JPH1040015A - Touch panel control circuit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To attain practical use in a long time for a battery-driven equipment or the like by saving power consumption when an input to a touch panel is not present by using a coordinate detecting circuit and a touch detecting circuit while switching them according to the input state. SOLUTION: When an operator depresses the film of a touch panel 9 by a touch detecting circuit with a finger or a pen 27 or the like, transparent resistance films at the upper side and lower side of the touch panel 9 are brought into contact with each other. Thus, a DC signal impressed to an electrode 15 of the touch panel 9 is conducted with the transparent resistance film at the lower side of the touch panel 9, transmitted to an electrode 18, and transferred through a switch element 11 to an invertor 12. The output of the invertor 12 is transmitted to a controlling part 14 as a control signal 19 while the logic level is turned into a low level. When the control signal 19 is turned into a low level, the controlling part 14 confirms the depression on the touch panel 9, and switches an output signal 22 to a coordinate detecting circuit.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a touch panel control circuit of a coordinate input device for detecting a coordinate by switching a control circuit by detecting a voltage of a resistive voltage dividing method using a touch panel.

[0002]

2. Description of the Related Art In a conventional input device using a resistive voltage dividing type touch panel, a finger or a dedicated input pen is used to press or touch the touch panel to obtain a resistance value of a transparent resistive film used for the touch panel. The voltage was detected by dividing the applied voltage.

[0003]

In a conventional touch panel, since a signal is applied to the touch panel even when no signal is being input, there is a loss of energy consumed by the resistance of the transparent resistive film of the touch panel. When the touch panel is driven by a portable power source such as a battery, loss has been a problem.

[0004]

DISCLOSURE OF THE INVENTION The present invention has been made in view of the conventional problems, and comprises a plastic film having a transparent resistive film on its surface, and a glass opposed to the transparent resistive film of the plastic substrate via a spacer. A touch panel comprising a transparent resistive film on the surface of the substrate, a circuit forming a switch circuit by inputting a DC signal to the touch panel, and a control unit for switching an operation mode to a coordinate detection circuit based on a detection signal from the switch circuit The present invention proposes a touch panel control circuit having:

[0005]

In the present invention, in addition to the conventional coordinate detecting circuit in the coordinate detection using the touch panel, a circuit for detecting only the touch is added, and the circuit to be used is switched according to the situation.

[0006]

DESCRIPTION OF THE PREFERRED EMBODIMENTS A touch panel comprising a plastic plate having a transparent resistive film on its surface and a glass plate, a coordinate detecting circuit for detecting a coordinate signal, and detecting only pressing on the touch panel The touch detection unit, a switch element such as an analog switch or FET that switches between the coordinate detection circuit and the touch detection circuit, and a control unit that switches the circuit and calculates the coordinates from the coordinate signal presses the touch panel with a finger or a dedicated pen. Then, by transmitting a touch signal to the control unit, the switch element is switched to the coordinate signal detection circuit to start the coordinate signal detection operation.

[0007]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below with reference to the accompanying drawings. FIG. 1 is an electric block diagram of a resistive voltage dividing touch panel coordinate detecting device using the circuit of the present invention. A touch panel 9 has a transparent resistive film 2 composed of ITO (tin-indium oxide film) shown in FIG. The plastic film 1 of the variable substrate and the glass substrate 4 of the fixed substrate having the transparent resistive film 3 made of ITO are opposed to each other between the transparent resistive films 2 and 3 with the spacer 5 interposed therebetween. It is bonded, and has a configuration in which a plastic film 1 and a glass substrate 4 are stacked.

As a normal coordinate detection operation, in the case of coordinate detection on the X side, when an operator presses a point P on the touch panel 9 with a finger, a pen or the like 27, a first control signal 21 from the control unit 14 is used. Touch panel 9 by switching switch element 8
A DC signal (mark 24) is applied to the upper electrode 15. The switch element 6 is controlled by a first control signal 21 from the control unit 14 via an inverter to connect the electrode 18 to the ground. The switch element 10 is controlled by a first control signal 21 from the control unit 14 via an inverter, and the electrode 17 is in a non-connected state, that is, an electrically floating state. (× mark) The switch element 7 is connected to the switch element 13 by the first control signal 21 from the control unit 14.
The switch element 13 applies a signal from the electrode 18 to the control section 14 via the switch element 7 according to the first control signal 21 from the control section 14. As a result, the signal path has the form shown in FIG.

The actual detection of the coordinate signal is divided into a resistance R1 between the electrode 15 and the point P and a R2 between the electrode 18 and the point P with the pressed point P as a boundary, and the DC signal applied to the electrode 15 is The voltage is divided by R1 and R2 and output from the electrode 16. The signals from the electrodes 16 are transferred to the switch elements 7 and 1
3 to the control unit 14 as an output signal 20. The control unit 14 A / D converts the detected signal and recognizes the position of the pressed point P on the X axis from the value.

Next, a description will be given of the case of detecting the coordinates on the Y side.
The switch element 10 is set to apply a DC signal to the electrode 17 of the touch panel 9 by the control signal 21 of. The switch element 7 connects the electrode 16 of the touch panel 9 to the ground according to the second control signal 21 from the control unit 14. The switch element 8 causes the electrode 15 of the touch panel 9 to be in a non-connect state according to the second control signal 21 from the control unit 14 (marked “x”). The switch element 6 connects the electrode 18 of the touch panel 9 to the switch element 13 according to a second control signal 21 from the control unit 14. The switch element 13 applies a signal from the switch element 6 to the control unit 14 according to a control signal 21 from the control unit 14. As a result, the signal path has the form shown in FIG.

The actual detection of the coordinate signal is divided into a resistor R3 between the electrode 17 and the point P and a electrode R4 between the electrode P and the point P at the boundary of the pressed point P, and the DC signal applied from the electrode 17 is divided into R3 and R3. The voltage is divided by R4 and output from the electrode 18. The signals from the electrodes 18 are transferred to the switch elements 6 and 13
Is transmitted to the control unit 14 as an output signal 20 via the. The control unit 14 A / D converts the detected signal and recognizes the pressed point P on the Y axis from the value.

Now, the actual operation will be described with reference to FIG.
When the control unit 14 is in a state of waiting for an input to the touch panel 9, the control unit 14 outputs a control signal 22 and outputs the switch elements 6, 7,
8, 10, 11, and 25. By this control signal 22, the switch element 6.7.8.10 enters a shutdown state, and the input / output terminals of each element become high impedance. The switch element 25 is turned on by the control signal 22 from the control unit 14 and the DC voltage is applied to the electrode 18 of the touch panel 9.
Apply a signal. The switch element 11 is turned on by a control signal 22 from the control unit 14 and connects the electrode 17 of the touch panel 9 to the inverter 12. Inverter 1
The output of 2 is sent to the control unit 14 as an output signal 19.
The above configuration is shown in FIG. Touch panel with finger or pen 2
If the signal is not pressed at 7, the output signal 19 keeps outputting a high level at a logic level. While the output signal 19 is outputting a high level, the control unit does not perform control for coordinate detection on the touch panel. Since the divided DC signal is not subjected to the voltage dividing process, the current consumption is maintained in a state much smaller than that at the time of detecting the coordinates.

Next, the operator touches the film 1 on the touch panel 9.
Is pressed with a finger or a pen 27, the upper transparent resistive film 2 of the touch panel 9 and the lower transparent resistive film 3 come into contact with each other. Thereby, the DC signal applied to the electrode 15 of the touch panel 9 is conducted to the transparent resistive film 3 on the lower side of the touch panel 9, and the DC signal is electrically floating because the electrode 15 of the touch panel 9 is in a non-connect state. As a result, it is transmitted to the electrode 18 and transferred to the inverter 12 via the switch element 11. In the inverter 12, the output becomes a low logic level and is sent to the control unit 14 as a control signal 19. The control unit 14 confirms that the touch panel 9 is pressed when the output signal 19 becomes low level, and switches the output signal 22 to the coordinate detection circuit. As a result, the switch element 6.7.8.10 detects signals on the X side and the Y side based on the first control signal 21 from the control unit 14. When the coordinate detection signal 19 has not been output for a certain period of time, the control unit 14 uses the control signal 22 to wait for an input to the touch panel 9 by the touch detection circuit.

[0014]

According to the coordinate detecting device using the circuit of the present invention, power consumption when there is no input to the touch panel can be saved by switching between the coordinate detecting circuit and the touch detecting circuit depending on the input state. As a result, it has become possible to use the battery for a long time in battery-powered equipment.

[Brief description of the drawings]

FIG. 1 is a block diagram of a touch panel coordinate detection device.

FIG. 2 is a configuration diagram of a touch panel

FIG. 3 is an X-side coordinate detection diagram

FIG. 4 is a Y-side coordinate detection diagram.

FIG. 5 is a configuration diagram of a touch detection circuit.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Plastic film 2 Transparent resistance film 3 Transparent resistance film 4 Glass substrate 5 Spacer 6 Switch element 7 Switch element 8 Switch element 9 Touch panel 10 Switch element 11 Switch element 12 Inverter 13 Switch element 14 Control part 15 Electrode 16 Electrode 17 Electrode 18 Electrode 19 Touch detection signal 20 Coordinate detection signal 21 XY control signal 22 Coordinate detection / touch detection switching signal 23 DC signal power supply 24 DC signal power supply 25 Switch element 26 DC signal power supply 27 Finger or pen

Claims (1)

[Claims] 1. A touch panel comprising: a plastic film having a transparent resistive film on its surface; a transparent resistive film on the surface of a glass substrate opposed to the transparent resistive film of the plastic substrate via a spacer; A circuit constituting a switch circuit by the input of the DC signal of
A touch panel control circuit, comprising: a control unit that switches an operation mode to a coordinate detection circuit according to a detection signal from the switch circuit.