CN215182409U - Control signal transparent transmission system based on 5G - Google Patents

Abstract

The utility model provides a control signal passes system thoroughly based on 5G, should pass system thoroughly and include management platform, first processing module and pair the second processing module who sets up with first processing module. The management platform is in communication connection with the first processing module and the second processing module 5G respectively. The first processing module is connected with the signal source end through a first preset serial port and used for converting a control signal sent by the signal source end into a first network signal and transmitting the first network signal to the management platform, and the second processing module is connected with the signal receiving end through a second preset serial port and used for reducing a second network signal transferred by the management platform into a control signal and transmitting the control signal to the signal receiving end, so that the control signal is transmitted from the signal source end to the signal receiving end. The transmission distance and the transmission range of the control signal are not required, the original application scene is not required to be subjected to line transformation, the application range of the transparent transmission system is widened, the transmission delay is effectively reduced, the transmission rate is increased, and the excellent transmission effect is ensured.

Description

Control signal transparent transmission system based on 5G

Technical Field

The utility model relates to a data transmission technical field especially relates to a control signal passes system thoroughly based on 5G.

Background

In some industrial application scenarios such as buildings, factories, parks, and the like, there is often a need for transmitting control signals over a very long distance, for example, control signals for controlling an AGV (automatic Guided Vehicle) to move need to be transmitted within a specified moving range of the factory. At present, in order to meet the transmission requirements, firstly, cables are adopted to transmit control signals, and secondly, wireless modes such as LORA, WI-FI and Bluetooth are adopted to transmit the control signals.

However, these transmission methods have corresponding technical defects in actual working conditions. For example, a cable transmission mode has certain requirements on transmission distance and transmission range, and corresponding line modification needs to be performed on an application scene along with continuous expansion of the application scene area, otherwise, the transmission requirement cannot be met. The wireless transmission mode has the problems of high transmission delay, slow transmission rate, incapability of effectively covering the transmission range and the like, so that the transmission effect is poor.

It can be seen that a solution is needed to effectively solve the problem of signal transmission over very long distances.

SUMMERY OF THE UTILITY MODEL

The utility model provides a control signal passes system thoroughly based on 5G for solve current transmission mode and can't satisfy control signal at the transmission demand of extra long distance and technical problem such as transmission effect is not good.

In a first aspect, the utility model provides a control signal passes system thoroughly based on 5G, include: the management platform is in communication connection with the first processing module and the second processing module through 5G respectively;

the first processing module is connected with the signal source end through a first preset serial port and used for converting the control signal sent by the signal source end into a first network signal and transmitting the first network signal to the management platform;

the second processing module is connected with the signal receiving terminal through a second preset serial port and used for reducing a second network signal transferred in the management platform into the control signal and then transmitting the control signal to the signal receiving terminal, and the serial port type of the first preset serial port is the same as that of the second preset serial port.

In a possible design, the first processing module is further configured to perform a packing process on the first network signal according to a preset time interval to obtain the second network signal, so that the management platform transfers the second network signal.

In a possible design, the second processing module is further configured to receive the second network signal transferred by the management platform, and perform unpacking processing on the second network signal according to the preset time interval, so as to restore the unpacked second network signal to the control signal.

In one possible design, the serial port type includes at least one of an RS232 interface, an SPI interface, a LIN interface, a PS/2 interface, and a GPIO interface;

the SPI interface comprises a three-wire SPI interface or a four-wire SPI interface.

In a possible design, when the serial port type includes the RS232 interface and/or the SPI interface, the first processing module acquires the control signal issued by the signal source end using a first preset mode, and the second processing module transmits the control signal to the signal receiving end using the first preset mode, where the first preset mode includes an immediate transmission mode and a buffered transmission mode.

In a possible design, when the serial port type includes the GPIO interface, the first processing module acquires the control signal sent by the signal source end in a second preset mode, the second processing module transmits the control signal to the signal receiving end in the second preset mode, and the second preset mode includes at least one of an interrupt trigger mode, a high-level trigger mode, and a low-level trigger mode.

In a possible design, the management platform is configured with a preset software for transferring the second network signal through the preset software and a preset protocol;

the preset software comprises a Netty service framework, and the preset protocol comprises a TCP/IP protocol.

In one possible design, the management platform includes a user management interface;

the user management interface comprises an account management control, and the account management control is used for carrying out user authority management on the first processing module and the second processing module.

In one possible design, the management platform further includes a device management interface;

the equipment management interface comprises an equipment management control, and the equipment management control is used for executing at least one operation of monitoring equipment, generating equipment identification and generating a user account according to a preset operation;

the preset operation comprises one of an adding operation, an editing operation and a deleting operation;

the device identifier is used for identifying the first processing module and the second processing module which are respectively connected with the signal source end and the signal receiving end through the first preset serial port and the second preset serial port;

the user account is used for the account management control to manage the user authority of the first processing module and the second processing module.

In one possible design, the device management interface further includes a device binding control;

the device binding control is used for binding the respective IP addresses of the first processing module and the second processing module so as to enable the first processing module and the second processing module to be paired and arranged;

the device binding control is further used for acquiring the serial port type.

In one possible design, the first and second processing modules include one of a SIM7020 module, a raspberry pi module, and a CAT1 module.

The utility model provides a control signal passes system thoroughly based on 5G, should pass system thoroughly and include management platform, first processing module and pair the second processing module who sets up with first processing module. The management platform is in 5G communication connection with the first processing module and the second processing module respectively. The first processing module is connected with the signal source end through a first preset serial port and used for converting a control signal transmitted by the signal source end into a first network signal and transmitting the first network signal to the management platform, the second processing module is connected with the signal receiving end through a second preset serial port and used for reducing a second network signal transferred by the management platform into a control signal and transmitting the control signal to the signal receiving end, transparent transmission of the control signal from the signal source end to the signal receiving end is achieved, no requirement is made on the distance between the signal source end and the signal receiving end and the transmission range, line transformation is not needed for the original application scene, and the application range of the transparent transmission system is widened. And the first processing module, the second processing module and the management platform are connected through 5G communication, so that the transmission delay is effectively reduced, the transmission rate is improved, and the excellent transmission effect is ensured.

Drawings

Fig. 1 is a schematic structural diagram of a transparent transmission system according to an embodiment of the present invention;

fig. 2 is a schematic structural diagram of another transparent transmission system provided in an embodiment of the present invention;

fig. 3 is a schematic structural diagram of another transparent transmission system according to an embodiment of the present invention;

fig. 4 is a schematic structural diagram of another transparent transmission system according to an embodiment of the present invention.

Reference numerals:

10: a transparent transmission system; 20: a signal source terminal; 30: a signal receiving end; 11: a management platform;

12: a first processing module; 13: a second processing module; 14: a first preset serial port;

15: a second preset serial port; 101: an RS232 interface; 102: an SPI interface;

103: a GPIO interface; 111: a user management interface; 100: an account management control;

112: an equipment management interface; 200: a device management control; 300: and (5) binding the control by the equipment.

Detailed Description

Reference will now be made in detail to the exemplary embodiments, examples of which are illustrated in the accompanying drawings. When the following description refers to the accompanying drawings, like numbers in different drawings represent the same or similar elements unless otherwise indicated. The embodiments described in the following exemplary embodiments do not represent all embodiments consistent with the present invention. Rather, they are merely examples of methods and apparatus consistent with certain aspects of the invention, as detailed in the appended claims.

The terms "first," "second," "third," "fourth," and the like in the description and in the claims, as well as in the drawings, if any, are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used is interchangeable under appropriate circumstances such that the embodiments of the invention described herein are capable of operation in sequences other than those illustrated or otherwise described herein. Furthermore, the terms "comprises," "comprising," and "having," and any variations thereof, are intended to cover a non-exclusive inclusion, such that a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements expressly listed, but may include other steps or elements not expressly listed or inherent to such process, method, article, or apparatus.

In some application scenarios, control signals are often required to be transmitted over a long distance, one of the prior art is to transmit the control signals by using cables, and the other is to transmit the control signals by using wireless methods such as LORA, WI-FI, bluetooth, and the like. However, these transmission methods have certain technical defects in the operation of actual working conditions. For example, a cable is used for transmitting a control signal, so that certain requirements are imposed on the transmission distance and the transmission range, when the area of an application scene is continuously enlarged, the original line needs to be correspondingly modified to adapt the transmission distance and the transmission range, otherwise, the transmission requirement of the control signal cannot be met. Due to the defects of the wireless signals, the transmission method has the problems of high transmission delay, low transmission rate, incapability of realizing effective coverage of a transmission range and the like, so that the transmission effect of the control signals is poor.

To the above-mentioned technical problem that prior art exists, the utility model provides a control signal passes system thoroughly based on 5G. The inventive concept of the utility model lies in: the first processing module is connected with the signal source end through a first preset serial port, the second processing module is connected with the signal receiving end through a second preset serial port, the management platform is in 5G communication connection with the first processing module and the second processing module respectively, the first processing module converts a control signal sent by the signal source end into a first network signal and transmits the first network signal to the management platform, the second network signal is transferred to the second terminal device through the management platform, and the second terminal device restores the second network signal into the control signal and then transmits the control signal to the signal receiving end, so that the control signal is transmitted between the signal source end and the signal receiving end. The first terminal device and the second terminal device are respectively connected with the signal source end and the signal receiving end through the first preset serial port and the second preset serial port, so that the signal source end and the signal receiving end do not need to adopt a cable in the prior art to transmit control signals, and further, the effective transmission in an infinite range can be met without any requirement on transmission distance and transmission range. And the first terminal equipment, the second terminal equipment and the management platform are connected through 5G communication, so that the problems of high transmission delay, slow transmission rate and the like in the prior art can be effectively solved, and further the excellent transmission effect can be ensured.

The technical solution of the present invention will be described in detail with specific examples. The following several specific embodiments may be combined with each other, and details of the same or similar concepts or processes may not be repeated in some embodiments.

Fig. 1 is a schematic structural diagram of a transparent transmission system according to an embodiment of the present invention. As shown in fig. 1, an embodiment of the present invention provides a control signal pass-through system 10 based on 5G, including: the system comprises a management platform 11, a first processing module 12 and a second processing module 13 which is paired with the first processing module 12.

The management platform 11 is in communication connection with the first processing module 12 and the second processing module 13 via a 5G network, and is configured to transfer the corresponding signal transmitted by the first processing module 12 to the second processing module 13. The first processing module 12 is connected to the signal source terminal 20 via a first predetermined serial port 14, and the second processing module 13 is connected to the signal receiving terminal 30 via a second predetermined serial port 15.

The management platform 11 may be configured as a server or a server cluster to relay the corresponding network signal transmitted by the first processing module 12 to the second processing module 13. For example, the management platform 11 is configured with corresponding preset software, the server of the management platform 11 can relay the second network signal by executing the preset software and a preset protocol, the preset software may include a Netty service framework, and the preset protocol may include a TCP/IP protocol. In an actual working condition, performance parameters such as the specification of the server configured by the management platform 11, the specifically executed software program, and the corresponding protocol may be set according to a specific situation in the actual working condition, and this embodiment is not limited.

The first processing module 12 and the second processing module 13 may be respectively configured as one of a SIM7020 module, a raspberry pi module, and a CAT1 module, where the specifically configured modules of the first processing module 12 and the second processing module 13 may be set according to transmission requirements for control signals in actual conditions, and this embodiment is not limited thereto. In addition, it is understood that the management platform 11 may be deployed at any location, such as a cloud or a console, the first processing module 12 may be deployed at a location where the signal source end 20 is located, and the second processing module 13 may be deployed at a location where the signal receiving end 30 is located.

The signal source terminal 20 issues a control signal, and the issued control signal is used to control the signal receiving terminal 30 to execute the corresponding action indicated by the control signal. For example, the signal receiving end 30 may be some terminals in the internet of things, such as an AGV, a control signal lamp of a factory, various meters of the factory, and the like, which have preset functions. The signal source terminal 20 may be a control device for controlling the signal sink terminal 30 to execute the preset function, wherein the corresponding action indicated by the control signal is determined by the preset function of the signal sink terminal 20, which is not limited in this embodiment.

For example, the first processing module 12 obtains a control signal sent by the signal source terminal 20 through the first preset serial port 14, converts the control signal into a first network signal, and transmits the first network signal to the management platform 11 through the 5G network in a network signal manner. The management platform 11 and the second processing module 13 are connected through a 5G network communication, and the second processing module 13 may receive a second network signal relayed by the management platform 11, restore the second network signal to a control signal originally issued by the signal source terminal 20, and transmit the control signal to the signal receiving terminal 30 through the second preset serial port 15, so as to implement transmission of the control signal from the signal source terminal 20 to the signal receiving terminal 30.

As can be seen from the description of the above embodiment, in the control signal transparent transmission system based on 5G provided by the embodiment of the present invention, the transmission of the control signal from the signal source terminal 20 to the first processing module 12 is via the first preset serial port 14, the transmission from the first processing module 12 to the second processing module 13 via the management platform 11 is via the 5G network, the transmission from the second processing module 13 to the signal receiving terminal 30 is via the second preset serial port 15, and the distance between the signal source terminal 20 and the signal receiving terminal 30 and the position range where the distance and the position range are located do not affect the transmission of the control signal, therefore, the transparent transmission system provided by this embodiment does not make any requirement on the transmission distance and the transmission range between the signal source terminal 20 and the signal receiving terminal 30 during the transmission of the control signal from the signal source terminal 20 to the signal receiving terminal 30, and further does not need to perform line modification on the original application scenario, therefore, the application range of the transparent transmission system can be improved. In addition, the first processing module 12 and the second processing module 13 are connected to the management platform 11 through 5G network communication, so that transmission delay can be effectively reduced, transmission rate can be increased, and excellent transmission effect can be ensured.

It is understood that the management platform 11 and the first processing module 12 and the second processing module 13 may also be connected via a network such as 4G or 6G.

In a possible design, in order to prevent the control failure or poor control effect of the signal receiving terminal 13 by the signal source terminal 12 due to confusion of the control signal in the transmission process, the first processing module 12 may further perform a packing process on the acquired first network signal according to a preset time interval after converting the control signal into the first network signal, so as to obtain a second network signal, and then transmit the second network signal to the management platform 11, so that the management platform 11 transfers the second network signal. Here, the packing process may be understood as an operation of adding corresponding time information to the first network signal.

Correspondingly, the second processing module 13 may receive the second network signal forwarded by the management platform 11, perform unpacking processing on the second network signal according to the same preset time interval, and restore the unpacked second network signal to the control signal issued by the signal source terminal 20. The control signal after the unpacking process includes time information when the signal source terminal 20 issues the control signal.

It should be noted that, in the embodiment of the present invention, the serial port types of the first preset serial port 14 and the second preset serial port 15 are the same. The Serial port type may include at least one of a RS232 Interface, a Serial Peripheral Interface (SPI), a LIN Interface, a PS/2 Interface, a General-purpose input/output (GPIO) Interface, and other General-purpose interfaces. For example, the SPI interface includes a three-wire SPI interface or a four-wire SPI interface, and the SPI interface may be a four-wire interface including one clock signal line (SCLK), one transmission signal line (MOSI), one reception signal line (MISO), and one low-level active slave selection line (NSS), or may be a three-wire interface including the first three wires of the four wires, which is not limited in this embodiment. The RS232 interface may comprise a unidirectional transmit data line TX and a unidirectional receive data line RX. The GPIO interfaces may be set according to actual operating conditions, for example, the GPIO interfaces may include GPIO0 through GPIO3 shown in fig. 2, which is not limited in this embodiment. Fig. 2 is another kind of pass through structural schematic diagram of system that embodiment provided, wherein, include RS232 interface 101 simultaneously with the serial port type of first predetermined serial port 14 in fig. 2, these three kinds of SPI interface 102 and GPIO interface 103, and the serial port type that serial port 15 includes is predetermine to the second includes RS232 interface 101 equally, these three kinds of examples of SPI interface 102 and GPIO interface 103 show, in operating condition, the serial port type of serial port 15 can be carried out selectivity according to actual conditions to first predetermined serial port 14 and the second predetermined serial port 15, for example can confirm the serial port type that corresponds the setting on first processing module 12 and second processing module 13 by the serial port type that signal source end 20 and signal receiving end 30 supported, in order to form corresponding first predetermined serial port 14 and the serial port 15 is predetermine to the second.

The utility model provides a control signal passes system thoroughly based on 5G, should pass system thoroughly and include management platform, first processing module and pair the second processing module who sets up with first processing module. The management platform is in 5G communication connection with the first processing module and the second processing module respectively. The first processing module is connected with the signal source end through a first preset serial port and used for converting a control signal transmitted by the signal source end into a first network signal and transmitting the first network signal to the management platform, the second processing module is connected with the signal receiving end through a second preset serial port and used for reducing a second network signal transferred by the management platform into a control signal and transmitting the control signal to the signal receiving end, transparent transmission of the control signal from the signal source end to the signal receiving end is achieved, no requirement is made on the distance between the signal source end and the signal receiving end and the transmission range, line transformation is not needed for an original application scene, the application range of the transparent transmission system is widened, transmission delay is effectively reduced, transmission rate is increased, and excellent transmission effect is guaranteed.

In one possible design, the first default serial port 14 and the second default serial port 15 may be generally built in the first processing module 12 and the second processing module 13, respectively. Thus, different serial port types have correspondingly different transmission modes.

For example, when the serial port type of the selected first preset serial port 14 or the second preset serial port 15 includes an RS232 interface and/or an SPI interface, the first processing module 12 acquires the control signal issued by the signal source terminal 20 by using the first preset mode. Accordingly, the second processing module 13 transmits the restored control signal to the signal receiving terminal 30 in the first preset mode.

Specifically, the first preset mode may include an immediate transmission mode and a buffered transmission mode. The transmission mode may be that the first processing module 12 transmits a single byte of the control signal immediately after acquiring the single byte of the control signal through the first predetermined interface 14, and correspondingly, the second processing module 13 also transmits the control signal to the signal receiving terminal 30 in the same mode as the first processing module 12. The immediate transmission mode is generally suitable for transmission of control signals with shorter control commands and more time-critical requirements. The buffering transmission mode may be that the first processing module 12 transmits a preset control signal of multiple bytes after acquiring it through the first preset interface 14, or that the first processing module 12 transmits an already acquired byte when it does not receive a new control signal of a byte within a preset time period. Accordingly, the second processing module 13 also transmits the control signal to the signal receiving terminal 30 in the same mode as the first processing module 12. The buffered transmission mode is generally suitable for transmission of control signals where control commands are long and where timeliness is not a requirement. The number of the preset bytes and the preset duration may be set by the management platform 11 according to the transmission rate in the actual working condition or the local network condition, which is not limited in this embodiment. Generally, the transmission rate supported by the serial port type including the RS232 interface 101 may be a common baud rate such as 110, 300, 600, 1200, 2400, 4800, 9600, 14400, 19200, 38400, 57600, or 115200.

Optionally, when the serial port type packet GPIO interface 103 of the first preset serial port 14 or the second preset serial port 15 is used, the first processing module 12 collects the control signal sent by the signal source terminal 20 by using a second preset mode. Correspondingly, the second processing module 13 also transmits the restored control signal to the signal receiving terminal 30 in the second preset mode. The second preset mode comprises at least one of an interrupt trigger mode, a high level trigger mode and a low level trigger mode.

As described in the foregoing embodiments, the management platform 11 may be configured as a server for performing relay of the control signal converted into the corresponding network signal between the first processing module 12 and the second processing module 13. Further, in order to make the utility model provide a control signal based on 5G passes through system possesses stronger suitability and practicality in the thing networking, in a possible design, fig. 3 does the utility model provides a still another kind of structure schematic diagram that passes through system that passes through that provides, as shown in fig. 3, the control signal based on 5G that this embodiment provided passes through management platform 11 in the system 10 and can include user management interface 111, can carry out authority management to first processing module 12 and the second processing module 13 of deploying in signal source end 20 and signal receiving end 30 through user management interface 111. For example, the user management interface 111 may be provided with an account management control 100, and a corresponding user account may be entered through the account management control 100 to perform corresponding user authority management on information related to identity authentication, account security, and the like of the first processing module 12 and the second processing module 13, so that transmission of the control signal between the signal source end 20 and the signal receiving end 30 has certain security and confidentiality.

Further, fig. 4 is a schematic structural diagram of another transparent transmission system provided in the embodiment of the present invention. As shown in fig. 4, the management platform 11 in the control signal transparent transmission system 10 based on 5G provided in the embodiment of the present invention may further include: a device management interface 112.

The device management interface 112 is configured to perform device management on the first processing module 12 and the second processing module 13 corresponding to the signal source 20 and the signal sink 30, respectively.

For example, the device management interface 112 may be provided with a device management control 200 to perform at least one operation of, for example, supervising the device according to a preset operation, generating a device identifier, and generating a user account through the device management control 200.

The preset operation may include one of an adding operation, an editing operation, and a deleting operation performed on the first processing module 12 and the second processing module 13 associated with the signal source 20 and the signal sink 30.

The generating of the device identifier refers to generating unique device identifiers for the first processing module 12 and the second processing module 13 associated with the signal source 20 and the signal receiving terminal 30, so as to uniquely identify the first processing module 12 and the second processing module 13 connected to the signal source 20 and the signal receiving terminal 30 via the first preset serial port 14 and the second preset serial port 15, respectively, through the device identifiers.

The generation of the user account refers to the generation of corresponding account information which can be input into the account management control for an operator, so that the account management control is utilized to carry out user authority management on the first processing module and the second processing module according to the user account.

Continuing with FIG. 4, optionally, device management interface 112 may also include a device binding control 300. The device binding control 300 is configured to bind respective IPs of the first processing module 12 and the second processing module 13, so that the first processing module 12 and the second processing module 13 are paired. In addition, a first processing module 12 and a second processing module 13 can form a unique binding only, so as to use the respective IP addresses of the first processing module 12 and the second processing module 13 to authorize the 5G communication with the management platform 11. If the IP address of the first processing module 12 and/or the second processing module 13 is changed, the management platform 11 refuses to perform communication, and needs to re-use the device binding control 300 for binding, so as to form authorization with the management platform 11. The authorization manner may be a manner in which the mobile phone number of the manager to which the signal source terminal 20 and the signal receiving terminal 30 belong receives the verification information, or may be another manner, which is not limited in this embodiment.

In addition, the device binding control 300 is further configured to obtain a serial port type to determine whether the corresponding transmission mode is the first preset mode or the second preset mode.

It should be noted that the management platform 11 includes, but is not limited to, each management control listed in fig. 4, and a developer may also set other corresponding management controls according to actual needs, for example, some other corresponding controls capable of tracing back a control signal transmitted by the transparent transmission system 10 may also be set, which is not limited in this embodiment.

The embodiment of the utility model provides a management platform in control signal passes system thoroughly based on 5G includes user management interface and equipment management interface. The user management interface comprises an account management control so as to manage the user authority of the first processing module and the second processing module through the account management control. The device management interface may include a device management control and a device binding control, so as to perform operations, such as monitoring the device according to a preset operation, generating a device identifier, generating a user account, and the like, through the device management control, and bind the respective IP addresses of the first processing module and the second processing module through the device binding control, so that one first processing module is only paired with the first processing module and the second processing module. In addition, the device binding control is further used for acquiring the serial port type to determine a corresponding transmission mode. Set up a plurality of corresponding management controlling parts in the management platform, not only can effectively guarantee to pass through the security and the security of system to control signal in from the transmission process of signal source end to signal receiving terminal, still utilize the convenient management of user of service to pass through the system, make the embodiment of the utility model provides a control signal based on 5G passes through the system and has stronger suitability and practicality in the thing networking of present everything UNICOM, and then can be used by more application scenes among the operating condition.

Other embodiments of the disclosure will be apparent to those skilled in the art from consideration of the specification and practice of the disclosure disclosed herein. The invention is intended to cover any variations, uses, or adaptations of the disclosure following, in general, the principles of the disclosure and including such departures from the present disclosure as come within known or customary practice within the art to which the disclosure pertains. It is intended that the specification and examples be considered as exemplary only, with a true scope and spirit of the disclosure being indicated by the following claims.

It will be understood that the present disclosure is not limited to the precise arrangements described above and shown in the drawings and that various modifications and changes may be made without departing from the scope thereof. The scope of the present disclosure is limited only by the appended claims.

Claims (11)

1. A control signal pass-through system based on 5G is characterized by comprising: the management platform is in communication connection with the first processing module and the second processing module through 5G respectively;

the first processing module is connected with the signal source end through a first preset serial port and used for converting the control signal sent by the signal source end into a first network signal and transmitting the first network signal to the management platform;

the second processing module is connected with the signal receiving terminal through a second preset serial port and used for reducing a second network signal transferred in the management platform into the control signal and then transmitting the control signal to the signal receiving terminal, and the serial port type of the first preset serial port is the same as that of the second preset serial port.

2. The 5G-based control signal transparent transmission system according to claim 1, wherein the first processing module is further configured to perform a packing process on the first network signal according to a preset time interval to obtain the second network signal, so that the management platform transfers the second network signal.

3. The 5G-based control signal transparent transmission system according to claim 2, wherein the second processing module is further configured to receive the second network signal transferred by the management platform, and perform unpacking processing on the second network signal according to the preset time interval, so as to restore the unpacked second network signal to the control signal.

4. The 5G-based control signal pass-through system according to claim 3, wherein the serial port type comprises at least one of an RS232 interface, an SPI interface, a LIN interface, a PS/2 interface and a GPIO interface;

the SPI interface comprises a three-wire SPI interface or a four-wire SPI interface.

5. The 5G-based control signal transparent transmission system according to claim 4, wherein when the serial port type includes the RS232 interface and/or the SPI interface, the first processing module collects the control signal sent by the signal source end in a first preset mode, the second processing module transmits the control signal to the signal receiving end in the first preset mode, and the first preset mode includes an immediate transmission mode and a buffer transmission mode.

6. The 5G-based control signal pass-through system according to claim 4, wherein when the serial port type includes the GPIO interface, the first processing module collects the control signal sent by the signal source end in a second preset mode, the second processing module transmits the control signal to the signal receiving end in the second preset mode, and the second preset mode includes at least one of an interrupt trigger mode, a high-level trigger mode and a low-level trigger mode.

7. The 5G-based control signal transparent transmission system according to any one of claims 1-6, wherein the management platform is configured with preset software for relaying the second network signal through the preset software and a preset protocol;

the preset software comprises a Netty service framework, and the preset protocol comprises a TCP/IP protocol.

8. The 5G-based control signal pass-through system of claim 7, wherein the management platform comprises a user management interface;

the user management interface comprises an account management control, and the account management control is used for carrying out user authority management on the first processing module and the second processing module.

9. The 5G-based control signal pass-through system of claim 8, wherein the management platform further comprises a device management interface;

the equipment management interface comprises an equipment management control, and the equipment management control is used for executing at least one operation of monitoring equipment, generating equipment identification and generating a user account according to a preset operation;

the preset operation comprises one of an adding operation, an editing operation and a deleting operation;

the device identifier is used for identifying the first processing module and the second processing module which are respectively connected with the signal source end and the signal receiving end through the first preset serial port and the second preset serial port;

the user account is used for the account management control to manage the user authority of the first processing module and the second processing module.

10. The 5G-based control signal pass-through system of claim 9, wherein the device management interface further comprises a device binding control;

the device binding control is used for binding the respective IP addresses of the first processing module and the second processing module so as to enable the first processing module and the second processing module to be paired and arranged;

the device binding control is further used for acquiring the serial port type.

11. The 5G-based control signal pass-through system of any of claims 1-6, wherein the first and second processing modules comprise one of a SIM7020 module, a Raspy pie module, and a CAT1 module.

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