KR20120013061A - Method and apparatus for wireless repeaters in cellular mobile communication system - Google Patents

Abstract

PURPOSE: A wireless relay device and a method thereof are provided to prevent changes of a frequency channel and timing from simultaneously occurring in a mobile station. CONSTITUTION: A receiving signal selecting unit(620) selects a frequency channel signal among signals inputted through a receiving antenna. A transmission signal converting unit(630) converts the selected frequency channel signal into a frequency channel signal to be transmitted through a transmitting antenna. A relay device controller(650) selects a frequency channel to be used by the transmission signal converting unit and the receiving signal selecting unit. The relay device controller controls a relay device setup parameter. The relay unit controller controls the operation of the relay device.

Description

Wireless relay device and method {METHOD AND APPARATUS FOR WIRELESS REPEATERS IN CELLULAR MOBILE COMMUNICATION SYSTEM}

The present invention relates to a wireless relay apparatus and method in a wireless communication system, and more particularly, to a handover procedure using the wireless relay apparatus and method.

In a cellular mobile communication system, a handover procedure of a mobile station is frequently generated, and many technical reviews have been made to prevent a call disconnection due to a failure of a handover procedure occurring during a call. In particular, cellular mobile communication systems (eg, cdma2000 or WCDMA) employing CDMA technology in 2G or 3G mobile communication systems have minimized call disconnection between base stations through soft handover technology. . However, the soft handover technique is also not applicable when another frequency channel is used in a neighboring base station. In this case, an inter-frequency hard handover procedure is adopted.

In the soft handover procedure, the mobile station maintains a radio link with a plurality of base stations, so that the mobile station can smoothly conduct a call even when the radio link with one base station is unstable. Since only one radio link can be selected by the mobile station, the probability of call disconnection increases when the radio link with the selected base station is unstable.

According to the present invention, in configuring a wireless relay device at a boundary area between base stations in a cellular mobile communication system, the mobile station preferentially performs an intra-base frequency hard handover procedure within the same base station, and then includes an adjacent base station in a call base station. The present invention provides a method and apparatus for significantly reducing the possibility of frequency hard handover failure by configuring a wireless relay apparatus such that a soft handover is performed so that a change in frequency channel and a change in timing do not occur at the same time in the mobile station.

In addition, the present invention provides a method for easily changing the configuration of the relay device using the neighbor base station information in configuring the wireless relay device in the cellular mobile communication system.

In addition, the present invention provides a method for adjusting base station parameters of a cellular mobile communication system using information on a configured relay device.

In an exemplary embodiment of the present invention, a wireless relay apparatus includes a reception signal selector for selecting a frequency channel signal from a signal input through a reception antenna, and a transmission signal for converting the selected frequency channel signal into a frequency channel signal to be transmitted through a transmission antenna. And a relay device controller for selecting a frequency channel to be used by the reception signal selector and the transmission signal converter, controlling a relay device setting parameter, and controlling an operation of the relay device.

Also, the reception signal selector may select a frequency channel signal not used in the second base station from among frequency channels used in the first base station.

The transmission signal converter may convert the selected frequency channel signal into a frequency channel signal commonly used by the first base station and the second base station.

In addition, the relay device controller classifies frequency channels used only in a first base station as a primary base station and a second base station as a secondary base station, and frequency channels used only in a second base station as a secondary base station as a primary base station. The first base station may be classified as a secondary base station, and a frequency channel commonly used by the first base station and the second base station may classify the first base station and the second base station as the primary base station.

In addition, the relay device controller may select the frequency channels used only in the first base station as the reception frequency channel, and select the frequency channels commonly used in the first base station and the second base station as the transmission frequency channel.

In addition, the wireless relay device according to another embodiment of the present invention receives the system information of the base station through at least one frequency channel signal used in the base station around the wireless relay device, the reception for obtaining the relay device configuration parameters The antenna may further include an information processor and an antenna connected to the reception information processor.

In addition, the antenna connected to the receiving information processor may be used differently from the receiving antenna of the wireless relay device.

In addition, the reception information processing unit received through at least one frequency channel transmitted from at least one base station located around the wireless relay device, all base stations and frequency channels around the wireless relay device that can be measured and measured The base station associated with the wireless relay device and the frequency channel list to be used by the wireless relay device may be determined based on the received signal level or the quality information of.

In addition, the reception information processing unit measures the signal level or the quality of the adjacent base station and the frequency channels based on the frequency channel information of the received signal and the transmission signal selected by the wireless relay device to determine the parameters required by the wireless relay device. It can be adjusted adaptively.

In addition, the wireless relay apparatus may receive a downlink signal from a base station and transmit a downlink signal, and the uplink signal may not receive and transmit the uplink signal.

In a wireless relay method according to an embodiment of the present invention, selecting a frequency channel signal from a signal input through a receiving antenna, converting the selected frequency channel signal into a frequency channel signal to be transmitted through a transmission antenna and the frequency channel Selecting a frequency channel to be used in selecting a signal and converting the selected frequency channel signal, controlling a setting parameter used in a wireless relay, and controlling an operation of the wireless relay.

According to the present invention, in configuring a wireless relay device at a boundary area between base stations in a cellular mobile communication system, the mobile station preferentially performs an intra-base frequency hard handover procedure within the same base station, and then includes an adjacent base station in a call base station. It is possible to provide a method and apparatus for significantly reducing the likelihood of a frequency hard handover failure by configuring a wireless relay apparatus such that a change in frequency channel and a change in timing do not occur at the same time by performing a soft handover.

In addition, the present invention, when configuring a wireless relay device in a cellular mobile communication system, by internally using the system information of the neighboring base station and the measurement result of the frequency channel signal, it is possible to easily change the configuration of the wireless relay device, changes in the wireless environment In addition, it is possible to provide a method and apparatus for maximizing the efficiency of wireless relay device maintenance and network performance by deriving and reflecting optimized parameters on its own.

1 is a diagram illustrating a frequency hard handover operation between base stations in a cellular mobile communication system without a conventional wireless relay device.
FIG. 2 is a diagram illustrating a reception signal level according to a movement trajectory of a mobile station in FIG. 1.
3 is a diagram illustrating a frequency hard handover operation between base stations in a cellular mobile communication system including a conventional wireless relay device.
FIG. 4 is a diagram illustrating a reception signal level according to the movement trajectory of the mobile station in FIG. 3.
5 is a diagram illustrating a trajectory of a mobile station in a cellular mobile communication system including a wireless relay device according to an embodiment of the present invention.
6 is a block diagram of a wireless relay apparatus according to an embodiment of the present invention.
FIG. 7 is a diagram illustrating a received signal level according to the movement trajectory of the mobile station in FIG. 5.
8 is a diagram illustrating an example in which a relay device controller classifies a frequency channel in a wireless relay device according to an embodiment of the present invention.
9 is a diagram illustrating another example in which a relay device controller classifies a frequency channel in a wireless relay device according to an embodiment of the present invention.
10 is a block diagram of a relay apparatus for internally acquiring a parameter in a wireless relay apparatus according to an embodiment of the present invention.

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

1 is a diagram illustrating a frequency hard handover operation between base stations in a cellular mobile communication system without a conventional wireless relay device. FIG. 2 is a diagram illustrating the reception signal level according to the movement trajectory of the mobile station in FIG. 1. Hereinafter, a conventional inter-frequency hard handover procedure of a mobile station will be described with reference to FIGS. 1 and 2.

The first base station area 10 is a radio area by the first base station 11, and uses four frequency channels FA1, FA2, FA3 and FA4, and the adjacent second base station area 20 is the second base station. As the radio area by (12), it is assumed that two frequency channels FA1 and FA2 are used. It is assumed that mobile station 30 performs a call using frequency channel FA3 at first base station 11.

The mobile station 30 is conducting a call in the first base station area 10 at the time point ①. At this time, the mobile station 30 may exceed the threshold TH2 as well as the frequency channel signal FA3, which is already in talk, as well as the remaining frequency channel signals FA1, FA2, and FA4 included in the first base station region 10. have. Thus, the mobile station 30 acquires synchronization for each frequency channel signal and evaluates the signal level (or quality).

The mobile station 30 moves to an area where the first base station area 10 and the second base station area 20 overlap at a time point ②. Referring to FIG. 2, the frequency channel FA1 signal of the second base station 12 exceeds the threshold value TH2 at a time point ②. Thus, the mobile station 30 obtains synchronization of the signal of the second base station 12 and evaluates the signal level (or quality). Of course, the frequency channel FA2 signal of the second base station 12 may exceed the threshold value TH2 at the time point ②, but for the sake of simplicity, the signal exceeding the threshold value TH2 in the following description is referred to as the second base station ( It is limited to the frequency channel FA1 signal of 12) only.

Here, the signal level (or quality) may use various values, and in the 3GPP UMTS system, CPICH_Ec / Io or RSCP (Received Signal Code Power) may be used. The following description is based on Received Signal Code Power (RSCP) used in 3GPP UMTS.

Thereafter, the mobile station 13 enters the second base station area 20 after passing through the first base station area 10. At this time, the signal level (or quality) received by the mobile station 30 is a level DS1 of the second base station 12 frequency channel FA1 signal is more constant than the signal of the first base station 11 frequency channel FA3 as shown in FIG. ) Will be exceeded. The mobile station 30 reports the result of exceeding the predetermined level to the first base station 11 (corresponding to Event 2A in 3GPP UMTS) to request inter-base station hard handover.

Here, for the sake of simplicity, it is highly likely that the signals of the frequency channels FA1 and FA2 used by the second base station 12 satisfy the conditions, but only the frequency channel FA1 signals will be described.

In response to the inter-base station handover request received from the mobile station 30, the network determines the inter-base station frequency hard handover and instructs the mobile station 30 the inter-base station hard handover command to the frequency channel FA1 of the second base station 12. To provide. The mobile station 30 receiving the hard handover command performs frequency hard handover between base stations by disconnecting the FA3 radio link of the first base station 11 and attempting to connect the FA1 radio link of the second base station 12. . At this time, the mobile station 30 temporarily loses the radio link. Even if the disconnection time is maintained for a long time or a new radio link is established with the second base station 12 frequency channel FA1, the radio link quality is poor and the call continues. If a situation occurs that fails, the frequency hard handover procedure between base stations fails.

The reason for failing the inter-base station hard handover procedure is (1) because the timing of the first base station 11 and the second base station 12 is not synchronized, the time required for setting a new time is increased. The frequency hard handover failure between base stations may occur, and (2) the frequency channel FA3 of the first base station 11 and the frequency channel FA1 of the second base station 12 are different so that the mobile station 30 may perform a frequency shift. In this case, the frequency hard handover procedure between base stations may fail due to insufficient quality of a newly established radio link within a limited time.

In the cdma2000 method of 3GPP2 using the base station synchronization method, the timing difference between base stations has a constant offset, while in the WCDMA method of 3GPP using the base station asynchronous method, the timing difference between base stations may be an arbitrary value. Therefore, the frequency hard handover failure between base stations may be more severe in the WCDMA scheme. Since the frequency hard handover failure between base stations is a phenomenon of call disconnection during a call, which has a fatal effect on communication quality, various technical approaches have been attempted to successfully perform frequency hard handover between base stations.

As a method for successfully performing frequency hard handover between base stations, there is a method of installing a relay device in an overlapping area of a base station area. That is, by providing a radio relay apparatus for retransmitting a specific base station signal in the overlapping area of two adjacent base stations to maintain a stable radio link between the base station and the mobile station.

3 is a diagram illustrating a frequency hard handover operation between base stations in a cellular mobile communication system including a conventional wireless relay device. 4 is a diagram illustrating a reception signal level according to the movement trajectory of the mobile station in FIG.

Hereinafter, a frequency hard handover operation between base stations of a mobile station in a cellular mobile communication system including a conventional wireless relay device will be described in detail with reference to FIGS. 3 and 4. It is assumed that the conditions of the frequency channel and the mobile station used by the base station are the same as those of FIGS. 1 and 2.

In a cellular mobile communication system including a conventional wireless relay device, a method for reducing a frequency hard handover failure probability between base stations of a mobile station uses a wireless relay device. The wireless relay device is located in an overlapping area between base stations and is used by the second base station 121 among the frequency channels FA1, FA2, FA3, and FA4 used by the first base station 111. Frequency channel FA3 and FA4 signals excluding) are received from the first base station 111 and retransmitted to the second base station area 120. Here, the transmission power of the wireless relay device is determined in consideration of the geographical influence.

Referring to FIG. 4, the mobile station 140 acquires signal synchronization with respect to the frequency signals FA1, FA2, and FA4 in the first base station region 110 and evaluates the signal level (or quality) at the time point ①. If, at the time point ②, the mobile station 140 acquires synchronization of the second base station 121 signal when the second base station 121 frequency channel FA1 signal exceeds the threshold value TH2, the mobile station 140 evaluates the signal level (or quality). The operation is similar to FIG.

On the other hand, referring to FIGS. 3 and 4, the mobile station 140 is also included in the first repeater region 130 at the time point ②. Accordingly, the frequency channel FA3 signal level (or quality) received by the mobile station 140 is represented as an accumulated value of the signal received from the first base station 111 and the signal received from the first repeater 131. In fact, since the mobile station 140 cannot confirm whether or not the wireless relay device is installed, the mobile station 140 cannot distinguish between the signal received from the first base station 111 and the signal received from the first repeater 131 to remove the accumulated signal level. 1 Determined by the base station 111 frequency channel FA3 signal.

At time point ③, the mobile station 140 enters the second base station area 120 after passing through the first base station area 110 and the first repeater area 130. At this time, the signal level (or quality) received by the mobile station 140 is the second base station 121 frequency channel FA1 signal level (or quality) as shown in Figure 4 is the first base station 111 frequency channel FA3 and the first The repeater 131 does not exceed a predetermined level DS1 than the accumulated signal of the frequency channel FA3. Accordingly, the mobile station 140 does not make an inter-base station frequency hard handover request from the frequency channel FA3 to the frequency channel FA1 of the second base station 121.

The signal level received by the mobile station 140 at a time point ④ exceeds a predetermined level DS1 than the signal of the first base station 111 frequency channel FA3 in which the second base station 121 frequency channel FA1 signal is accumulated. The mobile station 140 reports the result of exceeding the predetermined level to the first base station 111 to request the frequency hard handover between the base stations. In response to the inter-base station handover request received from the mobile station 140, the network determines the inter-frequency handover and provides the inter-frequency handover command to the frequency channel FA1 of the second base station 121 to the mobile station 140. The mobile station 140 receiving the handover command attempts an inter-frequency handover by disconnecting the FA3 radio link of the first base station 111 and attempting to connect the FA1 radio link of the second base station 121.

If the wireless relay device is configured in the overlapping area of the base station area to reduce the probability of handover failure between frequencies, the time point for the handover between the frequencies is delayed compared to the case where there is no wireless relay device, and the signal quality of the frequency channel is further improved. Frequency hard handover between base stations occurs in a good area, thereby improving the quality of a newly set radio link. Therefore, the probability of handover failure between frequencies is reduced.

However, the first repeater 131 receives and retransmits the signals of the frequency channels FA3 and FA4 not used by the second base station 121 among the frequency channels used by the first base station 111. At this time, since the first repeater 131 needs to retransmit the frequency channels FA3 and FA4 received from the first base station 111 to the frequency channels of FA3 and FA4, a sufficient separation between the antennas of the transmitter and the receiver of the wireless repeater or ICS is performed. There is a problem in that a relay apparatus of an interference cancellation system method should be used.

In the wireless relay device, the problem of using a repeater or an ICS repeater between the antenna of the transmitter and the receiver is required to stabilize the wireless channel environment when the relay device is installed, and thus it is difficult to secure an optimal condition. In addition, when the surrounding base station environment changes, such as adding a frequency channel to the base station, there is a problem of overlapping investment that requires the removal and newly configured wireless relay device.

According to the conventional method of reducing the inter-frequency handover failure through the installation of the relay device, the effect of the inter-frequency handover failure due to the resetting of the timing and the difficulties of the installation of the relay device is inevitably limited. Therefore, there is a need for a method and apparatus for maximizing the quality of a call by further reducing the possibility of inter-frequency handover failure caused by the movement of a mobile station.

5 is a diagram illustrating a trajectory of a mobile station in a cellular mobile communication system including a wireless relay device according to an embodiment of the present invention.

Referring to FIG. 5, a cellular mobile communication system including a wireless relay device according to an embodiment of the present invention includes a first base station area 210 including at least one base station and a second base station area including at least one base station. 220, a first repeater region 230 associated with the first base station region 210 and composed of at least one wireless relay device, and at least one wireless relay apparatus associated with the second base station region 220; And a second repeater region 240.

The first base station area 210 includes a first base station 211. The second base station area 220 includes a second base station 221. The first relay region 230 includes a first relay device 231. The second base station area 240 includes a second relay device 241.

The first relay device 231 receives a frequency channel signal not used by the second base station 221 among the frequency channels used by the first base station 211. In addition, the first relay device 231 converts and transmits one frequency channel signal from one frequency channel used by the second base station 221.

Meanwhile, the second relay apparatus 241 receives a frequency channel signal not used by the first base station 211 among frequency channels used by the second base station 221. In addition, the second relay device 241 converts and transmits one frequency channel signal from one frequency channel used by the first base station 211.

6 is a block diagram of a wireless relay apparatus according to an embodiment of the present invention. FIG. 7 is a diagram illustrating a reception signal level according to the movement trajectory of the mobile station in FIG. 5.

Referring to FIG. 6, a wireless relay device reception signal selector 620, a transmission signal converter 630, and a relay device controller 650 according to an embodiment of the present invention are included.

The reception signal selector 620 selects a frequency channel signal from a signal input through the reception antenna 610.

The transmission signal converter 630 converts the selected frequency channel signal into a frequency channel signal to be transmitted through the transmission antenna 640.

The relay device controller 650 selects a frequency channel to be used by the reception signal selector 620 and the transmission signal converter 630, controls setting parameters of the relay device, and controls the operation of the relay device. The relay device controller 650 operates the reception antenna 610 and the transmission antenna 640, controls the relay device setting parameters such as the reception gain and the transmission gain, and controls the overall operation of the relay device.

8 is a diagram illustrating an example in which a relay device controller classifies a frequency channel in a wireless relay device according to an embodiment of the present invention.

The relay device controller 650 selects a frequency channel signal to receive and a frequency channel to transmit. First, the relay device controller 650 compares the frequency channels used by the base station that is in charge of the area where the wireless relay device is located and the adjacent base station. It is assumed that the first base station 211 uses four frequency channels FA1, FA2, FA3 and FA4, and the second base station 221 uses two frequency channels FA1 and FA2. In the set of frequency channels for each base station, FA1 and FA2 are frequency channels commonly used in both base stations, and FA3 and FA4 are frequency channels used only in the first base station 211. The relay device controller 650 divides both base stations into primary base stations for common frequency channels, and FA3 and FA4 used only in the first base station 211 indicate the first base station 211 as the primary base station and the second base station ( 221 is defined as a secondary base station.

The repeater controller 650 selects a primary base station and a secondary base station for each frequency channel by comparing the frequency channel set, and then selects frequency channels to be received by the first repeater 231. That is, the relay device controller 650 selects FA3 and FA4, which are frequency channels in which the first base station 211 is selected as the main base station, as reception frequency channel signals.

The second repeater 241 also selects a frequency channel signal to be received similarly to the first repeater 231. By the way, in order to be a reception frequency channel signal, only the second base station 221 should be a frequency channel signal selected as the main base station. Referring to FIG. 8, since there is no corresponding frequency channel signal, the second repeater 241 does not need to be used.

In addition, the relay device controller 650 selects a reception frequency channel signal and then determines a frequency channel signal to be transmitted. The relay device controller 650 selects a common frequency channel in which the first base station 211 and the second base station 221 are selected as the main base station as the transmission frequency channel of the first repeater 231. Referring to FIG. 8, the relay device controller 650 may determine the frequency channels FA1 and FA2 as transmission frequency channels. That is, the first repeater 231 receives the frequency channel FA3 and FA4 signals from the first base station 211 and converts them into the common frequency channels FA1 and FA2 and transmits them to the second base station 221. On the other hand, the second repeater 241 does not perform a separate operation.

9 is a diagram illustrating another example in which a relay device controller classifies a frequency channel in a wireless relay device according to an embodiment of the present invention.

Referring to FIG. 9, the first base station 211 uses four frequency channels FA1, FA2, FA3 and FA4, and the second base station 221 uses four frequency channels FA1, FA2, FA5 and FA6. Assume to use. In the set of frequency channels for each base station, FA1 and FA2 are frequency channels commonly used by both base stations, FA3 and FA4 are frequency channels used only in the first base station 211, and FA5 and FA6 are used only in the second base station 221. The frequency channel used. Accordingly, the relay device controller 650 classifies both base stations as primary base stations for the common frequency channels FA1 and FA2. In the first repeater 231, the relay device controller 650 uses only the first base station 211, and FA3 and FA4 use the first base station 211 as the primary base station and the second base station 221 as the secondary base station. Classify. Also, in the second relay 241, the relay device controller 650 uses only the second base station 221, and the frequency channels FA5 and FA6 refer to the second base station 221 as the main base station and the first base station 211 as the primary base station 211. Classify as a base station.

Referring to FIG. 9, in the first repeater 231, the relay device controller 650 selects FA3 and FA4, which are frequency channels in which the first base station 211 is selected as the main base station, as a reception signal of the first repeater 231. . Meanwhile, in the second repeater 241, the relay device controller 650 selects FA5 and FA6, which are frequency channels in which the second base station 221 is selected as the main base station, as the received frequency channel signal.

The repeater controller 650 selects a reception frequency channel, and then determines a frequency channel signal to be transmitted by the first repeater 231 and the second repeater 241. In this case, the frequency channel used for transmission should be a common frequency channel in which the first base station 211 and the second base station 221 are selected as the main base station. Thus, referring to FIG. 9, the frequency channels FA1 and FA2 correspond. In the case of the second repeater 241, since the common frequency channels for which the first base station 211 and the second base station 221 are selected as the primary base stations are channels FA1 and FA2, the transmission frequency channel signals are the first repeater and the second repeater. Is the same. That is, the first repeater 231 receives the frequency channel FA3 and FA4 signals from the first base station 211 and converts them into the common frequency channels FA1 and FA2 and transmits them to the second base station 221. On the other hand, the second repeater 241 receives the frequency channel FA5 and FA6 signals from the second base station 221 and converts them into common frequency channels FA1 and FA2 and transmits them toward the first base station 211.

Hereinafter, the operation of the inter-frequency handover of the mobile station in the situation where the reception and transmission frequency channel signal of the relay device is determined as described above will be described with reference to FIGS. 5, 7, and 8.

The wireless relay device according to an embodiment of the present invention is located in an overlapping area between base stations and is not used in the second base station 221 among the frequency channels FA1, FA2, FA3, and FA4 used by the first base station 211. Frequency channel FA3 and FA4 signals are received from the first base station 211 and converted into frequency channels FA1 and FA2, which are also used by the second base station 221, toward the second base station area 220. send. Hereinafter, it is assumed that the conditions of the frequency channel and the mobile station used by the base station are the same as those of FIGS. 3 and 4.

Referring to Fig. 5, at time ①, the mobile station 250 makes a call using the frequency channel FA3 of the first base station 211, but the signals of the frequency channels FA1, FA2 and FA4 of the first base station 211 are random. Since the threshold value TH2 is exceeded, the mobile station 250 is in a state of acquiring synchronization of the first base station 211 frequency channel FA1, FA2, and FA4 signals and evaluating the signal level (or quality). However, the mobile station 250 does not request a handover because the level difference between the first base station 211 frequency channel FA3 signal and another frequency channel signal does not exceed a predetermined level DS1.

The mobile station 250 then acquires synchronization of the second base station 221 signal and evaluates the signal level (or quality) while the second base station 221 frequency channel FA1 signal exceeds the threshold value TH2. . Here, the operation of the mobile station 250 is similar to the operation of the mobile station 140 of FIG.

The mobile station 250 then approaches the second base station area 220-in fact the first repeater area 230 in which the first repeater 231 is installed. The frequency channel FA1 signal level of the first base station 211 measured by the mobile station 250 at a point in time ③ exceeds the predetermined level DS than the first base station 211 frequency channel FA3 signal level used for the current call. This is because the frequency channel FA1 signal level of the first base station 211 measured by the mobile station 250 is actually a value accumulated by the signals transmitted from the first repeater 231 as well as the first base station 211.

Accordingly, the mobile station 250 reports to the first base station 211 that a difference exceeding a predetermined level DS occurs between frequency signals and requests in-base station hard handover (Event 2A or Event 1C). . According to the in-base station hard handover request received from the mobile station 250, the network determines inter-frequency handover, and the network determines in-base station hard handover to the frequency channel FA1 of the first base station 211 to the mobile station 250. Provide the command.

Unlike the conventional method, the radio relay apparatus according to an embodiment of the present invention preferentially performs an inter-frequency handover procedure within the same base station. In the hard handover procedure between frequency channels performed by the same base station, since the current timing remains the same even after performing the handover, only the radio link according to the frequency transition is newly set. The handover apparatus using the wireless relay apparatus according to an embodiment of the present invention has a merit that the probability of handover failure between frequencies is significantly reduced, which can maintain a very stable radio link, compared to the prior art in which timing and frequency are changed at the same time. There is this.

Then, at time point ④, if the frequency channel FA1 signal of the second base station 221 transmitted on the same frequency channel as the frequency channel FA1 in use exceeds the predetermined threshold value TH1-where the first base station ( 211) The signal level difference between the frequency channel signal FA1 and the frequency channel signal FA2 of the second base station 221 may be used, but for the sake of brevity, the description will be made using an arbitrary threshold value TH1-the second base station 221. ) Soft handover is requested for the frequency channel FA1 signal (defined as Event 1A in WCDMA). The network receiving the request determines the soft handover, and informs the mobile station 250 of the handover command (Active Set Update Message in WCDMA), the mobile station 250 performs a soft handover procedure.

Since the soft handover procedure is basically the same inter-frequency handover, there is no instability of the radio link due to frequency shift. In addition, the soft handover procedure does not remove the frequency channel FA1 signal of the first base station 211, but replaces the frequency channel FA1 signal of the second base station 221 with the existing frequency channel FA1 signal of the first base station 211. In addition, no timing shift occurs.

Thereafter, at time ⑤, the mobile station 250 causes the frequency channel FA1 signal of the first base station 211 to be a predetermined level DS2 smaller than the frequency channel FA1 signal of the second base station 221-where the first base station 211 frequency channel A method of comparing the signal level of the signal FA1 with an arbitrary threshold may be used, but described using the difference of the signal levels to provide diversity-request to disconnect the frequency channel FA1 signal of the first base station 211 (Corresponds to Event 1B in 3GPP UMST).

The wireless relay apparatus according to an embodiment of the present invention performs a hard handover between frequencies at the same base station and performs a soft handover within the same frequency as compared with the conventional inter-frequency hard handover procedure of the mobile station. The probability of failure of inter-frequency hard handover can be lowered. In addition, the wireless relay apparatus according to an embodiment of the present invention may be configured to receive a downlink signal from a base station to transmit a downlink signal, and the uplink signal may not be received and transmitted.

10 is a block diagram of a repeater for internally acquiring parameters in the wireless relay apparatus according to an embodiment of the present invention.

Referring to FIG. 10, the wireless relay device according to an embodiment of the present invention can easily change the configuration of the relay device by using neighboring base station information. The wireless relay apparatus according to an embodiment of the present invention may include an antenna 1010 and a reception information processor 1020 connected to the reception information processor.

The antenna 1010 connected to the reception information processor 1020 may receive information about frequency channels and system information of the base station from a base station located near the wireless relay device. Here, the antenna 1010 may be distinguished from the reception antenna 610 and the transmission antenna 640 to operate independently, or may perform various functions in common with one antenna.

The reception information processor 1020 may receive a frequency channel signal from an associated base station and receive system information on frequency channels used by the adjacent base station as well as the corresponding base station to obtain a parameter necessary for configuring a relay device. The reception information processor 1020 may receive a frequency channel signal transmitted from the first base station 211 and a frequency channel signal transmitted from the second base station 221 through the antenna 1010. At this time, the base station and the frequency channel signal received by the reception information processor 1020 may be determined by the relay device controller 650 as a separate rule. The system information received by the reception information processor 1020 may include system information transmitted by the first base station 211 and the second base station 221. Hereinafter, a method of easily configuring a relay device and optimizing parameters by using the system information received by the reception information processing unit 1020 will be described.

First, the relay device controller 650 determines and reports a frequency channel signal to be received by the reception information processor 1020. For example, when the frequency channel FA1 of the first base station 211 is determined, the relay device controller 650 notifies the reception information processor 1020 as a frequency channel signal to receive FA1. The reception information processor 1020 receives the system information of the first base station 211 and transmits the system information to the relay device controller 650. The system information includes not only the system information used in the frequency channel FA1 of the first base station 211, but also a list of other frequency channels used by the first base station 211 and adjacent base stations, and a second base station 221. It may include information such as a frequency channel used for each base station.

Subsequently, the relay device controller 650 informs the reception information processor 1020 of the frequency channel FA1 of the first base station 211 selected as the signal to be received and the frequency channel list of the base stations that should measure the signal level. The reception information processor 1020 receiving the frequency channel list measures a signal level (or quality) for each frequency channel, and transmits the measurement result to the relay device controller 650.

The relay device controller 650 may select an associated base station based on a signal level measurement result for each frequency channel. The selection method may select a base station transmitting a frequency channel signal having the largest signal level (or quality) as the associated base station. Another method may select a base station having many frequency channels as an associated base station.

The relay device controller 650 selects an associated base station and determines a reception signal and a transmission signal for use in the wireless relay device.

In addition, the relay device controller 650 may configure parameters, such as a reception gain and a transmission gain, used by the first repeater 231 based on a result of measuring a frequency channel signal of an associated base station and a frequency channel signal used by an adjacent base station. Control accordingly. Adaptive parameter control can maximize the efficiency of relay device maintenance and network performance by deriving and reflecting parameters optimized for itself even in the wireless environment changes such as relay device initial installation and relay device redundant installation.

In a wireless relay method according to an embodiment of the present invention, the method includes selecting a frequency channel signal from a signal input through a receiving antenna (a1), and converting the selected frequency channel signal into a frequency channel signal to be transmitted through a transmitting antenna ( a2) and selecting a frequency channel to be used in the step of selecting the frequency channel signal and converting the selected frequency channel signal, controlling the relay method setting parameter, and controlling the operation of the relay method (a3). Include.

The step (a1) of selecting a frequency channel signal among the received signals includes comparing a frequency channel used by two adjacent base stations and one base station for each frequency channel with respect to the compared frequency, and another base station. And classifying the base station into secondary base stations. Each of the above steps may be performed for each repeater. Hereinafter, a process of selecting a frequency channel to receive through the example of FIG. 8 will be described in detail.

First, the frequency comparison step compares the frequency channels used in the base station and the adjacent base station corresponding to the area where the repeater is located. Referring to FIG. 8, the first base station uses four frequency channels FA1, FA2, FA3 and FA4, and the second base station uses two frequency channels FA1 and FA2. In the set of frequency channels for each base station, FA1 and FA2 are frequency channels commonly used by both base stations, and FA3 and FA4 are frequency channels used only by the first base station.

In the frequency classifying step, common frequency channels of the frequency channels compared in the frequency comparing step are divided into two base stations, and FA3 and FA4 used only in the first base station are the first base station as the main base station, The second base station is classified as a secondary base station.

In another embodiment, referring to FIG. 9, the first base station uses four frequency channels FA1, FA2, FA3 and FA4, and the second base station uses four frequency channels FA1, FA2, FA5 and FA6. Use In the frequency comparison step, FA1 and FA2 are frequency channels commonly used by two base stations in a set of frequency channels for each base station, FA3 and FA4 are frequency channels used only by the first base station 211, and FA5 and FA6 are second channels. A frequency channel used only by the base station 221 is set.

The frequency classification step then divides both base stations into primary base stations for common frequency channels. On the other hand, in the frequency classification step, FA3 and FA4 used only in the first base station classify the first base station as the primary base station and the second base station as the secondary base station. In the frequency classification step, the frequency channels FA5 and FA6 used only in the second base station classify the second base station as the primary base station and the first base station as the secondary base station.

On the other hand, the step (a2) of converting the selected frequency channel signal converts the selected frequency channel signal into a frequency channel signal to be transmitted from the repeater to the associated base station. The frequency channel to be transmitted is determined as one of the channels classified as the common frequency channel in the frequency classification step. That is, one of frequency channels FA1 and FA2 commonly used in the first base station and the second base station is determined as a transmission signal.

In the meantime, the controlling of the relay method (a3) includes controlling an operation of an overall relay method, selecting a frequency channel signal among the received signals (a1) and converting the selected frequency channel signal (a2). ). That is, controlling the relaying method (a3) provides a parameter to be used in the step (a1) of selecting a frequency channel signal among the received signals and the step (a2) of converting the selected frequency channel signal, and the parameter ( Repeater operation may be controlled based on, for example, frequency channels.

As a method for obtaining a parameter used in the step (a3) of controlling the relay method, a required parameter may be received from an external source and may be derived and used internally within the repeater.

The wireless relay method according to an embodiment of the present invention may include a reception information processing step (a4) as a method for deriving a parameter by itself in the relay device. The receiving information processing step (a4) is a system information receiving step of receiving system information of a base station located around a wireless relay apparatus using one designated frequency channel, and adjacent to another frequency channel using the received system information. A signal level detecting step of detecting a level (or quality) of a use frequency channel signal of the base station and a base station selecting step of selecting an associated base station using the received system information and the detected signal levels.

Controlling the relay device (a3) transmits specific base station and frequency channel information to the reception information processing step (a4). If no separate information is provided, the reception information processing step (a4) is a measurement result. It can also be arbitrarily determined using. The reception information processing step (a4) receives system information of a base station located near the wireless relay device, and measures the level (or quality) of the neighbor base station and the frequency channel signal included in the received system information. The receiving information processing step (a4) includes selecting a frequency channel signal among the received signals by using the received system information and the detected signal levels (a1) and converting the selected frequency channel signal (a2). Determine the base station with which the frequency channel list to be used and the relay device are associated.

The step (a1) of selecting a frequency channel signal among the received signals and the step (a2) of converting the selected frequency channel signal comprise a relay device using a base station to which the frequency channel list and the relay device are associated, and the received signal. The step (a1) of selecting the frequency channel signal and the step (a2) of converting the selected frequency channel signal transfer the information of the configured relay device back to the reception information processing step (a4). The reception information processing step (a4) measures a parameter for determining a parameter to be used in the relay method-a reception gain, a transmission gain, and the like, and completes the setting of the relay method by obtaining the parameter. Controlling the relay method (a3) adjusts the control operation of the overall relay method.

In the method of controlling the relay method (a3), a method for deriving a parameter to be used in the repeater itself may be derived by reflecting a parameter optimized for itself in the wireless environment changes such as additional base station installation, repeater initial installation, and repeater redundant installation. This maximizes the efficiency of repeater maintenance and network performance.

Methods according to an embodiment of the present invention can be implemented in the form of program instructions that can be executed by various computer means and recorded in a computer readable medium. The computer readable medium may include program instructions, data files, data structures, etc. alone or in combination. Program instructions recorded on the media may be those specially designed and constructed for the purposes of the present invention, or they may be of the kind well-known and available to those having skill in the computer software arts.

As described above, the present invention has been described by way of limited embodiments and drawings, but the present invention is not limited to the above embodiments, and those skilled in the art to which the present invention pertains various modifications and variations from such descriptions. This is possible.

Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined not only by the claims below but also by the equivalents of the claims.

Claims (18)

A reception signal selection unit for selecting a frequency channel signal among signals input through the reception antenna;
A transmission signal conversion unit converting the selected frequency channel signal into a frequency channel signal to be transmitted through a transmission antenna; And
A relay device controller for selecting a frequency channel to be used by the reception signal selection unit and the transmission signal conversion unit, controlling a relay device setting parameter, and controlling an operation of the relay device;
Wireless relay device comprising a. The method of claim 1,
The reception signal selector,
And a frequency channel signal not used in the second base station among frequency channels used in the first base station. The method of claim 1,
The transmission signal converter,
And converting the selected frequency channel signal into a frequency channel signal commonly used in a first base station and a second base station. The method of claim 1,
The relay device control unit,
Frequency channels used only in the first base station classify the first base station as the primary base station and the second base station as the secondary base station,
Frequency channels used only in the second base station classify the second base station as the primary base station and the first base station as the secondary base station,
A frequency channel commonly used by the first base station and the second base station classifies the first base station and the second base station as a primary base station. The method of claim 1,
The relay device control unit,
Frequency channels used only in the first base station are selected as reception frequency channels,
Frequency relays commonly used in the first base station and the second base station is selected as a transmission frequency channel. The method of claim 1,
A reception information processor configured to receive system information of the base station through at least one frequency channel signal used in a base station around the wireless relay device, and to obtain a relay device configuration parameter; And
An antenna connected to the receiving information processor
Wireless relay device further comprising. The method of claim 6,
The antenna connected to the reception information processor,
The wireless relay device, characterized in that used separately from the receiving antenna of the wireless relay device. The method of claim 6,
The reception information processing unit,
System information received through at least one frequency channel transmitted from at least one base station located around the wireless relay device, and received signal level or quality information of all base stations and frequency channels around the measurable wireless relay device. And determine a list of frequency channels to be used in the wireless relay device and the base station associated with the wireless repeater based on. The method of claim 6,
The reception information processing unit,
Adaptively adjusts the parameters required in the wireless repeater by measuring the signal level or quality for the adjacent base station and the frequency channels based on the received signal and the frequency channel information of the transmission signal selected by the wireless relay device. Wireless relay device. The method of claim 1,
The wireless relay apparatus receives a downlink signal from a base station and transmits a downlink signal, and the uplink signal does not receive and transmit the uplink signal. Selecting a frequency channel signal among the signals input through the receiving antenna;
Converting the selected frequency channel signal into a frequency channel signal for transmission via a transmit antenna; And
Selecting a frequency channel for use in selecting the frequency channel signal and converting the selected frequency channel signal, controlling a relay method setting parameter, and controlling an operation of the relay method
Wireless relay method comprising a. The method of claim 11,
Selecting the frequency channel signal,
Comparing frequency channels used by base stations adjacent to the wireless relay device; And
A frequency classification step of classifying one base station as a primary base station and another base station as a secondary base station for each frequency channel with respect to the compared frequency channels
Wireless relay method comprising a. The method of claim 12,
The frequency classification step,
Frequency channels used only in the first base station classify the first base station as the primary base station and the second base station as the secondary base station,
Frequency channels used only in the second base station classify the second base station as the primary base station and the first base station as the secondary base station,
A frequency channel commonly used by the first base station and the second base station classifies the first base station and the second base station as a primary base station. The method of claim 11,
Converting the frequency channel signal,
And converting the selected frequency channel signal into a frequency channel signal commonly used in a first base station and a second base station. The method of claim 11,
Controlling the repeater,
And a parameter used for controlling the wireless relay method from an external source. The method of claim 11,
Controlling the relay method,
And a parameter used for controlling the wireless relay method is obtained in the wireless repeater itself. The method of claim 11,
A reception information processing step of receiving system information of the base station through at least one frequency channel signal used in a base station around the wireless relay device and obtaining a relay method configuration parameter;
Wireless relay method further comprising. The method of claim 17,
The receiving information processing step,
A system information receiving step of receiving system information using one designated frequency channel;
A signal level detecting step of detecting a level (or quality) of a use frequency channel signal of a base station adjacent to another frequency channel using the received system information; And
A base station selecting step of selecting an associated base station using the received system information and the detected signal levels
Wireless relay method comprising a.

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