KR100716518B1 - Wireless distress signal device with gps and wireless rescue system thereof - Google Patents

Abstract

The present invention relates to a GPS wireless distress alarm and a wireless distress alarm system using the same, which is interlocked with a ship and a navigational mark communication network, the GPS wireless distress alarm interlocked with the ship and a route mark communication network, to a wireless distress alarm provided in the life jacket In the sensor, the sensor unit detects moisture and determines whether or not to acquire water, a power unit for supplying power to each component of the wireless distress alarm, a GPS receiver for receiving a satellite signal transmitted from a GPS satellite and calculating and outputting a current coordinate. Memory unit for storing the current coordinates output from the GPS receiver, a frequency for communication to transmit a distress signal, a communication unit for receiving a response message transmitted from the management station that received the distress signal and the acquisition signal from the sensor unit Is input to the GPS receiver And a main control unit for applying power and storing current coordinates output from the GPS receiver, and generating and transmitting a distress signal by combining the current coordinates and an identification code. It is interlocked with GPS wireless distress alarm.

According to the GPS wireless distress alarm interlocked with the ship and the route mark communication network according to the present invention, by accurately grasp the current position of the distress and transmit the distress signal, it is possible to quickly and accurately rescue the distress, and minimize the power consumption of the radio distress alarm The distress signal can be transmitted for a long time, and the reception rate of the distress signal can be improved by shifting the crest and the distress signal transmission period.

In addition, according to the wireless distress alert system according to the present invention, by using the wireless distress alert relay device and the route marking system, even when the distress in the offshore as well as the distress occurred in the distress signal to the management station to quickly and accurately rescue work There is an advantage that can be made.

GPS, wireless distress alarm, wireless distress alarm system, life jacket

Description

GPS distress alarm system interworking with ship and route marking network and wireless distress alarm system using same {Wireless distress signal device with GPS and Wireless rescue system

1 is a block diagram of a wireless distress alert system according to an embodiment of the present invention.

Figure 2 is a block diagram showing the configuration of a radio distress alarm according to an embodiment of the present invention.

Figure 3 is a flow chart showing the operation of the radio distress alarm according to an embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

100: radio distress alarm 110: GPS satellite

120: radio distress alarm relay device 130: management station

140: Route marker station 150: Route marker station

170: Ship identification system 172: Ship identification system

180: Ship location information service country 184: Ship location information service country

The present invention relates to a GPS wireless distress alarm and a wireless distress alarm system using the same, and more specifically, to receive the information transmitted from the GPS satellites to calculate the exact current coordinates of the distress and use it The present invention relates to a wireless distress alarm using a GPS capable of transmitting a distress signal and a wireless distress alarm system using the same.

On the ground, disaster reporting and quick life-saving systems, such as 119 rescue, are well-used. On the other hand, survivors who are distressed at sea have very low survival rates over time due to rapid temperature drops. In particular, the distress reporting system is not established at sea, where the rapidity of rescue is required due to nighttime, bad weather, or sea current movement, and even if it is reported, it is difficult to determine the position of the distress on the scene. There was a problem of being very poor.

In connection with a positioning system related to marine distress according to the prior art, a vessel position information service or an automatic vessel identification device has been proposed.

In the case of Vessel Monitoring Service, the position and movement route of the vessel can be checked from the office PC through the Internet, and the service is configured through the VMS server and the terrestrial earth station. Since the information can be taken from the ship, the ship's position can be replaced manually by fax or telex, and the data can be accumulated and managed in the VMS server.

In addition, the Automatic Identification System is an automatic identification system of navigation information such as the specification, location, and track of a ship during navigation.It is a passenger ship of 150 tons or more, an outer ship of 300 tons and an inner port of more than 500 tons, and a fishing boat of more than 45 meters in length. It should be installed on the waste carrier, dangerous goods carrier, etc. and have high power equipment in VHF band.

However, the positioning system according to the prior art has a problem that it is irrelevant to the rescue of life as its object is limited to the ship, not the life, and also has a problem of having a high power radio equipment and a complex system associated with lifesaving. There was a problem that the technology could not be applied.

The present invention, in order to solve the problems of the prior art as described above, the GPS wireless distress alarm and the above-described GPS wireless distress alarm that can be transmitted to the distress signal by accurately calculating the current coordinates of the distress using the GPS satellite signal An object of the present invention is to provide a wireless distress alarm system capable of efficiently receiving a distress signal transmitted from a distress alarm and performing a quick and accurate lifesaving.

In order to achieve the above object, according to a preferred embodiment of the present invention, in the radio distress alarm provided in the life jacket,

A sensor unit for sensing moisture to determine whether or not to ripen; A power supply unit supplying power to each component of the wireless distress alarm; A GPS receiver which receives a satellite signal transmitted from a GPS satellite and calculates and outputs a current coordinate; A memory unit for storing current coordinates output from the GPS receiver; A communication unit configured to set a frequency for communication to transmit a distress signal and to receive a response message transmitted from the management station that has received the distress signal; And when the distress signal is input from the sensor unit, supply power to the GPS receiver, store the current coordinate output from the GPS receiver, and generate and transmit a distress signal by combining the current coordinate and the identification code. Provided is a GPS wireless distress alarm interlocked with a ship and a route mark communication network comprising a main fisherman.

In addition, in order to achieve the above object, according to another preferred embodiment of the present invention, in the wireless distress alarm system using GPS,

A radio distress alarm using a GPS to determine whether distress is provided in a life jacket and to calculate a current coordinate by receiving a signal transmitted from a GPS satellite when a distress occurs, and to generate and transmit a distress signal using the current coordinate; At least one radio distress provided on an island or a sea buoy or lighthouse, which receives distress signals transmitted from the radio distress alarm and / or another radio distress alarm relay device and transmits the distress signals to other radio distress alarm relay devices and / or management stations. Alarm repeater; And a management station for receiving, storing and displaying distress signals transmitted from the radio distress alarm or the wireless distress alert relay device, and generating and transmitting a response message to the distress signal. Provided is a GPS wireless distress alert system that works with.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the GPS radio distress alarm and a wireless distress alarm system using the same and interlocked with the ship and the route marker communication network according to the present invention.

1 is a block diagram showing the configuration of a radio distress alarm system according to an embodiment of the present invention, Figure 2 is a block diagram showing the configuration of a radio distress alarm according to an embodiment of the present invention.

With reference to the accompanying drawings will be described in detail with respect to the radio distress alarm using a PS and a wireless distress alarm system using the same.

As shown in FIG. 1, the wireless distress alert system according to the preferred embodiment of the present invention includes a GPS satellite 110, a wireless distress alert 100, a wireless distress alert relay device 120, and a management station 130. It may include.

The wireless distress alarm 100 is provided in the life jacket to determine whether the person wearing the life jacket is distressed, and when the distress occurs, the signal received from the GPS satellite 110 to calculate the current coordinates, then The distress signal is generated and transmitted using the coordinates. The distress signal may be configured to be transmitted through various wireless communication methods, and more preferably, may be configured to be transmitted using RFID. When the distress signal is transmitted using RFID, the distress signal can be transmitted for a long time with low power. The detailed configuration of the wireless distress alarm 100 according to the present invention will be described later with reference to FIG. 2.

The radio distress alarm relay device 120 is provided on an island or a sea buoy or lighthouse, and receives the distress signal transmitted from the radio distress alarm 100 and / or another radio distress alarm relay device 120 to relay another radio distress alarm relay. Device 120 and / or management station 130. The wireless distress alert relay device 120 is installed to ensure a smooth distress signal reception rate even in a region where the distance between the wireless distress alarm 100 and the management station 130 is far or impossible to secure the visible distance on the terrain. The wireless distress alert relay device 120 according to the present invention is configured to perform wireless communication in the same manner as the wireless communication protocol adopted by the wireless distress alarm 100 and the management station 130. That is, when the wireless distress alarm 100 and the management station 130 performs wireless communication using RFID, the wireless distress alarm relay device 120 according to the present invention is a communication unit capable of performing wireless communication using RFID ( Not shown). In addition, the wireless distress alarm relay device 120 according to the present invention is provided with a power supply (not shown) that is charged by receiving power from a solar self-generation unit (not shown) and a solar self-generation unit using the solar light relay You can keep it functioning.

In addition, the wireless distress alert system according to the present invention may include at least one or more wireless distress alert relay device 120 to transmit the distress signal transmitted from the wireless distress alert 100 to the management station 130 without restriction on the distance. It can be configured to be.

The management station 130 receives, stores and displays a distress signal transmitted from the wireless distress alarm 100 or the wireless distress alarm relay device 120 and generates and transmits a response message to the distress signal. More specifically, the management station 130 according to the present invention is a kind of management server managing a distress management system, a communication unit (not shown) for receiving a distress signal, a network communication unit (not shown) for performing data communication through the Internet. ), An operating program for operating the management station is stored, a memory unit (not shown) used as a temporary storage space of data generated during the operation of the management station, various information generated during the operation of the management station A display unit (not shown) for displaying, a storage unit (not shown) for storing various kinds of information, and a main control unit (not shown) for controlling each component described above and operating a management station. The configuration and function of each of the above-described components adopts the prior art, and further detailed description thereof will be omitted.

Since the distress signals transmitted from the wireless distress alarm 100 are weak signals transmitted from a very long distance, the management station 130 detects three high gain antennas (12 dB or more Yagi antenna, not shown) at 120 degree intervals. It is arranged to receive the weak transmission signal regardless of the 360 degree direction. The management station 130 receives the distress signal composed of the encrypted data packet, solves the encrypted data packet, performs the Manchester decryption process and the error correction process, and continuously displays and stores the time at which the distress signal was received. At the same time, the management station 130 generates a response message for the distress signal and sends it to the wireless distress alarm 100 to psychologically stabilize the distress, generate an alarm and activate the event window to notify the person in charge that the distress signal has been received. Let go. In this case, the management station 130 displays the corresponding identification code and each reception time in the distress point coordinates on the sea map through a display unit (not shown).

In addition, the management station 130 according to the present invention receives the distress signal transmitted from the wireless distress alarm 100 or the wireless distress alert relay device 120, and then using the interworking communication network (mobile communication network, wired communication network) It may be configured to notify the administrator of the reception of the distress signal.

In addition, the wireless distress alert system according to the present invention may further include a route marker station 140 and a route marker station 150.

The route marker station 140 receives the distress signal transmitted from the wireless distress alarm 100, converts the received distress signal into the VHF band, and transmits the distress signal to the route mark mother station 150. The distress signal transmitted from the route marker station 140 is received, and the received distress signal is transmitted to the management station 130 connected through the Internet 160.

The wireless distress alert system according to the present invention is capable of direct communication between a transmitter and a receiver within an area of 10 km from the shoreline, and interlocks with existing marine facilities to ensure a smooth distress signal reception rate even at a distance between 10 km and 50 km from the coastline. It may be configured to receive a random signal. That is, it is possible to receive a distress signal transmitted from the radio distress alarm 100 to a station (corresponding to a sea buoy, a lighthouse) of a "path mark intensive management system" that displays a route of ships moving at sea and manages a mark. After receiving the distress signal transmitted from the wireless distress alarm 100 by adding a communication unit (not shown, if the wireless distress alarm 100 and the management station 130 is configured to communicate by RFID method) It may be configured to convert to the VHF band to be transmitted to the route marker station 150.

The route marker station 150 is connected to the management station 130 through the Internet 160, and receives the distress signal transmitted from the route marker station 150 and transmits the distress signal to the management station 130.

In addition, the wireless distress alert system according to the present invention can be configured to receive a distress signal in conjunction with the existing system in order to ensure a smooth distress signal reception rate even at a medium distance between 50km ~ 100km from the coastline. That is, the distress signal transmitted from the wireless distress alarm 100 to the ship Automatic Identification System (AIS) station 170, which is a device for automatic recognition of navigation information such as the specification, location, and track of the ship during navigation of the ship The communication unit (not shown, if the wireless radio distress alarm 100 and the management station 130 is configured to communicate by RFID method, which can be received by adding a RFID receiver) is transmitted from the wireless radio distress alarm 100 After receiving the distress signal, it may be configured to convert to the VHF band to be transmitted to the vessel automatic identification device station 172.

The vessel ID system 172 is connected to the management station 130 through the Internet 160, and receives the distress signal transmitted from the vessel ID 170 and transmits the distress signal to the management station 130. .

In addition, the wireless distress alert system according to the present invention can be configured to receive a distress signal in conjunction with the existing system to ensure a smooth distress signal reception rate even at a distance between 100km ~ 300km from the coastline. That is, the distress signal transmitted from the wireless radio distress alarm 100 is received to the station 180 of the Vessel Monitoring Service (VMS), which can confirm the position and the movement route of the vessel from the office PC through the Internet. Distress signal transmitted from the wireless distress alarm 100 by adding a communication unit (not shown, if the wireless wireless distress alarm 100 and the management station 130 is configured to communicate in an RFID manner, RFID) After receiving the distress signal may be configured to transmit to the ship location information service station 184 via the communication satellite 182.

The ship location information service mother station 184 located in the satellite ground station is connected to the management station 130 through the Internet 160 and transmits a distress signal transmitted from the ship location information service station 180 through the communication satellite 182. It receives and transmits to the management station 130.

As shown in FIG. 2, the wireless distressing view according to the preferred embodiment of the present invention includes a sensor unit 202, a power unit 204, a GPS receiver 206, a memory unit 210, a communication unit 208, and the like. The main control unit 200 may include.

The sensor unit 202 detects water and judges whether or not to learn whether or not to learn whether or not to drown, if the person wearing the life jacket is distressed, the sensor signal 202 is output, the sensor unit 202 according to the present invention has two electrodes 180 inside the tube It is arranged in the direction of the water is configured so that water can be detected only through the inside of the tube. Therefore, it is configured to output a signal by more accurately judging whether or not. Of course, it will be apparent to those skilled in the art that the present invention may be configured to output a signal by determining whether or not the distress of a distress wearing a life jacket is used by using various known techniques.

The power supply unit 204 supplies power to each component of the wireless distress alarm 100 (GPS receiver 206, communication unit 208, etc.) under the control of the main control unit 200, It may be composed of a battery. The main control unit 200 according to the present invention supplies power by controlling the power supply unit 204 using a power management algorithm devised to maximize the life of the wireless distress alarm 100. The characteristic power management algorithm according to the present invention will be described later.

The GPS receiver 206 receives the satellite signal transmitted from the GPS satellite 110 to calculate and output the current coordinates of the distress. Since the technology related to the GPS receiver 206 adopts a known technology, a detailed description thereof will be omitted.

The memory unit 210 is configured as a nonvolatile memory (ROM, Read Only Memory), and stores the current coordinates output from the GPS receiver 206.

The communication unit 208 transmits a distress signal generated by the main control unit 200 by setting a frequency for communication, and receives a response message transmitted from the management station 130 that receives the distress signal. The communication unit 208 may be implemented to perform wireless communication using various communication methods that are already commercially available, but more preferably, may be implemented to perform wireless communication using RFID.

The main control unit 200 receives a drowning signal from the sensor unit 202 (a 'swing signal' means a signal output from the sensor unit 202 when a distressed person wearing a life jacket is distressed). Power is applied to the 206 to store the current coordinates output from the GPS receiver 206 to the memory unit, and generates and transmits a distress signal by combining the current coordinates and the identification code.

More preferably, the main control unit 200 according to the present invention is configured to control the power supply unit 204 according to the power management algorithm of the present invention for more efficient power management.

When the battery is initially connected, the main control unit 200 operates in a power save mode and periodically monitors only whether the submerged signal is input from the sensor unit 202 with minimal power. When the learning signal is input from the sensor unit 202, the main control unit 200 is switched from the power saving mode to the working mode.

When the operation mode is switched, the main control unit 200 turns off all power except the GPS receiver 206, turns on only the power of the GPS receiver 206, and inputs normal coordinates from the GPS receiver 206. Wait until Here, the normal coordinates refer to coordinates when the 19th character of the GPRMC code is “A”, and the main control unit 200 determines the coordinates inputted from the receiving unit (G) in GS, and when the normal coordinates are input, the normal coordinates are stored in the memory unit. Immediately after storing in 210, the power of the GPS receiver 206 is turned off.

Next, the main control unit 200 applies a power to the communication unit 208 to set the frequency to activate the TCXO (not shown) and PLL (not shown) to set the frequency for communication, and after the frequency is set, the memory unit ( The first distress signal encrypted by BCH3121 and the Manchester method is transmitted by combining the normal coordinate value and the identification code (identification code is preset as a key value unique to the radio distress alarm) stored in 210.

Further, more preferably, the main control unit 200 according to the present invention waits for 1 second after transmitting the first distress signal, and if there is no response, switches to the power saving mode for 6 seconds, and 6 seconds (waiting time, which minimizes power consumption). After waiting for the power saving mode, the power of the GPS receiver 206 is turned on again to take normal coordinates, and then the above-described distress signal generation and transmission process is repeated. Will be performed. In this case, each time the number of distress signals are increased, the distress signal may be transmitted after increasing the waiting time in the power saving mode after transmitting the distress signal. In other words, when the first distress signal is transmitted and no response message is received within 1 second, after waiting for power saving mode for 6 seconds, the operation mode is changed again, and the second distress signal is transmitted and the response message is not received within 1 second. After waiting for 7 seconds in the power saving mode, the operation mode may be configured to regenerate and transmit a distress signal.

In addition, the main control unit 200 according to the present invention may be configured to efficiently transmit a distress signal according to the period of crest. If the time and crest of distress signal transmission are the lowest, the probability of communication success is low. Therefore, irregular transmission period is arbitrarily set so as to increase communication success rate. As a concrete method, distress signals are transmitted three times at an interval of one second, and after waiting for power saving mode for six seconds, new satellite signals are transmitted after satellite coordinates are taken (irregular depending on the environment and angle from 2 to 30 seconds). In this way, it is possible to make the transmission period of the distress signal and the period of wave height inconsistent by repeating infinite transmission.

3 is a flowchart illustrating the operation of the radio distress alarm according to an embodiment of the present invention.

With reference to the accompanying Figure 3 will be described in detail the process of operating a wireless distress alarm system using a wireless distress alarm and a wireless distress alarm according to an embodiment of the present invention.

The wireless distress alarm 100 normally consumes minimal power in the power saving mode in the normal state (ie, the state in which no ripening signal is output from the sensor unit 202) and determines only whether the ripening signal is output from the sensor unit 202. I'm doing it. If a person wearing a life jacket is distressed, the sensor unit 202 detects this and outputs a drowning signal (S300).

When the master part 200 is input from the sensor unit 202, the main control unit 200 switches from the power saving mode to the working mode, turns off all the power except the GPS receiver 206, and the GPS receiver 206. ) ON only and wait until normal coordinates are input from the GPS receiver 206 (S302).

The main control unit 200 determines whether the coordinates input from the GPS receiver 206 are normal coordinates (S304), and when the GS coordinates are input, the normal controller 200 stores the normal coordinates in the memory 210 immediately after receiving the GS coordinates 206. Cut off the power (S306).

Next, the main control unit 200 applies a power to the communication unit 208 to set the frequency to activate the TCXO (not shown) and PLL (not shown) to set the frequency for communication, and after the frequency is set, the memory unit ( Combination of normal coordinate value and identification code (identification code is preset as a unique key value for radio distress alarm) stored in 210) to transmit the first distress signal encrypted by BCH3121 and Manchester method and then received to receive a response message. Wait (S308).

When the main control unit 200 receives the response message transmitted from the management station 130, the main control unit 200 outputs the response message and ends the step (S318).

On the other hand, when the main control unit 200 does not receive a response message from the management station 130 within the waiting time for receiving, the main control unit 200 is switched to the power saving mode to consume the power consumption of each component in the wireless distress alarm 100. Minimize (S312).

After switching to the power saving mode, the main controller 200 determines whether the waiting time has elapsed (S314), and if the waiting time has elapsed, increases the setting of the waiting time and again performs steps S302 to S314 again (S316). ).

Preferred embodiments of the present invention described above are disclosed for purposes of illustration, and those skilled in the art will be able to make various modifications, changes and additions within the spirit and scope of the present invention. Additions should be considered to be within the scope of the following claims.

As described above, according to the GPS wireless distress alarm and the wireless distress alert system using the same according to the present invention, the ship and the route mark communication network accurately detect the current position of the distress and transmit the distress signal quickly and accurately. The advantage is that you can.

In addition, according to the present invention has the advantage that the distress signal can be transmitted for a long time by minimizing the power consumption of the wireless distress alarm.

In addition, the present invention has the advantage that the reception rate of the distress signal can be improved by shifting the crest and the distress signal transmission period.

In addition, according to the present invention, there is an advantage that the distress signal can be sent to the management station quickly and accurately by using the wireless distress alarm relay device and the route marking system, even when the distress accident occurs in the coast as well as the offshore.

Claims (12)

In the wireless distress alarm provided in the life jacket, A sensor unit for sensing moisture to determine whether or not to ripen; A power supply unit supplying power to each component of the wireless distress alarm; A GPS receiver which receives a satellite signal transmitted from a GPS satellite and calculates and outputs a current coordinate; A memory unit for storing current coordinates output from the GPS receiver; A communication unit configured to set a frequency for communication to transmit a distress signal and to receive a response message transmitted from the management station that has received the distress signal; And The main control unit supplies power to the GPS receiver when the learning signal is input from the sensor unit, stores the current coordinates output from the GPS receiver, and generates and transmits a distress signal by combining the current coordinates and the identification code. Including wealth, The main control unit determines whether the normal coordinates are output from the GPS receiver, and stores the normal coordinates output from the GPS receiver in the memory only when the normal coordinates are output, and generates a distress signal by combining the current coordinates and the identification code. GPS wireless distress alarm interlocked with the ship and the route marker network, characterized in that for transmitting. delete The method of claim 1, The main control unit is kept in a power saving mode until the learning signal is input from the sensor unit, and when the learning signal is input from the sensor unit, the main control unit switches to an operation mode to supply power only to the GPS receiver and cut off power supply to other components. When the normal coordinates are output from the GPS receiver, the power is applied to the other GPS receiver, and then power is applied to each component to generate and transmit a distress signal. GPS wireless distress alarm. The method of claim 3, The main control unit is a GPS wireless distress alarm interlocked with a ship and a route mark communication, characterized in that for transmitting the distress signal three times at 1 second intervals. The method of claim 4, wherein If the main control unit does not receive the response message within 1 second after transmitting the distress signal, the main controller waits for 6 seconds in the power saving mode and then switches to the operation mode, applies power to the GPS receiver, regenerates the distress signal by receiving a new normal coordinate, GPS wireless distress alarm interlocked with a ship and a route mark network, characterized in that for transmitting the regenerated distress signal. The method of claim 5, When the main control unit does not receive a response message within 1 second after transmitting the regenerated distress signal, the main control unit waits by adding a predetermined time to the standby time of the power saving mode before switching to the operation mode. GPS wireless distress alarm works with. In the wireless distress alarm system using GPS, It is provided with life jackets to determine whether distress exists, and in the event of a distress, it receives signals transmitted from GPS satellites to calculate the current coordinates, and then interlocks with ships and route marker communication networks that generate and transmit distress signals using the current coordinates. GPS wireless distress alarm; At least one radio distress provided on an island or a sea buoy or lighthouse, which receives distress signals transmitted from the radio distress alarm and / or another radio distress alarm relay device and transmits the distress signals to other radio distress alarm relay devices and / or management stations. Alarm repeater; And And a management station for receiving, storing, and displaying a distress signal transmitted from the wireless distress alarm or the wireless distress alert relay device, and generating and transmitting a response message to the distress signal. The wireless distress alarm determines whether the normal coordinates are output from the GPS receiver, and stores the normal coordinates output from the GPS receiver only in the memory unit when the normal coordinates are output, and combines the current coordinates and the identification code to generate a distress signal. GPS wireless distress alert system interlocked with the ship and the route marker network, characterized in that for generating and transmitting. The method of claim 7, wherein The wireless distress alert relay device is a GPS wireless distress alert system that is interlocked with the ship and route marker communication network, characterized in that it comprises a solar self-power generation unit. The method of claim 7, wherein The radio distress alarm is a GPS distress alarm system interlocked with the ship and route marker communication network, characterized in that the wireless distress alarm according to any one of claims 1 to 6. The method of claim 7, wherein The wireless distress alert system, A route marker station that receives a distress signal transmitted from the radio distress alarm, converts the received distress signal into a VHF band, and transmits the distress signal to a route mark mother station; And GPS wireless interworking with the vessel and the route mark communication network further comprising a route mark station for receiving a distress signal transmitted from the route mark station and transmitting the received distress signal to the management station connected through an internet network. Distress Alert System. The method of claim 7, wherein The wireless distress alert system, A ship automatic identification device station which receives a distress signal transmitted from the radio distress alarm and converts the received distress signal into a VHF band and transmits the distress signal to a ship automatic identification device mother station; And And a ship automatic identification device mother station which receives a distress signal transmitted from the ship automatic identification device station and transmits the received distress signal to the management station connected through an internet network. GPS wireless distress alert system that works with. The method of claim 7, wherein The wireless distress alert system, A ship location information service station provided on the ship to receive a distress signal transmitted from the radio distress alarm, converting the received distress signal into a satellite signal and transmitting the distress signal to a communication satellite; A communication satellite receiving a distress signal transmitted from the ship location information service station and transmitting the distress signal to a ship location information service mother station; And GPS interworking with the vessel and the route mark communication network, further comprising a ship location information service mother station for receiving a distress signal transmitted from the communication satellite and transmitting the received distress signal to the management station connected through an internet network. Wireless Distress Alert System.

Images