CN110895441A - Progress bar control method and device, electronic device and medium - Google Patents

Abstract

The embodiment of the invention discloses a progress bar control method, a progress bar control device, an electronic device and a storage medium, wherein the method is applied to a terminal and comprises the following steps: acquiring a pressure value borne on a terminal display screen; and correspondingly adjusting the precision of the progress bar according to the pressure value.

Description

Progress bar control method and device, electronic device and medium

Technical Field

The present invention relates to the field of electronic device applications, and in particular, to a method and an apparatus for controlling a progress bar, an electronic apparatus, and a storage medium.

Background

The progress bar is a linear rapid regulation and control and display tool for rapidly controlling vector characteristics such as time or space, and is used for time progress of videos, time precision of music, page numbers of books and the like. It can be seen through the progress bar that the current time or page number is at the position of the total time and page number. In the related art, a user slides a slider on a progress bar or clicks a corresponding position on the progress bar, so that a current interface jumps to a corresponding time interface or page. Because the width of the mobile terminal, such as a mobile phone and a tablet, is narrow, the length of the precision bar is limited, and a user cannot accurately slide the progress bar slider to move the progress bar slider to a target position or a position near the target position in the process of adjusting the progress bar.

Disclosure of Invention

The embodiment of the invention discloses a progress bar control method, which mainly solves the problem that a progress bar sliding block cannot be accurately slid to move to a target position or a position near the target position due to the limited length of a terminal.

An embodiment of the invention discloses a progress bar control method, which is applied to a terminal and comprises the following steps: acquiring a pressure value borne on a terminal display screen; and correspondingly adjusting the precision of the progress bar according to the pressure value.

Another embodiment of the present invention discloses a progress bar control device, including: the pressure value acquisition module is used for acquiring a pressure value borne on a terminal display screen; and the adjusting module is used for correspondingly adjusting the progress bar according to the pressure value.

Yet another embodiment of the present invention discloses an electronic device, including: a memory and a processor for storing a data processing program which when executed by the processor implements the steps of a progress bar control method.

Yet another embodiment of the invention discloses a storage medium having a computer program stored therein, wherein the computer program is arranged to perform the steps of a progress bar control method when run.

The method and the device mainly control the adjustment of the precision of the progress bar through the pressure value applied by the user, and the precision of the progress bar is gradually increased along with the increase of the pressure value. After the progress of the precision bar is amplified, a user drags the progress bar slider to solve the problem that the progress bar slider cannot be accurately slid to move to a target position or a position near the target position due to the fact that the length of the terminal is limited.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the invention and together with the description serve to explain the invention without limiting the invention. In the drawings:

FIG. 1 is a hardware block diagram of an electronic device implementing precision bar control according to an embodiment of the present invention;

FIG. 2 is a flow chart of a progress bar control method of an embodiment of the invention;

FIG. 3 is a schematic diagram of an electronic device according to an embodiment of the invention;

FIG. 4 is a functional block diagram of the memory of FIG. 1 according to an embodiment of the present invention;

FIG. 5 is a flow chart of another method of control of a progress bar according to an embodiment of the present invention;

fig. 6 is a structural diagram of a progressive bar control apparatus according to an embodiment of the present invention.

Detailed Description

The invention will be described in detail hereinafter with reference to the accompanying drawings in conjunction with embodiments. It should be noted that the embodiments and features of the embodiments in the present application may be combined with each other without conflict.

It should be noted that the terms "first," "second," and the like in the description and claims of the present invention and in the drawings described above are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order.

In the related art, a user slides a slider on a progress bar or clicks a corresponding position on the progress bar, so that a current interface jumps to a corresponding time interface or page. When a slider on the progress bar is slid or a corresponding position on the progress bar is clicked, it is difficult to accurately find a corresponding time interface or page. This is clearly more so in a mobile phone. Such as: a 120 minute movie, since the length of the mobile phone is only ten and a few centimeters, assuming 15 centimeters (150mm), the progress bar is at most 150 mm. The time interval represented by 1mm at this time was 0.8 minutes (48 seconds). Therefore, if the user wants to watch a 1:07:48 movie page, it is difficult to accurately move the slider to a position corresponding to or near the 1:07:48 second. On the other hand, since it is difficult to grasp fine movements of a human finger during the movement, the slight movement is a few millimeters, and the fine movements are difficult to be detected by the terminal.

Example 1

Fig. 1 is a hardware structure diagram of an electronic device implementing a progress bar control according to an embodiment of the present invention. The electronic device 1 may be: mobile terminal, computer or any suitable device. As shown in fig. 1, the electronic device 1 may include: displacement sensor 11, display screen 15, pressure sensor 12, memory 13 and processor 14. The memory 13 may be used to store computer programs, for example, application software programs and modules, such as computer programs corresponding to the progress bar method in the embodiment of the present invention, and the processor 14 may execute various functional applications and data processing by running the programs stored in the memory 13, that is, implement the above method.

The memory 13 may include high speed random access memory, and may also include non-volatile memory, such as one or more magnetic storage devices, flash memory, or other non-volatile solid state memory. In some examples, the memory 13 may further include storage devices remotely located from the processor 14, which may be connected to the electronic device 1 via a network. Examples of such networks include, but are not limited to, the internet, intranets, local area networks, mobile communication networks, and combinations thereof.

In this embodiment, the pressure sensor 12 may acquire a pressure value operated by the user on the display screen 15. The processor 14 executes the program instructions of the progress bar control of the present invention stored in the memory 13, and correspondingly adjusts the accuracy of the progress bar according to the pressure value on the display screen 15 acquired by the pressure sensor 12. The displacement sensor 11 may acquire moving position information of a slider of the progress bar (e.g., moving position information generated by a user adjusting the slider), and the processor 14 may control the display screen 15 to display content corresponding to the moving position information according to the moving position information.

Example 2

Fig. 2 is a flowchart of a progress bar control method according to an embodiment of the present invention.

Step S201, acquiring a pressure value borne by the display screen 15;

the pressure sensor 12 can detect the pressure value acting on the display screen 15. Here, the pressure area in which the pressure value is detected may be a specific area of the display screen. In one embodiment, the pressure area includes a partial area of a progress bar. As shown in the schematic diagram of fig. 3, reference numeral 17 denotes a progress bar; reference numeral 16 denotes a slider. When the user presses the display screen 15 of the electronic device 1 with a finger, the area where the finger contacts the display screen is the pressing area, and the pressing area covers a part of the progress bar. Pressing the progress bar with a certain pressure can avoid the conflict with other shortcuts, such as clicking the display screen to show that such shortcuts are paused. Of course, the pressure area is not limited to the illustrated example, and may be any area of the display screen without causing a conflict with other shortcuts or being able to resolve the conflict.

Step S202, judging whether the pressure value is not less than a first pressure threshold value.

Step S203, acquiring a duration that the pressure value exceeds the first pressure threshold value when the pressure value is not less than the first pressure threshold value. Wherein the continuous time here indicates that the pressure values detected by the pressure sensor 12 are not less than the first pressure threshold value in the time period.

Step S204, judging whether the continuous time exceeds a preset time threshold value. Here, the time threshold may be set to a fixed value, and further, the time threshold may be preset according to the habit and the preference of the user. The time threshold is set as a judgment condition in order to distinguish from the existing shortcut operation. In the related art, there is a technique of pausing display of content by clicking a display screen. For example, when a movie is played, clicking the screen indicates pausing the play. When the continuous time exceeds the time threshold, the user can be considered to adjust the precision of the progress bar at the moment.

Step S205, acquiring starting point information, ending point information, and current slider position information of the progress bar when the continuous time exceeds the time threshold. In an embodiment, when the progress bar represents time information, the start point information, the end point information, and the current slider position information may all be time information. When the progress bar indicates that the length information indicates the length information, the start point information, the end point information, and the current slider position information may be all length information, for example, when the progress bar indicates the number of pages of a book, the start point information, the end point information, and the current slider position information are all page number information.

And step S206, calculating the starting point information and the end point information of the progress bar after the precision adjustment.

In this embodiment, the step may further include setting a second pressure threshold, and when the pressure value exceeds the second threshold, considering that the operation is wrong, and stopping adjusting the progress of the progress bar. This prevents damage to the display screen caused by high pressure values.

In one embodiment, the start point information Ts1 and the end point information Te1 after the progress bar adjustment can be represented as follows:

Ts1＝Ts+(Tn-Ts)(F-F1)/(F2-F1)；

Te1＝Te-(Te-Tn)(F-F1)/(F2-F1)；

wherein: ts is starting point information before the progress bar is adjusted; te is terminal point information before the progress bar is adjusted; ts1 is the starting point information after the progress bar is adjusted; te1 is the terminal point information after the progress bar is adjusted; tn is the position information of the current slide block of the progress bar; f is the pressure value; f1 is the first pressure threshold; f2 is the second pressure threshold.

The adjustment of the precision of the whole progress bar is a dynamic process, and the starting point information and the end point information of the progress bar are continuously adjusted along with the change of the pressure value.

In another embodiment, during the process of adjusting the precision of the progress bar, the position information corresponding to the starting point information and the end point information is displayed at the corresponding position in real time. For example: when the time represented by the start point information is 1:21:12(1 hour 21 minutes 12 seconds), the time information 1:21:12 is displayed below the position of the start point of the progress bar at this time.

For the dynamic display of the progress bar precision adjustment, a user can intuitively judge whether the precision of the progress bar meets the requirement or not, so that whether the progress bar needs to be stopped to be adjusted or not is determined.

In one embodiment, the adjusted starting point information gradually moves towards the direction close to the slider along with the increase of the pressure value, and when the pressure value decreases, the starting point information gradually moves towards the direction away from the slider along with the decrease of the pressure value. And when the pressure value is reduced, the starting point information is gradually moved in the direction departing from the slide block along with the reduction of the pressure value. That is, the adjusted starting point information may be moved in the slider direction or in the direction away from the slider.

In another embodiment, the adjusted starting point information is gradually moved towards the direction of the slider along with the increase of the pressure value, and when the pressure is reduced, the starting point information is kept unchanged. And gradually moving the adjusted terminal information to the direction of the sliding block along with the increase of the pressure value, and keeping the adjusted terminal information unchanged when the pressure is reduced.

Step S207, calculating the pressure value deviation within a preset time interval.

Here, the pressure value deviation is a real-time detection process, for example: and the time interval is 2 seconds, the current time is 12 hours, 01 minutes and 02 seconds, counting the pressure values in the time period from 12 hours, 01 minutes and 0 seconds to 12 hours, 01 minutes and 02 seconds, calculating the average value of the pressure values, and judging that the pressure values are 12 hours from 01 minutes and 0 seconds to 12 hours, 01 minutes and 02 seconds, wherein the maximum value/minimum value of the pressure values and the maximum value of the difference between the average values are used as the deviation of the pressure values. Similarly, if the current time is 12 hours 01 minutes 03 seconds, counting pressure values in a time period from 12 hours 01 minutes 1 seconds to 12 hours 01 minutes 03 seconds, calculating an average value of the pressure values, and then judging that the pressure values are 12 hours 01 minutes 1 seconds to 12 hours 01 minutes 03 seconds, wherein the maximum value/minimum value of the pressure values and the maximum value of the difference between the average values are used as pressure value deviations. The average value of the pressure values may vary over time, as may the corresponding pressure value deviations.

And step S208, judging whether the pressure value deviation does not exceed a preset deviation.

And when the deviation of the pressure value does not exceed the preset deviation, stopping adjusting the precision of the progress bar. If the deviation of the pressure value does not exceed the preset deviation, which indicates that the force applied to the display screen 15 by the user fluctuates within a small range within the preset time interval and remains substantially unchanged, it may be determined that the user has adjusted the progress bar at this time, and the adjustment of the progress bar is finished, where the finishing of the adjustment of the progress bar means that the start point information and the end point information of the progress bar remain unchanged after the adjustment. And when the pressure value deviation exceeds a preset deviation, the terminal acquires the pressure applied on a display screen by a user and adjusts the precision of the progress bar according to the pressure.

And when the detected pressure value deviation does not exceed the preset deviation within the preset time interval, indicating that the user keeps the pressure of the existing pressing display screen unchanged. Since the user keeps the pressing pressure constant, the pressure value is hardly maintained at the same value, but is less fluctuated. Therefore, the preset deviation is set, and the user can be considered to keep the pressing pressure unchanged as long as the fluctuation deviation of the pressure value does not exceed the preset deviation, so that the operability and the user experience are improved.

Step S209, when the pressure value deviation does not exceed the preset deviation, acquiring the target position information of the precision bar sliding block;

and when the adjusted starting point information and the adjusted end point information both move towards the sliding block, indicating the precision of the progress bar. After the precision of the progress bar is enlarged, a user drags the slider or clicks the progress bar to stop the slider at the target position of the progress bar. The target position information is the target position information after the sliding block moves. It should be noted that, when the display screen 15 displays the content of any other image or signal that changes continuously with time, such as a video file or an audio file, the target position information refers to the current time information corresponding to the slider on the current progress bar; when other spatially continuously changing images such as an electronic book, a photo album, and the like are displayed on the display screen 15, the target position information refers to current page number information corresponding to the slider on the current progress bar.

When the slider or the progress bar is dragged, the target position information may be displayed below the slider, may be displayed above the slider, or may be displayed at any suitable place around the slider, so that the user can know the current adjustment condition. As shown in fig. 3, the target position information is displayed below the slider, and when the user drags the slider to 1:01:09, the corresponding time is displayed below the slider, so that the user can adjust the slider conveniently, and the adjustment speed and accuracy are improved.

And step S210, displaying corresponding display content according to the target position information. In one embodiment, according to the target position information, the electronic device 1 displays a display content corresponding to the target position information. For example: when the display screen 15 displays a video, an electronic book, a photo album, and other files that need to be viewed on the display screen 15, a video frame image corresponding to the current target position information, or an electronic book page corresponding to the current target position information, or a photo corresponding to the current target position information is displayed on the display screen 15. When the audio file is displayed on the display screen 15, the electronic device 1 controls the currently played audio to jump to the audio content corresponding to the target position information.

According to the scheme, the pressure value received by the display screen 15 is detected to adjust the progress bar and adjust the precision of the progress bar. The setting of the first pressure threshold and the time threshold is used as a judgment condition to avoid misoperation, such as: the display screen 15 is accidentally touched by hand. And dynamically adjusting the starting information and the end information of the progress bar through the pressure value. The user can intuitively judge whether the precision of the progress bar meets the requirement or not, so that whether the progress bar needs to be stopped to be adjusted or not is determined. After the precision of the progress bar is enlarged, a user clicks the dragging slider or clicks the progress bar to stop the slider at the target position of the progress bar. Thereby reach accurate adjustment progress bar slider.

Example 3

Fig. 4 is a functional block diagram of the memory 13 in fig. 1 according to an embodiment of the invention. The memory 13 includes: the pressure value determination module comprises a pressure value acquisition module 131, a first judgment module 132, a continuous time module 133, an information module 134, a first calculation module 135, a second calculation module 136, a second judgment module 137 and a target position determination module 138.

The pressure value obtaining module 131 is configured to obtain a pressure value received by the display screen 15. In an embodiment, when a progress bar is displayed in the current interface, if a touch operation is received on the display screen, the pressure value obtaining module 131 starts to detect the pressure value received by the display screen 15 in real time. The pressure area where the pressure value is acquired may be a specific area of the display screen. In one embodiment, the pressure area includes a partial area of a progress bar. As shown in the schematic diagram of fig. 3, reference numeral 17 denotes a progress bar; reference numeral 16 denotes a slider. When the user presses the display screen 15 with a finger, the area where the finger contacts the display screen is the pressing area, and the pressing area is to cover a part of the progress bar. When the user presses the display screen 15 with a finger, the finger presses the progress bar and applies a certain pressure. This has the advantage that it is possible to avoid collision of other shortcuts, such as clicking on the display screen to indicate that such a shortcut is paused. Of course, the pressure area is not limited to the illustrated example, and may be any area of the display screen without causing a conflict with other shortcuts or being able to resolve the conflict.

The pressure value obtaining module 131 may be further configured to send the pressure value to the first determining module 132. The first determining module 132 determines whether the pressure value is not less than a first pressure threshold. When the pressure value is determined to be not less than the first pressure threshold, the first determining module 132 sends the determination result or the control command to the continuous time module 133.

The continuous time module 133 is configured to identify a continuous time during which the pressure value exceeds the first pressure threshold.

Here, the continuous time indicates that the pressure values detected by the pressure sensor 12 are not less than the first pressure threshold value in the time period.

The continuous time module 133 may be further configured to determine whether the continuous time exceeds a time threshold. When the continuous time exceeds the time threshold, the continuous time module 133 sends a control command to the information module 134.

The time threshold is set as a judgment condition in order to distinguish from the existing shortcut operation. In the related art, there is a technique of pausing display of content by clicking a display screen. For example, when a movie is played, clicking the screen indicates pausing the play. When the continuous time exceeds the time threshold, the user can be considered to adjust the progress bar at the moment.

The information module 134 is configured to obtain starting point information, ending point information, and current slider position information of the progress bar. And when the progress bar represents time information, the starting point information, the end point information and the current slide block position information are all time information. When the progress bar indicates that the length information indicates the length information, the starting point information, the end point information and the current slider position information are all length information, for example, when the progress bar indicates the number of pages of a book, the starting point information, the end point information and the current slider position information are all page number information.

The first calculating module 135 is configured to read the starting point information and the ending point information of the progress bar and the current slider position information obtained by the information module 134, so as to perform related calculation according to the above information.

The first calculating module 135 is further configured to set a second pressure threshold, and when the pressure value exceeds the second pressure threshold, it is determined that the operation is faulty, and the process is terminated. This prevents damage to the display screen caused by high pressure values.

The first calculating module 135 is further configured to calculate start point information and end point information of the adjusted progress bar. The adjusted start point information Ts1 and end point information Te1 of the progress bar are represented as follows:

Ts1＝Ts+(Tn-Ts)(F-F1)/(F2-F1)；

Te1＝Te-(Te-Tn)(F-F1)/(F2-F1)；

wherein: ts is starting point information before the progress bar is adjusted; te is terminal point information before the progress bar is adjusted; ts1 is the starting point information after the progress bar is adjusted; te1 is the terminal point information after the progress bar is adjusted; tn is the position information of the current slide block of the progress bar; f is the pressure value; f1 is the first pressure threshold; f2 is the second pressure threshold.

The adjustment of the whole progress bar is a dynamic process, and the starting point information and the end point information of the progress bar are continuously adjusted along with the change of the pressure value.

In another embodiment, during the process of adjusting the precision of the progress bar, the position information corresponding to the starting point information and the end point information is displayed at the corresponding position in real time. For example: when the time represented by the start point information is 1:21:12(1 hour 21 minutes 12 seconds), the time information 1:21:12 is displayed below the position of the start point of the progress bar at this time.

For the dynamic display of the progress bar precision adjustment, a user can intuitively judge whether the precision of the progress bar meets the requirement or not, so that whether the progress bar needs to be stopped to be adjusted or not is determined.

In one embodiment, the adjusted starting point information gradually moves towards the direction close to the slider along with the increase of the pressure value, and when the pressure value decreases, the starting point information gradually moves towards the direction away from the slider along with the decrease of the pressure value. And when the pressure value is reduced, the starting point information is gradually moved in the direction departing from the slide block along with the reduction of the pressure value. That is, the adjusted starting point information may be moved in the slider direction or in the direction away from the slider.

In another embodiment, the adjusted starting point information is gradually moved towards the direction of the slider along with the increase of the pressure value, and when the pressure is reduced, the starting point information is kept unchanged. And gradually moving the adjusted terminal information to the direction of the sliding block along with the increase of the pressure value, and keeping the adjusted terminal information unchanged when the pressure is reduced.

The second calculating module 136 is configured to calculate the pressure value deviation within a preset time interval.

The second calculating module 136 may further send the pressure value deviation to a second judging module 137, where the second judging module 137 is configured to judge whether the pressure value deviation does not exceed a preset deviation.

When the pressure value deviation does not exceed the preset deviation, it indicates that the force applied by the user on the display screen 15 fluctuates within a small range within the preset time interval and remains substantially unchanged, and it can be considered that the user has adjusted the progress bar at this time. Here, the ending of the progress bar adjustment means that the adjusted positions of the start point information and the end point information of the progress bar are maintained.

And when the detected pressure value deviation does not exceed the preset deviation within the preset time interval, indicating that the user keeps the pressure of the existing pressing display screen unchanged. Since the user keeps the pressing pressure constant, the pressure value is hardly maintained at the same value, but is less fluctuated. A threshold deviation is thus set, and the user can be considered to keep the pressing pressure unchanged as long as the fluctuation deviation of the pressure value does not exceed the preset deviation.

The target position determining module 138 is configured to obtain target position information of the progress bar slider.

And when the adjusted starting point information and the adjusted end point information both move towards the sliding block, indicating the precision of the progress bar. After the precision of the progress bar is enlarged, a user drags the slider or clicks the progress bar to stop the slider at the target position of the progress bar. The target position information is the target position information after the sliding block moves.

And when the slider or the progress bar is dragged, the target position information is displayed below the slider. As shown in the schematic diagram 3, when the user drags the slider to 1:01:09, the corresponding time is displayed below the slider, so that the user can conveniently adjust the slider, and the adjustment speed and accuracy are improved.

The target position determining module 138 sends the target position information of the slider to the display module 139, and the display module 139 displays the display content corresponding to the target position information on the display screen 15 according to the target position information.

According to the scheme, the pressure value received by the display screen 15 is detected to adjust the progress bar and adjust the precision of the progress bar. The setting of the first pressure threshold and the time threshold is used as a judgment condition to avoid misoperation, such as: the display screen 15 is accidentally touched by hand. And dynamically adjusting the starting information and the end information of the progress bar through the pressure value. The user can intuitively judge whether the precision of the progress bar meets the requirement or not, so that whether the progress bar needs to be stopped to be adjusted or not is determined. After the precision of the progress bar is enlarged, a user clicks the dragging slider or clicks the progress bar to stop the slider at the target position of the progress bar. Thereby reach accurate adjustment progress bar slider.

Example 4.

Fig. 5 is a flowchart illustrating another method for controlling a progress bar according to an embodiment of the present invention. As shown in fig. 5, the progress bar control method includes:

step S401, acquiring a pressure value received on the terminal display screen 15.

The pressure value applied by the user on the terminal display screen 15 is detected by the pressure sensor 12. Here, the pressure area in which the pressure value is detected may be a specific area of the display screen. In one embodiment, the pressure area may be a partial area including a progress bar. As shown in the schematic diagram of fig. 3, reference numeral 17 denotes a progress bar; reference numeral 16 denotes a slider. When the user presses the display screen 15 with a finger, the area where the finger contacts the display screen is the pressing area, and the pressing area is to cover a part of the progress bar. Pressing the progress bar with a certain pressure can avoid the conflict with other shortcuts, such as clicking the display screen to show that such shortcuts are paused. Of course, the pressure area is not limited to the illustrated example, and may be any area of the display screen without causing a conflict with other shortcuts or being able to resolve the conflict.

And S402, correspondingly adjusting the precision of the progress bar according to the pressure value.

In one embodiment, before said adjusting said progress bar according to said pressure value further comprises:

presetting a first pressure threshold; when the pressure value is not smaller than a first pressure threshold value, acquiring the continuous time of the pressure value exceeding the first threshold value; and when the continuous time exceeds a time threshold, adjusting the progress bar according to the pressure value.

Wherein the continuous time here indicates that the pressure values detected by the pressure sensor 12 are not less than the first pressure threshold value in the time period.

In yet another embodiment, said adjusting said progress bar according to said pressure value comprises: presetting a second pressure threshold; and under the condition that the pressure value exceeds a preset second threshold value, determining misoperation, and stopping adjusting the precision of the progress bar. This prevents damage to the display screen caused by high pressure values.

In another embodiment, before adjusting the accuracy of the progress bar according to the pressure value, the method further includes: acquiring starting point information before the progress bar is adjusted, end point information before the progress bar is adjusted and position information of a current sliding block of the progress bar; and determining the starting point information and the end point information after the progress bar is adjusted according to the starting point information before the progress bar is adjusted, the end point information before the progress bar is adjusted and the position information of the current sliding block of the progress bar.

The starting point information Ts1 is Ts + (Tn-Ts) (F-F1)/(F2-F1) after the precision of the progress bar is adjusted;

the end point information Te1 after the progress bar precision adjustment is Te- (Te-Tn) (F-F1)/(F2-F1);

wherein: ts is starting point information before the progress bar is adjusted in precision; te is terminal point information before the precision of the progress bar is adjusted; ts1 is the starting point information after the precision of the progress bar is adjusted; te1 is the terminal point information after the precision of the progress bar is adjusted; tn is the position information of the current slide block of the progress bar; f is the pressure value; f1 is the first pressure threshold; f2 is the second pressure threshold.

The adjustment of the precision of the whole progress bar is a dynamic process, and the starting point information and the end point information of the progress bar are continuously adjusted along with the change of the pressure value.

In another embodiment, during the process of adjusting the precision of the progress bar, the position information corresponding to the starting point information and the end point information is displayed at the corresponding position in real time. For example: when the time represented by the start point information is 1:21:12(1 hour 21 minutes 12 seconds), the time information 1:21:12 is displayed below the position of the start point of the progress bar at this time.

For the dynamic display of the progress bar adjustment, a user can intuitively judge whether the precision of the progress bar meets the requirement or not, so as to determine whether the adjustment of the progress bar needs to be stopped or not.

In one embodiment, the adjusted starting point information gradually moves towards the direction close to the slider along with the increase of the pressure value, and when the pressure value decreases, the starting point information gradually moves towards the direction away from the slider along with the decrease of the pressure value. And when the pressure value is reduced, the starting point information is gradually moved in the direction departing from the slide block along with the reduction of the pressure value. That is, the adjusted starting point information may be moved in the slider direction or in the direction away from the slider.

In another embodiment, the adjusted starting point information is gradually moved towards the direction of the slider along with the increase of the pressure value, and when the pressure is reduced, the starting point information is kept unchanged. And gradually moving the adjusted terminal information to the direction of the sliding block along with the increase of the pressure value, and keeping the adjusted terminal information unchanged when the pressure is reduced.

In yet another embodiment, further comprising: acquiring target position information of the progress bar sliding block; and displaying display content corresponding to the target position information.

And when the adjusted starting point information and the adjusted end point information both move towards the sliding block, indicating the precision of the progress bar. After the precision of the progress bar is enlarged, a user drags the slider or clicks the progress bar to stop the slider at the target position of the progress bar. The target position information is the target position information after the sliding block moves.

And when the slider or the progress bar is dragged, the target position information is displayed below the slider. As shown in the schematic diagram 3, when the user drags the slider to 1:01:09, the corresponding time is displayed below the slider, so that the user can conveniently adjust the slider, and the adjustment speed and accuracy are improved.

The display screen 15 displays corresponding display contents according to the target position information.

In another embodiment, before obtaining the target position information of the progress bar slider, determining when to stop adjusting the progress bar is further included. The method comprises the following steps: calculating the pressure value deviation within a preset time interval; and when the pressure value deviation is detected to be not more than the preset deviation within the preset time interval, acquiring the target position information of the progress bar sliding block.

If the deviation of the pressure value does not exceed the preset deviation, which indicates that the force applied to the display screen 15 by the user fluctuates within a small range within the preset time interval and remains substantially unchanged, it may be determined that the user has adjusted the progress bar at this time, and the adjustment of the progress bar is finished, where the finishing of the adjustment of the progress bar means that the start point information and the end point information of the progress bar remain unchanged after the adjustment.

And when the detected pressure value deviation does not exceed the preset deviation within the preset time interval, indicating that the user keeps the pressure of the existing pressing display screen unchanged. Since the user keeps the pressing pressure constant, the pressure value is hardly maintained at the same value, but is less fluctuated. A threshold deviation is thus set, and the user can be considered to keep the pressing pressure unchanged as long as the fluctuation deviation of the pressure value does not exceed the preset deviation.

According to the scheme, the pressure value received by the display screen 15 is detected to adjust the progress bar and adjust the precision of the progress bar. The setting of the first pressure threshold and the time threshold is used as a judgment condition to avoid misoperation, such as: the display screen 15 is accidentally touched by hand. And dynamically adjusting the starting information and the end information of the progress bar through the pressure value. The user can intuitively judge whether the precision of the progress bar meets the requirement or not, so that whether the progress bar needs to be stopped to be adjusted or not is determined. After the precision of the progress bar is enlarged, a user clicks the dragging slider or clicks the progress bar to stop the slider at the target position of the progress bar. Thereby reach accurate adjustment progress bar slider.

Example 5

Fig. 6 is a schematic structural diagram of another progressive bar control device according to an embodiment of the present invention. The method comprises the following steps: a pressure value acquisition module 51 and an adjustment module 52.

The pressure value acquisition module 51 is used for acquiring the pressure value borne by the display screen;

the pressure value applied by the user to the display screen 15 is detected by the pressure sensor 12. Here, the pressure area in which the pressure value is detected may be a specific area of the display screen. In one embodiment, the pressure area includes a partial area of a progress bar. As shown in the schematic diagram of fig. 3, reference numeral 17 denotes a progress bar; reference numeral 16 denotes a slider. When the user presses the display screen 15 with a finger, the area where the finger contacts the display screen is the pressing area, and the pressing area is to cover a part of the progress bar. Pressing the progress bar with a certain pressure can avoid the conflict with other shortcuts, such as clicking the display screen to show that such shortcuts are paused. Of course, the pressure area is not limited to the illustrated example, and may be any area of the display screen without causing a conflict with other shortcuts or being able to resolve the conflict.

An adjusting module 52, configured to adjust the progress bar according to the pressure value;

in one embodiment, the control device according to the progress bar further comprises:

the first pressure threshold setting module is used for presetting a first pressure threshold;

and the continuous time acquisition module is used for acquiring the continuous time of the pressure value exceeding the first threshold value under the condition that the pressure value is not less than the first pressure threshold value.

Wherein the continuous time here indicates that the pressure values detected by the pressure sensor 12 are not less than the first pressure threshold value in the time period.

The adjusting module 52 includes: a second pressure threshold setting unit 521, a progress bar information acquisition unit 522, and a calculation unit 523.

The second pressure threshold setting unit 521 is configured to preset a second pressure threshold; and when the pressure value exceeds a second threshold value, determining that the operation is wrong, and stopping adjusting the precision of the precision strip. This prevents damage to the display screen caused by high pressure values.

The progress bar information obtaining unit 522 is configured to obtain starting point information before the progress bar is adjusted, end point information before the progress bar is adjusted, and position information of a current slider of the progress bar;

the calculating unit 523 is configured to calculate start point information and end point information after the progress bar is adjusted, and the specific calculation is as follows:

the adjusted starting point information Ts1 ═ Ts + (Tn-Ts) (F-F1)/(F2-F1);

the adjusted end point information Te1 of the progress bar is Te- (Te-Tn) (F-F1)/(F2-F1);

wherein: ts is starting point information before the progress bar is adjusted; te is terminal point information before the progress bar is adjusted; ts1 is the starting point information after the progress bar is adjusted; te1 is the terminal point information after the progress bar is adjusted; tn is the position information of the current slide block of the progress bar; f is the pressure value; f1 is the first pressure threshold; f2 is the second pressure threshold.

The adjustment of the whole progress bar is a dynamic process, and the starting point information and the end point information of the progress bar are continuously adjusted along with the change of the pressure value.

In another embodiment, during the process of adjusting the precision of the progress bar, the position information corresponding to the starting point information and the end point information is displayed at the corresponding position in real time. For example: when the time represented by the start point information is 1:21:12(1 hour 21 minutes 12 seconds), the time information 1:21:12 is displayed below the position of the start point of the progress bar at this time.

For the dynamic display of the progress bar adjustment, a user can intuitively judge whether the precision of the progress bar meets the requirement or not, so as to determine whether the adjustment of the progress bar needs to be stopped or not.

In one embodiment, the adjusted starting point information gradually moves towards the direction close to the slider along with the increase of the pressure value, and when the pressure value decreases, the starting point information gradually moves towards the direction away from the slider along with the decrease of the pressure value. And when the pressure value is reduced, the starting point information is gradually moved in the direction departing from the slide block along with the reduction of the pressure value. That is, the adjusted starting point information may be moved in the slider direction or in the direction away from the slider.

In another embodiment, the adjusted starting point information is gradually moved towards the direction of the slider along with the increase of the pressure value, and when the pressure is reduced, the starting point information is kept unchanged. And gradually moving the adjusted terminal information to the direction of the sliding block along with the increase of the pressure value, and keeping the adjusted terminal information unchanged when the pressure is reduced.

In another embodiment, the apparatus of embodiment 5 further comprises: a target position information acquisition module 53 and a display module 54.

The target position information obtaining module 53 is configured to obtain target position information of the progress bar slider.

And when the adjusted starting point information and the adjusted end point information both move towards the sliding block, indicating the precision of the progress bar. After the precision of the progress bar is enlarged, a user drags the slider or clicks the progress bar to stop the slider at the target position of the progress bar. The target position information is the target position information after the sliding block moves.

And when the slider or the progress bar is dragged, the target position information is displayed below the slider. As shown in the schematic diagram 3, when the user drags the slider to 1:01:09, the corresponding time is displayed below the slider, so that the user can conveniently adjust the slider, and the adjustment speed and accuracy are improved.

The display module 54 is configured to display content corresponding to the target location information.

The display screen 15 displays corresponding display contents according to the target position information.

In another embodiment, the adjusting module 52 further comprises: a preset time interval unit 524 and a control unit 525.

The preset time interval unit 524 is used for presetting a time interval.

The control unit 525 is configured to calculate the pressure value deviation within a preset time interval, and when it is detected that the pressure value deviation does not exceed a preset deviation within the preset time interval, obtain target position information of the progress bar slider.

The pressure value deviation does not exceed the preset deviation, which indicates that the force applied on the display screen 15 by the user fluctuates within a small range within the preset time interval and remains substantially unchanged, it can be considered that the user has adjusted the accuracy of the progress bar at this time, and the adjustment of the accuracy of the progress bar is finished, where the finishing of the adjustment of the progress bar means that the start point information and the end point information of the progress bar remain unchanged after the adjustment.

And when the detected pressure value deviation does not exceed the preset deviation within the preset time interval, indicating that the user keeps the pressure of the existing pressing display screen unchanged. Since the user keeps the pressing pressure constant, the pressure value is hardly maintained at the same value, but is less fluctuated. A threshold deviation is thus set, and the user can be considered to keep the pressing pressure unchanged as long as the fluctuation deviation of the pressure value does not exceed the preset deviation.

According to the scheme, the pressure value received by the display screen 15 is detected to adjust the progress bar and adjust the precision of the progress bar. The setting of the first pressure threshold and the time threshold is used as a judgment condition to avoid misoperation, such as: the display screen 15 is accidentally touched by hand. And dynamically adjusting the starting information and the end information of the progress bar through the pressure value. The user can intuitively judge whether the precision of the progress bar meets the requirement or not, so that whether the progress bar needs to be stopped to be adjusted or not is determined. After the precision of the progress bar is enlarged, a user clicks the dragging slider or clicks the progress bar to stop the slider at the target position of the progress bar. Thereby reach accurate adjustment progress bar slider.

Example 6

Embodiments of the present invention also provide an electronic device, which may include a memory 12 having a computer program stored therein and a processor 13 configured to perform the steps in any of the above method embodiments by the computer program.

For specific examples in this embodiment, reference may be made to the examples described in the above embodiments and optional implementation manners, and details of this embodiment are not described herein again.

It will be apparent to those skilled in the art that the modules or steps of the present invention described above may be implemented by a general purpose computing device, they may be centralized on a single computing device or distributed across a network of multiple computing devices, and alternatively, they may be implemented by program code executable by a computing device, such that they may be stored in a storage device and executed by a computing device, and in some cases, the steps shown or described may be performed in an order different than that described herein, or they may be separately fabricated into individual integrated circuit modules, or multiple ones of them may be fabricated into a single integrated circuit module. Thus, the present invention is not limited to any specific combination of hardware and software.

Example 7

Embodiments of the present invention also provide a storage medium having a computer program stored therein, wherein the computer program is arranged to perform the steps of any of the above method embodiments when executed.

In this embodiment, the storage medium may include, but is not limited to: a U-disk, a Read-only Memory (ROM), a Random Access Memory (RAM), a removable hard disk, a magnetic disk, or an optical disk, which can store computer programs.

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the principle of the present invention should be included in the protection scope of the present invention.

Claims (16)

1. A progress bar control method is applied to a terminal, and is characterized by comprising the following steps:

acquiring a pressure value borne on a terminal display screen;

and correspondingly adjusting the precision of the progress bar according to the pressure value.

2. The method of claim 1, wherein before adjusting the accuracy of the progress bar according to the pressure value, further comprising:

when the pressure value is not smaller than a preset first pressure threshold value, acquiring the duration of the pressure value exceeding the first pressure threshold value;

and when the continuous time exceeds a preset time threshold, correspondingly adjusting the precision of the progress bar according to the pressure value.

3. The method of claim 1, further comprising:

and when the pressure value exceeds a preset second pressure threshold value, stopping adjusting the precision of the progress bar.

4. The method of claim 1, wherein before adjusting the accuracy of the progress bar according to the pressure value, comprising:

acquiring starting point information before the progress bar is adjusted, end point information before the progress bar is adjusted and position information of a current sliding block of the progress bar;

and determining the starting point information and the end point information after the progress bar is adjusted according to the starting point information before the progress bar is adjusted, the end point information before the progress bar is adjusted and the position information of the current sliding block of the progress bar.

5. The method of claim 4, wherein the determining the start point information and the end point information after the progress bar adjustment according to the start point information before the progress bar adjustment, the end point information before the progress bar adjustment, and the position information of the current slider of the progress bar comprises:

the starting point information Ts1 is Ts + (Tn-Ts) (F-F1)/(F2-F1) after the precision of the progress bar is adjusted;

the end point information Te1 after the progress bar precision adjustment is Te- (Te-Tn) (F-F1)/(F2-F1);

wherein: ts is starting point information before the precision of the progress bar is adjusted; te is terminal point information before the precision of the progress bar is adjusted; ts1 is the starting point information after the precision of the progress bar is adjusted; te1 is the terminal point information after the precision of the progress bar is adjusted; tn is the position information of the current slider of the progress bar precision; f is the pressure value; f1 is the first pressure threshold; f2 is the second pressure threshold.

6. The method of claim 4, wherein said adjusting the accuracy of the progress bar according to the pressure value further comprises:

and the adjusted starting point information and the adjusted end point information gradually move towards the direction close to the sliding block along with the increase of the pressure value.

7. The method of claim 4, wherein said adjusting the accuracy of the progress bar according to the pressure value further comprises:

the adjusted starting point information and the adjusted end point information gradually move in the direction away from the sliding block along with the reduction of the pressure value;

or the like, or, alternatively,

the adjusted start point information and the adjusted end point information are kept unchanged as the pressure value decreases.

8. The method of claim 1, wherein after adjusting the accuracy of the progress bar according to the pressure value, further comprising:

acquiring target position information of the precision bar sliding block;

and displaying display content corresponding to the target position information.

9. The method of claim 1, wherein said adjusting the accuracy of the progress bar according to the pressure value comprises:

presetting a time interval;

and when the pressure value deviation is smaller than the preset deviation in the preset time interval, finishing the precision adjustment of the progress bar.

10. An apparatus for progress bar control, comprising:

the pressure value acquisition module is used for acquiring a pressure value borne on a terminal display screen;

and the adjusting module is used for correspondingly adjusting the precision of the progress bar according to the pressure value.

11. The apparatus of claim 10, further comprising:

the first pressure threshold setting module is used for presetting a first pressure threshold;

and the continuous time acquisition module is used for acquiring the continuous time of the pressure value exceeding a first pressure threshold value under the condition that the pressure value is not less than the preset first pressure threshold value.

12. The apparatus of claim 10, further comprising:

and the second calculation module is used for stopping adjusting the precision of the progress bar under the condition that the pressure value exceeds a preset second pressure threshold value.

13. The apparatus of claim 12, wherein the adjustment module comprises:

the progress bar information acquisition unit is used for acquiring starting point information before the progress bar is adjusted, end point information before the progress bar is adjusted and position information of a current sliding block of the progress bar;

the calculating unit is used for calculating the starting point information and the end point information after the progress bar is adjusted, and the specific calculation is as follows: the adjusted starting point information Ts1 ═ Ts + (Tn-Ts) (F-F1)/(F2-F1);

the adjusted end point information Te1 of the progress bar is Te- (Te-Tn) (F-F1)/(F2-F1);

wherein: ts is starting point information before the progress bar is adjusted; te is terminal point information before the progress bar is adjusted; ts1 is the starting point information after the progress bar is adjusted; te1 is the terminal point information after the progress bar is adjusted; tn is the position information of the current slide block of the progress bar; f is the pressure value; f1 is the first pressure threshold; f2 is the second pressure threshold.

14. The apparatus of claim 10, further comprising:

the target position information acquisition module is used for acquiring target position information of the progress bar sliding block;

and the display module is used for displaying the display content corresponding to the target position information.

15. An electronic device, comprising a memory and a processor for storing a data processing program which when executed by the processor implements the steps of the progress bar control method according to any one of claims 1 to 9.

16. A storage medium having stored thereon a computer program, wherein the computer and program are arranged to execute the steps of the progress bar control method according to any one of claims 1 to 9 when run.

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