CN117768772A - Interaction method and device of camera application interface - Google Patents

Abstract

An embodiment of the application relates to an interaction method of a camera application interface, relates to the technical field of terminal display interface interaction, and aims of single-hand operability and shorter path of a common function menu of each mode of a camera are achieved by readjusting a menu structure of the camera and displaying all high-frequency function controls of the camera application in a single-hand easy-operation area of a display screen of electronic equipment, wherein the method comprises the following steps: in response to the first interaction event, displaying a first interface of the camera application; the first subarea of the first interface comprises a plurality of camera mode controls and a current first mode of camera application, and the second subarea of the first interface comprises a first type of setting control corresponding to the first mode; the electronic equipment responds to a second interaction event and displays a second interface of the camera application interface; and displaying a second type of setting control corresponding to the first mode in a second subarea of the second interface, and replacing the first type of setting control corresponding to the first mode.

Description

Interaction method and device of camera application interface

Technical Field

Embodiments of the present application relate to the field of terminal display interface interaction technologies, and in particular, to an interaction method for a camera application interface, an electronic device, a computer readable storage medium, and a computer program product.

Background

With the rapid development of multifunctional applications of portable electronic devices such as mobile phones, cameras on electronic devices are also being endowed with more functions, such as time-lapse photography, slow motion, movies, videos, photographs, figures, and the like.

However, there are many problems in the photographing process of the current electronic device, such as an unclean photographing interface, multiple modes, long path, poor legibility, etc. Many times, a user needs to operate the mobile phone with one hand, but because the related camera application interfaces are provided with camera controls (shortcut switches) at the bottom and the top of the screen, for example, the shortcut switches such as a camera mode (large aperture, night scene, portrait, photographing, video recording, profession, etc.), a shutter, front-back camera switching, etc. serving as a primary menu are arranged at the bottom of the mobile phone which is easy to operate with one hand, but because of the limitation of the display area of the mobile phone, when the primary menu is relatively more, the problem that the primary menu cannot be completely presented is caused, and the use experience of the user is affected; moreover, the intelligent vision, ai photographic master, flash lamp, the color of the card, the filter, the camera setting and other shortcut switches are all arranged at the top of the mobile phone, so that a user cannot finish the top shortcut switch by one hand, and one-hand operation is difficult when photographing; and the zoom control is arranged on the right side of the mobile phone, so that one-hand operation is difficult to zoom, and meanwhile, the zoom control, the secondary menu and the tertiary menu under certain primary menus are displayed in a view finding area, so that the view finding area is not concise, and shooting experience is influenced.

In addition, in the related art, a setting control of a camera mode needs to be called out in a sliding manner to replace display of the camera mode control. The calling mode of the setting control needs to exit the current application interface step by step when switching between different modes of the camera application, and has the advantages of multiple and complex operation steps and poor application experience of users.

Disclosure of Invention

Some embodiments of the present application provide an interaction method for a camera application interface, an electronic device, and a computer readable storage medium, which aim at improving the use experience of a user by performing more reasonable classification control on a high-frequency functional control of a camera, so that the camera control is operable with a single hand in a common function of each mode and has a shorter path.

In order to achieve the above objective, an interaction method of a camera application interface provided by an embodiment of the present application is applied to an electronic device, where the camera application interface includes a view-taking area, a shutter, and a first area, the view-taking area displays an image acquired by a camera in real time, and the electronic device captures and saves the image displayed by the view-taking area in response to an operation of the shutter; the first region includes: a first sub-region adjacent to the region in which the shutter is located, and a second sub-region adjacent to the first sub-region; the method comprises the following steps:

The electronic equipment receives a first interaction event;

the electronic equipment responds to a first interaction event and displays a first interface of the camera application interface; the first subarea of the first interface comprises a plurality of camera mode controls and a current first mode of camera application, and the second subarea of the first interface comprises a first type of setting control corresponding to the first mode;

the electronic device receives a second interaction event aiming at the first interface;

the electronic equipment responds to a second interaction event and displays a second interface of the camera application interface; wherein,

the first subarea of the second interface comprises the plurality of camera mode controls and a current first mode of camera application, and a second type of setting control corresponding to the first mode is displayed in the second subarea of the second interface to replace the first type of setting control corresponding to the first mode.

The area where the shutter is located at the bottom end of the screen, and the first sub-area and the second sub-area adjacent to the area where the shutter is located are also located in a single-hand easy-operation area of the electronic device. Therefore, if each camera mode displayed in the first subarea is regarded as a first-level menu of the camera application, a first-class setting control displayed in the current first mode of the camera application in the second subarea is regarded as a high-frequency second-level menu of the camera application, a second-class setting control displayed in the current first mode of the camera application in the second subarea is regarded as a second-frequency second-level menu of the camera application, after the camera function is started, a user can display the first-level menu of the camera application in the first subarea adjacent to the shutter area in the screen of the electronic device, and simultaneously display the high-frequency second-level menu of the camera application in the second subarea adjacent to the first subarea, and the user can replace the high-frequency second-level menu with the second-frequency second-level menu of the camera application through a preset gesture, so that convenient operation experience of single-hand calling of the second-frequency second-level menu is realized, the second-class setting control displayed in the display position of the high-frequency second-level menu as the second-class setting control of the second-frequency second-level menu is not occupied by an extra control display screen display area, and user experience is better.

Optionally, the method further comprises: the electronic equipment receives a third interaction event aiming at the second interface;

the electronic equipment responds to a third interaction event and displays a third interface of the camera application interface; wherein,

the first subarea of the third interface comprises a plurality of camera mode controls and a current first mode of camera application, a menu corresponding to a second setting control corresponding to the first mode is displayed in the second subarea of the third interface, and the second type setting control corresponding to the first mode is replaced; the second setting control is any one of second type setting controls corresponding to the first mode.

Optionally, the method further comprises: the electronic equipment receives a fourth interaction event aiming at the first interface;

the electronic equipment responds to the fourth interaction event and displays a fourth interface of the camera application interface; wherein,

the first subarea of the fourth interface comprises a plurality of camera mode controls and a current first mode of camera application, a menu corresponding to a first setting control corresponding to the first mode is displayed in the second subarea of the fourth interface, and the first type setting control corresponding to the first mode is replaced; the first setting control is any one of first type setting controls corresponding to the first mode.

The menu corresponding to the first setting control corresponding to the first mode and the menu corresponding to the second setting control corresponding to the first mode can be regarded as three-level menus of the camera application, so that a user can replace the corresponding high-frequency two-level menu or the second-high-frequency two-level menu with the three-level menu of the camera application in the second sub-area through a preset gesture, the convenient operation experience of single-hand calling of the three-level menu of any control in the two-level menu is realized, the three-level menu is displayed in the second sub-area, no additional screen display control is occupied, the control display area is not increased, and the user experience is better.

Optionally, the method further comprises: the electronic equipment receives a fifth interaction event aiming at any one of the second interface, the third interface or the fourth interface;

the electronic equipment responds to the fifth interaction event and displays a fifth interface of the camera application interface; wherein,

the first subarea of the fifth interface comprises a plurality of camera mode controls and a first mode or a second mode of the camera application, and the second subarea of the fifth interface displays a first type of setting control corresponding to the first mode or the second mode.

Thus, the user can select any one of the camera mode controls in the first subarea on any one of the interfaces of the camera application, namely the interface can be directly displayed to the selected camera mode, and the first type of setting control of the camera mode is displayed in the second subarea. The mode switching operation is simple and quick.

Optionally, the electronic device receives a sixth interaction event for the third interface;

the electronic equipment responds to the sixth interaction event and displays a sixth interface of the camera application interface; wherein,

the first subarea of the sixth interface comprises a plurality of camera mode controls and a current first mode of the camera application, and the second subarea of the sixth interface displays a second type of setting control corresponding to the first mode.

Therefore, after the camera application interface displays the tertiary menu of the secondary high-frequency secondary menu, the user can return to the secondary high-frequency secondary menu again through a preset gesture.

Optionally, the fourth interface further comprises a second area, the second area being located on the fourth interface on the opposite side to the area where the shutter is located,

the menu corresponding to the first setting control comprises a plurality of first sub-controls,

the method further comprises the following steps:

the electronic device receives a seventh interaction event of one of the plurality of first sub-controls on the fourth interface;

the electronic equipment responds to a seventh interaction event, a seventh interface of the camera application interface is displayed, a first subarea of the seventh interface comprises a plurality of camera mode controls and a current first mode of the camera application, a menu corresponding to a first setting control corresponding to the first mode is displayed in a second subarea of the seventh interface, and a state icon corresponding to one first sub control is displayed in a second area of the seventh interface.

Optionally, the third interface further comprises a second region, the second region being located on the third interface on a side opposite to the region where the shutter is located,

the menu corresponding to the second setting control comprises a plurality of second sub-controls,

the method further comprises the following steps:

the electronic device receives an eighth interaction event for one of the plurality of second sub-controls on the third interface;

the electronic equipment responds to an eighth interaction event, an eighth interface is displayed, wherein a first subarea of the eighth interface comprises a plurality of camera mode controls and a current first mode of camera application, a menu corresponding to a second setting control corresponding to the first mode is displayed in a second subarea of the eighth interface, and a state icon corresponding to one second sub control is displayed in a second area of the eighth interface.

The shutter is located on the opposite side of the area and is located at the top end of the display screen, so that only the camera state is displayed at the top end of the display screen, the shortcut switch originally displayed at the top end of the screen is released, and the display range of the scenic spot is effectively expanded. The released shortcut switch can be displayed in the second subarea, belongs to a single-hand easy-operation area and can be operated by one hand.

Optionally, the plurality of camera mode controls includes a combination of a plurality of the following controls: large aperture, night scenes, figures, photographs, videos, movies, professions, and more. The first type of setting control for the modes of portrait, video and movie comprises: large aperture.

Therefore, when the large aperture state in the camera mode of the portrait, the video and the movie is set, the camera can be directly set in the current mode without the need of exiting the current mode and then setting from other modes of the primary menu, thereby providing convenience for the user to adjust the large aperture state in the camera mode.

Optionally, before the electronic device displays the first interface of the camera application interface, the method further includes: determining an application mode of the electronic device based on a sensor of the electronic device, wherein the application mode comprises a vertical screen application mode and a horizontal screen application mode;

when the electronic equipment is in a vertical screen application mode, the second interaction event is a mode control of a current first mode or a slide-up gesture of a first sub-region applied to the camera; a fifth interaction event is a click of a return key or a swipe gesture on the second sub-region; when the electronic equipment is in the transverse screen application mode, the second interaction event is a transverse outer side sideslip gesture of a mode control of the current first mode applied to the camera; the sixth interaction event is a back key click or a laterally inboard side-slip gesture to the second sub-region.

That is, the determination of the interaction area of the camera application interface of the electronic device is different according to different modes of horizontal screen, vertical screen, left-hand single-hand operation and right-hand single-hand operation of the electronic device, so that the application state of the electronic device is determined according to the built-in sensor of the electronic device, and then the content of each area of the camera application interface in the corresponding application state is determined in a targeted manner, thereby more accurately determining the interaction area of the camera application interface and facilitating single-hand operation.

Optionally, the first type of setting control of the large aperture mode control includes: the second type of setting control of the aperture and the large aperture comprises: drawing and setting;

the second type of setting control of the night scene mode control comprises the following steps: drawing and setting;

the first type of setting control of the portrait mode control comprises: the second type of setting control of the zoom, face-beautifying control and large aperture comprises: blurring function, picture, flash and setting;

the first type of setting control of the photographing mode control comprises: zooming, wherein the second type of setting control of the photographing mode control comprises the following steps: filter control, picture, ai switch, flash and setup;

The first type of setting control of the video mode control comprises: the second type of setting control of the zoom, face-beautifying and large aperture and video mode control comprises: filters, frames, resolution frame rates, flash and settings;

the first type of setting control of the movie mode control comprises: zooming, beautifying, large aperture and AiLUT, and the second type of setting control of the film mode control comprises: slow motion, LOG, LUT, frame, flash, and resolution frame rate;

the first type of setting control of the professional mode control comprises: the second type of setting control of the professional mode control comprises the following functions: JPG function, flash function, and setup function;

more mode controls include: slow motion, panoramic, time-lapse photography, watermarking, document correction, super-macro, multi-mirror video, high-pixel, micro-motion film, and super-night scenes.

Therefore, the high-frequency functional controls (first type setting controls) and the secondary high-frequency functional controls (second type setting controls) of the camera are more reasonably classified and controlled according to the use frequency of the mode controls of the camera application, the control of the camera application can be operated by a common function single hand in each mode, the path is shorter, and the use experience of the user is effectively improved.

Optionally, the method further comprises:

the electronic device receives a ninth interaction event for any interface of the camera application interfaces; a ninth interaction event is for selecting a third mode within the further modes;

the electronic equipment responds to the ninth interaction event and displays an eighth interface of the camera application; wherein,

and stopping displaying the more mode controls in the eighth interface, displaying the controls in the third mode at the positions of the more mode controls, and displaying the first type setting controls in the third mode in the second subarea of the eighth interface.

Therefore, the camera interaction interface can flexibly adjust the display of the first-level menu according to the actual use state, has greater flexibility, and is beneficial to the improvement of the use experience of users.

To solve the above object, an embodiment of the present application further provides an electronic device, including:

at least one processor; the method comprises the steps of,

a memory communicatively coupled to the at least one processor and a touch display; wherein,

the touch display screen is used for displaying an application interface;

the memory stores instructions executable by the at least one processor to cause the electronic device to perform steps in an interaction method of a camera application interface as described above.

To solve the above-mentioned object, an embodiment of the present application further provides a computer-readable storage medium having at least one instruction stored therein, the at least one instruction being executed by a processor in an electronic device, so that the electronic device performs the above-mentioned interaction method of a camera application interface.

In yet another aspect, the present application provides a computer program product comprising computer instructions which, when run on an electronic device, cause the electronic device to perform steps in an interaction method of a camera application interface as described above.

It will be appreciated that the electronic device, the computer storage medium, and the computer program product provided above are all configured to perform the corresponding methods provided above, and thus, the advantages achieved by the electronic device and the computer storage medium may refer to the advantages in the corresponding methods provided above, which are not described herein.

Drawings

FIGS. 1-1 and 1-2 are schematic views of a single-hand easy-operation area of an electronic device in a single-hand vertical screen holding state and a single-hand horizontal screen holding state according to an embodiment of the present application;

FIG. 2 is a schematic diagram of an implementation of a related art camera application interface interaction;

FIG. 3a is a diagram illustrating a related art camera menu control classification;

FIG. 3b is a schematic diagram illustrating classification of camera menu controls according to an embodiment of the present application;

fig. 4 is a schematic view of area division of a camera interaction interface according to an embodiment of the present application;

fig. 5-1 to 5-7 are schematic views of interface interaction of a photographing mode according to an embodiment of the present application;

FIGS. 6-1 to 6-7 are schematic diagrams illustrating interface interactions of portrait mode according to an embodiment of the present application;

FIGS. 7-1 to 7-5 are schematic diagrams illustrating interface interactions of video recording modes according to an embodiment of the present application;

8-1 to 8-3 are schematic views of interface interactions of a movie mode according to an embodiment of the present application;

8-4 and 8-5 are interface diagrams of the camera interaction interface cross-screen application modes shown in FIG. 8-1 and FIG. 8-3;

9-1 to 9-4 are schematic views illustrating interface interactions of a multi-mirror video recording mode according to an embodiment of the present application;

FIGS. 10-1 to 10-4 are schematic views illustrating interface interactions of a professional mode according to an embodiment of the present application;

FIG. 11 is a schematic diagram of an auxiliary return control in a time-lapse photography mode according to an embodiment of the present application;

FIGS. 12-1 and 12-2 are schematic diagrams illustrating an interface of a cross-screen application mode corresponding to FIGS. 5-1 and 5-2 according to an embodiment of the present application;

Fig. 13 is a schematic structural diagram of an electronic device implementing an interaction method of a camera application interface according to an embodiment of the present application;

fig. 14 is a software structural block diagram of an electronic device according to an embodiment of the present application.

The realization, functional characteristics and advantages of the present application will be further described with reference to the embodiments, referring to the attached drawings.

Detailed Description

For the purposes of making the objects, technical solutions and advantages of the embodiments of the present application more clear, the technical solutions of the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is apparent that the described embodiments are some embodiments of the present application, but not all embodiments. All other embodiments, which can be made by one of ordinary skill in the art without undue burden from the present disclosure, are within the scope of the present disclosure.

When the present application refers to the ordinal words "first" or "second", unless the context clearly indicates the order, it should be understood that the words "first", "second", etc. are used for distinction only, and those skilled in the art will understand that the words "first", "second", etc. do not limit the number and order of execution, and that the words "first", "second", etc. do not necessarily differ. Meanwhile, the terms "exemplary" or "such as" and the like are used to mean serving as examples, illustrations or descriptions. Any embodiment or design described herein as "exemplary" or "for example" should not be construed as preferred or advantageous over other embodiments or designs. Rather, the use of words such as "exemplary" or "such as" is intended to present related concepts in a concrete fashion that may be readily understood.

Unless otherwise indicated, herein "/" generally indicates that the context associated object is an "or" relationship, e.g., a/B may represent a or B. The term "and/or" is merely an association relationship describing an associated object, meaning that there may be three relationships, e.g., a and/or B, may represent: a exists alone, A and B exist together, and B exists alone. In addition, in the description of the present application, "a plurality" means two or more.

Before describing in detail the interaction method, the electronic device, the computer-readable storage medium, and the program product of the camera application interface provided in the embodiments of the present application, some terms of the embodiments of the present application are explained in order to facilitate understanding by those skilled in the art.

1. Electronic equipment

In the application scenario of the application, a user can operate the electronic device with one hand to meet the requirement of the user on the control convenience of one hand.

In the following description of the embodiments of the present application, a smart phone is used as an application example of an electronic device.

2. Single hand easy operation area

For electronic devices such as mobile phones, when a user holds the electronic device with one hand, an area where a thumb is easy to touch on a touch screen of the electronic device is a single-hand easy-operation area. Correspondingly, when a user holds the electronic equipment with one hand, the area where the thumb is not easy to touch on the touch screen of the electronic equipment is the difficult area of one hand.

Generally, the single-hand grip is that the palm and at least two fingers except the thumb cooperate to stabilize the electronic device, so that the thumb has a relatively flexible control space. According to experimental verification, in the right-hand single-hand vertical screen holding state, the single-hand easy operation area is shown as a grid area in fig. 1-1, the single-hand easy operation area is positioned in the lower area of the screen, fig. 1-1 shows a right-hand single-hand holding scene, and if the right-hand single-hand vertical screen holding is performed, the single-hand easy operation area and the drawing shown in fig. 1-1 are symmetrically distributed by a vertical central thread of the screen. In the state of holding the single-left-hand transverse screen, the single-hand easy-operation area is shown as a grid area in fig. 1-2, the single-hand easy-operation area is positioned on the right side of the screen, and if the single-hand transverse screen is held by left and right single hands, the single-hand easy-operation area and the drawing shown in fig. 1-2 are symmetrically distributed by the vertical central threads of the screen.

3. Current mode/functionality of camera applications

In the embodiment of the present application, the current mode/function of the camera application refers to a mode or function currently being applied under the camera function of the electronic device, for example, in a photographing mode, the current mode of the camera application is a photographing mode; and in the flash lamp setting interface of the photographing mode, the current application function is a flash lamp setting function.

Currently, cameras in electronic devices are widely used, and on a camera application interface of the electronic device, a display area of the electronic device may generally be divided into a shutter area, a menu area and a view area. Taking an electronic device as an example of a mobile phone, an exemplary, one possible implementation manner of the related art is shown in fig. 2, where a camera application interface display area of the mobile phone includes four main areas, and the four main areas are sequentially from bottom to top: a shutter area, a bottom menu area, a view area, and a top menu area.

The control arranged in the shutter area comprises the following components from left to right: shortcut entry, shutter and camera switching control of gallery (album) application.

The bottom menu area provides a plurality of camera mode controls, and controls for setting parameters of the current mode, the camera modes mainly including: large aperture, night scene, portrait, photograph, video, movie, specialty, more etc. and the current photograph mode setting control is displayed in the view-finding area (above the display position of the camera mode). The current mode as shown in fig. 2 is a photographing mode, and a zoom function 206 of the photographing mode is displayed at a lower position of the viewfinder area above the camera mode. In the interactive interface displayed in the top menu area at the uppermost part of the display area, the interactive interface comprises the following components in sequence from left to right: intelligent recognition 201, ai photography 202, flash 203, filter 204, setting 205. Corresponding to the one-hand easy operation area shown in fig. 1-1 and 1-2, it can be seen that in the related art camera application interface display area, the top menu area is located in the one-hand difficult area.

In some embodiments, the electronic device may adjust a specific camera mode of the menu area and a setting control corresponding to the camera mode according to a software and hardware configuration of the camera, and may also adjust a range of the scenic spot according to the camera mode and a requirement of the software and hardware configuration. However, such a display manner of the top menu area in the related art cannot conveniently implement one-hand operation regardless of adjustment.

It should be noted that, in the user interface in the embodiment of the present application, an electronic device is taken as an example of a mobile phone to be illustrated. Of course, the electronic device may be any other suitable device (such as a tablet computer, a smart watch, etc.), which is not limited in this application.

Therefore, in the related technology of the camera application interface, the shooting of the single-hand electronic device still has a certain problem, such as the fact that the top shortcut switch operation cannot be completed by one hand, the zooming by one hand is difficult, the primary function cannot be completely presented, and the like.

In one possible implementation, as shown in fig. 3a, before adjustment, a first level menu of the camera in the related art mainly includes different photographing modes of the camera: large aperture, night view, portrait, photograph, video, movie, specialty, more, etc., while displaying the first level menu, a setting control of the current camera mode is displayed in the viewfinder area (upper portion of the first level menu) or the top area of the camera, such as when the current camera mode shown in fig. 2 is a photograph mode, the zoom function 206 is displayed in the bottom menu area that is easy to operate by one hand, and the smart recognizer 201, ai photograph 202, flash 203, filter 204, setting 205 functions are displayed in the top menu area that belongs to the one-hand difficult area. For another example, when the current camera mode is a video mode, the zoom and beauty functions are displayed in the bottom menu area, and the night view, the flash, the filter and the setting functions are displayed in the top menu area; in the large aperture mode, the aperture function is displayed in the bottom menu area, and the setting function is displayed in the top menu area; a night view mode in which a zoom function is displayed in a bottom menu area and a set function is displayed in a top menu area; in the portrait mode, zoom, beautify and virtual functions are displayed in a bottom menu area, and a flash lamp and a setting function are displayed in a top menu area; in the movie mode, the zoom function is displayed in the bottom menu area, and the slow motion, 4k HDR (4 k resolution high dynamic range image), LOG (Logarithmic) mode, LUT (Look Up Table) filter, flash, setup function are displayed in the top menu area; in the professional mode, zoom and professional parameter adjusting functions are displayed in a bottom menu area, and JPG, a flash lamp and setting functions are displayed in a top menu area; in the more modes, a slow motion mode, a panoramic mode, a delayed shooting mode, a watermark mode, a document correction mode, a super macro mode, a multi-mirror video mode, a micro movie mode and the like are displayed. In the related art camera interactive interface, it is difficult for a user to implement one-hand operation for the interactive interface of the top menu displayed at the uppermost portion of the viewing area.

In one possible implementation of the present application, as shown in fig. 3b, a primary menu is configured with a plurality of mode controls (which may be regarded as primary controls): large aperture mode, night scene mode, portrait mode, photo mode, video mode, movie mode, professional mode, and more. Each mode control in the primary menu is provided with a secondary menu, one or more mode controls (which can be regarded as secondary controls) can be configured in the secondary menu according to the application requirement of the mode control, the secondary controls can be divided into a high-frequency secondary control and a secondary high-frequency secondary control according to the conventional application frequency, and the secondary menu of each primary control can comprise a high-frequency secondary menu and a secondary high-frequency secondary menu.

Specifically, the high-frequency secondary menu in the large aperture mode may include aperture adjustment, and the secondary high-frequency secondary menu in the large aperture mode is configured with a frame and a setting. Available controls are not configured in the high-frequency secondary menu of the night scene mode, and pictures and settings are configured in the secondary high-frequency secondary menu of the night scene mode. Three secondary controls are configured in the high-frequency secondary menu of the portrait mode: the secondary high-frequency secondary menu of the portrait mode is provided with a filter, a picture, a flash lamp and settings. The high-frequency secondary menu of the photographing mode is provided with a zoom, and the secondary high-frequency secondary menu of the photographing mode is provided with a filter, a picture, an Ai switch, a flash lamp and a setting. The high-frequency secondary menu of the video mode is provided with zooming, beautifying and large aperture, and the next high-frequency secondary menu of the video mode is provided with a filter, a picture, a resolution frame rate, a flash lamp and settings. Zoom, face, large aperture and AiLUT (Artificial Intelligent Look Up Table, artificial intelligence Look-Up Table) are arranged in the high-frequency secondary menu of the movie mode, and slow motion, LOG, LUT (Look Up Table), frame, flash and resolution frame rate are arranged in the secondary high-frequency secondary menu of the movie mode. Two secondary controls are configured in the high-frequency secondary menu of the professional mode: three secondary controls are configured in a secondary high-frequency secondary menu of a professional mode in zooming and parameter adjustment: JPG, flash, and settings. The more modes are a set of preset primary menus, wherein a slow motion mode, a panoramic mode, a delayed shooting mode, a watermark mode, a document correction mode, a super-macro mode, a multi-lens video recording mode, a high-pixel mode, a micro-film mode, a super-night view mode and the like are configured.

Of course, the configuration of the specific mode control in the primary menu is only one embodiment of the application, and the specific mode control in the primary menu can be flexibly configured according to specific products or application requirements. For example, in another embodiment of the present application, a multi-mirror video recording mode is further configured in the primary menu; in yet another embodiment of the present application, ai (Artificial Intelligence ) functions are also configured in the high-frequency secondary menu of the photographing mode; in another embodiment of the present application, a large aperture function or the like is also provided in the high-frequency secondary menu of the portrait mode. Similarly, for the tertiary menu of each secondary control in the secondary menu, the configuration may also be performed according to specific application requirements of each function in the secondary menu, for example, the tertiary menu of the flash lamp function in the secondary menu may be configured to include four states of flash lamp on, flash lamp normally on, flash lamp off and flash lamp automatic. The three-level menu of other functions of the camera is not listed here.

It can be seen that, in the above implementation of the present application, according to the camera mode provided in the current electronic device: large aperture, night scenes, figures, photographs, videos, movies, professions, more, etc., readjust the secondary menu for each camera mode. For example, in the related art, the large aperture mode control is only displayed in the first-level menu, and in the embodiment of the application, the large aperture function is configured in the high-frequency second-level menu of the portrait mode, the video mode and the movie mode, so that convenience is provided for the user to adjust the large aperture in the camera mode.

For another example, in the embodiment of the present application, the shortcut operation displayed at the top of the screen in the related art is configured in the secondary menu of the camera mode according to the needs of each camera mode, and the function control is configured in the secondary menu of the large aperture mode, the night scene mode, the portrait mode, the photographing mode, the video mode, and the movie mode: the resolution frame rate function control is configured in the secondary high-frequency secondary menu of the video mode and the film mode, and convenience is provided for the user to adjust the frames and the resolution frame rate in the camera mode.

In one possible implementation manner of the present application, the display area in the camera mode of the electronic device is divided into four main areas as shown in fig. 4, which are, for a mobile phone for a vertical screen application, a shutter area, a high frequency function area (first area), a view taking area, and a camera status bar area (second area) from bottom to top, respectively. The electronic equipment captures and stores the image displayed by the scenic spot in response to the operation of the shutter. Compared with the camera interaction interface arrangement mode of the related art, in the embodiment of the application, the controls corresponding to the core functions of the camera are all displayed in a high-frequency functional area, and the high-frequency functional area is located in a single-hand easy-operation area of the display area of the electronic equipment; and the resident switch and the real-time state which are basically not required or not required to be controlled are displayed in the uppermost camera state column area of the display area, so that classification and identification are facilitated.

In one possible implementation manner of the present application, the first area as the high-frequency functional area includes: the first subarea can be regarded as a primary menu display area, and the second subarea can be regarded as a secondary menu display area, wherein the first subarea is adjacent to the area where the shutter is positioned, and the second subarea is adjacent to the first subarea. The first-level menu display area is used for displaying controls corresponding to a first-level menu of the camera, the controls corresponding to the first-level menu comprise various mode controls of the camera, the second-level menu display area is used for displaying controls corresponding to a second-level menu of the camera and controls corresponding to a third-level menu, and the controls corresponding to the second-level menu and the controls corresponding to the third-level menu comprise functional controls in all modes.

Each control displayed in the primary menu may have a corresponding secondary menu, and likewise, in some embodiments, a functionality control in the secondary menu may have a corresponding tertiary menu. The control corresponding to the second-level menu comprises a first-type setting control and a second-type setting control, the third-level menu comprises a menu corresponding to the first-type setting control and a menu corresponding to the second-type setting control, at least one first setting control is arranged in the menu corresponding to the first-type setting control, and at least one second setting control is arranged in the menu corresponding to the second-type setting control.

Further, the secondary menu in the embodiment of the application includes a high-frequency secondary menu and a secondary high-frequency secondary menu; the function control in the high-frequency secondary menu is a first type setting control, the function control in the secondary high-frequency secondary menu is a second type setting control, and when a certain camera mode (such as a photographing mode) in the primary menu is a current mode of camera application, the high-frequency secondary menu (such as zooming) of the camera mode is synchronously displayed above the primary menu; when the electronic equipment receives an operation gesture of a user for calling the secondary high-frequency secondary menu by sliding up, long pressing and the like of the current mode of the camera application, the secondary high-frequency secondary menu of the current mode of the camera application replaces the previously displayed high-frequency secondary menu and is displayed above the primary menu.

That is, after the above adjustment, the user can display each camera mode in the primary menu display area on the screen of the electronic device after turning on the camera function, and simultaneously display the high-frequency secondary menu belonging to the current mode of the camera application (typically, the camera mode located at the center line position of the mobile phone screen) in the primary menu in the secondary menu display area. Then, the user can display a next-highest frequency secondary menu of the current mode of the camera application in the secondary menu display area through a preset gesture applied to the display screen. Therefore, the convenient operation experience of high-frequency single-hand one-step direct and secondary high-frequency single-hand sliding out is realized, and the parameter setting of the camera can be completed in a single-hand easy-operation area.

It should be noted that, in the embodiment shown in fig. 4, the partition lines shown by the solid lines and the dashed lines are only for convenience of describing the display area division in the camera mode of the electronic device, where the partition lines shown by the two dashed lines are not displayed in the actual camera mode, and the area between the partition lines shown by the two solid lines is the scenic spot when the current camera mode is photographing. For convenience of explanation, in the following embodiments, the viewfinder area is marked only by the partition line, and the partition lines of other areas are not particularly marked.

Also, the order and position of the camera modes displayed in the primary menu display area in fig. 4, such as the left-to-right camera mode display shown in fig. 4: large aperture, night scenes, portraits, photographs, videos, movies, professions, more, and the like are also only for exemplary display of the display content of the primary menu display area, and are not limited to the order and position of the camera modes displayed by the primary menu display area, and in different camera applications, the order and position of the camera modes displayed by the primary menu display area can be adjusted. In the following description of the embodiments, the order and position of the camera modes displayed in the primary menu display area of the camera application interface shown in the corresponding drawings are also merely exemplary, and are not limiting of the order and position of the camera modes displayed in the primary menu display area of the camera application interface.

In an embodiment of the present application, the interfaces of the camera application include the first interface described above and other interfaces described below. As shown in fig. 4, the first interface may further include, in addition to the above-described high-frequency functional region: the scenic spot is taken, and the scenic spot can be used for displaying the image acquired by the camera in real time; a shutter area, which may include a shutter control 401, a camera switch control 402, a gallery application shortcut entry 403, and the like; the electronic equipment can take a picture and store a corresponding image in response to the operation of the shutter control by a user, or the electronic equipment can start video recording; responding to the operation of a user on the camera switching control, the electronic equipment can switch the camera for collecting the image, and the image displayed in real time in the view-finding frame can change along with the operation of the user on the camera switching control; in response to a user's operation of applying a shortcut to a gallery, the electronic device may display an interface of the gallery application, display, on the interface of the gallery application, a picture saved in the gallery, related information (such as a photographing time, a photographing place, a photographing parameter, etc.) of the picture, and an operation control for the picture, such as: sharing, collecting, editing, deleting, etc.

In addition, in the embodiment shown in fig. 4, three interface manipulation function keys of the electronic device are also displayed on the screen: a return key 405, a main interface direct key 406, and a multi-interface manipulation key 407. The three interface manipulation function keys are not function keys unique to interfaces of the camera application, but function keys displayed on respective application interfaces of the electronic device. Wherein, in response to the user's operation on the return key 405, the electronic device may display the previous interface of the current interface; in response to a user operation of the home interface direct key 406, the electronic device may display a home interface of the electronic device; in response to a user operation of the multi-interface manipulation key 407, the electronic device may display interfaces of all applications recently running in the electronic device.

For simplicity of the schematic diagrams in the drawings, in the following embodiments of the present application, the three interface manipulation function keys are not specifically identified unless applied.

The high-frequency functional area may be referred to as a first area, and the first interface may be an interface that is displayed vertically when the electronic device is in a vertical screen state, and the shutter area may be an area located at a lowermost portion of the first interface, and the first area may be located at a lower portion of the first interface, for example, the first area may be located above the shutter area. In the electronic device in the landscape state, the first interface is a landscape display interface, the shutter area may be an area located at the leftmost side or the rightmost side of the first interface, and the first area may also be located at the left side or the right side of the first interface, for example, may be adjacent to the shutter area.

Therefore, the electronic equipment is in a single-hand easy-operation area of the display screen of the electronic equipment no matter in a vertical screen state or in a horizontal screen state, and the first-level menu display area for displaying the camera mode controls and the second-level menu display area for displaying the function controls in each camera mode are arranged in the single-hand easy-operation area of the display screen of the electronic equipment. After the camera is started, a user can display each camera mode in a first-level menu display area of the first interface, and simultaneously display a second-level menu of the current camera mode in a second-level menu display area of the first interface, and all camera mode controls and high-frequency function controls are displayed in a single-hand easy-operation area of the electronic device, so that the common function menus of the camera modes are immediately visible, single-hand operation is performed, the operation path is shorter, and the use experience of the user is improved.

The following describes in detail an interaction method of the camera application interface according to the embodiments of the present application with reference to the accompanying drawings.

In one embodiment of the present application, an exemplary process from turning on a camera application to setting a flash state in a photographing mode is shown in fig. 5-1 to 5-7.

Firstly, after a user opens a camera application through clicking operation, the electronic device responds to the clicking operation of the user to display an interactive interface of the camera application, and the interactive interface of the camera application can be an interface in a default photographing mode, as shown in fig. 5-1, or can be a photographing interface in other modes. Here, the operation of clicking the camera application to start is the first interaction event, and the first interface may be the default interface in the photographing mode shown in fig. 5-1, or may be the photographing interface in other modes.

For example, if the user does not open the camera application for a long time, the electronic device displays an interface of the camera application as an interface of a default photographing mode after opening the camera application in response to the user clicking the camera application icon; or the user exits the camera application to the background under the interface of the photographing mode, the camera application is run in the background for a period of time, and if the period of time is less than the preset period of time, for example less than 5s, when the user clicks the camera application icon again or selects the camera application from the multi-task interface, the electronic device displays that the interaction interface of the camera application is still the interface of the photographing mode in response to the operation of the user.

If the user exits the camera application to the background in a camera mode (such as a video recording mode) other than the photographing mode, and runs the camera application in the background for a period of time, if the period of time is less than a preset period of time, such as less than 5s, then when the user clicks the camera application icon again or selects the camera application from the multi-task interface, in response to the operation of the user, the electronic device displays the interactive interface of the camera application as the mode when exiting the foreground to the background this time, such as displaying the interface of the video recording mode. If the length of the period of time during which the camera application is running in the background is greater than a preset length of time, such as greater than 5s, when the user clicks the camera application icon again or selects the camera application from the multi-task interface, the electronic device displays the interface of the camera application as an interface of a default photographing mode in response to the user's operation.

If the interactive interface of the camera application is in other modes such as a video mode and a portrait mode when the interactive interface of the camera application is opened, the user can select the operation (a second interactive event) through the camera mode, namely, the user clicks a photographing mode control in the primary menu or slides the primary menu, so that the photographing mode control is in the middle current mode position, and the electronic equipment responds to the clicking or sliding operation of the user to display the interactive interface of the photographing mode.

In the example shown in fig. 5-1, the controls in the primary menu that are not fully displayed due to the width of the screen itself are automatically partially hidden (more mode controls are shown hidden in fig. 5-1 with a portion) or fully hidden, the zoom 506 in the high frequency secondary menu of the photographing mode is synchronously displayed in the secondary menu display area, while the dash line over the photographing mode control indicates that the secondary high frequency secondary menu of the photographing mode can be displayed by a swipe-up gesture (e.g., a swipe-up gesture is operated at the position of the photographing mode control). The camera status bar area then displays the Ai status (Ai on 513) and the flash status (flash off 514) in the current photographing mode. In the interface shown in fig. 5-1, the user makes a click operation on the zoom 506, and the electronic apparatus brings up and displays a three-level menu of the zoom function in response to the user operation in a manner of replacing the high-frequency two-level menu (zoom 506 in fig. 5-1) previously displayed in the two-level menu display area. At this time, the display of the interface on the screen is shown in fig. 5-6, the display of the camera mode control in the primary menu is unchanged, and the secondary menu display area displays the tertiary menu of the zoom function of the photographing mode.

Because the flash function control of the photographing mode is located in the secondary high frequency menu of the photographing mode, the user makes a slide-up gesture (third interaction event) in the primary menu display area or directly in the viewfinder area of the interface shown in fig. 5-1 to call out the secondary high frequency menu of the photographing mode. The electronic device calls out and displays the secondary high-frequency secondary menu in response to the user's operation in a manner of replacing the high-frequency secondary menu (zoom 506 in fig. 5-1) previously displayed in the secondary menu display area. At this time, the display of the interface on the screen is shown in fig. 5-2, the display of the camera mode control in the primary menu is unchanged, the secondary menu displayed in the secondary menu display area is the secondary menu in the photographing mode, which is sequentially, from left to right, a filter 501, a frame 502, an Ai switch 503 (the current application function, a thickened icon in fig. 5-2), a flash lamp 504 and a setting 505, at this time, a short horizontal line above the Ai switch indicates that the secondary menu can be retracted by sliding down the position, and the high-frequency secondary menu displayed in the secondary menu display area before the display is resumed (the interface is resumed to the interface shown in fig. 5-1).

In another possible implementation of the present application, the user may directly click the flash control in the interactive interface shown in fig. 5-2, and the electronic device displays the interface shown in fig. 5-4 in response to the user's operation, and displays a three-level menu of flash controls in the photographing mode. The third-level menu of the flash function control replaces the secondary high-frequency second-level menu shown in fig. 5-2, and is displayed in the second-level menu display area, four state setting functions of flash on 507, flash normally on 508, flash off 509 and flash automatic 510 are configured in the third-level menu of the flash function control, a user clicks the state setting function control in the third-level menu, and the electronic equipment responds to the operation of the user to complete setting of the photographing flash function. As an example, if the user clicks on the functionality control shown in fig. 5-4: the flash is turned on 507, and the electronic device may set the flash status of the current photographing mode to an on state in response to the user operation, and the camera application interface is changed as shown in fig. 5-5, and is displayed as the flash on state 511 in the camera status bar area.

In another possible implementation manner of the present application, the interaction process of the flash function set by the user may also be the following more rapid manner: the user may directly click the flash 502 in the interactive interface shown in fig. 5-2, and the electronic device displays the interface shown in fig. 5-4 in response to the user's operation, displaying a three-level menu of flash controls in the photographing mode. And the user clicks the state setting function control in the three-level menu, and the electronic equipment responds to the operation of the user to finish setting the photographing flash lamp control.

In another possible implementation, the user may further adjust the flash function to the current application function by directly clicking on the flash function control in the secondary high frequency menu. The electronic device adjusts the flash function to the current application function in response to the user sliding operation (as shown in fig. 5-3). In fig. 5-3, the arrow displayed on the right side of the functionality control indicates that the menu can be slid to the right to display the functionality control (in this embodiment, the filter functionality control) that is not displayed on the left side due to screen limitations. The user may then click on the flash functionality control and the electronic device brings up a three-level menu of flash functionality control in a photographing mode as shown in fig. 5-4 in response to the user's operation.

Camera application interface in the interface shown in fig. 5-2, the user can also call out a three-level menu of filter functions 501 by directly clicking on the filter functions 501 in the next highest frequency two-level menu. And the electronic equipment responds to clicking operation of a user, and brings up a three-level menu of filter function controls in a photographing mode as shown in fig. 5-7.

The third-level menu of the filter function control replaces the secondary high-frequency second-level menu shown in fig. 5-2, the secondary high-frequency second-level menu is displayed in the second-level menu display area, a plurality of filter state setting functions (shown in the second-level menu display area of fig. 5-7) are configured in the third-level menu of the filter function control, a user clicks the state setting function control, and the electronic equipment responds to the operation of the user to finish setting the photographing filter function. As an example, if the user clicks the morning light filter 516 shown in fig. 5-7, the electronic device may set the filter state of the current photographing mode to the morning light filter in response to the user's operation, and display the filter on 515 in the camera state field.

As described above, the specific functions and numbers of the camera mode controls and the function controls in the primary menu, the secondary menu and the tertiary menu can also be configured according to specific products and application requirements. For example, if more functional controls are configured in the secondary high-frequency secondary menu of the photographing mode, so that the current secondary menu display area cannot be completely displayed, a specific prompt can be used to prompt that the area has other functional controls which are not displayed, such as a right arrow symbol shown at the rightmost side in the secondary menu display area of fig. 5-3, so that the secondary high-frequency secondary menu of the photographing mode has other functional controls which are not displayed. The right arrow symbol 512 shown at the leftmost side in the two-level menu display areas of fig. 5-4, 5-5, and 5-7, prompts can be returned from the three-level menu under the flash control to the upper-level menu (back to the next highest frequency two-level menu as shown in fig. 5-2) by clicking the right arrow symbol 512.

After the photo flash control is set, the user may further make a slide-down gesture on the tertiary menu, and the electronic device closes the tertiary menu in response to the user operation, and synchronizes the previously replaced secondary menu with the secondary menu displayed at the same location (e.g., reverts to the interactive interface shown in fig. 5-2). The user may continue to perform a sliding operation in the area of the secondary high frequency secondary menu display in the interface shown in fig. 5-2 or fig. 5-3, such as the user performing a sliding operation in the area of the secondary high frequency secondary menu display, the electronic device closes the secondary high frequency secondary menu in response to the sliding operation of the user, and displays the previously replaced high frequency secondary menu (returning to the camera interaction interface shown in fig. 5-1).

5-1 through 5-7, the user may directly click on any one of the camera mode controls other than the photographing mode control, or slide the one-level menu left and right to bring any one of the camera mode controls other than the photographing mode control into an intermediate current camera mode position, and the electronic device may display the clicked or slide-adjusted camera photographing interface of the camera mode in response to a user operation. Of course, in any of the interfaces of FIGS. 5-2 through 5-7, the user may click directly on the photographing mode control and the electronic device may display the interface shown in FIG. 5-1 in response to user operation. The bold arrows between fig. 5-1 through 5-5 represent a single step through between the interfaces shown in each of the figures, where exemplary changes to the camera application interfaces detailed in the above-described embodiments are shown, as well as changes to camera application interfaces not detailed in some of the above-described embodiments.

In any of the interfaces of fig. 5-1 to 5-7, the user directly clicks the portrait mode control, and the electronic device displays a portrait mode shooting interface as shown in fig. 6-1 in response to a user operation, that is, the electronic device may enable a portrait mode to display the interface as shown in fig. 6-1. At this time, the controls (professional mode controls and more mode controls) which cannot be completely displayed due to the width of the screen in the primary menu are automatically partially or completely hidden (the professional mode is partially hidden and more modes are completely hidden in fig. 6-1), the high-frequency secondary menu corresponding to the portrait mode can be displayed in the secondary menu display area above the primary menu, and the high-frequency secondary menu corresponding to the portrait mode which is synchronously displayed comprises: large aperture 601, zoom 602, and beauty 603. A dash 604 displayed on the portrait mode control is used to prompt a next highest frequency secondary menu that can display portrait mode via a swipe gesture.

The user may invoke a specific function adjustment tertiary menu, such as the large aperture function adjustment tertiary menu shown in fig. 6-2 or the beauty function adjustment tertiary menu shown in fig. 6-3, by clicking a specific function control in the secondary menu.

The user may make a slide-up gesture on the area where the primary menu is displayed in fig. 6-1 or slide up in the viewfinder area, and in response to the user operation, the electronic device brings up a secondary high-frequency secondary menu in portrait mode, where the display on the screen is as shown in fig. 6-5, and the controls corresponding to the blurring 605, the frame 606, the flash 607, and the setting 608 are displayed. The user can click a flash control in the secondary high-frequency secondary menu, in response to the clicking operation of the user, the electronic device can display a tertiary menu of the flash function at the position of the secondary high-frequency secondary menu in the portrait mode, as shown in fig. 6-6, four state setting functions of flash on 609, flash normally on 610, flash off 611 and flash automatic 612 are configured in the tertiary menu of the flash function, the user clicks the state setting function control, and the electronic device completes setting of the portrait flash control in response to the clicking operation of the user. For example, the user clicks on the flash auto 612 of the secondary menu area of fig. 6-6, and the electronic device responds to the clicking operation of the user, and the display on the screen is shown as 6-7, and the flash status in the camera status bar is flash auto 616.

After the flash control is set, the user can close the tertiary menu through a sliding gesture corresponding to the tertiary menu, the electronic device responds to the sliding operation of the user, closes the tertiary menu, and synchronizes the secondary high-frequency secondary menu which is replaced before being displayed at the same position (returning to the camera interaction interface shown in fig. 6-5).

The user may continue to operate the swipe gesture on the secondary high frequency secondary menu, and the electronic device closes the secondary high frequency secondary menu in response to the user's swipe operation and synchronizes the previously replaced high frequency secondary menu to be displayed in the same position (returning to the camera interactive interface as shown in fig. 6-1). The above-mentioned two-slide gesture operation of the user may also be returned directly from the camera application interface shown in fig. 6-6 or fig. 6-7 to the camera application interface shown in fig. 6-1 by directly clicking the portrait mode control in the primary menu.

In the interfaces shown in fig. 6-5, the user may also call out the tertiary menu of the blurring 605 by directly clicking on the blurring 605 in the secondary menu of the next highest frequency. The electronic device brings up a three-level menu of virtual function controls in portrait mode as shown in fig. 6-4 in response to a user sliding operation.

The third-level menu of the blurring function control replaces the secondary high-frequency second-level menu shown in fig. 6-5, the secondary high-frequency second-level menu is displayed in the second-level menu display area, a plurality of blurring setting functions (shown as the second-level menu display area in fig. 6-4) are configured in the third-level menu of the blurring function control, a user clicks the state setting function control, and the electronic equipment responds to the operation of the user to finish setting the blurring of the portrait. As an example, if the user clicks on the circular light effect 613 shown in fig. 6-4, the electronic device may set the blurring of the current portrait mode to a circular light effect in response to the user's operation, and display the blurring state 615 in the camera state field.

The bold arrows between fig. 6-1 to 6-7 represent a single step through between the interfaces shown in each of the figures, wherein the changes to the camera application interfaces detailed in the above embodiments are shown for example, as well as changes to the camera application interfaces not detailed in the above embodiments.

Similarly, the interface displays in the primary menu, the secondary menu, and the recording interface of the video mode are shown in fig. 7-1 to 7-4, respectively. As can be seen from the examples shown in fig. 7-1 to 7-4, the viewing area of the video mode occupies almost the entire screen.

In any of the interfaces shown in fig. 5-1 to 5 or fig. 6-1 to 6-5, the user may click the video mode control directly or slide the menu one level to the left to bring the video mode control to the middle current camera mode position, and the electronic device displays the shooting interface of the video mode in response to the user operation, that is, the electronic device may enable the video mode to display the interface shown in fig. 7-1. At this time, a camera mode control (large aperture mode control) which cannot be completely displayed in the primary menu display area due to the width of the screen in the primary menu is automatically hidden, a high-frequency secondary menu corresponding to a video mode can be synchronously displayed in the secondary menu display area, and the high-frequency secondary menu corresponding to the video mode which is synchronously displayed can comprise: large aperture 701, zoom 702, and beauty 703. A dash 704 over the record mode control indicates that a next highest frequency secondary menu of record modes may be displayed via a swipe gesture. In the example shown in fig. 7-1, the camera state of the current recording mode includes: resolution, frame rate 1080, 30, flash off 717.

The user can click the shutter control 705 in the camera mode (video mode) shown in fig. 7-1 or fig. 7-2, fig. 7-3 or fig. 7-5, the electronic device enters a recording state in response to a user operation, the corresponding interface display is shown in fig. 7-4, and in the recording state shown in fig. 7-4, the zoom function (the function control in the original secondary menu) is displayed at the position of the primary menu, and during the video recording, the user can also adjust the focal length through the zoom control. In the interface shown in fig. 7-4, the user may click a pause control 706 or an end video control 707, and in response to a user operation, the electronic device pauses or ends video, after which the electronic device may save the recorded video.

The user may also make a slide-up gesture on the area or viewing area where the primary menu is displayed in the camera mode shown in fig. 7-1, and the electronic device calls out a secondary high-frequency secondary menu of the video mode in response to the user operation, where the secondary high-frequency secondary menu of the video mode is displayed with a filter 708, a frame 709, a resolution frame rate 710, a flash 711, and controls corresponding to the settings 712, as shown in fig. 7-2. The user can click a flash control in the high-frequency secondary menu displayed in fig. 7-2, the electronic device displays a three-level menu of flash functions at the position of the secondary high-frequency secondary menu in the video mode in response to the clicking operation of the user, as shown in fig. 7-3, the three-level menu of flash functions is configured with four state setting functions of flash on 713, flash normally on 714, flash off 715 and flash automatic 716, the user clicks the state setting function control, and the electronic device completes flash function setting of the video mode in response to the clicking operation of the user. For example, in the embodiment shown in fig. 7-3, the user clicks on the flash auto 716, and the electronic device displays the flash status of the video mode from flash off 717 shown in fig. 7-3 to flash auto 718 shown in fig. 7-5 in response to the user's click operation.

The user clicks the video mode control on any interface shown in fig. 7-2, 7-3 or 7-5, and the electronic device responds to the user operation to display the video image mode shooting interface shown in fig. 7-1, that is, the electronic device can enable the video mode to display the interface shown in fig. 7-1.

The bold arrows between fig. 7-1 through 7-5 represent a single step through between the interfaces shown in each of the figures, wherein the exemplary changes to the camera application interfaces detailed in the above-described embodiments are illustrated, as well as changes to the camera application interfaces not detailed in the above-described embodiments are partially illustrated.

In any of the interfaces shown in fig. 5-1 to 5 or fig. 6-1 to 6-5 or fig. 7-1 to 7-3, the user may click directly on the movie mode control displayed in the primary menu or slide the primary menu to the left with the movie mode control in the middle current camera mode position, and the electronic device may display an interactive interface for the movie mode in response to user operation, such as in one possible embodiment of the present application, an interactive interface for the movie mode as shown in fig. 8-1. In this embodiment, the camera mode control (large aperture mode control, night scene mode control, portrait mode control) in the primary menu which cannot be completely displayed in the primary menu display area due to the width of the screen is automatically completely or partially hidden (in fig. 8-1, the large aperture mode control and the night scene mode control are completely hidden, the portrait mode control is partially hidden), and the short horizontal line above the movie mode control indicates that the secondary high-frequency secondary menu of the movie mode can be displayed through the up-slide gesture. The high-frequency secondary menu corresponding to the film mode can be synchronously displayed in the secondary menu display area, and the high-frequency secondary menu corresponding to the film mode synchronously displayed comprises: large aperture 801, zoom 802, and beauty 803. In the example shown in fig. 8-1, the camera states of the current movie mode include: LUT filter on 804, resolution/frame rate 805, flash off 806.

The user may also make a slide-up gesture on the movie mode control in the camera mode shown in fig. 8-1 to call out a secondary high frequency secondary menu of the movie mode, the electronic device responds to the user operation, displays the secondary high frequency secondary menu of the movie mode, and on the screen, as shown in fig. 8-2, controls corresponding to slow actions 807, LOG808, LUT809, frame 810 and resolution frame rate 811 are displayed in the secondary high frequency secondary menu of the movie mode, and part of the functional controls (such as a flash lamp and a setting) cannot be displayed in fig. 8-2 due to the limitation of the screen width.

In the embodiment shown in fig. 8-2, the centrally displayed LUT functionality setting control is the current application control. The user can set the LUT filters of the movie mode by clicking the LUT function in the secondary high frequency secondary menu, the electronic device displays the tertiary menu of the LUT function at the position of the secondary high frequency secondary menu of the movie mode in response to the clicking operation of the user, and simultaneously displays the example corresponding to the currently selected LUT filter in the view-finding area, as shown in fig. 8-3, the tertiary menu of the LUT function is configured with a plurality of LUT filters (only 3 are displayed in fig. 8-3 due to the limitation of the screen width, and other hidden LTU filters can be displayed by sliding the tertiary menu left and right), the user clicks one of the LUT filters, and the electronic device can complete the LUT filter setting of the movie mode in response to the clicking operation of the user. In the embodiment shown in fig. 8-3, the user clicks on the "mystery border" filter, and the electronic device displays the LUT filter of the movie mode in the viewfinder area as "mystery border" in response to the clicking operation by the user.

It should be noted that, in the embodiment shown in fig. 8-3, the pattern in the filter is only exemplary, and does not represent the filter pattern in practical application.

In the camera interactive interface shown in fig. 8-3, the user can also close the tertiary menu of the LUT function by a slide-down gesture to the tertiary menu of the LUT function, and the electronic apparatus closes the tertiary menu of the LUT function in response to the slide-down operation by the user and synchronizes the next highest frequency secondary menu that was previously replaced (returning to the camera interactive interface shown in fig. 8-2) for display at the same location. In the camera interactive interface shown in fig. 8-2, the user may then continue to operate the swipe gesture on the secondary high frequency secondary menu, and the electronic device closes the secondary high frequency secondary menu in response to the user's swipe operation and synchronizes the high frequency secondary menu that was previously replaced (displaying the camera interactive interface shown in fig. 8-1) with the same location. The above two-time slide gesture operation of the user may also be performed by directly clicking the movie mode control in the primary menu, and returning from the camera interactive interface shown in fig. 8-2 or fig. 8-3 to the camera interactive interface display shown in fig. 8-1.

The camera interaction interfaces shown in fig. 8-1 and 8-3 are respectively displayed as the camera interaction interfaces shown in fig. 8-4 and 8-5 when the electronic device is in a landscape application mode. In one possible embodiment of the present application, a multi-mirror video control may also be displayed in a primary menu.

An example of a multi-mirror video control configured in a primary menu is shown in fig. 9-1 through 9-3. In the camera application interface displayed with the primary menu, the user directly clicks the multi-mirror video control displayed in the primary menu or slides the primary menu to enable the multi-mirror video control to be positioned in the middle current camera mode position, and the electronic equipment responds to the operation of the user to display a shooting interface of the multi-mirror video mode, namely the electronic equipment can enable the multi-mirror video mode to display the interface shown in fig. 9-1. At this time, the camera mode control in the primary menu which cannot be completely displayed in the primary menu display area due to the width of the screen is automatically hidden, and the high-frequency secondary menu corresponding to the multi-mirror video recording mode is synchronously displayed in the secondary menu display area, wherein the high-frequency secondary menu (the display sequence in fig. 9-1 is from left to right) comprises: multi-mirror mode switch 901, zoom 902, and beauty 903. In the example shown in fig. 9-1, the camera status of the current multi-mirror recording mode displayed in the camera status bar field includes: multiple mirrors on 904, resolution, frame rate 905, flash off 906.

The viewing area of the multi-lens video recording occupies the whole screen, the viewing area comprises an upper part and a lower part, and images displayed in the two part viewing areas correspond to images respectively shot by a front camera and a rear camera of the electronic equipment. In the camera interactive interface shown in fig. 9-1, the user initiates an interface interactive event through a sliding operation of a single-hand sliding multi-mirror video control, and the electronic device displays a secondary high-frequency secondary menu of a multi-mirror video mode as shown in fig. 9-2 in a secondary menu display area in response to the user operation: a clear mirror 907, a photo scale 908, a resolution/frame rate 909, a flash 910, and controls corresponding to the settings 911.

The user clicks a multi-mirror mode switch 901 function control in the secondary high-frequency secondary menu at the interface shown in fig. 9-1, and the electronic device responds to the operation of the user to display a tertiary menu of the multi-mirror mode switch 901 in a mode of replacing the high-frequency secondary menu displayed in the secondary menu display area before: multi-mirror mode. At this time, as shown in fig. 9-3, the display of the camera mode control in the primary menu is unchanged, the display of the secondary menu display area is a multi-mirror mode with a multi-mirror function of a multi-mirror video mode, and in the multi-mirror mode shown in fig. 9-3, five multi-mirror modes are displayed: picture-in-picture, back, front-to-back, single front. It should be noted that, in the embodiment shown in fig. 9-3, the patterns in the multi-mirror mode and in the scenic spot are only used for exemplary display, and do not represent the multi-mirror video pattern in practical application. The user clicks the multi-mirror video mode control in the camera application interface shown in fig. 9-3, and the electronic device displays the camera application interface shown in fig. 9-1 in response to the user operation.

In one possible embodiment of the present application, the user may also click a photographing mode control in the camera application interface shown in fig. 9-3, and the electronic device displays the camera application interface shown in fig. 5-1 in response to the operation of the user; the user clicks the video mode control in the camera application interface shown in fig. 9-3, and the electronic device displays the camera application interface shown in fig. 7-1 in response to the user's operation. The user starts multi-mirror recording by clicking the start multi-mirror recording shutter 912 of the shutter area of any one of the camera application interfaces of fig. 9-1, 9-2, and 9-3, and the electronic device responds to the clicking operation of the user to start multi-mirror recording, and displays the recording interface of the multi-mirror recording as shown in fig. 9-4. In the shutter area shown in fig. 9-4, the leftmost control is a multi-mirror photographing control 913, which is used for synchronously photographing in the multi-mirror video recording process; in the middle are video controls, including a termination function key 914 and a pause function key 915; the rightmost side is a camera inversion control 916 for inversion of front and rear cameras of the electronic device.

In one possible embodiment of the present application, the camera application interface when the current camera mode of the camera application is the professional mode is as shown in fig. 10-1 to 10-4.

If the interactive interface of the camera application is in a mode other than the professional mode when the interactive interface of the camera application is opened, the user can select the operation (a second interactive event) through the camera mode, namely, the user clicks the professional mode control in the primary menu or slides the primary menu, so that the professional mode control is in the middle current mode position, and the electronic equipment responds to the clicking or sliding operation of the user to display the interactive interface of the professional mode. At this time, in the example shown in fig. 10-1, the controls which cannot be completely displayed in the primary menu due to the sliding of the menu and the width of the screen itself are automatically partially or completely hidden, and the professional parameters in the high-frequency secondary menu of the professional mode are adjusted 1002 to be synchronously displayed in the secondary menu display area, wherein the professional parameters include: a light metering mode M, a light sensitivity ISO, a shutter speed S, an exposure compensation EV ', a focusing mode AF ' and a white balance WB '; a zoom 1001 of a high-frequency secondary menu of the professional mode is displayed above the secondary menu display area. The dash line over the specialty mode control then indicates that a next highest frequency secondary menu of specialty modes may be displayed via a swipe-up gesture (e.g., a swipe-up gesture operated at the location of the specialty mode control). The camera status field then displays the flash status in the current professional mode (flash off 1003).

In the interface shown in fig. 10-1, the user makes a click operation on the white balance WB ', and the electronic device brings up and displays a three-level menu of the white balance WB' in response to the user operation in a manner of replacing the high-frequency two-level menu (the proprietary parameter adjustment 1002 in fig. 10-1) previously displayed in the two-level menu display area. At this time, as shown in fig. 10-2, the display of the camera mode control in the first-level menu is unchanged, the third-level menu 1004 of the white balance WB' is displayed on the interface instead of the professional parameter adjustment 1002 in the high-frequency second-level menu, and the zoom 1001 of the high-frequency second-level menu is displayed above the menu set by the white balance WB. In the display interface of the camera application shown in fig. 10-2, the tertiary menu of the white balance WB' displayed in the secondary menu display area includes different weather icons for setting the white balance.

In the interface shown in fig. 10-1, the user makes a click operation on the exposure compensation EV', and the electronic device displays the camera application interface shown in fig. 10-3 in response to the operation of the user. As shown in fig. 10-3, in professional parameter adjustment 1002 in the high-frequency secondary menu displayed in the secondary menu display area, the exposure compensation EV function control is highlighted, which indicates that the exposure compensation EV function control is a current application function control in the camera application mode, and the primary menu display area displays an exposure value adjustment interface, instead of the primary menu shown in fig. 10-1.

In the interface shown in fig. 10-1, the user makes a slide-up gesture (third interaction event) in the primary menu display area or directly in the viewfinder area of the interface shown in fig. 10-1, and can call out a secondary high-frequency secondary menu of the professional mode. The electronic apparatus calls out and displays the sub-high-frequency secondary menu 1005 in response to the user's operation in a manner of replacing the high-frequency secondary menu previously displayed in the viewing area. At this time, as shown in fig. 10-4, the display of the camera mode control in the primary menu is unchanged, and the secondary menu display area displays a secondary high-frequency secondary menu 1005 in a professional mode, which is sequentially from left to right: JPG, flash, set, flash, and set.

Then, the user can directly click the JPG or the flash lamp in the secondary high-frequency secondary menu or set the mode of the function control, and the electronic equipment responds to the click operation of the user to display the tertiary menu of the JPG or the flash lamp or the set function control in the professional mode.

In the embodiment of the present application, the configuration of other camera modes in the primary menu and the conversion calling manner between the functional controls in the primary menu and the menu are similar, and will not be described in detail here.

In addition, it should be noted that more modes in the first-level menu are a special type of control used for packing and placing camera modes which can be independently used as camera modes and are not commonly used, so that the mode range of the camera is expanded more. Thus, in one embodiment of the present application, when a more mode control is located at the position of the current mode control of the camera application, all camera mode controls under the more mode control are synchronously displayed in the form of a slider bar in the secondary menu display area, and these camera mode controls may all be regarded as controls in the high-frequency secondary menu in the display manner. In response to a user operation, after the electronic device selects a certain camera mode control in the more mode controls, the selected camera mode control can be used as a primary control to be displayed at the position of the more mode control in the primary menu to replace the display of the more mode controls, in addition, an auxiliary return control can be displayed on the right side of the selected high-frequency function control, and the auxiliary return control is used for returning the selected high-frequency function control to the auxiliary return control on the right side of the time-lapse photography, such as the auxiliary return control on the right side of the time-lapse photography shown in fig. 11. The user turns off the time-lapse photography mode and returns to the display of the more mode control by assisting a return control or other preset gesture (e.g., a preset hover control gesture).

In the above embodiment, the large aperture control in the first-level menu in the related technology is also set in the portrait control, video control and movie control needing to use the large aperture function as the configuration of the high-frequency second-level menu, so that the night scene control is put in the range of more controls, and the calling of the large aperture control is more convenient. In addition, aiming at the problems that the function control arranged at the top of the screen of the electronic equipment is inconvenient to operate by one hand and the two-level menu positioned in the single-hand easy operation area is too simple in the related technology, the embodiment of the application also takes the function control such as 'setting', 'flash lamp', 'JPG', 'slow action' and the like positioned at the top of the screen of the related technology as the single-hand easy operation area of the screen, thereby not only overcoming the problem that the top shortcut switch cannot be completed by one hand in the related technology, but also effectively expanding the display area of the scenic spot due to releasing the shortcut switch originally displayed at the top of the screen, and displaying the secondary high-frequency two-level menu at the display position of the original high-frequency two-level menu in a mode of replacing the display mode of the high-frequency two-level menu, and occupying more display space in the single-hand easy operation area at the bottom of the electronic equipment.

In addition, in the embodiment of the application, the primary menu, the secondary menu and the tertiary menu are respectively arranged and displayed in the primary menu display area and the secondary menu display area in a sliding bar mode, and a camera mode control and a function control which are positioned in the center of the high-frequency function area are used as current application controls. The sorting control of the control can basically meet the requirement that the menu of each level can be completely presented in the corresponding menu display area.

Therefore, the embodiment of the application carries out more reasonable classification control on the high-frequency functional control of the camera according to the use frequency of each control of the camera, the control habit of the user and other factors, so that the common function of the camera control in each mode is single-handed to operate, the path is shorter, and the use experience of the user is effectively improved.

In practical application, because the usage habits and application requirements of all people are different, the application state of electronic equipment such as a mobile phone can be a horizontal screen state or a vertical screen state, so in order to determine the camera application interface interaction mode of the electronic equipment, firstly, the application mode of the electronic equipment needs to be determined based on a built-in sensor of the electronic equipment, and then, the camera control configuration area of the electronic equipment is determined based on the application mode; the application modes comprise a vertical screen application mode and a horizontal screen application mode. There are many means for determining the application mode of the electronic device, for example, according to whether the electronic device is in a landscape screen state or in a portrait screen state, the relative horizontal or vertical positional relationship of the sensors disposed at different positions inside the electronic device may be changed, or whether the mobile phone is in the landscape screen state or in the portrait screen state may also be determined by a specific sensor.

As shown in fig. 1-1 and fig. 1-2, the mobile phone has a slight difference in the single-hand easy-to-operate area in the vertical screen application mode and the horizontal screen application mode, so that the application mode of the electronic device is determined not only for identifying the operation action of the user in the later period, but also for determining the interaction area of the application interface of the camera more accurately, so that the single-hand operation is facilitated.

In a specific embodiment of the application, when the electronic device determines that the electronic device is in a portrait application mode through a sensor arranged inside the electronic device, an operation gesture of a user calling the tertiary menu and the secondary high-frequency secondary menu is a slide-up gesture. The electronic equipment responds to the user operation and displays a three-level menu of the function control to replace the high-frequency two-level menu displayed in the two-level menu display area before; and the electronic equipment responds to the user operation, and displays a secondary high-frequency secondary menu of the current camera mode in a secondary menu display area to replace the high-frequency secondary menu displayed in the secondary menu display area before. And in the camera interactive interface displayed with the tertiary menu or the secondary high-frequency secondary menu, the user clicks a return key or operates a downward sliding gesture opposite to the upward sliding gesture, the electronic equipment responds to the user operation, closes the tertiary menu or the secondary high-frequency secondary menu, and synchronizes the secondary menu replaced before being displayed in the secondary menu display area.

The above embodiments are camera interaction embodiments in which the electronic device is in a portrait application mode. The two camera interaction interfaces in the photographing modes shown in fig. 5-1 and 5-2 are shown in fig. 12-1 and 12-2 when the electronic device is in the horizontal screen application mode.

When the electronic equipment determines that the electronic equipment is in a transverse screen application mode through a sensor arranged in the electronic equipment, the user invokes the operation gesture of the three-level menu and the secondary high-frequency secondary menu to be a transverse outer sliding gesture. The electronic equipment responds to the lateral outward sliding operation of the user to display a three-level menu of the functional control so as to replace the high-frequency two-level menu displayed in the two-level menu display area before; the user slides a camera mode control in the primary menu laterally outwards, and the electronic equipment responds to the user operation and displays the secondary high-frequency secondary menu of the current camera mode in the secondary menu display area to replace the high-frequency secondary menu displayed in the secondary menu display area before. In the camera interactive interface displayed with the tertiary menu or the secondary high-frequency secondary menu, the user can click a return key or operate a lateral inner sliding gesture opposite to the lateral outer sliding gesture, and the electronic equipment responds to the user operation, closes the tertiary menu or the secondary high-frequency secondary menu and synchronizes the secondary menu replaced before being displayed in the secondary menu display area. The secondary menu displayed here may be a high-frequency secondary menu or a second-highest-frequency secondary menu. For example, if the closed tertiary menu is a tertiary menu of the function controls in the secondary high-frequency secondary menu, the secondary high-frequency secondary menu of the previous stage of the tertiary menu is displayed after the tertiary menu is closed; if the three-level menu of the function control in the high-frequency two-level menu is closed or the secondary high-frequency two-level menu is closed, after the three-level menu and the secondary high-frequency two-level menu are closed, the menu displayed in the two-level menu display area is the high-frequency two-level menu of the upper level of the three-level menu or the high-frequency two-level menu which belongs to the same camera mode with the secondary high-frequency two-level menu.

Further, considering the habit of the user when using the mobile phone, the user operation habit can be divided into a left-hand operation habit and a right-hand operation habit, wherein the left-hand operation habit refers to that the user is usually used to operate by using the left hand when operating the terminal by using one hand, and the right-hand operation habit refers to that the user is usually used to operate by using the right hand when operating the terminal by using one hand. The operation habit of the user can be preset by the user according to the use habit of the user, and the operation mode of the electronic equipment operated by the user can be influenced by different operation habits. In general, for electronic devices in a vertical screen application mode, the left-hand operation habit and the right-hand operation habit are not greatly different from each other for the specific operation mode of operating the electronic device; however, for electronic devices in the landscape mode, the left-hand and right-hand operating habits are opposite to the direction of the operating gesture for a particular operating electronic device.

The operation mode of the camera application interface shown in fig. 12-1 and 12-2 is a right-hand operation mode that most users are accustomed to, and the sliding direction of the lateral outside sliding gesture is leftward and the sliding direction of the lateral inside sliding gesture is rightward. For the user of the left-handed electronic device, the camera application interface of the electronic device may be operated with an operation gesture opposite to the right-handed operation gesture direction shown in the above-described embodiment, or the display of the high-frequency menu area in the camera application interface of the electronic device may also be controlled in the same manner as the right-handed operation gesture direction.

Therefore, in a specific embodiment of the present application, before determining the camera interaction interface of the electronic device, it may be further determined whether the manipulation mode of the electronic device is the left-hand mode or the right-hand mode based on the built-in sensor of the electronic device. There are a number of specific means of determining the manipulation mode of an electronic device, for example, whether the electronic device is operated by one hand or two hands, left hand or right hand, may be determined by a sensor provided at a corner position of the electronic device. Specifically, as an example, when the user operates the electronic device with one hand in the left hand, the left hand is usually closer to the lower left corner of the electronic device, so that the sensing result of the sensor located in the lower left corner of the electronic device is that the target is sensed, and the sensing result of the sensor located in the lower right corner of the electronic device is that the target is not sensed, thereby determining that the operation mode of the user operating the electronic device is left-hand one-hand operation, and the operation mode is left-hand mode. The right-hand mode is judged in a similar manner and will not be described in detail herein.

Then, for the electronic equipment in the horizontal screen application mode, when the control mode of the electronic equipment is a left-hand mode, according to the general action habit, the user performs interactive operation of the camera application interface through a horizontal right-side sliding gesture, and the electronic equipment responds to the horizontal right-side sliding operation of the user to display a three-level menu of the function control so as to replace a high-frequency two-level menu displayed in a two-level menu display area before; and in the camera interactive interface displayed with the tertiary menu or the secondary high-frequency secondary menu, the user can close the tertiary menu and the secondary high-frequency secondary menu through a transverse left sliding action opposite to the transverse right sliding gesture direction, and the electronic equipment responds to the transverse left sliding operation of the user, closes the tertiary menu and the secondary high-frequency secondary menu and synchronizes the secondary menu before being displayed in the secondary menu display area. Also, the secondary menu displayed here may be a high frequency secondary menu or a second highest frequency secondary menu.

Of course, the user can also achieve the above-mentioned operation purpose through the return key on the camera interactive interface.

For electronic devices in the landscape mode, when the manipulation mode of the electronic device is the right hand mode, the interaction of the camera application interface is as described above for the embodiments shown in fig. 12-1 and 12-2, and the description is not repeated here.

As a specific example, the camera application interface interaction area of the embodiment of the present application further includes a shutter area disposed at the bottom end of the display screen of the electronic device and a camera status bar area disposed at the top end of the display screen of the electronic device, where the camera status bar area displays a resident switch (such as a flash switch) of the camera and a functional status that indicates a real-time status of a current mode of the camera, and specific display contents of the functional status are different according to functional status settings of different modes of the camera, and are mainly used for displaying various statuses (such as a flash, ai, resolution frame rate, picture, filter, etc.) in the current camera mode, so that a user can timely understand the various statuses in the current camera mode. Because the camera state does not have to be manually manipulated, it is displayed on the top of the display screen of the electronic device to be distinguished from the manual manipulation control displayed on the bottom of the display screen of the electronic device.

For example, in the embodiment of the camera interaction interface shown in fig. 5-4, the current camera mode shown in the camera status bar area is the camera status in the case of a photographing mode, a flash function: ai is on and the flash is off. It should be noted that, the user operates to modify or set the state of the camera function, and the electronic device, in response to the user operation, acts the modified or set state of the function on the photographing mode, and the real-time state displayed in the camera status bar area is the state that is to be modified or set. Setting the state of the picture on the camera interactive interface shown in the user fig. 5-4, the flash lamp function three-level menu (returning to the camera interactive interface shown in fig. 5-3) can be closed, the secondary high-frequency secondary menu displayed in a sliding manner to the right or the picture function control is clicked directly, the picture function in the secondary high-frequency secondary menu is moved to the central line position of the screen, and the picture function control is slid upwards. The electronic equipment responds to the user operation, and calls out the three-level menu of the picture function so as to set the picture state of shooting by the user, the set picture state is simultaneously acted on a shooting mode, and the real-time state displayed in the camera state column area is increased by the corresponding picture state relative to the example shown in fig. 5-4.

In the interaction method based on the camera application interface of the electronic device in the embodiment of the invention, the area division of the display screen of the electronic device is not fixed, especially the area occupied by the scenic spot is taken, and the area occupied by the scenic spot on the screen of the whole electronic device can be adjusted according to a specific camera mode.

For example, when the current camera mode displayed in the primary menu display area is a portrait mode or a photo mode, the shutter area, the camera status bar area, and the primary menu display area are displayed outside the view-finding area of the display screen of the electronic device, and the secondary menu display area of the photo mode is within the view-finding area of the display screen of the electronic device, as shown in fig. 6-1 to 6-7 and examples of fig. 5-1 to 5-7;

when the current camera mode of the camera application displayed in the primary menu display area is a video mode, the camera status bar area is displayed outside the view-finding area of the display screen of the electronic device, and the shutter area, the primary menu display area and the secondary menu display area of the video mode are displayed in the view-finding area of the display screen of the electronic device, as shown in fig. 7-1 to 7-5;

when the current camera mode of the camera application displayed in the primary menu display area is the movie mode, the display screen of the whole electronic device is the view finding area, and all the controls of the camera are displayed in the view finding area, as shown in fig. 8-1 to 8-5.

Based on the above embodiments, the interaction method of the camera application interface provided in the present application may include:

the electronic equipment receives a first interaction event;

the electronic equipment responds to the first interaction event and displays a first interface of the camera application interface; the first subarea of the first interface comprises a plurality of camera mode controls and a current first mode of camera application, and the second subarea of the first interface comprises a first type of setting control corresponding to the first mode;

the electronic device receives a second interaction event aiming at the first interface;

the electronic equipment responds to a second interaction event and displays a second interface of the camera application interface; wherein,

the first subarea of the second interface comprises a plurality of camera mode controls and a current first mode of camera application, a second type of setting control corresponding to the first mode is displayed in the second subarea of the second interface, and the first type of setting control corresponding to the first mode is replaced.

Since the area where the shutter is located at the bottom end of the screen, the first sub-area and the second sub-area adjacent to the area where the shutter is located are also in the one-hand easy-operation area of the electronic device. Therefore, if each camera mode displayed in the first sub-area is regarded as a first-level menu of the camera application, the first type of setting control displayed in the first sub-area is regarded as a high-frequency second-level menu of the camera application, the second type of setting control displayed in the second sub-area and in the first sub-area adjacent to the shutter area is regarded as a second high-frequency second-level menu of the camera application, after the camera function is started, the user can display the high-frequency second-level menu of the camera application and the menu in the first sub-area adjacent to the shutter area in the screen of the electronic device, and simultaneously display the high-frequency second-level menu of the camera application in the second sub-area adjacent to the first sub-area, and the user can replace the high-frequency second-level menu with the second high-frequency second-level menu of the camera application by a preset gesture, for example, the user can well experience the second-level menu is not occupied by the second-level control, and the user can not display the high-level menu in the second-level menu.

Therefore, when the user directly reaches the high-frequency secondary menu through one hand, the high-frequency secondary menu can be replaced by the secondary high-frequency secondary menu in the current mode through the camera in the secondary menu display area by the preset gesture, so that the convenient operation experience of single-hand calling of the secondary high-frequency secondary menu is realized, the secondary high-frequency secondary menu called by one hand is also displayed in the single-hand operable area, and the operation of the secondary high-frequency secondary menu can be continued in the later period conveniently.

Specifically, as an example, the second interaction event may be an operation of the user to slide the camera application current mode control on the first interface, such as a slide-up operation in the secondary menu area, a slide-up operation in the viewfinder area, or the like. For example, when the current camera mode is the professional mode, the user slides up the professional mode control (or the secondary menu area corresponding to the professional mode), and in the displayed second interface, the secondary high-frequency secondary menu corresponding to the professional mode is displayed in the secondary menu display area: JPG, flash, set, replace the high frequency secondary menu of the professional mode corresponding to the first mode. In one possible implementation manner, the interaction method of the camera application interface provided by the application further comprises the following steps: the electronic equipment receives a third interaction event aiming at the second interface;

The electronic equipment responds to a third interaction event and displays a third interface of the camera application interface; wherein,

the first subarea of the third interface comprises a plurality of camera mode controls and a current first mode of camera application, a menu corresponding to a second setting control corresponding to the first mode is displayed in the second subarea of the third interface, and the second type setting control corresponding to the first mode is replaced; the second setting control is any one of second type setting controls corresponding to the first mode.

In one possible implementation manner, the interaction method of the camera application interface provided by the application further comprises the following steps: the electronic equipment receives a fourth interaction event aiming at the first interface;

the electronic equipment responds to the fourth interaction event and displays a fourth interface of the camera application interface; wherein,

the first subarea of the fourth interface comprises a plurality of camera mode controls and a current first mode of camera application, a menu corresponding to a first setting control corresponding to the first mode is displayed in the second subarea of the fourth interface, and the first type setting control corresponding to the first mode is replaced; the first setting control is any one of first type setting controls corresponding to the first mode.

The menu corresponding to the first setting control corresponding to the first mode and the menu corresponding to the second setting control corresponding to the first mode can be regarded as three-level menus of the camera application, so that a user can replace a corresponding high-frequency two-level menu or a sub-high-frequency two-level menu with the three-level menu of the camera application in the second sub-area through a preset gesture, for example, the interface shown in fig. 5-2 is operated to the interface shown in fig. 5-3, the interface shown in fig. 6-1 is operated to the interface shown in fig. 6-2 and the interface shown in fig. 6-3, and the interface shown in fig. 6-5 is operated to the example of the interface shown in fig. 6-6.

Therefore, when the user directly reaches the high-frequency secondary menu through one hand, the high-frequency secondary menu can be replaced by the three-level menu of the function control in the high-frequency secondary menu in the secondary menu display area through the preset gesture, and the secondary high-frequency secondary menu is replaced by the three-level menu of the function control in the secondary high-frequency secondary menu, so that the convenient operation experience of single-hand calling of the three-level menu is realized, the three-level menu called by one hand is also displayed in the single-hand operable area, and the operation of the three-level menu is convenient to continue in the later period.

Specifically, as an example, the third interaction event and the fourth interaction event may be operations of clicking the high-frequency secondary menu or the functionality control in the secondary high-frequency secondary stope displayed in the secondary menu display area on the first interface or the second interface by the user.

For example, when the current camera mode is a portrait mode, the function controls in the high-frequency secondary menu displayed in the secondary menu display area are: zooming, beautifying and large aperture, clicking the beautifying function control of the secondary menu display area by a user, displaying a tertiary menu of the beautifying function control in the secondary menu display area in a fourth displayed interface, adjusting the beautifying parameters of the portrait mode by the user through the tertiary menu, and replacing the corresponding high-frequency secondary menu by the tertiary menu.

For another example, when the current camera mode is a portrait mode, the function controls in the secondary high-frequency secondary menu displayed in the secondary menu display area are: the method comprises the steps of a filter, a frame, a flash lamp and settings, wherein a user clicks a flash lamp function control in a secondary menu display area, and a tertiary menu of the flash lamp function control is displayed in the secondary menu display area in a displayed third interface: the flash lamp is started, the flash lamp is always on, the flash lamp is closed, the flash lamp is automatic, a user can adjust the flash lamp state of the portrait mode through the three-level menu, and the three-level menu replaces the corresponding secondary high-frequency two-level menu.

In one possible implementation manner of the present application, the method further includes: the electronic equipment receives a fifth interaction event aiming at any one of the second interface, the third interface or the fourth interface;

the electronic equipment responds to the fifth interaction event and displays a fifth interface of the camera application interface; wherein,

the first subarea of the fifth interface comprises a plurality of camera mode controls and a first mode or a second mode of the camera application, and the second subarea of the fifth interface displays a first type of setting control corresponding to the first mode or the second mode.

Therefore, a user can directly display the interface to the selected camera mode by clicking any one of the camera mode controls in the first subarea on any one of interfaces of the camera application, and display the first type of setting controls of the camera mode in the second subarea, so that the mode switching operation is simple and quick. If the clicked camera mode control is a current mode control of the camera application in the first subarea, the second subarea displays a first type of setting control corresponding to the current mode (first mode) of the camera application; if the clicked camera mode control selected by the user is a mode control in the first subarea except for the current mode control of the camera application, the second subarea displays a first type of setting control corresponding to the clicked camera mode (second mode) of the user. For example, in any one of the interfaces of fig. 5-1 to 5-7 in the foregoing embodiments, the user clicks the portrait mode control, and the electronic device displays an example of a portrait mode shooting interface as shown in fig. 6-1 in response to a user operation.

In one possible implementation manner of the present application, the method further includes: the electronic equipment responds to the sixth interaction event and displays a sixth interface of the camera application interface; the first subarea of the sixth interface comprises a plurality of camera mode controls and a current first mode of the camera application, and the second subarea of the sixth interface displays a second type of setting control corresponding to the first mode.

Therefore, after the camera application interface displays the tertiary menu of the secondary high-frequency secondary menu, the user can return to the secondary high-frequency secondary menu again through a preset gesture. For example, the previous embodiments return from the interfaces shown in FIGS. 5-3 and 5-4 to the examples of interfaces shown in FIG. 5-2.

In one possible implementation manner of the application, the fourth interface further includes a second area, the second area is located on the side opposite to the area where the shutter is located on the fourth interface, the menu corresponding to the first setting control includes a plurality of first sub-controls,

the method further comprises the following steps:

the electronic device receives a seventh interaction event of one of the plurality of first sub-controls on the fourth interface;

the electronic equipment responds to a seventh interaction event, a seventh interface of the camera application interface is displayed, a first subarea of the seventh interface comprises a plurality of camera mode controls and a current first mode of the camera application, a menu corresponding to a first setting control corresponding to the first mode is displayed in a second subarea of the seventh interface, and a state icon corresponding to one first sub control is displayed in a second area of the seventh interface.

In one possible implementation manner of the application, the third interface further includes a second area, the second area is located on the opposite side of the third interface to the area where the shutter is located, the menu corresponding to the second setting control includes a plurality of second sub-controls,

the method further comprises the following steps:

the electronic device receives an eighth interaction event for one of the plurality of second sub-controls on the third interface;

the electronic equipment responds to an eighth interaction event, an eighth interface is displayed, wherein a first subarea of the eighth interface comprises a plurality of camera mode controls and a current first mode of camera application, a menu corresponding to a second setting control corresponding to the first mode is displayed in a second subarea of the eighth interface, and a state icon corresponding to one second sub control is displayed in a second area of the eighth interface.

Because the shutter is positioned at the top end of the display screen on the opposite side of the area, only the camera state is displayed at the top end of the display screen, the shortcut switch originally displayed at the top end of the screen is released, and the display range of the scenic spot is effectively expanded. The released shortcut switch can be displayed in the second subarea, belongs to a single-hand easy-operation area and can be operated by one hand.

In one possible implementation of the present application, the plurality of camera mode controls includes a combination of a plurality of the following controls: large aperture, night scenes, figures, photographs, videos, movies, professions, and more.

Correspondingly, the first interaction event may be an operation of clicking to start the camera application by the user, and the second interaction event may be an operation of sliding the current camera mode of the camera application by the user. For example, the user clicks to open the camera application, the electronic device displays a first interface of the camera application as a photographing interface (as shown in fig. 5-1), the first sub-region includes a plurality of camera mode controls and a current photographing mode of the camera application, and the second sub-region includes a first type of setting control (high-frequency secondary menu) corresponding to the photographing mode: zooming; the user slides up the photographing mode control, the electronic device displays an interface as shown in fig. 5-2, the display of the first subarea is unchanged, and a second type of setting control (a secondary high-frequency secondary menu) of the photographing mode is displayed in the second subarea: filter, frame, resolution frame rate, flash, setup.

In one possible implementation, the first type of setting control of the modes of portrait, video, and movie includes: large aperture.

Therefore, when the large aperture state in the camera mode of the portrait, the video and the movie is set, the camera can be directly set in the current mode without the need of exiting the current mode and then setting from other modes of the primary menu, thereby providing convenience for the user to adjust the large aperture state in the camera mode.

In one possible implementation, before the electronic device displays the first interface of the camera application interface, the method further includes: determining an application mode of the electronic device based on a built-in sensor of the electronic device, wherein the application mode comprises a vertical screen application mode and a horizontal screen application mode;

when the electronic equipment is in a vertical screen application mode, the second interaction event is a mode control of a current first mode or a slide-up gesture of a first sub-region applied to the camera; a sixth interaction event is a click of a return key or a swipe gesture on the second sub-region; when the electronic equipment is in the transverse screen application mode, the second interaction event is a transverse outer side sideslip gesture of a mode control of the current first mode applied to the camera; the fifth interaction event is a back key click or a laterally inboard side-slip gesture to the second sub-region.

That is, the determination of the interaction area of the camera application interface of the electronic device is different according to different modes of horizontal screen, vertical screen, left-hand single-hand operation and right-hand single-hand operation of the electronic device, so that the application state of the electronic device is determined according to the built-in sensor of the electronic device, and then the content of each area of the camera application interface in the corresponding application state is determined in a targeted manner, thereby more accurately determining the interaction area of the camera application interface and facilitating single-hand operation.

In one possible implementation, the first type of setting control of the large aperture mode control includes: the second type of setting control of the aperture and the large aperture comprises: drawing and setting;

the second type of setting control of the night scene mode control comprises the following steps: drawing and setting;

the first type of setting control of the portrait mode control comprises: the second type of setting control of the zoom, face-beautifying control and large aperture comprises: blurring function, picture, flash and setting;

the first type of setting control of the photographing mode control comprises: zooming, wherein the second type of setting control of the photographing mode control comprises the following steps: filter control, picture, ai switch, flash and setup;

The first type of setting control of the video mode control comprises: the second type of setting control of the zoom, face-beautifying and large aperture and video mode control comprises: filters, frames, resolution frame rates, flash and settings;

the first type of setting control of the movie mode control comprises: zooming, beautifying, large aperture and AiLUT, and the second type of setting control of the film mode control comprises: slow motion, LOG, LUT, frame, flash, and resolution frame rate;

the first type of setting control of the professional mode control comprises: the second type of setting control of the professional mode control comprises the following functions: JPG function, flash function, and setup function;

more mode controls include: slow motion, panoramic, time-lapse photography, watermarking, document correction, super-macro, multi-mirror video, high-pixel, micro-motion film, and super-night scenes.

Therefore, the high-frequency functional controls (first type setting controls) and the secondary high-frequency functional controls (second type setting controls) of the camera are more reasonably classified and controlled according to the use frequency of the mode controls of the camera application, the control of the camera application can be operated by a common function single hand in each mode, the path is shorter, and the use experience of the user is effectively improved.

In one possible implementation manner, the method further includes:

the electronic device receives a ninth interaction event for any interface of the camera application interfaces; a ninth interaction event is for selecting a third mode within the further modes;

the electronic equipment responds to the ninth interaction event and displays an eighth interface of the camera application; wherein,

and stopping displaying the more mode controls in the eighth interface, displaying the controls in the third mode at the positions of the more mode controls, and displaying the first type setting controls in the third mode in the second subarea of the eighth interface.

Therefore, the camera interaction interface can flexibly adjust the display of the first-level menu according to the actual use state, has greater flexibility, and is beneficial to the improvement of the use experience of users.

Fig. 13 is a schematic structural diagram of an electronic device implementing the interaction method of the camera application interface.

As shown in fig. 13, the electronic device may be a mobile phone. The electronic device may specifically include: a touch screen 1201, the touch screen 1201 including a touch sensor 1206 and a display screen 1207; one or more processors 1202; a memory 1203; one or more applications (not shown); and one or more computer programs 1204, the devices described above may be connected by one or more communication buses 1205. Wherein the one or more computer programs 1204 are stored in the memory 1203 and configured to be executed by the one or more processors 1202, the one or more computer programs 1204 comprise instructions that can be used to perform the relevant steps in the above embodiments.

It will be appreciated that the electronic device or the like may include hardware structures and/or software modules that perform the functions described above. Those of skill in the art will readily appreciate that the elements and algorithm steps of the examples described in connection with the embodiments disclosed herein may be implemented as hardware or combinations of hardware and computer software. Whether a function is implemented as hardware or computer software driven hardware depends upon the particular application and design constraints imposed on the solution. Skilled artisans may implement the described functionality in varying ways for each particular application, but such implementation decisions should not be interpreted as causing a departure from the scope of the embodiments of the present application.

The embodiment of the present application may divide the functional modules of the electronic device or the like according to the above method example, for example, each functional module may be divided corresponding to each function, or two or more functions may be integrated into one processing module. The integrated modules may be implemented in hardware or in software functional modules. It should be noted that, in the embodiment of the present application, the division of the modules is schematic, which is merely a logic function division, and other division manners may be implemented in actual implementation.

In the case of dividing the respective functional modules with the respective functions, one possible composition diagram of the electronic device involved in the above-described embodiment may include: a display unit, a transmission unit, a processing unit, etc. It should be noted that, all relevant contents of each step related to the above method embodiment may be cited to the functional descriptions of the corresponding functional modules, which are not described herein.

Fig. 14 shows a software architecture block diagram of an electronic device according to an embodiment of the present application.

As shown in fig. 14, in the embodiment of the present application, the layered architecture divides the software into several layers, each with a clear role and division of work. Wherein the layers communicate with each other through a software interface. In some embodiments, the system is divided into five layers, from top to bottom, an application layer, an application framework layer, a system library, a hardware abstraction layer, and a kernel layer, respectively.

The application layer may include a series of application packages, among other things. The application may be simply referred to as an application, and as shown in fig. 14, an application layer may include a lock screen, a desktop, sharing, bluetooth, a picture, voice interaction, a contact, and the like, which is not limited in this embodiment of the present application.

The application framework layer provides an application programming interface (application programming interface, API) and programming framework for the application of the application layer, which includes some predefined functions such as the view, animation, packaging manager, window manager, broadcast receiver, screen light, input manager, power manager, database, etc. shown in fig. 13.

The system library comprises a browser kernel, 3D graphics, a font library and the like.

The hardware abstraction layer may include a touch screen, a display screen, sensors, cameras, audio, bluetooth, etc.

The kernel layer comprises a camera driver, a display driver, a Bluetooth driver, an Ultra Wide Band (UWB) driver, a sensor driver, a touch screen driver, an audio driver and the like.

The kernel layer is a layer between hardware and software, and an application program of the application program layer or a hardware abstraction layer or the kernel layer detects related events and acquires states of the events, such as detecting bluetooth connection, network connection, and the like. The kernel layer at least contains display drivers. In particular to aspects of embodiments of the present application, the hardware involved may include a display driver integrated chip (display driver integratedcircuit, DDIC) and a display screen (e.g., OLED or LCD). The display driver is used for driving the DDIC to complete the processing and implementation of the display.

Fig. 13 and 14 illustrate only an electronic device and software structure having components, and it will be understood by those skilled in the art that the structures illustrated in fig. 13 and 14 are not limiting of the electronic device and its software structure and may include fewer or more components than illustrated, or may combine certain components, or a different arrangement of components.

Embodiments of the present application also provide an electronic device including one or more processors and one or more memories. The one or more memories are coupled to the one or more processors, the one or more memories being configured to store computer program code comprising computer instructions that, when executed by the one or more processors, cause the electronic device to perform the related method steps described above to implement the method of interaction of the camera application interface in the embodiments described above.

Embodiments of the present application also provide a computer readable storage medium having stored therein computer instructions that, when executed on an electronic device, cause the electronic device to perform the above-described related method steps to implement the interaction method of the camera application interface in the above-described embodiments.

Embodiments of the present application also provide a computer program product comprising computer instructions which, when run on an electronic device, cause the electronic device to perform the above-described related method steps to implement the interaction method of the camera application interface in the above-described embodiments.

In addition, embodiments of the present application also provide an apparatus, which may be specifically a chip, a component, or a module, and may include a processor and a memory connected to each other; the memory is configured to store computer-executable instructions, and when the apparatus is running, the processor may execute the computer-executable instructions stored in the memory, so that the apparatus executes the interaction method of the camera application interface executed by the electronic device in the above method embodiments.

The electronic device, the computer readable storage medium, the computer program product or the apparatus provided in this embodiment are configured to perform the corresponding method provided above, and therefore, the advantages achieved by the electronic device, the computer readable storage medium, the computer program product or the apparatus can refer to the advantages of the corresponding method provided above, which are not described herein.

From the foregoing description of the embodiments, it will be apparent to those skilled in the art that, for convenience and brevity of description, only the above-described division of functional modules is illustrated, and in practical application, the above-described functional allocation may be implemented by different functional modules according to needs, i.e. the internal structure of the apparatus is divided into different functional modules to implement all or part of the functions described above. The specific working processes of the above-described systems, devices and units may refer to the corresponding processes in the foregoing method embodiments, which are not described herein.

The functional units in the embodiments of the present application may be integrated in one processing unit, or each unit may exist alone physically, or two or more units may be integrated in one unit. The integrated units may be implemented in hardware or in software functional units.

The integrated units described above, if implemented in the form of software functional units and sold or used as stand-alone products, may be stored in a computer readable storage medium. Based on such understanding, the technical solution of the embodiments of the present application may be essentially or a part contributing to the related art or all or part of the technical solution may be embodied in the form of a software product stored in a storage medium, including several instructions to cause a computer device (may be a personal computer, a server, or a network device, etc.) or a processor to perform all or part of the steps of the methods of the embodiments of the present application. And the aforementioned storage medium includes: flash memory, removable hard disk, read-only memory, random access memory, magnetic or optical disk, and the like.

The foregoing is merely a specific embodiment of the present application, but the protection scope of the present application is not limited thereto, and any changes or substitutions within the technical scope of the present disclosure should be covered in the protection scope of the present application. Therefore, the protection scope of the present application shall be subject to the protection scope of the claims.

Claims (15)

1. An interaction method of camera application interface is applied to electronic equipment, which is characterized in that,

the camera application interface comprises a view finding area, a shutter and a first area, wherein the view finding area displays images acquired by a camera in real time, and the electronic equipment captures and stores the images displayed by the view finding area in response to the operation of the shutter; the first region includes: a first sub-region adjacent to the region in which the shutter is located, and a second sub-region adjacent to the first sub-region;

the method comprises the following steps:

the electronic equipment receives a first interaction event;

the electronic equipment responds to the first interaction event and displays a first interface of the camera application interface; the first subarea of the first interface comprises a plurality of camera mode controls and a first current mode of camera application, and the second subarea of the first interface comprises a first type of setting control corresponding to the first mode;

The electronic equipment receives a second interaction event aiming at the first interface;

the electronic equipment responds to the second interaction event and displays a second interface of the camera application interface; wherein,

the first subarea of the second interface comprises the plurality of camera mode controls and the current first mode of the camera application, and the second type of setting control corresponding to the first mode is displayed in the second subarea of the second interface to replace the first type of setting control corresponding to the first mode.

2. The method of interaction of a camera application interface of claim 1, further comprising:

the electronic equipment receives a third interaction event aiming at the second interface;

the electronic equipment responds to the third interaction event and displays a third interface of the camera application interface; wherein,

the first subarea of the third interface comprises the plurality of camera mode controls and a current first mode of the camera application, and a menu corresponding to a second setting control is displayed in the second subarea of the third interface to replace a second type setting control corresponding to the first mode; the second setting control is any one control in the second type of setting control corresponding to the first mode.

3. The interaction method of a camera application interface according to claim 1 or 2, further comprising:

the electronic device receives a fourth interaction event for the first interface;

the electronic equipment responds to the fourth interaction event and displays a fourth interface of the camera application interface; wherein,

the first subarea of the fourth interface comprises the plurality of camera mode controls and a current first mode of the camera application, and a menu corresponding to a first setting control is displayed in the second subarea of the fourth interface to replace a first type of setting control corresponding to the first mode; the first setting control is any one control in the first type of setting control corresponding to the first mode.

4. The method of interaction of a camera application interface of claim 3, further comprising:

the electronic device receives a fifth interaction event for any one of the second interface, the third interface or the fourth interface;

the electronic equipment responds to a fifth interaction event and displays a fifth interface of the camera application interface; wherein,

the first subarea of the fifth interface comprises the plurality of camera mode controls and a second mode of the camera application, and the second subarea of the fifth interface displays a first type of setting control corresponding to the second mode.

5. The method of interaction of a camera application interface of claim 3, further comprising:

the electronic device receives a sixth interaction event for the third interface;

the electronic equipment responds to a sixth interaction event and displays a sixth interface of the camera application interface; wherein,

the first subarea of the sixth interface comprises the plurality of camera mode controls and a current first mode of the camera application, and the second subarea of the sixth interface displays a second type of setting control corresponding to the first mode.

6. The method of interacting with a camera application interface of claim 3, wherein the fourth interface further comprises a second region, the second region being located on a side of the fourth interface opposite the region where the shutter is located,

the menu corresponding to the first setting control comprises a plurality of first sub-controls,

the method further comprises the steps of:

the electronic device receives a seventh interaction event of one of the plurality of first sub-controls on the fourth interface;

the electronic device responds to the seventh interaction event, a seventh interface of the camera application interface is displayed, wherein a first subarea of the seventh interface comprises the plurality of camera mode controls and a current first mode of the camera application, a menu corresponding to the first setting control corresponding to the first mode is displayed in a second subarea of the seventh interface, and a state icon corresponding to the first sub-control is displayed in a second area of the seventh interface.

7. The method of interaction of a camera application interface of claim 2, wherein the third interface further comprises a second region, the second region being located on a side of the third interface opposite the region where the shutter is located,

the menu corresponding to the second setting control comprises a plurality of second sub-controls,

the method further comprises the steps of:

the electronic device receives an eighth interaction event for one of the plurality of second sub-controls on the third interface;

and the electronic equipment responds to the eighth interaction event, and displays an eighth interface, wherein a first subarea of the eighth interface comprises the plurality of camera mode controls and a current first mode of the camera application, a menu corresponding to a second setting control corresponding to the first mode is displayed in a second subarea of the eighth interface, and a state icon corresponding to one second sub control is displayed in a second area of the eighth interface.

8. A method of interaction of a camera application interface as recited in any of claims 1-7,

the plurality of camera mode controls includes a combination of a plurality of the following controls: large aperture, night scenes, figures, photographs, videos, movies, professions, and more.

9. The method of interaction of a camera application interface of claim 8,

the first type of setting control of the modes of the portrait, the video and the movie comprises: large aperture.

10. The method of interaction of a camera application interface of claim 8, wherein before the electronic device displays the first interface of the camera application interface, the method further comprises:

determining an application mode of the electronic equipment based on a sensor of the electronic equipment, wherein the application mode comprises a vertical screen application mode and a horizontal screen application mode;

wherein,

when the electronic equipment is in the vertical screen application mode, the second interaction event is a mode control of a current first mode or a slide-up gesture of a first sub-region applied to the camera; the fifth interaction event is a back key click or a swipe gesture on the second sub-region;

when the electronic device is in the horizontal screen application mode, the second interaction event is a horizontal outside side-slip gesture of a mode control of a current first mode applied to the camera; the sixth interaction event is a back key click or a laterally inboard side-slip gesture to the second sub-region.

11. The method of interaction of a camera application interface of claim 8,

the first type of setting control of the large aperture mode control comprises the following steps: the second type of setting control of the large aperture comprises the following steps: drawing and setting;

the second class of setting controls of the night scene mode control comprises: drawing and setting;

the first type of setting control of the portrait mode control comprises: zooming, beautifying controls and a large aperture, wherein the second type of setting controls of the portrait mode control comprise: blurring function, picture, flash and setting;

the first type of setting control of the photographing mode control comprises: zooming, wherein the second type of setting control of the photographing mode control comprises the following steps: filter control, picture, ai switch, flash and setup;

the first type of setting control of the video mode control comprises: zooming, beautifying and large aperture, wherein the second type of setting control of the video mode control comprises: filters, frames, resolution frame rates, flash and settings;

the first type of setting control of the movie mode control comprises the following steps: zooming, beautifying, large aperture and AiLUT, wherein the second type of setting control of the film mode control comprises the following steps: slow motion, LOG, LUT, frame, flash, and resolution frame rate;

The first type of setting control of the professional mode control comprises the following steps: the second type of setting control of the professional mode control comprises the following components: JPG function, flash function, and setup function;

the more mode control comprises the following steps: slow motion, panoramic, time-lapse photography, watermarking, document correction, super-macro, multi-mirror video, high-pixel, micro-motion film, and super-night scenes.

12. The method of interaction of a camera application interface of claim 11, further comprising:

the electronic device receives a ninth interaction event for any interface of the camera application interfaces; the ninth interactivity event is used to select a third mode within the further modes;

the electronic equipment responds to the ninth interaction event and displays an eighth interface of the camera application; wherein,

and stopping displaying the more mode controls in the eighth interface, displaying the controls in the third mode at the positions of the more mode controls, and displaying the first type setting controls in the third mode in the second subarea of the eighth interface.

13. An electronic device, the electronic device comprising:

At least one processor; the method comprises the steps of,

a memory communicatively coupled to the at least one processor and a touch display; wherein,

the touch display screen is used for displaying an application interface;

the memory stores instructions executable by the at least one processor to cause the electronic device to perform steps in the interaction method of the camera application interface of any of claims 1-12.

14. A computer readable storage medium storing a computer program, characterized in that the computer program, when executed on an electronic device, causes the electronic device to perform the interaction method of the camera application interface of any of claims 1 to 12.

15. A computer program product comprising computer instructions which, when run on an electronic device, cause the electronic device to perform the steps in the interaction method of the camera application interface of any of claims 1-12.