KR101884088B1 - Lbt method and system for operating long range wide area network in the rfid/usn frequency band - Google Patents

Abstract

An LBT method and system for LoRa network operation in an RFID / USN license-exempt band is disclosed. An LBT method for operating a LoRa network using an RFID / USN license-exempt band, the method comprising: performing channel sensing for data to be transmitted through a LoRa network among a plurality of channels corresponding to the RFID / USN license- Performing additional sensing based on the state of the channel based on the state of the channel detected through the channel sensing, and if the state of the detected channel is confirmed as the idle state through the additional sensing, And transmitting the LoRa data through the corresponding channel.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an LBT method and system for operating a LoRa network in a license-

Embodiments of the present invention relate to techniques for operating a long range wide area network (LoRa), which is a low power long distance wireless communication, among the Internet of Things (IoT) technology for Internet of Small Things in a license-exempt space.

LoRa (Long Range Wide Area Network), a low-power long-distance wireless communication technology, is a technology used for transmitting and receiving data in smart cities and outdoor areas because of low standby power and low module price. Unlike the conventional LTE, a chip set supporting LoRa is attached to a terminal without a separate base station or relay equipment, and data is transmitted and received at a low power. Bluetooth, ZigBee, etc. are low-power wireless communication protocols, but only provide short-range data transmission service, but LoRa provides long-distance data transmission service with lower power than Bluetooth or Zigbee.

In order to use the existing LTE network instead of using the LoRa network, it is necessary to install the expensive chipset in the terminal in order to utilize the existing LTE base station. Therefore, the LoRa terminal equipped with the low- . For example, the amount of data to be exchanged through the network, such as the location of a child, an elderly person (such as a demented elderly), a patient, confirmation of arrival, parking management of a car, a motorcycle, a bicycle, In order to provide a small amount of simple functions, it is not necessary to install a costly chipset for providing an LTE service such as a smart phone to the terminal, and it only increases the price of the terminal. In other words, it is only necessary to mount an inexpensive LoRa chipset capable of performing the above simple function without needing to mount an LTE chipset on a bicycle or a car key for identifying a car of the user.

Furthermore, LoRa provides data transmission / reception using the license-exempt band, and provides data transmission / reception through the LoRa network supporting the LoRa wireless communication technology using the RFID / USN frequency band. As such, LoRa shares interference with RFID devices in the RFID / USN license-exempt band, resulting in interference.

1 is a diagram showing an RFID / USN license-exempt band.

Referring to FIG. 1, the RFID / USN license-exempt band is a 900 MHz band, and may include, for example, 917 to 923.5 MHz band.

The license-exempted band may include a total of 32 channel bands divided into a high-power channel period and a small-power channel period. At this time, frequency hopping is performed in at least six channels in a high power channel period in the case of the fixed type RFID and in a small power channel period in the case of the mobile RFID, and data communication can be performed. In this case, when the LoRa service is provided in a state in which the high power channel section or the small output channel section occupies the RFID, interference may occur in the existing system, that is, the RFID system.

Accordingly, when transmitting / receiving data through LoRa network using the RFID / USN license-exempted band (ie providing LoRa service), a LoRa network providing LoRa service using the license-exempt band without affecting the existing RFID system Communication technology is required. Korean Patent Laid-Open No. 10-2013-0107942 relates to an ultra low power wireless communication method and apparatus, and discloses a technique of assigning a communication channel with priority to use of the ISM band.

The present invention relates to a method and system for operating a LoRa network for Internet communication of goods using an RFID / USN license-exempt band without affecting an existing RFID system, that is, transmitting and receiving data (i.e., LoRa data) using the license- Technology.

An LBT method for operating a LoRa network using an RFID / USN license-exempt band, the method comprising: performing channel sensing for data to be transmitted through a LoRa network among a plurality of channels corresponding to the RFID / USN license- Performing additional sensing on the basis of the state of the channel detected through the channel sensing, and if the state of the detected channel is confirmed as an idle state through the additional sensing, LoRa data And transmitting the data.

According to an aspect of the present invention, the step of performing the additional sensing includes a step of, when the state of the channel detected through the channel sensing is Busy, waiting until the state of the corresponding channel is changed to the idle state And performing additional sensing on the changed channel when the state of the corresponding channel is changed to the idle state.

According to another aspect of the present invention, in the step of transmitting the LoRa data, if it is determined that the state of the corresponding channel is changed from the idle state to the busy state through the additional sensing, And transmits the LoRa data through a channel moved by a predetermined number or more.

According to another aspect of the present invention, the step of performing channel sensing comprises the steps of: determining an occupation time of the corresponding channel for the LoRa data transmission; and, when the occupied time is a predefined occupation duration, And performing channel sensing again for transmission.

An LBT system for operating a LoRa network using an RFID / USN license-exempted band, the LBT system performing channel sensing for data to be transmitted through a LoRa network among a plurality of channels corresponding to the RFID / USN license- A channel sensing unit for performing additional sensing on the basis of a state of a channel detected through channel sensing; and a channel sensing unit for sensing a state of the detected channel through the additional sensing, And a data transmission / reception unit for transmitting the data.

In the present invention, in providing LoRa service using the RFID / USN license-exempt band, LBT (Listen Before Talk) is applied to transmit data (i.e., LoRa Data) can be transmitted and received.

1 is a diagram showing an RFID / USN license-exempt band.
2 is a diagram showing a LoRa network according to an embodiment of the present invention.
3 is a block diagram illustrating an internal configuration of an LBT system according to an embodiment of the present invention.
FIG. 4 is a flowchart illustrating an LBT method for LoRa network operation in a license-exempt band according to an exemplary embodiment of the present invention.
FIG. 5 is a flowchart illustrating an operation of confirming a state of a channel through channel sensing according to an exemplary embodiment of the present invention. Referring to FIG.

The present invention relates to a technology for providing a LoRa service, which is a technology for providing a goods Internet communication service using an RFID / USN license-exempt band, and more particularly to a technology for providing a LoRa service, To a technology for providing an appropriate LBT (Listen Before Talk) technique to enable transmission and reception of LoRa service, that is, LoRa data.

In the present embodiments, the 'license-exempt band' is a frequency band used for RFID / USN communication, and may include the 917 MHz to 923.5 MHz band.

In the present embodiments, the 'Long Range Wide Area Network' may represent a dedicated network for providing the Internet of things and the Internet of goods using LoRa, which is one of low power long distance communication technologies. For example, it may mean a dedicated IoT network or a dedicated Internet network.

In the present embodiments, the 'LBT system' may include a base station (ie, a LoRa base station) having a channel sensing function, for example, a LoRa gateway, or the like. In addition, the LBT system may have a channel sensing function, i.e., a terminal equipped with a LoRa chipset (LoRa terminal). For example, the LoRa terminal may include various things such as a smart PC, a smart TV, a smart refrigerator, a car key, a bicycle, a smart location notification device, a smart watch, a wearable device, In the present embodiments, the case where the LoRa base station is used as the LBT system will be described as an example, but the LBT system may be the LoRa terminal.

In the present embodiments, in order to provide the LoRa service using the license-exempt band, the LBT system may have to satisfy the following regulations. In this specification, 'LoRa service' may mean a service that provides transmission / reception (or exchange) of data through a LoRa network using a license-exempt band.

1. For passive RFID, occupied frequency bandwidth should be 200kHz or less.

2. For passive RFID reader and writer in frequency hopping, use more than 6 non-overlapping channels and the continuous occupancy time per channel should be less than 0.4 second.

3. When using LBT (Listen Before Talk), if the received signal strength is less than -65dBm after receiving for more than 5msec before transmission, it should transmit radio wave, stop transmission within 4seconds and stop for more than 5msec.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a diagram showing a LoRa network according to an embodiment of the present invention.

2, the LoRa network 200 may include a LoRa terminal 210, a LoRa base station 220, a wired network 230, and a LoRa server 240. At this time, a conventional RFID system using an unlicensed band such as an RFID reader (not shown) and an RFID tag (not shown) may be located around the LoRa terminal 210, If so, the LoRa terminal 210 can start LoRa service such as data transmission.

The LoRa terminal 210 may be one or more electronic devices equipped with a LoRa chipset that enables LoRa communication services such as data transmission and reception using a license-exempt band via a LoRa network. The LoRa terminal 210 can transmit or request data to and receive data from the LoRa server 240 through the LoRa base station.

For example, if the LoRa terminal 210 is a wearable device that provides location tracking of an eye or an old person, the LoRa terminal 210 may transmit its location information to the LoRa server 240 via the LoRa base station 220 And the LoRa server 240 may store data received from the LoRa terminal 210 by matching with the identifier of the LoRa terminal 210. [ When the position confirmation request of the child or the elderly is received from another terminal registered in association with the position confirmation of the LoRa terminal 210 (for example, a LoRa terminal held by a guardian, a parent, a teacher or the like), the LoRa server 240 transmits a LoRa The location information can be provided to the terminal such as the parent or guardian based on the registration information (for example, terminal identification information such as a parent or guardian) matched to the terminal 210.

As another example, in the case of gas meter reading, water meter reading, and electricity meter reading, a meter reading meter installed in the house may be used as the LoRa terminal 210. Data measured and quantified for a predetermined period of time in the meter reading meter may be transmitted to the LoRa server 240 through the LoRa base station 220. The LoRa server 240 transmits the identifier information of the meter reading meter and the received (E.g., user name, user address, user's mobile phone number, etc.) of the meter reading data and the user of the meter reading meter (for example, gas, water, electricity meter subscriber) If there is a data request, the LoRa server 240 can provide the meter reading data to the device registered by the user or the meter reading terminal. At this time, the meter probe provider or the user's device may be a LoRa terminal using a LoRa network, or a terminal of a smart phone, a desktop PC, a notebook or a tablet using an LTE network or a wired network.

At this time, the LoRa terminal 210 transmits data to the LoRa terminal 210 in order to perform data communication with the server 240 through the LoRa base station 220 using the license-exempt band, that is, the RFID / USN band A channel for starting the LoRa service can be allocated. At this time, it is checked whether the RFID / USN service is used around the LoRa terminal 210 before the channel is allocated, and a channel that is not used for the RFID / USN service can be allocated. That is, the LoRa base station 220 can perform channel sensing for checking presence / absence of the RFID / USN service and allocate a channel for starting the LoRa service. Here, the LoRa base station 220 is an example of the LBT system, and detailed operation will be described later with reference to FIG. 3 and FIG.

The LoRa terminal 210 wirelessly connects to the LoRa base station 220 to perform data transmission and reception and the LoRa base station 220 collects data received from the LoRa terminal 210 and transmits the data to the wired backhaul 230 to the LoRa server 240 via the Internet.

FIG. 3 is a block diagram illustrating an internal configuration of an LBT system according to an exemplary embodiment of the present invention. FIG. 4 is a flowchart illustrating an LBT method for operating a LoRa network in a license- to be.

3, the LBT system 300 may include a data transmission / reception unit 310, a channel sensing unit 320, and a packetization unit 330 as the LoRa base station 220 of FIG. 4 may be performed by the components shown in FIG. 3, that is, the data transmission / reception unit 310, the channel sensing unit 320, and the packetization unit 330 .

The data transmitting and receiving unit 310 may transmit data to the LoRa server 240 through the LoRa base station 220 or may receive data from the LoRa server 240. [ As described above, when the LoRa service such as data transmission / reception is requested, the LoRa service is performed using the RFID / USN license-exempt band, so channel sensing for providing the corresponding service may be required.

In operation 410, the channel sensing unit 320 may perform channel sensing to check presence or absence of a terminal using the RFID / USN service in order to start the LoRa service. That is, the channel sensing unit 320 can perform channel sensing to check whether the RFID system or the like is using the RFID / USN service through a specific one of the license-exempt bands.

At this time, the channel sensing unit 320 may perform channel sensing many times as many times as the predetermined sensing number in order to secure reliability.

In operation 420, the channel sensing unit 320 can check the channel state of the specific channel detected for starting the LoRa service through channel sensing. At this time, if the channel state is a Busy state (420: YES) that is used (i.e., occupied) by another LoRa terminal or an RFID system or the like, waiting is performed until the channel becomes idle state )can do.

For example, if the detected state of the specific channel is a Busy state, the channel sensing unit 320 continuously performs channel sensing at a predetermined time interval in step 430, It can wait until the channel state of the channel becomes the idle state. That is, if it is in a Busy state, it repeats step 430 and performs channel sensing again to wait until the state of the corresponding channel becomes an idle state. Here, the idle state may mean a state in which the corresponding channel is not occupied, that is, an empty state that is not used by another terminal, and the state is available. In order to continuously perform channel sensing while waiting for the idle state, the channel sensing interval may be set in advance in consideration of a trade-off relationship between the hardware implementation and the sensing delay time.

If the channel state is the idle state in step 440, the channel sensing unit 320 may perform additional channel sensing in step 450.

For example, if the state of the specific channel detected in the first channel sensing is an idle state, or if a specific channel detected during the first channel sensing process is in a Busy state, ), The channel sensing unit 320 may perform additional sensing on the idle channel again. In the case of the LoRa, since the license-exempt band used for the existing RFID / USN service is used, if there is an RFID system in the vicinity, the RFID system around the channel may suddenly use the idle channel, ) Can perform additional sensing once again.

For example, the channel sensing unit 320 may perform additional channel sensing for a predetermined period of time such as 5 msec. That is, the state of the channel can be checked again by performing additional channel sensing for 5 msec for a channel whose channel state is an idle state.

In step 460, the channel sensing unit 320 can again check whether the state of the corresponding channel is an idle state through additional sensing.

In step 470, if the state of the corresponding channel is confirmed to be an idle state again, the data transmission / reception unit 310 can provide a LoRa communication service. For example, the data transmission / reception unit 310 may receive data to be transmitted from the LoRa terminal to the server through the LoRa network through the channel identified as the idle state again. At this time, the data transmitting / receiving unit 310 may transmit or receive data for the LoRa service by occupying the channel for 0.4 seconds according to the restriction of the RFID / USN band.

If it is determined in step 460 that the state of the channel checked through the additional sensing is not an idle state, that is, in a Busy state, the channel sensing unit 320 outputs a channel to be used for providing a LoRa service Can be changed.

For example, the channel sensing unit 320 may change a channel from a corresponding channel to a channel shifted from a predetermined reference value or more. For example, if it is determined in step 440 that the idle state is the channel 1, the channel sensing unit 320 may change the channel for the LoRa service to the channel 4 that has moved more than three channels from the channel 1. That is, the channel for the LoRa service can be changed from channel 1 to channel 4. In this case, if the state of the channel is idle state but the state of the corresponding channel is changed to the busy state during the additional channel sensing for the corresponding channel for 5 msec, the channel is changed (for example, 4), the data transmission / reception unit 210 can start the LoRa service through the changed channel. For example, the data transmission / reception unit 210 may receive data or transmit data from the LoRa terminal through the channel 4. [

At this time, the data transmitting / receiving unit 210 can provide the LoRa service through the channel 4 for 0.4 seconds according to the restriction of the RFID / USN license-exempt band. For example, when the size of data to be transmitted / received through the channel 4 is large to transmit for 0.4 second, the packetizer 330 may perform packet segmentation / concatenation for segmenting and re-combining the data , The data transmission / reception unit 210 may transmit or receive the divided data packet through the channel 4 through packetization.

When changing the channel, the maximum sensing delay time may be calculated based on the number of hopping channels and 5 msec (sensing delay time). For example, if the maximum sensing delay time is assumed to be 5 msec per hopping channel, the sensing delay time increases in proportion to the number of hopping channels, so that the maximum sensing delay time may take 80 msec in consideration of a total of 16 channels .

If the state of the channel detected through the first channel sensing is not busy (420: No) in step 420, the channel sensing unit 320 determines that the state of all the channels is the idle state State or not. For example, the channel sensing unit 320 can check the status of all 16 channels.

At this time, if the state of all the channels is not the idle state (490: No), the channel sensing unit 320 may perform additional channel sensing. For example, if only some of the 16 channels are in the idle state and the remaining channels are in the busy state, the channel sensing unit 320 determines whether the channels in the idle state are still in the idle state or in the busy state Additional channel sensing can be performed for 5 msec to confirm whether or not it has been changed. If the idle state is confirmed through the additional channel sensing, the data transmission / reception unit 310 provides the LoRa service through the corresponding channel. If the idle state is confirmed, the channel sensing unit 320 changes from the idle state to the busy state It is possible to change a channel that has moved more than three channels from a channel to a channel to provide a LoRa service. Then, the data transmission / reception unit 310 can transmit / receive data for the LoRa service through the changed channel.

If it is determined in step 490 that all the channels are idle (490: YES), the channel sensing unit 320 may determine any one of the plurality of channels as a channel for LoRa service. Then, the data transmission / reception unit 310 can provide the LoRa service through the determined channel. At this time, the data transmitting / receiving unit 310 can provide the LoRa service through the corresponding channel for 0.4 seconds according to the RFID / USN license-exempt band regulation. If the data is large, the packetizing unit 330 transmits the packetized data packet Lt; / RTI >

For example, when providing a LoRa service using a bandwidth of 125 kHz and SF = 12, the time used to transmit the LoRa data, that is, the time required to occupy the channel, is 1 second or more. In order to occupy the channel and transmit the LoRa data, the packetizing unit 330 may perform packetization that divides the LoRa data based on the bandwidth of the channel, SF.

FIG. 5 is a flowchart illustrating an operation of confirming a state of a channel through channel sensing according to an exemplary embodiment of the present invention. Referring to FIG.

In step 510, the channel sensing unit 320 may measure the energy of a channel to be used for the LoRa service through channel sensing or additional channel sensing. For example, the strength of a signal received through the channel can be measured.

In operation 520, the channel sensing unit 320 may compare the measured energy with the predetermined reference energy. For example, the reference energy may be preset to -65 dBm. Then, the channel sensing unit 320 can compare whether the measured energy of the corresponding channel is less than -65 dBm.

If the measured energy is lower than the reference energy in step 530, the channel sensing unit 320 may determine that the state of the corresponding channel is the idle state.

In step 540, if the measured energy is greater than the reference energy, the channel sensing unit 320 may determine that the channel is in an idle state.

That is, in the case of a channel having a signal strength of -65 dBm or less, it is confirmed that it is an idle state which is not used for the RFID / USN service. In the case of a channel having a received signal intensity of greater than -65 dBm, It can be confirmed that it is a busy state being used.

As described above, the LBT system that provides the LoRa service using the existing RFID / USN license-exempt band checks whether there exists a system that uses the RFID / USN service in the vicinity through the channel sensing, That is, if the channel state is busy, the system waits until the channel state is changed to the idle state. After the state changes to the idle state, the system performs additional channel sensing again for 5 msec, It is possible to provide the LoRa service using the license-exempt band without affecting the existing RFID / USN service by checking once again whether the idle state exists.

The method according to an embodiment 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 to be recorded on the medium may be those specially designed and configured for the embodiments 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.

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. For example, it is to be understood that the techniques described may be performed in a different order than the described methods, and / or that components of the described systems, structures, devices, circuits, Lt; / RTI > or equivalents, even if it is replaced or replaced.

Therefore, other implementations, other embodiments, and equivalents to the claims are also within the scope of the following claims.

Claims (5)

An LBT method for operating a LoRa network using an RFID / USN license-exempt band,
Performing channel sensing for data to be transmitted through a LoRa network among a plurality of channels corresponding to the RFID / USN license-exempt band;
Performing additional sensing based on the state of the channel detected through the channel sensing; And
If the state of the detected channel is identified as an idle state through the additional sensing, transmitting LoRa data through the corresponding channel
Lt; / RTI >
Wherein performing the additional sensing comprises:
Waiting until the state of the corresponding channel is changed to an idle state when the state of the channel detected through the channel sensing is Busy state; And
Performing the additional sensing to check whether the channel is in the idle state and whether the channel is in the idle state for the channel detected in the channel sensing,
Lt; / RTI >
Wherein the step of transmitting the LoRa data comprises:
If it is determined that the state of the corresponding channel is changed from the idle state to the busy state through the additional sensing, the LoRa data is transmitted through the predetermined number of channels moved from the corresponding channel that
/ RTI > for a LoRa operation. delete delete The method according to claim 1,
Wherein the step of performing channel sensing comprises:
Confirming occupancy time of the corresponding channel for LoRa data transmission; And
If the confirmed occupation time reaches the predefined occupancy duration, performing the channel sensing for the LoRa data transmission again
The LBT method for LoRa operation. 1. An LBT system for operating a LoRa network using an RFID / USN license-
A channel sensing unit for performing channel sensing for data to be transmitted through the LoRa network among a plurality of channels corresponding to the RFID / USN license-exempted band and for performing additional sensing based on the detected state of the channel through the channel sensing, part; And
If the state of the detected channel is confirmed as an idle state through the additional sensing, the data transmission / reception unit for transmitting LoRa data through the corresponding channel
Lt; / RTI >
The channel sensing unit includes:
If the state of the channel detected through the channel sensing is a busy state, the controller waits until the state of the corresponding channel is changed to the idle state, and if the state of the channel detected through the channel sensing is Performing the additional sensing to determine whether the channel maintains the idle state for a channel that is in an idle state,
The data transmitting /
If it is determined that the state of the corresponding channel is changed from the idle state to the busy state through the additional sensing, the LoRa data is transmitted through the predetermined number of channels moved from the corresponding channel that
LBT system for LoRa operation.

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