JP2013196457A - Display device, display method and display program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To avoid erroneous detection due to an obstacle in the case of detecting an object in proximity to a screen.SOLUTION: A proximity sensor 12 is disposed in the periphery of a display 11 of a display device 10, and when the proximity sensor output is turned to be less than a proximity detection threshold, the proximity of an object which is present within the distance is detected. When the proximity is detected, icons for various operations, "operation screen", is displayed on the display on the premise of an input operation from a touch panel. When the input operation to the touch panel is not performed in a predetermined time after the proximity is detected and the detected object is left as it is during this time, it is determined that the detected object is an obstacle, and the value of the proximity detection threshold in the proximity sensor 12 is changed to a distance to the obstacle.

Description

  The present invention relates to a display device, a display method, and a display program. For example, the present invention relates to a display device in which a touch panel is arranged on a display and the display program.

A display device that can perform input in accordance with a display screen from a touch panel (touch sensor) arranged on the surface of the display is, for example, a digital photo frame that displays a digital photograph or a navigation device that is mounted on a vehicle. Widely used.
In such a display device, it is possible to reduce the number of operation buttons (hardware configuration) arranged around the display by inputting from the touch panel.
On the other hand, there is a problem that the display area for digital photographs, map images, and the like is narrowed by the area of operation buttons displayed on the screen.
Therefore, Patent Document 1 describes a technique for providing a proximity detection unit and displaying an information menu such as an icon that was not displayed before detection when detecting that an input unit such as a finger has approached the touch panel. ing.

  However, in the technique described in Patent Literature 1, when an obstacle unrelated to the input operation is fixedly arranged on the front surface (detection range of the proximity detection unit) of the display device, the input means approaches. There is a problem that false detection continues.

For example, if the display device is a photo frame, a vase, a remote controller, a stuffed animal, or the like may be placed in the detection range.
In addition, when a display device installed in a vehicle is installed in the lower part of the center console, a plastic bottle or a drink with a straw contained in a cup folder is placed on the front surface of the display device. . In the case of a display device of the type installed on the dashboard, the same problem will occur if a simple cup folder is attached to the air outlet of an air conditioner.
As described above, when an obstacle is placed in the detection range of the proximity sensor (proximity detection unit), the sensor is always in a detection state, and an icon or the like is always displayed on the display screen.

Although a method of avoiding erroneous detection due to an obstacle by setting the detection distance (range) of the sensor in advance short is also conceivable, there is no big difference from touching the touch panel when the detection distance is close, and input means (finger, touch pen, etc.) The significance of displaying an icon or the like in advance by detecting the approach of () is diminished.
Further, it may be necessary to increase the number of sensors mounted in order to cope with a decrease in the detection range.

JP 2010-277377 A

  An object of the present invention is to avoid continuous erroneous detection due to an obstacle when detecting a predetermined object close to a screen.

(1) In the first aspect of the present invention, a display that displays an image, a touch panel that is disposed on the display and receives an input operation, and is disposed around the display, detects a physical quantity with respect to a predetermined object, and performs the detection. When the value r1 when the physical quantity is converted into the distance is less than the value R when the proximity detection threshold is converted into the distance, the proximity detection unit that detects the proximity state and the proximity detection unit detects the proximity state In such a case, after the proximity state is detected by the proximity detection unit and the screen switching unit for displaying the input operation on at least a part of the display, the input operation by the touch panel is not performed for a predetermined time, and the predetermined object And a threshold value changing means for changing the proximity detection threshold value to the detected physical quantity when the physical quantity with respect to is not changed. Providing a display device comprising.
(2) In the invention described in claim 2, after the threshold value detecting means detects the proximity state by the proximity detecting means, the input operation by the touch panel is not performed for a predetermined time, and the physical quantity for the predetermined object changes. The proximity detection threshold value before the proximity state is detected by the proximity detection means when the physical quantity (distance converted value r1) detected by the proximity detection means and not changed for the predetermined time is not detected. 2. The display device according to claim 1, wherein when the distance is smaller than (distance converted value R), the proximity detection threshold (distance converted value R) is changed to the physical quantity (distance converted value r <b> 1). provide.
(3) In the invention described in claim 3, the screen switching means displays the input operation when the touch panel is touched even when the proximity state is not detected. A display device according to claim 1 or 2 is provided.
(4) In the invention according to claim 4, the threshold value changing unit is configured to detect proximity when the physical quantity (distance converted value r1) detected by the proximity detecting unit is larger than a proximity detection threshold value (distance converted value R). 4. The display device according to claim 1, wherein the detection threshold is returned to a default value (distance converted value R0).
(5) In the invention according to claim 5, the apparatus includes a threshold storage unit that stores a proximity detection threshold value, and the threshold change unit changes the proximity detection threshold value stored in the threshold storage unit, The said proximity detection means sets the proximity detection threshold value memorize | stored in the said memory | storage means in the case of initial setting, The claim in any one of Claims 1-4 characterized by the above-mentioned. A display device is provided.
(6) In the invention according to claim 6, the physical quantity is any one of distance, illuminance, light, sound wave, and electromagnetic wave, according to any one of claims 1 to 5. A display device according to the claims is provided.
(7) The invention according to claim 7 is a display method for a display device including a display for displaying an image and a touch panel disposed on the display and receiving an input operation. A proximity detection step for detecting a proximity state when the detected value r1 when the detected physical quantity is converted into a distance is less than a value R when the proximity detection threshold is converted into a distance; and the proximity detection step When the proximity state is detected, the screen switching step for displaying the input operation on at least a part of the display and the proximity operation detected in the proximity detection step, the input operation on the touch panel is not performed for a predetermined time. And when the physical quantity for the predetermined object has not changed, the threshold change threshold is changed to change the proximity detection threshold to the detected physical quantity. And-up, to provide a display wherein the consisting.
(8) In the invention according to claim 8, there is provided a display program for a display device including a display for displaying an image, and a touch panel provided on the display for receiving an input operation, wherein a physical quantity for a predetermined object is obtained. A proximity detection function for detecting a proximity state when the value r1 when the detected physical quantity is converted into a distance is less than a value R when the proximity detection threshold is converted into a distance; and the proximity detection function When the proximity state is detected, the screen switching function for displaying an input operation on at least a part of the display, and the proximity operation is detected by the proximity detection function, the input operation by the touch panel is not performed for a predetermined time. And a threshold value changing function for changing the proximity detection threshold value to the detected physical quantity when the physical quantity for the predetermined object has not changed. It provides a display program for implementing the computer.

  According to the present invention, the proximity detection threshold is set to the detected physical quantity when an input operation on the touch panel is not performed for a predetermined time after the proximity state is detected by the proximity detection means and the physical quantity for the predetermined object has not changed. Since the change is made, it is possible to avoid continuous erroneous detection due to an obstacle.

It is an external appearance block diagram of the display apparatus of this embodiment. It is explanatory drawing which illustrated the display screen displayed on a display. It is explanatory drawing showing the function structure of the display apparatus. It is a flowchart showing the first half of proximity detection processing. It is a flowchart showing the second half of the proximity detection process. It is explanatory drawing showing the typical positional relationship of the proximity detection threshold value R and a detection target in proximity detection processing. It is another explanatory view showing a typical positional relationship between the proximity detection threshold R and the detection target in the proximity detection process. It is explanatory drawing showing the state which looked at the display apparatus which has arrange | positioned multiple proximity sensors from the top.

Hereinafter, preferred embodiments of a display device, a display method, and a display program according to the present invention will be described with reference to FIGS. Will be described in detail with reference to FIG.
(1) Outline of Embodiment In this embodiment, as shown in FIG. 1, a proximity sensor 12 is arranged around the display 11 of the display device 10, and a predetermined object (object) is within a predetermined distance (within a proximity detection threshold R). ) Proximity is detected when approaching.
And when proximity is not detected (proximity non-detection state), the display 11 uses the whole area to display a “screen to be displayed”, for example, a display device for a car navigation system. Displays a screen that displays the map information and current vehicle location.
On the other hand, when proximity is detected (proximity detection state), on the display 11, various operation icons “operation screens” on the premise of input operations from the touch panel, such as operation buttons for audio operations, are displayed around the screen to be displayed. Is displayed.

And the proximity detection of the target object (predetermined object) using the proximity sensor 12 is performed as follows.
The proximity sensor 12 detects and outputs a distance r1 to the object. Then, when it is detected that the distance r1 is equal to or less than a predetermined proximity detection threshold value R (for example, 8 cm to 10 cm) (r1 ≦ R), it is determined as the proximity state.
Then, after the proximity sensor 12 detects a predetermined predetermined object, if the touch input to the touch panel is not detected within a specified time, or the detection distance r1 (output value) at the proximity sensor 12 does not change ( In the case of r2 = r1), it is determined that there is an erroneous detection due to an obstacle, and the sensor detection state is canceled.
Further, the proximity detection threshold R is changed (R ← r1) to the proximity sensor output r1 (= r2) at this time. Thereby, even if the detected obstacle is left as it is, it is possible to prevent the erroneous detection state due to the obstacle from continuing and displaying the operation screen continuously.

Thereafter, when a predetermined object other than the obstacle approaches the changed proximity detection threshold R (the value of the distance to the obstacle), the proximity state is detected and an operation screen is displayed.
When the proximity sensor output r1 becomes larger than the proximity detection threshold R changed by the obstacle, it is determined that the obstacle has been removed, and the proximity detection threshold R is set to an initial value (default) R0.

  As described above, by changing the value of the proximity detection threshold R for detecting the proximity of the object by the proximity sensor 12 according to the situation, switching between the screen to be displayed and the operation screen can be reliably determined.

(2) Details of Embodiment FIG. 1 is a diagram showing an external configuration of a display device according to this embodiment.
As shown in FIG. 1, the display device 10 includes a display 11 for displaying an image such as a map image.
A proximity sensor 12 is disposed on the outer frame for attaching the display 11.
Although the case where one proximity sensor 12 in the present embodiment is arranged at the lower right of the display 11 will be described as an example, a plurality of proximity sensors 12 may be arranged. That is, it may be arranged in other places such as the lower left and the upper left, arranged in four corners, or arranged in four sides according to the region where the object is desired to be detected.
The proximity sensor 12 detects and outputs a physical quantity that can be converted into a distance to the object.

The proximity sensor 12 detects and outputs a specific physical quantity, and any physical quantity that can be converted into a distance may be used as the physical quantity to be detected.
In the proximity sensor 12 of the present embodiment, a case will be described in which the distance r (r1, r2) converted from the illuminance of the reflected infrared light is detected, but as other physical quantities, the illuminance s of the reflected infrared light, light, You may make it detect reflection time t etc., such as a sound wave and electromagnetic waves.
It is determined whether or not the physical quantity detected by the proximity sensor 12 is in the proximity state based on whether it is larger or smaller than the proximity detection threshold corresponding to the physical quantity.
That is, the proximity state is determined when the distance conversion value of the detected physical quantity is smaller than the distance conversion value of the proximity detection threshold corresponding to the physical quantity.

FIG. 2 illustrates a display screen displayed on the display 11.
FIG. 2A illustrates a “screen to be displayed” in a state where proximity by the proximity sensor 12 is not detected (proximity non-detected state).
In this embodiment, since the case where the display device 10 is used in a navigation system for a vehicle is described, in the example of FIG. It is displayed on the display 11 together with the position (displayed with black triangles and circles) and the travel route (displayed with a thick dotted line) that is a guidance target by the route search.

On the other hand, FIG. 2B illustrates an “operation screen” in a state where proximity is detected by the proximity sensor 12 (proximity detection state). This operation screen is partially overwritten (upper and lower parts) and partially transparent (right and left parts) around the “show screen”.
In the example shown in FIG. 2B, screen transition icons for shifting from the full map image display for navigation to another operation screen are displayed at the four corners of the display 11. That is, the top icon 111 that shifts to the top screen of the entire apparatus is at the lower left of the screen, the audio button 112 that shifts to the audio selection screen for selecting audio is at the upper left of the screen, and the navigation button 113 that shifts to the top screen of the navigation function is at the upper right. In addition, a setting button 114 for shifting to a setting screen for performing various settings is displayed on the lower right.
On the right side of the display 11, a search icon for searching for a desired point, a memory icon for registering the point, and a navigation related icon 115 such as a scale display are displayed.
On the bottom side of the display 11, an audio operation icon 116 for instructing volume adjustment of a CD, a radio or the like driven in parallel with the map display, changing a playback track, ejecting, or the like is displayed.
Further, an enlargement / reduction change bar 117 for enlarging and reducing the displayed map is displayed on the left side of the screen.

FIG. 3 shows the configuration of the display device 10.
The display device 10 includes a control unit 100, a display control unit 101, a proximity detection unit 102, a touch input detection unit 103, a timer 104, and a memory 105.
The control unit 100 is configured by a computer system including a CPU, ROM, RAM, and storage unit (not shown).
The control unit 100 includes the proximity detection program according to the present embodiment. When the CPU executes the proximity detection program, the control unit 100 outputs a display screen switching command based on the detection of the target object, or the proximity detection threshold of the proximity sensor 12. Avoid false detection by changing R value.

A display 11 is connected to the display control unit 101, and the display screen displayed on the display 11 is switched between the “show screen” and the “operation screen” shown in FIG. 2 in response to a switching command from the control unit 100. To display.
The display control unit 101 superimposes and displays the operation switch icons 111 to 117 on the operation screen.

A proximity sensor 12 is connected to the proximity detection unit 102, and an output value r1 (distance) of the proximity sensor 12 is compared with a currently set proximity detection threshold value R to determine whether or not an object has approached. judge.
In the present embodiment, the physical quantity output from the proximity sensor 12 and the proximity detection threshold R are distances.
When the output value r1 (distance r1) of the proximity sensor 12 is smaller than the proximity detection threshold R, the proximity detection unit 102 outputs that the object has approached.

The proximity sensor 12 detects a physical quantity (physical quantity that can be converted into a distance) that changes in accordance with the distance to the object, and outputs the detected distances r1 and r2.
When the output of the proximity sensor 12 is the distance r1, the proximity detection unit 102 compares the distance R that is a proximity detection threshold, and detects that the target object has approached when the detection distance r1 <R.
However, another physical quantity x (f (x) = r1, r2) that can be converted into the distance r1 may be detected. In this case, proximity is detected by using a physical quantity X (f (X) = R) whose converted value to distance is R as a proximity detection threshold.
For example, the convertible illuminance s may be detected. However, since the detected illuminance s increases as the distance from the proximity sensor to the object (an input means such as a finger or an obstacle) decreases, the proximity detection threshold value for the illuminance at which the distance conversion value is R is S. , Proximity is detected when s ≧ S.
If the physical quantity to be detected is the reflection time t of light, sound wave, electromagnetic wave, etc., when the proximity detection threshold T is set, the smaller the distance to the object, the smaller the reflection time t. Detect proximity to.

The touch input detection unit 103 includes a touch panel disposed on the surface of the display 11, detects a position touched by an input unit such as a finger, and outputs coordinates (x, y) of the touch position on the display 11. To do.
If a touch input is detected by the touch input detection unit 103 and the screen shown in FIG. 2A is being displayed, the control unit 100 switches to the operation screen in the same manner as the proximity detection by the proximity sensor 12. . On the other hand, if the operation screen of FIG. 2B is being displayed, it is determined that the operation is a touch input operation, and processing corresponding to the icon displayed at the output coordinate position (x, y) (switch correspondence) Process).

The timer 104 starts time measurement in response to a start instruction from the control unit 100 and notifies the control unit 100 that a predetermined time has elapsed.
The timer 104 includes a proximity determination time timer and an icon display timer.
The proximity determination time timer is a timer that measures a proximity determination time (for example, 10 msec to 100 msec) that defines a cycle for determining whether or not an object has approached.
The icon display timer is a timer that measures a response waiting time (for example, 5 seconds to 10 seconds) after switching to the operation screen. The response waiting time is a time (time for detecting a no-operation state) for continuing to determine whether or not a touch input has been made after switching to the operation screen.

The memory 105 is a storage unit that stores the output values r1 and r2 of the proximity sensor 12, the proximity detection threshold R for determining the proximity state, and the default (initial value) proximity detection threshold R0.
The output values r1 and r2 of the proximity sensor 12 are erased when the power is turned off, but the proximity detection thresholds R and R0 are stored without being erased even when the power is turned off. As will be described later, the proximity detection threshold R is a value that is appropriately changed depending on the obstacle detection status, but the default proximity detection threshold R0 is a fixed value.

Next, the proximity detection processing operation by the display device 10 configured as described above will be described.
4 and 5 are flowcharts showing the proximity detection process.
6 and 7 show typical positional relationships between the proximity detection threshold R and the detection target in the proximity detection process.
Each unit such as the display control unit 101 and the proximity detection unit 102 performs a corresponding process (display, output, etc.) based on an instruction from the control unit 100, but from the control unit 100 for easy understanding of the process. Description of individual instructions will be omitted. However, the program may be configured as a process of the control unit 100 instead of the display control unit 101 or the like.
In the following description, it is assumed that the “display screen” illustrated in FIG. 2A is displayed on the display 11.

The display device 10 executes the proximity detection processing program when a proximity processing start condition (usually, the power of the display device 10 is turned on when the vehicle is turned on) is satisfied.
Then, the control unit 100 initializes the sensor level of the proximity sensor 12 (step 10), and then starts output of the proximity sensor 12 (step 11). Thereby, infrared rays are output from the proximity sensor 12, and it is determined whether or not the output level exceeds a certain level (whether or not normal output is performed) (step 12). ), Return to step 11 and continue output.

When the infrared output level exceeds a certain level (step 12; Y), the control unit 100 reads the proximity detection threshold value R stored in the memory 105 and sets it for proximity determination in the proximity detection unit 102 (step 13). .
The proximity detection threshold R is a value that is changed when an obstacle is continuously detected for a certain period of time as will be described later, and the changed proximity detection threshold R is stored in the memory 105 and is not deleted. For this reason, by setting the stored proximity detection threshold value R as the proximity detection threshold value, it is possible to continue the state before the power is turned off regardless of whether the display device 10 is turned on or off by the ignition operation.

Next, the control unit 100 starts time measurement by the proximity determination time timer of the timer 104 (step 14), and monitors the passage of the proximity determination time (step 15).
When the proximity determination time has elapsed (step 15; Y), the control unit 100 acquires the output r1 of the proximity sensor 12 at that time and stores it in the memory 105 (step 16).

Next, the control unit 100 compares the acquired proximity sensor output r1 with the proximity detection threshold R (step 17, FIG. 5).
As a result of the comparison, when the proximity sensor output r1 is smaller than the proximity detection threshold R (step 17; r1 <R), the control unit 100 is close to the target (input means such as a finger or a touch pen for the user to operate). Is determined, or an obstacle is approaching), and an icon is displayed on the display screen of the display 11 (step 18). That is, the control unit 100 switches the display on the display 11 from the screen shown in FIG. 2A to the operation screen shown in FIG.

Next, the control unit 100 starts time measurement by the icon display timer of the timer 104 (step 19).
Then, the control unit 100 monitors whether the user performs a touch operation during the response waiting time and the touch input detection unit 103 detects the touch input (steps 20 and 21).
When a touch input by the user is detected during the response waiting time (step 20; Y), the control unit 100 performs a switch handling process (step 22). FIG. 6 (1) illustrates this state, in which the input means such as the user's finger enters inside the proximity detection threshold R (r1 <R) and touches the operation screen switched in step 18 (Step 20; Y).

In the switch handling process, the control unit 100 obtains an operation icon (switch) displayed on the coordinate value (x, y) output from the touch input detection unit 103, and executes the process defined by the icon. .
For example, when the audio button 112 at the upper left of the screen is touched on the operation screen of FIG. 2B, the display 11 displays audio for selecting various audio such as CD, DVD, radio, television, etc. corresponding to the icon. Move to the selection screen.

  Next, the control unit 100 determines whether or not the display device 10 is turned off by turning off the ignition (step 23). If the turning-off operation is performed (step 23; Y), the proximity detection process is terminated and turned off. If there is no operation (step 23; N), the process returns to step 14 to continue the proximity process.

  On the other hand, when the touch input is not detected (step 20; N) and the response waiting time has elapsed (step 21; Y), the control unit 100 displays the display 11 on the display 11 because the touch input has not been performed. By switching from the operation screen shown in FIG. 2B to the screen shown in FIG. 2A, the icons on the screen are deleted (step 24).

Next, since the control unit 100 has detected proximity but no touch input has been made, the object for which proximity has been detected in step 17 is in a permanent state (a state in which it is placed within the proximity detection threshold R). A determination is made as to whether the object is an obstacle or whether it is in a state in which it has been brought close to the proximity detection threshold value R but has been released because it is determined that an input operation is unnecessary.
That is, the control unit 100 newly acquires the proximity sensor output r2 from the proximity sensor 12 (step 25), the proximity sensor output r2 is equal to the proximity sensor output r1 acquired in step 16, and the proximity sensor output r1 is It is determined whether or not it is smaller than the proximity detection threshold R (step 26).

When r2 = r1 and r1 <R (step 26; Y), as illustrated in FIG. 6B, the object Z that has entered the proximity detection threshold R is left as it is even after the response waiting time has elapsed. It can be judged that it is in a state where
Therefore, it is determined that the obstacle is permanently installed, and the control unit 100 changes the value of the proximity detection threshold value R in order to avoid continuing the erroneous detection state of the obstacle Z (step 27). That is, the proximity detection threshold value R stored in the memory 105 is changed to the proximity sensor output r1 detected in step 16. In FIG. 6B, the proximity detection threshold R is represented by changing from the position of the solid line arrow to the position of R indicated by the dotted line arrow.
Thereafter, the control unit 100 proceeds to step 23 described above, and if there is no OFF operation (step 23; N), the control unit 100 returns to step 14 and continues the proximity detection process.
By changing the value of the proximity detection threshold value R to r1 in this way, the subsequent proximity determination is approached when the object enters before the distance to the obstacle (r1 = R) (step 17; Y) is determined.

On the other hand, when the acquired proximity sensor output r2 and the proximity sensor output r1 are not equal (r2 ≠ r1) (step 26; N), as illustrated in FIG. Although it has entered the detection threshold R, it can be determined that it has moved (retracted) outside the proximity detection threshold R without touch input.
Therefore, the control unit 100 proceeds to step 23 without changing the value of the proximity detection threshold value R.
In addition, there are cases where r1 = R and r1> R as cases where the determination condition of step 26 is not satisfied. These cases will be described later.

In step 17, when the proximity sensor output r1 acquired in step 16 is equal to the proximity detection threshold R (r1 = R), the control unit 100 determines whether a touch input has been detected (step 28).
When the touch input is not detected (step 28; N), as illustrated in FIG. 6 (4), the object existing at the distance r1 = R is the obstacle whose proximity detection threshold R is changed in step 27. Since it can be determined that it is Z, the control unit 100 proceeds to Step 23.
Thus, even if the proximity sensor 12 continuously outputs the distance r1 (<default proximity detection threshold R0) to the obstacle Z, the obstacle Z is determined in steps 25 and 26, and in step 27. Since the value of the proximity detection threshold R is changed to the distance r1 to the obstacle Z, depending on the presence of the obstacle Z, the screen may be switched from a screen that erroneously determines that the target object is close to the operation screen. Avoided.

On the other hand, when the proximity sensor output r1 is equal to the proximity detection threshold R (step 17; r1 = R) and a touch input is detected (step 28; Y), as illustrated in FIG. It is determined that the touch panel is touched (for example, the upper left of the screen is touched from the left direction of the display 11) through a region other than 12 detection regions. That is, it can be determined that the touch input by the user is a case where an input operation is desired.
Therefore, even when the proximity sensor 12 has not detected the proximity of the object, the control unit 100 proceeds to step 18 to continue the processing after switching to the operation screen in order to reflect the user's wishes. To do.

After the example state of FIG. 6 (5), if there is a retouch on the operation screen, the switch corresponding process in step 22 is executed.
On the other hand, if retouching is not performed within the response waiting time, as illustrated in FIG. 6 (5), since r1 = R, this corresponds to the case of step 26; N described above, and the proximity detection threshold R is set. The process proceeds to step 23 without changing (step 27).

  In addition, the touch input detection in step 28 is a case where the touch input detection (step 20) is continuously monitored during the response waiting time in order to determine whether or not the obstacle Z is permanently installed (still placed). Unlike the above, the setting of the original timer is not performed. It is determined whether or not the touch input detection in step 28 is detected in the proximity determination time cycle in steps 14 and 15.

In step 17, when the proximity sensor output r1 acquired in step 16 is larger than the proximity detection threshold R (step 17; r1> R), in this case, the following two cases are considered.
As a first case, as illustrated in FIG. 7 (6), a case where the obstacle Z existing in the default proximity detection threshold value R0 is removed may be considered.
In the second case, as illustrated in FIG. 7 (7), an object that originally has no obstacle and is located farther than the default proximity detection threshold value R0 is detected (a case where there is no object). This is considered to be the case.

For this reason, the control unit 100 determines whether or not the currently set proximity detection threshold value R is the default proximity detection threshold value R0 (step 29). If R = R0 is not satisfied (step 29; N), a failure is detected. It is determined that the object Z has been removed (see FIG. 7 (6)), and the value of the proximity detection threshold value R is changed to the default proximity detection threshold value R0 (step 28).
As a result, the changed state of the proximity detection threshold value R that has been changed for the obstacle Z is canceled and returned to the default proximity detection threshold value R0.

  On the other hand, when the value of the proximity detection threshold R is the default value R0 (step 29; Y, see FIG. 7 (7)), the control unit 100 changes the proximity detection threshold R by the obstacle Z (step 27). Therefore, it is determined that the input means such as a finger and the detection target such as an obstacle are not close to each other within the proximity detection threshold value R, and the process proceeds to step 31.

Next, the control unit 100 determines whether or not a touch input is detected (step 31). As for the touch input detection, as described in step 28, the original timer setting is not performed, and it is determined whether or not the detection is performed in the proximity determination time cycle in steps 14 and 15.
Then, as illustrated in FIG. 7 (8), when a touch input is detected (step 31; Y), the touch panel is touched through the area other than the detection area of the proximity sensor 12 as described in step 28. Since it can be determined that the user desires some input operation, the control unit 100 proceeds to step 18 and continues the process of switching to the operation screen.
On the other hand, if retouching is not performed within the response waiting time, as illustrated in FIG. 7 (9), since r1 = r2 but r1> R, this corresponds to the case where Step 26; N described above, The process proceeds to step 23 without changing the proximity detection threshold R (step 27).

Although the embodiment of the display device and the display program of the present invention has been described above, the present invention is not limited to the described embodiment, and various modifications can be made within the scope described in each claim. It is.
For example, in the embodiment described above, when proximity of an object is detected, the display 11 is used for various operations based on input operations from a touch panel such as audio around the map information (screen to be displayed) being displayed. The case where an icon (operation screen) is displayed has been described.
On the other hand, you may make it switch not the part of the display 11 but the whole surface from the screen shown before proximity detection to the operation screen. In this case, the entire screen may be always switched to the operation screen, but depending on the display content of the screen that is displayed before proximity detection, a part of the screen may be used as the operation screen or the entire screen may be switched to the operation screen. It may be.

  In addition, in the case of proximity detection, not only the operation screen based on the operation, but also the information provision screen that provides specific information according to the display content on the screen displayed before proximity detection is part of the screen to be displayed, Or you may make it display by replacing. Further, specific information that is not premised on the operation may be displayed in accordance with the operation screen.

In the embodiment described above, the case where the proximity sensor 12 is arranged at the lower right of the screen to detect the proximity corresponding to the driver has been described, but the proximity sensor is also arranged at the lower left, A passenger in the passenger seat may be a detection target.
In addition, the arrangement position, the number of arrangements, and the direction of the proximity sensor 12 may be set according to the directivity of the proximity sensor to be used.
As described above, the position and number of the proximity sensors 12 can be arranged according to the range to be detected. For example, when the size of the display 11 is large and the detection area of the proximity sensor 12 cannot cover the entire screen, the proximity sensor 12 may be added on a diagonal line or arranged at four corners.

FIG. 8 shows a state in which a display device in which a plurality of proximity sensors 12a and 12b are arranged is viewed from above.
As shown in FIG. 8A, the proximity sensor 12a and the proximity sensor 12b have a default proximity detection threshold value R0. However, different threshold values can be used.
When it is detected that the obstacle Z is permanently installed on the proximity sensor 12a side, as shown in FIG. 8B, the control unit 100 detects the proximity of the proximity sensor 12a that detects the proximity of the obstacle Z. The threshold value R is changed to r1a, and the proximity detection threshold value R on the proximity sensor 12b side that has not detected proximity is left at the default value R0.
As described above, when a plurality of proximity sensors 12a and 12b are arranged, the value of the proximity detection threshold R may be set and changed for each sensor.

In the case of the modification described in FIG. 8B, the proximity detection threshold R of the proximity sensor 12a is changed to r1a, so that the detection range of the proximity sensor 12a becomes narrow. Proximity detection in the region P is not performed.
Therefore, as shown in FIG. 8C, the proximity detection threshold R of the proximity sensor 12b that has not detected the permanent presence of the obstacle Z is set to a distance r1b (r1b ≧ R0) to the obstacle Z. (Not determined) may be changed to the enlarged proximity detection threshold value R1 of the proximity sensor 12b (R2 = r1b).
Thus, when any one proximity sensor 12a detects the permanent presence of the obstacle Z, the proximity detection threshold R of the other proximity sensor 12b that has not detected the permanent presence is also changed to the proximity sensor output r1b of the proximity sensor 12b. To do.
As a result, the proximity detection range of the other proximity sensor 12b can be prevented from greatly fluctuating by expanding the proximity detection range of the other proximity sensor 12b against the field where the proximity detection range of the proximity sensor 12a becomes narrow due to the permanent installation of the obstacle Z. The

In the embodiment described above, the case where both r2 = r1 and r1 ≦ R are satisfied as a condition for changing the value of the proximity detection threshold R to the proximity sensor output r1 has been described (step 26).
On the other hand, the proximity detection threshold R may be changed when the condition r2 = r1 is satisfied.
In this case, the condition r1 ≦ R is removed, so that r1 = R (when the retouch is not performed in the state of FIG. 6 (5)) and r1> R (the case of FIG. 7 (9)). ), The proximity detection threshold R is changed to r1.
However, when it is not retouched in FIG. 6 (5), there is no problem because r1 = R originally.
On the other hand, in the case of FIG. 7 (9), since r1> R0, in order to avoid the proximity detection threshold R (= r1)> R0 from being changed, the maximum of the proximity detection threshold R in step 27 is avoided. The value may be the default value R0.

In step 17, the case where r1 and R are compared has been described. However, there is a possibility that r1> R may be detected even when an obstacle placed at the proximity detection threshold R is shaken by vibration of the vehicle or the like. is there.
Therefore, in step 17, when proximity detection threshold value R = R0, r1 is compared with R (= R0), and when proximity detection threshold value R is changed and R (= r1) ≠ R0, it is changed. The display device Rz (Rz = R−α to + Rβ) may be compared.
In this case, in step 17, for the sensor output r1,
(A) r1> R + β (step 17; corresponding to r1> R),
(B) r1 <R−α (step 17; corresponding to Y),
(C) R−α ≦ r1 ≦ R + β (step 17; corresponding to r1 = R)
It is judged whether it corresponds to either.
As a result, an excessive reaction to a slight change in the distance r1 to the obstacle due to shaking or the like is avoided.

As described above, in the display device and the display program according to the present embodiment, the proximity sensor 12 is arranged around the display 11 of the display device 10, and the proximity sensor output r1 is at the distance r1 when the proximity sensor output r1 is less than the proximity detection threshold R. When the approach of the object is detected and the proximity is detected, an icon “operation screen” for various operations on the premise of the input operation from the touch panel is displayed on the display 11, and after the proximity is detected, the input operation to the touch panel is performed. If the predetermined object detected during this time is not placed for a predetermined time, it is determined that the detected predetermined object is an obstacle, and the value of the proximity detection threshold R in the proximity sensor 12 is changed to the distance r1 to the obstacle. To do.
Thereby, the following effect can be acquired.

(1) Since the proximity sensor 12 for detecting the proximity of the object is disposed around the display 11, when the proximity of the object is detected, an input operation icon or other information is displayed on the display screen of the display 11. Can do.
In addition, in a state where proximity is not detected (proximity non-detected state), since an input operation icon or the like is not displayed, a wide display screen of information desired to be shown to the user can be secured.
(2) It is determined whether or not the object existing within the proximity detection threshold R is an obstacle (steps 20 to 26), and when it is determined as an obstacle, the value of the proximity detection threshold R is set to the distance r1 to the obstacle. Therefore, it is possible to avoid erroneously detecting that an object is approaching due to an obstacle that has been placed and continuously switching to the operation screen. That is, it is avoided that the display screen of the display 11 is continuously narrowed by the operation screen due to erroneous detection.
(3) Even when the proximity sensor output r1 is equal to or greater than the proximity detection threshold R, that is, when the proximity of the target is not detected because the target is not within the proximity detection threshold R, the touch panel The touch input is detected (step 28; Y, step 31; Y), and the operation screen is switched as in the proximity detection state.
As described above, since the means for switching to the operation screen is provided in addition to the proximity sensor 12, the detection range of the proximity sensor 12 is narrowed to detect the proximity dedicated to the driver, or the number of the proximity sensors 12 arranged is reduced. You can.
Even if the proximity sensor 12 is out of order, the user can display the operation screen by touch input on the screen.
(4) When the proximity sensor output r1 is larger than the proximity detection threshold R, the proximity detection threshold R is returned to the default value R0, so that the obstacle placed in front of the display device 10 is removed. The default proximity detection state can be restored.
(5) The proximity detection threshold value R is stored in the memory 105, including the case where it is changed due to the presence of an obstacle, and the proximity detection threshold value R stored at the time of restart is set (step 13). The state before the 10 OFF operation can be maintained and resumed.

DESCRIPTION OF SYMBOLS 10 Display apparatus 11 Display 12 Proximity sensor 100 Control unit 101 Display control part 102 Proximity detection part 103 Touch input detection part 104 Timer 105 Memory Z Obstacle

Claims (8)

A display for displaying images,
A touch panel disposed on the display and receiving an input operation;
Proximity when a physical quantity for a predetermined object is detected around the display, and a value r1 when the detected physical quantity is converted into a distance is less than a value R when the proximity detection threshold is converted into a distance. Proximity detection means for detecting a state;
A screen switching means for displaying an input operation on at least a part of the display when a proximity state is detected by the proximity detection means;
After the proximity state is detected by the proximity detection unit, when the input operation by the touch panel is not performed for a predetermined time and the physical quantity for the predetermined object has not changed, the proximity detection threshold is changed to the detected physical quantity. Threshold changing means;
A display device comprising: The threshold value changing means includes
After the proximity state is detected by the proximity detection means, the input operation by the touch panel is not performed for a predetermined time, and the physical quantity for the predetermined object has not changed,
The physical quantity (distance converted value r1) detected by the proximity detecting means and not changing for the predetermined time is based on the proximity detection threshold (distance converted value R) before the proximity state is detected by the proximity detecting means. Is also small,
Changing the proximity detection threshold (distance converted value R) to the physical quantity (distance converted value r1);
The display device according to claim 1. The screen switching means displays the input operation when the touch panel is touched even when the proximity state is not detected.
The display device according to claim 1, wherein the display device is a display device. The threshold value changing means sets the proximity detection threshold value to a default value (distance conversion value R0) when the physical quantity (distance conversion value r1) detected by the proximity detection means is larger than the proximity detection threshold value (distance conversion value R). Back to
The display device according to claim 1, claim 2, or claim 3. Threshold storage means for storing the proximity detection threshold value,
The threshold value changing means changes the value of the proximity detection threshold value stored in the threshold value storage means,
The proximity detection means sets a proximity detection threshold stored in the storage means at the time of initial setting.
The display device according to claim 1, wherein the display device is a display device. The physical quantity is any of distance, illuminance, light, sound wave, electromagnetic wave,
The display device according to claim 1, wherein the display device is a display device. A display method for a display device, comprising: a display that displays an image; and a touch panel that is disposed on the display and receives an input operation.
A proximity detection step of detecting a proximity state when a physical quantity for a predetermined object is detected and a value r1 when the detected physical quantity is converted into a distance is less than a value R when a proximity detection threshold is converted into a distance; ,
A screen switching step for displaying an input operation on at least a part of the display when a proximity state is detected in the proximity detection step;
After the proximity state is detected in the proximity detection step, when the input operation by the touch panel is not performed for a predetermined time and the physical quantity for the predetermined object has not changed, the proximity detection threshold is changed to the detected physical quantity. A threshold change step;
A display method characterized by comprising: A display program for a display device comprising a display for displaying an image and a touch panel disposed on the display and receiving an input operation,
A proximity detection function for detecting a proximity state when a physical quantity for a predetermined object is detected and a value r1 when the detected physical quantity is converted into a distance is less than a value R when a proximity detection threshold is converted into a distance; ,
A screen switching function for displaying an input operation on at least a part of the display when a proximity state is detected by the proximity detection function;
After the proximity state is detected by the proximity detection function, when the input operation by the touch panel is not performed for a predetermined time and the physical quantity for the predetermined object has not changed, the proximity detection threshold is changed to the detected physical quantity. A threshold change function;
A display program for realizing a computer.

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