JPH05175820A - Non-touch switch device - Google Patents

Abstract

PURPOSE:To eliminate the malfunction and to improve the reliability by making difference between a close conductor and a noise. CONSTITUTION:Key scanning is performed with 20ms sampling period; and when input is confirmed continuously three times (40ms), a formal input is discriminated. An input switch group at the time (10ms) of first input confirmation, that at the time (20ms) of second input confirmation, and that at the time (40ms) of third input confirmation are denoted as A, B, and C respectively. In this case, the formal input of a switch in the group A is discriminated when relations shown in the Venn diagram are satisfied. Since the input switch group A exists in sets (c) and (d) in this Venn diagram, the switch (non-touch switch) input of the group A is discriminated as the formal input. If a switch in the group A which does not satisfy relations in the Venn diagram exists, input to this non-touch switch is not discriminated as the formal input, and application of noise is discriminated.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a non-touch switch device which detects the on / off state of an input by detecting a change in its electrostatic capacitance using a plate capacitor.

[0002]

The basic patent for this non-touch switch is owned by Intellect Electronics Limited of Australia. Patent number is PCT
/ AU86 / 00043. Next, the configuration and basic operation of this non-touch switch will be described. As shown in FIG. 4, the non-touch switch 1 includes an outer electrode plate 2,
An insulator 3 arranged inside the outer electrode plate 2 and shown by diagonal lines
It is formed of a flat plate capacitor composed of a central electrode plate 4 and a central electrode plate 4.

As shown in FIG. 5, a square wave is input to the outer plate 2 as a drive signal, and a detection transistor Q ₁ is connected to the central plate 4. FIG. 7A shows a charge distribution state of the flat plate capacitor, and FIG. 7B shows a charge distribution state when the fingertip is approached. That is, when the fingertip approaches the switch surface of the non-touch switch 1, the finger acts as a third electrode, and in addition to the capacitor between the outer electrode plate 2 and the central electrode plate 4, the electrode plate between the outer electrode plate 2 and the fingertip, the central electrode plate. 4 will be formed between the fingertip and the fingertip.

Therefore, the charge between the electrodes is divided, the electrostatic capacitance between the electrode plates 2 and 4 is reduced as compared with the normal state, and accordingly, a normal fingertip is not approached, as shown in FIG. 6 (a). As for the output waveform, as shown in FIG. 6B, the current flowing through the transistor Q ₁ decreases and the output pulse changes. This change is detected to determine whether the non-touch switch 1 is on or off.

On the other hand, to determine whether the non-touch switch 1 is turned on or off, a reference value created from the peak value of the detection pulse when the power is turned on is stored, and the peak value of the detection pulse signal is successively compared to obtain the reference value. If it is smaller than the (threshold level), the non-touch switch 1 is determined to be on. The detection pulse is taken out at a constant cycle and the comparison judgment is repeated.

FIG. 3 is a block diagram showing a signal system of the non-touch switch 1. A square-wave key scan drive signal is scanned and input to each non-touch switch 1 from the arithmetic and control circuit 10 including a microcomputer as described above. And
The output of the non-touch switch 1 is detected by the transistor Q _1, the output of the transistor Q ₁ is a direct current component is removed by the DC component removing circuit 11.

The output signal amplified by the amplifier circuit 12 is peak-held by the peak-hold circuit 13, and
The comparator 14 compares the reference value from the arithmetic control circuit 10 and inputs the output to the arithmetic control circuit 10. Also,
The light emitting diode 7 receives the output of the comparator 14 by the arithmetic control circuit 10 and is controlled by an on / off control signal,
Further, the light emitting diode 7 is dynamically turned on by an LED scan signal.

In order to clarify the on / off state of the non-touch switch 1, as shown in FIG. 3, a hole 6 is provided at the center of the central electrode plate 4 and the substrate 5 of the non-touch switch 1, and the hole 6 is provided in the hole 6. The light emitting diode 7 is arranged. Further, as shown in FIG. 8, the non-touch switches 1 are arranged in a matrix to form a non-touch switch device. Of course, the single non-touch switch may be used.

[0009]

Non-touch switch 1
As described above, the determination of whether to turn on or off is caused by the approaching conductor (an object having a sufficiently large capacity with respect to the ground), but variations in peak value due to noise cannot be overlooked. Differentiation between noise and close conductors prevents malfunction. The present invention has been made in view of the above points, and an object of the present invention is to provide a highly reliable non-touch switch device in which an approaching conductor and noise are differentiated and no malfunction occurs.

[0010]

SUMMARY OF THE INVENTION The present invention uses a plate capacitor to detect a change in its capacitance and to turn on the input,
A non-touch switch that detects off is formed, this non-touch switch is key-scanned at a fixed sampling cycle, and if the same non-touch switch confirms continuous input at any number of times, it is judged as an official input In the non-touch switch for which continuous input is not recognized, a control means for judging that noise is applied is provided.

According to the second aspect of the present invention, a variation area of the output level due to the approach and contact of the conductor is set in advance, and it is determined that noise is applied when the output level is a level other than the variation area. A control means is provided.
Further, in claim 3, a filter for removing a signal band other than the signal band of the feedback signal from the non-touch switch is provided at an arbitrary position after the non-touch switch.

[0012]

When the same non-touch switch confirms continuous input at any number of times, it is judged as an official input,
The non-touch switch, in which continuous input was not recognized at an arbitrary number of times, is judged as noise applied,
It is possible to accurately differentiate between the formal input and the input due to noise, and thus the probability of malfunction due to noise can be reduced.

According to the second aspect of the present invention, it is determined that noise is applied when the output level is in a level other than the fluctuation range, so that the formal input and the input due to noise are accurately differentiated. Therefore, the probability of malfunction due to noise can be reduced. Further, in claim 3, the filter eliminates a signal band other than the signal band possessed by the feedback signal from the non-touch switch, so that the formal input and the input due to noise can be accurately differentiated. Therefore, the probability of malfunction due to noise can be reduced.

[0014]

Embodiments of the present invention will be described below with reference to the drawings. Since the entire structure is the same as the conventional one, the gist of the part will be described in detail. A case where a plurality of non-touch switches 1 are arranged will be described. Now, as shown in FIG. 1A, the arithmetic control circuit 10 performs a key scan at a sampling period of 20 ms and performs three consecutive scans (40 ms).
If the input is confirmed in, it is judged as the official input.

That is, in FIG. 1A, the input switch group at the time (0 ms) when the input is first recognized is A,
Set the second (20 ms) input switch group to B and the third (4 ms)
When the input switch group of 0 ms) is C, the formal input determination of the switches in the A group is the case where the Venn diagram of FIG. 1B is satisfied. In this case, since the input switch groups of the A group are present in each of A and B, the switch (non-touch switch 1) input of the A group is determined to be the official input.

A that does not satisfy the Venn diagram of FIG.
When there is a switch in the group, the input to the non-touch switch 1 is not an official input, it is determined that noise is applied, and the process associated therewith is performed. Further, the switch inputs of the B group and the C group are determined to be noise. The arithmetic control circuit 10 constituting the control means controls the key scan and determines whether the switch input is formal input or noise input.

When the non-touch switch 1 is single, the relationship of A = B = C (the number is one) is satisfied. With this configuration, high-frequency noise (relay circuit, inverter lighting, etc.) can be differentiated from approaching conductors, and thus the probability of malfunction due to noise is reduced.

(Second Embodiment) FIG. 2 shows a second embodiment. As shown in the figure, a noise detection reference value is provided above and below the input determination reference value of the switch input. A level equal to or higher than the noise detection reference value is a noise area, and a level equal to or lower than the noise detection reference value is a noise area. The non-noise region is between the two noise detection reference values, and it is determined whether the switch input is formal or due to noise.

Next, a detailed description will be given. The reference value for input detection and the reference value for noise detection (the value does not change for each non-touch switch 1) are key-scanned alternately, and the non-touch switch 1 in which the peak value above the reference value for noise detection is confirmed is Is determined to be applied and processed. In addition, the non-touch switch 1 in which the reference value for input detection and the reference value for noise detection (the value is unchanged for each non-touch switch 1) are alternately key-scanned, and the peak value below the reference value for noise detection is confirmed, , Judge that noise has been applied and process.

Further, the reference value is alternately scanned for input detection, noise detection reference value, and noise detection reference value (the value is unchanged for each non-touch switch 1), and the value is equal to or larger than the noise detection reference value, or The non-touch switch 1 whose peak value is lower than the noise detection reference value is
It is determined that noise has been applied, and processing is performed. Therefore, if it is detected between the noise detection reference value and the noise detection reference value, it is determined to be a formal input. The arithmetic control circuit 10 performs the above control and judgment.

(Embodiment 3) By the way, when the band of the feedback signal from the non-touch switch 1 is around 200 KHz, a filter for removing the other band is constructed by hardware, and noise is removed by using this filter. This is the case with this embodiment. As shown in FIG. 3, the filter is installed in the circuit on the back surface of the non-touch switch 1 including the transistor Q or in the preceding stage. Further, the filter is installed in the DC component removing circuit 11 or in the preceding stage thereof, and further, the filter is installed in the amplifying circuit 12 or in the preceding stage thereof. Further, the above filter may be installed in the peak hold circuit 13 or in the preceding stage. Furthermore, a combination of the above installation locations may be used.

[0022]

As described above, the present invention forms a non-touch switch for detecting the on / off of the input by detecting the change of the electrostatic capacitance by using the plate capacitor, and the non-touch switch has a constant sampling period. Key scan, and if the same non-touch switch confirms continuous input at any number of times, it is judged to be formal input, and non-touch switch for which continuous input is not recognized at any number of times is judged to have noise applied. Since the same non-touch switch is confirmed to be a formal input when the continuous input is confirmed at any number of times, the non-touch switch that does not recognize continuous input at any number of times is noisy. It is possible to accurately distinguish between the formal input and the input due to noise by determining that the noise is applied, and therefore In which it is provided an advantage of being able to reduce the probability of occurrence of malfunction due.

In the second aspect, a variation area of the output level due to the approach and contact of the conductor is set in advance, and it is determined that noise is applied when the output level is a level other than the variation area. Since the control means is provided, it is determined that noise is applied when the output level is in a level other than the above-mentioned fluctuation region, thereby accurately differentiating between formal input and noise input. Therefore, the probability of malfunction due to noise can be reduced.

Further, in the present invention, since the filter for removing the signal band other than the signal band possessed by the feedback signal from the non-touch switch is provided at an arbitrary position after the non-touch switch, the non-touch can be performed by the filter. By removing the signal band other than the signal band that the feedback signal from the switch has, it is possible to accurately differentiate between the formal input and the input due to noise, thus reducing the probability of malfunction due to noise. Can be made

[Brief description of drawings]

FIG. 1 is an explanatory diagram of an example of the present invention.

FIG. 2 is an explanatory diagram of Example 2 of the above.

FIG. 3 is an overall block diagram of a non-touch switch device.

FIG. 4 is a plan view of a non-touch switch.

FIG. 5 is a circuit diagram of a non-touch switch.

FIG. 6 is a diagram showing an output waveform of a non-touch switch.

FIG. 7 is an explanatory diagram of a non-touch switch.

FIG. 8 is a diagram showing a case where non-touch switches are arranged in a matrix.

[Explanation of symbols]

 1 Non-touch switch

Claims (3)

[Claims] 1. A non-touch switch for detecting an ON / OFF of an input is formed by detecting a change in its capacitance using a flat plate capacitor, and the non-touch switch is key-scanned at a constant sampling cycle to obtain the same non-touch. A non-touch switch that has been determined to be a formal input when the switch has confirmed continuous input for any number of times and for which the continuous input has not been recognized for any number of times has a control means for judging that noise has been applied. Characteristic non-touch switch device. 2. A control means is provided in which a variation area of the output level due to the approach and contact of the conductor is set in advance and noise is applied when the output level is a level other than the variation area. The non-touch switch according to claim 1, wherein: 3. The non-touch switch device according to claim 1, wherein a filter for removing a signal band other than the signal band of the feedback signal from the non-touch switch is provided at an arbitrary position after the non-touch switch.