KR101501422B1 - Designated position detection apparatus - Google Patents

Abstract

Thereby easily detecting the touch coordinate position with respect to the XY coordinate forming unit.
The drive signal input unit 21 and the position detection signal output unit 31 are provided for the XY coordinate forming unit 11 consisting of a plurality of hulls each intersecting with the XY coordinate forming unit 11, When a position is specified by the position specifying means 5 and 6 with respect to the XY coordinate forming section 11 of the opposite configuration from the position detecting signal output section 31 And the designated position detection mode of the XY coordinate forming section 11 is switched by the electrostatic coupling method or the electromagnetic induction method by the mode switching sections 12 and 13, The designated position detecting device can be realized.

Description

{DESIGNATED POSITION DETECTION APPARATUS}

The present invention relates to a designated position detecting device, and is suitable for application to an information processing apparatus having, for example, a tablet display surface.

The information processing apparatus having the tablet display surface is widely used as a means by which a user can easily perform processing of information corresponding to the display position by designating a specific display position on the operation display surface.

As this type of information processing apparatus, detection means for detecting a position designated on the operation display surface by the user includes a plurality of loop coils provided on the operation display surface, and a pen type position designation in which a parallel resonance circuit, (See Patent Documents 1 and 2). In this case, the position of the nearest coordinate is detected as a designated position of the user.

In addition, as the designated position detecting means, a two-dimensional coordinate of a touch point of a touch panel is detected by electrostatic capacitively coupling a plurality of X electrodes and a plurality of Y electrodes crossing the X electrodes, (See Patent Documents 3 and 4).

Japanese Unexamined Patent Application Publication No. 7-44304 Japanese Patent Application Laid-Open No. 2010-85378 Japanese Patent Application Laid-Open No. 2010-176571 Japanese Patent Application Laid-Open No. 2013-131079

In an information processing apparatus having a tablet display surface, it is preferable to make it possible to maintain the detection accuracy as high as possible with a simple configuration that enables detection of a designated position on the operation display surface of the user as much as possible. It is considered that various information can be easily input from the operation display surface by combining the information input operation by the fingertip and the information input operation by the pen type positioning member.

SUMMARY OF THE INVENTION The present invention has been made in view of the above points, and an object of the present invention is to propose a position detecting device which can easily input various information with high position detection precision.

In order to solve such a problem, in the invention of claim 1, an XY coordinate system having a configuration in which X-axis hulls X1 to XN composed of a plurality of hulls and Y-axis hulls Y1 to YM made of a plurality of hulls are crossed each other A drive signal input section 21 provided at one end side of either one of the X-axis hull X1 to XN and the Y-axis hull Y1 to YM for inputting a drive input signal, (X1 to XN) and Y-axis hulls (Y1 to YM), and when the positioning means 5 and 6 designate the XY coordinate position of the XY coordinate forming section 11 A position detection signal output section 31 for outputting a position detection signal corresponding to the designated coordinate position, a mode switching section 31 for switching the designated position detection mode of the XY coordinate forming section 11 by the electrostatic coupling method or the electromagnetic induction method, And the X-axis coordinate forming unit 11 is arranged by arranging the X-axis hull members X1 to XN Axis line plate portion 3C and the Y-axis line plate portion 3D are formed by arranging the X-axis line plate portion 3C and the Y-axis line bodies Y1 to YM, And one end of each of the plurality of hulls Y1 to YM is connected to a drive signal input part (corresponding to one end) of the axis line plate part 3D of any one of the Y1 to YM, 25 connected to the input drive pulse generating circuit 24A via a plurality of signal input switches 22Y1 to 22YM provided in the plurality of hulls Y1 to YM The first mode selection switches SY1 to SY (N-5) of the mode switching portions 12 and 13 are connected between the other end portions of the axial line plate portions 3C of the other side (X1 to XN) One end of each of the plurality of hulls X1 to XN is connected to the detection signal output circuits 34 and 36 through a plurality of signal output switches 32X1 to 32XN provided in the position detection signal output section 31, Connected ball And the second mode selection switches SX1 to SX (N-5) of the mode switching units 12 and 13 are connected between the other ends of the plurality of hulls X1 to XN, And the mode switching sections 12 and 13 are connected to the first mode selection switches SY1 to SY (N-5) and the second mode selection switch (second selection switch) when the XY coordinate forming section 11 is switched to the electrostatic coupling type The first mode selection switches SY1 to SY (N-5) and the second mode selection switches SX1 to SX (N-5) are turned off when the XY coordinate forming unit 11 is switched to the electromagnetic induction mode, The switches SX1 to SX (N-5) are turned on.

In the invention according to claims 3 to 6, an XY coordinate forming section (11) having an X-axis hull (X1 to XN) composed of a plurality of hulls and a Y-axis hull (Y1 to YM) A drive signal input section 21 provided at one end side of one of the X-axis hull X1 to XN and the Y-axis hull Y1 to YM and inputting a drive input signal, The positioning means 5 and 6 are provided on the other end side of the other X1 to XN of the X-axis hull X1 to XN and the Y-axis hull Y1 to YM, A position detection signal output section 31 for outputting a position detection signal corresponding to the designated coordinate position when the XY coordinate position of the XY coordinate position And the first mode switching section 12 provided on the other end side not in contact with the position detection signal output section 31 of the other axial hull, And the second mode switching section 21 provided on the other end side. The XY coordinate forming section 11 includes an X axis line plate section 3C in which X axis bodies X1 to XN are arranged, Axis line plate portion 3C and the Y-axis line plate portion 3D are stacked with the insulating layer material 3B sandwiched therebetween, and a Y- One end of each of the plurality of hulls Y1 to YM is connected to one of the axial line plate portions 3D via an input / output switch 22Y1 to 22YM provided on the drive signal input portion 21, Is connected to the common signal lines 23 and 25 connected to the pulse generating circuit 24A and the first mode switching section 13 is connected between the other ends of the plurality of hulls Y1 to YM And one end of the plurality of hulls X1 to XN is connected to the other axial line plate portion 3C so as to correspond to the position detection signals SY1 to SY (N-5) Is connected to the common lines (33, 35) connected to the detection signal output circuits (34, 36) through a plurality of signal output switches (32X1 to 32XN) provided in the output section (31) The second mode selection switches SX1 to SX (N-5) of the second mode switching unit 12 are connected between the other ends of the first and second mode switching units 13 and 12, , The first mode selection switches SY1 to SY (N-5) and the second mode selection switches SX1 to SX (N-5) are turned off when the XY coordinate forming section 11 is switched to the electrostatic coupling type. The first mode selection switches SY1 to SY (N-5) and the second mode selection switches SX1 to SX (N-5) are operated when the XY coordinate forming section 11 is switched to the electromagnetic induction mode, .
In addition, in the invention of Claims 3 to 6, in particular, in the invention of Claim 3, the drive signal inputting section (21) sequentially inputs two drive input signals from one end of the connected hull, The first mode switching unit 12 forms the loop coils LI1 to LIK for input signal input by connecting the other sequentially selected two hull members respectively by the two hulls, And the second mode switching section 13 connects between the other ends of the selected two hulls so as to output the position detection signal to the second hull, Loop coils LO1 to LOJ for position detection signal output are formed by a plurality of hull members and when the pen-touch type position designation unit 6 designates the XY coordinate position of the XY coordinate forming unit 11, The loop coils (LI1 to LIK) The inputted input signal is transmitted to the position detection signal output loop coils LO1 to LOJ via the position designating means 6 to output the pen touch operation detection output of the electromagnetic induction detection mode from the position detection signal output unit 31 do.
In the invention of claims 3 to 6, in particular, in the invention of claim 4, the first and second mode selection switches SY1 to SY (N-5) and SX1 to SX (N-5) The drive signal input unit 21 sequentially inputs drive input signals to one end of the connected hulls Y1 to YM in a state where the drive unit 11 is switched to the electrostatic coupling mode, When the XY coordinate position of the XY coordinate forming section 11 is specified as the position designating means 5 or 6, the position specifying means 5 and 6 are inputted from the drive signal inputting section 21 and are moved by the user's fingertips to the hulls Y1 to YM, XN as the finger touch operation detection output of the electrostatic coupling detection mode from the position detection signal output unit 31. [
In addition, in the invention of Claims 3 to 6, in particular the invention of Claim 5, the driving signal inputting portion 21, the position detecting signal outputting portion 31, the first mode switching portion 13 and the second mode switching portion 12 ) Allows the user to always operate the finger-touch inputting operation with respect to the XY-coordinate forming unit 11 by keeping the XY-coordinate forming unit 11 in the normal operation state of the electrostatic coupling detection mode.
In addition, in the invention of Claims 3-6, particularly the invention of Claim 6, the driving signal inputting portion 21, the position detecting signal outputting portion 31, the first mode switching portion 13 and the second mode switching portion 12, Is always kept in the operating state of the electromagnetic induction detection mode, so that the pen touch input operation can be always performed with respect to the XY coordinate forming unit.

In the invention according to claims 7 to 9, an XY coordinate forming section (11) having an X-axis hull form (X1 to XN) composed of a plurality of hulls and a Y-shaped hull form (Y1 to YM) A drive signal input section 21 which is provided at one end side of either one of the X-axis hull X1 to XN and the Y-axis hull Y1 to YM and receives a drive input signal; XN and the Y-axis hull members Y1 to YM and the position designating means 5 designates the XY coordinate position of the XY coordinate forming section 11, A first mode switching section 13 provided on the other end side of either one of the shaft hulls on which the drive signal input section 21 is not provided, And a second mode switching section 31 provided on the other end side where the position detection signal output section 31 of the other axial hull structure is not provided, (12).
In addition, in the invention of Claims 7 to 9, in particular, the invention of Claim 7 has the drive signal inputting portion 21, the position detection signal outputting portion 31, the first mode switching portion 13, and the second mode switching portion 12 The ratio of the period set in the operating state in which the finger touch input operation can be performed in the electrostatic coupling detection mode for each unit time required for the designated position detecting operation with respect to the XY coordinate forming section 11, The pen touch input operation by the electromagnetic induction detection mode was made large.
The position detection signal output section 31, the first mode switching section 13, and the second mode switching section 12 are provided in the present invention, The ratio of the period set in the operating state in which the pen touch input operation can be performed in the electromagnetic induction detection mode for each unit time required for the designated position detecting operation for the XY coordinate forming section 11 by electrostatic induction preferential operation, Mode for the finger touch input operation.
The drive signal input unit 21, the position detection signal output unit 31, the first mode switching unit 13, and the second mode switching unit 12 are provided in the invention of Claims 7-9, Executes a standby operation for detecting and confirming whether the user has made a designation input relating to electrostatic coupling detection or made a designation input relating to electromagnetic induction detection at the time of starting the designated position detection operation, , The electrostatic coupling priority detection operation or the electromagnetic induction priority detection operation is executed.

According to the present invention, the drive signal input unit and the position detection signal output unit are provided for the XY coordinate forming unit comprising a plurality of hulls each intersecting with each other, and the drive signal is inputted from the drive signal input unit to the XY coordinate forming unit in the unit configuration And the position detection signal output section obtains the designated position detection signal when the position is designated by the position specifying means with respect to the XY coordinate forming section in the unit configuration, The detection mode is switched between the electrostatic coupling mode and the electromagnetic induction mode so that the XY coordinate forming section is constituted by a three-layer structure of the X axis line section, the insulating layer material and the Y axis line section, One end of the plurality of hulls is connected to either one of the axial line board portions via a plurality of signal input switches, The first mode selection switch of the mode switching unit is connected to the other end and the other end of the plurality of hulls is connected to the detection signal output circuit via the plurality of signal output switches And the second mode selection switch of the mode switching unit is connected to the other end of the other stage, the driving signal inputting operation and the designated position detecting operation, or the switching operation of the electrostatic coupling method and the electromagnetic induction method, Axis line plate portion and the Y-axis line plate portion of the XY coordinate forming portion of the XY-coordinate forming portion.

BRIEF DESCRIPTION OF DRAWINGS FIG. 1 is a block diagram showing the entire configuration of an information processing apparatus to which a specified position detecting apparatus of the present invention is applied. FIG.
2 is a schematic diagram showing the detailed configuration of the tablet display panel unit 3 of Fig.
3 is an electrical connection diagram showing the detailed configuration of the designated position detecting section 4 in Fig.
Fig. 4 is an electrical connection diagram showing the configuration of the XY coordinate forming unit 11 in Fig.
5 is a schematic diagram provided for explanation of the XY coordinate system of the electromagnetic induction system formed by the XY coordinate forming unit 11 of FIG.
6 is an electric block diagram showing the detailed configuration of the synchronous detection circuit 37 in Fig.
Fig. 7 is a schematic diagram provided for explanation of the XY coordinate system of the electrostatic coupling system formed by the XY coordinate forming unit 11. Fig.
FIG. 8 is a schematic diagram showing a touch operation performed by the fingertip on the XY coordinate system of the electrostatic coupling system of FIG. 7;
Fig. 9 is a flowchart showing the designated position detection mode switching processing procedure.
10 is a signal waveform diagram provided in the explanation of the standby detection operation mode processing SP1 of FIG.
11 is a flowchart showing the detailed configuration of the fixed detection mode processing procedure SP3 in Fig.
Fig. 12 is a signal waveform diagram provided in the explanation of the electrostatic coupling fixed detection processing procedure SP12 in Fig.
Fig. 13 is a signal waveform diagram provided in the explanation of the electromagnetic induction fixing detection processing procedure SP14 in Fig.
Fig. 14 is a flowchart showing the detailed configuration of the priority detection mode processing procedure SP5 in Fig.
Fig. 15 is a signal waveform diagram provided in the explanation of the standby operation processing procedure SP21 in Fig.
Fig. 16 is a signal waveform diagram provided in the explanation from the stand-by operation to the electrostatic coupling preferential operation.
17 is a signal waveform diagram provided in the explanation of the operation from the standby operation to the electromagnetic induction priority operation.
18 is a flowchart showing the detailed configuration of the electrostatic coupling priority processing procedure SP23 in Fig.
FIG. 19 is a signal waveform diagram provided in the explanation of the electrostatic coupling priority detecting operation. FIG.
20 is a flowchart showing the detailed configuration of the electromagnetic induction preferential processing procedure SP24 of Fig.
21 is a signal waveform diagram provided in the explanation of the operation from the electrostatic coupling priority control to the electromagnetic induction priority operation.
22 is a flowchart showing the detailed configuration of the power failure priority switching check processing step SP47 in Fig.
23 is a signal waveform diagram provided in the explanation of the power failure priority switch check processing operation.

(1) Overall configuration of information processing apparatus

1, reference numeral 1 denotes an information processing apparatus according to the first embodiment as a whole, and the central processing unit 2 exchanges the information display signal S1 with the tablet display panel section 3, In the designated position detection section 4 including the tablet display panel section 3, the user places the specific position on the XY display face of the tablet display panel section 3 at the fingertip 5 on the display face of the tablet display panel section 3, (Referred to as a " finger touch operation ") or an operation of touching or bringing the position specifying tool 6 having a pen shape (this is referred to as a " pen touch operation ") The designated position detection signal S2 indicating the designated position is output from the designated position detection control unit 7 to the central processing unit 2 so that the central processing unit 2 can execute various information processing There is off.

In this embodiment, as shown in Fig. 2, the tablet display panel section 3 is provided with an information display panel section 3A on the information display panel section 3A for displaying the information display signal S1 given from the central processing unit 2, The X axis line plate portion 3C and the Y axis line plate portion 3D which are stacked with the layer material 3B sandwiched therebetween are laminated and the X axis line plate portion 3C and the Y axis line portion 3D, Is protected by a transparent protective glass plate member 3E forming an operation display surface.

In this way, the tablet display panel unit 3 allows the user to read the information display displayed on the information display panel unit 3A from the side of the transparent protective glass plate member 3E and display a specific information display material on the user's fingertip 5 or the pen And can be specified by a position designating section 6 having a shape.

(2) Coordinate position designation input means

In the case of this embodiment, the tablet display panel section 3 is constituted by the X-axis line plate section 3C, the insulating layer material 3B and the Y-axis line section 3D as the coordinate position designation inputting means, And the operation mode switching signal S3 given from the designated position detection control section 7 to the X axis mode switching section 12 and the Y axis mode switching section 13 causes the XY coordinate forming section 11 to be subjected to electromagnetic induction Type designation position detection operation mode and the electrostatic coupling type designation position detection operation mode can be switchably carried out.

As shown in Figs. 3 and 4, the X-axis line plate section 3C constituting the XY coordinate forming section 11 of the tablet display panel section 3 extends linearly in the Y-axis direction, A plurality of N (for example, 32) linear X-axis hulls X1, X2 ... arranged in parallel with each other at equal intervals in the direction of the X- ... XN.

On the other hand, the Y-axis line plate 3D includes a plurality of M (for example, twenty) linear Ys extending in a straight line in the X-axis direction and arranged at equal intervals in the Y- The axial hull members Y1, Y2 ... ... YM.

In this manner, the insulating layer material 3B is sandwiched between the X-axis hulls X1, X2 ... ... XN and Y-axis hulls Y1, Y2 ... ... And the XY coordinate forming section 11 having the laminated X axis line plate section 3C and the Y axis line section 3D intersect with each other on the display surface of the tablet display panel section 3, As XY coordinate positions on the operation display surface of the plate member 3E, the X-axis hull X1, X2 ... ... XN and Y-axis hulls Y1, Y2 ... ... YM coordinates of the coordinate point.

Y-axis hulls Y1, Y2 ... of the Y-axis line plate 3D ... One end of Y (M-3), Y (M-2), Y (M-1), and YM (FIG. 4) are provided so as to correspond to the drive signal input unit 21 The signal input switches 22Y1, 22Y2, ..., ... 22Y (M-3), 22Y (M-2), 22Y (M-1), and 22YM.

Signal input switches 22Y1, 22Y2 ... ... Among 22YM, one of the signal input switches 22Y1, 22Y3, 22Y5 ... ... The other end of the input signal line 22Y (M-5) is connected to the common signal line 23, and the common signal line 23 is connected to the input drive pulse generating circuit 24 via the mode switching switch ST1, The driving pulse signal S4 generated in the driving pulse generating circuit 24A of the driving pulse generating circuit 24 is supplied to the common signal line 23 through the amplifying circuit 24B.

Signal input switches 22Y1, 22Y2 ... ... Remaining signal input switches 22Y2, 22Y4 ... ... 22Y (M-1), 22YM are connected to the common signal line 25, and the common signal line 25 is connected to the mode Is connected to the output terminal of the amplifying circuit 24B of the input drive pulse generating circuit 24 through the changeover switch ST2 and connected to the ground via the mode changeover switch ST3.

In this way, as described later, when the mode switching switches ST1 and ST3 are turned on based on the control signal S6 given from the designated position detection control unit 7 in the electromagnetic induction type designated position detection operation mode, The drive pulse signal S4 is supplied from the signal line 23 to the Y-axis hull, and the drive pulse signal S4 is derived from the common signal line 25 and flows to the ground, so that the Y- Axis loop coil as the electromagnetic drive input means in the operation mode.

On the other hand, when the mode changeover switches ST1 and ST2 are turned on in the designated position detecting operation mode of the electrostatic coupling type, the drive pulse signal S4 sent from the input drive pulse generating circuit 24 is supplied to the common signal lines 23 and 25 Through all Y-axis hulls Y1, Y2 ... ... YM, thereby operating the Y-axis hull as the electrostatic drive input means in the designated position detection mode of the electrostatic coupling type.

The X-axis hull X1, X2 ... of the X-axis line section 3C ... One end of the signal output switches 32X1, 32X2 ... XN is connected to the signal output switches 32X1, 32X2 ... ... 32XN.

The signal output switches 32X1, 32X2 ... ... One of 32XN, one of the signal output switches 32X1, 32X3, 32X5 ... ... 32X (N-5) are connected to the common signal line 33 and the common signal line 33 is connected to the non-inverting input terminal of the electromagnetic induction signal output circuit 34 of the differential amplifier circuit configuration via the mode switching switch SR1 do.

The signal output switches 32X1, 32X2 ... ... Remaining signal output switches of 32XN 32X2, 32X4 ... ... 32X (N-1), and 32XN are connected to the common signal line 35 and the common signal line 35 is connected to the mode switching And is connected to the inverting input terminal of the electromagnetic induction signal output circuit 34 via the switch SR2 together with the ground line.

As described later, when the mode changeover switches SR1 and SR2 are turned on in the electromagnetic induction type designated position detection operation mode, the designated position detection signal flows through the common signal lines 33 and 35, And the X-axis hull is operated as an X-axis loop coil in the electromagnetic induction type designated position detection operation mode.

Thereby, the electromagnetic induction detection signal S11 obtained at the output terminal of the electromagnetic induction signal output circuit 34 is output as the designated position detection output signal S12 through the output switch SC1.

On the contrary, the common signal lines 33 and 35 are respectively connected to the input terminals of the electrostatic coupling signal output circuit 36 via the mode changeover switches SR3 and SR4, and the electrostatic coupling detection signal S13 obtained at the output terminal thereof is connected to the output switching switch SC2 And is output as the designated position detection output signal S12, thereby operating the X-axis hull as the electrostatic drive output means in the designated position detection mode of the electrostatic coupling type.

The designated position detection output signal S12 is sent to the designated position detection control section 7 as the designated position detection signal S14 of the position detection signal output section 31 after being subjected to synchronous detection processing in the synchronous detection circuit 37. [

(3) Mode switching unit 14

The mode switching unit 14 includes an X-axis mode switching unit 12 and a Y-axis mode switching unit 13 shown in Fig. 3, and the X-axis hulls X1 to XN disposed on the X- And a Y-axis hull (Y1 to YM) provided so as to intersect with the X-axis hulls X1 to XN on the Y-axis line plate 3D so that the designated position detection operation mode of the electromagnetic induction system and the designation of the electrostatic coupling system The position detection operation mode can be executed by using the XY coordinate forming unit 11 of one single plate structure.

In this embodiment, in the X-axis mode switching section 12, of the N (N = 32) X-axis hull structures arranged in the X-axis direction, two hulls X1 sandwiching four X- And X6, X3 and X8, X5 and X10 ... ... The mode selection switches SX1, SX3, SX5, ..., XX are connected between one end of X (N-5) and XN, respectively. ... SX (N-5) is installed.

In this manner, the X-axis mode switching unit 12 switches the mode selection switches SX1, SX3, SX5 ... ... When the SX (N-5) is turned on, the X-axis hulls X1 and X6, X3 and X8, X5 and X10 ... ... As shown in Fig. 5, by connecting X (N-5) and XN, output loop coils LO1, LO2 ... ... LOJ is formed.

Likewise, the Y-axis mode switching unit 13 switches the Y-axis hulls Y1 and Y6, Y3 and Y8, Y5 and Y10, ... Mode selection switches SY1, SY3, SY5 ... Y (M-5) and YM are provided between the other ends of the Y ... Y-axis hulls Y1 and Y6, Y3 and Y8, Y5 and Y10 are connected to each other by connecting these Y-axis hulls to each other when SY (M-5) ... The input loop coils LI1, LI2, LI3, ..., LM3 for long input in the X-axis direction by Y (M-5) ... LIK, the output loop coils LO1, LO2, ..., LO formed by the X axis line plate 3C, ... LOJ.

In this way, in the X-axis line plate portion 3C and the Y-axis line plate portion 3D, the mode selection switches SX1, SX3, SX5 ... of the X- ... The mode selection switches SY1, SY3, SY5, ..., Y5 are closed in the Y axis mode switching section 13, ... When the user designates the coordinate position by the pen-shaped position designating tool 6 based on the electromagnetic induction method by forming the XY coordinate system on the XY coordinate forming portion 11 by closing SY (M-5) It is possible to set the electromagnetic induction method specified position detection operation mode capable of transmitting the designated position detection signal S14 of the electromagnetic induction method from the position detection signal output section 31. [

(4) Configuration of designated position detection operation mode by electromagnetic induction method

When the user designates the designated position detection operation mode by the electromagnetic induction method, the central processing unit 2 controls the X-axis mode switching unit 12 and the Y-axis mode switching unit 12 of the mode switching unit 14 via the designated position detection control unit 7, By controlling the axial mode switching section 13, the input loop coils LI1, LI2 ... ... Loop coils for LIK and output LO1, LO2 ... ... LOJ (FIG. 5) and switches the drive signal input unit 21 and the position detection signal output unit 31 to the electromagnetic induction detection mode (FIG. 3).

The designated position detecting operation of the XY coordinate forming unit 11 at this time is referred to as " electromagnetic induction detecting operation ".

At this time, the drive signal input unit 21 turns on the mode changeover switches ST1 and ST3, and the signal input switches 22Y1 and 22Y6, 22Y3 and 22Y8 ... ... 22Y (M-5) and 22YM are successively turned on at the reference detection cycle, whereby the input loop coils LI1, LI2 ... ... The induction electromagnetic field is generated in the Y-axis line section (3D) by flowing a sequential drive input current to the LIK.

In this state, the user designates the coordinate position by performing the " pen touch operation " on the XY coordinate plane of the XY coordinate forming section 11 with the pen-shaped position designating tool 6. [

In this embodiment, the position designating tool 6 has a resonance circuit composed of the induction coil 6A and the resonance capacitor 6B, and the input loop coils LI1 and LI2 ... ... The resonance resonance current is generated in the induction coil 6A and the resonance capacitor 6B by the electromagnetic field generated by the LIK and the induced electromagnetic field generated in the induction coil 6A based on the tuned resonance current , The output loop coils LO1, LO2 ... ... Induced voltage is induced in LOJ.

At this time, the position detection signal output section 31 outputs the output loop coils LO1, LO2 ... ... Signal output switches connected to LOJ 32X1 and 32X6, 32X3 and 32X8 ... ... (N-5) and 32XN to the electromagnetic induction signal output circuit 34 via the mode changeover switches SR1 and SR2 and outputs the detection voltage based on the induced voltage to the electromagnetic induction signal output circuit 34 through the output switch SC1 to the designated position detection output signal S12 .

In this embodiment, the signal output switches 32X1 and 32X6, 32X3, and 32X8 ... of the position detection signal output unit 31, ... The ON operation period of the 32X (N-5) and 32XN is controlled by the signal input switches 22Y1 and 22Y6, 22Y3 and 22Y8 ... ... 22Y (M-5) and 22YM, respectively. Thus, the input loop coils LI1, LI2 ... ... LIK, during the respective driving periods in which the driving input pulse current flows, the output loop coils LO1, LO2 ... ... So that the position detection output can be obtained from the LOJ (including the output loop coil in which the " pen touch operation " is performed).

In the case of this embodiment, the value of the resonance capacitor 6B of the position designating aperture 6 is set such that the tip of the pen is fixed to the transparent protective glass plate member 3E (Fig. 2 The phase of the tuning resonance current generated in the position designating aperture 6, and therefore the output loop coils LO1, LO2, ... ... The phase of the electromagnetic induction detection signal S11 obtained from the electromagnetic induction signal output circuit 34 of the position detection signal output section 31 and thus the designated position detection output signal S12 is synchronously detected And the circuit 37 detects the pressure.

6, the synchronous detection circuit 37 outputs a designated position detection output signal S12 based on the electromagnetic induction detection signal S11 obtained from the electromagnetic induction signal output circuit 34 to a filter composed of a notch filter and a low-pass filter Phase reference signal component and a + 90 [deg.] Phase signal component through the circuit 41 and the programmable gain amplifying circuit 42, And the + 90 DEG phase detection circuit 43B to the integration circuits 44A and 44B, and the integrated outputs are sampled and held in the sample hold circuits 45A and 45B together with the sampling values , And the sampling hold value is converted into a digital value by the AD converters 46A and 46B.

In this manner, the 0-degree phase detection signal S21A representing the reference phase component of the designated position detection output signal S12 obtained from the coordinate position where the pen touch operation is performed from the 0-degree reference phase side AD converter 46A is obtained, The 90 DEG phase detection signal S21B of the designated position detection output signal S12 is obtained from the AD converter 46B on the phase side and sent out as part of the designated position detection signal S14.

In this embodiment, the drive pulse signal S4 of the drive pulse generating circuit 24A of the drive signal input section 21 is attenuated at the non-inverting input terminal of the electromagnetic induction signal output circuit 34 (Fig. 3) Circuit 50, whereby the signal input switches 22Y1, 22Y3 ... ... 22Y (M-5), the input loop coils LI1, LI2 ... ... Phase detection signal S21A in which the phase of the drive pulse signal S4 given to the LIK is given as reference phase information to one side of the differential input stage and thereby the synchronous detection circuit 37 becomes the reference phase, The signal S21B can be obtained easily.

(5) Configuration of position detection operation mode by electrostatic coupling method

3, the central processing unit 2 is connected to the mode selection switch 3 of the X-axis mode switching section 12 in the configuration of the X-axis line plate section 3C and the Y-axis line section 3D of the XY- SX1, SX3, SX5 ... ... SX (N-5) are turned off and the mode selection switches SY1, SY3, SY5 ... ... When the SY (M-5) is turned off, the designated position detection section 4 executes the processing of the electrostatic coupling type position detection operation mode.

The designated position detecting operation of the XY coordinate forming unit 11 at this time is referred to as " electrostatic engagement detecting operation ".

At this time, the X-axis hull X1 to XN and the Y-axis hulls Y1 to YM form an XY coordinate system orthogonal to each other on the X-axis line section 3C and the Y-axis line section 3D, As shown in Fig. 7, an electrostatic field due to the floating capacitance CZ is formed around the intersections of the X-axis hulls X1 to XN and the Y-axis hulls Y1 to YM.

7, when viewed from the plate surface of the transparent protective glass plate member 3E, the X-axis line plate portion 3C and the Y-axis line plate portion 3D, which are laminated to each other, (N-1) and X (n + 1) and two Y-axis line segments Y (m-1) and X (n + 1) adjacent to each other with the coordinates (Xn, Ym) 1) and Y (m + 1) substantially uniformly in the XY coordinate system.

8, when the user touches the coordinates (Xn, Ym) by the fingertip 5, the X-axis hull X (n And the stray capacitance values Cf between the Y-axis hulls Y (m-1), Xn and X (n + 1) and Y-axis hulls Y (m-1), Ym and Y (m + 1).

In this state, when the drive pulse voltage is input to the Y axis line Ym, the voltage output corresponding to the stray capacitance value Cf is transmitted to the X axis Xn.

Thereby, the central processing unit 2 outputs the signal input switches 22Y1, 22Y2 ... of the drive signal input unit 21 to the XY coordinate forming unit 11, ... 22YM are sequentially turned on and the signal output switches 32X1, 32X2 ... 32X2 of the position detection signal output section 31 are turned on ... When the signal output switch 32Xn is turned on in sequence (the ON operation of this order is referred to as a detection scan), the detection output is obtained at the time of the ON operation of the signal output switch 32Xn in the ON operation state of the signal input switch 22YM, , Ym) is touched by the fingertip 5 as an electrostatic engagement detection signal S13 and is finally outputted as the designated position detection signal S14 of the position detection signal output section 31 .

In this manner, when the user touches the operation input face of the transparent protective glass plate member 3E corresponding to an arbitrary position of the XY coordinate forming unit 11 with the fingertip 5 at the designated position The electrostatic field of the user's finger can be changed to the electrostatic value corresponding to the user's finger so that the electrostatic field is changed at the output terminal of the electrostatic coupling signal output circuit 36 of the position detection signal output unit 31 Whereby the designated position detection signal S14 in the position detection operation mode of the capacitive type can be obtained.

In this way, the XY coordinate forming section 11 of this embodiment has a single member structure in which the X-axis line section 3C and the Y-axis line section 3D are laminated with the insulating layer material 3B interposed therebetween The mode switching unit 14 including the X axis mode switching unit 12 and the Y axis mode switching unit 13 is switched so that the designated position detecting operation in the pen touch operation by the electromagnetic induction method can be performed It is possible to perform the designated position detecting operation in the finger touch operation by the electrostatic coupling method.

(6) Designated position detection mode switching processing procedure

(6-1) Standby detection operation mode

1, when the user designates the designated position detection mode for the central processing unit 2, the central processing unit 2 causes the designated position detection control section 7 to perform the designated position detection mode switching processing The designated position detection control section 7 outputs the designated position detection mode instruction signals S18 and S19 containing the switching operation of the position detection mode as the content to the drive signal input section 21 and the position detection signal output section 31, The standby detection operation mode process is executed in step SP1.

The operation of the central processing unit 2 by the central processing unit 2 when entering the designated position detection mode switching processing procedure RT1 is basically the same as that shown in Figs. 10 (a) to 10 (g) And executes the detection operation mode based on the operation condition indicated as the signal waveform in the standby detection operation mode.

By executing this waiting detection operation mode process, the central processing unit 2 then adjusts the operating conditions under which the designated position detection section 4 can perform the active operation for the detection mode performed by the user.

10 (a), the central processing unit 2 sets the detection mode period for executing the designated detection mode (in this case, the standby detection mode period T1 adjusted for the start of the detection operation) , One cycle of the reference clock signal CL (Fig. 10 (d)) is defined as the reference operation period t1 for performing the specified detection operation (Fig. 10 (c)) only once for this detection mode period, The switching signal S21 (FIG. 10 (e)) is switched to the electrostatic coupling switching level LI or the electromagnetic inductive switching level L2 (in accordance with the detection mode designated by the user) 10 (f) (obtained in the electrostatic coupling detection mode) or the pen touch detection output S24 (Fig. 10 (g)) (in the electromagnetic induction detection mode) in accordance with the position detection signal S14 Is obtained.

The central processing unit 2 operates the XY coordinate forming section 11 as an XY coordinate system by the electromagnetic induction method described above with reference to Fig. 5 under the conditions shown in Figs. 10A to 10F, Or the XY coordinate system by the electrostatic coupling method described above with reference to Figs. 7 and 8 (Fig. 10 (c)).

10 (a) to 10 (g) show the control in the case of the standby detection operation mode process SP1. In the standby detection mode period T1 (FIG. 10 (a) The XY coordinate forming unit 11 is operated to stand by at every reference operation period t1 (Fig. 10 (b)) for one cycle of the reference clock signal CL (Fig. 10 (d) c)].

In this waiting operation, the switching signal S21 is set to the electrostatic coupling switching level LI. However, since the XY coordinate forming unit 11 is not operated as the XY coordinate system of the electrostatic coupling system nor the XY coordinate system of the electromagnetic induction system, The output S23 (Fig. 10 (f)) and the pen touch detection output S24 (Fig. 10 (g)) do not rise to a valid signal level.

When the user designates the operation mode to the central processing unit 2 in the standby detection operation mode processing SP1 of Fig. 9, the central processing unit 2 judges which operation mode is designated in the processing step SP2.

In the case of this embodiment, the operation modes in which the central processing unit 2 can control the XY coordinate forming section 11 include the " electrostatic engagement fixed detection mode " and the "Quot; standby operation mode ", " electrostatic coupling priority detection operation mode ", " electromagnetic induction priority detection operation mode ", " no priority detection mode ", and " other detection mode "

(6-2) Fixed detection mode

When the central processing unit 2 determines that the fixed detection mode is designated in the processing step SP2 in Fig. 9, the central processing unit 2 enters the fixed detection mode processing procedure SP3. In step SP11, as shown in Fig. 11, When the positive result is obtained, the process proceeds to step SP12 to execute the electrostatic coupling fixed detection processing procedure. Thereafter, the process returns to step SP3 of the main routine of Fig. 9, The detection mode switching processing procedure RT1 ends.

12 (a), in the electrostatic coupling fixed detection operation mode period T2, the electrostatic coupling fixed detection processing procedure SP12 is configured such that the reference for one cycle of the reference clock signal CL shown in Fig. 12 (d) The electrostatic coupling detection operation is continuously performed (referred to as a fixed detection operation) every operation period t1 (Fig. 12 (b)) as shown in Fig. 12 (c).

As described above with reference to Figs. 7 and 8, the electrostatic coupling detection operation is performed on the floating capacitance CZ between the X-axis hulls X1 to XN and the Y-axis hulls Y1 to YM of the XY coordinate system of the electrostatic coupling system , The detection operation for obtaining the finger touch detection output S23 based on the electrostatic engagement detection signal S13 as shown in (f) of Fig. 12 is performed when the user's fingertip 5 touches the coordinate position (Xn, Ym) Is done.

12 (e), the central processing unit 2 sets the switching signal S21, which is set to either the electrostatic coupling switching level LI or the electromagnetic inductive switching level L2, And when the switching signal S21 is at the electrostatic coupling switching level LI, the XY coordinate forming section 11 performs the electrostatic coupling detecting operation, so that the user performs the finger touch operation by the fingertip 5 , The finger touch detection output S23 as shown in Fig. 12 (f) is formed based on the electrostatic coupling detection signal S13 sent from the electrostatic coupling signal output circuit 36. Fig.

At this time, since the XY coordinate forming unit 11 does not perform the electromagnetic induction detecting operation, the central processing unit 2 receives the electromagnetic induction detection signal S11 (see FIG. 12 (g)) from the electromagnetic induction signal output circuit 34 Is not obtained, the pen touch detection output S24 is not formed.

In this way, the central processing unit 2 executes the electrostatic coupling fixed detection processing procedure SP12, and thereby, when the user performs a finger touch operation with respect to the XY coordinate forming section 11, the finger touch detection output The finger touch detection output S23 at an effective signal level can not be obtained when the finger touch is not performed.

In this manner, the central processing unit 2 continues to form the finger touch detection output S23 until the user stops designating the electrostatic engagement fixed detection mode. When the operation is stopped, the central processing unit 2 returns to step SP4, The position detection mode switching processing procedure RT1 is terminated.

On the other hand, if a negative result is obtained in step SP11 of FIG. 11, this means that the fixed operation of the fixed detection mode performed by the user to the central processing unit 2 was the electromagnetic induction fixed detection mode, 2) proceeds to step SP14 to execute the electromagnetic induction fixed detection processing procedure.

This electromagnetic induction fixed detection processing procedure is given the same reference numerals as the corresponding parts in FIG. 12 and is referred to as a reference operation period t1 (FIG. 13 (a)) in the electromagnetic induction fixed detection operation mode period T3 (Referred to as a fixed detection operation) for every XY coordinate forming unit 11 as described above with respect to the XY coordinate system of the electromagnetic induction system of Fig. 5 The electromagnetic induction detection operation by the pen touch operation is performed (Fig. 13 (c)).

In this electromagnetic induction fixed detection operation, the switching signal S21 is switched to the electromagnetic induction switching level L2, and when there is a pen touch operation with respect to the XY coordinate forming section 11 by the user, As shown in Fig. 13 (f), the finger touch detection output S23 based on the electrostatic coupling detection signal S13 is formed while the pen touch detection output S24 based on the electromagnetic induction detection signal S11 is formed .

This electromagnetic induction fixed detection operation continues until the user stops designation of the electromagnetic induction fixed detection mode in the central processing unit 2, and when the operation by the user is stopped, the central processing unit 2 proceeds to step SP4 To the main routine of Fig. 9, and ends the designated position detection mode switching processing procedure RT1.

(6-3) standby operation processing operation

The central processing unit 2 enters the priority detection mode processing procedure SP5 shown in Fig. 14 when it is determined at step SP2 of the designated position detection mode switching processing procedure RT1 of Fig. 9 that the user has designated the priority detection mode.

At this time, the central processing unit 2 first performs the waiting operation in the waiting operation mode procedure T21 in the waiting operation mode period T4 in Fig. 15 (a) the standby operation is repeatedly performed a predetermined number of times q times, and in the electrostatic coupling operation period T21 and the electromagnetic induction operation period T22 between the standby operations 1 to q for the next q times, The detection operation and the electromagnetic induction detection operation are executed one by one in sequence.

15 (e)], the central processing unit 2 sets the switching signal S41 to the electrostatic coupling switching level LI while the XY coordinate forming section 11 is set to the XY coordinate system of the electrostatic coupling system It is not operated by an electromagnetic induction type XY coordinate system.

Here, the user designates the priority detection mode as any one of the intention that the user intends to use the XY coordinate forming section 11 in the finger touch operation mode or intends to use the pen touch operation mode .

In general, in the input operation device using the touch panel, since it is considered that the finger touch operation has many opportunities, and thus the information input operation can be performed easily, the XY coordinate forming portion 11 is formed as the XY coordinate system of the electrostatic coupling type It is expected that the detection frequency for detecting the designated position is selected so that it can be detected at any time.

On the other hand, in general, when a pen touch operation is performed using a position designation port such as an electronic pen, it is often used in a special opportunity to write a handwritten memo or a picture, and in this case, do.

Therefore, the detection frequency of the designated position when the pen touch operation is performed on the XY coordinate forming section 11 is required to be shifted to the detection operation at a timing close to the operated timing, and the position specifying phrase 6 is moved from the touch operation face It is expected that the detection operation is continuously performed as the XY coordinate system of the electromagnetic induction system for a predetermined time.

In order to appropriately cope with such a condition, in this embodiment, the detection frequency for operating the XY coordinate forming unit 11 by the electrostatic coupling method and the electromagnetic induction method is given priority, respectively (the frequency ratio is 1 to 10, and 1 to 100, respectively). When the user designates the priority detection mode, the electrostatic coupling detection operation and the electromagnetic induction detection are performed between the standby operations 1 to q in which the electrostatic coupling priority processing and the electromagnetic induction preferential processing are not performed By executing the operation once, it is confirmed which detection operation the user designates (Fig. 15 (b)).

At this time, as shown in FIG. 15E, the switching signal S41 is switched to the electromagnetic induction switching level L2 side in the electromagnetic induction operation period T22, while the electrostatic coupling operation period T21 and the q- And is held on the level LI side.

In this state, the central processing unit 2 executes the detection output confirmation processing step SP22 of Fig. 14, whereby the electromagnetic induction operation period T22 and the electrostatic coupling operation period T21 (Fig. 15A) It is confirmed whether the pen touch detection output S24 or the finger touch detection output S23 shown in Figs. 15 (g) and 15 (f) is obtained.

If a negative result is obtained at this step SP22, the central processing unit 2 returns to the above-mentioned step SP21 and repeats the standby operation processing procedure (Fig. 15 (c)).

When the finger touch detection output S23 is obtained as shown in Fig. 16F in the electrostatic coupling operation period T31 shown in Fig. 16A in the standby operation mode period T4, , The flow advances from step SP22 to step SP23 to execute the electrostatic coupling preferential processing procedure, thereby shifting to the electrostatic coupling preferential detection mode period T5 (Fig. 16 (a)).

In contrast, when the pen touch detection output S24 is obtained as shown in FIG. 17 (g) in the electromagnetic induction operation period T42 shown in FIG. 17 (a), the central processing unit 2 returns from step SP22 to step SP24 And the electromagnetic induction preferential processing procedure is executed to shift to the electromagnetic induction priority detection mode period T6 (Fig. 17 (a)).

In this way, in the state in which the XY coordinate forming section 11 is kept in the standby state, the central processing unit 2 responds to the finger touch operation or the pen touch operation with respect to the XY coordinate forming section 11 , And shifts the XY coordinate forming section 11 to the electrostatic engagement priority detection operation state or the electromagnetic induction priority detection operation state.

(6-4) Electrostatic coupling priority processing procedure

When the central processing unit 2 enters the electrostatic coupling preferential processing step SP23, as shown in Fig. 18, first, in step SP31, the XY coordinate forming section 11 is moved to the XY direction of the electrostatic coupling method described above with reference to Figs. 7 and 8 After switching to the operation mode of the coordinate system, the coordinate detection detection is executed once in step SP32 for the next electrostatic coupling priority detection mode period T5 (Fig. 19A), and then, in step SP33, It is determined whether or not a predetermined number of times q has been completed. If a negative result is obtained, the process returns to the step SP32 and the scanning operation of the steps SP32 to SP33 is repeated until the number of times of scanning is finished a predetermined number of times q Fig. 19 (c)].

When the electromagnetic induction operation period T53 shown in FIG. 19 (a) has elapsed and an affirmative result is obtained at step SP33, the central processing unit 2 switches to the electromagnetic induction detection mode at the next step SP34 (C) of Fig. 5), the coordinate detection in the electromagnetic induction detection mode is performed once at step SP35.

Subsequently, the central processing unit 2 determines whether there is a pen touch detection output at the next step SP36, and returns to the above-mentioned step SP31 when a negative result is obtained.

19C, the central processing unit 2 continues the electrostatic coupling detection operation for q times in the electrostatic coupling preferential detection mode period T5 (Fig. 19C). Then, The electromagnetic induction detection operation is performed in the electromagnetic induction operation period T53 (Fig. 19 (e)) to determine whether or not the pen touch detection output S24 (Fig. 19 (g)) is obtained.

19, the finger touch detection output S23 is output in the electromagnetic induction operation period T53 (Fig. 19 (f)). Since the pen touch detection output S24 (Fig. 19 (g) A negative result is obtained in step SP36, whereby the central processing unit 2 returns from the step SP36 to the above-mentioned step SP31, and repeats the electrostatic coupling detection processing for q times in this manner.

In this manner, the central processing unit 2 performs the electromagnetic induction coupling operation once for each q electrostatic coupling detection operation, thereby giving priority to the electrostatic power feeding detection frequency q times, and thereby, when operating the normal touch panel When it is necessary to perform the finger touch detection operation preferentially, it is possible to perform a detection operation suitable for this.

If an affirmative result is obtained at this step SP36, this means that in the electromagnetic induction operation period T53 following the electrostatic detection operation at q times for the electrostatic engagement preferential detection mode period T5 (Fig. 19 (a) g indicates that the pen touch detection output S24 is not obtained but the pen touch detection output S24 is obtained. At this time, the central processing unit 2 determines in step SP36 that the main routine 14) to determine whether or not to end the priority detection mode processing procedure SP5. When a negative result is obtained, the process proceeds to step SP24 to execute the electromagnetic induction priority processing procedure.

On the other hand, when an affirmative result is obtained at step SP25, the central processing unit 2 ends the priority detection mode processing procedure SP5, and at the step SP6 of the main routine of Fig. 9, the central processing unit 2 executes the designated position detection mode switching processing procedure RT1 Lt; / RTI >

(6-5) Electromagnetic induction preferential treatment

14, when the electromagnetic induction priority processing procedure SP24 is entered from the step SP22 or the step SP25, the central processing unit 2 first proceeds to the step SP41 in Fig. 20 and sets the fan flag FLG (also referred to as " pen FLG " Is set to be invalid.

Here, the fan flag FLG is a flag for the central processing unit 2 to determine the validity of the pen-touch operation performed by the user in the electromagnetic induction detection operation, and the central processing unit 2 controls the pen- And whether the detection output S24 (FIG. 21 (g)) is valid or not is displayed.

Therefore, when the electromagnetic induction preferential processing step SP24 is entered, the central processing unit 2 first sets the pen FLG as invalid in step SP41, whereby the central processing unit 2 executes the electromagnetic induction preferential processing procedure SP24 When entered, it is indicated by the fan flag (FLG) that there has been no pen touch operation before that.

Subsequently, the central processing unit 2 switches the state of the XY coordinate forming section 11 to operate as the XY coordinate system of the electromagnetic induction method described above with reference to Fig. 5 at step SP42, and at the next step SP43, Scan is executed.

The operation of the central processing unit 2 at this time is such that, as shown in Fig. 21 (A), in the electromagnetic induction operation period T62 of the previous electrostatic coupling preferential detection mode period T5, the switching signal S41 is shifted from the electrostatic coupling switching level L1 21 (F)], the central processing unit 2 is in the state of being in the state of being subjected to the pen touch operation when the user has switched to the electromagnetic induction switching level L2, In the induction operation period T62, the pen touch detection output S24 is formed by the processing of step SP43 (Fig. 21 (G)).

21 (G) of Fig. 21) from the position detection signal output section 31 (Fig. 21 (G)) when the pen touch operation is performed by the position designating section 6 with respect to the XY coordinate forming section 11 And is sent to the central processing unit 2.

Subsequently, the central processing unit 2 judges whether there is a pen touch detection output at step SP44.

When an affirmative result is obtained at the step SP44, the central processing unit 2 proceeds to step SP45 to set the penultiple level FLG to an effective level, and then proceeds to step SP46. On the other hand, when a negative result is obtained, After setting the penultimate level FLG in the SP45X to the invalid level, the process proceeds to step SP46.

When the pen touch detection output S24 (FIG. 21 (G)) actually generated based on the electromagnetic induction detection signal S11 is obtained, the central processing unit 2, when performing the processing of step SP46, ) To the valid level, whereas when there is no pen touch detection output S24, the penultimate level FLG is set to the invalid level.

The state of the pen touch using the penultimate FLG is thus unstable in reality as the state of the pen touch is unstable and the position designating aperture 6 is protruded from the operation display surface of the XY coordinate forming section 11 It is possible to appropriately reflect the fact that the pen-touch operation is performed by the user as valid or invalid of the penultimate (FLG).

The central processing unit 2 determines whether or not the number of times of scanning, which is the number of times of electromagnetic induction detection operation, has reached a predetermined value r in step SP46. When a negative result is obtained, the central processing unit 2 returns to step SP43 described above, Repeat the scan operation.

21, the central processing unit 2 detects the pen touch detection output S24 (also shown in FIG. 21A) for the electromagnetic induction operation period T62 in the electromagnetic induction preferential detection mode period T6 21 (G)] is obtained, the coordinate detection scan operation is repeated through the loop of steps SP46-SP43 by setting the penultiple FLG to be valid at step SP45, and the electromagnetic detection operation for a predetermined number of times r (C) of Fig.

If an affirmative result is obtained in step SP46, the central processing unit 2 proceeds to the next step SP47 to execute the power failure priority switching check processing.

The power failure priority switching check processing step SP47 is a processing for confirming the suitability when switching to the electrostatic coupling detection mode in the electromagnetic induction priority detection mode period T6. The central processing unit 2, as shown in Fig. 22 , First, in step SP61, the XY coordinate forming unit 11 is switched to the electromagnetic induction detecting mode.

Subsequently, the central processing unit 2, after executing the coordinate detection scan at step SP62, determines whether or not there is a pen touch detection output S24 at step SP63.

When an affirmative result is obtained here, the central processing unit 2 sets the penultimate flag FLG at step SP64 to be valid, and at step SP65, it is judged whether or not the number of scans is terminated s times.

On the other hand, when a negative result is obtained in step SP63, the central processing unit 2 sets the penultimate flag FLG to invalid in step SP64X.

In this manner, the central processing unit 2 resets the penultimate FLG in steps SP64 and SP64X to indicate the presence or absence of the pen touch detection output S24 actually generated based on the electromagnetic induction detection signal S11.

If a negative result is obtained in step SP65, the central processing unit 2 returns to step SP62 described above and repeats the processing of steps SP62 to SP65.

23, the central processing unit 2 performs the electromagnetic induction detection operation for s times for the electrostatic engagement preferential switching check operation period T7 (Fig. 23 (A)) (Fig. 23 C).

23 (E)), the finger touch detection output S23 (Fig. 23 (F)) is switched to the electromagnetic induction switching level L2 in the electrostatic coupling preferential switching check operation period T7 The pen touch detection output S24 (Fig. 23 (G)) may not be able to obtain the detection output during the s electromagnetic induction detection operation.

This state is a state in which the central processing unit 2 switches the detection operation of the XY coordinate forming section 11 to the electrostatic coupling detection mode at the next step SP67 and then executes the coordinate detection scan at step SP68, The presence or absence of an actual finger touch operation in the detection mode can be detected.

The detection result is confirmed by determining whether the central processing unit 2 has the finger touch detection output at step SP69 and whether the penultimate FLG is invalid.

If the central processing unit 2 obtains an affirmative result in the determination of this step SP69, this indicates that the finger touch operation is actually being performed and the pen touch detection output is invalid (therefore, the pen touch operation is not performed) At this time, the central processing unit 2 moves from the processing operation node "2" to the processing step SP49 of the electromagnetic induction preferential processing procedure SP24 (FIG. 20) to switch the XY coordinate forming section 11 to the electrostatic coupling operation mode .

This process is followed by a detection operation for confirming whether or not the user is performing the finger touch operation with respect to the XY coordinate forming section 11 by executing the coordinate detection scan at step SP50, 2) determines whether or not there is a touch detection output and the penultimate FLG is invalid at the next step SP51.

Here, when an affirmative result is obtained, this means that the user actually performs the finger touch operation in the XY coordinate forming section 11 in the electrostatic coupling operation mode. At this time, the central processing unit 2 performs the detection mode processing procedure SP5 14). ≪ / RTI >

In this processing step SP26, the central processing unit 2 judges whether or not the user designates the termination of the priority detection processing mode. When a negative result is obtained, the processing proceeds to the above-mentioned electrostatic coupling priority processing procedure SP23, The XY coordinate forming unit 11 is switched from the electromagnetic induction preferential processing operation state to the electrostatic bonding preferential processing procedure operation state.

On the other hand, when a negative result is obtained in step SP51, there is no finger touch detection output or the penulture FLG is not in the invalid level. Therefore, when the user touches the XY coordinate forming section 11 in a realistic manner At this time, the central processing unit 2 returns to the above-described processing step SP42 and shifts to the state in which the XY coordinate forming section 11 is operated in the electromagnetic induction detection mode again for the processing steps SP42 to SP46.

In this manner, the central processing unit 2 executes the processing from step SP47 to step SP51 in the power failure priority switching check processing after executing the processing in steps SP42 to SP46 of the electromagnetic induction priority processing step SP24, It is checked whether or not the operation is necessary, and if necessary, the transition to the electrostatic coupling priority processing is performed, whereas if not necessary, the electromagnetic induction preferential processing is repeated.

As a result, the user's touch operation on the XY coordinate forming unit 11 is accurately corresponded to whether it is a finger touch operation or a pen touch operation, so that the XY coordinate forming unit 11 can be formed in the XY coordinate system of the electrostatic coupling system or the electromagnetic induction system And can function as an operation input means of the XY coordinate system.

(6-6) No priority Processing procedure

When the central processing unit 2 detects that the priority no-detection mode is designated at the processing step SP2 in Fig. 9, the priority no-detection mode processing procedure is executed at the step SP7, and at the step SP8, The mode switching processing procedure RT1 ends.

At this time, the central processing unit 2 alternately performs the electrostatic coupling processing and the electromagnetic induction processing procedure for each unit processing time, and the detection frequency of each unit processing time is set to a predetermined value for each processing procedure.

The detection frequency in the unit processing time is, for example, 10 [times / second] for the electrostatic coupling processing procedure and 50 [times / second] for the electromagnetic induction processing procedure.

According to the above-described non-priority detection mode processing procedure, for example, when the user performs an input operation with the electronic pen while performing a "beck" on the display operating surface of the XY coordinate forming section 11, And the designated position detection operation result by the electromagnetic induction method can be securely obtained with a predetermined priority.

(6-7) Other detection mode Processing procedure

When the detection operation mode other than the "fixed detection" operation mode, the "priority detection" operation mode and the "no priority detection" operation mode in FIG. 9 is designated by the user, the central processing unit 2, at the processing step SP9, After the other detection mode processing procedure is executed, the designated position detection mode switching processing procedure RT1 is ended in step SP10.

In this way, the designated position detection operation result can be obtained with respect to the input operation performed by the user with respect to the XY coordinate forming section 11, with little or no effect.

(6-8) According to the above-described designated position detection mode switching processing procedure, the electrostatic engagement detecting operation and the electromagnetic induction detecting operation for the XY coordinate forming unit 11 are performed by the electrostatic coupled fixed detecting operation, Axis switching operation of the X-axis mode switching unit 12 and the Y-axis mode switching unit 13 as an operation processing operation, an electrostatic coupling preferential processing operation, and an electromagnetic induction preference processing operation, It is possible to perform the operation by the user's finger touch operation or the like by the simple structure in which the X-axis line plate portion 3C and the Y-axis line plate portion 3D are stacked with the insulating layer material 3B interposed therebetween, It is possible to realize the designated position detecting device capable of correctly operating the pen touch operation in accordance with the user's needs.

(7) Another embodiment

(7-1) In the above-described embodiment, the drive signal inputting section 21 is provided for the Y-axis line plate section 3D of the XY coordinate forming section 11 and the position The position detection signal output section 31 is provided for the Y-axis line section 3D and the detection signal output section 31 is provided for the X-axis line section 3C, Even if the input section 21 is provided, the same operational effects as those of the above-described case can be obtained.

(7-2) In the above-described embodiment, the case where the linear hull is used for the X-axis line plate portion 3C and the Y-axis line plate portion 3D has been described. However, as the hull, The same effect as in the case described above can be obtained. In addition, even if a band-shaped one in which fine wires are combined in a lattice form is used as the hull, the same effect as in the above case can be obtained.

(7-3) In the above-described embodiment, the serial resonance circuit of the induction coil 6A and the resonance capacitor 6B is used as the pen-touch type position designing tool 6. However, In other words, when the input transmission loop is supplied to the input loop coils LI1 to LIK, the input signal is inputted to the input loop coils LI1 to LIK through the position designating opening 6, The output loop coils LO1 to LOJ of the output coils LO1 to LOJ may be applied. In this way, the same operational effects as those of the above-described case can be obtained.

(7-4) In the case of the above-described embodiment, as the XY coordinate forming section 11 constituting the XY coordinate system of the electromagnetic induction system of Fig. 5, the N X-axis hulls X1 to XN and the M- The loop coils LO1 to LOJ for output and the loop coils LI1 to LIK for input are formed by two hulls sandwiching four hulls in the YM direction. However, the number of hulls sandwiched therebetween is not limited to four, Three or more, or five or more, the same effect as the above-described case can be obtained.

The present invention can be used when a touch input signal is input to an information processing apparatus having a tablet display surface.

1: Information processing device
2: central processing unit
3: Tablet display board part
3A: Information display panel section
3B: Insulation layer material
3C: X-axis line plate
3D: Y-axis line plate
3E: transparent protective glass plate member
4: Designated position detection section
5: Hand tip
6: Positioning phrase
11: XY coordinate forming unit
12: X-ray mode switching section
13: Y axis mode switching section
14: Mode switching processor
21: drive signal input section
22Y1 ~ 22YM: Signal input switch
23: common signal line
24: Input drive pulse generating circuit
25: common signal line
31: Position detection signal output section
32X1 to 32XN: Signal output switch
33: common signal line
34: electromagnetic induction signal output circuit
36: electrostatic coupling signal output circuit
37: Synchronous detection circuit
X1 to XN: X-axis hull
Y1 to YM: Y-axis hull
LI1 to LIK: Loop coil for input
LO1~LIJ: Loop coil for output

Claims (12)

An XY coordinate forming unit having a configuration in which an X-axis hull constituted by a plurality of hulls and a Y-axis hull constituted by a plurality of hulls intersect with each other,
A drive signal input unit provided at one end side of either one of the X-axis hull and the Y-axis hull, for inputting a drive input signal,
Axis hull and the Y-axis hull, and when the position designating means designates the XY coordinate position of the XY coordinate forming portion, the position detecting means outputs a position detecting signal corresponding to the designated coordinate position A position detection signal output unit,
A first mode switching unit provided on the other end side of the X-axis hull and the Y-axis hull without the drive signal input unit,
And a second mode switching section provided on the other end side where the position detection signal output section of the other of the X-axis hull and the Y-
And,
Wherein the drive signal inputting unit, the position detection signal outputting unit, the first mode switching unit, and the second mode switching unit perform the electrostatic coupling preferential detection operation so that, for each unit time required for the specified position detecting operation, Wherein the ratio of the period set in the operating state in which the finger touch input operation is performed in the electrostatic coupling detection mode is made larger for the pen touch input operation by the electromagnetic induction detection mode. The method according to claim 1,
Wherein the XY coordinate forming unit comprises:
An X-axis line section formed by arranging the X-axis hull,
A Y-axis line plate portion in which the Y-
And the X-axis line plate portion and the Y-axis line plate portion are laminated with an insulating layer material interposed therebetween. The method according to claim 1,
Wherein the drive signal input unit sequentially selects two of the one end of the connected hull and inputs the drive input signal and the first mode switching unit switches the two hulls sequentially selected by the drive signal input unit, The loop coils for inputting the input signals are formed by the two hulls, respectively,
Wherein the position detection signal output section sequentially selects two of the connected hulls to output the position detection signal and the second mode switching section outputs the two hulls selected by the position detection signal output section The loop coil for position detection signal output is formed by the two hulls by connecting the ends,
When the position designating means of the pen touch type designates the XY coordinate position of the XY coordinate forming portion, the input signal inputted from the loop coil for input signal input formed is inputted to the position detection signal outputting loop And outputs it as a pen touch operation detection output of the electromagnetic induction detection mode from the position detection signal output section. The method according to claim 1,
The first and second mode switching sections are in an operating state in which the X-axis hull and the Y-axis hull are not connected to each other, and the drive signal input section is provided on one end side of either the X- Wherein the drive input signal is sequentially input to each hull and the fingertip of the user is input from the drive signal input unit when the XY coordinate position of the XY coordinate forming unit is specified as the position designating unit, Axis hull and the Y-axis hull by a fingertip of the Y-axis hull, the drive input signal transmitted from the position detection signal output unit as the finger touch operation detection output of the electrostatic coupling detection mode And the predetermined position detection device. An XY coordinate forming unit having a configuration in which an X-axis hull constituted by a plurality of hulls and a Y-axis hull constituted by a plurality of hulls intersect with each other,
A drive signal input unit provided at one end side of either one of the X-axis hull and the Y-axis hull, for inputting a drive input signal,
Axis hull and the Y-axis hull, and when the position designating means designates the XY coordinate position of the XY coordinate forming portion, the position detecting means outputs a position detecting signal corresponding to the designated coordinate position A position detection signal output unit,
A first mode switching unit provided on the other end side of the X-axis hull and the Y-axis hull without the drive signal input unit,
And a second mode switching section provided on the other end side where the position detection signal output section of the other of the X-axis hull and the Y-
And,
The electromagnetic induction priority operation is performed by the drive signal input unit, the position detection signal output unit, the first mode switching unit, and the second mode switching unit so that electromagnetic induction is performed for the unit time required for the designated position detection operation Wherein the ratio of the period set in the operating state in which the pen touch input operation in the detection mode is set is made larger for the finger touch input operation in the electrostatic coupling detection mode. 6. The method of claim 5,
Wherein the XY coordinate forming unit comprises:
An X-axis line section formed by arranging the X-axis hull,
A Y-axis line plate portion in which the Y-
And the X-axis line plate portion and the Y-axis line plate portion are laminated with an insulating layer material interposed therebetween. 6. The method of claim 5,
Wherein the drive signal input unit sequentially selects two of the one end of the connected hull and inputs the drive input signal and the first mode switching unit switches the two hulls sequentially selected by the drive signal input unit, The loop coils for inputting the input signals are formed by the two hulls, respectively,
Wherein the position detection signal output section sequentially selects two of the connected hulls to output the position detection signal and the second mode switching section outputs the two hulls selected by the position detection signal output section The loop coil for position detection signal output is formed by the two hulls by connecting the ends,
When the position designating means of the pen touch type designates the XY coordinate position of the XY coordinate forming portion, the input signal inputted from the loop coil for input signal input formed is inputted to the position detection signal outputting loop And outputs it as a pen touch operation detection output of the electromagnetic induction detection mode from the position detection signal output section. 6. The method of claim 5,
The first and second mode switching sections are in an operating state in which the X-axis hull and the Y-axis hull are not connected to each other, and the drive signal input section is provided on one end side of either the X- Wherein the drive input signal is sequentially input to each hull and the fingertip of the user is input from the drive signal input unit when the XY coordinate position of the XY coordinate forming unit is specified as the position designating unit, Axis hull and the Y-axis hull by a fingertip of the Y-axis hull, the drive input signal transmitted from the position detection signal output unit as the finger touch operation detection output of the electrostatic coupling detection mode And the predetermined position detection device. An XY coordinate forming unit having a configuration in which an X-axis hull constituted by a plurality of hulls and a Y-axis hull constituted by a plurality of hulls intersect with each other,
A drive signal input unit provided at one end side of either one of the X-axis hull and the Y-axis hull, for inputting a drive input signal,
Axis hull and the Y-axis hull, and when the position designating means designates the XY coordinate position of the XY coordinate forming portion, the position detecting means outputs a position detecting signal corresponding to the designated coordinate position A position detection signal output unit,
A first mode switching unit provided on the other end side of the X-axis hull and the Y-axis hull without the drive signal input unit,
And a second mode switching section provided on the other end side where the position detection signal output section of the other of the X-axis hull and the Y-
And,
Wherein the drive signal input section, the position detection signal output section, the first mode switching section, and the second mode switching section determine whether the user has made a designation input relating to electrostatic coupling detection or electromagnetic induction detection And performs an electrostatic coupling priority detection operation or an electromagnetic induction priority detection operation in accordance with the confirmation result after the waiting operation. 10. The method of claim 9,
Wherein the XY coordinate forming unit comprises:
An X-axis line section formed by arranging the X-axis hull,
And a Y-axis supporting plate portion having the Y-axis hull disposed therein,
And the X-axis line plate portion and the Y-axis line plate portion are laminated with an insulating layer material interposed therebetween. 10. The method of claim 9,
Wherein the drive signal input unit sequentially selects two of the one end of the connected hull and inputs the drive input signal and the first mode switching unit switches the two hulls sequentially selected by the drive signal input unit, The loop coils for inputting the input signals are formed by the two hulls, respectively,
Wherein the position detection signal output section sequentially selects two of the connected hulls to output the position detection signal and the second mode switching section outputs the two hulls selected by the position detection signal output section The loop coil for position detection signal output is formed by the two hulls by connecting the ends,
When the position designating means of the pen touch type designates the XY coordinate position of the XY coordinate forming portion, the input signal inputted from the loop coil for input signal input formed is inputted to the position detection signal outputting loop And outputs it as a pen touch operation detection output of the electromagnetic induction detection mode from the position detection signal output section. 10. The method of claim 9,
The first and second mode switching sections are in an operating state in which the X-axis hull and the Y-axis hull are not connected to each other, and the drive signal input section is provided on one end side of either the X- Wherein the drive input signal is sequentially input to each hull and the fingertip of the user is input from the drive signal input unit when the XY coordinate position of the XY coordinate forming unit is specified as the position designating unit, Axis hull and the Y-axis hull by a fingertip of the Y-axis hull, the drive input signal transmitted from the position detection signal output unit as the finger touch operation detection output of the electrostatic coupling detection mode And the predetermined position detection device.

Images