CN116383329A - Data importing method, device, equipment and medium - Google Patents

Abstract

The application discloses a data importing method, a device, equipment and a medium, which relate to the field of digital twinning, and the method is applied to a digital twinning platform and comprises the following steps: receiving a global unique identification code, an equipment number and three-dimensional position information of a target radio frequency identification tag sent by a handheld reader-writer after being paired with the target radio frequency identification tag; the device number and the three-dimensional position information are imported into the handheld reader-writer from the digital twin platform in advance; and importing the globally unique identification code, the equipment number and the three-dimensional position information of the target radio frequency identification tag into a database in the digital twin platform. The invention uses RFID technology, reads and writes the relative position information by the hand-held reader, and then leads the information to the digital twin platform end by the hand-held reader, thus greatly reducing time cost and improving coordinate position accuracy and data leading-in efficiency.

Description

Data importing method, device, equipment and medium

Technical Field

The present invention relates to the field of digital twinning, and in particular, to a data importing method, apparatus, device, and medium.

Background

In the existing digital twin platform equipment visualization application, related information of equipment is generally input manually, and the input 3D coordinate information is generally not accurately measured, only one relative position can be estimated manually, and then equipment position deployment is carried out at a platform end. In this case, the efficiency is very low when the device position information is entered, and for a large-scale scene with mass devices, the efficient device coordinate entry and positioning cannot be performed. Still other related digital twinning platforms do not have the positioning function of the device, and therefore, the 3D coordinate information cannot be accurately acquired because the accurate device position cannot be acquired. Without accurate location information, positioning and monitoring of some devices can also be affected.

From the above, how to avoid the situations that the 3D coordinates cannot be accurately measured and the 3D coordinate information is imported with low efficiency in the process of applying the digital twin platform is a problem to be solved in the field.

Disclosure of Invention

Accordingly, the present invention is directed to a data importing method, device, apparatus and medium, which can utilize a radio frequency identification technology to read and write relevant position information by using a handheld reader, and import the relevant position information to a digital twin platform end by using the handheld reader, so that time cost is greatly reduced, and accuracy of coordinate position and data importing efficiency are improved. The specific scheme is as follows:

in a first aspect, the present application discloses a data importing method, applied to a digital twin platform, including:

receiving a global unique identification code, an equipment number and three-dimensional position information of a target radio frequency identification tag sent by a handheld reader-writer after being paired with the target radio frequency identification tag; the device number and the three-dimensional position information are imported into the handheld reader-writer from the digital twin platform in advance;

and importing the globally unique identification code, the equipment number and the three-dimensional position information of the target radio frequency identification tag into a database in the digital twin platform.

Optionally, the receiving the global unique identification code, the equipment number and the three-dimensional position information of the target radio frequency identification tag sent by the handheld reader-writer after being paired with the target radio frequency identification tag includes:

receiving a globally unique identification code in a target radio frequency identification tag identified by a handheld reader, determining the globally unique identification code of the target radio frequency identification tag and the equipment number and three-dimensional position information of the target radio frequency identification tag currently selected by the handheld reader as a target mapping relation corresponding to the target radio frequency identification tag, and then transmitting the globally unique identification code, the equipment number and the three-dimensional position information of the target radio frequency identification tag by the handheld reader.

Optionally, the receiving the global unique identification code, the equipment number and the three-dimensional position information of the target radio frequency identification tag sent by the handheld reader-writer after being paired with the target radio frequency identification tag includes:

receiving a target file corresponding to a target radio frequency identification tag sent by a handheld reader-writer after being paired with the target radio frequency identification tag; the target file comprises a global unique identification code, a device number and three-dimensional position information of the target radio frequency identification tag;

correspondingly, the importing the globally unique identification code, the equipment number and the three-dimensional position information of the target radio frequency identification tag into a database in the digital twin platform comprises the following steps:

analyzing the target file by using a preset file analysis method to determine the global unique identification code, the equipment number and the three-dimensional position information of the target radio frequency identification tag, and importing the global unique identification code, the equipment number and the three-dimensional position information of the target radio frequency identification tag into a database in the digital twin platform.

Optionally, the receiving the global unique identification code, the equipment number and the three-dimensional position information of the target radio frequency identification tag sent by the handheld reader-writer after being paired with the target radio frequency identification tag includes:

after the handheld reader-writer is paired with the target radio frequency identification tag by utilizing a local equipment read-write module, the global unique identification code, the equipment number and the three-dimensional position information of the target radio frequency identification tag, which are sent by utilizing a local transmission module configured in advance based on a remote radio technology, are received.

In a second aspect, the present application discloses a data importing method, applied to a handheld reader, including:

after the digital twin platform is paired with a target radio frequency identification tag, the global unique identification code, the equipment number and the three-dimensional position information of the target radio frequency identification tag are sent to the digital twin platform, so that the digital twin platform can import the global unique identification code, the equipment number and the three-dimensional position information into a database in the digital twin platform; the equipment number and the three-dimensional position information are imported into the handheld reader-writer from the digital twin platform in advance.

Optionally, the data importing method further includes:

and when a first pairing instruction for carrying out tag pairing on the single radio frequency identification tag is received, determining a target radio frequency identification tag in the first pairing instruction, and executing the step of transmitting a global unique identification code, a device number and three-dimensional position information of the target radio frequency identification tag to a digital twin platform after the target radio frequency identification tag is paired.

Optionally, the data importing method further includes:

when a second pairing instruction for carrying out label pairing on the batch radio frequency identification labels is received, determining a first radio frequency identification label in the second pairing instruction as a current target radio frequency identification label, and triggering a step of sending a global unique identification code, a device number and three-dimensional position information of the target radio frequency identification label to a digital twin platform after the target radio frequency identification label is paired;

reading the end bit of the global unique identification code of the current target radio frequency identification tag, generating a prompt signal for representing the completion of the pairing of the current target radio frequency identification tag, determining the next radio frequency identification tag in the second pairing instruction as the current target radio frequency identification tag, triggering the step of transmitting the global unique identification code, the equipment number and the three-dimensional position information of the target radio frequency identification tag to a digital twin platform after the current target radio frequency identification tag is paired, and jumping to the step of reading the end bit of the global unique identification code of the current target radio frequency identification tag until the next radio frequency identification tag does not exist in the second pairing instruction.

In a third aspect, the present application discloses a data importing apparatus, applied to a digital twin platform, including:

the data receiving module is used for receiving the global unique identification code, the equipment number and the three-dimensional position information of the target radio frequency identification tag, which are sent by the handheld reader-writer after being paired with the target radio frequency identification tag; the device number and the three-dimensional position information are imported into the handheld reader-writer from the digital twin platform in advance;

the data importing module is used for importing the globally unique identification code, the equipment number and the three-dimensional position information of the target radio frequency identification tag into a database in the digital twin platform.

In a fourth aspect, the present application discloses an electronic device comprising:

a memory for storing a computer program;

and a processor for executing the computer program to implement the aforementioned data importing method.

In a fifth aspect, the present application discloses a computer storage medium for storing a computer program; wherein the computer program when executed by a processor implements the steps of the previously disclosed data import method.

The digital twin platform receives a global unique identification code, an equipment number and three-dimensional position information of a target radio frequency identification tag, which are sent by a handheld reader-writer after being paired with the target radio frequency identification tag; the device number and the three-dimensional position information are imported into the handheld reader-writer from the digital twin platform in advance; and importing the globally unique identification code, the equipment number and the three-dimensional position information of the target radio frequency identification tag into a database in the digital twin platform. In this way, the invention determines the global unique identification code from the target radio frequency identification tag by the pairing mode of the handheld reader-writer and the radio frequency identification tag, and combines the equipment number and the three-dimensional position information of the target radio frequency identification tag in the handheld reader-writer to send to the digital twin platform, thereby completing the writing of the position information by the data twin platform.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings that are required to be used in the embodiments or the description of the prior art will be briefly described below, and it is obvious that the drawings in the following description are only embodiments of the present invention, and that other drawings can be obtained according to the provided drawings without inventive effort for a person skilled in the art.

FIG. 1 is a flow chart of a data importing method provided in the present application;

FIG. 2 is a flowchart of a specific data importing method provided in the present application;

FIG. 3 is a schematic diagram of a data importing apparatus according to the present application;

fig. 4 is a block diagram of an electronic device provided in the present application.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

In the prior art, the situation that 3D coordinates cannot be accurately measured and 3D coordinate information is low in importing efficiency can occur in the process of applying the digital twin platform. In the application, the radio frequency identification technology is utilized, the relative position information is read and written through the handheld reader-writer, and then the relative position information is imported to the digital twin platform end through the handheld reader-writer, so that the time cost is greatly reduced, the coordinate position accuracy and the data importing efficiency are improved, and meanwhile, the functions and the diversity of the digital twin platform are enriched.

The embodiment of the invention discloses a data importing method which is applied to a digital twin platform, and is described with reference to fig. 1, and the method comprises the following steps:

step S11: and receiving the global unique identification code, the equipment number and the three-dimensional position information of the target radio frequency identification tag, which are sent by the handheld reader-writer after being paired with the target radio frequency identification tag.

The device number and the three-dimensional position information are imported into the handheld reader-writer from the digital twin platform in advance.

It will be appreciated that the target radio frequency identification tag is a tag device constructed using RFID (i.e. Radio Frequency Identification, radio frequency identification) technology, preferably a passive RFID tag. The handheld reader-writer can read and write the radio frequency identification tag. In this embodiment, the handheld reader-writer and the digital twin platform have previously set up a communication link, and both parties may transmit data through the communication link. Specifically, after the handheld reader-writer is paired with the target radio frequency identification tag, the handheld reader-writer can send a global unique identification code (i.e. TID), a device number and three-dimensional position information of the target radio frequency identification tag to the digital twin platform. That is, after the handheld reader-writer is paired with the target radio frequency identification tag, the handheld reader-writer can send the global unique identification code, the equipment number and the three-dimensional position information of the target radio frequency identification tag to the digital twin platform based on the communication link.

In this embodiment, before the receiving handheld reader-writer matches the global unique identifier, the device number, and the three-dimensional position information of the target radio frequency identification tag, the receiving handheld reader-writer may further include: acquiring equipment numbers and three-dimensional position information of all target radio frequency identification tags through a preset data receiving interface; and transmitting the equipment numbers and the three-dimensional position information of all the target radio frequency identification tags to a handheld reader-writer connected with the current digital twin platform. It can be understood that in this embodiment, the device number and the three-dimensional position information of all the radio frequency identification tags are written in advance in the digital twin platform, where the device number is a number that is set for each tag in a customized manner by the digital twin platform for marking the identity of each radio frequency identification tag, and the three-dimensional position information is a 3D position coordinate of each tag corresponding to a specific 3D scene.

In addition, it can be understood that the globally unique identification code of the radio frequency identification tag is an identification code of each radio frequency identification tag, when the handheld reader-writer is paired with the target radio frequency identification tag, the globally unique identification code of the radio frequency identification tag can be identified, and after pairing, the globally unique identification code, the equipment number and the three-dimensional position information of the target radio frequency identification tag are sent to the digital twin platform.

In specific implementation, the handheld reader-writer needs to import the equipment numbers and the three-dimensional position information of all the radio frequency identification tags in advance, so that the handheld reader-writer is utilized to import the equipment numbers and the three-dimensional position information into the corresponding radio frequency identification tags respectively. Before the method, the device numbers and the three-dimensional position information of all the radio frequency identification tags in the digital twin platform can be imported into the handheld reader-writer. That is, the device numbers and the three-dimensional position information of all the radio frequency identification tags in the handheld reader-writer are imported from the digital twin platform. In other specific embodiments, the handheld reader may also receive the device number and the three-dimensional position information of the radio frequency identification tag sent by other external platforms or external devices, where the device number and the three-dimensional position information of the radio frequency identification tag stored in the handheld reader are required to be consistent with corresponding data in the digital twin platform.

In this embodiment, the receiving the global unique identification code, the device number and the three-dimensional position information of the target radio frequency identification tag sent by the handheld reader-writer after being paired with the target radio frequency identification tag may include: receiving a globally unique identification code in a target radio frequency identification tag identified by a handheld reader, determining the globally unique identification code of the target radio frequency identification tag and the equipment number and three-dimensional position information of the target radio frequency identification tag currently selected by the handheld reader as a target mapping relation corresponding to the target radio frequency identification tag, and then transmitting the globally unique identification code, the equipment number and the three-dimensional position information of the target radio frequency identification tag by the handheld reader. That is, in this embodiment, the handheld reader-writer may be paired with the target radio frequency identification tag, and in a specific pairing process, the handheld reader-writer may identify a globally unique identification code in the target radio frequency identification tag, and determine the globally unique identification code of the target radio frequency identification tag and the device number and the three-dimensional position information of the target radio frequency identification tag currently selected by the handheld reader-writer as a target mapping relationship corresponding to the target radio frequency identification tag. And then the handheld reader-writer can send the global unique identification code, the equipment number and the three-dimensional position information of the target radio frequency identification tag to the digital twin platform.

In this embodiment, the receiving the global unique identification code, the device number and the three-dimensional position information of the target radio frequency identification tag sent by the handheld reader-writer after being paired with the target radio frequency identification tag may include: receiving a target file corresponding to a target radio frequency identification tag sent by a handheld reader-writer after being paired with the target radio frequency identification tag; the target file comprises a global unique identification code, a device number and three-dimensional position information of the target radio frequency identification tag; correspondingly, the importing the globally unique identification code, the equipment number and the three-dimensional position information of the target radio frequency identification tag into a database in the digital twin platform comprises the following steps: analyzing the target file by using a preset file analysis method to determine the global unique identification code, the equipment number and the three-dimensional position information of the target radio frequency identification tag, and importing the global unique identification code, the equipment number and the three-dimensional position information of the target radio frequency identification tag into a database in the digital twin platform. That is, in this embodiment, after the handheld reader-writer is paired with the target radio frequency identification tag, a target file is generated based on the global unique identification code of the target radio frequency identification tag, the device number and the three-dimensional position information, and in a preferred embodiment, the target file is a JSON (i.e. JavaScript Object Notation, JS object profile) file, and after the handheld reader-writer sends the JSON file to the digital twin platform, the digital twin platform analyzes the file to obtain the global unique identification code of the target radio frequency identification tag, the device number and the three-dimensional position information, so as to perform subsequent data import.

In this embodiment, the receiving the global unique identification code, the device number and the three-dimensional position information of the target radio frequency identification tag sent by the handheld reader-writer after being paired with the target radio frequency identification tag may include: after the handheld reader-writer is paired with the target radio frequency identification tag by utilizing a local equipment read-write module, the global unique identification code, the equipment number and the three-dimensional position information of the target radio frequency identification tag, which are sent by utilizing a local transmission module configured in advance based on a remote radio technology, are received.

In a specific embodiment, the handheld reader mainly comprises two modules, wherein the first module is a device read-write module and is used for pairing with a target radio frequency identification tag; the second module is a transmission module, and the transmission module is constructed based on Long Range Radio (LoRa) technology and is used for transmitting the globally unique identification code, the equipment number and the three-dimensional position information of the target Radio frequency identification tag to the digital twin platform.

Step S12: and importing the globally unique identification code, the equipment number and the three-dimensional position information of the target radio frequency identification tag into a database in the digital twin platform.

In this embodiment, the digital twin platform obtains the globally unique identification code of the target rfid tag, the device number, and the three-dimensional location information, so as to perform subsequent data import.

The digital twin platform in the embodiment receives the global unique identification code, the equipment number and the three-dimensional position information of the target radio frequency identification tag, which are sent by the handheld reader-writer after being paired with the target radio frequency identification tag; the device number and the three-dimensional position information are imported into the handheld reader-writer from the digital twin platform in advance; and importing the globally unique identification code, the equipment number and the three-dimensional position information of the target radio frequency identification tag into a database in the digital twin platform. In this way, the invention determines the global unique identification code from the target radio frequency identification tag by the pairing mode of the handheld reader-writer and the radio frequency identification tag, and combines the equipment number and the three-dimensional position information of the target radio frequency identification tag in the handheld reader-writer to send to the digital twin platform, thereby completing the writing of the position information by the data twin platform.

Fig. 2 is a schematic diagram of a specific data importing method applied to a handheld reader according to an embodiment of the present application. Referring to fig. 2, the method includes:

step S21: after the digital twin platform is paired with a target radio frequency identification tag, the global unique identification code, the equipment number and the three-dimensional position information of the target radio frequency identification tag are sent to the digital twin platform, so that the digital twin platform can import the global unique identification code, the equipment number and the three-dimensional position information into a database in the digital twin platform; the equipment number and the three-dimensional position information are imported into the handheld reader-writer from the digital twin platform in advance.

In this embodiment, the data importing method may further include: and when a first pairing instruction for carrying out tag pairing on the single radio frequency identification tag is received, determining a target radio frequency identification tag in the first pairing instruction, and executing the step of transmitting a global unique identification code, a device number and three-dimensional position information of the target radio frequency identification tag to a digital twin platform after the target radio frequency identification tag is paired.

In this embodiment, the handheld reader may include two tag matching modes. When a small number of RFID tags are matched, a single tag matching mode can be selected; when a batch of RFID tag matches are faced, a batch tag matching mode may be selected.

In a first specific embodiment, when the handheld reader receives a first pairing instruction for performing tag pairing on a single radio frequency identification tag, the handheld reader determines that the handheld reader is in a single tag matching mode, the first pairing instruction is only specific to one target radio frequency identification tag, and after the handheld reader is paired with the target radio frequency identification tag, the global unique identification code, the equipment number and the three-dimensional position information of the target radio frequency identification tag are sent to the digital twin platform, so that the handheld reader is considered to be the first pairing instruction.

In a specific implementation scenario, a user may select a target radio frequency identification tag in the handheld reader-writer, which is used to send a first pairing instruction to the handheld reader-writer, and then the user may pair with the target radio frequency identification tag by holding the handheld reader-writer in the hand.

In this embodiment, the data importing method may further include: when a second pairing instruction for carrying out label pairing on the batch radio frequency identification labels is received, determining a first radio frequency identification label in the second pairing instruction as a current target radio frequency identification label, and triggering a step of sending a global unique identification code, a device number and three-dimensional position information of the target radio frequency identification label to a digital twin platform after the target radio frequency identification label is paired; reading the end bit of the global unique identification code of the current target radio frequency identification tag, generating a prompt signal for representing the completion of the pairing of the current target radio frequency identification tag, determining the next radio frequency identification tag in the second pairing instruction as the current target radio frequency identification tag, triggering the step of transmitting the global unique identification code, the equipment number and the three-dimensional position information of the target radio frequency identification tag to a digital twin platform after the current target radio frequency identification tag is paired, and jumping to the step of reading the end bit of the global unique identification code of the current target radio frequency identification tag until the next radio frequency identification tag does not exist in the second pairing instruction.

In a second specific embodiment, when the handheld reader receives a second pairing instruction for performing tag pairing on a plurality of radio frequency identification tags, the handheld reader determines that the handheld reader is in a batch tag matching mode, the second pairing instruction is specific to a plurality of radio frequency identification tags, the handheld reader firstly determines a first tag in sequence from the second pairing instruction as a current target radio frequency identification tag, after the handheld reader is paired with the target radio frequency identification tag, the global unique identification code, the equipment number and the three-dimensional position information of the target radio frequency identification tag are sent to a digital twin platform, then the ending bit of the global unique identification code of the current target radio frequency identification tag is read, a prompt signal for representing that the pairing of the current tag is completed is generated, and the pairing process of the current target radio frequency identification tag is completed. And then determining the next radio frequency identification tag in the second pairing instruction as the current target radio frequency identification tag, and repeatedly executing the tag pairing process, the data sending process and the end bit reading and signal prompting process until all radio frequency identification tags corresponding to the second pairing instruction are processed, and then, considering that the execution of the first pairing instruction is completed.

It can be understood that in the second embodiment, after each data importing process is executed, the handheld reader processes and reads the end bit of the globally unique identification code of the current target rfid tag, and generates a prompt signal for representing that the current tag pairing is completed, where the prompt signal is used to remind a user to map and pair the next device, so that batch pairing of the rfid tags is facilitated.

In a specific implementation scenario, a user can select a plurality of target radio frequency identification tags in the handheld reader-writer and send a second pairing instruction to the handheld reader-writer, and then the user can hold the handheld reader-writer to pair the radio frequency identification tags in sequence respectively, wherein the handheld reader-writer can send a prompt after the data importing process for each tag is executed, and after receiving the prompt, the user can hold the handheld reader-writer to pair the next tag, and finally batch pairing of the tags is completed.

In addition, it can be understood that, in this embodiment, the handheld reader-writer also imports the device number and the three-dimensional position information stored in the reader-writer into the radio frequency identification tag when the handheld reader-writer is matched with the radio frequency identification tag each time, so as to facilitate the subsequent checking when necessary.

In this embodiment, after a handheld reader-writer is paired with a target radio frequency identification tag, a global unique identification code, a device number and three-dimensional position information of the target radio frequency identification tag are sent to a digital twin platform, so that the digital twin platform imports the global unique identification code, the device number and the three-dimensional position information into a database in the digital twin platform; the equipment number and the three-dimensional position information are imported into the handheld reader-writer from the digital twin platform in advance. Two tag matching modes are proposed in this embodiment. When a small number of RFID tags are matched, a single tag matching mode can be selected; when a batch of RFID tag matches are faced, a batch tag matching mode may be selected.

Referring to fig. 3, an embodiment of the present application discloses a data importing apparatus, which is applied to a digital twin platform, and may specifically include:

the data receiving module 11 is used for receiving the global unique identification code, the equipment number and the three-dimensional position information of the target radio frequency identification tag, which are sent by the handheld reader-writer after being paired with the target radio frequency identification tag; the device number and the three-dimensional position information are imported into the handheld reader-writer from the digital twin platform in advance;

the data importing module 12 is configured to import the globally unique identification code, the device number, and the three-dimensional location information of the target rfid tag into a database in the digital twin platform.

The digital twin platform receives a global unique identification code, an equipment number and three-dimensional position information of a target radio frequency identification tag sent by a handheld reader-writer after being paired with the target radio frequency identification tag; the device number and the three-dimensional position information are imported into the handheld reader-writer from the digital twin platform in advance; and importing the globally unique identification code, the equipment number and the three-dimensional position information of the target radio frequency identification tag into a database in the digital twin platform. In this way, the invention determines the global unique identification code from the target radio frequency identification tag by the pairing mode of the handheld reader-writer and the radio frequency identification tag, and combines the equipment number and the three-dimensional position information of the target radio frequency identification tag in the handheld reader-writer to send to the digital twin platform, thereby completing the writing of the position information by the data twin platform.

Further, the embodiment of the present application further discloses an electronic device, and fig. 4 is a block diagram of an electronic device 20 according to an exemplary embodiment, where the content of the figure is not to be considered as any limitation on the scope of use of the present application.

Fig. 4 is a schematic structural diagram of an electronic device 20 according to an embodiment of the present application. The electronic device 20 may specifically include: at least one processor 21, at least one memory 22, a power supply 23, a display screen 24, an input-output interface 25, a communication interface 26, and a communication bus 27. Wherein the memory 22 is configured to store a computer program that is loaded and executed by the processor 21 to implement the relevant steps of the data import method disclosed in any of the foregoing embodiments. In addition, the electronic device 20 in the present embodiment may be specifically an electronic computer.

In this embodiment, the power supply 23 is configured to provide an operating voltage for each hardware device on the electronic device 20; the communication interface 26 can create a data transmission channel between the electronic device 20 and an external device, and the communication protocol to be followed is any communication protocol applicable to the technical solution of the present application, which is not specifically limited herein; the input/output interface 25 is used for acquiring external input data or outputting external output data, and the specific interface type thereof may be selected according to the specific application requirement, which is not limited herein.

The memory 22 may be a carrier for storing resources, such as a read-only memory, a random access memory, a magnetic disk, or an optical disk, and the resources stored thereon may include an operating system 221, a computer program 222, virtual machine data 223, and the virtual machine data 223 may include various data. The storage means may be a temporary storage or a permanent storage.

The operating system 221 is used for managing and controlling various hardware devices on the electronic device 20 and computer programs 222, which may be Windows Server, netware, unix, linux, etc. The computer program 222 may further include a computer program that can be used to perform other specific tasks in addition to the computer program that can be used to perform the data import method performed by the electronic device 20 disclosed in any of the previous embodiments.

Further, the present application also discloses a computer readable storage medium, where the computer readable storage medium includes random access Memory (Random Access Memory, RAM), memory, read-Only Memory (ROM), electrically programmable ROM, electrically erasable programmable ROM, registers, hard disk, magnetic disk, or any other form of storage medium known in the art. Wherein the computer program, when executed by a processor, implements the data import method disclosed previously. For specific steps of the method, reference may be made to the corresponding contents disclosed in the foregoing embodiments, and no further description is given here.

In this specification, each embodiment is described in a progressive manner, and each embodiment is mainly described in a different point from other embodiments, so that the same or similar parts between the embodiments are referred to each other. For the device disclosed in the embodiment, since it corresponds to the method disclosed in the embodiment, the description is relatively simple, and the relevant points refer to the description of the method section. Those of skill would further appreciate that the various illustrative elements and algorithm steps described in connection with the embodiments disclosed herein may be implemented as electronic hardware, computer software, or combinations of both, and that the various illustrative elements and steps are described above generally in terms of functionality in order to clearly illustrate the interchangeability of hardware and software. Whether such functionality is implemented as hardware or software depends upon the particular application and design constraints imposed on the solution. Skilled artisans may implement the described functionality in varying ways for each particular application, but such implementation decisions should not be interpreted as causing a departure from the scope of the present application.

The steps of a method or algorithm described in connection with the embodiments disclosed herein may be embodied directly in hardware, in a software module executed by a processor, or in a combination of the two. The software modules may be disposed in Random Access Memory (RAM), memory, read Only Memory (ROM), electrically programmable ROM, electrically erasable programmable ROM, registers, hard disk, a removable disk, a CD-ROM, or any other form of storage medium known in the art.

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

The above description of the data importing method, device, apparatus and storage medium provided by the present invention applies specific examples to illustrate the principles and embodiments of the present invention, and the above examples are only used to help understand the method and core idea of the present invention; meanwhile, as those skilled in the art will have variations in the specific embodiments and application scope in accordance with the ideas of the present invention, the present description should not be construed as limiting the present invention in view of the above.

Claims (10)

1. A data importing method, applied to a digital twin platform, comprising:

receiving a global unique identification code, an equipment number and three-dimensional position information of a target radio frequency identification tag sent by a handheld reader-writer after being paired with the target radio frequency identification tag; the device number and the three-dimensional position information are imported into the handheld reader-writer from the digital twin platform in advance;

and importing the globally unique identification code, the equipment number and the three-dimensional position information of the target radio frequency identification tag into a database in the digital twin platform.

2. The data importing method according to claim 1, wherein the receiving unique global identification code, the device number and the three-dimensional location information of the target radio frequency identification tag, which are sent by the receiving handheld reader-writer after being paired with the target radio frequency identification tag, includes:

receiving a globally unique identification code in a target radio frequency identification tag identified by a handheld reader, determining the globally unique identification code of the target radio frequency identification tag and the equipment number and three-dimensional position information of the target radio frequency identification tag currently selected by the handheld reader as a target mapping relation corresponding to the target radio frequency identification tag, and then transmitting the globally unique identification code, the equipment number and the three-dimensional position information of the target radio frequency identification tag by the handheld reader.

3. The data importing method according to claim 1, wherein the receiving unique global identification code, the device number and the three-dimensional location information of the target radio frequency identification tag, which are sent by the receiving handheld reader-writer after being paired with the target radio frequency identification tag, includes:

receiving a target file corresponding to a target radio frequency identification tag sent by a handheld reader-writer after being paired with the target radio frequency identification tag; the target file comprises a global unique identification code, a device number and three-dimensional position information of the target radio frequency identification tag;

correspondingly, the importing the globally unique identification code, the equipment number and the three-dimensional position information of the target radio frequency identification tag into a database in the digital twin platform comprises the following steps:

analyzing the target file by using a preset file analysis method to determine the global unique identification code, the equipment number and the three-dimensional position information of the target radio frequency identification tag, and importing the global unique identification code, the equipment number and the three-dimensional position information of the target radio frequency identification tag into a database in the digital twin platform.

4. A data importing method according to any one of claims 1 to 3, wherein the receiving unique global identification code, device number and three-dimensional location information of the target radio frequency identification tag sent by the receiving handheld reader-writer after pairing with the target radio frequency identification tag, includes:

after the handheld reader-writer is paired with the target radio frequency identification tag by utilizing a local equipment read-write module, the global unique identification code, the equipment number and the three-dimensional position information of the target radio frequency identification tag, which are sent by utilizing a local transmission module configured in advance based on a remote radio technology, are received.

5. A data importing method, which is applied to a handheld reader, comprising:

after the digital twin platform is paired with a target radio frequency identification tag, the global unique identification code, the equipment number and the three-dimensional position information of the target radio frequency identification tag are sent to the digital twin platform, so that the digital twin platform can import the global unique identification code, the equipment number and the three-dimensional position information into a database in the digital twin platform; the equipment number and the three-dimensional position information are imported into the handheld reader-writer from the digital twin platform in advance.

6. The data import method of claim 5, further comprising:

and when a first pairing instruction for carrying out tag pairing on the single radio frequency identification tag is received, determining a target radio frequency identification tag in the first pairing instruction, and executing the step of transmitting a global unique identification code, a device number and three-dimensional position information of the target radio frequency identification tag to a digital twin platform after the target radio frequency identification tag is paired.

7. The data import method of claim 5, further comprising:

when a second pairing instruction for carrying out label pairing on the batch radio frequency identification labels is received, determining a first radio frequency identification label in the second pairing instruction as a current target radio frequency identification label, and triggering a step of sending a global unique identification code, a device number and three-dimensional position information of the target radio frequency identification label to a digital twin platform after the target radio frequency identification label is paired;

reading the end bit of the global unique identification code of the current target radio frequency identification tag, generating a prompt signal for representing the completion of the pairing of the current target radio frequency identification tag, determining the next radio frequency identification tag in the second pairing instruction as the current target radio frequency identification tag, triggering the step of transmitting the global unique identification code, the equipment number and the three-dimensional position information of the target radio frequency identification tag to a digital twin platform after the current target radio frequency identification tag is paired, and jumping to the step of reading the end bit of the global unique identification code of the current target radio frequency identification tag until the next radio frequency identification tag does not exist in the second pairing instruction.

8. A data importing apparatus, applied to a digital twin platform, comprising:

the data receiving module is used for receiving the global unique identification code, the equipment number and the three-dimensional position information of the target radio frequency identification tag, which are sent by the handheld reader-writer after being paired with the target radio frequency identification tag; the device number and the three-dimensional position information are imported into the handheld reader-writer from the digital twin platform in advance;

the data importing module is used for importing the globally unique identification code, the equipment number and the three-dimensional position information of the target radio frequency identification tag into a database in the digital twin platform.

9. An electronic device comprising a processor and a memory; wherein the processor, when executing the computer program stored in the memory, implements the data import method according to any one of claims 1 to 7.

10. A computer-readable storage medium storing a computer program; wherein the computer program when executed by a processor implements the data import method according to any of claims 1 to 7.

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