JP6194860B2 - Touch sensor - Google Patents

Description

  The present invention relates to a touch sensor that detects proximity or contact of a human body. More specifically, the present invention relates to a touch sensor that prevents erroneous detection of proximity or contact due to external noise by detecting external noise from the detection result of one detection electrode.

Conventionally, in various devices and equipment installed indoors / outdoors, in vehicles, etc., one or more detection electrodes are provided on the operation part operated by a person, and the capacitance for detecting the proximity or contact of a person's finger etc. A type touch sensor (also referred to as a touch switch) is widely used. In many touch sensors, the proximity or contact of a human body to a detection electrode is detected by measuring a change in capacitance between the floating capacitance or the ground generated in the detection electrode.
In such a touch sensor, if a change in the amount of electricity corresponding to the capacitance is simply observed and it is determined that there is a human body approaching or touching when the value exceeds a certain reference value, it is detected. When the level of capacitance generated on the electrode changes depending on the surrounding environment, etc., or when the amount of electricity detected changes due to the influence of external noise, there is a problem that erroneous determination of proximity or contact of the human body occurs. .
As a countermeasure against this problem, for example, a touch sensor device is known in which a dummy electrode for detecting the influence of environmental conditions such as noise is provided, and the sensitivity of the sensor is adjusted based on the amount of change in capacitance generated in the dummy electrode. (See Patent Document 1). This touch sensor device includes a detection electrode for detecting the proximity of a human body and the like and a dummy electrode for detecting noise. The capacitance is measured by switching the detection electrode and the dummy electrode with a multiplexer. When the change in the capacitance measured in (1) exceeds the threshold value, erroneous detection due to noise is prevented by discarding the measurement result of the electrode. This dummy electrode is disposed in the vicinity of the detection electrode and at a position where no proximity of the human body occurs.

JP 2010-20673 A

However, in the touch sensor device disclosed in Patent Document 1, a dummy electrode must be provided separately from the detection electrode. The detection electrode needs a certain area to obtain sufficient detection sensitivity, and the dummy electrode needs to be equal to or larger than the detection electrode in order to obtain electrostatic characteristics close to the detection electrode. . Further, the dummy electrode needs to be arranged at a position in the vicinity of the detection electrode that does not cause the proximity of the human body. For these reasons, there is a problem that the structure of the touch sensor device provided with the detection electrode and the dummy electrode becomes complicated and the size becomes large.
In addition, the touch switch device must include a noise detection circuit having excellent frequency response in order to detect noise. Furthermore, since the detection electrode and the dummy electrode have different wiring from each electrode to the multiplexer, it is difficult to make the capacitance measurement conditions the same. For this reason, when the measurement value fluctuates due to the influence of the change in the electric field that becomes noise, the influence of the noise may not be accurately detected.
Therefore, the present inventor attempted a method of determining the presence or absence of external electromagnetic noise using only one detection electrode, and tried to prevent erroneous determination of the touch sensor due to external noise. However, depending on the magnitude of the external noise, it may be determined that there is a human touch due to the noise.

  The present invention has been made in view of the above circumstances, and detects proximity or contact of a human body using one detection electrode and detects external electromagnetic noise, thereby preventing erroneous determination of proximity or contact due to external noise. An object is to provide a touch sensor.

In order to solve the above-described problems, the first invention provides a connection between a detection electrode that is a conductor that is close to or in contact with a human body, a power source for charging a capacitance generated in the detection electrode, and the detection electrode. Switch means for switching to a charged state in which the power is supplied to the detection electrode or a floating state in which the detection electrode and the power source are disconnected, and an amount of electricity corresponding to the capacitance of the detection electrode, An electric quantity detecting means for measuring an electric quantity at the time of charging in a charging state and measuring an electric quantity at the time of floating in the floating state, and applying a first-order lag filter process to the signal of the floating electric quantity, Filter means for generating, peak hold means for generating a peak signal that holds the peak value of the floating electricity quantity for each period of a predetermined period, and the charge state and the previous state by the switch means. A determination means for alternately switching between a floating state and determining proximity or contact of a human body based on the change in the amount of electricity during charging and the change in the amount of electricity during floating measured by the amount of electricity detection means. The gist of the present invention is that, when the first-order lag signal intersects the peak signal, it is judged that there is no human body approaching or touching.
The gist of a second aspect of the present invention is that, in the first aspect, the predetermined period in which the peak value of the floating quantity of electricity is held is equal to or less than a quarter of a time constant of the first-order lag filter.
In a third aspect based on the first aspect or the second aspect, the peak hold means outputs two peak signals holding the maximum value and the minimum value of the floating electricity quantity for each period of the predetermined period as the peak value. The gist of the present invention is that, when the first-order lag signal intersects at least one of the two peak signals, the determination means determines that there is no human body approaching or touching.
According to a fourth invention, in any one of the first to third inventions, the determining means determines that there is no proximity or contact of a human body in a predetermined period before and after the time when the first-order lag signal crosses the peak signal. The gist is to do.
According to a fifth invention, in any one of the first to fourth inventions, the determination means is such that the charge electricity amount exceeds a predetermined threshold, and the floating electricity amount or a variation thereof is within a predetermined range. The gist of the present invention is that when there is no intersection between the first-order lag signal and the peak signal, it is determined that there is a human body approaching or contacting.

According to the touch sensor of the present invention, the detection electrode, which is a conductor that is close to or in contact with the human body, and the power supply for charging the capacitance generated in the detection electrode and the connection circuit between the detection electrode, Switch means for switching to a charged state in which the power is supplied to the detection electrode or a floating state in which the detection electrode and the power source are disconnected, and an amount of electricity corresponding to the capacitance of the detection electrode An electric quantity detecting means that measures the quantity as a floating electric quantity in the floating state, and the switch means alternately switches between the charged state and the floating state, and is measured by the electric quantity detecting means. A determination means for determining the proximity or contact of the human body based on the change in the amount of electricity during charging and the change in the amount of electricity when floating, only one detection electrode is used It is possible to measure the change in the amount of electricity generated in the detection electrode due to the human body and the external noise under the same conditions, detect the proximity or contact of the human body in the charged state, and detect the external noise in the floating state. be able to. Further, it is not necessary to provide a special circuit for detecting external noise, and the structure can be made simple and a small touch sensor.
Then, a filter means for generating a first-order lag signal by applying a first-order lag filter process to the floating-electric-quantity signal, and generating a peak signal that holds the floating-electric-quantity peak value every predetermined period And a peak hold means for measuring when the first-order lag signal intersects the peak signal, so that it is determined that there is no proximity or contact with a human body, and is measured in a charged state and a floating state. Even in a relatively weak noise environment that shows different fluctuations in the amount of electricity, it is possible to determine whether fluctuations in the amount of electricity in the floating state are due to the effects of noise, and stable or close proximity to the human body. It becomes possible to prevent erroneous determination.

When the predetermined period in which the peak value of the floating amount of electricity is held is equal to or less than one-fourth of the time constant of the first-order lag filter, the first-order is reliably ensured when there is a relatively weak external noise. The delay signal and the peak signal can be set to cross each other.
The peak hold means generates two peak signals that hold the maximum value and minimum value of the floating electricity quantity for each period of a predetermined cycle as the peak value, and the determination means determines that the first-order lag signal is the 2 If it intersects with at least one of the two peak signals, it can be determined that there is no proximity or contact with the human body, and if there is an external noise effect, the intersection between the first-order lag signal and at least one of the peak signals can be detected. Therefore, it is possible to prevent erroneous determination of the proximity or contact of the human body more reliably.
In the case where it is determined that there is no human body approaching or touching in a predetermined period before and after the time when the first-order lag signal intersects the peak signal, the determination means may determine whether the human body has Since it is not determined that there is a contact, it is possible to prevent a human body from approaching or an erroneous determination of contact more stably.
The determination means, when the charge electricity amount exceeds a predetermined threshold, the floating electricity amount or its fluctuation amount is within a predetermined range, and there is no intersection between the primary delay signal and the peak signal, If it is determined that there is a human body approaching or touching, the amount of floating electricity or its fluctuation amount exceeds a predetermined range in a relatively strong noise environment, and the first-order lag signal and the peak signal in a relatively weak noise environment. Since the intersection is detected, it is possible to prevent erroneous determination of the proximity or contact of the human body in a wider noise environment.

The present invention will be further described in the following detailed description with reference to the drawings referred to, with reference to non-limiting examples of exemplary embodiments according to the present invention. Similar parts are shown throughout the several figures.
It is a block diagram showing the structural example of a touch sensor. It is a block diagram for demonstrating the circuit structure in a charge state. It is a block diagram for demonstrating the circuit structure in a floating state. It is a block diagram for demonstrating the circuit structure in a discharge state. It is the graph which measured the change of the amount of electricity in a charge state, and the change of the amount of electricity in a floating state when there was proximity or contact of a human body when there was no external noise. It is the graph which modeled the change of the electric quantity in a charge state, and the change of the electric quantity in a floating state when there is comparatively strong external noise and there is no proximity or contact of a human body. It is the graph which measured the change of the electric quantity in a charge state, and the change of the electric quantity in a floating state, when there is a comparatively weak external noise and there is no proximity | contact or contact of a human body. It is the graph which measured the fluctuation | variation of the signal of the electric quantity at the time of a floating in the floating state by a comparatively weak external noise, a primary delay signal, and a peak signal (a maximum value signal and a minimum value signal). FIG time t ₁ in 8 - is a graph enlarged between time t _2. It is a graph which shows the fluctuation | variation of the signal of the electric quantity at the time of floating, the first order lag signal, and the peak signal (maximum value signal and minimum value signal) when the external noise larger than the case of FIG. 8 is added. It is a graph which shows the fluctuation | variation of the signal of the electric quantity at the time of floating, the first order lag signal, and the peak signal (the maximum value signal and the minimum value signal) when there is no external noise and the human body approaches or touches.

Hereinafter, the present invention will be described in detail with reference to the drawings.
The items shown here are for illustrative purposes and exemplary embodiments of the present invention, and are the most effective and easy-to-understand explanations of the principles and conceptual features of the present invention. It is stated for the purpose of providing what seems to be. In this respect, it is not intended to illustrate the structural details of the present invention beyond what is necessary for a fundamental understanding of the present invention. It will be clear to those skilled in the art how it is actually implemented.

1. Configuration of Touch Sensor The touch sensor according to the present embodiment includes a detection electrode in an operation part provided in various devices / equipment provided in indoors and outdoors, vehicles, and the like, and is applied to the detection electrode of a human body (such as a user's finger). Detect proximity or touch. The “proximity” of the human body to the detection electrode includes not only a form in which the palm or finger of the human body is brought close to the surface of the detection electrode, but also a form in which the human body contacts via an insulator covering the surface of the detection electrode. "Is intended to be a form in which the human body directly contacts the surface of the sensing electrode. This proximity or contact to the detection electrode is hereinafter referred to as “touch”.

  FIG. 1 is a block diagram illustrating a configuration of a touch sensor according to the present embodiment. The touch sensor 1 is provided in a detection circuit 3 that is a conductor that can be touched by a human body 9, and a connection circuit 21 between the power source 2 and the detection electrode 3 for charging a capacitance generated in the detection electrode 3. Switch unit 4 for switching to a charged state (S1) for supplying power source 2 to 3 or a floating state (S2) in which detection electrode 3 and power source 2 are disconnected, and charging the amount of electricity corresponding to the capacitance of detection electrode 3 An electric quantity detector 5 that measures the amount of electricity during charging in the state S1 and measures the amount of electricity as floating in the floating state S2, and performs a first-order lag filtering process on the signal of the floating amount of electricity to generate a first-order lag signal. The filter means 6 to be generated, the peak hold means 7 to generate a peak signal that holds the peak value of the floating electric quantity every period of a predetermined period, and the charging state S1 and the floating state S2 by the switch means 4 Alternately switching, and a change of the electric charge amount time electricity measured by the detector 5 and the change in the floating time electricity, the determining means 8 of the human body touch based on the. The touch sensor 1 is supplied with power from a power source (not shown) for operating each of the above means.

The detection electrode 3 is a conductor on which the human body 9 is disposed so as to be touchable on the surface or via an insulating layer. The material of the conductor is not particularly limited, and a conductive cloth or the like may be used in addition to the metal. The stray capacitance generated in the detection electrode 3 and the capacitance (Cx) between the detection electrode 3 and the ground (ground) change depending on whether or not a human body is touched. In addition, when electromagnetic noise from peripheral commercial power supply, electric power device, electronic device or the like is generated, an electrical signal is generated in the detection electrode 3 by inducing noise or the like through space or a human body. The touch sensor 1 is configured to detect an electrical signal generated by a change in capacitance due to a touch of a human body and external noise by the same means.
The shape, size, structure and the like of the detection electrode 3 are not particularly limited. In addition, regardless of the number of detection electrodes 3 provided in the operation portion, a plurality of detection electrodes 3 are provided, and a switch means 4 is provided for each detection electrode 3 so that a touch is determined for each detection electrode 3. be able to.

  The power source 2 is a power source for charging the capacitance generated in the detection electrode 3. The detection electrode 3 can be electrically connected to the power source 2 via the connection circuit 21. The voltage, type, and the like of the power source 2 are not particularly limited as long as the capacitance of the detection electrode 3 can be charged, but it is preferable to use a DC power source (Vcc).

  The connection circuit 21 is an electric circuit that connects the detection electrode 3 to the power source 2 and the electric quantity detection means 5. The specific configuration is not particularly limited, and the capacitance of the detection electrode 3 can be charged by switching, and the amount of electricity corresponding to the capacitance generated in the detection electrode 3 can be measured by the amount-of-electricity detection means 5. I just need it. In this example, the detection electrode 3 is configured to be connectable to the power supply 2 via a capacitor C1 and a resistance element in series. The detection electrode 3 can be connected to the electric quantity detection means 5 through a resistance element in series.

The switch means 4 is a switch circuit provided for connecting and disconnecting at least the detection electrode 3 and the power source 2. The switch means 4 has two states: a charged state S1 in which the detection electrode 3 and the power source 2 are electrically connected via the connection circuit 21, and a floating state S2 in which the detection electrode 3 and the power source 2 are electrically disconnected. The state is configured to be switchable. In this example, the switch means 4 includes a switch SW1 that connects and disconnects the power source 2 and the detection electrode 3 via the connection circuit 21. In addition, the switch means 4 includes a switch SW2 that connects the detection electrode 3 and the electric quantity detection means 5 via the connection circuit 21 or connects the detection electrode 3 to the ground potential via the connection circuit 21. Can do.
The types of the switches SW1 and SW2 are not particularly limited. The switch means 4 (switches SW1 and SW2) are configured to be switched by the determination means 8, respectively.

The charging state S1 refers to a state in which the detection electrode 3 and the power source 2 are electrically connected by the connection circuit 21 and the capacitance generated in the detection electrode 3 is charged by the power source 2. The floating state S2 is a state where the detection electrode 3 and the power source 2 are electrically disconnected.
2 and 3 show circuit configurations of the charging state S1 and the floating state S2 in this example. As shown in FIG. 2, the charging state S <b> 1 is a state in which the power source 2 and the connection circuit 21 are connected by the switch SW <b> 1 (SW <b> 1 is turned on) and the detection electrode 3 is charged by the power source 2. On the other hand, as shown in FIG. 3, the floating state S2 is a state in which the power source 2 and the connection circuit 21 are disconnected by the switch SW1 (SW1 is turned off) and the detection electrode 3 is not charged by the power source 2. In this floating state S2, since the input of the electric quantity detection means 5 has a high impedance, the detection electrode 3 can be brought into an electrically floating state (floating potential).

  The switch means 4 can be configured to connect the detection electrode 3 to the ground potential (0 V) via the connection circuit 21 in the floating state S2. In this example, as shown in FIG. 3, when the switch SW1 is off, the detection electrode 3 is connected to the ground potential via the connection circuit 21 (resistive element and capacitor C1).

  Furthermore, the switch means 4 can be configured to be switchable to a discharge state (S3) that quickly discharges the capacitance generated in the detection electrode 3 and the electric charge accumulated in the capacitor C1. FIG. 4 shows a circuit configuration of the discharge state S3 in this example. The switch means 4 is provided with a switch SW2 for setting the discharge state S3. In the charging state S1 and the floating state S2, as shown in FIGS. 2 and 3, the detection electrode 3 can be connected to the electric quantity detection means 5 (SW2 is turned on) via the connection circuit 21. . In addition to the floating state S2, the detection electrode 3 can be connected to the ground potential (SW2 is turned off) via the connection circuit 21 (resistive element) by the switch SW2. If both the switches SW1 and SW2 are connected to the ground potential side as shown in FIG. 4, the charge accumulated in the capacitance Cx of the detection electrode 3 and the charge accumulated in the capacitor C1 are quickly discharged.

  1-4 measures the amount of electricity corresponding to the stray capacitance generated in the detection electrode 3 and the capacitance Cx between the detection electrode 3 and the ground (ground). It is configured. The amount of electricity corresponding to the capacitance Cx is not particularly limited, and can be, for example, the potential (voltage) of the detection electrode 3 with respect to the ground potential. The specific configuration of the electric quantity detection means 5 is not particularly limited. For example, the electric quantity detection means 5 is provided with an analog-digital converter (ADC) 51 or the like to convert the potential of the detection electrode 3 into a digital value. It can be configured to obtain a measured value of the electric quantity. The subsequent filter means 6 and peak hold means 7 can be configured to perform digital processing using the measurement value signal output from the electric quantity detection means 5. The period (sampling period) for digitally converting the amount of electricity by the AD converter 51 is not particularly limited, and can be, for example, about 0.5 to 2 ms.

When electromagnetic noise is present in the vicinity, an electrical signal is generated in the detection electrode 3 by inducing noise or the like directly through the space or through the human body. The electric quantity detection means 5 can measure the electric quantity generated in the detection electrode 3 due to external noise by the same circuit that measures the electric quantity corresponding to the capacitance.
It should be noted that the same effect can be obtained even if an electric circuit or the like is provided as the electric quantity detection means 5 and the filter means 6 and the peak hold means 7 are constituted by analog circuits.

  Usually, in the touch sensor, a filter (for example, a low-pass filter) process is performed in order to remove an external noise component from the detected electric quantity signal. The presence or absence of touch is determined by a method such as comparing the value of the signal from which the noise component has been removed by the filtering process with a threshold value. However, it is difficult to completely remove the influence of external electromagnetic noise by filtering. For this reason, in this touch sensor 1, the electric quantity detection means 5 measures the electric quantity generated in the detection electrode 3 as the electric quantity during charging in the charging state S1, and as the electric quantity during floating in the floating state S2. I have to. Filtering can be applied to the charge amount signal and the floating amount signal separately or in common. That is, it is possible to provide a charging time filter means for processing a charge time electric quantity signal and a floating time filter means for processing a floating time electric quantity signal, each having different characteristics. Further, the charging time filter means and the floating time filter means may be a single filter means so as to perform a common filtering process. The determination means 8 to be described later is configured to determine the presence or absence of a touch using a signal that has been filtered by the filter means in the charging state S1 and the floating state S2.

The filter means 6 shown in FIG. 1 and subsequent figures is configured to output a signal obtained by subjecting the output signal of the electric quantity detection means 5 (AD converter 51) to a first-order lag filter process as a first-order lag signal. The The time constant of the first-order lag filter can be appropriately set according to the type, intensity, frequency, etc. of the external noise.
The filter means 6 may be common with the floating time filter means or may be provided separately. Further, the filter means 6 only needs to act on at least a floating amount of electricity signal, but may be configured to act on a charge amount of electricity signal in common. That is, the filter means 6 that performs the first-order lag filter processing can be used as the charging time filter means and the floating time filter means.

The peak hold means 7 is a means for generating a peak signal that holds the peak value of the floating electricity quantity every predetermined period. The peak hold means 7 can generate a peak signal (maximum value signal) that holds the maximum value of the floating electricity quantity in each period of the predetermined period. Further, it is possible to generate a peak signal (minimum value signal) that holds the minimum value of the floating electricity quantity in each period of the predetermined cycle. The peak hold means 7 may be configured to generate two peak signals of the maximum value signal and the minimum value signal as peak signals, or may be configured to generate one of them.
The predetermined period for holding the peak value of the floating electricity quantity may be set as appropriate, but is preferably set to a quarter or less of the time constant of the first-order lag filter provided in the filter means 6. Moreover, it is preferable that the said predetermined period shall be 10 times or more (for example, 20-50 times) of the said sampling period in the electric quantity detection means 5. FIG.

  The determination unit 8 can be configured to switch between the charged state S1 and the floating state S2 by controlling the switch unit 4. The timing for switching each state, the switching cycle, the time for which each state is continued, and the like can be selected as appropriate. The determination means 8 is generated by the filter means 6 by sampling the amount of electricity generated in the detection electrode 3 using the electricity amount detection means 5 at a constant period in each period of the charging state S1 and the floating state S2. The first-order lag signal and the peak signal generated by the peak hold means 7 are input. Further, when a filter unit different from the filter unit 6 is provided, a signal generated by the other filter unit can be input.

Then, the determination unit 8 alternately switches between the charging state S1 and the floating state S2, and changes between a change in the electricity amount during charging measured in the charging state S1 and a change in the electricity amount during floating measured in the floating state S2. Based on this, it is configured to determine whether or not a human body is touched.
Further, when the primary delay signal crosses the peak signal (maximum value signal and / or minimum value signal), that is, when the magnitude relationship between the primary delay signal and the peak signal changes, the determination means 8 Since there is a possibility of being affected by external noise, it is configured to determine that there is no human touch. Here, regardless of the method of “determining that there is no touch”, a method of prohibiting or invalidating the determination that there is a human touch, a method of stopping the determination, a method of prohibiting output of the determination result to the outside, etc. It is done.
It is preferable that the determination unit 8 is configured not to determine that there is a human touch in a predetermined period (prohibition period) before and after the time when the first-order lag signal intersects the peak signal. The prohibition period can be set as appropriate, and can be, for example, between −40 ms and +40 ms, based on when an intersection occurs.

The above electric quantity detection means 5, filter means 6, peak hold means 7 and determination means 8 may be realized by either hardware or software, and preferably a CPU, memory (ROM, RAM, etc.) not shown. It can be configured by providing peripheral circuits such as an input / output interface around a microcontroller (microcomputer) including an input / output circuit. Alternatively, a programmable logic circuit, a gate array, or other logic circuit may be used. An AD converter 51 or the like may be incorporated in this microcontroller or the like.
When the determination means 8 is electrically connected to various devices / equipment (for example, lighting, air conditioning, AV equipment, automatic opening / closing window, etc.) and determines that there is a human body touch on the detection electrode 3, The proximity detection signal S for performing the determination or the operation based on the determination can be configured to be output to these devices.

2. Action of Touch Sensor (1) Measurement Processing in Charging State The stray capacitance generated in the detection electrode 3 and the capacitance Cx between the detection electrode 3 and the ground (ground) vary depending on whether or not the human body 9 is touched. For this reason, the presence or absence of the touch of the human body 9 can be detected by measuring the charge (or discharge) characteristics of the capacitance Cx generated in the detection electrode 3.
The touch sensor 1 can measure the amount of electricity (the potential of the detection electrode 3) corresponding to the capacitance Cx generated in the detection electrode 3 in the charging state S1 in which the power source 2 is connected to the detection electrode 3. Then, for example, the determination unit 8 compares the measured value with a predetermined threshold value, and when it exceeds the threshold value, it can be detected that there is a touch (a touch may be made). Further, when the threshold value is exceeded for a certain time or more, it may be detected that there is a touch. Not limited to this, the determination unit 8 may detect the presence or absence of touch by measuring a time (time constant) during which the potential rises to a predetermined value after the start of the charging state S1.

  Specifically, in the circuit in the charging state S1 shown in FIG. 2, the switch SW1 of the switch means 4 is turned on (connected to the power supply 2 side), and current is detected from the power supply 2 via the switch SW1 and the connection circuit 21. The electrostatic capacity Cx flowing in the electrode 3 and occurring in the detection electrode 3 is charged. Since the amount to be charged varies depending on the capacitance Cx of the detection electrode 3 and the like, this is measured by the electric quantity detection means 5. The electric quantity detection means 5 is connected to the detection electrode 3 via the connection circuit 21 and can measure the potential (Vd) of the detection electrode 3. When the supply voltage of the power supply 2 is Vcc, since the voltage is divided by the capacitance Cx of the capacitor C1 and the detection electrode 3, the potential Vd = Vcc · C1 / (C1 + Cx) detected by the electric quantity detection means 5 is obtained. . As the human body 9 approaches, the capacitance Cx between the detection electrode 3 and the ground increases, so the measured potential Vd decreases. The measured charge electricity quantity is subjected to noise removal by the charge filter means or filter means 6 and sent to the determination means 8.

  Usually, in addition to the presence or absence of a touch, the amount of electricity at the time of charging generated in the detection electrode 3 varies depending on the environment such as temperature and humidity, and as a result, the level of the measurement value by the amount of electricity detection means 5 varies. For this reason, it is preferable that the determination unit 8 is configured to sequentially calculate and set the threshold value for detecting the presence or absence of the touch based on the temporal variation of the measurement value. In order to detect the presence or absence of touch more reliably, various detection methods such as detecting that there is a touch when the measured value exceeds a certain time threshold can be applied.

(2) Measurement process in floating state On the other hand, when there is electromagnetic noise around the detection electrode 3, a change in the amount of electricity occurs in the detection electrode 3 due to the noise. In an environment with external noise, the amount of electricity measured for the detection electrode 3 is superimposed with the amount of electricity corresponding to the capacitance Cx that changes depending on whether or not the human body is touched, and the amount of electricity generated by the noise. Become. Therefore, when there is external noise, the change in the amount of electricity due to the noise is superimposed on the change in the amount of electricity during charging in the charging state S1. For this reason, in the measurement performed in the charging state S1, when there is external noise, the measured value of the amount of electricity at the time of charging fluctuates, and there is a case where it is erroneously detected that there is a human touch.

For this reason, the touch sensor 1 measures the floating electricity amount (the potential of the detection electrode 3) generated in the detection electrode 3 even in the floating state S2 in which the power source 2 is disconnected from the detection electrode 3. The measurement in the charging state S1 and the measurement in the floating state S2 are preferably performed repeatedly in succession.
In the floating state S2, as shown in FIG. 3, the switch SW1 of the switch means 4 is turned off, and the detection electrode 3 is not charged by the power source 2. When switching from the charging state S1 to the floating state S2, the detection electrode 3 is charged in the charging state S1. Even if the human body 9 approaches the detection electrode 3 at this time, the detection electrode 3 is not further charged, so that the change in the floating electricity amount corresponding to the change in the capacitance Cx does not occur. And since one end of the capacitor C1 and the detection electrode 3 is connected to the electric quantity detection means 5, if the electric field by external noise is added to the detection electrode 3, the electric potential of the detection electrode 3 will change by it (refer FIG. 6). . That is, it can be considered that the change in the amount of electricity measured in the floating state S2 is mainly caused by external noise.

(3) Determination process 1
The determination unit 8 can repeatedly switch between the charging state S1 and the floating state S2 for a certain time, and sample and acquire the amount of electricity generated in the detection electrode 3 in each state. In addition, when switching from the charged state S1 to the floating state S2, the discharge state S3 is once set, and the capacitance charged in the charged state S1 can be quickly discharged (see FIG. 4). As a result, the influence of accumulated charges in the floating state S2 can be eliminated, and the influence of noise can be measured more reliably.

The determination unit 8 determines the influence of noise based on the amount of electricity measured in the charging state S1 or the change thereof and the amount of electricity measured in the floating state S2 or the change thereof, and determines whether or not the human body is touched. To be able to.
For example, when it is detected that there is a human touch from the measurement value in the charging state S1, and it is detected that there is no influence of noise from the measurement value in the floating state S2, it is determined that there is a human touch. can do. That is, even if it is detected that there is a touch from the measurement value in the charging state S1, if there is an external noise from the measurement value in the floating state S2, there is finally a human touch. It can be made not to judge. Thereby, the erroneous determination of the touch of the human body due to the influence of external noise can be prevented.

5 and 6 are graphs simulating changes in the measured value of electricity (charged electricity) in the charging state S1 and changes in the measured value of electricity (floating electricity) in the floating state S2. The amount of electricity during charging is a value corresponding to the capacitance Cx generated in the detection electrode 3 when there is no external noise because the detection electrode 3 is charged by the power source 2. The lower part of the figure corresponds to a larger capacitance Cx. Here, determination unit 8, the charge time electricity exceeds a threshold value Th ₁ (below) when it is assumed to detect that there is a touch.
In addition, since the detection electrode 3 is separated from the power source 2 and is in a floating state, the floating electricity amount does not change greatly in the measured electricity amount if there is no external noise or the like. Here, determination unit 8, floating time electricity exceeds a threshold value Th ₂ (below) when it is assumed to detect that there is a noise.
FIGS. 5 and 6 are diagrams continuously showing the time change of the measurement value of the electric quantity (after the filter process) in the charging state S1 and the floating state S2, and the touch sensor 1 actually floats in the charging state S1. The timing for switching the state S2, the repetition period thereof, the sampling period of electric quantity, and the like can be set as appropriate.

FIG. 5 shows measured values when a human body touches when there is no external noise. In this figure, the detection electrode 3 is touched with a finger at times t ₁ , t ₂ , t ₃ and t ₄ . When a touch is, charging time electricity exceeds a threshold value Th ₁ (below) for, determining means 8 detects that there is a touch. Meanwhile, since the floating time electricity is within a predetermined range (threshold value Th ₂ or more), the noise is detected as no. Based on the detection result in the charging state S1 and the detection result in the floating state S2, the determination unit 8 can determine that there is a touch at times t ₁ , t ₂ , t ₃ and t ₄ .

FIG. 6 shows an example where no touch is made and there is external noise. In this figure, since the amount of electricity at the time of charging is affected by noise and changes beyond the threshold value Th ₁ in the period t _n , the determination unit 8 detects that there is a touch. On the other hand, the amount of electricity at the time of floating also changes greatly during the period t _n due to the influence of noise, indicating a change exceeding the predetermined range (below the threshold Th ₂ ). For this reason, the determination means 8 can invalidate the detection that there is a touch in the period t _n and can not determine that there is a touch.

As described above, whether or not a human body is touched can be detected based on a change in the amount of electricity during charging measured in the charging state S1, but the measured value of the amount of electricity during charging changes due to external noise. In such a case, it is necessary not to determine that there is a touch. The external noise that affects the determination can be detected by the change in the floating electricity amount at the same time when the touch is detected from the measured value of the charging electricity amount. That is, when the amount of electricity in floating or the amount of change thereof is within a predetermined range, it can be determined that there is no external noise that affects the determination.
For example, when the measurement value of the floating electricity amount exceeds a predetermined threshold value, it is possible to detect that there is noise and invalidate the detection based on the electricity amount during charging that there is a human touch. Also, when the amount of change in the measured value of the floating electricity amount exceeds a predetermined range, it is detected that there is noise, and the detection based on the electricity amount during charging that there is a human touch is invalidated. You can also. In addition, as shown in FIG. 6, when there is a correlation between the temporal change in the measured value of the charge electricity amount and the temporal change in the measured value of the floating electricity amount, it is detected that there is noise. Also good.

(4) Determination process 2
However, the level of floating electricity measured in the floating state S2 changes due to changes in environmental conditions, changes in detection sensitivity due to the detection electrodes 3, and the like. Further, due to the limitation of the measurement range of the electric quantity detection means 5, the electric quantity generated in the detection electrode 3 may not be accurately measured as a floating electric quantity. In such a case, it becomes difficult to detect the presence or absence of noise based on the measured value of the floating electric quantity and the amount of change as described above.
For example, FIG. 7 shows a signal of charge electricity amount and floating electricity amount when relatively weak noise is applied to the detection electrode 3 at times t _n1 , t _n2, and t _n3 , and after filtering processing for each. Represents the signal. As noise, high-frequency noise having a frequency of 120 MHz and an electric field strength of 100 V / m is radiated from an antenna placed at a distance of 1 m from the detection electrode 3 (the same applies in the following examples). In this example, when there is noise, both the amount of electricity during charging and the amount of electricity during floating change greatly. In addition, since the signal level of the floating amount of electricity is low and the amount of electricity is converted using the unipolar AD converter 51, the measured value has a fixed value (zero) as the lower limit (in the following example) The same). In such a case, it is difficult to determine whether the human body is touched.

FIG. 8 shows the fluctuation of the floating electric quantity signal, the first-order lag signal, and the peak signal (maximum value signal and minimum value signal) when there is no human touch and there is noise. FIG. 9 is an enlarged view between the times t ₁ and t ₂ in FIG. The peak signal is generated while holding the maximum value and the minimum value in each period of a predetermined cycle. In this example, the determination means 8 performs the first-order lag signal (and the measured value of the floating-time electric quantity). The processing is performed by shifting the time axis by one period and superimposing the same (in the following examples).

In the example shown in FIG. 8 and FIG. 9, there is noise in the period t _n , thereby causing a cross between the first-order lag signal and the peak signal at the points X1, X2, and the like. That is, at the point X1, the value of the first-order lag signal thereafter crosses so as to exceed the value of the peak signal (maximum value signal), and at the point X2, the value of the first-order lag signal thereafter becomes the peak signal (maximum value signal). Crossing below the value. In order to detect the presence or absence of the influence of noise, how to select or combine the direction of intersection with the maximum value signal, the minimum value signal, the first-order lag signal, or the like can be appropriately determined. For example, it may be detected based on whether or not an intersection has occurred so that the value of the primary delay signal exceeds the value of the peak signal (maximum value signal), or the primary delay signal and the peak signal (maximum value) regardless of the direction of the intersection. The signal and the minimum value signal) may be detected based on whether or not an intersection has occurred.

FIG. 10 shows a signal of a floating electric quantity, a first-order lag signal, and a peak signal (maximum value signal and minimum value signal) when extraneous noise larger than that shown in FIG. 8 is applied to the periods t _n1 and t _n2 . It represents the fluctuation. As described above, the floating electric quantity is a value converted by the electric quantity detection means 5 (unipolar AD converter), so that the fluctuation reaches the lower limit of the conversion range when noise is added (L point). A first-order lag signal and a peak signal are generated using the limited value of the floating electric quantity. In such a case, simply detecting the human touch based on the measured change in the amount of electricity during charging and change in the amount of electricity during floating (see FIGS. 5 and 6) is a variation caused by noise. Nevertheless, there is a risk of erroneous determination that a human body touched.

In the above case, the influence of noise can be detected based on whether or not an intersection between the first-order lag signal and the peak signal of the floating electricity quantity has occurred. In FIG. 10, the first-order lag signal of the floating electricity quantity crosses the peak signal (maximum value signal) at five points (X1 to X5).
On the other hand, FIG. 11 shows that there is no noise and the human body touch (time t ₁ , t ₂ , t ₃ , t ₄ , t ₅ ), the signal of the electric quantity at the time of floating, the first order lag signal and the peak signal (maximum Value signal and minimum value signal). As is apparent from this figure, there is no crossing between the first-order lag signal of the floating electricity quantity and the peak signal (maximum value signal and minimum value signal).

Accordingly, when the first-order lag signal and the peak signal of the floating amount of electricity occur, even if the measurement range of the amount-of-electricity detection means 5 is limited by determining that it is not a human touch. An erroneous determination can be prevented. In order to detect noise, both the maximum value signal and the minimum value signal may be used as the peak signal, or one of them may be used.
Further, when an intersection between the first-order lag signal and the peak signal occurs, it can be prohibited to determine that there is a human touch in a predetermined period before and after that point.

As described above, the presence / absence of a touch on the human body can be determined by the determination unit 8 based on various criteria. For example,
(A) When there is a period in which the amount of electricity during charging exceeds a predetermined threshold and there is no intersection between the first-order lag signal of the floating amount of electricity and the peak signal in the period, it is determined that there is a human touch. it can.
(B) There is a period in which the amount of electricity during charging exceeds a predetermined threshold value, the amount of floating electricity or the amount of fluctuation thereof is within a predetermined range, and the intersection of the primary delay signal and the peak signal in the amount of floating electricity If there is no touch, it can be determined that there is a human touch.
(C) When there is a period in which the amount of electricity at the time of charging exceeds a predetermined threshold and the amount of electricity at the time of floating or its fluctuation amount is within a predetermined range in that period, it is primarily determined that there is a human touch, When there is an intersection between the first-order lag signal of the floating electricity quantity and the peak signal, the primary determination can be invalidated.
The determination means 8 is not limited to this, and the determination means 8 can change the amount of electricity when charging, change of the amount of electricity when floating, and whether or not there is an intersection between the first-order lag signal and the peak signal. The presence or absence can be determined. When the determination unit 8 finally determines that there is a touch, the proximity detection signal S can be output to the outside.

  The present invention is not limited to the embodiment described above, and various modifications can be made within the scope of the present invention depending on the purpose and application. This touch sensor can be used for devices and devices installed indoors and outdoors, in addition to proximity sensors mounted on vehicles. In addition, it can be widely applied as a touch sensor for operating various devices and devices such as lighting, air conditioners, AV equipment, and electric devices.

  DESCRIPTION OF SYMBOLS 1; Touch sensor, 2; Charging power supply, 21; Connection circuit, 3; Detection electrode, 4; Switch means, 5: Electric quantity detection means, 6: Filter means, 7: Peak hold means, 8; ;human body.

Claims (5)

A sensing electrode that is a conductor that is close to or in contact with the human body;
A charging state provided in a connection circuit between the power source for charging the capacitance generated in the detection electrode and the detection electrode, and supplying the power source to the detection electrode, or a floating state in which the detection electrode and the power source are disconnected Switch means for switching to
An electric quantity detecting means for measuring an electric quantity corresponding to the capacitance of the detection electrode as an electric quantity at the time of charging in the charged state and measuring as an electric quantity at the time of floating in the floating state;
Filter means for generating a first-order lag signal by applying a first-order lag filter process to the floating-time electric quantity signal;
Peak holding means for generating a peak signal that holds the peak value of the floating electricity quantity for each predetermined period; and
The switch means alternately switches between the charging state and the floating state, and the proximity of the human body based on the change in the charging electricity quantity and the change in the floating electricity quantity measured by the electricity quantity detection means or Determining means for determining contact;
With
The said determination means determines that there is no proximity | contact or contact of a human body, when the said primary delay signal cross | intersects the said peak signal.   The touch sensor according to claim 1, wherein the predetermined period in which the peak value of the floating amount of electricity is held is equal to or less than a quarter of a time constant of the first-order lag filter. The peak hold means generates two peak signals holding the maximum value and the minimum value of the floating electricity quantity for each period of the predetermined period as the peak value,
The touch sensor according to claim 1, wherein the determination unit determines that there is no proximity or contact of a human body when the first-order lag signal intersects at least one of the two peak signals.   4. The touch sensor according to claim 1, wherein the determination unit determines that there is no proximity or contact of a human body in a predetermined period before and after the time when the first-order lag signal intersects the peak signal.   The determination means, when the charge electricity amount exceeds a predetermined threshold, the floating electricity amount or its fluctuation amount is within a predetermined range, and there is no intersection between the primary delay signal and the peak signal, The touch sensor according to claim 1, wherein the touch sensor determines that there is proximity or contact with a human body.

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