area as a tablet is also limited to this range.

[0023]

In the display-integrated tablet device, characters, symbols, patterns, and the like are input to a display area 1 'on the liquid crystal panel 1 shown in FIG. However, when actually using the display-integrated tablet device, as shown in FIG. 14, a plurality of keys 14 in which various processing contents are assigned to an area 13 outside the display area 1 'of the liquid crystal panel 1 are arranged. Are arranged, and when inputting the processing content by operating the key 14, the detection pen held in the hand is once released and the desired key 14 is pressed with a fingertip to enable input of the processing content. It is necessary.

However, in this case, two means, the detection pen and the finger, must be used as input means.
Very poor operability. Therefore, it is desired that desired processing contents can be executed only by touching the detection unit on which the processing menu in the area 13 outside the display area 1 'is printed with the detection pen used for inputting characters and figures. In addition, the operability of the detection unit, which can perform input using the detection pen, can be further improved if an input using finger pressure can be performed in addition to the detection pen.

An object of the present invention is to provide a display-integrated tablet device that can easily select the processing content by using a tablet detecting pen or finger pressure.

[0026]

According to a first aspect of the present invention, there is provided a display-integrated tablet device in which a first electrode group and a second electrode group arranged in different directions intersect with each other. A display panel having pixels corresponding to
A detection pen having a tip electrode electrostatically coupled to the first electrode group and the second electrode group of the display panel, a first electrode drive circuit for driving the first electrode group, and a second electrode group; A second electrode driving circuit for driving, a display control circuit for controlling the first electrode driving circuit and the second electrode driving circuit during a display period to display an image on the display panel, and a first electrode driving circuit during a coordinate detection period. A detection control circuit for controlling a drive circuit to sequentially scan the first electrode group of the display panel while controlling the second electrode drive circuit to sequentially scan the second electrode group;
An x-coordinate detection circuit for detecting an x-coordinate on a display panel indicated by the tip of the detection pen from a generation timing of an output signal from the detection pen and a scanning timing of the first electrode group; and an output from the detection pen. In the display-integrated tablet device having a y-coordinate detection circuit for detecting a y-coordinate on a display panel indicated by the tip of the detection pen from a signal generation timing and a scanning timing of the second electrode group, the first electrode group And a plurality of electrodes which are arranged on the outer periphery of the display area formed by the second electrode group and are electrostatically coupled to the tip electrode of the detection pen, and to which processing contents are assigned, and each of the plurality of electrodes. And a power supply unit for applying a pulse voltage of a different application timing or a sine wave voltage of a different frequency to the respective electrodes. A pulse voltage or a sine wave voltage is applied, and a voltage induced in the detection pen is captured, and the detection pen tip of the plurality of electrodes detects the voltage or timing of the voltage signal from the detection pen. A plurality of electrodes arranged on the outer periphery of the display area are provided with an indication electrode detection unit for sensing the designated electrode, the first electrode drive circuit, the second electrode drive circuit, and both the drive circuits and the second electrode drive circuit. The power supply unit is provided at a location other than the installation location of the connection circuit for connecting the first electrode or the second electrode, and the pulse voltage is applied to the electrode independently of the first electrode drive circuit and the second electrode drive circuit. Alternatively, a sine wave voltage is applied.

According to a second aspect of the present invention, there is provided a display-integrated tablet device, comprising: a display panel having pixels corresponding to intersections of a first electrode group and a second electrode group arranged in different directions; A detection pen having a tip electrode electrostatically coupled to the first electrode group and the second electrode group of the display panel;
A first electrode driving circuit for driving the first electrode group, a second electrode driving circuit for driving the second electrode group, and controlling the first and second electrode driving circuits during a display period to control the first and second electrode driving circuits. A display control circuit for displaying an image on the display panel, and controlling the first electrode drive circuit during the coordinate detection period to sequentially scan the first electrode group of the display panel while controlling the second electrode drive circuit. A detection control circuit that sequentially scans the second electrode group, and an x coordinate on the display panel indicated by the tip of the detection pen is obtained from a timing of generating an output signal from the detection pen and a timing of scanning the first electrode group. An x-coordinate detection circuit for detecting, and a y-coordinate for detecting a y-coordinate on the display panel indicated by the tip of the detection pen from a timing of generating an output signal from the detection pen and a timing of scanning the second electrode group. In a display-integrated tablet device having an output circuit, the tablet is arranged on the outer periphery of a display area formed by the first electrode group and the second electrode group, is electrostatically coupled to the tip electrode of the detection pen, and performs processing. A plurality of electrodes to which contents are assigned, a power supply unit for applying a pulse voltage of a different application timing or a sine wave voltage of a different frequency to each of the plurality of electrodes, and the pulse voltage to each of the electrodes by the power supply unit Alternatively, by taking in the voltage induced in the detection pen when a sine wave voltage is applied, the detection is instructed by the tip of the detection pen among the plurality of electrodes based on the timing or frequency of generation of a voltage signal from the detection pen. A plurality of electrodes arranged on the outer periphery of the display area, wherein the first electrode driving circuit and the first electrode driving circuit are connected to the first electrode driving circuit. A connection electrode group for connecting the electrode group or a connection electrode group for connecting the second electrode drive circuit to the second electrode group, wherein the power supply unit is configured by the first electrode drive circuit or the second electrode drive circuit; It is characterized by being.

According to a third aspect of the present invention, there is provided a display-integrated tablet device according to the second aspect of the present invention, wherein a plurality of the connection electrode groups are present, and each of the connection electrode groups has a region. An auxiliary electrode having a gap in the form of a grid, stripe, or spot is provided over this area, and the tip electrode of the detection pen is electrostatically coupled to the auxiliary electrode and The connection electrodes are also electrostatically coupled through the electrode gap, and during the coordinate detection period, a pulse voltage of a different application timing or a sine wave voltage of a different frequency is applied to each of the auxiliary electrodes. An auxiliary power supply that applies independently of the first electrode drive circuit and the second electrode drive circuit;
The indication electrode detection unit is configured to output the pulse voltage or the sine wave voltage to each of the auxiliary electrodes by the auxiliary power supply unit based on a voltage induced in the detection pen. While specifying the auxiliary electrode on which the tip of the detection pen is located, based on the voltage induced on the detection pen when a scanning voltage is applied to the connection electrode group by the first electrode drive circuit or the second electrode drive circuit. A connection electrode indicated by the tip of the detection pen is detected from the connection electrode group covered by the specified auxiliary electrode.

[0029]

According to the first aspect of the present invention, locations other than the locations where the first electrode drive circuit, the second electrode drive circuit, and the connection circuit are provided in the outer peripheral portion of the display area formed by the first electrode group and the second electrode group. The electrode to which the desired processing content is assigned among the plurality of electrodes arranged in is designated by the detection pen. Then, a voltage is induced at the tip electrode of the detection pen due to a pulse voltage or a sine wave voltage applied independently from the drive circuits to the indication electrode indicated by the detection pen from the power supply unit. The induced voltage is taken into the indicator electrode detection unit.

The indicating electrode detecting unit detects the indicating electrode indicated by the tip of the detecting pen among the plurality of electrodes based on the timing or frequency of the voltage signal from the detecting pen. . Thus, the detection pen for inputting characters and symbols in the display area formed by the first electrode group and the second electrode group can be used.
One of a plurality of electrodes arranged on the outer periphery of the display area is designated, and desired processing content is selected from a processing menu. The selection of the processing content at that time is performed by simple control independent of the first electrode driving circuit and the second electrode driving circuit.

Further, in the invention according to claim 2, during the coordinate detection period, the scanning voltage is applied to the first electrode group via the connection electrode group by the first electrode driving circuit. Similarly the second
A scanning voltage is applied to the second electrode group via the connection electrode group by the electrode driving circuit. At this time, if the connection electrode to which the desired processing content is assigned is specified by the detection pen, a voltage is induced at the tip electrode of the detection pen. Thus, based on the timing of generation of the voltage signal from the detection pen, the connection electrode specified by the detection pen tip is detected by the indicating electrode detection unit, and the desired processing content is selected.

Further, in the invention according to claim 3, prior to detecting the connection electrode pointed by the detection pen among the connection electrode groups, the auxiliary power supply unit causes the area above each area of the connection electrode groups to be detected. A pulse voltage of a different timing or a sine wave voltage of a different frequency is applied to each of the auxiliary electrodes having a gap provided over this region independently of the first electrode driving circuit and the second electrode driving circuit. You. Then, based on the generation timing or frequency of the voltage signal from the detection pen, the auxiliary electrode on which the tip of the detection pen is located is specified by the indicator electrode detection unit.

Thus, the connection electrode group to which the connection electrode specified by the detection pen belongs is specified from among the plurality of connection electrode groups on the outer periphery of the display area. Thereafter, in the same manner as in the above-described invention, the connection electrode specified by the detection pen is detected from the specified connection electrode group, and desired processing content is selected.

[0034]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the illustrated embodiments. FIG. 1 is a block diagram of a tablet unit of the display-integrated tablet device according to the first embodiment, and FIG. 2 is a cross-sectional view thereof. 1 and 2, the tablet unit 21 includes a common substrate 22U and a segment substrate 22 similarly to the display-integrated tablet device shown in FIG.
The liquid crystal panel 22 made of L is arranged. Further, a common drive circuit for driving the common electrodes Y _{1 to} Y _n is provided on the substrate CTAB1.
Is formed on ～CTAB3, substrate segment drive circuit for driving the segment electrodes X ₁ ~X _m STAB1~STAB
4 is formed. The common drive circuit, segment drive circuit, switching circuit, display control circuit, detection control circuit, control circuit, x-coordinate detection circuit, and y-coordinate detection circuit are the same as those in FIG.

Auxiliary electrodes 24, 25, 26, and 27 are formed on an auxiliary electrode substrate 23 at locations where the substrates CTAB1 and STAB4 of each drive circuit are not provided outside the display area 22 ', and are connected to the power supply circuit 28, respectively. As shown in FIG. 2, the auxiliary electrodes 24 to 27 are disposed substantially on the same plane as the liquid crystal panel 22, and are covered with a panel 29 such as a plastic or the like serving as an input surface. Further, for example, a processing menu similar to the key 14 shown in FIG. 14 is printed on the lower surface of the panel 29 at a position located above each of the auxiliary electrodes 24 to 27.

An electrode circuit 28 is connected to each of the auxiliary electrodes 24-27.
Is a voltage that changes with time, such as a pulse (or a sine wave), and generates an induced voltage at the detection electrode of the detection pen 30 approaching the auxiliary electrodes 24 to 27. At this time, the application timing (or frequency) of the voltage to each of the auxiliary electrodes 24 to 27 is set to a different value in advance, and the scan timing of the common electrode Y and the segment electrode X in the display area 22 'is set to a different value. I do. In this way, by setting the timing of voltage application to each of the electrodes X, Y, and 24 to 27 differently, various processes are performed on the induced voltage induced in the detection pen, and the induced voltage caused by the voltage of any of the electrodes is changed. It can be specified whether it is an induced voltage.

That is, by instructing the processing menu printing location 31 on the panel 29 with the detection pen 30, the designated processing content is detected by the coordinate detection circuit and the CPU (central processing unit) (both not shown). And run immediately.

As described above, in the present embodiment, the auxiliary electrode substrate 2 is provided outside the display area 22 ′ of the tablet 21.
3 and a plurality of auxiliary electrodes 24 to 27 connected to the power supply circuit 28 are formed on the auxiliary electrode substrate 23. Therefore, based on the timing or frequency of voltage generation induced in the detection pen 30 by the stray capacitance between the tip electrode of the detection pen 30 and the auxiliary electrodes 24 to 27, the detection pen 3
It is possible to determine which auxiliary electrode 0 indicates. As a result, the processing content assigned to the auxiliary electrode specified by the detection pen 30 can be selected.

Therefore, according to the present embodiment, when it is desired to select the processing content during the input of the detection pen to the display area 22 'in the tablet unit 21, the detection pen 3
Without releasing the hand from 0, the processing content can be easily selected simply by touching the location of the auxiliary electrode to which the desired processing content is allocated by the detection pen 30.

In the above embodiment, the auxiliary electrodes 24-2
7 is formed on a different surface from the panel 29,
Auxiliary electrodes 24 to 27 may be formed directly on 9.

FIG. 3 is a plan view of an auxiliary electrode portion in another embodiment, and FIG. 4 is a sectional view taken along the line AA 'in FIG. In this case, the auxiliary electrode substrate 23 uses a flexible thin insulating film. The electrode 35 is the auxiliary electrode 24 to
27, and are spaced apart from the auxiliary electrodes 24 to 27 via the spacers 36, 36,. Any one of the auxiliary electrodes 24 to 27
When the auxiliary electrode substrate 23 on (for example, the auxiliary electrode 25) is pressed by a finger or the like, the auxiliary electrode substrate 23 is deformed, and the auxiliary electrode 25 comes into contact with the counter electrode 35. Therefore, the counter electrode 3
This means that the voltage from the auxiliary electrode 25 is applied to the touch detection circuit 37 connected to 5, and the auxiliary electrode 25 is depressed from the timing at which the voltage from the auxiliary electrode 25 is generated.

As described above, in this embodiment,
The content of the above processing can be selected by either the detection pen for the tablet or the finger pressure.

FIG. 5 is a block diagram of a tablet unit according to another embodiment. This embodiment uses an LSI chip (C-LSI) for a common drive circuit and an LSI chip for a segment drive circuit of the liquid crystal panel 42 as the auxiliary electrodes provided outside the display area 42 'of the liquid crystal panel 42 of the tablet unit 41. (S-LSI) uses a connection electrode connecting the common electrode Y or the segment electrode X of the liquid crystal panel 42, and there is no need to newly set an auxiliary electrode.

[0044] In the display-integrated type tablet device of the present embodiment, the coordinate detection period, scan pulse is applied sequentially from the common electrodes Y ₁ or the segment electrode X ₁ in the endmost of the liquid crystal panel 42 by the common drive circuit or the segment drive circuit Then, the position of the detection pen is detected based on the generation timing of the induced voltage induced on the tip electrode of the detection pen placed in the display area 42 'of the liquid crystal panel 42.

In the coordinate detection period, when the detection pen is placed on the connection electrode area 43 of the rectangular area on the segment drive circuit side, the connection electrode group belonging to the connection electrode area 43 and the tip electrode of the detection pen are connected. Induced voltage is induced in the detection pen by the electrostatic coupling of. Therefore, the position of the detection pen outside the display area 42 'in the direction of the arrangement of the segment electrodes X can be detected based on the generation timing of the induced voltage from the detection pen and the scanning timing of the segment electrode group. At this time, whether the detection pen is located in the display area 42 'or the connection electrode area 43 is determined as follows. That is, when an induced voltage is induced in the detection pen when scanning the common electrode group, it is determined that the induced voltage is in the display area 42 ', and when it is not induced, it is in the connection electrode area 43.

The detection value of the detection pen position outside the display area 42 'is less linear than the x coordinate detection value inside the display area 42'. However, the detection of the position of the detection pen outside the display area 42 'may be performed not by detecting the point coordinates but by detecting a large area having a size of several mm, so that there is no problem in practical use. The reason why the linearity of the position detection value in the connection electrode region 43 is low is that the pitch between the electrodes of the connection electrode group in the connection electrode region 43 is not uniform. Therefore, although the non-linearity in this case has a regularity and the correction process is possible, it is not always necessary when the present invention is limited to the present embodiment.

Similarly, when the detection pen is placed on the connection electrode area 44 on the common drive circuit side during the coordinate detection period, the common electrode Y of the detection pen outside the display area 42 'is obtained.
The position in the arrangement direction can be detected.

Therefore, if a protection panel larger than the liquid crystal panel 42 is placed on the liquid crystal panel 42 and a processing menu is printed and placed on each of the connection electrode areas 43 and 44 as shown in FIG. The processing contents can be selected by indicating the desired processing contents at 43 and 44 with the detection pen.

The above embodiment is effective in the case of a so-called one-screen system in which one display screen is constituted by one liquid crystal panel. However, in the case of a so-called two-screen system in which one display screen as shown in FIG. 6 is composed of two liquid crystal panels of an upper liquid crystal panel 45U and a lower liquid crystal panel 45L, the detection pen is connected to the upper segment driving circuit 46U. Upper connection electrode area 48U
It is difficult to determine whether the pixel is in the lower connection electrode region 48L on the side of the lower segment drive circuit 46L. This is also true for the connection electrode region 49 on the common drive circuit 47 side.

The embodiment described below uses a second embodiment as shown in FIG.
In the display-integrated tablet device of the screen type, it is easy to determine whether the position of the detection pen in the coordinate detection period is in the upper connection electrode region 48U or in the lower connection region 48L. According to the present embodiment, whether the position of the detection pen in the one-screen type display-integrated tablet device shown in FIG.
The determination as to whether or not it is within 3,44 can be performed with higher accuracy.

FIG. 7 is a diagram showing the configuration of the auxiliary electrode used in this embodiment. In FIG. 7, the auxiliary electrode 51
Is formed on the auxiliary electrode substrate 50 made of a thin insulating plate. The auxiliary electrode 51 has a grid shape, a slit shape, a spot shape, or the like. FIG. 7A shows an example in which the auxiliary electrode 51a has a grid shape, and FIG. An example is shown. Either auxiliary electrode 51a, 51
In the case of b, the scanning voltage is supplied from the auxiliary electrode terminal 52. The auxiliary electrode 51 may be formed of a thin metal plate without using a substrate. The auxiliary electrode 51 having the above-described configuration is disposed on the connection electrode regions 43 and 44 in FIG. 5 or the connection electrode regions 48U, 48L and 49 in FIG. 6, and further has a processing menu at the end as shown in FIG. A panel 54 having a printing unit 53 is placed.

For example, each of the auxiliary electrodes 51 provided in the upper connection electrode region 48U and the lower connection electrode region 48L in FIG.
Supplies the above pulse voltage or sine wave voltage. Thus, an induced voltage is generated in the detection pen 55 by electrostatic coupling with the tip electrode of the detection pen 55 (see FIG. 8) approaching the auxiliary electrode 51. At this time, the application timing or frequency of the voltage applied to each of the auxiliary electrodes 51 is set to be different in advance between the auxiliary electrode 51 in the upper connection electrode region 48U and the auxiliary electrode 51 in the lower connection electrode region 48L. Further, the voltage application timing or frequency is set to a value different from the scan pulse application timing or frequency value to the common electrode Y and the segment electrode X in the display area 45 '.

By setting the application timing or frequency of the voltage to be applied to each auxiliary electrode 51 differently in this manner, the detection pen 55 can move the upper connection electrode region 48U, based on the induced voltage induced in the detection pen 55. It is possible to specify which of the lower connection electrode region 48L and the display region 45 'is present.

Further, the auxiliary electrode 51 provided on each of the connection electrode regions 48U and 48L in the liquid crystal panel 45.
Has a lattice shape or a slit shape as described above. Therefore, the scan pulse applied to each connection electrode in the connection electrode regions 48U and 48L also acts on the detection pen 55 through the gap between the auxiliary electrodes 51, and a voltage caused by this scan pulse is induced in the detection pen 55. You. As a result, it is possible to detect which connection electrode the detection pen 55 indicates.

That is, in this embodiment, the auxiliary electrode 51 scans which of the connection electrode regions 48U and 48L the detection pen 55 is located on, and further detects the detected connection electrode region. The position of the connection electrode in the inside of which the detection pen 55 is located is detected in detail by scanning the connection electrode. Therefore, according to the present embodiment, the processing content can be selected more accurately and easily by using the auxiliary electrode 51 provided outside the display area 45 '.

In the above embodiment, the auxiliary electrode 51
Are formed on the auxiliary electrode substrate 50, but may be formed on the surface of the processing menu printing section 53 on the panel 54.

The embodiment shown in FIG. 9 is an embodiment for further improving the accuracy of the selection of the above processing contents, and the same members as those in FIG. 7 are denoted by the same reference numerals as in FIG. In this embodiment, a shield electrode 56 is provided on the auxiliary electrode substrate 50 in parallel with the auxiliary electrode 51 and above the C-LSI for the common drive circuit or the S-LSI for the segment drive circuit (see FIG. 8). Provide and ground. The shield electrode 56 prevents electrostatic coupling between the LSI for the common drive circuit or the segment drive circuit and a lead wire drawn out around the LSI and the tip electrode of the detection pen. Thus, the above LSI
Alternatively, high coordinate detection accuracy can be obtained by removing noise based on electrostatic coupling with the lead wire using the shield electrode 56.

[0058]

As is apparent from the above description, the display-integrated tablet device according to the first aspect of the present invention processes data at locations other than the first electrode drive circuit, the second electrode drive circuit, and the connection circuit on the outer periphery of the display area. A plurality of electrodes to which the contents are allocated are arranged, and a pulse voltage of a different application timing or a sine wave voltage of a different frequency is applied to each of the electrodes independently of the above-mentioned two drive circuits, and the indication electrode is detected. The unit detects the electrode specified by the tip of the detection pen based on the timing or frequency of generation of a voltage signal from the detection pen, so that the operator performs a process in the middle of pen input to the display area. If you want to do so, simply specify the electrode to which the desired processing content is assigned with the detection pen and select the desired processing from the processing menu. You can easily select the contents.

Therefore, according to the present invention, the input of characters and symbols in the display area and the selection of processing contents such as "line feed" and "conversion" can all be easily performed only with the detection pen, and the operation is extremely easy. A good display-integrated tablet device can be provided. Further, the selection of the processing content in that case can be performed by simple control independent of the two driving circuits.

According to a second aspect of the present invention, there is provided a display-integrated tablet device, wherein a plurality of electrodes for designating desired processing content are connected to a first electrode drive circuit and a first electrode electrode group. Alternatively, it is constituted by a connection electrode group that connects the second electrode drive circuit and the second electrode group, and when the scanning voltage is applied to the first electrode or the second electrode by each of the drive circuits, the connection electrode and the detection pen are connected. Since the connection electrode designated by the detection pen tip is detected based on the voltage induced on the detection pen by the electrostatic coupling with the tip electrode, the processing selection electrode and the voltage applied to this electrode are detected. It is not necessary to newly provide a power supply unit for applying the voltage.

Therefore, according to the present invention, it is possible to provide an inexpensive display-integrated tablet device in which desired processing contents can be easily selected by the detection pen.

According to a third aspect of the present invention, there is provided a display-integrated tablet device, wherein an auxiliary electrode having a gap is provided above each area of the plurality of connection electrode groups so as to cover this area, and the auxiliary power supply unit provides the auxiliary electrode. Since a pulse voltage having a different application timing or a sine wave voltage having a different frequency is applied to each of the auxiliary electrodes independently of the first / second electrode driving circuit, first, the voltage applied to the auxiliary electrode is applied. The auxiliary electrode where the detection pen is located is specified based on the voltage induced in the detection pen due to the detection pen, and then the detection is performed by the electrostatic coupling between the connection electrode and the detection pen through the gap between the specific auxiliary electrodes. The connection electrode indicated by the tip of the detection pen can be detected based on the voltage induced in the pen.

Therefore, according to the present invention, the connection electrode group to which the connection electrode designated by the detection pen belongs can be specified in advance, and even if there are a plurality of connection electrode groups to which a plurality of processing contents are assigned, high accuracy can be obtained. It is possible to reliably select the processing content instructed.

[Brief description of the drawings]

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

FIG. 2 is a cross-sectional view of the tablet unit shown in FIG.

FIG. 3 is a plan view of an auxiliary electrode unit in a display-integrated tablet device different from FIG. 1;

FIG. 4 is a cross-sectional view of the auxiliary electrode unit shown in FIG.

FIG. 5 is a block diagram of a tablet unit in a display-integrated tablet device different from FIGS. 1 and 3;

FIG. 6 is an explanatory diagram of a display-integrated tablet device using a two-screen system.

FIG. 7 is a diagram showing auxiliary electrodes in a display-integrated tablet device different from FIGS. 1, 3, and 5;

8 is a cross-sectional view of a tablet unit having the auxiliary electrode shown in FIG.

FIG. 9 is an explanatory diagram of a case where a shield electrode is used in combination with the auxiliary electrode shown in FIG. 7;

FIG. 10 is a block diagram of a display-integrated tablet device.

11 is a diagram showing an example of a display period and a coordinate detection period in the display-integrated tablet device shown in FIG.

12 is a timing chart of a segment electrode scanning signal and a common electrode scanning signal in the display-integrated tablet device shown in FIG.

FIG. 13 is a detailed view of the liquid crystal panel, the segment drive circuit, and the common drive in FIG.

FIG. 14 is an external view of a display-integrated tablet device.

[Explanation of symbols]

21, 41: tablet unit, 22, 42: liquid crystal panel, 24 to 27: auxiliary electrode, 28: power supply circuit, 30, 55: detection pen, 31, 53: processing menu print location, 35: counter electrode, 36: spacer , 37 ... touch detection circuit, 43, 44, 49 ...
Connection electrode area, 48U: upper connection electrode area, 48L: lower connection electrode area, 50: auxiliary electrode substrate, 51a, 51b: auxiliary electrode, 56: shield electrode, C-LSI: LSI chip for common drive circuit, S- LSI: LSI chip for a segment drive circuit.

Claims (3)

(57) [Claims] 1. A display panel having a pixel corresponding to a location where a first electrode group and a second electrode group arranged in different directions intersect, and a first electrode group and a second electrode group of the display panel, A detection pen having an electrically coupled tip electrode;
A first electrode driving circuit that drives the first electrode group, a second electrode driving circuit that drives the second electrode group, and controlling the first electrode driving circuit and the second electrode driving circuit during a display period to control the first electrode driving circuit. A display control circuit for displaying an image on the display panel, and controlling the first electrode drive circuit during a coordinate detection period to sequentially scan the first electrode group of the display panel while controlling the second electrode drive circuit. A detection control circuit for sequentially scanning the second electrode group; and an x coordinate on the display panel indicated by the tip of the detection pen, based on a generation timing of an output signal from the detection pen and a scanning timing of the first electrode group. An x-coordinate detection circuit for detecting, a y-coordinate on the display panel indicated by the tip of the detection pen is detected from a generation timing of an output signal from the detection pen and a scanning timing of the second electrode group. A display-integrated tablet device having a coordinate detection circuit, wherein the display-integrated tablet device is arranged on the outer periphery of a display area formed by the first electrode group and the second electrode group, and is electrostatically coupled to a tip electrode of the detection pen. A plurality of electrodes to which processing contents are assigned; a power supply unit for applying a pulse voltage of a different application timing or a sine wave voltage of a different frequency to each of the plurality of electrodes; and the pulse for each of the electrodes by the power supply unit A voltage induced in the detection pen when a voltage or a sine wave voltage is applied is taken in, and is indicated by the tip of the detection pen among the plurality of electrodes based on the timing or frequency of generation of a voltage signal from the detection pen. A plurality of electrodes arranged on the outer periphery of the display area, the plurality of electrodes being arranged on the first electrode. A driving circuit, a second electrode driving circuit, and a connection circuit for connecting both driving circuits to the first electrode or the second electrode. And a tablet device integrated with a display, wherein the pulse voltage or the sine wave voltage is applied to the electrode independently of the second electrode drive circuit. 2. A display panel having pixels corresponding to intersections of a first electrode group and a second electrode group arranged in different directions, and a first electrode group and a second electrode group of the display panel, and A detection pen having an electrically coupled tip electrode;
A first electrode driving circuit that drives the first electrode group, a second electrode driving circuit that drives the second electrode group, and controlling the first electrode driving circuit and the second electrode driving circuit during a display period to control the first electrode driving circuit. A display control circuit for displaying an image on the display panel, and a first electrode drive circuit for controlling the first electrode group during the coordinate detection period to sequentially scan the first electrode group of the display panel while controlling the second electrode drive circuit. A detection control circuit for sequentially scanning the second electrode group; and an x coordinate on the display panel indicated by the tip of the detection pen, based on a generation timing of an output signal from the detection pen and a scanning timing of the first electrode group. An x-coordinate detection circuit for detecting, a y-coordinate on the display panel indicated by the tip of the detection pen is detected from a generation timing of an output signal from the detection pen and a scanning timing of the second electrode group. A display-integrated tablet device having a coordinate detection circuit, wherein the display-integrated tablet device is arranged on the outer periphery of a display area formed by the first electrode group and the second electrode group, and is electrostatically coupled to a tip electrode of the detection pen. A plurality of electrodes to which processing contents are assigned; a power supply unit for applying a pulse voltage of a different application timing or a sine wave voltage of a different frequency to each of the plurality of electrodes; and the pulse for each of the electrodes by the power supply unit A voltage induced in the detection pen when a voltage or a sine wave voltage is applied is taken in, and is indicated by the tip of the detection pen among the plurality of electrodes based on the timing or frequency of generation of a voltage signal from the detection pen. A plurality of electrodes arranged on an outer periphery of the display area, the plurality of electrodes being arranged on the first electrode; A connection electrode group for connecting a driving circuit to a first electrode group or a connection electrode group for connecting the second electrode drive circuit to a second electrode group; and the power supply section includes the first electrode drive circuit or the second electrode drive circuit. A display integrated tablet device comprising an electrode drive circuit. 3. The display-integrated tablet device according to claim 2, wherein a plurality of said connection electrode groups are present, and a grid-like, stripe-like or spot-like portion is provided above each of said connection electrode groups so as to cover said area. An auxiliary electrode having a gap having a shape is provided, and a tip electrode of the detection pen is electrostatically coupled to the auxiliary electrode and is also electrostatically coupled to the connection electrode through a gap between the auxiliary electrodes. In the coordinate detection period, a pulse voltage of a different application timing or a sine wave voltage of a different frequency is applied to each of the auxiliary electrodes independently of the first electrode drive circuit and the second electrode drive circuit. An auxiliary power supply for applying the pulse voltage or the sine wave voltage to each of the auxiliary electrodes by the auxiliary power supply. A scanning voltage is applied to the connection electrode group by the first electrode driving circuit or the second electrode driving circuit while the auxiliary electrode in which the tip of the detection pen is located is specified based on the voltage induced in the auxiliary electrode. Detecting the connection electrode indicated by the tip of the detection pen from the connection electrode group covered by the specified auxiliary electrode based on the voltage induced in the detection pen when applied. Characteristic display integrated tablet device.