CN106325835B - 3D application icon interaction method applied to touch terminal and touch terminal - Google Patents

Abstract

The invention discloses a 3D application icon interaction method applied to a touch terminal and the touch terminal, wherein the display mode of the touch terminal comprises a use mode and an icon editing mode, a backboard and a 3D application icon suspended on the backboard are displayed on a user interface of the touch terminal in the use mode, and the method comprises the following steps: detecting operation information input by an operator aiming at the 3D application icon; determining the current operation type of the operation body according to the detected operation information and the current display mode of the touch terminal; according to the determined operation type, carrying out deformation processing on the 3D application icon, and executing an operation corresponding to the determined operation type; wherein the three-dimensional effect of the 3D application icon is realized by adopting a layering technology. Through the mode, the interaction of the 3D application icons is realized, the user control experience is improved, and the usability, flexibility and fun of a user interface are greatly enhanced.

Description

3D application icon interaction method applied to touch terminal and touch terminal

Technical Field

The invention relates to the technical field of 3D processing, in particular to a 3D application icon interaction method applied to a touch terminal and the touch terminal.

Background

The touch terminals such as mobile phones and tablet computers are greatly convenient for interaction between people and terminal equipment due to the adoption of touch operation, and the touch terminals such as the mobile phones and the tablet computers become common equipment for daily office work and entertainment of people.

However, in the prior art, the interaction of the user interface is relatively single in function except the interaction satisfying the basic operation function, and particularly, the application icons are not changed at all, and certain relation is lacked among the application icons, so that the user feels rigid, and flexibility and fun are lacked.

Disclosure of Invention

The invention provides a 3D application icon interaction method and a touch terminal thereof, which improve the user control experience and enhance the usability, flexibility and fun of a user interface through the interaction of 3D application icons.

In order to solve the technical problems, the invention adopts a technical scheme that:

A3D application icon interaction method applied to a touch terminal is characterized in that the display mode of the touch terminal comprises a use mode and an icon editing mode, a backboard and a 3D application icon suspended on the backboard are displayed on a user interface of a screen of the touch terminal in the use mode, and the method comprises the following steps:

detecting operation information input by an operator aiming at the 3D application icon;

determining the current operation type of the operation body according to the detected operation information and the current display mode of the touch terminal;

according to the determined operation type, carrying out deformation processing on the 3D application icon, and executing an operation corresponding to the determined operation type;

wherein the three-dimensional effect of the 3D application icon is realized by adopting a layering technology.

In order to solve the technical problems, the invention adopts a technical scheme that:

a touch terminal, the display mode of which comprises a use mode and an icon editing mode, in the use mode, a backboard and a 3D application icon suspended on the backboard are displayed on a user interface of a screen of the touch terminal, and the touch terminal further comprises:

the acquisition module is used for acquiring the current display mode of the touch terminal;

the detection module is used for detecting operation information input by an operation body aiming at the 3D application icon;

the determining module is used for determining the current operation type of the operation body according to the operation information detected by the detecting module and the current display mode of the touch terminal acquired by the acquiring module;

and the processing module is used for performing deformation processing on the 3D application icon according to the operation type determined by the determining module and executing the operation corresponding to the determined operation type.

In order to solve the technical problems, the invention adopts a technical scheme that:

the touch terminal comprises a processor, a screen and a bus, wherein the processor and the screen are respectively connected with the bus; the display mode of the touch terminal comprises a use mode and an icon editing mode, and in the use mode, a backboard and a 3D application icon suspended on the backboard are displayed on a user interface of a screen of the touch terminal;

the processor is used for detecting operation information input by an operation body aiming at the 3D application icon, determining the current operation type of the operation body according to the detected operation information and the current display mode of the touch terminal, performing deformation processing on the 3D application icon according to the determined operation type, and executing operation corresponding to the determined operation type.

In the embodiment of the invention, the display mode of the touch terminal and the operation information input by the operation body at the touch terminal aiming at the 3D application icon are obtained, the operation type is determined according to the display mode and the operation information, the 3D application icon which adopts the layering technology to realize the three-dimensional effect is subjected to deformation processing according to the operation type, and the corresponding operation is executed, so that the interaction of the 3D application icon is realized, the interaction mode of a user interface is enriched, the user control experience is improved, and the usability, the flexibility and the enjoyment of the user interface are greatly enhanced. Meanwhile, because the layering technology is adopted to realize the three-dimensional effect, compared with a method for realizing the three-dimensional effect by adopting three-dimensional modeling or parallax images, the method has the advantages of small storage capacity, lower requirement on hardware configuration and better applicability.

Drawings

FIG. 1 is a schematic diagram of a user interface of a touch terminal screen of the present invention;

FIG. 2 is a schematic diagram of a 3D application icon floating on a backplane according to the present invention;

FIG. 3 is a flowchart of a first embodiment of a 3D application icon interaction method of the present invention;

FIG. 4 is a flowchart of a second embodiment of a 3D application icon interaction method of the present invention;

FIG. 5 is a schematic illustration of an icon of a gear graphic in an embodiment of the present invention;

FIG. 6 is a schematic diagram of a variation of a deformed image with a rotation angle according to an embodiment of the present invention;

FIG. 7 is a flow chart of the present invention for determining the type of operation in a usage mode;

FIG. 8 is a schematic diagram of the present invention sliding sub-level functionality up and down on a touch terminal;

FIG. 9 is a flow chart of the present invention for determining the type of operation in the icon edit mode;

FIG. 10 is a schematic diagram of the present invention changing the position of a 3D application icon;

FIG. 11 is a schematic diagram of the present invention in creating a new folder;

FIG. 12 is a schematic diagram of the present invention deleting a 3D application icon;

FIG. 13 is a schematic diagram of the invention in an icon edit mode with the operator sucking up a 3D application icon;

FIG. 14 is a schematic diagram of releasing a 3D application icon in an icon edit mode according to the present invention;

fig. 15 is a schematic structural diagram of a touch terminal according to a first embodiment of the present invention;

FIG. 16 is a schematic structural diagram of a touch terminal according to a second embodiment of the present invention;

fig. 17 is a schematic structural diagram of a touch terminal according to a third embodiment of the present invention.

DETAILED DESCRIPTION OF EMBODIMENT (S) OF INVENTION

The present invention will be described in detail below with reference to the accompanying drawings and examples.

It should be noted that, if not conflicted, the various features of the embodiments of the invention may be combined with each other within the scope of protection of the invention. Additionally, while functional block divisions are performed in apparatus schematics, with logical sequences shown in flowcharts, in some cases, steps shown or described may be performed in sequences other than block divisions in apparatus or flowcharts.

To facilitate an understanding of the embodiments of the invention, some terms referred to in all embodiments of the invention are explained before beginning to describe various embodiments of the invention. Specifically, a 3D application icon is displayed on the screen of the touch terminal, and the 3D application icon refers to an application icon with a 3D display effect, namely, an APP icon with a stereoscopic effect. The display modes of the touch terminal include an icon editing mode and a use mode. Among them, a mode in which a touch terminal normally displays a UI (user interface) is referred to as a use mode, and a mode in which an application icon on a user interface is edited is referred to as an icon editing mode. When the touch terminal is in a use mode, a backboard and a 3D application icon suspended on the backboard are displayed on a user interface of the touch terminal. Referring to fig. 1 and 2, when the touch terminal is in the use mode, a backboard 11 and a 3D application icon 12 suspended on the backboard 11 are displayed on a user interface of the touch terminal. In the use mode, the back plate 11 is formed by seamlessly splicing a plurality of polyhedrons 111. In the icon editing mode, a plurality of polyhedrons are split, and each 3D application icon corresponds to one polyhedron which can be used for bearing the 3D application icon.

In all embodiments of the present invention, the touch terminal includes devices such as a computer, a PDA, a tablet computer, an MP4, a smart phone, an electronic paper book, a game machine, etc. which implement human-computer interaction using a graphical User Interface (UI). The user can operate the 3D application icon displayed in the touch terminal through the operation body, and the touch terminal can respond correspondingly according to the operation of the operation body so as to realize the interaction of the 3D application icon.

A plurality of 3D application icons are generally displayed on a user interface of the touch terminal. In the following, taking an example that an operator operates a certain 3D application icon on a user interface, the interaction method of the 3D application icon and the touch terminal in the embodiment of the present invention are described in detail.

Referring to fig. 3, a flowchart of a 3D application icon interaction method according to a first embodiment of the present invention is shown, the method includes:

step S301, detecting operation information input by an operator aiming at a 3D application icon;

the operator is a touch carrier which generates an operation signal by touching the terminal when approaching or contacting the screen, and may be a touch pen, a touch glove, a hand of a user, and the like, and the 3D application icon on the screen refers to an icon of an application program with a stereoscopic effect, and does not include a widget icon or a folder icon.

Step S302, determining the current operation type of the operation body according to the detected operation information and the current display mode of the touch terminal;

wherein, the operation type of the operation body comprises: a blank operation and/or a touch screen operation. In which an idle operation, that is, a so-called floating operation, is performed, the operating body does not touch the screen of the touch screen terminal, and the operation may occur only when the touch terminal is in the use mode. And touch screen operation, namely operation of an operator contacting a screen, exists in both a use mode and an icon editing mode. Specifically, the touch screen operation in the use mode includes: one or more of click operation, up-down sliding operation, left-right sliding operation, or long-press operation. The touch screen operation in the icon editing mode comprises the following steps: one or more of a move operation, a screen cut operation, or a shortcut setting operation.

It is understood that, in the blank operation, since the operator does not contact the screen, the operation information detected at this time may be a distance between the operator and the touch terminal screen. When the distance satisfies a preset distance condition, it may be determined that the current operation type is a null operation. When the operation type of the operation body is detected to be the blank operation, the 3D application icon can be subjected to deformation processing such as rendering and displayed according to the actual distance between the operation body and the display screen.

However, in the touch screen operation, since the operating body contacts the screen, the operation information detected at this time may include: the time information of the contact of the operating body with the screen and/or the motion trail information of the operating body on the screen. The time information of the operator contacting the screen refers to the time length of the operator contacting the screen, and the motion track information of the operator on the screen refers to the related information of the operator contacting the screen and sliding on the screen. And judging the current operation type of the operation body according to the time information of the operation body contacting the screen and/or the motion track information of the operation body on the screen and the combination display mode.

And step S303, according to the operation type determined in the step S302, performing deformation processing on the 3D application icon, and executing the operation corresponding to the determined operation type.

In step S303, the touch terminal may perform a corresponding response operation according to the determined operation type. In the process of responding to the corresponding operation, the icon may be deformed first, and then the corresponding operation is executed; the icon may be deformed simultaneously during the execution of the operation.

It should be noted that, in all embodiments of the present invention, the stereoscopic effect of the 3D application icon on the touch terminal is realized by using a layered technology. The layered technique is a technique for realizing a 3D stereoscopic effect by changing a distortion parameter of layered pictures combined in a specific order. Therefore, before step S301, the method may further include:

and step S300, presetting the hierarchical information of the 3D application icon. Wherein, the hierarchical information of the 3D application icon includes: layered pictures and the arrangement order of the layered pictures. And after the layered pictures are combined according to a specific arrangement sequence, a 3D application icon can be formed.

In the embodiment of the invention, the display mode of the touch terminal and the operation information input by the operation body at the touch terminal aiming at the 3D application icon are obtained, the operation type is determined according to the display mode and the operation information, the 3D application icon which adopts the layering technology to realize the three-dimensional effect is subjected to deformation processing according to the operation type, and the corresponding operation is executed, so that the interaction of the 3D application icon is realized, the interaction mode of a user interface is enriched, the user control experience is improved, and the usability, the flexibility and the enjoyment of the user interface are greatly enhanced. Meanwhile, because the layering technology is adopted to realize the three-dimensional effect, compared with a method for realizing the three-dimensional effect by adopting three-dimensional modeling or parallax images, the method has the advantages of small storage capacity, lower requirement on hardware configuration and better applicability.

Referring to fig. 4, a flowchart of a 3D application icon interaction method according to a second embodiment of the present invention is shown, where the method includes:

step S400, presetting the layered information of the 3D application icon, wherein the layered information of the 3D application icon comprises: the arrangement sequence of the layered pictures;

step S401, detecting operation information input by an operation body aiming at a 3D application icon;

step S402, determining the current operation type of the operation body according to the detected operation information and the current display mode of the touch terminal;

the operations of steps S400-S402 are the same as those of steps S300-S302, and are not described herein again. The difference between this embodiment and the previous embodiment is that, when performing the deformation processing on the 3D application icon according to the determined operation type, that is, when performing the deformation processing part in step S303 in the previous embodiment, the method may specifically include the following steps:

step S403, acquiring the layered information of the 3D application icon;

since hierarchical information of all 3D application icons on a display screen of the touch terminal is preset in a database of the touch terminal. For example: the hierarchical information of the WeChat icon is pre-stored in a database of the touch terminal, specifically, three hierarchical pictures, namely, a picture A, a picture B and a picture C, are respectively stored in the database of the touch terminal, and the three hierarchical pictures are arranged in sequence of the picture A, the picture B and the picture C, wherein the picture A is a bottom picture, and the picture C is a top picture, namely, the picture C is a picture close to a user side.

The hierarchical information of the 3D application icon is obtained by a developer by performing hierarchical splitting according to attributes such as the material and the structural configuration of the icon.

Step S404, obtaining deformation parameters of each layer of layered pictures included in the layered information under the determined operation type;

the method is used for achieving different 3D application icons under different operation types or different presentation effects of the same 3D application icon. Therefore, deformation parameters of each layered picture of each 3D application icon displayed on the screen under different operation types are preset in the database of the touch terminal. In the embodiment of the present invention, the deformation parameter includes a layer rotation coefficient, a layer offset coefficient, a layer scaling coefficient, a layer inclination coefficient, a following coefficient, and the like. The coefficient of the deformation parameter may be set to 0, and when a certain deformation parameter is 0 in a certain operation type, it indicates that the corresponding operation is not required to be performed. For example, when the layer rotation parameter is 0, it indicates that the rotation processing of the layered picture is not required under the operation type. By way of example and not limitation, the deformation parameters can be used for deformation processing of the 3D application icons in operations including a blank operation, a click operation, a screen cutting operation, an icon moving operation and the like.

In the embodiment of the present invention, the layer rotation coefficient is used to describe a rotation angle of each layer along the Z axis in the X, Y plane. For example, in a gear graphic icon, as shown in fig. 5, the gear needs to have a rotating effect when clicking. In order to display the 3D visual effect of the gear, the touch terminal needs to acquire layered pictures of the gear and acquire layer rotation coefficients of the layered pictures of the icon under single click operation.

The X and Y planes are X and Y planes in a standard coordinate of the touch terminal, wherein in the standard coordinate, an X axis is in a horizontal direction, a Y axis is in a vertical direction, the X axis is perpendicular to the Y axis, a display interface of the touch terminal is parallel to a plane formed by the X axis and the Y axis, a Z axis is perpendicular to the outward direction of the mobile phone interface, and the Z axis is perpendicular to the X axis and the Y axis.

In the embodiment of the invention, the layer shift coefficient is used for calculating the shift of the layered picture of the icon on the X and Y axes. Such as: when the icon rotates along the Y axis, the offset of each layer of layered picture of the icon on the X axis can be obtained by calculating the product of the positive rotation value of the rotation angle theta and the layer offset coefficient of each layer of layered picture of the icon, so as to carry out offset processing on the layered pictures, wherein the offset of each layer of layered picture on the X axis is calculated in the mode of xOffsetFactor & sin theta, wherein the xOffsetFactor represents the layer offset coefficient on the X axis, and the offset of each layer of picture on the Y axis is calculated in the mode of yOffsetFactor & sin theta, wherein the yOffsetfactor represents the layer offset coefficient on the Y axis.

For better understanding, please refer to fig. 6, which is a schematic diagram illustrating a variation of a deformed image with a rotation angle according to an embodiment of the present invention. In fig. 6, the arrow direction indicates that the rotation angle of the touch terminal on the Y axis gradually increases, and as can be seen from fig. 6, when the rotation angle of the icon on the Y axis gradually increases, the rolling width of the ball in the icon also gradually increases.

In the embodiment of the present invention, the layer scaling factor is used to describe the scaling of the icon for zooming in and zooming out. Taking a user clicking an icon as an example, when clicking, the overall visual effect of the icon is an effect of packing into a display screen (namely, being far away from the user side), and since the overall icon is far away from the user, the overall icon needs to be reduced, so that generally, the layer scaling coefficient of the layered pictures of each layer of the icon can be set to be less than 1; however, for some special layers, for example, when water drops or other easily deformable objects exist, the special layer may have a flattening effect when clicked, and the value of the set layer scaling coefficient is greater than 1.

In the embodiment of the invention, the layer inclination coefficient is used for describing the deformation degree of the layered picture when the layered picture is rotated along the X and Y axes. Taking the rotation of the icon along the Y-axis as an example, the image distortion becomes more noticeable as the rotation angle is larger. In the embodiment of the invention, the product of the rotation angle of the layered picture along the X and Y axes and the layer inclination coefficient can be used as the deformation degree of the layered picture so as to perform inclination processing on the layered picture.

Wherein, the deformation degree on the X axis is as follows: xSkewFactor tan theta_xWhere xSkewFactor represents the layer tilt coefficient on the X-axis, θ_xIndicating the angle of rotation on the X-axis. The degree of deformation on the Y axis is: ySkewfactor tan theta_yWhere ySkewFactor represents a layer inclination coefficient on the Y-axis, θ_yIndicating the rotation angle on the Y-axis.

In the embodiment of the present invention, the following coefficient is used to describe the relative displacement between each layered picture and the operation body when the icon is moved. The faster the dragging speed of the operation body is, the greater the relative distance between the icon and the operation body is; the slower the operation body is dragged, the smaller the relative distance between the icon and the operation body is. If the moving speed of the operation body is s_fAnd the relative distance between the layer and the operation body is the product of the moving speed and the following coefficient.

It should be noted that, for different icon operations, the types and the parameter sizes of the deformation parameters used for performing deformation processing on the icon to obtain the 3D dynamic display effect may be the same or different, and in practical applications, the deformation parameters required to be used for different icon operations may be selected according to specific needs.

Step S405, according to the deformation parameters of each layer of layered pictures under the determined operation types, carrying out deformation processing on each layer of layered pictures of the 3D application icon to obtain a deformation image of each layer of layered pictures of the 3D application icon;

when executing this step, according to the deformation parameters obtained in step S404, that is, according to the obtained layer scaling coefficient, layer rotation coefficient, layer offset coefficient, layer inclination coefficient, and following coefficient, scaling, rotation, offset, inclination, and following processing are performed on each layer of layered pictures of the 3D application icon, so as to obtain a deformed image of each layer of layered pictures of the 3D application icon.

Step S406, determining a deformed image of the 3D application icon by using the deformed image of each layered picture and the arrangement order of the layered pictures.

In a specific implementation, the deformed images of each layer of layered pictures of the 3D application icon obtained in step S405 may be combined according to the obtained arrangement order of the layered pictures, so as to obtain the deformed image of the 3D application icon.

It should be noted that, for different icon operations, the types and the parameter sizes of the deformation parameters used for performing deformation processing on the icon to obtain the 3D dynamic display effect may be the same or different, and in practical applications, the deformation parameters required to be used for different icon operations may be selected according to specific needs.

In the embodiment of the invention, the mobile terminal receives operation information input by an operation body, acquires the layered information of the icon according to the operation information, the layered information comprises layered pictures of the icon and the arrangement sequence of the layered pictures, acquires the deformation parameter of each layered picture of the icon under the operation of the icon, carries out deformation processing on each layered picture of the icon according to the deformation parameter of each layered picture of the icon under different operation types to obtain the deformation image of each layered picture, determines the deformation image of the icon according to the deformation image of each layered picture and the arrangement sequence of the layered pictures, displays the deformation image of the icon to realize 3D dynamic display of the icon, generates the deformation image of the icon according to the layered information of the icon and the deformation parameter of each layered picture, and obtains a 3D visual effect with better display effect, the fidelity is better, and the user experience is better.

Referring to fig. 7, a flowchart of a 3D application icon interaction method according to a second embodiment of the present invention is shown, the method includes:

step S301, detecting operation information input by an operator aiming at a 3D application icon;

step S302, determining the current operation type of the operation body according to the detected operation information and the current display mode of the touch terminal;

the operation information includes: the time information of the contact of the operating body with the screen and/or the motion trail information of the operating body on the screen.

Step S303, according to the determined operation type, performing a deformation process on the 3D application icon, and executing an operation corresponding to the determined operation type.

The following description focuses on the touch screen operation of the operation body in the use mode and the editing mode.

In the use mode or the icon editing mode, the operation body may input different operations, and different operation triggers different operation types, and the touch terminal responds to different contents according to different operation types. The different operations in the use mode and the icon editing mode will be described separately below.

Mode of use

In the use mode, the touch screen operation includes: one or more of click operation, up-down sliding operation, left-right sliding operation, or long-press operation. When the touch terminal is in the use mode, the step of determining the current operation type of the operation body according to the detected operation information and the display mode in which the touch terminal is currently located, that is, when step S302 is executed, as shown in fig. 7, may include:

step S3021, when the time for the operating body to contact the screen is less than a preset first time threshold, judging whether a motion track exists on the screen by the operating body, if no motion track exists, entering step S3022, if a motion track exists and the motion track is displaced up and down, entering step S3023, and if a motion track exists and the motion track is displaced left and right, entering step S3024;

step S3022: determining the current operation type of the operation body as single click operation;

step S3023: determining the current operation type of the operation body as the up-down sliding operation;

step S3024: determining the current operation type of the operation body as a left-right sliding operation;

or, when the operation body presses the screen for a long time, it is determined that the operation type is a long press operation, and when the touch terminal is in the use mode, according to the detected operation information, it is determined that the current operation type of the operation body is determined, that is, step S302 may be specifically: and when the time that the operating body contacts the screen is greater than or equal to a preset first time threshold and the operating body does not have a motion track on the screen, determining that the current operation type of the operating body is long-press operation. It is worth mentioning that: when the operation type is determined to be long-press operation, the time that the operation body contacts the screen is greater than or equal to a preset first time threshold, and no motion track of the operation body on the screen includes two meanings: the first time is that the time for which the operation body contacts the screen is greater than or equal to a preset first time threshold, and the second time is that the operation body does not have any motion action in the time for which the operation body contacts the screen.

It should be noted that, in the use mode, the 3D application icon may sink differently when the user presses a different position on the user interface, for example: when the long press is a blank area on the user interface and the long press duration is judged to exceed the first time threshold, the 3D application icons on the user interface sink together below the screen, and meanwhile, the sunk 3D application icons float on the corresponding polyhedrons along with the separation of the back panel into the polyhedrons. When a certain 3D application icon on the user interface is pressed for a long time, the operated 3D application icon begins to sink, when the long-time pressing duration is judged to exceed a certain time, the rest application icons on the user interface sink to the lower side of the screen together, meanwhile, the rest application icons are separated into a plurality of polyhedrons along with the backboard, and the sunk 3D application icon is suspended on the corresponding polyhedron. The touch terminal can set two response modes for long-time pressing operation of a user in a use mode, wherein one mode is as follows: entering a currently selected and pressed icon into an icon editing mode; the other is as follows: not only the currently selected pressed icon enters the icon edit mode state, but all 3D application icons displayed on the screen of the touch terminal enter the icon edit mode. That is, in the icon edit mode, all 3D application icons displayed on the screen may enter the icon edit mode, or only the 3D application icon pressed by the user enters the icon edit mode. In the icon editing mode, the user can exit the icon editing mode by clicking a hardware key of the touch terminal and return to the use mode.

When the touch terminal is in the use mode and the operation type is a single-click operation, the application is started, and step S303 may be further specifically: and when the operation type is single-click operation, executing the operation of starting the application corresponding to the 3D application icon.

When the touch terminal is in the use mode and the operation type is the up-down sliding operation, the sub-level function is activated, and step S703 may further include: when the operation type is the up-down sliding operation, executing the operation of starting the corresponding sub-level function of the 3D application icon; after the sub-level function is started, the sub-level function of the sub-application can be directly displayed, the sub-level application does not need to be accessed, and the method is very convenient. That is, when step S703 is executed, specifically, the following steps may be executed: and turning over the polyhedron corresponding to the 3D application icon along the sliding direction, displaying an icon corresponding to the sub-level function on the other surface of the polyhedron to prompt the function of the currently started sub-level function, starting the sub-level function, and displaying a user interface of the sub-level function, as shown in FIG. 8.

At this point, to achieve the purpose of directly starting the sub-level function of the 3D application icon when the 3D application icon is slid up and down, a mapping relationship between the operation command and the directly starting the sub-level function of the certain 3D application icon needs to be generated in advance and stored in the touch terminal, so that when the touch terminal receives the corresponding operation command, the sub-level function can be directly started in response.

When the touch terminal is in the use mode and the operation type is a left-right sliding operation, the screen switching operation is performed, and step S303 may be specifically: and when the operation type is a left-right sliding operation, executing screen switching operation. Further, when the touch terminal is used for screen switching, the screen switching can be performed according to the sliding parameter of the operation body, and then step S303 may specifically be: the method comprises the steps of obtaining sliding parameters of an operation body, judging whether the sliding parameters are larger than a preset parameter threshold value, executing screen switching operation if the sliding parameters are larger than the preset parameter threshold value, and rebounding if the sliding parameters are smaller than or equal to the preset parameter threshold value, wherein screen switching fails. Of course, the screen can be switched according to the sliding direction during the screen switching, for example: when sliding to the left, the icon of the user interface on the left is switched to, and when sliding to the right, the icon of the user interface on the right is switched to. Touch terminal still can show different screen cutting effects at the in-process of screen cutting to the interest is strengthened, for example: the 3D application icons displayed on the screen are switched by turning over the whole backboard, or the 3D application icons displayed on the screen are switched by turning over all polyhedrons, or the 3D application icons fly into the display screen from the outside of the screen to be cut.

When the touch terminal is in the use mode and the operation type is long press operation, the display mode of the touch terminal is switched, and step S303 may further include: and when the operation type is long press operation, executing the operation of switching the touch terminal to the icon editing mode. In the use mode, the backplane is integrated, and in the icon editing mode, the backplane is separated into a plurality of polyhedrons, and then performing switching the touch terminal to the icon editing mode includes: and splitting the back panel into a plurality of polyhedrons, so that the 3D application icons respectively shrink and sink in the space between the screen and the polyhedron corresponding to the screen. The polyhedrons are characterized by the splitting identifier to make the separation between the polyhedrons more remarkable, and in the embodiment, the splitting identifier is preferably a splitting line with depth information.

It can be understood that, when the back panel is split into a plurality of polyhedrons and the polyhedrons are seamlessly spliced, the following method can be specifically adopted:

the back plate is formed by splicing a plurality of polyhedrons with a three-dimensional spatial position relationship, specifically, a three-dimensional coordinate is established by taking a certain position (for example, the upper left corner) of a screen as an origin of a coordinate system, each polyhedron is respectively provided with a fixed point (for example, a central point) with a fixed position in the three-dimensional coordinate, and when a terminal receives a trigger signal for triggering the contraction or amplification of each polyhedron, each polyhedron contracts to a preset size around the respective fixed point within a preset time, so that cracks with depth information appear between the polyhedrons, further, interval features exist between the polyhedrons, or each polyhedron expands to a preset size around the respective fixed point within the preset time, so that the polyhedrons return to an initial seamless splicing state. For example: during splitting, each polyhedron contracts inwards along a certain position (such as a central position) of the polyhedron, and the contraction with a preset amplitude is completed within a preset time, such as within 0.2 second, and the contraction amplitude reaches 2% of the size of the original polyhedron when the contraction is completed; and when the polyhedron is contracted, the edge of the surface of each polyhedron automatically forms a round chamfer, and the radius of the chamfer is equal to the contraction amplitude at the moment, so that cracks are generated among the polyhedrons. In addition, the contraction process can simulate some physical effects, such as acceleration and deceleration effects, vibration effects, changes of colors and relative positions and the like, so that the effects of increasing fun and feeling are achieved. The contraction time, the contraction amplitude, the chamfer radius, the contraction effect and the like can be set in a user-defined mode in the touch terminal. Obviously, when there are cracks having depth information between the polyhedrons, it is also possible to provide other spacers having different shapes from the polyhedrons in the cracks, thereby playing the same role as a cue for switching between the use mode and the icon editing mode.

After the touch terminal enters the icon editing mode from the use mode, the sizes of the polyhedrons separated from the back plate can be the same or different, and a certain spacing distance is kept between the polyhedrons. The 3D application icon may be suspended on a corresponding polyhedron, and the 3D application icon and the icon text may be placed in the middle of the polyhedron and centered in alignment. When a user presses a certain polyhedron, the polyhedron can present a raised or floating visual effect on a screen, and when no 3D application icon exists in the area where the current polyhedron is located, the polyhedron presents a naked polyhedron surface.

When the touch terminal is in a use mode and the operation body is not in contact with the touch terminal, the 3D application icon corresponding to the operation body gradually sinks along with the approach of the operation body to the icon, so that a visual angle effect that the operation body presses the 3D application icon is generated on the visual angle effect; in addition, the icon sinks when the operation body is close to the icon, so that the user can know which application program is to be operated, and misoperation can be reduced, and therefore before step S301, the 3D application icon deformation processing needs to be executed according to the distance between the operation body and the touch terminal screen.

Since the 3D application icon in the present embodiment is implemented using a layering technique, when a decrease in the distance between the operator and the screen is detected, the 3D application icon is made to appear as if it is pressed down by some rendering means.

It can be understood that, in the use mode, if the touch terminal is accompanied by a dynamic change of the icon during the operation in response to the operation corresponding to the determined operation type, the touch terminal is accompanied by a deformation process of the 3D application icon during the response. At this time, the deformation processing of the 3D application icon is specifically implemented according to the embodiment shown in fig. 4, that is, the hierarchical information (hierarchical pictures and the arrangement order of the hierarchical pictures) of the 3D application icon is acquired, the deformation parameter of the 3D application icon under the click operation is acquired, and each hierarchical picture of the 3D application icon is deformed according to the acquired deformation parameter, and the deformed 3D application icon is displayed.

In order to make the 3D effect of the 3D application icon better, a shadow effect of the 3D application icon may also be presented on the user interface of the touch terminal screen in the use mode. In order to achieve the purpose that the 3D application icon has the shadow effect in the use mode, the layered pictures of the 3D application icon can also comprise shadow pictures, and the shadow pictures and other layered pictures are arranged and combined according to a preset arrangement sequence to form the 3D application icon with the shadow effect.

(II) icon editing mode

When the touch terminal is in the icon editing mode, all polyhedrons of seamless splicing where the 3D application icons are located shrink and split, and all the 3D application icons sink between the screen and all the polyhedrons, so that the icon editing mode and the using mode of the touch terminal are obviously different.

In the icon editing mode, the touch screen operation of the operator includes: one or more of a move operation, a screen cut operation, or a shortcut setting operation. When the touch terminal is in the icon editing mode, the current operation type of the operator may also be determined by the time when the operator contacts the screen and/or the motion trajectory of the operator, as shown in fig. 9, step S302 further includes:

step S3025: when the time that the operation body contacts the screen is less than a preset second time threshold, judging whether the operation body has a motion track on the screen, if not, entering step S3026, if the motion track exists and the motion track is rapid vertical displacement, entering step S3027, and if the motion track exists and the motion track is rapid horizontal displacement, entering step S3028;

step S3026: determining the current operation type of the operation body as an adsorption icon operation;

step S3027: determining the current operation type of the operation body as a shortcut setting operation;

step S3028: determining the current operation type of the operation body as screen cutting operation;

or, when the operator presses the screen and moves, the operation type is determined to be a moving operation, and step S302 may be further specifically: and when the time for the operating body to contact the screen is greater than a preset second time threshold and the motion trail exists, judging the current operation type of the operating body to be the moving operation.

The second time threshold may be set according to actual conditions, for example: 3 seconds, 5 seconds, etc. The moving operation is used to change the arrangement of the 3D application icons in the user interface, and in this embodiment, the moving operation includes: an icon position replacing operation, an icon position changing operation, a folder creating operation, and an icon deleting operation.

When the touch terminal is in the icon editing mode and the operation type is a moving operation, step S303 is specifically: and when the motion track is moved from the initial position of the 3D application icon currently adsorbed by the operation body to the position above another target icon and stops for a preset time, releasing the operation body, leaving the screen of the operation body, and executing the icon position replacement operation.

Wherein, executing the icon position replacement operation specifically comprises: under the control of the touch terminal, the replaced target icon is extruded and moved to the initial position of the 3D application icon currently adsorbed by the operation body, and the position of the replaced target icon is replaced by the 3D application icon currently adsorbed by the operation body, namely the 3D application icon is controlled to sink to the position of the target icon; or, the replaced target icon sinks into the polyhedron to gradually recede, the replaced target icon gradually appears at the original position of the 3D application icon currently adsorbed by the operation body, and the 3D application icon currently adsorbed by the operation body replaces the position of the replaced target icon, that is, the 3D application icon is controlled to sink at the position of the target icon.

When the touch terminal is in the icon editing mode and the operation type is a moving operation, step S303 is specifically: and when the motion track is that the operation body moves to the position above a blank polyhedron from the initial position of the 3D application icon currently adsorbed by the operation body and stops for a preset time, the operation body is released, the operation body leaves the screen, and then the icon position changing operation is executed. Wherein, executing the icon position change operation specifically comprises: the 3D application icon currently adsorbed by the operator is sunk onto the blank polyhedron as shown in fig. 10.

It can be understood that, in the icon position replacing operation and the icon position changing operation, in order to ensure that the icon can still be directly started when the icon is slid up and down after the icon position is changed, when the icon position replacing operation or the icon position changing operation is executed, the background of the touch terminal needs to change the mapping relationship between the icon sub-level function and the screen position where the icon is located. Specifically, assuming that a mapping relationship is established between the sub-level function of icon 1 and screen position 1 before icon 1 changes its position on the screen, when icon 1 changes from screen position 1 to screen position 2, the sub-level function of icon 1 should remove its mapping relationship with screen position 1 and establish its mapping relationship with screen position 2.

When the touch terminal is in the icon editing mode and the operation type is a moving operation, step S303 is specifically: and when the movement track moves from the initial position of the 3D application icon currently adsorbed by the operating body to the position above another polyhedron with the icon and not above the icon on the polyhedron, executing the operation of creating the folder. The executing of the folder creating operation specifically includes: under the control of the touch terminal, the icon above the polyhedron is made small, and the 3D application icon attracted by the operator sinks into the polyhedron and becomes small, and is placed in a newly created folder together with the icon on the polyhedron, as shown in fig. 11. For example: dragging the current 3D application icon to the edge of the polyhedron where another 3D application icon is located, wherein the 3D application icon can be automatically sucked and zoomed together with the original 3D application icon to form a new folder.

When the touch terminal is in the icon editing mode and the operation type is a moving operation, step S303 is specifically: and when the movement track moves from the initial position of the icon currently adsorbed by the operation body to the icon deletion position area, executing icon deletion operation. The operation of deleting the icon specifically comprises the following steps: under the control of the touch terminal, the 3D application icon attracted by the operated body is sucked into the icon deletion position area and disappears, as shown in fig. 12. In this embodiment, the icon deletion position can also display the shredder icon and the deleted typeface, so that the user can conveniently find the icon deletion position area.

When the touch terminal is in the icon editing mode and the operation type is the icon adsorption operation, step S702 may further specifically be:

and floating the 3D application icon adsorbed by the touched operation body to the screen direction by a preset height. For example: if a certain 3D application icon is selected by the operator, the 3D application icon and the corresponding polyhedron float upward to approach the backboard, and the positions of the other 3D application icons and the corresponding polyhedrons which are not selected by the operator remain unchanged, the selected 3D application icon presents a feeling of being sucked by the operator, but the 3D application icon does not protrude out of the screen at this time, as shown in fig. 13. After the operator sucks up the 3D application icon, the operator can slide on the screen at will. When the operator selects a certain position to release and release the 3D application icon, the 3D application icon sinks to return to the initial state when entering the icon editing mode, as shown in fig. 14.

When the touch terminal is in the icon editing mode and the operation type is the shortcut setting operation, step S303 may further specifically be: and generating a corresponding relation between the 3D application icon sub-level function and a preset signal for quickly starting the application program sub-level function. Preferably, generating the pair of relationships comprises: receiving a preset signal for quickly starting the sub-level function of the selected application program input by aiming at the selected 3D application icon, displaying a sub-level function list corresponding to the selected 3D application icon, receiving the sub-level function selected from the sub-level function list, and establishing and storing a corresponding relation between the input preset signal and the selected sub-level function.

The preset signal may be a sliding operation in any sliding direction, such as an upward sliding operation, a downward sliding operation, a leftward sliding operation, a rightward sliding operation, or other sliding operations. In specific operation, a user may perform a sliding operation by pressing and holding a certain 3D application icon and selecting any one of the directions, for example: and the user executes a sliding operation upwards or downwards, namely, a preset signal for quickly starting the selected 3D application sublevel function can be input. And after receiving the preset signal, the touch terminal responds to the received preset signal for quickly starting the sub-level function of the selected application program and displays a sub-level function list corresponding to the icon selected by the sliding operation. And displaying a sub-level function list of the 3D application icon selected by the sliding operation, enabling a user to select a sub-level function from the sub-level function list, and establishing a corresponding relation between the sub-level function and a preset signal after the sub-level function is selected. For example: after the user performs the upward sliding operation on the WeChat icon, a secondary application list of the WeChat icon is displayed, and the secondary application list comprises: and after a scanning sub-level function is selected from the secondary application list, establishing a corresponding relation between the scanning sub-level function and the upward sliding operation, and storing the corresponding relation, wherein the quick start setting is completed at the moment.

It should be noted that: after the sub-level function list is popped up and a user selects a certain sub-level function, that is, after the quick start setting is completed, the response mode of the touch terminal has three modes:

the first method is as follows: once a user selects a certain sub-level function, the current sub-level function list automatically disappears, and the icon editing mode is returned;

the second method is as follows: the user can click on the area where the current sublevel function list is not located, at the moment, the sublevel function list disappears, and the electronic equipment returns to the icon editing mode. In this way, the area where the sub-level function list is located and the area where the non-sub-level function list is located can be distinguished by a shading technique for prompting.

The third is: the user selects a hardware key to return to the icon editing mode; the user can return to the icon editing mode by pressing a hardware key, for example, by pressing a return key (home key).

Further, in order to ensure that each preset signal only corresponds to a sub-level function under a selected application program, when multiple times of quick start setting are performed on the same APP icon, whether coverage relationships exist in the multiple times of setting needs to be considered. For example, if the WeChat icon is slid up for the first time, a quick start mode of shaking the two-level sub-level function is set. If the WeChat icon is set to be the quick starting mode of the second-level application friend circle when the upward sliding operation is performed on the WeChat icon for the second time, the electronic equipment is required to cover the setting of the last time with the setting of the last time, namely, the upward sliding operation of the WeChat icon is set to be the quick starting mode of the second-level sub-level function friend circle, and under the condition, if the upward sliding operation is not covered, system errors can occur to influence user experience. For example, if the WeChat icon is slid up for the first time, the quick start mode of shaking the secondary sub-level function is set, and if the WeChat icon is slid down for the second time, the quick start mode of shaking the secondary sub-level function is set. In this case, the second setting does not need to cover the first setting, so that the user can start the secondary application of shaking when the user executes the up-sliding and down-sliding of the WeChat icon in the use mode. Therefore, the criterion for judging whether the current quick start setting mode covers the previous quick start setting mode is as follows: whether the sliding direction of the current quick start setting mode is consistent with the sliding direction of the previous quick start setting mode or not is judged, and if so, the current quick start setting covers the previous quick start setting; otherwise, it is not covered.

In the embodiment of the invention, the display mode of the touch terminal and the operation information input by the operation body at the touch terminal aiming at the 3D application icon are obtained, the operation type is determined according to the display mode and the operation information, and the operation is carried out according to the operation type, so that the interaction of the 3D application icon is realized, the interaction mode of a user interface is enriched, the user operation experience is improved, and the usability, the flexibility and the enjoyment of the user interface are greatly enhanced.

In fig. 1 to 14, the interaction method of the 3D icon is described in detail, and a touch terminal using the interaction method will be described with reference to fig. 15 to 17.

The invention also provides a touch terminal embodiment. Referring to fig. 15, fig. 15 is a schematic structural diagram of a touch terminal according to a first embodiment of the present invention. The display mode of the touch terminal includes a use mode and an icon editing mode, in the use mode, a backboard and a 3D application icon suspended on the backboard are displayed on a user interface of a screen of the touch terminal, and the touch terminal 4 includes: an acquisition module 40, a detection module 41, a determination module 42 and a processing module 43.

And the obtaining module 40 is configured to obtain a display mode in which the touch terminal is currently located. The detection module 41 is configured to detect operation information input by an operator for the 3D application icon. The determining module 42 determines the current operation type of the operation body according to the detected operation information and the display mode in which the touch terminal is currently located, which is acquired by the acquiring module 40. The processing module 43 is configured to perform a deformation process on the 3D application icon according to the operation type determined by the determining module 42, and execute an operation corresponding to the determined operation type. In this embodiment, the operation types of the touch terminal include: a blank operation and a touch screen operation. Under the touch operation, the operation information input by the operation body comprises: the time information of the contact of the operating body with the screen and/or the motion trail information of the operating body on the screen. The time information of the operator contacting the screen refers to the time length of the operator contacting the screen, and the motion track information of the operator on the screen refers to the related information of the operator contacting the screen and sliding on the screen.

It should be noted that, in all embodiments of the present invention, the stereoscopic effect of the 3D application icon on the touch terminal is realized by using a layered technology. The layered technique is a technique for realizing a 3D stereoscopic effect by changing a distortion parameter of layered pictures combined in a specific order. Accordingly, the touch terminal 4 may further include:

and the presetting module 44 is used for presetting the hierarchical information of the 3D application icon. Wherein, the hierarchical information of the 3D application icon includes: layered pictures and the arrangement order of the layered pictures. The processing module may combine the layered pictures according to a specific arrangement order according to the layered information preset by the preset module, so as to form the 3D application icon.

In the embodiment of the invention, the display mode of the touch terminal and the operation information input by the operation body at the touch terminal aiming at the 3D application icon are obtained, the operation type is determined according to the display mode and the operation information, the application icon is subjected to deformation processing according to the operation type, and the operation corresponding to the determined operation type is executed, so that the interaction of the 3D application icon is realized, the interaction mode of a user interface is enriched, the user control experience is improved, and the usability, the flexibility and the interest of the user interface are greatly enhanced. Meanwhile, because the layering technology is adopted to realize the three-dimensional effect, compared with a method for realizing the three-dimensional effect by adopting three-dimensional modeling or parallax images, the method has the advantages of small storage capacity, lower requirement on hardware configuration and better applicability.

Referring to fig. 15, fig. 15 is a schematic structural diagram of a touch terminal according to a second embodiment of the present invention. The touch terminal comprises an acquisition module 54, a detection module 50, a determination module 51, a processing module 52 and a preset module 55.

And an obtaining module 54, configured to obtain a display mode in which the touch terminal is currently located. The detection module 50 is used for detecting operation information input by an operator for the 3D application icon. The determining module 51 determines the current operation type of the operation body according to the operation information detected by the detecting module 50 and the current display mode of the touch terminal acquired by the acquiring module 54. The processing module 52 is configured to perform deformation processing on the 3D application icon according to the operation type determined by the determining module 51, and execute an operation corresponding to the determined operation type. And the presetting module 55 is used for presetting the hierarchical information of the 3D application icon. Wherein, the hierarchical information of the 3D application icon includes: layered pictures and the arrangement order of the layered pictures.

In this embodiment, the operation information includes: the method comprises the following steps of obtaining time information of an operation body contacting a screen and/or motion trail information of the operation body on the screen, wherein the time information of the operation body contacting the screen refers to the time length of the operation body contacting the screen, and the motion trail information of the operation body on the screen refers to the information that the operation body contacts the screen and slides on the screen.

The following description focuses on the touch screen operation of the operation body in the use mode and the editing mode.

In the use mode or the icon editing mode, the operation body can execute different operations, different operation types are generated by triggering different operations, and the touch terminal responds to different contents according to different operation types. The different operations in the use mode and the icon editing mode will be described separately below.

Mode of use

In the use mode, the touch screen operation includes: one or more of click operation, up-down sliding operation, left-right sliding operation, or long-press operation. When the touch terminal is in the use mode, the current operation type of the operation body is determined by the time when the operation body contacts the screen, the motion track of the operation body and the display mode in which the touch terminal is currently located, as shown in fig. 16, and then the determination module 51 includes a first judgment unit 510, a first determination unit 511, a second determination unit 512, a third determination unit 513 and a fourth determination unit 514. The first determining unit 510 is configured to determine whether a motion trajectory of the operating body exists on the screen when the time that the operating body contacts the screen is less than a preset first time threshold and the touch terminal is in the use mode. The first determination unit 511 is configured to determine that the current operation type of the operation body is a single-click operation when the first determination unit 510 determines that there is no motion trajectory. The second determining unit 512 is configured to determine that the current operation type of the operation body is a vertical sliding operation when the first determining unit 510 determines that the motion trajectory exists and the motion trajectory is a fast vertical displacement operation. The third determination unit 513 determines that there is a movement trajectory and the movement trajectory is a fast left-right displacement operation at the determination unit, and determines that the current operation type of the operation body is a left-right sliding operation. The fourth determining unit 514 is configured to determine that the current operation type of the operation body is a long press operation when the time that the operation body contacts the screen is greater than or equal to a preset first time threshold and the touch terminal is in the use mode.

The processing module 52 includes a first execution unit 521, a second execution unit 522, a third execution unit 523, and a fourth execution unit 524.

And a first execution unit 521 for executing launching of the application corresponding to the 3D application icon when the touch terminal is in the use mode and the operation type is a single-click operation.

The second execution unit 522 is configured to execute the function of starting the sub-level corresponding to the 3D application icon when the touch terminal is in the use mode and the operation type is the up-down sliding operation. Further, after the sub-level function is started, the sub-level function may be displayed in the original position of the 3D application icon, and it is not necessary to enter the sub-level function, so that it is very convenient, then the second execution unit 522 may further specifically display an icon corresponding to the sub-level function to prompt the currently started sub-level function, start the sub-level function, and display a user interface of the sub-level function.

The third performing unit 523 is configured to perform a screen switching operation when the touch terminal is in the use mode and the operation type is a slide left-right operation.

The fourth execution unit 524 is configured to execute an operation of switching the touch terminal to the icon editing mode when the touch terminal is in the use mode and the operation type is a long press operation. In order to make the 3D display effect of the touch terminal better, in the icon editing mode, the back panel is split, and the 3D application icons are respectively shrunk, and then the fourth executing unit 524 may further specifically be: and splitting the back panel into a plurality of polyhedrons, and respectively shrinking and sinking the 3D application icons to the corresponding polyhedrons. The polyhedrons are characterized by a split identifier, which is a split line with depth information in this embodiment, to make the separation between the polyhedrons more significant.

Further, the present invention can simulate a 3D effect of pressing a 3D application icon in a simulation mode, and the touch terminal 50 further includes an adjusting module 53.

The detection module 50 is also used for detecting the distance between the operation body and the screen. The adjusting module 53 is configured to adjust a distance that the 3D application icon protrudes from the screen when the distance between the operation body and the screen is smaller than a maximum distance that the 3D application icon protrudes from the screen, so that the 3D application icon sinks toward the backboard. In the process that the 3D application icon sinks towards the backboard direction, the distance that the 3D application icon protrudes from the screen is kept equal to the distance between the operation body and the screen, so that from the perspective effect, the 3D application icon sinks due to the operation body being pressed down, and then the adjusting module 53 is specifically configured to adjust the distance that the 3D application icon protrudes from the screen to be equal to the distance between the operation body and the screen.

In order to make the 3D effect better, in the use mode, a projection of an icon is also displayed on the back plate, wherein the size or shape of the projection is changed according to time and/or date in combination with a preset change model.

(II) icon editing mode

The back panel is formed by combining a plurality of polyhedrons, in a use mode, the display module is used for enabling the polyhedrons to be seamlessly spliced to form the back panel, and the 3D application icons are suspended on the corresponding polyhedrons; in the icon editing mode, the back panel is split into a plurality of polyhedrons, and the 3D application icons are respectively contracted and sunk in the space between the screen and the corresponding polyhedron, so that the touch terminal has obvious distinguishing characteristics in the using mode and the icon editing mode.

In the icon editing mode, the operation types of the operation body include: one or more of a move operation, a screen cut operation, or a shortcut setting operation. When the touch terminal is in the icon editing mode, the current operation type of the operator can also be determined by the time when the operator touches the screen and the motion track of the operator, and then the determining module 51 includes a second judging unit 515, a fifth determining unit 516, a sixth determining unit 517, a seventh determining unit 518, and an eighth determining unit 519.

The second judging unit 515 is configured to judge whether a motion trajectory of the operation body exists on the screen when the time for the operation body to contact the screen is less than a preset second time threshold and the touch terminal is in the icon editing mode. The fifth determining unit 516 is configured to determine that the current operation type of the operation body is the icon adsorption operation when the second judging unit 515 judges that there is no motion trajectory. The sixth determining unit 517 is configured to determine that the current operation type of the operation body is the shortcut setting operation when the second determining unit 515 determines that the motion trajectory exists and the motion trajectory is the fast vertical displacement operation. The seventh determining unit 518 is configured to determine that the motion trajectory exists and the motion trajectory is a fast left-right displacement operation in the second determining unit 515, and determine that the current operation type of the operation body is a screen-cut operation. The eighth determining unit 519 is configured to determine that the current operation type of the operator is a moving operation when the time that the operator touches the screen is greater than a preset second time threshold, the motion trajectory exists, and the touch terminal is in the icon editing mode.

The 3D application icon arrangement in the user interface may be changed by a move operation, which in this embodiment includes: an icon position replacing operation, an icon position changing operation, a folder creating operation, and an icon deleting operation. The processing module 52 includes a fifth execution unit 525, a sixth execution unit 526, a seventh execution unit 528, and an eighth execution unit 529.

The fifth executing unit 525 is configured to execute an icon position replacing operation when the motion trajectory is that the operating body is released after the operating body moves from the currently adsorbed 3D application icon position to above another icon position and pauses for a predetermined time. The icon position replacing operation comprises that when the 3D application icon currently adsorbed by the operating body moves to the position above the replaced icon, the replaced icon is extruded and moves to the original position of the 3D application icon currently adsorbed by the operating body, and the 3D application icon currently adsorbed by the operating body replaces the position of the replaced icon; or, when the 3D application icon currently adsorbed by the operating body moves to above the replaced icon, the replaced icon sinks into the polyhedron to gradually recede and gradually appears at the original position of the 3D application icon currently adsorbed by the operating body.

The sixth executing unit 526 is configured to execute an icon position changing operation when the motion trajectory is that the operation body is released after the operation body moves from the currently adsorbed 3D application icon position to above a blank polyhedron and is paused for a predetermined time. Executing icon position change operation, including: and when the 3D application icon currently adsorbed by the operation body moves to the upper part of the blank polyhedron and the operation body leaves the screen, the 3D application icon adsorbed by the operation body sinks into the blank polyhedron.

The seventh execution unit 527 is configured to execute a create folder operation when the motion trajectory is that the operator moves from the position of the currently adsorbed 3D application icon to above another polygon having the icon and is not above the icon on the polygon. Wherein executing the folder creation operation comprises: when the 3D application icon currently adsorbed by the operator moves to another polyhedron having an icon above and is not above the icon on the polyhedron, the original icon above the polyhedron becomes small, and the icons adsorbed by the operator sink into the polyhedron and become small and are placed together in the newly created folder.

The eighth executing unit 528 is configured to execute the icon deleting operation when the motion trajectory is that the operating body moves from the currently adsorbed icon position to the icon deletion position area. Wherein, executing the icon deleting operation comprises: when the 3D application icon currently being suctioned by the operator is moved to the edge of the icon deletion position area, the suctioned 3D application icon is suctioned by the icon deletion position area and disappears.

When the touch terminal is in the icon editing mode and the operation type is the icon adsorption operation, the processing module 52 may further specifically be: and enabling the touched and pressed 3D application icon to float upwards to the screen by a preset height. When the touch terminal is in the icon editing mode and the operation type is the shortcut setting operation, the processing module 52 may further specifically be: and generating a corresponding relation between the 3D application icon sub-level function and a preset signal for quickly starting the application program sub-level function. Preferably, generating the pair of relationships comprises: receiving a preset signal for quickly starting the sub-level function of the selected application program input by aiming at the selected 3D application icon, displaying a sub-level function list corresponding to the selected 3D application icon, receiving the sub-level function selected from the sub-level function list, and establishing and storing a corresponding relation between the input preset signal and the selected sub-level function.

In the embodiment of the invention, the display mode of the touch terminal and the operation information input by the operation body at the touch terminal aiming at the 3D application icon are obtained, the operation type is determined according to the display mode and the operation information, and the operation is carried out according to the operation type, so that the interaction of the 3D application icon is realized, the interaction mode of a user interface is enriched, the user operation experience is improved, and the usability, the flexibility and the enjoyment of the user interface are greatly enhanced.

Referring to fig. 17, fig. 17 is a schematic structural diagram of a touch terminal according to a third embodiment of the present invention, where the touch terminal includes a processor 601, a screen 602, and a bus 603. The processor 601 and the screen 602 are both connected to a bus 603.

The display modes of the touch terminal 60 include a use mode in which a backplane and 3D application icons suspended from the backplane are displayed on the user interface of the screen 602 of the touch terminal 60, and an icon editing mode. The processor 601 is configured to detect operation information input by the operation body for the 3D application icon, determine a current operation type of the operation body according to the detected operation information and a current display mode of the touch terminal, perform deformation processing on the 3D application icon according to the determined operation type, and perform an operation corresponding to the determined operation type.

Of course, the processor 601 may also perform other operations, so that the touch terminal 60 may also perform other functions, and for the other operations performed by the processor 601, reference may be made to the touch terminal embodiment, which is not described herein again.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes performed by the present specification and drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (24)

1. A3D application icon interaction method applied to a touch terminal is characterized in that display modes of the touch terminal comprise a use mode and an icon editing mode, in the use mode, a backboard and a 3D application icon suspended on the backboard are displayed on a user interface of a screen of the touch terminal, the backboard is formed by combining a plurality of polyhedrons, and the method comprises the following steps:

detecting operation information input by an operator aiming at the 3D application icon;

determining the current operation type of the operation body according to the detected operation information and the current display mode of the touch terminal;

according to the determined operation type, carrying out deformation processing on the 3D application icon, and executing an operation corresponding to the determined operation type;

wherein the three-dimensional effect of the 3D application icon is realized by adopting a layering technology;

the method further comprises the following steps: presetting the hierarchical information of the 3D application icon, wherein the hierarchical information of the 3D application icon comprises: the arrangement sequence of the layered pictures;

and performing deformation processing on the 3D application icon according to the determined operation type, specifically comprising:

acquiring the hierarchical information of the 3D application icon;

acquiring deformation parameters of each layer of layered pictures included in the layered information under the determined operation type;

according to the deformation parameters of each layer of layered pictures under the operation types, deformation processing is carried out on each layer of layered pictures of the 3D application icon to obtain a deformation image of each layer of layered pictures of the 3D application icon;

and determining the deformation image of the 3D application icon by using the deformation image of each layered picture and the arrangement sequence of the layered pictures.

2. The method of claim 1, wherein the deformation parameters comprise: the image layer scaling coefficient, the image layer rotation coefficient, the image layer offset coefficient, the image layer inclination coefficient and the following coefficient.

3. The method of claim 2, further comprising:

and presetting an image layer scaling coefficient, an image layer rotation coefficient, an image layer offset coefficient, an image layer inclination coefficient and a following coefficient of each layer of layered image of the 3D application icon under different operation types.

4. The method according to claim 2, wherein the deforming each layer of layered picture of the 3D application icon according to the deformation parameter of each layer of layered picture under the operation type to obtain a deformed image of each layer of layered picture of the 3D application icon comprises:

and carrying out scaling processing, rotation processing, offset processing, inclination processing and following processing on each layer of layered picture of the 3D application icon according to the obtained layer scaling coefficient, layer rotation coefficient, layer offset coefficient, layer inclination coefficient and following coefficient to obtain a deformed image of each layer of layered picture of the 3D application icon.

5. The method according to any one of claims 1 to 4, wherein the operation type of the operation body comprises: an air operation and/or a touch screen operation;

the blank operation exists in a use mode;

the touch screen operation includes: one or more of single-click operation, up-and-down sliding operation, left-and-right sliding operation or long-press operation in the use mode; and/or one or more of a move operation, a screen cut operation or a shortcut setting operation in the icon editing mode.

6. The method according to claim 5, wherein when the operation type of the operation body is a touch screen operation, the operation information includes:

and the time information of the operation body contacting the screen and/or the motion track information of the operation body on the touch terminal screen.

7. The method according to claim 6, wherein when the touch terminal is in a use mode, the determining the current operation type of the operation body according to the detected operation information and the current display mode of the touch terminal comprises:

when the time that the operating body contacts the screen is less than a preset first time threshold, judging whether the operating body has a motion track on the screen, and if the motion track does not exist, determining that the current operation type of the operating body is single-click operation; if the motion trail exists and the motion trail is rapid vertical displacement, determining that the current operation type of the operation body is vertical sliding operation; if the motion trail exists and the motion trail is rapid left-right displacement, determining that the current operation type of the operation body is left-right sliding operation;

alternatively, the first and second electrodes may be,

and when the time that the operating body contacts the screen is greater than or equal to a preset first time threshold and the operating body does not have a motion track on the screen, determining that the current operation type of the operating body is long-press operation.

8. The method according to claim 7, wherein when the touch terminal is in the use mode, the executing the operation corresponding to the determined operation type specifically includes:

when the operation type is single click operation, executing operation for starting corresponding application; alternatively, the first and second electrodes may be,

when the operation type is the up-down sliding operation, executing the operation of starting the 3D application icon sub-level function; alternatively, the first and second electrodes may be,

when the operation type is a left-right sliding operation, executing screen switching operation; alternatively, the first and second electrodes may be,

and when the operation type is long-press operation, executing the operation of switching the touch terminal to the icon editing mode.

9. The method of claim 8, wherein the back plate is assembled from a plurality of polyhedrons; in the use mode, the plurality of polyhedrons are seamlessly spliced to form the back plate; in the icon editing mode, the backboard is split into a plurality of polyhedrons, and the 3D application icon is located between the screen and the polyhedron corresponding to the 3D application icon.

10. The method according to claim 9, wherein the executing the operation of starting the 3D application icon sub-level function specifically includes:

turning a polyhedron corresponding to the 3D application icon along a sliding direction;

displaying an icon corresponding to the sub-level function on the other surface of the polyhedron to prompt the currently started sub-level function;

and starting the sub-level function and displaying a user interface of the sub-level function.

11. The method according to claim 9, wherein the performing of the operation of switching the touch terminal to the icon editing mode includes:

splitting the back plate into a plurality of polyhedrons;

and shrinking and sinking the 3D application icon between the screen and a polyhedron corresponding to the 3D application icon.

12. The method of claim 9, wherein the plurality of polyhedrons are separated by a split line having depth information.

13. The method according to claim 6, wherein when the touch terminal is in an icon editing mode, the determining a current operation type of the operation body according to the detected operation information and a display mode in which the touch terminal is currently located specifically includes:

when the time for the operating body to contact the screen is less than a preset second time threshold, judging whether a motion track exists on the screen of the operating body, and if the motion track does not exist, determining that the current operation type of the operating body is icon adsorption operation; if the motion trail exists and the motion trail is rapid vertical displacement, determining the current operation type of the operation body to be rapid setting operation; if the motion trail exists and the motion trail is rapid left-right displacement, determining that the current operation type of the operation body is screen switching operation;

alternatively, the first and second electrodes may be,

and when the time for the operating body to contact the screen is greater than a preset second time threshold and the motion track of the operating body exists, determining that the current operation type of the operating body is a moving operation.

14. The method of claim 13, wherein the back plate is assembled from a plurality of polyhedrons; in the icon editing mode, the backboard is split into a plurality of polyhedrons, and the 3D application icon is located between the screen and the polyhedron corresponding to the 3D application icon;

the moving operation includes: icon position replacement operation, icon position change operation, folder creation operation and icon deletion operation;

when the touch terminal is in an icon editing mode and the operation type is a mobile operation, the executing the operation corresponding to the determined operation type includes:

when the motion trail is moved to the position above the target icon from the initial position of the 3D application icon currently adsorbed by the operation body and is stopped for a preset time, executing icon position replacement operation; or the like, or, alternatively,

when the motion track moves from the initial position of the 3D application icon currently adsorbed by the operation body to the position above a blank polyhedron and stops for a preset time, executing icon position change operation; or the like, or, alternatively,

when the movement track moves from the initial position of the 3D application icon currently adsorbed by the operation body to the position above another polyhedron with icons and not above the icons on the polyhedron, executing a folder creating operation; or the like, or, alternatively,

and when the motion trail moves from the initial position of the 3D application icon currently adsorbed by the operation body to the icon deletion position area, executing icon deletion operation.

15. The method of claim 14, wherein the performing the icon position replacement operation comprises:

causing the target icon to be extruded and moved to an initial position of the 3D application icon, and controlling the 3D application icon to sink to the position of the target icon; alternatively, the first and second electrodes may be,

and controlling the target icon to gradually hide and sink into the corresponding polyhedron of the target icon, gradually displaying the target icon at the initial position of the 3D application icon, and controlling the 3D application icon to sink at the position of the target icon.

16. The method of claim 14, wherein the performing an icon position change operation comprises:

and controlling the 3D application icon to sink to the blank polyhedron.

17. The method of claim 14, when performing the delete icon operation, comprising:

causing the 3D application icon to be inhaled by the icon deletion location area.

18. The method according to claim 14, wherein when performing the folder creation operation, the method specifically comprises:

and making the icon on the other polyhedron smaller, and making the 3D application icon sink to the other polyhedron and become smaller, and locate in the newly created folder together with the icon on the other polyhedron.

19. The method according to claim 13, wherein when the operation type is an icon adsorption operation, the executing the operation corresponding to the determined operation type specifically includes:

and enabling the 3D application icon to float upwards to the screen direction by a preset height.

20. The method according to claim 13, wherein when the operation type is a shortcut setting operation, the executing the operation corresponding to the determined operation type specifically includes:

and generating a corresponding relation between the 3D application icon sub-level function and a preset signal for quickly starting the application program sub-level function.

21. The method according to claim 20, wherein the generating the corresponding relationship between the 3D application icon sub-level function and the preset signal for quickly starting the application icon sub-level function comprises:

receiving a preset signal for quickly starting the selected application program sub-level function input by aiming at the selected 3D application icon;

displaying a sub-level function list corresponding to the selected 3D application icon;

and receiving the selected sub-level function from the sub-level function list, and establishing and storing the corresponding relation between the input preset signal and the selected sub-level function.

22. The method of any of claims 1 to 4, wherein the layered picture comprises a shadow picture.

23. A touch terminal is characterized in that the display mode of the touch terminal comprises a use mode and an icon editing mode, in the use mode, a backboard and a 3D application icon suspended on the backboard are displayed on a user interface of a screen of the touch terminal, the backboard is formed by combining a plurality of polyhedrons, and the touch terminal further comprises:

the acquisition module is used for acquiring the current display mode of the touch terminal;

the detection module is used for detecting operation information input by an operation body aiming at the 3D application icon;

the determining module is used for determining the current operation type of the operation body according to the operation information detected by the detecting module and the current display mode of the touch terminal acquired by the acquiring module;

the processing module is used for performing deformation processing on the 3D application icon according to the operation type determined by the determining module and executing the operation corresponding to the determined operation type;

the touch terminal further includes:

a preset module, configured to preset hierarchical information of the 3D application icon, where the hierarchical information of the 3D application icon includes: the arrangement sequence of the layered pictures;

the processing module is used for generating the 3D application icon according to the layered pictures preset by the preset module and the arrangement sequence of the layered pictures.

24. The touch terminal is characterized by comprising a processor, a screen and a bus, wherein the processor and the screen are respectively connected with the bus; the display mode of the touch terminal comprises a use mode and an icon editing mode, wherein in the use mode, a backboard and a 3D application icon suspended on the backboard are displayed on a user interface of a screen of the touch terminal, and the backboard is formed by combining a plurality of polyhedrons;

the processor is configured to detect operation information input by an operator for the 3D application icon, determine a current operation type of the operator according to the detected operation information and a display mode in which the touch terminal is currently located, perform deformation processing on the 3D application icon according to the determined operation type, execute an operation corresponding to the determined operation type, and preset hierarchical information of the 3D application icon, where the hierarchical information of the 3D application icon includes: the method comprises the steps of obtaining layered pictures and the arrangement sequence of the layered pictures, obtaining layered information of the 3D application icon, obtaining deformation parameters of each layered picture under the determined operation type, which are included in the layered information, carrying out deformation processing on each layered picture of the 3D application icon according to the deformation parameters of each layered picture under the operation type, obtaining a deformation image of each layered picture of the 3D application icon, and determining the deformation image of the 3D application icon by using the deformation image of each layered picture and the arrangement sequence of the layered pictures.

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