KR102261924B1 - Data transmission node device capable of determining a communication scheduling method for performing communication with a data receiving node device in a multi-hop relay cooperative communication network and operating method thereof - Google Patents

Abstract

Disclosed are a data transmission node device capable of determining a communication scheduling scheme for performing communication with a data receiving node device in a multi-hop relay cooperative communication network, and an operating method thereof. The present invention provides orthogonal frequency (OFDM) that enables insertion of information on a communication scheduling scheme when a data transmission node device intends to transmit data through a specific multi-hop communication path to a data reception node device in a multi-hop relay cooperative communication network. Division Multiplexing) A technique for generating and transmitting a packet to the data receiving node device, and then allowing the data transmitting node device to receive feedback from the data receiving node device on information on a communication scheduling scheme usable in the specific multi-hop communication path By presenting , it is possible to support the data transmission node device to determine an appropriate communication scheduling scheme.

Description

A data transmission node device capable of determining a communication scheduling method for performing communication with a data receiving node device in a multi-hop relay cooperative communication network, and an operating method thereof DATA RECEIVING NODE DEVICE IN A MULTI-HOP RELAY COOPERATIVE COMMUNICATION NETWORK AND OPERATING METHOD THEREOF}

The present invention relates to a data transmission node apparatus capable of determining a communication scheduling method for performing communication with a data reception node apparatus in a multi-hop relay cooperative communication network, and an operating method thereof.

Recently, due to the development of communication technology, research on a technology that allows access to the Internet anywhere, such as the Internet of Things, is being actively conducted.

In particular, interest in wireless sensor networks is growing, and wireless sensor networks are being used in various fields such as logistics, distribution, environmental monitoring, home automation, etc. in that they can acquire sensing data through various sensors and provide it to managers. .

In the wireless sensor network, a multi-hop communication method in which node devices constituting the network perform a relay role may be utilized. In addition, since two or more node devices configure one hop, a method of transmitting data to the next hop through cooperative communication may be utilized.

Such a communication network may be referred to as a multi-hop relay cooperative communication network.

In the multi-hop relay cooperative communication network, when the data transmission node device 110 transmits data to the data reception node device 120 as shown in FIG. 2 , a new multi-hop communication path (hereinafter, 'first multi-hop') The data may be transmitted to the data receiving node device 120 through the first multi-hop communication path by creating a communication path '.

In this case, a plurality of hops 131 , 132 , 133 , 134 , and 135 may exist in the first multi-hop communication path, and at least one node device configures one hop in each hop, so that each Data can be transmitted and received between hops.

At this time, among the plurality of hops 131 , 132 , 133 , 134 , and 135 , specific hops such as 132 and 134 are other multi-hops before the data transmission node device 110 creates the first multi-hop communication path. It may be included in the communication path to transmit/receive data.

At this time, the data transmission node device 110 needs to determine a predetermined communication scheduling method to transmit data to the data reception node device 120, and is indicated by reference numerals 132 and 134 on the first multi-hop communication path. As shown in the figure, when a hop already included in another multi-hop communication path exists, the data transmission node device 110 completely transmits data to the data reception node device 120 through the first multi-hop communication path. For this, a communication scheduling method that does not overlap with the communication scheduling method applied to the hops indicated by reference numerals 132 and 134 should be used.

Therefore, in the multi-hop relay cooperative communication network, when the data transmission node device 110 intends to transmit data to the data reception node device 120 through a specific multi-hop communication path, to determine an appropriate communication scheduling method. Technology research is needed.

The present invention provides orthogonal frequency (OFDM) that enables insertion of information on a communication scheduling scheme when a data transmission node device intends to transmit data through a specific multi-hop communication path to a data reception node device in a multi-hop relay cooperative communication network. Division Multiplexing) A technique for generating and transmitting a packet to the data receiving node device, and then allowing the data transmitting node device to receive feedback from the data receiving node device on information on a communication scheduling scheme usable in the specific multi-hop communication path By presenting , it is intended to support the data transmission node device to determine an appropriate communication scheduling scheme.

A data transmission node device capable of determining a communication scheduling method for performing communication with a data receiving node device in a multi-hop relay cooperative communication network according to an embodiment of the present invention is S ( S is a natural number of 2 or more) a scheduling information storage unit storing information on communication scheduling schemes, a path generating unit generating a first multi-hop communication path for transmitting data from the cooperative communication network to the data receiving node device, A packet generator for generating an Orthogonal Frequency Division Multiplexing (OFDM) packet composed of S different bands designated to insert information on each of the S communication scheduling schemes, and the OFDM packet to the first multi-hop communication path at least one relay node device included in each of a plurality of hops constituting the first multi-hop communication path, wherein the OFDM packet is propagated from the previous hop and received , check whether there is a communication scheduling scheme already in use in the hop from among the S communication scheduling schemes, and when the first communication scheduling scheme among the S communication scheduling schemes is used, the first one of the S bands. The OFDM packet is propagated to a next hop after inserting information indicating that the first communication scheduling method is being used for a first band designated to insert information on the communication scheduling method, and the data receiving node device When a packet is received, it is checked whether information on a communication scheduling scheme is inserted into each of the S bands, and then it is confirmed that information is not inserted into the S bands among the S communication scheduling schemes. 2 The information on the communication scheduling method is fed back to the data transmission node device through the first multi-hop communication path.

In addition, the method of operating a data transmission node device capable of determining a communication scheduling method for performing communication with a data receiving node device in a multi-hop relay cooperative communication network according to an embodiment of the present invention is supported in the cooperative communication network. Maintaining a scheduling information storage unit in which information about S (S is a natural number greater than or equal to 2) predetermined communication scheduling schemes is stored, the first multi-hop communication for transmitting data from the cooperative communication network to the data receiving node device generating a path; generating an OFDM packet composed of S different bands designated to insert information on each of the S communication scheduling schemes; and transmitting the OFDM packet through the first multi-hop communication path. and transmitting to a data receiving node device, wherein at least one relay node device included in each of a plurality of hops constituting the first multi-hop communication path receives the OFDM packet by propagating from a previous hop, the S It is checked whether there is a communication scheduling scheme already in use in the hop among the communication scheduling schemes, and when the first communication scheduling scheme among the S communication scheduling schemes is used, the first communication scheduling scheme among the S bands The OFDM packet is propagated to the next hop after inserting information indicating that the first communication scheduling scheme is being used for a first band designated for inserting information on the OFDM packet, and the data receiving node device receives the OFDM packet. , after checking whether information on a communication scheduling scheme is inserted into each of the S bands, it is confirmed that information is not inserted into the S bands among the S communication scheduling schemes. Method information is fed back to the data transmission node device through the first multi-hop communication path.

The present invention provides orthogonal frequency (OFDM) that enables insertion of information on a communication scheduling scheme when a data transmission node device intends to transmit data through a specific multi-hop communication path to a data reception node device in a multi-hop relay cooperative communication network. Division Multiplexing) A technique for generating and transmitting a packet to the data receiving node device, and then allowing the data transmitting node device to receive feedback from the data receiving node device on information on a communication scheduling scheme usable in the specific multi-hop communication path By presenting , it is possible to support the data transmission node device to determine an appropriate communication scheduling scheme.

1 is a diagram showing the structure of a data transmission node apparatus according to an embodiment of the present invention.
2 and 3 are diagrams for explaining the operation of a data transmission node apparatus according to an embodiment of the present invention.
4 is a flowchart illustrating a method of operating a data transmission node apparatus according to an embodiment of the present invention.

Hereinafter, embodiments according to the present invention will be described in detail with reference to the accompanying drawings. These descriptions are not intended to limit the present invention to specific embodiments, and should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention. In describing each drawing, like reference numerals are used for similar components, and unless otherwise defined, all terms used in this specification, including technical or scientific terms, refer to those of ordinary skill in the art to which the present invention belongs. It has the same meaning as is commonly understood by those who have it.

In this document, when a part "includes" a certain component, it means that other components may be further included, rather than excluding other components, unless otherwise stated. In addition, in various embodiments of the present invention, each of the components, functional blocks or means may be composed of one or more sub-components, and the electrical, electronic, and mechanical functions performed by each component are electronic. A circuit, an integrated circuit, an ASIC (Application Specific Integrated Circuit), etc. may be implemented with various well-known devices or mechanical elements, and may be implemented separately or two or more may be integrated into one.

On the other hand, the blocks in the accompanying block diagram or steps in the flowchart are computer program instructions that are loaded in a processor or memory of equipment capable of data processing, such as a general-purpose computer, a special-purpose computer, a portable notebook computer, and a network computer, and perform specified functions. can be interpreted as meaning Since these computer program instructions may be stored in a memory provided in a computer device or in a memory readable by a computer, the functions described in the blocks of the block diagrams or the steps of the flowcharts are produced as articles of manufacture containing instruction means for performing the same. could be In addition, each block or each step may represent a module, segment, or portion of code comprising one or more executable instructions for executing the specified logical function(s). It should also be noted that, in some alternative embodiments, it is also possible for the functions recited in blocks or steps to be executed out of the prescribed order. For example, two blocks or steps shown in succession may be performed substantially simultaneously or in the reverse order, and in some cases, some blocks or steps may be omitted.

1 is a diagram showing the structure of a data transmission node apparatus according to an embodiment of the present invention.

Referring to FIG. 1 , the data transmission node apparatus 110 according to the present invention includes a scheduling information storage unit 111 , a path generation unit 112 , a packet generation unit 113 , and a packet transmission unit 114 .

First, the data transmission node device 110 according to the present invention is one of the node devices constituting the multi-hop relay cooperative communication network, and in the present invention, the data transmission node device 110 is another node device constituting the cooperative communication network. It relates to a technique for determining a communication scheduling method for performing communication with the in-data receiving node device 120 .

The scheduling information storage unit 111 stores information on S (S is a natural number equal to or greater than 2) predetermined communication scheduling schemes supported by the cooperative communication network.

The path generating unit 112 creates a first multi-hop communication path 100 through which data is transmitted to the data receiving node device 120 in the cooperative communication network.

The packet generator 113 generates an Orthogonal Frequency Division Multiplexing (OFDM) packet composed of S different bands designated to insert information on each of the S communication scheduling schemes.

The packet transmission unit 114 transmits the OFDM packet to the data receiving node device 120 through the first multi-hop communication path 100 .

At this time, when the OFDM packet is propagated and received from the previous hop, at least one relay node device included in each of the plurality of hops constituting the first multi-hop communication path 100 is selected from among the S communication scheduling schemes. The hop checks whether a communication scheduling scheme already in use exists, and when the first communication scheduling scheme among the S communication scheduling schemes is used, information on the first communication scheduling scheme among the S bands is designated to be inserted. After inserting information indicating that the first communication scheduling scheme is used for the first band, the OFDM packet may be propagated to the next hop.

Then, when the OFDM packet is received, the data receiving node device 120 checks whether information on a communication scheduling scheme is inserted into each of the S bands, and then checks whether the S bands among the S communication scheduling schemes. Information on the second communication scheduling method, in which it is confirmed that the information is not inserted in the fields, is fed back to the data transmission node device 110 through the first multi-hop communication path 100 .

At this time, according to an embodiment of the present invention, at least one relay node device included in each of the plurality of hops constituting the first multi-hop communication path 100 receives the OFDM packet by propagating from the previous hop, Information indicating that a communication scheduling scheme is being used when none of the S communication scheduling schemes is used by checking whether a communication scheduling scheme already in use in the hop among the S communication scheduling schemes exists Without the insertion of , the OFDM packet can be propagated to the next hop.

In addition, according to an embodiment of the present invention, the packet generator 113 is configured with the S bands, and K (K is a natural number greater than or equal to 2) subcarriers that are different from each other are allocated to each of the S bands. OFDM packets can be generated.

At this time, when the OFDM packet is propagated and received from the previous hop, at least one relay node device included in each of the plurality of hops constituting the first multi-hop communication path 100 is selected from among the S communication scheduling schemes. It is checked whether there is a communication scheduling scheme already in use in the hop, and when the first communication scheduling scheme among the S communication scheduling schemes is used, information on the first communication scheduling scheme among the S bands is inserted. By transmitting an on-off keying (OOK) symbol '1' as information indicating that the first communication scheduling scheme is being used through each of the K subcarriers constituting the designated first band, the The OFDM packet in which information indicating that the first communication scheduling scheme is being used is inserted may be propagated to the next hop.

At this time, according to an embodiment of the present invention, the packet transmission unit 114 may transmit the S bands when a third communication scheduling scheme among the S communication scheduling schemes is currently being used by the data transmission node device 110 . By transmitting the OOK symbol '1' as information indicating that the third communication scheduling method is being used through each of the K subcarriers constituting the second band in which the information on the third communication scheduling method is inserted, the OOK symbol '1' is transmitted, The OFDM packet in which information indicating that the third communication scheduling scheme is used in the second band is inserted may be transmitted to the data receiving node device 120 through the first multi-hop communication path 100 .

Further, according to an embodiment of the present invention, when the OFDM packet is received, the data receiving node device 120 detects the energy of a signal in each of the S bands, thereby scheduling communication in each of the S bands. After checking whether information on the method is inserted, information on the second communication scheduling method in which it is confirmed that information is not inserted in the S bands among the S communication scheduling methods is transferred to the first multi-hop It may be fed back to the data transmission node device 110 through the communication path 100 .

At this time, according to an embodiment of the present invention, when the OFDM packet is received, the data receiving node device 120 detects the energy of a signal in K subcarriers constituting each of the S bands, and the S In each of the S bands, by confirming that information on a communication scheduling method is inserted for a band in which the sum of energy detected from the K subcarriers in each band among the bands is confirmed to be equal to or greater than a preset reference value After checking whether information on the communication scheduling method is inserted, the information on the second communication scheduling method in which it is confirmed that information is not inserted in the S bands among the S communication scheduling methods is added to the first It may be fed back to the data transmission node device through the multi-hop communication path 100 .

Also, according to an embodiment of the present invention, the data transmission node device 110 may further include a data communication performing unit 115 .

When the information on the second communication scheduling method is fed back from the data receiving node device 120 through the first multi-hop communication path 100 and received, the data communication performing unit 115 is configured to adjust the second communication scheduling method. Accordingly, data communication with the data receiving node device 120 is performed through the first multi-hop communication path 100 .

Hereinafter, an operation of the data transmission node apparatus 110 according to the present invention will be described in detail with reference to FIGS. 2 and 3 .

2 and 3 are diagrams for explaining the operation of the data transmission node apparatus 110 according to an embodiment of the present invention.

First, it is assumed that there are four (ie, S=4) communication scheduling schemes that are predetermined to be supported in a cooperative communication network. In this case, information on four communication scheduling methods may be stored in the scheduling information storage unit 111 .

As illustrated in FIG. 2 , the path generator 112 may generate a first multi-hop communication path 100 for transmitting data to the data receiving node device 120 in the cooperative communication network.

Here, it is assumed that the first multi-hop communication path 100 is composed of multi-hops 131 , 132 , 133 , 134 , and 135 as shown in FIG. 2 .

The packet generator 113 is composed of four different bands designated to insert information on each of the four communication scheduling schemes, and K (K is a natural number greater than or equal to 2) different K (K is a natural number greater than or equal to 2) in each of the four bands. It is possible to generate an OFDM packet to which subcarriers are assigned.

If K is 3, the packet generator 113 performs four bands 301, 302, 303, and 304 called _{B 1} , B ₂ , B ₃ , and B _{4 as shown in FIG. 3 .} ), three subcarriers 311, 312, 313, 321, 322, 323, 331, 332, 333, 341, 342, 343 in each of the four bands 301, 302, 303, 304. An allocated OFDM packet may be generated.

In this case, when the four communication scheduling schemes are referred to as communication scheduling schemes 1, 2, 3, and 4, in FIG. 3 , the B ₁ band 301 may be designated as a band corresponding to the communication scheduling scheme 1, and the B ₂ band 302 may be designated as a band corresponding to communication scheduling scheme 2, B ₃ band 303 may be designated as a band corresponding to communication scheduling scheme 3, and B ₄ band 304 may be designated as communication scheduling scheme 4 may be designated as a band corresponding to .

And, three subcarriers 311, 312, 313 may be allocated to the _{B 1} band 301, and three subcarriers 321, 322, 323 _{may be allocated to the B 2 band 302,} Three subcarriers 331 , 332 , and 333 may be allocated to the B ₃ band 303 , and three subcarriers 341 , 342 , 343 may be allocated to the _{B 4 band 304 .}

In this way, when the OFDM packet is generated, the packet transmission unit 114 transmits the OFDM packet to the data receiving node device 120 through the first multi-hop communication path 100 .

At this time, at least one relay node device included in each of the hops 131 , 132 , 133 , 134 , 135 constituting the first multi-hop communication path 100 receives the OFDM packet by propagating from the previous hop, It is checked whether there is a communication scheduling scheme already in use in the hop among the four communication scheduling schemes, and when the first communication scheduling scheme among the four communication scheduling schemes is used, the four bands 301, 302, 303 and 304), the OFDM packet can be propagated to the next hop after inserting information indicating that the first communication scheduling scheme is being used for the first band designated for inserting the information on the first communication scheduling scheme. have.

If at least one relay node device included in each of the hops 131 , 132 , 133 , 134 and 135 constituting the first multi-hop communication path 100 does not use any communication scheduling scheme in the hop , it is possible to propagate the OFDM packet to the next hop without inserting information indicating that the communication scheduling scheme is being used.

In this regard, hop 1 131 is a hop that is not included in another multi-hop communication path, and is included in hop 1 131 because there is no communication scheduling method already used in hop 1 131 . When the OFDM packet is received from the data transmission node device 110, the at least one relay node device may propagate the OFDM packet to the next hop without inserting additional information into the OFDM packet.

However, in the case of hop 2 132 , it is a hop already included in another multi-hop communication path before being included in the first multi-hop communication path 100 , and since a predetermined communication scheduling method is used, hop 2 132 . When the OFDM packet is received from the previous hop, at least one relay node device included in ) is already used in hop 2 132 of the four bands 301 , 302 , 303 , 304 constituting the OFDM packet. The OFDM packet may be propagated to the next hop after inserting information indicating that the communication scheduling method is being used for a band designated so that information on the existing communication scheduling method is inserted.

In relation to this, if the communication scheduling scheme already used in hop 2 132 through another multi-hop communication path is called communication scheduling scheme 1, at least one relay node device included in hop 2 132 is in the OFDM packet. After inserting information indicating that the communication scheduling scheme 1 is used in the B _{1 band 301 , the OFDM packet may be propagated to the next hop.}

At this time, at least one relay node device included in hop 2 132 _{inserts information indicating that communication scheduling scheme 1 is used in the B 1} band 301 and then propagates the OFDM packet to the next hop, For _{each of the three subcarriers 311 , 312 , and 313 constituting the B 1} band 301 , the OOK symbol '1' may be carried and transmitted as information indicating that the communication scheduling scheme 1 is used.

In this way, hop 3 133 and hop 5 135 propagate the OFDM packet to the next hop without inserting separate information into the OFDM packet, and hop 4 134 is a communication scheduling scheme that is already in use. information on the OFDM packet may be inserted into the OFDM packet to propagate to the next hop.

If the data transmission node device 110 is already included in another multi-hop communication path before the first multi-hop communication path 100 is created, it is said that a predetermined communication scheduling method is already applied. When the packet transmission unit 114 of the data transmission node device 110 transmits the OFDM packet to the data reception node device 120 through the first multi-hop communication path 100, the data transmission node device 110 The OOK symbol '1' may be loaded and transmitted through three subcarriers of a band corresponding to the communication scheduling scheme already used.

In this way, when the OFDM packet is received by the data receiving node device 120 through the first multi-hop communication path 100 , the data receiving node device 120 performs the four bands 301 , 302 , 303 , 304 . ) after checking whether information on the communication scheduling method is inserted in each of the four communication scheduling methods, the first confirmation that information is not inserted into the four bands 301 , 302 , 303 , 304 among the four communication scheduling methods 2 The information on the communication scheduling method is fed back to the data transmission node device 110 through the first multi-hop communication path 100 .

This regard, the communication scheduling scheme if said first two, and is already being used, the communication scheduling scheme 3 is already in use in the hop 4 134, the data receiving node apparatus 120 B ₁ band 301 in hop 2 132 The OFDM in which OOK symbol '1' is included through subcarriers 311, 312, and 313 and OOK symbol '1' is included through subcarriers 331, 332, 333 of _{B 3 band 303} packets can be received.

At this time, the data receiving node device 120 determines which band among the four bands 301, 302, 303, and 304 includes the OOK symbol '1', the four bands 301, 302, 303 and 304), it is possible to detect the energy of the signal in the three subcarriers 311, 312, 313, 321, 322, 323, 331, 332, 333, 341, 342, 343 constituting each.

Then, the data receiving node device 120 determines that the sum of energy detected from three subcarriers in each of the four bands 301, 302, 303, and 304 is equal to or greater than a preset reference value. It can be confirmed that information on the communication scheduling method is inserted for the .

In this regard, since it is assumed that communication scheduling scheme 1 is already used in hop 2 132 and communication scheduling scheme 3 is already used in hop 4 134 , in the OFDM packet received by the data receiving node device 120 , the 4 the two bands (301, 302, 303, 304) of the three sub-carriers constituting each (311, 312, 313, 321, 322, 323, 331, 332, 333, 341, 342, 343) of the B ₁ The energy of the signal in the subcarriers 311 , 312 , 313 of the band 301 and the energy of the signal in the subcarriers 331 , 332 , 333 of the _{B 3 band 303 will be detected to be high.}

Due to this, the sum of the energy of the signal in the subcarriers 311 , 312 and 313 of the _{B 1} band 301 and the sum of the energy of the signal in the subcarriers 331 , 332 , 333 _{of the B 3 band 303 .} When it is confirmed that this is equal to or greater than the reference value, the data receiving node device 120 may confirm that information on the communication scheduling method is inserted into the _{B 1} band 301 and the B _{3 band 303 .}

After that, the data receiving node device 120 determines that the communication scheduling scheme 1 corresponding to the _{B 1 band 301 and the communication scheduling scheme 3 corresponding to the B 3} band 303 are already configured in the first multi-hop communication path 100 . After determining that it is being used in a specific hop on the first multi-hop communication path ( 100 ) may be fed back to the data transmission node device 110 .

If it is assumed that the data reception node device 120 feeds back information on the communication scheduling scheme 2 to the data transmission node device 110 through the first multi-hop communication path 100, the data transmission node device 110 When the information on the communication scheduling method 2 is fed back and received, the data communication performing unit 115 of the data communication performing unit 115 communicates with the data receiving node device 120 through the first multi-hop communication path 100 according to the communication scheduling method 2 Data communication can be performed.

In this case, the hops 131 , 132 , 133 , 134 , and 135 constituting the first multi-hop communication path 100 allow the data receiving node device 120 to transmit information on the communication scheduling scheme 2 to the first multi-hop. It can be seen that data communication will be performed according to the communication scheduling method 2 because backpropagation is performed to the data transmission node device 110 through the communication path 100 . For this reason, when the data transmission node device 110 performs data communication with the data reception node device 120 through the first multi-hop communication path 100 according to the communication scheduling scheme 2, the first multi-hop The hops 131 , 132 , 133 , 134 , and 135 constituting the communication path 100 may naturally perform relay communication according to the communication scheduling scheme 2 .

4 is a flowchart illustrating an operation method of a data transmission node device capable of determining a communication scheduling scheme for performing communication with a data reception node device in a multi-hop relay cooperative communication network according to an embodiment of the present invention.

In step S410, a scheduling information storage unit in which information about S (S is a natural number greater than or equal to 2) communication scheduling methods predetermined to be supported by the cooperative communication network is stored is maintained.

In step S420, a first multi-hop communication path through which data is transmitted from the cooperative communication network to the data receiving node device is generated.

In step S430, an OFDM packet composed of S different bands designated to insert information on each of the S communication scheduling schemes is generated.

In step S440, the OFDM packet is transmitted to the data receiving node device through the first multi-hop communication path.

At this time, when at least one relay node device included in each of the plurality of hops constituting the first multi-hop communication path receives the OFDM packet propagated from the previous hop, the S communication scheduling scheme has already been performed at the corresponding hop. It is checked whether a communication scheduling scheme in use exists, and when the first communication scheduling scheme among the S communication scheduling schemes is used, a first band designated to insert information on the first communication scheduling scheme among the S bands. After inserting information indicating that the first communication scheduling scheme is being used, the OFDM packet is propagated to the next hop.

Then, when the OFDM packet is received, the data receiving node device checks whether information on a communication scheduling method is inserted in each of the S bands, and then applies the information to the S bands among the S communication scheduling methods. Information on the second communication scheduling method, which is confirmed as not having information inserted, is fed back to the data transmission node device through the first multi-hop communication path.

At this time, according to an embodiment of the present invention, at least one relay node device included in each of the plurality of hops constituting the first multi-hop communication path receives the OFDM packet by propagating from the previous hop, the S Among the communication scheduling schemes, it is checked whether there is a communication scheduling scheme already being used in the hop, and when none of the S communication scheduling schemes is used, information indicating that the communication scheduling scheme is being used is not inserted. , the OFDM packet may be propagated to the next hop.

In addition, according to an embodiment of the present invention, in step S430, the OFDM packet is configured with the S bands, and K (K is a natural number greater than or equal to 2) subcarriers different from each other are allocated to each of the S bands. can create

At this time, when at least one relay node device included in each of the plurality of hops constituting the first multi-hop communication path receives the OFDM packet propagated from the previous hop, the S communication scheduling scheme has already been performed at the corresponding hop. It is checked whether there is a communication scheduling scheme in use, and when the first communication scheduling scheme among the S communication scheduling schemes is used, the first communication scheduling scheme designated to insert information on the first communication scheduling scheme among the S bands. By transmitting an OOK symbol '1' as information indicating that the first communication scheduling method is being used through each of the K subcarriers constituting 1 band, the first communication scheduling method is used in the first band The OFDM packet in which the indicating information is inserted may be propagated to the next hop.

At this time, according to an embodiment of the present invention, in step S440, when a third communication scheduling scheme among the S communication scheduling schemes is currently being used by the data transmission node device, the third one of the S bands By transmitting the OOK symbol '1' as information indicating that the third communication scheduling method is being used through each of the K subcarriers constituting the second band designated to insert the communication scheduling method information, the second band The OFDM packet in which information indicating that the third communication scheduling scheme is being used is inserted in the , may be transmitted to the data receiving node device through the first multi-hop communication path.

In addition, according to an embodiment of the present invention, when the OFDM packet is received, the data receiving node device detects the energy of a signal in each of the S bands, thereby providing a communication scheduling method for each of the S bands. After checking whether the information on the S communication scheduling method is inserted, the information on the second communication scheduling method in which it is confirmed that information is not inserted in the S bands among the S communication scheduling methods is transferred to the first multi-hop communication path. can be fed back to the data transmission node device through

At this time, according to an embodiment of the present invention, when the OFDM packet is received, the data receiving node device detects the energy of a signal in K subcarriers constituting each of the S bands, and the S bands Communication scheduling is performed in each of the S bands by confirming that information on a communication scheduling method is inserted for a band in which the sum of energy detected from the K subcarriers in each band is equal to or greater than a preset reference value. After checking whether information on the method is inserted, information on the second communication scheduling method in which it is confirmed that information is not inserted in the S bands among the S communication scheduling methods is transferred to the first multi-hop It may be fed back to the data transmission node device through a communication path.

According to an embodiment of the present invention, in the method of operating the data transmission node device, when information on the second communication scheduling scheme is fed back and received from the data reception node device through the first multi-hop communication path, the first The method may further include performing data communication with the data receiving node device through the first multi-hop communication path according to the second communication scheduling method.

In the above, a method of operating a data transmission node apparatus according to an embodiment of the present invention has been described with reference to FIG. 4 . Here, since the operation method of the data transmission node apparatus according to an embodiment of the present invention may correspond to the configuration of the operation of the data transmission node apparatus 110 described with reference to FIGS. 1 to 3 , a more detailed description thereof is to be omitted.

The method of operating a data transmission node device according to an embodiment of the present invention may be implemented as a computer program stored in a storage medium for execution through combination with a computer.

In addition, the method of operating a data transmission node apparatus according to an embodiment of the present invention may be implemented in the form of a program command that can be executed through various computer means and recorded in a computer-readable medium. The computer-readable medium may include program instructions, data files, data structures, etc. alone or in combination. The program instructions recorded on the medium may be specially designed and configured for the present invention, or may be known and available to those skilled in the art of computer software. Examples of the computer-readable recording medium include magnetic media such as hard disks, floppy disks and magnetic tapes, optical media such as CD-ROMs and DVDs, and magnetic media such as floppy disks. - includes magneto-optical media, and hardware devices specially configured to store and execute program instructions, such as ROM, RAM, flash memory, and the like. Examples of program instructions include not only machine language codes such as those generated by a compiler, but also high-level language codes that can be executed by a computer using an interpreter or the like.

As described above, the present invention has been described with specific matters such as specific components and limited embodiments and drawings, but these are provided to help a more general understanding of the present invention, and the present invention is not limited to the above embodiments. , various modifications and variations are possible from these descriptions by those of ordinary skill in the art to which the present invention pertains.

Therefore, the spirit of the present invention should not be limited to the described embodiments, and not only the claims to be described later, but also all those with equivalent or equivalent modifications to the claims will be said to belong to the scope of the spirit of the present invention. .

110: data transmission node device
111: scheduling information storage unit 112: path generation unit
113: packet generation unit 114: packet transmission unit
115: data communication performing unit
120: data receiving node device
100: first multi-hop communication path

Claims (16)

A data transmission node device capable of determining a communication scheduling method for performing communication with a data receiving node device in a multi-hop relay cooperative communication network, the data transmission node device comprising:
S (S is a natural number greater than or equal to 2) communication scheduling schemes predetermined to be supported in the cooperative communication network - The S communication scheduling schemes interfere with data transmitted and received through different multi-hop communication paths for each multi-hop communication path. means a method for a pre-specified data transmission/reception schedule for transmitting/receiving without a scheduling information storage unit in which information is stored;
a path generating unit generating a first multi-hop communication path through which data is transmitted from the cooperative communication network to the data receiving node device;
a packet generator for generating an Orthogonal Frequency Division Multiplexing (OFDM) packet composed of S different bands designated to insert information on each of the S communication scheduling schemes; and
A packet transmission unit for transmitting the OFDM packet to the data receiving node device through the first multi-hop communication path
including,
At this time, at least one relay node device included in each of the plurality of hops constituting the first multi-hop communication path transmits the OFDM packet through the first multi-hop communication path by the data transmission node device. When the OFDM packet is propagated and received from a previous hop on the first multi-hop communication path, it is checked whether there is a communication scheduling scheme already in use in the hop among the S communication scheduling schemes, and from among the S communication scheduling schemes. When the first communication scheduling method is used, information indicating that the first communication scheduling method is being used is inserted for a first band designated to insert information on the first communication scheduling method among the S bands. Then, the OFDM packet is propagated to the next hop,
When the OFDM packet propagated through the first multi-hop communication path is finally received, the data receiving node device checks whether information on a communication scheduling scheme is inserted into each of the S bands, and then Feeding back information on a second communication scheduling method in which it is confirmed that information is not inserted in the S bands among the communication scheduling methods to the data transmission node device through the first multi-hop communication path,
At this time, the data transmission node device
When information on the second communication scheduling method is fed back and received from the data receiving node device through the first multi-hop communication path, the data is received through the first multi-hop communication path according to the second communication scheduling method Data communication performing unit that performs data communication with the node device
characterized in that it further comprises,
Data transfer node device. According to claim 1,
At least one relay node device included in each of the plurality of hops constituting the first multi-hop communication path transmits the OFDM packet through the first multi-hop communication path by the data transmission node device. When the OFDM packet is propagated and received from a previous hop on a multi-hop communication path, it is checked whether there is a communication scheduling scheme already in use in the hop among the S communication scheduling schemes, and which communication among the S communication scheduling schemes exists. When the scheduling method is not used, the OFDM packet is propagated to the next hop without inserting information indicating that the communication scheduling method is being used,
Data transfer node device. According to claim 1,
The packet generator
generating the OFDM packet configured with the S bands, to which K different subcarriers (K is a natural number greater than or equal to 2) are allocated to each of the S bands;
At this time, at least one relay node device included in each of the plurality of hops constituting the first multi-hop communication path transmits the OFDM packet through the first multi-hop communication path by the data transmission node device. When the OFDM packet is propagated and received from a previous hop on the first multi-hop communication path, it is checked whether there is a communication scheduling scheme already in use in the hop among the S communication scheduling schemes, and from among the S communication scheduling schemes. When the first communication scheduling method is used, the first communication scheduling method is performed through each of K subcarriers constituting the first band designated to insert information on the first communication scheduling method among the S bands. By transmitting an on-off keying (OOK) symbol '1' as information indicating that characterized by propagating with
Data transfer node device. 4. The method of claim 3,
The packet transmission unit
When a third communication scheduling scheme among the S communication scheduling schemes is currently being used by the data transmission node device, configuring a second band designated to insert information on the third communication scheduling scheme among the S bands By transmitting the OOK symbol '1' as information indicating that the third communication scheduling method is being used through each of the K subcarriers, information indicating that the third communication scheduling method is being used is inserted into the second band characterized in that the OFDM packet is transmitted to the data receiving node device through the first multi-hop communication path,
Data transfer node device. 4. The method of claim 3,
The data receiving node device
When the OFDM packet propagated through the first multi-hop communication path is finally received, information on a communication scheduling scheme is inserted into each of the S bands by detecting the energy of the signal in each of the S bands. After confirming whether or not information on the second communication scheduling method is confirmed that information is not inserted in the S bands among the S communication scheduling methods, information on the second communication scheduling method is transmitted to the data through the first multi-hop communication path. characterized in that it feeds back to the transmitting node device,
Data transfer node device. 6. The method of claim 5,
The data receiving node device
When the OFDM packet propagated through the first multi-hop communication path is finally received, signal energy is detected on K subcarriers constituting each of the S bands, and each band among the S bands Information on the communication scheduling method in each of the S bands by confirming that the information on the communication scheduling method is inserted for the band in which the sum of the energy detected from the K subcarriers is equal to or greater than the preset reference value After checking whether or not is inserted, information on the second communication scheduling method in which it is confirmed that information is not inserted in the S bands among the S communication scheduling methods is transmitted through the first multi-hop communication path. characterized in that the feedback to the data transmission node device,
Data transfer node device. delete A method of operating a data transmission node device capable of determining a communication scheduling method for performing communication with a data reception node device in a multi-hop relay cooperative communication network, the method comprising:
S (S is a natural number greater than or equal to 2) communication scheduling schemes predetermined to be supported in the cooperative communication network - The S communication scheduling schemes interfere with data transmitted and received through different multi-hop communication paths for each multi-hop communication path. means a method for a predetermined data transmission/reception schedule for enabling transmission and reception without - maintaining a scheduling information storage unit in which information is stored;
generating a first multi-hop communication path for transmitting data from the cooperative communication network to the data receiving node device;
generating an OFDM (Orthogonal Frequency Division Multiplexing) packet composed of S different bands designated to insert information on each of the S communication scheduling schemes; and
transmitting the OFDM packet to the data receiving node device through the first multi-hop communication path;
including,
At this time, at least one relay node device included in each of the plurality of hops constituting the first multi-hop communication path transmits the OFDM packet through the first multi-hop communication path by the data transmission node device. When the OFDM packet is propagated and received from a previous hop on the first multi-hop communication path, it is checked whether there is a communication scheduling scheme already in use in the hop among the S communication scheduling schemes, and from among the S communication scheduling schemes. When the first communication scheduling method is used, information indicating that the first communication scheduling method is being used is inserted for a first band designated to insert information on the first communication scheduling method among the S bands. Then, the OFDM packet is propagated to the next hop,
When the OFDM packet propagated through the first multi-hop communication path is finally received, the data receiving node device checks whether information on a communication scheduling scheme is inserted into each of the S bands, and then Feeding back information on a second communication scheduling method in which it is confirmed that information is not inserted in the S bands among the communication scheduling methods to the data transmission node device through the first multi-hop communication path,
At this time, the method of operation of the data transmission node device is
When information on the second communication scheduling method is fed back and received from the data receiving node device through the first multi-hop communication path, the data is received through the first multi-hop communication path according to the second communication scheduling method performing data communication with the node device;
characterized in that it further comprises,
How a data transfer node device works. 9. The method of claim 8,
At least one relay node device included in each of the plurality of hops constituting the first multi-hop communication path transmits the OFDM packet through the first multi-hop communication path by the data transmission node device. When the OFDM packet is propagated and received from a previous hop on a multi-hop communication path, it is checked whether there is a communication scheduling scheme already in use in the hop among the S communication scheduling schemes, and which communication among the S communication scheduling schemes exists. When the scheduling method is not used, the OFDM packet is propagated to the next hop without inserting information indicating that the communication scheduling method is being used,
How a data transfer node device works. 9. The method of claim 8,
The step of generating the OFDM packet is
generating the OFDM packet configured with the S bands, to which K (K is a natural number greater than or equal to 2) subcarriers different from each other are allocated to each of the S bands;
At this time, at least one relay node device included in each of the plurality of hops constituting the first multi-hop communication path transmits the OFDM packet through the first multi-hop communication path by the data transmission node device. When the OFDM packet is propagated and received from a previous hop on the first multi-hop communication path, it is checked whether there is a communication scheduling scheme already in use in the hop among the S communication scheduling schemes, and from among the S communication scheduling schemes. When the first communication scheduling method is used, the first communication scheduling method is performed through each of K subcarriers constituting the first band designated to insert information on the first communication scheduling method among the S bands. By transmitting an on-off keying (OOK) symbol '1' as information indicating that characterized by propagating with
How a data transfer node device works. 11. The method of claim 10,
The step of transmitting to the data receiving node device is
When a third communication scheduling scheme among the S communication scheduling schemes is currently being used by the data transmission node device, configuring a second band designated to insert information on the third communication scheduling scheme among the S bands By transmitting the OOK symbol '1' as information indicating that the third communication scheduling method is being used through each of the K subcarriers, information indicating that the third communication scheduling method is being used is inserted into the second band characterized in that the OFDM packet is transmitted to the data receiving node device through the first multi-hop communication path,
How a data transfer node device works. 11. The method of claim 10,
The data receiving node device
When the OFDM packet propagated through the first multi-hop communication path is finally received, information on a communication scheduling scheme is inserted into each of the S bands by detecting the energy of the signal in each of the S bands. After confirming whether or not information on the second communication scheduling method is confirmed that information is not inserted in the S bands among the S communication scheduling methods, information on the second communication scheduling method is transmitted to the data through the first multi-hop communication path. characterized in that it feeds back to the transmitting node device,
How a data transfer node device works. 13. The method of claim 12,
The data receiving node device
When the OFDM packet propagated through the first multi-hop communication path is finally received, signal energy is detected on K subcarriers constituting each of the S bands, and each band among the S bands Information on the communication scheduling method in each of the S bands by confirming that the information on the communication scheduling method is inserted for the band in which the sum of the energy detected from the K subcarriers is equal to or greater than the preset reference value After checking whether or not is inserted, information on the second communication scheduling method in which it is confirmed that information is not inserted in the S bands among the S communication scheduling methods is transmitted through the first multi-hop communication path. characterized in that the feedback to the data transmission node device,
How a data transfer node device works. delete A computer-readable recording medium recording a computer program for executing the method of any one of claims 8 to 13 through combination with a computer. A computer program stored in a storage medium for executing the method of any one of claims 8 to 13 through combination with a computer.

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