JP2016119032A - Touch display contact detection apparatus and touch display contact detection method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a technique for improving the operability of a touch display mounted in a vehicle.SOLUTION: A contact with a touch display having touch sensors provided not only on a display screen but also on a frame is detected. When a contact with the frame is detected for a period since a contact with the display screen is detected until predetermined standby time passes, it is determined that the previously detected contact with the display screen is a user's fault contact and a signal corresponding to the contact with the frame is output. On the other hand, when the contact with the frame is not detected for the period since the contact with the display screen is detected until the predetermined standby time passes, it is determined that the contact with the display screen is a contact to fit a user's operation intention and a signal corresponding to the contact with the display screen is output.SELECTED DRAWING: Figure 4

Description

  The present invention is applied to a vehicle having a touch display, and relates to a technique for outputting a signal corresponding to a touch on the touch display.

In recent years, various functions such as car navigation and audio are generally installed in vehicles, and a touch display is often used as a means for operating these various functions (for example, Patent Document 1). On the display screen of the touch display, information provided by various functions is displayed and a touch sensor is provided. The user (driver or passenger) can easily operate various functions by touching the display screen while viewing the information on the display screen.
Recently, various driving support functions have been introduced rapidly, and the opportunity to operate various functions using a touch display is increasing. In response to this, there is an increasing demand for technology development that improves the operability of touch displays mounted on vehicles.

JP 2010-173374 A

  However, at present, there has been a problem that the above request has not been sufficiently met. The present invention has been made in view of this problem, and an object thereof is to provide a technique for improving the operability of a touch display mounted on a vehicle.

In order to solve the above-described problems, the touch display contact detection device and the touch display contact detection method of the present invention detect contact with a touch display in which a touch sensor is provided on a frame body in addition to a display screen. Here, if contact to the frame is detected between the time when the touch on the display screen is detected and the predetermined waiting time has elapsed, the touch on the display screen that has been detected earlier is erroneous contact by the user. And outputs a signal corresponding to the contact with the frame.
On the other hand, if contact to the frame is not detected between the time when the contact to the display screen is detected and the predetermined waiting time has elapsed, the contact with the display screen is suitable for the user's intention to operate. A contact is determined and a signal corresponding to the touch on the display screen is output.

  In this way, even if the user who tried to operate by touching the frame accidentally touches the display screen, it is determined that the contact with the display screen is an erroneous contact, and a signal corresponding to the erroneous contact is sent. Output can be avoided. As a result, the user does not feel the trouble of touching the frame while paying attention not to touch the display screen accidentally, and the operability of the touch display can be improved.

It is explanatory drawing which shows the rough structure of the contact detection apparatus 10 of a present Example. FIG. 3 is an explanatory diagram showing a state when a touch display 2 mounted on the vehicle 1 is touched. It is a flowchart of the contact signal output process (S100) which the contact detection apparatus 10 performs. It is explanatory drawing which showed the outline | summary of the process performed when there exists a miscontact on the display screen. It is explanatory drawing which showed a mode that it touches and operates the display screen 21 while putting a hand on the frame 22. FIG. 6 is an explanatory diagram showing an outline of processing executed in response to contact between a standby area and a normal area provided on a display screen. FIG. It is explanatory drawing which shows the rough structure of the contact detection apparatus 10 which changes the standby area | region 23 according to driving | running load. It is a flowchart of the contact signal output process (S200) which the contact detection apparatus 10 performs when setting the standby | waiting area | region 23. It is explanatory drawing which showed the outline | summary of the process performed corresponding to the contact to the inclined surface 22a or the inclined surface 21a. It is explanatory drawing which shows a mode that an incorrect contact is prevented by making the right-and-left both corners on the upper side of the display screen 21 into the shape rounded.

Hereinafter, examples will be described in order to clarify the contents of the present invention described above.
A-1. Apparatus configuration of this embodiment:
FIG. 1 shows a rough structure of a contact detection device 10 mounted on the vehicle 1. In this embodiment, the contact detection device 10 corresponds to the “touch detection device for touch display” in the present invention. The illustrated contact detection device 10 is a device for detecting contact with the touch display 2 and outputting a signal corresponding to the contact to the in-vehicle device 3. The in-vehicle device 3 has a function mounted on the vehicle 1, displays information provided by the function on the touch display 2, and operates the above function according to an operation via the touch display 2. The functions provided in the in-vehicle device 3 include functions such as car navigation and audio, as well as driving support functions such as parking support and distance maintenance.

The touch display 2 includes a display screen 21 that displays information provided by the in-vehicle device 3 toward a user (driver or passenger), and a frame 22 provided on the outer side surface of the display screen 21. The display screen 21 and the frame body 22 are each provided with a touch sensor, and a signal based on contact with the display screen 21 or the frame body 22 is output to the contact detection device 10 of the present embodiment.
The contact detection device 10 is connected to the touch display 2 and includes a screen contact detection unit 11 that detects contact with the display screen 21, a frame contact detection unit 12 that detects contact with the frame 22, and the display screen 21 or And a signal output unit 13 that outputs a signal corresponding to the contact with the frame body 22 to the in-vehicle device 3.

  The “part” included in the contact detection device 10 is a concept in which the inside of the contact detection device 10 is classified from the viewpoint of function, and does not represent that the contact detection device 10 is physically divided. Therefore, these “units” can be realized as a computer program executed by the CPU, an electronic circuit including an LSI, a memory, a timer, or a combination thereof. it can.

  FIG. 2 shows a state where the touch display 2 mounted on the vehicle 1 is touched. As shown in FIG. 2A, the touch display 2 is fixed on the dashboard so that the display screen 21 can be seen by a user sitting in a driver seat or a passenger seat. Therefore, when the user tries to operate the function of the in-vehicle device 3 by touching the touch display 2, the hand is extended toward the touch display 2 fixed on the dashboard. Here, for example, if the touch display is provided in a mobile terminal such as a smartphone, the user can freely change the mobile terminal so that it can be easily operated. However, in the case of the in-vehicle touch display 2, the user can only operate by extending his / her hand toward the touch display 2 fixed on the dashboard. Therefore, it tends to be difficult to perform detailed operations as compared with the case of a mobile terminal.

  In addition, the vehicle 1 may shake as the vehicle travels, and the body may be shaken back and forth and right and left as the vehicle 1 is accelerated and decelerated and the course is changed. For this reason, as shown in FIG. 2B, the fingertip touching the touch display 2 tends to be unstable. Under such circumstances, even if a touch sensor is provided on the frame 22 of the touch display 2, a fingertip trying to touch the frame 22 easily touches the display screen 21 and malfunctions. It is difficult to lead to improvement. Therefore, in order to improve the operability of the touch display 2 by providing a touch sensor on the frame 22 without causing such a malfunction, the contact detection device 10 of the present embodiment outputs the following contact signal. Execute the process.

A-2. Contact signal output processing:
FIG. 3 shows a flowchart of the contact signal output process (S100) executed by the contact detection device 10 of the present embodiment. This contact signal output process is started when the touch display 2 is turned on, for example, by starting the engine of the vehicle 1.
When the contact signal output process is started, first, it is confirmed whether or not contact with the frame 22 is detected (S101). The presence or absence of contact with the frame body 22 can be detected by the output of a touch sensor provided on the frame body 22 (see FIG. 1). It is considered that the user's finger is not touching the frame 22 of the touch display 2 as soon as the power is turned on. Accordingly, it is determined as “no” in S101, and then it is confirmed whether or not contact with the display screen 21 is detected (S102).

  The presence or absence of contact with the display screen 21 can also be detected by the output of a touch sensor provided on the display screen 21 (see FIG. 1). As for the display screen 21 as well, since it is considered that the user's finger is not touching immediately after the power to the touch display 2 is turned on, it is determined as “no” in S102 and whether or not the contact signal output process is terminated. (S103). Whether or not to end the process is determined by whether or not the touch display 2 is powered off. If the power is turned off, it is determined that the contact signal output process is finished (S103: yes), but if the power is not turned off, it is judged that the process is not finished (S103: no), and the beginning of the process Returning to (S101), the contact signal output process is repeated.

When the touch display 2 is turned on and the contact signal output process is started, the above determinations (S101, S102, S103) are repeated. If the user touches the frame 22 of the touch display 2 while repeating such a determination, contact with the frame 22 is detected (S101: yes), and a frame contact signal is output (S104). ). The frame body contact signal is a signal that the signal output unit 13 outputs to the in-vehicle device 3 in response to the contact with the frame body 22.
Then, after outputting the frame contact signal (S104), it is confirmed whether or not the contact signal output process is to be ended (S103). If not completed (S103: no), the process returns to the beginning again to check whether or not contact with the frame 22 has been detected (S101).

  In some cases, the user touches the display screen 21 before touching the frame 22 of the touch display 2. In this case, contact with the display screen 21 is detected (S102: yes). When contact with the display screen 21 is detected (S102: yes), a standby timer is started without immediately outputting a signal corresponding to the contact (screen contact signal described later) (S105). The standby timer is a timer (not shown) built in the contact detection device 10 and counts a predetermined standby time. The waiting time can be set arbitrarily.

After the standby timer is activated (S105), it is determined whether or not contact with the frame 22 has been detected (S106) until a time-out occurs (S109: yes). As a result, when a timeout occurs without detecting contact with the frame body 22 during the standby time (S109: yes), a screen contact signal is output (S110). The screen contact signal is a signal that the signal output unit 13 outputs to the in-vehicle device 3 in response to the contact with the display screen 21.
On the other hand, if contact with the frame body 22 is detected during the standby time until timeout (S106: yes), the standby timer is ended (S107), and a frame body contact signal is output (S108). That is, even when contact with the display screen 21 is detected (S102: yes), when contact with the frame 22 is detected before the standby time elapses from the contact (S106: yes), the display is performed. It is determined that the contact with the screen 21 is a false contact, and the frame contact signal is output without outputting the screen contact signal. The reason why this determination can be made will be described with reference to FIG.

  FIG. 4A shows a case where the user tries to touch the frame 22 with the index finger, but the middle finger erroneously contacts the display screen 21 before that. Even when such an erroneous contact occurs, the user tries to touch the frame 22 with the index finger as it is. As a result, it is considered that the user's finger touches the frame 22 immediately after the erroneous contact with the display screen 21, that is, within the waiting time, and the contact is detected (see FIG. 4B). From this, when the contact to the frame 22 is detected within the waiting time immediately after the contact to the display screen 21 is detected, it may be considered that the contact to the display screen 21 is a false contact. Therefore, in such a case, it is considered that the contact with the display screen 21 is an erroneous contact not depending on the user's operation intention, and the frame contact signal is output without outputting the screen contact signal (FIG. 3). S106: see yes to S108).

  On the contrary, after detecting contact with the display screen 21, if contact with the frame 22 is not detected during the standby time, the contact with the display screen 21 is not a false contact and is suitable for the user's intention to operate. It is thought that. In such a case, a screen contact signal is output (see S106: no to S110 in FIG. 3).

By determining whether or not the contact with the display screen 21 is an erroneous contact as described above, the screen contact signal or the frame contact signal can be received regardless of whether or not the frame 22 is contacted during the standby time. Of these, the signal suitable for the user's intention to operate is output. As a result, the user does not feel bothered by touching the frame 22 while paying attention not to touch the display screen 21 by mistake, and the operability of the touch display 2 is improved.
Note that the standby time only needs to secure a time necessary for determining whether or not there is an erroneous contact, and may be set to about 0.1 to 1.0 seconds, for example.

  So far, the description has been made assuming that when the touch to the display screen 21 is detected, the output of the screen contact signal is waited. However, in the following cases, it is preferable to output the screen contact signal immediately without waiting even if contact with the display screen 21 is detected.

For example, a contact in a predetermined manner that is detected over time, such as a contact that takes a long time without moving the contact position on the display screen 21 or a contact that moves the contact position on the display screen 21 in a predetermined direction. If it is detected, the screen contact signal may be output as it is without waiting for the output of the screen contact signal. This continues for a certain period of time, such as when the contact with the display screen 21 takes a long time like a long press operation, or the contact position moves in a predetermined direction like a swipe operation or a flick operation. This is because the detected contact is unlikely to occur due to erroneous contact.
In addition, the contact of a predetermined aspect should just be a contact of the aspect which can be distinguished from a mere momentary contact, and can set it arbitrarily, without restricting to said long press and swipe. This is because such a contact with time is different from a momentary contact, and the user's intention to operate is already recognized when the contact is detected.

Further, for example, when contact with the display screen 21 is detected in a state where contact with the frame 22 is detected, the output of the screen contact signal may not be waited. The reason for this will be described with reference to FIG.
FIG. 5 shows an operation mode in which the user touches the display screen 21 while holding the frame 22. In this operation mode, when the user touches the frame body 22 (FIG. 5A), a menu selection screen appears on the display screen 21 (FIG. 5B). This is an operation mode when a desired selection item in the selection screen is selected by touching with a thumb (FIG. 5C). Note that while the user touches the frame 22 and continues to touch it, a new frame contact signal is not output.

  In FIG. 5C, the user touches the selection screen, that is, the display screen 21. Of course, the contact with the display screen 21 is not an erroneous contact but a contact due to the user's intention to operate. Therefore, when the contact to the display screen 21 is detected while the contact to the frame body 22 is detected, the user's intention to operate is already recognized when the contact is detected. Do not wait.

As described above, as described with reference to the two cases, when it is determined that there is no erroneous contact when the contact with the display screen 21 is detected, the screen contact signal may be output immediately without waiting. By so doing, it is possible to avoid delays in the output of the screen contact signal caused by providing the standby time.
In addition, by doing as follows, it is possible to reduce the chance of delay in output of the screen contact signal.

  4 is an aspect in which the middle finger makes an erroneous contact with the display screen 21 while trying to touch the frame 22 with the index finger. In this erroneous contact aspect, the area of the display screen 21 Among these, erroneous contact occurs in a region away from the frame body 22. However, it is considered that the erroneous contact with the display screen 21 is more likely to occur in a region near the frame body 22 than in a region away from the frame body 22. This is because an erroneous contact is likely to occur near the frame 22 because the erroneous contact is made when the frame 22 is touched.

Therefore, it is not always necessary to determine whether or not there is an erroneous contact in the entire area of the display screen 21, and it may be determined only in the area close to the frame body 22 as shown in FIG. 6. Here, in the area of the display screen 21, an area adjacent to the frame body 22 is referred to as a standby area 23, and the other area is referred to as a normal area 24. As shown in FIG. 6A, when contact with the standby area 23 is detected, output of the screen contact signal is waited. On the other hand, as shown in FIG. 6B, when a contact with the normal area 24 is detected, a screen contact signal is output without waiting. In this way, in the standby area 23 where erroneous contact is likely to occur, it is determined whether or not the erroneous contact has occurred, so that the influence of the erroneous contact is avoided, and the output delay of the screen contact signal does not occur in the normal area 24. Can be.
The normal area 24 is an area for outputting a screen contact signal without waiting for the standby time to elapse even when contact with the display screen 21 is detected, and corresponds to the “predetermined area” of the present invention. In addition, the normal area 24 is set to include at least the center of the display screen 21 and has an area larger than the majority of the display screen 21, and the standby area 23 is an area set around the normal area 24. .

  Further, the frequency of occurrence of erroneous contact is not limited to which position on the display screen 21, but the situation where the driver is placed, that is, the high driving load on the driver due to driving the vehicle 1. Is also affected. For example, if the vehicle 1 is stopped, it is possible to touch the touch display 2 carefully, but if the vehicle 1 is traveling, it is likely to touch roughly and erroneous contact is likely to occur. Therefore, the standby area 23 may be changed according to the operating load.

FIG. 7 shows a rough structure of the contact detection device 10 that changes the standby area 23 according to the operation load. The driving load acquisition unit 14 acquires the traveling speed of the vehicle 1 from the vehicle speed sensor 4 mounted on the vehicle 1 and determines the height of the driving load based on the traveling speed.
The driving load is not limited to the traveling speed of the vehicle 1 as long as it is an index that can confirm the situation where the driver is placed, and is based on the operation amount necessary for driving the vehicle 1, the physical condition of the driver, and the like. Can be judged. Examples of the operation amount necessary for driving the vehicle 1 include an accelerator operation amount, a steering operation amount, a brake operation amount, and whether or not the direction indicator operates. As a driver | operator's physical condition, a driver | operator's heartbeat, the direction of a gaze, etc. are mentioned, for example. These various types of information may be acquired from various sensors provided in the vehicle 1 such as the vehicle speed sensor 4 or may be acquired via a communication network connected to facilities that provide traffic information such as other vehicles and traffic lights. .

The standby area changing unit 15 changes the area of the standby area 23 according to the height of the operation load. The screen contact detection unit 11 acquires the range where the standby area 23 is set from the standby area changing unit 15, and whether the position where the contact with the display screen 21 is detected is the standby area 23 or the normal area 24. And the contact is detected. The standby area changing unit 15 corresponds to the “predetermined area changing unit” of the present invention.
Hereinafter, the contact signal output process (S200) including the setting of the standby area 23 will be described.

  FIG. 8 shows a flowchart of the contact signal output process (S200) executed by the contact detection device 10 including the driving load acquisition unit 14 and the standby area change unit 15. Since this touch signal output process (S200) has a process that is common in content with the touch signal output process (S100) described above with reference to FIG. 3, the description will focus on different processes.

When the contact signal output process (S200) is started, first, an operation load is acquired (S201). When the operating load is acquired (S201), the standby area 23 is changed according to the height of the operating load (S202). That is, when the operating load is higher than the predetermined threshold load, the area of the standby region 23 is changed to a larger value than when the operating load is lower than the predetermined threshold load. As a result, the normal area 24 is changed to a small area.
For example, when the driving load is lower than a predetermined threshold load, such as when the vehicle 1 is stopped, even if the driver touches the touch display 2, it is considered that there is relatively little erroneous contact. Change to a smaller value (or zero). On the other hand, when the driving load is higher than a predetermined threshold load such as when the vehicle speed is high, the driver pays attention to the driving operation and the safety confirmation of the surroundings. Since the contact is considered to be relatively large, the area of the standby region 23 is changed to a large value. Only one predetermined threshold load may be set, or it may be provided in a plurality of stages.

When the standby area 23 is set (S202), it is determined whether or not contact with the frame body 22 is detected (S203). When contact with the frame body 22 is detected (S203: yes), the frame body contact is determined. A signal is output (S207).
On the other hand, if contact with the frame 22 is not detected (S203: no), it is then determined whether contact with the normal region 24 is detected (S204). When contact with the normal area 24 is detected (S204: yes), the screen contact signal is output as it is (S208). As described above, when the contact with the frame 22 is not detected (S203: no), the presence / absence of the contact with the normal region 24 is determined (S204). If the contact with the normal region 24 is made (S204: yes) The point that the screen contact signal is output without waiting is different from the contact signal output process (S200) described in FIG.

When contact with the normal area 24 is not detected (S204: no), it is next determined whether contact with the standby area 23 is detected (S205). If contact with the standby area 23 is not detected (S205: no), the vehicle speed is acquired by returning to the top of the process unless the contact signal output process (S200) is terminated (S206: no) ( S201).
On the other hand, when contact with the standby area 23 is detected (S205: yes), processing is performed in the same flow as the contact signal output process (S200) described in FIG. That is, the standby timer is started (S209), and if contact with the frame body 22 is detected during the standby time (S210: yes), the standby timer is ended (S211) and a frame body contact signal is output ( S212). If no contact with the frame body 22 is detected during the standby time (S210, S213: no), a screen contact signal is output (S214).
By performing such a contact signal output process (S200), it is possible to reduce the chance of output delay of the screen contact signal while avoiding the influence of erroneous contact according to the height of the driving load. it can.

  Up to this point, the case where the position where the user tries to touch the frame body 22 is the upper surface of the frame body 22 has been described as an example. However, the position is not limited to the upper surface of the frame body 22, In this way, the effect of erroneous contact can be avoided. Further, the shape of the frame 22 is not limited to the shape only for enclosing the outer periphery of the display screen 21.

  For example, as shown in FIG. 9A, if an inclined surface 22 a in which a part of the frame body 22 is inclined toward the display screen 21 is formed, it is easy for a user who approaches his / her hand from the front of the display screen 21. Since the inclined surface 22a is a part of the frame 22, a frame contact signal is output for contact with the inclined surface 22a. Then, as described above, an erroneous contact occurs between the inclined surface 22a and the display screen 21 as well as an erroneous contact between the frame 22 and the display screen 21. In accordance with this idea, it is possible to avoid the influence of erroneous contact between the inclined surface 22a and the display screen 21. The inclined surface 22a is not limited to a flat surface, and may be formed as a curved surface.

  Further, as shown in FIG. 9B, an inclined surface 21 a having the same shape as the inclined surface 22 a may be formed by inclining a part of the display screen 21 toward the frame body 22. Since the inclined surface 21a is a part of the display screen 21, when there is a contact with the inclined surface 21a, the screen contact detection unit 11 that detects the contact with the display screen 21 detects the contact. Become. However, the signal output from the signal output unit 13 in response to the contact with the inclined surface 21a is not the screen contact signal but the frame body contact signal in spite of the detection by the screen contact detection unit 11. .

  In this way, even when the user tries to touch the frame body 22 and makes an erroneous contact with the inclined surface 21a, a frame body contact signal suitable for the user's operation intention can be output. Of course, since the screen is also displayed on the inclined surface 21a, there is a possibility that the user may touch the inclined surface 21a when trying to operate using the display screen 21. However, since it is easier for the user to touch the wide area other than the inclined surface 21a, rather than the small inclined surface 21a at the corner of the display screen 21, it is difficult to assume that the user touches the inclined surface 21a. There seems to be no problem. In addition, by providing the inclined surface 21a with an appropriate width, it is possible to reduce the possibility that the user touches the inclined surface 21a when trying to operate using the display screen 21. Therefore, the width of the inclined surface 21a is preferably about 2 to 10 mm. Furthermore, a dead zone that is controlled so that neither a screen contact signal nor a frame contact signal is output even if a contact is detected in a region of a predetermined width adjacent to the inclined surface 21a in the region of the display screen 21. It may be provided. In this way, even if the user touches the inclined surface 21a when operating using the display screen 21, it can be more reliably avoided that the frame body contact signal is output against the user's intention to operate. .

The dead zone described above is not limited to the case where an inclined surface is provided, and erroneous contact that occurs between the frame body 22 and the display screen 21 by appropriately providing the area of the display screen 21 adjacent to the frame body 22. Can also be reduced.
In addition, the erroneous contact with the display screen 21 may occur while trying to touch the frame body 22 or may occur while the frame body 22 is being touched. For example, while a swipe operation is performed by sliding a finger on the frame body 22, the belly of the finger bites into a corner portion at the boundary between the frame body 22 and the display screen 21 and touches the frame body 22. At the same time, the display screen 21 may be erroneously touched. For erroneous contact in this manner, while detecting contact with the frame 22, the user's intention to operate is determined by not outputting a screen contact signal even if contact with the display screen 21 is detected. It is possible to avoid malfunctions contrary to
Furthermore, as shown in FIG. 10A, when the display screen 21 is rectangular, when the user performs a rough swipe operation on the upper surface of the frame 22, the display is performed in the latter half of the operation of sliding the finger. Although it is easy to make erroneous contact with the screen 21, as shown in FIG. 10 (b), it is preferable that the left and right corners on the upper side of the display screen 21 are rounded to prevent the erroneous contact.

  As mentioned above, although the present Example and the modified example were demonstrated, this invention is not restricted to said Example and modified example, In the range which does not deviate from the summary, it can implement in a various aspect.

1 ... vehicle, 2 ... touch display, 3 ... vehicle equipment,
4 ... Vehicle speed sensor, 10 ... Touch detection device for touch display,
DESCRIPTION OF SYMBOLS 11 ... Screen contact detection part, 12 ... Frame body contact detection part, 13 ... Signal output part,
14 ... Driving load acquisition unit, 15 ... Standby area change unit, 21 ... Display screen,
21a ... inclined surface, 22 ... frame, 22a ... inclined surface,
23: Standby area 24: Normal area

Claims (7)

A touch display contact detection device (10) for detecting contact with a touch display (2) mounted on a vehicle (1),
A screen contact detection unit (11) for detecting contact with the display screen (21) of the touch display;
A frame contact detection unit (12) for detecting contact with the frame (22) of the touch display;
If contact with the frame is not detected between the time when the contact with the display screen is detected and the predetermined waiting time elapses, a screen contact signal corresponding to the contact with the display screen is generated. If the contact to the frame body is detected during the period from when the contact to the display screen is detected until the waiting time elapses, the frame body is output without outputting the screen contact signal. And a signal output unit (13) for outputting a frame contact signal corresponding to contact with the touch. The touch detection device for a touch display according to claim 1,
The screen contact detection unit is a detection unit that detects whether or not a position where contact with the display screen is detected is a predetermined region (24) set on the display screen, and detects the contact;
The signal output unit is an output unit that outputs the screen contact signal without waiting for the standby time to elapse when the contact with the display screen is the contact with the predetermined region. Contact detection device. The touch detection device for a touch display according to claim 2,
A driving load acquisition unit (14) for acquiring the driving load of the driver by driving the vehicle;
When the driving load is higher than a predetermined threshold load, the predetermined load changing unit (15) for changing the predetermined region to a smaller area than when the driving load is lower than the threshold load is provided for touch display Contact detection device. The touch detection device for a touch display according to any one of claims 1 to 3,
The screen contact detection unit is a detection unit that detects a contact mode on the display screen in addition to the contact position on the display screen,
The signal output unit is an output unit that outputs the screen contact signal without waiting for the standby time to elapse when the contact mode on the display screen is a predetermined mode. Touch display contact detection device . The touch detection device for a touch display according to any one of claims 1 to 4,
Even when the signal output unit detects contact with the display screen, when contact with the display screen is detected in a state where contact with the frame is detected, A touch detection device for a touch display, which is an output unit that outputs the screen touch signal without waiting for the standby time to elapse. A touch detection device for a touch display according to any one of claims 1 to 5,
Between the display screen of the touch display and the side surface of the frame, there are inclined surfaces (21a, 22a) that intersect at an obtuse angle with both the side surface of the frame and the display screen. Or formed by a part of the display screen,
The said signal output part is an output part which outputs the said frame body contact signal, when the contact to the said inclined surface is detected. Touch detection apparatus for touch displays. A touch detection method for a touch display that detects contact with a touch display mounted on a vehicle,
Detecting contact with the display screen of the touch display (S102);
Detecting contact with the frame of the touch display (S101);
If contact with the frame is not detected between the time when the contact with the display screen is detected and the predetermined waiting time elapses, a screen contact signal corresponding to the contact with the display screen is generated. Outputting (S110);
If contact to the frame is detected between the detection of contact to the display screen and the elapse of the waiting time, contact to the frame without outputting the screen contact signal A touch detection method for a touch display, comprising: a frame contact signal corresponding to the step (S108).

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