CN113626900A - Facility asset icon generation method and system for road comprehensive rod system - Google Patents

Abstract

The invention discloses a facility asset icon generation method of a road comprehensive rod system, which comprises the following steps: establishing data objects including the ID and asset icons of each data object for each part of the comprehensive rod system; establishing an installation relation matrix of each component of the comprehensive rod according to the size and the installation relation of the components; and reading the ID of the data object according to the installation relation of each part, establishing a part installation layer queue stack, splicing the corresponding part icons to corresponding positions according to a first-in and last-out principle, and generating facility asset icons. The complex logic relation among all parts of the comprehensive rod system is calibrated in a map building mode, a single data object of the road comprehensive rod system can be managed, and a two-dimensional axis side icon which reflects a three-dimensional installation perspective relation of a space can be generated.

Description

Facility asset icon generation method and system for road comprehensive rod system

Technical Field

The invention belongs to the technical field of road combination poles, and particularly relates to a facility asset icon generation method and system of a road combination pole system.

Background

With the formal issuance of 5G operation license plates, the government requires that tower resources such as municipal light poles, public security monitoring poles, city management monitoring poles, power towers and the like are opened to 5G network facilities so as to meet the functional applications of intelligent lighting, video monitoring, traffic management, environmental monitoring, 5G communication, information interaction, emergency help seeking and the like. Under the background, the urban illumination street lamp rod piece can well meet the signal coverage requirements of the 5G micro base station and the macro base station due to the inherent convenience of reasonable distribution of the power taking network. Therefore, the street lamp pole network becomes an important platform for carrying 5G equipment.

The entrance of many highly sensitive devices will significantly change the single function and management attributes of conventional light poles. The multi-rod integrated equipment using the intelligent illumination combined rod as a main part brings more and new technical management requirements to the management of the traditional illumination equipment. Under the new demand of combining poles, after various types and ownership units of equipment are centralized in the traditional lighting business, the outstanding contradiction between limited operation and maintenance resources and increasingly complex fault maintenance can be caused.

After a road rod enters the era of comprehensive rods, various devices enter the same comprehensive rod, and the problems of compatibility, coexistence and sharing among the devices need to be solved. At the same time, there is also the problem of coordination between different specialties in maintenance work. Therefore, how to reasonably and integrally configure limited maintenance resources is a key for determining the improvement of the operation and maintenance efficiency of the whole system, so that the system state can be judged in time, interference is filtered and alarm is given, the fault equipment can be accurately repaired, and the overstaffed and repeated waste of the frame-type and multi-bed mechanism can be reduced.

The portrait technology can label the research object, select and calculate a series of attributes which can describe the object condition most, so that the portrait technology can be considered to assist in improving the equipment maintenance and management of the road comprehensive rod system. In the prior art, the portrait technology is not used for equipment maintenance and management of a road comprehensive rod system, and a large amount of data relation needs to be stored in the equipment asset portrait of the road comprehensive rod system. Such as business object to tag relationships, tag to algorithm relationships, and the like. In addition, a large number of relational queries are required during operation, for example, which devices the tag value of the health status of the device is "abnormal" are queried. The invention is achieved accordingly.

Disclosure of Invention

In view of the above-mentioned technical problems, an object of the present invention is to provide a method and a system for generating facility asset icons of a road comprehensive rod system, which calibrate complex logical relationships among parts of the comprehensive rod system by means of map construction, manage single data objects of the road comprehensive rod system, and generate two-dimensional axis-side icons reflecting three-dimensional installation perspective relationships of a space.

The technical scheme of the invention is as follows:

a method for generating a facility asset icon of a road comprehensive rod system comprises the following steps:

s01: establishing data objects including the ID and asset icons of each data object for each part of the comprehensive rod system;

s02: establishing an installation relation matrix of each component of the comprehensive rod according to the size and the installation relation of the components;

s03: and reading the ID of the data object according to the installation relation of each part, establishing a part installation layer queue stack, splicing the corresponding part icons to corresponding positions according to a first-in and last-out principle, and generating facility asset icons.

In a preferred technical solution, the establishing of the installation relationship matrix of each component of the integrated rod in the step S02 includes:

s21: according to the actual working condition and the size of the product, establishing an installation size information table for recording the installation size of the component;

s22: establishing an installation attitude coordinate system by taking the ground elevation as 0 elevation as an initial origin, the horizontal coordinate as a horizontal direction x, the vertical coordinate as a height y and the plane vertical to the x-y as a thickness z, and establishing a position data table for recording positions by taking the installation attitude coordinate system as a basis;

s23: the configuration characteristics of the configuration installation relation matrix include a component model number, a component asset ID, an installation project ID, a longitude coordinate, a latitude coordinate, an elevation coordinate, a previous component ID, a previous component installation property code, a next component ID, a next component installation property code, a component installation attitude coordinate system horizontal coordinate x, a component installation attitude coordinate system height coordinate y, a component installation attitude coordinate system thickness coordinate z, a component icon x-direction scaling coefficient, a component icon y-direction scaling coefficient, and a component icon z-direction scaling coefficient.

In a preferred technical solution, in step S03, according to the arrangement order and the association property between the components recorded in the installation relationship matrix, according to the previous component ID and the next component ID fields, the branches and leaf nodes are sequentially retrieved from the root node to form a complete component installation logical relationship, the icon corresponding to each component is called, and the component icons are assembled to the corresponding positions according to the scaling factor and the pixel position.

In a preferred technical solution, the assembling method in step S03 includes:

s31: selecting a corresponding model icon according to the component model; reading the installation item ID and the component asset ID to generate a title character string and marking the title character string;

s32: reading longitude and latitude elevation coordinates of the equipment point location, and calibrating an icon at a corresponding point location of a GIS map;

s33: reading the ID of the upper-level component, and selecting an icon corresponding to the installation property according to the installation property code of the upper-level component;

s34: respectively zooming pixels of the component icon and the installation property icon according to zoom coefficients of the component icon in x, y and z directions to generate a final installation icon;

s35: and splicing the generated final installation icon at a corresponding position according to a horizontal coordinate x, a height coordinate y and a thickness coordinate z of the component installation attitude coordinate system.

In a preferred embodiment, the step S02 further includes:

and defining the component classification assets and the installation relation as an equipment relation matrix, wherein the equipment relation matrix is used for the influence weight of a component corresponding to a certain ID on a certain time segment point of a component state monitoring sensor, the sampling data value and the data item of the component state monitoring sensor are in a spatial attitude, the equipment relation matrix comprises a sensor sampling data item, the sampling data item is in the position of a correspondingly installed comprehensive pole and box component and the influence severity degree on the component, and the installation spatial attitude and the installation property of the sensor.

In a preferred technical scheme, the ordinate of the device relationship matrix is a shaft asset ID sequence, and the abscissa is an asset installation relationship attribute, where the asset installation relationship attribute includes 0 connected ID, 1 connection property, 2 connection configuration parameters, 3 connection x coordinate, 4 connection y coordinate, 5 connection z coordinate, 6 horizontal space angle, 7 vertical space angle, 8 sensor ID, 9 sensor installation position x coordinate, 10 sensor installation position y coordinate, 11 sensor installation position z coordinate, 12 sensor monitoring data, 13 monitoring data weight, 14 weight value, and 15 data item.

In a preferred embodiment, the step S02 further includes:

constructing a component contact matrix, wherein the component contact matrix comprises a type, an asset table ID, a component picture library code, a picture pixel x, a picture pixel y and a length x after splicing₁Conversion rule, height after splicing y₁Conversion rules, the types comprise 100 prefixes representing a combined pole main pole part, 200 combined pole auxiliary pole parts, 300 lamp arm parts, 400 accessory intelligent devices and 500 accessory non-accessory devices, the asset table ID is used for associating icons of asset types corresponding to device asset IDs in assembly, the component picture library codes are used for defining example side view file names of the component devices of the type, the picture pixel x is used for defining an x pixel value of a component picture, the picture pixel y is used for defining a y pixel value of the component picture, and the spliced length x is a length₁Conversion rule is x₁X is the size height in the asset table, Y is the size length in the asset table, and the conversion rule of the height h after splicing is Y₁＝1。

The invention also discloses a system for generating the facility asset icon of the road comprehensive rod system, which comprises the following components:

the data object establishing module is used for establishing data objects including the IDs and asset icons of the data objects for all the parts of the comprehensive rod system;

the installation relation matrix calculation module is used for establishing an installation relation matrix of each component of the comprehensive rod according to the size and the installation relation of the components;

and the assembly module reads the data object ID according to the installation relation of each component, establishes a component installation hierarchical queue stack, and assembles the corresponding component icons to corresponding positions according to a first-in and last-out principle to generate facility asset icons.

In an optimal technical scheme, the establishing of the installation relationship matrix of each component of the comprehensive pole in the installation relationship matrix calculation module comprises:

s21: according to the actual working condition and the size of the product, establishing an installation size information table for recording the installation size of the component;

s22: establishing an installation attitude coordinate system by taking the ground elevation as 0 elevation as an initial origin, the horizontal coordinate as a horizontal direction x, the vertical coordinate as a height y and the plane vertical to the x-y as a thickness z, and establishing a position data table for recording positions by taking the installation attitude coordinate system as a basis;

s23: the configuration characteristics of the configuration installation relation matrix include a component model number, a component asset ID, an installation project ID, a longitude coordinate, a latitude coordinate, an elevation coordinate, a previous component ID, a previous component installation property code, a next component ID, a next component installation property code, a component installation attitude coordinate system horizontal coordinate x, a component installation attitude coordinate system height coordinate y, a component installation attitude coordinate system thickness coordinate z, a component icon x-direction scaling coefficient, a component icon y-direction scaling coefficient, and a component icon z-direction scaling coefficient.

In a preferred technical scheme, the assembling method of the assembling module comprises the following steps:

s31: selecting a corresponding model icon according to the component model; reading the installation item ID and the component asset ID to generate a title character string and marking the title character string;

s32: reading longitude and latitude elevation coordinates of the equipment point location, and calibrating an icon at a corresponding point location of a GIS map;

s33: reading the ID of the upper-level component, and selecting an icon corresponding to the installation property according to the installation property code of the upper-level component;

s34: respectively zooming pixels of the component icon and the installation property icon according to zoom coefficients of the component icon in x, y and z directions to generate a final installation icon;

s35: and splicing the generated final installation icon at a corresponding position according to a horizontal coordinate x, a height coordinate y and a thickness coordinate z of the component installation attitude coordinate system.

Compared with the prior art, the invention has the beneficial effects that:

1. the invention constructs a component mounting mirror image method under the comprehensive rod box system, uses the same-proportion icons, and can generate real rod box facility asset icons according to the real component mounting sequence, position and combination mode, so as to assemble the comprehensive rod system which accords with the actual engineering mounting proportion and the actual posture, thereby being convenient for calibrating the complex logic relationship among the components of the comprehensive rod system. Different maps (identification maps and state maps) can be drawn, the complex coupling of different regression lesions of various devices in the comprehensive rod can be simplified, and the manual readability of the dyed state pictures can be improved. The intelligent equipment, the steel structural member, the civil engineering equipment and the environmental factor maintenance equipment are simplified into pictures and colors for representation, and the model decision complexity caused by the coupling of complex factors can be obviously reduced. The characteristics of various types of equipment and the daily operation and maintenance requirements can be fully considered, and the diagnosis of the whole health state is facilitated.

2. The facility asset icon generated by the invention is also integrated with complex field installation space relation of the comprehensive pole box, and relates to more complex geographic space data such as horizontal orientation, mutual relation, vertical posture and the like. The single data object of the road comprehensive rod system can be effectively managed.

Drawings

The invention is further described with reference to the following figures and examples:

FIG. 1 is a flow chart of a facility asset icon generation method of a roadway integrated pole system of the present invention;

FIG. 2 is a schematic view of a facility asset icon of the road integrator rod system of the present invention;

FIG. 3 is a functional block diagram of a facility asset icon generation system of the road integrator rod system of the present invention;

FIG. 4 is a status map of facility asset icon and color block pattern spot stitching of the road comprehensive rod system 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 with reference to the accompanying drawings in conjunction with the following detailed description. It should be understood that the description is intended to be exemplary only, and is not intended to limit the scope of the present invention. Moreover, in the following description, descriptions of well-known structures and techniques are omitted so as to not unnecessarily obscure the concepts of the present invention.

Examples

Interpretation of terms:

(1) the comprehensive rod system comprises: the physical carrying platform is composed of an integrated rod, an integrated equipment box, an integrated power supply box, an integrated pipeline and other auxiliary facilities, provides service guarantees such as carrying carriers, cable laying channels, power supply and the like on the rod and in a case, and is a novel public infrastructure.

(2) Carrying out facilities: the general name of various city management and service facilities carried by the comprehensive rod facility.

(3) A comprehensive rod: the rod body for carrying on the rod is provided for various carrying facilities needing to be arranged on the rod and is formed by assembling a main rod, an auxiliary rod, a cross arm, a lamp arm and the like.

(4) The comprehensive equipment box comprises: the case provides an in-case carrying cabin space, a power supply, a grounding environment and a wiring environment for various carrying facilities needing to be installed in the case.

(5) Comprehensive pipeline: the comprehensive rod, the comprehensive equipment box, the comprehensive power box and the public information (power) pipeline are connected and communicated, and the comprehensive pipeline is used for laying communication, control and power distribution cables.

(6) The mobile jib: the basic rod body of the comprehensive rod can independently form the comprehensive rod or be combined with other parts to form the comprehensive rod.

(7) Auxiliary rod: one of the parts of the comprehensive pole is arranged on the upper part of the main pole of the comprehensive pole and can be used for bearing the carrying facilities such as a lamp arm, a mobile communication base station and the like.

(8) A cross arm: one of the parts of the comprehensive pole is arranged on the side surface of the comprehensive pole and can be used for horizontally bearing carrying facilities such as signal lamps, cameras, signboards and the like.

(9) A lamp arm: one of the parts of the comprehensive rod is arranged on the auxiliary rod and can be used for bearing facilities such as lighting lamps and lanterns.

As shown in fig. 1, a method for generating a facility asset icon of a road integrated lever system includes the following steps:

s01: establishing data objects including the ID and asset icons of each data object for each part of the comprehensive rod system;

s02: establishing an installation relation matrix of each component of the comprehensive rod according to the size and the installation relation of the components;

s03: reading the data object ID according to the installation relationship of each component, establishing a component installation layer queue stack, splicing the corresponding component icons to corresponding positions according to a first-in-last-out principle, and generating facility asset icons as shown in FIG. 2.

Each part in the integrated rod system needs to be decomposed into different metadata separately. One specific possible scenario is: the comprehensive pole system (system) is disassembled into a 5G base station, a main pole, an auxiliary pole, a cross arm, a lamp arm, a comprehensive equipment box, a comprehensive power box, a comprehensive pipeline, a public service cabin, an electric power metering cabin, a lighting control cabin, a carrying facility power distribution cabin, a comprehensive pipe well, a monitoring camera head, an advertising (electronic) board, a traffic indication road sign, a cable and other single data object sets for management. Other disassembly methods are of course possible. The invention is not limited.

In a preferred embodiment, the complex pole box installation space in the field is complex, involving more complex geospatial data such as horizontal orientation, interrelationship, and vertical attitude. The method aims at service state evaluation, and provides an icon perspective relation calculation method capable of simplifying spatial attitude. The step S02 of establishing the installation relationship matrix of each component of the integrated pole includes:

s21: according to the actual working condition and the size of the product, establishing an installation size information table for recording the installation size of the component;

s22: establishing an installation attitude coordinate system by taking the ground elevation as 0 elevation as an initial origin, the horizontal coordinate as a horizontal direction x, the vertical coordinate as a height y and the plane vertical to the x-y as a thickness z, and establishing a position data table for recording positions by taking the installation attitude coordinate system as a basis;

s23: the configuration characteristics of the configuration installation relation matrix include a component model number, a component asset ID, an installation project ID, a longitude coordinate, a latitude coordinate, an elevation coordinate, a previous component ID, a previous component installation property code, a next component ID, a next component installation property code, a component installation attitude coordinate system horizontal coordinate x, a component installation attitude coordinate system height coordinate y, a component installation attitude coordinate system thickness coordinate z, a component icon x-direction scaling coefficient, a component icon y-direction scaling coefficient, and a component icon z-direction scaling coefficient.

The installation relation matrix is a relational data table constructed according to the equipment installation attribute information and expresses the actual installation sequence and properties among the equipment under the comprehensive pole.

The stack in step S03 refers to the concept of a stack in a data structure stack, and performs a related operation after the data object arrives first, i.e., a principle of first-in-last-out. When the integrated rod units are assembled into icons, the rod foundation is the first determined object. The parts are a main rod, an auxiliary rod, a cross arm, an overhaul cabin door and a rod body equipment box in sequence. In the icon assembling process, according to the installation sequence and the installation position under the actual working condition, the icons are respectively assembled to the corresponding positions according to the pixel positions and the scaling. Thus, an axis side mirror image reflecting the actual mounting position and posture is formed.

In a preferred embodiment, in step S03, according to the arrangement order and the association property between the components recorded in the installation relationship matrix, the branches and leaf nodes are successively retrieved from the root node according to the previous component ID and the next component ID fields to form a complete component installation logical relationship, the icon corresponding to each component is retrieved, and the component icons are assembled to the corresponding positions according to the scaling factor and the pixel position.

In a preferred embodiment, the assembling method in step S03 includes:

s31: selecting a corresponding model icon according to the component model; reading the installation item ID and the component asset ID to generate a title character string and marking the title character string;

s32: reading longitude and latitude elevation coordinates of the equipment point location, and calibrating an icon at a corresponding point location of a GIS map;

s33: reading the ID of the upper-level component, and selecting an icon corresponding to the installation property according to the installation property code of the upper-level component;

s34: respectively zooming pixels of the component icon and the installation property icon according to zoom coefficients of the component icon in x, y and z directions to generate a final installation icon;

s35: and splicing the generated final installation icon at a corresponding position according to a horizontal coordinate x, a height coordinate y and a thickness coordinate z of the component installation attitude coordinate system.

In a preferred embodiment, the step S02 further includes:

and defining the component classification assets and the installation relation as an equipment relation matrix, wherein the equipment relation matrix is used for the influence weight of a component corresponding to a certain ID on a certain time segment point of a component state monitoring sensor, the sampling data value and the data item of the component state monitoring sensor are in a spatial attitude, the equipment relation matrix comprises a sensor sampling data item, the sampling data item is in the position of a correspondingly installed comprehensive pole and box component and the influence severity degree on the component, and the installation spatial attitude and the installation property of the sensor.

The device relationship matrix focuses on the position and influence of the recording rod box state sensor on the control installed on the ID component to which the recording rod box state sensor belongs. Finally, a plurality of two-dimensional matrix sequences of the monitoring data are formed according to the time sequence, and a three-dimensional state matrix along the time axis is further formed.

In a preferred embodiment, the ordinate of the device relationship matrix is a shaft asset ID sequence and the abscissa is an asset installation relationship attribute including 0 connected ID, 1 connection property, 2 connection configuration parameter, 3 connection x coordinate, 4 connection y coordinate, 5 connection z coordinate, 6 horizontal space angle, 7 vertical space angle, 8 sensor ID, 9 sensor installation location x coordinate, 10 sensor installation location y coordinate, 11 sensor installation location z coordinate, 12 sensor monitoring data, 13 monitoring data weight, 14 weight value, 15 data item.

In a preferred embodiment, the step S02 further includes:

constructing a component contact matrix, wherein the component contact matrix comprises a type, an asset table ID, a component picture library code, a picture pixel x, a picture pixel y and a length x after splicing₁Conversion rule, height after splicing y₁Conversion rules, the types comprise 100 prefixes representing a combined pole main pole part, 200 combined pole auxiliary pole parts, 300 lamp arm parts, 400 accessory intelligent devices and 500 accessory non-accessory devices, the asset table ID is used for associating icons of asset types corresponding to device asset IDs in assembly, the component picture library codes are used for defining example side view file names of the component devices of the type, the picture pixel x is used for defining an x pixel value of a component picture, the picture pixel y is used for defining a y pixel value of the component picture, and the spliced length x is a length₁Conversion rule is x₁X is the size height in the asset table, Y is the size length in the asset table, and the conversion rule of the height h after splicing is Y₁＝1。

The device relation matrix and the component relation matrix form a parallel complementary relation to serve different business scenarios. The component relation matrix focuses on recording the serial connection relationship among the components, aims to reflect the spatial correlation and the proportional relationship among the components, and can construct an identification map.

As shown in fig. 2, the present invention also discloses a facility asset icon generating system of a road integrated rod system, comprising:

the data object establishing module 10 is used for establishing data objects including the IDs and asset icons of all the data objects for all the components of the comprehensive rod system;

the installation relation matrix calculation module 20 is used for establishing an installation relation matrix of each component of the comprehensive pole according to the size and the installation relation of the components;

and the assembling module 30 reads the data object ID according to the installation relation of each component, establishes a component installation hierarchical queue stack, and assembles the corresponding component icons to corresponding positions according to a first-in and last-out principle to generate facility asset icons.

The comprehensive pole system is disassembled into a 5G base station, a main pole, an auxiliary pole, a cross arm, a lamp arm, a comprehensive equipment box, a comprehensive power box, a comprehensive pipeline, a public service cabin, an electric power metering cabin, an illumination control cabin, a carrying facility distribution cabin, a comprehensive pipe well and other single data objects for management. And recording the installation property relation of each comprehensive rod system part, establishing the ID of a data object, an asset icon and the like.

According to the actual working condition and the size of the product, a data table for recording positions is constructed, the ground elevation is taken as the initial origin of 0 elevation, the horizontal coordinate is taken as the horizontal direction x, the vertical coordinate is taken as the height y, and the thickness z is taken as the position perpendicular to the x-y plane. Based on the coordinate system of the component installation posture, a table for recording the installation size information of the equipment component is established.

And constructing a component mounting table, wherein the structural characteristics of the component mounting table are { component model, component asset ID, mounting item ID, longitude coordinate, latitude coordinate, elevation coordinate, previous-stage component ID, previous-stage component mounting property code, next-stage component ID, next-stage component mounting property code, horizontal coordinate x of a component mounting posture coordinate system, height coordinate y of the component mounting posture coordinate system, thickness coordinate z of the component mounting posture coordinate system, scaling coefficient of x direction of a component icon, scaling coefficient of y direction of the component icon, and scaling coefficient of z direction of the component icon }. The fields of the table are used to record the order of arrangement and the nature of the association between the parts, and from the last part ID and next part ID fields, branches and leaf nodes can be retrieved one by one from the root node. According to the logical relationship, a complete component installation logical relationship can be formed, and therefore complete component space attributes can be recorded. And then the icon corresponding to each component can be called, and the component pictures are spliced according to the zooming coefficient.

By the data record organization method, the assembly sequence is as follows: the corresponding model icon can be selected according to the model of the component; reading the installation item ID and the component asset ID to generate a title character string, and marking the title character string to be centered under the model icon; reading longitude and latitude elevation coordinates of the equipment point location, and calibrating an icon at a corresponding point location of a GIS map; reading the ID of the upper-level component, and selecting an icon corresponding to the changed installation property according to the installation property code of the upper-level component; recording the ID operation of the part, when the ID of the next-level part needs to be calculated, building a tree-shaped hierarchical installation relation according to an installation sequence relation table, searching the next-level part, and recalculating once again according to the calculation method of the operation of the previous-level part. In actual program implementation, a calculation method is defined as a class object containing function or method, and calculation resources consistent with methods and references can be provided for all part IDs; performing pixel deformation on the component icon and the installation property icon according to scaling coefficients of the component icon in the x direction, the y direction and the z direction to generate a final installation icon; splicing the compressed installation icons at corresponding positions according to a horizontal coordinate x, a height coordinate y and a thickness coordinate z of a component installation attitude coordinate system; and finishing the final output of the spliced icon.

In addition, after the single comprehensive rod asset icon is generated, a two-dimensional comprehensive rod system node group installation map is constructed among the single rods according to the topological link relation of the underground pipelines.

And two parallel relation matrixes are constructed, and data sources are provided for different services such as constructing a state map and an identification map.

And defining the component classification assets and the installation relation as an equipment relation matrix, wherein the equipment relation matrix comprises sampling data items of the Internet of things equipment (sensor) and aims to reflect the specific positions of the sampling data at the corresponding installed comprehensive pole box equipment IDs and the influence severity degree on the pole box component IDs. Meanwhile, the installation space attitude and the installation property of the sensor are reflected. Wherein the positive azimuthal direction of the attitude is defined as follows: the horizontal direction takes the north direction as zero degree, the clockwise direction as the positive direction, and the recording unit is degree. The positive direction of the vertical direction is 0 degree vertically downwards and 180 degrees vertically upwards, and the included angle between the positive direction of the vertical direction and the 0 degree is recorded. The function of the equipment relation matrix is used for integrating the rod box component state monitoring sensors, and at a certain time segment point, the influence weight of a sampled data value and a data item on a certain ID corresponding rod box component is influenced.

The abscissa of the device relationship matrix is an asset installation relationship attribute and comprises 0 connected ID, 1 connection property, 2 connection configuration parameters, 3 connection x coordinate/length, 4 connection y coordinate/width, 5 connection z coordinate/height, 6 horizontal space angle, 7 vertical space angle, 8 sensor ID, 9 sensor installation position x coordinate/length, 10 sensor installation position y coordinate/width, 11 sensor installation position z coordinate/height, 12 sensor monitoring data, 13 monitoring data weight, 14 weight numerical value and 15 data item. The ordinate is the shaft asset ID sequence and records how many body parts are specified in the club-closing system. The device relationship matrix is specifically shown in the following table:

wherein the columns are defined as follows:

0 connected ID: recording the asset ID of the attached device under the asset ID of the local line, wherein the specific format is as follows, ID1, ID2, … IDj, the middle is full comma, separated or other unusual symbols as separators to distinguish the records of different devices, and the splicing program divides the records by the separators, constructs a tree-shaped storage structure in the memory and reproduces the specific asset installation relation logic.

1 connection property: the installation property between the devices is defined, and the method can be selected from the following steps of 0 welding, 1 riveting, 2 bolts, 3 hinges, 4 hoops, 5 pasting, 6 laying, 7 hanging, 8 plugging wires and 9 others. The middle part uses full code comma, separation or other unusual symbols as separating symbols to distinguish the records of different devices, and the splicing (assembling) procedure is used for splitting.

2, connection configuration parameters: the connection size and installation parameters of the components are recorded, and the parameters of the components are divided by using a "$" half-angle currency symbol as a separator or other unusual symbols to distinguish records of different devices, and the splicing program is used for splitting.

3 connect x-coordinate/length: and recording the length midpoint of the part to be connected, which is arranged in the row of parts, in the length direction with the defined x coordinate as the part, and taking the lower left corner of the left side view of the part product picture as the origin of coordinates. If there are multiple records, the "$" half-angle currency symbol is used as a separator or other unusual symbols are used as separators to distinguish the records of different devices, and the splicing program cuts the records according to the separator.

4 connect y-coordinate/Width: and recording the width midpoint of the part to be connected, which is arranged in the row of parts, in the width direction with the y coordinate defined as the part, and taking the lower left corner of the left side view of the part product picture as the origin of coordinates. If there are multiple records, the "$" half-angle currency symbol is used as a separator or other unusual symbols are used as separators to distinguish the records of different devices, and the splicing program cuts the records according to the separator.

5 connect z-coordinate/height: and in the height direction of defining the z coordinate as the component, recording the height midpoint of the component arranged in the row by the connected component, and taking the lower left corner of the left side view of the component product picture as the origin of coordinates. If there are multiple records, the "$" half-angle currency symbol is used as a separator or other unusual symbols are used as separators to distinguish the records of different devices, and the splicing program cuts the records according to the separator.

6 horizontal space angle: the horizontal angle of the space posture of the connected part connected with the row of parts is recorded, the value is [0-360 ] degrees, the due north direction is 0(360) degree direction, and the installation point between the connected part and the row of parts is taken as the origin of coordinates. If there are multiple records, the "$" half-angle currency symbol is used as a separator or other unusual symbols are used as separators to distinguish the records of different devices, and the splicing program cuts the records according to the separator.

7 vertical space angle: the vertical angle of the connected part in the space posture connected with the row of parts is recorded, the value is [0-180 ]) degrees, the vertical downward direction is 0 degree direction, the vertical upward direction is 180 degrees direction, and the installation point between the connected part and the row of parts is taken as the origin of coordinates. If there are multiple records, the "$" half-angle currency symbol is used as a separator or other unusual symbols are used as separators to distinguish the records of different devices, and the splicing program cuts the records according to the separator.

8, sensor ID: if the connected component is preceded by a sensor with the row of components, then the entry is the sensor asset ID. The asset ID code comprises the model number of the sensor and a physical serial number, so that the service management program can further search the interface address and the access parameter of the service management program, and the real-time acquisition of the sensor parameters is realized. The ID number of the sensor should contain type and model information, and specific interface information can be looked up from the asset table, and if there are multiple records, the "$" half-angle currency symbol is used as a separator or other unusual symbols are used as separators to distinguish the records of different devices.

9 sensor mounting position x coordinate/length: and in the length direction with the defined x coordinate as the component, the recording sensor is installed at the middle point of the length of the component, and the lower left corner of the left side view of the component product picture is taken as the origin of coordinates. If there are multiple records, the "$" half-angle currency symbol is used as a separator or other unusual symbols are used as separators to distinguish the records of different devices, and the splicing program cuts the records according to the separator.

10 sensor mounting position y-coordinate/width: and in the width direction with the defined y coordinate as the component, the recording sensor is installed at the middle point of the width of the component, and the lower left corner of the left side view of the component product picture is taken as the origin of coordinates. If there are multiple records, the "$" half-angle currency symbol is used as a separator or other unusual symbols are used as separators to distinguish the records of different devices, and the splicing program cuts the records according to the separator.

11 sensor mounting position z coordinate/height: and in the height direction with the defined z coordinate as the component, recording the height midpoint of the component on which the sensor is installed, and taking the lower left corner of the left side view of the component product picture as the origin of coordinates. If there are multiple records, the "$" half-angle currency symbol is used as a separator and the stitching program cuts it up.

12, sensor monitoring data: monitoring data are divided into four categories, namely 0 pole box electrical performance state monitoring sensors (0 voltage, 1 current, 2 instantaneous electric quantity, 3 accumulated electric quantity, 4 phases, 5 active power, 6 reactive power, 7 loop states and 8 others); 1 pole box external environment internet of things sensor (1 door state, 2 door control state, 3 water accumulation state, 4 three-way inclination, 5 three-way acceleration, 6 three-way angular velocity, 7 three-way angular magnetic field, 8 horizontal azimuth, 9 longitudinal azimuth, 10 temperature and humidity, 11 wind speed, 12 wind direction, 13 signal intensity, 14 illuminance, 15 rainfall, 16 noise, 17PM2.5, 18PM10, 19 fan rotating speed, 20 electric leakage grounding, 21 other); 2 tube well state monitoring sensors (0 well lid displacement, 1 comprehensive well liquid level, 2 pipeline occupation 0, 3 pipeline occupation 1, 4 theft prevention, 5 power supply, 6 hydraulic pressure, 7 flow, 8 others); the 3 staff patrol the equipment status (0 attachment damage, 1 appearance stain, 2 dents, 3 scratches, 4 equipment cracks, 5 rust, 6 cracked, 7 broken, 8 dropped, 9 water in, 10 equipment aging, 11 deformed, 12 loose, 13 stolen, 14 heat dissipation, 15 foreign matters, 16 water accumulation, 17 parasitic animal nest, 18 collapsed, 19 displacement, 20 sloshing, 21 clean, 22 cable joint, 23 out of service, 24 in maintenance, 25 others); 4 sensor itself and data status (0 online, 1 offline, 2 disabled, 3 in service, 4 disabled, 5 normal calibration range, 6 threshold absolute values between 10% and 20%, 7 threshold absolute values between 21% and 40%, 8 threshold absolute values between 41% and 60%, 9 threshold absolute values between 61% and 80%, 10 threshold absolute values between 81% and 99%, 11 threshold absolute values between 100% and 150%, 12 threshold absolute values between 151% and 200%, 13 threshold absolute values between 201% and 300%, 14 threshold absolute values above 301%, 15 others). The term is used for selecting wire frames with different shapes and describing a health state map of the closed-rod system. If there are multiple records, the "$" half-angle currency symbol is used as a separator or other unusual symbols are used as separators to distinguish the records of different devices, and the splicing program cuts the records according to the separator.

13 monitoring data weight: this definition is used to define the degree of influence of this sensor data on the overall closed-lever system, with no hazard being defined as 0 and severe hazard or even need to be deactivated being defined as 19. Specifically, as follows, 0 shows data, 1 slight effect, 2 slight effect, 3 slight effect, 4 moderate effect, 5 moderate effect, 6 moderate effect, 7 large effect, 8 large effect, 9 large effect, 10 severe effect, 11 severe effect, 12 severe effect, 13 severe effect, 14 severe effect, 15 severe effect, 16 proposed deactivation, 17 proposed deactivation, 18 proposed deactivation, 19 must be deactivated. The corner vertex number and the radius of the wire frames in different shapes are selected, the more serious the influence degree is, the larger the radius is, and the service is in describing the health state atlas of the closed rod system. If there are multiple records, the "$" half-angle currency symbol is used as a separator or other unusual symbols are used as separators to distinguish the records of different devices, and the splicing program cuts the records according to the separator.

14 weight values: this term is used to describe the severity of the status of the corresponding component of the record in the corresponding weight under item 13, with 0 being almost none and 100 being the most severe. The numerical value is 0 to 100 percent. The item is changed to be used for selecting the gradual change speed of the colors in the wire frames with different shapes, so that the health state map of the closed rod system is drawn. If there are multiple records, the "$" half-angle currency symbol is used as a separator or other unusual symbols are used as separators to distinguish the records of different devices, and the splicing program cuts the records according to the separator.

15 data items: the data records the data of the equipment installation, serves the (RGB) numerical value of the color in the state wire frame, and if one sensor collects a plurality of data, such as temperature and humidity sensors can simultaneously collect temperature and humidity, the data items are separated by full code commas and signs. If there are different records of multiple sensor devices, the "$" half-angle currency symbol or other unusual symbols are used as separators to distinguish the records of the different devices, and the splicing program cuts the records according to the separators.

When the time segments are accumulated within a certain time period, for example, from a certain time beginning to a certain time end, a state sequence covering several time segments will be formed. In this case, a three-dimensional matrix of component classification assets is formed, with a timeline as a clue. This matrix will serve for the subsequent delineation and stitching of the colour-block pattern patches, forming a series of state patterns, as shown in fig. 4, serving for the subsequent further identification and diagnosis of the monitoring state evolution law of the integrated pole box.

When the pictures are spliced, reading a component contact matrix in the asset installation table, and calling the pictures of the components (assemblies) according to the component contact matrix to complete splicing. When a plurality of cantilever arms are arranged on the comprehensive rod, side views of a single cantilever arm are respectively formed, namely side views with different visual angles are generated, namely the side view of each cantilever arm on the combined rod is independently established for each cantilever arm, and a ground map is provided for the subsequent drawing of a state map. The component association matrix rules are as follows:

after state mapping, the identification will be dominated by the axonometric map, while the thickness parameter z is only a reference factor serving for the updating of the axonometric map, so that the parameter z is not introduced in the rule table. The method can improve the manual readability of the dyed state picture, and the side view of the comprehensive rod system conforming to the actual engineering installation proportion is assembled as far as possible through the conversion of the dimension proportion of the state picture and the assets, so that the side view conforming to the actual postures of the comprehensive rod and the pipe well can be drawn.

It is to be understood that the above-described embodiments of the present invention are merely illustrative of or explaining the principles of the invention and are not to be construed as limiting the invention. Therefore, any modification, equivalent replacement, improvement and the like made without departing from the spirit and scope of the present invention should be included in the protection scope of the present invention. Further, it is intended that the appended claims cover all such variations and modifications as fall within the scope and boundaries of the appended claims or the equivalents of such scope and boundaries.

Claims (10)

1. A method for generating a facility asset icon of a road comprehensive rod system is characterized by comprising the following steps:

s01: establishing data objects including the ID and asset icons of each data object for each part of the comprehensive rod system;

s02: establishing an installation relation matrix of each component of the comprehensive rod according to the size and the installation relation of the components;

s03: and reading the ID of the data object according to the installation relation of each part, establishing a part installation layer queue stack, splicing the corresponding part icons to corresponding positions according to a first-in and last-out principle, and generating facility asset icons.

2. The method for generating asset icons of a road integrated pole system according to claim 1, wherein the step S02 of establishing the installation relationship matrix of the components of the integrated pole comprises:

s21: according to the actual working condition and the size of the product, establishing an installation size information table for recording the installation size of the component;

s22: establishing an installation attitude coordinate system by taking the ground elevation as 0 elevation as an initial origin, the horizontal coordinate as a horizontal direction x, the vertical coordinate as a height y and the plane vertical to the x-y as a thickness z, and establishing a position data table for recording positions by taking the installation attitude coordinate system as a basis;

s23: the configuration characteristics of the configuration installation relation matrix include a component model number, a component asset ID, an installation project ID, a longitude coordinate, a latitude coordinate, an elevation coordinate, a previous component ID, a previous component installation property code, a next component ID, a next component installation property code, a component installation attitude coordinate system horizontal coordinate x, a component installation attitude coordinate system height coordinate y, a component installation attitude coordinate system thickness coordinate z, a component icon x-direction scaling coefficient, a component icon y-direction scaling coefficient, and a component icon z-direction scaling coefficient.

3. The method of claim 2, wherein in step S03, according to the arrangement order and the association property between the components recorded in the installation relationship matrix, according to the previous component ID and the next component ID fields, the branches and leaf nodes are sequentially retrieved from the root node to form a complete component installation logical relationship, the icon corresponding to each component is retrieved, and the component icons are assembled into corresponding positions according to the scaling factor and the pixel position.

4. The method for generating asset icons of a road integrator rod system according to claim 1, wherein the assembling method in step S03 comprises:

s31: selecting a corresponding model icon according to the component model; reading the installation item ID and the component asset ID to generate a title character string and marking the title character string;

s32: reading longitude and latitude elevation coordinates of the equipment point location, and calibrating an icon at a corresponding point location of a GIS map;

s33: reading the ID of the upper-level component, and selecting an icon corresponding to the installation property according to the installation property code of the upper-level component;

s34: respectively zooming pixels of the component icon and the installation property icon according to zoom coefficients of the component icon in x, y and z directions to generate a final installation icon;

s35: and splicing the generated final installation icon at a corresponding position according to a horizontal coordinate x, a height coordinate y and a thickness coordinate z of the component installation attitude coordinate system.

5. The method for generating an asset icon of a road integrator bar system according to claim 4, wherein said step S02 further comprises:

and defining the component classification assets and the installation relation as an equipment relation matrix, wherein the equipment relation matrix is used for the influence weight of a component corresponding to a certain ID on a certain time segment point of a component state monitoring sensor, the sampling data value and the data item of the component state monitoring sensor are in a spatial attitude, the equipment relation matrix comprises a sensor sampling data item, the sampling data item is in the position of a correspondingly installed comprehensive pole and box component and the influence severity degree on the component, and the installation spatial attitude and the installation property of the sensor.

6. The asset icon generation method of a road integrator bar system as claimed in claim 5, wherein the ordinate of said device relationship matrix is a bar asset ID sequence and the abscissa is an asset installation relationship attribute comprising 0 connected ID, 1 connection property, 2 connection configuration parameter, 3 connection x coordinate, 4 connection y coordinate, 5 connection z coordinate, 6 horizontal space angle, 7 vertical space angle, 8 sensor ID, 9 sensor installation position x coordinate, 10 sensor installation position y coordinate, 11 sensor installation position z coordinate, 12 sensor monitoring data, 13 monitoring data weight, 14 weight value, 15 data item.

7. The method for generating an asset icon of a road integrator bar system according to claim 1, wherein said step S02 further comprises:

constructing a component contact matrix, wherein the component contact matrix comprises a type, an asset table ID, a component picture library code, a picture pixel x, a picture pixel y and a length x after splicing₁Conversion rule, height after splicing y₁Conversion rules, the types comprise 100 prefixes representing a combined pole main pole part, 200 combined pole auxiliary pole parts, 300 lamp arm parts, 400 accessory intelligent devices and 500 accessory non-accessory devices, the asset table ID is used for associating icons of asset types corresponding to device asset IDs in assembly, the component picture library codes are used for defining example side view file names of the component devices of the type, the picture pixel x is used for defining an x pixel value of a component picture, the picture pixel y is used for defining a y pixel value of the component picture, and the spliced length x is a length₁Conversion rule is x₁And (X/Y) × Y, wherein X is the height of the asset in the asset table, the length of the asset in the Y table, and the conversion rule of the height h after splicing is Y₁=1。

8. A system for generating an asset icon of a road integrated pole system, comprising:

the data object establishing module is used for establishing data objects including the IDs and asset icons of the data objects for all the parts of the comprehensive rod system;

the installation relation matrix calculation module is used for establishing an installation relation matrix of each component of the comprehensive rod according to the size and the installation relation of the components;

and the assembly module reads the data object ID according to the installation relation of each component, establishes a component installation hierarchical queue stack, and assembles the corresponding component icons to corresponding positions according to a first-in and last-out principle to generate facility asset icons.

9. The system of claim 8, wherein the building of the installation relationship matrix of the components of the integrated pole in the installation relationship matrix calculation module comprises:

s21: according to the actual working condition and the size of the product, establishing an installation size information table for recording the installation size of the component;

s22: establishing an installation attitude coordinate system by taking the ground elevation as 0 elevation as an initial origin, the horizontal coordinate as a horizontal direction x, the vertical coordinate as a height y and the plane vertical to the x-y as a thickness z, and establishing a position data table for recording positions by taking the installation attitude coordinate system as a basis;

s23: the configuration characteristics of the configuration installation relation matrix include a component model number, a component asset ID, an installation project ID, a longitude coordinate, a latitude coordinate, an elevation coordinate, a previous component ID, a previous component installation property code, a next component ID, a next component installation property code, a component installation attitude coordinate system horizontal coordinate x, a component installation attitude coordinate system height coordinate y, a component installation attitude coordinate system thickness coordinate z, a component icon x-direction scaling coefficient, a component icon y-direction scaling coefficient, and a component icon z-direction scaling coefficient.

10. The system of claim 8, wherein the method of assembling the assembly module comprises:

s31: selecting a corresponding model icon according to the component model; reading the installation item ID and the component asset ID to generate a title character string and marking the title character string;

s32: reading longitude and latitude elevation coordinates of the equipment point location, and calibrating an icon at a corresponding point location of a GIS map;

s33: reading the ID of the upper-level component, and selecting an icon corresponding to the installation property according to the installation property code of the upper-level component;

s34: respectively zooming pixels of the component icon and the installation property icon according to zoom coefficients of the component icon in x, y and z directions to generate a final installation icon;

s35: and splicing the generated final installation icon at a corresponding position according to a horizontal coordinate x, a height coordinate y and a thickness coordinate z of the component installation attitude coordinate system.

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