Disclosure of Invention
The invention provides a method for reconstructing and storing the priority of a functional control, which is used for solving the problems.
According to a first aspect of the present invention, there is provided a method of reconstructing and storing priorities of functionality controls, comprising the steps of:
According to the adjustment instruction, changing a priority parameter preset by a target function control in the display interface to reconstruct the priority of the function control; and/or
The method comprises the steps of self-learning using parameters of the function control to change priority parameters preset by a target function control in a display interface and reconstructing the priority of the function control;
In one embodiment, the priority parameter is the size of the area occupied by the functional control on the display interface and/or the position of the functional control on the display interface.
In one embodiment, according to the adjustment instruction, changing the priority parameter preset by the target function control in the display interface to reconstruct the priority of the function control includes the following sub-steps:
Step 110: changing the size of the area occupied by the target functional control on the display interface according to the instruction for adjusting the display size; the size of the area occupied by the other functions on the display interface is adaptively adjusted;
Step 120: and storing the priority parameters of the changed functional controls to reconstruct the priorities of the functional controls.
In one embodiment, according to the adjustment instruction, changing the priority parameter preset by the target function control in the display interface to reconstruct the priority of the function control includes the following sub-steps:
step 110: changing the position of the target function control on the display interface according to the position adjusting instruction; the positions of the other functions on the display interface are adaptively adjusted;
Step 120: and storing the priority parameters of the changed functional controls to reconstruct the priorities of the functional controls.
In one embodiment, the functionality control in the middle of the display interface has the highest priority.
In one embodiment, the functionality control with the largest area occupied by the display interface has the highest priority.
In one embodiment, the usage parameters of the target functionality control include the number of uses and/or frequency of uses of the target functionality control.
In one embodiment, the self-learning of the usage parameters of the functionality control to change the priority parameters preset for the target functionality control in the display interface and to reconstruct the priority of the functionality control comprises the sub-steps of:
recording and analyzing the use times and/or the frequency of the target function control;
changing a priority parameter preset by the target function control in the display interface and reconstructing the priority of the function control according to the using times and the frequency of the target function control;
in one embodiment, the method further comprises:
and displaying the display interface in a layout mode of the functional controls formed after the priority of the functional controls is reconstructed.
According to a second aspect of the present invention, the present invention provides a terminal device, including a display interface, where the display interface is configured to display the functionality control, and the method is used to reconstruct and store the priority of the functionality control.
Compared with the prior art, the invention has the advantages that: by changing the priority parameter preset by the target functional control in the display interface to reconstruct the priority of the functional control, the user operation is convenient, the effect of continuous adjustment is achieved, and the automatic adjustment of the optimization of the functional priority can be realized, so that the requirements of the user on the self-learning and intelligent functions of the equipment are met.
Detailed Description
The invention will be further described with reference to the accompanying drawings.
According to a first aspect of the present invention, as shown in fig. 1, the present invention provides a method for reconstructing and storing priorities of function controls, which is based on a terminal device of a mobile control home appliance, and is capable of performing self-learning according to an instruction of a user to reconstruct the priorities of functions so as to adjust priority parameters of the function controls.
In one embodiment, the method of the present invention comprises the following steps.
Firstly, according to an adjustment instruction, changing a priority parameter preset by a target function control in a display interface to reconstruct the priority of the function control. The priority parameter is the size of the area occupied by the functional control on the display interface of the terminal equipment and/or the position of the functional control on the display interface.
In one embodiment, the size of the area occupied by the functionality control on the display interface of the terminal device is adjusted according to the following steps. In this embodiment, the user may place the function with a large frequency of use or the function control (such as the function control 1 shown in fig. 2) extremely desiring to be used quickly in the center of the interface according to the use requirement of the user on the function, or place the function with a secondary requirement in a bottom or lower position, and the user in each position may define the use level of the function.
Specifically, in a first step, a display interface displays a functionality control. The priority of the functionality control displayed by the first entry display interface of the user is shown in fig. 2. Changing the size of the area occupied by the target functional control on the display interface according to the instruction of the user for adjusting the display size; and the size of the area occupied by the rest functions on the display interface is adaptively adjusted. As shown in fig. 3 and 4, the area occupied by the function control 1 on the display interface is increased, and accordingly, the area occupied by the function controls 2,3 and 4 on the display interface is reduced; similarly, the area occupied by the functional control 1 on the display interface is reduced, and accordingly, the area occupied by the functional controls 2,3 and 4 on the display interface is increased.
And a second step of storing the priority parameters of the changed function controls to reconstruct the priorities of the function controls. As shown in fig. 3 and 4, the size of the area occupied by each changed functional control is stored, and the priorities of the functional controls shown in fig. 3 and 4 are re-organized according to the priority parameters of each changed functional control.
In one embodiment, the position of the functionality control on the display interface is adjusted as follows. In this embodiment, in order to further enhance the interface workspace for the user to use functions, an interactive manner is provided in which the user can customize to zoom in or out one or more function control blocks through a dragged gesture.
Specifically, in a first step, a display interface displays a functionality control. The priority of the functionality control displayed by the first entry display interface of the user is shown in fig. 2. Changing the position of the target function control on a display interface according to an instruction of a user for adjusting the position; and adaptively adjusting the positions of the rest functions on the display interface. As shown in fig. 5 and 6, when the position of the functional control 1 is changed from the position shown in fig. 5 to the position shown in fig. 6, the positions of the functional controls 2, 3 and 4 are also changed correspondingly, for example, the functional controls 2 and 4 occupy the original positions of the functional control 1.
For example, after the user selects the arrangement of the positions of the functional controls, the user presses the finger to press the functional controls in any area to zoom in or zoom out; the control can be pushed to a certain angle for pulling and zooming in or out. The enlarged or reduced functional controls can be slid to any position in the most interfaces, users in different areas of each interface can be placed in a self-defined mode, and different use levels of the functional controls are self-defined.
It should be noted that, since the original functionality control 1 occupies the largest area on the display interface, i.e. has the highest priority, and after the position is changed, it is located at a lower position in the display interface, in other words, it becomes less important, so that the area occupied by the functionality control 1 on the display interface is correspondingly reduced.
That is, the area occupied by the functionality control at the display interface and the location of the functionality control 1 at the display interface may be related, and if one of the priority parameters is changed, the other priority parameter may be changed accordingly.
And a second step of storing the priority parameters of the changed function controls to reconstruct the priorities of the function controls. As shown in fig. 5 and 6, the positions of the changed functional controls are stored, and the priorities of the functional controls shown in fig. 5 and 6 are re-organized according to the priority parameters of the changed functional controls.
Optionally, the functionality control in the middle of the display interface has the highest priority, as shown in fig. 3, functionality control 1 is the most important. Optionally, the functionality control with the largest area occupied by the display interface has the highest priority, as shown in fig. 5, and the functionality control 1 is the most important.
And secondly, displaying the function controls on the display interface in a layout mode of the function controls formed after the priority of the function controls is reconstructed. Therefore, when the user enters the display interface again, the user does not need to operate again, the learned function priority can be automatically reconstructed in the interface, as shown in fig. 7, and the displayed function control 1 is positioned below the function controls 2 and 3.
In the above embodiment, the instruction for adjusting the display size may be a gesture instruction for pressing the finger against the target function control, opening or closing the finger, or a gesture instruction for pressing the finger against a certain angle of the target function control, and dragging the finger. The instruction for adjusting the position can be a gesture instruction that a user presses a finger to hold the target functional control and slides the finger in any direction, or a gesture instruction that the user presses the finger to hold the target functional control and continuously slides downwards or favors functional sliding.
In another embodiment, the method of the present invention comprises the following steps.
Firstly, the use parameters of the functional control are self-learned so as to change the preset priority parameters of the target functional control in the display interface and reconstruct the priority of the functional control. The use parameters of the target function control comprise the use times and/or the use frequency of the target function control.
Specifically, in the first step, the number of times and/or the frequency of using the target function control are recorded and analyzed, and the function priority parameters required by the user can be obtained. And secondly, changing a priority parameter preset by the target function control in the display interface and reconstructing the priority of the function control according to the using times and the frequency of the target function control. The position and the size of the functional control can be automatically reconstructed according to the obtained parameters. If the number and frequency of the functions used by the user change, the data generated by the system also changes, so that the reconstructed function control also changes.
It should be noted that, the functional control in the present invention may be, for example, a functional control for controlling home appliances such as an air conditioner. In addition, the self-learning method of the invention can refer to the prior art, and relates to a digital welding machine with a parameter self-learning function (for example, chinese patent CN 201010618379.4), which automatically generates a plurality of working point parameters with good welding effect through a received parameter self-adjusting algorithm, and puts forward parameter storage modes with different attribute priorities, thereby optimizing the welding parameters and realizing the self-learning function of the digital welding machine. The present invention is not described in detail herein.
In summary, the gesture instruction of the user is identified, so that the priority parameters of the corresponding functional components are changed, the operability of the functional control is improved, the space of the interface of the household appliance is optimally used and controlled by the user, the user interface is improved, the user can clearly and intuitively see the most wanted or most frequently operated function, and the purpose of rapid function operation of the household appliance is realized.
Further, through the habit of self-learning the user to operate the function control, the parameter is utilized to perform self-learning, so that the user can automatically learn and generate the function priority reconstruction required by the user without manual operation in the interface.
According to a second aspect of the present invention, there is provided a mobile terminal, which includes a display interface for displaying the functionality control, and the method is adopted to reconstruct and store the priority of the functionality control.
While the invention has been described with reference to a preferred embodiment, various modifications may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In particular, the technical features mentioned in the respective embodiments may be combined in any manner as long as there is no structural conflict. The present invention is not limited to the specific embodiments disclosed herein, but encompasses all technical solutions falling within the scope of the claims.