The present invention relates to an operation input device and a door handle.
On the door of a car, a door handle for opening and closing the door is provided on the outside of the car. A vehicle door opening/closing control device is disclosed (for example, Patent Document 1) that enables operation of the door of a car and the like without touching the door handle.
In such a vehicle door opening/closing control device, the operation such as opening/closing the door can be performed by touching the door handle and the like with a hand and moving the touching hand.
However, in the above-described vehicle door opening/closing control device, the door handle and the like reliably need to be touched with the hand, and the operation range is limited. In addition, when a variety of pieces of operation information is intended to be input, the vehicle door opening/closing control device is likely to be large in size, and the structure is likely to be complicate, thereby increasing a cost.
For this reason, there is a need for an operation input device having a simple structure and capable of inputting a variety of pieces of operation information without limiting a range of operation a lot.
Patent Document 1: Japanese Laid-Open Patent Application Publication No. 2009-79353
Patent Document 2: Japanese Laid-Open Patent Application Publication No. S60-254312
According to one embodiment of the present embodiment, there is provided an operation input device that includes a resistance element configured to generate a capacitance between an operating medium and the resistance element in response to an approach of the operating medium to the resistance element, and a power source configured to supply electric charge to one end and the other end of the resistance element. A first electric charge amount measuring unit is configured to measure a first electric charge transfer amount supplied to the one end of the resistance element in response to generation of the capacitance. A second electric charge amount measuring unit configured to measure a second electric charge transfer amount supplied to the other end of the resistance element in response to the generation of the capacitance. A controller is connected to the first electric charge amount measuring unit and the second electric charge amount measuring unit and is configured to detect a first position of the operating medium in a direction perpendicular to a surface of the resistance element based on a sum of the first and second electric charge transfer amounts.
An embodiment for carrying out is described below. The description of the same member and the like will be omitted by putting the same reference numerals.
An operation input device according to a first embodiment will be described. The operation input device according to the present embodiment is built in a door handle attached to a door of a car and the like, and has a function to input operation information.
Specifically, the operation input device according to the present embodiment is a door handle 100 attached to a door 10, such as a car, as shown in
In the present embodiment, as shown in
In the door handle 100 of the present embodiment, an AC voltage is applied to one end 110a of the sensor 110 from the first AC power source 131, and the amount of AC current supplied to one end 110a of the sensor 110 can be measured by the first current meter 121. Alternatively, an AC voltage is applied to the other end 110b of the sensor 110 from the second AC power source 132, and the amount of alternating current supplied to the other end 110b of the sensor 110 can be measured by the second current meter 122.
In the present embodiment, the first AC power source 131 and the second AC power source 132 output AC voltages having the same frequency, the same amplitude, and the same phase. In addition, the first AC power source 131 and the second AC power source 132 can be shared as a single power source. Accordingly, as shown in
In contrast, as shown in
Thus, the alternating current supplied from the first AC power source 131 passes through one end 110a of the sensor 110 to the location 110c of the sensor 110 closest to the finger 200. Accordingly, the alternating current supplied from the first AC power source 131 passes through the resistance formed between one end 110a of the sensor 110 and the location 110c of the sensor 110 closest to the finger 200. Also, the alternating current supplied from the second AC power source 132 passes through the other end 110b of the sensor 110 to the location 110c of the sensor 110 closest to the finger 200. Accordingly, the alternating current supplied from the second AC power source 132 passes through the resistance formed between the other end 110b of the sensor 110 and the location 110c of the sensor 110 closest to the finger 200. Accordingly, as shown in
Accordingly, as shown in
Thus, the value of the sum of the alternating currents Is (=Ia+Ib) is correlated with the distance Y between the sensor 110 and the finger 200. When the distance Y between the sensor 110 and the finger 200 is long, the sum of the alternating currents is small, and when the distance Y is short, the sum of the alternating currents is great. Specifically, it is noted that the sum Is of the alternating currents is inversely proportional to the power of the distance Y based on knowledge from experience, and the sum Is of the alternating currents and the distance Y between the sensor 110 and the finger 200 have the relationship shown in
As described above, the distance Y between the sensor 110 and the finger 200 can be calculated from the value of the sum Is of the alternating current Ia measured by the first current meter 121 and the alternating current Ib measured by the second current meter 122.
(Method of Detecting Position of Finger by Operation Input Device)
Next, a method for detecting a position of a finger by the operation input device according to the present embodiment will be described with reference to
First, in step 102 (S102), the alternating currents Ia, Ib are measured. Specifically, the alternating current Ia is measured by the first current meter 121, and the alternating current Ib is measured by the second current meter 122.
Next, in step 104 (S104), the sum of the alternating current Is (=Ia+Ib) is calculated from the alternating current la and the alternating current Ib.
Next, in step 106 (S106), the distance Y from the sensor 110 to the finger 200 is calculated from the sum of the alternating currents Is.
As described above, the position of the finger, that is, the distance Y from the sensor 110 to the finger 200 in the operation input device according to the present embodiment, can be calculated by the operation input device according to the present embodiment.
In the present embodiment, because the area of the sensor 110 is large and because the capacitance between the fingers 200 and the sensor 110 is great, the position of the finger can be detected with high accuracy.
The operation input device according to the present embodiment has a simple structure, and operation information can be input even when the finger 200 is separated from the sensor 110. Accordingly, the operable range of the finger 200 is not so limited, and a variety of pieces of operating information can be input.
Next, a second embodiment will be described. In the present embodiment, detection of a gesture by a finger and the like is performed by detecting the position of a finger in the X direction and the Y direction.
As shown in
When the same voltage is applied to a resistance element, a more current flows through a resistance element with a lower resistance value than a current that flows through a resistance element with a higher resistance value. Thus, when the position of the finger 200 approaching the sensor 110 is closer to one end 110a than the other end 110b of the sensor 110, the alternating current Ia flows more than the alternating current Ib. Also, when the position is closer to the other end 110b than to one end 110a, the alternating current Ib flows more than the alternating current Ia.
Specifically, when the finger 200 is present in the vicinity of one end 110a of the sensor 110 as shown in
In the meantime, even if the finger 200 is present in the vicinity of one end 110a of the sensor 110, when the distance Y between the sensor 110 and the finger 200 is long, as shown in
For example, as shown in
Therefore, when a distance Ya1 from one end 110a to the finger 200 of the sensor 110 is relatively close, because the difference between a distance Yb1 from the other end 110b to the finger 200 of the sensor 110 and the distance Ya1 is great, the ratio between the alternating current Ia and the alternating current Ib is great. As the finger 200 gets away from the sensor 110, the distance Ya2 from one end 110a to the finger 200 of the sensor 110 is lengthened; the difference between the distance Yb2 from the other end 110b to the finger 200 of the sensor 110 and the distance Ya2 is gradually decreased; and the ratio between the alternating current Ia and the alternating current Ib is gradually decreased. When the finger 200 farther gets away from the sensor 110, the difference between the distance Yb3 from the other end 110b of the sensor 110 to the finger 200 and the distance Ya3 is further decreased, and the ratio between the alternating current Ia and the alternating current Ib is further decreased.
That is, when the distance Ya is small, because the ratio between the distance Ya and the distance Yb is close to the ratio between the distances between the projection position of the finger to the sensor surface from the ends 110a and 110b of the sensor 110, the alternating currents Ia and Ib flow corresponding to the distances (the resistance value), and a relatively accurate distance X can be obtained from the value of Ib/Is. However, when the finger 200 much farther gets away from the sensor 110 and the distance Ya from the finger 200 increases, the influence of the three-dimensional distribution of the capacitance component increases, and the error between the value of the distance X obtained from the value of Ib/Is and the actual distance X increases.
For this reason, in the present embodiment, a correction coefficient E corresponding to the value of the distance Y is introduced, and correction is performed for the position of the finger 200 in the X direction. Specifically, the relationship between the distance Y and the correction coefficient E is shown in
(Method for Detecting Position of Finger by Operation Input Device)
Next, a method for detecting a position of a finger by the operation input device according to the present embodiment will be described with reference to
First, in step 202 (S202), the alternating currents Ia, Ib are measured. Specifically, the alternating current Ia is measured by the first current meter 121, and the alternating current Ib is measured by the second current meter 122.
Next, in step 204 (S204), the sum of the alternating currents Is (=Ia+Ib) is calculated from the alternating current Ia and the alternating current Ib.
Next, in step 206 (S206), the distance Y from the sensor 110 to the finger 200 is calculated from the sum of the alternating currents Is.
Next, in step 208 (S208), Ib/Is is calculated. Specifically, the Ib/Is is calculated by dividing the alternating current Ib by the sum of the alternating currents Is. In the present embodiment, the Ib/Is may be expressed as DX.
Next, in step 210 (S210), the correction coefficient E is calculated from the distance Y. Specifically, from the distance Y obtained in step 206, the correction coefficient E is calculated based on the relationship between the distance Y and the correction coefficient E as shown in
Next, in step 212 (S212), the distance X is calculated based on the correction coefficient E obtained in step 210. Specifically, the distance X from one end 110a of the sensor 110 is calculated by calculating the position index D from the equation shown in Formula 2 below and multiplying the length L by the position index D. The position index D represents the ratio of the distance X from one end 110a of the sensor 110 to the length L of the sensor 110 (the length between one end 110a and the other end 110b of the sensor 110). Formula 2 is an example of calculating the position index D, and the position index D is calculated by correcting the magnitude of the difference between the sensor center (position index 0.5) where the distance from both ends of the sensor 110 becomes equal and the actual measured position index DX while using the correction coefficient E.
Next, in step 214 (S214), the two-dimensional coordinate position of finger 200 is output. The distance X and the distance Y at this two-dimensional coordinate position are coordinate positions when one end 110a of the sensor 110 is made a reference.
Thus, the two-dimensional position of the finger 200 can be obtained by the operation input device according to the present embodiment.
Specifically, in steps S210 and S212, the position of the finger 200 in the direction parallel to the plane of the sensor 110 is detected by correcting the value (Ib/Is) of the alternating current Ib with respect to the sum of the alternating currents Is obtained from the alternating current Ia and the alternating current Ib based on the ratio between the distance Ya from one end 110a of the sensor 110 to the finger 200 that is an operating medium and the distance Yb from the other end 110b of the sensor 110 to the finger.
By repeating the detection of the two-dimensional position of the finger 200 in the above procedure, the trajectory of finger 200 can be detected, and the gesture detection of the finger can be performed. This allows a gesture input of the finger 200.
In the resent embodiment, as shown in
Because the operation input device according to the present embodiment can detect a movement of the finger 200 in two dimensions, various gesture inputs can be performed.
The descriptions other than the above are the same as those of the first embodiment.
Next, a third embodiment will be described. In the present embodiment, an integrated circuit 160 is mounted on the back side of the sensor 110 as shown in
In the present embodiment, an alternating current having the same phase and the same amplitude of voltage as alternating currents supplied from the first AC power source 131 and the second AC power source is supplied to the shield electrode 170. This can reduce the influence of a noise from the back side of the sensor 110 and can increase the dynamic range, thereby improving the sensitivity of the sensor 110.
The descriptions other than the above are the same as those of the first and second embodiments.
In the embodiment, the case where the AC power source is connected to the end of the sensor that is substantially at the end of the substrate has been described, but it may be connected to an intermediate location of the sensor. In such a case, the connection location corresponds to the end of the sensor in the embodiment described above.
As described above, according to the disclosed operation input device of the embodiments, the operation input device has a simple structure, and can input a variety of pieces of operation information without significantly limiting a range of operation.
The embodiments have been described in detail above, but are not limited to any particular embodiment, and various modifications and variations can be made within the scope of the appended claims.
Number | Date | Country | Kind |
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2017-191201 | Sep 2017 | JP | national |
The present application is a continuation application of International Application No. PCT/JP2018/027648 filed on Jul. 24, 2018 and designated the U.S., which is based on and claims priority to Japanese Patent Application No. 2017-191201 filed with the Japanese Patent Office on Sep. 29, 2017, the entire contents of which are hereby incorporated by reference.
Number | Date | Country | |
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Parent | PCT/JP2018/027648 | Jul 2018 | US |
Child | 16818101 | US |