CN111045663B - Method and system for automatically generating vector graphic frame - Google Patents

Abstract

The invention discloses a method and a system for automatically generating a vector graphic frame. The whole vector graphic frame generation process is full-automatic, manual intervention on the generation process is not needed, and graphical drawing on each concerned object is not needed. Each graphic element is automatically drawn according to the size proportion by different types, so that the graphic drawing workload of the warehouse management system is greatly reduced.

Description

Method and system for automatically generating vector graphic frame

Technical Field

The invention belongs to the technical field of intelligent logistics warehouse management, and particularly relates to a method and a system for automatically generating a vector graphic frame.

Background

Along with the continuous improvement of the economic development level in China, the modern logistics industry also rapidly develops, and the warehousing link plays a role in receiving the upstream and downstream of the supply chain in the modern logistics industry, so that the traditional warehousing management faces a great challenge, is mutually disjointed with the modern logistics industry, is very unfavorable for the progress and development of the logistics industry, and has the necessary trend of the warehousing management development of an intelligent and unmanned warehousing management system.

The intelligent warehouse management system has the main functions of managing the material storage state and the warehouse running state, automatically generating a warehouse work state vector graphic frame, providing the warehouse manager with instant and visual display of the warehouse work state, and providing instant and comprehensive reference information for comprehensively controlling the occupancy rate of warehouse storage positions, the running state of crown blocks, the production state and the scheduling decision.

By means of the vector graphic frame, management staff can comprehensively monitor the warehouse status from macroscopic to microscopic, and the vector graphic frame is utilized to directly control and schedule crown blocks and production equipment, manually inventory the materials in warehouse and the like, so that the comprehensiveness and convenience of warehouse management are greatly improved.

Disclosure of Invention

In order to solve the technical problems, the invention provides a method and a system for automatically generating a vector graphic frame.

The technical scheme adopted by the method is as follows: a method for automatically generating a vector graphics framework, comprising the steps of:

step 1: inquiring database configuration information to obtain corresponding association library information according to the local application ID in the configuration file;

step 2: locating the upper left origin of the association library primitives according to the original point azimuth and coordinate information in the association library information, drawing association library primitive bodies and features according to the length and width in the association library information, and generating prompt data according to the association library information;

step 3: obtaining partition information under a current association library;

step 4: the origin of the association library is used as the origin coordinates of the partition coordinate system, the upper left coordinate point of the partition graphic element is positioned according to the partition information, the partition graphic element body and the characteristics are drawn according to the length, the width and the partition type in the partition information, and prompt data are generated according to the partition information;

step 5: acquiring the crossing information of the current association library;

step 6: the origin of the association library is used as the origin coordinates of a cross coordinate system, the upper left coordinate point of the cross primitive is positioned according to the cross information, the cross beams on two sides of the cross primitive are drawn in proportion according to the length, the width and the cross direction in the cross information, and prompt data are generated according to the cross information;

step 7: acquiring current cross-under crown block information according to the related cross-over configuration of the association library;

step 8: determining the direction of a crane girder according to the length, the width and the crossing direction in the crossing information by taking an origin of a correlation library as origin coordinates of a crane coordinate system, positioning a current coordinate point of a crane primitive according to the crane information, drawing a crane girder, a crane trolley, a crane carrying material and a crane real-time height columnar bar according to a proportion, and generating prompt data according to the crane information;

step 9: acquiring storage bit information under a current association library;

step 10: and (3) taking the origin of the association library as the origin coordinates of a storage bit coordinate system, positioning the center coordinate point of the storage bit map element according to the storage bit information, drawing the storage bit map element body and the characteristics according to the length, the width, the storage bit direction and the storage bit state in the storage bit information in proportion, and generating prompt data according to the storage bit information.

The system of the invention adopts the technical proposal that: a system for automatically generating a vector graphics framework, comprising: the system comprises a graphic view module, a reservoir area primitive module, a partition primitive module, a cross primitive module, a crown block primitive module and a storage bitmap primitive module;

the graphic view module is used for reading configuration information data, establishing a graphic frame scene, establishing vector graphic primitives, responding to user operation, acquiring real-time equipment state data and refreshing the states of the graphic primitives; the configuration information comprises association library information, current association library partition information, current association library crossing information, current crossing crown block information and current association library storage bit information;

the library area primitive module is used for positioning the upper left origin of the association library primitives according to the original point azimuth and coordinate information in the association library information, drawing association library primitive bodies and features according to the length and width in the association library information, and generating prompt data according to the association library information;

the partition primitive module is used for taking the origin of the association library as the origin coordinates of a partition coordinate system, positioning the upper left coordinate point of the partition primitive according to partition information, drawing a partition primitive body and characteristics according to the length, the width and the partition type in the partition information, and generating prompt data according to the partition information;

the cross-primitive module is used for positioning a cross-primitive upper left coordinate point according to cross-information by taking an origin of the association library as a cross-coordinate system origin coordinate, drawing cross-primitive two-side cross beams in proportion according to the length, the width and the cross-direction in the cross-information, and generating prompt data according to the cross-information;

the overhead crane graphic primitive module is used for determining the direction of the overhead crane large crane beam according to the length, the width and the cross direction in the cross information by taking the origin of the association library as the origin coordinates of an overhead crane coordinate system, positioning the current coordinate point of the overhead crane graphic primitive according to overhead crane information, drawing the overhead crane large crane beam, the overhead crane trolley, overhead crane carrying materials and overhead crane real-time height columnar bars according to proportion, and generating prompt data according to the overhead crane information;

and the storage bitmap element module is used for taking the origin of the association library as the origin coordinate of the storage bit coordinate system, positioning the center coordinate point of the storage bitmap element according to the storage bit information, drawing the storage bitmap element body and the characteristics according to the length, the width, the storage bit direction and the storage bit state in the storage bit information in proportion, and generating prompt data according to the storage bit information.

According to the invention, the stock area in the logistics warehouse, different functional partitions in the stock area, the crown block span-up running crown block and storage positions in the partitions are graphically presented for each concerned object in a real proportion model according to configuration information. The whole vector graphic frame generation process is full-automatic, manual intervention on the generation process is not needed, and graphical drawing on each concerned object is not needed. Each graphic element is automatically drawn according to the size proportion by different types, so that the graphic drawing workload of the warehouse management system is greatly reduced.

The invention collects the matrix area and various attributes of the graphic element according to the configuration information, and adopts the graphic element object self-drawing mode to draw graphic element units of different positions, sizes, types, states and the like independently. And dynamically constructing the whole architecture partition of the warehouse area, the crown block and the storage bit distribution detail according to the configuration. The whole vector diagram of the graphic framework is drawn, and the scale is unlimited from macroscopic to detail. And each graphic primitive object is visualized and interacted, the graphic primitive object configuration information is quickly checked along with the display of the shortcut information of the mouse, and the state of the graphic primitive object is displayed in real time and intuitively. According to the primitive types, various primitives are positioned and displayed according to a hierarchical coordinate system, and graphical man-machine interaction is realized by combining a view control and refreshing mechanism.

Drawings

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

fig. 2 is a system schematic diagram of an embodiment of the present invention.

Detailed Description

In order to facilitate the understanding and practice of the invention, those of ordinary skill in the art will now make further details with reference to the drawings and examples, it being understood that the examples described herein are for the purpose of illustration and explanation only and are not intended to limit the invention thereto.

Referring to fig. 1, the method for automatically generating the vector graphic frame provided by the invention comprises the following steps:

step 1: inquiring database configuration information to obtain corresponding association library information according to the local application ID in the configuration file;

step 2: locating the upper left origin of the association library primitives according to the original point azimuth and coordinate information in the association library information, drawing association library primitive bodies and features according to the length and width in the association library information, and generating prompt data according to the association library information;

step 3: obtaining partition information under a current association library;

step 4: the origin of the association library is used as the origin coordinates of the partition coordinate system, the upper left coordinate point of the partition graphic element is positioned according to the partition information, the partition graphic element body and the characteristics are drawn according to the length, the width and the partition type in the partition information, and prompt data are generated according to the partition information;

step 5: acquiring the crossing information of the current association library;

step 6: the origin of the association library is used as the origin coordinates of a cross coordinate system, the upper left coordinate point of the cross primitive is positioned according to the cross information, the cross beams on two sides of the cross primitive are drawn in proportion according to the length, the width and the cross direction in the cross information, and prompt data are generated according to the cross information;

step 7: acquiring current cross-under crown block information according to the related cross-over configuration of the association library;

step 8: determining the direction of a crane girder according to the length, the width and the crossing direction in the crossing information by taking an origin of a correlation library as origin coordinates of a crane coordinate system, positioning a current coordinate point of a crane primitive according to the crane information, drawing a crane girder, a crane trolley, a crane carrying material and a crane real-time height columnar bar according to a proportion, and generating prompt data according to the crane information;

step 9: acquiring storage bit information under a current association library;

step 10: and (3) taking the origin of the association library as the origin coordinates of a storage bit coordinate system, positioning the center coordinate point of the storage bit map element according to the storage bit information, drawing the storage bit map element body and the characteristics according to the length, the width, the storage bit direction and the storage bit state in the storage bit information in proportion, and generating prompt data according to the storage bit information.

Referring to fig. 2, the system for automatically generating a vector graphic frame provided by the invention comprises a graphic view module, a library area primitive module, a partition primitive module, a cross primitive module, an overhead crane primitive module and a storage bitmap primitive module;

the graphic view module is used for reading configuration information data, establishing a graphic frame scene, establishing vector primitives, responding to user operation (view scaling, translation, user click response and real-time position data drawing update), acquiring real-time equipment state data and refreshing the states of all the primitives; the configuration information comprises association library information, current association library partition information, current association library crossing information, current crossing crown block information and current association library storage bit information;

the library area primitive module is used for positioning the upper left origin of the association library primitives according to the original point azimuth and coordinate information in the association library information, drawing association library primitive bodies and features according to the length and width in the association library information, and generating prompt data according to the association library information;

the partition primitive module is used for taking the origin of the association library as the origin coordinates of a partition coordinate system, positioning the upper left coordinate point of the partition primitive according to partition information, drawing a partition primitive body and characteristics according to the length, the width and the partition type in the partition information, and generating prompt data according to the partition information;

the cross-primitive module is used for positioning a cross-primitive upper left coordinate point according to cross-information by taking an origin of the association library as a cross-coordinate system origin coordinate, drawing cross-primitive two-side cross beams in proportion according to the length, the width and the cross-direction in the cross-information, and generating prompt data according to the cross-information;

the overhead crane graphic primitive module is used for determining the direction of the overhead crane large crane beam according to the length, the width and the cross direction in the cross information by taking the origin of the association library as the origin coordinates of an overhead crane coordinate system, positioning the current coordinate point of the overhead crane graphic primitive according to overhead crane information, drawing the overhead crane large crane beam, the overhead crane trolley, overhead crane carrying materials and overhead crane real-time height columnar bars according to proportion, and generating prompt data according to the overhead crane information;

and the storage bitmap element module is used for taking the origin of the association library as the origin coordinate of the storage bit coordinate system, positioning the center coordinate point of the storage bitmap element according to the storage bit information, drawing the storage bitmap element body and the characteristics according to the length, the width, the storage bit direction and the storage bit state in the storage bit information in proportion, and generating prompt data according to the storage bit information.

The graphic view module of the embodiment comprises a reading sub-module of configuration information data, a building sub-module of a graphic framework scene, a building sub-module of vector graphic primitives, a response sub-module of user operation, a real-time equipment state data acquisition sub-module and a state refreshing sub-module of each graphic primitive.

The library region primitive module of the embodiment comprises a library region configuration data receiving sub-module, a library region prompt data generating sub-module and a library region primitive coordinate and body drawing sub-module.

The map partitioning primitive module of the embodiment comprises a partitioning configuration data receiving sub-module, a partitioning prompt data generating sub-module and a partitioning primitive coordinate and body drawing sub-module.

The cross-primitive module of the embodiment comprises a cross-configuration data receiving sub-module, a cross-prompt data generating sub-module and a cross-primitive coordinate and ontology drawing sub-module.

The crown block primitive module of the embodiment comprises a crown block configuration data receiving sub-module, a crown block prompt data generating sub-module, a crown block primitive coordinate and body drawing sub-module combined with a span of the crown block, a crown block real-time state data receiving sub-module and a crown block real-time state primitive drawing refreshing sub-module.

The storage bitmap metadata module of the embodiment comprises a storage bit configuration data receiving sub-module, a storage bit prompt data generating sub-module, a storage bitmap metadata coordinate and ontology drawing sub-module and a storage bit time state data receiving sub-module.

It should be understood that portions of this specification not specifically set forth are all of the prior art; the foregoing description of the preferred embodiments is not to be construed as limiting the scope of the invention, and persons of ordinary skill in the art may make substitutions or alterations without departing from the scope of the invention as set forth in the appended claims.

Claims (8)

1. A method for automatically generating a vector graphics framework, comprising the steps of:

step 1: inquiring database configuration information to obtain corresponding association library information according to the local application ID in the configuration file;

step 2: locating the upper left origin of the association library primitives according to the original point azimuth and coordinate information in the association library information, drawing association library primitive bodies and features according to the length and width in the association library information, and generating prompt data according to the association library information;

step 3: obtaining partition information under a current association library;

step 4: the origin of the association library is used as the origin coordinates of the partition coordinate system, the upper left coordinate point of the partition graphic element is positioned according to the partition information, the partition graphic element body and the characteristics are drawn according to the length, the width and the partition type in the partition information, and prompt data are generated according to the partition information;

step 5: acquiring the crossing information of the current association library;

step 6: the origin of the association library is used as the origin coordinates of a cross coordinate system, the upper left coordinate point of the cross primitive is positioned according to the cross information, the cross beams on two sides of the cross primitive are drawn in proportion according to the length, the width and the cross direction in the cross information, and prompt data are generated according to the cross information;

step 7: acquiring current cross-under crown block information according to the related cross-over configuration of the association library;

step 8: determining the direction of a crane girder according to the length, the width and the crossing direction in the crossing information by taking an origin of a correlation library as origin coordinates of a crane coordinate system, positioning a current coordinate point of a crane primitive according to the crane information, drawing a crane girder, a crane trolley, a crane carrying material and a crane real-time height columnar bar according to a proportion, and generating prompt data according to the crane information;

step 9: acquiring storage bit information under a current association library;

step 10: and (3) taking the origin of the association library as the origin coordinates of a storage bit coordinate system, positioning the center coordinate point of the storage bit map element according to the storage bit information, drawing the storage bit map element body and the characteristics according to the length, the width, the storage bit direction and the storage bit state in the storage bit information in proportion, and generating prompt data according to the storage bit information.

2. A system for automatically generating a vector graphics framework, comprising: the system comprises a graphic view module, a reservoir area primitive module, a partition primitive module, a cross primitive module, a crown block primitive module and a storage bitmap primitive module;

the graphic view module is used for reading configuration information data, establishing a graphic frame scene, establishing vector graphic primitives, responding to user operation, acquiring real-time equipment state data and refreshing the states of the graphic primitives; the configuration information comprises association library information, current association library partition information, current association library crossing information, current crossing crown block information and current association library storage bit information;

the library area primitive module is used for positioning the upper left origin of the association library primitives according to the original point azimuth and coordinate information in the association library information, drawing association library primitive bodies and features according to the length and width in the association library information, and generating prompt data according to the association library information;

the partition primitive module is used for taking the origin of the association library as the origin coordinates of a partition coordinate system, positioning the upper left coordinate point of the partition primitive according to partition information, drawing a partition primitive body and characteristics according to the length, the width and the partition type in the partition information, and generating prompt data according to the partition information;

the cross-primitive module is used for positioning a cross-primitive upper left coordinate point according to cross-information by taking an origin of the association library as a cross-coordinate system origin coordinate, drawing cross-primitive two-side cross beams in proportion according to the length, the width and the cross-direction in the cross-information, and generating prompt data according to the cross-information;

the overhead crane graphic primitive module is used for determining the direction of the overhead crane large crane beam according to the length, the width and the cross direction in the cross information by taking the origin of the association library as the origin coordinates of an overhead crane coordinate system, positioning the current coordinate point of the overhead crane graphic primitive according to overhead crane information, drawing the overhead crane large crane beam, the overhead crane trolley, overhead crane carrying materials and overhead crane real-time height columnar bars according to proportion, and generating prompt data according to the overhead crane information;

and the storage bitmap element module is used for taking the origin of the association library as the origin coordinate of the storage bit coordinate system, positioning the center coordinate point of the storage bitmap element according to the storage bit information, drawing the storage bitmap element body and the characteristics according to the length, the width, the storage bit direction and the storage bit state in the storage bit information in proportion, and generating prompt data according to the storage bit information.

3. The system for automatically generating a vector graphics framework according to claim 2, wherein: the graphic view module comprises a reading sub-module of configuration information data, a building sub-module of a graphic frame scene, a building sub-module of vector graphic elements, a response sub-module of user operation, a real-time equipment state data acquisition sub-module and a state refreshing sub-module of each graphic element.

4. The system for automatically generating a vector graphics framework according to claim 2, wherein: the library region primitive module comprises a library region configuration data receiving sub-module, a library region prompt data generating sub-module and a library region primitive coordinate and body drawing sub-module.

5. The system for automatically generating a vector graphics framework according to claim 2, wherein: the partition primitive module comprises a partition configuration data receiving sub-module, a partition prompt data generating sub-module and a partition primitive coordinate and body drawing sub-module.

6. The system for automatically generating a vector graphics framework according to claim 2, wherein: the cross-primitive module comprises a cross-configuration data receiving sub-module, a cross-prompt data generating sub-module and a cross-primitive coordinate and body drawing sub-module.

7. The system for automatically generating a vector graphics framework according to claim 2, wherein: the crown block primitive module comprises a crown block configuration data receiving sub-module, a crown block prompt data generating sub-module, a crown block primitive coordinate and body drawing sub-module combining a span of the crown block, a crown block real-time state data receiving sub-module and a crown block real-time state primitive drawing refreshing sub-module.

8. The system for automatically generating a vector graphics framework according to claim 2, wherein: the storage bitmap meta-module comprises a storage bit configuration data receiving sub-module, a storage bit prompt data generating sub-module, a storage bitmap meta-coordinate and ontology drawing sub-module and a storage bit time state data receiving sub-module.

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