CN111083676A

CN111083676A - Wireless linkage monitoring method, device and system

Info

Publication number: CN111083676A
Application number: CN201911395733.9A
Authority: CN
Inventors: 唐成礼; 梁文桦; 谢锦华; 徐力
Original assignee: Shenzhen Alm Technology Co ltd
Current assignee: Shenzhen Alm Technology Co ltd
Priority date: 2019-12-30
Filing date: 2019-12-30
Publication date: 2020-04-28
Anticipated expiration: 2039-12-30
Also published as: CN111083676B

Abstract

The invention discloses a wireless linkage monitoring method, wherein the method comprises the following steps: acquiring object access information corresponding to an object state beacon transmitted by at least one peripheral wireless sensing device in a wireless modulation mode; the cooperative service node carries out state monitoring analysis on the object access information to obtain object state identification information containing a plurality of state monitoring variables; the cooperative service node judges according to the object state identification information: when the state monitoring variable or the combination thereof is matched with a certain event trigger condition which is configured in advance, obtaining an event response correlation parameter corresponding to event trigger; and the cooperative service node responds to the associated parameters according to the linkage event to perform linkage adjustment control on the associated linkage monitoring processing equipment. Based on the technical scheme of the invention, the linkage monitoring system can respond to the event trigger from the wireless sensing equipment in real time and quickly focus the associated target object or space range, thereby obtaining the service capability with good timeliness and high reliability.

Description

Wireless linkage monitoring method, device and system

Technical Field

The invention relates to the field of wireless Internet of things, in particular to a wireless linkage monitoring method, device and system.

Background

With the rapid development of related technologies such as the internet, mobile communication, the internet of things and the like, the edge intelligent technology based on the wireless internet of things utilizes the integration and matching of modern wireless network communication technology, automatic control and sensing monitoring technology, cloud computing, database information processing and other technologies, and promotes the rapid development of product innovation and application scale degree of various intelligent hardware devices and intelligent information systems brought by the requirements of individuals and different industries/regions. The cloud computing and edge computing based data processing and artificial intelligence technology plays a key role in advancing of intelligent technologies.

The cooperative task (namely the cooperative service task) is a processing task forming a cooperative service flow module; perception service is the interactive processing of associated information caused by response based on object sensing and recognition; the information interaction processing comprises an information processing flow consisting of a plurality of technical means such as communication, modulation, tracking, monitoring, data acquisition and processing and the like.

Service node devices (such as local hosts, routers, base stations, gateways and the like) in a wireless edge domain and front-end sensing devices (such as wearable and portable accessory devices, mobile monitoring devices, distributed sensors and the like) and/or terminal execution devices (including peripheral control devices, terminal receiving devices, terminal monitoring devices and the like) serving as service object devices (namely devices bound or dynamically associated with service objects) have various information access and output interaction relations, including information broadcasting, sensing, triggering, transmitting and the like, so that purposes of local or remote information transmission, control, monitoring and the like are achieved.

The existing wireless edge domain network and the service node equipment thereof rely too much on the system service mode based on remote dispatch communication for the information interaction service of the peripheral service objects, but the cooperative communication and cooperative service capability among the service node equipment in the field edge domain network are weak, and the defects are mainly represented by the cooperativity and real-time property of the field local network for real-time response to event triggering: 1) the service node equipment has relatively strong capability for data communication service (including data acquisition and uploading) of peripheral service object equipment, but lacks association response processing capability (including preposed data processing, analysis and identification, judgment decision and response processing) based on a predetermined scheme for field event triggering; the collected large amount of redundant data needs to be uploaded to a system host, which results in the decrease of real-time performance, reliability and service capacity (referring to the number of devices that can simultaneously serve objects in parallel in the same edge domain or service node device).

2) Service node devices in a wireless edge domain network and user smart phones which are dynamically moved in lack of more cooperativeness when information interaction and service are carried out on service object devices bound or associated with users, and due to the fact that the user smart phones are excessively dependent on connecting associated accessory devices of the user smart phones to carry out data communication uploading and remote scheduling communication service, the cooperativeness, flexibility, compatibility and instantaneity of the service are reduced.

3) Monitoring, collecting and data processing and application service management of service object equipment mainly depend on binding of a smart phone and a system host/server by a user, and essential field cooperative processing capability is lacked; the lack of more effective management of the relationship between the monitoring acquisition information obtained by different monitoring methods and different service object devices and the common related information (such as location, environment, event) results in the decrease of the service's cooperativity, timeliness and perception or efficiency of the various related information and its events in the field.

Disclosure of Invention

The technical problems to be solved by the invention include that the on-site real-time response and the rapid identification are carried out on event triggering, and the associated target object or the space range is rapidly focused, so that the service capability with good timeliness and high reliability is obtained, and the method comprises the following steps:

the cooperative service node performs rapid wireless detection response and state monitoring identification on the service object equipment dynamically accessed in a mobile manner through wireless scanning modulation and access response filtering; performing state monitoring analysis on object access information corresponding to an object state beacon sent by wireless sensing equipment in a wireless modulation mode to obtain object state identification information containing a plurality of state monitoring variables; dynamic wireless signal coupling optimization is realized through wireless scanning modulation when necessary; and rejecting non-valid (or non-preferential) service object equipment layer by layer through access response filtering; the service efficiency of wireless detection response and sensing identification of the wireless edge domain to more peripheral effective service object devices is improved.

Through state monitoring analysis, object state identification information containing a plurality of state monitoring variables is extracted from object access information, so that the cooperative service node equipment has flexible dynamic configurability for state monitoring and identification perception of different service object equipment, and the compatibility, flexibility and timeliness of state monitoring and identification perception of different service object equipment are improved.

Through state analysis identification and event trigger identification (based on event trigger conditions), the wireless edge domain has strong processing capacity of quick response and identification based on plan association for field event trigger, so that the real-time performance and reliability of service and the capacity of serviceable object equipment are improved.

The cooperative service node indexes based on the event response plan to obtain event response correlation parameters corresponding to event triggering; performing the linkage adjustment control on the associated linkage monitoring processing equipment according to the event response association parameters; for linkage event triggering from wireless sensing equipment (serving as service object equipment), indexing is carried out based on an event response plan, and event response association parameters corresponding to the event triggering are obtained so as to carry out linkage monitoring of rapid focusing on a specified associated target object or a space range, and the technical effects of high response speed, high reliability and good timeliness are obtained compared with the prior art; therefore, the real-time response and field service capability of the linkage monitoring system are improved.

Therefore, according to a first aspect, an embodiment of the present invention discloses a wireless linkage monitoring method, in which a linkage coordination service node performs linkage adjustment control on a linkage monitoring processing device based on a trigger response from a wireless sensing device, the method including: the cooperative service node acquires object access information corresponding to an object state beacon sent by at least one peripheral wireless sensing device in a wireless modulation mode in a wireless detection response mode; the cooperative service node carries out state monitoring analysis on the object access information to obtain object state identification information containing a plurality of state monitoring variables; the cooperative service node judges according to the object state identification information: when the state monitoring variable or the combination thereof is matched with a certain event triggering condition which is configured in advance, the cooperative service node indexes based on the event response plan to obtain an event response correlation parameter corresponding to the event triggering; and the cooperative service node responds to the associated parameters according to the linkage event to perform linkage adjustment control on the associated linkage monitoring processing equipment.

Optionally, the object state analysis configuration information is mode information for performing state analysis and identification on object access information of a certain type of wireless sensing device, and the object state analysis configuration information includes: 1) the name or classification number of the wireless sensing device and/or the object status beacon; 2) a data segment for state variable resolution.

Optionally, the cooperative service node performs judgment according to the state monitoring variable, specifically: when the current values or time-space domain variation values of one or more state monitoring variables or the combination thereof in the object state identification information are matched with a certain event trigger condition configured in advance, the cooperative service node obtains corresponding event trigger identification information; the event trigger identification information is information obtained based on state variable analysis and event trigger conditions, and the event trigger identification information is information which can be referred to and used for responding and/or tracking, and is used for referring to an index to obtain event trigger response information, and the event trigger response information comprises any one or combination of event classification information, event response plan information and event tracking index information.

Optionally, the event trigger condition is a preset judgment condition that is judged according to a state range and/or a state jump of the specified state monitoring variable or the combination thereof, the state range is a trigger condition that is judged according to the state jump composed of a current value or a time-space domain variation value of the state monitoring variable or the combination thereof, and the trigger condition of the state jump includes a boundary condition, a jump direction and a stable jump condition; the event triggering condition also comprises a processing priority of the event triggering response, wherein the processing priority is to shield the execution of the classified service specification contained in the service processing plan triggered by the low-priority event in the effective holding period of the execution process or the execution of the service processing plan triggered by the high-priority event.

Optionally, the cooperative service node indexes based on the event response plan to obtain an event response associated parameter corresponding to the event trigger, specifically: the cooperative service node obtains an event response associated parameter according to the index of the event response plan based on the event trigger identification information, and the direct information or index information of the event response associated parameter is contained in the event response plan configuration information; before the cooperative service node performs linkage adjustment control on the bound or associated service object equipment, indexing event response associated parameters, wherein the event response associated parameters comprise linkage monitoring associated parameters; the cooperative service node performs corresponding linkage adjustment control on linkage monitoring equipment serving as service object equipment based on the event response correlation parameter or the linkage monitoring correlation parameter; and the cooperative service node processes the monitoring data based on the event trigger identification information and/or the event response association parameters, and performs corresponding linkage adjustment control on the linkage monitoring equipment according to output information of the monitoring data processing.

Optionally, the linkage monitoring device is an audio and video peripheral, and before the collaborative service node performs linkage adjustment control on the associated audio and video peripheral, the collaborative service node indexes event response associated parameters based on event trigger identification information and performs corresponding adjustment control on the audio and video peripheral; the event trigger identification information includes service object information associated with a wireless sensor device as a service object device; the event trigger identification information further comprises a direction angle and a position range between the service object devices obtained by the cooperative service node through monitoring data processing.

Optionally, the linkage monitoring device is a monitoring camera, the event response correlation parameter is a monitoring camera adjustment parameter, and the monitoring camera adjustment parameter includes a lens adjustment and focusing parameter and/or an image and audio/video processing parameter; the cooperative service node firstly adjusts the camera according to the lens adjustment and the focusing parameters, quickly focuses on a target object or a space range associated with the wireless sensing equipment, and then carries out corresponding monitoring record and monitoring information processing according to the image and the audio and video processing parameters.

Optionally, the classification service specification further comprises linkage event data processing, and the linkage event data processing comprises: 1) recording event data: backup storage and event log storage of object data acquisition; 2) linkage data transmission: performing linkage control, linkage alarm, linkage calling or data transmission of other specific data packets on the appointed wireless sensing equipment or the appointed wireless sensing equipment group in a wireless calling or wireless connection establishing mode; 3) adjusting a monitoring mode: adjusting the process parameters of object data acquisition and processing, and adjusting the monitoring data and event identification parameters and modes.

According to a second aspect, an embodiment of the present invention provides a wireless monitoring linkage device, including: the beacon detection module is used for acquiring object access information corresponding to an object state beacon sent by peripheral wireless sensing equipment in a wireless detection response mode in cooperation with the service node; the state monitoring module is used for monitoring and analyzing the state of the object access information by the cooperation of the service node to obtain object state identification information containing a plurality of state monitoring variables; and the trigger response module is used for judging by the cooperative service node according to the state monitoring variable: when the state jump of the state monitoring variable or the combination thereof is matched with a certain event trigger condition which is configured in advance, corresponding event trigger identification information is obtained; the task creating module is used for serving as a related collaborative routing node in the collaborative service node, and creating a corresponding new collaborative task item according to the index of the event response plan based on the event trigger identification information; and the task monitoring module is used for performing cooperative monitoring task management on the cooperative task items by the cooperative routing node, wherein the cooperative monitoring task management comprises task allocation and monitoring.

According to a third aspect, the present invention provides a wireless linkage monitoring system, the system comprising: the cooperative service node is used for acquiring object access information corresponding to an object state beacon sent by the peripheral wireless sensing equipment in a wireless detection response mode, performing state monitoring analysis on the object access information to acquire object state identification information containing a plurality of state monitoring variables, and judging according to the state monitoring variables: when the state jump of the state monitoring variable or the combination thereof is matched with a certain pre-configured event trigger condition, corresponding event trigger identification information is obtained to be used as a related collaborative routing node, and a corresponding new collaborative task item is created according to the index of the event response plan based on the event trigger identification information; the cooperative routing node is used for performing cooperative monitoring task management on the cooperative task item, and the cooperative monitoring task management comprises task allocation and monitoring; and the wireless sensing equipment is used for receiving the wireless detection message of the service node and sending the object access information corresponding to the object state beacon to the service node.

According to a fourth aspect, the present invention provides a computer terminal comprising a processor for executing a computer program stored in a memory to implement the method of any one of the first aspect described above.

According to a fifth aspect, the present invention provides a computer readable storage medium having stored thereon a computer program for implementing the method of any one of the first aspect above.

The invention has the beneficial effects that:

compared with the prior art, the developed edge domain and collaborative service node device and system for the wireless Internet of things have the on-site, rapid and efficient mechanisms of state perception monitoring, event recognition response, network mode scheme selection, task collaborative processing and the like for peripheral service object equipment, and the local and remote combined online data processing and information service capability.

(1) The comprehensive perception capability and the associated event response processing capability of the service object equipment are as follows: according to the technical scheme, efficient collaborative data processing is carried out between each service node device and the collaborative routing node, based on scanning detection of wireless beacon broadcast of the service object device, identity, position and state information of a plurality of surrounding service objects are effectively and rapidly sensed, identified and monitored, and classified event response and processing are carried out based on the service object device and associated event trigger identification according to service object configuration and event plan configuration.

(2) The timeliness of the network cooperation information interaction service based on wireless perception triggering is as follows: the technical scheme of the patent shows technical advancement in the aspect of timeliness of wireless intelligent perception, the wireless edge domain and the cooperative service node equipment thereof not only have the data communication capacity and the data cooperative processing capacity of the Internet of things, but also have stronger independent capacity in a single service node or subnet area, so that the wireless edge domain and the cooperative service node equipment thereof have better timeliness of information interactive service triggered based on perception. When the same information interaction service needs to be obtained, the requirement on real-time network data flow of the Internet layer can be reduced, and the information interaction service based on perception triggering can be normally provided for the service object under the condition that a remote server or a system is not required to be disconnected.

(3) Low power consumption preference mechanism (substantial saving of power consumption of service object devices): the service object device of the technical scheme of the patent is not only a smart phone, but also comprises intelligent wearable devices without mobile network communication capacity and other intelligent portable monitoring devices. The wireless edge domain and the cooperative service node thereof dynamically modulate and manage the wireless sensing mode, the associated parameters thereof and the network service mode based on a low-power-consumption optimal strategy according to the current state and event trigger of the service object equipment and by combining the system service requirement and the surrounding environment resource.

(4) On-site collaborative data processing capability: the monitoring and data acquisition processing of the service object equipment not only depends on the binding of the smart phone and the system host/server by the user, but also comprises the monitoring and processing of the cooperative tasks based on event trigger response born by the field cooperative service node and the related edge calculation and data processing, so that the necessary field cooperative data processing capacity is improved; the processing capability and efficiency of the wireless edge domain for sensing various relevant information and events thereof on site are improved.

(5) The user smart phone is used as a dynamic cooperative service node: service node equipment in the wireless edge domain network and user smart phones which are dynamically moved in have more cooperativeness when information interaction and service are carried out on service object equipment bound or associated by users, so that the cooperativeness, flexibility, compatibility and instantaneity of providing information interaction service for associated accessory equipment of the user smart phones are improved.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and other drawings can be obtained by those skilled in the art without creative efforts.

FIG. 1 is a flow chart of a wireless linkage monitoring method according to an embodiment of the present invention;

fig. 2 is a schematic structural diagram of a wireless linkage monitoring device according to an embodiment of the present invention.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the accompanying drawings, and it should be understood that the described embodiments are some, but not all embodiments of the present invention. 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.

Example one

Please refer to fig. 1, which is a flowchart illustrating a wireless linkage monitoring method according to an embodiment of the present disclosure, the wireless linkage monitoring method includes:

step S101, the cooperative service node acquires object access information corresponding to an object state beacon sent by at least one peripheral wireless sensing device in a wireless modulation mode in a wireless detection response mode;

step S102, the cooperative service node carries out state monitoring analysis on the object access information to obtain object state identification information containing a plurality of state monitoring variables;

step S103, the cooperative service node judges according to the object state identification information: when the state monitoring variable or the combination thereof is matched with a certain event triggering condition which is configured in advance, the cooperative service node indexes based on the event response plan to obtain an event response correlation parameter corresponding to the event triggering;

and step S104, the cooperative service node responds to the associated parameters according to the linkage event to perform linkage adjustment control on the associated linkage monitoring processing equipment.

It should be noted that, when a plurality of cooperative service nodes serve as service nodes in an edge domain of the internet of things to perform edge cooperative service on peripheral service object devices, the wireless sensing device (serving as a front-end sensing device) and the linkage monitoring device (serving as a terminal execution device) are different types of service object devices in the edge domain of the internet of things.

It should be further noted that, if scanning and detecting of the service object need to be performed based on cooperative modulation, the task items of the linkage monitoring further include a cooperative modulation task item, specifically: a cooperative modulation base station serving as a cooperative service node analyzes object access information of an object state beacon sent by service object equipment, and extracts a beacon modulation state identifier; judging the beacon modulation state identifier based on the beacon modulation trigger condition; if the service object equipment needs to be subjected to cooperative beacon modulation, the cooperative modulation base station sends a beacon modulation data frame containing beacon modulation information to the service object equipment according to the configuration information of the beacon modulation scheme; the service object device sets a corresponding beacon modulation state identifier according to the beacon modulation information in the received beacon modulation data frame, and executes beacon modulation state resetting according to a corresponding specified mode.

The service node device: the local area network of the Internet of things is oriented to network communication node equipment which provides information interaction service for service node equipment. The cooperative service node: a service node apparatus which can provide a cooperative service to a service object apparatus through multi-node interconnection.

One of the plurality of cooperative service nodes assumes the role of the cooperative routing node based on the dynamic role triggering of the cooperative service information processing process, wherein the dynamic role triggering comprises the following steps:

1) triggering based on network dynamic attributes, wherein the network dynamic attributes comprise device dynamic node roles and/or network dynamic topology attributes;

2) triggered based on dynamic processing timing, including event trigger timing and/or task trigger timing.

When the cooperative service node triggers and finds that cooperative task items meeting dynamic role triggering to a plurality of surrounding service object devices and monitoring events thereof in the same time period exceed a preset number, the priority of the cooperative task items meeting the dynamic role triggering is determined according to the associated object type, the emergency degree of the event and/or the beacon signal response physical quantity of the service object devices.

The object state beacon is a wireless beacon which is sent by the service object equipment and reflects the characteristic attribute and the current physical state of the equipment and the associated service object; the wireless beacon is a wireless signal which is sent by the wireless equipment in an intermittent periodic mode in a wireless broadcast or response mode, contains equipment states and other short messages and can be acquired by the similar wireless equipment at the periphery through wireless detection.

And (3) wireless beacon configuration: the wireless equipment sets and/or starts the process for the beacon sending data contained in the wireless beacon sent by the wireless equipment; the wireless beacon configuration comprises broadcast beacon configuration and response beacon configuration;

object beacon configuration: wireless beacon configuration for an object status beacon transmitted by a service object device;

service beacon configuration: wireless beacon configuration of a node service beacon transmitted by a serving node device.

Wireless scanning modulation: in the wireless scanning detection process, the cooperative service node dynamically sets the value range and the time domain value of the radio frequency control parameter transmitted and received by the wireless signal of the equipment or the specified service object equipment so as to adjust the transmitting and receiving coupling performance of the wireless signal; the wireless scanning modulation comprises wireless scanning receiving modulation and wireless beacon transmitting modulation:

1) wireless scanning receiving modulation: setting and starting process of coordinating service node to adjust radio frequency receiving control parameter of signal detection coupling performance of wireless detection response of equipment;

2) wireless beacon transmission modulation: setting and starting process for adjusting radio frequency emission time sequence parameters of wireless beacon signals sent by wireless equipment (service node equipment or service object equipment);

the wireless scanning modulation comprises the following modes:

(1) the service node equipment or the service object equipment actively changes the radio frequency control parameters of the equipment on the basis of the current modulation configuration information;

(2) and the service object equipment and the service node equipment carry out readjustment setting and starting on the current modulation configuration information based on the dynamic modulation requirement.

Wireless beacon transmission modulation: setting and starting process for adjusting radio frequency emission time sequence parameters of wireless beacon signals sent by wireless equipment; the wireless beacon transmitting modulation comprises object beacon modulation and service beacon modulation; object beacon modulation: wireless beacon transmission modulation is performed on an object state beacon transmitted by a service object device; modulation of service beacon: modulation of wireless beacon transmission of node service beacons transmitted by a serving node device.

The corresponding relation between the beacon modulation state and a group of object beacon modulation parameters is preset through program parameters or configuration information; the beacon modulation status is an index sequence number, and has a corresponding relationship with a set of object beacon modulation parameters (if the beacon is a connectable wireless beacon, the beacon modulation status may further include associated scan listening slot parameters or default values): beacon modulation state S object beacon modulation parameter M [ N ]; (scanning listening slot (time window) width: Tw).

The object beacon modulation parameter is composed of one or more different beacon radio frequency transient values and corresponding interval time multiplying factors:

beacon transmission transient L0, interval time T0, (phase time);

beacon transmission transient L1, interval time T1, (phase time);

beacon transmission transient L2, interval time T2, (phase time);

typically, the beacon radio frequency transient value is a beacon transmission power level, and the object beacon modulation parameter is composed of one or more different beacon transmission power levels and corresponding beacon interval times; the beacon interval time is an integer multiple of the reference interval time. The object beacon modulation parameters are pre-given by the program parameters and can be updated by a dynamic reset.

The beacon transmission power level configuration comprises calibration values of the transmission power corresponding to different beacon transmission powers and the reference deviation:

beacon transmit power level 0, transmit power P0, reference offset Δ 0;

beacon transmit power level 1, transmit power P1, reference offset Δ 1;

beacon transmit power level 2, transmit power P2, reference offset Δ 2;

the reference deviation is the deviation of the response physical quantity of a beacon signal of a certain association between the current beacon transmission power level and a certain reference beacon transmission power level; typically, the beacon signal response physical quantity is a positioning signal reception variable corresponding to a specified service target device, and the reference deviation Δ is a positioning signal reception reference deviation Δ Xt.

The beacon reception sensitivity level configuration includes calibration values of reception sensitivity and reference deviation corresponding to different beacon reception sensitivities:

beacon reception sensitivity level 0, reception sensitivity S0, reference deviation Δ 0

Beacon reception sensitivity level 1, reception sensitivity S1, reference deviation Δ 1

Beacon reception sensitivity level 2, reception sensitivity S2, reference deviation Δ 2

The reference deviation is the deviation of the response physical quantity of a beacon signal of a certain association between the current beacon receiving sensitivity level and a certain reference beacon receiving sensitivity level; typically, the beacon signal response physical quantity is a positioning signal receiving variable, and the reference deviation Δ is a positioning base station receiving reference deviation Δ Xr corresponding to the specified serving node device.

In the specific implementation process, the classification authority verification information is configuration information of a classification authority verification calculation parameter and/or a check parameter corresponding to the object identification code list or the object classification code/group code thereof; the classification authority verification information is information for further identifying authority classification of the service object device, service limitation information (such as range, space, time), and additional security verification.

In a specific implementation process, the object state analysis configuration information is mode information for performing state analysis identification on object access information of a certain type of wireless sensing equipment, and the object state analysis configuration information includes: 1) the name or classification number of the wireless sensing device and/or the object status beacon; 2) a data segment for state variable resolution.

The method comprises the steps that a plurality of cooperative service nodes in the edge domain of the Internet of things, wherein the cooperative routing nodes which take the role of cooperative routing, perform cooperative positioning monitoring calculation according to the current values or time-space domain variation values of state monitoring variables of the wireless sensing equipment at the same time interval from a plurality of cooperative service nodes and the self positions of the plurality of cooperative service nodes to obtain the calculated values of the cooperative positioning characteristic variables of the wireless sensing equipment;

and the cooperative positioning monitoring calculation also comprises the step of calculating and evaluating positioning state monitoring variables related to other positions nearby according to the cooperative positioning characteristic variables corresponding to different positions, wherein the positioning state monitoring variables are state monitoring variables related to the environment space or the positions.

The time-space domain change value is a corrected calculation value obtained by the cooperative service node on the basis of a variable value obtained by the time near term and/or space approach on the state monitoring variable and the current value of the state monitoring variable in a specific mathematical fitting mode, wherein the specific mathematical fitting mode comprises a calculation method for fitting and correcting the variable value, and the calculation method comprises the mathematical methods of filtering, averaging, interpolating, predicting and the like.

The state jumps to: when the current value or the time-space domain variation value of the state monitoring variable or the combination thereof is different from the current value range, whether the preset value domain jump occurs is further judged according to the instant jump or stable jump condition. Instant jump: when the current value of the state monitoring variable is different from the previous region, the current value is considered to have value range jump; and (3) stable jumping: and judging value range jump based on anti-jitter processing, wherein the value range jump judgment comprises any one or a combination of the following modes: 1) and (3) stable jumping of a boundary: when the variable value is in a predetermined value range boundary cache region, the value range jump is not considered to occur; 2) and (3) stable and jumping of the period: examining statistical values (such as average value, maximum value and minimum value) of the state monitoring variable in a preset period; the value range jump decision may be selective for jumps in different directions, such as wide-in-strict: the forward jump is determined according to the instantaneous jump determination mode, and the reverse jump is determined according to the stable jump determination mode.

In a specific implementation process, the cooperative service node performs judgment according to the state monitoring variable, specifically: when the current values or time-space domain variation values of one or more state monitoring variables or the combination thereof in the object state identification information are matched with a certain event trigger condition configured in advance, the cooperative service node obtains corresponding event trigger identification information;

the event trigger identification information is information obtained based on state variable analysis and event trigger conditions, and the event trigger identification information is information which can be referred to and used for responding and/or tracking, and is used for referring to an index to obtain event trigger response information, and the event trigger response information comprises any one or combination of event classification information, event response plan information and event tracking index information.

In the specific implementation process, the event triggering condition is a preset judgment condition which is judged according to the state range and/or the state jump of the specified state monitoring variable or the combination of the state monitoring variable, the state range is a triggering condition which is judged according to the state jump formed by the current value or the time-space domain change value of the state monitoring variable or the combination of the state monitoring variable, and the triggering condition of the state jump comprises a boundary condition, a jump direction and a stable jump condition; the event triggering condition also comprises a processing priority of the event triggering response, wherein the processing priority is to shield the execution of the classified service specification contained in the service processing plan triggered by the low-priority event in the effective holding period of the execution process or the execution of the service processing plan triggered by the high-priority event.

The event trigger condition further includes a spatiotemporal range definition for event triggering, the spatiotemporal range definition including a start-stop time definition and/or a location range definition.

In a specific implementation process, the event response plan includes event trigger response information, which is index information of the collaborative service processing plan specified based on the event trigger condition; the event response plan is configured as configuration information for pre-associating the event trigger authority, the event trigger condition and the collaborative service processing plan, and the configuration information of the event response plan may further include: the event response associates parameters and/or a collaborative service task flow.

In a specific implementation process, the cooperative service node indexes based on the event response plan to obtain event response associated parameters corresponding to event triggers, specifically:

the cooperative service node obtains an event response associated parameter according to the index of the event response plan based on the event trigger identification information, and the direct information or index information of the event response associated parameter is contained in the event response plan configuration information; before the cooperative service node performs linkage adjustment control on the bound or associated service object equipment, indexing event response associated parameters, wherein the event response associated parameters comprise linkage monitoring associated parameters;

the cooperative service node performs corresponding linkage adjustment control on linkage monitoring equipment serving as service object equipment based on the event response correlation parameter or the linkage monitoring correlation parameter; and the cooperative service node processes the monitoring data based on the event trigger identification information and/or the event response association parameters, and performs corresponding linkage adjustment control on the linkage monitoring equipment according to output information of the monitoring data processing.

In a specific implementation process, the linkage monitoring equipment is an audio and video peripheral, and before the linkage adjustment control is performed on the associated audio and video peripheral by the cooperative service node, the event response associated parameters are indexed based on event trigger identification information, and the corresponding adjustment control is performed on the audio and video peripheral;

the event trigger identification information includes service object information associated with a wireless sensor device as a service object device; the event trigger identification information further comprises a direction angle and a position range between the service object devices obtained by the cooperative service node through monitoring data processing.

Optionally, the linkage monitoring device is a monitoring camera, the event response correlation parameter is a monitoring camera adjustment parameter, and the monitoring camera adjustment parameter includes a lens adjustment and focusing parameter and/or an image and audio/video processing parameter;

the cooperative service node firstly adjusts the camera according to the lens adjustment and the focusing parameters, quickly focuses on a target object or a space range associated with the wireless sensing equipment, and then carries out corresponding monitoring record and monitoring information processing according to the image and the audio and video processing parameters.

The cooperative service node inquires and checks the trigger authority of the object identification code of the wireless sensing equipment according to the event trigger authority configuration information to obtain trigger authority verification information, wherein the trigger authority verification information comprises a trigger authority code or a trigger authority code list and/or an object identification list index or an index list and/or classification authority verification information;

the trigger authority code is a self-defined structure variable composed of a trigger matching code and a trigger wildcard code, the trigger matching code is matched with any object identification code with the trigger authority, and the trigger wildcard code is a code for explaining a subcode which needs or does not need authority verification.

Service processing plan: the service task flow which can be quoted and comprises a plurality of classification service specifications is preset; collaborative service processing plan: namely, the service processing plan comprises a service task flow which is carried out in a cooperative service mode; the classified service specification is a reference specification to a co-processing task that can be independently completed by a certain co-service node, independent of the event trigger itself, of the criteria contained in the service processing plan. The classification service specification comprises classification service codes, service classes, service processing modes and a plurality of standard functions or process references related to information interaction processing.

The classification service specification includes radio beacon configuration/modulation: 1) configuration/modulation of serving node beacons: the cooperative routing node performs node service beacon configuration and/or node service beacon modulation on the peripheral interconnected cooperative service nodes; 2) configuration/modulation of object status beacons: the service node equipment performs object beacon configuration and/or object beacon modulation on the service object equipment; two configuration modes are as follows: 1) reference to a standard wireless beacon; 2) directly configuring beacons to send data according to a wireless beacon configuration format;

in the specific implementation process, the classification service specification further comprises linkage event data processing, and the linkage event data processing comprises the following steps:

1) recording event data: backup storage and event log storage of object data acquisition;

2) linkage data transmission: performing linkage control, linkage alarm, linkage calling or data transmission of other specific data packets on the appointed wireless sensing equipment or the appointed wireless sensing equipment group in a wireless calling or wireless connection establishing mode;

3) adjusting a monitoring mode: adjusting the process parameters of object data acquisition and processing, and adjusting the monitoring data and event identification parameters and modes.

Cooperative task management refers to the creation, distribution and monitoring of cooperative tasks, including: the method comprises the steps of collaborative task creation, collaborative task allocation, collaborative task query, collaborative task execution, collaborative task feedback and collaborative task update. The method specifically comprises the following steps: the cooperative task management comprises cooperative sensing, cooperative monitoring, cooperative communication, cooperative modulation and cooperative positioning/tracking service; collaborative awareness management, namely collaborative task management caused by state awareness triggering; collaborative monitoring management, namely collaborative task management pointed to by monitoring event response; collaborative communication management, namely collaborative task management of object-oriented data communication; collaborative modulation management, namely collaborative task management of object-oriented modulation control; co-location/tracking management, i.e. object oriented localization tracking co-task management.

The collaborative service nodes serve as associated linkage routing nodes, and based on event trigger identification information, a corresponding new collaborative task item is created according to an index of an event response plan, specifically:

and the cooperative routing node creates a corresponding new cooperative task item in the cooperative task list based on the index of the event response plan according to the event trigger identification information, wherein each cooperative task item in the cooperative task list comprises a corresponding cooperative processing task identifier, and the cooperative task item is a cooperative task which exists in the cooperative task list and can be completed by different cooperative service nodes. And the cooperative routing node shares and sends the cooperative task list or the decomposed subset thereof to the cooperative service node associated with the cooperative routing node.

And the cooperative service node inquires the cooperative processing task identifier in the current cooperative task list, and if and only if the associated state attribute of the cooperative service node meets the cooperative state condition corresponding to the cooperative processing task identifier, the cooperative service node executes the cooperative task item corresponding to the cooperative processing task identifier.

And the cooperative service node executes the tasks of one or a plurality of continuous cooperative processing units according to the cooperative task item, wherein each cooperative processing unit correspondingly comprises different cooperative processing task identifiers.

The cooperative processing task identifier is used for correspondingly identifying a cooperative processing unit contained in each cooperative task item in the cooperative task list, the cooperative processing task identifier is contained in the cooperative processing unit, and the cooperative processing task identifier is formed in the following mode:

1) when the parallel processing of the tasks is not allowed, the cooperative processing task is marked as a serial unit identification number;

2) when the parallel processing of a plurality of groups of tasks is allowed, the cooperative processing task identifier is formed by overlapping a task item identification number and a serial unit identification number;

and after the cooperative service node successfully completes the task of the cooperative processing unit, updating the cooperative processing state identifier according to the cooperative processing task identifier contained in the last cooperative processing unit, and sending feedback to the cooperative routing node.

And the cooperative routing node updates or deletes the cooperative task item in the cooperative task list according to the cooperative processing state identifier fed back by the cooperative sensing node.

After the cooperative service node successfully completes the task of the cooperative processing unit, updating the cooperative processing state identifier according to the cooperative processing task identifier included in the last cooperative processing unit, specifically:

when the cooperative service node successfully receives a certain cooperative data frame contained in a cooperative data packet of a certain cooperative communication task item, the serial detection identification number in the corresponding single task state identification is updated according to the matching of the task item identification number in the corresponding cooperative communication task identification, and the cooperative processing state identification is a characteristic identification which is used by the cooperative service node for identifying and feeding back the completion state of the current cooperative task item.

The cooperative communication state identifier exists in the object state beacon and is used for identifying and feeding back the characteristic identifier of the current communication state of the service object device; (the cooperative communication status flag may be obtained as a status monitoring variable through status resolution identification).

When the communication task is not allowed to be processed in parallel, the cooperative communication state identifier is a single-task state identifier, and the single-task state identifier is a characteristic identifier which is equal to or has a corresponding relation with the cooperative communication task identifier contained in the cooperative data frame which is received and verified last time successfully; otherwise, when the parallel processing of a plurality of communication tasks is allowed, the cooperative communication state identifier comprises a multi-task state identifier formed by a plurality of single-task state identifiers; and each single task state identifier in the multi-task state identifiers respectively reflects the current completion state of different cooperative communication task items which are allowed to be processed in parallel.

When a cooperative communication base station serving as a cooperative service node detects and finds that surrounding service object equipment meeting a cooperative matching relationship (namely meeting cooperative communication service requirements) exceeds a preset number in the same time period, the cooperative communication base station decides the priority for initiating the establishment of wireless connection and the associated connection sequence and/or connection time sequence according to the class of the service object equipment and/or the beacon signal response physical quantity; typically, the beacon signal response physical quantity is a positioning signal reception variable; typically, the cooperative communication base station determines a priority level for initiating a wireless connection with a corresponding service object device according to the RSSI or positioning signal reception variable received by detecting different service object devices (i.e. the cooperative communication base station preferentially initiates a wireless connection with a service object device with a higher RSSI value).

When the service object equipment successfully (including verification) receives a certain cooperative data frame contained in a cooperative data packet of a certain cooperative communication task item, updating the serial detection identification number in the corresponding single task state identification according to the matching of the task item identification number in the corresponding cooperative communication task identification; and when the service object equipment successfully (including verification) receives the cooperative data frame containing the ending detection mark, correspondingly updating or clearing the single task state mark matched with the task item identification number.

Example two

The embodiment also discloses a wireless linkage monitoring device, please refer to fig. 2, the device includes: a beacon detection module 201, configured to cooperate with a service node to obtain, in a wireless detection response manner, object access information corresponding to an object state beacon sent by a peripheral wireless sensing device; the state monitoring module 202 is configured to perform state monitoring analysis on the object access information in cooperation with the service node to obtain object state identification information including a plurality of state monitoring variables; the trigger response module 203 is configured to perform, by the cooperative service node, a judgment according to the state monitoring variable: when the state jump of the state monitoring variable or the combination thereof is matched with a certain event trigger condition which is configured in advance, corresponding event trigger identification information is obtained; the task creating module 204 is configured to create a corresponding new collaborative task item according to an index of an event response plan based on event trigger identification information and as a related collaborative routing node in the collaborative service nodes; and the task monitoring module 205 is configured to perform cooperative monitoring task management on the cooperative task item by the cooperative routing node, where the cooperative monitoring task management includes task allocation and monitoring.

This embodiment has still disclosed a wireless linkage monitored control system, its characterized in that, the system includes:

the cooperative service node is used for acquiring object access information corresponding to an object state beacon sent by the peripheral wireless sensing equipment in a wireless detection response mode, performing state monitoring analysis on the object access information to acquire object state identification information containing a plurality of state monitoring variables, and judging according to the state monitoring variables: when the state jump of the state monitoring variable or the combination thereof is matched with a certain pre-configured event trigger condition, corresponding event trigger identification information is obtained to be used as a related collaborative routing node, and a corresponding new collaborative task item is created according to the index of the event response plan based on the event trigger identification information;

the cooperative routing node is used for performing cooperative monitoring task management on the cooperative task item, and the cooperative monitoring task management comprises task allocation and monitoring;

and the wireless sensing equipment is used for receiving the wireless detection message of the service node and sending the object access information corresponding to the object state beacon to the service node.

EXAMPLE III

In addition, the embodiment of the present invention further provides a computer terminal, and the processor executes the computer instruction, so as to implement the following method:

the cooperative service node acquires object access information corresponding to an object state beacon sent by at least one peripheral wireless sensing device in a wireless modulation mode in a wireless detection response mode; the cooperative service node carries out state monitoring analysis on the object access information to obtain object state identification information containing a plurality of state monitoring variables; the cooperative service node judges according to the object state identification information: when the state monitoring variable or the combination thereof is matched with a certain event triggering condition which is configured in advance, the cooperative service node indexes based on the event response plan to obtain an event response correlation parameter corresponding to the event triggering; and the cooperative service node responds to the associated parameters according to the linkage event to perform linkage adjustment control on the associated linkage monitoring processing equipment.

Example four

Those skilled in the art will appreciate that all or part of the processes of the methods of the embodiments described above can be implemented by a computer program, which can be stored in a computer-readable storage medium, and when executed, can include the processes of the embodiments of the methods described above. The storage medium may be a magnetic disk, an optical disk, a read-only memory (ROM), a Random Access Memory (RAM), or the like. The computer processor is used to execute a computer program stored in a storage medium to implement the following method:

In summary, compared with the prior art, the edge domain, collaborative service node device and system for wireless internet of things developed by the patent have the mechanisms of on-site fast and efficient state perception monitoring, event recognition response, network mode scheme selection, task collaborative processing and the like for peripheral service object devices, and the capacity of local area and remote combined online data processing and information service.

The foregoing is merely an example of the present invention and common general knowledge of known specific structures and features of the embodiments is not described herein in any greater detail. It should be noted that variations and modifications can be made by those skilled in the art without departing from the structure of the present invention. These should also be construed as the scope of the present invention, and they should not be construed as affecting the effectiveness of the practice of the present invention or the applicability of the patent. The scope of the claims of the present application shall be determined by the contents of the claims, and the description of the embodiments and the like in the specification shall be used to explain the contents of the claims.

Claims

1. A wireless linkage monitoring method is characterized in that a cooperative service node carries out linkage adjustment control on linkage monitoring equipment based on a trigger response from wireless sensing equipment, and the method comprises the following steps:

the cooperative service node acquires object access information corresponding to an object state beacon sent by at least one peripheral wireless sensing device in a wireless modulation mode in a wireless detection response mode;

the cooperative service node carries out state monitoring analysis on the object access information to obtain object state identification information containing a plurality of state monitoring variables;

the cooperative service node judges according to the object state identification information: when the state monitoring variable or the combination thereof is matched with a certain event triggering condition which is configured in advance, the cooperative service node indexes based on an event response plan to obtain an event response correlation parameter corresponding to event triggering;

and the cooperative service node performs the linkage adjustment control on the associated linkage monitoring equipment according to the event response association parameters.

2. The wireless linkage monitoring method according to claim 2, wherein the object state analysis configuration information is a mode information for performing state analysis identification on object access information of a certain type of wireless sensor equipment, and the object state analysis configuration information includes: 1) the name or classification number of the wireless sensing device and/or object status beacon; 2) a data segment for state variable resolution.

3. The wireless linkage monitoring method according to claim 1, wherein the cooperative service node performs a determination according to the state monitoring variable, specifically: when the current values or time-space domain variation values of one or more state monitoring variables or the combination thereof in the object state identification information are matched with a certain event trigger condition configured in advance, the cooperative service node obtains corresponding event trigger identification information;

the event trigger identification information is obtained based on the state variable analysis and event trigger condition and is used for obtaining event trigger response information by referring to an index, and the event trigger response information comprises any one or combination of event classification information, event response plan information and event tracking index information.

4. The wireless linkage monitoring method according to claim 1, wherein the event triggering condition is a preset judgment condition that is judged according to a state range and/or a state jump of the state monitoring variables or the combination thereof, the state range is formed by current values or time-space domain variation values of the state monitoring variables or the combination thereof, and the triggering condition of the state jump comprises a boundary condition, a jump direction and a stable jump condition; the event triggering condition also comprises a processing priority of the event triggering response, wherein the processing priority is to shield the execution of the classified service specification contained in the service processing plan triggered by the low-priority event in the effective holding period of the execution process or the execution of the service processing plan triggered by the high-priority event.

5. The wireless linkage monitoring method according to claim 1, wherein the cooperative service node indexes based on an event response plan to obtain event response association parameters corresponding to event triggers, specifically:

the cooperative service node obtains the event response associated parameter according to the index of the event response plan based on the event trigger identification information, and the direct information or the index information of the event response associated parameter is contained in the event response plan configuration information; before the cooperative service node performs linkage adjustment control on the bound or associated service object equipment, indexing the event response associated parameters, wherein the event response associated parameters comprise linkage monitoring associated parameters;

the cooperative service node performs corresponding linkage adjustment control on linkage monitoring equipment serving as service object equipment based on the event response correlation parameter or the linkage monitoring correlation parameter; and the cooperative service node processes monitoring data based on the event trigger identification information and/or the event response correlation parameter, and performs corresponding linkage adjustment control on the linkage monitoring equipment according to output information of the monitoring data processing.

6. The wireless linkage monitoring method according to claim 1 or 5, wherein the linkage monitoring device is an audio-video peripheral device, and the collaborative service node indexes the event response association parameters and correspondingly adjusts and controls the audio-video peripheral device based on the event trigger identification information before performing linkage adjustment control on the associated audio-video peripheral device;

the event trigger identification information comprises service object information associated with a wireless sensing device serving as a service object device; the event trigger identification information further includes a direction angle and a position range between the service object devices obtained by the cooperative service node through monitoring data processing.

7. A wireless linkage monitoring method according to claim 1 or 5,

the linkage monitoring equipment is a monitoring camera, the event response correlation parameter is a monitoring camera shooting adjustment parameter, and the monitoring camera shooting adjustment parameter comprises a lens adjustment and focusing parameter and/or an image and audio and video processing parameter;

the cooperative service node firstly adjusts the camera according to the lens adjustment and the focusing parameters, quickly focuses on a target object or a space range associated with the wireless sensing equipment, and then carries out corresponding monitoring record and monitoring information processing according to the image and audio and video processing parameters.

8. The wireless linkage monitoring method according to claim 5, wherein the classification service specification further comprises linkage event data processing, the linkage event data processing comprising:

9. A wireless linkage monitoring device, the device comprising:

the beacon detection module is used for acquiring object access information corresponding to an object state beacon sent by peripheral wireless sensing equipment by the cooperative service node in a wireless detection response mode;

the state monitoring module is used for the cooperative service node to perform state monitoring analysis on the object access information so as to obtain object state identification information containing a plurality of state monitoring variables;

a trigger response module, configured to the cooperative service node, perform judgment according to the state monitoring variable: when the state jump of the state monitoring variable or the combination thereof is matched with a certain event trigger condition which is configured in advance, corresponding event trigger identification information is obtained;

the task creating module is used for serving as a related collaborative routing node in the collaborative service nodes, and creating a corresponding new collaborative task item according to the index of the event response plan based on the event trigger identification information;

and the task monitoring module is used for the cooperative routing node to perform cooperative monitoring task management on the cooperative task item, wherein the cooperative monitoring task management comprises task allocation and monitoring.

10. A wireless linkage monitoring system, the system comprising:

the cooperative service node is used for acquiring object access information corresponding to an object state beacon sent by peripheral wireless sensing equipment in a wireless detection response mode, performing state monitoring analysis on the object access information to acquire object state identification information containing a plurality of state monitoring variables, and judging according to the state monitoring variables: when the state jump of the state monitoring variable or the combination thereof is matched with a certain pre-configured event trigger condition, acquiring corresponding event trigger identification information as a related collaborative routing node, and creating a corresponding new collaborative task item according to the index of an event response plan based on the event trigger identification information;

the cooperative routing node is used for performing cooperative monitoring task management on the cooperative task item, wherein the cooperative monitoring task management comprises task allocation and monitoring;

and the wireless sensing equipment is used for receiving the wireless detection message of the service node and sending object access information corresponding to the object state beacon to the service node.