JP2009032128A - Touch panel device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a touch panel device with good operability, capable of performing sure and smooth input in continuous input of performing point input of designating an operation by touching an icon and drawing. <P>SOLUTION: The touch panel device for calculating a contact position of a finger on a panel surface from a current value or a voltage value for a touch position of the finger is provided with a means for storing touch position coordinates to compare them and a means for determining ON/OFF correspondingly to a stable period of the touch position coordinates to vary a stable period correspondingly to a variation in the position coordinates. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a touch panel device that detects a touch state of a coordinate indicator such as a finger on a sensor panel.

The touch panel device provides a simple and intuitive interface for a computer or other data processing device. In particular, in a transparent touch panel device, the user can send information via the touch panel device by touching an icon on the screen or drawing a character or a picture instead of using a keyboard for data input.
As a touch position coordinate detection method for the touch panel device, there is a method called a resistance film method using a panel having a structure in which two layers of resistance films facing inside are connected to each other at a pressing point. As another method, a constant voltage is applied to one electrode of the upper resistive film, the other electrode is grounded, the voltage value is detected via the lower resistive film at the pressing point, and the X (Y) axis direction The coordinate value of is calculated. As another coordinate detection method, the entire surface resistor is subjected to voltage oscillation, and the current value distributed to the four vertices of the current entering and exiting one point of the surface resistor from the position where the finger approaches or contacts is measured. There is something that specifies coordinates.
JP 2000-132319 A.

  In the conventional technology described above, when an operator unintentionally touches the touch panel surface lightly or accidentally touches the touch surface accidentally, the operator detects a different coordinate from the point at which the operator tried to instruct. It was the cause. In particular, when an icon or instruction item is touched on the screen and the computer or information processing device performs processing corresponding to the touch position, the position where the operator touches the touch panel surface by mistake is entered first because the operator is unfamiliar with it. As a result, there was a problem that the operation was completely different.

  In the touch panel device described above, in order to accurately detect the position of the point touched by the finger, the coordinates are stable. {Stable means that the difference between the new coordinates and the past coordinates is small (the difference is about 1 mm). ) }, The coordinates become effective after the finger is moved, but the contact position coordinates become effective as soon as the finger stabilizes the contact position coordinates, which may not be the position intended by the operator. In addition, when the coordinates are valid after a certain period after the contact position coordinates are stabilized, quick input cannot be performed (response is poor). As described above, smooth and reliable input becomes a problem in the case where the operator touches the touch panel surface to perform continuous input operations such as drawing or the point input operation in which an operation is specified by touching an icon.

  The present invention is an apparatus for detecting a touch position on a sensor panel surface of a finger, and an apparatus for detecting a touch position on the sensor panel surface of the finger, wherein the sensor panel is made of a resistive film material. Signal processing that is formed uniformly and is provided with resistive surrounding electrodes surrounding the periphery, and holds input voltage or current from the four apexes of the resistive surrounding electrodes or each point of the medium connected to the sensor panel surface In the touch panel device that calculates the contact position of the finger on the panel surface from the current value or voltage value that flows to the four vertices of the touch position of the finger, the contact position coordinates are stored, and the new contact position coordinates are A means for comparing past contact position coordinates and a means for determining ON / OFF corresponding to a period for confirming that the contact position coordinates are stable are provided. During is to propose a touch panel device for varying the period of stability confirmation of the contact coordinates to correspond to the change in position coordinates.

  In the touch panel device of the present invention, ON / OFF determination that can clearly indicate the contact position coordinates and the validity / invalidity of the position coordinates is performed, the contact position is turned ON when it is stabilized for a certain period, and the position designated by the operator is input as valid it can. In addition, since the stable period is changed by changing the position coordinates, smooth input can be performed even during continuous input. That is, when the finger moves quickly on the touch panel surface, the stable period is lengthened, and when the finger moves relatively slowly, the stable period is shortened so that smooth continuous input can be performed at the time of drawing.

  In the sensor panel, a resistive film material is uniformly formed on the surface of a resin or glass as a base, and a resistive peripheral electrode surrounding the periphery of the resistive film is disposed. An electrical circuit is connected to the conductor cable and holds the input voltage from the four vertices of the surrounding electrode via the conductor cable. The arithmetic processing unit determines the contact position of the finger on the sensor panel surface from the current value flowing at the four vertices. A means for calculating, storing the contact position coordinates, comparing the new contact position coordinates with the past contact position coordinates, and a means for determining ON / OFF corresponding to a period when the contact position coordinates are stable; The period is a touch panel device provided with means that can be varied according to the amount of change in position coordinates.

  Hereinafter, the details of the present invention will be described with reference to FIG. FIG. 1 is an explanatory diagram of a capacitive touch panel device in which a finger 4 detects a contact position (X, Y coordinates) on a surface resistor 1 on an input surface of a coordinate input panel. The surface resistor 1 is uniformly formed on one side of a transparent glass, resin, or opaque insulating substrate by coating, vapor deposition, or the like. The surface resistor 1 is normally coated with a thin non-conductive film so as not to touch the finger 4 directly. A low-resistance peripheral electrode 2 is closely attached so as to surround the periphery of the uniform surface resistor 1 (surface touched by the finger 4).

  The detection electrodes 3-A, 3-B, 3-C, and 3-D provided at the four vertices of the surface resistor 1 are connected to the signal processing unit 6 by lead wires 5 formed of conductor cables. Yes. The signal processing unit 6 generates an electric signal (AC signal) used by the capacitive touch panel device to detect the position of the finger 4 and drives the signal. Further, the signal processing unit 6 is connected to four lead wires 5 and has a function of measuring each AC current from the detection electrodes 3-A, 3-B, 3-C, and 3-D. Further, the signal processing unit 6 stores the contact position coordinates in a memory or the like (not shown), and calculates the change amount calculated by comparing the contact position coordinates with the newly detected contact position coordinates. Correspondingly, means for changing the stable period is provided. Further, there is provided means for determining that the change amount is ON if there is no change amount beyond the stable period, and turning OFF if the stable period is short.

  The finger 4 is grounded via the human body's ground impedance due to the equivalent resistance 7 and ground capacitance 8 of the human body. When the finger 4 is in contact with the surface resistor 1, there is a capacitance (capacitive coupling) 9 as shown in FIG. 1 between them (between the finger and the surface resistor). Therefore, a small amount of AC current is caused to flow between the finger 4 and the surface resistor 1 due to the signal generator 6 (← “signal processing unit”). The surface resistor 1 has a uniform distribution of resistance values as described above. When the finger 4 is in contact with or close to the surface resistor 1, the detection electrode 3 (3-A, 3- More AC signals flow to the surface resistor 1 through the finger 4 at points B, 3-C, 3-D). Accordingly, the touch point (X, Y coordinates) of the finger 4 on the surface resistor 1 of the coordinate input panel is determined by the signal processing unit 6 from the ratio of the AC signal current values flowing through the detection electrodes 3 that are the terminals of the four apexes. calculate.

FIG. 2 is a diagram showing the relationship between the amount of change in coordinates and time when the operator continuously inputs by moving his / her finger on the panel surface. 4-1, finger 4 is in contact with surface resistor 1, 4-2 is finger 4 moving on surface resistor 1, and 4-3 is a state where finger 4 is in contact with surface resistor 1 and stopped. is there. The lower diagram of FIG. 2 shows the relationship between the time lapse T of the movement of the finger 4 and the coordinate change amount. As shown in FIG. 2, the coordinate change amount increases when the moving speed of the finger 4 is fast (C2) and decreases when the moving speed is slow (C1).
The present invention pays attention to the movement speed and coordinate change amount of the finger 4 described above, and the position coordinate change amount is large when the operator moves the finger 4 in contact with the surface resistor 1 (C2). Is set to the on2 period in which the coordinate stability confirmation period T2 (period in which the amount of change is small) is set long and it is determined to be ON after the coordinate stability confirmation period T2 has elapsed. The period before the on2 period is referred to as the off2 period. When the operator moves the finger 4 in contact with the surface resistor 1 and the change amount of the position coordinates is small (C1), the coordinate stability confirmation period T1 is set short, and the coordinate stability confirmation period T1 has elapsed. It becomes the on1 period when it is determined to be ON later. The period before the on1 period is the off1 period. Here, the OFF1 and OFF2 periods can be made to correspond to the operation of the mouse pointer and the button-off by outputting OFF information to the external device separately from the contact position information of the finger 4. Further, in the on 1 and 2 periods, the contact position information and the ON information are output to the external device, which can correspond to the operation of the mouse pointer and the button on.
By changing the coordinate stability confirmation period according to the coordinate change amount as described above, it is determined that the coordinate information is OFF when moving quickly, and the coordinate information is determined ON when stopping, so that the cursor movement is the same as the mouse operation. Corresponds to click action.
FIG. 3 is a diagram showing another embodiment showing the relationship between the coordinate change amount and time when the operator moves his / her finger on the panel surface and continuously inputs. A lower limit L of the coordinate change amount is set, and when the change amount is smaller than L (C3), all periods are set as an on3 period for determining ON, and when larger than L (C2), a coordinate stability confirmation period T2 is set. Thus, continuous input can be performed when the finger 4 moves relatively slowly, and smooth drawing can be performed.

Next, the control operation sequence will be described. FIG. 4 shows the control operation sequence described in FIG.
In S1, touch position coordinates are acquired. In step S2, the position coordinates acquired in step S1 are compared with the position coordinates acquired previously and stored in the memory. In S3, the magnitude of the compared difference between the position coordinates is determined. If the difference is large compared to S3, the coordinate stability confirmation period T2 is set in S4. If the difference is small, the coordinate stability confirmation period T1 is set in S5.
In S6, the touch position coordinates are acquired. In S7, the position coordinates acquired in S6 are compared with the position coordinates previously acquired and stored in the memory. In S8, the magnitude of the compared difference between the position coordinates is determined. If the difference compared in S8 is large, the touch position coordinates and the OFF information are output to an external apparatus such as a personal computer or a processing apparatus in S9, and the process returns to S1. If the difference is small in S8, it is determined in S10 whether the coordinate stability confirmation period has elapsed. If the determination at S10 has not elapsed, the touch position coordinates and the OFF information are output to the external device at S11. If the determination has elapsed, the touch position coordinates and the ON information are output to the external device at S12. After S11 or S12 processing, the process returns to S6.
S1 to S11 are the off periods off1 and 2 in FIG. S6 to S11 are coordinate stability confirmation periods T1 and T2 in FIG. S12 is the on periods on 1 and 2 in FIG.
In the control sequence of FIG. 4 described above, the coordinate stability confirmation period changes corresponding to the moving speed of the finger 4, so that the operator moves while touching the touch surface in the point input for designating the operation by touching the icon. However, the desired position can be input reliably.

FIG. 5 shows the control operation sequence described in FIG. In S1, touch position coordinates are acquired. In step S2, the position coordinates acquired in step S1 are compared with the position coordinates acquired previously and stored in the memory. In S3, the magnitude of the difference between the position coordinates compared to the set value L is determined. If the difference is larger than L in S3, the coordinate stability confirmation period T2 is set in S4. If the difference is smaller than L, the coordinate stability confirmation period is canceled in S5, that is, the coordinate stability confirmation is performed. Absent. In S13, the touch position coordinates and ON information are output to the external device. After S13 processing, the process returns to S1.
In S6, the touch position coordinates are acquired. In S7, the position coordinates acquired in S6 are compared with the position coordinates previously acquired and stored in the memory. In S8, the magnitude of the compared difference between the position coordinates is determined. If the difference compared in S8 is large, the touch position coordinates and the OFF information are output to the external device in S9, and the process returns to S1. If the difference is small in S8, it is determined in S10 whether the coordinate stability confirmation period has elapsed. If the determination at S10 has not elapsed, the touch position coordinates and the OFF information are output to the external device at S11. If the determination has elapsed, the touch position coordinates and the ON information are output to the external device at S12. After S11 or S12 processing, the process returns to S6.
The period from S1 to S11 (excluding S5 and 13) is the off period off2 in FIG. S6 to S11 is the coordinate stability confirmation period T2 in FIG. S12 is the on period on2 in FIG. S1, 2, 3, 5, and 13 become the on period on3 in FIG.
In the control sequence of FIG. 5 described above, the coordinate stability confirmation period is set according to the movement speed of the finger 4, that is, whether the coordinate comparison result is larger or smaller than the set value L. It is effective for continuous input.

  As described above, according to the present invention, reliable point input at the time of touch and smooth input at the time of continuous input can be achieved at the same time. In particular, reliable point input can be realized while the touch position moves. In addition, a smooth transition to continuous input can be performed depending on the presence or absence of a coordinate stabilization period. A touch panel device with better operability can be realized by properly using it according to the purpose of use and necessity.

Explanatory drawing of capacitive touch panel device Explanatory diagram showing the relationship between the amount of coordinate change and time when the operator moves his / her finger on the panel and continuously inputs Explanatory diagram showing the relationship between the amount of coordinate change and time when the operator moves his / her finger on the panel and continuously inputs Flowchart of the control operation sequence of FIG. Flowchart of the control operation sequence of FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Surface resistor 2 Surrounding electrode 3-A Detection electrode 3-B Detection electrode 3-C Detection electrode 3-D Detection electrode 4 Finger 5 Lead-out line 6 Signal processing part 7 Human body resistance 8 Ground capacity 9 Electrostatic capacity

Claims (1)

An apparatus for detecting a touch position on a sensor panel surface of a finger, wherein the sensor panel is formed of a resistive film material uniformly and is provided with a resistive surrounding electrode surrounding the periphery, From the four vertices of the electrodes or from each point of the medium connected to the sensor panel surface, connected to a signal processing unit that holds an input voltage or current, and from the current value or voltage value flowing through the four vertices, the panel touches the finger touch position. In the touch panel device that calculates the contact position of the finger on the surface, the contact position coordinates are memorized, a means for comparing the new contact position coordinates with the past contact position coordinates, and the period during which the contact position coordinates are confirmed to be stable Correspondingly, a means for determining ON / OFF is provided, and the period during which the contact position coordinates are stable varies the period during which the contact coordinates are confirmed in accordance with the amount of change in the position coordinates. The touch panel device according to claim and.