KR102313034B1 - Underwater communication apparatus and id transmitting and receiving method thereof - Google Patents

Abstract

Disclosed are an underwater communication apparatus and an ID transmitting and receiving method thereof. The underwater communication apparatus according to the present invention includes: a synchronization signal generating unit which generates a frame synchronization signal for obtaining synchronization of a receiving end when transmitting ID data; a data generating unit which uses the ID of the underwater communication apparatus as a spreading code and generates a frame check sequence (FCS) corresponding to the data of the spreading code in the form of data; and an ID data transmitting unit which connects the FCS generated by the data generating unit to the frame synchronization signal generated by the synchronization signal generating unit to form a frame, and transmits the formed frame as ID data. According to the present invention, a plurality of underwater communication apparatuses can transmit data at the same frequency by using a code division method in the water, while transmitting data without limiting a transmission start time of the data.

Description

UNDERWATER COMMUNICATION APPARATUS AND ID TRANSMITTING AND RECEIVING METHOD THEREOF

The present invention relates to an underwater communication device and a method for transmitting and receiving an ID thereof, and more particularly, using a code division method in the water, a plurality of underwater communication devices can transmit data at the same frequency while transmitting data without limitation at the start time of data transmission In addition, the present invention relates to an underwater communication device capable of reducing power consumption by minimizing the data transmission time, and transmitting data for a longer period of time with a small amount of power, and an ID transmission/reception method thereof.

With the development of digital electronic devices and communication technology, underwater communication devices are installed in fish, fishermen, nets, and equipment installed in the water, and by using information communication between underwater communication devices, fish distribution monitoring, underwater accident recovery, underwater It became possible to monitor lifesaving and underwater situation judgment.

Such underwater communication devices are each given a unique ID (identity), and the transmitting end includes its ID in the transmitted signal and transmits it, and the receiving end selects each transmitting end based on the IDs of signals received from a plurality of transmitting ends. should be able to distinguish

At this time, a general underwater communication device transmits and receives signals wirelessly, and in order to prevent signals transmitted and received between a plurality of underwater communication devices from interfering with each other, ID signals are transmitted using different frequencies between each underwater communication device. Transmits/receives or transmits and receives ID signals at different times.

However, in the case of an underwater wireless communication system that transmits a signal using sound waves in the water, the usable frequency is limited, and in order for each underwater communication device to transmit a signal at different times, the synchronization of all underwater communication devices is required. There is a problem in that the complexity of the underwater communication system is greatly increased because it must be correct.

In addition, a general underwater communication device needs to have its own battery due to the nature of the environment in which it is used. Since the transmission time of ID data is long, there is a problem in that the battery must be frequently replaced because of the large amount of power consumed.

Registered Patent Publication No. 10-2226408 (Registration Date: 2021.03.05)

The present invention has been devised to solve the above-described problems, and by using a code division method in the water, a plurality of underwater communication devices can transmit data at the same frequency while transmitting data without limitation at the start time of data transmission, and the data transmission An object of the present invention is to provide an underwater communication device capable of reducing power consumption by minimizing time, and transmitting data for a longer period of time with a small amount of power, and an ID transmission/reception method thereof.

Underwater communication device according to an aspect of the present invention for achieving the above object, when transmitting ID (identity) data, an underwater communication device comprising a synchronization signal generator for generating a frame synchronization signal for obtaining synchronization of the receiving end In the following, the ID of the underwater communication device as a spreading code, the data generation unit for generating the FCS (Frame Check Sequence) corresponding to the data of the spreading code as data; and an ID data transmitter configured to directly connect the FCS generated by the data generator to the frame sync signal generated by the sync signal generator to form a frame structure, and transmit the formed frame structure. characterized.

The above-described underwater communication apparatus includes: a synchronization search unit for searching for frame synchronization based on a frame synchronization signal of a frame received from a transmitter; a despreading unit for performing despreading using a plurality of spreading codes included in the received frame; and a transmitting end determining unit that determines the ID of the transmitting end based on the performed despreading.

The above-described underwater communication apparatus may further include a redundancy check performing unit that performs a cyclic redundancy check by using a result of the despreading performed by the despreading unit as an FCS. In this case, the transmitting end determining unit determines the spreading code included in the received frame as the ID of the transmitting end when it is determined that there is no error in the spreading code included in the received frame by the redundancy check performing unit.

The above-described underwater communication device includes: a pilot adding unit for adding a pilot signal to at least one of a front end and a rear end of the FCS generated by the data generating unit among the frames formed by the ID data transmitting unit; may include

ID transmission/reception method according to an aspect of the present invention for achieving the above object is performed by an underwater communication device, generating a frame synchronization signal for obtaining synchronization of a receiving end when transmitting ID (identity) data; An ID transmission/reception method comprising: using the ID of the underwater communication device as a spreading code, and generating as data a Frame Check Sequence (FCS) corresponding to the data of the spreading code; and forming a frame structure by directly connecting the FCS to the frame synchronization signal, and transmitting the formed frame structure.

The above-described ID transmission/reception method includes: searching for frame synchronization based on a frame synchronization signal of a frame received from a transmitter; performing despreading using a plurality of spreading codes included in the received frame; and determining the ID of the transmitting end based on the performed despreading.

The above-described ID transmission/reception method may further include performing a cyclic redundancy check using the result of the despreading performed by the despreading step as the FCS. In this case, in the step of determining the ID of the transmitting end, when it is determined that there is no error in the spreading code included in the received frame by performing the cyclic redundancy check, the spreading code included in the received frame is It is determined by the ID of the transmitting end.

The above-described ID transmission/reception method may further include adding a pilot signal to at least one of a front end and a rear end of the FCS among the transmitted ID data frames.

According to the present invention, a plurality of underwater communication devices can transmit data at the same frequency while transmitting data at the same frequency using the code division method in the water without limiting the transmission start time of the data.

In addition, according to the present invention, power consumption can be reduced by minimizing the data transmission time, and data can be transmitted for a longer period of time with a small amount of power.

1 is a view showing an example of an underwater communication network system to which an underwater communication device according to an embodiment of the present invention is applied.
2 is a diagram schematically showing the configuration of an underwater communication device according to an embodiment of the present invention.
3 is a diagram illustrating an example of a frame structure for general ID transmission.
FIG. 4 is a diagram illustrating a method of transmitting an ID for itself generally using a code division method.
5 is a diagram illustrating an ID transmission method according to an embodiment of the present invention.
FIG. 6 is a diagram illustrating an example of a method of transmitting a pilot signal by adding a pilot signal in FIG. 5 .
7 is a flowchart illustrating an ID transmission/reception method according to an embodiment of the present invention.

Hereinafter, some embodiments of the present invention will be described with reference to exemplary drawings. In describing the reference numerals for the components of each drawing, the same components are denoted by the same reference numerals as much as possible even if they are displayed on different drawings. In addition, in describing the embodiment of the present invention, if it is determined that a detailed description of a related known configuration or function interferes with the understanding of the embodiment of the present invention, the detailed description thereof will be omitted.

In addition, in describing the components of the embodiment of the present invention, terms such as first, second, A, B, (a), (b), etc. may be used. These terms are only for distinguishing the components from other components, and the essence, order, or order of the components are not limited by the terms. When it is described that a component is “connected”, “coupled” or “connected” to another component, the component may be directly connected, coupled, or connected to the other component, but the component and the other component It should be understood that another element may be “connected”, “coupled” or “connected” between elements.

1 is a view showing an example of an underwater communication network system to which an underwater communication device according to an embodiment of the present invention is applied.

Referring to FIG. 1 , the underwater communication devices 10 and 20 according to an embodiment of the present invention may be implemented as a centrally controlled underwater communication network system. That is, a plurality of underwater communication devices are installed to be fixed or movable, operate as the sensor node 10 , and may transmit/receive data to and from the central node 20 . In this case, the central node 20 may transmit data collected from the plurality of sensor nodes 10 to a terrestrial network (not shown).

However, the underwater communication device according to the embodiment of the present invention is not limited to the centrally controlled underwater communication network system and can be applied to any underwater communication system capable of one-to-many communication.

2 is a diagram schematically showing the configuration of an underwater communication device according to an embodiment of the present invention.

2, the underwater communication device 100 according to the embodiment of the present invention is a synchronization signal generation unit 102, data generation unit 104, ID data transmission unit 106, synchronization search unit 108, It may include a despreading performing unit 110 , a transmitting end determining unit 112 , a redundancy checking performing unit 114 , and a pilot adding unit 116 .

The synchronization signal generating unit 102 generates a frame synchronization signal for obtaining synchronization of the receiving end when the ID (identity) data is transmitted. Here, the frame synchronization signal is a specific bit or pattern inserted so that the receiving end can identify the start position and the end position of the frame, and follows a known method, and a detailed description thereof is omitted here.

The data generation unit 104 uses the ID of the underwater communication device 100 as a spreading code, and generates FCS corresponding to the data of the spreading code as data. Here, the spreading code refers to a code multiplied by an information signal for the purpose of spreading a bandwidth in a spread-band communication method.

The ID data transmission unit 106 forms a frame by connecting the FCS generated by the data generation unit 104 to the frame synchronization signal generated by the synchronization signal generation unit 102, and transmits the formed frame.

In general, as shown in FIG. 3, the frame structure for transmitting ID transmits a frame sync signal (frame sync.) for obtaining synchronization at the receiving end, transmits data corresponding to each communication device, and transmits ID data. After , FCS (Frame Check Sequence) corresponding to each ID data is transmitted. Here, the FCS is for the receiving end to check whether there is an error in the ID data received from the transmitting end, and corresponds to the Cyclic Redundancy Check (CRC) method for checking the presence or absence of errors in the data received from the transmitting end in digital communication. . In this case, the FCS is a code that causes the remainder to be 0 when the receiving end divides the data received from the transmitting end into a predetermined pattern.

When a communication device using a general code division method transmits ID data for itself, as shown in FIG. 4 , the communication device spreads the ID data using its own spreading code and transmits it. At this time, when the ID data is n bits, the FCS is k bits, and the processing gain is m chips, the data of the transmission signal excluding the frame synchronization signal is (n+k) x m chips. become chips. That is, during this period, the transmitting end must continue to transmit a signal. Here, the chip refers to a very fast signal waveform used to spread a digital symbol in the frequency domain, and is a pulse of each spreading code waveform, and is distinguished from a data bit.

In contrast, as shown in FIG. 5 , the data generation unit 104 uses the ID of the underwater communication device 100 as a spreading code and generates FCS corresponding to each spreading code data as data, the generated data is It becomes a kxn chip.

The ID data transmitter 106 forms a frame by connecting the FCS generated by the data generator 106 to the frame synchronization signal, and transmits the formed frame, thereby spreading the ID data and the FCS to form a frame. The amount of data in a frame to be transmitted can be significantly reduced compared to .

For example, if the ID is 16 bits, the gain of the spreading code is 16 chips, and the FCS is 8 bits, if the ID data is transmitted according to the general method, except for the frame synchronization signal (16 bits + 8 bits) x 16 chips = a data amount of 384 chips must be transmitted.

However, according to the embodiment of the present invention, if the ID is used as the spreading code and the FCS corresponding to the data of the spreading code is transmitted, only 16 chips x 8 bits = 128 chips need to be transmitted, so the amount of transmitted data is 1/3 decreases to

Power consumed during signal transmission in underwater communication accounts for one of the largest power consumption. Therefore, if the signal transmission time is reduced, the signal can be transmitted for a long time even with a battery of the same capacity. That is, when an underwater communication device in the water periodically transmits its ID, compared to general signal transmission, if the amount of data transmission is reduced by 1/3, the battery consumption is reduced by that amount, resulting in more time with the same capacity battery. can be used while Such a configuration and function can be used to find IDs of different communication devices even on land rather than underwater.

When the underwater communication device 100 operates as a receiving end, the synchronization search unit 108 searches for frame synchronization based on a frame synchronization signal of a frame received from the transmitting end. That is, the synchronization search unit 108 identifies the start position and the end position of the frame based on the frame synchronization signal received from the transmitter. A method for the synchronization search unit 108 to search for frame synchronization based on the frame synchronization signal may use a known technique, and a detailed description thereof will be omitted herein.

The despreading unit 110 performs despreading using a plurality of spreading codes included in the frame received from the transmitting end, and the transmitting end determining unit 112 performs despreading performed by the despreading unit 110 based on the ID of the transmitter.

At this time, since the transmitting end uses its ID as the spreading code and transmits the FCS corresponding to the spreading code as data, the despreading unit 110 can use the despreading result for the frame received from the transmitting end as the FCS. have.

The redundancy check performing unit 114 performs a cyclic redundancy check by using the result of the despreading performed by the despreading performing unit 110 as an FCS. In this case, the redundancy check performing unit 114 determines whether or not there is an error in the received frame according to whether the remainder becomes 0 when the result of the despreading is divided into a predetermined pattern, and there is an error in the frame. When it is determined that there is no FCS, the number of bits of the FCS is known based on the frame synchronization signal, so the spreading code of the frame calculated by dividing the total number of chips in the frame by the number of bits of the FCS can be determined as the ID of the transmitter. In this case, when the result of despreading is divided into a predetermined pattern, there may be a plurality of frame spreading codes whose remainder is 0. That is, there may be a plurality of frame spreading codes that are determined to have no error in the cyclic redundancy check. In this case, it is preferable that the redundancy check performing unit 114 determines the respective frame spreading codes as IDs of a plurality of different transmitting terminals.

The pilot adding unit 116 places a pilot in at least one of the front end of the FCS data generated by the data generating unit 104, the middle of the FCS data, and the rear end of the FCS data, among the frames formed by the ID data transmitting unit 106 . Add a (pilot) signal. That is, when the underwater communication device 100 operates as a transmitting end, the pilot adding unit 116 applies a pilot signal to at least one of the front end of the FCS data, the middle of the FCS data, and the rear end of the FCS data, as shown in FIG. 6 . can be added Such a pilot signal may be used for channel estimation or compensation at the receiving end.

7 is a flowchart illustrating an ID transmission/reception method according to an embodiment of the present invention. ID transmission/reception method according to an embodiment of the present invention may be performed by the underwater communication device 100 shown in FIG.

Referring to FIGS. 1 to 7 , the underwater communication device 100 generates a frame synchronization signal for obtaining synchronization of the receiving end when transmitting ID (identity) data (S102). Here, the frame synchronization signal is a specific bit or pattern inserted so that the receiving end can identify the start position and the end position of the frame, and follows a known method, and a detailed description thereof is omitted here.

The underwater communication device 100 uses its ID as a spreading code and generates an FCS corresponding to the data of the spreading code as data (S104). Here, the spreading code refers to a code multiplied by an information signal for the purpose of spreading a bandwidth in a spread-band communication method.

The underwater communication device 100 forms a frame by connecting the FCS generated to the generated frame synchronization signal, and transmits the formed frame (S106).

In general, the frame structure for ID transmission transmits a frame sync signal (frame sync.) for obtaining synchronization at the receiving end, transmits data corresponding to each communication device, and after ID data, it corresponds to each ID data FCS (Frame Check Sequence) is transmitted. Here, the FCS is for the receiving end to check whether there is an error in the ID data received from the transmitting end, and corresponds to the Cyclic Redundancy Check (CRC) method for checking the presence or absence of errors in the data received from the transmitting end in digital communication. . In this case, the FCS is a code that causes the remainder to be 0 when the receiving end divides the data received from the transmitting end into a predetermined pattern.

When a communication device using a general code division method transmits ID data for itself, it spreads the ID data using its own spreading code and transmits it. At this time, when the ID data is n bits, the FCS is k bits, and the processing gain is m chips, the data of the transmission signal excluding the frame synchronization signal is (n+k) x m chips. become chips. That is, during this period, the transmitting end must continue to transmit a signal. Here, the chip refers to a very fast signal waveform used to spread a digital symbol in the frequency domain, and is a pulse of each spreading code waveform, and is distinguished from a data bit.

In contrast, the underwater communication device 100 according to the embodiment of the present invention uses its ID as a spreading code and generates FCS corresponding to each spreading code data as data, so that the generated data becomes k x n chips.

The underwater communication device 100 forms a frame by connecting the FCS generated to the frame synchronization signal, and transmits the formed frame, thereby spreading the ID data and the FCS to form a frame compared to the general method of forming a frame. can be greatly reduced.

For example, if the ID is 16 bits, the gain of the spreading code is 16 chips, and the FCS is 8 bits, if the ID data is transmitted according to the general method, except for the frame synchronization signal (16 bits + 8 bits) x 16 chips = a data amount of 384 chips must be transmitted.

However, according to the embodiment of the present invention, if the ID is used as the spreading code and the FCS corresponding to the data of the spreading code is transmitted, only 16 chips x 8 bits = 128 chips need to be transmitted, so the amount of transmitted data is 1/3 decreases to

Power consumed during signal transmission in underwater communication accounts for one of the largest power consumption. Therefore, if the signal transmission time is reduced, the signal can be transmitted for a long time even with a battery of the same capacity. That is, when an underwater communication device in the water periodically transmits its ID, compared to general signal transmission, if the amount of data transmission is reduced by 1/3, the battery consumption is reduced by that amount, resulting in more time with the same capacity battery. can be used while Such a configuration and function can be used to find IDs of different communication devices even on land rather than underwater.

Meanwhile, the underwater communication device 100 may add a pilot signal to at least one of the front end of the FCS data, the middle of the FCS data, and the rear end of the FCS data among the formed frames ( S108 ). Such a pilot signal may be used for channel estimation or compensation at the receiving end.

When the underwater communication device 100 operates as a receiving end, it searches for frame synchronization based on a frame synchronization signal of a frame received from the transmitting end (S110). That is, the underwater communication device 100 identifies the start position and the end position of the frame based on the frame synchronization signal received from the transmitter. A method for the underwater communication device 100 to search for frame synchronization based on the frame synchronization signal may use a known technique, and a detailed description thereof will be omitted herein.

The underwater communication device 100 performs despreading using a plurality of spreading codes included in the frame received from the transmitting end (S112).

At this time, since the transmitting end uses its ID as the spreading code and transmits the FCS corresponding to the spreading code as data, the underwater communication device 100 can use the result of despreading for the frame received from the transmitting end as the FCS. .

The underwater communication device 100 performs a cyclic redundancy check by using the result of the performed despreading as the FCS (S114), and may determine the ID of the transmitter based on the despreading (S116). In this case, the underwater communication device 100 determines whether there is an error in the received frame according to whether the remainder becomes 0 when the result of the despreading is divided into a predetermined pattern, and there is no error in the frame. Since the number of bits of the FCS is known based on the frame synchronization signal, the spreading code of the frame calculated by dividing the total number of chips in the frame by the number of bits of the FCS can be determined as the ID of the transmitter. In this case, when the result of despreading is divided into a predetermined pattern, there may be a plurality of frame spreading codes whose remainder is 0. That is, there may be a plurality of frame spreading codes that are determined to have no error in the cyclic redundancy check. In this case, it is preferable that the underwater communication device 100 determines the respective frame spreading codes as IDs of a plurality of different transmitting terminals.

Although the embodiments according to the present invention have been described above, these are merely exemplary, and those of ordinary skill in the art will understand that various modifications and equivalent ranges of embodiments are possible therefrom. Accordingly, the protection scope of the present invention should be defined by the following claims as well as their equivalents.

Claims (10)

In the underwater communication device comprising a synchronization signal generator for generating a frame synchronization signal for obtaining synchronization of the receiving end when transmitting ID (identity) data,
a data generating unit that uses the ID of the underwater communication device as a spreading code and generates a frame check sequence (FCS) corresponding to the data of the spreading code as data; and
an ID data transmitter configured to directly connect the FCS generated by the data generator to the frame sync signal generated by the sync signal generator to form a frame structure, and transmit the formed frame structure;
Underwater communication device, characterized in that it further comprises. According to claim 1,
a synchronization search unit for searching for frame synchronization based on a frame synchronization signal of a frame received from a transmitter;
a despreading unit for performing despreading using a plurality of spreading codes included in the received frame; and
a transmitting end determining unit that determines the ID of the transmitting end based on the performed despreading;
Underwater communication device, characterized in that it further comprises. 3. The method of claim 2,
a redundancy check performing unit for performing a cyclic redundancy check using the result of the despreading performed by the despreading performing unit as an FCS;
further comprising,
The transmitting end determining unit determines that the spreading code included in the received frame is the ID of the transmitting end when it is determined that there is no error in the spreading code included in the received frame by the redundancy check performing unit. Underwater communication device. 4. The method of claim 3,
If there are a plurality of spreading codes determined by the redundancy check performing unit to have no error, the transmitting end determining unit determines the respective spreading codes as IDs of a plurality of different transmitting end IDs. According to claim 1,
a pilot adding unit for adding a pilot signal to at least one of a front end of FCS data generated by the data generating unit, a middle of FCS data, and a rear end of FCS data, among the frames formed by the ID data transmitting unit;
Underwater communication device, characterized in that it further comprises. In the ID transmission/reception method comprising a; performed by an underwater communication device, generating a frame synchronization signal for obtaining synchronization of a receiving end when transmitting ID (identity) data,
using the ID of the underwater communication device as a spreading code, and generating a Frame Check Sequence (FCS) corresponding to the data of the spreading code as data; and
forming a frame structure by directly connecting the FCS to the frame synchronization signal, and transmitting the formed frame structure;
ID transmission and reception method, characterized in that it further comprises. 7. The method of claim 6,
searching for frame synchronization based on a frame synchronization signal of a frame received from a transmitter;
performing despreading using a plurality of spreading codes included in the received frame; and
determining the ID of the transmitting end based on the performed despreading;
ID transmission and reception method, characterized in that it further comprises. 8. The method of claim 7,
performing a cyclic redundancy check using a result of the despreading performed by the despreading performing step as an FCS;
further comprising,
In the step of determining the ID of the transmitting end, when it is determined that there is no error in the spreading code included in the received frame by performing the cyclic redundancy check, the spreading code included in the received frame is transmitted to the transmitting end. ID transmission/reception method, characterized in that it is determined by ID. 9. The method of claim 8,
In the step of determining the ID of the transmitting end, if there are a plurality of spreading codes that are determined to have no errors, each of the plurality of spreading codes is determined as IDs of a plurality of different transmitting end IDs. 7. The method of claim 6,
adding a pilot signal to at least one of a front end, a middle end, and a rear end of the FCS among the transmitted ID data frames;
ID transmission and reception method, characterized in that it further comprises.

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