CN116450009A - Watch menu navigation system based on graphic interface interaction - Google Patents

Abstract

The invention discloses a watch menu navigation system based on graphic interface interaction, which relates to the technical field of menu navigation systems and comprises a user input module, a navigation control module, a hierarchical control module, a menu management module, an isolation module and a display module; the method comprises the steps of processing a request of a user for navigating a watch menu through a navigation control module, obtaining multiple items of data of software, establishing adjustment coefficients according to the multiple items of data, controlling the ascending and descending of the software on a menu page through the adjustment coefficients, namely switching to a previous menu or entering a submenu, tracking the hierarchical structure of the current menu by a hierarchical control module, and coordinating the software quantity of each layer of the menu by combining a user input instruction and menu adjustment information of the navigation control module. The invention adopts the ascending method to carry out menu classification on the software in the watch menu, thereby not only facilitating the user to search the software, but also avoiding the waste operation when the user navigates and improving the efficiency of inquiring the watch menu software by the user.

Description

Watch menu navigation system based on graphic interface interaction

Technical Field

The invention relates to the technical field of menu navigation systems, in particular to a watch menu navigation system based on graphical interface interaction.

Background

The watch menu navigation system is an interface system for browsing and selecting different functions on the watch, and as the popularity and functions of the smart watch increase, the watch menu navigation system has been developed in order to provide better user experience and a more efficient operation mode;

conventional watches often provide limited functions, such as displaying time and date, however, as technology advances, modern watches gradually merge more intelligent functions, such as notification reminders, health monitors, pedometers, music playing, etc., and watch menu navigation systems have evolved to facilitate user access to these functions.

The prior art has the following defects:

the existing menu navigation system cannot comprehensively classify the software according to the habit of using the software by the user, so that the user is inconvenient to search the software, and the user is easy to generate non-operation in the process of using the menu navigation system, thereby reducing the inquiring efficiency of the user on the watch menu.

Disclosure of Invention

The invention aims to provide a watch menu navigation system based on graphical interface interaction, which aims to solve the defects in the background technology.

In order to achieve the above object, the present invention provides the following technical solutions: the watch menu navigation system based on the graphical interface interaction comprises a user input module, a navigation control module, a hierarchical control module, a menu management module, an isolation module and a display module;

a user input module: the method comprises the steps that an input instruction of a user is received, the user browses and selects menu items by using the input instruction, and multiple items of data of software used by the user are obtained;

and a navigation control module: processing a request of a user for navigating a watch menu, establishing an adjustment coefficient according to a plurality of items of data, and controlling the software to ascend and descend on a menu page through the adjustment coefficient;

the hierarchy control module: tracking the hierarchical structure of the current menu, and coordinating the software quantity of each layer of the menu by combining the user input instruction and the menu regulation information of the navigation control module;

and a menu management module: generating a watch menu structure according to the menu regulation information, and providing a menu structure editing function;

isolation module: regularly acquiring an adjustment coefficient, comparing the adjustment coefficient of the software with an isolation threshold value, and judging whether the software needs to be divided into an isolation area according to the comparison;

and a display module: for displaying the menu structure and the isolated software information.

In a preferred embodiment, the navigation control module processes a request of a user for navigating a watch menu, and obtains a plurality of data of the software, wherein the plurality of data comprises a software use frequency, a software running total time length, a software error detection discrete value and a software power consumption in an operation state.

In a preferred embodiment, the navigation control module calculates and establishes the adjustment coefficient by integrating the software use frequency, the total software operation time, the software error detection variation coefficient and the software power consumption in the operation state after dividing the dimensionThe computational expression is:

；

in the method, in the process of the invention,for the total duration of software running, +.>For software power consumption in the operating state, +.>Detecting a coefficient of variation for software errors, < >>For software use frequency, ++>、/>、/>、/>The total running time of the software, the power consumption of the software in the operating state, the error detection variation coefficient of the software and the proportionality coefficient of the use frequency of the software are respectively +.>、/>、/>、/>Are all greater than 0.

In a preferred embodiment, the navigation control module obtains adjustment coefficients for all softwareAfter that, every 6h all the software is according to the adjustment coefficient +.>And sorting from big to small to generate a software sorting table, wherein the menu adjusting information is the sorting table.

In a preferred embodiment, the hierarchical control module generates the number of software placed in each layer of menu according to the user input instruction, and then fills all software into the menu hierarchy structure from top to bottom in sequence according to the ranking table.

In a preferred embodiment, the isolation module obtains the adjustment coefficients of all the software every 24 hours, and calculates the average value of the adjustment coefficients of the softwareThen the adjustment coefficient of the software is averaged +.>And isolation threshold->Comparing;

if the adjustment coefficient of the software is averageIsolation threshold ∈>The isolation module judges that the software does not need isolation;

if the adjustment coefficient of the software is average< isolation threshold->The isolation module judges that the software needs to be isolated and divides the software into isolation areas.

In a preferred embodiment, the software running total length acquisition logic is:

acquisition of start and end times: acquiring a starting time point of the query and acquiring an ending time point of the query;

acquiring a software list: acquiring a software list on the intelligent watch, which is realized through an operating system of the watch;

traversing a software list: traversing the software list and performing the following steps for each piece of software: acquiring an operation log of the software to acquire an activity record of the software in a specified time period, and calculating the total operation time length of the software in the specified time period;

recording the total operation time length: and recording the total running time of each piece of software, and storing the total running time of each piece of software by using a data structure.

In a preferred embodiment, the software error detection variation coefficient is calculated by the following expression:

；

in the method, in the process of the invention,for software within a specific period of timeSum of error reporting number,/->Total number of data>For each error count data point, +.>Mean value representing number of errors reported,/->Total data points representing the number of errors reported.

In a preferred embodiment, the software power consumption acquisition logic in the operating state is:

acquiring operation state information: acquiring operation state information of the intelligent watch;

acquiring the power consumption information of the software: acquiring power consumption information of each piece of software in a time period through an operating system;

recording the power consumption of the software: and for each piece of software, recording the power consumption information corresponding to the piece of software, and storing the power consumption of the piece of software in the operation state of each piece of software by using a data structure.

In a preferred embodiment, the software usage frequency is calculated as:wherein->For the number of software uses in a time period, < >>Total duration of the time period.

In the technical scheme, the invention has the technical effects and advantages that:

according to the invention, a navigation control module processes a request of a user for navigating a watch menu, multiple items of data of software are obtained, an adjustment coefficient is established according to the multiple items of data, the ascending and descending of the software on a menu page are controlled through the adjustment coefficient, namely, the menu is switched to a higher-level menu or enters a submenu, a hierarchical control module tracks the hierarchical structure of the current menu, and coordinates the number of each layer of software of the menu by combining a user input instruction and menu adjustment information of the navigation control module;

according to the invention, after the software use frequency, the total software operation duration, the software error detection variation coefficient and the software power consumption in the operation state are taken out and removed through the navigation control module, the adjustment coefficient is comprehensively calculated and established, so that the analysis of all the software is more comprehensive, the efficiency is higher, when the average value of the adjustment coefficients of the software is smaller than the isolation threshold value, the isolation module judges that the software needs to be isolated, the software is divided into the isolation area, the software divided into the isolation area is disconnected with the network through the watch safety software, and the software is limited to be started, thereby ensuring the safe use of the intelligent watch, reducing the occupation of the isolation software on the operation memory of the intelligent watch, and improving the operation speed of other software of the intelligent watch.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings that are needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments described in the present invention, and other drawings may be obtained according to these drawings for a person having ordinary skill in the art.

FIG. 1 is a block diagram of a system according to the present invention.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present invention more apparent, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is apparent that the described embodiments are some embodiments of the present invention, but not all embodiments of the present invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Example 1: referring to fig. 1, the watch menu navigation system based on graphical interface interaction according to the present embodiment includes a user input module, a navigation control module, a hierarchical control module, a menu management module, an isolation module, and a display module;

the user input module is used for receiving input of a user, such as a touch screen, physical buttons, a scroll wheel and the like, the user can browse and select menu items in the input modes, the user uses multiple items of data of software to send the data to the navigation control module, and a user input instruction is sent to the hierarchical control module;

the navigation control module processes a request of a user for navigating a watch menu, acquires multiple items of data of software, establishes adjustment coefficients according to the multiple items of data, controls the ascending and descending of the software on a menu page through the adjustment coefficients, namely, switches to a higher-level menu or enters a submenu, sends software control information to the hierarchical control module, sends the adjustment coefficients to the isolation module, and sends menu adjustment information to the menu management module;

the hierarchical control module tracks the hierarchical structure of the current menu, coordinates the software quantity of each layer of the menu by combining a user input instruction and menu regulation information of the navigation control module, and sends the menu regulation information to the menu management module;

the menu management module generates a menu structure on the watch according to the menu regulation information, wherein the menu structure comprises menu items, submenus, navigation levels and the like, and generally provides functions of creating, editing and deleting the menu, and the menu structure information is sent to the display module;

the isolation module periodically acquires the average value of the adjustment coefficients of all the software, compares the adjustment coefficients of the software with an isolation threshold value, judges whether the software needs to be divided into an isolation area according to the comparison, and sends an isolation log to the display module after the software is divided into the isolation area;

and a display module: this is the screen of the watch for displaying the menu structure and the isolated software information, the display module is a touch screen, and after the user views the software in the isolated area, the user can choose to move the software out of the isolated area or directly uninstall it.

According to the method, the navigation control module processes the request of the user for navigating the watch menu, multiple items of data of the software are obtained, the adjustment coefficient is built according to the multiple items of data, the ascending and descending of the software on the menu page is controlled through the adjustment coefficient, namely, the menu is switched to the upper level menu or enters the submenu, the hierarchical control module tracks the hierarchical structure of the current menu, and coordinates the number of each layer of software of the menu by combining the user input instruction and the menu adjustment information of the navigation control module.

Example 2: the navigation control module processes a request of a user for navigating a watch menu, acquires multiple items of data of software, establishes adjustment coefficients according to the multiple items of data, controls the ascending and descending of the software on a menu page through the adjustment coefficients, namely, switches to a higher-level menu or enters a submenu, sends software control information to the hierarchical control module, sends the adjustment coefficients to the isolation module, and sends menu adjustment information to the menu management module;

the navigation control module processes a request of a user for navigating a watch menu, and acquires a plurality of data of software, wherein the plurality of data comprise software use frequency, software running total duration, software error detection discrete values and software power consumption in an operation state;

the navigation control module comprehensively calculates and establishes an adjustment coefficient after dividing the software use frequency, the software running total time length, the software error reporting detection variation coefficient and the software power consumption in the operation stateThe computational expression is:

；

in the method, in the process of the invention,for the total duration of software running, +.>For software power consumption in the operating state, +.>Detecting a coefficient of variation for software errors, < >>For software use frequency, ++>、/>、/>、/>The total running time of the software, the power consumption of the software in the operating state, the error detection variation coefficient of the software and the proportionality coefficient of the use frequency of the software are respectively +.>、/>、/>、/>Are all greater than 0.

The navigation control module obtains the adjustment coefficients of all the softwareAfter that, every 6h all the software is according to the adjustment coefficient +.>Sorting from big to small to generate a software sorting tableThe larger the adjustment coefficient is, the greater the importance of the software to the user is, and the menu adjusting information is an ordering table;

the hierarchical control module tracks the hierarchical structure of the current menu, coordinates the software quantity of each layer of the menu by combining a user input instruction and menu regulation information of the navigation control module, and sends the menu regulation information to the menu management module;

the hierarchical control module generates the software quantity placed in each layer of menu according to the user input instruction, and then fills all software into the menu hierarchical structure from top to bottom in sequence according to the ranking table.

The isolation module periodically acquires the average value of the adjustment coefficients of all the software, compares the adjustment coefficients of the software with an isolation threshold value, judges whether the software needs to be divided into an isolation area according to the comparison, and sends an isolation log to the display module after the software is divided into the isolation area;

after the isolation module obtains the adjustment coefficients of all the software every 24 hours, the average value of the adjustment coefficients of the software is calculatedThen the adjustment coefficient of the software is averaged +.>And isolation threshold->Comparing;

if the adjustment coefficient of the software is averageIsolation threshold ∈>The isolation module judges that the software does not need isolation;

if the adjustment coefficient of the software is average< isolation threshold->The isolation module judges that the software needs to be isolated, and the software is divided into an isolation area, the software divided into the isolation area is disconnected with a network through watch safety software, the starting of the software is limited, and a user can manually divide the software in the isolation area through the display module;

according to the method, after the software use frequency, the total software operation duration, the software error detection variation coefficient and the software power consumption in the operation state are taken out and removed through the navigation control module, the adjustment coefficient is comprehensively calculated and established, so that analysis of all the software is more comprehensive, the efficiency is higher, the average value of the adjustment coefficients of the software is smaller than the isolation threshold value, the isolation module judges that the software needs to be isolated, the software is divided into the isolation area, the software divided into the isolation area is disconnected with the network through the watch safety software, the starting of the software is limited, the safe use of the intelligent watch is guaranteed, the occupation of the isolation software to the running memory of the intelligent watch is reduced, and the running speed of other software of the intelligent watch is improved.

The total time length of software operation obtaining logic is as follows:

1) Acquiring the starting time: firstly, acquiring a starting time point of inquiry, namely, starting time of a time period;

2) Acquisition end time: acquiring an end time point of the query, namely, an end time of the time period;

3) Acquiring a software list: acquiring a software list on the smart watch, which can be realized through an interface or an API provided by an operating system or an application store of the watch;

4) Traversing a software list: traversing the software list and performing the following operations for each piece of software:

a. acquiring a running log or a history record of the software to acquire an activity record of the software in a specified time period;

b. calculating the total running time of the software in a specified time period, which can be realized by calculating the duration of each activity record and accumulating the duration into a total time variable;

5) Recording the total operation time length: recording the total running time of each piece of software, and storing each piece of software and the corresponding total time by using a data structure (such as a list);

the greater the total duration of software operation, the greater the importance of the software.

The software power consumption acquisition logic in the operational state is:

1) Acquiring operation state information: firstly, acquiring operation state information of the intelligent watch, which may include currently running software, system states and the like;

2) Acquiring the power consumption information of the software: acquiring power consumption information of each software in a specific time period through an operating system or other related interfaces;

3) Recording the power consumption of the software: for each piece of software, the corresponding power consumption information is recorded, and a data structure (such as a dictionary or a list) can be used for storing each piece of software and the corresponding power consumption;

the greater the power consumption of the software in the operational state, the greater the importance of the software.

The calculation expression of the software error detection variation coefficient is as follows:wherein->Sum of error number of software in specific time period, +.>Total number of data>For each error count data point, +.>Mean value representing number of errors reported,/->Total number of data points representing number of errors reported;

the coefficient of variation is the ratio of standard deviation to mean value, and is used for measuring the relative discrete degree of data, when the coefficient of variation is larger, it indicates that the number of errors reported around the mean value fluctuates greatly, and the difference between data points is larger, in other words, when the coefficient of variation is larger, the fluctuation of the number of errors reported is higher, and the relative discrete degree of the number of errors reported is larger, which may mean that the number of errors reported by software in different time periods changes greatly, or the difference between the number of errors reported by software in certain time periods and the mean value is larger, so that a larger coefficient of variation may indicate that the stability of software is worse, and there is larger fluctuation and inconsistency.

The calculation expression of the software use frequency is as follows:wherein->For the number of software uses in a time period, < >>The total duration of the time period refers to the total number of times a certain piece of software is opened or used in a specific time period, the total duration of the time period refers to the length of the time period for calculating the frequency of use, and the greater the frequency of use of the piece of software, the greater the importance of the piece of software.

The hierarchical control module tracks the hierarchical structure of the current menu, coordinates the software quantity of each layer of the menu by combining a user input instruction and menu regulation information of the navigation control module, and sends the menu regulation information to the menu management module;

when the user inputs an instruction to control the hierarchical structure of the menu, the software accommodation amount of each menu layer can be controlled.

Example 3: the watch menu navigation method based on graphical interface interaction of the embodiment comprises the following steps:

the processing terminal receives an input instruction of a user, the user browses and selects menu items by using the input instruction, obtains multiple items of data of software used by the user, processes a request of the user for navigating a watch menu, establishes adjustment coefficients according to the multiple items of data, controls the ascending and descending of the software on a menu page by the adjustment coefficients, tracks the hierarchical structure of the current menu, coordinates the number of each layer of software of the menu by combining the input instruction of the user and menu adjustment information, generates a watch menu structure according to the menu adjustment information, provides a menu structure editing function, periodically obtains the adjustment coefficients, compares the adjustment coefficients of the software with an isolation threshold, and judges whether the software needs to be divided into an isolation area according to comparison, so as to display the menu structure and the isolated software information;

processing a request of a user for navigating a watch menu, and acquiring a plurality of data of software, wherein the plurality of data comprise software use frequency, software running total duration, software error detection discrete values and software power consumption in an operation state;

after the software use frequency, the software running total time length, the software error reporting detection variation coefficient and the software power consumption in the operation state are divided into dimensions, the adjustment coefficient is established by comprehensive calculationThe computational expression is:

；

in the method, in the process of the invention,for the total duration of software running, +.>For software power consumption in the operating state, +.>Detecting a coefficient of variation for software errors, < >>For software use frequency, ++>、/>、/>、/>The total running time of the software, the power consumption of the software in the operating state, the error detection variation coefficient of the software and the proportionality coefficient of the use frequency of the software are respectively +.>、/>、/>、/>Are all greater than 0.

Obtaining adjustment coefficients of all softwareAfter that, every 6h all the software is according to the adjustment coefficient +.>Sequencing from big to small to generate a software sequencing table, wherein the larger the adjustment coefficient is, the larger the importance of the software to the user is, and the menu adjusting information is the sequencing table;

tracking the hierarchical structure of the current menu, and coordinating the software quantity of each layer of the menu by combining the user input instruction and the menu regulation information;

and generating the software quantity placed in each layer of menu according to the user input instruction, and then filling all the software into the menu hierarchical structure from top to bottom in sequence according to the ranking table.

The average value of the adjustment coefficients of all the software is obtained regularly, the adjustment coefficients of the software are compared with an isolation threshold value, whether the software needs to be divided into an isolation area or not is judged according to the comparison, and after the software is divided into the isolation area, an isolation log is sent to a display module;

after obtaining the adjustment coefficients of all the software every 24 hours, calculating to obtain the average value of the adjustment coefficients of the softwareThen the adjustment coefficient of the software is averaged +.>And isolation threshold->Comparing;

if the adjustment coefficient of the software is averageIsolation threshold ∈>Judging that the software does not need to be isolated;

if the adjustment coefficient of the software is average< isolation threshold->Judging that the software needs to be isolated, and dividing the software into an isolation area, wherein the software divided into the isolation area is disconnected with a network through watch safety software, and the starting of the software is limited, so that a user can manually divide the software in the isolation area.

The above formulas are all formulas with dimensions removed and numerical values calculated, the formulas are formulas with a large amount of data collected for software simulation to obtain the latest real situation, and preset parameters in the formulas are set by those skilled in the art according to the actual situation.

In the description of the present specification, the descriptions of the terms "one embodiment," "example," "specific example," and the like, mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the present invention. In this specification, schematic representations of the above terms do not necessarily refer to the same embodiments or examples. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The preferred embodiments of the invention disclosed above are intended only to assist in the explanation of the invention. The preferred embodiments are not intended to be exhaustive or to limit the invention to the precise form disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, to thereby enable others skilled in the art to best understand and utilize the invention. The invention is limited only by the claims and the full scope and equivalents thereof.

Claims (10)

1. The watch menu navigation system based on the interaction of the graphic interface is characterized in that: the system comprises a user input module, a navigation control module, a hierarchical control module, a menu management module, an isolation module and a display module;

a user input module: the method comprises the steps that an input instruction of a user is received, the user browses and selects menu items by using the input instruction, and multiple items of data of software used by the user are obtained;

and a navigation control module: processing a request of a user for navigating a watch menu, establishing an adjustment coefficient according to a plurality of items of data, and controlling the software to ascend and descend on a menu page through the adjustment coefficient;

the hierarchy control module: tracking the hierarchical structure of the current menu, and coordinating the software quantity of each layer of the menu by combining the user input instruction and the menu regulation information of the navigation control module;

and a menu management module: generating a watch menu structure according to the menu regulation information, and providing a menu structure editing function;

isolation module: regularly acquiring an adjustment coefficient, comparing the adjustment coefficient of the software with an isolation threshold value, and judging whether the software needs to be divided into an isolation area according to the comparison;

and a display module: for displaying the menu structure and the isolated software information.

2. The graphical interface interaction based watch menu navigation system of claim 1, wherein: the navigation control module processes a request of a user for navigating a watch menu, and acquires multiple data of software, wherein the multiple data comprise software use frequency, software running total time length, software error detection discrete values and software power consumption in an operation state.

3. The graphical interface interaction based watch menu navigation system of claim 2, wherein: the navigation control module comprehensively calculates and establishes an adjustment coefficient after the software use frequency, the software running total time length, the software error reporting detection variation coefficient and the software power consumption in the operation state are taken out and divided into dimensionsThe computational expression is:

；

in the method, in the process of the invention,for the total duration of software running, +.>For software power consumption in the operating state, +.>Detecting a coefficient of variation for software errors, < >>For software use frequency, ++>、/>、/>、/>The total running time of the software, the power consumption of the software in the operating state, the error detection variation coefficient of the software and the proportionality coefficient of the use frequency of the software are respectively +.>、/>、/>、/>Are all greater than 0.

4. A watch menu navigation system based on graphical interface interactions as recited in claim 3, wherein: the navigation control module obtains the adjustment coefficients of all the softwareAfter that, every 6h all the software is according to the adjustment coefficient +.>And sorting from big to small to generate a software sorting table, wherein the menu adjusting information is the sorting table.

5. The graphical interface interaction based watch menu navigation system of claim 4, wherein: the hierarchical control module generates the software quantity placed in each layer of menu according to the user input instruction, and then fills all software into the menu hierarchical structure from top to bottom in sequence according to the ranking table.

6. The graphical interface interaction based watch menu navigation system of claim 5, whereinThe method comprises the following steps: after the isolation module obtains the adjustment coefficients of all the software every 24 hours, the average value of the adjustment coefficients of the software is calculatedThen the adjustment coefficient of the software is averaged +.>And isolation threshold->Comparing;

if the adjustment coefficient of the software is averageIsolation threshold ∈>The isolation module judges that the software does not need isolation;

if the adjustment coefficient of the software is average< isolation threshold->The isolation module judges that the software needs to be isolated and divides the software into isolation areas.

7. The graphical interface interaction based watch menu navigation system of claim 6, wherein: the software running total duration obtaining logic is as follows:

acquisition of start and end times: acquiring a starting time point of the query and acquiring an ending time point of the query;

acquiring a software list: acquiring a software list on the intelligent watch, which is realized through an operating system of the watch;

traversing a software list: traversing the software list and performing the following steps for each piece of software: acquiring an operation log of the software to acquire an activity record of the software in a specified time period, and calculating the total operation time length of the software in the specified time period;

recording the total operation time length: and recording the total running time of each piece of software, and storing the total running time of each piece of software by using a data structure.

8. The graphical interface interaction based watch menu navigation system of claim 7, wherein: the calculation expression of the software error detection variation coefficient is as follows:

；

in the method, in the process of the invention,sum of error number of software in specific time period, +.>Total number of data>For each error count data point, +.>Mean value representing number of errors reported,/->Total data points representing the number of errors reported.

9. The graphical interface interaction based watch menu navigation system of claim 8, wherein: the software power consumption acquisition logic in the operation state is as follows:

acquiring operation state information: acquiring operation state information of the intelligent watch;

acquiring the power consumption information of the software: acquiring power consumption information of each piece of software in a time period through an operating system;

recording the power consumption of the software: and for each piece of software, recording the power consumption information corresponding to the piece of software, and storing the power consumption of the piece of software in the operation state of each piece of software by using a data structure.

10. The graphical interface interaction based watch menu navigation system of claim 9, wherein: the calculation expression of the software use frequency is as follows:wherein->For the number of software uses in a time period, < >>Total duration of the time period.