KR101990788B1 - Base station, networl apparatus and control method thereof - Google Patents

Abstract

The present invention realizes a new scheme (method) for optimizing a transmission time point at which a downlink packet is transmitted to a base station at a network end for each base station. By using a transmission delay time which is estimated in a lump manner for all IoT base stations, (IoT) service by avoiding a problem situation that may be caused by the Internet.

Description

TECHNICAL FIELD [0001] The present invention relates to a base station, a network device,

The present invention relates to Internet (IoT) technology, and more particularly, to a method and system for improving Internet quality (IoT) service by optimizing a transmission time point at which a downlink packet is transmitted to a base station Technology.

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 customer Internet terminal (IoT terminal) at a remote location, a customer terminal installed with a destination Internet application (hereinafter referred to as " IoT application ") for checking data of the remote IoT terminal and controlling the IoT terminal, And a gateway (eg, IoT base station) that performs packet transmission / reception between a network device (or IoT app server) that connects customer terminals (IoT apps) through a wired / wireless network, an IoT terminal, and a network device.

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

In the case of the uplink in which the IoT terminal transmits the uplink packet to the network device, the IoT terminal transmits the uplink packet in a broadcast manner, and the at least one IoT base station receives the packet and transmits it to the network device.

In the case of a downlink in which a network device transmits a downlink packet to the IoT terminal, the network device transmits a downlink packet to one downlink base station to the IoT terminal, and the downlink base station that receives the downlink packet transmits the downlink packet to the IoT terminal Method.

Meanwhile, in the interval between the network device and the IoT base station, there is a transmission delay (Tx Delay) due to the physical distance, and the transmission delay (Tx Delay) may vary depending on the physical distance.

Most of the IoT terminals are configured to wait for a downlink packet reception only for a predetermined time and receive only a downlink packet received at this time (for example, Type).

In order to transmit the downlink packet to the IoT terminal, the network device must transmit the downlink packet in advance so that it can be received at a predetermined time of the IoT terminal in consideration of the transmission delay (Tx Delay) between the network device and the downlink base station .

However, since the time of the transmission delay (Tx Delay) between the network device and the downlink base station (hereinafter referred to as the transmission delay time) can not be known in the network device, the time (transmission delay time) To transmit the downlink packet in advance.

In this case, when the network device transmits the downlink packet with the IoT base station, which is close to the network device, as the downlink base station, a situation occurs in which the downlink packet transmitted by the network device is received too early in the downlink base station.

When such a situation occurs, it takes a long time for the downlink base station to store the downlink packet in the internal buffer until the actual transmission time of the downlink packet to the terminal, and if the internal buffer amount is exceeded, the downlink packet received thereafter is stored It can lead to a situation where it can not be dropped.

However, in the current Internet (IoT) technology, a specific method for improving the problematic situation caused by transmission of the downlink packet using the transmission delay time which is collectively estimated for all the IoT base stations as described above It is not present.

Accordingly, in the present invention, a method for avoiding the above-mentioned problematic situation is proposed.

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 method and apparatus for transmitting a downlink packet using a transmission delay time, (Technology) that can avoid situations.

In order to achieve the above object, a network device according to a first aspect of the present invention is a network device for transmitting a downlink packet to be transmitted to a terminal to a specific base station at a transmission time calculated using a transmission delay time set in a specific base station A transmitting unit; A response receiver for receiving a response including a code value determined based on a reception time of the downlink packet received from the specific base station; And a transmission delay time changing unit for changing the transmission delay time set in the specific base station according to the code value in the response.

Preferably, the response includes at least one of a fast reception time when the reception time of the downlink packet received at the specific base station is faster than a transmission time point of the downlink packet, Lt; / RTI > may be included.

Preferably, the response includes, when the reception time of the downlink packet received at the specific base station is slower than the transmission time point of the downlink packet, The defined second code value may be included.

Preferably, the transmission delay time changing unit may change the transmission delay time set in the specific base station to a shorter transmission delay time than the previous transmission delay time, when the first code value is confirmed in the response.

Preferably, the transmission delay time changing unit may change the transmission delay time set in the specific base station to a longer transmission delay time than the previous transmission delay time, when the second code value is confirmed in the response.

Preferably, the terminal includes: a first type terminal capable of receiving a downlink packet only at a predetermined reception time interval based on a specific number of specific time intervals based on a time point at which the uplink packet is transmitted; And a second type of terminal capable of receiving a link packet.

According to a second aspect of the present invention, there is provided a method for operating a network device, the method comprising: transmitting a downlink packet to be transmitted to a mobile station to a specific base station at a transmission time calculated using a transmission delay time set in a specific base station Transmitting a packet; A response reception step of receiving a response including a code value determined based on a reception time of the downlink packet received from the specific base station; And a transmission delay time changing step of changing the transmission delay time set in the specific base station according to the code value in the response.

Preferably, the response includes at least one of a fast reception time when the reception time of the downlink packet received at the specific base station is faster than a transmission time point of the downlink packet, Lt; / RTI > may be included.

Preferably, the response includes, when the reception time of the downlink packet received at the specific base station is slower than the transmission time point of the downlink packet, The defined second code value may be included.

Preferably, the transmission delay time changing step may change the transmission delay time set in the specific base station to a shorter transmission delay time than the previous transmission delay time, when the first code value is confirmed in the response.

Preferably, the step of changing the transmission delay time may change the transmission delay time set in the specific base station to a longer transmission delay time than the previous transmission delay time when the second code value is confirmed in the response.

According to a third aspect of the present invention, there is provided a base station for transmitting a downlink packet to a terminal, the base station comprising: a base station for transmitting downlink packets transmitted from a network device at a transmission time calculated using a transmission delay time set in the base station, A packet receiving unit for receiving a packet; And a response transmission unit for returning a response including a code value determined based on a reception time point of the reception of the downlink packet to the network device and changing a transmission delay time set in the base station according to the code value in the response .

According to the operation method of the base station, the network device and the network device of the present invention, a new scheme (technique) for optimizing the transmission time point at which the downlink packet is transmitted from the network end to the base station is optimized for each base station, It is possible to obtain the effect of improving the quality of the Internet service (IoT) by avoiding the problematic situation which may be caused by using the transmission delay time which is collectively estimated.

FIG. 1 is an exemplary diagram illustrating a structure of an Internet (IoT) network to which the present invention is applied.
2 is an exemplary diagram illustrating a downlink packet transmission situation according to the prior art.
3 is a block diagram illustrating a configuration of a network device according to a preferred embodiment of the present invention.
4 is a block diagram illustrating a configuration of a base station according to a preferred embodiment of the present invention.
FIGS. 5 to 6 are diagrams illustrating an example in which a response (TxAck) is returned according to a scheme proposed by the present invention.
7 is a flowchart illustrating an operation method of a network device 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.

As shown in FIG. 1, the Internet IoT network structure to which the present invention is applied includes a remote Internet Internet terminal (IoT terminal, for example, terminals 1, 2, 3...), A network device 100 for connecting an IoT terminal and a customer terminal (IoT app) via a wired / wireless network, an IoT terminal, and a network device (not shown) IoT base stations (base stations 1, 2, ...) serving as gateways for performing packet transmission / reception between the base stations 1, 2, and 100.

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

In the case of an uplink in which an IoT terminal transmits an uplink packet to a network device, the IoT terminal transmits an uplink packet in a broadcast manner, and the at least one IoT base station receives and transmits the uplink packet to the network device, The transmission success rate of the packet is excellent.

On the other hand, in the case of a downlink in which a network device transmits a downlink packet to the IoT terminal, the network device transmits a downlink packet to one IoT base station (hereinafter referred to as a downlink base station) selected as a downlink base station for the IoT terminal, Since the received downlink base station transmits to the IoT terminal, it can be considered that the downlink packet transmission success rate is affected by which downlink base station is used.

Meanwhile, in the interval between the network device and the IoT base station, there is a transmission delay (Tx Delay) due to the physical distance, and the transmission delay (Tx Delay) may vary depending on the physical distance.

Most of the IoT terminals wait for reception of a downlink packet only at a predetermined time (reception time interval, period section, which will be described later) rather than at all times because the power (battery) (Reception period, reception period, period) of the downlink packet.

Accordingly, in order for the network device to transmit the downlink packet to the IoT terminal, it is necessary to transmit the downlink packet to the IoT terminal in consideration of the transmission delay (Tx Delay) between the network device and the downlink base station, The downlink packet must be transmitted in advance.

However, since the time of the transmission delay (Tx Delay) between the network device and the downlink base station can not be known in the network device, the downlink (downlink) The packet is transmitted in advance.

In this case, when the network device transmits the downlink packet with the IoT base station, which is close to the network device, as the downlink base station, a situation occurs in which the downlink packet transmitted by the network device is received too early in the downlink base station.

Hereinafter, with reference to FIG. 2, a downlink packet transmission situation according to existing technology using a time (transmission delay time) estimated in a lump manner for all IoT base stations will be briefly described.

2, when an uplink packet transmitted by a terminal 1 in a broadcast manner is transmitted to a network device via one or more base stations including a base station and the network device selects the base station 1 as a downlink base station for the terminal 1 .

2, the terminal 1 is assumed to be a terminal of the "downlink packet reception restriction type (= first type)" to be described later.

The terminal 1 of the first type transmits an uplink packet and transmits the uplink packet to the terminal 1 based on the reception time intervals DL1 and DL2 defined by a specified number of times (for example, twice) , Each one second) can receive downlink packets.

Therefore, as shown in FIG. 2, when the terminal 1 transmits the uplink packet (UL), the terminal 1 must receive the downlink packet (DL) during the first reception time period corresponding to a specific time, do.

The network device transmits the downlink packet (DL) to the terminal 1 at the transmission time calculated using the transmission delay time which is collectively estimated for all the IoT base stations to the base station 1, (DL) to be received by the terminal 1 within the first reception time interval.

2, the base station 1 stores the downlink packet DL of the terminal 1 in the internal buffer until the terminal 1 has to transmit the downlink packet DL to the terminal 1, and then transmits the downlink packet DL to the terminal 1.

At this time, the transmission time calculated by the network device corresponds to a time point elapsed by a time obtained by subtracting the transmission delay time from the reception time of the uplink packet (UL) of the terminal 1 at a specific time, i.e., 1 second.

Here, the actual transmission delay (Tx Delay) between the network device and the base station 1 will be different due to the physical distance between the network device and the base station 1. The network device calculates the transmission time at which the downlink packet DL of the terminal 1 is transmitted The downlink packet DL transmitted by the network device is received too early for the base station 1, and the downlink packet DL transmitted by the network device is received too early A situation will arise.

If such a situation occurs, the buffer time for storing the downlink packet DL in the internal buffer until the time when the base station 1 actually transmits the downlink packet DL to the terminal 1 becomes long, and if the internal buffer amount is exceeded, The link packet can not be stored and can be dropped.

However, in the current Internet (IoT) technology, a specific method for improving the problematic situation caused by transmission of the downlink packet using the transmission delay time which is collectively estimated for all the IoT base stations as described above It is not present.

Accordingly, the present invention proposes a scheme for avoiding a problem situation that may be caused by transmitting a downlink packet by using a transmission delay time which is collectively estimated for all IoT base stations.

More specifically, the present invention proposes a network apparatus that realizes a proposal for avoiding the above-described problem situation.

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

The network device 100 of the present invention includes a packet transmission unit 110 that transmits a downlink packet to be transmitted to a terminal to the specific base station at a transmission time calculated using a transmission delay time set in a specific base station, A response reception unit (120) for receiving a response including a code value determined based on a reception time point at which the downlink packet is received from a base station; and a transmission delay unit And a transmission delay time changing unit 130 for changing the transmission delay time.

The packet transmission unit 110 transmits the downlink packet to be transmitted to the terminal to the specific base station at the transmission time calculated using the transmission delay time set in the specific base station.

Here, the specific base station means an IoT base station selected as a downlink base station for the terminal.

Therefore, hereinafter, the downlink base station will be referred to as a downlink base station instead of the specific base station.

More specifically, in the present invention, an initial transmission delay time (for example, 500 msec) can be set for each IoT base station.

When a downlink packet to be transmitted to a terminal occurs, the packet transmission unit 110 identifies a downlink base station selected for the terminal.

Then, the packet transmission unit 110 calculates the transmission time point using the transmission delay time set in the downlink base station in order to transmit the downlink packet of the terminal.

The terminal may be a first type terminal capable of receiving a downlink packet only in a reception time interval determined by a specific number of specific time intervals based on a time point when the uplink packet is transmitted, And a second type of terminal capable of receiving a downlink packet.

The IoT terminal is classified into several types according to a downlink packet reception method. The IoT terminal is mainly classified into a type capable of receiving a downlink packet only when the IoT terminal first transmits an uplink packet (hereinafter referred to as a downlink packet reception restriction type And a type in which a downlink packet can be received even if the IoT terminal does not transmit the uplink packet first (hereinafter, a downlink packet reception free type).

Here, the downlink packet reception restriction type means the above-mentioned first type.

Specifically, the IoT terminal of the downlink packet reception restriction type (= first type) transmits a response (downlink packet) to data (uplink packet) after data transmission (uplink packet transmission) It can be received only in the reception time interval of the interval.

For example, assuming that a specific number of times is 2, a reception time interval is 1 second, and a specific time interval between reception time intervals is 1 second, the IoT terminal operating as the first type transmits the pre- (Downlink) packet is transmitted (transmitted), and the downlink packet can be received at the first downlink reception time interval (DL1) after 1 second based on the completion time of the uplink packet transmission. At this time, It is possible to receive the downlink packet at a second receiving time interval (DL2) after 3 seconds based on the completion time of the uplink packet transmission after 1 second based on the ending time DL1.

This type of downlink packet reception restriction type (= first type) is one of the IoT technologies (LoRa (IoT)) which is specialized in small amount data transmission supporting low-speed transmission (<1 kbps) and low- : Long Range) is mainly adopted / operated.

On the other hand, the second type IoT terminal, which is one of the downlink packet reception free types, can receive the downlink packet periodically every predetermined period irrespective of whether the data (uplink packet) is transmitted (transmitted) or not.

Hereinafter, for convenience of description, the terminal 1 will be referred to as a first type terminal, the terminal 2 will be referred to as a second type terminal, and the base station 1 will be described as a downlink base station selected for both the terminals 1 and 2.

Accordingly, if the downlink packet is transmitted to the terminal 1, the packet transmission unit 110 transmits the uplink packet to the terminal 1 after elapse of a predetermined time, i.e., a time obtained by subtracting the transmission delay time set in the base station 1 from the reception time of the uplink packet of the terminal 1 One point can be calculated as the transmission point.

The packet transmission unit 110 can calculate a transmission time point, which is obtained by subtracting the transmission delay time set for the base station 1 from the start time of the periodic section of the terminal 2, in the case of downlink packet transmission to the terminal 2.

Hereinafter, the terminal 1 of the first type will be described as a representative for convenience of explanation.

That is, the packet transmission unit 110 subtracts the transmission delay time (the initial transmission delay time or the changed transmission delay time, which will be described later) set for the base station 1 at a specific time, that is, 1 second from the reception time of receiving the uplink packet of the terminal 1 The time point that has elapsed by the time will be calculated as the transmission time point.

Then, the packet transmission unit 110 transmits the downlink packet to be transmitted to the terminal 1 to the base station 1 at the calculated transmission time point.

The response reception unit 120 receives a response including a code value determined based on the reception time of the downlink packet received from the specific base station, that is, the base station 1.

More specifically, in the Internet of Object (IoT) technology, a code value (eg, normal, error (Too Early) is determined between the network device and the IoT base station, based on the reception time of the downlink packet received from the network device Or Too Late) is defined.

In the Internet of Things (IoT) technology, a specific field (e.g., an imme field / tmst field / time field) indicating information related to a time point at which the IOT base station should transmit the downlink packet is defined in the header of the downlink packet .

In the Internet (IoT) technology, in the case of the downlink packet transmitted to the terminal of the second type by the network device 100, "false" is written in the imme field, The IoT base station receives the downlink packet and stores it in the buffer when the imme field is "false" in the header of the downlink packet and the tmst field has no value and the time field has the "time value" And stores it and transmits it to the terminal when the time is "time value".

In the Internet (IoT) technology, the network device 100 records "false" in the imme field in the case of the downlink packet transmitted to the terminal of the first type, and adds "time" and " Tmst value "to the IoT base station. If the imme field is" false " in the header of the downlink packet and the tmst field contains the "tmst value ", the IoT base station internal type stamp counter and "tmst value ".

As shown in FIG. 5, in the present invention, the IoT base station determines whether or not the reception time of the downlink packet received from the IoT base station is equal to the transmission time point The first code value (Too Early) defined for the fast reception is determined to be TxAck (t) if the Txst value is faster than the predetermined threshold time (t) (Response).

As shown in FIG. 5, in the present invention, the IoT base station determines whether or not the IoT base station has received the downlink packet from the IoT base station, The second code value (Too Late) defined for the slow reception is determined, and the TxAck (TxAck) value is determined for the slow reception if the threshold value is slower than the predetermined threshold time (t) (Response).

The response reception unit 120 receives the TxAck (response) including the code value from the base station 1 after transmitting the downlink packet of the terminal 1 to the base station 1 at the transmission time in the packet transmission unit 110 .

At this time, the TxAck (response) returned from the base station 1 includes a transmission time point to the terminal 1 in which the reception time point at which the downlink packet is received at the base station 1 is confirmed in the header (specific field) of the downlink packet The first code value (Too Early) defined for the fast reception will be included if the reception time of the downlink packet is higher than the threshold value (t) (Tmst value in case of the first type) is slower than the threshold time (t) than the transmission time point to the terminal 1 (the first field), the second code value Too Late defined for the slow reception will be included .

The transmission delay time changing unit 130 changes the transmission delay time set in the base station 1 in accordance with the TxAck (response) in-code value (e.g., normal, error (Too Early or Too Late) returned from the base station 1).

More specifically, when the code value (normal) is confirmed in the TxAck (response) returned from the base station 1, the transmission delay time changing unit 130 will maintain the transmission delay time set in the base station 1 unchanged.

On the other hand, when the first code value (Too Early) is confirmed in the TxAck (response) returned from the base station 1, the transmission delay time changing unit 130 changes the transmission delay time set in the base station 1 to a short transmission time The delay time can be changed.

For example, when the first code value (Too Early) is confirmed in the TxAck (response) returned from the base station 1, the transmission delay time changing section 130 changes the transmission delay time set in the base station 1 the transmission delay time set in the base station 1 can be changed to a shorter transmission delay time compared to the previous transmission delay time.

When the second code value (Too Late) is confirmed in the TxAck (response) returned from the base station 1, the transmission delay time changing section 130 changes the transmission delay time set in the base station 1 to the long transmission time The delay time can be changed.

For example, when the second code value (Too Late) is confirmed in the TxAck (response) returned from the base station 1, the transmission delay time changing section 130 changes the transmission delay time set in the base station 1 (d), the transmission delay time set in the base station 1 can be changed to the long transmission delay time compared to the previous transmission delay time.

When the downlink packet is transmitted from the network device 100 to the subscriber station through the base station 1, the network device 100, particularly the packet transmitter 110, transmits the downlink packet of the subscriber station to the base station 1, And transmit it to the base station 1 at the transmission time calculated using the transmission delay time.

As described above, the network device 100 of the present invention changes the transmission delay time set in the base station 1 according to the code value in the TxAck (response) to be returned every time a downlink packet is transmitted through the base station 1 ) Will be repeated.

Therefore, the transmission delay time of the base station 1 used in the calculation of the transmission time point for transmitting the downlink packet to the base station 1 in the network device 100 is determined by the actual transmission delay Tx (Tx) due to the physical distance between the network device 100 and the base station 1 Delay so that the transmission time point at which the network device 100 transmits the downlink packet to the base station 1 will be optimized by reflecting the transmission delay (Tx Delay) between the network device 100 and the base station 1 .

Although the network device 100 of the present invention refers to the base station 1 in the above description, each time the downlink packet is transmitted through the corresponding IoT base station for every IoT base station including the base station 1, the TxAck (response) , The transmission delay time set in the corresponding IoT base station is changed (shortened or longer than before).

Therefore, according to the present invention, it is possible to optimize the transmission time point at which the downlink packet is transmitted from the network device to the corresponding IoT base station for each IoT base station, thereby minimizing the buffer time for storing the downlink packet in the IoT base station have.

Thus, according to the present invention, a new scheme (technique) for optimizing a transmission time point at which a downlink packet is transmitted to an IoT base station at a network end is optimized for each IoT base station, so that a transmission delay time The effect of improving the quality of the Internet service (IoT) is avoided by avoiding a problem situation caused by the use of the service.

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

The base station 200 according to the present invention is a base station for transmitting a downlink packet to a terminal and includes a downlink packet transmitted from the network device 100 at a transmission time calculated using a transmission delay time set in the base station 200, To the network device 100, a response including a code value determined based on a reception time point of the packet reception unit 210 receiving the downlink packet, and a code value determined based on the reception time point of the downlink packet, 200 to change the transmission delay time set in the transmission delay unit 220.

Herein, the BS 200 may refer to an IoT BS selected as a downlink BS for the MS.

Also, as described above, the terminal may be a terminal of a first type capable of receiving a downlink packet only at a reception time interval determined by a specific number of specific time intervals based on a time point of transmission of the uplink packet, And a second type of terminal capable of receiving a link packet.

The network device 100 transmits a downlink packet for transmission to the mobile station at a transmission time calculated using a transmission delay time set in a specific base station. Here, the packet reception unit 210 receives a transmission delay And receives a downlink packet transmitted from the network device 100 at a transmission time calculated using time.

For example, in the case of the downlink packet for the first type of terminal, when the network device 100 receives the downlink packet at a point of time after subtracting the transmission delay time set in the base station from the reception time of the uplink packet of the terminal, Lt; RTI ID = 0.0 &gt; downlink &lt; / RTI &gt;

The response transmission unit 220 returns a response including the code value determined based on the reception time point at which the downlink packet was received to the network device 100. [ If the network device 100 changes the transmission delay time set in the specific base station according to the code value in the response received from the base station 200, the specific changing method is as described above.

Hereinafter, an operation method of a network device according to a preferred embodiment of the present invention will be described with reference to FIG.

For convenience of explanation, the following description will be made with reference to the reference numerals shown in Fig. 1, as in the above-described embodiments.

In the present invention, an initial transmission delay time (for example, 500 msec) may be set for each IoT base station (S100).

In a method of operating a network device according to the present invention, when a downlink packet for transmission to a terminal occurs (S110), the network device 100 identifies a downlink base station selected for the terminal (S120).

Hereinafter, the terminal 1 of the first type will be described as a representative, and the base station 1 will be described as a downlink base station selected in the terminal 1. [

In the method of operating the network device according to the present invention, the network device 100 calculates the transmission time point using the transmission delay time set in the downlink base station, i.e., the base station 1, in order to transmit the downlink packet of the terminal 1 (S130 ).

Specifically, the network device 100 can calculate, as the transmission time point, a time point that has elapsed by a time obtained by subtracting the transmission delay time set for the base station 1 from the reception time point of the reception of the uplink packet of the terminal 1 at a specific time, i.e., 1 second (S130).

The network device 100 transmits the downlink packet to the base station 1 for transmission to the terminal 1 at the transmission time calculated in step S130 (S140).

As described with reference to FIG. 5 and FIG. 6, in the present invention, the IoT BS determines whether or not the reception time of the downlink packet received from the IoT base station is a transmission time point (Too Early) defined for fast reception is determined if the time is faster than the predetermined threshold time (t) than the predetermined threshold value (tmst value for the first type and time value for the second type) To return TxAck (response).

Further, in the present invention, the IoT base station determines whether or not the reception time point at which the downlink packet is received from the IoT base station is the transmission time point to the terminal (in the case of the first type, "tmst value" , The second code value (Too Late) defined for the slow reception is determined to be higher than the predefined threshold time (t) longer than the predetermined threshold time (t) for the second type, and TxAck (response) is returned.

Accordingly, in the method of operating the network device according to the present invention, when the downlink packet of the terminal 1 is transmitted to the base station 1 at the transmission time in the step S140, the network device 100 transmits the TxAck (Response) will be received (S150).

At this time, the TxAck (response) returned from the base station 1 includes a transmission time point to the terminal 1 in which the reception time point at which the downlink packet is received at the base station 1 is confirmed in the header (specific field) of the downlink packet The first code value (Too Early) defined for the fast reception will be included if the reception time of the downlink packet is higher than the threshold value (t) (Tmst value in case of the first type) is slower than the threshold time (t) than the transmission time point to the terminal 1 (the first field), the second code value Too Late defined for the slow reception will be included .

In the operation method of the network device according to the present invention, the network device 100 sets the TxAck (response) code value (e.g., normal, error (Too Early or Too Late) The transmission delay time is changed (S160, S170).

More specifically, when the code value (normal) is confirmed in the TxAck (response) returned from the base station 1 (Yes in S160), the network device 100 will keep the transmission delay time set in the base station 1 unchanged.

On the other hand, when the code value (error) is confirmed in the TxAck (response) returned from the base station 1 (S160 No), the network device 100 transmits the code value (error) The transmission delay time set in the base station 1 is changed according to the code value (Too Late) (S170).

Specifically, when the first code value (Too Early) is confirmed in the TxAck (response) returned from the base station 1, the network device 100 sets the transmission delay time set in the base station 1 to a short transmission delay time Can be changed.

For example, when the first code value (Too Early) is confirmed in the TxAck (response) returned from the base station 1, the network device 100 determines the time value d defined in the transmission delay time set in the base station 1, The transmission delay time set in the base station 1 can be changed to a shorter transmission delay time than the previous transmission delay time.

When the second code value (Too Late) is confirmed in the TxAck (response) returned from the base station 1, the network device 100 changes the transmission delay time set in the base station 1 to the long transmission delay time compared to the previous transmission delay time .

For example, when the second code value (Too Late) is confirmed in the TxAck (response) returned from the base station 1, the network device 100 determines the time value d defined in the transmission delay time set in the base station 1, The transmission delay time set in the base station 1 can be changed to the long transmission delay time compared to the previous transmission delay time.

In the method of operation of the network device according to the present invention, the network device 100 waits for the step S110 until the operation of the device is terminated (No in S180), and every time a downlink packet is transmitted through the base station 1, The transmission delay time set in the base station 1 is changed according to the code value in the TxAck (response) (S110 to S170).

Therefore, the transmission delay time of the base station 1 used in the calculation of the transmission time point for transmitting the downlink packet to the base station 1 in the network device 100 is determined by the actual transmission delay Tx (Tx) due to the physical distance between the network device 100 and the base station 1 Delay so that the transmission time point at which the network device 100 transmits the downlink packet to the base station 1 will be optimized by reflecting the transmission delay (Tx Delay) between the network device 100 and the base station 1 .

As described above, according to the present invention, it is possible to optimize the transmission time point at which the downlink packet is transmitted from the network device to the corresponding IoT base station for each IoT base station, and the buffer time for storing the downlink packet in the IoT base station Can be minimized.

Thus, according to the present invention, a new scheme (technique) for optimizing a transmission time point at which a downlink packet is transmitted to an IoT base station at a network end is optimized for each IoT base station, so that a transmission delay time The effect of improving the quality of the Internet service (IoT) is avoided by avoiding a problem situation caused by the use of the service.

A method of operating a network device 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, 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.

According to the operation method of the base station, the network device and the network device of the present invention, since the transmission time point at which the downlink packet is transmitted to the base station at the network end is optimized for each base station, It is an invention that is industrially applicable because it is not only the use but also the possibility of commercialization or operation of the applicable device, but it is practically possible to carry out clearly.

100: Network device
110: packet transmission unit 120: response reception unit
130: Transmission delay time changing section

Claims (8)

A packet transmission unit for transmitting a downlink packet for transmission to a terminal to the specific base station at a transmission time calculated using a transmission delay time set in a specific base station;
A response receiver for receiving a response including a code value determined based on a reception time of the specific base station receiving the downlink packet and a transmission time point of the downlink packet; And
And a transmission delay time changing unit for changing the transmission delay time set in the specific base station according to the code value in the response. The method according to claim 1,
In the response,
If the reception time of the downlink packet received at the specific base station is faster than the transmission time point of the downlink packet, Lt; / RTI &
When the reception time of the downlink packet received at the specific base station is slower than the predetermined threshold time than the transmission time of the downlink packet to the terminal, the second code value defined for the slow reception The network device comprising: 3. The method of claim 2,
Wherein the transmission delay time changing unit comprises:
And changing the transmission delay time set in the specific base station to a shorter transmission delay time than the previous transmission delay time when the first code value is confirmed in the response,
And changes the transmission delay time set in the specific base station to a longer transmission delay time than the previous transmission delay time when the second code value is confirmed in the response. The method according to claim 1,
The terminal,
A first type terminal capable of receiving a downlink packet only at a reception time interval determined by a specific number of specific time intervals based on a time point at which an uplink packet is transmitted,
And a second type of terminal capable of receiving a downlink packet every predetermined period. A packet transmission step of transmitting a downlink packet for transmission to a terminal to the specific base station at a transmission time calculated using a transmission delay time set in a specific base station;
Receiving a response including a code value determined based on a reception time of the specific base station receiving the downlink packet and a transmission time point of the downlink packet; And
And a transmission delay time changing step of changing the transmission delay time set in the specific base station according to the code value in the response. 6. The method of claim 5,
In the response,
If the reception time of the downlink packet received at the specific base station is faster than the transmission time point of the downlink packet, Lt; / RTI &
When the reception time of the downlink packet received at the specific base station is slower than the predetermined threshold time than the transmission time of the downlink packet to the terminal, the second code value defined for the slow reception Wherein the network device is a network device. The method according to claim 6,
The transmission delay time changing step may include:
And changing the transmission delay time set in the specific base station to a shorter transmission delay time than the previous transmission delay time when the first code value is confirmed in the response,
And changing the transmission delay time set in the specific base station to a longer transmission delay time than the previous transmission delay time when the second code value is confirmed in the response. A base station for transmitting a downlink packet to a terminal,
A packet receiver for receiving a downlink packet transmitted from a network device at a transmission time calculated using a transmission delay time set in the base station; And
A response including a code value determined based on a reception time of the downlink packet and a transmission time point to the terminal identified in the downlink packet is returned to the network device, And a response transmission unit for changing a transmission delay time set in the base station.

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