CN116156474B - Identification management method and system applied to intelligent scenic spot - Google Patents

Abstract

The invention relates to a data processing method and a system suitable for management in a new generation of information technology, and discloses an identification management system and a method applied to an intelligent scenic spot so as to improve the management and control capability of the scenic spot for processing emergency help. The method comprises the following steps: the method comprises the steps that a server obtains at least one class A tour area with the quality of a mobile communication signal lower than a threshold value and at least one class B tour area with the quality of the mobile communication signal equal to or greater than a set threshold value, which are divided in a scenic spot map; respectively marking SOS virtual identifiers corresponding to the offline intelligent identification system coordinates in each class A tour area for searching; and the client program prompts an on-line SOS operation mode in an operation menu of the scenic spot map, judges whether the current position of the mobile communication terminal corresponding to the SOS signal is in the scenic spot or not when the user sends the SOS signal in the corresponding on-line operation mode, and establishes communication connection with a scenic spot monitoring center through a server if the current position of the mobile communication terminal corresponding to the SOS signal is in the scenic spot.

Description

Identification management method and system applied to intelligent scenic spot

Technical Field

The invention relates to a data processing system and a method suitable for management in a new generation of information technology, in particular to an identification management method and a system applied to intelligent scenic spots.

Background

The traditional signboard has relatively simple interactivity and mainly takes guide information which cannot be changed easily. The intelligent identification is a good information carrier, and the intelligent identification can enable a user to find information wanted by the user in different places. Meanwhile, smart cities have become a future development direction of China cities.

The intelligent identifier is an identifier product combining a static identifier with software and hardware of the informatization system. Generally, an LED screen is used as a carrier, and technologies such as Internet of things, sensing technology and cloud computing are integrated, so that a static traditional identifier can be dynamically displayed under the drive of data, and an identifier manager can conveniently manage all the identifier devices in a field. On the basis of the advantages of high interactivity and flexible content replacement, the intelligent identification increases technological sense and fashion sense, can well improve the surrounding environment, enables the surrounding environment to be connected with high-end and fashion rails, and improves the image.

In tourist attractions, the traffic is mostly in light and strong seasons, so that the operation and maintenance cost for widely paving intelligent marks is not enough; in addition, the application of the existing intelligent identification in tourist attractions is mostly limited by the realization of simple functions, such as parking space allowance, toilet use condition and the like, and the cost performance is poor. Therefore, the functions of map navigation, real-time broadcasting of resource use conditions and the like are realized in part of tourist attractions through small programs or independent APP (application) in platforms such as WeChat, payment treasures and the like.

Meanwhile, in tourist attractions, the situations of potential safety hazards, sudden tourist diseases and the like caused by factors such as natural environment exist, and emergency rescue needs to be sought. The existing mobile communication terminals such as mobile phones and the like can send help seeking information to emergency contacts arranged in advance by continuously pressing a power key for 5 times, but most of the emergency contacts do not go out along with the mobile communication terminals, so that the contradiction that the emergency contacts are far hydrolyzed and nearly thirsty is not caused, and if the emergency contacts go out along with the mobile communication terminals, the emergency help seeking signals do not need to be sent under the condition that help can be provided. However, the scenic spot usually bears the responsibility of guaranteeing the life safety of tourists, and how to reasonably control such demands at low cost is mostly neglected and needs to be solved.

Disclosure of Invention

The invention aims to disclose an identification management method and an identification management system applied to an intelligent scenic spot so as to improve the management and control capacity of the scenic spot for processing emergency help.

In order to achieve the above purpose, the present invention discloses a method for managing an identifier applied to an intelligent scenic spot, comprising:

the server imports a scenic spot map;

the server acquires at least one class A tour area with the quality of the mobile communication signal lower than a threshold value and at least one class B tour area with the quality of the mobile communication signal equal to or greater than a set threshold value, which are divided in a scenic spot map;

the server performs differentiated visual presentation on the class B sightseeing areas and the class A sightseeing areas through different color assignments, marks SOS virtual identifiers corresponding to off-line intelligent identification system coordinates in the class A sightseeing areas respectively for a user to load corresponding client programs for searching through a mobile communication terminal, and the intelligent identification system comprises a camera, a talkback module and an SOS alarm module which are fixed on an identification support and are in wired communication connection with a scenic spot monitoring center;

the client program prompts an on-line SOS operation mode for a class B sightseeing area in an operation menu of a scenic spot map, judges whether the current position of a mobile communication terminal corresponding to the SOS signal is in a scenic spot or not when a user sends the SOS signal in a corresponding on-line operation mode is detected, and if so, establishes communication connection with a scenic spot monitoring center through the server; and the SOS on-line operation mode is different from the SOS emergency help-seeking mode inherent to various mobile communication terminals.

Preferably, the SOS on-line operation mode is to press the power key 4 times so as to intervene before the mobile communication terminal starts the inherent SOS emergency help.

Optionally, after the client program judges that the current position of the mobile communication terminal corresponding to the SOS distress signal is not in the scenic spot, the SOS distress signal is ignored or a user is prompted to perform related processing based on the inherent SOS emergency distress mode of the mobile communication terminal.

Further, in any one of the off-line intelligent identification systems, a control module which is respectively connected with the camera, the intercom module and the SOS alarm module is arranged, and any one of the control modules is respectively connected with the scenic spot monitoring center and the server in a communication way; the method further comprises the steps of:

the control module sets priority according to people flow density in the field of view acquired by the current camera when forwarding SOS distress signals of the SOS alarm module to the scenic spot monitoring center, forwards priority information to the server after monitoring that the local intercom module and the scenic spot monitoring center establish an intercom channel, and sends intercom ending information to the server after confirming that intercom is ended;

the server evaluates the processing pressure of the scenic spot monitoring center according to the synchronous processing capacity of the scenic spot monitoring center, the received priority information and the intercom ending information, and sends an SOS distress signal to the on-line operation mode according to the current processing pressure to carry out queuing processing in the forwarding process according to the priority;

the priority is divided into three levels, and when the people flow density in the field of view acquired by the camera is lower than a first threshold value, the priority is set to be high; setting to be low-level when the people flow density in the field of view acquired by the camera is higher than a second threshold value; setting the camera to be a middle stage when the people flow density in the field of view acquired by the camera is greater than or equal to a first threshold value and less than or equal to a second threshold value; the priority of SOS distress signals sent by the on-line operation mode is uniformly set as a middle level; in the queuing process, the priority is queued from high to low, and the same priority is subjected to queue maintenance according to the first-in first-out principle; correspondingly, the scenic spot monitoring center resolves the resource conflict according to the same priority rule.

In order to achieve the above object, the present invention also discloses an identification system applied to a smart scenic spot, comprising:

the off-line intelligent identification system comprises a camera, an intercom module and an SOS alarm module, wherein the camera, the intercom module and the SOS alarm module are fixed on an identification bracket and are in wired communication connection with a scenic spot monitoring center;

the server is used for importing a scenic spot map, acquiring at least one class A sightseeing area with the quality of a mobile communication signal lower than a threshold value and at least one class B sightseeing area with the quality of the mobile communication signal equal to or greater than a set threshold value, performing differentiated visual presentation on the class B sightseeing area and the class A sightseeing area through different color assignment, and respectively marking SOS virtual identifiers corresponding to offline intelligent identification system coordinates in each class A sightseeing area so as to enable a user to load corresponding client programs for searching through a mobile communication terminal;

the client program loaded by the mobile communication terminal is used for prompting an on-line SOS operation mode for the class B sightseeing area in an operation menu of the scenic spot map, judging whether the current position of the mobile communication terminal corresponding to the SOS signal is in the scenic spot or not when a user is detected to send the SOS signal in the corresponding on-line operation mode, and if so, establishing communication connection with the scenic spot monitoring center through the server; and the SOS on-line operation mode is different from the SOS emergency help-seeking mode inherent to various mobile communication terminals.

The invention has the following beneficial effects:

1. in the class B tour area, the mobile communication terminal can load a corresponding client program to send an on-line SOS emergency help; therefore, the intelligent identification system for sending SOS distress signals off-line can be simplified and even deployed in zero; the operation and maintenance cost of the scenic spot for processing the emergency help is saved.

2. SOS virtual identifiers corresponding to the offline intelligent identification system coordinates are marked in the A-type tour area of the scenic spot map respectively, so that users in the A-type tour area can conveniently search and navigate to a nearby intelligent identification system which sends SOS distress signals through an offline map downloaded in advance by a client program. In addition, the server performs differentiated visual presentation on the B-class sightseeing area and the A-class sightseeing area through different color assignments, and the corresponding client program also presents differentiated visual effects on the two-class areas, so that a user can conveniently and quickly select a sending mode of SOS distress signals according to current positioning, and the instantaneity of processing emergency recourse in a scenic spot is improved.

3. In the operation and maintenance process, scenic spot operators can broadcast and notice the tourists in B-type areas, scenic spot entrances and the like to download and install client programs in advance, so that mobile communication terminal resources carried by the tourists and intelligent identification systems under scenic spot lines can be integrated with complementary resources, and the management and control capacity of scenic spot processing emergency help is improved.

4. When a client program monitors that a user sends an SOS distress signal in a corresponding online operation mode, the client program is connected with a scenic spot monitoring center through a server only when judging that the current position of a mobile communication terminal corresponding to the SOS distress signal is in a scenic spot, so that the effectiveness and the accuracy of server forwarding are ensured.

5. The server and the inherent monitoring center of the scenic spot can reasonably manage and control the job through cooperation, so that the server has good expansibility (for example, a remote management interface which is opened to personnel of the monitoring center of the scenic spot and logged in by a browser or a client, and the SOS distress signal is shunted, etc.); therefore, the operation and maintenance cost brought by the inherent hardware upgrade of the scenic spot monitoring center can be reduced.

The invention will be described in further detail with reference to the accompanying drawings.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the invention. In the drawings:

fig. 1 is a schematic flow chart of an identification management method applied to a smart scenic spot according to an embodiment of the invention.

Detailed Description

Embodiments of the invention are described in detail below with reference to the attached drawings, but the invention can be implemented in a number of different ways, which are defined and covered by the claims.

Example 1

The embodiment discloses an identification management method applied to an intelligent scenic spot, as shown in fig. 1, comprising the following steps:

step S1, importing a scenic spot map by a server.

Step S2, the server acquires at least one class A tour area with the mobile communication signal quality lower than a threshold value and at least one class B tour area with the mobile communication signal quality equal to or greater than a set threshold value, which are divided in the scenic spot map.

In this step, the server preferably estimates the mobile communication signal quality of each coordinate point on each tour route in the scenic spot by importing the coordinates and configuration information (such as the number of channels and the relationship between the baseband and radio frequency processing capability and the transmission distance) of each base station in and adjacent to the scenic spot, and then determines the distribution attribute of the class a and class B tour areas by actual measurement.

In a specific actual measurement process, the scenic spot operator can carry two smart phones to communicate through a mobile communication network and observe the intensity of signals. More accurate measurements may be detected using specialized signal quality detection equipment, such variations being well known to those skilled in the art and not described in detail herein. In addition, in the dividing process of the A-type area and the B-type area, background developers can carry out area delineation and attribute classification in a manual edging mode.

Noteworthy are: the application scene of the invention is mainly based on remote tourist attractions, such as forest parks, which are usually far away from a base station and are affected by mountain bodies, terrains and the like, so that the scenic spots without mobile communication signals or with large fluctuation of the mobile communication signals along with the positions exist; while tourist attractions such as parks in city centers are not within the application scenario of the invention.

And S3, the server performs differentiated visual presentation on the class B sightseeing areas and the class A sightseeing areas through different color assignments, and marks SOS virtual identifiers corresponding to the coordinates of the offline intelligent identification system in each class A sightseeing area respectively for a user to load corresponding client programs for searching through the mobile communication terminal, wherein the intelligent identification system comprises a camera, an intercom module and an SOS alarm module which are fixed on an identification support and are in wired communication connection with a sightseeing area monitoring center.

In this step, the SOS virtual identifier is mainly used for navigation, so that the user can identify the precise location of the offline intelligent identification system. The sign support is mainly used for supporting the display of the sign, and the sign can be a traditional printing sign based on an acrylic panel or a smart sign based on a display screen. The cameras are connected with the scenic spot monitoring center, and the scenic spot monitoring center can flexibly schedule the cameras on the wall by adopting a spliced large screen. The intercom module is used for realizing voice call with intercom equipment of the scenic spot monitoring center, avoiding audio mixing with audio signals collected by videos, and ensuring communication effect between the scenic spot monitoring center and SOS sending help-seeking users; and the video channel of the camera and the voice channel of the intercom module are independent of each other, so that the basic notification function can be realized when the single-type channel fault is handled. In addition, in a communication topology network commonly constructed with a scenic spot monitoring center, each SOS alarm module, each camera and each intercom module are usually bound with a unique identifier, the system can bind components belonging to the same intelligent identification system into a site or a subnet, and each site or subnet is mapped with a unique positioning address, so that the linkage relation among the modules can be quickly established according to the mapping relation, and the resource scheduling scheme for processing emergency help is more convenient to determine according to positioning accuracy.

Step S4, the client program prompts an on-line SOS operation mode for the class B sightseeing area in an operation menu of the scenic spot map, judges whether the current position of a mobile communication terminal corresponding to the SOS signal is in the scenic spot or not when the SOS signal is detected to be sent by a user in a corresponding on-line operation mode, and establishes communication connection with a scenic spot monitoring center through a server if the current position of the mobile communication terminal corresponding to the SOS signal is in the scenic spot; and the SOS on-line operation mode is different from the SOS emergency help-seeking mode inherent to various mobile communication terminals.

Preferably, the SOS line of this embodiment is operated by pressing the power key 4 times to intervene before the mobile communication terminal starts the inherent SOS emergency call. By analogy, the inherent SOS emergency help-seeking mode of the mobile communication terminal is that the power key is pressed for 5 times, so that the preferred mode of the embodiment can not only minimize misjudgment caused by normal operation of the mobile communication terminal (generally, the adjacent interval of the pressing should be smaller than a set first threshold value, and the continuous overall duration is also smaller than a set second threshold value, for example, the first threshold value can be set to 2 seconds, the second threshold value can be set to 5 seconds, so that the urgency of operation of a user can be identified), but also can realize effective interception of a plurality of troubles such as repetition caused by the inherent SOS emergency help-seeking mode of the mobile communication terminal by quickly establishing communication connection with a scenic spot monitoring center.

In contrast, optionally, the client program in this embodiment may ignore the SOS distress signal or prompt the user to perform related processing based on the inherent SOS emergency distress mode of the mobile communication terminal after determining that the current location of the mobile communication terminal corresponding to the SOS distress signal is not in the scenic spot.

Example 2

The embodiment is further optimized based on the above embodiment 1, and specifically includes:

in any intelligent identification system under line, a control module which is respectively connected with the camera, the intercom module and the SOS alarm module is arranged, and any control module is respectively connected with the scenic spot monitoring center and the server in a communication way. The method of the embodiment further comprises the following steps:

and S4, when the control module forwards the SOS distress signal of the SOS alarm module to the scenic spot monitoring center, setting priority according to the people flow density in the field of view acquired by the current camera, after the local intercom module and the scenic spot monitoring center are monitored to establish an intercom channel, forwarding priority information to the server, and after the intercom is confirmed to be finished, sending intercom finishing information to the server.

And S5, the server evaluates the processing pressure of the scenic spot monitoring center according to the synchronous processing capacity of the scenic spot monitoring center, the received priority information and the intercom ending information, and sends an SOS distress signal to the on-line operation mode according to the current processing pressure to carry out queuing processing in the forwarding process according to the priority.

In the embodiment, the priority is specifically divided into three levels, and when the people flow density in the field of view collected by the camera is lower than a first threshold value, the priority is set to be high; setting to be low-level when the people flow density in the field of view acquired by the camera is higher than a second threshold value; setting the camera to be a middle stage when the people flow density in the field of view acquired by the camera is greater than or equal to a first threshold value and less than or equal to a second threshold value; the priority of SOS distress signals sent by the on-line operation mode is uniformly set as a middle level; in the queuing process, the server queues according to the priority from high to low and performs queue maintenance according to the first-in first-out principle with the same priority; correspondingly, the scenic spot monitoring center resolves the resource conflict according to the same priority rule.

To sum up, in this embodiment, based on the common sense that the people stream density is high, which is beneficial for the third party in the people stream to provide assistance, the priority of the whole system constructed based on complementarity is reasonably set, so that resource conflict under special conditions is effectively avoided, and further, the overall management and control capability of scenic spot processing emergency help is also improved.

Example 3

The present embodiment discloses an identification system applied to smart scenic spots, which at least includes:

the off-line intelligent identification system comprises a camera, an intercom module and an SOS alarm module, wherein the camera, the intercom module and the SOS alarm module are fixed on an identification support and are in wired communication connection with a scenic spot monitoring center.

The server is used for importing a scenic spot map, acquiring at least one A-type sightseeing area with the mobile communication signal quality lower than a threshold value and at least one B-type sightseeing area with the mobile communication signal quality equal to or greater than a set threshold value, performing differentiated visual presentation on the B-type sightseeing area and the A-type sightseeing area through different color assignment, and respectively marking SOS virtual identifiers corresponding to off-line intelligent identification system coordinates in each A-type sightseeing area so as to enable a user to load corresponding client programs for searching through the mobile communication terminal.

The client program loaded by the mobile communication terminal is used for prompting an on-line SOS operation mode for the class B sightseeing area in an operation menu of the scenic spot map, judging whether the current position of the mobile communication terminal corresponding to the SOS signal is in the scenic spot or not when a user is detected to send the SOS signal in the corresponding on-line operation mode, and if so, establishing communication connection with a scenic spot monitoring center through a server; and the SOS on-line operation mode is different from the SOS emergency help-seeking mode inherent to various mobile communication terminals.

Similarly, the SOS on-line operation mode in the system of this embodiment is preferably to press the power key 4 times to intervene before the mobile communication terminal starts the inherent SOS emergency call. Moreover, the operation mode is similar to the mode that the mobile communication terminal starts the inherent SOS emergency help, so that the user can conveniently memorize, and the user experience is improved.

Preferably, the server of this embodiment is further configured to: and estimating the quality of mobile communication signals of coordinate points on each sightseeing route in the scenic spot through the coordinates and configuration information of each base station led into and adjacent to the scenic spot, and determining the distribution attribute of the A-class and B-class sightseeing areas through actual measurement.

Optionally, the client program of the present embodiment is further configured to: after judging that the current position of the mobile communication terminal corresponding to the SOS distress signal is not in the scenic spot, ignoring the SOS distress signal or prompting a user to perform related processing based on the inherent SOS emergency distress mode of the mobile communication terminal.

Further, in the intelligent identification system under any line of the embodiment, a control module connected with the camera, the intercom module and the SOS alarm module respectively is provided, and any control module is connected with the scenic spot monitoring center and the server in a communication mode respectively. The control module is used for setting priority according to people flow density in the field of view acquired by the current camera when forwarding SOS distress signals of the SOS alarm module to the scenic spot monitoring center, forwarding priority information to the server after monitoring that the local intercom module and the scenic spot monitoring center establish an intercom channel, and sending intercom ending information to the server after confirming that intercom is ended. The server is matched with the on-line operation mode, and is also used for evaluating the processing pressure of the scenic spot monitoring center according to the synchronous processing capacity of the scenic spot monitoring center, the received priority information and the intercom ending information, and sending an SOS distress signal according to the current processing pressure to carry out queuing processing in the forwarding process according to the priority.

Similarly, the priority is divided into three levels, and when the people flow density in the field of view collected by the camera is lower than a first threshold value, the priority is set to be high; setting to be low-level when the people flow density in the field of view acquired by the camera is higher than a second threshold value; setting the camera to be a middle stage when the people flow density in the field of view acquired by the camera is greater than or equal to a first threshold value and less than or equal to a second threshold value; the priority of SOS distress signals sent by the on-line operation mode is uniformly set as a middle level; in the queuing process, the priority is queued from high to low, and the same priority is subjected to queue maintenance according to the first-in first-out principle; correspondingly, the scenic spot monitoring center resolves the resource conflict according to the same priority rule.

In summary, the method and system for managing the identifier applied to the smart scenic spot disclosed in each embodiment of the present invention have at least the following advantages:

1. in the class B tour area, the mobile communication terminal can load a corresponding client program to send an on-line SOS emergency help; therefore, the intelligent identification system for sending SOS distress signals off-line can be simplified and even deployed in zero; the operation and maintenance cost of the scenic spot for processing the emergency help is saved.

2. SOS virtual identifiers corresponding to the offline intelligent identification system coordinates are marked in the A-type tour area of the scenic spot map respectively, so that users in the A-type tour area can conveniently search and navigate to a nearby intelligent identification system which sends SOS distress signals through an offline map downloaded in advance by a client program. In addition, the server performs differentiated visual presentation on the B-class sightseeing area and the A-class sightseeing area through different color assignments, and the corresponding client program also presents differentiated visual effects on the two-class areas, so that a user can conveniently and quickly select a sending mode of SOS distress signals according to current positioning, and the instantaneity of processing emergency recourse in a scenic spot is improved.

3. In the operation and maintenance process, scenic spot operators can broadcast and notice the tourists in B-type areas, scenic spot entrances and the like to download and install client programs in advance, so that mobile communication terminal resources carried by the tourists and intelligent identification systems under scenic spot lines can be integrated with complementary resources, and the management and control capacity of scenic spot processing emergency help is improved.

4. When a client program monitors that a user sends an SOS distress signal in a corresponding online operation mode, the client program is connected with a scenic spot monitoring center through a server only when judging that the current position of a mobile communication terminal corresponding to the SOS distress signal is in a scenic spot, so that the effectiveness and the accuracy of server forwarding are ensured.

5. The server and the inherent monitoring center of the scenic spot can reasonably manage and control the job through cooperation, so that the server has good expansibility (for example, a remote management interface which is opened to personnel of the monitoring center of the scenic spot and logged in by a browser or a client, and the SOS distress signal is shunted, etc.); therefore, the operation and maintenance cost brought by the inherent hardware upgrade of the scenic spot monitoring center can be reduced.

The above description is only of the preferred embodiments of the present invention and is not intended to limit the present invention, but various modifications and variations can be made to the present invention by those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. An identification management method applied to an intelligent scenic spot is characterized by comprising the following steps:

the server imports a scenic spot map;

the server acquires at least one class A tour area with the quality of the mobile communication signal lower than a threshold value and at least one class B tour area with the quality of the mobile communication signal equal to or greater than a set threshold value, which are divided in a scenic spot map;

the server performs differentiated visual presentation on the class B sightseeing areas and the class A sightseeing areas through different color assignments, marks SOS virtual identifiers corresponding to off-line intelligent identification system coordinates in the class A sightseeing areas respectively for a user to load corresponding client programs for searching through a mobile communication terminal, and the intelligent identification system comprises a camera, a talkback module and an SOS alarm module which are fixed on an identification support and are in wired communication connection with a scenic spot monitoring center;

the client program prompts an on-line SOS operation mode for a class B sightseeing area in an operation menu of a scenic spot map, judges whether the current position of a mobile communication terminal corresponding to the SOS signal is in a scenic spot or not when a user sends the SOS signal in a corresponding on-line operation mode is detected, and if so, establishes communication connection with a scenic spot monitoring center through the server; and the SOS on-line operation mode is different from the SOS emergency help-seeking mode inherent to various mobile communication terminals.

2. The method of claim 1, wherein the SOS on-line operation is by pressing a power key 4 times to intervene before the mobile communication terminal initiates an inherent SOS emergency call.

3. The method according to claim 1 or 2, wherein the server estimates the quality of the mobile communication signal at each coordinate point on each tour route in the scenic spot by importing the coordinates and configuration information of each base station in and adjacent to the scenic spot, and then determines the distribution properties of the class a and class B tour areas by actual measurement.

4. The method according to claim 1 or 2, further comprising:

and after judging that the current position of the mobile communication terminal corresponding to the SOS distress signal is not in the scenic spot, the client program ignores the SOS distress signal or prompts a user to perform related processing based on the inherent SOS emergency distress mode of the mobile communication terminal.

5. The method according to claim 4, wherein a control module respectively connected with a camera, an intercom module and an SOS alarm module is arranged in any one of the off-line intelligent identification systems, and any one of the control modules is respectively connected with a scenic spot monitoring center and the server in a communication manner; the method further comprises the steps of:

the control module sets priority according to people flow density in the field of view acquired by the current camera when forwarding SOS distress signals of the SOS alarm module to the scenic spot monitoring center, forwards priority information to the server after monitoring that the local intercom module and the scenic spot monitoring center establish an intercom channel, and sends intercom ending information to the server after confirming that intercom is ended;

the server evaluates the processing pressure of the scenic spot monitoring center according to the synchronous processing capacity of the scenic spot monitoring center, the received priority information and the intercom ending information, and sends an SOS distress signal to the on-line operation mode according to the current processing pressure to carry out queuing processing in the forwarding process according to the priority;

the priority is divided into three levels, and when the people flow density in the field of view acquired by the camera is lower than a first threshold value, the priority is set to be high; setting to be low-level when the people flow density in the field of view acquired by the camera is higher than a second threshold value; setting the camera to be a middle stage when the people flow density in the field of view acquired by the camera is greater than or equal to a first threshold value and less than or equal to a second threshold value; the priority of SOS distress signals sent by the on-line operation mode is uniformly set as a middle level; in the queuing process, the server queues according to the priority from high to low and performs queue maintenance according to the first-in first-out principle with the same priority; correspondingly, the scenic spot monitoring center resolves the resource conflict according to the same priority rule.

6. An identification system for a smart attraction, comprising:

the off-line intelligent identification system comprises a camera, an intercom module and an SOS alarm module, wherein the camera, the intercom module and the SOS alarm module are fixed on an identification bracket and are in wired communication connection with a scenic spot monitoring center;

the server is used for importing a scenic spot map, acquiring at least one class A sightseeing area with the quality of a mobile communication signal lower than a threshold value and at least one class B sightseeing area with the quality of the mobile communication signal equal to or greater than a set threshold value, performing differentiated visual presentation on the class B sightseeing area and the class A sightseeing area through different color assignment, and respectively marking SOS virtual identifiers corresponding to offline intelligent identification system coordinates in each class A sightseeing area so as to enable a user to load corresponding client programs for searching through a mobile communication terminal;

the client program loaded by the mobile communication terminal is used for prompting an on-line SOS operation mode for the class B sightseeing area in an operation menu of the scenic spot map, judging whether the current position of the mobile communication terminal corresponding to the SOS signal is in the scenic spot or not when a user is detected to send the SOS signal in the corresponding on-line operation mode, and if so, establishing communication connection with the scenic spot monitoring center through the server; and the SOS on-line operation mode is different from the SOS emergency help-seeking mode inherent to various mobile communication terminals.

7. The system of claim 6, wherein the SOS on-line operation is by pressing a power key 4 times to intervene before the mobile communication terminal initiates an inherent SOS emergency call.

8. The system of claim 6 or 7, wherein the server is further configured to:

and estimating the quality of mobile communication signals of coordinate points on each sightseeing route in the scenic spot through the coordinates and configuration information of each base station led into and adjacent to the scenic spot, and determining the distribution attribute of the A-class and B-class sightseeing areas through actual measurement.

9. The system of claim 6 or 7, wherein the client program is further configured to: after judging that the current position of the mobile communication terminal corresponding to the SOS distress signal is not in the scenic spot, ignoring the SOS distress signal or prompting a user to perform related processing based on the inherent SOS emergency distress mode of the mobile communication terminal.

10. The system according to claim 9, wherein a control module connected to the camera, the intercom module and the SOS alarm module respectively is provided in any one of the off-line intelligent identification systems, and any one of the control modules is connected to the scenic spot monitoring center and the server in a communication manner respectively;

the control module is used for setting priority according to the people flow density in the field of view acquired by the current camera when forwarding the SOS distress signal of the SOS alarm module to the scenic spot monitoring center, forwarding priority information to the server after monitoring that the local intercom module and the scenic spot monitoring center establish an intercom channel, and sending intercom ending information to the server after confirming that intercom is ended;

the server is also used for evaluating the processing pressure of the scenic spot monitoring center according to the synchronous processing capacity of the scenic spot monitoring center, the received priority information and the intercom ending information, sending SOS distress signals according to the current processing pressure and carrying out queuing processing in the forwarding process according to the priority on-line operation mode;

the priority is divided into three levels, and when the people flow density in the field of view acquired by the camera is lower than a first threshold value, the priority is set to be high; setting to be low-level when the people flow density in the field of view acquired by the camera is higher than a second threshold value; setting the camera to be a middle stage when the people flow density in the field of view acquired by the camera is greater than or equal to a first threshold value and less than or equal to a second threshold value; the priority of SOS distress signals sent by the on-line operation mode is uniformly set as a middle level; in the queuing process, the server queues according to the priority from high to low and performs queue maintenance according to the first-in first-out principle with the same priority; correspondingly, the scenic spot monitoring center resolves the resource conflict according to the same priority rule.

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