CN116170324A - Visual view generation method and device suitable for computing power network - Google Patents

Abstract

The application provides a visual view generation method and device suitable for a computing power network, wherein the method comprises the following steps: obtaining visual information of object elements of the computing power network; obtaining the geographic attribute of the object element; obtaining a base map layer corresponding to the computing power network; mapping the object elements and the visual information of the object elements to the base map layer to form a visual model; obtaining a gridded visual model; wherein the meshed visualization model is used to generate a visual view of the computational power network. According to the method and the system, a better and more visual display means is realized under the presentation requirement of various power networks, and elements and business expressions under various power networks are displayed through creative simulated geographic map superposition virtualization polygonal grid elements.

Description

Visual view generation method and device suitable for computing power network

Technical Field

The invention relates to the technical field of computing power network business, in particular to a visual view generation method and device suitable for a computing power network.

Background

The current computing power network belongs to a novel network service and combines multiple characteristics of cloud and network. A computing network is a new type of information infrastructure that allocates and flexibly schedules computing resources, storage resources, and network resources as needed among clouds, networks, edges, according to business needs. For the new network service of the computing power network, on the one hand, the diversity of various elements in the computing power network, the volume of the scale of the computing power node, the relation between the computing power request and the computing power node and the value and bearing range of the computing power capability of each region are required to be represented on the display means of the computing power network.

At present, most of the existing visualization display of network related services still uses a traditional network topological graph to display the connection relation and layout of network nodes in the form of logical relation or physical network connection through 2D points, lines and the like. And a part of network elements which need to express the position information are displayed based on the GIS geographic information system, and the real positions of related network element objects are reflected through the display of the GIS map.

For the novel network service of the power computing network, the prior art scheme basically follows the two types of forms to perform visual display. The conventional presentation means described above cannot optimally present the diversity, volume, relationship, and value load that satisfy the aforementioned computing networks.

Therefore, a novel visual technology display means is needed to display the computational power network element and the computational power relation in visual view on the computational power network, so that a user is helped to better understand the computational power network, analyze the computational power network and apply the computational power network.

Disclosure of Invention

The object of the present application is to solve the drawbacks of the prior art.

The visual view generation method and the visual view generation device are suitable for the power computing network, and a better and more visual display means are realized under the presentation requirement of the power computing network facing diversity.

In a first aspect, the present application provides a method for generating a visual view suitable for a computing power network, including: obtaining visual information of object elements of the computing power network; obtaining the geographic attribute of the object element based on the visual information of the object element; obtaining a base map layer corresponding to the computing power network based on the geographic attribute of the object element; mapping the object elements and the visual information of the object elements to the base map layer to form a visual model; dividing a base map layer of the visual model into at least one virtual grid based on the visual information to obtain a gridded visual model; the gridded visualization model is used for generating a visual view of the computing power network, and comprises a computing power coverage display view and/or a computing power path display view.

In one possible embodiment, the generating the computing force overlay presentation view includes: and increasing the computational power resource coverage of the object element to the visual model by changing the colors of the virtual grids adjacent to the object element, and generating a computational power coverage display view.

In one possible embodiment, the generating a computing force path presentation view includes: and adding the computational force path of the object element to the visual model through connecting the object element, and generating a computational force path display view, wherein the computational force path of the object element is embodied in the form of a color-changing path of a virtual grid.

In a possible embodiment, the obtaining the visual information of the object element of the computing power network includes: collecting object elements of the computing power network for visual display; acquiring a related attribute state of the object element, wherein the related attribute state comprises a geographic attribute; analyzing and generating related resources and network relations of the object elements; and obtaining the visual information of the object element of the computing power network based on the related attribute state of the object element and the related resource and network relation.

In a possible embodiment, the obtaining the geographic attribute of the object element based on the visualized information of the object element includes: analyzing and obtaining geographic attributes and/or spatial attributes of the object elements based on geographic information fields of the object elements of the visual information; obtaining the geographic attribute of the object element based on the geographic attribute and/or the spatial attribute of the object element; or based on the attribute of the object element of the visual information, carrying out keyword analysis and/or semantic analysis to obtain the geographic attribute and/or the spatial attribute of the object element; and obtaining the geographic attribute of the object element based on the geographic attribute and/or the spatial attribute of the object element.

In a possible embodiment, the obtaining, based on the geographic attribute of the object element, a base map layer corresponding to the computing power network includes: based on the geographic attribute of the object element, obtaining a visual geographic space range of the computing power network; and obtaining a base map layer corresponding to the computing power network based on the visual geographic space range.

In one possible embodiment, the virtual grid has editability including adding, deleting, and changing the virtual grid.

In a second aspect, the present application provides a visual view generating apparatus adapted for use in a computing network, comprising: the visual information acquisition module is used for acquiring visual information of object elements of the computing power network, wherein the visual information comprises attributes, resources and network relations of the object elements; the geographic attribute confirming module is used for obtaining the geographic attribute of the object element based on the visual information of the object element; the base map layer confirming module is used for obtaining a base map layer corresponding to the computing power network based on the geographic attribute of the object element; the visual model generation module is used for mapping the object elements and the visual information of the object elements to the base map layer to form a visual model; the gridding module is used for dividing a base map layer of the visual model into at least one virtual grid based on the visual information to obtain a gridded visual model; the gridded visualization model is used for generating a visual view of the computing power network, and comprises a computing power coverage display view and/or a computing power path display view.

In a third aspect, the application provides an electronic device, including a memory and a processor, where the memory stores a computer program that can run on the processor, and the processor implements the visual view generating method applicable to the computing power network when executing the computer program.

In a fourth aspect, the present application provides a computer readable medium having non-volatile program code executable by a processor, wherein the program code causes the processor to perform the method for generating a visual view suitable for a computing network.

According to the method and the system, a better and more visual display means is realized under the presentation requirement of various power networks, and elements and business expressions under various power networks are displayed through creative simulated geographic map superposition virtualization polygonal grid elements. The visual display system realizes visual display of various main power network business elements such as power service objects, power resource objects and the like on a visual interface, can be continuously perfected according to business development and requirements of a power network, performs business display from the existing power network path, and can provide visual functions such as editing, automatic creation, visual display, demonstration business processes, animation display and the like of display contents for various power network businesses such as other power dispatching, power transaction and the like. In the process of editing the model of the topology and the network relation of the visual display of the computing power network, a user can intuitively combine means such as the geographical position, the display change of the real-time service influence range on the visual network when the network model is changed, and the like, so that the user is helped to better and intuitively edit the visual display model.

Drawings

FIG. 1 is a flow chart of a visual view generation method suitable for a computing network according to an embodiment of the present invention;

fig. 2 is a schematic diagram of a visual view generating device suitable for a computing network according to an embodiment of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in further detail below with reference to the accompanying drawings and examples, it being apparent that the described examples are some, but not all, of the examples of the present invention. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the invention. All other embodiments, which can be made by those skilled in the art without making any inventive effort, are intended to be within the scope of the present invention.

In the following detailed description of the present invention, certain specific details are set forth in order to provide a thorough understanding of the present invention. The present invention will be fully understood by those skilled in the art without the details described herein.

The technical means of visualization of the computing power network still adopts the traditional network topology relationship-based representation of the computing power related network element relationship, or adopts the network element position which is combined with the GIS geographic information relationship to represent the actual spatial position. The former is shown by a topology algorithm of a logic layout, and only whether nodes of the correlation are distributed uniformly or not is concerned. The geographical and spatial attributes to which the nodes belong cannot be reflected, and the business impact with geographical and peripheral ranges cannot be reflected from the topology nodes or connections. The latter is true to the actual geographic position, however, for dense actual geographic element information display such as base stations, vehicle navigation and the like, accurate display can be possibly made by combining with GIS, but for concept elements such as calculation nodes and calculation paths which are alternately physically and virtually exist, the business characteristics and the attributes are expressed simply from the geographic display form of the GIS, because the actual map is huge in scale, and too few elements exist, the display information content on the interface is clear, the visual sense is difficult or the meaning and the capability of bearing various business elements under the calculation network are enhanced.

The above mentioned technical means do not optimally demonstrate the diversity, volume, relativity and value bearing that meet the above mentioned power networks.

Therefore, a novel visual technology display means is needed to display the computational power network element and the computational power relation in visual view on the computational power network, so that a user is helped to better understand the computational power network, analyze the computational power network and apply the computational power network.

The embodiment of the application is oriented to a novel network, namely an algorithm network, through a novel graphic visual display means, and through a novel visual layout and visual display form. And by combining the service characteristics of the power calculation network, the visual view generation of the power calculation network is performed, and a whole set of editable, generatable, presentable and interactive power calculation network visual system is realized. The method and the system help users to better understand the computing power network, analyze the computing power network and apply the computing power network, display the computing power network capacity, resources and scale, and intuitively reflect the actual business content and state of the computing power network.

Fig. 1 is a flow chart of a visual view generating method suitable for a computing network according to an embodiment of the present invention. As shown in fig. 1, the method mainly comprises the following steps:

step S110, obtaining the visual information of the object elements of the power network.

Step S120, obtaining the geographic attribute of the object element based on the visual information of the object element.

Step S130, obtaining a base map layer corresponding to the computing power network based on the geographic attribute of the object element.

And step S140, mapping the object elements and the visual information of the object elements to the base map layer to form a visual model.

Step S150, dividing a base map layer of the visual model into at least one virtual grid based on the visual information to obtain a meshed visual model; the gridded visualization model is used for generating a visual view of the computing power network, and comprises a computing power coverage display view and/or a computing power path display view.

In step S110, the visual information of the object elements of the computing power network is obtained by collecting, obtaining the relevant attribute states, analyzing and generating relevant resources and network relationships, including relationships such as subordinate relationships, dependent relationships, connection relationships, inclusion relationships, and the like, of the object elements required for visual presentation in the existing computing power network. The object element is an object element to be visualized, including: the power computing gateway and the power computing resource information node. The computing power resource information node comprises general computing resources such as CPU, GPU and the like, special computing resources such as FPGA, ASIC and the like, and basic computing resources such as storage resources and the like, and also comprises service class resources such as application, service, algorithm and the like. The various computing resources form a node set concept such as a plurality of computing resource pools. The node set is also a visualized object element. In addition, the system also comprises a computing power controller, a virtual abstract node of a computing power requester, cloud network related network resources for bearing a computing power network and the like.

In one possible embodiment, the object elements required for visual presentation are all data and acquired from the system database of the computing network through the present node. And analyzing and carding for constructing a visual model of the display.

In step S120, relevant geographic attributes are extracted from the presentation elements with geographic features and location features, and this extraction process may be based on geographic information fields/attributes in the data structure, or may be based on semantic recognition of unstructured attribute contents, based on keyword rule base or NLP (natural language processing of AI), to analyze the geographic or spatial attributes of the node elements, so as to determine the actual relevant location to be drawn.

In step S130, a visualization range is first estimated and evaluated, the visualization range being the geospatial range of the computing power network that needs to be revealed. In the current practical product application field, the geographical space range of the computing power network to be displayed is generally nationwide or one-province, multi-province and the like. According to manual configuration of a user; or a maximum geographic scope involving a geographic display node. The automatic generation of the estimated measurement refers to that the geographical ranges involved in the furthest computing power network are Shenzhen and Shanzen respectively. And the system judges that the range to be displayed by the computing power network is the full-province range of Guangdong province according to the rule, and the range of all the computing power visual elements does not exceed a province range.

Then loading a related computing power network range base map layer, wherein the type of the base map layer can be a preset satellite map, a 3D topographic map and a 2D GIS map; since the whole computational power network visual presentation system is presented based on a 3D interaction mode, a 2D plane layer can be pre-overlaid on a 3D base plate object.

In step S140, first, according to the cloud network bearer network relationship on which the computing power network depends, the service relationship between computing power nodes is related. The system evaluation first divides the layout positions among each other in the form of a logical topology. And taking the core computing power access point and the computing power gateway as a plurality of central nodes in the topology layout, and expanding other element objects of each computing power network visualization connected on the central nodes. And as much as possible ensures that no overlap occurs.

Then according to the geographic attributes of the computing power access point and the computing power gateway, the nearest relative coordinate position is found on the range base map layer; because the range base map layer is constructed by the geographic map layer, the longitude and latitude of the relevant geographic attribute can be mapped into a corresponding coordinate system.

In one possible embodiment, the system initially builds a visualization model of all elements and topologies on the computing power network that need to be visualized and presented in association with the approximate geographic location, and can be used for the next special virtualized network drawing process.

In one possible embodiment, the visualization model generation process is mainly after all relevant visualization element objects and associated attributes and data states of the computing power network to be exposed are acquired. And generating a visual display layout and a drawing model through a specific display algorithm.

In step S150, since the current visual display means only displays related network resources based on the GIS layer, the map is huge, and the resource content is distributed sparsely, so that a good display effect cannot be obtained, and the visual display means is neither intuitive, nor is the operation often difficult. Thus, after the system obtains a visualization model of the elements and topology of a visual presentation in relation to the approximate geographic location. Furthermore, visual drawing of the computational power network is required by a special display means.

In a feasible embodiment, the system innovatively adopts a drawing form of virtualized grid abstraction, which can reflect approximate geographic distribution and spatial position relation, is not limited by actual geographic position distance relation proportion, and can dynamically show the relation, state and characteristics among element object nodes in the computing power network.

In one possible embodiment, the concept and method of mapping dynamically segments a geographic map, such as a satellite map or a terrain map, into a plurality of virtual location grids. The geographic base map is generally an irregular polygon, but regardless of the form of the base map, the range can be constructed and divided by the composition of a plurality of virtual grids, just as the chessboard of chess can be divided by a plurality of square grids, and the range base map to be displayed by all the involved computational power networks can be composed of a plurality of regular hexagonal honeycomb-like grids, wherein the regular hexagons are just an example and can be also be said to be other regular polygons or irregular figures.

In one possible embodiment, each grid is regular hexagon, and the reason for using the hexagonal grids is that the center distance between any one grid and other adjacent grids is equal in length, so that the adjacent relation between different visual elements of the computing power network can be better reflected, and the difference of affine and sparse is avoided.

In a possible embodiment, each grid represents a visual meaning, but one representing an actual computing element object, e.g. an access point, routing node, request point, gateway, etc., or a specific coverage area. Different 2D icons or 3D graphic models can be overlaid and presented on each virtual network according to the display requirements to express different business meanings and element characteristics.

In one possible embodiment, each virtual grid may be automatically calculated or manually configured according to the system to change the radius of the grid to meet the number of elements to be displayed. If hundreds of thousands of computing power access points are drawn on a 3D base map of a map, the radius of the virtual grid can be dynamically reduced so as to meet massive display requirements.

In a possible embodiment, the radius of the virtual grid may be dynamically increased if a small number of logical connections of the computational power nodes need to be represented on the floor map of a local area, respectively. Thus, a high-level abstract but intuitive computational network topology can be reflected by using fewer grids.

In one possible embodiment, the extent and full mesh of the visual presentation required for the entire computational power network is abstracted into a geographically relevant 3D graphical view of the multiple virtual grid constructions. The geographical position which needs to be shortened or does not need to be emphasized can be reduced to be displayed with a small number of blank grid patterns. The local scope that needs emphasis or highlighting magnification can be presented with multiple grid patterns overlaid with business element icons or 3D models. Thus, the user or user can precisely edit and adjust the view of the whole computational network on the 3D view which is globally high-abstract but locally visual and magnified.

In one possible embodiment, the user may select a certain virtualized grid to change the element object type, or may add a computing network object, such as a specific computing access point, a newly added computing resource pool, etc., on a blank grid. Operations such as deletion, modification, etc. may also be performed.

In one possible embodiment, all operations can be intuitively and directly reflected and reflected on the whole 3D grid view, and the system can automatically adjust the layout and the positions of the elements carried on the virtual grid on the whole geographic base map according to geographic position response. Because the geographic absolute longitude and latitude positions and the virtual abstract grid positions are not linearly mapped, the system can change grid contents according to the sparseness and the compactness of the displayed contents, so that view viewers can know the approximate geographic distribution, and certain abstraction and adjustment can be performed to meet the demands of attractive appearance and practicability.

In step S150, one application of the meshed visualization model is to generate a computational force coverage presentation view. In one possible embodiment, for visualization of the power network, one important function is to show coverage and influence scope of power resources that each power node can carry, for example, a certain power node in a city, including a certain CPU or GPU power resource pool. The user needs to be able to know the coverage, service and radiation surrounding areas of these computing nodes, e.g. if different levels of computing service coverage can be provided for the geographical area of how much to respond, e.g. around the city, town, county. In conventional visual presentation means, this is typically presented by thermodynamic diagrams. In practice, however, the mapping of GIS-based thermodynamic diagrams often requires very accurate and massive geographic location coordinate information. The method adopts a mode of combining virtual grids with geographic distribution for displaying. Therefore, the display of the calculation coverage can quickly and intuitively express the specific calculation coverage only by switching the virtual grid into the display graphic form of the coverage.

In one possible embodiment, by changing the colors of the adjacent virtual grids around the virtual grid where different computing nodes are located, which are generally different colors capable of adjusting transparency, the system can adopt filling colors with different transparency and brightness under the same color system through the shades of the colors, and the adjacent virtual grids are subjected to epitaxial filling, so that computing coverage and supporting capability around a certain computing node can be displayed.

In a possible embodiment, the filling color of the virtual grid covered by the computing power can also change the state of the color, namely the color is dark or light and transparent at any time according to the computing power performance index to be reacted by the service, such as network delay, load of CPU resources, occupancy rate of network storage and the like, or a dynamic numerical label is superposed in the grid. This can reflect the change in the calculated force coverage in real time. The real-time situation of the coverage situation related to each computing node of the computing network is better reflected.

In step S150, another application of the meshed visualization model is to generate a computational force path presentation view. The computational power network visualization view may be required to exhibit a presentation of computational power paths in addition to the presentation of the distribution of computational power resources and node elements, the presentation of computational power coverage.

In a possible embodiment, the computing path is a combination of a request access point, a network path and computing nodes, and in the process of performing service visualization, the construction of the computing path, the scoring of the computing path, the recall of the computing path, the fine-ranking and other forms need to be visually presented. The intelligent power calculation method and the intelligent power calculation system help users to better understand the business of the power calculation network and understand the intelligent change process of the power calculation path in the large-scale power calculation node.

In one possible embodiment, the visual view of the computational power network innovatively embodies the presentation of the computational power paths through two presentation means and forms. Firstly, in the first presentation means, when the computing power network performs visual presentation on the computing power path, the path can be presented in the color-changing path form of the virtual grid through the form of the virtual grid. The virtual grid combined with the geographic base map can take different presentation roles by changing colors and overlapping graphical models of graphical icons, such as representing a computing power access point, a routing device and a computing power coverage condition of the geographic place of the underlying coverage city. The virtual grid can be transformed into a specific calculation force path, and a plurality of relevant logic channels, namely calculation force paths, between the calculation force nodes and the access nodes after the optimization of the system are drawn through the form of the virtual grid. A virtual grid of consecutive identical fill colors is typically rendered. In order to more accurately reflect paths and logic channels, the system dynamically adjusts the radius of the virtual grid so that the represented paths become finer, and thus, different computational force path differences can be reflected on the base map. When a user selects or floats on the virtual grid expressing the calculation force path through a mouse, the visual view can also display the state index information corresponding to the calculation force path through a floating information window or a text prompt.

In one possible embodiment, the second presentation of the visual view to the computing force path is to draw dynamic animated wiring directly over the computing force nodes and access points on the 3D visual view. The connection line is a 3D graph line segment. The suspension or both ends are connected on the virtual grid that represents the power access point or the power node, and the user can watch different power paths from different directions, positions and pitch angles by selecting the angle and the visual angle of the 3D view, and the 3D graph line segment represents the selection, optimization, adjustment or transformation of different paths through the changing thickness, color transformation and animation form, so that the user can better understand the scoring process, the ranking process and the recommending process of the power paths of the power network.

In the embodiment of the application, the specific visual display form and method based on the computing power network service are combined with the display of the actual geography, the logic relation model and the grid diagram display form. And visually displaying the calculation network nodes, the calculation network paths, the calculation force flow directions, the calculation force path bearing relations, the calculation force path recommendation results, the calculation force service scheduling process, the calculation force deconstructing process, the calculation force and the like. The display means comprises: the method comprises the steps of combining geographic information and 3D topology of a virtualized hexagonal grid, a dynamically switchable 3D network element model, and a computing network element relation, a business flow and information display, wherein the computing network element relation is displayed in real time by a 3D animation. Optionally, the method for generating the specific presentation model of the visual relationship of each correlation element in the computing power network on the computing power network grid chart. Optionally, the computing process and method of the visual presentation form, the influence range of the computing power bearing capacity and the influence range of the computing power network node. Optionally, the network path is specified in visual representation form, and the path scoring, recommending and other business processes are specified in visual representation form.

According to the embodiment of the application, a better and more visual display means is realized under the presentation requirement of various computing networks, and elements and business expressions under various computing networks are displayed through the superposition of the virtualized hexagonal grid elements of the creative simulated geographic map.

According to the embodiment of the application, visual display of various main power network business elements such as a power service object, a power resource object and the like on a visual interface is realized, wherein the visual display comprises, but is not limited to, a 3D model capable of scaling and rotating, a 3D virtual grid topology capable of switching multi-level views and a map capable of changing a geographic layer. And the service influence capacity and service relation carried by the object elements can be displayed by a more novel and visual means.

According to the embodiment of the application, a display system which can be continuously perfected according to the service development and the requirements of the power network is realized, service display is carried out from the existing power network paths, and visual functions such as editing, automatic creation, visual presentation, service demonstration process, animation display and the like of display contents can be provided for various power network services such as other power scheduling, power transaction and the like.

In the embodiment of the application, in the process of editing the model of the topology and the network relation of the visual display of the computing power network, a user can intuitively combine means such as the geographical position, the display change of the real-time service influence range on the visual network when the network model is changed, and the like, so that the user is helped to better and intuitively edit the visual display model.

Fig. 2 is a schematic diagram of a visual view generating device suitable for a computing network according to an embodiment of the present invention. As shown in fig. 2, an embodiment of the present application provides a visual view generating apparatus suitable for a computing power network, including:

the visual information acquisition module is used for acquiring visual information of object elements of the computing power network, wherein the visual information comprises attributes, resources and network relations of the object elements.

And the geographic attribute confirming module is used for obtaining the geographic attribute of the object element based on the visual information of the object element.

And the base map layer confirming module is used for obtaining the base map layer corresponding to the computing power network based on the geographic attribute of the object element.

And the visualization model generation module is used for mapping the object elements and the visualization information of the object elements to the base map layer to form a visualization model.

The gridding module is used for dividing a base map layer of the visual model into at least one virtual grid based on the visual information to obtain a gridded visual model; the gridded visualization model is used for generating a visual view of the computing power network, and comprises a computing power coverage display view and/or a computing power path display view.

The apparatus embodiments described above are merely illustrative, wherein the elements illustrated as separate elements may or may not be physically separate, and the elements shown as elements may or may not be physical elements, may be located in one place, or may be distributed over a plurality of network elements. Some or all of the modules may be selected according to actual needs to achieve the purpose of the solution of this embodiment. Those of ordinary skill in the art will understand and implement the present invention without undue burden.

From the above description of the embodiments, it will be apparent to those skilled in the art that the embodiments may be implemented by means of software plus necessary general hardware platforms, or of course may be implemented by means of hardware. Based on this understanding, the foregoing technical solution may be embodied essentially or in a part contributing to the prior art in the form of a software product, which may be stored in a computer readable storage medium, such as ROM/RAM, a magnetic disk, an optical disk, etc., including several instructions for causing a computer device (which may be a personal computer, a server, or a network device, etc.) to execute the method described in the respective embodiments or some parts of the embodiments.

The foregoing embodiments have been provided for the purpose of illustrating the general principles of the present invention, and are more fully described herein with reference to certain specific embodiments thereof, it being understood that the invention has been described above with reference to certain specific embodiments thereof, but it is not intended to limit the scope of the invention to the specific embodiments, but it is intended to cover all modifications, equivalents, alternatives, and modifications falling within the spirit and principles of the invention.

Claims (10)

1. A method for generating a visual view suitable for a computing network, comprising:

obtaining visual information of object elements of the computing power network;

obtaining the geographic attribute of the object element based on the visual information of the object element;

obtaining a base map layer corresponding to the computing power network based on the geographic attribute of the object element;

mapping the object elements and the visual information of the object elements to the base map layer to form a visual model;

dividing a base map layer of the visual model into at least one virtual grid based on the visual information to obtain a gridded visual model; the gridded visualization model is used for generating a visual view of the computing power network, and comprises a computing power coverage display view and/or a computing power path display view.

2. The method of generating a visual view according to claim 1, wherein the generating a computing force overlay presentation view comprises:

and increasing the computational power resource coverage of the object element to the visual model by changing the colors of the virtual grids adjacent to the object element, and generating a computational power coverage display view.

3. The method of generating a visual view according to claim 1, wherein the generating a computing force path presentation view comprises:

and adding the computational force path of the object element to the visual model through connecting the object element, and generating a computational force path display view, wherein the computational force path of the object element is embodied in the form of a color-changing path of a virtual grid.

4. The method for generating a visual view according to claim 1, wherein the acquiring visual information of the object element of the computing power network includes:

collecting object elements of the computing power network for visual display;

acquiring a related attribute state of the object element, wherein the related attribute state comprises a geographic attribute;

analyzing and generating related resources and network relations of the object elements;

and obtaining the visual information of the object element of the computing power network based on the related attribute state of the object element and the related resource and network relation.

5. The method for generating a visual view according to claim 1, wherein the obtaining the geographic attribute of the object element based on the visual information of the object element comprises:

analyzing and obtaining geographic attributes and/or spatial attributes of the object elements based on geographic information fields of the object elements of the visual information; obtaining the geographic attribute of the object element based on the geographic attribute and/or the spatial attribute of the object element; or alternatively

Based on the attribute of the object element of the visual information, keyword analysis and/or semantic analysis are carried out, and the geographic attribute and/or the spatial attribute of the object element are obtained through analysis; and obtaining the geographic attribute of the object element based on the geographic attribute and/or the spatial attribute of the object element.

6. The visual view generating method according to claim 1, wherein the obtaining a base map layer corresponding to the computing power network based on the geographic attribute of the object element includes:

based on the geographic attribute of the object element, obtaining a visual geographic space range of the computing power network;

and obtaining a base map layer corresponding to the computing power network based on the visual geographic space range.

7. The visual view generating method according to claim 1, wherein the virtual grid has editability including adding, deleting, changing the virtual grid.

8. A visual view generation apparatus adapted for use in a computing network, comprising:

the visual information acquisition module is used for acquiring visual information of object elements of the computing power network, wherein the visual information comprises attributes, resources and network relations of the object elements;

the geographic attribute confirming module is used for obtaining the geographic attribute of the object element based on the visual information of the object element;

the base map layer confirming module is used for obtaining a base map layer corresponding to the computing power network based on the geographic attribute of the object element;

the visual model generation module is used for mapping the object elements and the visual information of the object elements to the base map layer to form a visual model;

the gridding module is used for dividing a base map layer of the visual model into at least one virtual grid based on the visual information to obtain a gridded visual model; the gridded visualization model is used for generating a visual view of the computing power network, and comprises a computing power coverage display view and/or a computing power path display view.

9. An electronic device comprising a memory, a processor, the memory having stored thereon a computer program executable on the processor, characterized in that the processor implements the method of any of the preceding claims 1 to 7 when the computer program is executed.

10. A computer readable medium having non-volatile program code executable by a processor, the program code causing the processor to perform the method of any one of claims 1 to 7.

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