KR20180123889A - Terminal device, data tranmission device - Google Patents

Abstract

The present invention discloses a technique for improving quality of an internet of things (IoT) service by realizing a transmission channel selection manner (function) suitable for an IoT network in which an IoT terminal itself can select an optimal transmission channel and transmit data. A terminal device comprises: an information collecting part; and a channel selecting part.

Description

[0001] TERMINAL DEVICE, DATA TRANMISSION DEVICE [0002]

The present invention relates to Internet (IoT) technology, and more particularly to a technology for realizing a transmission channel selection function (function) suitable for an IoT network, in which an IoT terminal itself can select an optimal transmission channel and transmit data .

Internet of Things (IoT) technology, which connects information of living things through wired / wireless networks in various fields such as healthcare, remote meter reading, smart home, smart car and smart farm, is attracting attention.

The following is a brief description of the IoT network structure for providing the Internet (IoT) service based on the Internet (IoT) technology.

The IoT network includes a remote object Internet (IoT) terminal, a client terminal having an object Internet application (hereinafter referred to as " IoT application ") for checking data of the remote IoT terminal and controlling the IoT terminal, And a base station (hereinafter referred to as IoT base station) serving as a gateway for performing packet transmission / reception between a network device (or IoT app server) for connecting customer terminals (IoT apps) through a wired / wireless network, an IoT terminal and a network device .

In the Internet (IoT) service provided in the IoT network structure, when the IoT terminal transmits an uplink packet (data, response, etc.) to a network device, the IoT terminal transmits an uplink packet in a broadcast manner And a plurality of IoT base stations receive and transmit the same to a network device.

In the Internet Internet (IoT) service, when a network device transmits a downlink packet (response, data, etc.) to the IoT terminal, the network device transmits a downlink packet to one IoT base station selected by the IoT terminal , And the one IoT base station receiving it transmits to the object Internet terminal.

In this Internet of Object (IoT) technology, a high degree of computation is not introduced to the IoT terminal in consideration of the low power support of the IoT terminal.

When data to be transmitted is generated in the IoT terminal, the IoT terminal selects an arbitrary frequency transmission channel from among a plurality of transmission channels available for data transmission, for example, N transmission channels, And transmits a packet (data).

As described above, the current Internet (IoT) technology does not suggest a separate scheme for allowing the IoT terminal itself to select an optimum transmission channel.

Accordingly, the present invention proposes a transmission channel selection function (function) suitable for the IoT network, in which the IoT terminal itself can select an optimal transmission channel and transmit data.

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a transmission channel selection function (function) suitable for an IoT network, in which an IoT terminal itself can select an optimal transmission channel and transmit data, Thereby improving the quality of the Internet (IoT) service.

According to a first aspect of the present invention, there is provided a terminal device including at least one of data transmission information using a transmission channel or response reception information returned at the time of data transmission, for each of a plurality of transmission channels available for data transmission, An information collecting unit for collecting channel state information based on the channel state information; And a channel selector for selecting a transmission channel, which is determined to have the highest transmission success rate based on the channel state information for the plurality of transmission channels among the plurality of transmission channels, to be used for data transmission when data to be transmitted is generated, .

The channel selection unit may arbitrarily select a transmission channel to be used for data transmission among the plurality of transmission channels when the channel state information for each of the plurality of collected transmission channels is invalid.

Advantageously, the terminal device is capable of receiving a response to the data a predetermined number of times in a predetermined time period after data transmission.

Preferably, the data transmission information includes at least one of a number of times of data transmission using the transmission channel or a number of times of data retransmission, and the response reception information includes at least one of a number of successes of receiving a response, The measured reception sensitivity, and information on how many times of the specific number of times the reception of the response is received.

Preferably, the information collecting unit collects channel state information for the one transport channel and transmits the channel state information for each of the plurality of transport channels at each time of data transmission using one of the plurality of transport channels. You can update it.

Preferably, the information collecting unit may determine that the channel state information for each of the plurality of transport channels, which have been collected, is valid when the updated channel state information for each of the plurality of transport channels exceeds a preset reference size.

According to a second aspect of the present invention, there is provided a data transmission apparatus including: an information collection unit for collecting channel state information based on data reception information using a transmission channel from a terminal for each of a plurality of transmission channels; And transmitting the transmission channel determined to have the highest transmission success rate based on the channel state information for each of the plurality of transmission channels collected for the terminal among the plurality of transmission channels, And a channel selection unit for selecting a transmission channel to be used.

According to a third aspect of the present invention, there is provided a recording medium on which a command for performing a transmission channel selection function is recorded. The recording medium records data transmission information using a transmission channel or a response An information collecting step of collecting channel state information based on at least one of reception information; A selecting step of selecting, as a transmission channel to be used for data transmission, a transmission channel determined to have the highest transmission success rate based on channel state information of the plurality of transmission channels among the plurality of transmission channels, when generating data to be transmitted .

Thus, according to the terminal device and the transmission channel selection function (scheme) of the present invention, by realizing a transmission channel selection function (function) suitable for the IoT network, in which the IoT terminal itself can select the optimal transmission channel and transmit data, The effect of improving the quality of the Internet (IoT) service can be obtained.

FIG. 1 is an exemplary diagram illustrating a structure of an Internet (IoT) network to which the present invention is applied.
2 is a block diagram illustrating a configuration of a terminal device according to a preferred embodiment of the present invention.
3 is a block diagram showing the configuration of a data transmission apparatus (base station or network apparatus) according to a preferred embodiment of the present invention.
FIG. 4 is an exemplary diagram illustrating a restriction state in which a terminal device according to the present invention receives a response. FIG.
5 is an execution flowchart showing a process of executing a transmission channel selection function (scheme) according to a preferred embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

FIG. 1 shows a network structure of Internet of Things (IOT) to which the present invention is applied.

1, the object Internet (IoT) network structure to which the present invention is applied is configured to check data of a remote IoT terminal (e.g., terminals 1, 2, ..., X) and a remote IoT terminal, (IoT app server), an IoT terminal, and a network device (not shown) for connecting an IoT terminal and a customer terminal (IoT app) via a wired / wireless network 10) is composed of an IoT base station (for example, base stations 1, 2, ..., L) serving as a gateway for performing packet transmission and reception.

An uplink / downlink transmission process of the Internet (IoT) service provided in the IoT network structure will be briefly described as follows.

First, when the IoT terminal transmits an uplink packet (data, response, etc.) to a network device, the IoT terminal transmits an uplink packet in a broadcast manner, and a plurality of IoT base stations receive the uplink packet, .

Also, when the network device transmits a downlink packet (response, data, etc.) to the IoT terminal, the network device transmits a downlink packet to one IoT base station selected by the IoT terminal, To the object Internet terminal.

The quality of the Internet (IoT) service provided in the IoT network structure is greatly influenced by the transmission success rate of the uplink / downlink packets transmitted and received between the three nodes of the IoT terminal / IoT base station / network device.

Therefore, in the IoT network using the frequency of the license-exempted band, the transmission success rate of the uplink / downlink packet will be increased only if the packet collision transmitted and received through the transmission channel of the license-exempt frequency can be avoided.

On the other hand, in the Internet of Object (IoT) technology, a high degree of computation is not introduced to the IoT terminal in consideration of the low power support of the IoT terminal.

When data to be transmitted is generated in the IoT terminal, the IoT terminal selects an arbitrary transmission channel from among a plurality of transmission channels, for example, N transmission channels available for data transmission, Link packet).

As described above, in the current Internet (IoT) technology, the IoT terminal selects a transmission channel among a plurality of transmission channels at each generation of data to be transmitted and transmits data through the selected transmission channel. Thus, a disadvantage There is a high possibility of impulse.

Therefore, in the IoT network, it is necessary to search for another scheme for allowing the IoT terminal itself to select an optimal transmission channel.

Accordingly, the present invention proposes a transmission channel selection function (function) suitable for the IoT network, in which the IoT terminal itself can select an optimal transmission channel and transmit data.

More specifically, in the present invention, a terminal device for realizing a transmission channel selection function (function) is proposed.

Hereinafter, a terminal device according to a preferred embodiment of the present invention will be described in detail with reference to FIG.

The terminal device 100 of the present invention includes information for collecting channel state information based on at least one of data transmission information using a transmission channel or response reception information returned at the time of data transmission for each of a plurality of transmission channels available for data transmission And a transmission unit for transmitting the transmission channel determined to have the highest transmission success rate based on the channel state information for each of the plurality of transmission channels among the plurality of transmission channels, And a channel selection unit 120 for selecting a channel.

In addition, the terminal device 100 of the present invention may include a communication unit 130 for transmitting an uplink packet (data, response, etc.) and receiving a downlink packet (response, data, etc.).

Here, the terminal device 100 of the present invention may be one of the IoT terminals (e.g., terminals 1, 2, ..., X) mentioned in the description of FIG.

Hereinafter, for convenience of explanation, the terminal device 100 of the present invention will be described by referring to one terminal, for example, one terminal, of the IoT terminals, i.e., terminals 1, 2, ...,

The information collecting unit 110 collects channel state information based on at least one of data transmission information using a transmission channel or response reception information returned at the time of data transmission, for each of a plurality of transmission channels available for data transmission.

More specifically, the terminal device 100 of the present invention, which is an IoT terminal, recognizes information on a plurality of transmission channels, for example, N transmission channels available for data transmission, from the base station.

For example, the terminal apparatus 100 can receive information on N transmission channels from the base station (e.g., base station 1) selected by the network apparatus 10 as a downlink base station for the terminal apparatus 100 have.

The information collecting unit 110 collects channel state information for a plurality of transmission channels, for example, N transmission channels.

More specifically, the information collecting unit 110 acquires data using any of the plurality of transmission channels, regardless of the transmission channel selected by the channel selecting unit 120, which will be described later, At each transmission, channel state information for one transmission channel used for data transmission is collected and channel state information for a plurality of transmission channels is updated.

At this time, the data transmission information includes at least one of the number of times of data transmission using the transmission channel or the number of data retransmission.

The response reception information includes at least one of a response reception success count, a reception sensitivity measured at the time of receiving a response, and information on a reception time of the specific number at the time of reception of a response at the time of data transmission using the transmission channel do.

Accordingly, the channel state information for each of a plurality of transmission channels includes data transmission information, i.e., the number of times of data transmission using the transmission channel, the number of data retransmissions, and the number of times of response reception, The received sensitivity and the number of times of the specific number of times when the response is received.

In the IoT network, the IoT terminal is divided into several types according to the receivable time in the downlink packet reception method. Among these types, the IoT terminal has to transmit data (uplink packet) after data transmission (uplink packet transmission) There is a type (hereinafter referred to as a reception restriction type) capable of receiving a response (downlink packet) by a specific number of time intervals in a certain period of time.

For example, assuming that a predetermined time is 1 second and a specific number is 2, as shown in FIG. 3, the IoT terminal operating as the reception restriction type transmits, after data transmission (uplink packet transmission) The downlink packet can be received in the first time interval RX1 after 1 second based on the time point t1 and the second time interval RX2 after 1 second based on the ending time of the first time interval RX1 Downlink packet reception is possible.

The above-mentioned reception restriction type is an IoT terminal used in IoT technology (LoRa: Long Range) specialized in small amount data transmission supporting low-rate transmission (<1 kbps) and low power This mainly adopts / operates.

Hereinafter, it is assumed that the terminal device 100 of the present invention is an IoT terminal operating in a type having a time interval and a number of times restriction in receiving a downlink packet (response) as described above.

Further, in the IoT network, the uplink / downlink frequency bands are defined to be used equally.

Accordingly, in the terminal 100, more specifically, the communication unit 130 transmits data using a transmission channel (e.g., a first frequency transmission channel) among a plurality of transmission channels, e.g., N transmission channels (Downlink packet) to be returned to this data will also be received by the communication unit 130, more specifically, through the first frequency transmission channel.

More specifically, in the communication unit 130 of the terminal device 100, data transmission (uplink packet transmission) using one of a plurality of transmission channels, for example, N transmission channels (e.g., a first frequency transmission channel) The information collecting unit 110 increases the number of times of data transmission using the first frequency transmission channel by one and increases the number of times of successful reception of the response upon receiving a response (downlink packet) by one, And a method of recording information on how many times the response reception is received in the specified number of times (for example, twice) (for example, RX1 or RX2) , And collect / update channel state information for the first frequency transmission channel.

In addition, the information collecting unit 110 collects the number of data retransmissions using the first frequency transmission channel once (in the uplink packet retransmission) due to the failure in receiving the response (downlink packet) using the first frequency transmission channel The channel state information for the first frequency transmission channel can be collected / updated.

In this manner, the information collecting unit 110 collects channel state information in the same manner as the channel state information collection for the first frequency transmission channel at the time of data transmission using any one of the plurality of transmission channels , And update channel state information for a plurality of transmission channels.

Whenever the channel state information is updated for each of a plurality of transmission channels, the information collecting unit 110 determines whether the updated channel state information for each of the plurality of transmission channels is greater than or equal to a preset reference size, It can be determined that the channel status information for each of the plurality of transport channels is valid.

Hereinafter, a state in which channel state information for a plurality of collected transport channels is invalid, that is, a state in which channel state information is continuously collected is referred to as a collection mode.

In addition, it is assumed that the collecting mode is released in a state in which channel state information for a plurality of collected transport channels is valid, that is, a sufficient amount of channel state information is collected for each of a plurality of transport channels.

The channel selection unit 120 determines whether the channel state information for each of the plurality of transmission channels, which are collected by the information collection unit 110, is valid when the transmission target data to be transmitted from the terminal device 100 is generated.

For example, the channel selection unit 120 may determine that the channel state information for each of a plurality of transmission channels is valid when the current collection mode is released (DISABLE) according to the result of the determination by the information collecting unit 110 .

On the other hand, the channel selection unit 120 may determine that channel state information for a plurality of transmission channels is invalid if the current acquisition mode state is determined according to the result of the previous determination by the information collection unit 110. [

If the channel state information for each of the plurality of collected transport channels is valid (collection mode DISABLE), the channel selection unit 120 selects a transmission channel to be used for data transmission among a plurality of transmission channels, Choose based on information.

More specifically, the channel selection unit 120 may select a specific transmission channel determined to have the highest transmission success rate based on channel state information for a plurality of transmission channels among a plurality of transmission channels.

In this case, determining which transmission channel of the plurality of transmission channels has the highest transmission rate based on the channel state information for each of the plurality of transmission channels is determined based on the channel state information (the number of data transmissions, the number of data retransmissions, Response weighting, response reception sensitivity and time interval of response reception), or how to combine the elements in various ways.

However, the decision algorithm is designed such that the higher the ratio of response reception success rate in data transmission / retransmission, the better the response reception sensitivity, the longer the time interval in response reception, the higher the transmission success rate of the transmission channel .

Hereinafter, it will be assumed that a first frequency transmission channel is selected as a specific transmission channel among a plurality of transmission channels, for example, N transmission channels.

That is, the channel selection unit 120 may select a specific transmission channel, i.e., a first frequency transmission channel, which is determined to have the highest transmission success rate based on channel state information for a plurality of transmission channels among a plurality of transmission channels.

In this case, the communication unit 130 transmits the currently generated data (uplink packet) to be transmitted in the terminal device 100 in a broadcast manner using a specific transmission channel, that is, the first frequency transmission channel .

Accordingly, a plurality of IoT base stations, which receive uplink packets (data) of the terminal 1 in the vicinity of the terminal device 100 (terminal 1) of the present invention, will transmit uplink packets of the terminal 1 to the network device 10. [

The response (downlink packet) from the network device 10 to this data is transmitted to the terminal device 100, the terminal 1 (E.g., base station 1) as a downlink base station for the base station (e.g., base station 1).

At this time, the information collecting unit 110 also collects channel state information on the first frequency transmission channel in accordance with the current data transmission using the first frequency transmission channel, thereby updating the channel state information for a plurality of transmission channels something to do.

On the other hand, the channel selection unit 120 arbitrarily selects a transmission channel to be used for data transmission among a plurality of transmission channels when the channel state information for each of the plurality of collected transmission channels is invalid (the collection mode).

That is, the channel selection unit 120 selects an arbitrary frequency transmission channel from among a plurality of transmission channels, for example, N transmission channels, as in the conventional case, while the acquisition mode is maintained.

In this case, the communication unit 130 transmits the data (uplink packet) to be transmitted, which has been generated in the terminal device 100, to a broadcast system using an arbitrary transmission channel (e.g., a third frequency transmission channel) .

Accordingly, a plurality of IoT base stations, which receive uplink packets (data) of the terminal 1 in the vicinity of the terminal device 100 (terminal 1) of the present invention, will transmit uplink packets of the terminal 1 to the network device 10. [

The response (downlink packet) from the network device 10 to this data is transmitted to the terminal device 100, the terminal 1 (E.g., base station 1) as a downlink base station for the base station (e.g., base station 1).

At this time, the information collecting unit 110 also collects channel state information about the third frequency transmission channel in the same manner as described above according to the current data transmission using the third frequency transmission channel, thereby updating channel state information for a plurality of transmission channels something to do.

In addition, the functions (transmission channel selection function) performed by the information collection unit 110 and the channel selection unit 120 of the present invention may be implemented in the form of a program or an application.

As described above, the terminal apparatus according to the present invention collects / updates channel state information on a transport channel used for data transmission (uplink packet transmission) State information can be databaseized by itself.

Accordingly, the terminal device according to the present invention can transmit data by selecting an optimal transport channel by itself, based on the channel state information for each transport channel obtained by making a data face of itself.

In this case, since each terminal device (IoT terminal) according to the present invention selects an optimal transport channel by itself in the IoT network, the disadvantage of using the frequency of the license-exempt band, that is, the possibility of packet impulsiveness, The transmission success rate of the downlink packet will increase.

As a result, according to the present invention, it is possible to improve the quality of the Internet (IoT) service by realizing a transmission channel selection function (function) suitable for the IoT network, in which the IoT terminal itself can select the optimal transmission channel and transmit data Effect can be derived.

On the other hand, in the above description, the terminal apparatus (IoT terminal) according to the present invention selects the optimum transmission channel by itself based on the uplink transmission.

Assuming that downlink transmission is a standard, the functions performed by the functional units of the terminal device according to the present invention are realized in the base station or the network device, so that the base station or the network device transmits data to the IoT terminal Downlink packet transmission). &Lt; / RTI &gt;

Specifically, the specific data transmitted from the network device 10 to the terminal device 100 is transmitted to the network device 10 by the base station that has received the specific data from the network device 10, Lt; / RTI &gt;

In this case, the specific data is preferably network initiated data that is initiated in the network device 10 and transmitted to the terminal device 100, instead of responding to the data transmitted from the terminal device 100.

To this end, the present invention proposes a data transmission apparatus.

As shown in FIG. 3, the data transmission apparatus 200 according to the present invention includes an information collecting unit (not shown) for collecting channel state information based on data reception information using a transmission channel from a terminal (210) for transmitting data to the terminal (1), and a transmitter (210) for transmitting data to the terminal (1) based on the channel state information of the plurality of transmission channels And a channel selection unit 220 for selecting a transmission channel to be used for data transmission.

The data transmission apparatus 200 of the present invention may be an IoT base station, i.e., a base station 1, 2, ..., L, serving as a gateway for transmitting and receiving a packet between the terminal and the network apparatus 10, Lt; / RTI &gt;

One embodiment is a method for constructing channel state information at a base station.

When generating the start data to be transmitted from the network device 10 to the terminal device 100, the network device 10 transmits the start data to the downlink base station (e.g., base station 1) selected by the terminal device 100 (Downlink packet).

For example, when the data transmission apparatus 200 of the present invention is the base station 1, the information collecting unit 210 acquires the transmission channel at each time of data reception (uplink packet reception) from the terminal apparatus 100 (terminal 1) The channel state information for each of the plurality of transmission channels is collected in units of terminals on the basis of the received data reception information (signal-to-noise ratio (SNR), reception sensitivity (RSSI) can do.

The channel selection unit 220 of the base station 1, that is, the channel selection unit 220 of the data transmission apparatus 200 that has received the start data transmitted from the network device 10 to the terminal device 100 (terminal 1) (For example, a first frequency transmission channel) among the plurality of transmission channels, for example, N transmission channels, based on the plurality of channel state information for each transmission channel, The downlink packet can be transmitted to the terminal device 100 (terminal 1) using the channel.

Yet another embodiment is a method for constructing channel state information in a network device.

When generating the start data to be transmitted from the network device 10 to the terminal device 100, the network device 10 transmits the start data to the downlink base station (e.g., base station 1) selected by the terminal device 100 (Downlink packet).

For example, in the case where the data transmission apparatus 200 of the present invention is the network apparatus 10, the information collecting unit 210 acquires, for each data reception (uplink packet reception) from the terminal apparatus 100 (terminal 1) A method of collecting / updating channel state information for a currently used transmission channel based on data reception information (signal-to-noise ratio (SNR) and reception sensitivity (RSSI)) using a transmission channel, Can be converted into a database.

The channel selection unit 220 of the network device 10, that is, the data transmission apparatus 200, based on the channel state information for each of a plurality of transmission channels, (E.g., the first frequency transmission channel) among the plurality of transmission channels.

Thus, the network device 10 may request to use a transmission channel (e.g., a first frequency transmission channel) in transmission of a downlink packet to the terminal 1, and the base station 1 transmits the requested transmission channel Channel) to the terminal device 100 (terminal 1).

In this case, since the IoT network defines the use of the same uplink / downlink frequency band, the response (uplink packet) from the terminal device 100 to this data is transmitted using the first frequency transmission channel A plurality of IoT base stations to receive the uplink packet (response) of the terminal 1 around the terminal device 100 (terminal 1) will transmit the uplink packet of the terminal 1 to the network device 10.

Hereinafter, with reference to FIG. 4, a description will be made of a process in which the transmission channel selection function (scheme) proposed in the present invention is executed.

Meanwhile, the transmission channel selection function proposed by the present invention can be realized in the IoT terminal, or in the form of a program or an application, and can be realized based on mounting / execution in the IoT terminal.

Therefore, in the following, the operation of the IoT terminal, more specifically, the operation method of the terminal device 100 (terminal 1) will be described with reference to the transmission channel selection function (scheme) proposed by the present invention.

According to the transmission channel selection function (method) of the present invention, the terminal device 100 (terminal 1) determines whether the channel state information for each of a plurality of transport channels that have been collected is valid (S110).

According to the transmission channel selection function of the present invention, the terminal device 100 (terminal 1) collects / updates channel state information on a transport channel to be used for each data transmission (uplink packet transmission) The channel status information for each transport channel can be converted into a database by itself through data transmission history based learning.

The description of the channel state information database for each transport channel will be described again in S130 and S180 described later.

Accordingly, the terminal device 100 (terminal 1) determines whether the channel state information for each of a plurality of transmission channels (collected) is valid (S 110) when data to be transmitted is generated (S 100) .

For example, the terminal apparatus 100 (terminal 1) can determine that the channel status information for each of a plurality of transport channels (collected) is valid if it is greater than or equal to the reference size (Yes in S110, DISABLE in the collection mode) (S110 No, collecting mode).

When the channel state information for each of a plurality of transport channels held (collected) is not valid (S110 No, collection mode), the terminal apparatus 100 (terminal 1) arbitrarily selects a transport channel to be used for data transmission among a plurality of transport channels (S120).

That is, while the acquisition mode is maintained, the terminal device 100 (terminal 1) selects an arbitrary frequency transmission channel from among a plurality of transmission channels, for example, N transmission channels, as in the conventional case.

Then, the terminal apparatus 100 (terminal 1) broadcasts the data (uplink packet) to be transmitted at this time in the terminal apparatus 100 by using an arbitrary transmission channel (for example, a third frequency transmission channel) (S120).

Accordingly, a plurality of IoT base stations, which receive uplink packets (data) of the terminal 1 in the vicinity of the terminal device 100 (terminal 1) of the present invention, will transmit uplink packets of the terminal 1 to the network device 10. [

The response (downlink packet) from the network device 10 to this data is transmitted to the terminal device 100, the terminal 1 (E.g., base station 1) as a downlink base station for the base station (e.g., base station 1).

At this time, according to the current data transmission using the third frequency transmission channel, the terminal device 100 (terminal 1) can collect channel state information about the third frequency transmission channel, thereby updating channel state information for a plurality of transmission channels (S130).

Specifically, the terminal device 100 (terminal 1) increases the number of times of data transmission using the third frequency transmission channel by one, in accordance with data transmission (uplink packet transmission) using the third frequency transmission channel, (RSSI) of response reception is increased by increasing the number of times of successful reception of the response (downlink packet) by one time, and the response reception is recorded by recording a response time of a certain number of times (for example, twice) : RX1 or RX2), the channel state information for the third frequency transmission channel can be collected / updated.

In addition, the terminal device 100 (terminal 1) transmits the number of data retransmissions using the third frequency transmission channel at the time of data retransmission (uplink packet retransmission) due to a failure in receiving a response (downlink packet) using the third frequency transmission channel The channel state information for the third frequency transmission channel can be collected / updated in a manner that the channel state information is incremented by one.

In this manner, the terminal device 100 (terminal 1) can acquire channel state information in the same manner as the channel state information collection for the third frequency transmission channel at the time of data transmission using any one of the plurality of transmission channels Thereby updating channel state information for a plurality of transmission channels.

At this time, each time the terminal device 100 or the terminal 1 updates channel state information for a plurality of transmission channels, it determines whether the updated channel state information for each transmission channel is greater than a preset reference size (S140) It is judged that the channel state information for each of the plurality of transport channels held (collected) is valid (S150, collection mode DISABLE).

On the other hand, when the channel status information for each of a plurality of transport channels held (collected) is valid (Yes in S110, DISABLE in the collection mode), the terminal device 100 (terminal 1) And selects channel state information for a plurality of transmission channels based on the channel state information (S160).

More specifically, the terminal device 100 (terminal 1) can select a specific transmission channel determined to have the highest transmission success rate based on channel state information for a plurality of transmission channels among a plurality of transmission channels.

In this case, determining which transmission channel of the plurality of transmission channels has the highest transmission rate based on the channel state information for each of the plurality of transmission channels is determined based on the channel state information (the number of data transmissions, the number of data retransmissions, Response weighting, response reception sensitivity and time interval of response reception), or how to combine the elements in various ways.

However, the decision algorithm is designed such that the higher the ratio of response reception success rate in data transmission / retransmission, the better the response reception sensitivity, the longer the time interval in response reception, the higher the transmission success rate of the transmission channel .

Hereinafter, it will be assumed that a first frequency transmission channel is selected as a specific transmission channel among a plurality of transmission channels, for example, N transmission channels.

That is, the terminal 100 (terminal 1) can select a specific transmission channel, i.e., a first frequency transmission channel, which is determined to have the highest transmission success rate based on channel state information for a plurality of transmission channels among a plurality of transmission channels have.

In this case, the terminal device 100 (terminal 1) transmits the data (uplink packet) to be transmitted, which is now generated in the terminal device 100, to the terminal device 100 through a specific transmission channel, (S170).

Accordingly, a plurality of IoT base stations, which receive uplink packets (data) of the terminal 1 in the vicinity of the terminal device 100 (terminal 1) of the present invention, will transmit uplink packets of the terminal 1 to the network device 10. [

The response (downlink packet) from the network device 10 to this data is transmitted to the terminal device 100, the terminal 1 (E.g., base station 1) as a downlink base station for the base station (e.g., base station 1).

At this time, the terminal device (100, terminal 1) collects channel state information for the first frequency transmission channel according to the current data transmission using the first frequency transmission channel, (S180).

Then, the terminal device 100 (terminal 1) repeats the above-described steps S110 to S180 every time data to be transmitted occurs (S100) until the in-use Internet IoT service is terminated (No in S190) .

As described above, according to the transmission channel selection function (scheme) proposed by the present invention, the IoT terminal itself can select the optimal transmission channel and transmit the data. The effect of improving the quality of the Internet (IoT) service can be obtained.

The transmission channel selection function according to an exemplary 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, and the like, alone or in combination. The program instructions recorded on the medium may be those specially designed and constructed for the present invention or may be available to those skilled in the art of computer software. Examples of computer-readable media include magnetic media such as hard disks, floppy disks and magnetic tape; optical media such as CD-ROMs and DVDs; magnetic media such as floppy disks; Magneto-optical media, and hardware devices specifically configured to store and execute program instructions such as ROM, RAM, flash memory, and the like. Examples of program instructions include machine language code such as those produced by a compiler, as well as high-level language code that can be executed by a computer using an interpreter or the like. The hardware devices described above may be configured to operate as one or more software modules to perform the operations of the present invention, and vice versa.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

According to the terminal device and the transmission channel selection function (function) of the present invention, in realizing a transmission channel selection function (function) suitable for the IoT network, in which the IoT terminal itself can select the optimal transmission channel and transmit data, It is an invention that is industrially applicable because it is beyond the limit of the existing technology, and it is not only the use of the related technology, but also the possibility of commercialization or operation of the applied device is sufficient and practically possible.

10: Network device
100: terminal device
110: information collecting unit 120: channel selecting unit
130:

Claims (8)

An information collecting unit for collecting channel state information based on at least one of data transmission information using a transmission channel or response reception information returned at the time of data transmission, for each of a plurality of transmission channels available for data transmission; And
And a channel selection unit selecting a transmission channel determined to have the highest transmission success rate as a transmission channel to be used for data transmission based on the channel state information of the plurality of transmission channels among the plurality of transmission channels, And the terminal device. The method according to claim 1,
Wherein the channel selector comprises:
And selects a transmission channel to be used for data transmission among the plurality of transmission channels when channel state information for each of the plurality of transmission channels collected is not valid. The method according to claim 1,
Wherein the terminal device is capable of receiving, after data transmission, a response to the data by a predetermined number of time intervals in a predetermined period of time. The method of claim 3,
Wherein the data transmission information includes at least one of a number of times of data transmission using a transmission channel or a number of data retransmission,
The response reception information includes at least one of a response reception success count, a reception sensitivity measured at the time of receiving a response, and information on a reception time interval of the specific number at the time of receiving a response at the time of data transmission using a transmission channel . The method according to claim 1,
The information collecting unit,
And collects channel state information for the one transport channel and updates channel state information for each of the plurality of transport channels whenever data is transmitted using one of the plurality of transport channels. 6. The method of claim 5,
The information collecting unit,
Wherein the controller determines that the channel state information for each of the plurality of transport channels that are collected is valid if the updated channel state information for each of the plurality of transport channels is greater than or equal to a preset reference size. An information collecting unit for collecting channel state information based on data reception information using a transmission channel from a terminal for each of a plurality of transmission channels; And
When generating data for transmission to the MS, a transmission channel determined to have the highest transmission success rate based on the channel state information for each of the plurality of transmission channels collected for the MS among the plurality of transmission channels is used for data transmission And a channel selection unit for selecting the transmission channel as a transmission channel. An information collecting step of collecting channel state information based on at least one of data transmission information using a transmission channel or response reception information returned at the time of data transmission for each of a plurality of transmission channels;
A selecting step of selecting, as a transmission channel to be used for data transmission, a transmission channel determined to have the highest transmission success rate based on channel state information of the plurality of transmission channels among the plurality of transmission channels, when generating data to be transmitted Wherein the computer-readable storage medium includes a computer-readable medium having computer-readable program code embodied thereon.

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