阅读说明：本技术 一种全球气象灾害卫星遥感快速响应与可视化服务平台 (Satellite remote sensing quick response and visualization service platform for global meteorological disasters ) 是由 杨军 于 2020-04-28 设计创作，主要内容包括：本发明实施例公开了一种全球气象灾害卫星遥感快速响应与可视化服务平台,包括：系统存储层、气象分析层、气象业务服务层和服务接口与门户层；系统存储层,用于存储气象数据；气象业务服务层,用于接收用户通过服务接口与门户层输入的任务；以及将任务推送到气象数据分析层；气象分析层,用于根据任务进行分析；以及把分析的结果发送给服务接口与门户层；服务接口与门户层,用于与用户进行交互；包括接收用户的查询以及显示分析结果。(The embodiment of the invention discloses a global meteorological disaster satellite remote sensing quick response and visualization service platform, which comprises: the system comprises a system storage layer, a meteorological analysis layer, a meteorological service layer, a service interface and a portal layer; the system storage layer is used for storing meteorological data; the weather service layer is used for receiving tasks input by a user through the service interface and the portal layer; pushing the task to a meteorological data analysis layer; the meteorological analysis layer is used for analyzing according to the tasks; sending the analysis result to a service interface and a portal layer; the service interface and portal layer is used for interacting with the user; including receiving a user's query and displaying the results of the analysis.)

1. A global meteorological disaster satellite remote sensing quick response and visualization service platform is characterized by comprising: the system comprises a system storage layer, a meteorological analysis layer, a meteorological service layer, a service interface and a portal layer;

the system storage layer is used for storing meteorological data;

the weather service layer is used for receiving tasks input by a user through the service interface and the portal layer; pushing the task to a meteorological data analysis layer;

the meteorological analysis layer is used for analyzing according to the tasks; sending the analysis result to a service interface and a portal layer;

the service interface and portal layer is used for interacting with the user; including receiving a user's query and displaying the results of the analysis.

2. The global weather disaster satellite remote sensing rapid response and visualization service platform as claimed in claim 1,

the system storage layer adopts a general x86 architecture storage server as a construction unit to form a uniform shared storage pool;

the system storage layer is based on a big data storage technology, and aiming at multi-source meteorological disaster data, a plurality of big data distributed cluster storage technologies are adopted to meet the storage access requirements of different types of meteorological data.

3. The global weather disaster satellite remote sensing rapid response and visualization service platform as claimed in claim 1,

the meteorological big data analysis layer comprises a data layer, a service layer and an application layer;

the data layer is used for managing business data and product data;

the service layer is used for performing containerization packaging on the algorithm for calculating and processing the meteorological data and performing distributed calculation;

the application layer is used for acquiring commands and settings of the user and displaying the calculation result to the user.

4. A method for constructing a global meteorological disaster satellite remote sensing quick response and visualization service platform comprises the following steps:

storing large meteorological data and constructing a computing environment based on service arrangement;

integrating a meteorological application algorithm based on a container in a complex operating environment;

performing multi-dimensional multi-scene visual display on global meteorological disaster data/products;

the method comprises the steps of constructing a global main meteorological disaster satellite remote sensing quick response and visualization service platform.

5. The method of claim 4, wherein integrating the weather application algorithm in a complex vessel-based operating environment comprises:

the container-based packaging and operation technology can support seamless integration of different algorithm models;

the operation environment required by the meteorological disaster monitoring algorithm model can be packaged in a mirror image, and the capability of resource isolation and dynamic mounting of input and output data is realized;

defining an algorithm self-description model and a data access specification, supporting automatic series connection of algorithm models, and realizing comprehensive integration of a platform and an algorithm plug-in.

6. The method of claim 4, wherein the multi-dimensional multi-scene visualization of global meteorological disaster data/products comprises: establishing a visualization mode system of meteorological disaster data, inversion parameters and thematic products based on a browser front-end WebGL and server middle layer caching technology, defining visualization effects from three dimensions of space, time and numerical values, storing a distributed object as a middle layer, realizing a mechanism of periodic incremental updating, and forming a multi-scale three-dimensional visualization middle result format and an index method capable of progressive transmission; and the three-dimensional real-time display of the meteorological data is realized through the H5 and the JS script at the front end.

Technical Field

The invention relates to the field of meteorological satellite data processing and the technical field of three-dimensional visualization processing, in particular to a global meteorological disaster satellite remote sensing quick response and visualization service platform.

Background

The meteorological satellite is the most effective data source for rapidly and efficiently carrying out global meteorological and ecological environment elements and major disaster monitoring and evaluation, and particularly, with the high-speed development of meteorological satellite technology in China, the detection capability is increasingly enhanced, and the meteorological satellite is at an advanced level internationally. How to utilize meteorological satellite data well, fuse more advanced satellite remote sensing information retrieval, calamity monitoring and evaluating technology, develop multidimensional, visual, quick service platform, for government decision-making, trade application, public life etc. provide more high-efficient, accurate service, be urgent to the problem that needs to solve.

Disclosure of Invention

Therefore, the embodiment of the invention provides a global meteorological disaster satellite remote sensing quick response and visualization service platform to solve the problems.

In order to achieve the above object, the embodiments of the present invention provide the following technical solutions:

according to a first aspect of the embodiments of the present invention, a global meteorological disaster satellite remote sensing rapid response and visualization service platform includes: the system comprises a system storage layer, a meteorological analysis layer, a meteorological service layer, a service interface and a portal layer;

the system storage layer is used for storing meteorological data;

the weather service layer is used for receiving tasks input by a user through the service interface and the portal layer; pushing the task to a meteorological data analysis layer;

the meteorological analysis layer is used for analyzing according to the tasks; sending the analysis result to a service interface and a portal layer;

the service interface and portal layer is used for interacting with the user; including receiving a user's query and displaying the results of the analysis.

Further, a system storage layer adopts a general x86 architecture storage server as a construction unit to form a uniform shared storage pool;

the system storage layer is based on a big data storage technology, and aiming at multi-source meteorological disaster data, a plurality of big data distributed cluster storage technologies are adopted to meet the storage access requirements of different types of meteorological data.

Further, the meteorological big data analysis layer comprises a data layer, a service layer and an application layer;

the data layer is used for managing business data and product data;

the service layer is used for performing containerization packaging on the algorithm for calculating and processing the meteorological data and performing distributed calculation;

the application layer is used for acquiring commands and settings of the user and displaying the calculation result to the user.

According to a second aspect of the embodiment of the invention, a method for constructing a global meteorological disaster satellite remote sensing quick response and visualization service platform comprises the following steps:

storing large meteorological data and constructing a computing environment based on service arrangement;

integrating a meteorological application algorithm based on a container in a complex operating environment;

performing multi-dimensional multi-scene visual display on global meteorological disaster data/products;

the method comprises the steps of constructing a global main meteorological disaster satellite remote sensing quick response and visualization service platform.

Further, integrating a weather application algorithm under a complex container-based operating environment, comprising:

the container-based packaging and operation technology can support seamless integration of different algorithm models;

the operation environment required by the meteorological disaster monitoring algorithm model can be packaged in a mirror image, and the capability of resource isolation and dynamic mounting of input and output data is realized;

defining an algorithm self-description model and a data access specification, supporting automatic series connection of algorithm models, and realizing comprehensive integration of a platform and an algorithm plug-in.

Further, the multi-dimensional multi-scene visualization display of global meteorological disaster data/products comprises: establishing a visualization mode system of meteorological disaster data, inversion parameters and thematic products based on a browser front-end WebGL and server middle layer caching technology, defining visualization effects from three dimensions of space, time and numerical values, storing a distributed object as a middle layer, realizing a mechanism of periodic incremental updating, and forming a multi-scale three-dimensional visualization middle result format and an index method capable of progressive transmission; and the three-dimensional real-time display of the meteorological data is realized through the H5 and the JS script at the front end.

The embodiment of the invention has the following advantages: aiming at the problem that the global main meteorological disaster monitoring management has the problems that the response speed is not timely enough and the requirement of rapid change of meteorological disasters in any time and any place can not be met, the invention utilizes the advantages of novel meteorological satellite remote sensing data on space-time resolution and macroscopic monitoring, takes the improvement of the global main meteorological disaster monitoring business rapid service capability of domestic satellites as the core, and constructs a global meteorological disaster satellite remote sensing visual comprehensive analysis and rapid service platform with the international advanced technology.

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. It should be apparent that the drawings in the following description are merely exemplary, and that other embodiments can be derived from the drawings provided by those of ordinary skill in the art without inventive effort.

The structures, ratios, sizes, and the like shown in the present specification are only used for matching with the contents disclosed in the specification, so that those skilled in the art can understand and read the present invention, and do not limit the conditions for implementing the present invention, so that the present invention has no technical significance, and any structural modifications, changes in the ratio relationship, or adjustments of the sizes, without affecting the functions and purposes of the present invention, should still fall within the scope of the present invention.

Fig. 1 is a schematic structural diagram of a global meteorological disaster satellite remote sensing quick response and visualization service platform according to an embodiment of the present invention;

FIG. 2 is a schematic diagram of a storage node management interface according to an embodiment of the present invention;

FIG. 3 is a system architecture diagram of a weather big data analysis layer according to an embodiment of the present invention.

Detailed Description

The present invention is described in terms of particular embodiments, other advantages and features of the invention will become apparent to those skilled in the art from the following disclosure, and it is to be understood that the described embodiments are merely exemplary of the invention and that it is not intended to limit the invention to the particular embodiments disclosed. 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.

From the perspective of data analysis, visualization and rapid and high-quality service capability, a set of visualization platform with high efficiency and easy expansion is established, monitoring of global main meteorological disasters (typhoons, rainstorms, high temperatures, drought, sand and dust and snow disasters), rapid response and three-dimensional visualization analysis are urgent, low coupling degree is achieved between the visualization platform and the field, and requirements on software expansibility and universality of the visualization platform can be met through a hierarchical and componentized framework.

Based on this, the application provides a global meteorological disaster satellite remote sensing quick response and visualization service platform, which is shown in fig. 1, and the structural schematic diagram of the global meteorological disaster satellite remote sensing quick response and visualization service platform is shown; the platform includes: the system comprises a system storage layer, a meteorological analysis layer, a meteorological service layer, a service interface and a portal layer;

the system storage layer is used for storing meteorological data;

the weather service layer is used for receiving tasks input by a user through the service interface and the portal layer; pushing the task to a meteorological data analysis layer;

the meteorological analysis layer is used for analyzing according to the tasks; sending the analysis result to a service interface and a portal layer;

the service interface and portal layer is used for interacting with the user; including receiving a user's query and displaying the results of the analysis.

The service interface and the portal layer can be desktop applications of a mobile phone or a computer, and can be a Web browser.

Also includes a virtualized base resource layer; the system bottom layer realizes a micro service architecture capable of being dynamically stretched by relying on virtualized basic resource facilities and taking Kubernets as a main operation environment. And the support to the cloud virtual environment, the bare metal environment and the GPU server is realized. Based on the meteorological disaster monitoring business requirements, the available meteorological micro-service technical standard is established, the micro-service management technology is closely combined, complete decoupling with the bottom infrastructure is achieved, and the method has modern cloud native application characteristics of automatic service discovery, automatic horizontal expansion, load balancing, central configuration management and the like. On top of the virtualized base resources is a storage system. The global meteorological disaster satellite remote sensing monitoring service platform needs to support data products of different satellite types and different data types, so that data storage schemes aiming at different product characteristics need to be researched. The system comprises a meteorological disaster satellite remote sensing database, a global main meteorological disaster pregnant environment satellite remote sensing database, a global main meteorological disaster distribution database, a global geographic information auxiliary database and the like so as to support visual analysis and quick response of an upper-layer unified platform of the system.

The virtualized foundation resource layer determines the technical standard of the available meteorological microservice for production based on the meteorological disaster monitoring business requirements, and is closely combined with the microservice management technology to realize complete decoupling with the bottom infrastructure;

the system storage layer aims at multi-source heterogeneous meteorological data, such as high-grade data, wind cloud data, meteorological monitoring data, ground observation data, disaster products, vector data, chart documents and the like, and various big data storage technologies such as distributed file system storage, relational database storage, object storage, search engines and the like are adopted to meet the storage requirements of different types of data; the system storage layer can adopt a general x86 architecture storage server as a construction unit, a user can flexibly increase or reduce storage nodes according to business needs and form a uniform shared storage pool, the aggregate IOPS and the throughput which are several times higher than those of the traditional storage can be provided, the device-level redundancy of the system can be realized, damaged hard disks and node devices can be replaced online, and online seamless dynamic lateral expansion is supported.

The meteorological big data analysis layer integrates meteorological disaster application algorithm models of different programming languages and different operating environments under the support of the storage layer and the virtualization base resource layer, and provides production services of six disaster products for the outside;

the weather service layer is established above the weather big data analysis layer and is responsible for data production in an automation or user customization mode of weather products, and the weather service layer can regularly push tasks to the weather data analysis layer for automatic production; the weather service layer comprises a weather product monitoring service, a weather product access service, a disaster product production service, a weather disaster early warning service, a disaster product updating service, a weather product management service and a disaster product management service. The weather product monitoring service is used for monitoring an external shared storage device, converting the change condition of the weather product into an event notification and sending the event notification to the message queue. The weather product access service is to receive the product change notification through the message queue and then transfer the required data into the system according to the product rules. The disaster product production service is used for producing different types of disaster products according to the update notification of the meteorological products. The meteorological disaster early warning service automatically generates early warning information according to predefined disaster early warning rules, and the early warning information is written into a database and needs to be sent out through a message queue. The weather product management service and the disaster product management service are mainly used for providing a front-end data query and retrieval function. The disaster product update service refers to updating in a database for products modified at the front end.

The service interface and the portal layer provide a weather product display window for a user, weather product display can be divided into two-dimensional plane display and three-dimensional display according to specific product content, and displayed data come from a system storage layer. The service interface and the portal layer are three-dimensional visualization platforms developed completely based on the WEB technology, and have the characteristics of no plug-in and light weight. Compiling through Javascript language, building a basic framework by using WebGL technology and H5 technology, processing the basic geographic data by slicing and the like, and importing the basic geographic data into a platform to realize the superposition distribution of the meteorological disaster thematic data and the basic remote sensing products. The client sends a request to the server through a TCP/IP protocol, then the content returned by the server is processed, and the three-dimensional scene is rendered by using Javascript language based on WebGL technology.

Under the support of a storage system and a virtualized basic resource, the meteorological big data analysis system provides calculation support. The subsystem is based on a container technology, realizes the calling of algorithms of different programming languages and different operating environments, and provides production services of six products to the outside. The weather service analysis system is established on the weather big data analysis system and is used for realizing the business operation of weather products. The display system is located on the uppermost layer, the system is based on a browser front end WebGL and a server middle layer caching technology, intermediate data results suitable for network transmission and three-dimensional visualization are formed aiming at different scales and can be cached in an object storage environment, the intermediate data results are served to the outside through a RESTful API, three-dimensional real-time visualization rendering can be directly carried out on the basis of the WebGL technology after the browser front end is obtained, and a plug-in is not required to be installed independently. By providing various visualization functions such as three-dimensional dynamic display, layer control, element superposition and the like for meteorological inversion, fusion and disaster products, the meteorological data visualization service supporting secondary development is realized, and verification is completed for typical areas.

The system storage layer is based on a big data storage technology, aiming at multi-source meteorological disaster data, a plurality of big data distributed cluster storage technologies such as distributed file storage, relational database storage, object storage, k-v storage and search engines are adopted to meet the storage and access requirements of different types of meteorological data, comprehensive management and unified application are carried out on the storage system modeling, specific technical implementation ways for realizing the multi-source remote sensing data in a user application mode, a logical organization mode and a physical storage mode are needed to be designed, and a mapping relation between the multi-source remote sensing data and the physical storage mode is established.

The large meteorological data distributed storage system dispersedly stores data on a plurality of independent devices, can be transversely expanded, shares storage load by using a plurality of storage devices, positions and stores information by using the metadata server, not only improves the reliability, the usability and the access efficiency of the system, but also is easy to expand, and constructs the dispersed storage devices into a virtual large storage pool for upper-layer application.

Referring to FIG. 2, a storage node management interface is shown; the administrator can inquire the condition of the current storage node through a storage node management interface, and can inquire the following information:

1) GlusterFS, Ceph, ES and Etcd node deployment conditions and basic information of each node. The basic information of the node includes: node name, storage capacity of the node, etc.

2) And (4) idle node information. The user administrator can freely set the attribution of the nodes through the interface.

With respect to the analysis layer, see the system architecture diagram of the weather big data analysis layer shown in fig. 3; the data layer includes management of business data and management of product data. The service data is mainly stored in the etcd of the platform. etcd stores recorded data in the form of k-V, where the value of k is a key field or ID, while the value of V may store simple field data, as well as complex structured data. The etcd storage adopts a memory database, has the characteristic of supporting large-scale data concurrent access, and mainly stores service information such as job state progress information, job statistical data, workflow message queues and the like. And the product data is stored by adopting a distributed file system. The storage of each meteorological product supports high concurrency access, and provides good data support for distributed computing. The application layer belongs to a UI layer of the meteorological big data analysis layer and is responsible for acquiring commands and settings of the user and displaying calculation results to the user. The service layer is the most important layer of the distributed process computing subsystem. In a service layer, the system performs containerization packaging on all algorithms for calculating and processing meteorological data, and realizes distributed calculation by adopting a Kubernetes self-scheduling system. The service layer includes API services, job monitoring services, scheduling services, resource monitoring services, other services, and the like.

With respect to the process of interaction among the internal services after the job task is submitted, referring to fig. 3, first, the system receives a job submission request through the API service. The operation is then written to the etcd storage. The etcd storage records the job submission task, and feeds back the recording state to the API service, and the etcd storage triggers a message notification. Message notifications are managed by a message queue service implementation. And after receiving the message, the queue service judges one by one and feeds back the message related to the operation to the etcd for storage. The user may also obtain the processing progress and the processing status through the queue service. For example, a user submits a batch of job tasks for inverting the earth surface temperature, and information such as the execution progress and the parallelism of the tasks is acquired in real time on a task management interface, which is realized through the message queue service. The scheduling service determines the parallelism of Job tasks by analyzing task types and task volumes, and by the resource information obtained from the task monitoring service, and then decomposes the tasks into jobs. Job is the basic unit of task for platform processing, so the number of Job determines the parallelism of this Job. Job from the dispatch service eventually runs through k8s to get the final result. During the k8s running these tasks, the scheduling service will acquire the running states in real time and show these states to the user interface, so that the user can know the progress at any time. Meanwhile, the Etcd also records the intermediate process information related to the operation through the monitoring service.

In a second aspect, the application further provides a method for constructing a global main meteorological disaster satellite remote sensing quick response and visualization service platform, and the method comprises the following steps:

step 1, constructing a weather big data storage and calculation environment based on service arrangement;

step 2, integrating a meteorological application algorithm under a container-based complex operation environment;

step 3, visually displaying the multi-dimensional multi-scene of global meteorological disaster data/products;

and 4, constructing a global main meteorological disaster satellite remote sensing quick response and visualization service platform.

In one embodiment, the step 1 comprises:

the meteorological disaster big data has the characteristics of multiple dimensions, multiple sources, heterogeneity and the like, and the meteorological disaster big data has the characteristics of multiple batches, large single data volume and frequent updating, so that the use modes are different, and when the meteorological disaster big data is stored in the traditional relational database, the problems of high concurrent reading and writing, high-efficiency mass data storage, high expandability and high availability need to be solved. Therefore, aiming at multi-source heterogeneous meteorological data, such as high-score data, wind cloud data, meteorological monitoring data, ground observation data, disaster products, vector data, chart documents and the like, the invention adopts a plurality of big data storage technologies such as distributed file system storage, relational database storage, object storage, search engines and the like to meet the storage requirements of different types of data, and designs a specific technical implementation way for realizing the multi-source meteorological data in a user application mode, a logical organization mode and a physical storage mode by carrying out comprehensive management and unified application on the storage system modeling, thereby establishing a mapping relation among the multi-source meteorological data.

The invention realizes and integrates a plurality of operators required by a heterogeneous big data environment based on a micro-service architecture, achieves the purposes of automatic deployment, expansion and management, introduces an independent storage environment management plane on a higher level, and establishes a uniform description model for a heterogeneous storage system, thereby providing a consistent retrieval, access and state notification interface for upper-layer services. The storage environment management plane is a containerized stateless service system essentially, provides automatic deployment, retrieval, expansion and management services of a big data environment for upper-layer applications in a meteorological disaster service platform through RESTful API, records deployment and state conditions of a plurality of storage systems by using distributed K-V services, and can uniformly release state changes and measurement conditions of each internal storage system through a high-level message queue.

In one embodiment, the step 2 comprises: because various meteorological disaster monitoring application algorithm models such as a meteorological disaster data fusion algorithm, a meteorological disaster automatic extraction algorithm, a meteorological data inversion algorithm and the like are based on different programming languages and different operating environments and may comprise algorithms developed in the modes of MATLAB, IDL, executable files, Python and the like, the different algorithm models have great difference to the operating environments in terms of implementation and even have potential conflict in consideration of complexity and inconsistency of algorithm integration, the container-based packaging and operating technology can support seamless integration of the different algorithm models, the operating environments required by the meteorological disaster monitoring algorithm models can be packaged in a mirror image, and the capacity of resource isolation and dynamic hanging of input and output data is achieved. By defining an algorithm self-description model and a data access specification, automatic series connection of the algorithm models can be supported, and comprehensive integration of a platform and an algorithm plug-in is realized. The container mirror image is a physical entity file packaged by the operating environment and the algorithm model, and can be operated only by depending on an operating system kernel. By using a combined file system supporting Copy-On-Write, an operating system, a basic dependency library, a running environment and an algorithm model are superposed together in an independent 'layer' form to form a complete and isolated execution environment; meanwhile, the layers can be shared among different algorithm models, and the completely same layer only needs to be stored once, so that the overall storage requirement is reduced.

In one embodiment, the step 3 comprises: in the internet environment, the traditional three-dimensional rendering mode is restricted by factors such as transmission rate, data scale and the like, and efficient remote real-time visualization is difficult to realize. The method is based on a browser front-end WebGL and server middle layer caching technology, a visualization mode system of meteorological disaster data, inversion parameters and special products is established, visualization effects are defined from three dimensions of space, time and numerical values, a distributed object is stored as a middle layer, a periodic increment updating mechanism is realized, a multi-scale three-dimensional visualization middle result format capable of being transmitted gradually and an index method are formed, and finally three-dimensional real-time display of the meteorological data is realized through a front-end H5 and a JS script.

Firstly, a meteorological product visual organization model is established based on a meteorological disaster monitoring service scene and meteorological disaster data/product characteristics, dynamic visual requirements of a meteorological inversion/fusion/monitoring product and a disaster data set on a space dimension, a time dimension and a numerical dimension are determined, a set of standardized meteorological disaster data/product visual standards are customized to describe data of different types, different sources and different service requests, and attribute description files of the data exist in a JSON file form. The JSON file comprises unique identification of data, JSON self-description, monitoring object entities, marking information, style definition, document reports, sequence raster data, production units, production time and other attribute information.

And then, based on a browser front end WebGL and a server middle layer caching technology, forming intermediate data results suitable for network transmission and three-dimensional visualization aiming at different scales, wherein the intermediate data results can be cached in an object storage environment, the intermediate data results are externally served through a RESTful API, the browser front end can directly perform three-dimensional real-time visualization rendering based on the WebGL technology after obtaining the intermediate data results, and a plug-in is not required to be installed independently. By providing various visualization functions such as three-dimensional dynamic display, layer control, element superposition and the like for meteorological inversion, fusion and disaster products, the meteorological data visualization service supporting secondary development is realized, and verification is completed for typical areas.

In one embodiment, the step 4 comprises: the existing meteorological disaster monitoring system has the problems of weak comprehensiveness, insufficient timeliness, low service range and the like, on one hand, the system can effectively carry out comprehensive analysis and monitoring on various meteorological disasters, and is mainly regional in scale; on the other hand, due to the limitation of processing and visualization technologies, the overall response speed is not timely enough, and the delay of hours or even days exists, so that the meteorological service is prevented from playing a greater role in the actual disaster prevention and reduction requirements. The invention establishes a meteorological disaster quick response service platform based on a container and a micro-service architecture, integrates various meteorological disaster data analysis and visualization technologies in the global scope for the first time, and realizes near-real-time disaster monitoring service.

The method realizes the functions of dynamic access, query retrieval, distribution and downloading of multi-source information such as meteorological satellite key parameter inversion, monitoring of main global meteorological disasters such as typhoons and rainstorms and the like; based on a distributed computing technology, a containerization mode is adopted to integrate the high-precision inversion, fusion and quantitative monitoring algorithms of the project, and the functions of periodic batch computing and real-time online computing are provided; based on the remote control and three-dimensional visualization capability of meteorological data, the monitoring and analysis service for main global meteorological disasters is provided. The intelligent full-service chain service capability of satellite remote sensing data acquisition, meteorological disaster identification, disaster evaluation information extraction, product automatic production, three-dimensional dynamic monitoring display, remote visual control and information distribution is formed.

And finally, aiming at the meteorological disaster monitoring practical service application scenes such as typhoons and rainstorms, the service capability of the platform in the aspects of satellite remote sensing data acquisition, meteorological disaster identification, disaster assessment information extraction, product automatic production, three-dimensional dynamic monitoring display, remote visual control, information release and the like in the intelligent full-service chain is assessed, and the service stability, timeliness and the like of the platform are checked.

Although the invention has been described in detail above with reference to a general description and specific examples, it will be apparent to one skilled in the art that modifications or improvements may be made thereto based on the invention. Accordingly, such modifications and improvements are intended to be within the scope of the invention as claimed.