JP2019211954A - Controller of touch sensor, touch sensor unit and operation input method - Google Patents

Abstract

To provide a controller of a touch sensor capable of suppressing an erroneous operation with higher accuracy, a touch sensor unit, and an operation input method.SOLUTION: In a controller 120 of a touch sensor 110, a detection unit 40 detects contact with a first touch sensor surface and contact with a second touch sensor surface. An operation input unit 60 receives a prescribed operation input in the case that contact with the second touch sensor surface is detected after the detection of the touch with the first touch sensor surface ends. The operation input unit 60 cancels the prescribed operation unit in the case that the contact with the second touch sensor surface is detected before the detection of the touch with the first touch sensor surface ends.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a touch sensor controller, a touch sensor unit, and an operation input method.

  A technology that enables a switch operation when a user touches the operation switch with a fingertip using a touch sensor is used. A mechanical switch causes a failure due to wear or breakage of a switch portion by a switch operation, but a touch sensor switch has an advantage that such a mechanical failure does not occur.

  In general, the sensitivity of a touch sensor with respect to a touch operation is higher than that of a mechanical switch. Therefore, a touch sensor is more likely to malfunction than a mechanical switch when touched unintentionally. Japanese Patent Application Laid-Open No. 2004-228561 discloses a technique in which two touch sensors are provided in a camera casing in order to suppress malfunction, and a switch operation is performed to capture an image when the two touch sensors are touched in order.

JP 2002-232770 A

  In the technique of Patent Document 1, even when one touch sensor is unintentionally touched with one touch sensor and the other touch sensor is touched with another finger, there is a possibility that the switch operation is erroneously performed. is there. Therefore, there is room for improvement in suppressing malfunction.

  The present invention has been made in view of such circumstances, and an object of the present invention is to provide a touch sensor controller, a touch sensor unit, and an operation input method that can suppress malfunctions with higher accuracy.

  In order to solve the above problems, a touch sensor controller according to an aspect of the present invention includes a detection unit that detects contact on a first touch sensor surface and contact on a second touch sensor surface, and a first touch. When contact on the second touch sensor surface is detected after detection of contact on the sensor surface is interrupted, the second touch sensor receives a predetermined operation input and before the detection of contact on the first touch sensor surface is interrupted. An operation input unit that cancels a predetermined operation input when contact on the surface is detected.

  Another aspect of the present invention is a touch sensor unit. The touch sensor unit includes: a first touch sensor surface; a second touch sensor surface; a contact on the first touch sensor surface; a detection unit that detects contact on the second touch sensor surface; When contact on the second touch sensor surface is detected after the detection of contact on the touch sensor surface is interrupted, a predetermined operation input is received, and the second touch before the detection of contact on the first touch sensor surface is interrupted. An operation input unit that cancels a predetermined operation input when contact on the touch sensor surface is detected.

  Yet another embodiment of the present invention is an operation input method. In this method, when a contact on the first touch sensor surface is detected and a contact on the second touch sensor surface is detected after the detection of the contact on the first touch sensor surface is interrupted, a predetermined operation input is performed. Receiving and canceling a predetermined operation input when contact on the second touch sensor surface is detected before detection of contact on the first touch sensor surface is interrupted.

  It should be noted that any combination of the above-described constituent elements and the expression of the present invention converted between a method, an apparatus, a system, a computer program, a data structure, a recording medium, and the like are also effective as an aspect of the present invention.

  According to the present invention, malfunction can be suppressed with higher accuracy in a touch sensor.

It is a block diagram of the touch sensor unit which concerns on embodiment. It is a figure explaining the slide operation in the touch sensor of FIG. It is sectional drawing explaining another structural example of a touch sensor. It is sectional drawing explaining another example of a structure of a touch sensor. It is a top view explaining another example of composition of a touch sensor. It is a top view explaining another example of composition of a touch sensor. It is a top view explaining another example of composition of a touch sensor. It is a top view explaining another example of composition of a touch sensor. FIG. 9A and FIG. 9B are diagrams illustrating still another configuration example of the touch sensor. It is a top view explaining another example of composition of a touch sensor. FIG. 11A and FIG. 11B are perspective views illustrating still another configuration example of the touch sensor. FIG. 12A and FIG. 12B are plan views illustrating still another configuration example of the touch sensor. It is a top view explaining another example of composition of a touch sensor. It is a top view explaining another example of composition of a touch sensor.

  FIG. 1 is a configuration diagram of a touch sensor unit 100 according to an embodiment. The touch sensor unit 100 functions as a touch sensor switch. The touch sensor unit 100 includes a touch sensor 110 and a controller 120.

  The touch sensor 110 is an input device that detects a contact point by a finger or the like and a state quantity such as a capacitance or an electric resistance indicating a contact state at the contact point by various methods. The touch sensor 110 is, for example, a capacitive, resistive, or infrared touch sensor. Alternatively, the touch sensor 110 may be an ultrasonic surface acoustic wave type touch sensor including a plurality of piezoelectric elements. As an example, the touch sensor 110 may be embedded in a wall or may be provided in a specific device.

  The touch sensor 110 includes a first touch sensor surface (also referred to as A surface) 10 a, a second touch sensor surface (also referred to as B surface) 10 b, and an operation surface 20. The first and second touch sensor surfaces 10 a and 10 b are collectively referred to as a touch sensor surface 10. The touch sensor 110 senses whether there is contact with each of the A surface 10a and the B surface 10b. The distance between the A surface 10a and the B surface 10b is, for example, not less than the width of the user's finger. The operation surface 20 is provided between the A surface 10a and the B surface 10b.

  FIG. 2 is a diagram for explaining a slide operation in the touch sensor 110 of FIG. A slide operation from the A surface 10 a to the B surface 10 b via the operation surface 20 or a slide operation from the B surface 10 b to the A surface 10 a via the operation surface 20 is performed by the user's fingertip or the like. After touching one touch sensor surface 10 with a fingertip or the like, even if a finger is released from one touch sensor surface 10 and the operation surface 20 is not slid, the touch operation touching the other touch sensor surface 10 is performed. Good.

  Returning to FIG. The controller 120 is connected to the touch sensor 110, detects a contact point and a state quantity on the touch sensor 110, and performs predetermined signal processing on the detected signal. The controller 120 determines whether or not a predetermined touch operation has been performed on the touch sensor 110 with a fingertip of the user or the like, and when a predetermined touch operation is performed, receives the predetermined operation input and shifts the operation to execution. . The predetermined operation input is, for example, an operation of turning on or off a switch used for lighting or specifying an elevator stop floor, or an operation of increasing or decreasing a volume such as a volume.

  The controller 120 includes a detection unit 40, a determination unit 50, and an operation input unit 60. These functional configurations can be implemented by hardware, software, or a combination thereof.

  The detection unit 40 detects the presence or absence of contact with a fingertip or the like in the touch sensor 110. The detection unit 40 detects contact on the A surface 10a and contact on the B surface 10b.

  Based on the presence or absence of the contact detected by the detection unit 40, the determination unit 50 performs the first touch operation when the contact on the B surface 10b is detected within a predetermined time after the detection of the contact on the A surface 10a is interrupted. It is determined that has been made. Moreover, the determination part 50 determines with 2nd touch operation having been performed, when the contact in A surface 10a is detected within the predetermined time after the detection of the contact in B surface 10b interrupted. The predetermined time is not particularly limited, but may be, for example, 1 second or less, and the optimum value can be appropriately determined by experiment.

  When the determination unit 50 determines that a touch operation has been performed, the operation input unit 60 receives a predetermined operation input corresponding to the touch operation and shifts to execution. For example, the operation input unit 60 accepts an operation input such as turning on a switch or increasing the volume in response to a first touch operation, and turning off the switch or lowering the volume in response to a second touch operation. Is controlled so that the operation is executed.

  The determination unit 50 determines that the touch operation is incomplete when the contact on the B surface 10b is not detected within a predetermined time after the detection of the contact on the A surface 10a is interrupted. If the determination unit 50 determines that the touch operation has not been completed, the operation input unit 60 cancels reception of the operation input.

  As described above, since the operation input is not accepted unless the plurality of touch sensor surfaces 10 are sequentially touched, it is possible to prevent the switch from malfunctioning when the touch sensor surface 10 is unintentionally touched. Even when only one touch sensor surface 10 is touched by mistake and the other touch sensor surface 10 is touched after a predetermined time has elapsed, malfunction can be suppressed.

  In addition, since an active operation that requires the user to pay attention to the plurality of touch sensor surfaces 10 in sequence is required during operation, the touch switch can be operated only by touching one place. The user can clearly recognize that the operation has been input.

  Further, the determination unit 50 detects the contact on the A surface 10a when the contact on the B surface 10b is detected before the detection of the contact on the A surface 10a is interrupted, or before the detection of the contact on the B surface 10b is interrupted. In this case, it is determined that the touch operation is not completed. That is, when contact is simultaneously detected on both the A surface and the B surface 10b, it is determined that the touch operation is incomplete.

  Since the distance between the A surface 10a and the B surface 10b is larger than the width of the finger, it is assumed that the slide operation intended for the switch operation hardly makes contact with both the A surface 10a and the B surface 10b at the same time. On the other hand, when the touch sensor surface 10 is touched with another finger while one finger is unintentionally touched instead of a slide operation, a malfunction that the operation input is erroneously performed when the other touch sensor surface 10 is touched with another finger. Can be suppressed. Therefore, malfunction can be suppressed with higher accuracy.

  By the way, in the case of a touch sensor switch, since there is no mechanical switch operation, the switch operation may not be transmitted to the fingertip as a tactile sensation, and it may be difficult to determine whether the switch is turned on. For this reason, conventionally, even in the case of a touch sensor, a method has been adopted in which mechanical vibration is transmitted to the fingertip to give an operational feeling. However, in the method of applying some mechanical vibration in the touch sensor, it is necessary to provide a vibration mechanism in the touch sensor, which increases the number of components, hinders downsizing, and increases manufacturing costs.

  Accordingly, various configuration examples of the touch sensor 110 that can provide a tactile sense of operation with a simple configuration will be described below. Hereinafter, the basic operation of the controller 120 is the same as described above.

  FIG. 3 is a cross-sectional view illustrating another configuration example of the touch sensor 110. FIG. 3 is a longitudinal section along the operation direction of the slide operation.

  In this configuration example, the operation surface 20 is changed in tactile sensation during a slide operation from the A surface 10a to the B surface 10b via the operation surface 20 and in a slide operation in the opposite direction. Composed. Specifically, the operation surface 20 is provided with an inclined surface 22. The inclined surface 22 rises as it approaches the B surface 10b from the A surface 10a. Here, it is assumed that the fingertip is moved from the state in which the fingertip is in contact with the A surface 10a to climb the inclined surface 22, and the state is changed to a state in which the fingertip is in contact with the B surface 10b. At this time, a feeling that the fingertip has climbed the inclined surface 22 is transmitted.

  In addition, a sliding operation from the B surface 10b to the A surface 10a conveys a feeling that the fingertip has descended the inclined surface 22. That is, the change in tactile sensation during the slide operation from the A surface 10a to the B surface 10b via the operation surface 20 is the change in the tactile sensation during the slide operation from the B surface 10b to the A surface 10a via the operation surface 20. Different.

  Since the user feels feedback of the finger feeling that the user has climbed the slope 22 or has gone down the slope 22, the user is given a feeling of operation input. Therefore, it is possible to perform an operation while predicting the operation result or confirming the operation direction without looking at the hand. Since it is not necessary to look at the hand, it is also suitable for operation in dark places.

  For example, when the predetermined operation input is an operation for increasing the temperature of the air conditioner, there is a possibility that a time difference may occur between the time when the operation is performed and the time when the temperature is increased. In this case, since the operation result can be predicted by the touch of the finger that has climbed the inclined surface 22, it is possible to give the user a sense of security that the correct operation has been performed even before experiencing the operation result.

  FIG. 4 is a cross-sectional view illustrating still another configuration example of the touch sensor 110. In this configuration example, a convex portion 24 is provided on the operation surface 20. By the sliding operation from the A surface 10a to the B surface 10b, a feeling that the fingertip has been overcome is transmitted to the fingertip. Since the user feels feedback of the finger feeling that the user has overcome the convex portion 24, the user is given an operational feeling that an operation input has been performed.

  The shape of the convex portion 24 is arbitrary, and may be a shape that gives some feeling when the user slides the finger. For example, the convex portion 24 may be an acute-angle convex portion 24 or a convex portion 24 having a curvature. The size of the convex portion 24 in the sliding operation direction may be smaller than the width of the finger. The operation surface 20 may be provided with a concave portion (not shown) instead of the convex portion 24.

  The convex part 24 may be provided near the B surface 10b, for example. This is to make the user perceive that the B surface 10b side corresponds to ON. The presence of the convex portion 24 makes it possible to tactilely sense which of the two touch sensor surfaces 10 is on, so that the user can be prevented from performing a sliding operation in an incorrect direction.

  FIG. 5 is a plan view illustrating still another configuration example of the touch sensor 110. In addition to the configuration of FIG. 1, the touch sensor 110 has a convex portion 26, a third touch sensor surface (also referred to as C surface) 10 c, a fourth touch sensor surface (also referred to as D surface) 10 d, and another operation The surface 20b and the convex part 28 are provided.

  The convex portion 26 is provided on the operation surface 20a. The set of A surface 10a and B surface 10b is arranged in parallel with the set of C surface 10c and D surface 10d. The distance between the A surface 10a and the B surface 10b is substantially equal to the distance between the C surface 10c and the D surface 10d.

  Another operation surface 20b is provided between the C surface 10c and the D surface 10d. The other operation surface 20b is configured such that a tactile sensation is changed during a slide operation from the C surface 10c to the D surface 10d via the other operation surface 20b. The convex portion 28 is provided on another operation surface 20b.

  The change in tactile sensation during the sliding operation in the same direction is different between the operation surface 20a and another operation surface 20b. In this configuration example, the convex portion 26 is provided closer to the B surface 10b. The convex portion 28 is provided closer to the C surface 10c.

  The processing of the controller 120 related to the C surface 10c and the D surface 10d is the same as the processing related to the A surface 10a and the B surface 10b except that the received operation input is different. The detection unit 40 detects contact on the C surface 10c and contact on the D surface 10d. The operation input unit 60 receives an operation input different from a predetermined operation input when the contact on the D surface 10d is detected after the detection of the contact on the C surface 10c is interrupted. In this case, for example, a switch different from a switch to be turned on by a predetermined operation input is turned on.

  Compared with the sliding operation from the A surface 10a to the B surface 10b, the sliding operation from the C surface 10c to the D surface 10d has the same sliding direction, but the timing at which the feeling that the bump 28 has been overcome is transmitted to the fingertip. Is early. Therefore, even when a plurality of sets of touch sensor surfaces 10 corresponding to different operation inputs are arranged, the user can easily recognize what switch the touch sensor surface 10 is operating due to the difference in tactile sense. Can do.

  FIG. 6 is a plan view illustrating still another configuration example of the touch sensor 110. In this configuration example, the convex portion 30 of the operation surface 20 extends in the direction from the A surface 10a toward the B surface 10b, and the width of the convex portion 30 changes according to the distance from the A surface 10a. Specifically, the width of the convex portion 30 increases as the distance from the A surface 10a increases. The operation surface 20 may be provided with a concave portion instead of the convex portion 30.

  By the sliding operation from the A surface 10a to the B surface 10b, a feeling that the width of the convex portion 30 gradually increases is transmitted to the fingertip. By the sliding operation in the opposite direction, a feeling that the width of the convex portion 30 is gradually narrowed is transmitted to the fingertip. Therefore, the operation feeling that the operation input has been performed is given, and the operation result can be predicted and the operation direction can be confirmed without looking at the hand.

  FIG. 7 is a plan view illustrating still another configuration example of the touch sensor 110. The operation surface 20 is provided with a plurality of convex portions 32 arranged in the operation direction of the slide operation. In plan view, the convex portion 32 is asymmetric with respect to the axis in the operation surface 20 orthogonal to the operation direction, and has a crescent shape with an apex located on the A surface 10a side as an example.

  In this configuration example, compared with the sliding operation from the A surface 10a to the B surface 10b, the resistance transmitted to the fingertip by the convex portion 32 is large in the sliding operation in the opposite direction, and the user may feel it difficult to slide the finger. Therefore, it is possible to perform an operation while predicting the operation result or confirming the operation direction without looking at the hand.

  By providing physical convex portions, concave portions, or inclined surfaces on the operation surface 20 of the touch sensor 110 in this way, the operation feeling is transmitted as a touch to the fingertip when a slide operation is performed. It has the effect of being clearly recognized. Since it is only necessary to provide the touch sensor 110 with a convex part, a concave part or an inclined surface, the number of parts can be reduced and the manufacturing cost can be reduced compared with the case where mechanical vibration is given by a vibration element or the like, and the structure is also simple. Therefore, there are few failures.

  FIG. 8 is a plan view illustrating still another configuration example of the touch sensor 110. In this configuration example, the operation surface 20 is not provided with a physical bump or the like, and the surface processing is different between the A surface 10 a and the B surface 10 b and the operation surface 20. As an example, the A surface 10a and the B surface 10b are flat and smooth surfaces, but the operation surface 20 is subjected to rough surface processing. Therefore, when the fingertip is slid from the A surface 10a to the B surface 10b, the difference in texture is transmitted to the fingertip. Since the user feels that the tactile sensation has changed, the user feels that the operation input has been performed. The surface processing of the operation surface 20 may be changed according to the distance from the A surface 10a, or may be different for only a part of the operation surface 20.

  FIG. 9A and FIG. 9B are diagrams illustrating still another configuration example of the touch sensor 110. 9A is a perspective view of the touch sensor 110, and FIG. 9B is a cross-sectional view taken along the line X-X ′ of FIG. 9A.

  In this configuration example, the texture when touching the A surface 10a and the B surface 10b and the operation surface 20 is different. Specifically, the material of the operation surface 20 is different from the material of the A surface 10a and the B surface 10b. For example, the operation surface 20 is made of wood, and the A surface 10a and the B surface 10b are made of plastic, glass, or the like. Since the user feels that the tactile sensation has changed, the user feels that the operation input has been performed. In addition, the user can enjoy the touch of wood during the slide operation.

  Further, the surface of the touch sensor 110 is recessed, and the operation surface 20 and the touch sensor surface 10 are provided in the recessed region. Therefore, the user can easily perform a slide operation along the recessed area.

  In this way, when the sliding motion is performed, the texture perceived by the fingertip is changed, so that the operational feeling can be fed back to the user without providing a physical bump or the like on the operation surface 20.

  As another configuration example, the surface temperatures of the A surface 10a and the B surface 10b and the operation surface 20 can be made different. The difference in surface temperature may be an actual temperature difference, but not an actual temperature difference, but a difference in temperature experienced.

  The temperature of the operation surface 20 may change according to the distance from the A surface 10a. For example, when the touch sensor 110 is a heating switch, the on-side B surface 10b may be heated with a heating wire or the like so that the surface temperature is higher than that on the off-side A surface 10a.

  FIG. 10 is a plan view illustrating still another configuration example of the touch sensor 110. In this configuration example, the B surface 10b has an annular shape surrounding the circumference of the circular A surface 10a in plan view. An annular operation surface 20 is provided between the A surface 10a and the B surface 10b. In the sliding operation from the A surface 10a to the B surface 10b and the sliding operation in the opposite direction, a sliding operation in an arbitrary direction such as up / down / left / right and diagonal in the surface can be detected. Therefore, the degree of freedom in the direction of the slide operation can be increased.

  FIG. 11A and FIG. 11B are perspective views illustrating still another configuration example of the touch sensor 110. In FIG. 11A, the touch sensor 110 has a convex portion formed in a truncated cone shape. The A surface 10a is provided on the upper surface of the convex portion. The B surface 10b is annularly provided on the side surface of the convex portion. An operation surface 20 is annularly provided on the side surface of the convex portion between the A surface 10a and the B surface 10b.

  In FIG.11 (b), the touch sensor 110 has a recessed part formed in the truncated cone shape. The A surface 10a is provided on the bottom surface of the recess. The B surface 10b is annularly provided on the side surface of the recess. An operation surface 20 is annularly provided on the side surface of the recess between the A surface 10a and the B surface 10b.

  In these configuration examples, it is possible to give the user a feeling of operation different from the configuration example in which the two touch sensor surfaces 10 are provided on the same plane in FIG. In addition, a convex part or a recessed part may be a truncated pyramid shape etc. instead of a truncated cone shape.

  FIGS. 12A and 12B are plan views for explaining still another configuration example of the touch sensor 110. FIG. The touch sensor 110 is used, for example, as a volume control that increases or decreases the volume in stages.

  In the configuration example of FIG. 12A, the touch sensor 110 has four touch sensor surfaces 10 arranged in a line, that is, an A surface 10a, a B surface 10b, a C surface 10c, and a D surface 10d. An operation surface 20 is provided between two adjacent touch sensor surfaces 10.

  The operation input unit 60 increases the amount of operation input when the contact on the B surface 10b is detected within a predetermined time after the detection of the contact on the A surface 10a is interrupted, and after the detection of the contact on the B surface 10b is interrupted. When contact on the C surface 10c is detected within a predetermined time, the operation input amount is increased. The operation input unit 60 increases the amount of operation input when contact on the D surface 10d is detected within a predetermined time after detection of contact on the C surface 10c is interrupted.

  By sliding the fingertip from the A surface 10a to the B surface 10b, the C surface 10c, and the D surface 10d, a volume adjustment command such as increasing the sound volume is executed. By sliding the fingertip in the reverse direction, for example, a volume adjustment command such as decreasing the volume is executed. The amount of operation input changes according to the number of touch sensor surfaces 10 in contact.

  In the configuration example of FIG. 12B, the touch sensor 110 has an A surface 10a, a B surface 10b, a C surface 10c, a D surface 10d, an E surface 10e, and an F surface 10f that are arranged in a circular shape. Is made into a circle. For example, a slide operation is performed in the order of A surface 10a, B surface 10b, C surface 10c, D surface 10d, E surface 10e, and F surface 10f, followed by a slide operation on A surface 10a, B surface 10b, etc. As compared with the case where the touch sensor surfaces 10 are arranged in a line, the volume adjustment can be executed continuously with a wider adjustment width.

  In these configuration examples, the volume can be adjusted even when a slide operation is performed only on any two adjacent touch sensor surfaces 10 such as the A surface 10a to the B surface 10b. The operation input unit 60 cancels the increase or decrease of the operation input amount when the contact on the touch sensor surface 10 adjacent to the touch sensor surface 10 is detected before the detection of the contact on one touch sensor surface 10 is interrupted. To do. Thereby, it can suppress that volume adjustment is carried out, etc., when it touches the two arbitrary adjacent touch sensor surfaces 10 unintentionally.

  FIG. 13 is a plan view illustrating still another configuration example of the touch sensor 110. This touch sensor is used for unlocking and the like. Nine touch sensor surfaces 10, that is, A surface 10a, B surface 10b, C surface 10c, D surface 10d, E surface 10e, F surface 10f, G surface 10g, H surface 10h, and I surface 10i are arranged in a matrix. Has been.

  The detection unit 40 detects contact on each of the plurality of touch sensor surfaces 10. If the operation input unit 60 detects contact on another touch sensor surface 10 adjacent to the one touch sensor surface 10 within a predetermined time after detection of contact on one touch sensor surface 10 is interrupted, the operation input unit 60 A predetermined operation input corresponding to the operation is received. The operation input unit 60 may cancel a predetermined operation input when contact on another touch sensor surface 10 is detected before detection of contact on one touch sensor surface 10 is interrupted. The operation input unit 60 executes a predetermined operation such as unlocking when a predetermined number of operation inputs are received in a predetermined order.

  In the controller 120, the order of contact of the plurality of touch sensor surfaces 10 is registered in advance. For example, the slide operation is performed in the order of the pre-registered H surface 10h, G surface 10g, D surface 10d, E surface 10e, F surface 10f, B surface 10b, E surface 10e, H surface 10h, I surface 10i, and H surface 10h. Thus, unlocking can be executed.

  FIG. 14 is a plan view illustrating still another configuration example of the touch sensor 110. In this configuration example, the touch sensor 110 is provided on the wall surface 210 next to the door 200 of the building, and turns on or off a lighting switch, for example.

  The A surface 10a and the B surface 10b are arranged in the horizontal direction (first direction) d1 on the operation surface 20. The C surface 10c and the D surface 10d are arranged in a vertical direction (second direction) d2 on the operation surface 20 that intersects the first direction.

  A line 220 extending in the horizontal direction d1 to the A surface 10a and a line 222 extending in the horizontal direction d1 to the B surface 10b are provided. These lines 220 and 222 may have a three-dimensional structure as long as the user can recognize them, or may be formed by applying paint or the like. Lines 220 and 222 are not provided between the A surface 10a and the B surface 10b. A dotted line 224 extending in the vertical direction d2 is provided between the C surface 10c and the D surface 10d. This dotted line 224 may also have a three-dimensional structure or may be formed of a paint or the like.

  The operation input unit 60 is configured such that when contact detection on the B surface 10b is detected within a predetermined time after detection of contact on the A surface 10a is interrupted, or within a predetermined time after detection of contact on the B surface 10b is interrupted. When contact on the surface 10a is detected, the switch is turned on.

  The operation input unit 60 detects the contact on the D surface 10d within a predetermined time after the detection of the contact on the C surface 10c is interrupted, or the operation input unit 60 detects the contact within the predetermined time after the detection of the contact on the D surface 10d stops. When contact on the surface 10c is detected, the switch is turned off.

  That is, the switch is turned on by a sliding operation from the A surface 10a to the B surface 10b or a sliding operation in the opposite direction. This slide operation reminds the user of an image connecting two lines 220 and 222. On the other hand, the switch is turned off by a sliding operation from the C surface 10c to the D surface 10d or a sliding operation in the opposite direction. Since this slide operation intersects the direction of the slide operation for turning on the switch, the user is reminded of an image that cuts off the connected line 220 and line 222. Therefore, erroneous operations can be suppressed with higher accuracy.

  Other functions and effects of the touch sensor unit 100 will be described.

(1) Hard to break down The touch sensor 110 according to the present embodiment does not have a movable mechanism such as a normal button or switch. Therefore, the device is not deformed or damaged, and is not easily broken. .

(2) The touch sensor 110 according to the present embodiment can be manufactured at low cost. The touch sensor 110 according to the present embodiment is composed of an existing inexpensive member, that is, a component representing a shape as a switch and a touch sensor. In addition, since a complicated mechanical mechanism is not required, processing time is less than manufacturing a general switch. With these features, the touch sensor unit 100 can be manufactured at low cost.

(3) Easy to expand the application environment The touch sensor 110 according to the present embodiment is relatively simple in structure, and thus is not easily limited in size or shape. As a result, the degree of freedom in size and shape increases, so that it can be installed in a narrow place or on a curved surface, and can be applied to various environments and scenes.
In general, when a movable switch member is present in a certain device, water and dust enter from a gap portion necessary for moving the switch, so that it is difficult to ensure dustproofness and waterproofness. Since the touch sensor unit 100 according to the present embodiment has no movable mechanism, the sealing of the switch can be ensured by a simple coating, and the protection grade such as dustproof and waterproof can be easily increased. When considering the waterproof property, the sensing method of the touch sensor on the operation surface is not an electrostatic capacity, and it is necessary to make it difficult to be affected by water like a resistive film.

  The present invention has been described based on the embodiments. This embodiment is an exemplification, and it will be understood by those skilled in the art that various modifications can be made to combinations of the respective constituent elements and processing processes, and such modifications are within the scope of the present invention. is there.

  The operation input unit 60 may accept a predetermined operation input when contact on the B surface 10b is detected after detection of contact on the A surface 10a is interrupted within a predetermined time from detection of contact on the A surface 10a. . In this case, the operation input unit 60 cancels the predetermined operation input when the contact on the B surface 10b is not detected within a predetermined time after the contact on the A surface 10a is detected. According to this modification, the degree of freedom of the configuration of the controller 120 can be improved.

  When the predetermined operation input is an operation for turning on an emergency stop switch or the like that needs to suppress an erroneous operation with higher accuracy, the operation surface 20 may be provided with a height barrier that prevents the slide operation. In this case, the operation input can be executed by releasing the finger after touching the A surface 10a instead of the slide operation, and performing a touch operation that touches the B surface 10b through a barrier within a predetermined time. According to this modification, erroneous operations can be suppressed with higher accuracy.

  10 to 14, the operation surface 20 may be configured so that a tactile sensation is changed during a slide operation.

DESCRIPTION OF SYMBOLS 10 ... Touch sensor surface, 20 ... Operation surface, 22 ... Inclined surface, 24, 26, 28, 30, 32 ... Convex part, 40 ... Detection part, 50 ... Determination part, 60 ... Operation input part, 100 ... Touch sensor unit 110: Touch sensor, 120: Controller.

Claims (13)

A detection unit for detecting contact on the first touch sensor surface and contact on the second touch sensor surface;
When contact detection on the second touch sensor surface is detected after detection of contact on the first touch sensor surface is interrupted, a predetermined operation input is received and before detection of contact on the first touch sensor surface is interrupted. An operation input unit that cancels the predetermined operation input when a contact on the second touch sensor surface is detected;
A touch sensor controller comprising:   The operation input unit may detect the second touch within a predetermined time after the contact on the first touch sensor surface is detected or within a predetermined time after the detection of the contact on the first touch sensor surface is interrupted. The touch sensor controller according to claim 1, wherein when the contact on the sensor surface is not detected, the predetermined operation input is canceled. The predetermined operation input is an operation input for increasing or decreasing an operation input amount,
The detection unit detects a contact on the third touch sensor surface,
The operation input unit increases or decreases an operation input amount when the contact on the third touch sensor surface is detected after the detection of the contact on the second touch sensor surface is interrupted, and the second touch sensor 3. The touch sensor according to claim 1, wherein when the contact on the third touch sensor surface is detected before the detection of the contact on the sensor surface is interrupted, the increase or decrease in the operation input amount is canceled. Controller. A first touch sensor surface;
A second touch sensor surface;
A detection unit that detects contact on the first touch sensor surface and contact on the second touch sensor surface;
When contact detection on the second touch sensor surface is detected after detection of contact on the first touch sensor surface is interrupted, a predetermined operation input is received and before detection of contact on the first touch sensor surface is interrupted. An operation input unit that cancels the predetermined operation input when a contact on the second touch sensor surface is detected;
A touch sensor unit comprising: An operation surface provided between the first touch sensor surface and the second touch sensor surface;
The operation surface is configured so that a tactile sensation is changed in a sliding operation from the first touch sensor surface to the second touch sensor surface via the operation surface. 5. The touch sensor unit according to 4.   The change in tactile sensation during the sliding operation from the first touch sensor surface to the second touch sensor surface via the operation surface is caused by the first touch from the second touch sensor surface via the operation surface. The touch sensor unit according to claim 5, wherein the touch sensor unit is different from a change in tactile sensation during a slide operation on the sensor surface.   The touch sensor unit according to claim 5, wherein the operation surface is provided with a convex portion, a concave portion, or an inclined surface.   The convex portion or the concave portion extends in a direction from the first touch sensor surface toward the second touch sensor surface, and the width of the convex portion or the concave portion is a distance from the first touch sensor surface. The touch sensor unit according to claim 7, wherein the touch sensor unit changes according to the change.   The touch sensor unit according to claim 5 or 6, wherein the first touch sensor surface and the operation surface have different textures.   The touch sensor unit according to claim 5, wherein perceived temperatures are different between the first touch sensor surface and the operation surface. A third touch sensor surface;
A fourth touch sensor surface;
Another operation surface provided between the third touch sensor surface and the fourth touch sensor surface,
The detection unit detects contact on the third touch sensor surface and contact on the fourth touch sensor surface,
The operation input unit receives an operation input different from the predetermined operation input when contact on the fourth touch sensor surface is detected after detection of contact on the third touch sensor surface is interrupted,
The another operation surface is configured such that a tactile sensation is changed during a slide operation from the third touch sensor surface to the fourth touch sensor surface via the another operation surface,
The touch sensor unit according to claim 5, wherein a change in tactile sensation during a slide operation is different between the operation surface and the another operation surface. An operation surface provided between the first touch sensor surface and the second touch sensor surface;
A third touch sensor surface;
A fourth touch sensor surface,
The first touch sensor surface and the second touch sensor surface are aligned in a first direction on the operation surface, and the third touch sensor surface and the fourth touch sensor surface are Arranged along a second direction on the operation surface intersecting the direction,
The predetermined operation input is an operation input for turning on a switch,
The detection unit detects contact on the third touch sensor surface and contact on the fourth touch sensor surface;
The operation input unit receives an operation input for turning off the switch when contact on the fourth touch sensor surface is detected after detection of contact on the third touch sensor surface is interrupted. Item 11. The touch sensor unit according to any one of Items 4 to 10. Detecting contact on the first touch sensor surface;
When contact detection on the second touch sensor surface is detected after detection of contact on the first touch sensor surface is interrupted, a predetermined operation input is received and before detection of contact on the first touch sensor surface is interrupted. A step of canceling the predetermined operation input when a contact on the second touch sensor surface is detected;
The operation input method characterized by including.