CN115019829A - Data processing method for flight seat display, electronic equipment and storage medium - Google Patents

Abstract

The invention provides a data processing method, electronic equipment and a storage medium for flight seat display, which comprise the following steps: the method comprises the steps of responding to a position selection request of a user, obtaining position coordinate information of a plurality of first positions and data information of a plurality of sound sources, determining target sound source information and sound level parameters according to the position coordinate information of the first positions, determining second positions from the plurality of first positions according to the sound level parameters of the first positions, marking the second positions, and obtaining and displaying first target display data. According to the method and the device, the second position influenced by the noise is determined from the plurality of first positions according to the maximum sound intensity information of the sound source and the distance information between the sound source and the first positions as the basis for judging the influence of the noise, and the second position is marked, so that a user can visually observe the second position influenced by the noise.

Description

Data processing method for flight seat display, electronic equipment and storage medium

Technical Field

The present invention relates to the field of data processing, and in particular, to a data processing method, an electronic device, and a storage medium for displaying a seat of a flight.

Background

When a user is on-duty and selects seats, the user can only know the seat layout information of airplane flights and cannot know the positions of other equipment on the airplane generating sound, and the noise on the airplane can influence the user and influence the riding experience of the user.

Therefore, when a flight selects a seat, the noise level is also a consideration factor for selecting the seat, and how to add noise information into the display information of the flight seat is a technical problem to be solved urgently.

Disclosure of Invention

Aiming at the technical problems, the technical scheme adopted by the invention is as follows:

the data processing method for flight seat display comprises the following steps:

s100, responding to a position selection request of a user, and acquiring data to be displayed corresponding to the position selection request; the data to be displayed comprises a plurality of first positions and a plurality of sound sources, and the sound sources are objects capable of emitting sounds with sound intensity higher than a first preset threshold;

s200, obtaining position coordinate information of a plurality of first positions to obtain a position coordinate information set M = { M = { (M) } ₁ ,M ₂ ,...,M _n }，M _j Corresponding position coordinate information of a jth first position in the data to be displayed, wherein j =1, 2., n and n are the number of the first positions;

s300, acquiring data information of a plurality of sound sources to obtain a data information set Q = { Q = { (Q) ₁ ,Q ₂ ,...,Q _k }，Q _h =(D _h ,T _h ) H =1, 2.. k, k is the number of sound sources, Q _h For data information of the h-th sound source, D _h Maximum sound intensity information, T, for the h-th sound source _h Is Q _h Corresponding position coordinate information of the corresponding sound source in the data to be displayed;

s400, according to the position coordinate information M of the jth first position _j Determining a target sound from the set of data information QSource information Q _f(j) =(D _j ,T _j )，1≤f(j)≤k，Q _f(j) Target sound source information corresponding to the jth first position, the target sound source information Q _f(j) The corresponding target sound source is the sound source closest to the jth first position, D _j Maximum sound intensity information for the target sound source, T _j Corresponding position coordinate information of the target sound source in the data to be displayed is obtained;

s500, according to D _j 、T _j And M _j Determining a sound level parameter of the jth first location; the sound level parameter represents the sound intensity of the sound received by the corresponding first position;

s600, determining a second position from the plurality of first positions according to the sound level parameter of each first position;

s700, marking each second position in the data to be displayed to obtain first target display data;

and S800, displaying the first target display data.

The invention has at least the following beneficial effects:

the method and the device respond to a position selection request of a user, acquire position coordinate information of a plurality of first positions and data information of a plurality of sound sources, determine target sound source information according to the position coordinate information of the first positions, determine second positions from the plurality of first positions according to sound level parameters of the first positions, mark the second positions, and obtain and display first target display data. According to the method and the device, the second position influenced by the noise is determined from the plurality of first positions according to the maximum sound intensity information of the sound source and the distance information between the sound source and the first positions as the basis for judging the influence of the noise, and the second position is marked, so that a user can visually observe the second position influenced by the noise, namely the marked first position.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings needed to be used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without creative efforts.

Fig. 1 is a schematic diagram of a data processing method for flight seat display according to a first embodiment of the present invention;

fig. 2 is a schematic diagram of a data processing method for flight seat display according to a second embodiment of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

A data processing method for flight seat display is used for displaying seats (first positions) in an airplane when a user purchases an air ticket.

A data processing method for flight seat display, comprising the steps of:

s100, responding to a position selection request of a user, and acquiring data to be displayed corresponding to the position selection request according to the position selection request of the user; the position selection request can be a ticket booking and seat selecting request of a user on public transport such as an airplane, and the user is a corresponding passenger. The data to be displayed includes a plurality of first positions and a plurality of sound sources, the sound sources are objects capable of emitting sounds with sound intensities higher than a first preset threshold, the first preset threshold can be a maximum sound decibel value of a person in quiet sleep, for example, 40 decibels, the sound sources can be objects generating sound intensities higher than 40 decibels, and the objects are considered as noise sources, for example, equipment influencing passenger rest, such as an engine, and as shown in fig. 1, horizontal and vertical stripe boxes at the edge position of an airplane are represented as the sound sources. The first position may be one of the positions of all seats on the airplane, as indicated by the white boxes in fig. 1, i.e., the first position;

s200, obtaining position coordinate information of a plurality of first positions to obtain a position coordinate information set M = { M = { (M) } ₁ ,M ₂ ,...,M _n }，M _j The method comprises the steps that corresponding position coordinate information of a jth first position in data to be displayed is obtained, j =1,2,.., n, n is the number of the first positions, the position coordinate information of the first positions can be a coordinate system with a central point of an airplane as an origin, and coordinate division is carried out on each first position according to the corresponding coordinate information of the first position on the coordinate system of the airplane;

s300, acquiring data information of a plurality of sound sources to obtain a data information set Q = { Q = { (Q) ₁ ,Q ₂ ,...,Q _k }，Q _h =(D _h ,T _h ) H =1, 2.. k, k is the number of sound sources, Q _h For data information of the h-th sound source, D _h The maximum sound intensity information corresponding to the h-th sound source. The maximum sound intensity information is selected as the data information of the sound source, and the seat which meets the user position selection request can be screened out, T _h Is Q _h The method comprises the steps that corresponding position coordinate information of a corresponding sound source in data to be displayed is the same as the position coordinate information of a first position in the building, and the sound source and the first position use the same coordinate system to carry out coordinate division on each sound source;

s400, according to the position coordinate information M of the jth first position _j Determining a target sound source information Q from the data information set Q _f(j) =(D _j ,T _j )，1≤f(j)≤k，Q _f(j) Target sound source information corresponding to the jth first position, target sound source information Q _f(j) The corresponding target sound source is the sound source closest to the jth first position, the sound source closest to the jth first position is selected as the target sound source, the maximum influence of noise on the jth first position can be determined, and D _j Maximum sound intensity information for the target sound source, T _j And obtaining corresponding position coordinate information of the target sound source in the data to be displayed. The target sound source is selected from several sound sourcesThe sound source closest to the jth first position, for example, the target sound source corresponding to the 1 st first position is the sound source closest to the 1 st first position, and the target sound source corresponding to the 2 nd first position is the sound source closest to the 2 nd first position. The target sound sources are multiple, each first position corresponds to one target sound source, the sound source closest to each first position is determined as the corresponding target sound source, and the influence of noise on each first position can be judged;

s500, according to D _j 、T _j And M _j Determining a sound level parameter of the jth first location; the sound level parameter represents the sound intensity of the sound received by the corresponding first position, and if the sound intensity of the sound received by the first position is higher, the higher the sound level parameter is, the greater the influence of the noise received by the first position is;

further, the step S500 includes:

s510, determining a target parameter value Y of the jth first position _j =βD _j /dist(M _j ,T _j )；

Wherein, beta is a correction coefficient to correct the target parameter influenced by noise at each first position, the correction coefficient is set to correct the deviation of the target parameter value at the first position to reflect the real performance of the target parameter value as much as possible, and D _j Maximum sound intensity information, dist (M) for the target sound source _j ,T _j ) Is M _j Corresponding first position and T _j The distance between the corresponding target sound sources can be obtained through the coordinate calculation of the target sound sources, if the vector subtraction represented by the coordinates is a negative number, the absolute value of the vector subtraction is taken, and dist () is a preset distance determining function and represents the distance between two pieces of data information in brackets. Judging the influence of noise on the first position according to the ratio of the maximum sound intensity of the target sound source closest to the first position to the distance between the first position and the target sound source;

s520, according to the target parameter value Y of the jth first position _j Determining a sound level parameter of the jth first location;

the method for determining the sound level parameter comprises the following steps:

if Y is _j If the sound level parameter is smaller than the first sound threshold, determining the sound level parameter of the jth first position as a first sound level parameter;

if Y is _j If the sound level parameter is greater than or equal to the first sound threshold and smaller than the second sound threshold, determining the sound level parameter of the jth first position as a second sound level parameter, wherein the second sound threshold is greater than the first sound threshold;

if Y is _j If the sound level parameter is larger than or equal to the second sound threshold, determining the sound level parameter of the jth first position as a third sound level parameter;

the determination limit value of the sound level parameter is divided into a first sound threshold value and a second sound threshold value, the smaller the sound level parameter is, the smaller the influence of noise on the corresponding first position is, so that the first sound level parameter can be regarded as the smallest influence of noise on the corresponding first position, the third sound level parameter can be regarded as the largest influence of noise on the corresponding first position, the first sound threshold value and the second sound threshold value are judgment nodes used for judging the sound level parameter, specific values of the first sound threshold value and the second sound threshold value can be determined according to actual conditions, the positions of sound sources are different due to different masses of airplanes, and the generated sound intensities are also different, and the specific first sound threshold value and the second sound threshold value are determined according to the masses of the airplanes.

S600, determining a second position from the plurality of first positions according to the sound level parameter of each first position, wherein the second position can be the first position influenced by the target sound source, and the second position is represented by a diagonal stripe box shown in fig. 1;

further, the step S600 includes:

s610, determining the first position where the sound level parameter is the second sound level parameter and the third sound level parameter as the second position, where the second sound level parameter and the third sound level parameter may indicate that the corresponding first position is greatly influenced by the target sound source, and screening the first position influenced by noise from the first position set as the second position.

S700, marking each second position in the data to be displayed to obtain first target display data, wherein each second position represents that the area where the second position is located is greatly influenced by noise, and marking each second position which is greatly influenced by the noise correspondingly, so that a user can observe the size of the noise influence of the area where each second position is located more intuitively;

further, the step S700 includes:

s710, marking the sound level parameter as a second position of a second sound level parameter as a second marking color;

s720, marking the sound level parameter as a second position of a third sound level parameter as a third marking color;

the second mark color and the third mark color are two different colors, and the influence degree of the noise represented by the third sound level parameter is larger than that represented by the second sound level parameter, so that the dark color can be selected as the third mark color, such as scarlet, and the color lighter than the third mark color is selected as the second mark color, such as pink, and the sound level parameter is represented by the shade of the mark color, and the influence degree of the noise in the area where the user is located can be known by observing the mark color of each second position.

S800, displaying first target display data, wherein the first target display data can be a marked second position, namely, the mark color is the second mark color and the second mark color of the third mark color, in addition, the sound level parameter is the first position of the first sound level parameter and can be marked as the first mark color, the color of the first mark color is lighter than that of the second mark color, the influence degree of the first mark color on noise is the lowest, and the first mark color can also be selected not to be marked as long as the purpose of distinguishing each first position according to the different influence degrees of the noise can be realized.

The steps S400 to S800 are the first embodiment of the present invention, and determine the second position affected by the noise from the plurality of first positions according to the sound intensity information of the sound source, and mark the second position affected by the noise with different colors, so that the user can more intuitively observe the noise level of the area where each first position is located, and a darker marked first position indicates that the area is affected by the noise to a greater extent, and the user can use the marked first position as a basis for determining seat selection and select a first position with a relatively lower noise level.

In the first embodiment of the invention, the strength information of the sound emitted by the equipment (sound source) which may generate noise on the airplane is used as the judgment basis to judge which seats of the candidate seats (a part of the first positions) on the airplane are affected by the noise, and each candidate seat affected by the noise is marked and displayed for the user to select the proper seat, namely the rest vacant seat on the airplane. Besides the fixed sound source on the airplane, there are other noise-generating factors, such as other passengers who have purchased the airplane ticket, because the user cannot know the identity information of other passengers who have purchased the airplane ticket before purchasing the airplane ticket, the user is not aware of the status of other passengers on the airplane flight, and can only know that the first position around the user has been reserved, if the person who has been reserved at the first position around the user has a fellow passenger, who cannot take the first position alone, such as a child aged 3 years, a noisy situation may occur during traveling, and because the user cannot know in advance, such a situation will also affect the user.

Therefore, in order to avoid the above mentioned influence, the second embodiment of the present invention is proposed, that is, the age information of the passenger on duty is used as the judgment basis to judge the influence of the noise on each first position, and it is generally considered that a child with a small age will generate a certain degree of noise because the child cannot move independently and is lively, and the noise will also affect the journey of the surrounding users, so the age information of the user on the seat selected on duty is used as the criterion for judging whether the noise will be generated and the degree of the noise generated.

In the second embodiment of the present invention, the aforementioned steps are all the same as steps S100 to S700 of the first embodiment, a coordinate system is defined with the central point of the aircraft as the origin, the coordinate system can be shared with the coordinate system of the first embodiment, and the coordinates of each first position on the aircraft are obtained, and after step S700 of the first embodiment, the data processing method for flight seat display according to the second embodiment further includes:

s710, obtaining a user information set A = { A) corresponding to data to be displayed ₁ ,A ₂ ,...,A _x }，A _b =（E _b ,F _b ,G _b ) B =1, 2.. x, x is the number of users corresponding to the data to be displayed, and the user information in the user information set a may be all users who have purchased air tickets, a _b User information corresponding to the b-th user, E _b The user identification information corresponding to the b-th user comprises a first identification and a second identification, the user identification information is used for distinguishing the identities of all users, if the user is on-duty, the user identification information is the first identification if the user is on-duty, and if the user is not on-duty, the user identification information is the second identification, F _b Age information corresponding to the b-th user, G _b Position coordinate information of the first position associated for the b-th user, G _b Position coordinate information of a first position where a user who has purchased an airline ticket is located, if the user has taken an opportunity, G _b Position coordinate information of a first position of a seat for check-in, G if the user is not checking in _b Empty, indicating that the user has not selected a seat;

s720, the user identification information in the user information set A is the user information of the first identification, the corresponding user is determined as the target user, the target user can be the user with the on-duty seat selection, the user with the on-duty seat selection is selected from the user information set A of all the users, the coordinate information of the first position selected by each user with the selected seat can be accurately checked, if the user does not have the on-duty seat selection, the corresponding coordinate information of the first position does not exist, the user does not belong to the target user, other information of the user does not need to be checked, and only the identity information of the user with the on-duty seat selection needs to be checked;

s730, acquiring a target user information set C = { C = { (C) ₁ ,C ₂ ,...,C _z }，1≤z≤x，C _d =（L _d ,H _d ) D =1, 2.. said, z, z is the number of target users, C _d User information for the d-th target user, L _d Is C _d Age information of the corresponding d-th target user, H _d Position coordinate information of a first position associated with the d-th target user, wherein the information set C is user information of the target user, and the target user is a user with a selected seat on the computer, so that each piece of user information has accurate position coordinate information of the first position of the selected seat;

s740, according to the age information of the target user, determining a third position from the plurality of first positions, wherein the third position is the target position, and selecting the user in a certain age interval by taking the age information of the target user as a judgment basis to show that the noise possibly generated by the user is relatively large, and the first position around the position where the user is located is determined as the third position;

s750, marking each third position in the first target display data to obtain second target display data;

and S810, displaying second target display data, wherein the second target display data can be a marked third position, and the marked third position is displayed, so that a user can know the noise range generated around the target user.

Further, the step S740 includes:

s741, if the age information of the target user belongs to a first age range, determining a corresponding first location as a fourth location, where the first age range may be from 2 to 10 years old, it is considered that the user in this age range may generate loud noise and may generate noise influence on the users around the user, and the first location where the user in this age range is located is determined as the fourth location, which is represented as a noise source, and is the same as the sound source in the first embodiment, and can be regarded as the sound source in the first embodiment, i.e., the fourth location, as represented by a black box shown in fig. 2;

s742, the first position having a distance from the fourth position smaller than the first distance value is determined as the third position, and the first distance value may indicate a range most affected by noise, and as long as the distance from the fourth position is smaller than the first distance value, it is considered as being affected by noise of the user corresponding to the fourth position, and is indicated as the third position as a dotted box shown in fig. 2.

Further, the step S750 includes:

s751, marking a third position, which is away from the fourth position by less than the first distance value and greater than the second distance value, as a fourth marking color;

s752, marking a third position with a distance from the fourth position smaller than the second distance value as a fifth marking color;

the second distance value is smaller than the first distance value, the influence range of the noise emitted by the fourth position is a circular range which takes the fourth position as a point and spreads outwards, namely, the circular range taking the fourth position as the center of a circle and the first distance value as the radius, because the influence of noise on the third position closer to the center of the circle is larger, therefore, a second distance value is defined, and a third position, which is considered to be a distance from the fourth position smaller than the second distance value, is most affected by noise, and the closer to the edge of the circular range, the less affected by noise from the fourth position, therefore, the third position, which is more affected by the noise, is marked to be dark, that is, the color of the fifth mark color is darker than that of the fourth mark color, in order to distinguish the influence degree of noise on each third position, and the fourth position can be marked with a sixth marking color so that the user can observe the position where the fourth position is located.

The fourth mark color, the fifth mark color and the sixth mark color in the second embodiment are distinguished from the second mark color and the third mark color in the first embodiment, the first embodiment and the second embodiment can be implemented by different colors, respectively, or by combination, the sound source or the user age can be used as a single judgment basis to judge the noise influence of the first position, or the sound source and the user age can be used as double judgment basis to judge the noise influence of the first position together, such as judging the noise influence degree together, more specifically, the influence degree of each first position by different noises is observed, each marking color also represents the different influence degrees generated by different noise sources, the first positions influenced by the noises are marked for the user to check, and the user can select the seats with smaller noise degrees according to the marking result.

In the second embodiment of the invention, in addition to taking the age information of the target user as a basis for judging the noise generation degree, the noise generation judgment method can also be used as a judgment factor for noise generation according to the history of the users who are logged in the blacklist of the navigation department, for example, after a certain user is logged in the blacklist of the navigation department, the first position selected by the user can be marked after the user selects a seat on the computer, the color of the mark can be determined according to the requirements of the user, the color of the mark can also be designated by a system, after the mark, the first position around the user can be marked with different colors, and the deeper the color of the mark closer to the first position of the user is, the higher the possibility of being influenced by the noise of the user is indicated.

The first embodiment and the second embodiment of the invention take the age information of the sound source on the airplane or/and the user who has purchased the air ticket as the judgment standard, and mark each first position of the flight correspondingly to represent different noise influence degrees, and the user can more intuitively know the noise influence degree of each first position through the mark colors with different colors.

The method comprises the steps of responding to a position selection request of a user, obtaining position coordinate information of a plurality of first positions, data information of a plurality of sound sources and user information of the user purchasing an air ticket, determining target sound source information according to the position coordinate information of the first positions, determining a second position from the plurality of first positions according to sound level parameters of the first positions, marking the second position, obtaining and displaying first target display data, determining a third position from the plurality of first positions according to age information of the target user, marking the third position, obtaining and displaying second target display data. The invention takes the sound intensity information of the sound source and/or the age information of the user as the basis for judging the influence of noise, marks the first position influenced by the noise, and the user can visually observe the second position and the third position of the mark, marks different mark colors according to different degrees influenced by the noise, acquires the degree of the influence of the noise on each first position, and displays the influence range of the noise on all flight seats.

Embodiments of the present invention also provide a non-transitory computer-readable storage medium, which may be disposed in an electronic device to store at least one instruction or at least one program for implementing a method of the method embodiments, where the at least one instruction or the at least one program is loaded into and executed by a processor to implement the method provided by the above embodiments.

Embodiments of the present invention also provide an electronic device comprising a processor and the aforementioned non-transitory computer-readable storage medium.

Embodiments of the present invention also provide a computer program product comprising program code means for causing an electronic device to carry out the steps of the method according to various exemplary embodiments of the invention described above in the present description, when said program product is run on the electronic device.

Although some specific embodiments of the present invention have been described in detail by way of illustration, it should be understood by those skilled in the art that the above illustration is only for the purpose of illustration and is not intended to limit the scope of the invention. It will also be appreciated by those skilled in the art that various modifications may be made to the embodiments without departing from the scope and spirit of the invention. The scope of the invention is defined by the appended claims.

Claims (10)

1. A data processing method for flight seat display, the method comprising the steps of:

s100, responding to a position selection request of a user, and acquiring data to be displayed corresponding to the position selection request; the data to be displayed comprises a plurality of first positions and a plurality of sound sources, and the sound sources are objects capable of emitting sounds with sound intensity higher than a first preset threshold;

s200, obtaining position coordinate information of a plurality of first positions to obtain a position coordinate information set M = { M = { (M) } ₁ ,M ₂ ,...,M _n }，M _j For the jth first position in the corresponding position in the data to be displayedTarget information, j =1,2,. ang, n, n is the number of first locations;

s300, acquiring data information of a plurality of sound sources to obtain a data information set Q = { Q = { (Q) ₁ ,Q ₂ ,...,Q _k }，Q _h =(D _h ,T _h ) H =1, 2.. k, k is the number of sound sources, Q _h For data information of the h-th sound source, D _h Maximum sound intensity information, T, for the h-th sound source _h Is Q _h Corresponding position coordinate information of the corresponding sound source in the data to be displayed;

s400, according to the position coordinate information M of the jth first position _j Determining a target sound source information Q from the data information set Q _f(j) =(D _j ,T _j )，1≤f(j)≤k，Q _f(j) Target sound source information corresponding to the jth first position, the target sound source information Q _f(j) The corresponding target sound source is the sound source closest to the jth first position, D _j Maximum sound intensity information for the target sound source, T _j Corresponding position coordinate information of the target sound source in the data to be displayed is obtained;

s500, according to D _j 、T _j And M _j Determining a sound level parameter of the jth first location; the sound level parameter represents the sound intensity of the sound received by the corresponding first position;

s600, determining a second position from the plurality of first positions according to the sound level parameter of each first position;

s700, marking each second position in the data to be displayed to obtain first target display data;

and S800, displaying the first target display data.

2. The method according to claim 1, wherein the step S500 comprises:

s510, determining a target parameter value Y of the jth first position _j =βD _j /dist(M _j ,T _j )；

Where β is a correction factor, dist(M _j ,T _j ) Is M _j Corresponding first position and T _j The distance between corresponding target sound sources, dist () is a preset distance determining function;

s520, according to the target parameter value Y of the jth first position _j Determining a sound level parameter of the jth first location;

the method for determining the sound level parameter comprises the following steps:

if Y is _j If the sound level parameter is smaller than the first sound threshold, determining the sound level parameter of the jth first position as a first sound level parameter;

if Y is _j If the sound level parameter is greater than or equal to the first sound threshold and smaller than the second sound threshold, determining the sound level parameter of the jth first position as a second sound level parameter, wherein the second sound threshold is greater than the first sound threshold;

if Y is _j And if the sound level parameter is larger than or equal to the second sound threshold, determining the sound level parameter of the jth first position as a third sound level parameter.

3. The method according to claim 2, wherein the step S600 comprises:

s610, determining the first position where the sound level parameter is the second sound level parameter and the third sound level parameter as the second position.

4. The method according to claim 3, wherein the step S700 comprises:

s710, marking the sound level parameter as a second position of a second sound level parameter as a second marking color;

and S720, marking the sound level parameter as a second position of the third sound level parameter as a third marking color.

5. The method of claim 1, wherein after the step S700, the method further comprises:

s710, obtaining a user information set A = { A } corresponding to data to be displayed ₁ ,A ₂ ,...,A _x }，A _b =（E _b ,F _b ,G _b ) B =1, 2.. times, x, x is the number of users corresponding to the data to be displayed, a _b User information corresponding to the b-th user, E _b User identification information corresponding to the b-th user, the user identification information comprising a first identification and a second identification, F _b Age information corresponding to the b-th user, G _b Location coordinate information for a first location associated with a b-th user;

s720, determining the user identification information in the user information set A as the user information of the first identification, and determining the corresponding user as a target user;

s730, acquiring a target user information set C = { C = { (C) ₁ ,C ₂ ,...,C _z }，1≤z≤x，C _d =（L _d ,H _d ) D =1, 2.. said, z, z is the number of target users, C _d User information for the d-th target user, L _d Is C _d Age information of the corresponding d-th target user, H _d Location coordinate information of a first location associated with a d-th target user;

s740, determining a third position from the plurality of first positions according to the age information of the target user;

s750, marking each third position in the first target display data to obtain second target display data;

step S800 is replaced with:

and S810, displaying the second target display data.

6. The method according to claim 5, wherein the step S740 comprises:

s741, if the age information of the target user belongs to the first age interval, determining the corresponding first position as a fourth position;

and S742, determining the first position with the distance from the fourth position smaller than the first distance value as the third position.

7. The method according to claim 6, wherein the step S750 comprises:

s751, marking a third position with a distance from the fourth position smaller than the first distance value and larger than the second distance value as a fourth marking color;

s752, marking a third position with a distance from the fourth position smaller than the second distance value as a fifth marking color;

the second distance value is less than the first distance value.

8. The method of claim 6, wherein the step S750 further comprises:

marking the fourth location as a sixth marking color.

9. A non-transitory computer readable storage medium having stored therein at least one instruction or at least one program, the at least one instruction or the at least one program being loaded and executed by a processor to implement the method of any one of claims 1-8.

10. An electronic device comprising a processor and the non-transitory computer readable storage medium of claim 9.

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