CN219592405U - Water body communication architecture - Google Patents

Abstract

The utility model relates to the technical field of communication architecture, and provides a water body communication architecture, which comprises the following components: buoy module, submerged buoy module and connection box module; a first optical fiber and a first cable are arranged between the buoy module and the submerged buoy module, and data transmission is performed between the buoy module and the submerged buoy module through the first optical fiber or the first cable; the submerged buoy module and the connection box module are provided with a second optical fiber and a second cable, and data transmission is carried out between the submerged buoy module and the connection box module through the second optical fiber or the second cable. According to the water body communication architecture provided by the utility model, by adopting a photoelectric dual-channel communication mode, when one of optical fiber communication or electric channel communication fails, the other one of the optical fiber communication or the electric channel communication is started to serve as a standby communication channel, so that the problem of communication interruption of a single optical fiber system is solved, and the communication reliability of the water body communication architecture is improved.

Description

Water body communication architecture

Technical Field

The utility model relates to the technical field of communication architecture, in particular to a water body communication architecture.

Background

The marine water body communication system is a system for monitoring the environment of water body, and comprises a buoy module, a submerged buoy module and a connection box module.

At present, the connection among the buoy module, the submerged buoy module and the connection box module adopts optical communication. And the buoy module merges the data of the submerged buoy module and the connection box module and finally sends the data to the shore-based server in a wireless mode.

However, the conditions of water bodies such as oceans, lakes and the like are complex, and the communication among the buoy module, the submerged buoy module and the connection box module is easy to break, so that the communication system is unreliable.

Disclosure of Invention

The utility model provides a water body communication architecture, which is used for solving the problem of unreliable communication of the water body communication architecture in the prior art.

The utility model provides a water body communication architecture, which comprises: buoy module, submerged buoy module and connection box module; a first optical fiber and a first cable are arranged between the buoy module and the submerged buoy module, and data transmission is performed between the buoy module and the submerged buoy module through the first optical fiber or the first cable; the submerged buoy module and the connection box module are provided with a second optical fiber and a second cable, and data transmission is carried out between the submerged buoy module and the connection box module through the second optical fiber or the second cable.

According to the present utility model, there is provided a water communication architecture, the buoy module comprising: a first optical fiber transceiver and a first electrical transmission unit; the submerged buoy module comprises: the system comprises a second optical fiber transceiver, a second electric transmission unit, a third optical fiber transceiver and a third electric transmission unit; the docking box module includes: a fourth optical fiber transceiver and a fourth electrical transmission unit; the two ends of the first optical fiber are respectively connected with the first optical fiber transceiver and the second optical fiber transceiver; the two ends of the first cable are respectively connected with the first electric transmission unit and the second electric transmission unit; two ends of the second optical fiber are respectively connected with the third optical fiber transceiver and the fourth optical fiber transceiver; and two ends of the second cable are respectively connected with the third electric transmission unit and the fourth electric transmission unit.

According to the water body communication architecture provided by the utility model, the buoy module further comprises: the first controller is respectively connected with the first optical fiber transceiver and the first electric transmission unit and is used for respectively controlling the first optical fiber transceiver and the first electric transmission unit to be opened or closed; the submerged buoy module further comprises: the second controller is respectively connected with the second optical fiber transceiver, the second electric transmission unit, the third optical fiber transceiver and the third electric transmission unit, and is used for respectively controlling the opening or closing of the second optical fiber transceiver, the second electric transmission unit, the third optical fiber transceiver and the third electric transmission unit; the docking box module further includes: and the third controller is respectively connected with the fourth optical fiber transceiver and the fourth electric transmission unit and is used for respectively controlling the opening or closing of the fourth optical fiber transceiver and the fourth electric transmission unit.

According to the water body communication architecture provided by the utility model, the buoy module further comprises: the first switch is in communication connection with the first controller at one end, and is in communication connection with the first optical fiber transceiver and the first electric transmission unit at the other end; the submerged buoy module further comprises: the first end of the second switch is in communication connection with the second controller, the second end of the second switch is in communication connection with the second optical fiber transceiver and the second electric transmission unit, and the third end of the second switch is in communication connection with the third optical fiber transceiver and the third electric transmission unit; the docking box module further includes: and one end of the third switch is in communication connection with the third controller, and the other end of the third switch is in communication connection with the fourth optical fiber transceiver and the fourth electric transmission unit.

According to the water body communication architecture provided by the utility model, the first controller and the first switch establish communication connection through a TCP/IP protocol; and/or, the second controller establishes communication connection with the second switch through TCP/IP protocol; and/or, the third controller establishes communication connection with the third switch through TCP/IP protocol.

According to the water body communication architecture provided by the utility model, the first switch establishes communication connection with the first optical fiber transceiver and the first electric transmission unit through a TCP/IP protocol; and/or the second switch establishes communication connection with the second optical fiber transceiver, the second electrical transmission unit, the third optical fiber transceiver and the third electrical transmission unit through TCP/IP protocol; and/or the third switch establishes communication connection with the fourth optical fiber transceiver and the fourth electrical transmission unit through a TCP/IP protocol.

According to the water body communication architecture provided by the utility model, the first switch also establishes communication connection with the first optical fiber transceiver and the first electric transmission unit through an NTP protocol; and/or the second switch establishes communication connection with the second optical fiber transceiver, the second electrical transmission unit, the third optical fiber transceiver and the third electrical transmission unit through an NTP protocol; and/or, the third switch also establishes communication connection with the fourth optical fiber transceiver and the fourth electrical transmission unit through an NTP protocol.

According to the water body communication architecture provided by the utility model, the buoy module further comprises: the first timer is connected with the first controller; the submerged buoy module further comprises: the second timer is connected with the second controller; the docking box module further includes: and the third timer is connected with the third controller.

According to the water body communication architecture provided by the utility model, the first cable is a communication twisted pair; and/or, the second cable is a communication twisted pair.

According to the water body communication architecture provided by the utility model, the water body communication architecture further comprises: a shore-based server; the shore-based server is connected with the buoy module.

According to the water body communication architecture provided by the utility model, by adopting a photoelectric dual-channel communication mode, namely, a redundant optical fiber channel and an electric channel are arranged between the buoy module and the submerged buoy module, and a redundant optical fiber channel and an electric channel are arranged between the submerged buoy module and the connection box module, when one of the optical fiber communication or the electric channel communication fails, the other one of the optical fiber communication or the electric channel communication is started to serve as a standby communication channel, so that the problem of communication interruption of a single optical fiber system is solved, and the communication reliability of the water body communication architecture is improved.

Drawings

In order to more clearly illustrate the utility model or the technical solutions of the prior art, the following description will briefly explain the drawings used in the embodiments or the description of the prior art, and it is obvious that the drawings in the following description are some embodiments of the utility model, and other drawings can be obtained according to the drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic structural diagram of a water communication architecture according to some embodiments of the present utility model.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the present utility model more apparent, the technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings, and it is apparent that the described embodiments are some embodiments of the present utility model, not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

In describing embodiments of the present utility model, it should be noted that, unless explicitly stated and limited otherwise, the terms "coupled," "coupled," and "connected" should be construed broadly, and may be either a fixed connection, a removable connection, or an integral connection, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium. The specific meaning of the above terms in embodiments of the present utility model will be understood in detail by those of ordinary skill in the art.

The marine water body communication system is a system for monitoring the environment of water body, and comprises a buoy module, a submerged buoy module and a connection box module.

At present, the connection among the buoy module, the submerged buoy module and the connection box module adopts optical communication. And the buoy module merges the data of the submerged buoy module and the connection box module and finally sends the data to the shore-based server in a wireless mode.

However, due to the complex water conditions, the existing water communication architecture is unreliable and needs to be improved.

The water communication architecture of the present utility model is described below with reference to fig. 1.

As shown in fig. 1, the water body communication architecture provided by the present utility model includes: buoy module, submerged buoy module and connection box module; a first optical fiber and a first cable are arranged between the buoy module and the submerged buoy module, and data transmission is carried out between the buoy module and the submerged buoy module through the first optical fiber or the first cable; the second optical fiber and the second cable are arranged between the submerged buoy module and the connection box module, and data transmission is carried out between the submerged buoy module and the connection box module through the second optical fiber or the second cable.

The buoy module and the submerged buoy module establish a fiber channel through a first optical fiber, and the buoy module and the submerged buoy module are in optical communication; or the buoy module and the submerged buoy module establish an electric channel through the first cable, the buoy module and the submerged buoy module are in electric communication, the optical fiber channels and the electric communication channels are redundant, and when one of the optical fiber channels and the electric communication channels fails, the other one of the optical fiber channels and the electric communication channels is started, so that continuous communication between the buoy module and the submerged buoy module is ensured.

The optical fiber channel is established between the submerged buoy module and the connection box module through a second optical fiber, and the submerged buoy module and the connection box module are in optical communication; or, the electric channel is established between the submerged buoy module and the connection box module through the second cable, the submerged buoy module is in electric communication with the connection box module, the optical fiber channel and the electric communication channel are mutually redundant, when one of the optical fiber channel and the electric communication channel fails, the other of the optical fiber channel and the electric communication channel is started, and continuous communication between the submerged buoy module and the connection box module is ensured.

In the related art, the three-dimensional communication system of the water body adopts optical communication among the buoy, the submerged buoy and the connection box, the physical medium is an optical fiber, the bending radius of the optical fiber under the common condition is required to be larger than 5 CM to 10CM, and the actual Zhonghai Kuang Jiaocha cannot meet the requirement of the bending radius. And the optical fiber is easy to damage, and in practice, the case of interruption of the communication system caused by the optical fiber is all right.

According to the water body communication architecture provided by the utility model, by adopting a photoelectric dual-channel communication mode, namely, a redundant optical fiber channel and an electric channel are arranged between the buoy module and the submerged buoy module, and a redundant optical fiber channel and an electric channel are arranged between the submerged buoy module and the connection box module, when one of the optical fiber communication or the electric channel communication fails, the other one of the optical fiber communication or the electric channel communication is started to serve as a standby communication channel, so that the problem of communication interruption of a single optical fiber system is solved, and the communication reliability of the water body communication architecture is improved.

In some embodiments, the water body communication architecture provided by the present utility model further includes: a shore-based server; the shore-based server is connected with the buoy module and is used for receiving information sent by the buoy module.

The first optical fiber and the second optical fiber can be communication optical fibers known in the art.

The first cable and the second cable may be communication cables known in the art.

In some embodiments, the first cable is a communication twisted pair; and/or the second cable is a communication twisted pair.

Further, the buoy module includes: a first optical fiber transceiver and a first electrical transmission unit; the submerged buoy module comprises: the system comprises a second optical fiber transceiver, a second electric transmission unit, a third optical fiber transceiver and a third electric transmission unit; the docking box module includes: a fourth optical fiber transceiver and a fourth electrical transmission unit; two ends of the first optical fiber are respectively connected with the first optical fiber transceiver and the second optical fiber transceiver; two ends of the first cable are respectively connected with the first electric transmission unit and the second electric transmission unit; two ends of the second optical fiber are respectively connected with the third optical fiber transceiver and the fourth optical fiber transceiver; and two ends of the second cable are respectively connected with the third electric transmission unit and the fourth electric transmission unit.

The first optical fiber transceiver can be connected with the second optical fiber transceiver through a first optical fiber to establish a first optical channel.

The first electric transmission unit and the second electric transmission unit can be connected through a first cable to establish a first electric channel.

The third optical fiber transceiver and the fourth optical fiber transceiver can be connected through a second optical fiber to establish a second optical channel.

The third electric transmission unit and the fourth electric transmission unit can be connected through a second cable to establish a second electric channel.

The first optical channel and the first electrical channel are redundant, and the buoy module and the submerged buoy module can communicate through the first optical channel or the first electrical channel.

The second optical channel and the second electrical channel are redundant, and the submerged buoy module and the connection box module can communicate with the second electrical channel through the second optical channel.

The water body communication framework provided by the utility model at least comprises the following connection modes.

First, through first optical channel communication connection, the buoy module, between the submerged buoy module, through second optical channel communication connection between submerged buoy module and the box module of plugging into.

And the buoy module and the submerged buoy module are in communication connection through a first optical channel, and the submerged buoy module and the connection box module are in communication connection through a second electrical channel.

Thirdly, the buoy module and the submerged buoy module are in communication connection through a first electric channel, and the submerged buoy module and the connection box module are in communication connection through a second optical channel.

Fourthly, the buoy module and the submerged buoy module are in communication connection through a first electric channel, and the submerged buoy module and the connection box module are in communication connection through a second electric channel.

Wherein the first optical fiber transceiver, the second optical fiber transceiver, the third optical fiber transceiver and the fourth optical fiber transceiver are all photoelectric converters known in the art.

The fourth fiber optic transceiver may be configured to convert an electrical signal that the docking pod module needs to transmit into an optical signal and transmit to the third fiber optic transceiver.

The third optical fiber transceiver may be configured to convert an optical signal sent by the docking box module into an electrical signal for receiving, and send the received electrical signal to the second optical fiber transceiver or the second electrical transmission unit.

The second optical fiber transceiver can be used for receiving the electric signal sent by the third optical fiber transceiver, and meanwhile, converting the electric signal required to be sent by the submerged buoy module into an optical signal and sending the optical signal to the buoy module.

The first optical fiber transceiver can be used for converting a received optical signal into an electrical signal for receiving, and meanwhile, converting the electrical signal required to be sent by the buoy module into the optical signal and sending the optical signal to the shore-based server.

Wherein the first electrical transmission unit, the second electrical transmission unit, the third electrical transmission unit and the fourth electrical transmission unit are all electrical communication structures known in the art.

The fourth electrical transmission unit may be configured to transmit an electrical signal to be transmitted by the docking box module to the submerged buoy module.

The third electrical transmission unit may be configured to transmit the received electrical signal to the second electrical transmission unit or the second optical fiber transceiver.

The second electrical transmission unit may be configured to transmit the received electrical signal to the first electrical transmission unit.

Further, the buoy module further comprises: the first controller is respectively connected with the first optical fiber transceiver and the first electric transmission unit and is used for respectively controlling the opening or closing of the first optical fiber transceiver and the first electric transmission unit; the submerged buoy module further comprises: the second controller is respectively connected with the second optical fiber transceiver, the second electric transmission unit, the third optical fiber transceiver and the third electric transmission unit, and is used for respectively controlling the opening or closing of the second optical fiber transceiver, the second electric transmission unit, the third optical fiber transceiver and the third electric transmission unit; the docking box module further includes: and the third controller is respectively connected with the fourth optical fiber transceiver and the fourth electric transmission unit and is used for respectively controlling the opening or closing of the fourth optical fiber transceiver and the fourth electric transmission unit.

It will be appreciated that opening an optical or electrical channel requires a controller to control the transceivers at both ends of the optical or electrical channel to be open, and closing the optical or electrical channel requires the controller to control at least the transceivers at one end of the optical or electrical channel to be closed.

The first controller can control the first optical fiber transceiver to be opened, and the second controller can control the second optical fiber transceiver to be opened, so that the first optical channel is communicated.

The first controller controls the first electrical transmission unit to be turned off and/or the second controller controls the second electrical transmission unit to be turned off, thereby disconnecting the first electrical path.

The second controller controls the third optical fiber transceiver to be opened, and the third controller controls the fourth optical fiber transceiver to be opened, so that the second optical channel is communicated.

The second controller controls the third electric transmission unit to be turned off and/or the third controller controls the fourth electric transmission unit to be turned off, thereby disconnecting the second electric channel.

Further, the buoy module further comprises: one end of the first switch is in communication connection with the first controller, and the other end of the first switch is in communication connection with the first optical fiber transceiver and the first electric transmission unit; the submerged buoy module further comprises: the first end of the second switch is in communication connection with the second controller, the second end of the second switch is in communication connection with the second optical fiber transceiver and the second electric transmission unit, and the third end of the second switch is in communication connection with the third optical fiber transceiver and the third electric transmission unit; the docking box module further includes: and one end of the third switch is in communication connection with the third controller, and the other end of the third switch is in communication connection with the fourth optical fiber transceiver and the fourth electric transmission unit.

The first switch, the second switch, and the third switch may be network devices for forwarding electrical (optical) signals, such as ethernet switches, optical fiber switches, and the like, which are known in the art.

Further, the first controller establishes communication connection with the first switch through a TCP/IP protocol; and/or, the second controller establishes communication connection with the second switch through TCP/IP protocol; and/or the third controller establishes communication connection with the third switch through TCP/IP protocol.

Further, the first switch establishes communication connection with the first optical fiber transceiver and the first electric transmission unit through a TCP/IP protocol; and/or the second switch establishes communication connection with the second optical fiber transceiver, the second electric transmission unit, the third optical fiber transceiver and the third electric transmission unit through TCP/IP protocol; and/or the third switch establishes communication connection with the fourth optical fiber transceiver and the fourth electrical transmission unit through the TCP/IP protocol.

Wherein the TCP/IP protocol is a transmission control protocol/Internet protocol, and the TCP/IP protocol is a communication protocol well known in the art.

Further, the first switch establishes communication connection with the first optical fiber transceiver and the first electrical transmission unit through the NTP protocol; and/or the second switch also establishes communication connection with the second optical fiber transceiver, the second electrical transmission unit, the third optical fiber transceiver and the third electrical transmission unit through the NTP protocol; and/or the third switch also establishes communication connection with the fourth optical fiber transceiver and the fourth electrical transmission unit through the NTP protocol.

The NTP protocol is a network time protocol, which is a protocol known in the art for time synchronization of time devices.

Further, the buoy module further comprises: the first timer is connected with the first controller; the submerged buoy module further comprises: the second timer is connected with the second controller; the docking box module further includes: and the third timer is connected with the third controller.

The following is a specific example.

As shown in FIG. 1, the water body communication architecture provided by the utility model comprises a buoy module, a submerged buoy module and a connection box module, wherein the buoy module, the submerged buoy module and the connection box module all adopt optical fibers and communication twisted pair communication double-channel channels.

The buoy module includes: the system comprises a first controller, a first switch, a first fiber optic transceiver and a first electrical transmission unit.

The submerged buoy module comprises: the system comprises a second controller, a second switch, a second optical fiber transceiver, a second electrical transmission unit, a third optical fiber transceiver and a third electrical transmission unit.

The docking box module includes: a third controller, a third switch, a fourth fiber optic transceiver, and a fourth electrical transmission unit.

The buoy module is communicated with the submerged buoy module: when the system is started, the first controller and the second controller cooperate to control the first optical channel to be opened and the first electric channel to be closed, TCP network communication is established between the first controller and the second controller, heartbeat packets are sent at regular intervals 30S, and if the heartbeat packets are continuously over 5 times without receiving data of the other party, the first optical channel is closed and the first electric channel is opened. And reestablishing TCP network communication between the first controller and the second controller, sending heartbeat packets at regular intervals 30S, closing the first electric channel, opening the first timer and the second timer if the data of the other party are not received for more than 5 times continuously, and restarting the optical fiber channel after waiting for 1H to try the connection of the first optical channel.

Communication between the submerged buoy module and the connection box module: when the system is started, the second controller and the third controller cooperate to control the second optical channel to be opened and the second electric channel to be closed, TCP network communication is established between the third controller and the second controller, heartbeat packets are sent at regular intervals 30S, and if the heartbeat packets are continuously over 5 times without receiving data of the other party, the second optical channel is closed and the second electric channel is opened. The third controller reestablishes TCP network communication with the second controller, and periodically transmits heartbeat packets in 30S, if no data of the other party is received for more than 5 times continuously, the second electric channel is closed, a timer is started, the second optical channel is restarted after waiting for 1H, and connection of the second optical channel is attempted.

The second controller is in charge of collecting data of the connection box module and self-mounted sensor data, and the first controller is in charge of collecting data of the submerged buoy module and self-mounted sensor data, wherein the data of the submerged buoy module comprise the data of the connection box module, namely the first controller collects all data of the buoy module, the submerged buoy module and the connection box module. And finally, the first controller performs packaging processing on the data and uploads the data to the shore-based system through wireless communication.

According to the water body communication architecture provided by the utility model, by adopting a photoelectric dual-channel communication mode, namely, a redundant optical fiber channel and an electric channel are arranged between the buoy module and the submerged buoy module, and a redundant optical fiber channel and an electric channel are arranged between the submerged buoy module and the connection box module, when one of the optical fiber communication or the electric channel communication fails, the other one of the optical fiber communication or the electric channel communication is started to serve as a standby communication channel, so that the problem of communication interruption of a single optical fiber system is solved, and the communication reliability of the water body communication architecture is improved.

Finally, it should be noted that: the above embodiments are only for illustrating the technical solution of the present utility model, and are not limiting; although the utility model has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit and scope of the technical solutions of the embodiments of the present utility model.

Claims (10)

1. A water communication architecture, comprising: buoy module, submerged buoy module and connection box module;

a first optical fiber and a first cable are arranged between the buoy module and the submerged buoy module, and data transmission is performed between the buoy module and the submerged buoy module through the first optical fiber or the first cable;

the submerged buoy module and the connection box module are provided with a second optical fiber and a second cable, and data transmission is carried out between the submerged buoy module and the connection box module through the second optical fiber or the second cable.

2. The water communication infrastructure of claim 1, wherein,

the buoy module includes: a first optical fiber transceiver and a first electrical transmission unit; the submerged buoy module comprises: the system comprises a second optical fiber transceiver, a second electric transmission unit, a third optical fiber transceiver and a third electric transmission unit; the docking box module includes: a fourth optical fiber transceiver and a fourth electrical transmission unit;

the two ends of the first optical fiber are respectively connected with the first optical fiber transceiver and the second optical fiber transceiver; the two ends of the first cable are respectively connected with the first electric transmission unit and the second electric transmission unit; two ends of the second optical fiber are respectively connected with the third optical fiber transceiver and the fourth optical fiber transceiver; and two ends of the second cable are respectively connected with the third electric transmission unit and the fourth electric transmission unit.

3. The water communication architecture of claim 2, wherein,

the buoy module further comprises: the first controller is respectively connected with the first optical fiber transceiver and the first electric transmission unit and is used for respectively controlling the first optical fiber transceiver and the first electric transmission unit to be opened or closed;

the submerged buoy module further comprises: the second controller is respectively connected with the second optical fiber transceiver, the second electric transmission unit, the third optical fiber transceiver and the third electric transmission unit, and is used for respectively controlling the opening or closing of the second optical fiber transceiver, the second electric transmission unit, the third optical fiber transceiver and the third electric transmission unit;

the docking box module further includes: and the third controller is respectively connected with the fourth optical fiber transceiver and the fourth electric transmission unit and is used for respectively controlling the opening or closing of the fourth optical fiber transceiver and the fourth electric transmission unit.

4. The water communication infrastructure of claim 3, wherein,

the buoy module further comprises: the first switch is in communication connection with the first controller at one end, and is in communication connection with the first optical fiber transceiver and the first electric transmission unit at the other end;

the submerged buoy module further comprises: the first end of the second switch is in communication connection with the second controller, the second end of the second switch is in communication connection with the second optical fiber transceiver and the second electric transmission unit, and the third end of the second switch is in communication connection with the third optical fiber transceiver and the third electric transmission unit;

the docking box module further includes: and one end of the third switch is in communication connection with the third controller, and the other end of the third switch is in communication connection with the fourth optical fiber transceiver and the fourth electric transmission unit.

5. The water communication infrastructure of claim 4, wherein,

the first controller establishes communication connection with the first switch through a TCP/IP protocol;

the second controller establishes communication connection with the second switch through TCP/IP protocol;

and the third controller and the third switch establish communication connection through a TCP/IP protocol.

6. The water communication infrastructure of claim 4, wherein,

the first switch establishes communication connection with the first optical fiber transceiver and the first electrical transmission unit through a TCP/IP protocol;

the second switch establishes communication connection with the second optical fiber transceiver, the second electric transmission unit, the third optical fiber transceiver and the third electric transmission unit through TCP/IP protocol;

and the third switch establishes communication connection with the fourth optical fiber transceiver and the fourth electrical transmission unit through TCP/IP protocol.

7. The water communication infrastructure of claim 6, wherein,

the first switch also establishes communication connection with the first optical fiber transceiver and the first electrical transmission unit through an NTP protocol;

the second switch also establishes communication connection with the second optical fiber transceiver, the second electric transmission unit, the third optical fiber transceiver and the third electric transmission unit through an NTP protocol;

the third switch also establishes communication connection with the fourth optical fiber transceiver and the fourth electrical transmission unit through an NTP protocol.

8. The aquatic communication infrastructure of any of claims 3 to 7, wherein,

the buoy module further comprises: the first timer is connected with the first controller;

the submerged buoy module further comprises: the second timer is connected with the second controller;

the docking box module further includes: and the third timer is connected with the third controller.

9. The water communication architecture of any one of claims 1 to 7, wherein the first cable is a communication twisted pair; the second cable is a communication twisted pair.

10. The water communication architecture of any one of claims 1 to 7, further comprising: a shore-based server;

the shore-based server is connected with the buoy module.