JP6234616B2 - Touch detection device, display device with touch detection function, and navigation device - Google Patents

Description

  The present invention relates to a touch detection device that detects that a user's finger or the like has touched a touch panel, a display device with a touch detection function, and a navigation device.

  In recent years, many display devices including a touch panel as an input unit have been used. A display device equipped with a touch panel is a device that is equipped with a touch panel on a display device such as a liquid crystal display device, and allows various information to be input instead of mechanical buttons by displaying various buttons on the display device. is there.

  For example, a capacitive touch panel has a sensor electrode covered with a protective layer, a detection circuit that detects a capacitance formed between the sensor electrode and the periphery, and a capacitance detected by the detection circuit. A capacitance-voltage conversion circuit for conversion, and detects a change in capacitance when a user's finger or a touch pen touches the protective layer. Since the change in capacitance at the time of touch is very small, it is necessary to increase the detection sensitivity of the capacitance-voltage conversion circuit in order to reliably detect a touch. However, when the detection sensitivity is increased, there is a problem that it is easily affected by external noise and causes erroneous touch detection.

  Therefore, the capacitance sensor described in Patent Document 1 provides a shield electrode in the vicinity of the sensor electrode, and switches the state of the shield electrode according to the electrical state of the sensor electrode, thereby propagating noise to the sensor electrode. Cut off.

JP 2010-61405 A

  As described above, in order to reliably detect the user's touch and improve operability, it is necessary to increase the sensitivity. However, if the sensitivity is constantly increased, erroneous detection is likely to occur due to the influence of external noise. There was a problem. In order to improve user operability and suppress the effects of external noise, (1) lower the original sensitivity and increase the sensitivity when the user operates, (2) increase the original sensitivity. Therefore, it is necessary to lower the sensitivity when the user does not operate, (3) increase the sensitivity when the user operates, and decrease the sensitivity when the user does not operate. However, in the conventional touch panel such as Patent Document 1 described above, the sensitivity cannot be changed according to the user's operation status as in any of (1) to (3) above.

  The present invention has been made to solve the above-described problems, and it is an object of the present invention to improve user operability and to suppress the influence of external noise when the touch panel is not operated. .

In the touch detection device according to the present invention, an acquisition unit that acquires a detection value detected for each position in a touch panel mounted on a vehicle, the detection value acquired by the acquisition unit is compared with a threshold value, and the touch panel is touched. A touch determination unit that determines whether or not the touch panel is operated, a situation determination unit that determines whether or not the touch panel is in a predetermined situation, and a correction unit that corrects the threshold based on a determination result by the situation determination unit. When the user who operates the touch panel is a vehicle driver, the situation determination unit determines that the touch panel is operated when the vehicle is stopped, and predetermined when the vehicle is running. If the user operating the touch panel is a passenger in the passenger seat, the touch panel is operated regardless of whether the vehicle is stopped or traveling. It is intended to determine that.

According to the present invention, the threshold value is corrected based on the determination result as to whether or not the touch panel is operated , so that the user operability can be improved and the touch panel is operated. The influence of external noise when not present can be suppressed.

It is a block diagram which shows the structural example of the navigation apparatus which concerns on Embodiment 1 of this invention. It is a figure which shows the example of an operation screen for character input which the navigation apparatus which concerns on Embodiment 1 displays. 6 is a diagram illustrating an example of an operation screen for destination setting displayed by the navigation device according to Embodiment 1. FIG. It is a figure which shows the example of a navigation screen which the navigation apparatus which concerns on Embodiment 1 displays. 4 is a graph showing a change over time of a detection value at a position where the touch panel according to Embodiment 1 is present. 2 is a hardware configuration diagram of the navigation device according to Embodiment 1. FIG. 4 is a flowchart for explaining the operation of the touch detection device according to the first embodiment. It is a block diagram which shows the structural example of the navigation apparatus which concerns on Embodiment 2 of this invention. 12 is a flowchart illustrating an operation when the touch detection device according to the second embodiment uses the determination result of the user determination unit. It is a block diagram which shows the structural example of the navigation apparatus concerning Embodiment 3 of this invention. FIG. 10 is a diagram illustrating an example of a correction amount stored in a correction amount storage unit according to Embodiment 3. 10 is a flowchart for explaining the operation of the touch detection device according to the third embodiment. It is a block diagram which shows the structural example of the navigation apparatus concerning Embodiment 4 of this invention. 10 is a graph showing a change over time of a detected value at a position where a touch panel according to Embodiment 4 is present. 10 is a flowchart for explaining the operation of the touch detection device according to the fourth embodiment.

Hereinafter, in order to explain the present invention in more detail, modes for carrying out the present invention will be described with reference to the accompanying drawings.
Embodiment 1 FIG.
FIG. 1 is a block diagram illustrating a configuration example of a navigation device 100 according to the first embodiment. The navigation device 100 includes a display device 101 with a touch detection function and a navigation function unit 11. The display device 101 with a touch detection function includes a touch detection device 102, a touch panel 12, a display unit 13, and a control unit 14.

  The navigation device 100 can be used for a moving body including a person, a railway, a ship, an aircraft, and the like, and is particularly suitable for being brought into a vehicle or mounted on a vehicle. Hereinafter, a case where the navigation device 100 is mounted on a vehicle will be described as an example.

  The navigation device 100 displays information on the display device 101 with a touch detection function according to a touch input performed by the user on the display device 101 with a touch detection function, and performs navigation to a destination. In addition, the navigation device 100 can control the operated device 200 mounted on the vehicle according to a touch input performed by the user on the display device 101 with a touch detection function.

The operated device 200 is, for example, an air conditioner device 201, an audio device 202, and a hands-free call device 203. The air conditioner 201 is a device that adjusts the temperature inside the vehicle. The audio device 202 is a device that performs volume adjustment, music selection, and the like. The hands-free call device 203 is a device for making a call or the like in the vehicle.
The operated device 200 is not limited to the above example, and may be any device as long as it is a target operated by the user through the navigation device 100.

The navigation function unit 11 has a navigation function and generates information related to navigation to be displayed on the display device 101 with a touch detection function. For example, the navigation function unit 11 performs a route search to the destination touch-inputted by the user, and generates navigation information including contents such as the name of the current location, the distance to the destination, and the direction of the turn.
Note that the content included in the navigation information is not limited to the above example, and may be anything as long as it is displayed on the display device 101 with a touch detection function.

  The display device 101 with a touch detection function displays a navigation screen, an operation screen of the navigation function unit 11 or the operated device 200 on the display unit 13, accepts a user's touch input on these screens by the touch panel 12, and performs a touch detection device. Control information is detected at 102, and control information for controlling the navigation function unit 11, the display unit 13, and the operated device 200 is generated and output based on the detection result.

  The touch panel 12 outputs a position touched by a user's finger or a touch pen and a detected value. As the touch panel 12, various types such as a capacitance type, a resistance film type, and an electromagnetic induction type can be used. In the following, a capacitance type is used as an example. Further, the touch panel 12 is mounted on the display unit 13, and the user views information displayed on the display unit 13 through the touch panel 12.

In general, the capacitive touch panel 12 includes a sensor electrode covered with a protective layer, a detection circuit that detects a capacitance formed between the sensor electrode and the periphery, and a capacitance detected by the detection circuit. A capacitance-voltage conversion circuit that converts the voltage into a voltage, and outputs information indicating the position of the sensor electrode and a detection value obtained by converting the capacitance of the sensor electrode into a voltage.
The information indicating the position of the sensor electrode may represent the position, for example, coordinates indicating the vertical and horizontal directions on the touch surface of the touch panel 12, or numbers assigned to the respective positions on the touch surface of the touch panel 12. Anything is acceptable.

  The display unit 13 displays information that the control unit 14 instructs to display. This information is information such as an operation screen of the navigation function unit 11, a navigation screen generated from the navigation information, and an operation screen of the operated device 200, for example.

The control unit 14 controls the display of the display unit 13, the navigation function unit 11, and the operated device 200.
The control unit 14 acquires information related to operation items and the like of the navigation function unit 11 from the navigation function unit 11, generates an operation screen, and outputs and displays the operation screen information on the display unit 13. Specifically, for example, when the user can operate the destination setting, the control unit 14 acquires information on operation items necessary for the destination setting from the navigation function unit 11, and generates an operation screen for the destination setting. To be displayed on the display unit 13. In addition, the control unit 14 generates a navigation screen using the navigation information generated by the navigation function unit 11 and causes the display unit 13 to display the navigation screen.

Further, the control unit 14 acquires information on the operation items and the like of the operated device 200 from the operated device 200, generates an operation screen, and outputs the operation screen information to the display unit 13 for display. Specifically, for example, when the user can operate the temperature of the air conditioner 201, the control unit 14 acquires information on operation items necessary for temperature adjustment from the air conditioner 201, and an operation screen on which buttons for temperature adjustment are arranged. Is generated and displayed on the display unit 13.
Note that the above-described operation screen is an example, and does not limit the information that the control unit 14 displays on the display unit 13.

The control unit 14 receives information indicating the position touched by the user from the touch detection device 102 and compares it with information instructed to be displayed on the display unit 13 to determine an operation touched by the user. The control unit 14 generates control information for performing the determined operation, and outputs the control information to the navigation function unit 11, the display unit 13, or the operated device 200.
The information indicating the position touched by the user represents the position, for example, coordinates indicating the vertical direction and the horizontal direction on the touch surface of the touch panel 12, or a number assigned to each position on the touch surface of the touch panel 12. Anything is acceptable.

  For example, when the display unit 13 displays an operation screen for inputting characters for destination search, if the character “ji” is displayed at the position touched by the user, the control unit 14 displays “ji”. It determines with having touched, and outputs control information to the display part 13 so that "ji" may be displayed on the destination input column. In the same way, when the characters “ta” and “ku” are touched after “ji” and the “route search” button is touched, the control unit 14 searches for a route to the destination “jitaka”. Control information is output to the navigation function unit 11 so as to generate navigation information.

  For example, when the display unit 13 displays an operation screen for adjusting the temperature of the air conditioner 201, if the button for raising the temperature in the vehicle once is displayed at the position touched by the user, the control unit 14 determines the temperature in the vehicle. The control information is output to the air conditioner 201 so that the temperature inside the vehicle is raised once.

  Further, the control unit 14 also outputs information indicating the display to the display unit 13 to the status determination unit 16 of the touch detection device 102.

  The touch detection device 102 includes an acquisition unit 15 that acquires detection values detected for each position of the touch panel 12, a situation determination unit 16 that determines whether or not the touch panel 12 is in a predetermined situation, and a situation determination. A correction unit 17 that corrects the sensitivity of the touch determination that determines whether or not the touch panel 12 has been touched based on the situation determination result of the unit 16, and a correction amount storage that stores a correction amount used for sensitivity correction of the correction unit 17 And a touch determination unit 19 that determines whether or not the touch panel 12 is touched based on the sensitivity correction result of the correction unit 17.

  As a method of correcting the sensitivity of touch determination, there are a method of correcting the detection value of the touch panel 12 and a method of correcting a threshold value to be compared with the detection value. In the first embodiment, a method for correcting a detection value will be described. A method for correcting the threshold will be described in a fourth embodiment described later.

The acquisition unit 15 acquires information indicating the position of the sensor electrode output by the touch panel 12 and a detection value obtained by converting the capacitance of the sensor electrode into a voltage, and outputs the acquired value to the correction unit 17. As described above, the information indicating the position of the sensor electrode may be any information that represents a position, for example, coordinates indicating the vertical and horizontal directions of the touch panel 12 or numbers assigned to the respective positions of the touch panel 12. It may be anything.
Note that the acquisition unit 15 does not acquire detection values at all positions on the touch panel 12, but acquires only detection values that have changed, that is, only detection values at positions that may have been touched by the user. Also good.

The situation determination unit 16 acquires information indicating the content of the screen currently displayed on the display unit 13 from the control unit 14. The situation determination unit 16 determines whether or not the touch panel 12 is in a predetermined situation in which the touch panel 12 is operated based on information indicating the content of the screen acquired from the control unit 14, and outputs the situation determination result to the correction unit 17. .
In Embodiment 1, the case where the screen which the display part 13 is displaying is a screen operated by the user is illustrated as a predetermined situation.

Here, the processing of the situation determination unit 16 will be described with reference to the screen examples of FIGS.
FIG. 2 is a diagram illustrating an example of an operation screen for character input of the navigation function unit 11. Since this operation screen prompts the user to input characters representing the destination, the user is highly likely to perform touch input within a few seconds. For this reason, the situation determination unit 16 determines that there is a predetermined situation in which the touch panel 12 is operated.

  FIG. 3 is a diagram illustrating an example of an operation screen for setting the destination of the navigation function unit 11. This operation screen is a screen showing the result of the navigation function unit 11 searching for the destination using the characters entered on the character input operation screen of FIG. 2 as a clue. The user is prompted to enter a search. For this reason, the situation determination unit 16 determines that there is a predetermined situation in which the touch panel 12 is operated.

  FIG. 4 is a diagram illustrating an example of a navigation screen of the navigation function unit 11. In this navigation screen, the navigation function unit 11 searches for a route to the destination according to the destination input on the destination setting operation screen in FIG. 3 and a route search instruction to the destination. It is a screen for guidance. The user is likely to drive while looking at the navigation screen, and is less likely to be operated than the operation screens shown in FIGS. Therefore, the situation determination unit 16 determines that there is no predetermined situation in which the touch panel 12 is operated.

In the above example, whether or not the touch panel 12 is in a predetermined situation is determined uniformly over the entire screen, but may be determined for each area of the screen.
For example, in the example of the operation screen of FIG. 3, a “set to destination” button 132a, a “route search” button 132b, a “surrounding facility search” button 132c, and a “return” button 132d are displayed in an area 131 on the left side of the screen. A map showing the destination is displayed in the area 133 on the right side of the screen. The area 131 on the left side of the screen on which these buttons 132a to 132d are displayed is more likely to be operated by the user than the area 133 on the left side of the screen on which a map is displayed. Therefore, the situation determination unit 16 determines that the area 131 in the touch panel 12 is in the predetermined situation, and determines that the area 133 is not in the predetermined situation.
Further, the situation determination unit 16 may determine that only the areas of the buttons 132a to 132d are in a predetermined situation among the areas 131 and determine that the remaining areas are not in the predetermined situation.

For example, when the information obtained from the control unit 14 includes information indicating the operation screen of the navigation function unit 11 or the operated device 200, the situation determination unit 16 is a predetermined operation on the touch panel 12. It is judged that it is in the situation. On the other hand, when the information indicating that it is a navigation screen is included, it is determined that the touch panel 12 is not in a predetermined situation where it is operated.
For example, when information indicating the position of the area where the button is arranged is included, it is determined that the area of the button in the touch panel 12 is in a predetermined situation, and the remaining area is not in the predetermined situation. .
A judgment criterion for judging which screen or which area in the screen is a predetermined situation where the touch panel 12 is operated may be set in the situation judgment unit 16 in advance.

  The correction unit 17 corrects the detection value for each position output from the acquisition unit 15 by using a correction amount according to the situation determination result of the situation determination unit 16. The correction amount used for correction by the correction unit 17 is stored in advance in the correction amount storage unit 18. The correction unit 17 outputs a corrected detection value for each position (hereinafter referred to as a correction detection value) to the touch determination unit 19 as a sensitivity correction result.

The correction formula used by the correction unit 17 for correction is, for example, the following formula (1). The correction coefficient corresponds to the correction amount stored in the correction amount storage unit 18.
Correction detection value = correction coefficient × detection value (1)

  The correction amount storage unit 18 stores a correction amount when the touch panel 12 is operated in a predetermined situation and a correction amount when the touch panel 12 is not operated. This correction amount is, for example, the correction coefficient of the above equation (1).

  The touch determination unit 19 compares the correction detection value for each position output by the correction unit 17 with a threshold value, determines whether or not the touch is touched for each position, and outputs the determination result to the control unit 14. The determination result includes, for example, information indicating the position determined to be touched.

Here, an example of touch determination will be described with reference to FIG.
FIG. 5A and FIG. 5B are graphs showing the change over time of the detected value at a certain position, where the solid line indicates the detected value before correction, and the dotted line indicates that the touch panel 12 is in a predetermined situation. The corrected detection value and the alternate long and short dash line in the case of being performed indicate the correction detection value when it is determined that the touch panel 12 is not in a predetermined situation. A broken line indicates a threshold used by the touch determination unit 19 for determination.
The capacitance type touch panel 12 has a detection value that rises when the user touches it as shown in FIG. 5A due to the difference in the configuration of the detection circuit built in the touch panel 12, as shown in FIG. 5B. Some detection values decrease when the user touches.

In the case of FIG. 5A, the touch determination unit 19 determines that the position of the correction detection value is touched when the correction detection value is greater than the threshold, and outputs the touch position to the control unit 14. On the other hand, when the correction detection value is equal to or smaller than the threshold value, the touch determination unit 19 determines that the touch is not performed.
The correction detection value (dotted line) in the case where it is determined that the touch panel 12 is in a predetermined situation is corrected so as to be larger than the detection value (solid line) before correction. It becomes easy to be judged. As a result, the sensitivity of touch determination increases. Therefore, user operability can be improved.
On the contrary, the correction detection value (one-dot chain line) in the case where it is determined that the touch panel 12 is not in a predetermined situation is corrected so that the value is smaller than the detection value (solid line) before correction. Therefore, it is easy to determine that there is no touch. As a result, the sensitivity of touch determination decreases. Therefore, it is possible to avoid a situation in which it is erroneously determined that there is a touch when the detection value rises due to the influence of external noise even though the user is not touching.

In the case of FIG. 5B, the touch determination unit 19 determines that the position of the correction detection value is touched when the correction detection value is smaller than the threshold value, and outputs the touch position to the control unit 14. On the other hand, when the correction detection value is equal to or greater than the threshold value, the touch determination unit 19 determines that the touch is not performed.
The correction detection value (dotted line) when it is determined that the touch panel 12 is in a predetermined situation is corrected so as to be smaller than the detection value (solid line) before correction. It becomes easy to be judged. As a result, the sensitivity of touch determination is increased, and the operability for the user can be improved.
On the other hand, the corrected detection value (one-dot chain line) when it is determined that the touch panel 12 is not in a predetermined situation is corrected so as to be larger than the detection value before correction (solid line). Therefore, it is easy to determine that there is no touch. As a result, the sensitivity of touch determination is reduced, and a situation in which it is erroneously determined that there is a touch due to the influence of external noise can be avoided.

For example, when the minimum value of the correction coefficient is 0 and the maximum value is 2 in the above equation (1), the touch panel 12 of a type whose detection value increases when the user touches is in a predetermined situation where the touch panel 12 is operated. In this case, the correction coefficient is set to 1.5, and the correction coefficient when not in a predetermined situation is set to 0.5. In the type of touch panel 12 in which the detection value decreases when the user touches, the correction coefficient when the touch panel 12 is operated in a predetermined situation is set to 0.5, and the correction coefficient when the touch panel 12 is not operated is set to 1.5. To do. Thereby, compared with the sensitivity in the situation where the user operates, the sensitivity in the situation where the user does not operate is relatively lowered.
Note that the above numerical example is an example of a correction coefficient and does not limit the value.

Further, for example, for the touch panel 12 whose detection value increases when the user touches, the touch determination unit 19 determines that there is a touch when the correction coefficient is 0 when the touch panel 12 is not in a predetermined situation where the touch panel 12 is operated. It is also possible not to have it.
Furthermore, the user may be able to change the correction coefficient.

  Next, a hardware configuration of navigation device 100 according to Embodiment 1 will be described. FIG. 6 is a hardware configuration diagram of the navigation device 100. The display unit 13 shown in FIG. 1 is the display 300 of FIG. Although the display unit 13 is a display, it may be anything that displays information.

  The navigation function unit 11, the control unit 14, the acquisition unit 15, the situation determination unit 16, the correction unit 17, and the touch determination unit 19 are realized by the processor 301 executing a program stored in the memory 302. The processor 301 is a processing circuit such as a CPU or a system LSI. The correction amount storage unit 18 is a memory 302, and the correction amount is stored in the memory 302. Note that the program and the correction amount are stored in the memory 302. However, any program may be used as long as it can store information. A plurality of processors and a plurality of memories may execute the above functions in cooperation.

Next, the operation of the touch detection device 102 according to the first exemplary embodiment will be described with reference to FIG.
Here, as an example, a case where a touch panel 12 of a type whose detection value increases when the user touches as shown in FIG.

  In a state where the power of the display 300 is turned on, the touch panel 12 outputs a detection value detected for each position. The acquisition unit 15 acquires a detection value that has changed, that is, a detection value of a position that may have been touched by the user, and information indicating the position (step ST11 “YES”). If the acquisition unit 15 cannot acquire the detected value and the position where the change has occurred (step ST11 “NO”), the acquisition unit 15 repeats step ST11 until it can be acquired.

  Subsequently, the situation determination unit 16 acquires information indicating the contents of the screen output by the control unit 14 and determines whether or not the touch panel 12 is in a predetermined situation (step ST12). As a result of the situation determination by the situation determination unit 16, if the touch panel 12 is in a predetermined situation in which it is operated (“YES” in step ST <b> 13), the correction unit 17 from the correction amount storage unit 18 A correction amount (correction coefficient) in a situation is acquired, and a correction detection value corrected in the direction of increasing the value is obtained by multiplying the detection value by the correction coefficient (step ST14).

  On the other hand, if the result of the situation determination by the situation determination unit 16 is that the touch panel 12 is not in a predetermined situation (step ST13 “NO”), the correction unit 17 operates the touch panel 12 from the correction amount storage unit 18. A correction amount (correction coefficient) when not in a predetermined situation is acquired, and a correction detection value corrected in the direction of decreasing the value is obtained by multiplying the detection value by the correction coefficient (step ST15).

  The touch determination unit 19 determines whether or not the correction detection value output from the correction unit 17 is greater than the threshold value (step ST16). When the corrected detection value is larger than the threshold value (step ST16 “YES”), the touch determination unit 19 determines that the touch has been made (step ST17). When the correction detection value is equal to or smaller than the threshold value (step ST16 “NO”), the touch determination unit 19 determines that the touch is not performed, and returns to step ST11.

  As described above, according to the first embodiment, the touch detection device 102 has the situation determination unit 16 that determines whether or not the touch panel 12 is in a predetermined situation in which the touch panel 12 is operated, and the situation determination unit 16 operates the touch panel 12. A correction unit 17 for performing correction to increase the sensitivity of touch determination when it is determined that the predetermined condition is determined, and to decrease the sensitivity of touch determination when it is determined that the predetermined condition is not detected, and sensitivity correction of the correction unit 17 Based on the result, the touch determination unit 19 is configured to determine whether or not the touch panel 12 is touched. In order to correct the sensitivity of the touch determination, the correction unit 17 according to the first embodiment is configured to correct the detection value acquired by the acquisition unit 15 according to the situation determination result of the situation determination unit 16. For this reason, in the situation where the user operates the touch panel 12, the sensitivity of touch determination increases, and the operability for the user is improved. On the other hand, in a situation where the user does not operate the touch panel 12, the sensitivity of touch determination is reduced, and the influence of external noise can be suppressed. In Patent Document 1, it is necessary to add a shield electrode to the touch panel. However, in Embodiment 1, the touch panel 12 does not need to be structurally changed, and can be realized relatively easily.

  Further, according to the first embodiment, the situation determination unit 16 determines whether or not the touch panel 12 is in a predetermined situation based on the content of information displayed on the display unit 13 through the touch panel 12. Made the configuration. For this reason, for example, when an operation screen for inputting characters is displayed on the entire surface of the display unit 13, the sensitivity of the entire screen can be increased to improve the operability for the user.

  Further, according to the first embodiment, the situation determination unit 16 is not in a predetermined situation with an area in the predetermined situation on the touch panel 12 based on the content of information displayed on the display unit 13 through the touch panel 12. The region is determined, and the correction unit 17 is configured to perform correction to increase the sensitivity of the region determined to be in the predetermined state by the state determination unit 16 and decrease the sensitivity of the region determined not to be in the predetermined state. . For this reason, for example, when a character input screen or the like is displayed on the left side of the display unit 13 and a map screen or the like is displayed on the right side of the screen, the sensitivity can be increased only for the character input screen. Operability can be improved. At the same time, the influence of external noise can be suppressed by reducing the sensitivity of the map screen.

Embodiment 2. FIG.
In the first embodiment, whether or not the touch panel is in a predetermined situation is determined based on the content of information displayed on the display unit through the touch panel. On the other hand, in Embodiment 2, it is determined whether or not the touch panel is in a predetermined situation based on the moving speed of the moving body equipped with the touch panel.

  FIG. 8 is a block diagram illustrating a configuration example of the navigation apparatus 100 according to the second embodiment. 8, parts that are the same as or equivalent to those in FIG. 1 are given the same reference numerals, and descriptions thereof are omitted. Hereinafter, Embodiment 2 will be described using an example in which navigation device 100 is mounted on a vehicle.

  The control unit 14a acquires information indicating the traveling speed of the vehicle from the navigation function unit 11, and outputs the information to the situation determination unit 16a.

  The situation determination unit 16a acquires information indicating the traveling speed of the vehicle from the control unit 14a, and determines whether the vehicle is traveling or stopped. The situation determination unit 16a determines that the touch panel 12 is in a predetermined situation where the touch panel 12 is operated when the vehicle is stopped. If the vehicle is running, the situation determination unit 16a is not in the predetermined situation where the touch panel 12 is operated. to decide. Similar to the first embodiment, the correction unit 17 corrects the sensitivity of touch determination according to the situation determination result of the situation determination unit 16a.

The touch detection apparatus 102 according to the second embodiment is the same as the other steps ST11 and ST13 to ST17 except that the processing content of the “status determination” in step ST12 is different from the flowchart shown in FIG.
That is, in the second embodiment, in step ST12 of FIG. 7, the situation determination unit 16a acquires information indicating the vehicle traveling speed from the control unit 14, and determines whether or not the touch panel 12 is in a predetermined situation. to decide.

  However, in the case of a vehicle, the driver is driving while the vehicle is running and is not in a situation to operate the touch panel 12, but a passenger in the passenger seat operates the touch panel 12 while the vehicle is running. Is possible. Therefore, the display device 101 with a touch detection function may be provided with a user determination unit 20, and the user determination unit 20 may determine whether the user operating the touch panel 12 is a driver or a passenger. When the user is determined to be a driver, the situation determination unit 16a changes the situation determination depending on whether the vehicle is traveling or stopped, and when the user is determined to be a passenger, whether the vehicle is traveling or stopped. Regardless of the condition, it is determined that the touch panel 12 is operated by the passenger.

For example, the user determination unit 20 installs an infrared sensor around the touch surface of the touch panel 12, and detects from which direction the user's finger or touch pen is inserted from the touch panel 12. Then, the user determination unit 20 determines whether the user is a driver or a passenger based on the insertion direction. For example, when the touch panel 12 is installed on the center console of the left-hand drive vehicle, a driver is inserted when a finger or the like is inserted from the left side of the touch panel 12, and a passenger is inserted when a finger or the like is inserted from the right side of the touch panel 12. Can be determined.
Moreover, the user determination part 20 may determine whether the user who operates the touch panel 12 is a driver or a passenger using, for example, a captured image of a camera that images the inside of the vehicle.
These determination methods are merely examples, and any method can be used as long as it can determine whether the user is a driver or a passenger.

FIG. 9 is a flowchart illustrating an operation when the touch detection apparatus 102 according to the second embodiment uses the determination result of the user determination unit 20. Steps ST11 and ST13 to ST17 shown in FIG. 9 are the same processing as in FIG.
After step ST11, the user determination unit 20 determines whether the user is a driver or a passenger, and outputs the determination result to the situation determination unit 16a (step ST21).

  As a result of the determination by the user determination unit 20, if the user is a driver ("YES" in step ST22), the situation determination unit 16a acquires information indicating the traveling speed of the vehicle output by the control unit 14a, and determines the situation. This is performed (step ST12a). The situation determination unit 16a determines that the touch panel 12 is in a predetermined situation where the touch panel 12 is operated by the user, that is, the driver if the vehicle is stopped, and the touch panel 12 is determined by the user, that is, the driver, if the vehicle is running. It is determined that there is no predetermined situation to be operated.

  On the other hand, if the result of determination by the user determination unit 20 is that the user is a passenger (step ST22 “NO”), the situation determination unit 16a skips step ST12a and step ST13, and “increases sensitivity” in step ST14. Proceed to processing.

  As described above, according to the second embodiment, the situation determination unit 16a determines that the touch panel 12 is in a predetermined situation when the mobile object equipped with the touch panel 12 is stopped, and the mobile object moves. When it is doing, it was judged that it was not in a predetermined situation. For this reason, when the user is likely to operate the touch panel 12, the sensitivity of touch determination is increased, and the operability for the user is improved. On the other hand, during traveling where the user is unlikely to operate the touch panel 12, the sensitivity of touch determination is reduced, and the influence of external noise can be suppressed. Furthermore, there is a possibility that a hand shakes and erroneously touches while traveling, but erroneous touch can be prevented by lowering the sensitivity of touch determination.

  Further, according to the second embodiment, when the user operating the touch panel 12 is a vehicle driver, the situation determination unit 16a is in a predetermined situation where the touch panel 12 is operated when the vehicle is stopped. When the vehicle is traveling, it is determined that the vehicle is not in a predetermined situation. When the user who operates the touch panel 12 is a passenger in the passenger seat, the touch panel 12 does not matter whether the vehicle is stopped or traveling. It is configured to determine that the device is in a predetermined situation where it is operated. For this reason, when the user is a passenger in the passenger seat, the sensitivity of touch determination is increased regardless of whether the vehicle is running or stopped, and the operability for the user is improved.

Embodiment 3 FIG.
In the first embodiment, whether or not the touch panel is in a predetermined situation is determined based on the content of information displayed on the touch panel over the touch panel. In the second embodiment, the moving speed of the moving object is determined. Based on. On the other hand, in Embodiment 3, it judges based on both the content of the information which a display part displays via a touch panel, and the moving speed of a moving body.

  FIG. 10 is a block diagram illustrating a configuration example of the navigation device 100 according to the third embodiment. 10, parts that are the same as or equivalent to those in FIG. 1 are given the same reference numerals and explanation thereof is omitted. Hereinafter, Embodiment 3 will be described using an example in which navigation device 100 is mounted on a vehicle.

  The control unit 14b instructs the display unit 13 to display information indicating the contents of the screen, and outputs this information to the situation determination unit 16b. Moreover, the control part 14b acquires the information which shows the travel speed of a vehicle from the navigation function part 11, and outputs it to the condition judgment part 16b.

  The situation determination unit 16b acquires information indicating the content of the display screen output by the control unit 14b. Moreover, the situation determination part 16b acquires the information which shows the traveling speed of the vehicle output from the control part 14b, and determines whether the vehicle is traveling or is stopped. Then, the situation determination unit 16b determines whether the touch panel 12 is in a predetermined situation where the touch panel 12 is operated based on the information indicating the content of the display screen and the traveling state of the vehicle, and the situation determination result is corrected by the correction unit 17b. Output to.

In the third embodiment, whether or not the touch panel 12 is in a predetermined situation is operated, and the degree of possibility is divided into multiple stages.
In the following description, a case where the touch panel 12 of a type whose detection value increases when the user touches as shown in FIG. 5A is taken as an example.
For example, when the operation screen for inputting characters as shown in FIG. 2 is displayed on the display unit 13 and the vehicle is stopped (situation 1), the situation determination unit 16b operates the touch panel 12. Is determined to be most likely to be in a predetermined situation. When an operation screen or the like is displayed on the display unit 13 and the vehicle is traveling (situation 2), it is determined that there is a high possibility of being in a predetermined situation next to situation 1. When a navigation screen such as a map as shown in FIG. 4 is displayed on the display unit 13 and the vehicle is stopped (situation 3), there is a possibility that the situation is in a predetermined situation next to situation 2 Judged to be high. When the navigation screen is displayed on the display unit 13 and the vehicle is traveling (situation 4), it is determined that the possibility of being in a predetermined situation is the lowest.

The correction amount storage unit 18b stores correction amounts corresponding to each of situations 1 to 4. Here, FIG. 11 shows an example of the correction amount stored in the correction amount storage unit 18b. This correction amount is the correction coefficient of the above equation (1). If the minimum value of the correction coefficient is 0 and the maximum value is 2, the correction coefficient is set to 1.5 when the operation screen is most likely to be in a predetermined situation in which the touch panel 12 is operated and stopped (Situation 1). Has been. The correction coefficient is set to 1.3 when the operation screen is most likely next to the situation 1 and the vehicle is traveling (situation 2). The correction coefficient is set to 0.8 when the navigation screen is most likely next to situation 2 and is stopped (situation 3). The correction coefficient is set to 0.5 on the navigation screen with the lowest possibility and while traveling (situation 4). As a result, the sensitivity in a situation where there is a high possibility that the user will not operate is relatively lower than the sensitivity in a situation where the user is likely to operate.
Note that the above numerical example is an example of a correction coefficient and does not limit the value.

  The correction unit 17b acquires a correction amount (correction coefficient) according to the situation determination result of the situation determination unit 16b from the correction amount storage unit 18b, and corrects the detection value for each position output from the acquisition unit 15.

FIG. 12 is a flowchart showing the operation of the touch detection apparatus 102 according to the third embodiment. Steps ST11, ST16, and ST17 shown in FIG. 12 are the same processing as in FIG.
After step ST11, the situation determination unit 16b acquires information indicating the content of the screen currently displayed on the display unit 13 and information indicating the traveling speed of the vehicle from the control unit 14b, and the touch panel 12 is operated. The possibility of whether or not the situation is present is determined in multiple stages (step ST12b).

  The correction unit 17b acquires the correction amount (correction coefficient) corresponding to the result of the situation determination by the situation determination unit 16b from the correction amount storage unit 18b (step ST31), and multiplies the detection value output from the acquisition unit 15 by multiplying the detection value. A corrected detection value is obtained (step ST32).

  As described above, according to the third embodiment, the situation determination unit 16b is operated by the touch panel 12 based on the content of information displayed on the display unit 13 through the touch panel 12 and the traveling state of the moving body on which the touch panel 12 is mounted. It is configured to determine whether or not a predetermined situation is in effect. For this reason, the higher the possibility that the user operates the touch panel 12, the higher the sensitivity of touch determination, and the user's operability improves. In addition, the lower the possibility that the user operates the touch panel 12, the lower the sensitivity of touch determination, and the more the influence of external noise can be suppressed.

As in the first embodiment, in the third embodiment, the situation determination unit 16b may determine the possibility of operation for each screen area.
Similarly to the second embodiment, in the third embodiment, the situation determination can be changed depending on whether the user is a driver or a passenger in the passenger seat. For example, when the user who operates the touch panel 12 is a driver, the situation determination unit 16b determines the possibility of operation according to the situation. When the user is a passenger in the passenger seat, the situation determination unit 16b is uniform regardless of the situation. It may be determined that the possibility of operation is the highest.

Embodiment 4 FIG.
In the first to third embodiments, the sensitivity of touch determination is corrected by correcting the detection value of the touch panel. On the other hand, in the fourth embodiment, the sensitivity of touch determination is corrected by correcting the threshold value to be compared with the detected value.

  FIG. 13 is a block diagram illustrating a configuration example of the navigation apparatus 100 according to the fourth embodiment. In FIG. 13, the same or equivalent parts as in FIG.

  The correction unit 17c corrects the threshold value used for the determination by the touch determination unit 19c using the correction amount according to the situation determination result of the situation determination unit 16. The correction amount used for correction by the correction unit 17c is stored in advance in the correction amount storage unit 18c. The correction unit 17c outputs the corrected threshold value (hereinafter referred to as a correction threshold value) to the touch determination unit 19 as a sensitivity correction result.

The correction formula used by the correction unit 17c for correction is, for example, the following formula (2). The correction coefficient corresponds to the correction amount stored in the correction amount storage unit 18c.
Correction threshold = correction coefficient × threshold (2)

  The touch determination unit 19c compares the detection value for each position output by the acquisition unit 15 with the correction threshold value output by the correction unit 17c, determines whether or not the touch is performed for each position, and determines the determination result as the control unit 14. Output to.

Here, an example of touch determination will be described with reference to FIG.
FIG. 14A and FIG. 14B are graphs showing changes over time in the detected value (solid line) at a certain position. A broken line indicates a threshold value before correction, a dotted line indicates a correction threshold value when it is determined that the touch panel 12 is in a predetermined condition, and a one-dot chain line indicates a correction value when it is determined that the touch panel 12 is not in a predetermined condition. Indicates the threshold value.
As described with reference to FIG. 5 of the first embodiment, the capacitance type touch panel 12 has a detection value that increases when the user touches it as shown in FIG. In some cases, the detected value decreases when the user touches.

In the case of FIG. 14A, the touch determination unit 19 c determines that the position of the detection value is touched when the detection value is larger than the correction threshold, and outputs the touch position to the control unit 14. On the other hand, when the detected value is equal to or smaller than the correction threshold, the touch determination unit 19c determines that the touch is not performed.
The correction threshold value (dotted line) in the case where it is determined that the touch panel 12 is in a predetermined situation is corrected so as to be smaller than the threshold value (dashed line) before correction. It becomes easy. As a result, the sensitivity of touch determination increases. Therefore, user operability can be improved.
On the other hand, the correction threshold (one-dot chain line) when it is determined that the touch panel 12 is not in a predetermined situation is corrected so that the value is larger than the threshold (dashed line) before correction. It becomes easier to determine that there is no touch. As a result, the sensitivity of touch determination decreases. Therefore, it is possible to avoid a situation in which it is erroneously determined that there is a touch when the detection value rises due to the influence of external noise even though the user is not touching.

In the case of FIG. 14B, the touch determination unit 19 c determines that the position of the detection value is touched when the detection value is smaller than the correction threshold, and outputs the touch position to the control unit 14. On the other hand, when the detected value is equal to or greater than the correction threshold, the touch determination unit 19c determines that the touch is not performed.
The correction threshold value (dotted line) in the case where it is determined that the touch panel 12 is in a predetermined situation is corrected so as to be larger than the threshold value (dashed line) before correction. It becomes easy. As a result, the sensitivity of touch determination is increased, and the operability for the user can be improved.
On the contrary, the correction threshold value (one-dot chain line) when it is determined that the touch panel 12 is not in a predetermined situation is corrected so as to be smaller than the threshold value (dashed line) before correction. It becomes easier to determine that there is no touch. As a result, the sensitivity of touch determination is reduced, and a situation in which it is erroneously determined that there is a touch due to the influence of external noise can be avoided.

For example, if the minimum value of the correction coefficient is 0 and the maximum value is 2 in the above equation (2), the touch panel 12 of a type whose detection value increases when the user touches is in a predetermined situation where the touch panel 12 is operated. In this case, the correction coefficient is set to 0.5, and the correction coefficient when not in a predetermined situation is set to 1.5. In the type of touch panel 12 in which the detection value is lowered when the user touches, the correction coefficient when the touch panel 12 is operated in a predetermined situation is 1.5, and the correction coefficient when the user is not in the predetermined situation is 0.5. To do. Thereby, compared with the sensitivity in the situation where the user operates, the sensitivity in the situation where the user does not operate is relatively lowered.
Note that the above numerical example is an example of a correction coefficient and does not limit the value.
Further, the user may be able to change the correction coefficient.

Next, the operation of the touch detection apparatus 102 according to the fourth embodiment will be described with reference to FIG.
Here, a case where a touch panel 12 of a type whose detection value increases when the user touches as shown in FIG. 14A is taken as an example.
Steps ST11 to ST13 and ST17 shown in FIG. 15 are the same processing as FIG.

  As a result of the situation determination by the situation determination unit 16, when the touch panel 12 is in a predetermined situation to be operated ("YES" in step ST13), the correction unit 17c receives a predetermined operation for operating the touch panel 12 from the correction amount storage unit 18c. A correction amount (correction coefficient) when the situation is present is acquired, and a correction threshold value corrected in the direction of decreasing the value is obtained by multiplying the threshold value by the correction coefficient (step ST14c). This correction increases the sensitivity of touch determination.

  On the other hand, as a result of the situation determination by the situation determination unit 16, when the touch panel 12 is not in a predetermined situation (step ST13 “NO”), the correction unit 17c operates the touch panel 12 from the correction amount storage unit 18c. A correction amount (correction coefficient) when not in a predetermined situation is acquired, and the correction threshold value corrected in the direction of increasing the value is obtained by multiplying the threshold value by the correction coefficient (step ST15c). This correction reduces the sensitivity of touch determination.

  The touch determination unit 19c determines whether or not the detection value output from the acquisition unit 15 is larger than the correction threshold output from the correction unit 17c (step ST16c). When the detected value is larger than the correction threshold (step ST16c “YES”), the touch determination unit 19c determines that the touch has been made (step ST17). When the detected value is equal to or smaller than the correction threshold value (step ST16c “NO”), the touch determination unit 19c determines that the touch is not performed, and the process returns to step ST11.

  As described above, according to the fourth embodiment, the correction unit 17c corrects the threshold value used for the determination by the touch determination unit 19c according to the situation determination result of the situation determination unit 16 in order to correct the sensitivity of the touch determination. I made it. For this reason, as in the first embodiment, in the situation where the user operates the touch panel 12, the sensitivity of touch determination is increased, and the operability for the user is improved. On the other hand, in a situation where the user does not operate the touch panel 12, the sensitivity of touch determination is reduced, and the influence of external noise can be suppressed. Further, there is no need to structurally change the touch panel 12, and this can be realized relatively easily.

  As in the first embodiment, in the fourth embodiment, the situation determination unit 16 can determine an area in the touch panel 12 that is in a predetermined situation and an area that is not in the predetermined situation. In that case, a threshold value may be prepared for each position of the touch panel 12, and the correction unit 17c may correct the threshold value for each position in the region.

  Similarly to the second embodiment, in the fourth embodiment, whether or not the situation determination unit 16 is in a predetermined situation in which the touch panel 12 is operated based on the moving speed of the moving body on which the touch panel 12 is mounted. Can be determined. Furthermore, the situation judgment can be changed depending on whether the user is a driver or a passenger in the passenger seat.

  Similarly to the third embodiment, in the fourth embodiment, the situation determination unit 16 is in a predetermined situation in which the touch panel 12 is operated based on both the content of information to be displayed and the moving speed of the moving body. It can be determined whether or not.

Further, in the above-described first to fourth embodiments, correction is performed to increase the sensitivity of touch determination when it is determined that the touch panel 12 is in a predetermined situation, and touch is performed when it is determined that the touch panel 12 is not in the predetermined situation. Although the correction is performed to reduce the sensitivity of determination, only one of the correction for increasing the sensitivity and the correction for decreasing the sensitivity may be performed. In the case of this configuration, the correction unit 17 reduces the original sensitivity, and performs correction to increase the sensitivity when it is determined that the touch panel 12 is in a predetermined situation. Alternatively, the correction unit 17 increases the original sensitivity, and performs correction to decrease the sensitivity when it is determined that the touch panel 12 is not in a predetermined situation where the touch panel 12 is operated. In any method, the sensitivity is increased when the touch panel 12 is operated, so that the operability of the user can be improved, and the sensitivity is decreased when the touch panel 12 is not operated. Therefore, the influence of external noise can be suppressed.
Similarly, at least one of the correction for increasing the sensitivity of the area determined to be in the predetermined state of the touch panel 12 or the correction for decreasing the sensitivity of the area determined not to be in the predetermined condition is performed. Is also possible.

  In addition to the above, within the scope of the present invention, the present invention can freely combine each embodiment, modify any component of each embodiment, or omit any component of each embodiment. It is.

  In the present invention, the touch detection device 102 is applied to the display device 101 with a touch detection function and the navigation device 100 for a moving body. However, the present invention is not limited to this. For example, a mobile phone, an ATM device, a printer, The present invention can be applied to electronic devices using a touch panel as input means, such as a television device, a digital camera, and a notebook personal computer. In these electronic devices, the same effects as those of the first to fourth embodiments can be obtained.

  Since the touch detection device according to the present invention corrects the sensitivity of touch determination depending on whether or not the touch panel is in a predetermined situation, it is suitable for use in a navigation device for a moving body. Yes.

  DESCRIPTION OF SYMBOLS 11 Navigation function part, 12 Touch panel, 13 Display part, 14, 14a, 14b Control part, 15 Acquisition part, 16, 16a, 16b Situation judgment part, 17, 17b, 17c Correction part, 18, 18b, 18c Correction amount memory | storage part , 19, 19c Touch determination unit, 20 User determination unit, 100 Navigation device, 101 Display device with touch detection function, 102 Touch detection device, 131, 133 area, 132a to 132d buttons, 200 operated device, 201 air conditioner device, 202 Audio device, 203 handsfree call device, 300 display, 301 processor, 302 memory.

Claims (8)

An acquisition unit that acquires detection values detected for each position in the touch panel mounted on the vehicle ;
A touch determination unit that compares the detection value acquired by the acquisition unit with a threshold value to determine whether the touch panel is touched;
A situation determination unit that determines whether or not the touch panel is in a predetermined situation to be operated;
A correction unit that corrects the threshold based on a determination result by the situation determination unit ,
The situation determination unit
When the user who operates the touch panel is a driver of the vehicle, it is determined that the touch panel is operated when the vehicle is stopped, and the vehicle is traveling when the vehicle is running. Judge that it is not in the prescribed situation,
When the user who operates the touch panel is a passenger in a passenger seat, it is determined that the touch panel is operated in the predetermined condition regardless of whether the vehicle is stopped or traveling. Detection device.   The said situation judgment part judges whether it is in the said predetermined | prescribed situation where the said touch panel is operated based on the content of the information which a display part displays over the said touch panel. Touch detection device. The situation determination unit determines at least one of an area in the predetermined situation or an area not in the predetermined situation on the touch panel based on the content of information displayed by the display unit through the touch panel.
The correction unit corrects the threshold value of an area of the touch panel that is determined to be in the predetermined situation by the situation determination unit, or the threshold value of an area that is determined not to be in the predetermined situation. The touch detection device according to claim 2, wherein at least one of correction is performed. A touch panel;
A display unit for displaying information through the touch panel;
A display device with a touch detection function, comprising the touch detection device according to claim 1. A touch panel;
A display unit for displaying information through the touch panel;
The touch detection device according to claim 1,
A navigation device comprising a navigation function unit that operates based on a touch determination result of the touch detection device and information displayed on the display unit. An acquisition unit that acquires detection values detected for each position in the touch panel mounted on the vehicle;
A touch determination unit that compares the detection value acquired by the acquisition unit with a threshold value to determine whether the touch panel is touched;
When the user who operates the touch panel is a driver of the vehicle, it is determined that the touch panel is operated in a predetermined state when the vehicle is stopped, and the predetermined operation is performed when the vehicle is running. A situation determination unit that determines that the vehicle is in a predetermined state regardless of whether the vehicle is stopped or traveling when the user operating the touch panel is a passenger on the passenger seat. ,
A touch detection apparatus comprising: a correction unit that corrects detection sensitivity in the acquisition unit based on a determination result by the situation determination unit. A touch panel;
A display unit for displaying information through the touch panel;
A display device with a touch detection function, comprising the touch detection device according to claim 6 . A touch panel;
A display unit for displaying information through the touch panel;
A touch detection device according to claim 6 ;
A navigation device comprising a navigation function unit that operates based on a touch determination result of the touch detection device and information displayed on the display unit.

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