KR102146478B1 - System and method for transmitting/receiving the message in maritime wireless communication system - Google Patents

Abstract

The present invention relates to a system for transmitting and receiving a message in a maritime wireless communication system and a method thereof. The present invention includes the following steps of generating an e-navigation service-related HTTP message and transmitting the message to a ship station gateway, generating a gateway message by combining the header and the payload of the HTTP message in accordance with a gateway message format, generating gateway message packets by fragmenting the gateway message, generating VDE message packets by inserting the gateway message packets into the payloads of the messages in accordance with a VDE message format, transmitting the VDE message packets to a ship station mobile station, receiving the VDE message packets and transmitting the packets to a coast station base station through a VDES communication network in accordance with a VDES wireless communication protocol, receiving the VDE message packets and transmitting the packets to a coast station gateway, generating the gateway message by combining the payloads of the VDE message packets in accordance with the gateway format, generating the HTTP message including the header and the payload by segmenting the gateway message, transmitting the HTTP message to a service host, and receiving and processing the HTTP message.

Description

A system and method for transmitting and receiving messages in a maritime wireless communication system {SYSTEM AND METHOD FOR TRANSMITTING/RECEIVING THE MESSAGE IN MARITIME WIRELESS COMMUNICATION SYSTEM}

The present invention relates to a maritime wireless communication system, and more particularly, to a system and method for transmitting and receiving messages in a maritime wireless communication system.

In line with the development of wireless communication, the International Maritime Organization (IMO) uses the terrestrial wireless communication link of the Very High Frequency Data Exchange System (hereinafter referred to as'VDES') to keep pace with the development of wireless communication. Standards for providing e-Navigation) services are being established.

Meanwhile, the e-navigation service basically uses HTTP (HyperText Transfer Protocol) based on Transmission Control Protocol/Internet Protocol (TCP/IP). Therefore, in order to provide an e-navigation service through a VDES terrestrial wireless communication link, a communication protocol technology for interworking between a TCP/IP-based e-navigation service and a non-IP-based VDES base station and mobile station equipment is required.

The present invention proposes a system and method for providing an e-navigation service through a VDES wireless communication link.

In addition, the present invention proposes a system and method for reconstructing a message to provide an e-navigation service through a VDES wireless communication link.

In addition, the present invention proposes a system and method for routing a reconfigured message to provide an e-navigation service through a VDES wireless communication link.

In addition, the present invention proposes a system and method for providing an interface between a service host and a service client, a coast station gateway and a ship station gateway, a VDES base station, and a VDES mobile station in order to provide an e-navigation service through a VDES wireless communication link.

In addition, the present invention proposes a system and method for constructing a VDES test network for effectively delivering an e-navigation service through a VDES wireless communication link.

A system for transmitting and receiving messages in a maritime wireless communication system according to an embodiment of the present invention includes a service client that generates an HTTP message related to an e-navigation service and transmits it to a ship station gateway, and the HTTP message according to a gateway message format. A gateway message is generated by combining a header and a payload, and a plurality of gateway message packets are generated by fragmenting the gateway message, and a plurality of VDE messages by inserting the gateway message packets into the payloads of messages according to the VDE message format. The ship station gateway that generates packets and transmits the VDE message packets to the ship station mobile station, and the VDE message packets are received from the ship station gateway and transmitted to the coast station base station through a VDES communication network according to the VDES wireless communication protocol. , The ship station mobile station receiving VDE message packets from the coast station base station and transmitting it to the ship station gateway, and the VDE message packets received from the ship station mobile station and transmitted to the coast station gateway, and VDE from the coast station gateway The coast station base station receiving message packets and transmitting them to the ship station mobile station through the VDES communication network according to the VDES wireless communication protocol, and the gateway message by combining the payloads of the VDE message packets according to the gateway format. And the coast station gateway generating the HTTP message including the header and the payload by dividing the gateway message, and transmitting the HTTP message to a service host, and the service receiving and processing the HTTP message Includes the host.

A method of transmitting and receiving a message in a maritime wireless communication system according to an embodiment of the present invention includes a process of generating an HTTP message related to an e-navigation service and transmitting it to a ship station gateway, the header and the payout of the HTTP message according to the gateway message format. A process of generating a gateway message by combining loads, a process of generating a plurality of gateway message packets by fragmenting the gateway message, a plurality of VDE message packets by inserting the gateway message packets into payloads of messages according to a VDE message format And transmitting the VDE message packets to the ship station mobile station, receiving the VDE message packets and transmitting them to the coast station base station through the VDES communication network according to the VDES wireless communication protocol, and receiving the VDE message packets Transmitting to a station gateway, generating the gateway message by combining payloads of the VDE message packets according to the gateway type, dividing the gateway message to generate the HTTP message including the header and the payload And generating and transmitting the HTTP message to a service host, and receiving and processing the HTTP message.

The present invention can provide an e-navigation service through a VDES wireless communication link.

In addition, the present invention can reconstruct a message to provide an e-navigation service through a VDES wireless communication link.

In addition, the present invention can route a reconfigured message to provide an e-navigation service through a VDES wireless communication link.

In addition, the present invention can provide an interface between a service host and a service client, a coast station gateway and a ship station gateway, a VDES base station, and a VDES mobile station in order to provide an e-navigation service through a VDES wireless communication link.

In addition, the present invention can effectively provide an e-navigation service through a VDES test network.

1 is a simple configuration diagram of a maritime wireless communication system according to an embodiment of the present invention.
2 is a detailed configuration diagram of a maritime wireless communication system according to an embodiment of the present invention.
3 is a diagram illustrating a procedure for reconfiguring a message in a maritime wireless communication system according to an embodiment of the present invention.
4 is a diagram illustrating a protocol stack between equipments in a maritime wireless communication system according to an embodiment of the present invention.
5 is a diagram illustrating an HTTP message format used in a maritime wireless communication system according to an embodiment of the present invention.
6 is a flowchart of a message transmission in a maritime wireless communication system according to an embodiment of the present invention.
7 is a flowchart for transmitting a message from a ship station gateway according to an embodiment of the present invention.
8 is a flowchart for transmitting a message from a coast station gateway according to an embodiment of the present invention.
9 is a block diagram of a VDES test network in a maritime wireless communication system according to an embodiment of the present invention.
10 is a diagram illustrating an interface interlocked between devices in a VDES test network according to an embodiment of the present invention.
11 is a flowchart showing a test scenario provided by a VDES test network according to an embodiment of the present invention.

In the present invention, various modifications may be made and various embodiments may be provided, and specific embodiments will be described in detail by exemplifying them in the drawings. However, this is not intended to limit the present invention to a specific embodiment, it is to be understood to include all changes, equivalents, and substitutes included in the spirit and scope of the present invention.

Terms including ordinal numbers, such as first and second, may be used to describe various elements, but the elements are not limited by the terms. These terms are used only for the purpose of distinguishing one component from another component. For example, without departing from the scope of the present invention, a first element may be referred to as a second element, and similarly, a second element may be referred to as a first element. The term and/or includes a combination of a plurality of related listed items or any of a plurality of related listed items.

The terms used in the present application are used only to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In the present application, terms such as "comprise" or "have" are intended to designate the presence of features, numbers, steps, actions, components, parts, or combinations thereof described in the specification, but one or more other features. It is to be understood that the presence or addition of elements or numbers, steps, actions, components, parts, or combinations thereof, does not preclude in advance.

Unless otherwise defined, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs. Terms as defined in a commonly used dictionary should be interpreted as having a meaning consistent with the meaning in the context of the related technology, and should not be interpreted as an ideal or excessively formal meaning unless explicitly defined in this application. Does not.

In the present invention, the e-navigation service host or client may be any device, and the e-navigation service host or client may be referred to as a portable terminal, a mobile terminal, a communication terminal, a portable communication terminal, a portable mobile terminal, and the like.

For example, an e-navigation service host or client may be a smartphone, cell phone, TV, display device, vehicle head unit, notebook computer, laptop computer, tablet computer, Personal Media Player (PMP), Personal Digital Assistants (PDA). ), etc. The e-navigation service host or client can be implemented as a pocket-sized portable communication terminal having a wireless communication function. Also, the e-navigation service host or client may be a flexible device or a flexible display device.

In the present invention, the maritime wireless communication system provides an e-navigation service using a VDES terrestrial wireless communication link. Here, e-navigation is an electronic navigation system for ships, which is a system that supports ship operation related services by collecting, analyzing, and exchanging maritime information of ships and land in an electronic method for the purpose of marine safety security and marine environment protection. Hereinafter, a configuration diagram of a maritime wireless communication system will be described with reference to FIGS. 1 and 2.

1 is a simple configuration diagram of a maritime wireless communication system according to an embodiment of the present invention.

Referring to FIG. 1, a maritime wireless communication system includes a first user 101, an e-Navigation Service Host 103, a Shore Gateway 105, and VDES base stations (VDES). Base stations (107, 109, 111) and VDES networks (VDE (VHF Data Exchange) and Application Specific Message (ASM) radio channels) 113 and VDES mobile stations (115, 117, 119) and ship station gateways (121, 123, 125) and e-navigation service clients (127, 129, 131) and second to fourth users (133, 135, 137).

These devices may be divided into an operation center 201, a coast station 211, and a ship station 221, as shown in FIG. 2.

The operation center 201 includes an e-navigation service host 203, a router, and a coast station gateway 209. The e-navigation service host 203 may include a database 205 and a host 207. The database 205 stores various types of data related to the e-navigation service, and stores or outputs data according to the request of the host 207. The host 207 is a terminal that provides an e-navigation service, is connected to a network, and inputs or outputs data to the database 205 according to the request of an external device. The interface between the database 205 and the host 207 is formed based on data of a Geographic Markup Language (hereinafter referred to as'GML') (S-100). Here, GML represents an XML-based geographic information encoding language developed by OGC (Open GIS Consortium) to improve interoperability of geographic information.

The e-navigation service host 203 exchanges VDES service messages based on HTTP (HyperText Transfer Protocol) with external devices, provides a seamless roaming function between heterogeneous communication networks, and logs or processes data.

The router selects and delivers an appropriate communication path by analyzing the information contained in the packet at the connection point between networks. For example, the router may receive data according to HTTP from the e-navigation service host 203 through a network and transmit the received data to the coast station gateway 209. In addition, the router may receive data according to HTTP from the coast station gateway 209 and transmit the received data to the e-navigation service host 203.

The coast station gateway 209 provides a function of converting and processing protocols between a plurality of communication networks having different protocols. And the coast station gateway 209 provides a function of converting and processing an e-navigation service message. For example, the coast station gateway 209 may convert a message according to HTTP into a message according to the VDES wireless communication protocol or convert a message according to the VDES wireless communication protocol into a message according to HTTP. And the coast station gateway 209 provides a message routing function. For example, the message may be a message related to an e-navigation service.

For example, an interface between the e-navigation service host 203 and the coast station gateway 209 may be formed based on HTTP.

The coast station 211 includes a plurality of routers and a plurality of VDES base stations 213 and 215. The routers receive data according to the VDES wireless communication protocol from the coast station gateway 209 through the network, and transmit the received data to the VDES base stations 213 and 215. Further, the routers receive data according to the VDES wireless communication protocol from the VDES base stations 213 and 215, and transmit the received data to the coast station gateway 209 through the network.

The VDES base stations 213 and 215 provide a function of transmitting and receiving a VDES message in the coast station 211. For example, the VDES message may be a message according to the VDES wireless communication protocol. For example, the VDES base stations 213 and 215 receive data according to the VDES wireless communication protocol from a plurality of routers, and received according to the VDES wireless communication protocol through the VDE or ASM wireless channels 217 and 219. Data can be transmitted to the VDES mobile stations 223 and 225. In addition, the VDES base stations 213 and 215 receive data according to the VDES wireless communication protocol from the VDES mobile stations 223 and 225 through the VDE or ASM radio channels 217 and 219, and transmit the received data to a plurality of routers. Can be transmitted to.

For example, the interface between the coast station gateway 209 and the VDES base stations 213 and 215 may be formed based on the User Datagram Protocol (hereinafter referred to as'UDP') (IEC 61162-450). have. Here, UDP is one of the protocols underlying TCP/IP, which is a standard set of Internet protocols, and is used in multimedia applications that require high speed rather than reliability. In addition, an interface between the VDES base stations 213 and 215 and the VDES mobile stations 223 and 225 may be formed based on the VDES terrestrial wireless communication protocol.

The ship station 221 includes a plurality of VDES mobile stations 223 and 225, a plurality of routers, ship station gateways 227 and 231, and a plurality of e-navigation service clients 229 and 233.

The VDES mobile stations 223 and 225 provide a function of transmitting and receiving a VDES message in the ship station 221. For example, each of the VDES mobile stations 223 and 225 receives data according to the VDES wireless communication protocol from a connected router, and data received according to the VDES wireless communication protocol through the VDE or ASM wireless channels 217 and 219. May be transmitted to the VDES base stations 213 and 215. Further, the VDES mobile stations 223 and 225 receive data according to the VDES wireless communication protocol from the VDES base stations 213 and 215 through the VDE or ASM radio channels 217 and 219, and transmit the received data to the connected router. Can be transmitted.

Each of the routers receives data according to the VDES wireless communication protocol from the connected ship station gateway, and transmits the received data to the connected VDES mobile stations. Each of the routers receives data according to the VDES wireless communication protocol from the connected VDES mobile station, and transmits the received data to the connected ship station gateway.

The ship station gateways 227 and 231 provide a function of converting and processing e-navigation service messages. For example, each of the ship station gateways 227 and 231 receives a message according to HTTP from the connected e-navigation service client, converts the received message into a message according to the VDES wireless communication protocol, and converts the converted message into a connected message. It can be transmitted to the VDES mobile station. And each of the ship station gateways 227 and 231 receives a message according to the VDES wireless communication protocol from the connected VDES mobile station, converts the received message into a message according to HTTP, and converts the converted message to the connected e-navigation service client. Can be transmitted.

For example, an interface between the VDES mobile stations 223 and 225 and the ship station gateways 227 and 231 may be formed based on UDP (IEC 61162-450).

Each of the e-navigation service clients 229 and 233 exchanges HTTP-based VDES service messages with external devices, provides a seamless roaming function between heterogeneous communication networks, and logs or processes data.

For example, an interface between the e-navigation service clients 229 and 233 and the ship station gateways 227 and 231 may be formed based on HTTP.

3 is a diagram illustrating a procedure for reconfiguring a message in a maritime wireless communication system according to an embodiment of the present invention.

3, the ship station 301 includes an e-navigation service client 303, a ship station gateway 305 and a VDES mobile station 307, and the coast station 331 includes a VDES base station 333 and a coast It includes a station gateway 335 and an e-navigation service host 337 for VDES testing.

Looking at each component, the e-navigation service client 303 transmits a message (hereinafter referred to as a'request message') for requesting an e-navigation service to the ship station gateway 305. For example, the e-navigation service client 303 may transmit a request message 309 according to HTTP.

The ship station gateway 305 receives a request message from the e-navigation service client 303, reconstructs the received request message according to the gateway message format, and generates a gateway request message. For example, the ship station gateway 305 may generate the gateway request message 311 by extracting and combining an HTTP header and a payload from the request message 309.

In addition, the ship station gateway 305 generates a VDES request message by reconstructing the gateway request message generated according to the VDE message format. For example, the ship station gateway 305 may generate gateway request message packets by fragmenting the gateway request message 311. In addition, the ship station gateway 305 stores gateway request message packets generated in payloads 315, 317, and 319 of messages according to the binary image data format defined in the UDP (IEC 61162-450) standard. By including it, you can generate binary request message packets.

For example, the message 313 in the binary image data format may include a header, a binary image descriptor, and a binary image data payload. For example, the header may include control information for VDES request message packets. For example, the binary image descriptor may include description information in VDES request message packets. For example, the size of the message 313 may be 1472 bytes or less by standard.

In addition, the ship station gateway 305 adds an Ethernet header, an IP header, a UDP header, and a Cyclic Redundancy Check (CRC) to each of the binary request message packets 323 and 327 according to UDP, thereby adding VDES request message packets 321 and 325. ) Can be created.

In the above, since the VDE message format is not defined, the binary image data format is used, but when the VDE message format is defined, the ship station gateway 305 may generate VDES request message packets using the VDE message format.

In addition, the ship station gateway 305 may transmit a VDES request message to the VDES mobile station 307. For example, the ship station gateway 305 may transmit VDES request message packets 321 and 325 generated using UDP.

The VDES mobile station 307 receives the VDES request message from the ship station gateway 305 and transmits the received VDES request message to the VDES base station 333 according to the VDES wireless communication protocol. For example, the VDES mobile station 307 may transmit the VDES request message packets 321 and 325 received through the VDES communication network.

The VDES base station 333 receives a VDES request message from the VDES mobile station 307 according to the VDES wireless communication protocol, and transmits the received VDES request message to the coast station gateway 335.

The coast station gateway 335 receives the VDES request message from the VDES base station 333, reconstructs the VDES request message according to the gateway message format, and generates a gateway request message.

For example, the coast station gateway 335 may generate binary request message packets by removing the Ethernet header, the IP header, the UDP header, and the CRC from the VDES request message packets 339 and 341. In addition, the coast station gateway 335 uses the control information and description information included in the header and descriptor of one of the generated binary request message packets 343 to provide payloads 345, 347, 349 of the binary request message packets. The gateway request message 351 may be generated by de-fragmentation.

In addition, the coast station gateway 335 generates a request message by reconstructing the gateway request message according to HTTP. For example, the coast station gateway 335 may recover the gateway request message 351 as a header and payload according to HTTP. In addition, the coast station gateway 335 may generate a request message 353 by adding an Ethernet header, an IP header, a TCP header, and a CRC to a header and payload recovered according to TCP/IP.

Then, the coast station gateway 335 transmits the generated request message to the e-navigation service host 337.

The e-navigation service host 337 receives a request message from the coast station gateway 335 and processes the received request message.

The present invention can provide an e-navigation service through a VDES wireless communication link through such an operation. In addition, the present invention can reconstruct a message to provide an e-navigation service through a VDES wireless communication link. In addition, the present invention can route a reconfigured message to provide an e-navigation service through a VDES wireless communication link.

4 is a diagram illustrating a protocol stack between equipments in a maritime wireless communication system according to an embodiment of the present invention. The physical connection is LAN, and data flow is used from layer 1 to application layer (HTTP).

4, the e-navigation service host 401 transmits data to the coast station gateway 403 by sequentially using an HTTP layer, a TCP layer, an IP layer, a link layer, and an Ethernet layer. do.

The coast station gateway 403 sequentially uses an Ethernet layer, a link layer, an IP layer, a TCP layer, and an HTTP layer to receive data from the e-navigation service host 401, and provides an HTTP layer, a UDP layer, an IP layer, and a link. The data is transmitted to the coast station base station 405 by sequentially using the layer and the Ethernet layer.

The coast station base station 405 sequentially uses the Ethernet layer, the link layer, the IP layer, and the UDP layer to receive data from the coast station gateway 403, and sequentially uses the L2 layer and the L1 layer to receive data from the ship station mobile station. It sends to (409). At this time, the coast station base station 405 transmits data through the VHF radio channel 407.

The ship station mobile station 409 sequentially uses the L1 layer and the L2 layer to receive data from the coast station base station 405, and sequentially uses the UDP layer, the IP layer, the link layer, and the Ethernet layer to transfer the data to the ship station gateway. Send to (411).

The ship station gateway 411 sequentially uses the Ethernet layer, the link layer, the IP layer, the UDP layer and the HTTP layer to receive data from the ship station mobile station 409, and the HTTP layer, the TCP layer, the IP layer, the link layer, and Data is transmitted to the e-navigation service client 413 by sequentially using the Ethernet layer.

The e-navigation service client 413 sequentially receives data using an Ethernet layer, a link layer, an IP layer, a TCP layer, and an HTTP layer.

So far, the operation of transmitting data from the e-navigation service host 401 to the e-navigation service client 413 has been described. The operation of transmitting data from the e-navigation service client 413 to the e-navigation service host 401 operates opposite to the above operation.

5 is a diagram illustrating an HTTP message format used in a maritime wireless communication system according to an embodiment of the present invention. Here, the HTTP message format represents an HTTP message format transmitted as a VDES service message. For example, the VDES service message may indicate an HTTP-based e-navigation service message transmitted using VDES.

Referring to FIG. 5, the HTTP message format includes an HTTP header 501 and an HTTP payload 503. The HTTP header 510 is divided into srcMRN, dstMRN, URL, and msgSeq. srcMRN represents the MRN address of the sender who sent the message. dstMRN represents the address of the recipient's MRN to receive the message. The URL represents the address of the destination service to be used. msgSeq is used to classify messages in order to calculate performance such as the transmission error rate of messages.

The e-navigation service message using such an HTTP-based message may be transmitted to the e-navigation service host 401 or the e-navigation service client 413 through the coast station gateway 403 or the ship station gateway 411. .

6 is a flowchart of a message transmission in a maritime wireless communication system according to an embodiment of the present invention.

Referring to FIG. 6, in step 613, the e-navigation service client 611 generates a request message and transmits it to the ship station gateway 609. For example, the request message may be a request message defined using HTTP.

In step 615, the ship station gateway 609 receives a request message from the e-navigation service client 611. For example, the ship station gateway 609 may receive all messages for other communication services, including e-navigation services. And the ship station gateway 609 generates a VDES request message by reconstructing the received request message according to the VDE message format.

In step 617, the ship station gateway 609 transmits the generated VDES request message to the VDES mobile station 607. For example, the ship station gateway 609 may transmit data packets to the VDES mobile station 607 to transmit data from the local network of the ship station 221 to the network of the coast station 211. For example, the ship station gateway 609 may transmit the generated VDES request message to the VDES mobile station 607 in packet units.

The VDES mobile station 607 receives the VDES request message from the ship station gateway 609, and transmits the VDES request message received according to the VDES wireless communication protocol to the VDES base station 605 through the VDES communication network. The VDES base station 605 receives the VDES request message from the VDES mobile station 607 according to the VDES wireless communication protocol through the VDES communication network, and transmits the received VDES request message to the coast station gateway 603. For example, the VDES mobile station 607 or the VDES base station 605 may receive and transmit the VDES request message in packet units.

In step 619, the coast station gateway 603 receives the VDES request message, reconstructs the received VDES request message according to HTTP, and generates a request message. For example, the request message may be an HTTP-based message.

In step 621, the coast station gateway 603 transmits the generated request message to the e-navigation service host 601.

In step 623, the e-navigation service host 601 receives a request message from the coast station gateway 603, generates a response message for the received request message according to HTTP, and sends the generated response message to the coast station gateway ( 603). For example, the response message may be an HTTP-based message.

In step 625, the coast station gateway 603 receives the response message from the e-navigation service host 601, reconstructs the received response message according to the VDE message format, and generates a VDES response message.

In step 627, the coast station gateway 603 transmits the generated VDES response message to the VDES base station 605. For example, the coast station gateway 603 may transmit data packets to the VDES base station 605 in order to transmit data from the network of the coast station 211 to the local network of the ship station 221. For example, the coast station gateway 603 may transmit the generated VDES response message to the VDES base station 605 in packet units.

The VDES base station 605 receives the VDES response message from the coast station gateway 603, and transmits the VDES response message received according to the VDES wireless communication protocol to the VDES mobile station 607 through the VDES communication network.

The VDES mobile station 607 receives a VDES response message from the VDES base station 605 according to the VDES wireless communication protocol through the VDES communication network, and transmits the received VDES response message to the ship station gateway 609. For example, the VDES mobile station 607 or the VDES base station 605 may receive and transmit the VDES response message in packet units.

In step 629, the ship station gateway 609 receives the VDES response message from the VDES mobile station 607, reconstructs the received VDES response message according to HTTP, and generates a response message. For example, the response message may be an HTTP-based message.

In step 631, the ship station gateway 609 transmits the generated response message to the e-navigation service client 611.

7 is a flowchart for transmitting a message from the ship station gateway 609 according to an embodiment of the present invention.

Referring to FIG. 7, in step 701, the ship station gateway 609 receives a request message from the e-navigation service client 611. For example, the request message may be an HTTP-based message.

In step 703, the ship station gateway 609 generates a gateway request message by reconstructing the received request message according to the gateway message format. For example, the gateway request message may be an HTTP-based message according to the gateway message format.

For example, the ship station gateway 609 may generate the gateway request message 311 according to the gateway message format by extracting and combining the HTTP header and the payload from the request message 309 as shown in FIG. 3.

In step 705, the ship station gateway 609 may generate a VDES request message by reconstructing the gateway request message generated according to the VDE message format. For example, the VDES request message may be an HTTP-based message conforming to the VDE message format.

For example, the ship station gateway 609 may generate gateway request message packets by fragmenting the gateway request message 311 as shown in FIG. 3. In addition, the ship station gateway 609 inserts the generated packets into the payloads 315, 317, and 319 of messages according to the binary image data format defined in the UDP (IEC 61162-450) standard. Can be generated.

In addition, the ship station gateway 609 may generate VDES request message packets 321 and 325 by adding an Ethernet header, an IP header, a UDP header and a CRC to each of the binary request message packets 323 and 327 according to UDP. have.

In the above, since the VDE message format is not defined, the binary image data format is used, but if the VDE message format is defined, the ship station gateway 609 may generate VDES request message packets using the VDE message format.

In step 707, the ship station gateway 609 may transmit a VDES request message to the VDES mobile station 607. For example, the ship station gateway 609 may transmit VDES request message packets 321 and 325 generated using UDP.

In step 709, the ship station gateway 609 may receive a VDES response message from the VDES mobile station 607 in response to the VDES request message. For example, the ship station gateway 609 may receive VDES response message packets using UDP.

In step 711, the ship station gateway 609 generates a gateway response message by reconstructing the VDES response message according to the gateway message format.

For example, the ship station gateway 609 may generate binary response message packets by removing the Ethernet header, IP header, UDP header, and CRC from the VDES response message packets. In addition, the ship station gateway 609 may generate a gateway response message by combining the payloads of the binary response message packets by using the control information and description information included in the descriptor and one header of the generated binary response message packets. have.

In step 713, the ship station gateway 609 may generate a response message by reconfiguring the gateway response message according to HTTP. For example, the ship station gateway 609 may recover the gateway response message as a header and payload according to HTTP. In addition, the ship station gateway 609 may generate a response message by adding an Ethernet header, an IP header, a TCP header and a CRC to the header and payload restored according to TCP/IP.

In step 715, the ship station gateway 609 transmits the generated response message to the e-navigation service client 611. For example, the ship station gateway 609 may transmit a response message using TCP/IP.

8 is a flowchart for transmitting a message from the coast station gateway 603 according to an embodiment of the present invention.

Referring to FIG. 8, the coast station gateway 603 receives a VDES request message from the VDES base station 605. For example, the coast station gateway 603 may receive VDES request message packets.

In step 803, the coast station gateway 603 generates a gateway request message by reconstructing the VDES request message according to the gateway message format.

For example, the coast station gateway 603 can generate binary request message packets by removing the Ethernet header, the IP header, the UDP header, and the CRC from the VDES request message packets 339 and 341, as shown in FIG. I can. In addition, the coast station gateway 603 uses the control information and description information included in the header and descriptor of one of the generated binary request message packets 343 to provide payloads 345, 347, 349 of the binary request message packets. A gateway request message 351 can be generated by combining

In step 805, the coast station gateway 603 may generate a request message by reconfiguring the gateway request message according to HTTP. For example, the coast station gateway 603 may recover the gateway request message 351 as a header and payload according to HTTP. In addition, as shown in FIG. 3, the coast station gateway 603 may generate a request message 353 by adding an Ethernet header, an IP header, a TCP header, and a CRC to the header and payload recovered according to TCP/IP.

In step 807, the coast station gateway 603 transmits the generated request message to the e-navigation service host 601.

In step 809, the coast station gateway 603 receives a response message from the e-navigation service host 601 in response to the request message. For example, the response message may be an HTTP-based message.

In step 811, the coast station gateway 603 generates a gateway request message by reconstructing the received request message according to the gateway message format. For example, the coast station gateway 603 may generate a gateway response message according to the gateway message format by extracting and combining the HTTP header and the payload from the response message.

In step 813, the coast station gateway 603 may generate a VDES response message by reconstructing the gateway response message generated according to the VDE message format.

For example, the coast station gateway 603 may generate gateway response message packets by fragmenting the gateway response message. In addition, the coast station gateway 603 may generate binary response message packets by inserting each generated gateway response message packets into payloads of messages according to the binary image data format defined in the UDP (IEC 61162-450) standard. .

In addition, the coast station gateway 603 may generate VDES response message packets by adding an Ethernet header, an IP header, a UDP header, and a CRC to each of the VDES response message packets according to UDP.

In the above, since the VDE message format is not defined, the binary image data format is used, but when the VDE message format is defined, the coast station gateway 603 may generate VDES response message packets using the VDE message format.

In step 815, the coast station gateway 603 may transmit a VDES response message to the VDES base station 605. For example, the coast station gateway 603 may transmit VDES response message packets generated using UDP.

9 is a block diagram of a VDES test network in a maritime wireless communication system according to an embodiment of the present invention.

Referring to FIG. 9, the VDES test network includes a VDES test center 901, first and second VDES coast stations 911, 921, and first to third VDES ship stations 931, 933, and 935. do.

Looking at each component, the VDES test center 901 includes a VDES management system 903, a coast station gateway 905, an e-navigation service host 907, a switching hub, and Long Term Evolution. LTE') and a router 909.

The first VDES coast station 911 is connected to the switching hub of the VDES test center 901 and includes a first VDES base station 913 and a first VHF antenna 915. The second VDES coast station 921 is an LTE router 923 connected to the LTE router 909 through a wide area network (hereinafter referred to as'WAN'), a second VDES base station 925 and a second It includes a VHF antenna 927.

The third VDES ship station 935 includes a VHF antenna 937, a VDES mobile station 939, an LTE router 941, a switching hub, an e-navigation service client 943, and a ship station gateway 945. The first and second VDES ship stations 931 and 933 may include the same or similar equipment as the third VDES ship station 935.

In the VDES test network, the VDES management system 903 and the ASM client (not shown) provide a function to test ASM through the VDES test network. In addition, the VDES management system 903 provides a monitoring function and a control function for monitoring the state of the VDES test network, and outputs a map.

10 is a diagram illustrating an interface interlocked between devices in a VDES test network according to an embodiment of the present invention.

10, the VDES test network includes a VDES management system 1001, an e-navigation service host 1003, a coast station gateway 1005, a coast station base station 1007, a ship station mobile station 1009, and a ship station gateway. It includes (1011) and the client (1013). The client 103 includes an e-navigation service client 1017 and an ASM client 1015.

Looking at the interface between each component, between the VDES management system 1001 and the coast station gateway 1005, a control message and an ASM message of the coast station base station 1007 may be transmitted/received through Ethernet. Between the coast station gateway 1005 and the coast station base station 1007, VDE messages, ASM messages, and control messages may be transmitted/received through Ethernet.

VDE messages may be transmitted/received through Ethernet between the e-navigation service host 1003 and the coast station gateway 1005. Between the VDES management system 1001 and the e-navigation service host 1003, a function of monitoring messages transmitted/received from the e-navigation service host 1003 through Ethernet may be provided.

VDE messages may be transmitted/received between the e-navigation service client 1017 and the ship station gateway 1011 through Ethernet. VDE messages may be transmitted/received between the ship station gateway 1011 and the ship station mobile station 1009 through Ethernet. ASM messages may be transmitted/received between the ASM client 1015 and the ship station gateway 1011 through Ethernet.

The e-navigation service client 1017 and the VDES management system 1001 provide a function of monitoring messages transmitted/received from the e-navigation service client 1017 through a commercial LTE network. Between the ship station gateway 1011 and the VDES management system 1001, the ship station gateway 1011 provides a function of monitoring messages transmitted/received through a commercial LTE network.

A polling or relaying function is provided between the e-navigation service host 1003 and the e-navigation service client 1017 through a commercial LTE network. For example, in polling, the e-navigation service host 1003 sequentially inquires about the presence or absence of a transmission request for a plurality of e-navigation service clients, and if there is a request, the e-navigation service client 1017 is contacted. It commands to start transmission, and when not present, it can indicate the transmission control method that inquires about the next e-navigation service client.

In this way, the present invention can provide an interface between a service host and a service client, a coast station gateway and a ship station gateway, a VDES base station, and a VDES mobile station in order to provide an e-navigation service through a VDES wireless communication link. In addition, the present invention can effectively provide an e-navigation service through a VDES test network.

11 is a flowchart showing a test scenario provided by a VDES test network according to an embodiment of the present invention.

Referring to FIG. 11, the VDES test network includes a ship station 1101, a coast station 1103, and a test center 1105. The ship station 1101 includes first and second e-navigation service clients 1111 and 1113, a ship station gateway 1115 and a VDES mobile station 1117. The coast station 1103 includes a VDES base station 1119. The test center 1105 includes a coast station gateway 1121 and an e-navigation service host 1123 and a management system 1125.

In step 1131, one of the first and second e-navigation service clients 1111 and 1113 requests a service inquiry from the ship station gateway 1115.

In step 1133, the ship station gateway 1115 requests a service inquiry from the e-navigation service host 1123 through the VDES mobile station 1117, the VDES base station 1119, and the coast station gateway 1121.

In step 1135, the e-navigation service host 1123 is the first and second e-navigation service clients through the ship station gateway 1115, the VDES mobile station 1117, the VDES base station 1119, and the coast station gateway 1121. The service inquiry result is transmitted to one of the elements 1111 and 1113.

The ship can operate scenarios in which service is possible using the service inquiry request and service inquiry result.

The first scenario is a scenario for exchanging maritime data exchange standard messages (GML) as an accident alarm service.

In step 1141, the first e-navigation service client 1113 transmits an alarm notifying that a dangerous situation has occurred to the ship station gateway 1115.

In step 1143, the ship station gateway 1115 transmits a dangerous situation occurrence alarm to the e-navigation service host 1123 through the DES mobile station 1117, the VDES base station 1119, and the coast station gateway 1121.

In step 1145, the e-navigation service host 1123 requests the management system 1125 for a Manifest Reference Number (MRN) of a vessel in which a dangerous situation has occurred. In step 1147, in step 1147, the management system 1125 searches for the MRN of the vessel, and transmits the found MRN to the e-navigation service host 1123.

In step 1149, the e-navigation service host 1125 receives the MRN, and uses the MRN to specify a second e-navigation service client 1111 located in the same vessel. And the e-navigation service host 1123 passes through the ship station gateway 1115, the VDES mobile station 1117, the VDES base station 1119, and the coast station gateway 1121 to the second e-navigation service client 1111 in a dangerous situation. Send the occurrence message. At this time, the e-navigation service host 1123 may also transmit a countermeasure for a dangerous situation.

The second e-navigation service client 1111 receives a risk situation occurrence message, recognizes that a risk situation has occurred using the received risk situation occurrence message, and notifies the user of a countermeasure for the risk situation.

The second scenario is a scenario in which a message is transmitted from the first e-navigation service client 1113 to the second e-navigation service client 1111. For example, the message may be a short message.

In step 1151, the first e-navigation service client 1113 transmits a message to the ship station gateway 1115.

In step 1153, the ship station gateway 1115 transmits the received message to the e-navigation service host 1123 through the VDES mobile station 1117, the VDES base station 1119, and the coast station gateway 1121, and message queuing ( queuing). For example, message queuing refers to the operation of controlling the order in which message texts are stored, processed and transmitted.

In step 1155, the e-navigation service host 1123 passes through the ship station gateway 1115, the VDES mobile station 1117, the VDES base station 1119, and the coast station gateway 1121, and the second e-navigation service client 1111 The message to The second e-navigation service client 1111 performs message polling and receives a message.

The third scenario is a scenario in which seamless roaming is performed in a heterogeneous communication network. When a network error is detected, a message can be transmitted through link switching.

In step 1161, the first e-navigation service client 1113 detects a communication error in the network including the ship station gateway 1115, the VDES mobile station 1117, the VDES base station 1119, and the coast station gateway 1121. .

In step 1163, the first e-navigation service client 1113 switches links between heterogeneous communication networks. For example, when the first e-navigation service client 1113 is communicating through VDES, it may switch to LTE, or when communicating through LTE, it may switch to VDES.

In step 1165, the first e-navigation service client 1113 checks whether link switching is successful by performing communication with the management system 1125 through the switched link.

It will be appreciated that the embodiments of the present invention can be realized in the form of hardware, software, or a combination of hardware and software. Any such software may be, for example, a volatile or nonvolatile storage device such as a storage device such as a ROM, or a memory device such as a RAM, memory chip, device or integrated circuit, for example, whether erasable or rewritable. Or, for example, it may be optically or magnetically recordable, such as a CD, DVD, magnetic disk or magnetic tape, and stored in a machine (eg, computer) readable storage medium. It will be appreciated that the storage unit that may be included in the server or the terminal is an example of a machine-readable storage medium suitable for storing a program or programs including instructions for implementing the embodiments of the present invention. Accordingly, the present invention includes a program including code for implementing the apparatus or method described in any claim of the present specification, and a machine-readable storage medium storing such a program. Further, such a program may be transferred electronically through any medium, such as a communication signal transmitted through a wired or wireless connection, and the present invention suitably includes equivalents thereto.

In the above description of the present invention, specific embodiments have been described, but various modifications may be made without departing from the scope of the present invention. Therefore, the scope of the present invention should not be determined by the described embodiments, but should be determined by the equivalent of the claims and the claims.

For example, in the present invention, it has been described that the coast station gateway 209 or the ship station gateway 227 converts an HTTP-based message into a VDE message format or a VDE message into an HTTP-based message, but other devices perform this operation. Can be done. For example, the coast station base station 213 or the ship station mobile station 223 may convert an HTTP-based message into a VDE message format or a VDE message into an HTTP-based message.

101: first user
103: e-navigation service host
105: coast station gateway
107, 109, 111: VDES base stations
113: VDES network
115, 117, 119: VDES mobile stations
121, 123, 125: ship station gateways
127, 129, 131: e-navigation service clients
127, 129, 131: second to fourth users

Claims (6)

In a system for transmitting and receiving messages in a maritime wireless communication system,
A service client that generates an HTTP message related to e-navigation service and transmits it to the ship station gateway,
After removing the Ethernet header, IP header, TCP header, and CRC from the HTTP message, a gateway message is generated by combining the HTTP header and payload of the HTTP message according to the gateway message format, and the VDE message packet according to the VDE message format The gateway message is fragmented according to the payload size to generate a plurality of gateway message packets, and after each of the gateway message packets is inserted into payloads of a plurality of VDE message packets according to the VDE message format, the payloads The ship station gateway for generating a plurality of VDE message packets by adding a UDP header, an IP header, an Ethernet header and a CRC to each, and transmitting the VDE message packets to the ship station mobile station according to UDP;
Receives the VDE message packets from the ship station gateway and transmits them to the coast station base station through the VDES communication network according to the VDES wireless communication protocol, and receives VDE message packets from the coast station base station and transmits them to the ship station gateway according to the UDP. The mobile station of the ship station,
The ship station mobile station receives the VDE message packets from the ship station mobile station and transmits it to the coast station gateway according to the UDP, and receives VDE message packets from the coast station gateway through the VDES communication network according to the VDES wireless communication protocol. The coast station base station for transmitting to the base station,
A UDP header, an IP header, an Ethernet header, and a CRC are removed from each of the VDE message packets to generate payloads of the VDE message packets, and a gateway message is generated by combining the payloads according to the gateway type, and the Splitting a gateway message to generate an HTTP header and a payload, adding an Ethernet header, an IP header, a TCP header, and a CRC to the HTTP header and the payload to generate an HTTP message, and transmitting the HTTP message to the service host. The coast station gateway,
A system for transmitting and receiving a message in a maritime wireless communication system including the service host receiving and processing the HTTP message.
The method of claim 1,
The coast station gateway receives an HTTP message from the service host, removes the Ethernet header, IP header, TCP header, and CRC from the HTTP message, and then determines the HTTP header and payload of the HTTP message according to the gateway message format. It combines to generate a gateway message, and generates a plurality of gateway message packets by fragmenting the gateway message according to the payload size of the VDE message packet according to the VDE message format, and a plurality of VDE message packets according to the VDE message format. After inserting each of the gateway message packets into payloads, a UDP header, an IP header, an Ethernet header, and a CRC are added to each of the payloads to generate a plurality of VDE message packets, and the VDE message packets are added to the coast station. A system for transmitting and receiving messages in a maritime wireless communication system, characterized in that transmitting and receiving to the ship station base station through a base station.
The method of claim 2,
The ship station gateway receives the VDE message packets from the ship station mobile station, and generates payloads of the VDE message packets by removing a UDP header, an IP header, an Ethernet header and a CRC from each of the VDE message packets, The payloads are combined according to the gateway type to generate a gateway message, the gateway message is divided to generate an HTTP header and a payload, and an Ethernet header, an IP header, and a TCP header are added to the HTTP header and the payload. A system for transmitting and receiving messages in a maritime wireless communication system, comprising generating an HTTP message by adding a CRC, and transmitting the HTTP message to the service client.
In the method of transmitting and receiving a message in a maritime wireless communication system,
The process of the service client generating an HTTP message related to the e-navigation service and transmitting it to the ship station gateway,
The process of generating a gateway message by the ship station gateway removing the Ethernet header, the IP header, the TCP header, and the CRC from the HTTP message, and combining the HTTP header and the payload of the HTTP message according to the gateway message format,
The ship station gateway generating a plurality of gateway message packets by fragmenting the gateway message according to the payload size of the VDE message packet according to the VDE message format,
The ship station gateway inserts the gateway message packets into payloads of a plurality of VDE message packets according to the VDE message format, and then adds a UDP header, an IP header, an Ethernet header, and a CRC to each of the payloads. Generating a plurality of VDE message packets and transmitting the VDE message packets to a ship station mobile station according to UDP,
The process of receiving the VDE message packets by the ship station mobile station and transmitting them to the coast station base station through the VDES communication network according to the VDES wireless communication protocol,
The process of receiving, by the coast station base station, the VDE message packets and transmitting them to the coast station gateway according to the UDP,
The coast station gateway generates payloads of the VDE message packets by removing a UDP header, an IP header, an Ethernet header, and a CRC from each of the VDE message packets, and combining the payloads according to the gateway type The process of creating a message,
The coast station gateway generates an HTTP header and a payload by dividing the gateway message, and generates an HTTP message by adding an Ethernet header, an IP header, a TCP header and a CRC to the HTTP header and the payload, and the HTTP The process of transmitting the message to the service host, and
The method of transmitting and receiving a message in a maritime wireless communication system, comprising the step of receiving and processing the HTTP message by the service host.
The method of claim 4,
The process of receiving, by the coast station gateway, an HTTP message from the service host,
The coast station gateway, after removing the Ethernet header, the IP header, the TCP header and the CRC from the HTTP message, and generating a gateway message by combining the HTTP header and the payload of the HTTP message according to the gateway message format,
The coast station gateway generating a plurality of gateway message packets by fragmenting the gateway message according to the payload size of the VDE message packet according to the VDE message format,
The coast station gateway inserts the gateway message packets into payloads of a plurality of VDE message packets according to the VDE message format, and then adds a UDP header, an IP header, an Ethernet header, and a CRC to each of the payloads. To generate a plurality of VDE message packets, and
The method of transmitting and receiving a message in a maritime wireless communication system further comprising the step of the coast station gateway transmitting the VDE message packets to the ship station base station through the coast station base station.
The method of claim 5,
The process of the ship station gateway receiving the VDE message packets from the ship station mobile station,
The ship station gateway generates payloads of the VDE message packets by removing a UDP header, an IP header, an Ethernet header, and a CRC from each of the VDE message packets, and combining the payloads according to the gateway format to a gateway The process of creating a message,
The process of generating an HTTP message by the ship station gateway dividing the gateway message to generate an HTTP header and a payload, and adding an Ethernet header, an IP header, a TCP header and a CRC to the HTTP header and the payload, and
The method of transmitting and receiving a message in a maritime wireless communication system, further comprising the step of transmitting, by the ship station gateway, the HTTP message to the service client.

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