KR101865390B1 - Method, apparatus and computer readable record media for sharing radio resource on unlicensed band - Google Patents

Abstract

The present invention relates to a method, an apparatus and a computer-readable recording medium for sharing radio resources in a license-exempt band. A method for sharing radio resources in a license-exempted band includes the steps of: determining whether the cellular network system is in a saturation state of the wireless LAN system; and adjusting the channel occupancy time on the license-exempt band if the wireless LAN system is saturated Wherein the license-exempted band is a frequency band shared by the cellular network system and the wireless LAN system, and the cellular network system and the wireless LAN system can perform channel access on the license-exempt band.

Description

METHOD, APPARATUS AND COMPUTER-READABLE RECORDING MEDIUM FOR SHARING RADIO RESOURCES IN A LICENSE BAND BACKGROUND OF THE INVENTION [0001]

The present invention relates to a radio resource sharing method, apparatus and computer-readable recording medium in a license-exempt band. More particularly, to a radio resource sharing method, apparatus, and computer-readable recording medium in a license-exempt band for improving the fairness of radio resource allocation in a license-exempt band between a cellular network system and a wireless LAN system.

As the demand for wireless resources grows, many telecommunications companies and telecommunications organizations are seeking ways to satisfy the demand for wireless resources. The international telecommunication union-radio sector (ITU-R) is aimed at future mobile radio technologies that provide a peak data rate of 20 gigabits per second (gigabits per second).

Various methods can be used as a method for increasing the peak data rate. For example, a modulation and coding scheme (MCS) with a relatively high number (or index) may be used, a large number of antennas may be used, or a wider frequency domain may be utilized to increase the peak data rate.

In order to increase the peak data rate in the cellular network, standardization of channel access technology called licensed assisted access (LAA) is completed in the 3GPP (3 ^rd generation partnership project). LAA is a new technology introduced in long term evolution (LTE) release 13. The LAA defines an access method to utilize an unlicensed band of 5 GHz to support downlink transmission of LTE- and LTE-A (advanced) based cellular network systems.

(E. G., A wireless local area network system based on IEEE 802.11) that previously performed communication on a license-exempt band due to the utilization of the license-exempt band of a cellular network system based on LAA, A problem of sharing the radio resources with the mobile station may occur.

Thus, in LAA, the spectrum sharing mechanism may be important for coexistence with other wireless communication technology-based systems operating on the existing license-exempt bands. However, due to the utilization of the license-exempt band based on the LAA of the cellular network system, the throughput of other wireless communication technologies such as the wireless LAN system that have been operated on the license-exempted band is reduced.

It is an object of the present invention to solve all the problems described above.

It is another object of the present invention to prevent deterioration of throughput of the wireless LAN system due to use of the license-exempt band of the cellular network system.

According to another aspect of the present invention, there is provided a method for determining whether a wireless LAN system is saturated and adjusting a time resource allocated to the cellular network system when the wireless LAN system is saturated, thereby improving the fairness of wireless resource allocation between the cellular network system and the wireless LAN system It is another purpose.

In order to accomplish the above object, a representative structure of the present invention is as follows.

According to one aspect of the present invention, a method for sharing wireless resources in a license-exempt band includes the steps of: determining whether the cellular network system is in a saturation state of a wireless LAN system; Wherein the license-exempt zone is a frequency band shared by the cellular network system and the wireless LAN system, and the cellular network system and the wireless LAN system are capable of performing channel access on the license- Can be performed.

According to another aspect of the present invention, a cellular network device sharing radio resources in a license-exempt band includes a processor operatively coupled to a radio frequency (RF) portion and a RF portion for transmitting and receiving a radio signal, The processor may be configured to determine whether the WLAN system is saturated and adjust the channel occupancy time on the unlicensed band if the WLAN system is in the saturation state, And a frequency band shared by the wireless LAN system, and the cellular network system and the wireless LAN system can perform channel access on the license-exempt band.

According to the present invention, deterioration in throughput of the wireless LAN system due to use of the license-exempt band of the cellular network system can be prevented.

In addition, according to the present invention, it is possible to determine whether the wireless LAN system is saturated and adjust the time resources allocated to the cellular network system when the wireless LAN system is saturated, thereby improving the fairness of the radio resource allocation between the cellular network system and the wireless LAN system .

1 shows the structure of a radio frame in a cellular network system.
2 is a conceptual diagram illustrating the structure of a wireless local area network (WLAN).
3 is a conceptual diagram showing an A-MSDU.
4 is a conceptual diagram showing an A-MPDU.
5 is a conceptual diagram illustrating a distributed coordination function (DCF) -based channel access procedure in a wireless LAN system.
6 is a conceptual diagram showing a backoff procedure of a plurality of STAs.
7 is a graph comparing the performance of a wireless LAN system and a cellular network system on a license-exempted band.
8 is a conceptual diagram illustrating a COTA algorithm according to an embodiment of the present invention.
9 is a flowchart illustrating a saturation detection step according to an embodiment of the present invention.
10 is a flowchart showing a COT adjustment step according to an embodiment of the present invention.
11 is a flowchart illustrating a method for detecting a saturation of a wireless LAN system according to an embodiment of the present invention.
12 is a graph showing the detection rate of PPDUMaxTime according to an embodiment of the present invention.
13 is a graph showing the saturation detection performance of the COTA algorithm according to the embodiment of the present invention.
14 is a graph illustrating performance of a COTA algorithm according to an embodiment of the present invention.
15 is a graph illustrating performance of a COTA algorithm according to an embodiment of the present invention.
16 is a graph illustrating performance of the COTA algorithm according to an embodiment of the present invention.
17 is a graph illustrating performance of a COTA algorithm according to an embodiment of the present invention.
18 is a block diagram illustrating a wireless device according to an embodiment of the present invention.

The following detailed description of the invention refers to the accompanying drawings, which illustrate, by way of illustration, specific embodiments in which the invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention. It should be understood that the various embodiments of the present invention are different, but need not be mutually exclusive. For example, the specific shapes, structures, and characteristics described herein may be implemented by changing from one embodiment to another without departing from the spirit and scope of the invention. It should also be understood that the location or arrangement of individual components within each embodiment may be varied without departing from the spirit and scope of the present invention. Therefore, the following detailed description is not to be taken in a limiting sense, and the scope of the present invention should be construed as encompassing the scope of the appended claims and all equivalents thereof. In the drawings, like reference numbers designate the same or similar components throughout the several views.

Hereinafter, various embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention.

1 shows the structure of a radio frame in a cellular network system.

Cellular network system structure of the radio frame 100 (for ^{example, 3GPP (3 rd generation partnership project} ) LTE (long term evolution), LTE-A (advanced) based on the system) is 3GPP TS 36.211 V8.2.0 (2008 -03) "Technical Specification Group Radio Access Network (E-UTRA), Physical Channels and Modulation (Release 8)"

Referring to FIG. 1, a radio frame 100 is composed of 10 subframes (120). One subframe 120 is composed of two slots (140). The wireless frame 100 may be indexed based on the slot 140 from the slot # 0 to the slot # 19 or may be indexed on the basis of the subframe # 0 to the subframe # 9 according to the subframe 120 . For example, subframe # 0 may include slot # 0 and slot # 1.

The time taken for one subframe 120 to be transmitted is called a transmission time interval (TTI). The TTI may be a scheduling unit for data transmission. For example, the length of one radio frame 100 is 10 ms, the length of one subframe 120 is 1 ms, and the length of one slot 140 may be 0.5 ms.

One slot 140 includes a plurality of orthogonal frequency division multiplexing (OFDM) symbols in a time domain and a plurality of subcarriers in a frequency domain. In a cellular network system, a base station (eNB) uses OFDMA as an access method in a downlink channel. An OFDM symbol is used to represent one symbol period and may be referred to as a different name depending on the multiple access scheme. For example, a single carrier-frequency division multiple access (SC-FDMA) may be used as a multiple access scheme in an uplink channel in which user equipment (UE) transmits data to a base station (eNB). The symbol interval for transmitting data on the uplink channel may be referred to as an SC-FDMA symbol.

The structure of the radio frame 100 disclosed in FIG. 1 is one embodiment of the frame structure. Accordingly, the number of subframes 120 included in the radio frame 100, the number of slots 140 included in the subframe 120, or the number of OFDM symbols included in the slot 140 can be variously changed, Frame format can be defined.

The number of symbols including one slot may be changed depending on whether a cyclic prefix (CP) is used or not.

For example, when a radio frame uses a normal CP, one slot may include 7 OFDM symbols. When a radio frame uses an extended CP, one slot may include six OFDM symbols. A cellular network system can use a frequency division duplex (FDD) scheme and a time division duplex (TDD) scheme in a duplexing scheme. According to the FDD scheme, uplink transmission and downlink transmission can be performed based on different frequency bands. According to the TDD scheme, uplink and downlink transmissions can be performed using a time division based on the same frequency band. The TDD channel response may have a reciprocal nature by using the same frequency band. That is, in the TDD scheme, the downlink channel response and the uplink channel response may be substantially the same in a given frequency domain. Therefore, the TDD-based wireless communication system can obtain the channel state information of the downlink channel from the channel state information of the uplink channel. Since the TDD scheme divides the entire frequency band into uplink transmission and downlink transmission in a time division manner, downlink transmission by the eNB and uplink transmission by the UE can not be simultaneously performed.

The base station can perform carrier aggregation based on a primary component carrier (PCC) of a primary (P) cell and a secondary component carrier (SCC) of one or more secondary (S) If there are two or more cells, the base station can determine one cell as a P-cell and the remaining cells as an S-cell. The base station can aggregate the determined P-cell and S-cell CCs and transmit the data to the UE using the aggregated frequency bandwidth. The terminal can also transmit data to the base station using the aggregated frequency bandwidth.

In order to increase the peak data rate in the cellular network, 3GPP has completed standardization of channel access technology called licensed assisted access (LAA). LAA is a new technology introduced in long term evolution (LTE) release 13. The LAA defines an access method to utilize an unlicensed band of 5 GHz to support downlink transmission of LTE- and LTE-A (advanced) based cellular network systems.

The cellular network system can utilize a licensed band as a P-cell and an LAA-based channel-accessible license-exempt band as an S-cell. As described above, due to the utilization of the license-exempt band of the cellular network system based on the LAA, a system based on another wireless communication technology (for example, a wireless local area network system) may be generated. Hereinafter, a wireless LAN system will be described

2 is a conceptual diagram illustrating the structure of a wireless local area network (WLAN).

The upper part of FIG. 2 shows the structure of an infrastructure basic service set (BSS) of IEEE (institute of electrical and electronic engineers) 802.11.

2, the WLAN system may include one or more infrastructure BSSs 200 and 205 (hereinafter, BSS). The BSSs 200 and 205 are a set of APs and STAs such as an access point 225 and a STA1 (station 200-1) capable of successfully synchronizing and communicating with each other. The BSS 205 may include one or more associatable STAs 205-1 and 205-2 in one AP 230. [

The BSS may include at least one STA, APs 225 and 230 providing a distribution service, and a distribution system (DS) 210 connecting a plurality of APs.

The distributed system 210 may implement an extended service set (ESS) 240, which is an extended service set, by connecting a plurality of BSSs 200 and 205. ESS 240 may be used to refer to one network in which one or more APs 225 and 230 are connected through a distributed system 210. [ An AP included in one ESS 240 may have the same service set identification (SSID).

A portal 220 may serve as a bridge for performing connection between a wireless LAN network (IEEE 802.11) and another network (for example, 802.X).

2, a network between APs 225 and 230 and a network between APs 225 and 230 and STAs 200-1, 205-1 and 205-2 may be implemented in the BSS as shown in the upper part of FIG. However, it is also possible to establish a network and perform communication between STAs without the APs 225 and 230. An ad-hoc network or an independent basic service set (IBSS) is defined as a network that establishes a network and establishes communication between STAs without APs 225 and 230.

2 is a conceptual diagram showing the IBSS.

Referring to the lower part of FIG. 2, the IBSS is a BSS operating in an ad-hoc mode. Since IBSS does not include APs, there is no centralized management entity. That is, in the IBSS, the STAs 250-1, 250-2, 250-3, 255-4, and 255-5 are managed in a distributed manner. In the IBSS, all the STAs 250-1, 250-2, 250-3, 255-4, and 255-5 may be mobile STAs, and the access to the distributed system is not allowed, network.

The STA is an arbitrary functional medium including a medium access control (MAC) conforming to IEEE (Institute of Electrical and Electronics Engineers) IEEE 802.11 standard and a physical layer interface for a wireless medium. May be used to mean both an AP and a non-AP STA (Non-AP Station).

An access point (AP) operating in a wireless local area network (WLAN) system can transmit data to each of a plurality of STAs through the same time resource. If the transmission from the AP to the STA is referred to as downlink transmission, the transmission from the STA to the AP may be referred to as uplink transmission.

The unit of data transmitted in the wireless LAN system can be expressed by the communication layer. The PPDU includes a PPDU header and a physical layer service data unit (PSDU) (or a MAC protocol data unit (MPDU)). The PPDU is a physical layer downlink data unit (PPDU) As shown in FIG. The PPDU header may include a PHY header and a PHY preamble, and a PSDU (or MPDU) may include or indicate a frame. The MPDU is a data unit transmitted from the medium access control (MAC) layer to the PHY layer and may be a data unit equal to the PSDU.

3 is a conceptual diagram showing an A-MSDU.

A method of aggregating data frames to reduce MAC error overhead in IEEE 802.11n has been defined. The MAC service data unit (MSDU) 300 generated at the application layer for the aggregation of data frames can be aggregated at the upper layer of the MAC layer and generated as one MSDU. The aggregated MSDU in the upper layer of the MAC layer may be defined with the term aggregate-MSDU (A-MSDU) The A-MSDU 350 may be generated based on the aggregation of a plurality of MSDUs 300 having the same priority and the same RA (receiver address).

Each MSDU 300 may include a subframe header (subframe HDR) including a destination address (DA), a source address (SA), and an MSDU length. The A-MSDU subframe may be padded to make the total length of the A-MSDU subframe a certain multiple (a multiple of 4 octets). A plurality of A-MSDU subframes may be gathered to form one A-MSDU 350.

The A-MSDU 350 may be formed and transmitted as a single quality of service (QoS) data MAC protocol data unit (MPDU) without fragmentation unlike a single MSDU. For example, the A-MSDU 350 can transmit only when the HT capability of the MIB (management information base) field is TRUE, that is, when it is the HT STA, and can also be transmitted only to the HT STA. HT STA, the HT STA has the ability to de-aggregate the A-MSDU 350, and the HT STA determines whether the A-MSDU 350 exists in the QoS field of the received MAC header of the QoS data And can perform the deaggregation.

If the ACK policy of the QoS data MPDU of the HT STA is set to the normal ACK, the A-MSDU 300 can not be aggregated into the A-MPDU. In addition, whether or not the A-MSDU 300 can be aggregated into the A-MPDU depends on whether a block acknowledgment agreement is established for each TID (traffic identifier). In addition, even if a block ACK agreement is established for the TID, the A-MSDU block ACK support indicator of the ADDBA response frame of the receiving side according to the ADDBA request frame (block acknowledgment request frame) A-MSDU can not be included in the A-MPDU if it indicates not to support it.

4 is a conceptual diagram showing an A-MPDU.

Referring to FIG. 4, a plurality of MPDUs 400 having the same RA (receiver address) and TID and ACK policies may be collected in the lower part of the MAC layer to form one A-MPDU 450.

The A-MPDU 450 includes one or more A-MPDU subframes, and each A-MPDU subframe may include an MPDU delimiter and an MPDU 400. The MPDU delimiter may be used to determine whether an A-MPDU subframe constituting the A-MPDU 450 has an error. A plurality of A-MPDU subframes may form one A-MPDU 450.

The successful reception of the A-MPDU 450 can be indicated based on the block ACK. The A-MPDU 450 can be formed only for the TID having the HT-immediate BA agreement and the duration / ID field of the MPDU 400 constituting the A-MPDU 450 The values can be set the same.

Specifically, a block ACK mechanism was introduced to transmit a response frame containing ACK information for a plurality of frames (or MPDUs) transmitted during a transmission opportunity (TXOP) period at a time. When the block ACK mechanism is used, the efficiency of the MAC layer due to the reduction of the overhead can be improved like the A-MSDU or the A-MPDU.

5 is a conceptual diagram illustrating a distributed coordination function (DCF) -based channel access procedure in a wireless LAN system.

In a distributed coordination function (DCF) -based channel access, the STA can use the carrier sensing mechanism based on a clear channel assessment (CCA) to determine whether to use the medium. If the medium is not in use beyond the DIFS (DCF inter frame symbol) period (ie, if the channel is idle), the STA may send a MAC protocol data unit (MPDU) with an impending transmission.

Conversely, if the medium is busy during the DIFS period (i.e., the channel is busy), the STA may set the backoff time by a random backoff algorithm.

The backoff time may be defined as a time after the channel waits for a predetermined time (for example, DIFS) and then waits before transmitting the frame. The backoff time may be defined by the following equation.

&Quot; (1) "

Random () is a function that calculates a pseudo-random integer (or a random value) that is evenly distributed in the [0, CW] interval. CW can be selected from an integer of aCWMin or more and aCWmax or less. aCWMin and aCWmax may be determined according to PHY characteristics. aSlotTime may be a time unit defined according to PHY characteristics. If the STA fails to access the channel, CWmin may increase exponentially and CWmin may increase to a maximum CWmax. That is, an STA that fails to access a channel can select a pseudo-random integer (or a random value) within a set range based on a relatively larger CWmin value.

The STA determines whether the channel is idle, and if the channel is idle, the backoff time can be reduced in units of SlotTime. Before the backoff time is reduced in units of SlotTime, the STA can again determine whether the channel is idle during the interval corresponding to DIFS. When the backoff time becomes zero, the STA can perform channel access. In other words, the random value may be decremented by one in SlotTime units so that the backoff count can be set, and when the backoff count is zero, the STA can perform channel access.

6 is a conceptual diagram showing a backoff procedure of a plurality of STAs.

Referring to FIG. 6, the backoff time (or the size of the contention window (CW)) may be reduced after the medium is determined to be idle for the duration of the DIFS. If media activity is not detected, the STA may reduce the backoff time in SlotTime units. If it is determined that the medium is busy during a backoff slot, the STA may defer the reduction of the backoff time. The frame transmission of the STA can be started every time the set backoff timer becomes zero. In other words, the STA may reduce the random value and transmit a frame if the random value becomes zero.

The backoff time set by the STA B 620, the STA C 630, and the STA D 640 after the frame transmission of the STA A 610 can be reduced. STA C 630, whose backoff time is reduced to the earliest among STA B 620, STA C 630, and STA D 640, can transmit frames through the medium. When STA C 630 transmits a frame, the reduction of the backoff time of STA B 620 and STA D 640 may be postponed.

In the DCF transmission method, there is an RTS / CTS access mode in which control frames (request to send (RTS) and clear to send (CTS)) are exchanged and channels are occupied in advance before data frames are transmitted. This method can reduce the waste of the channel by replacing the collision that may occur when the STA transmits the data frame with the collision caused by the relatively short control frame.

A PCF (Point Coordination Function) may be defined as another method for a plurality of STAs in the MAC layer to share wireless media. In the case of the DCF described above, it is a channel access based on carrier sense multiple access with collision avoidance (CSMA / CA). Therefore, real-time transmission of data transmitted between the STA and the AP can not be guaranteed. On the other hand, the PCF can be used as a method for providing quality of service (QoS) when transmitting real-time data. Unlike DCF, PCF is a non-contention-based transport service. The PCF is not used exclusively for the entire transmission period of the medium, but can be used alternately with the DCF-based competition-based service. The PCF can control the right of each STA to occupy the medium by using a polling scheme implemented by a point coordinator implemented in the AP of the BSS. PIFS, which is the inter-frame space (IFS) in the PCF, can be set to a smaller value than DIFS, which is the IFS of the DCF. By using this method, a STA connecting to a medium based on a PCF can have priority over a STA connected to a channel based on a DCF. The IFS indicates the interval between frames and can be used by the STA to set the priority for accessing the medium. The IFS can be defined specifically as follows.

The STA can use the carrier sense method to determine whether the channel is used during the time interval of the interframe space (IFS) defined by the standard. The MAC layer using the DCF defines a plurality of IFSs. The priority of the STA that occupies the wireless medium by the IFS can be determined. The intervals between frames according to IFS type are as follows.

(1) SIFS (short inter frame symbol): Used for RTS / CTS, ACK frame transmission. Highest priority

(2) PIFS (PCF IFS): used for frame transmission of STA operating based on PCF

(3) DIFS (DCF IFS): Used for frame transmission of STA operating based on DCF

(4) EIFS (extended IFS): Used only when a frame transmission error occurs, but not at a fixed interval

When DCF is used as a method for a plurality of STAs to share a wireless medium in the MAC layer, various problems may occur. For example, in the case of using the DCF, frames transmitted by a plurality of STAs may collide if a plurality of STAs simultaneously perform initial access to the AP. In DCF, there is no concept of transmission priority. Therefore, quality of service (QoS) for the traffic data transmitted by the STA can not be guaranteed. To solve this problem, IEEE 802.11e defines a new coordination function, HCF (hybrid coordination function).

HCF defines HCFC controlled channel access (HCCA) and enhanced distributed channel access (EDCA) as the channel access method. The EDCA can define the access categories of traffic.

The priority of accessing the channel based on the access category of traffic can be determined. That is, the size of the CW and the size of the IFS may be defined according to the category of the traffic data transmitted by the STA. The size of the different CW and the size of the IFS can determine the channel access priority according to the category of the traffic data.

For example, if the traffic data is e-mail, the corresponding traffic data may be assigned to a low priority class. In another example, when traffic data is voice communication over a wireless LAN, the corresponding traffic data may be assigned to a high priority class.

In the following, a specific EDCA-based channel access is posted.

In the EDCA-based channel access, the STA that transmits the high-priority traffic data can have a relatively higher transmission opportunity than the STA that transmits the low-priority traffic data. Also, on average, an STA that transmits high priority traffic may have less latency than an STA that transmits low priority traffic before transmitting a packet. To implement this method, CWs of different sizes may be defined according to the priority of the traffic data to be transmitted. In addition, different sizes of arbitration inter-frame space (AIFS) may be defined according to the priority of traffic data to be transmitted.

Specifically, in EDCA-based channel access, traffic data can be classified into eight user priorities. Each of the user priorities can correspond to one AC of four access categories (AC_BK, AC_BE, AC_VI, AC_VO).

Table 1 is an exemplary table showing a mapping relationship between AC and user priority of traffic data arriving at the MAC layer.

<Table 1>

Traffic data corresponding to a relatively high user priority can be preferentially transmitted based on different backoff parameters between ACs. Specifically, in EDCA-based channel access, backoff procedures for transmitting frames can be performed based on AIFS [AC], CWmin [AC], and CWmax [AC] instead of DCF-based parameters DIFS, CWmin, have. That is, different values of AIFS, CWmin, and CWmax can be defined for each AC. The lower the values of AIFS [AC] and CWmin [AC] are, the higher the priority is, and accordingly, the channel access delay is shortened so that more bandwidth can be used in a given traffic environment. The backoff parameters for each AC can be passed to each STA via a beacon frame.

Also, in EDCA-based channel access, the STA can access the channel without contention for a period called TXOP (transmit opportunity). As long as the TXOP period does not exceed the maximum duration, the STA can transmit as many packets as possible. If one frame is too long and can not be transmitted during one TXOP, it can be cut into small frames and transmitted. The use of TXOP can reduce the situation in which the STA having a low data rate, which is a problem of existing 802.11 DCF MAC, occupies an excessive channel.

Hereinafter, unfairness of the radio resource allocation between the cellular network system and the wireless LAN system due to the LAA-based channel access method of the cellular network system introduced for the coexistence on the license-exempt band between the cellular network system and the wireless LAN system is disclosed.

Licensed assisted access (LAA) is a channel access technology on an unlicensed band (e.g., 5 GHz) to support downlink transmission of cellular network systems based on LTE and LTE-A (advanced). In the cellular network system based on the carrier aggregation technology as described above, the license-exempted band can be used with the P (primary) -cell defined in the secondary (secondary) cell and defined on the license band.

A reservation signal, a partial subframe, is defined for the LAA of the cellular network system. For example, the channel access timing on the S-cell based on the LAA may not match the subframe boundary transmitted on the P-cell. That is, channel access timing on the S-cell may not coincide with subframe boundaries on the P-cell due to contention-based channel access on the S-cell.

Therefore, a device of a cellular network system that has performed channel access based on the LAA can transmit a preliminary signal before transmission of actual traffic data on the S-cell at a timing synchronized with the subframe boundary on the P-cell. The spare signal may not include any additional information. When a spare signal is transmitted, the cellular network system or other devices of the WLAN system that desire to access the channel may determine that the channel is not idle. Thus, channel access on the license-exempt band of other devices based on the preliminary signal can be limited.

Partial subframes have been defined to utilize portions of the subframe to reduce the overhead due to the spare signal. A partial subframe may be divided into an initial partial subframe or an ending partial subframe. The initial partial sub-frame may enable the transmission of actual data in the middle of the sub-frame (e.g., the second slot of the sub-frame) upon LAA-based channel access. The initial partial subframe can replace a part of the preliminary signal, and the utilization efficiency of radio resources can be increased. The ending partial sub-frame may enable transmission of data up to the middle of the sub-frame (e.g., the first slot of the sub-frame) upon LAA-based channel access. Therefore, a channel occupy time (COT), which is an allocated time resource in LAA-based channel access, can be more effectively utilized. That is, the initial partial subframe and the ending subframe can increase the data transmission time and reduce the ratio of the preliminary signal, thereby reducing the overhead due to the preliminary signal.

In addition, the LAA supports channel access in the license-exempt band based on a listen before talk (LBT) mechanism. In the LBT mechanism, channel sensing based on clear channel assessment (CCA) can be performed prior to utilization of frequency resources. That is, as a result of CCA-based channel sensing, utilization of the license-exempt band of the LAA-based cellular network system can be allowed only when the channel is idle.

The LBT mechanism for the LAA is a contention-based channel access mechanism similar to the channel access method (DCF-based channel access, EDCA, etc.) of the wireless LAN system defined in the existing IEEE802.11. In the channel access method of the wireless LAN system defined in IEEE 802.11, it is determined whether the channel is idle based on the CCA before the backoff procedure for channel access. Only when the channel is idle, the channel access Is allowed.

If the channel is determined to be idle based on the LBT mechanism, the cellular network system may occupy the channel for a period of time (e.g., 8 ms). The channel occupancy time of the license-exempt band of the LAA-based cellular network system can be expressed by the term COT (channel occupancy time). The COT may be defined as a fixed value that is not dependent on the transmission data rate (or data size (frame size)).

On the other hand, in the wireless LAN system, the channel can be occupied during the PPDU transmission time which is the data unit of the physical layer. As described above, in the wireless LAN system, an aggregate-MPDU in which an MPDU, which is a basic data unit defined in the MAC layer, is aggregated can be utilized as one data transmission unit. An A-MPDU including a plurality of MPDUs can be transmitted in one PPDU. The time resources allocated for the transmission of PPDUs in the WLAN system may be limited by various factors. For example, the bitmap size of the block ACK (block acknowledgment) transmitted in response to the PPDU, the maximum PHY service data unit (PSDU) length (or maximum A-MPDU length), the maximum PPDU transmission time ) It is possible to limit the transmission time of the PPDU in this WLAN system.

The length in the maximum PSDU length may mean the size of the data, and in the maximum PPDU duration, the duration means the size of the time resource allocated for transmission of the PPDU.

In the case where the wireless LAN system and the cellular network system share the license-exempt band, the wireless LAN system is saturated with a large amount of data to be transmitted / received, and the time resource for transmission of the PPDU of the wireless LAN system is smaller than that of the cellular network system (Or throughput) of the WLAN system is lower than that of the WLAN system when it coexists with another WLAN system (i.e., when the cellular network system does not communicate on the license-exempted band) . This is because the COT (channel occupancy time) of the license-exempt band of the cellular network system is 8 ms, whereas the wireless LAN system can have a relatively short channel occupancy time than the COT for each transmission opportunity.

7 is a graph comparing the performance of a wireless LAN system and a cellular network system on a license-exempted band.

In FIG. 7, simulation results for the performance of a WLAN system and a cellular network system are disclosed when an LAA-based channel access is used by a cellular network system on an existing license-exempt band. Hereinafter, the cellular network system disclosed in the embodiment of the present invention is assumed to utilize the license-exempt band based on the LAA.

7, a simulation topology is disclosed.

The wireless LAN system includes an AP 710 and an STA 720, and the cellular network system may include an eNode B (eNode B) 730 and a UE 740. The distance between the AP 710 and the STA 720 and the distance between the eNB 730 and the UE 740 is 30 m and the distance between the AP 710 and the eNB 730 and the distance between the STA 720 and the UE 740, May be 10 m.

In the simulation, the exemption bandwidth of 20 MHz is utilized in the wireless LAN system and the cellular network system, the AP 710 performs downlink transmission to the STA 720, and the eNB 730 performs downlink transmission to the UE 740 Is assumed. It is also assumed that there is no hidden node in the simulation.

Table 2 below shows the simulation setting values.

<Table 2>

7, when two APs (or a plurality of wireless LAN systems) exist in the wireless LAN system, the throughput according to the A-MPDU duration of each of the two APs is started. Referring to the interruption of FIG. 7, each of the two APs has a similar throughput of 20 Mb / s (megabyte for second), regardless of whether the duration of the A-MPDU transmitted by the wireless LAN system is long.

7 shows a case where the wireless LAN system and the cellular network system share the license-exempt band, and the wireless LAN system (or AP) and the cellular network system (or eNB) according to the A-MPDU duration transmitted by the wireless LAN system The throughput is initiated. 7, when the duration of the A-MPDU transmitted by the WLAN system is long, if the throughput is 20 Mb / s but the duration of the A-MPDU is short, It can be confirmed that the throughput is relatively reduced as compared with the use. In addition, since the cellular network system has robust characteristics even at a lower signal-to-interference-plus-noise ratio (SINR) than that of the wireless LAN system, the throughput of the cellular network system is relatively higher than that of the wireless LAN system.

As described above, the LBT mechanism, which is a channel access mechanism similar to the wireless LAN system, is used for channel access from the cellular network system to the license-exempt band. In the conventional cellular network system, a COT (8 ms) fixed to the cellular network system after the success of the channel access based on the LBT mechanism can be allocated as a time resource. On the other hand, in the wireless LAN system, the A-MPDU duration can be allocated as a time resource after the success of the channel access based on the wireless LAN channel access mechanism (e.g., DCF, EDCA, etc.).

The A-MPDU is a set of a plurality of MPDUs and can have the following three restrictions. 1) The maximum number of MPDUs included in the A-MPDU is limited to the size (8-octet, 64 bits) of the block ACK bitmap included in the block ACK frame, 2) The maximum PSDU length can be limited to 65,535 bytes (= PSDUMaxLength) as PSDUMaxLength. 3) the maximum PPDU duration (= PPDUMaxTime) set. In the IEEE802.11n standard, PPDUMaxTime is defined as 10 ms, but the default value of PPDUMaxTime is set to a different value (for example, 4 ms) in many wireless LAN network interface cards (NIC) Allow adjustment of PPDUMaxTime.

Even if the PPDUMaxTime value is set to 10ms, if the wireless LAN system uses a high data rate and the number of MPDUs to be aggregated by the size of the block ACK bitmap is limited, or the maximum PSDU length is limited, the duration of the A- Can be shortened. Specifically, when the PPDUMaxTime is less than 8 ms or the transmission rate of the wireless LAN system is 65,535 bytes (= PSDUMaxLength) or 64 MPDUs can be transmitted within 8 ms, the A-MPDU duration of the wireless LAN system may be less than 8 ms.

Thus, a fixed 8 ms COT of the cellular network system may cause unfair allocation of severe radio resources if the WLAN system is saturated and the duration of the A-MPDU of the WLAN system is short.

An embodiment of the present invention discloses a COTA (COT adaptation) algorithm for solving the problem of such unfair radio resource allocation. The COTA algorithm acquires information on the frame / PPDU transmitted by the wireless LAN system during the channel sensing time based on the LBT mechanism, and transmits the frame / PPDU transmitted from the wireless LAN system to the wireless LAN We define a method to adaptively adjust the COT by judging the state of the system.

8 is a conceptual diagram illustrating a COTA algorithm according to an embodiment of the present invention.

In Fig. 8, a COTA algorithm for adaptively adjusting COT based on the state of a wireless LAN system is disclosed. Based on the COTA algorithm, more fair allocation of radio resources can be performed for the cellular network system and the wireless LAN system in the license-exempt band.

In the COTA algorithm, it is assumed that the eNB of the cellular network system can interpret the frame / PPDU transmitted by the wireless LAN system (or if decoding (or overhearing) is possible for the frame / PPDU).

Referring to FIG. 8, the COTA algorithm may include a saturation detection step 800 and a channel occupancy time adaptation step 810.

In the saturation detection step 800, the cellular network system may determine whether the WLAN system is saturated. The fact that the WLAN system is saturated means that packets to be sent to the queues in the WLAN system still remain.

When there are many wireless LAN data to be transmitted on the license-exempt band by the wireless LAN system, the cellular network system can determine the wireless LAN system to be saturated. The cellular network system can determine whether the WLAN system is saturated based on the information about the number of MPDUs aggregated in the A-MPDU, information on the length of the PSDU, and information on the PPDU duration. A method for detecting the saturation of a specific wireless LAN system will be described later.

In the COT adjustment step 810, when the wireless LAN system is saturated, adjustment to the value of COT may be performed. Specifically, when the wireless LAN system is saturated, the cellular network system can adjust the value of the COT to 8 ms or less. For example, the cellular network system may adjust the value of COT in consideration of the duration of a previously detected frame / PPDU. Conversely, in the COT adjustment step 810, if the WLAN system is not in saturation, the adjustment to the value of COT is not performed and can be maintained at 8 ms.

If the wireless LAN system is determined to be saturated based on the adjustment of the COT, a relatively large amount of wireless resources may be allocated to the wireless LAN system than the conventional wireless LAN system. As a result, the deterioration of the wireless LAN system Can be reduced.

The saturation detection step 800 and the COT adjustment step 810 based on the COTA algorithm can be performed by a device constituting the cellular network (e.g., the base station eNB).

Hereinafter, in the embodiment of the present invention, the saturation detection step 800 and the COT adjustment step 810 are specifically disclosed.

9 is a flowchart illustrating a saturation detection step according to an embodiment of the present invention.

The saturation of the wireless LAN system can be judged by various conditions. The eNB of the cellular system may override the PPDU transmitted by the wireless LAN system to determine whether the wireless LAN system is saturated.

In the embodiment of the present invention, when one of the following three conditions is satisfied, it can be determined that the wireless LAN system is in a saturated state.

First Condition) When the number (M) of MPDUs included in the A-MPDU is equal to the size (8-octet, 64 bits) of the block ACK bitmap of the block ACK frame

Second condition) When the length L of the PSDU corresponding to the A-MPDU is equal to or larger than the value of PSDUMaxLength-L _mpdu . Where L _mpdu is the average length of a plurality of MPDUs that are aggregated into an A-MPDU.

Third condition) The duration (T) of the PPDU including the A-MPDU is T _{longest -Tmpdu} Or more. The T _longest may be the maximum PPDU duration of the observed PPDU duration and the T _mpdu may be the average duration of the MPDUs aggregated to the A-MPDU. T _mpdu may be a value obtained by dividing L _mpdu by the transmission data rate of the A-MPDU.

Unlike the block ACK bitmap size and PSDUMaxLength, T _longest may vary depending on the setting of the PPDUMaxTime set by the network interface card (NIC) of the wireless LAN system. PPDUMaxTime may be the maximum PPDU duration, and T _longest may be limited by PPDUMaxTime.

Therefore, the maximum duration of the previously detected PPDUs can be estimated with T _max .

Referring to FIG. 9, the cellular network system may determine whether at least one of a first condition, a second condition, and a third condition is satisfied (step S900).

) 또는 제3 조건(

)를 만족하는지 여부를 판단할 수 있다.More specifically, the cellular network system determines whether the first condition (M = 64) or the second condition (M = 64) based on the information of the PPDU / frame of the over-

) Or the third condition (

) Is satisfied.

If at least one of the first condition, the second condition, and the third condition is satisfied, the cellular network system may determine the wireless LAN system to be saturated (step S910).

If the received A-MPDU satisfies at least one of the first condition, the second condition, and the third condition, the cellular network system can determine the wireless LAN system to be saturated.

S _i can be defined as a variable indicating saturation of the wireless LAN system determined based on the i-th received A-MPDU. When the wireless LAN system is saturated, S _i is set to true, and if the wireless LAN system is not saturated, S _i may be set to false.

It is determined whether to set T _longest newly (step S920).

If the detection result T _i is greater than T _longest , T _i may be set to a new T _longest value (step S 930).

T _i may be the duration (T) of the PPDU including the i-th received A-MPDU. That is, the value of T _longest may be updated according to the new observation result T _i . Thereafter, the cellular system may perform a search for the third condition in accordance with the updated T _longest .

10 is a flowchart showing a COT adjustment step according to an embodiment of the present invention.

In FIG. 10, as a result of the saturation detection in the saturation detection step, when the wireless LAN system is saturated, a COT adjustment step for adjusting the COT is started.

Referring to FIG. 10, the cellular system determines whether the wireless LAN system is in saturation (step S1000).

It may be determined whether the wireless LAN system is saturated or not in order to perform the COT adjustment step. Whether the WLAN system is in saturation can be determined based on the value of S _i . If the WLAN system is not saturated, the COT adjustment step may not be performed, and if the WLAN system is saturated, a COT adjustment step may be performed.

If the WLAN system is saturated, an adjustment to the COT may be performed (step S1010).

The adjustment to the COT can be performed based on Equation (2) below.

&Quot; (2) &quot;

COT _next = min (T _i , 8 ms)

In Equation 2 COT _next may be a value adjusted COT, the initial value of the _next COT may be unadjusted 8ms. T _i may be the duration of the PPDU including the i-th A-MPDU as described above.

Where i may be 1 to N, and N may be the number of A-MPDUs (or PPDUs) detected (or overheard) by the cellular network system. That is, the base station of the cellular network system can perform a saturation detection step and a COT re-adjustment step based on each detected A-MPDU (or PPDU) to re-adjust the COT for each A-MPDU (or PPDU). As an example, it is possible to periodically perform sensing for the A-MPDU and perform the saturation detection step and the COT re-adjustment step instead of the saturation detection step and the COT re-adjustment step based on all the sensed A-MPDUs. Even if the duration (T _i ) of the PPDU exceeds 8 ms in the wireless LAN system, the cellular network system can be guaranteed a COT of up to 8 ms.

Hereinafter, simulation results according to traffic environments of three different wireless LAN systems are disclosed in the embodiment of the present invention. The traffic environment of three different WLAN systems simulated can be either a saturated WiFi traffic environment, a non-saturating WiFi traffic environment, or a bursty WiFi traffic environment.

11 is a flowchart illustrating a method for detecting a saturation of a wireless LAN system according to an embodiment of the present invention.

11, a saturation detection method for determining saturation of a wireless LAN system according to another embodiment of the present invention is disclosed.

As described above, in the third condition described in FIG. 9, the saturation of the WLAN system is detected based on the information on the T _max , which is the maximum PPDU duration observed so far.

According to another embodiment of the present invention, whether or not the maximum PPDU duration observed so far is the maximum PPDU duration (PPDUMaxTime) set by the NIC of the wireless LAN system may be detected and whether the wireless LAN system is saturated may be detected.

Specifically, the cellular system network determines 1) the maximum PPDU duration (PPDUMaxTime) set by the NIC of the WLAN system based on the maximum PPDU duration observed so far (step S1100), 2) It is determined whether the wireless LAN system is saturated or not (step S1110).

In order to determine whether the wireless LAN system is saturated, the following third condition may be used instead of the third condition described above in FIG.

3 ' condition) The duration (T) of the PPDU including the A-MPDU is PPDUMaxTime-T _mpdu Or more. PPDUMaxTime is the maximum PPDU duration set by the network interface card (NIC) of the wireless LAN system, and _Tmpdu may be the average duration of the MPDUs aggregated to the A-MPDU. T _mpdu may be a value obtained by dividing L _mpdu by the transmission data rate of the A-MPDU. PPDUMaxTime may vary depending on the configuration of the NIC (network interface card) of the wireless LAN system.

To determine the third condition, the PPDUMaxTime of each transmitter of the wireless LAN system should be determined.

If the PPDU transmission duration of the transmitter of the wireless LAN system is always the same, it is difficult to judge whether transmission of the PPDU by each transmitter of the wireless LAN system is limited by the PPDUMaxTime in the saturation detection stage, The determination of PPDUMaxTime may be difficult.

For example, when the CBR (constant bitrate) traffic transmission is performed on the license-exempt band for the traffic of the source rate lower than the achievable throughput of the transmitter of the wireless LAN system, the PPDU transmission duration of the transmitter of the wireless LAN system is always Can be the same. Therefore, it can not be determined whether the transmission of each transmitter of the wireless LAN system is limited by PPDUMaxTime in the saturation detection step. However, even if the CBR traffic transmission is performed by the transmitter of the wireless LAN system, the PPDU transmission duration may be changed.

If the license-exempt band is occupied by another device by data transmission on the license-exempt band of another device, a frame to be transmitted is accumulated in a queue of a transmitter that performs CBR traffic transmission. Therefore, if CBR traffic transmission of the transmitter is performed after occupation of the license-exempt band by another device, a relatively large number of MPDUs may be included in the A-MPDU transmitted by the transmitter that transmits the CBR traffic. The duration of a PPDU carrying an A-MPDU including a relatively large number of MPDUs can be relatively increased.

In addition, the beacon frame may be periodically transmitted by the AP on the license-exempt band. For example, the transmission period of the beacon frame may be 102.4 ms. The transmission of the beacon frame may occupy the license-exempt band, and in this case, a frame to be transmitted is accumulated in the queue of the transmitter performing the CBR traffic transmission. Therefore, after the transmission of the beacon frame, a relatively large number of MPDUs may be included in the A-MPDU transmitted by the transmitter transmitting the CBR traffic. The duration of a PPDU carrying an A-MPDU including a relatively large number of MPDUs can be relatively increased.

That is, when the transmitter of the WLAN system performs CBR traffic transmission for a source rate lower than the available throughput, the PPDU duration for the A-MPDU transmitted by the transmitter of the WLAN system is temporarily increased, Can be drastically reduced. If it is determined that the wireless LAN system is saturated based on these values, the accuracy of determination of saturation can be reduced.

If the WLAN system is saturated, PPDU durations _longer than T _longest- T _mpdu limited by _PPDUMaxTime can be continuously observed. Thus, in accordance with an embodiment of the present invention, in a continuous han A-MPDU received from the transmitter, each of the wireless LAN system by more than a threshold number of times (C _thres) T -T _{longest mpdu} If more PPDU durations are observed, the cellular system may determine T _longest as PPDUMaxTime. If the PPDU duration _longer than T _longest- T _mpdu occurs after the determination of _PPDUMaxTime , the cellular system may be determined to saturate the wireless LAN system.

The threshold number of times (C _thres ) for determining T _longest as PPDUMaxTime can be expressed by the term PPDUMaxTime decision threshold coefficient.

Conversely, if PPDU durations _longer than T _longest- T _mpdu are observed in A-MPDUs consecutively received from each transmitter of the wireless LAN system, the cellular system does not determine T _longest as PPDUMaxTime, It may not perform judgment as to whether or not it is saturated. If a PPDU duration _longer than T _longest- T _mpdu is observed in the A-MPDU continuously received from each transmitter of the wireless LAN system, the count value counting the threshold number can be reset to 0 again.

The T _longest can be reset every set time (T _resetlongest ).

If an A-MPDU having a PPDU duration that is longer than the previously set T _longest is observed while determining whether the A-MPDU is more than the threshold number, the T _longest may be newly set based on the PPDU duration of the observed A-MPDU have. Further, the value counted up to now has been carried out is T _longest counting for the threshold number of times, based on the _longest T set is again set to one, the newly set re-updated in the same manner can choose to PPDUMaxTime.

If the cellular system receives a non-A-MPDU that is not an A-MPDU, then the cellular system determines a threshold number of times The counting value to be counted may again be reset to zero.

The cellular network system performs saturation detection based on the first condition, the second condition, and the third condition in the saturation detection step, and when the wireless LAN system is saturated, the adjustment to the COT is performed as described in FIG. 10 And perform the COT adjustment step to be performed.

12 is a graph showing the detection rate of PPDUMaxTime according to an embodiment of the present invention.

In Fig 12 is disclosed PPDUMaxTime detection rate (detection rate) according to the threshold number of times (C _thre) for determining a PPDUMaxTime.

The PPDUMaxTime detection rate may be the number of A-MPDUs whose PPDU duration of PPDUs carrying A-MPDUs is PPDUMaxTime out of the total number of A-MPDUs.

11 PHY rates (13, 19.5, 26, 39, 52, 58.5, 65, 78, 104, 117, 130 Mb / s) and 9 PPDUMaxTime values (2,3, 4,5, 6,7, (60Mb / s, 20Mb / s) at two different transmission rates for a total of 99 combinations with respect to a total of 8, 9, 10ms).

If the source rate of the WLAN system is greater than the achievable throughput of the WLAN system, as many MPDUs as possible within the A-MPDU frame may be fully aggregated. The possible throughput of the WLAN system can be determined based on the PHY rate and the PPDUMaxTime value.

Threshold number of times (C _thres) above for determination of a continuous PPDUMaxTime in A-MPDU received as described above in FIG. 11 as T -T _{longest mpdu} If more PPDU durations are observed, the cellular system may determine T _longest as PPDUMaxTime. If the threshold count (C _thres ) is too small, a judgment error for PPDUMaxTime may be generated in the saturation detection step.

Referring to the top and bottom of FIG. 12, when the threshold number of times (C _thres ) is set to 0, the PPDUMaxTime detection rate can be almost 100%. This is because, if the threshold number of times (C _thres ) is set to 0, the T _longest is determined to be PPDUMaxTime without consecutive observation on the A-MPDU.

On the other hand, as the critical number (C _thres ) increases, PPDUMaxTime can be determined more accurately in the saturation detection step.

If CBR traffic transmission is performed based on each of the above 99 combinations for a source rate of 60 Mb / s, PPDUMaxTime may be determined for 60 of the 99 combinations. If CBR traffic transmission is performed based on each of the above 99 combinations for a source rate of 20 Mb / s, PPDUMaxTime can be determined for 18 combinations out of 99 combinations.

Referring to the graph of FIG. 12, it can be seen that a cumulative distribution function (CDF) curve clearly detects saturation in the saturation detection step when the critical number (C _thres ) for determining _PPDUMaxTime is greater than 1. The threshold number of times (C _thres ) for determining _PPDUMaxTime may be set to 3 for more accurate detection.

13 to 17, the performance of the COTA algorithm is disclosed when the third 'condition is used.

13 is a graph showing the saturation detection performance of the COTA algorithm according to the embodiment of the present invention.

In Fig. 13, the saturation detection performance of the COTA algorithm for various WiFi traffic source rates is disclosed.

At the top of FIG. 13, when the WLAN system is saturated, the saturation detection capability of the COTA algorithm is initiated.

13, the saturation ratio may be a ratio to the number of A-MPDU frames in which the saturation is detected by the saturation detection algorithm among the total number of observed A-MPDUs. In the graph at the top of FIG. 13, a saturated WLAN system is assumed, so the saturation rate can be nearly 100% for all PHY rates and PPDUMaxTime combinations. The low PHY rate will bring a long A-MPDU transmission time, and the A-MPDU frame can be limited by PPDUMaxTime. On the other hand, since the long PHY rate has a short A-MPDU transmission time, the A-MPDU can be limited by the block ACK bitmap size or PSDUMaxLength.

The graph of the interruption of FIG. 13 discloses the saturation rate for the combination of PHY rate and PPDUMaxTime when the wireless LAN traffic source rate is 60 Mb / s.

The graph at the bottom of FIG. 13 shows the saturation rate for the combination of PHY rate and PPDUMaxTime when the wireless LAN traffic source rate is 20 Mb / s.

Depending on the PHY rate / PPDUMaxTime, the WLAN system may be in a saturated or non-saturated state in performing CBR traffic transmission.

13, if the PHY rate is lower than the source rate (60 Mb / s or 20 Mb / s) based on the saturation detection step in the COTA algorithm, the WLAN system may be detected as saturated. Conversely, if the PHY rate is relatively larger than the source rate (60 Mb / s or 20 Mb / s), the WLAN system may be detected as non-saturated.

14 is a graph illustrating performance of a COTA algorithm according to an embodiment of the present invention.

14, throughput performance is initiated in a saturated WiFi traffic environment. The saturated WiFi traffic environment is when the WLAN system is saturated.

Referring to FIG. 14, WiFi + WiFi indicates a situation where two wireless LAN systems (or two APs) coexist in a license-exempt band. Under such circumstances, WiFi (WiFi + WiFi) is a graph showing the throughput of the wireless LAN system according to the A-MPDU duration of the wireless LAN system.

WiFi + LAA indicates a situation where one wireless LAN system and one cellular network system coexist in the license-exempt band, but the COTA algorithm according to the embodiment of the present invention is not applied. In this situation, WiFi (WiFi + LAA) is a graph showing the throughput of the wireless LAN system according to the A-MPDU duration of the wireless LAN system, and LAA (WiFi + LAA) FIG.

WiFi + COTA indicates a situation where one wireless LAN system and one cellular network system coexist in the license-exempt band, but the COTA algorithm according to the embodiment of the present invention is applied. Under such circumstances, WiFi (WiFi + COTA) is a graph indicating the throughput of the wireless LAN system according to the A-MPDU duration of the wireless LAN system, and COTA (WiFi + COTA) is a graph indicating the throughput of the cellular network system In the case of the second embodiment.

Referring to the WiFi (WiFi + LAA) graph, it can be confirmed that as the duration of the A-MPDU decreases in the WiFi + LAA situation, the throughput of the wireless LAN system decreases as described above.

Referring to the WiFi (WiFi + COTA) graph, there is little decrease in the throughput of the wireless LAN system according to the duration of the A-MPDU in the WiFi + COTA situation and only the wireless LAN system uses the license- WiFi + WiFi is the same throughput. This is because, when it is determined that the wireless LAN system operates in a saturated WiFi traffic environment according to the COTA algorithm, the deterioration of the throughput of the wireless LAN system is prevented because the COT is adaptively reduced.

15 is a graph illustrating performance of a COTA algorithm according to an embodiment of the present invention.

At the top of FIG. 15, the fractional airtime ratio is started under the WiFi + LAA and WiFi + COTA situations.

The fractional occupation time ratio can be defined as the ratio of the total transmission time during the entire simulation time.

WiFi (WiFi + LAA) is a graph showing the partial occupancy time ratio of the wireless LAN system according to the A-MPDU duration of the wireless LAN system under the WiFi + LAA situation, and LAA (WiFi + LAA) And a partial occupancy time ratio of the cellular network system according to the duration.

WiFi (WiFi + COTA) is a graph of partial occupancy time ratio of the wireless LAN system according to the A-MPDU duration of the wireless LAN system under the WiFi + COTA situation, and LAA (WiFi + COTA) And a partial occupancy time ratio of the cellular network system according to the duration.

Referring to the WiFi (WiFi + LAA) graph and the LAA (WiFi + LAA) graph at the top of FIG. 15, as the A-MPDU duration of the WLAN system decreases, the ratio of the partial occupancy time of the WLAN system to that of the cellular network system The partial occupancy time ratio can be increased. For example, when the A-MPDU duration of the wireless LAN system is 2ms, the gap between the partial occupancy time ratio of the wireless LAN system and the partial occupancy time ratio of the cellular network system may be four times.

Referring to the WiFi (WiFi + COTA) graph and the COTA (WiFi + COTA) graph at the top of FIG. 15, as the A-MPDU duration of the wireless LAN system decreases / increases, It can be confirmed that the difference in the partial occupation time ratio of the occupancy rate does not occur. When the A-MPDU duration of the wireless LAN system is more than 8 ms, the partial occupancy time ratio of the wireless LAN system may be relatively larger than the partial occupancy time ratio of the cellular network system because the COT of the cellular network system does not exceed 8 ms . That is, based on the COTA algorithm, the radio resource allocation between the wireless LAN system and the cellular network system can be made more equitable.

In the lower part of FIG. 15, a graph showing an index for an occupancy time process diagram based on JFI (jain's fairness index) is disclosed.

Equation 3 below is a formula for calculating JFI.

&Quot; (3) &quot;

In Equation (3), x _n is the ratio of the partial occupancy time of the wireless LAN system to the specific A-MPDU duration indicated by the WiFi (WiFi + COTA) graph, Lt; RTI ID = 0.0 &gt; cellular network &lt; / RTI &gt; JFI can have a value between 1 / n and 1 to indicate fairness of radio resource allocation. The closer the JFI is to 1, the more likely it is that the radio resources are fairly allocated.

15, when the A-MPDU duration is relatively small in the WiFi + LAA environment, the JFI has a low value which is far from 1, and when the A-MPDU duration is relatively high, the JFI is close to 1 Lt; / RTI &gt; That is, it can be seen that the allocation of radio resources in the WiFi + LAA environment based on JFI is unfair.

In a WiFi + COTA environment, the JFI can have a value close to 1 regardless of the decrease / increase of the A-MPDU duration. That is, it can be seen that the allocation of radio resources in the WiFi + COTA environment is fair based on JFI.

16 is a graph illustrating performance of the COTA algorithm according to an embodiment of the present invention.

In Figure 16, throughput performance is initiated in an unsaturated WiFi traffic state. Unpublished WiFi traffic environment is a situation where the wireless LAN system is not saturated.

Referring to FIG. 16, WiFi + LAA indicates a situation where one wireless LAN system and one cellular network system coexist in a license-exempt band, but the COTA algorithm is not applied. Under this circumstance, WiFi (WiFi + LAA) indicates a graph of the throughput of the wireless LAN system according to the source rate of the wireless LAN system, and LAA (WiFi + LAA) A graph of the throughput of the system can be indicated.

WiFi + COTA-w / o SD is a case where one wireless LAN system and one cellular network system coexist in the license-exempt band, but only the COT adjustment step is performed without the saturation detection step among the COTA algorithms according to the embodiment of the present invention. If only the COT adjustment step is performed, adjustment to the COT based on Equation (2) can be performed irrespective of whether the wireless LAN system is saturated or not. In this situation, WiFi (WiFi + COTA-w / o SD) is a graph of the throughput of the wireless LAN system according to the source rate of the wireless LAN system, and COTA-w / o SD Indicates a graph of the throughput of the cellular network system according to the source rate of the LAN system.

WiFi + COTA indicates a situation where one wireless LAN system and one cellular network system coexist in the license-exempt band, but the COTA algorithm according to the embodiment of the present invention is applied. Under such circumstances, WiFi (WiFi + COTA) is a graph of the throughput of the wireless LAN system according to the source rate of the wireless LAN system, and COTA (WiFi + COTA) is a graph of the throughput of the cellular network system according to the source rate of the wireless LAN system .

Referring to FIG. 16, when the source rate of the WLAN system is 15 Mb / s or less, the WLAN system and the cellular network system can have the same throughput characteristics in the WiFi + COTA environment and the WiFi + LAA environment. This is because the COTA can only make adjustments to the COT if the WLAN system is saturated.

When the source rate of the WLAN system is 15 Mb / s or more, the WiFi + COTA environment exhibits a relatively high throughput characteristic as compared with the WiFi + LAA environment. That is, the throughput of the wireless LAN system can be increased based on the COTA algorithm.

In the WiFi + COTA-w / o SD environment, if the source rate of the wireless LAN system increases, it may show the same characteristics as the WiFi + COTA environment. This is because, if the source rate of the WLAN system increases even under the WiFi + COTA environment (i.e., when the WLAN system is saturated), the adjustment of the COT is performed in the same manner as the WiFi + COTA-w / o SD environment to be.

On the other hand, in the WiFi + COTA-w / o SD environment, if the source rate of the wireless LAN system is reduced, the performance of the cellular network system may deteriorate. Referring to the COTA-w / o SD (WiFi + COTA-w / o SD) graph, it can be seen that the cellular network system exhibits deteriorated performance compared to COTA (WiFi + COTA). This is because, in the WiFi + COTA-w / o SD environment, the COT can be reduced without considering saturation of the wireless LAN system.

17 is a graph illustrating performance of a COTA algorithm according to an embodiment of the present invention.

In Figure 17, throughput performance is initiated in a bursty WiFi traffic environment. The bus-tee WiFi traffic environment may be an environment where data is suddenly and intensively generated at a specific timing.

Referring to the top of FIG. 17, WiFi is a graph showing throughput of the wireless LAN system over time under the WiFi + COTA environment. COTA is a graph showing the throughput of a cellular network system over time under the WiFi + COTA environment.

Referring to the WiFi graph, the throughput of the WLAN system may increase when data is received on the license-exempt band, and may be decreased after the data transmission is completed.

Referring to the COTA graph, the throughput of the cellular network system can be reduced when data is transmitted in the wireless LAN system, and the throughput of the cellular network system can be increased when the transmission of data is terminated in the wireless LAN system. That is, the COT of the cellular network system is immediately reduced when data is transmitted in the wireless LAN system, and the COT can be recovered after the data transmission is completed in the wireless LAN system.

18 is a block diagram illustrating a wireless device according to an embodiment of the present invention.

Referring to FIG. 18, the wireless device may be an eNB or a UE capable of implementing the above-described embodiment.

The eNB 1800 includes a processor 1810, a memory 1820, and a radio frequency unit 1830.

RF section 1830 may be operatively coupled to processor 1810 to transmit / receive wireless signals.

Processor 1810 may implement the functions, processes, and / or methods suggested in the present invention. For example, processor 1810 may be implemented to perform operations of a cellular system (or base station (or eNB)) according to embodiments of the present invention described above. The processor may perform operations of the cellular system (or eNB) disclosed in the embodiment of Figs. 8-17.

For example, the processor 1810 may be configured to determine whether the WLAN system is saturated and adjust the channel occupancy time on the license-exempt band if the WLAN system is saturated. The channel occupancy time can be adjusted based on information about the duration of the PPDU.

The license-exempted band is a frequency band shared by the cellular network system and the wireless LAN system, and the cellular network system and the wireless LAN system can perform channel access on the license-exempt band.

The cellular network system and / or the wireless LAN system may be channel access based on contention-based channel access (e.g., LBT (listen before talk) based channel access) on the license-exempt band, Contention-based channel access, such as allocating time resources to perform channel access.

Whether the wireless LAN system is saturated may be determined based on the wireless LAN data transmitted by the wireless LAN system overlaid by the cellular network system. The WLAN data may include a physical protocol data unit (PPDU), a PPDU may include an aggregate-MAC (medium access control) protocol data unit (A-MPDU), and the A- MPDUs. Whether the wireless LAN system is in a saturated state includes at least one of information on the number of MPDUs aggregated in the A-MPDU, information on the length of the A-MPDU (or PSDU), and information on the duration of the PPDU As shown in FIG.

The processor determines the maximum PPDU duration of the wireless LAN system based on the duration of the previous PPDU received from the wireless LAN system to determine whether the wireless LAN system is in the saturation state, and determines a duration of the determined maximum PPDU and a duration of the received PPDU And determine whether the wireless LAN system is in a saturated state.

The UE 1850 includes a processor 1860, a memory 1870, and a radio frequency unit 1880.

The RF unit 1880 can communicate with the processor 1560 to transmit / receive wireless signals.

Processor 1860 may implement the functions, processes, and / or methods suggested in the present invention. For example, the processor 1860 may be implemented to perform the operations of the UE according to the embodiments of the present invention described above. The processor may perform the operation of the UE in the embodiment of Figures 8-17.

For example, the processor 1860 may be configured to receive downlink data transmitted on the coordinated COT from the base station. In addition, processor 1860 may perform coordination on the COT for uplink transmission based on its own COTA algorithm.

Processors 1810 and 1860 may include application-specific integrated circuits (ASICs), other chipsets, logic circuits, data processing devices, and / or converters for converting baseband signals and radio signals. Memory 1820 and 1870 may include read-only memory (ROM), random access memory (RAM), flash memory, memory cards, storage media, and / or other storage devices. RF sections 1830 and 1880 may include one or more antennas for transmitting and / or receiving wireless signals.

When the embodiment is implemented in software, the above-described techniques may be implemented with modules (processes, functions, and so on) that perform the functions described above. The modules may be stored in memory 1820, 1870 and executed by processors 1810, 1860. The memories 1820 and 1870 may be internal or external to the processors 1810 and 1860 and may be coupled to the processors 1810 and 1860 in various well known means.

Claims (11)

The method of sharing radio resources in the license-
The method comprising: determining whether the cellular network system is in a saturated state; And
And adjusting the channel occupancy time on the license-exempt band if the WLAN system is in the saturation state,
Wherein the license-exempt band is a frequency band shared by the cellular network system and the wireless LAN system,
Wherein the cellular network system and the wireless LAN system perform channel access on the license-
Whether or not the wireless LAN system is in the saturation state is determined based on wireless LAN data transmitted by the wireless LAN system overhear by the cellular network system,
The wireless LAN data includes a physical protocol data unit (PPDU)
The PPDU includes an aggregate-MAC (medium access control) protocol data unit (A-MPDU)
The A-MPDU includes a plurality of MPDUs,
Whether or not the wireless LAN system is in the saturation state may include at least one of information on the number of MPDUs aggregated in the A-MPDU, information on the length of the A-MPDU, and information on the duration of the PPDU Is determined on the basis of the information of &lt; RTI ID = 0.0 &gt; delete delete 2. The method of claim 1, wherein the determining whether the cellular network system is in the saturation state comprises:
Determining a maximum PPDU duration of the wireless LAN system based on a duration of a previous PPDU received from the wireless LAN system by the cellular network system; And
And the cellular network system determining whether the WLAN system is in the saturation state based on the maximum PPDU duration and the duration of the PPDU. The method according to claim 1,
Wherein the channel occupancy time is adjusted based on information on a duration of the PPDU. A cellular network device sharing wireless resources in a license-
A radio frequency (RF) unit for transmitting and receiving a radio signal; And
A processor operatively coupled to the RF unit,
The processor determines whether the wireless LAN system is saturated,
Wherein when the wireless LAN system is in the saturation state, a channel occupancy time is adjusted on a license-exempt band,
Wherein the license-exempt band is a frequency band shared by the cellular network system and the wireless LAN system,
Wherein the cellular network system and the wireless LAN system perform channel access on the license-
Whether or not the wireless LAN system is in the saturation state is determined based on wireless LAN data transmitted by the wireless LAN system overhear by the cellular network system,
The wireless LAN data includes a physical protocol data unit (PPDU)
The PPDU includes an aggregate-MAC (medium access control) protocol data unit (A-MPDU)
The A-MPDU includes a plurality of MPDUs,
Whether or not the wireless LAN system is in the saturation state may include at least one of information on the number of MPDUs aggregated in the A-MPDU, information on the length of the A-MPDU, and information on the duration of the PPDU Of the cellular network device. delete delete The method according to claim 6,
Wherein the processor determines a maximum PPDU duration of the WLAN system based on a duration of a previous PPDU received from the WLAN system,
And determine whether the WLAN system is in the saturation state based on the maximum PPDU duration and the duration of the PPDU. The method according to claim 6,
Wherein the channel occupancy time is adjusted based on information on the duration of the PPDU. A computer-readable recording medium having recorded thereon a computer program for executing the method according to any one of claims 1, 4 and 5.

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