KR102140828B1 - LBT Method of Base Station Apparatus Coexisting Heterogeneous Legacy Network and Base Station Apparatus thereof - Google Patents

Abstract

An LBT method of a base station apparatus coexisting with a heterogeneous legacy system and a base station apparatus thereof are disclosed. The present invention is useful when the latest mobile communication systems such as LTI coexist in the same frequency band with heterogeneous legacy systems that cannot receive system operation information. The present invention proposes an LBT Gap that stops transmission of an LTE signal by setting at least one radio reception signal measurement interval to measure the strength of a radio reception signal by a heterogeneous legacy system that is not mutually synchronized. A base station apparatus to which the present invention is applied coexists with a heterogeneous legacy system by determining a transmission power level of a radio signal based on an LBT gap over at least one radio reception signal measurement period and an RSSI obtained through measurement in a corresponding gap period.

Description

LBT method of a base station device coexisting with a heterogeneous legacy system and its base station device {LBT Method of Base Station Apparatus Coexisting Heterogeneous Legacy Network and Base Station Apparatus thereof}

The present invention relates to an LBT method for solving a problem that may occur when a new wireless telephone service is performed in a frequency band served by a heterogeneous legacy system.

Wireless telephone technology, from the very old communication method to the recent 4G LTE (LTE) or 5G communication method coexist virtually. While the latest wireless technologies, such as LTI, are being released every day, very old legacy cordless phone methods such as Digital Enhanced Cordless Telecommunications (DECT) and Personal Handy-phone System (PHS) are still being discontinued, even though they are losing marketability. Is being used. It may take several years to convert an existing heterogeneous legacy system to a new system. During the transition period, the LTI system must coexist with the heterogeneous legacy system in the same frequency domain. Naturally, a new communication system based on LTI is needed to coexist with a legacy communication system. For reference, DECT stands for Digital European Cordless Telecommunications, and PHS is also called'Personal Access System (PAS)'.

In order for the newly provided new equipment based on the LTC to coexist with older devices operating in the same service frequency band, the LTI equipment must not affect the service of the older devices on the same frequency. Before providing the LTI service, it is necessary to check whether there is a signal of a heterogeneous legacy system in a service target area and determine the output size of the LTI signal according to the measured received signal level of the heterogeneous legacy system. Even after the LTI service starts, it is necessary to periodically check whether there are heterogeneous legacy systems in surrounding cells.

Common LBT technology is used between network devices that share channels and have equal rights. According to the LBT, network devices first detect whether the corresponding channel is used, and use the shared channel when the channel is not occupied by another device. While data transmission is in progress on the shared channel, other devices detect that the channel is occupied and suspend the transmission. By the LBT process, there is no collision between network devices.

The present invention starts with the idea that a recent mobile communication system such as an LTI system can apply LBT to coexist in the same frequency band with a conventional heterogeneous legacy system. However, a little different consideration is needed to use LBT to coexist with heterogeneous legacy systems. Representing the latest mobile communication system in contrast to the heterogeneous legacy system, it will be described based on the LTI system.

The LT system replaces the existing communication protocol, but the new equipment should not affect the service of the heterogeneous legacy system equipment. Therefore, when both the old network equipment and the new network equipment are operated in the same frequency band, unlike the conventional LBT technology, the old network equipment must be operated in preference to the new equipment, and the conventional network equipment must be able to continuously occupy the channel. do.

Therefore, the new standard equipment first detects whether the old equipment is in service or not, and if the old equipment provides service (when the signal of the old equipment is confirmed), it is wireless enough to not affect the quality of service of the old equipment. It should not weaken or even transmit power. Since the new standard equipment is different from the old equipment and the radio protocol standard itself, in this situation, the LBT technology between the heterogeneous network systems should be applied.

The LBT-applied device may determine whether the channel is idle by comparing the average power detected in the channel during a so-called'channel detection time' with a preset threshold. If the detected average power is less than the threshold, no one has occupied the channel, and if the detected average power is greater than the threshold, the channel is occupied and used by either party.

There are two methods to measure the average power during the channel detection time by the LBT-applied device.

1. Energy detection method: This method compares the average power of a signal received during the channel detection time with a threshold value, and determines that the channel is idle when it is smaller than the threshold value.

2. Wireless protocol signal detection method: This method detects signals of heterogeneous radio protocols of other devices sharing a channel. It is a method to detect the signal of heterogeneous radio protocol of other devices and to determine the channel usage status by measuring the average power of the signal of the protocol. When heterogeneous network equipment is mixed, the'wireless protocol signal detection method' that explicitly distinguishes the signals of each protocol is more effective.

First, in order to apply LBT by the wireless protocol signal detection method, the LTI system must be able to detect heterogeneous legacy system signals. However, modems (MODEM) and other devices used in the LTI system generally only support the detection function of the LTI or WCDMA signals alone and do not have a means to detect signals of heterogeneous legacy systems. Therefore, the LT system can detect the LT signal and the WCDMA radio signal, but cannot detect radio signals of heterogeneous networks such as DECT or PHS that do not belong to the 3rd Generation Partnership Project (3GPP).

Therefore, when the LTI system coexists with a heterogeneous network, an energy detection method is preferable. In the LT system, the energy detection method determines whether a signal is present by measuring Received Signal Strength Indication (RSSI) or Reference Signals Received Power (RSRP). However, it is not easy to apply the energy detection method for LBT because it is not possible to distinguish the RSSI level of the old heterogeneous equipment from the measured RSSI level.

In a conventional LTI device using an energy detection method, when the measured received signal is less than a threshold, it is not a situation that heterogeneous legacy systems coexist, so the LTI device transmits an LTV signal with a rated output power.

In a typical LTI device, if the measured received signal is from a heterogeneous legacy system and the received signal is greater than a threshold value, the transmission level of the LTI signal is limited. On the other hand, in another case, if the heterogeneous legacy system does not coexist and instead the received signal measured by another adjacent LTI base station is greater than the threshold value, the conventional LTI device is configured to measure the energy component by the neighboring heterogeneous legacy system. In this case, the transmission level of the LTI signal is limited because it is not possible to distinguish whether the other LTI is a signal from the base station. In other words, adjacent LTI base stations may not transmit the rated output due to the RSSI measurement results of each other, and as a result, there may not be a coverage overlap between the LTI base stations, so it may not be possible to configure a handover zone. .

An object of the present invention is to solve the problems raised above, when providing services at the same frequency band with the heterogeneous legacy system at the same time, while providing service priority to the heterogeneous legacy system, it is possible to minimize the impact on the service of the heterogeneous network It provides an LBT method and a mobile communication base station apparatus for performing the method.

The present invention proposes an LBT gap that stops radio signal transmission for a specific time period in all base station devices, and measures the RSSI using the LBT gap to measure the energy level of the existing heterogeneous legacy system signal existing in the corresponding frequency band. To suggest. According to this method, it is possible to increase the reliability of the LBT measurement result by excluding the influence of the radio signal power level between neighboring base stations, and to configure normal coverage between mobile communication base stations in regions where signals of heterogeneous legacy systems can be ignored.

The base station apparatus of the present invention is installed so that cell coverage overlaps with the legacy wireless telephone system and uses the same frequency band. In the LBT method of the base station apparatus of the present invention, a setting step of setting a plurality of radio reception signal measurement intervals spaced apart from each other, and when the current subframe is a subframe belonging to the measurement interval, the LBT radio transmission signal is not transmitted. Determining the radio signal transmission level based on the RSSI measured by repeatedly performing the LBT gap step for measuring the strength (RSSI) of the radio reception signal and the LBT gap step over the plurality of radio reception signal measurement intervals Steps. If the current subframe does not belong to the plurality of radio reception signal measurement intervals, the radio transmission signal is transmitted without measuring the strength (RSSI) of the radio reception signal. According to an embodiment, the base station apparatus of the present invention may set one radio reception signal measurement interval.

According to an embodiment, a plurality of listening intervals in which the setting step, the LBT gap step, and the step of determining the radio signal transmission level are performed within the LBT reference time, which is a period in which the Hyper Frame Number (HFN) cycles from 0 to 1023 1 Can be set. It is preferable to set the size of the radio reception signal measurement section shorter than the radio signal transmission period of the legacy radio telephone system.

According to an embodiment, when dividing the time in which the plurality of radio reception signal measurement intervals are arranged into a predetermined time period, it is preferable that the plurality of radio reception signal measurement intervals are located in different sections of the time period. Further, the plurality of radio reception signal measurement intervals may be arranged once every predetermined time period. Here, the predetermined time period may be a radio signal transmission period of the legacy wireless telephone system. Through this, the base station apparatus can perform the radio measurement using the radio signal transmission period of the legacy radio telephone system even if the accurate radio signal transmission time information of the legacy radio telephone system is not known.

According to another embodiment, the base station apparatus may receive the LBT Gap parameter necessary for the setting step from the management server. Accordingly, in the present invention, the setting step may further include receiving the LBT Gap parameter provided by the management server, and setting the plurality of radio reception signal measurement intervals based on the LBT Gap parameter. .

The LBT Gap parameter may include a plurality of pairs of LBT_start and LBT_duration to designate positions of the plurality of radio reception signal measurement sections. The LBT_start parameter is a 20-bits variable composed of HFN (Hyper Frame Number, 10 bits) and SFN (System Frame Number, 10 bits) and indicates the position of the system frame starting from the plurality of radio reception signal measurement sections. . The LBT_duration parameter indicates the size of the plurality of radio reception signal measurement sections as the size of the system frame SF.

The LBT Gap parameter may further include a subframe_pattern parameter to set LBT Gap to be performed on all or part of the frames designated as LBT_duration. By the subframe_pattern parameter (1) All subframes of the frame designated as the LBT_duration are included in the measurement interval, (2) ABS subframes are included in the measurement interval among all the subframes, or (3) among all the subframes An MBSFN subframe may be included in the measurement section.

According to another embodiment, the method of the present invention may include a Boot Up Gap step. The Boot Up Gap of the base station device evaluates the wireless transmission power set when the RSSI measured by performing the NMM is less than the minimum-threshold value while performing NMM (Network Monitoring Mode) between the same frequencies during the boot up process. Setting a transmission power level and finishing the boot up; And if the RSSI measured by performing the NMM is equal to or greater than the minimum-threshold value, but the LTI neighbor cell is not detected, setting the wireless transmission power to a predetermined level according to the RSSI and finishing the boot up.

Further, when the RSSI measured by performing the NMM is equal to or greater than the minimum-threshold value and the LTI neighbor cell is detected, the Boot Up Gap of the base station apparatus of the present invention completes the Boot Up but turns off the wireless signal transmission. Step, requesting a boot-up gap that stops transmitting a radio signal during a boot-up gap period to the LTC neighbor cell and measuring RSSI during the boot-up gap period, and measuring radio transmission power during the boot-up gap period. It may include setting a predetermined level according to the RSSI and turning on the wireless signal transmission. Here, the base station apparatus of the present invention can provide the LBT Gap parameter for setting the Boot Up Gap period to the neighboring cell.

The LBT method of the base station apparatus of the present invention may further include designating at least one listening completion time. In this case, the step of determining the radio signal transmission level is based on the RSSI measured through the LBT gap step when the listening completion time is reached while repeating the LBT gap step for the plurality of radio reception signal measurement sections. It is possible to determine the radio signal transmission level.

The present invention is an LTI base station apparatus installed to overlap cell coverage with a legacy radiotelephone system, and extends to the LTI base station apparatus that performs the LBT method described above.

The present invention is useful when the latest mobile communication systems such as LTI coexist in the same frequency band with heterogeneous legacy systems that cannot receive system operation information. The present invention proposes an LBT Gap that stops the transmission of radio signals from the base station by setting one or more radio reception signal measurement intervals in order to measure the strength of radio reception signals by heterogeneous legacy systems that are not mutually synchronized. Coexistence with the heterogeneous legacy system by determining the transmission power level of the radio signal of the LT system based on the LBT gap over one or more radio reception signal measurement intervals and the RSSI obtained through radio measurement. Therefore, the LTI base station apparatus of the present invention can perform radio measurement even if the radio signal transmission time information of the heterogeneous legacy system operating in the same frequency band is not known and there is no function to distinguish and measure the heterogeneous legacy system signal.

Since the wireless measurement for the LBT of the present invention uses a method of measuring by dispersing it over several periods for a very short time, it is possible to perform wireless measurement without interruption of the long-term LTI service. On the other hand, during the boot-up, regardless of the periodic gap time proposed by the present invention, wireless measurement may be performed at short intervals to rapidly boot up.

According to the present invention, since the effect of the LTI power level between neighboring LTI base station devices can be excluded, the reliability of the LBT measurement result is increased, and normal coverage between LTI base stations is provided in regions where signals of heterogeneous legacy systems can be ignored. Can be configured.

1 is a view showing an LTE system of the present invention coexisting with a heterogeneous legacy system,
Figure 2 is a flow chart provided in the description of the wireless signal measurement method using the LBT Periodic Gap of the present invention,
3 is a view for explaining a method of setting the LBT Periodic Gap of the present invention,
4 is a frame structure diagram for explaining the LBT Periodic Gap of the present invention,
Figure 5 is a flow chart provided in the description of the wireless signal measurement method using the Boot Up Gap of the present invention, and
6 is a frame structure diagram illustrating an LBT Periodic Gap according to another embodiment of the present invention.

Hereinafter, the present invention will be described in more detail with reference to the drawings.

The mobile communication system according to the present invention includes a management server and at least one base station device, and constitutes a mobile communication network in an assigned frequency band. The mobile communication system to which the present invention is applied can be any mobile communication system that transmits voice/video and data according to the 3rd Generation Partnership Project (3GPP) or 3GPP2 standard, for example, WCDMA as well as 4G LTE or 5G. B. CDMA also applies.

Referring to FIG. 1, FIG. 1 is an example including the first base station apparatus 103 and the second base station apparatus 105 adjacent to each other according to the LTI protocol. The first base station device 103 configures the first cell C1 which is an LTI network, and the neighboring second base station device 105 also configures the second cell C2 that is an LTI network, and the first cell C1 and The coverage of the second cell C2 partially overlaps each other. The first cell C1 and the second cell C2 may be macro cells, or smaller pico cells or femto cells.

In addition, the present invention is based on the premise of using HFN (Hyper Frame Number, or Hyper SFN) and System Frame Number (SFN), which are synchronized between LT systems. In the case of a time division duplexing (TDD), there is no problem, but in the case of a frequency division duplexing (FDD), time synchronization between cells must be aligned. That is, in order to realize the present invention, all LTI systems must be synchronized with each other so that radio frame boundaries and SFN values are matched, and by synchronizing time synchronization between cells, all LTI systems use the same HFN and SFN at the same time. It is assumed to be used. Here, HFN and SFN are defined according to 3GPP (3rd Generation Partnership Project) standards. According to the LTI standard, SFN is defined as 10 bits, and the range of the value is 0 to 1023. The SFN increases by 1 for every 10 ms radio frame. HFN increases by 1 when SFN is reset to 0 after 1023, and HFN also has a value between 0 and 1023 and resets to 0 after 1023. A section in which HFN cycles from 0 to 1023 is the maximum period of time synchronization of the LTI base station devices 103 and 105 of the present invention, hereinafter referred to as'LBT Standard Time'. Therefore, the'LBT reference time' has a period of approximately 2.91 hours (≒1024×1024×10 ms).

As described above, the present invention relates to a method of coexistence between a heterogeneous legacy system using the same frequency band (Legacy System) and a non-legacy system (Non-Legacy System) (eg, an LTI system). For example, as illustrated in FIG. 1, it is assumed that the first cell C1 in which the first base station device 103 is planning or operating and the legacy cell LC in which the legacy base station device 10 is operating overlap or partially overlap. do. Although the legacy base station apparatus 10 may be operating the legacy cell LC before the first base station apparatus 103, the first base station apparatus 103 may be applied even when the legacy base station apparatus 10 is operating before the legacy base station apparatus 10. . The coverage of the legacy cell L-C may partially overlap with the second cell C2. Here, the legacy base station apparatus 10 uses the same frequency band as the first cell C1 of the first base station apparatus 103 installed in an area where coverage overlaps, but uses a different radio protocol from the first base station apparatus 103. By doing so, it is a device that cannot receive mutually operational information including status information. For example, DECT (Digital Enhanced Cordless Telecommunications) or PHS (Personal Handy-phone System). DECT stands for Digital European Cordless Telecommunications, and PHS is also called'Personal Access System (PAS)'.

The present invention uses the'energy detection method' among the methods for LBT with a heterogeneous legacy system, but in order to solve the problem that the signal of the LTI cell and the signal of the heterogeneous legacy system cannot be distinguished, the radio signal of the LTI radio signal for a certain period of time is used. We propose'LBT Gap', a wireless reception signal measurement section to stop transmission. The first base station apparatus 103 and the second base station apparatus 105 of the present invention stop the transmission of the radio signal during the radio reception signal measurement interval (LBT Gap) and measure the RSSI, thereby measuring legacy system signals existing in the corresponding frequency band Perform LBT to measure only the energy level. At this time, it is desirable to measure the RSSI at the same frequency and bandwidth as the corresponding legacy device. When a radio reception signal measurement period of a relatively long period is required, the measurement period is divided into a plurality of radio reception signal periods, which are relatively short and spaced apart, so that the transmission time of the radio signal transmission is not stopped. Hereinafter, the LBT performing procedure of the first base station apparatus 103 will be mainly described, and the operation of the neighboring second base station apparatus 105 will be described only when necessary.

The management server 101 sets the'LBT Gap parameter' that designates at least one radio reception signal measurement interval in the first base station apparatus 103 described below and provides it to the first base station apparatus 103. Here, the'LBT Gap parameter' is shown in Table 1 below.

{LBT_start, LBT_duration}[n] -LBT_start: It is a 20bits variable composed of HFN and SFN and specifies when LBT Gap starts.
-LBT_duration: Length of LBT gap section to stop radio signal transmission and perform RSSI measurement
-Specify n LBT_start and LBT_duration pairs repetition_count -Infinity: Periodic Gap
-Once: Boot Up Gap subframe_pattern -full: All subframes of LBT_duration frame are used for LBT Gap
-eICIC: ABS subframe is used for LBT Gap among LBT_duration frames
-eMBMS: MBSFN subframe among LBT_duration frames is used for LBT Gap T _LC [m] -It is a 20-bits variable composed of HFN and SFN and displays the time at which all dispersion measurements corresponding to one cycle of a heterogeneous legacy system are completed (Listen Completion, listening completion time).
-The LTI base station device coexisting with the heterogeneous legacy system may recalculate the power level for transmitting the LTI signal based on the RSSI measured during the LBT gap up to this time. May contain m within the LBT reference time period.
-If repetition_count is Once, it can be omitted.

(1) The LBT_start and LBT_duration parameters are used to set the start time of the LBT Gap performing the LBT operation and the length of the measurement section (i.e., the LBT Gap section).Total n (0<n is a natural number) pairs Can be specified.

LBT_start and LBT_duration parameters apply to both Periodic Gap and Boot Up Gap described below. In the case of a periodic gap, one (n=1) radio reception signal measurement interval may be set, or a plurality of (n>1) radio reception signal measurement intervals may be set apart from each other. In the case of setting a plurality, a plurality of (n>1) LBT_start and LBT_duration parameter pairs are set within the LBT reference time to designate a plurality of radio reception signal measurement intervals (ie, LBT Gap). 3 and 4 are examples in which six (n=6) LBT start times and radio reception signal measurement intervals are set.

The LBT_start parameter means a position at which the LBT gap starts, and is indicated as a specific time on the LBT reference time.

LBT_duration is for designating the length of the radio reception signal measurement section, and indicates the length of a section in which the LT transmission signal Tx is turned off to perform RSSI measurement. For example, LBT_duration can be defined as the number of frames per 10ms. According to another embodiment, LBT_duration may be indicated as a specific time on the LBT reference time indicating the location at which the LBT Gap ends (that is, the location where the radio reception signal measurement section ends).

Since the LBT_start and LBT_duration parameters are only one of various methods for specifying the location of the LBT gap within the LBT reference time, any parameter that can specify the location of the LBT gap within the LBT reference time can be applied. For example, instead of the LBT_duration parameter, the LBT_end parameter that the LBT Gap ends may be designated. Also, instead of the LBT_start parameter, the duration (Duration) of the intervals between LBT gaps may be specified.

(2) repetition_count determines whether the radio reception signal measurement process is repetitive according to the periodic gap or a one-time measure according to the boot up gap. When setting the repetitive measurement according to the periodic gap, set the'repetition_count' parameter to'Infinity', and when setting the measurement according to the boot up gap, set the'repetition_count' parameter to'Once'. When the'repetition_count' parameter is set to'Infinity', the LBT Gap operation is continuously performed with the same n LBT_start parameters and LBT_duration parameter pairs in the next cycle in which the LBT reference time is initialized and restarted.

(3) The subframe_pattern parameter designates the operation method of the LBT Gap during LBT_duration. If set to'Full', all subframes during LBT_duration are used for the LBT Gap. When the subframe_pattern parameter is set to'eICIC', the ABS subframe is used for the LBT Gap among the frames that are LBT_duration, and when set to'eMBMS', the MBSFN subframe is used for the LBT gap from the frames that are LBT_duration. Here, eICIC (enhanced Inter-Cell Interference Coordination) is an interference control technology defined in 3GPP release 10, and is an improvement of the ICIC technology defined in 3GPP release 8 for HetNet environment. ABS (Almost Blank Subframe) is defined in eICIC. eMBMS (enhanced Multimedia Broadcast Multicast Service) is a multiple simultaneous video transmission technology defined in 3GPP release 13.

(4) T _LC denotes'listening completion time', which is the time when the dispersion measurement (or measurement) of 1 cycle for the heterogeneous legacy system is completed. The section between the previous T _LC (or the time at which the LBT reference time is reset) and the current T _LC becomes a'listening section'. The first base station apparatus 103 determines the output level of the LTI using the measured value in at least one LBT Gap set during the listening period. T _LC can designate m (0<m is a natural number), and means that there is m listening time during the LBT reference time.

The T _LC parameter may not be set when the repetition_count parameter is Once (eg, during Boot Up Gap). When the T _LC parameter is omitted, the first base station apparatus 103 determines that variance measurement is completed when measurement for all sections in which the LBT Gap is set is performed, and then performs an operation.

On the other hand, when the Boot Up Gap is set using the'LBT Gap parameter', the'LBT Gap parameter' may be provided to the base station device in the form of an X2 message through an X2 connection.

Radio Signal Measurement Using LBT Periodic Gap

Since there is no connection between the first base station apparatus 103 and the legacy base station apparatus 10 operating the LTI network, the first base station apparatus 103 transmits radio time information or synchronization information from the legacy base station apparatus 10. Can not be provided. Therefore, the management server 101 or the first base station apparatus 103 cannot know when the legacy base station apparatus 10 performs wireless transmission. However, the LTI network manager can know an approximate transmission period (for example, 600ms) based on fragmentary information about a heterogeneous legacy system. When the radio transmission period of the legacy base station apparatus 10 is long, the first base station apparatus 103 cannot measure the radio reception signal over the entire period of the radio transmission period of the legacy base station apparatus 10.

Therefore, in the present invention, when the radio transmission period of the legacy base station apparatus 10 is short, one radio reception signal measurement interval is arranged, and when the radio transmission period is long, a plurality of radio reception signal measurement intervals of relatively short time are mutually spaced apart. A method for dispersing the radio signal measurement over multiple times is proposed.

As described above, at least one radio reception signal measurement interval is set with LBT_start and LBT_duration parameters, and individual radio reception signal measurement intervals (LBT_duration) need not be the same. In addition, by specifying multiple LBT_start and LBT_duration parameter pairs and T _LCs , the'dispersion measurement' of the present invention may be repeated several times within the LBT reference time (approximately 2.9 hours).

On the other hand, when a plurality of radio reception signal measurement intervals are set, the plurality of radio reception signal measurement intervals may be arranged at different locations within a preset new time period. In this way, it is desirable to set the radio measurement to be performed throughout the time period, although it is a distributed radio measurement. Here, the time period may correspond to, for example, a radio transmission period of the legacy base station apparatus 10, and thus, even if there is no information on the radio signal transmission time of the legacy base station apparatus 10, the legacy base station apparatus 10 transmits the time period. RSSI for wireless signals can be measured.

In the example of FIG. 3, when it is assumed that the radio signal transmission period of the legacy base station apparatus 10 is 600 ms and the radio reception signal measurement interval is repeated 6 times, the listening completion time (T _LC ) is 360 (3,600 ms) or It can be set to 310 (3,100 ms) and 6 wireless reception signal measurement intervals (LBT Gap) can be set in the listening section. FIG. 3 shows that six radio reception signal measurement intervals are arranged at different locations within the radio signal transmission period of the legacy base station apparatus 10. Based on FIG. 3, the offset and the radio reception signal measurement interval are set as shown in Table 2 below.

No LBT starting point
(LBT_start) Wireless reception signal measurement section
(LBT_duration) 0 500 ms (50) 100 ms (10) One 1000 ms (100) 100 ms (10) 2 1500 ms (150) 100 ms (10) 3 2000 ms (200) 100 ms (10) 4 2500 ms (250) 100 ms (10) 5 3000 ms (300) 100 ms (10)

The radio measurement schedule by the timing design of Table 2 is shown in FIG. 4. The first base station apparatus 103 distributes 600 ms, which is a radio signal transmission period of the legacy base station apparatus 10, into six sections to perform RSSI measurement in the LBT gap section. The RSSI measurement in the first base station device 103 is preferably measured with the same frequency and bandwidth as the legacy device 10. If six measurements are made during the first listening completion time (T _LC [0]), the measurement of the entire period of 600 ms, which is a radio signal transmission period of the legacy base station apparatus 10, is completed.

Hereinafter, a method of measuring a radio signal using the LBT Periodic Gap in the first base station apparatus 103 will be described with reference to FIGS. 2 to 4.

<LBT Gap and listening section setting; S201>

The first base station apparatus 103 arranges at least one radio reception signal measurement interval within the LBT reference time, and sets a listening interval for determining the RSSI of the heterogeneous legacy system. Here, the first base station apparatus 103 may set one listening period or a plurality of listening periods within the LBT reference time.

The wireless reception signal measurement section of the first base station apparatus 103 can be set in various ways, but it is simple and preferable to use the'LBT Gap parameter' provided by the management server 101. The'repetition_count' parameter of the LBT Gap parameter provided by the management server 101 is set to'Infinity'.

<LBT Gap subframe determination: S203>

As described above, the first base station device 103 is in a state in which HFN and SFN are synchronized with other base station devices in the LTI network regardless of whether it is a TDD method or an FDD method. The first base station apparatus 103 determines whether the current subframe is a subframe to perform LBT Gap.

In the example of FIG. 4, the LBT reference time is repeated at 1024×1024×10 ms intervals. The first base station apparatus 103 determines whether the current frame belongs to the LBT gap section by using LBT_start and LBT_duration of the LBT gap parameter, and if the LBT gap is the current subframe, the LBT gap must be performed according to the subframe_pattern setting. It is determined whether it is a subframe to be performed.

<If not the LBT Gap subframe: S205>

If the current subframe is not a subframe to perform the LBT Gap, the first base station apparatus 103 performs the normal LTI wireless communication service as it is, and does not perform radio reception signal measurement. If the current sub-frame is not a sub-frame to perform the LBT Gap, the power amplifier of the first base station apparatus 103 for radio signal transmission is kept on.

In the example of FIG. 3 and Table 2, since the new LBT reference time starts and the subframe before the time point designated as LBT_start[0] is not a subframe to perform the LBT Gap, the first base station apparatus 103 is an LTI The Tx signal is kept on. Wireless measurements are not performed.

<For LBT Gap subframe: S207, S209>

When the current subframe is identified as a subframe to perform the LBT Gap, the first base station apparatus 103 performs the LBT Gap to perform radio measurement. For the LBT Gap, the first base station apparatus 103 stops transmitting the LTI signal (S207) and measures and stores the strength (RSSI) of the received signal (S209). The RSSI measurement in the first base station device 103 is preferably measured with the same frequency and bandwidth as the legacy device 10.

<Judging whether to end the listening section: S211>

Measurement of the received signal according to the LBT gap of the first base station apparatus 103 is performed at least once during the listening section. As described above, in order to increase the possibility of measuring the radio signal of the heterogeneous legacy base station apparatus 10, it is preferable to set the listening section to a time corresponding to several times the radio signal transmission period of the legacy base station apparatus 10. As in the example of FIG. 3, when the legacy base station apparatus 10 transmits a radio signal in units of, for example, 600 ms, the listening section may be set to a value corresponding to approximately 3,600 ms.

The first base station apparatus 103 may determine whether the listening period has ended by determining whether the current time has reached the listening completion time (T _LC ). If the listening completion time (T _LC ) has not yet been reached, radio measurement is performed only in a part of the radio signal transmission period of the legacy base station apparatus 10, and steps S203 to S211 are performed until the listening completion time (T _LC ) is reached. Repeat.

<Measurement of electric power level upon reaching listening completion time (T _LC ): S213, S215>

When the listening completion time (T _LC ) is reached, the first base station apparatus 103 calculates the energy detection value of the heterogeneous legacy system signal using at least one RSSI measurement value measured during the listening period, and records the RSSI measurement value. Compare with the set threshold. The comparison can be performed in various ways. For example, the highest value among RSSIs measured while repeating steps S203 to S209 may be compared with a threshold, or an average of these may be used (S213).

The first base station apparatus 103 adjusts the transmission power level of the radio signal based on the comparison result (S215).

By performing step S215, the first base station apparatus 103 ends radio measurement for one listening section and returns to step S203. If a plurality of listening periods are set within the LBT reference time, the first base station apparatus 103 may start a new listening period in step S203.

In the example of FIG. 6, a plurality of (m=4) T _LC parameters are set, so that a plurality of (n=28) radio reception signal measurement intervals set within the LBT reference time are divided into a plurality of listening intervals. The first base station apparatus 103 of FIG. 6 starts a new listening section after reaching the listening completion time T _LC [0] and repeats radio measurement until the next listening completion time T _LC [1] is reached.

In the manner described above, the first base station apparatus 103 of the present invention can perform the LBT operation required to coexist with the legacy base station apparatus 10.

Request LT Gap operation at initial startup (Boot up Gap operation)

If the first base station apparatus 103 is newly booted up, when using the method of FIG. 2, the boot up process is delayed while the transmission level of the radio signal is not determined for at least the listening completion time (T _LC ). Accordingly, the first base station apparatus 103 of the present invention performs a boot up gap that detects a heterogeneous legacy system signal by applying an LBT gap in a relatively short time in place of the LBT periodic gap of FIG. 2 when newly booting up. can do.

Hereinafter, the LBT operation according to the Boot Up Gap of the first base station apparatus 103 of the present invention will be described with reference to FIG. 5.

<NMM performance between the same frequencies: S501>

When the first base station apparatus 103 enters the boot up process, it performs a network monitoring mode (NMM) between intra-frequency to measure RSSI of an operating frequency band. NMM is a function that measures the RSSI of the received signal, analyzes the signal, extracts necessary information, and composes a neighbor cell list. The NMM should be performed at least during the radio transmission period of the legacy device, and it is desirable to measure the RSSI with the same frequency and bandwidth as the legacy device.

<Compare RSSI with minimum-threshold: S503>

The first base station apparatus 103 compares the RSSI measured as a result of performing the NMM with the'minimum-threshold value'. Here, the'minimum-threshold' is a reference value that can be determined that a heterogeneous legacy system signal does not exist.

<When RSSI is below the minimum-threshold: S505, S507, S509>

If the RSSI is determined to be less than (or less than) the minimum-threshold value, the heterogeneous legacy system signal is regarded as non-existent, and the first base station apparatus 103 sets the TTL transmission signal to the rated output level (S505), The Boot Up process continues to finish (S507), and the LT signal transmission power is turned on (S509).

<When RSSI is above the minimum-threshold value and no other neighboring EL cells are detected: S511, S513>

If it is determined in step S503 that the RSSI is equal to or greater than the minimum-threshold value, the first base station apparatus 103 determines whether another neighbor LTI cell is detected based on the result of performing the NMM (S511).

If no other neighboring LTC cell is detected, the first base station apparatus 103 adjusts the LTI signal output level based on the RSSI measurement (S513). Thereafter, the first base station apparatus 103 enters steps S507 and S509 to continue the Boot Up process to finish and turns on the power of transmitting the LTI signal.

<When RSSI is above the minimum-threshold value and other neighboring EL cells are detected: S515 to S521>

If the RSSI is greater than the minimum-threshold value in step S511 and other neighboring EL cells are also detected, the first base station apparatus 103 continues by finishing the Boot Up process (S515), but turns off the wireless transmission power (Off). It starts in a state (S517).

Thereafter, the first base station apparatus 103 is directly connected to the neighbor base station apparatus 105 to request an LBT Gap. If the first base station apparatus 103 and the neighbor base station apparatus 105 follow the LTI protocol, the LBT Gap information is transmitted through the X2 connection to request the LBT Gap.

In the present invention, the LBT gap at this time is called a boot up gap. In order to request a Boot Up Gap, an Information Element (IE) can be added to an X2 message or an existing IE extension field can be used. The neighbor base station device 105 receiving the Boot Up Gap request with the X2 message performs a Boot Up Gap operation according to the LBT Gap parameter received with the X2 message. In this case, the LBT Gap parameter format of Table 1 may be used to set the start point and signal measurement section for the Boot Up Gap operation in the second base station apparatus 105.

The neighboring base station apparatus 105 turns off the LT transmission during the set Boot Up Gap. The newly started first base station device 103 performs RSSI measurement according to the set Boot Up Gap (S519). The RSSI measurement in the first base station device 103 is preferably measured with the same frequency and bandwidth as the legacy device 10.

After the RSSI measurement according to the Boot Up Gap is finished, the newly started first base station device 103 uses the RSSI measurement result as an energy detection value of a heterogeneous legacy system signal, and transmits the energy measurement value by comparing it with a threshold value. The power level is set (S521).

The first base station apparatus 103 enters step S509 to turn on the transmission power of the LTI signal. The LBT operation according to the characteristic Boot Up Gap of the present invention is performed by the above method.

Although the preferred embodiments of the present invention have been illustrated and described above, the present invention is not limited to the specific embodiments described above, and it is usually in the technical field to which the present invention pertains without departing from the gist of the present invention claimed in the claims. It is of course possible to perform various modifications by a person having knowledge of, and these modifications should not be individually understood from the technical idea or prospect of the present invention.

Claims (24)

In the LBT method of a mobile communication base station apparatus installed so that cell coverage overlaps with a legacy wireless telephone system using the same frequency band,
When the current sub-frame is included in the predetermined radio reception signal measurement interval, the LBT gap step of measuring the strength (RSSI) of the radio reception signal without transmitting the radio transmission signal. The radio reception signal measurement section is a plurality of spaced apart from each other is distributed; And
The legacy wireless telephone system signal is detected by comparing the RSSI measured by performing the LBT gap step for each of the plurality of wireless reception signal measurement intervals with a predetermined threshold value, and transmitting a radio signal according to whether the legacy wireless telephone system signal is detected. And determining a level.
According to claim 1,
And transmitting a radio transmission signal without measuring the strength (RSSI) of the radio reception signal when the current sub-frame does not belong to the plurality of radio reception signal measurement intervals.
According to claim 1,
When the time period in which the plurality of radio reception signal measurement intervals are arranged is divided into a predetermined time period, the plurality of radio reception signal measurement intervals are located in different sections of the time period, the LBT method of the base station apparatus.
According to claim 3,
The predetermined time period is the LBT method of the base station apparatus, characterized in that the radio signal transmission period of the legacy wireless telephone system.
According to claim 3,
The LBT method of the base station apparatus, wherein the plurality of radio reception signal measurement intervals are arranged once every predetermined time period.
The method of claim 5,
The predetermined time period is the LBT method of the base station apparatus, characterized in that the radio signal transmission period of the legacy wireless telephone system.
The method of claim 1
The LBT method of a base station apparatus, characterized in that the step of determining the LBT gap step and the radio signal transmission level is repeated a plurality of times within an LBT reference time that is a period in which a Hyper Frame Number (HFN) cycles from 0 to 1023 1.
The method of claim 1
The size of the radio reception signal measurement section is shorter than the radio signal transmission period of the legacy radiotelephone system LBT method of the base station apparatus.
According to claim 1,
Receiving an LBT gap parameter provided by the management server; And
And before the LBT gap step, setting the plurality of radio reception signal measurement intervals based on the LBT gap parameter.
The method of claim 9,
The LBT gap parameter,
LBT_start indicating a position of a system frame starting from a plurality of radio reception signal measurement sections as a 20-bit variable composed of a Hyper Frame Number (HFN) and a System Frame Number (SFN) of 10 bits;
LBT of the base station apparatus comprising the plurality of pairs of LBT_duration indicating the size of the plurality of radio reception signal measurement sections as the size of a system frame (SF), and designating the positions of the plurality of radio reception signal measurement sections Way.
The method of claim 10,
The LBT gap parameter,
The subframe_pattern parameter including all subframes of the frame designated as LBT_duration in the measurement interval, ABS subframe among all the subframes in the measurement interval, or MBSFN subframe among all the subframes in the measurement interval further By including,
LBT method of the base station apparatus, characterized in that to set to perform the LBT gap for all or part of the frame designated by the LBT_duration.
According to claim 1,
Performing NMM (Network Monitoring Mode) between the same frequencies during the boot-up process;
Setting the wireless transmission power set to a rated transmission power level when the RSSI measured by performing the NMM is less than a minimum-threshold value and finishing the boot up; And
When the RSSI measured by performing the NMM is greater than or equal to a minimum-threshold value, but a neighbor cell is not detected, further comprising setting the wireless transmission power to a predetermined level in accordance with the RSSI and finishing the boot up. LBT method of a base station apparatus characterized by.
The method of claim 12,
When the RSSI measured by performing the NMM is equal to or greater than a minimum-threshold value and the neighboring cell is detected,
Finishing the boot up but turning off wireless signal transmission;
Requesting a boot up gap to stop transmitting a radio signal during a boot up gap period to the neighboring cell, and measuring an RSSI during the boot up gap period;
And setting the radio transmission power to a predetermined level in accordance with the RSSI measured during the Boot Up gap period and turning on the radio signal transmission.
The method of claim 13,
And providing an LBT gap parameter for setting the Boot Up gap period to the neighboring cell.
According to claim 1,
Further comprising the step of designating at least one listening completion time,
Determining the radio signal transmission level,
When the listening completion time is reached while repeating the LBT gap step for the plurality of radio reception signal measurement intervals, the radio signal transmission level is determined based on the RSSI measured through the LBT gap step. LBT method.
delete delete delete delete delete delete delete delete A base station apparatus installed to overlap cell coverage with a legacy radiotelephone system, wherein the LBT base station apparatus performs the LBT method of any one of claims 1 to 15.

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