Source: https://patents.google.com/patent/JP5732580B2/en
Timestamp: 2020-05-29 16:28:00
Document Index: 299031677

Matched Legal Cases: ['art 1', 'art 1', 'art 2', 'art 2', 'art 1', 'art 1', 'art 2', 'art 2', 'art 4', 'art 6', 'art 4', 'art 4', 'art 4', 'art 4', 'art 4', 'art 4', 'art 6', 'art 5', 'art 6', 'art 10', 'art 23', 'art 30']

JP5732580B2 - Electronic device and coordinate detection method - Google Patents
Electronic device and coordinate detection method Download PDF
JP5732580B2
JP5732580B2 JP2014184185A JP2014184185A JP5732580B2 JP 5732580 B2 JP5732580 B2 JP 5732580B2 JP 2014184185 A JP2014184185 A JP 2014184185A JP 2014184185 A JP2014184185 A JP 2014184185A JP 5732580 B2 JP5732580 B2 JP 5732580B2
JP2014184185A
JP2015053058A (en
2013-08-08 Priority to JP2013164960 priority Critical
2013-08-08 Priority to JP2013164960 priority
2014-09-10 Application filed by パナソニック インテレクチュアル プロパティ コーポレーション オブアメリカＰａｎａｓｏｎｉｃ Ｉｎｔｅｌｌｅｃｔｕａｌ Ｐｒｏｐｅｒｔｙ Ｃｏｒｐｏｒａｔｉｏｎ ｏｆ Ａｍｅｒｉｃａ, パナソニック インテレクチュアル プロパティ コーポレーション オブ アメリカＰａｎａｓｏｎｉｃ Ｉｎｔｅｌｌｅｃｔｕａｌ Ｐｒｏｐｅｒｔｙ Ｃｏｒｐｏｒａｔｉｏｎ ｏｆ Ａｍｅｒｉｃａ filed Critical パナソニック インテレクチュアル プロパティ コーポレーション オブアメリカＰａｎａｓｏｎｉｃ Ｉｎｔｅｌｌｅｃｔｕａｌ Ｐｒｏｐｅｒｔｙ Ｃｏｒｐｏｒａｔｉｏｎ ｏｆ Ａｍｅｒｉｃａ
2014-09-10 Priority to JP2014184185A priority patent/JP5732580B2/en
2015-03-19 Publication of JP2015053058A publication Critical patent/JP2015053058A/en
2015-06-10 Publication of JP5732580B2 publication Critical patent/JP5732580B2/en
The present invention relates to an electronic device equipped with a touch panel and a coordinate detection method.
Electronic devices equipped with a touch panel, such as smartphones and tablets, are in widespread use. Some of such electronic devices include a capacitive touch panel. This capacitive touch panel is not only “touch operation” that is performed by directly touching the finger of the bare hand on the surface, but also at a predetermined height from the surface of the touch panel without touching the finger of the bare hand. A “hover operation” performed with a finger can also be accepted. Thereby, the user can operate not only with bare hands but also with fingers wearing gloves.
FIG. 19 is a diagram illustrating an example of a schematic configuration of a capacitive touch panel. In FIG. 19, a transmission electrode 101 and a reception electrode 102 are disposed on the lower surface of a plate-like dielectric 100, and a drive pulse is applied to the transmission electrode 101 from a drive buffer 103. When a drive pulse is applied, an electric field is generated. When a finger is placed in the electric field, the number of lines of electric force between the transmission electrode 101 and the reception electrode 102 decreases. This change in the electric lines of force appears as a change in charge at the receiving electrode 102. The approach of the finger to the touch panel is detected from the change in charge at the receiving electrode 102.
FIG. 20 is a diagram illustrating a detection state when a finger is gradually brought closer to the capacitive touch panel. 20A shows a state where the finger is not in the electric field, that is, a state where the finger is not detected. (B) is a state where the finger is in the electric field but not touching the touch panel, that is, a state where a hover operation is detected. (C) is a state where a finger enters the electric field and touches the touch panel, that is, a touch operation is detected. Note that in the case of an operation of touching the touch panel with a gloved finger, the finger does not directly touch the touch panel, so the state shown in FIG.
As a prior art related to such a capacitive touch panel, for example, there is an information processing apparatus described in Patent Document 1 (hereinafter referred to as “prior art 1”). This prior art 1 detects the amount of finger proximity to the touch panel and the pressure value applied to the touch panel, respectively, and distinguishes between a touch operation and a hover operation depending on whether or not they satisfy a predetermined condition. .
Further, as a prior art related to another capacitive touch panel, for example, there is a touch switch described in Patent Document 2 (hereinafter referred to as “prior art 2”). This prior art 2 determines that “touch operation is present” when the detection value on the touch panel exceeds the first threshold value, and a certain time elapses with the detection value on the touch panel being equal to or lower than the first threshold value and exceeding the second threshold value. In this case, it is determined that “the hover operation is present”. In addition, Patent Documents 3 and 4 also disclose related technologies.
JP 2011-53971 A JP 2009-181232 A JP 2009-87311 A JP 2006-323457 A
By the way, in the capacitive touch panel, in order to detect a hover operation, a very weak change in capacitance value is detected. However, when the water droplet (an example of a conductor) adheres to the touch panel and when the hover operation is actually performed on the touch panel, the change in the detected capacitance value is approximate. When water droplets adhere to the touch panel, there is a possibility that the adhesion is erroneously detected as an execution of a hover operation.
In the prior art 1, since an operation in which the pressure value by a finger close to the touch panel is not equal to or greater than a certain value is determined as a hover operation, it is impossible to distinguish between the attachment of a water droplet and the hover operation. Therefore, in the said prior art 1, when a water droplet adheres to a touch panel, the coordinate of the position will be validated and there exists a possibility that a misdetection may occur.
On the other hand, in the above-mentioned prior art 2, not only whether it is a touch operation or a hover operation but also whether it is an actual hover operation or water droplet adhesion is determined. If the hover operation is not performed, it is not determined that the actual hover operation is performed. Therefore, in the said prior art 2, when hover operation is not performed for sufficient time, there exists a possibility that it may misdetect that it is adhesion of a water drop.
The electronic device of the present invention protects the case, a display unit that is disposed in the case and displays predetermined information, a capacitive touch panel unit that transmits the display of the display unit, and the touch panel unit. And a transparent member that transmits the display of the display unit, and a pressure detection unit that is disposed between the display unit and the transparent member and detects distortion of the transparent member, An electronic apparatus capable of detecting a two-dimensional coordinate of an indicator having a predetermined conductivity, wherein a plurality of two-dimensional coordinates are detected by the touch panel unit, and a predetermined amount of distortion is detected by the press detection unit. In this case, at least one two-dimensional coordinate detected during a predetermined time toward the past is validated with reference to the time when the distortion is detected, and from the predetermined time based on the time when the distortion is detected. Previous The detected two-dimensional coordinates are not enabled.
This enables the two-dimensional coordinates detected during a predetermined time toward the past based on the time when the pressure is detected by operating with a bare hand or the like in a state where a conductor such as a water droplet continuously adheres to the touch panel. Since the previous two-dimensional coordinates are not validated, operations such as bare hands that are likely to be within a predetermined time immediately before pressing can be performed more reliably, and water drops that are likely to be before that can be performed. It is possible to further prevent erroneous detection of adhesion as an operation.
In the electronic device of the present invention, the predetermined time does not include a time when the distortion is detected. That is, the touch panel unit can detect the two-dimensional coordinates of the indicator separated by a predetermined distance (vertical direction), and when the indicator approaches the touch panel unit and contacts the touch panel unit to generate distortion, The two-dimensional coordinates of the indicator can be detected before the distortion is detected.
In the electronic device according to the present invention, when a plurality of two-dimensional coordinates are detected by the touch panel unit and a predetermined amount of distortion is detected by the press detection unit, the electronic device goes to the past based on the time when the distortion is detected. Among the two-dimensional coordinates detected during a predetermined time, the latest two-dimensional coordinates are validated with reference to the time when the distortion is detected, and the predetermined time is set with reference to the time when the distortion is detected. The two-dimensional coordinates detected earlier are not validated, and the two-dimensional coordinates other than the most recent one-dimensional coordinate among the two-dimensional coordinates detected during the predetermined time are not validated.
As a result, in the state in which a conductor such as a water droplet is continuously attached to the touch panel, when one two-dimensional coordinate is made effective, a predetermined time is passed toward the past based on the time when the pressure is detected by operating with a bare hand or the like. Since the two-dimensional coordinates detected in between are enabled and the previous two-dimensional coordinates are not enabled, operations such as bare hands that are likely to be within a predetermined time immediately before pressing can be performed more reliably. It is possible to further prevent erroneous detection of adhesion of water droplets or the like that are likely to be earlier as operations. In addition, since the most recent coordinates are validated within a predetermined time, it is possible to further prevent erroneous detection of adhesion of water droplets or the like as an operation.
In addition, the electronic device according to the present invention may be the latest two-dimensional coordinates detected during a predetermined time from the time when the distortion is detected, with the time when the distortion is detected as the reference. After validating the two-dimensional coordinates, the indicator according to the validated two-dimensional coordinates can follow the change of the validated two-dimensional coordinates until the indicator according to the predetermined distance from the touch panel unit, and The two-dimensional coordinates related to the indicator newly detected after the validation are not validated.
As a result, since the two-dimensional coordinates related to the newly detected indicator are not validated after the latest two-dimensional coordinates are validated, it is possible to manipulate the adhesion of water droplets etc. after the latest two-dimensional coordinates are validated. It is possible to prevent false detection.
In the electronic device of the present invention, when the predetermined time is the first predetermined time, a plurality of two-dimensional coordinates are detected by the touch panel unit, and a predetermined amount of distortion is detected by the press detection unit, the distortion is detected. From the two-dimensional coordinates detected during the first predetermined time toward the past with reference to the time when is detected, the two most recent two-dimensional coordinates are selected based on the time when the distortion is detected, If the difference between the detection start times of the indicators related to the two selected two-dimensional coordinates is smaller than the second predetermined time, the selected two two-dimensional coordinates are validated, and the selected two two-dimensional coordinates If the difference between the detection start times of the indicators is larger than the second predetermined time, the latest one two-dimensional coordinate is validated based on the time when the distortion is detected.
As a result, two-dimensional coordinates detected during the first predetermined time toward the past with reference to the time when pressing is detected by operating with a bare hand or the like in a state where a conductor such as a water droplet is continuously attached to the touch panel The two most recent two are selected, and the two most recent two-dimensional coordinates are enabled or the two most recent one-dimensional coordinates are enabled by switching between the two most recently disclosed detection times, and the two effective two-dimensional coordinates are switched. Since the two-dimensional coordinates before the three-dimensional coordinates are not validated, operations such as bare hands that are highly likely to be within the first predetermined time immediately before pressing can be performed more reliably and are more likely to be before that. It is possible to further prevent erroneous detection of attachment of water droplets or the like as an operation, and it is possible to cope with one-point touch and two-point touch.
In the electronic device of the present invention, the second predetermined time is shorter than the first predetermined time.
In the electronic device according to the present invention, after the two selected two-dimensional coordinates are validated, any one of the indicators according to the validated two-dimensional coordinates is separated from the touch panel unit by a predetermined distance. In the meantime, the change of the validated two-dimensional coordinate can be followed, and the two-dimensional coordinate related to the indicator newly detected after the validation is not validated.
As a result, since the two-dimensional coordinates related to the newly detected indicator are not validated after the two most recent two-dimensional coordinates are validated, the adhesion of water drops or the like after the two most recent two-dimensional coordinates are validated. It is possible to prevent erroneous detection as an operation.
The coordinate detection method of the present invention includes a housing, a display unit disposed in the housing and displaying predetermined information, a capacitive touch panel unit that transmits the display of the display unit, and the touch panel. A transparent member that protects the display and transmits the display on the display unit, and a press detection unit that is disposed between the display unit and the transparent member and detects distortion of the transparent member. The unit is a coordinate detection method that can be used for an electronic device, and is capable of detecting a two-dimensional coordinate of an indicator having a predetermined conductivity, wherein a plurality of two-dimensional coordinates are detected by the touch panel unit, and the press detection is performed. When a predetermined amount of distortion is detected by the unit, at least one two-dimensional coordinate detected during a predetermined time toward the past is validated with reference to the time when the distortion is detected, and the distortion is detected. Two-dimensional coordinates detected before the predetermined time based on when no enabled.
According to the present invention, in a state in which a conductor such as a water droplet continuously adheres to the touch panel, it is possible to more reliably perform an operation such as a bare hand and to erroneously detect the adhesion of a water droplet or the like as an operation. Can be prevented.
1 is a block diagram showing an example of a schematic configuration of an electronic device according to a first embodiment FIG. 6 is a diagram illustrating an example of a positional relationship between a touch panel layer and a finger in the electronic apparatus according to the first embodiment. The perspective view which shows an example of the external appearance of the front surface of the electronic device which concerns on 1st Embodiment FIG. 6 is a diagram illustrating an example of icon display in the electronic device according to the first embodiment. Side sectional view which shows the example 1 of arrangement | positioning of the glass in the electronic device which concerns on 1st Embodiment, a touchscreen layer, a press sensor, and a display part. The figure which shows an example of the coordinate determination when the touchscreen layer detects water and / or a finger in the electronic device which concerns on 1st Embodiment. The flowchart which shows the example of the coordinate determination process of the electronic device which concerns on 1st Embodiment The flowchart which shows the example of the coordinate determination process of the electronic device which concerns on 2nd Embodiment The figure which shows the example 2 of arrangement | positioning of the glass in the electronic device which concerns on 1st Embodiment, a touchscreen layer, a press sensor, and a display part. The figure which shows the example of arrangement | positioning of the press sensor in the electronic device which concerns on 1st Embodiment. The figure which shows the example 3 of arrangement | positioning of the glass in the electronic device which concerns on 1st Embodiment, a touchscreen layer, a press sensor, and a display part. The figure which shows the example 4 of arrangement | positioning of the glass in the electronic device which concerns on 1st Embodiment, a touchscreen layer, a press sensor, and a display part. The figure which shows the example 5 of arrangement | positioning of the glass in the electronic device which concerns on 1st Embodiment, a touchscreen layer, a press sensor, and a display part. The figure which shows the example 6 of arrangement | positioning of the glass in the electronic device which concerns on 1st Embodiment, a touch panel layer, a press sensor, and a display part. The figure which shows the example 7 of arrangement | positioning of the glass in the electronic device which concerns on 1st Embodiment, a touch panel layer, a press sensor, and a display part. The figure which shows the example 8 of arrangement | positioning of the glass in the electronic device which concerns on 1st Embodiment, a touchscreen layer, a press sensor, and a display part. The figure which shows the example 9 of arrangement | positioning of the glass in the electronic device which concerns on 1st Embodiment, a touchscreen layer, a press sensor, and a display part. The figure which shows the example 10 of arrangement | positioning of the glass in the electronic device which concerns on 1st Embodiment, a touchscreen layer, a press sensor, and a display part. The figure which shows schematic structure of the conventional capacitive touch panel The figure which shows a detection state when a finger is gradually brought close to a touch panel Side sectional view which shows the example 11 of arrangement | positioning of the glass in the electronic device which concerns on 1st Embodiment, a touchscreen layer, a press sensor, and a display part The figure which shows the detection area | region and reaction area | region in the electronic device which concerns on 3rd Embodiment The figure which shows the table | surface which manages the detection state of the coordinate in the electronic device which concerns on 3rd Embodiment. The figure which shows the table | surface which manages the detection state of the coordinate in the electronic device which concerns on 3rd Embodiment. The figure which shows the table | surface which manages the detection state of the coordinate in the electronic device which concerns on 3rd Embodiment. The figure which shows the table | surface which manages the detection state of the coordinate in the electronic device which concerns on 3rd Embodiment. The flowchart which shows the input method of detection start time etc. in the coordinate detection state management table | surface of 3rd Embodiment. The flowchart which shows the update method of the detection state in the coordinate detection state management table | surface of 3rd Embodiment The flowchart which shows the example of the coordinate determination process of the electronic device which concerns on 3rd Embodiment The schematic diagram which shows an example of the coordinate determination of the electronic device which concerns on 3rd Embodiment The schematic diagram which shows an example of the coordinate determination of the electronic device which concerns on 3rd Embodiment The schematic diagram which shows an example of the coordinate determination of the electronic device which concerns on 3rd Embodiment The schematic diagram which shows an example of the coordinate determination of the electronic device which concerns on 3rd Embodiment
FIG. 1 is a block diagram illustrating an example of a schematic configuration of an electronic device 1 according to the first embodiment.
In FIG. 1, the electronic device 1 includes a touch panel layer 2, a pressure sensor 3, a display unit 4, a storage unit 5, and a control unit 6. Examples of the electronic device 1 include a smartphone or a tablet.
The touch panel layer 2 employs a capacitance method, and can accept not only a touch operation but also a hover operation. As described above, the touch operation refers to an operation performed by the indicator directly touching the touch panel surface. On the other hand, as described above, the hover operation refers to an operation performed at a predetermined height from the surface of the indicator without directly touching the surface of the touch panel. An example of the hover operation is an operation of touching the touch panel surface with a finger wearing a glove. The indicator is a human finger or an object having conductivity (for example, a stylus pen). In the following description, the indicator is described as a finger. The touch panel surface refers to a surface that receives a user operation in the touch panel layer 2.
As shown in FIG. 19, the touch panel layer 2 includes a transmission electrode 101 and a reception electrode 102, and these are arranged separately on the lower surface of the plate-like dielectric 100. A driving pulse based on a transmission signal is applied to the transmission electrode 101. When a drive pulse is applied to the transmission electrode 101, an electric field is generated from the transmission electrode 101. When a finger enters the electric field, the number of lines of electric force between the transmission electrode 101 and the reception electrode 102 decreases. The change in the number appears as a change in charge at the receiving electrode 102.
Then, the touch panel layer 2 (an example of the touch panel unit) is configured such that the number of fingers and the two-dimensional coordinates (x, y) in the display unit 4 indicated by the fingers are based on the reception signal corresponding to the change in the charge in the reception electrode 102. The vertical distance (z) between the surface of the touch panel layer 2 and the finger is determined, and information indicating them is output to the control unit 6. The determination described here is performed in a touch panel control unit (not shown) included in the touch panel layer 2.
The vertical distance (z) refers to the distance between the touch panel surface of the touch panel layer 2 and the finger 70 as shown in FIG. The finger 70 is a bare finger. When the vertical distance (z) is equal to or smaller than a predetermined value, the touch panel layer 2 can determine a two-dimensional coordinate (x, y) coordinate. In addition, although illustration is abbreviate | omitted in FIG. 2, the glass (an example of a transparent member. Glass 11 mentioned later) for protecting the touchscreen layer 2 is provided in the touchscreen surface.
The pressure sensor 3 (an example of a pressure detection unit) detects glass distortion (predetermined distortion amount) for protecting the touch panel layer 2 and outputs a signal indicating the presence or absence of distortion to the control unit 6. It is assumed that the glass distortion occurs due to the pressing of the indicator, and does not occur due to adhesion of water droplets or the like. It should be noted that the signal need not necessarily indicate the presence / absence of distortion (presence / absence), and may be a signal indicating either distortion or non-distortion. Further, the press sensor 3 itself may not determine whether or not there is distortion, but may output a signal indicating the degree of distortion of the glass to the control unit 6 so that the control unit 6 determines whether or not there is distortion.
Here, the arrangement of the touch panel layer 2 and the pressure sensor 3 will be described. As shown in FIG. 3, the electronic device 1 has a rectangular parallelepiped casing 10. In FIG. 3, the touch panel layer 2 and the pressure sensor 3 are disposed on the front (front) side of the housing 10. The touch panel layer 2 and the pressure sensor 3 are formed in a vertically long rectangular shape (rectangular shape) in plan view, and have an area smaller than the area of the front surface of the housing 10. In FIG. 3, the area of the press sensor 3 is slightly larger than the area of the touch panel layer 2, but the area of the press sensor 3 may be small as will be described later. The touch panel layer 2 is disposed so as to overlap the pressure sensor 3 so as to be in front of the pressure sensor 3.
In addition, although illustration is abbreviate | omitted in FIG. 3, the glass for protecting the touch panel layer 2 is provided in the front side (namely, touch panel surface) of the touch panel layer 2 as mentioned above. Moreover, in the press sensor 3, the display part 4 which is a vertically long rectangular shape is arrange | positioned on the back surface of the surface where the touch-panel layer 2 was piled up planarly.
The display unit 4 is a device that is disposed inside the housing 10 and displays predetermined information based on instructions from the control unit 6, and includes an LCD (Liquid Crystal Display) 41 and a backlight 42. The display unit 4 may be configured to have a device such as an organic EL (Electro Luminescence) or electronic paper instead of the LCD 41.
The display unit 4 displays a predetermined image (for example, a pointer or an icon) as a display corresponding to the two-dimensional coordinates (x, y) determined by the touch panel layer 2. For example, as shown in FIG. 4A, when the two-dimensional coordinates (x 1 , y 1 ) are valid coordinates, the icon 30 is displayed as shown in FIG. 4B. In FIG. 4B, pointers may be displayed corresponding to the two-dimensional coordinates (x, y). In this case, when the pointer overlaps the icon, the icon may be selectable. Furthermore, when the finger 70 approaches the touch panel layer 2 within a predetermined vertical distance (z) (including zero), a function corresponding to the icon may be activated. Such display of pointers and icons and activation of functions corresponding to the icons are performed according to instructions from the control unit 6.
Here, an arrangement example 1 of the touch panel layer 2, the pressure sensor 3, and the display unit 4 in the electronic device 1 will be described. In FIG. 5, the glass 11 for protecting the touch panel layer 2 is disposed on the front side of the touch panel layer 2 as described above. The glass 11 and the touch panel layer 2 are planar and have a predetermined transmittance for visible light, and transmit the display on the display unit 4. Further, at least a part of the glass 11 is disposed so as to be exposed from the housing 10, and the other part is disposed inside the housing 10. The glass 11 may have a configuration integrated with the touch panel layer 2.
Further, as shown in FIG. 21, the press sensor 3 may be disposed between the glass 11 and the touch panel layer 2.
Moreover, in FIG. 5, the press sensor 3 is arrange | positioned as mentioned above in the back surface of the surface where the glass 11 was piled up in the touchscreen layer 2. As shown in FIG. Further, as described above, in the press sensor 3, the LCD 41 and the backlight 42 constituting the display unit 4 are sequentially arranged on the back surface of the surface on which the touch panel layer 2 is superimposed. As described above, since the pressure sensor 3 is disposed on the front side of the display unit 4, the pressure sensor 3 needs to be transparent and transparent to transmit visible light, like the glass 11 and the touch panel layer 2. is there. The press sensor 3 may be integrated with the touch panel layer 2.
Returning to the description of FIG. The storage unit 5 includes a volatile memory such as a DRAM (Dynamic Random Access Memory), and stores the settings when the user performs various settings on the electronic device 1.
The control unit 6 controls each unit of the electronic device 1 and includes a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), and an interface circuit. The ROM stores a program for controlling the CPU, and the RAM is used as a calculation area when the CPU operates.
In 1st Embodiment, the control part 6 performs the coordinate determination process based on the input information from the press sensor 3 and the touchscreen layer 2, It is characterized by the above-mentioned. This coordinate determination process will be described later with reference to FIGS. 6, 7, and 8.
Hereinafter, as an operation example of the electronic apparatus 1 according to the first embodiment, a coordinate determination process performed by the control unit 6 will be described.
First, a specific example of the coordinate determination process will be described with reference to FIG.
As shown in FIG. 6A, it is assumed that water droplets 80 adhere to the glass 11 due to rain or the like. At this time, the touch panel layer 2 outputs the two-dimensional coordinates (x 0 , y 0 ) of the location where the water droplet 80 is attached to the control unit 6. Further, the pressure sensor 3 outputs a signal indicating that the glass 11 is not distorted (hereinafter referred to as “no distortion signal”) to the control unit 6. The control unit 6 does not validate the two-dimensional coordinates (x 0 , y 0 ) upon receiving the no distortion signal. “Validation” refers to handling as valid coordinates. Therefore, processing corresponding to the two-dimensional coordinates (x 0 , y 0 ) (for example, display of information on the display unit 4) is not performed.
6A, it is assumed that the user touches the glass 11 with the finger 70 wearing the glove 71 and performs a hover operation in a state where the water droplet 80 is attached to the glass 11 as shown in FIG. 6B. At this time, in addition to the two-dimensional coordinates (x 0 , y 0 ) being output, the touch panel layer 2 outputs the two-dimensional coordinates (x 1 , y 1 ) of the location where the glove 71 is in contact to the control unit 6. Further, the press sensor 3 outputs a signal indicating that the glass 11 is distorted by pressing with the glove 71 (hereinafter referred to as “distortion present signal”) to the control unit 6. The control unit 6 validates only the two-dimensional coordinates (x 1 , y 1 ) received later in time by receiving the signal with distortion. Therefore, processing corresponding to the two-dimensional coordinates (x 1 , y 1 ) is performed.
In this way, in a state where a conductor such as water droplets continuously adheres to the touch panel, the two-dimensional coordinates immediately before (last) when the pressure is detected by operating with bare hands (eg, bare hands and gloves) are made effective. Since the previous two-dimensional coordinates are not validated, the operation of bare hands or the like (for example, bare hands and gloves), which is likely to be immediately before pressing, can be performed more reliably and is more likely to be before that. It is possible to further prevent erroneous detection of adhesion of water droplets or the like as an operation.
After FIG. 6B, as shown in FIG. 6C, in the state where the water droplet 80 is attached to the glass 11 and the user touches the glass 11 with the finger 70 wearing the glove 71 and performs the hover operation, the water droplet 81 Suppose that it adhered to the glass 11. At this time, in addition to the two-dimensional coordinates (x 0 , y 0 ) and (x 1 , y 1 ) being output, the touch panel layer 2 has the two-dimensional coordinates (x 2 , y 2 ) of the location where the water droplet 80 is attached. ) To the control unit 6. In addition, the pressure sensor 3 is outputting a signal with distortion to the control unit 6 by pressing of the hover operation. Although the control unit 6 has received the signal with distortion, the control unit 6 has already validated the two-dimensional coordinates (x 1 , y 1 ), so the two-dimensional coordinates (x 2 , y 2 ) received later in time are used. Do not activate. Therefore, processing corresponding to the two-dimensional coordinates (x 1 , y 1 ) is performed, but processing corresponding to the two-dimensional coordinates (x 2 , y 2 ) is not performed. Thus, when the validated two-dimensional coordinates already exist, the control unit 6 does not validate the new two-dimensional coordinates even if the press sensor 3 detects that there is distortion.
By doing in this way, when the activation is continued in a state where a conductor such as a water droplet continuously adheres to the touch panel, the two-dimensional coordinates determined after the activation are not activated, It is possible to prevent erroneous detection of water droplet adhesion as an operation.
In FIG. 6, the two-dimensional coordinates due to the attachment of the water droplets 80 and 81 and the contact with the glove 71 may be stationary or may move. Further, the control unit 6 continues to validate the two-dimensional coordinates once validated until a release is detected. The release means that the indicator is separated from the touch panel layer 2 and the value of the vertical distance (z) is equal to or greater than a predetermined value. A release is detected when it no longer receives two-dimensional coordinates. During the activation, the output of the pressure sensor 3 to the control unit 6 may be distorted or undistorted.
By doing in this way, based on the distance of the indicator and touch panel part which a touch panel part detects, validation is continued while this distance is smaller than predetermined distance. That is, when this distance becomes larger than the predetermined distance, the activation is stopped. Thereby, validation can be canceled regardless of the output of the press detection unit.
When an operator performs a long press operation with an indicator (eg, a finger) or performs a flick operation, the pressure on the touch panel part may gradually decrease at the end of these operations, and the gentle change in the pressure In some cases, it is difficult to determine the end of these operations only by the output of the pressing detection unit that is not good at detecting. However, as described above, since the activation can be stopped regardless of the output of the press detection unit, it is possible to appropriately determine the end of these operations.
The control unit 6 also receives the number of indicators and the vertical distance from the touch panel layer 2 together with the two-dimensional coordinates. Hereinafter, information including two-dimensional coordinates, the number of indicators, and the vertical distance is referred to as “coordinate information”.
In addition, the water droplets have been described here, but the same applies to liquid droplets having a predetermined conductivity as well as water.
Next, a first example of coordinate determination processing will be described with reference to FIG.
In step S <b> 101, the control unit 6 confirms the strain detection state of the pressure sensor 3 based on the signal from the pressure sensor 3 (that is, whether the pressure sensor 3 detects whether the glass 11 is distorted or not distorted). To do.
Here, when the control unit 6 receives a no-distortion signal from the pressure sensor 3, the control unit 6 determines that the glass 11 has no distortion (step S102: NO), and returns to step S101. On the other hand, when the control unit 6 receives a distortion signal from the pressure sensor 3, the control unit 6 determines that the glass 11 has distortion (step S102: YES), and proceeds to step S103.
In step S <b> 103, the control unit 6 confirms the two-dimensional coordinate determination state of the touch panel layer 2 (that is, whether the touch panel layer 2 is determining the two-dimensional coordinates) based on information from the touch panel layer 2.
Here, when the coordinate information is not received from the touch panel layer 2, the control unit 6 determines that the two-dimensional coordinates are not being determined (step S104: NO), and returns to step S101. On the other hand, when the coordinate information is received from the touch panel layer 2, the control unit 6 determines that the two-dimensional coordinates are being determined (step S104: YES), and proceeds to step S105.
In step S105, the control unit 6 validates the last determined two-dimensional coordinate. The two-dimensional coordinates validated here are the two-dimensional coordinates indicated by the latest coordinate information received by the control unit 6 at this time.
In step S106, the control unit 6 tracks the activated two-dimensional coordinates.
In step S107, the control unit 6 determines whether a release has been detected for the activated two-dimensional coordinates. “Release” means that the vertical distance (z) becomes equal to or larger than a predetermined value when the indicator indicating the activated two-dimensional coordinates is separated from the touch panel surface.
Here, when the coordinate information of the activated two-dimensional coordinates is received from the touch panel layer 2, the control unit 6 determines that the release is not detected (step S107: NO), and returns to step S106. On the other hand, when the control unit 6 does not receive the coordinate information of the validated two-dimensional coordinates from the touch panel layer 2, it determines that the release is detected (step S107: YES), and returns to step S101.
That is, when the two-dimensional coordinate is validated, the control unit 6 continues the validation unless a release is detected even if the two-dimensional coordinate changes. Further, the control unit 6 does not validate all the two-dimensional coordinates indicated by the coordinate information newly received during the validation, regardless of the distortion detection result.
As described above, according to the electronic device 1 according to the first embodiment, when the touch sensor layer 2 determines a two-dimensional coordinate and the pressure sensor 3 detects distortion, the touch panel layer 2 determines last. It is characterized by enabling only two-dimensional coordinates. With this feature, in a state where a conductor such as a water droplet adheres to the touch panel surface, not only an operation with a bare hand but also an operation with a gloved hand can be executed without erroneous detection.
In the electronic device 1 according to the first embodiment, when the touch sensor layer 2 determines a two-dimensional coordinate and the pressure sensor 3 does not detect distortion, a conductor such as a water droplet adheres to the touch panel surface. It is also possible to determine. In this case, for example, the electronic device 1 may display a display indicating the determination result on the display unit 4.
Further, in the electronic device 1 according to the first embodiment, a program for causing the electronic device 1 to execute the operation shown in the flowchart of FIG. 7 and / or FIG. 8 is stored in, for example, a ROM (not shown) of the control unit 6. However, the program may be stored other than the electronic device 1. For example, the program storage destination may be a storage medium such as a magnetic disk, an optical disk, a magneto-optical disk, or a flash memory, or a server on a network such as the Internet.
Moreover, although the electronic device 1 which concerns on 1st Embodiment was applied to portable terminals, such as a smart phone and a tablet, it is not limited to a portable terminal. The electronic device 1 can be applied to, for example, home appliances (for example, a microwave oven, a refrigerator, etc.), a car navigation system, a HEMS (Home Energy Management System), a BEMS (Building Energy Management System), and the like.
Moreover, in the electronic device 1 which concerns on 1st Embodiment, as shown in FIG. 5, although arrange | positioned in order of the touchscreen layer 2, the press sensor 3, and the display part 4 under the glass 11, it is not limited to this. . Hereinafter, arrangement examples other than the arrangement example 1 shown in FIG. 5 will be described with reference to the drawings.
FIG. 9 is a side cross-sectional view of the electronic apparatus 1 showing the second arrangement example. As shown in FIG. 9, below the glass 11, the touch panel layer 2, the display unit 4 (LCD 41 and backlight 42), a presser (plunger) 21, a press sensor 3, and a telescopic member 22 are arranged in this order. .
In FIG. 9, the pusher 21 is disposed between the backlight 42 and the press sensor 3. One end of the presser 21 is in contact with one surface of the backlight 42, and the other end of the presser 21 is fixed to one surface of the press sensor 3. The frame portion 12 of the housing 10 (an example of a portion of the housing 10) has a recess 23 formed therein. The expansion / contraction member 22 is erected in the recess portion 23, one end of which is fixed to the bottom surface of the recess portion 23, and the other end is one surface of the pressure sensor 3 (the back surface of the surface on which the presser 21 is fixed). It is fixed to. Further, both ends of the pressure sensor 3 are fixed to the frame portion 12.
In the configuration of FIG. 9, when pressure is applied to the glass 11 by the contact of a user's finger (a bare hand or a gloved hand), the pusher 21 pushes the pressure sensor 3 downward (in the direction of the recess 23). At this time, the elastic member 22 is contracted so as to absorb the pressure applied to the pressure sensor 3. When the user's finger is separated from the glass 11 and the pressure on the glass 11 is lost, the elastic member 22 extends and returns to its original length. As a result, the pressure sensor 3 is pushed upward (in the direction of the backlight 42).
An example of an arrangement position of the press sensor 3 shown in FIG. 9 in the electronic device 1 is shown in FIG. FIGS. 10A, 10 </ b> B, and 10 </ b> C show where the pressure sensor 3 is arranged on the front surface (front surface) of the housing 10 of the electronic device 1. The press sensor 3 is rectangular, but is considerably smaller than the area of the press sensor 3 shown in FIGS.
FIG. 10A is an example in which the pressure sensor 3 is arranged at the center of the housing 10. In FIG. 10A, the pressure sensor 3 is arranged so that its long side is parallel to the short side of the housing 10. FIG. 10B is an example in which the pressure sensor 3 is arranged at the center of the housing 10. In FIG. 10B, the press sensor 3 is arranged such that its long side is parallel to the long side of the housing 10. FIG. 10C is an example in which two pressure sensors 3 are arranged in the vicinity of the short side of the housing 10. In FIG. 10C, the two press sensors 3 are arranged such that the long sides thereof are parallel to the short sides of the housing 10.
Among the three examples of FIGS. 10A to 10C, the arrangement of the pressure sensor 3 shown in FIG. 10A can detect the distortion most and is low in cost. In addition, the arrangement | positioning position and number of the press sensors 3 are not limited to the example shown to FIG. For example, the four pressure sensors 3 may be arranged along all four sides of the housing 10.
FIG. 11 is a side cross-sectional view of the electronic device 1 showing the third arrangement example. As shown in FIG. 11, the touch panel layer 2 is disposed on the lower surface side of the glass 11, and the press sensor 3 is disposed on a peripheral portion on the lower surface side of the touch panel layer 2. Further, an LCD 41 and a backlight 42 are arranged as the display unit 4 at a position away from the lower surface side of the touch panel layer 2 and the pressure sensor 3. The LCD 41 is disposed toward the touch panel layer 2.
FIG. 12 is a side cross-sectional view of the electronic apparatus 1 showing the fourth arrangement example. As shown in FIG. 12, the touch panel layer 2 is fitted and arranged on the lower surface side of the glass 11. That is, the glass 11 and the touch panel layer 2 are integrated. The pressure sensor 3 is disposed across the glass 11 and the touch panel layer 2 on the lower surface side. In addition, the display part 4 is arrange | positioned similarly to the example 3 of an arrangement | positioning shown in FIG.
FIG. 13 is a side cross-sectional view of the electronic apparatus 1 showing the fifth arrangement example. Arrangement example 5 shown in FIG. 13 is basically the same as arrangement example 3 shown in FIG. A different point is that the touch panel layer 2 and the LCD 41 of the display unit 4 are arranged at a certain distance.
FIG. 14 is a side cross-sectional view of the electronic apparatus 1 showing the arrangement example 6. As shown in FIG. 14, the pressure sensor 3 is disposed on the peripheral portion on the lower surface side of the glass 11. The touch panel layer 2 is disposed at a position below the glass 11 and at a certain distance from the glass 11. In addition, the display part 4 is arrange | positioned similarly to the example 3 of an arrangement | positioning shown in FIG.
In the case of arrangement example 5 in FIG. 13 and arrangement example 6 in FIG. 14, the display unit 4 and the glass 11 can be separated (example: 5 mm to 15 mm). For example, this is effective when the glass 11 has a slight unevenness or a slight curvature, and the display unit 4 is hard and avoids contact with the unevenness of the glass 11. Or the display part 4 can be arrange | positioned inside the side surface (for example, door etc.) of a refrigerator, and the glass 11 which has a some curvature on the side surface of the position corresponding to the display part 4 can also be arrange | positioned. Or the display part 4 of a large screen (for example, 50 type | mold) can be arrange | positioned in a show window, and the glass (glass attached to a building) of the show window can also be used as the glass 11.
FIG. 15 is a side cross-sectional view of the electronic apparatus 1 showing the arrangement example 7. Arrangement example 7 shown in FIG. 15 is basically the same as arrangement example 6 shown in FIG. The difference is that the touch panel layer 2 and the glass 11 are arranged without leaving a certain distance.
FIG. 16 is a side cross-sectional view of the electronic apparatus 1 showing an arrangement example 8. The arrangement example 8 shown in FIG. 16 is basically the same as the arrangement example 3 shown in FIG. The difference is that the press sensor 3 is arranged not on the lower surface side of the touch panel layer 2 but on the lower surface side of the backlight 42. The press sensor 3 may be disposed on the upper surface side of either the LCD 41 or the backlight 42, on the side surface side of the LCD 41 or the backlight 42, or inside the LCD 41 or the backlight 42.
FIG. 17 is a side cross-sectional view of the electronic apparatus 1 showing the ninth arrangement example. As shown in FIG. 17, the display unit 4 includes at least a planar transparent member 41a and a transparent member 41b disposed so as to overlap with the transparent member 41a, and liquid crystal is interposed between the transparent member 41a and the transparent member 41b. Sandwiched.
As shown in FIG. 17, the transparent member 41a is disposed on the lower surface side of the touch panel layer 2, and the transparent member 41b is disposed on the lower surface side of the transparent member 41a. Further, a part of the transparent member 41b protrudes outward from the transparent member 41a at the end 41bb of the display unit 4. The pressure sensor 3 is disposed on the lower surface side of the touch panel layer 2 at a portion corresponding to the protruding end portion 41bb of the transparent member 41b.
According to this arrangement example 9, since the pressure sensor 3 is arranged at a portion corresponding to the protruding end portion 41bb of the transparent member 41b, there is no need for a new space for arranging the pressure sensor 3, and the electronic device 1 Space can be used efficiently.
FIG. 18 is a side cross-sectional view of the electronic apparatus 1 showing the tenth arrangement example. The arrangement example 10 shown in FIG. 18 is basically the same as the arrangement example 9 shown in FIG. The difference is that the backlight 42 is not provided. Therefore, in this case, the display unit 4 has a configuration (for example, organic EL (electroluminescence)) capable of displaying an image without requiring a backlight.
In this arrangement example 10, similarly to the arrangement example 9, the press sensor 3 is arranged at a portion corresponding to the protruding end portion 41bb of the transparent member 41b, so that a new space for arranging the press sensor 3 is not necessary. The space in the electronic device 1 can be used efficiently.
Further, the electronic device 1 and the like according to the first embodiment can be grasped as follows.
A case, a display unit disposed in the case and displaying predetermined information; a capacitive touch panel unit that transmits the display of the display unit; and protecting the touch panel unit, A transparent member that transmits the display; and a pressure detection unit that detects distortion of the transparent member. The touch panel unit can determine the two-dimensional coordinates of the indicator having predetermined conductivity and The electronic device is capable of determining the two-dimensional coordinates of the liquid adhering to the touch panel unit, wherein a plurality of two-dimensional coordinates are sequentially determined by the touch panel unit, and the pressure detection is performed. When a predetermined amount of distortion is detected by the unit, the last determined two-dimensional coordinate among the plurality of two-dimensional coordinates is validated, and the last determined two-dimensional coordinate among the plurality of two-dimensional coordinates. Two-dimensional coordinate other than the original coordinates is not enabled, the electronic device.
With this configuration, in a state in which a conductor such as a water droplet is continuously attached to the touch panel, the two-dimensional coordinates immediately before (last) when the pressure is detected by operating with a bare hand or the like (for example, bare hands and gloves) are made effective. Since the previous two-dimensional coordinates are not validated, operations such as bare hands that are likely to be immediately before pressing (for example, bare hands and gloves) can be performed more reliably, and water drops that are likely to be in front of them It is possible to further prevent erroneous detection of adhesion as an operation.
(1-1) The electronic device according to (1-1), wherein the validation is continued until the indicator that designates the validated two-dimensional coordinates is separated from the touch panel unit by a predetermined distance.
With this configuration, the activation is continued while the distance is smaller than the predetermined distance based on the distance between the indicator detected by the touch panel unit and the touch panel unit. That is, when this distance becomes larger than the predetermined distance, the activation is stopped. Thereby, validation can be canceled regardless of the output of the press detection unit.
In the electronic device according to (1-1) or (1-2), the activation is continued until the indicator that indicates the activated two-dimensional coordinates is separated from the touch panel unit by a predetermined distance, An electronic device that does not validate the two-dimensional coordinates determined after the validation.
With this configuration, when the activation is continued in a state in which a conductor such as a water droplet is continuously attached to the touch panel, the two-dimensional coordinates determined after the activation are not validated, so that the water droplet after the validation is adhered. Can be prevented from being erroneously detected as an operation.
The electronic device according to any one of (1-1) to (1-3), wherein when the vertical distance between the indicator and the touch panel unit is a predetermined value or less, the indicator An electronic device that determines the two-dimensional coordinates indicated by
The electronic device according to (1-4), wherein the predetermined value is a value greater than zero.
The electronic device according to (1-4), wherein the predetermined value is zero.
The electronic device according to any one of (1-1) to (1-6), wherein the press detection unit is disposed between the transparent member and the touch panel unit, and displays the display unit. Transparent electronic equipment.
The electronic device according to any one of (1-1) to (1-6), wherein the press detection unit is disposed between the display unit and a part of the housing. .
The electronic device according to any one of (1-1) to (1-6), wherein the transparent member is integral with the touch panel unit.
The electronic device according to any one of (1-1) to (1-6), wherein at least a part of the press detection unit is disposed so as to overlap the display unit.
The electronic device according to any one of (1-1) to (1-6), wherein the press detection unit is integrated with the touch panel unit.
A case, a display unit disposed in the case and displaying predetermined information; a capacitive touch panel unit that transmits the display of the display unit; and protecting the touch panel unit, A transparent member that transmits the display; and a pressure detection unit that detects distortion of the transparent member. The touch panel unit can determine the two-dimensional coordinates of the indicator having predetermined conductivity and This is a coordinate detection method that can be used in an electronic device and that can determine the two-dimensional coordinates of the liquid attached to the touch panel unit, and the touch panel unit sequentially determines a plurality of two-dimensional coordinates. And when a predetermined amount of distortion is detected by the pressure detection unit, the last-determined two-dimensional coordinate among the plurality of two-dimensional coordinates is validated, and the plurality of two-dimensional coordinates Chi, finally determined two-dimensional coordinates other than the two-dimensional coordinates were no activation, coordinate detection method.
The electronic device 1 according to the second embodiment of the present invention is the same as that of the first embodiment with respect to FIGS. 1 to 5, 9 to 18, and 21, and the description thereof is omitted.
FIG. 8 is a flowchart showing the coordinate determination process according to the second embodiment. The coordinate determination process according to the second embodiment will be described with reference to FIG.
In the first embodiment, the process is to validate only one two-dimensional coordinate, but in the second embodiment, in order to cope with an operation with a plurality of indicators (for example, multi-touch), This is a process for validating a plurality of two-dimensional coordinates. Since steps S201 to S204 in FIG. 8 are the same as steps S101 to S104 in FIG.
In step S205, the control unit 6 validates all the two-dimensional coordinates determined within a predetermined time. Therefore, the two-dimensional coordinates validated here are two-dimensional coordinates indicated by all coordinate information received by the control unit 6 within a predetermined time. The predetermined time is a time (for example, about several seconds) including a time point at which the last distortion is detected (a signal with distortion is received). As this time, the following (1)-(3) is raised, for example.
(1) A period in which the last time point at which distortion was detected (hereinafter referred to as “distortion detection time point”) is set as the end point, and a time point before the distortion detection time point is set as the start point. Period with the later time point as the end point (3) The period from the start point before the strain detection time to the end point after the strain detection time, including the strain detection time point
In step S206, the control unit 6 tracks all the activated two-dimensional coordinates.
In step S207, the control unit 6 determines whether or not release has been detected for all validated two-dimensional coordinates.
Here, the control unit 6 determines that no release has been detected when at least one piece of coordinate information of all activated two-dimensional coordinates has been received from the touch panel layer 2 (step S207: NO), and step Return to S206. On the other hand, when the control unit 6 stops receiving coordinate information of all the activated two-dimensional coordinates from the touch panel layer 2, it determines that release has been detected (step S207: YES), and returns to step S201.
That is, when a plurality of two-dimensional coordinates are validated, the control unit 6 continues the validation unless releases of all validated two-dimensional coordinates are detected even if each two-dimensional coordinate changes. Further, the control unit 6 does not validate all the two-dimensional coordinates indicated by the coordinate information newly received during the validation, regardless of the distortion detection result.
In the electronic device 1 according to the third embodiment of the present invention, FIGS. 1 to 5, FIGS. 9 to 18, and FIG. 21 are common to the first embodiment, and description thereof is omitted.
As shown in FIG. 22, the touch panel layer 2 includes a reaction region that is known to have approached when a finger approaches from a distance, and a vertical distance can be detected inside the reaction region. Furthermore, it is possible to provide a detection region that can stably detect the presence or absence of a finger within a predetermined vertical distance (eg, 5 mm).
Note that the predetermined vertical distance corresponding to the detection region can be determined as appropriate. For example, by making it larger than the thickness of the glove material (the predetermined vertical distance does not include 0 (zero)), it becomes possible to detect a finger or the like in the glove, and in some cases, the predetermined vertical distance is set to 0. It may be (zero).
The electronic device 1 according to the third embodiment uses the table for managing the coordinate detection state illustrated in FIG. 23A or FIG. 23B to manage the coordinate detection state and illustrates the coordinate determination process in FIG. By determining the coordinates based on the above, single point operation and multipoint operation are appropriately switched and executed. In the following, when either one of FIG. 23A and FIG. 23B is not specified, “FIG. 23” is described.
In the table of FIG. 23, one row corresponds to one coordinate to be managed. In the detection start time column, an absolute time when the finger first enters the detection region is input.
The detection area will be described with reference to FIG. The touch panel layer 2 includes a reaction region that can be known to approach when a finger approaches from a distance, and a vertical distance can be detected inside the reaction region. The detection region is a region within a predetermined vertical distance (for example, 5 mm) within a region where the vertical distance can be detected, and is a region where the presence / absence of a finger can be stably determined. Although the detection area is provided inside the reaction area here, the reaction area and the detection area may be the same.
In the table of FIG. 23, the detection status column indicates whether or not the finger is in the detection area. 1 indicates the presence, 0 indicates no. The column of xyz coordinates indicates the xyz coordinates output from the touch panel layer 2, the xyz coordinates starting detection at the detection start time in the same row, the xyz coordinates so as to follow even after the start of detection, and xyz until the end of detection Indicates coordinates. The # column indicates the serial number of the coordinate to be managed. Note that the table in FIG. 23 can be stored in the storage unit 5. The z-coordinate is a value based on the capacitance value with the indicator, and slightly changes depending on the area of the indicator.
FIG. 24 is a flowchart showing a method for inputting the detection start time and the like in the coordinate detection state management table of FIG. When starting, the control unit 6 first initializes the coordinate detection state management table (step S301). That is, 0 is input to each of the detection start time, the detection state, and the xyz coordinates for # 1 to # 10 in the coordinate detection state management table.
Next, it is determined whether an indicator or the like (including water droplets or the like) has entered the reaction region (step S302). If it is not within the reaction region (step S302: NO), step S302 is repeated. When the indicator or the like is in the reaction region (step S302: YES), the control unit 6 acquires the z coordinate from the touch panel layer 2 (step S303). Based on the acquired z coordinate, it is determined whether an indicator or the like has newly entered the detection area, for example, whether z has newly become 5 mm or less (step S304). When a new entry into the detection area is made (step S304: YES), the control unit 6 inputs the time when the detection is started in the row of detection state: 0 in the coordinate detection state management table, and sets the detection state of that row to 1. (Step S305), the xyz coordinates corresponding to the indicator or the like that has newly entered the detection area are started as indicated by the xyz coordinates of the row, and the xyz coordinates of the row follow the indicator or the like thereafter. (Step S306). Thereafter, the process returns to step S302. The control unit 6 includes a clock (not shown), and the time at which the above detection is started can be obtained with reference to this clock.
In step S304, if the detection area has not been entered or if it has entered the detection area but is not a new entry (step S304: NO), the process returns to step S302.
FIG. 25 is a flowchart showing a detection state update method in the coordinate detection state management table of FIG. The flowchart corresponds to one row of the coordinate detection state management table. When the control unit 6 starts and the detection state in the row is 1 (step S401: YES), the control unit 6 determines whether the z coordinate is outside the detection region based on the z coordinate of the xyz coordinate in the row (for example, the z coordinate is less than 5 mm). If it is outside the detection area (step S402: YES), the detection state is changed to 0 (step S403), and the process returns to step 401. Although there are 10 rows in the coordinate detection state management table, the detection state update method of FIG. 25 is executed for each row.
The control unit 6 executes the input method such as the detection start time in FIG. 24 and the update method of the detection state in FIG. 25 independently, thereby indicating the instruction in the detection state in the coordinate detection state management table in FIG. The detection start time and real time xyz coordinates corresponding to the body and the like can be obtained.
FIG. 26 is a flowchart illustrating an example of the coordinate determination process of the electronic device according to the third embodiment. When the control unit 6 starts, in step S501, based on the signal from the pressure sensor 3, the pressure sensor 3 detects a strain (that is, whether the pressure sensor 3 detects whether the glass 11 is distorted or not distorted). Confirm.
Here, when receiving the no distortion signal from the pressure sensor 3, the control unit 6 determines that the glass 11 has no distortion (step S502: NO), and returns to step S501. On the other hand, when the control unit 6 receives a distortion signal from the pressure sensor 3, the control unit 6 determines that the glass 11 has distortion (step S502: YES), and proceeds to step S503.
Next, the control unit 6 acquires the current time with reference to a clock (provided inside the control unit 6; not shown) (step S503), and in step S504, refers to the coordinate detection state management table of FIG. The number of xy coordinates that have been detected within the first predetermined time (for example, 2.00 seconds) in the xy coordinates being detected (detection state = 1) and based on the current time Determine.
Note that the first predetermined time may include the current time, or may not include the current time.
In step S504, when the number of xy coordinates that have been detected within the first predetermined time is two or more, the control unit 6 determines the nearest two of the xy coordinates that have been detected within the first predetermined time. Two xy coordinates are selected (step S510).
Next, in step S505, the control unit 6 determines whether the difference between the detection start times for the two most recent xy coordinates is within a second predetermined time (eg, 1.00 seconds). If it is within the second predetermined time (step S505: YES), the two most recent xy coordinates are validated (step S506), and the detection states of the two most recent xy coordinates are both 1 (step S507: YES). Step S506 and Step S507: YES is repeated, and the two most recent xy coordinates remain valid.
In principle, the second predetermined time is shorter than the first predetermined time. In step S510, step S505, step S506, and step S507, the process is performed for the two most recent xy coordinates. However, the process is not limited to the two most recent, and the process is performed for the three or more most recent xy coordinates. May be.
When at least one of the detection states of the two most recent xy coordinates is 0 in step S507 (step S507: NO), the control unit 6 returns to step S501.
In step S505, the control unit 6 determines that the difference between the detection start times of the two most recent xy coordinates is not within the second predetermined time (eg, 1.00 seconds) (step S505: NO), the one latest xy coordinate. Is valid (step S508), and when the detection state of the latest one xy coordinate is 1 (step S509: YES), step S508 and step S509: YES are repeated, and the latest one xy coordinate remains valid. .
In step S504, when the number of xy coordinates that have been detected within the first predetermined time is one, the control unit 6 determines the xy coordinates corresponding to the one (that is, the most recent xy coordinate). If it is valid (step S508) and the detection state of the latest one xy coordinate is 1 (step S509: YES), step S508 and step S509: YES are repeated, and the latest one xy coordinate remains valid.
In step S509, when the detection state of the latest xy coordinate becomes 0 (step S509: NO), the control unit 6 returns to step S501.
If the number of xy coordinates that have been detected within the first predetermined time is 0 in step S504, the control unit 6 returns to step S501.
In addition, in the coordinate determination method of FIG. 26, the control part 6 does not validate an xy coordinate in principle except validating an xy coordinate by step S506 or step S508.
The control unit 6 executes the coordinate determination method shown in FIG. 26 in addition to the input method such as the detection start time shown in FIG. 24 and the detection state update method shown in FIG. To do.
27A, 27B, 27C, and 27D are schematic diagrams illustrating examples of coordinate determination, respectively. FIG. 27A corresponds to FIG. 23A and is an example in which the coordinates of indicators such as # 2 and # 3 are validated. FIG. 27B corresponds to FIG. 23B and the coordinates of indicators such as # 3 are valid. This is an example. FIG. 27C corresponds to FIG. 23C and is another example in which the coordinates of the indicator or the like are validated only for # 3. FIG. 27D corresponds to FIG. 23D and any of # 1, # 2, and # 3 is valid. This is not an example. These four examples will be described with reference to FIGS. 23A, 23B, 23C, 23D, 27A, 27B, 27C, and 27D. Here, the first predetermined time is 2.00 seconds, and the first predetermined time is 1.00 seconds.
In the state of the coordinate detection state management table as shown in FIG. 23A, for example, when the pressure sensor 3 detects a pressure at 12: 33: 46.22 seconds, as shown in FIG. The detection disclosure time is earlier than the first predetermined time (2.00 seconds) based on the pressing time, and the difference between the detection start times of the indicators # 2, # 3, etc. is within the first predetermined time. It is.
Also, the detection disclosure time of # 3 indicator or the like is closest to the pressing time (the detection disclosure time of # 3 is closer to the pressing time than the detection disclosure time of # 2), and detection start of # 3 The detection disclosure time of # 2 with respect to the time is within the second predetermined time (1.00 seconds).
If such an example is applied to the coordinate determination method of FIG. 26, when the pressure is detected by the pressure sensor 3 (step S501, step S502: YES), the current time at the time of pressing (12: 33: 46.22 seconds) (Step S503), and within the first predetermined time (2.00 seconds) from the current time (12: 33: 46.22 seconds) among the coordinates of # 1, # 2, and # 3 being detected The two xy coordinates are # 2 and # 3 (step S504: 2 or more), and within the first predetermined time (2.00 seconds) from the current time (12: 33: 46.22 seconds). Certain coordinates of # 2 and # 3 are selected (step S510).
Next, since the difference between the coordinate detection start times of # 2 and # 3 is within the second predetermined time (1.00 second) (step S505: YES), the coordinates of # 2 and # 3 are validated ( Step S506). Note that the coordinates of # 1 are not validated.
While both indicators # 2 and # 3 are in the detection state (detection state = 1) (step S507: YES, repetition of step S506), the xy coordinates of # 2 and # 3 are kept valid and # When any of the indicators 2 and # 3 is not in the detection state (detection state = 0) (step S507: NO), the process returns to the beginning (step S501).
In FIGS. 27A, 27B, 27C, and 27D, the horizontal axis indicates the time, and the time increases as it goes to the right. In this horizontal axis, a thick white arrow indicates a time when the pressure sensor 3 detects a press, and thin arrows corresponding to # 1, # 2, and # 3 correspond to # 1, # 2, and # 3. Indicates the detection start time of an indicator or the like.
In the state of the coordinate detection state management table as shown in FIG. 23B, for example, when the pressure sensor 3 detects a pressure at 14: 01: 31.98 seconds, as shown in FIG. The detection disclosure time is before the first predetermined time (2.00 seconds) based on the pressing time, and the difference between the detection start times of the indicators # 2, # 3 etc. is from the first predetermined time. large.
When such an example is applied to the coordinate determination method of FIG. 26, when the pressure is detected by the pressure sensor 3 (step S501, step S502: YES), the current time at the time of pressing (14: 01: 31.98 seconds) (Step S503), and within the first predetermined time (2.00 seconds) from the current time (14: 01: 31.98 seconds) among the coordinates of # 1, # 2, and # 3 being detected The two xy coordinates are # 2 and # 3 (step S504: 2 or more), and within the first predetermined time (2.00 seconds) from the current time (14: 01: 31.98 seconds). Certain coordinates of # 2 and # 3 are selected (step S510).
Next, since the difference between the coordinate detection start times of # 2 and # 3 is larger than the second predetermined time (1.00 second) (step S505: NO), the coordinate of # 3 is validated (step S508). Note that the coordinates of # 1 and # 2 are not validated.
While both the indicators of # 3 are in the detection state (detection state = 1) (step S509: YES, repetition of step S508), the xy coordinate of # 3 is kept valid and the indicator of # 3 is detected When it is no longer in a state (detection state = 0) (step S509: NO), the process returns to the beginning (step S501).
In the state of the coordinate detection state management table as shown in FIG. 23C, for example, when the pressure sensor 3 detects a press at 15: 54: 23.24 seconds, as shown in FIG. The detection disclosure time of the body or the like is before the first predetermined time (2.00 seconds) when the pressing time is the reference, and the detection start time of the # 3 indicator or the like is the first when the pressing time is the reference. Within a predetermined time.
If such an example is applied to the coordinate determination method of FIG. 26, when the pressure is detected by the pressure sensor 3 (step S501, step S502: YES), the current time at the time of pressing (15: 54: 23.24 seconds) (Step S503), and within the first predetermined time (2.00 seconds) from the current time (15: 54: 23.24 seconds) among the coordinates of # 1, # 2, and # 3 being detected The xy coordinate is one of # 3 (step S504: one), and the coordinate of # 3 is validated (step S508). Note that the coordinates of # 1 and # 2 are not validated.
While the # 3 indicator is in the detection state (detection state = 1) (step S509: YES, repeat step S508), the xy coordinate of # 3 is kept valid and the # 3 indicator is in the detection state. If no more (detected state = 0) (step S509: NO), the process returns to the beginning (step S501).
In the state of the coordinate detection state management table as shown in FIG. 23D, for example, when the pressing sensor 3 detects pressing at 16: 01: 39.54 seconds, as shown in FIG. 27D, # 1, # 2, # The detection disclosure time of the indicator 3 or the like is before the first predetermined time (2.00 seconds) when the pressing time is used as a reference.
When such an example is applied to the coordinate determination method of FIG. 26, when the pressure is detected by the pressure sensor 3 (step S501, step S502: YES), the current time at the time of pressing (16: 01: 39.54 seconds) (Step S503), and within the first predetermined time (2.00 seconds) from the current time (16: 01: 39.54 seconds) among the coordinates of # 1, # 2, and # 3 being detected The number of xy coordinates is zero (step S504: zero), and the process returns to the beginning (step S501). In this example, the coordinates of # 1, # 2, and # 3 are not validated.
Note that the value of the xyz coordinate in FIG. 23 is a value indicating a difference from the origin with respect to xy with a predetermined point as the origin. The unit is, for example, mm. About z, it is a value which shows the distance from the said upper surface along the direction which makes the upper surface of the glass 11 0 and goes to the glass 11 from a touch panel layer. The unit is, for example, mm. However, the z-coordinate is a value based on the capacitance value with the indicator, and slightly changes depending on the area of the indicator.
Further, the two most recent xy coordinates validated in step S506 can be used for a pinch operation or the like, and the one most recent xy coordinate validated in step S508 can be used for a pointer coordinate or the like.
In the coordinate determination method of FIG. 26 described as described above, a part may be cut out and executed. For example, step S501, step S502, step S503, step S504, step S506, or step S508 may be cut out and executed. In this case, when a plurality of two-dimensional coordinates are detected by the touch panel unit and a predetermined amount of distortion is detected by the press detection unit, during the first predetermined time toward the past based on the time when the distortion is detected. Since at least one detected two-dimensional coordinate is valid and two-dimensional coordinates detected before a predetermined time are not valid based on the time when distortion is detected, a conductor such as a water drop continues on the touch panel. The two-dimensional coordinates detected during a predetermined time toward the past are validated with reference to the time when pressing is detected by operating with a bare hand or the like (for example, bare hands and gloves) Since the two-dimensional coordinates are not validated, the operation of bare hands or the like (for example, bare hands and gloves) that are likely to be within a predetermined time immediately before pressing can be performed more reliably, and the water that is likely to be before that. Adhesion etc. can be prevented more from being erroneously detected as an operation.
Further, for example, step S501, step S502, step S503, step S504, step S508, etc. may be cut out and executed. In this case, when a plurality of two-dimensional coordinates are detected by the touch panel unit and a predetermined amount of distortion is detected by the press detection unit, during the first predetermined time toward the past based on the time when the distortion is detected. Among the detected two-dimensional coordinates, at least one two-dimensional coordinate is validated, and the two-dimensional coordinates detected before the first predetermined time on the basis of when the distortion is detected are not validated. When a conductor such as a water droplet is continuously attached to at least one of the two-dimensional coordinates, the operation is performed with a bare hand or the like (for example, a bare hand or a glove) and the pressure is detected. The two-dimensional coordinates detected during a predetermined time are validated, and the previous two-dimensional coordinates are not validated, so bare hands, etc. that are likely to be within the predetermined time immediately before pressing (for example, bare hands and gloves) Operation Ri certainly is possible execution, it can be further prevented that the potential is earlier than erroneously detected as an operation adhesion of high water droplets. In addition, since the most recent coordinates are validated within a predetermined time, it is possible to further prevent erroneous detection of adhesion of water droplets or the like as an operation.
Further, for example, step S501, step S502, step S503, step S504, step S508, step S509, etc. may be cut out and executed. In this case, among the two-dimensional coordinates detected during the first predetermined time from the past when the distortion is detected, the latest two-dimensional coordinates are calculated based on the time when the distortion is detected. After the activation, the indicator related to the activated two-dimensional coordinates can follow the change of the activated two-dimensional coordinates until the indicator moves away from the touch panel unit, and is newly detected after the activation. Since the two-dimensional coordinates related to the indicator are not validated, it is possible to prevent erroneous detection of the attachment of water droplets or the like after the latest two-dimensional coordinates are validated as an operation.
Further, for example, step S501, step S502, step S503, step S504, step S510, step S505, step S506, step S508, etc. may be cut out and executed. In this case, when a plurality of two-dimensional coordinates are detected by the touch panel unit and a predetermined amount of distortion is detected by the press detection unit, during the first predetermined time toward the past based on the time when the distortion is detected. Among the detected two-dimensional coordinates, the two most recent two-dimensional coordinates are selected based on the time when the distortion is detected, and the difference between the detection start times of the indicators related to the two selected two-dimensional coordinates is the second. If it is smaller than the predetermined time, the two selected two-dimensional coordinates are validated, and if the difference between the detection start times of the indicators related to the two selected two-dimensional coordinates is larger than the second predetermined time, distortion is detected. Since the most recent two-dimensional coordinate is made effective on the basis of the contact time, when a touch is detected by operating with a bare hand or the like (for example, bare hands and gloves) in a state where a conductor such as a water droplet is continuously attached to the touch panel First in the past based on Select the two most recent two-dimensional coordinates detected during a given time and validate the two most recent two-dimensional coordinates according to the difference between the two most recent detection disclosure times, or activate the one most recent two-dimensional coordinate Since the two-dimensional coordinates before the activated two-dimensional coordinates are not validated by switching to or from, the bare hands or the like (eg, bare hands and gloves) that are likely to be within the first predetermined time immediately before pressing The operation can be executed more reliably, and it is possible to prevent more erroneous detection of the attachment of water drops or the like that are likely to be before it, and to support one-point touch and two-point touch. it can.
Further, for example, step S501, step S502, step S503, step S504, step S510, step S505, step S506, step S507, step S508, etc. may be cut out and executed. In this case, after the two selected two-dimensional coordinates are activated, the activated two-dimensional coordinates of the activated two-dimensional coordinates are kept until one of the indicators related to the activated two-dimensional coordinates is separated from the touch panel unit by a predetermined distance. Since it is possible to follow the change and the two-dimensional coordinates related to the newly detected indicator after the activation are not validated, it is an operation to attach water droplets etc. after the two most recent two-dimensional coordinates are validated. Can be prevented from being erroneously detected.
The present invention is useful for a technique (for example, an apparatus, a system, a method, a program, etc.) using a capacitive touch panel.
DESCRIPTION OF SYMBOLS 1 Electronic device 2 Touch panel layer 3 Press sensor 4 Display part 5 Memory | storage part 6 Control part 10 Housing | casing 11 Glass 12 Framework part 23 Indentation part 30 Icon 41 LCD
42 Backlight 70 Finger 71 Gloves 80, 81 Water drops
A display unit disposed in the housing and displaying predetermined information;
A capacitive touch panel that transmits the display of the display;
A transparent member that protects the touch panel unit and transmits the display of the display unit;
A pressure detection unit that is disposed between the display unit and the transparent member and detects distortion of the transparent member;
The touch panel unit is an electronic device capable of detecting a two-dimensional coordinate of an indicator having predetermined conductivity,
When a plurality of two-dimensional coordinates are detected by the touch panel unit and a predetermined amount of distortion is detected by the press detection unit,
Enabling at least one two-dimensional coordinate detected during a predetermined time toward the past with respect to the time when the distortion is detected;
Two-dimensional coordinates detected before the predetermined time on the basis of the time when the distortion is detected are not validated.
The predetermined time does not include a time when the distortion is detected,
Among the two-dimensional coordinates detected during a predetermined time toward the past with respect to the time when the distortion is detected, the latest one two-dimensional coordinate is enabled based on the time when the distortion is detected,
The two-dimensional coordinates detected before the predetermined time on the basis of the time when the distortion is detected are not valid, and among the two-dimensional coordinates detected during the predetermined time, the latest one two-dimensional coordinate Do not enable 2D coordinates other than
After validating the latest two-dimensional coordinates based on the time when the distortion is detected out of the two-dimensional coordinates detected during the predetermined time from the past when the distortion is detected Can follow the change of the validated two-dimensional coordinate until the indicator related to the validated two-dimensional coordinate moves away from the touch panel unit by a predetermined distance, and is newly detected after the validation. 2D coordinates related to the indicator are not activated,
The predetermined time is a first predetermined time,
Based on the time when the distortion is detected, the two most recent two-dimensional coordinates are selected from the two-dimensional coordinates detected during the first predetermined time period based on the time when the distortion is detected. And
If the difference between the detection start times of the indicators related to the two selected two-dimensional coordinates is smaller than the second predetermined time, the selected two two-dimensional coordinates are enabled,
When the difference between the detection start times of the indicators related to the two selected two-dimensional coordinates is larger than the second predetermined time, the latest one two-dimensional coordinate is enabled based on the time when the distortion is detected.
The second predetermined time is shorter than the first predetermined time;
The electronic device according to claim 5 or 6,
After the two selected two-dimensional coordinates are validated, the validated two-dimensional coordinates are kept until one of the indicators related to the validated two-dimensional coordinates is separated from the touch panel unit by a predetermined distance. The two-dimensional coordinates of the indicator that is newly detected after the activation is not activated,
The touch panel unit is a coordinate detection method that can be used for an electronic device, capable of detecting a two-dimensional coordinate of an indicator having predetermined conductivity,
Coordinate detection method.
JP2014184185A 2013-08-08 2014-09-10 Electronic device and coordinate detection method Active JP5732580B2 (en)
JP2014184185A JP5732580B2 (en) 2013-08-08 2014-09-10 Electronic device and coordinate detection method
JP2014110345 Division 2014-05-28
JP2015053058A JP2015053058A (en) 2015-03-19
JP5732580B2 true JP5732580B2 (en) 2015-06-10
ID=51176045
JP2014184185A Active JP5732580B2 (en) 2013-08-08 2014-09-10 Electronic device and coordinate detection method
US (1) US9141245B2 (en)
EP (1) EP2835725B1 (en)
JP (1) JP5732580B2 (en)
JP5866526B2 (en) * 2014-06-20 2016-02-17 パナソニックＩｐマネジメント株式会社 Electronic device, control method, and program
JP6486158B2 (en) * 2015-03-16 2019-03-20 三菱電機株式会社 Touch panel device
JPH05173695A (en) 1991-12-24 1993-07-13 Fujitsu Ltd Coordinate input device
JP2011096271A (en) 2010-12-10 2011-05-12 Tyco Electronics Corp Contact authentication touch screen using a plurality of touch sensors
US9753560B2 (en) 2011-12-30 2017-09-05 Sony Corporation Input processing apparatus
2014-02-07 US US14/174,994 patent/US9141245B2/en active Active
2014-05-28 EP EP14170261.3A patent/EP2835725B1/en active Active
2014-09-10 JP JP2014184185A patent/JP5732580B2/en active Active
JP2015053058A (en) 2015-03-19
EP2835725A3 (en) 2015-04-01
US20150042603A1 (en) 2015-02-12
EP2835725A2 (en) 2015-02-11
US9141245B2 (en) 2015-09-22
EP2835725B1 (en) 2017-01-25
JP2017079079A (en) 2017-04-27 Menu operation method and menu operation device including touch input device conducting menu operation
JP5660745B2 (en) 2015-01-28 Portable electronic device and brightness control method
US9632646B2 (en) 2017-04-25 Electronic apparatus
JP5642900B2 (en) 2014-12-17 Electronic device and vibration control method
TWI382739B (en) 2013-01-11 Method for providing a scrolling movement of information,computer program product,electronic device and scrolling multi-function key module
Ref document number: 5732580