CN110266688B - Method and device for monitoring group network lamp - Google Patents

Abstract

The embodiment of the application provides a method and a device for monitoring a group network lamp, and relates to the technical field of the Internet of things. The method comprises the following steps: acquiring equipment data of first street lamp equipment through a gateway; acquiring equipment data of second road lamp equipment through a third party management system; storing and processing the acquired equipment data to obtain a processing result; when the processing result meets a preset condition, a management control instruction is sent to the first street lamp device through the gateway; when the processing result meets a preset condition, sending a management control instruction to the second road lamp device through the third-party management system; the problem that networking control cannot be achieved due to the fact that a traditional street lamp cannot be connected into the Internet of things is solved.

Description

Method and device for monitoring group network lamp

Technical Field

The application relates to the technical field of Internet of things, in particular to a method and a device for monitoring a group network lamp.

Background

In the traditional street lamp industry, networking cannot be achieved, and engineers usually know the abnormal condition of the street lamp after regularly patrolling or informing related departments by mass calls, so that certain risks exist in road surface safety; through internet of things, the street lamp condition can be monitored in real time, and engineering personnel can arrange in order to handle the street lamp abnormity.

In traditional street lamp equipment, some street lamp equipment can not be networked, and some street lamp equipment can not access all street lamp equipment in a certain area (including the street lamp equipment which can not be networked and can not have a unified protocol) to the Internet of things because of coming from different manufacturers, so that the street lamp equipment is convenient to control in a unified manner, and the control mode of the street lamp equipment is single, and networking control can not be realized.

Disclosure of Invention

An object of the embodiments of the present application is to provide a method and an apparatus for monitoring a networking lamp, so as to solve the problem that the traditional street lamp equipment has a single control mode and cannot realize networking control.

The embodiment of the application provides a method for monitoring a group network lamp, which comprises the following steps:

acquiring equipment data of first street lamp equipment through a gateway;

acquiring equipment data of second road lamp equipment through a third party management system;

storing and processing the acquired equipment data to obtain a processing result;

when the processing result meets a first preset condition, a management control instruction is sent to the first street lamp device through the gateway;

and when the processing result meets a second preset condition, sending a management control instruction to the second road lamp device through a third-party management system.

In the implementation process, the first street lamp equipment can be networked or protocol-converted through the gateway, so that the timely transmission of equipment data is realized, some second street lamp equipment cannot be networked, the control of the second street lamp equipment is realized through a third-party management system, and the equipment data of the second street lamp equipment in the third-party management system is received, so that the problems that the traditional street lamp cannot be accessed to the Internet of things, a large amount of manpower and material resources are wasted in the control of the Internet of things, the control is single, and only timing switching can be performed, so that networking control cannot be realized are solved; the third-party management system acquires the equipment data, so that resource sharing is realized, and resource waste is avoided; the acquired equipment data are managed and stored in a unified mode, networking control of the street lamp equipment is achieved, unified management and control over the street lamp equipment in batches are facilitated, and the effects of energy conservation and emission reduction are achieved.

By analyzing the equipment data, when the preset conditions are met, if the preset conditions are met, the control of the street lamp equipment is realized through a gateway or a third-party management system.

Further, before the step of acquiring the device data of the first light device through the gateway, the method includes:

judging whether the own protocol of the first path of lamp equipment is consistent with the transmission protocol or not;

and when the own protocol of the first street lamp equipment is inconsistent with the transmission protocol, carrying out protocol conversion through the gateway.

In the implementation process, the first street lamp device is often from different manufacturers, so that the situation that the own protocol is inconsistent with the transmission protocol exists, and protocol conversion needs to be performed through the gateway, so that the first street lamp device is conveniently networked and uniformly managed.

Further, acquiring device data of the first street light device through the gateway includes:

accessing the gateway regularly;

acquiring a first equipment list of first road lamp equipment;

acquiring a second equipment list of second road lamp equipment in a third-party management system;

comparing the first equipment list with the second equipment list;

and when the first road lamp equipment exists in the first road lamp equipment list but does not exist in the second road lamp equipment list, acquiring equipment data of the corresponding first road lamp equipment through the gateway.

In the implementation process, in order to prevent the same street lamp device from existing in the first street lamp device and the second street lamp device, the situation that the first street lamp device and the second street lamp device are controlled by the gateway and the third-party management system respectively occurs, that is, the same street lamp device is controlled repeatedly, the first device list and the second device list need to be compared, the first street lamp device only existing in the first street lamp device list is screened out, the control is implemented through the gateway, the second street lamp device only existing in the second device list can be controlled through the third-party management system, and the resource waste caused by the repeated control is avoided.

Further, the step of sending the management control instruction to the first light device through the gateway includes:

acquiring a strategy task;

judging the type of the strategy task;

when the strategy task is a sensor strategy task, acquiring a sensor value corresponding to the first street lamp equipment, and judging whether the sensor value meets a preset value or not;

when the sensor value accords with a preset value, task data in the strategy task are acquired;

and controlling the first street light equipment according to the task data.

In the implementation process, the sensor is arranged in the first street lamp device and used for monitoring the device data of the first street lamp device in real time and comparing the sensor value measured by the sensor with the preset value, so that the first street lamp device can be controlled according to the sensor value, the first street lamp device is controlled by the timing switch, and the control range of the first street lamp device is expanded.

Further, the step of sending the management control instruction to the first light device through the gateway includes:

acquiring a strategy task;

judging the type of the strategy task;

when the strategy task is a longitude and latitude strategy task, acquiring a longitude and latitude value and running time, and judging whether the running time meets preset time;

when the running time accords with preset time, acquiring task data in the strategy task;

and controlling the first street lamp equipment according to the task data.

In the implementation process, the geographical position information and the running time of the first street lamp equipment can be obtained by obtaining the longitude and latitude value and the running time corresponding to the first street lamp equipment, and when the running time accords with the preset time, the first street lamp equipment can be correspondingly controlled, so that the control range of the first street lamp equipment is expanded.

Further, the step of sending the management control instruction to the first street lamp device through the gateway when the processing result meets a first preset condition includes:

judging whether the gateway establishes connection with the first street lamp equipment or not;

when the gateway is connected with the first street lamp device, the street lamp control instruction is sent to the first street lamp device through the gateway, and the street lamp control instruction comprises a switch and/or dimming.

In the implementation process, when the gateway is connected with the first street lamp device, namely the first street lamp device is on line, the gateway can send a street lamp control instruction to the first street lamp device, so that batch control of the first street lamp device is realized.

Further, the management control instruction comprises a street lamp control instruction, and when the processing result meets a second preset condition, the step of sending the management control instruction to the second street lamp device through a third-party management system comprises the following steps:

judging whether the gateway establishes connection with the second road lamp equipment;

and when the gateway is not connected with the second street lamp equipment, sending a street lamp control instruction to the second street lamp equipment to be controlled through a third-party management system.

In the implementation process, when it is determined that the gateway is not connected with the street lamp device, the street lamp device is the second street lamp device, and a street lamp control instruction needs to be sent to the second street lamp device through the third-party management system, so that the control of the second street lamp device is completed.

The embodiment of the present application further provides a group network lamp monitoring device, and the device includes:

the first data acquisition module is used for acquiring the equipment data of the first street lamp equipment through the gateway;

the second data acquisition module is used for acquiring the equipment data of the second road lamp equipment through a third-party management system;

the storage module is used for storing and processing the equipment data to obtain a processing result;

the first street lamp equipment control module is used for sending a management control instruction to the first street lamp equipment through the gateway when the processing result of the storage module meets a first preset condition;

and the second road lamp device control module is used for sending a management control instruction to the second road lamp device through a third party management system when the processing result of the storage module meets a second preset condition.

In the implementation process, the first data acquisition module acquires the equipment data of the first street lamp equipment through the gateway; the second data acquisition module acquires the equipment data of the second street lamp equipment through the third-party management system, the problem that the traditional street lamp equipment cannot be directly networked is solved, networking control over the street lamp equipment is achieved, and unified management over the street lamp equipment is facilitated.

Further, the first data acquisition module also comprises a protocol conversion submodule;

and the protocol conversion submodule is used for carrying out protocol conversion through the gateway when the own protocol of the first street lamp equipment is inconsistent with the transmission protocol.

In the implementation process, the first street lamp device is often from different manufacturers, most of the manufacturers have own protocols, and the own protocols are often different, so that the own protocols are inconsistent with the transmission protocol, and protocol conversion needs to be performed through a gateway, thereby facilitating networking of the first street lamp device and uniform management of the first street lamp device.

Further, the first data obtaining module further comprises:

the first processing submodule is used for accessing the gateway regularly to obtain a first equipment list of the first street lamp equipment;

the second processing submodule is used for acquiring a second equipment list of second road lamp equipment in the third-party management system;

the comparison processing submodule is used for comparing the first equipment list with the second equipment list; when the first road lamp device exists in the first road lamp device list but does not exist in the second road lamp device list, obtaining device data of the corresponding first road lamp device through the gateway.

In the implementation process, the first equipment list is acquired through the first processing submodule, the second equipment list is acquired through the second processing submodule, the first equipment list and the second equipment list are transmitted to the comparison processing module to be compared and processed, the first street lamp equipment in the first equipment list is screened, and the first street lamp equipment only existing in the first equipment list is screened out.

In order to prevent the situation that the same street lamp equipment exists in the first street lamp equipment and the second street lamp equipment and the repeated control is caused, the first equipment list and the second equipment list need to be compared, the first street lamp equipment only existing in the first street lamp equipment list is screened out, the control is realized through the gateway, the second street lamp equipment only existing in the second equipment list can be controlled through a third party management system, and the resource waste caused by the repeated control is avoided.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are required to be used in the embodiments of the present application will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present application and therefore should not be considered as limiting the scope, and that those skilled in the art can also obtain other related drawings based on the drawings without inventive efforts.

Fig. 1 is a schematic flowchart of a group network lamp monitoring method according to an embodiment of the present disclosure;

fig. 2 is a schematic diagram of a connection and data transmission relationship among a gateway, an internet of things platform, and a third-party management system;

fig. 3 is a schematic flow chart of acquiring device data of a first street light device through a gateway;

fig. 4 is a schematic view of a statistical flow of device data of the street lamp device;

fig. 5 is a flowchart illustrating that the policy task instruction is periodically sent to the first light device through the gateway in step S400;

FIG. 6 is a flow chart of a process of executing a policy task;

fig. 7 is a flowchart of sending street lamp control instructions to a first street lamp device and a second street lamp device through the IOT platform;

FIG. 8 is a flow chart of the execution of a thread pool timing task;

fig. 9 is a schematic diagram of logical relationships and control relationships of a specific implementation process of the networking street lamp monitoring method;

fig. 10 is a schematic structural diagram of a group network lamp monitoring apparatus according to an embodiment of the present application;

fig. 11 is a schematic overall structure diagram of a group network lamp monitoring device according to an embodiment of the present application.

Icon:

100-a first data acquisition module; 101-a first processing submodule; 102 a second processing submodule; 103-an alignment processing submodule; 200-a second data acquisition module; 300-a storage module; 400-a first street light device control module; 410-a first control module; 411-a first policy task obtaining and parsing module; 412-a first policy task determination module; 413-a first policy task execution module; 420-a second control module; 421-a second policy task obtaining and parsing module; 422-a second policy task judging module; 423-second policy task execution module; 430-a third control module; 431-first gateway state judgment module; 432-a first street light device control sub-module; 500-a second street light device control module; 501-a second gateway state judgment module; 502-a second street light device control sub-module; 600-protocol conversion module.

Detailed Description

The technical solutions in the embodiments of the present application will be described below with reference to the drawings in the embodiments of the present application.

It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, it need not be further defined and explained in subsequent figures. Meanwhile, in the description of the present application, the terms "first", "second", and the like are used only for distinguishing the description, and are not to be construed as indicating or implying relative importance.

Example 1

Referring to fig. 1, fig. 1 is a schematic flowchart illustrating a group network lamp monitoring method according to an embodiment of the present disclosure. The embodiment is applied to networking control of street lamp equipment, and therefore the networking control can be realized through an Internet of things platform.

Fig. 2 is a schematic diagram of a connection and data transmission relationship between a gateway, an internet of things platform, and a third-party management system. The first street lamp equipment is in communication connection with the gateway through an electric line, and the gateway is in communication connection with the Internet of things platform and is used for transmitting equipment data of the first street lamp equipment to the Internet of things platform; the Internet of things platform is in communication connection with the third party management system, can be in communication connection with the third party management system in an HTTP interactive connection mode through a Gateway such as a xagent Gateway, and is used for transmitting the equipment data of the second road lamp equipment to the Internet of things platform; the third-party management system can be a street lamp manufacturer system, the second street lamp equipment is electrically connected with the street lamp manufacturer system, and when the third-party platform controls the second street lamp equipment, the Internet of things platform sends an equipment control request to the street lamp manufacturer system through an HTTP (hyper text transport protocol) instruction so as to control the second street lamp equipment; the Internet of things platform is used for processing and storing device data, sending a strategy task instruction and/or a street lamp control instruction to the first street lamp device through the gateway, and sending the strategy task instruction and/or the street lamp control instruction to the second street lamp device through the third party management system.

The first street lamp equipment is defined as street lamp equipment capable of being directly networked, namely, the first street lamp equipment can be connected to the Internet through a TCP/IP protocol, and the second street lamp equipment is defined as street lamp equipment incapable of being directly networked, and the control of the second street lamp equipment is realized by means of a third party.

In an example, the networking street lamp monitoring method of the embodiment of the application is applied to a platform of the internet of things, and the method can include the following steps:

step S100: and acquiring the equipment data of the first road lamp equipment through the gateway.

Since different street lamp devices come from different manufacturers, the protocol conversion is required under the condition that the own protocol is inconsistent with the transmission protocol. Before the step of obtaining device data of the first light device through the gateway, the method further comprises:

judging whether the own protocol of the first path of lamp equipment is consistent with the transmission protocol or not;

and when the own protocol of the first street lamp equipment is inconsistent with the transmission protocol, carrying out protocol conversion through the gateway.

In the implementation process, the device data of the first street lamp device acquired through the gateway can be transmitted to an internet of things platform, for example, the internet of things platform can be an IOT platform, such as an Xlink-IOT platform of a cloud-smart internet of things platform, so that unified operation management, data analysis and data exchange can be performed on the acquired device data.

The first street lamp equipment is in communication connection with the Gateway through an electric line, specifically, the traditional street lamp equipment only has electric communication and control capacity and does not have the capacity of being connected into the internet for communication through a transmission protocol, or the communication protocol of some street lamp equipment is that the communication protocol of the street lamp equipment is inconsistent with the existing general protocol such as a TCP/IP protocol, so that the electric communication and control capacity and the existing protocol of the street lamp equipment are converted into the general communication protocol of the internet through the Gateway (Gateway), and unified management is convenient to carry out. The first street lamp equipment comprises two types, wherein one type is that an own protocol is consistent with a transmission protocol, and the first street lamp equipment can be directly networked through a gateway to realize that the equipment data of the first street lamp equipment is transmitted to an IOT platform;

the other is that the own protocol is not consistent with the transmission protocol, and the gateway plays a role of protocol conversion. Specifically, since most of manufacturers and devices usually have their own protocols or even service systems, street lamp devices may come from different manufacturers, and the own protocols of the manufacturers are often different, so that the own protocols and the transmission protocols are inconsistent, and protocol conversion is required to perform uniform management on the internet of things platform. The purpose of conversion is to convert the heterogeneous protocol into a unified protocol of the Internet of things platform equipment. To achieve this, the Gateway (XAgent-Gateway) acts as a unified protocol translation tool, also known as XAgent; XAgent is a framework of a plug-in development mode provided by the internet of things platform, and in this embodiment, it can enable the first street light device to access the IOT platform under the condition of retaining a custom protocol, and is used for connecting the first street light device, analyzing data, transmitting data to the IOT platform, receiving data from the IOT platform, and the like. The equipment data comprises cities, areas, time switches or automatic switch configurations and the like where the street lamps are located.

For example, as shown in fig. 3, a schematic flowchart of a process for acquiring device data of a first light device through a gateway is shown. Specifically, when the device data of the first street light device is acquired through the gateway in step S100, the method specifically includes the following steps:

s101: accessing the gateway at regular time;

s102: acquiring a first equipment list of first road lamp equipment;

s103: acquiring a second equipment list of second road lamp equipment in a third-party management system;

s104: comparing the first equipment list with the second equipment list, namely screening;

s105: when the first light device exists in the first light device list but does not exist in the second device list, the corresponding first light device is activated through the gateway.

In the implementation process, the IOT platform includes a street lamp SaaS (software as a service) service for controlling the street lamp device, the street lamp SaaS service includes a street lamp data service, the street lamp data service has a timing function, and the gateway and the third-party management system are accessed at regular time according to a set time, so that device data of the first street lamp device and the second street lamp device are obtained and stored in the street lamp SaaS service, and the device data are updated and stored.

The IOT platform regularly accesses the gateway to obtain a complete first equipment list of the current first road lamp equipment; then accessing a third party management system, and acquiring a second equipment list of second road lamp equipment in the third party management system; comparing the first equipment list with the second equipment list, namely screening, and activating the corresponding first street lamp equipment through the gateway when the first street lamp equipment exists in the first street lamp equipment list but does not exist in the second equipment list so that the first street lamp equipment is in communication connection with the IOT platform; the method and the device aim at avoiding the crossing of the street lamp devices in the first device list and the second device list, and causing the IOT platform to repeatedly control the crossed street lamp devices through the gateway and the third-party management system, and causing resource waste.

Step S200: and acquiring the equipment data of the second road lamp equipment through a third party management system.

In the implementation process, the second street lamp device is a street lamp device which is not in direct communication connection with the IOT platform and is indirectly controlled by a third-party management system. Because a large number of street lamp devices, that is, the second street lamp device, are in communication connection with a third-party management system, such as a geographic information system (Gis map), a height map, and the like, and the third-party management system provides an API communication interface, the IOT platform and the third-party management system can be in communication connection, such as HTTP communication connection, and thus the IOT platform can control the second street lamp device.

In one embodiment, in order to count the data of the street lamp equipment, a street lamp SaaS service can be added in an Internet of things platform, wherein the SaaS service is a back-end service for adding in street lamp management related scene services; the street lamp data service can be used for timing and acquiring the equipment data of the second street lamp equipment which cannot be directly networked according to the set time.

For example, in order to implement the classified storage and processing of the street lamp data, the device data of the street lamp device may be counted. The statistical flow diagram of the device data of the street lamp device is shown in fig. 4, and specifically includes the following steps:

step S201: judging the type of the street lamp equipment;

step S202: when the second street lamp equipment is used, the street lamp data service calls a street lamp SaaS service interface at regular time, and the equipment data of the second street lamp equipment is stored in the street lamp SaaS service;

step S203: storing the data electric meter, the concentrator and other meters into the street lamp SaaS service in a classified manner;

step S204: counting the timing task according to the equipment data;

step S205: calculating related data according to corresponding formulas in a classified manner;

step S206: counting the relevant data and storing the data into a street lamp SaaS service;

step S207: when the street lamp equipment is the first street lamp equipment, equipment data of the first street lamp equipment is transmitted to the street lamp SaaS service through the gateway; and performs step S203.

In the implementation process, the acquired equipment data of the street lamp equipment is transmitted to the IOT platform and the street lamp SaaS service; the method comprises the steps that a street lamp SaaS service calls an interface between a gateway and an IOT platform, the gateway addresses corresponding first street lamp equipment and sends a timing strategy task instruction and a street lamp control instruction to the corresponding first street lamp equipment; and the street lamp SaaS service completes the control of the second street lamp equipment by calling a third party management system interface.

In addition, the street lamp data service regularly acquires a first equipment list in the street lamp SaaS service, acquires a second equipment list in a third-party management system for comparison, and only the equipment data of the first street lamp equipment in the first equipment list is stored in the MongoDB database, so that the data stored in the database can be counted regularly.

Step S300: and storing and processing the acquired equipment data to obtain a processing result.

In the implementation process, the IOT platform comprises a MongoDB database and a Redis database, the obtained equipment data of the first road lamp equipment and the second road lamp equipment are stored in the MongoDB database, and the data statistics is carried out on the road lamp data at regular time through the road lamp data service; and the Redis database is a cache database and is used for storing and exchanging temporary data in the operation of the IOT platform.

The IOT platform includes a management mode for classified storage, such as project management, that is, street lamp devices deployed and installed in a certain area are managed, and street lamp devices can be added or removed; strategy management, including timing switch setting, region weight setting, brightness setting, batch control and group control of street lamp equipment and the like; managing energy consumption levels, namely managing strategies of automatically switching on and off the street lamp equipment according to the energy consumption levels; and (4) statistics management, wherein various equipment data of the street lamp equipment are counted, including the switching time, the energy consumption and the like.

In addition, the IOT platform may further include user management, sensor management, electricity meter management, concentrator management, light pole management, light fixture management, loop management, data collection, hyperlink management, device display setting, field hiding setting, group management, and the like.

Through above-mentioned multiple management mode, realize the multi-angle management to street lamp equipment, can be according to the external environment in street lamp equipment place region, in time carry out reasonable control to street lamp equipment, reach energy saving and emission reduction's effect.

Step S400: and when the processing result meets a first preset condition, sending a management control instruction to the first street lamp device through the gateway.

The management control instruction comprises a strategy task instruction and a street lamp control instruction. Policy tasks may include, but are not limited to: a sensor policy task and a latitude and longitude policy task.

The sensor strategy task is mainly used for monitoring the states of the street lamp equipment such as working time, brightness and the like through a sensor; the longitude and latitude strategy task is mainly used for recording the geographical position of the street lamp equipment, and if the longitude and latitude are different, the brightness or the starting time of the street lamp equipment can be different.

In an embodiment, as shown in fig. 5, a flowchart of the step S400 when the policy task instruction is sent to the first light device through the gateway at regular time may specifically include the following steps:

s401: acquiring a strategy task;

s402: judging the type of the strategy task;

s403: when the strategy task is a sensor strategy task, acquiring a sensor value corresponding to the first street lamp equipment, and judging whether the sensor value meets a preset value or not;

s404: when the sensor value accords with a preset value, task data in the strategy task are acquired; and controlling the first street lamp equipment according to the task data.

Further, when the policy task type determined in step S402 is a latitude and longitude policy type, the method further includes:

s405: when the strategy task is a longitude and latitude strategy task, acquiring a longitude and latitude value and running time, and judging whether the running time meets preset time;

s406: when the running time accords with the preset time, acquiring task data in the strategy task; controlling the first light device according to the task data.

In the implementation process, the sensor value can be the brightness of the street lamp equipment, and the longitude and latitude strategy task can be the longitude and latitude position of the street lamp equipment. The IOT platform provides a variety of policy tasks and control means, such as fixed time, latitude and longitude, sensors, etc. to control the device. Install the sensor like position sensor in the street lamp equipment, the sensor passes through electrical control signal connection to the gateway for the IOT platform can realize controlling the street lamp equipment through the gateway.

In addition, in another embodiment, the policy task may further include a time switch, a conditional switch, a fixed time policy task, and the like, in which case, the execution of the policy task integrating all the types described above may be determined according to a loop mode.

Therefore, as shown in fig. 6, it is a flowchart of an execution process of a policy task, and specifically includes the following steps:

step S421: the method comprises the steps that a strategy task is obtained through a street lamp data service timing meter reading; the strategy tasks comprise a sensor strategy task, a longitude and latitude strategy task and a fixed time strategy task;

step S422: judging which circulation mode is; the cyclic mode includes once per week and once per day;

step S423: when the loop mode is executed once per week, if it is determined that the current day meets the execution time per week, step S424 is executed;

step S424: when the circulation mode is executed once a day, judging the type of the strategy task;

step S425: when the strategy task is a sensor strategy task, calling a street lamp SaaS service interface to obtain a sensor value corresponding to first street lamp equipment,

step S426: judging whether the sensor value meets the execution condition of the strategy task, namely whether the sensor value meets a preset value;

step S427: when the policy task is met, acquiring task data in the policy task; calling an API (application program interface) of the IOT platform so as to control the first street lamp equipment through the gateway according to the task data;

step S428: when the strategy task is a fixed time strategy task;

step S429: judging whether the current time is execution time; when it is the execution time, step S427 is executed;

step S430: when the strategy task is a longitude and latitude strategy task, acquiring a longitude and latitude value and calculating the running time; step S429 is performed.

For controlling the street lamp device, for example, the street lamp control instruction includes but is not limited to switching and/or dimming, the street lamp device includes a first street lamp device and a second street lamp device, and the step of sending the street lamp control instruction to the first street lamp device through the gateway includes:

judging whether the gateway is connected with the street lamp equipment or not, namely whether the street lamp equipment is in an online state or not;

when connection with the street lamp equipment is established, judging the type of the street lamp equipment;

and when the street lamp equipment is first street lamp equipment, sending the street lamp control instruction to the first street lamp equipment through the gateway.

S500: and when the processing result meets a second preset condition, sending a management control instruction to the second road lamp device through a third-party management system.

For the second road lamp device, the execution flow of the policy task is the same as that of the first road lamp device, and the policy task is implemented by a third-party management system only when executed, which is not described herein again.

Exemplarily, a street lamp control instruction is sent to the second street lamp device through the third-party management system; the IOT platform controls the first street lamp equipment through a gateway; the first street lamp equipment is street lamp equipment capable of being directly networked, and the second street lamp equipment is street lamp equipment incapable of being directly networked.

And when the street lamp equipment is second street lamp equipment, acquiring equipment data of the second street lamp equipment.

Specifically, as shown in fig. 7, it is a flowchart for sending a street lamp control instruction to a first street lamp device and a second street lamp device through an IOT platform; the method specifically comprises the following steps:

step S511: judging whether the street lamp equipment is on line, namely whether the street lamp equipment is connected with the IOT platform;

step S512: if the connection is not established and the street lamp equipment is not on-line, the street lamp equipment cannot be controlled;

step S513: if the connection is established, sending a street lamp control instruction through the gateway;

step S514: judging whether the equipment is directly networked or not;

step S515: if the first street lamp equipment is the first street lamp equipment, directly sending a street lamp control instruction to the first street lamp equipment through the gateway to complete the control of the first street lamp equipment;

step S516: if not, the second road lamp equipment is obtained, calling a street lamp SaaS service to obtain equipment data of the second road lamp equipment;

step S517: and calling a third party management system interface to control the second road lamp equipment to complete the control of the second road lamp equipment.

In the implementation process, the internet of things platform acquires a plurality of street lamp devices in the same area at the same time, and the plurality of street lamp devices can be controlled through the gateway or the third-party management system, so that batch control of the street lamp devices is realized.

In an implementation manner, the method for establishing connection between the internet of things platform and the second street lamp device is implemented by using a timed task thread, wherein the thread includes a gateway thread corresponding to the second street lamp device and a street lamp data service thread of the second street lamp device. The timing task thread mainly aims at the second street lamp equipment, and can acquire the off-line or on-line state of the second street lamp equipment at regular time through the timing task thread and further display a list of the second street lamp equipment.

As shown in fig. 8, a flowchart for executing a timing task of a thread pool specifically includes the following steps:

step S520: timing a running thread according to set time;

step S521: judging the type of the thread;

step S522: when the gateway thread is adopted, calling a third party management system interface to acquire the equipment data of the second road lamp equipment;

step S523: judging whether the second road lamp equipment is on-line;

step S524: when the second road lamp equipment is on line, judging whether the second road lamp equipment is in an activated state;

step S525: if the second road lamp equipment is in the activated state, the agent logs in the second road lamp equipment, namely the second road lamp equipment is on-line;

step S526: updating the relevant data end points of the second road lamp equipment;

step S527: if not, activating the second road lamp device and executing the step S526;

step S528: when the second street lamp device is not on-line, the agent quits the second street lamp device, namely the second street lamp device is off-line, and executes step S526;

step S529: when the street lamp data service thread is used, obtaining the authorization authentication of a third-party management system;

step S530: calling a third party management system interface to obtain second road lamp equipment data;

step S531: processing and cleaning the equipment data;

step S532: and calling a street lamp SaaS service interface to store the second street lamp equipment data.

In one embodiment, as shown in fig. 9, a schematic diagram of a logic relationship and a control relationship in a specific implementation process of a networking street lamp monitoring method is shown, specifically, the logic relationship and the control relationship between a third-party management system, a gateway, a street lamp data service, a street lamp SaaS DB database, and an IOT platform are shown, and the specific implementation steps are as follows:

step 1: the gateway operates;

step 2: acquiring a first street lamp equipment list through a street lamp SaaS service interface;

and step 3: returning the first road lamp equipment list to the gateway;

and 4, step 4: mapping N first path light devices in a gateway memory;

and 5: the up-down line of the first street lamp equipment is realized;

step 6: inquiring the equipment state of the second road lamp equipment in batch through a third party management system;

and 7: returning the equipment state of the second road lamp equipment to a gateway connected with a third-party management system;

and 8: the IOT platform calls an online API of the gateway to complete the online of the first street lamp equipment;

and step 9: completing the on-line of the first street lamp equipment and feeding back the result to the gateway;

step 10: the street lamp SaaS service controls the street lamp equipment in batch through a strategy task instruction and/or a street lamp control instruction;

step 11: the IOT platform calls a control interface of the street lamp equipment and sets a data endpoint;

step 12: the IOT platform addresses the corresponding first street lamp equipment through a gateway equipment control mechanism;

step 13: the gateway connected with the third-party management system calls a third-party management system interface to control the second road lamp equipment;

step 14: responding to a timing strategy task instruction and/or a street lamp control instruction;

step 15: feeding back a control result to the IOT platform;

step 16: the IOT platform feeds back a control result to the SaaS service of the street lamp;

and step 17: the street lamp data service starts to synchronize data;

step 18: acquiring a second road lamp equipment list from a road lamp SaaS service;

step 19: the street lamp SaaS service returns the second street lamp equipment list to the street lamp data service;

step 20: the street lamp data service acquires street lamp data of the second road lamp equipment in batches through a third-party management system;

step 21: the third party management system returns the street lamp data of the second street lamp device to the street lamp data service;

step 22: the street lamp SaaS service calls a third-party platform management system synchronous interface to complete equipment data synchronization of the second street lamp equipment;

step 23: the street lamp SaaS service stores the equipment data of the second street lamp equipment into a street lamp SaaS DB database;

step 24: completing the storage of the equipment data of the second road lamp equipment;

step 25: the street lamp SaaS service synchronizes the device data to the street lamp data service.

The IOT platform updates the equipment data of the first road lamp equipment and the second road lamp equipment at regular time, and realizes the control of the first road lamp equipment and the second road lamp equipment by sending a timing strategy task instruction and/or a road lamp control instruction, thereby achieving the purposes of energy conservation and emission reduction. Meanwhile, the second road lamp equipment is controlled by calling a third-party management system, so that the problem that the second road lamp equipment cannot be directly networked or is connected with the third-party management system is solved, and the problem of resource and equipment waste caused by connection establishment again is avoided.

Example 2

As shown in fig. 10, an embodiment of the present application further provides a group network lamp monitoring apparatus, which includes:

a first data obtaining module 100, configured to obtain device data of a first road lamp device through a gateway;

a second data obtaining module 200, configured to obtain device data of a second road lamp device through a third party management system;

the storage module 300 is used for storing and processing the device data to obtain a processing result;

a first street lamp device control module 400, configured to send a management control instruction to the first street lamp device through the gateway when a processing result of the storage module meets a first preset condition;

and the second street lamp device control module 500 is configured to send a management control instruction to the second street lamp device through the third party management system when the processing result of the storage module meets a second preset condition.

In the implementation process, the first data acquisition module acquires the equipment data of the first street lamp equipment through the gateway; the second data acquisition module acquires the equipment data of the second street lamp equipment through the third-party management system, the problem that the traditional street lamp equipment cannot be directly networked is solved, networking control over the street lamp equipment is achieved, and unified management over the street lamp equipment is facilitated.

Further, as shown in fig. 11, which is a specific module diagram of the apparatus, the apparatus further includes a protocol conversion module 600;

a protocol conversion module 600, configured to perform protocol conversion through a gateway when the own protocol of the first light device is inconsistent with the transmission protocol.

In the implementation process, the first street lamp device is often from different manufacturers, most of the manufacturers have own protocols, and the own protocols are often different, so that the own protocols are inconsistent with the transmission protocol, and protocol conversion needs to be performed through a gateway, thereby facilitating networking of the first street lamp device and uniform management of the first street lamp device.

Further, the first data obtaining module 100 further includes:

the first processing submodule 101 is configured to access the gateway at regular time, and obtain a first device list of the first street lamp device;

the second processing submodule 102 is configured to obtain a second device list of a second road lamp device in the third-party management system;

the comparison processing submodule 103 is configured to compare the first device list with the second device list; and when the first road lamp equipment exists in the first road lamp equipment list but does not exist in the second road lamp equipment list, acquiring the corresponding equipment data of the first road lamp equipment through the gateway.

In the implementation process, the first equipment list is acquired through the first processing submodule, the second equipment list is acquired through the second processing submodule, the first equipment list and the second equipment list are transmitted to the comparison processing module to be compared and processed, the first street lamp equipment in the first equipment list is screened, and the first street lamp equipment only existing in the first equipment list is screened out.

In order to prevent the situation that the same street lamp equipment exists in the first street lamp equipment and the second street lamp equipment and the repeated control is caused, the first equipment list and the second equipment list need to be compared, the first street lamp equipment only existing in the first street lamp equipment list is screened out, the control is realized through the gateway, the second street lamp equipment only existing in the second equipment list can be controlled through a third party management system, and the resource waste caused by the repeated control is avoided.

Further, the first lighting device control module 400 includes a first control module 410, a second control module 420, and a third control module 430.

The first control module 410 includes:

a first policy task obtaining and analyzing module 411, configured to obtain a policy task and determine a type of the policy task;

the first policy task determining module 412: the system comprises a policy task module, a first street lamp device and a second street lamp device, wherein the policy task module is used for acquiring a sensor value corresponding to the first street lamp device and judging whether the sensor value meets a preset value or not when the policy task is a sensor policy task;

the first policy task execution module 413: the strategy task data acquisition unit is used for acquiring task data in the strategy task when the sensor value meets a preset value; and controlling the first street lamp equipment according to the task data.

Further, the second control module 420 includes:

the second policy task obtaining and parsing module 421: the method comprises the steps of obtaining a strategy task and judging the type of the strategy task;

the second policy task determination module 422: when the strategy task is a longitude and latitude strategy task, acquiring a longitude and latitude value and running time, and judging whether the running time meets preset time;

the second policy task execution module 423: the strategy task data acquisition unit is used for acquiring task data in the strategy task when the running time accords with preset time; and controlling the first street lamp equipment according to the task data.

Further, the third control module 430 includes:

the first gateway status determining module 431: the gateway is used for judging whether to establish connection with the first street lamp equipment;

the first lighting device control submodule 432: and the road lamp control instruction is sent to the first road lamp device through the gateway when the gateway is connected with the first road lamp device, and the road lamp control instruction comprises a switch and/or dimming.

Further, the second street light device control module 500 includes:

the second gateway state determination module 501: the gateway is used for judging whether to establish connection with the second road lamp equipment;

the second street light device control submodule 502: and the third party management system is used for sending the street lamp control instruction to the second street lamp device to be controlled when the gateway is not connected with the second street lamp device.

The embodiment of the application further provides electronic equipment, which comprises a memory and a processor, wherein the memory is used for storing a computer program, and the processor runs the computer program to enable the computer equipment to execute the networking street lamp monitoring method according to the embodiment 1 of the application.

The embodiment of the present application further provides a computer-readable storage medium, which stores computer program instructions, and when the computer program instructions are read and executed by a processor, the method for monitoring a networking street lamp in embodiment 1 of the present application is executed.

In the embodiments provided in the present application, it should be understood that the disclosed apparatus and method can be implemented in other ways. The apparatus embodiments described above are merely illustrative, and for example, the flowchart and block diagrams in the figures illustrate the architecture, functionality, and operation of possible implementations of apparatus, methods and computer program products according to various embodiments of the present application. In this regard, each block in the flowchart or block diagrams may represent a module, segment, or portion of code, which comprises one or more executable instructions for implementing the specified logical function(s). It should also be noted that, in some alternative implementations, the functions noted in the block may occur out of the order noted in the figures. For example, two blocks shown in succession may, in fact, be executed substantially concurrently, or the blocks may sometimes be executed in the reverse order, depending upon the functionality involved. It will also be noted that each block of the block diagrams and/or flowchart illustration, and combinations of blocks in the block diagrams and/or flowchart illustration, can be implemented by special purpose hardware-based systems which perform the specified functions or acts, or combinations of special purpose hardware and computer instructions.

In addition, functional modules in the embodiments of the present application may be integrated together to form an independent part, or each module may exist separately, or two or more modules may be integrated to form an independent part.

The functions, if implemented in the form of software functional modules and sold or used as a stand-alone product, may be stored in a computer readable storage medium. Based on such understanding, the technical solution of the present application or portions thereof that substantially contribute to the prior art may be embodied in the form of a software product stored in a storage medium and including instructions for causing a computer device (which may be a personal computer, a server, or a network device) to execute all or part of the steps of the method according to the embodiments of the present application. And the aforementioned storage medium includes: a U-disk, a removable hard disk, a Read-Only Memory (ROM), a Random Access Memory (RAM), a magnetic disk or an optical disk, and other various media capable of storing program codes.

The above description is only an example of the present application and is not intended to limit the scope of the present application, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, improvement and the like made within the spirit and principle of the present application shall be included in the protection scope of the present application. It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, it need not be further defined and explained in subsequent figures.

The above description is only for the specific embodiments of the present application, but the scope of the present application is not limited thereto, and any person skilled in the art can easily conceive of the changes or substitutions within the technical scope of the present application, and shall be covered by the scope of the present application. Therefore, the protection scope of the present application shall be subject to the protection scope of the claims.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.

Claims (9)

1. A group network light monitoring method, the method comprising:

acquiring equipment data of first street lamp equipment through a gateway;

acquiring equipment data of second road lamp equipment through a third party management system;

storing and processing the acquired equipment data to obtain a processing result;

when the processing result meets a first preset condition, a management control instruction is sent to the first street lamp device through the gateway;

when the processing result meets a second preset condition, sending a management control instruction to the second street lamp device through the third-party management system, wherein the management control instruction comprises a street lamp control instruction:

judging whether the gateway establishes connection with the second road lamp equipment;

and when the gateway is not connected with the second street lamp equipment, sending the street lamp control instruction to the second street lamp equipment to be controlled through the third-party management system.

2. The method for monitoring the networking street lamp according to claim 1, wherein before the step of obtaining the device data of the first street lamp device through the gateway, the method comprises:

judging whether the own protocol of the first path of lamp equipment is consistent with the transmission protocol or not;

and when the own protocol of the first street lamp equipment is inconsistent with the transmission protocol, carrying out protocol conversion through a gateway.

3. The method for monitoring the networking street lamp according to claim 1, wherein the obtaining of the device data of the first street lamp device through the gateway includes:

accessing the gateway regularly;

acquiring a first equipment list of the first road lamp equipment;

acquiring a second equipment list of second road lamp equipment in the third-party management system;

comparing the first equipment list with a second equipment list;

when the first road lamp device exists in the first road lamp device list but does not exist in the second road lamp device list, obtaining device data of the corresponding first road lamp device through the gateway.

4. The networking street lamp monitoring method according to claim 1, wherein the management control command includes a policy task command, and the step of sending the management control command to the first street lamp device through the gateway includes:

acquiring a strategy task;

judging the type of the strategy task;

when the strategy task is a sensor strategy task, acquiring a sensor value corresponding to the first street lamp device, and judging whether the sensor value meets a preset value;

when the sensor value meets a preset value, task data in the strategy task are acquired;

and controlling the first street lamp equipment according to the task data.

5. The networking street lamp monitoring method according to claim 1, wherein the management control command includes a policy task command, and the step of sending the management control command to the first street lamp device through the gateway includes:

acquiring a strategy task;

judging the type of the strategy task;

when the strategy task is a longitude and latitude strategy task, acquiring a longitude and latitude value and running time, and judging whether the running time meets preset time;

when the running time accords with preset time, acquiring task data in the strategy task;

and controlling the first street lamp equipment according to the task data.

6. The networking street lamp monitoring method according to claim 1, wherein the management control instruction includes a street lamp control instruction, and the step of sending the management control instruction to the first street lamp device through the gateway when the processing result meets a first preset condition includes:

judging whether the gateway establishes connection with the first street lamp equipment or not;

when the gateway is connected with the first street lamp device, the street lamp control instruction is sent to the first street lamp device through the gateway, and the street lamp control instruction comprises a switch and/or dimming.

7. A group network light monitoring apparatus, the apparatus comprising:

the first data acquisition module is used for acquiring the equipment data of the first street lamp equipment through the gateway;

the second data acquisition module is used for acquiring the equipment data of the second road lamp equipment through a third-party management system;

the storage module is used for storing and processing the equipment data to obtain a processing result;

the first street lamp equipment control module is used for sending a management control instruction to the first street lamp equipment through the gateway when the processing result of the storage module meets a first preset condition;

the second street lamp equipment control module is used for sending a management control instruction to the second street lamp equipment through the third party management system when the processing result of the storage module meets a second preset condition, wherein the management control instruction comprises a street lamp control instruction;

the second street light device control module comprises:

the second gateway state judgment module is used for judging whether the gateway establishes connection with the second road lamp equipment;

and the second street lamp device control submodule is used for sending the street lamp control instruction to the second street lamp device to be controlled through the third-party management system when the gateway is not connected with the second street lamp device.

8. The networking street lamp monitoring device according to claim 7, characterized in that the device further comprises a protocol conversion module;

and the protocol conversion module is used for carrying out protocol conversion through the gateway when the own protocol of the first street lamp equipment is inconsistent with the transmission protocol.

9. The networking street lamp monitoring device according to claim 7, wherein the first data acquisition module further comprises:

the first processing submodule is used for accessing the gateway regularly to obtain a first equipment list of the first street lamp equipment;

the second processing submodule is used for acquiring a second equipment list of second road lamp equipment in the third-party management system;

the comparison processing submodule is used for comparing the first equipment list with the second equipment list; when the first road lamp device exists in the first road lamp device list but does not exist in the second road lamp device list, obtaining device data of the corresponding first road lamp device through the gateway.

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