JPH06309138A - Screen control method using touch panel - Google Patents

Abstract

PURPOSE:To perform scroll more easily, quickly, and easy to observe by scrolling a display picture at a prescribed timing when it is decided that a touch position is changed in a state where the display picture is touched. CONSTITUTION:A control system is equipped with a CRT 1, a touch panel 2, two interface circuits(I/F) 3, 4, a CPU 5, and a bus 6, and when a picture 8 on the CRT 1 is moved as being touched by the finger of an operator, it is detected by the touch panel 2, and also, the picture 8 displayed on the CRT 1 is scrolled corresponding to the moving direction and the amount of travel of the finger by the CPU 5. Also, in such a case, it is permitted that the picture 8 on the CRT 1 can be scrolled successively when the picture 8 on the CRT 1 is touched with the finger of the operator and is moved on the screen without being separated from the screen.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention uses a touch panel such as an optical type, a resistance type, a capacitance type, an ultrasonic type, or a pressure type touch panel provided on the front surface of a CRT to control the screen of the CRT. Relates to a screen control method using.

[0002]

2. Description of the Related Art In a control system for controlling various plants, etc., a CRT for displaying various control contents.
When a scroll icon or the like is displayed on the screen of the operator and this is touched with the operator's finger or pen, the CR
In many cases, this is detected by a touch panel of an optical type, a resistance type, a capacitance type, an ultrasonic type, a pressure type, etc. arranged on the front surface of the T to scroll the screen of the CRT.

[0003]

However, in the above-described screen control method using the touch panel, it is necessary to display a scrolling icon or the like on the screen of the CRT, so that the effective display area of the screen is reduced. There was a problem of becoming smaller.

Further, when operating an icon or the like displayed on the CRT, it is necessary to aim and touch a certain narrow screen area. Therefore, the operation at the time of touch input must be carefully performed. However, there is a problem that operator fatigue increases.

Furthermore, when scrolling a desired amount of movement, the icon must be kept touching for a certain period of time, and quick input cannot be performed by that amount, which may cause a control delay. there were.

In view of the above circumstances, the present invention can scroll the screen with a screen display that is simpler, faster, and more intuitively understandable without using an icon or the like. It is an object of the present invention to provide a screen control method using a touch panel that can reduce control fatigue and the like while reducing the fatigue of the screen.

[0007]

To achieve the above object, the present invention provides a screen control using a touch panel for scrolling the display screen based on touch position detection information of the touch panel arranged in front of the display screen. In the method, it is determined whether or not the display screen is moved in a touched state based on touch position detection information output from the touch panel, and the touch position is changed in the touched state of the display screen. When it is determined that the display screen is scrolled based on a change in the position detection information at a predetermined timing.

[0008]

In the above structure, it is determined based on the touch position detection information output from the touch panel whether or not the display screen is moved in a touched state, and the touched position is determined in the touched state in the display screen. When it is determined that it is changing, by scrolling the display screen based on the change of the position detection information at a predetermined timing, it is easier, faster, and more intuitive without using an icon or the like. The screen is scrolled with an easy-to-understand screen display to reduce operator fatigue and prevent control delays.

[0009]

1 is a block diagram showing an example of a control system to which an embodiment of a screen control method using a touch panel according to the present invention is applied.

The control system shown in this figure includes a CRT 1 and
Touch panel 2 and two interface circuits (I /
F) 3, 4, CPU 5, and bus 6 are provided, and the screen 8 of the CRT 1 is displayed by the operator's finger 7 (see FIG. 3) or the like.
Touch panel 2 when is moved while being touched
This is detected by the CPU 5, and the screen 5 displayed on the CRT 1 is scrolled by the CPU 5 according to the moving direction and the moving amount of the finger 7.

The CRT 5 is provided with a cathode ray tube having a display capacity sufficient to display the state of an object controlled by this control system, such as a plant, and when a display signal is output from the interface circuit 4. , Capture this and display it on the screen.

The touch panel 2 is an optical type or a resistance type,
It is composed of a capacitance type panel, an ultrasonic type panel, etc., and the screen 8 of the CRT 1 is displayed by the operator's finger 7 or the like.
When is touched, this is detected to generate touch position data, which is supplied to one interface circuit 3.

One of the interface circuits 3 takes in the touch position data output from the touch panel 2, converts it into touch position data of a preset format, and sends the touch position data onto the bus 6 to send it to the CPU 5
Supply to.

The CPU 5 takes in process signals and the like output from a plant to be controlled, creates control screen data, supplies the control screen data to the other interface circuit 4 via the bus 6, and also supplies the one interface. When the touch position data is output from the circuit 3, the touch position data is fetched through the bus 6, and the scroll direction and the scroll amount of the screen are calculated based on the change of the touch position data, and then based on the calculation result. The scrolled control screen data is created and supplied to the other interface circuit 4 via the bus 6.

The other interface circuit 4 is the CPU
When the control screen data is output from the controller 5, the control screen data is captured via the bus 6, converted into an image signal and supplied to the CRT 1 for screen display.

Next, the operation of this embodiment will be described with reference to the flow chart shown in FIG.

First, the CPU 5 monitors the output of the interface circuit 3 and fetches information indicating whether or not the screen 8 of the CRT 1 is touched by a finger 7 of an operator or the like, and a part of the screen 8 of the CRT 1 is fetched. Wait until is touched (step ST1).

Then, as shown in FIG. 3, the finger 7 of the operator or the like is used.
When the screen 8 of the CRT 1 is touched by the touch panel 2 and is detected by the touch panel 2 and the touch position data is output from the interface circuit 3, the CPU 5 takes in the touch position data and, at the same time, for a preset time, the interface. It is checked whether the touch position data is continuously output from the circuit 3 (step ST2).

If the touch position data is not output from the interface circuit 3 for the certain period of time, the CPU 5 determines that the operator has input an input instruction other than the scroll input and determines the coordinates designated by the touch position data. The touch input processing is performed according to the icon and so on.

If the touch position data is output from the interface circuit 3 for a certain period of time or more (step ST2), the CPU 5 determines that a scroll command is issued by the operator, and the touch position data is set as the start point. After the coordinates (X1, Y1) are stored (step ST3), the interface circuit 3 waits until the touch position data is no longer output (step ST4).

At this time, the operator's finger 7 touching on the CRT 1 is moved without being released from the screen 8, and the value of the touch position data output from the touch panel 2 changes correspondingly. Each time, the CPU 5 takes in the touch position data via the interface circuit 3 and stores it as the end point candidate coordinates (X3, Y3).

The operator's finger 7 is placed on the CRT 1 from above.
When the touch panel 2 detects that the touch position data has been released and the touch position data is no longer output from the interface circuit 3, the CPU 5 determines the final stored end point candidate coordinates (X3, Y3) as the official end point coordinates (X2, Y2). (Step ST5).

After that, the CPU 5 calculates the moving amount (ΔX, ΔY) by performing the calculation shown in the following formula based on the starting point coordinates (X1, Y1) and the ending point coordinates (X2, Y2) as shown in FIG. Yes (step ST6).

ΔX = X2-X1 (1) ΔY = Y2-Y1 (2) Then, the CPU 5 controls the entire control screen 10 in the memory.
(See FIG. 3) From the current screen 8 displayed on the CRT 1, a portion of the image that is displaced by the movement amount (ΔX, ΔY) is cut out and sent to the bus 6 as control screen data. And supply it to the interface circuit 4 for CRT.
The screen 8 corresponding to the control screen data is displayed on the screen 1 (step ST7).

As described above, in this embodiment, when the screen 8 of the CRT 1 is moved while being touched by the operator's finger 7 or the like, the touch panel 2 detects this and the CPU 5 moves the finger 7. Since the screen 8 displayed on the CRT 1 is scrolled according to the direction and the amount of movement, the screen display is easier, faster, and more intuitively understandable without using an icon or the like. The screen 8 can be scrolled, thereby reducing the fatigue of the operator and preventing the control delay or the like from occurring.

Further, in the above-mentioned embodiment, the CRT is used.
When the operator's finger 7 is removed from the screen 8 on the CRT 1,
Although the upper screen 8 is scrolled, when the operator's finger 7 touches the screen 8 on the CRT 1 and the screen 8 is moved without being separated from the screen 8, the screen on the CRT 1 is moved. 8 may be scrolled continuously.

In this case, the CPU 5 of the control system is shown in FIG.
Such scroll control is performed by the procedure shown in the flowchart of FIG.

First, the CPU 5 monitors the output of the interface circuit 3 and fetches information indicating whether or not the screen 8 of the CRT 1 is touched by a finger 7 of an operator or the like, and a part of the screen 8 of the CRT 1 is fetched. Wait until is touched (step ST11).

Then, the CRT is operated by the finger 7 of the operator or the like.
When the screen 8 of No. 1 is touched, the touch panel 2 detects it, and the touch position data is output from the interface circuit 3, the CPU 5 takes in the touch position data and, at the same time, for a preset time, the interface circuit. It is checked whether the touch position data is continuously output from 3 (step ST1).
2).

If the touch position data is not output from the interface circuit 3 for the fixed time, the CPU 5 determines that the operator has issued an input instruction other than the scroll input, and determines the coordinates specified by the touch position data. The touch input processing is performed according to the icon and so on.

If the touch position data is output from the interface circuit 3 for the fixed time or more,
The CPU 5 determines that the operator has issued a scroll command, and determines the touch position data to be the start point coordinates (X1, Y).
After storing as 1) (step ST13), it is checked whether or not the touch position data is no longer output from the interface circuit 3 (step ST14).

If the touch position data is continuously output from the interface circuit 3, the CPU 5 checks whether the value of the touch position data output from the interface circuit 3 has changed (step ST15). If this changes, the finger 7 of the operator touching the CRT 5 is moved without being released from the screen 8, and the value of the touch position data output from the touch panel 2 changes correspondingly. If so, the new touch position data output from the interface circuit 3 is stored as the end point coordinates (X2, Y2) (step ST16).

Thereafter, the CPU 5 causes the start point coordinates (X1, Y
Based on 1) and the end point coordinates (X2, Y2), the calculation shown in the following equation is performed to calculate the movement amount (ΔX, ΔY) (step ST17).

ΔX = X2-X1 (3) ΔY = Y2-Y1 (4) Then, the CPU 5 controls the entire control screen 10 in the memory.
Of the image displayed on the CRT 1 is clipped out from the screen of the current screen 8 on the CRT 1 by the amount of movement (ΔX, ΔY) and sent to the bus 6 as control screen data to be output to the interface circuit 4. And the screen 8 corresponding to the control screen data is displayed on the CRT 1 (step ST18).

Thereafter, the CPU 5 causes the end point coordinate (X2,
Y2) is stored as a new start point coordinate (X1, Y1), and the process returns to the touch end determination process described above.

Then, the operator's finger 7 is placed on the CRT 5 from above.
Until the touch panel 2 detects that the touch position data is no longer output from the interface circuit 3, the CPU 5 repeats the screen scroll processing described above (steps ST14 to ST18), and the CR
When the operator's finger 7 is released from above T1, the scrolling process is ended (step ST14).

By doing so, the operator can operate the finger 7
When the screen 8 on the CRT 1 is moved by being touched by the, the screen on the CRT 1 can be continuously scrolled, which can further improve the operability.

In the above-described embodiment, the touch panel 2 is an optical type, a resistance type, a capacitance type, an ultrasonic type, or the like, but a pressure type touch panel is used. You can

In this case, the CPU 5 of the control system is shown in FIG.
Such scroll control is performed by the procedure shown in the flowchart of FIG.

First, the CPU 5 monitors the output of the interface circuit 3 and fetches information indicating whether or not the screen 8 of the CRT 1 is touched by the finger 7 of the operator or the like, and a part of the screen 8 of the CRT 1 is fetched. Wait until is touched (step ST21).

Then, the CRT is operated by the finger 7 of the operator or the like.
If the screen 8 of No. 1 is touched and the touch panel 2 detects it and the touch position data and the touch pressure data are output from the interface circuit 3, the CPU 5 takes in the touch position data and the touch pressure data, and It is checked whether the value of the touch pressure data is equal to or more than a preset constant pressure value (step ST22).

If the value of the touch pressure data output from the interface circuit 3 is not equal to or more than the constant pressure value, the CPU 5 determines that the operator has issued an input instruction other than the scroll input, and determines the touch position data based on the touch position data. Performs touch input processing according to the icon or the like at the designated coordinates.

If the value of the touch pressure data output from the interface circuit 3 is greater than or equal to the predetermined pressure value, the CPU 5 determines that a scroll command has been issued by the operator, and outputs it from the interface circuit 3. After storing the touch position data as the starting point coordinates (X1, Y1) (step ST23), it waits until the touch position data is no longer output from the interface circuit 3 (step ST24).

At this time, the finger 7 of the operator touching the CRT 5 is moved without being released from the screen 8, and the value of the touch position data output from the touch panel 2 changes correspondingly. Each time, the CPU 5 takes in the touch position data via the interface circuit 3 and stores it as the end point candidate coordinates (X3, Y3).

The operator's finger 7 is placed on the CRT 1 from above.
When the touch panel 2 detects that the touch position data has been output and the touch position data is no longer output from the interface circuit 3, the CPU 5 determines the final stored end point candidate coordinates (X3, Y3) as the official end point coordinates (X2, Y2). (Step ST25).

Thereafter, the CPU 5 causes the start point coordinates (X1, Y
Based on 1) and the end point coordinates (X2, Y2), the calculation shown in the following equation is performed to calculate the movement amount (ΔX, ΔY) (step ST26).

ΔX = X2-X1 (5) ΔY = Y2-Y1 (6) Next, the CPU 5 controls the entire control screen 10 in the memory.
Of the image displayed on the CRT 1 is clipped out from the screen of the current screen 8 on the CRT 1 by the amount of movement (ΔX, ΔY) and sent to the bus 6 as control screen data to be output to the interface circuit 4. And the screen 8 corresponding to the control screen data is displayed on the CRT 1 (step ST27).

As described above, even if the pressure-type touch panel is used, the screen 8 can be scrolled by a screen display that is easier, faster, and more intuitive to understand without using icons or the like. Therefore, it is possible to reduce the fatigue of the operator and prevent the control delay from occurring.

In each of the above embodiments, CR
Although the entire screen 8 of T1 is scrolled, the screen 8 of CRT1 is divided into a scroll target area 15 and a non-scroll target area 16 as shown in FIG. The key icon 17 and the scroll icon 18 may be arranged.

By doing so, an operator who is not in the scroll control according to the present invention described above, that is, an operator who can perform the conventional normal operation can be made to perform the scroll operation of the screen 8.

In each of the above embodiments, CR
When the touch position is moved while the screen 8 on T1 is being touched, the entire display screen is scrolled according to the movement amount. As shown in FIG. 8, the lower side of the current screen 8a is touched. When the touch position is moved to the right or left in the state of being operated, page break processing may be performed to display the screen 8b of the next page or the screen of the previous page.

In this case, when the lower side of the screen 8a is touched and the touch position is moved to the right, the screen 8b of the next page is displayed, and the lower side of the screen 8a is touched and the touch position is moved to the left. When moved, the screen of the previous page is displayed.

By doing so, the page break process can be smoothly performed when a screen such as a sentence is displayed on the CRT 1.

[0054]

As described above, according to the present invention, the screen can be scrolled easily, faster and more intuitively without using an icon or the like. As a result, it is possible to reduce operator fatigue and prevent a control delay or the like from occurring.

[Brief description of drawings]

FIG. 1 is a block diagram showing an example of a control system to which an embodiment of a screen control method using a touch panel according to the present invention is applied.

FIG. 2 is a flowchart showing an example of scroll operation of the control system shown in FIG.

FIG. 3 is a schematic diagram showing an example of a scroll operation of the control system shown in FIG.

4 is a schematic diagram showing a calculation example of a scroll amount during a scroll operation of the control system shown in FIG.

FIG. 5 is a flowchart showing another embodiment of a screen control method using a touch panel according to the present invention.

FIG. 6 is a flowchart showing another embodiment of a screen control method using a touch panel according to the present invention.

FIG. 7 is a schematic view showing another embodiment of the screen control method using the touch panel according to the present invention.

FIG. 8 is a schematic view showing another embodiment of the screen control method using the touch panel according to the present invention.

[Explanation of symbols]

 1 CRT 2 Touch panel 3, 4 Interface circuit 5 CPU 6 Bus

Claims (1)

[Claims] 1. A screen control method using a touch panel that scrolls the display screen based on touch position detection information of a touch panel arranged on the front surface of the display screen, wherein the touch position detection information is output from the touch panel. It is determined whether or not the display screen is being moved while being touched, and when it is determined that the touch position is changing while the display screen is being touched, the change in the position detection information at a predetermined timing. A screen control method using a touch panel, characterized in that the display screen is scrolled based on.