1. Field of the Invention
The present invention relates to a vehicle operation apparatus.
2. Description of the Related Art
A vehicle operation apparatus has been disclosed for performing an operation on a screen page of a display device by performing an operation on a touch panel (regardless of whether it is integrated with or separate from the display device). For example, Japanese Laid-Open Patent Application No. 2010-061224 discloses that a touch panel (touch pad) is separate from a display device and an operation is performed on the display device by using the touch pad.
According to one aspect of the present invention, a vehicle operation apparatus is provided for performing an operation on a screen page displayed on a display device using a touch panel. The vehicle operation apparatus includes an operation determination part configured to determine whether a cursor operation of moving a cursor in the screen page by touching the touch panel by an operation finger and sliding the operation finger on the touch panel or a flick operation of scrolling an operation target in the screen page by touching and flicking the touch panel by the operation finger is performed. The operation determination part is configured to change a threshold for determining the performed operation as the flick operation depending on a position of the cursor.
Other objects, features and advantages of the present invention will become more apparent from the following detailed description when read in conjunction with the accompanying drawings.
In a case of performing an operation on a screen page by using a touch panel, a cursor operation of moving a cursor or so on the screen page by sliding a finger on the touch panel and a flick operation of scrolling an operation target (a map, a list or so) on the screen page by flicking the touch panel may be performed. In such a case, it is determined based on the moving speed (tracing speed) of the finger on the touch panel whether the cursor operation or the flick operation is performed.
However, when sliding of the finger on the touch panel is performed relatively quickly, the tracing speed reaches a level of being determined as the flick operation and the sliding operation (cursor operation) may be erroneously determined as the flick operation. Further, if such a configuration is provided that determining the performed operation as the flick operation does not easily occur in order to prevent the cursor operation from erroneously being determined as the flick operation, there may occur a case where the flick operation that is intentionally performed cannot be determined as the flick operation, and thus, the operability may be degraded. Also, it is also possible to distinguish between the cursor operation and the flick operation based on the number of fingers which touch the touch panel by designating the numbers of fingers for respective types of operations such that, for example, the cursor operation should be performed by a single finger, the flick operation should be performed by two fingers, and so forth. However, in this method, degradation in the operability may be unavoidable.
In consideration of this matter, an objective of the embodiment is to provide a vehicle operation apparatus by which, for example, in a case where the cursor operation and the flick operation are performed on a touch panel by one finger, it is possible to positively determine the flick operation that is performed intentionally as the flick operation while preventing the cursor operation from being erroneously determined as the flick operation.
Below, the embodiment of the present invention will be described using drawings.
The vehicle operation apparatus 1 includes a touch pad (touch panel) 10, a display device 20, a display control part 30 and so forth.
The touch pad 10 is an operating part for performing an operation on a screen page (operating screen page) displayed on the display device 20. The touch pad 10 is installed at an appropriate place in the interior of the vehicle. It is preferable that the touch pad 10 is installed at a position such that the driver can easily operate it (i.e., a position that the driver's hand reaches while the driver is keeping the driving posture).
Using
As shown in
The coordinate detection part 12 is configured to be capable of moving in vertical directions (i.e., the Z-directions in
The pressing detection part 14 is a part detecting a downward movement of the coordinate detection part 12. The pressing detection part 14 outputs a signal indicating a downward movement of the coordinate detection part 12 to the control part 16. The pressing detection part 14 can be configured to have, for example, a tact switch or a pressure sensitive sensor (piezoelectric device or so). The pressing detection part 14 can be placed at any place as long as it is touched by the coordinate detection part 12 when the coordinate detection part 12 moves downward. In the example illustrated in
The control part 16 and the memory 18 can be, for example, configured to be a microcomputer.
The control part 16 detects a touch of a finger against the touch operating surface based on the output of the coordinate detection part 12. At this time, the control part 16 generates a coordinate signal indicating the coordinate position in the touch operating surface, i.e., the coordinate signal indicating the coordinate position indicating the touched position (the touched position of the operation finger). Note that when the coordinate detection part 12 is configured to include an electrostatic pad, charges are held in capacitors formed by the electrodes and the operation finger, and the variation amounts of the charges in the respective electrodes vary depending on the position of the operation finger. Therefore, it is possible to determine the position of the operation finger based on the detection signals from the respective electrodes. The generated coordinate signal is output to the display control part 30.
The control part 16 generates a determination signal indicating a fixing operation performed by the operator based on the output signal of the pressing detection part 14. For example, if the pressing detection part 14 is configured to include the pressure sensitive sensor, the control part 16 can detect the fixing operation performed by the operator when the output (pressing pressure) of the pressure sensitive sensor exceeds a threshold and generate the determination signal. If a plurality of the pressure sensitive sensors are placed at distributed places, the control part 16 can detect the fixing operation performed by the operator when the output of any one of the pressure sensitive sensors exceeds a threshold and generate the determination signal. If the pressing detection part 14 is configured to include the tact switch, the control part 16 can detect the fixing operation performed by the operator when an ON signal is input from the tact switch and generate the determination signal. If a plurality of the tact switches are placed at distributed places, the control part 16 can detect the fixing operation performed by the operator when an ON signal is input from any one of the tact switches and generate the determination signal. The generated determination signal is transmitted to the display control part 30.
Returning to
Using
As shown in
As shown in
Thus, on the operating screen page, a plurality of the selecting items (operating targets) are displayed. By placing the cursor at the selecting item (the selecting operation) and performing the fixing operation using the touch pad 10, the operator can cause the operation contents of the corresponding one of the respective selecting items to be implemented. Also, there can be a group of the selecting items (i.e., the list or the map) which can be scrolled as a result of the operator performing an operation on the touch pad 10. Note that the selecting items can be those concerning any types (functions). In other words, the contents to be able to be operated using the touch pad 10 can be any contents. For example, the selecting items can include those for carrying out various settings of an air conditioner and the selecting item for displaying the corresponding screen page on the display device 20.
The display control part 30 is a control part for controlling a screen page displayed on the display device 20. According to the embodiment, the display control part 30 synchronizes the display device 20 with the touch pad 10 and assists an operation performed on the display device 20. Specifically, the display control part 30 displays, on the display device 20, the operating screen page, and also, carries out a selecting process of selecting the various selecting items, a fixing process therefor, a scrolling process therefor (“list scrolling”, “map scrolling” and so forth) and so forth based on the signals from the touch pad 10 (the coordinate signal, the determination signal and so forth). For example, as a result of the operator touching the touch operating surface of the touch pad 10 by his or her finger and performing an operation of sliding the finger on the touch operating surface (i.e., the selecting operation), the display control part 30 responds to this operation, moves the cursor (that can be the pointer) on the operating screen page and causes a state to occur where any one of the selecting items is selected. Thus, in response to the operator's selecting operation, the display control part 30 executes a selecting function (the selecting process). Also, as a result of the operator performing an operation of pressing the touch pad 10 (the fixing operation) in a state where any one of the selecting items is thus selected, the display control part 30 implements the operation contents of the thus selected selecting item. That is, the display control part 30 executes s fixing function in response to the fixing operation (the fixing process). As a result of the operator performing an operation of flicking the touch operating surface by his or her finger while touching the touch operating surface by the finger (a flick operation) in a state where the map screen page or a “list scrollable” list is displayed on the display device 20, the display control part 30 responds to this operation and scrolls the map or the list. In other words, the display control part 30 responds to this operation and executes a scrolling function (the scrolling process). Note that, the term “cursor” used below also means the “pointer” unless otherwise specified.
More specifically, when receiving the coordinate signal corresponding to the selecting operation of the operator from the touch panel 10 in a state where the operating screen page is displayed on the display device 20, the display control part 30 causes a state to occur where any one of the selecting items in the operating screen page is selected. In other words, the display control part 30 determines the position of the cursor. At this time, the display control part 30 can operate in a “relative coordinate mode” or an “absolute coordinate mode”.
The “relative coordinate mode” means a mode where the coordinate system of the screen of the display device 20 is synchronized with the coordinate system of the operating surface of the touch pad 10 in a relative synchronization manner. Typically, in the relative coordinate mode, the coordinate systems of the screen of the display device 20 and the operating surface of the touch pad 10 are associated with each other in such a manner that the origin of the coordinate system of the display device 20 is positioned at the current position of the cursor while the origin of the coordinate system of the operating surface of the touch pad 10 is positioned at the current touched position of a finger. For example, when the operator touches his or her finger on the operating surface of the touch pad 10 and slides the finger downward thereon, the cursor on the screen of the display device 20 moves downward from the currently displayed position on the screen. At this time, according to the distance of sliding the finger on the operating surface, the moving distance of the cursor on the screen of the display device 20 is determined.
On the other hand, the “absolute coordinate mode” is such a mode that the coordinate system of the screen of the display device 20 is associated with the coordinate system of the operating surface of the touch pad 10 in an absolute synchronization manner (i.e., the respective points are associate with each other between the respective coordinate systems in a one-to-one correspondence manner). Typically, in the absolute coordinate mode, the coordinate systems of the screen of the display device 20 and the operating surface of the touch pad 10 are associated with each other in such a manner that the origin of the coordinate system of the screen of the display device 20 is positioned at a fixed position while the origin of the coordinate system of the operating surface of the touch pad 10 is positioned at a fixed position. For example, the coordinate system of the screen of the display device 20 where the origin is fixed at the bottom left corner of the screen of the display device 20 can be associated with the coordinate system of the operating surface of the touch pad 10 where the origin is fixed at the bottom left corner of the operating surface of the touch pad 10. At this time, when the operator touches the operating surface of the touch pad 10 by his or her finger, the cursor moves to the coordinates on the screen of the display device 20 corresponding to the coordinates of the operating surface of the touch pad 10 at which the finger is thus touching the operating surface. When the operator slides the finger downward from this state, the cursor on the screen of the display device 20 moves downward from the previous position to which the cursor was moved as mentioned above. Note that since generally the size of the screen of the display device 20 is not the same as the size of the operating surface of the touch pad 10, the correspondence relation between the respective coordinate systems can be a proportional relation according to the size ratio therebetween.
When receiving the determination signal from the touch pad 10 in a state where the operating screen page is displayed on the display device 20, the display control part 30 implements the fixing process, i.e., the operation contents of the selected selecting item. Note that the operation contents depend on the selecting item, and also, can be accompanied by a transition of the screen page such as to display subordinate selecting items, change the operating screen page, or so, a process for inputting letters, a start of an application, a process of transmitting a control signal to an operation target apparatus (for example, the air conditioner), or so.
Further, the display control part 30 executes scrolling a group of the selecting items (such as the map, the list or so) when receiving the coordinate signal corresponding to the operator's flick operation from the touch pad 10 in a state where the operating screen page that includes the group of the selecting items that are scrollable is displayed on the display device. Note that when the flick operation is performed, in a case of the map, for example, “map scrolling” can be carried out in a direction approximately the same as the operation direction of the flick operation (i.e., the moving direction of the operation finger). In a case of the list, the operation direction of the flick operation and the direction of “list scrolling” can be previously associated with each other, and then, “list scrolling” can be carried out in the direction according to the associating. For example, when the list is present for which “list scrolling” is carried out in the upward and downward directions in the operating screen page, “list scrolling” can be carried out in the upward direction if the flick operation is performed in a direction that is different upward from the leftward or rightward direction of the screen (for example, an upward and leftward direction). Similarly, “list scrolling” can be carried out in the downward direction if the flick operation is performed in a direction that is different downward from the leftward or rightward direction of the screen (for example, a downward and leftward direction).
Note that the display control part 30 is configured to be, for example, a microcomputer, and can perform various control processes described above as a result of a CPU executing various programs stored by a ROM. A part or all of the functions of the display control part 30 can be implemented by the control part 16 of the touch pad 10, another control part in the display device 20, or so. Also, a part or all of the functions of the control part 16 of the touch pad 10 can be implemented by the display control part 30. Further, to the display control part 30, vehicle speed information indicating the vehicle speed, power supply information concerning the states of vehicle power supplies (IG, ACC or so), or so, can be input, as is necessary.
Thus, according to the touch pad 10 in the present embodiment, the operator can select the desired selecting item by touching the operating surface of the coordinate detection part 12 by the operation finger (for example, the index finger) and moving the operation finger within the operating surface while viewing the display device 20. Then, the operator can perform the fixing operation by pressing the coordinate detection part 12 by the operation finger when a state occurs where the desired selecting item is selected. If a group of the selecting items that are scrollable are displayed on the display device 20 but the desired selecting item is not displayed there, the operator can scroll the group of the selecting items by performing a flick operation of flicking a finger while touching the operating surface of the coordinate detection part 12 by the operation finger. Thus, the operator can cause the desired selecting item to be displayed on the display device 20 and perform the above-described selecting operation and fixing operation.
Next, a characteristic process carried out by the vehicle operation apparatus 1 (the display control part 30) will be described. Specifically, a process of determining whether the selecting operation (a cursor operation) or the flick operation is performed will be described now. That is, the cursor operation and the flick operation are completely different when they are viewed from the operator. However, when they are viewed from the vehicle operation apparatus 1 (the display control part 30), the cursor operation and the flick operation are both detected as operations of moving the operation finger on the operating surface. Therefore, the display control part 30 cannot determine which operation is performed only by using the simple coordinate signal. Therefore, in a process of determining the flick operation described later, the display control part 30 determines the flick operation based on the moving speed of the operation finger on the touch operating surface of the touch pad 10.
As shown in
In Step S102, the display control part 30 calculates the moving direction D and the moving speed index value V of the operation finger on the operating surface of the touch pad 10. The moving speed index value V is an index value indicating the speed of moving of the operation finger on the operating surface. For example, the moving speed index value V can be the moving distance (the distance in the coordinate system of the touch pad 10) from when receiving the coordinate signal previously to when receiving the coordinate signal currently. Also, concerning the coordinate signals received in the past N times, the moving speed index value can be an average of the moving distances each from when receiving the coordinate signal to when receiving the coordinate signal next. The moving direction D can be calculated as an angle from a predetermined axis, for example, the x-axis or y-axis in the coordinate system of the operating surface of the touch pad 10 based on the coordinate position of the operating finger corresponding to the previously received coordinate signal and the coordinate position of the operating finger corresponding to the currently received coordinate signal.
Next, in Step S103, the display control part 30 determines a threshold for determining the flick operation (“determination threshold ThV”). As described above, in order to distinguish between the cursor operation and the flick operation, it is necessary to make the determination due to a difference in the moving speed of the operation finger. In other words, it is possible to determine the thus performed operation as the flick operation when the operation finger moves at a speed equal to or higher than a predetermined speed. Here, in order to determine whether or not the thus performed operation corresponds to the flick operation, the determination threshold ThV is determined for the moving speed index value V. Specifically, the display control part 30 changes the determination threshold ThV depending on the position of the cursor on the operating screen page. The details of the specific method of determining the determination threshold ThV will be described later.
Next, in Step S104, the display control part 30 determines whether the moving speed index value V is equal to or greater than the determination threshold Thy. When the moving speed index value V is equal to or greater than the determination threshold Thy, the display control part 30 proceeds to Step S105, determines that the operator's operation on the operating surface of the touch pad 10 is the flick operation and proceeds to Step S106. On the other hand, when the moving speed index value V is less than the determination threshold ThV, the display control part 30 proceeds to Step S107, determines that the operator's operation on the operating surface of the touch pad 10 is the cursor operation, and proceeds to Step S108.
In Step S106, the display control part 30 carries out scrolling of the group of the selecting items (the map, the list or so) corresponding to this flick operation.
On the other hand, in Step S108, the display control part 30 carries out moving the cursor according to the coordinate signal.
Thus, the vehicle operation apparatus 1 (the display control part 30) determines whether the cursor operation or the flick operation is performed based on the moving speed of the operation finger on the operating surface of the touch pad 10.
Next, the above-described method of determining the determination threshold ThV by the vehicle operation apparatus 1 (the display control part 30) will be described.
First, one example of the method of determining the determination threshold ThV by the display control part 30 when the display device 20 is displaying the map screen page will be described.
As described above, the vehicle operation apparatus 1 (the display control part 30) according to the present embodiment changes the determination threshold ThV depending on the position of the cursor on the operating screen page. In the example of
Thereby, the display control part 30 can positively determine the intentionally performed flick operation as the flick operation while avoiding erroneously determining the cursor operation as the flick operation. That is, when the pointer 80 is in the central area A11 of the map screen page, the cursor operation is likely to be performed more than the flick operation. Therefore, by setting the determination threshold ThV to be high, the display control part 30 can avoid erroneously determining the cursor operation, performed relatively quickly, as the flick operation. On the other hand, when the pointer 80 is in the outer area of the map screen page, this state is a state occurring after the pointer 80 is moved toward the outer area. Therefore, scrolling by the flick operation becomes likely to be performed. Thus, by setting the determination threshold ThV lower than that of the central area A11, the display control part 30 comes to more easily determine the performed operation as the flick operation and can positively determine the intentionally performed flick operation as the flick operation.
In this example, the display control part 30 changes the determination threshold ThV to reduce it as the position of the cursor becomes farther away from the center of the map screen page in two stages, i.e., the central area A11 and the outer area. However, it is also possible that the display control part 30 changes the determination threshold ThV more finely. At this time, it is also possible to change the determination threshold ThV continuously or in a step-by-step manner.
Next, another method of determining the determination threshold ThV by the display control part 30 when the display device 20 is displaying the map screen page will be described. In this example, display control part 30 changes the determination threshold ThV based on, in addition to the position of the cursor on the operating screen page, the moving direction D of the operation finger on the operating surface of the touch pad 10.
In this example, the display control part 30 determines (changes) the determination threshold ThV based on the direction of the pointer 80 from the center of the map screen page and the moving direction D of the operation finger. Specifically, the display control part 30 reduces the determination threshold Thy, i.e., comes to more easily determine the performed operation as the flick operation, when the direction of the pointer 80 from the center of the map screen page is approximately the same as the moving direction D of the operation finger, or the difference in direction therebetween falls within a predetermined range, and also, the position of the pointer 80 is in the outer area of the map screen page, in comparison to the case of the printer being in the central area A11.
As shown in
Thus, the display control part 30 can positively determine the intentionally performed flick operation as the flick operation while avoiding erroneously determining the cursor operation as the flick operation. That is, when the pointer 80 is in the outer area of the map screen page and also the operation finger is moved toward the outer part of the map screen page, this operation is further likely to be an operation for “map scrolling” (the flick operation). That is, when the position of the pointer 80 is in the outer area of the map screen page and also the direction of the pointer 80 from the center of the map screen page is the same as the moving direction D of the operation finger or the difference in direction therebetween falls within a predetermined range, this operation is further likely to be an operation for “map scrolling” (the flick operation). Conversely, even when the position of the pointer 80 is in the outer area of the map screen page, if the difference in direction between the direction of the position of the pointer 80 from the center of the map screen page and the moving direction D of the operation finger is out of the predetermined range, this operation may also be the cursor operation. Thus, the display control part 30 can positively avoid erroneously determining the cursor operation as the flick operation while positively determining the intentionally performed flick operation as the flick operation by setting the determination threshold ThV smaller when the direction of the pointer 80 from the center of the map screen page is the same as the moving direction D of the operation finger or the difference in direction therebetween falls within a predetermined range.
In this example, first, the display control part 30 sets the determination threshold ThV to be smaller, i.e., makes it easier to determine the performed operation as the flick operation when the moving direction D of the operation finger is the upward direction than the downward direction. For example, in
Note that in this example, the determination threshold ThV is changed (reduced) when the pointer 80 is in the outer area. However, it is also possible that, in an easier manner, the determination threshold ThV is changed only based on the relationship between the direction of the pointer 80 from the center of the map screen page and the moving direction D of the operation finger. Specifically, it is possible that when the direction of the pointer 80 from the center of the map screen page is approximately the same as the moving direction D of the operation finger, or the difference in direction therebetween falls within a predetermined range, the display control part 30 reduces the determination threshold ThV so as to make it easier to determine the performed operation as the flick operation. Also by this way, the display control part can positively determine the intentionally performed flick operation as the flick operation while avoiding erroneously determining the cursor operation as the flick operation. That is, a case where the direction of the pointer 80 from the center of the map screen page is approximately the same as the moving direction D of the operation finger or the difference in direction therebetween falls within a predetermined range is a case where the operation finger is moved toward an outer part of the map screen page. It is thought that such an operation that the operation finger is moved toward an outer part of the map screen page is more likely to be the flick operation than such an operation that the operation finger is moved toward an inner part of the map screen page. Therefore, by reducing the determination threshold ThV and making it possible to more easily determine the performed operation as the flick operation, the display control part 30 can positively determine the intentionally performed flick operation as the flick operation. Conversely, the display control part 30 can avoid erroneously determining the cursor operation as the flick operation for such an operation that the operation finger is moved toward an inner part of the map screen page by previously setting the determination threshold ThV higher.
Also in this case, in the same manner as that in the above-described example, the display control part 30 changes the determination threshold ThV to reduce it as the position of the cursor becomes farther away from the center of the map screen page in two stages, i.e., the central area A11 and the outer area. However, it is also possible that the display control part 30 changes the determination threshold ThV more finely. At this time, it is possible to change the determination threshold ThV continuously or in a step-by-step manner.
The above-described methods of determining the determination threshold ThV have been described using the map screen page allowing scrolling in all directions on the screen. However, it is also possible that the display control part 30 determines (changes) the determination threshold ThV in the same manner also in a case where the scrolling direction is limited to predetermined axis directions such as “list scrolling”.
For example,
In this example, in the same way as that in the above-described example of the map screen page, the display control part 30 reduces the determination threshold ThV when the position of the cursor 82 is included in the outer area of the track selecting screen page (i.e., the lower area A0 or the upper area A2), in comparison to the case of it being included in the central area A1 of the track selecting screen page. That is, when the position of the cursor 82 is included in the outer area of the track selecting screen page, the display control part 30 more easily determines the performed operation as the flick operation in comparison to the case of it being included in the central area A1. In other words, the display control part 30 changes the determination threshold ThV so as to more easily determine the performed operation as the flick operation as the position of the cursor in the operating screen page becomes farther away from the center of the operating screen page. That is, the display control part 30 reduces the determination threshold ThV as the position of the cursor becomes farther away from the center of the operating screen page.
As shown in
Note that also in a case where the list strolling directions are the leftward and rightward directions, the same method of determining the determination threshold ThV can be applied as the above-described example where the list strolling directions are the upward and downward directions. Further, in the above-described example, the display control part 30 changes the determination threshold ThV to reduce it as the position of the cursor becomes farther away from the center of the track selecting screen page in two stages, i.e., the central area A1 and the outer area. However, it is also possible that the display control part 30 changes the determination threshold ThV more finely. At this time, it is possible to change the determination threshold ThV continuously or in a step-by-step manner.
In this example, in the same manner as the above-described other example using the map screen page, the display control part 30 determines (changes) the determination threshold ThV based on the direction of the cursor 82 from the center of the track selecting screen page and the moving direction D of the operation finger. Specifically, the display control part 30 reduces the determination threshold ThV, i.e., comes to more easily determine the performed operation as the flick operation, when the direction of the cursor 82 from the center of the track selecting screen page is approximately the same as the moving direction D of the operation finger, or the difference in direction therebetween falls within a predetermined range, and also, the position of the cursor 82 is in the outer area of the track selecting screen page, in comparison to the case of the cursor 82 being in the central area A1.
As shown in
Thereby, in the same way as the above-described other example using the map screen page, the display control part 30 can positively determine the intentionally performed flick operation as the flick operation while positively avoiding erroneously determining the cursor operation as the flick operation.
In this example, in the same way as the above-described other example using the map screen page, first, the display control part 30 sets the determination threshold ThV to be smaller, i.e., makes it easier to determine the performed operation as the flick operation when the moving direction D of the operation finger is the downward direction rather than the upward direction. For example, in
Note that in this example, the determination threshold ThV is changed (reduced) when the cursor 82 is in the outer area. However, it is also possible that, in an easier manner, the determination threshold ThV is changed only based on the relationship between the direction of the cursor 82 from the center of the track selecting screen page and the moving direction D of the operation finger. Specifically, it is possible that when the direction of the pointer 80 from the center of the track selecting screen page is approximately the same as the moving direction D of the operation finger, or the difference in direction therebetween falls within a predetermined range, the display control part 30 reduces the determination threshold ThV so as to make it easier to determine the performed operation as the flick operation. Also by this way, in the same way as the above-described other example using the map screen page, the display control part can determine the intentionally performed flick operation as the flick operation while avoiding erroneously determining the cursor operation as the flick operation.
Note that also in a case where the list strolling directions are the leftward and rightward directions, the same method of determining the determination threshold ThV can be applied. Also, in this case, the display control part 30 changes the determination threshold ThV to reduce it as the position of the cursor becomes farther away from the center of the track selecting screen page in two stages, i.e., the central area A1 and the outer area. However, it is also possible that the display control part 30 changes the determination threshold ThV more finely. At this time, it is possible to change the determination threshold ThV continuously or in a step-by-step manner.
Thus, the vehicle operation apparatus has been described by the embodiment. However, the present invention is not limited to the specific embodiment, and variations, modifications and/or replacements can be made in embodiments without departing from the scope of the present invention claimed.
For example, in the vehicle operation apparatus 1 according to the present embodiment, the display device 20 is remotely placed away from the touch pad 10 that is an operating part. However, the touch pad 10 and the display device 20 can be configured integrally. That is, the display device 20 can be configured in a form of a touch panel display device that allows a touch operation, and an operation can be performed on the operating screen page through an operation performed on the touch panel in the display device 20. Also in this case, the same advantageous effects are acquired as those of the above-described embodiment.
Thus, according to the embodiment, it is possible to provide a vehicle operation apparatus by which, for example, in a case where the cursor operation and the flick operation are performed on a touch panel by one finger, it is possible to positively determine the flick operation that is performed intentionally as the flick operation while preventing the cursor operation from being erroneously determined as the flick operation.
The present application is based on and claims the benefit of priority of Japanese Priority Application No. 2014-046609, filed on Mar. 10, 2014, the entire contents of which are hereby incorporated herein by reference.
Number | Date | Country | Kind |
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2014-046609 | Mar 2014 | JP | national |