JP2015091060A - Base station device and radio access system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce a time required for determining a failure cause.SOLUTION: A base station device 110 comprises a communication unit 111, a detection unit 112, and a control unit 113. The communication unit 111 relays communication between a radio terminal device 121 and a radio control device 130 by radio communication with the radio terminal device 121 and by communication with the radio control device 130. The detection unit 112 detects a failure of communication with the radio control device 130 by the communication unit 111. The control unit 113 makes the communication unit 111 wirelessly transmit failure information indicating a failure on a common channel which a radio terminal device 122 can receive when the detection unit 112 has detected the failure.

Description

  The present invention relates to a base station apparatus and a radio access system.

  Conventionally, in a mobile communication system, the function of a base station apparatus is divided into a REC (Radio Equipment Control) and a RE (Radio Equipment: Radio Unit) connected via a CPRI (Common Public Radio Interface). The technology to do is known.

  In addition, when the line between the control station and the base station is disconnected, an emergency line is secured by performing inter-base station communication with the adjacent base station, and the system down to the line restoration of the disconnected base station zone is prevented. A technique is known (for example, refer to Patent Document 1 below).

  Further, there is known a technique for narrowing down an abnormality occurrence unit without disconnecting the line when a line abnormality occurs during a call (see, for example, Patent Document 2 below). Further, a technique for coping with a CPRI link failure of a radio base station that employs CPRI as an internal interface between the radio control unit and the radio unit is known (for example, see Patent Document 3 below).

JP 2001-45569 A JP-A-11-215042 JP 2008-99137 A

  However, in the above-described conventional technology, when a failure occurs in communication between the wireless unit and the wireless control unit, it is difficult to transmit failure information of the wireless unit related to the failure to the network side. For this reason, there is a problem that it takes a long time to identify the cause of the failure.

  In one aspect, an object of the present invention is to provide a base station apparatus and a radio access system that can reduce the time required for identifying the cause of a failure.

  In order to solve the above-described problem and achieve the object, according to one aspect of the present invention, a first base station device communicates with the wireless terminal device by wireless communication with a wireless terminal device and communication with a wireless control device. When relaying communication with the wireless control device and detecting a communication failure with the wireless control device, the failure information indicating the failure is wirelessly transmitted on a common channel, and the wireless terminal device A base station apparatus and a radio access system that receive fault information and wirelessly transmit the received fault information to a second base station apparatus different from the first base station apparatus are proposed.

  According to one aspect of the present invention, it is possible to reduce the time required for identifying the cause of a failure.

FIG. 1A is a diagram of an example of a wireless access system according to the first embodiment. FIG. 1B is a diagram showing an example of a signal flow in the radio access system shown in FIG. 1A. FIG. 2 is a diagram of an example of the communication system according to the second embodiment. FIG. 3 is a sequence diagram of an example of the operation of the communication system according to the second embodiment. FIG. 4 is a diagram illustrating an example of the defect information. FIG. 5 is a diagram illustrating an example of a malfunction bit. FIG. 6 is a diagram illustrating an example of a method for identifying the cause of the malfunction. FIG. 7A is a diagram illustrating an example of a configuration of an RE. FIG. 7B is a diagram illustrating an example of a signal flow in the RE illustrated in FIG. 7A. FIG. 8A is a diagram illustrating an example of a configuration of a UE. FIG. 8B is a diagram illustrating an example of a signal flow in the UE illustrated in FIG. 8A. FIG. 9 is a flowchart (part 1) illustrating an example of processing by the RE. FIG. 10 is a flowchart (part 2) illustrating an example of processing by the RE. FIG. 11 is a flowchart illustrating an example of processing upon reception of other RE defect information. FIG. 12 is a flowchart illustrating an example of processing by the UE.

  Exemplary embodiments of a base station apparatus and a radio access system according to the present invention are explained in detail below with reference to the drawings.

(Embodiment 1)
(Radio access system according to the first embodiment)
FIG. 1A is a diagram of an example of a wireless access system according to the first embodiment. FIG. 1B is a diagram showing an example of a signal flow in the radio access system shown in FIG. 1A. As shown in FIG. 1A and FIG. 1B, a radio access system 100 according to the first exemplary embodiment includes a base station device 110, 140, a radio control device 130, a remote monitoring device 150, radio terminal devices 121, 122, including.

  The wireless terminal devices 121 and 122 may be the same wireless terminal device. Each of the wireless terminal devices 121 and 122 may be a wireless terminal device that is connected to the base station device 110 or the base station device 140, or a wireless device that is not connected to the base station device 110 or the base station device 140. It may be a terminal device.

  The base station device 110 can perform wireless communication with the wireless terminal devices 121 and 122. In addition, the base station apparatus 110 is connected to a network, for example, via a radio control apparatus 130, and performs radio communication under the control of the radio control apparatus 130. The base station apparatus 110 includes a communication unit 111, a detection unit 112, and a control unit 113.

  The communication unit 111 relays communication between the wireless terminal device 121 and the wireless control device 130 by wireless communication with the wireless terminal device 121 and communication with the wireless control device 130. Communication with the wireless control device 130 by the communication unit 111 may be wireless communication or wired communication. The detection unit 112 detects a failure in communication with the wireless control device 130 by the communication unit 111. Then, the detection unit 112 notifies the control unit 113 of the failure detection result.

  Based on the detection result notified from the detection unit 112, the control unit 113 controls the communication unit 111 and detects the detected failure when the communication unit 111 detects a communication failure with the wireless control device 130. Is transmitted over the common channel by radio. The common channel is a radio channel that can be received by radio terminal apparatuses (for example, radio terminal apparatuses 121 and 122) located in the cell of base station apparatus 110.

  The wireless terminal device 122 receives failure information wirelessly transmitted from the base station device 110 from the common channel, and wirelessly transmits the received failure information to the base station device 140. Base station apparatus 140 is a radio base station different from base station apparatus 110. The base station device 140 receives the failure information wirelessly transmitted by the wireless terminal device 122 and transmits the received failure information to the remote monitoring device 150. The communication between the base station device 140 and the remote monitoring device 150 may be wireless communication or wired communication.

  The remote monitoring device 150 is a device that monitors the base station devices 110 and 140. Further, the remote monitoring device 150 may be connected to the wireless control device 130. In this case, if there is no failure in communication between the base station device 110 and the radio network controller 130, the remote monitoring device 150 displays information such as fault information from the base station device 110 and the radio network controller 130. You may receive via.

  As described above, when the base station device 110 detects a failure in communication with the radio network controller 130, the fault information is wirelessly transmitted through the common channel, thereby enabling remote transmission via the radio terminal device 122 and the base station device 140. Fault information can be transmitted to the monitoring device 150.

  As a result, failure information from the base station device 110 can be transmitted to the remote monitoring device 150 even in a situation where a failure occurs in communication between the base station device 110 and the radio network controller 130. Acquisition of information becomes easy. For this reason, it is possible to reduce the time required to identify the cause of the failure.

  Further, by transmitting the failure information via the wireless terminal device 122 capable of communicating with the wireless control device 130 via the base station device 110, it is possible to add a communication device for transferring the failure information. Fault information can be sent to the remote monitoring device 150.

  Further, by transmitting the failure information wirelessly using the common channel, the wireless terminal device 122 can receive the failure information even when the wireless terminal device 122 is not wirelessly connected to the base station device 110.

<Switching wireless connection of wireless terminal device>
Further, when the wireless terminal device 122 is wirelessly connected to the base station device 110 when the failure information from the base station device 110 is received, the base station device different from the base station device 110 (for example, the base station device 140) The wireless connection may be switched.

  As a result, the wireless terminal device 122 switches the wireless connection with the base station device 110 in which a failure has occurred in communication with the network side (wireless control device 130) to the wireless connection with another base station device. The period during which communication is disabled can be shortened. The switching destination of the wireless connection is not limited to the base station device 140 to which the failure information is transmitted, but may be a base station device different from the base station device 110 and the base station device 140.

  Further, switching of the wireless connection of the wireless terminal device 122 when the wireless terminal device 122 receives failure information from the base station device 110 may be performed by control from the base station device 110. In this case, for example, the control unit 113 of the base station device 110 controls the wireless terminal device 122 via the communication unit 111 to switch the wireless connection of the wireless terminal device 122 to another base station device.

<Wireless transmission of failure information by wireless terminal device>
The wireless terminal device 122 wirelessly transmits the failure information from the base station device 110 using, for example, a random access channel. Thereby, even when the wireless terminal device 122 is not wirelessly connected to the base station device 140, the failure information can be wirelessly transmitted to the base station device 140.

<Transfer response information>
The wireless terminal device 122 may receive response information from the base station device 140 with respect to the failure information transmitted wirelessly through a common channel, and wirelessly transmit the received response information to the base station device 110. Thereby, it is possible to notify the base station apparatus 110 that the failure information has been received by another base station apparatus (base station apparatus 140).

  The wireless transmission of response information by the wireless terminal device 122 can be performed using, for example, a random access channel. Thereby, even if the wireless terminal device 122 is not wirelessly connected to the base station device 110, the response information can be wirelessly transmitted to the base station device 110.

<Continuation of failure information wireless transmission by wireless terminal device>
Further, the wireless terminal device 122 may repeat the wireless transmission of the failure information from the base station device 110 until receiving response information from a base station device different from the base station device 110 (for example, the base station device 140). Good. Thereby, the wireless transmission of the failure information can be continued until the failure information is received by the base station apparatus 140.

<Continuation of failure information wireless transmission by base station device>
Further, the base station apparatus 110 may repeat the failure information wireless transmission until the response information wirelessly transmitted by the wireless terminal apparatus 122 is received. Thereby, the wireless transmission of the failure information from the base station device 110 can be continued until the failure information is received by the base station device 140 via the wireless terminal device 122.

(Embodiment 2)
(Communication system according to Embodiment 2)
FIG. 2 is a diagram of an example of the communication system according to the second embodiment. As illustrated in FIG. 2, the communication system 200 according to the second embodiment includes a UE 201 (User Equipment: user terminal), REs 211 and 212, RECs 231 and 232, and a remote monitoring device 240.

  The service areas 221 and 222 are service areas (cells) of the REs 211 and 212, respectively. In the example illustrated in FIG. 2, the UE 201 is located in an overlapping portion of the service areas 221 and 222 and is in a state where wireless communication is possible with both the REs 211 and 212.

  The RE 211 is connected to the REC 231 via an optical fiber or the like, and performs wireless communication under the control of the REC 231. For communication between the RE 211 and the REC 231, for example, a CPRI link can be used. The RE 212 is connected to the REC 232 via an optical fiber or the like, and performs wireless communication under the control of the REC 232. For communication between the RE 212 and the REC 232, for example, a CPRI link can be used.

  The REC 231 controls the wireless communication of the RE 211 and relays communication between the RE 211 and the network. Further, the REC 231 receives information such as defect information (failure information) of the RE 211 from the RE 211 and transmits the received information to the remote monitoring device 240. The REC 232 controls the radio communication of the RE 212 and relays communication between the RE 212 and the network. Also, the REC 232 receives information such as defect information of the RE 212 from the RE 212 and transmits the received information to the remote monitoring device 240.

  The remote monitoring device 240 is an OPS (Operation System) that monitors the REs 211 and 212 by receiving information about the REs 211 and 212 via the RECs 231 and 232.

  The radio access system 100 shown in FIGS. 1A and 1B can be realized by the communication system 200, for example. In this case, the base station apparatus 110 shown in FIGS. 1A and 1B can be realized by the RE 211, for example. Moreover, the radio | wireless terminal apparatuses 121 and 122 shown to FIG. 1A and FIG. 1B are realizable by UE201, for example.

  1A and 1B can be realized by REC231, for example. Moreover, the base station apparatus 140 illustrated in FIGS. 1A and 1B can be realized by the RE 212 and the REC 232, for example. Moreover, the remote monitoring device 150 shown in FIGS. 1A and 1B can be realized by the remote monitoring device 240, for example.

  The RE 211 continues radio transmission when a communication failure with the REC 231 occurs. Further, the RE 211 causes a failure in communication with the REC 231 as a trigger to place a failure factor related to the communication failure with the REC 231 on the common CH (common channel) as pre-defined bit information (failure information), and enters the wireless section. Send.

  The RE 212 continues radio transmission when a communication failure occurs with the REC 232. Further, the RE 212, when triggered by a communication failure with the REC 232, places a failure factor related to the communication failure with the REC 232 on the common CH as pre-defined bit information and transmits it to the radio section.

  Further, the RE 212 transmits the defect information of the other RE device (RE211) received from the UE 201 to the remote monitoring device 240. Further, the RE 211 transmits the failure information of the other RE device (RE 212) received from the UE 201 to the remote monitoring device 240.

  When the UE 201 receives the defect information of the REs 211 and 212 from the common CH, the UE 201 transmits the received defect information to the RE that is continuing the service, which is different from the cell that is the source of the defect information, and the RACH (Random Access Channel). Send it on.

  In the example illustrated in FIG. 2, a case where a communication failure occurs between the RE 211 and the REC 231 will be described. In this case, the RE 211 wirelessly transmits the defect information using the common CH, and the UE 201 receives the defect information from the RE 211. Then, the UE 201 wirelessly transmits the received defect information to the RE 212 using the RACH. The RE 212 transmits the defect information received from the UE 201 to the remote monitoring device 240 via the REC 232.

  Thereby, the failure information from the RE 211 can be transmitted to the remote monitoring device 240 when a communication failure occurs between the RE 211 and the REC 231. For this reason, it is easy to acquire defect information in the remote monitoring device 240. For this reason, it is possible to reduce the time required to identify the cause of the failure.

  Further, when UE 201 receives failure information from RE 211 while connected to RE 211, UE 201 wirelessly transmits the received failure information to RE 212 and autonomously reconnects to another cell (for example, RE 212). You may go.

  Thereby, even if RE211 continues radio transmission for transmission of defect information, even if the radio propagation quality between RE211 and UE201 is good, UE201 can switch the radio connection to another cell. For this reason, the time when communication between the UE 201 and the network is disabled can be shortened.

(Operation of Communication System According to Second Embodiment)
FIG. 3 is a sequence diagram of an example of the operation of the communication system according to the second embodiment. The communication system 200 operates as each step shown in FIG. 3, for example. It is assumed that the operation mode of the RE 211 is the operation mode 1 in the initial state. The operation mode 1 is an operation mode in which the communication between the RE 211 and the REC 231 is relayed by the RE 211 communicating between the UE 201 and the REC 231.

  First, it is assumed that a problem occurs in the RE 211 and the RE 211 detects the disconnection of the CPRI (step S301). Next, the RE 211 sets the operation mode to the operation mode 2 (step S302). The operation mode 2 is an operation mode in which the RE 211 repeatedly transmits the defect information (A1) wirelessly when a communication failure between the RE 211 and the REC 231 is detected.

  Next, the RE 211 wirelessly transmits defect information (A1) for notifying the defect using the common CH (step S303). At this time, the REC 231 may also transmit failure information related to disconnection of communication with the RE 211 to the remote monitoring device 240.

  Next, the UE 201 recognizes the defect information (A1) wirelessly transmitted in step S303 (step S304). Next, the UE 201 wirelessly transmits the defect information (A1) recognized in step S304 by RACH (step S305).

  Next, the RE 212 receives the defect information (A1) wirelessly transmitted in step S305. Then, the RE 212 transmits the received defect information (A1) to the remote monitoring device 240 via the REC 232 (step S306). Also, the RE 212 wirelessly transmits defect information (A2) indicating that the defect information (A1) has been notified using the common CH (step S307).

  Next, the UE 201 receives the defect information (A2) wirelessly transmitted in step S307. Then, the UE 201 wirelessly transmits the received defect information (A2) by RACH (step S308). Note that the UE 201 that receives the defect information (A2) may be a UE different from the UE 201 that transferred the defect information (A1).

  Next, the RE 211 receives the defect information (A2) wirelessly transmitted in step S308, and sets the operation mode to the operation mode 3 (step S309). The operation mode 3 is an operation mode in which transmission / reception of radio signals is stopped. By step S309, RE211 stops transmission / reception of each radio signal including defect information (A1).

  On the other hand, the remote monitoring device 240 identifies the cause of the failure of the RE 211 based on the failure information (A1) transmitted in step S306 (step S310). Then, the recovery work 301 of the RE 211 based on the cause of the failure identified in step S310 is performed. The identification of the cause of the failure in step S310 may be performed by the user (maintenance person) of the remote monitoring device 240 instead of the remote monitoring device 240. In this case, the remote monitoring device 240 outputs information related to the failure indicated by the failure information (A1) transmitted in step S306 to the user.

  When the RE 211 recovers from the failure by the recovery operation 301, the RE 211 sets the operation mode to the operation mode 1 (step S311). Thereby, RE211 restarts transmission / reception of each radio signal.

  As described above, in the communication system 200, when the RE 211 detects a communication failure with the REC 231, the communication system 200 shifts to the operation mode 2 without stopping the transmission / reception of the radio wave, and transmits the failure information (A1) to the common CH. Wireless transmission over the. As a result, the defect information (A1) from the RE 211 reaches the remote monitoring device 240 via the UE 201 and the RE 212 in normal operation. As a result, the remote monitoring device 240 can perform complex cause identification based on the defect information (A1) from the RE 211 and the defect information from the REC 231.

  Also, defect information (A2) notifying that the defect information (A1) has been received by the RE 212 via the UE 201 is transmitted to the RE 211 via the reverse path. When the RE 211 receives the defect information (A2), the RE 211 shifts to the operation mode 3 and stops wireless transmission. Then, the RE 211 returns to the operation mode 1 when the communication failure with the REC 231 is recovered.

(Bug information)
FIG. 4 is a diagram illustrating an example of the defect information. For example, the defect information 400 shown in FIG. 4 can be used as the defect information described above. The defect information 400 includes a cell ID (RE ID), a defect bit, and a notification bit. The cell ID (RE ID) is the cell ID (RE ID) of the RE in which the failure indicated by the failure information 400 has occurred. The defect bit is information indicating the content of the defect indicated by the defect information 400 (see, for example, FIG. 5).

  The notification bit is information indicating whether the defect information 400 is defect information (A1) for notifying a defect or defect information (A2) for notifying receipt of the defect information (A1). . For example, when the notification bit is “0” (initial notification), it indicates that the defect information 400 is defect information (A1) for notifying a defect. When the notification bit is “1” (notified), it indicates that the defect information 400 is defect information (A2) for notifying receipt of the defect information (A1).

(Defect bit)
FIG. 5 is a diagram illustrating an example of a malfunction bit. The content of the failure indicated by each value of the failure bit included in the failure information 400 illustrated in FIG. 4 may be, for example, the content illustrated in the table 500 of FIG. For example, when the failure bit is “0000 0000 0000 0001”, it indicates that the CPRI link is disconnected.

  Further, when the failure bit is “0000 0000 0000 0010”, the failure of the optical / electrical converter (for example, the electric / optical converter 708 or the optical / electrical converter 710 in FIGS. 7A and 7B) has occurred. Indicates. Further, when the failure bit is “0000 0000 0000 0100”, it indicates that a failure of the CPRI receiving unit (for example, the CPRI receiving unit 711 in FIGS. 7A and 7B) has occurred.

(How to identify the cause of failure)
FIG. 6 is a diagram illustrating an example of a method for identifying the cause of the malfunction. Identification of the cause of the defect based on the defect information 400 shown in FIG. 4 can be performed as shown in the table 600 shown in FIG. In the example illustrated in FIG. 6, a case where the cause of the failure of the RE 211 is specified will be described. In the table 600, “×” and “◯” of “REC” indicate a case where the REC 231 is defective and a case where the REC 231 is not defective, respectively. The presence / absence of a failure of the REC 231 can be obtained by a failure notification means from the REC 231 generally provided to the remote monitoring device 240.

  In the table 600, “×” and “◯” of “RE” indicate a case where there is a defect in the RE 211 and a case where there is no defect in the RE 211, respectively. The presence or absence of a defect in the RE 211 is obtained, for example, when the remote monitoring device 240 receives the defect information (A1) transmitted from the RE 211 via the REC 231 when the communication between the RE 211 and the REC 231 has not occurred. be able to. Also, regarding the presence / absence of a defect in the RE 211, the remote monitoring device 240 receives the defect information (A 1) transmitted from the RE 211 via the UE 201 and the REC 232 when communication between the RE 211 and the REC 231 occurs. Can be obtained.

  For example, when the defect bit of the defect information (A1) shown in FIG. 5 is “0000 0000 0000 0001”, it is determined that “RE” in the table 600 is “◯” because the CPRI link is broken. it can.

  Further, when the failure bit of the failure information (A1) shown in FIG. 5 is “0000 0000 0000 0010”, it is determined that “RE” in the table 600 is “x” because the optical / electrical conversion unit has failed. can do.

  Further, when the defect bit of the defect information (A1) shown in FIG. 5 is “0000 0000 0000 0100”, it is a failure of the CPRI receiving unit, and therefore “RE” in the table 600 is determined to be “x”. Can do.

  For example, when “REC” and “RE” are “◯”, it can be determined that the optical cable between RE 211 and REC 231 is disconnected or poorly fitted. This case can be dealt with, for example, by exchanging or adjusting the optical cable between the RE 211 and the REC 231.

  Further, when “REC” is “x” and “RE” is “◯”, it can be determined that the functional unit on the REC 231 side is in failure. This case can be dealt with, for example, by replacement or adjustment of REC231. Further, when “REC” is “◯” and “RE” is “x”, it can be determined that the functional unit on the RE 211 side is in failure. This case can be dealt with, for example, by replacing or adjusting the RE 211.

(Structure of RE)
FIG. 7A is a diagram illustrating an example of a configuration of an RE. FIG. 7B is a diagram illustrating an example of a signal flow in the RE illustrated in FIG. 7A. Each of REs 211 and 212 can be realized by RE 700 shown in FIGS. 7A and 7B, for example.

  The RE 700 includes an antenna unit 701, an antenna sharing unit 702, a reception filter unit 703, a radio reception unit 704, an analog / digital conversion unit 705, a demodulation unit 706, a CPRI transmission unit 707, and an electrical / optical conversion unit. 708 and an optical transmission / reception shared unit 709. The RE 700 also includes an optical / electrical converter 710, a CPRI receiver 711, a modulator 712, a digital / analog converter 713, a wireless transmitter 714, and a transmission filter 715. The RE 700 also includes a failure detection unit 716, a RACH reception unit 717, another RE failure extraction unit 718, a common CH transmission unit 719, and an operation mode control unit 720.

  The demodulator 706, the CPRI transmitter 707, the CPRI receiver 711, and the modulator 712 can be realized by a digital circuit 730, for example. In addition, the defect detection unit 716, the RACH reception unit 717, the other RE defect extraction unit 718, the common CH transmission unit 719, and the operation mode control unit 720 can be realized by, for example, the digital circuit 730. The digital circuit 730 can be realized by, for example, a DSP (Digital Signal Processor) or an FPGA (Field Programmable Gate Array).

  The antenna unit 701 receives a signal wirelessly transmitted from another communication device (for example, the UE 201), and outputs the received signal to the antenna sharing unit 702. Also, the antenna unit 701 wirelessly transmits the signal output from the antenna sharing unit 702 to another communication device.

  The antenna sharing unit 702 outputs the signal output from the antenna unit 701 to the reception filter unit 703. The antenna sharing unit 702 outputs the signal output from the transmission filter unit 715 to the antenna unit 701.

  Reception filter section 703 extracts the signal of the reception band component of RE 700 from the signals output from antenna sharing section 702, and outputs the extracted signal to radio reception section 704. The wireless reception unit 704 performs reception processing on the signal output from the reception filter unit 703. The wireless reception unit 704 outputs a signal obtained by the reception process to the analog / digital conversion unit 705. Further, the wireless reception unit 704 switches between execution and stop of reception of a wireless signal based on the operation mode set by the operation mode control unit 720.

  The analog / digital conversion unit 705 converts the signal output from the wireless reception unit 704 from an analog signal to a digital signal, and outputs the digitally converted signal to the demodulation unit 706. Demodulation section 706 demodulates the signal output from analog / digital conversion section 705 and outputs the data obtained by the demodulation to CPRI transmission section 707 and RACH reception section 717.

  The CPRI transmission unit 707 stores the data output from the demodulation unit 706 in the CPRI frame, and outputs the CPRI frame storing the data to the electrical / optical conversion unit 708. The CPRI transmission unit 707 stores the defect information (A1) output from the other RE defect extraction unit 718 in the CPRI frame, and outputs the CPRI frame storing the defect information (A1) to the electrical / optical conversion unit 708. . The electrical / optical converter 708 converts the CPRI frame output from the CPRI transmitter 707 from an electrical signal to an optical signal, and outputs the CPRI frame converted into the optical signal to the optical transmission / reception shared unit 709.

  The optical transmission / reception sharing unit 709 transmits the CPRI frame output from the electrical / optical conversion unit 708 to the REC connected to the RE 700 of the RECs 231 and 232. The optical transmission / reception sharing unit 709 outputs the CPRI frame received from the REC connected to the RE 700 of the RECs 231 and 232 to the optical / electrical conversion unit 710.

  The optical / electrical conversion unit 710 converts the CPRI frame output from the optical transmission / reception sharing unit 709 from an optical signal into an electric signal, and outputs the CPRI frame converted into the electric signal to the CPRI receiving unit 711. The CPRI reception unit 711 performs reception processing of the CPRI frame output from the optical / electrical conversion unit 710 and outputs data obtained by the reception processing to the modulation unit 712.

  The modulation unit 712 performs modulation based on the data output from the CPRI reception unit 711. Also, the modulation unit 712 performs modulation based on the defect information (A1, A2) output from the common CH transmission unit 719. Then, the modulation unit 712 outputs a signal obtained by the modulation to the digital / analog conversion unit 713. The digital / analog conversion unit 713 converts the signal output from the modulation unit 712 from a digital signal to an analog signal, and outputs the converted signal to the wireless transmission unit 714.

  The wireless transmission unit 714 outputs the signal output from the digital / analog conversion unit 713 to the transmission filter unit 715. Also, the wireless transmission unit 714 switches between execution and stop of wireless signal transmission based on the operation mode set by the operation mode control unit 720. Transmission filter section 715 extracts the signal of the transmission band component of RE 700 from the signals output from radio transmission section 714, and outputs the extracted signal to antenna sharing section 702.

  The defect detection unit 716 detects various defects in the RE 700. The defect detected by the defect detection unit 716 includes, for example, disconnection of communication with the REC connected to the RE 700 (REC communication disconnection). When the failure detection unit 716 detects the disconnection of the REC communication, the failure detection unit 716 generates failure information (A1) in which 0 is stored in the notification bit, and outputs the generated failure information (A1) to the common CH transmission unit 719. In addition, the defect detection unit 716 notifies the operation mode control unit 720 of the detection of the REC communication disconnection.

  The RACH reception unit 717 performs reception processing of RACH included in the data output from the demodulation unit 706 and outputs the reception processing result to the other RE defect extraction unit 718 and the operation mode control unit 720.

  Other RE defect extraction unit 718 extracts defect information (A1) of another RE from the reception processing result output from RACH reception unit 717. Then, the other RE defect extraction unit 718 outputs the extracted defect information (A1) to the CPRI transmission unit 707. The other RE defect extraction unit 718 replaces the notification bit of the extracted defect information (A1) from 0 to 1, and outputs the defect information (A2) with the notification bit replaced to the common CH transmission unit 719.

  The common CH transmission unit 719 outputs the defect information (A1) output from the defect detection unit 716 to the modulation unit 712, thereby wirelessly transmitting the defect information (A1) using the common CH. Also, the common CH transmission unit 719 outputs the defect information (A2) output from the other RE defect extraction unit 718 to the modulation unit 712, thereby wirelessly transmitting the defect information (A2) using the common CH.

  The operation mode control unit 720 controls the operation mode of the RE 700. For example, the operation mode control unit 720 sets the operation mode to the operation mode 1 in the initial state, and causes the wireless reception unit 704 and the wireless transmission unit 714 to transmit and receive wireless signals. In addition, when the failure detection unit 716 notifies the operation mode control unit 720 that the REC communication disconnection is detected, the operation mode control unit 720 sets the operation mode to the operation mode 2 and causes the wireless transmission unit 714 to transmit the failure information (A1). The wireless reception unit 704 receives the defect information (A2).

  In addition, the operation mode control unit 720 sets the operation mode to the operation mode 3 when the reception processing result output from the RACH reception unit 717 includes defect information (A2) including the cell ID of the RE 700. Then, the operation mode control unit 720 causes the wireless reception unit 704 and the wireless transmission unit 714 to stop transmitting and receiving wireless signals. Further, the operation mode control unit 720 returns the operation mode to the operation mode 1 by an operation from the administrator of the RE 700, for example, when the RE 700 returns from the disconnection of the REC communication.

  1A and 1B includes, for example, an antenna unit 701, an antenna sharing unit 702, a reception filter unit 703, a wireless reception unit 704, an analog / digital conversion unit 705, a demodulation unit 706, a CPRI transmission unit 707, / Optical conversion unit 708, optical transmission / reception sharing unit 709, optical / electrical conversion unit 710, CPRI reception unit 711, modulation unit 712, digital / analog conversion unit 713, wireless transmission unit 714, and transmission filter unit 715. .

  The detection unit 112 illustrated in FIGS. 1A and 1B can be realized by, for example, the defect detection unit 716. The control unit 113 shown in FIGS. 1A and 1B can be realized by, for example, the RACH receiving unit 717, the other RE defect extracting unit 718, the common CH transmitting unit 719, and the operation mode control unit 720.

(UE configuration)
FIG. 8A is a diagram illustrating an example of a configuration of a UE. FIG. 8B is a diagram illustrating an example of a signal flow in the UE illustrated in FIG. 8A. UE201 is realizable by UE800 shown, for example in FIG. 8A and FIG. 8B.

  The UE 800 includes an antenna unit 801, an antenna sharing unit 802, a reception filter unit 803, a radio reception unit 804, an analog / digital conversion unit 805, a demodulation unit 806, a call processing control unit 807, and an output unit 808. . In addition, the UE 800 includes a signal determination unit 809, a RACH transmission unit 810, an input unit 811, a call processing control unit 812, a modulation unit 813, a digital / analog conversion unit 814, a radio transmission unit 815, and a transmission filter. Part 816.

  Demodulation section 806, call processing control section 807, output section 808, signal determination section 809, RACH transmission section 810, input section 811, call processing control section 812, and modulation section 813 can be realized by digital circuit 830, for example.

  The antenna unit 801 receives a signal wirelessly transmitted from another communication device (for example, RE 211, 212), and outputs the received signal to the antenna sharing unit 802. Also, the antenna unit 801 wirelessly transmits the signal output from the antenna sharing unit 802 to another communication device.

  The antenna sharing unit 802 outputs the signal output from the antenna unit 801 to the reception filter unit 803. The antenna sharing unit 802 outputs the signal output from the transmission filter unit 816 to the antenna unit 801.

  The reception filter unit 803 extracts the reception band component signal of the UE 800 from the signals output from the antenna sharing unit 802, and outputs the extracted signal to the radio reception unit 804. The wireless reception unit 804 performs reception processing on the signal output from the reception filter unit 803, and outputs a signal obtained by the reception processing to the analog / digital conversion unit 805.

  The analog / digital conversion unit 805 converts the signal output from the wireless reception unit 804 from an analog signal to a digital signal, and outputs the digitally converted signal to the demodulation unit 806. Demodulation section 806 demodulates the signal output from analog / digital conversion section 805 and outputs data obtained by the demodulation to call processing control section 807.

  The call processing control unit 807 performs call processing control by outputting control data included in the data output from the demodulation unit 806 to the signal determination unit 809. Further, the call processing control unit 807 outputs user data included in the data output from the demodulation unit 806 to the output unit 808.

  The output unit 808 outputs the user data output from the call processing control unit 807 to an application upper layer processing unit and the like.

  When the control data output from the call processing control unit 807 includes defect information (A1) or defect information (A2), the signal determination unit 809 includes the defect information (A1) or defect information ( A2) is output to RACH transmission section 810.

  RACH transmission section 810 outputs defect information (A1) from signal determination section 809, and UE 800 is located in an RE cell different from RE of cell ID included in defect information (A1), A process of wirelessly transmitting the defect information (A1) by RACH is performed. For example, RACH transmission unit 810 outputs defect information (A1) to call processing control unit 812.

  Further, RACH transmission unit 810 outputs defect information when defect information (A2) is output from signal determination unit 809 and UE 800 is located in an RE cell having a cell ID included in defect information (A2). A process of wirelessly transmitting (A2) by RACH is performed. For example, RACH transmission unit 810 outputs defect information (A2) to call processing control unit 812.

  The input unit 811 outputs user data output from an upper layer processing unit or the like to the call processing control unit 812.

  The call processing control unit 812 performs call processing control, and performs transmission processing of user data output from the input unit 811 and defect information output from the RACH transmission unit 810. For example, the call processing control unit 812 outputs each data to be transmitted to the modulation unit 813.

  The modulation unit 813 performs modulation based on the data output from the call processing control unit 812, and outputs a signal obtained by the modulation to the digital / analog conversion unit 814. The digital / analog conversion unit 814 converts the signal output from the modulation unit 813 from a digital signal to an analog signal, and outputs the converted signal to the wireless transmission unit 815.

  The wireless transmission unit 815 outputs the signal output from the digital / analog conversion unit 814 to the transmission filter unit 816. Transmission filter section 816 extracts the signal of the transmission band component of UE 800 from the signal output from radio transmission section 815, and outputs the extracted signal to antenna sharing section 802.

(Processing by RE)
FIG. 9 is a flowchart (part 1) illustrating an example of processing by the RE. The RE 700 executes, for example, each step shown in FIG. In the initial state, the operation mode of the RE 700 is the operation mode 1. First, the RE 700 monitors the communication state between the RE 700 and the connected REC (Step S901). Next, the RE 700 determines whether or not a communication disconnection between the RE 700 and the connected REC is detected based on the monitoring result of the step S901 (step S902).

  In step S902, when communication disconnection is not detected (step S902: No), the RE 700 sets the operation mode to the operation mode 1 (step S903) and returns to step S901. Note that if the operation mode is the operation mode 1 immediately before step S903, the RE 700 may return to step S901 without performing step S903. When the communication disconnection is detected (step S902: Yes), the RE 700 determines whether or not the current operation mode is the operation mode 1 (step S904).

  In step S904, when the operation mode is operation mode 2 or operation mode 3 (step S904: No), RE 700 returns to step S901. When the operation mode is the operation mode 1 (step S904: Yes), the RE 700 sets the operation mode to the operation mode 2 (step S905). Next, the RE 700 starts radio transmission of the defect information (A1) storing the defect bit indicating the content of the detected defect using the common CH (step S906), and returns to step S901.

  FIG. 10 is a flowchart (part 2) illustrating an example of processing by the RE. The RE 700 executes, for example, the steps shown in FIG. 10 together with the steps shown in FIG. First, the RE 700 receives the RACH (step S1001). Next, the RE 700 determines whether or not the RACH received in step S1001 has defect information (step S1002).

  If there is no defect information in step S1002 (step S1002: No), RE 700 returns to step S1001. When there is defect information (step S1002: Yes), the RE 700 determines whether or not the cell ID included in the defect information is the ID of the own device (RE 700) (step S1003).

  In step S1003, when the cell ID is the ID of the own device (step S1003: Yes), the RE 700 determines whether the notification bit included in the defect information is “0” (step S1004). When the notification bit is “0” (step S1004: Yes), it can be determined that the received defect information is the UE 201 that has transferred the defect information (A1) for which wireless transmission has been started in step S906. . In this case, the RE 700 returns to step S1001.

  If the notification bit is “1” in step S1004 (step S1004: No), it may be determined that the defect information (A1) that has started wireless transmission in step S906 in FIG. 9 has been received by another RE. it can. In this case, the RE 700 sets the operation mode to the operation mode 3 (step S1005). Also, the RE 700 stops transmission / reception of radio signals including the radio transmission of the defect information (A1) started in step S906 in FIG. 9 (step S1006), and returns to step S1001.

  In step S1003, if the cell ID is not the ID of the own device (step S1003: No), it can be determined that defect information related to a defect that has occurred in another RE has been received. In this case, the RE 700 performs processing upon reception of other RE defect information (step S1007), and returns to step S1001. The processing at the time of receiving other RE defect information will be described later (see, for example, FIG. 11).

  FIG. 11 is a flowchart illustrating an example of processing upon reception of other RE defect information. In step S1007 of FIG. 10, RE 700 executes, for example, each step shown in FIG. 11 as a process when receiving other RE defect information. First, the RE 700 determines whether or not the notification bit included in the received defect information is “0” (step S1101).

  If the notification bit is “0” in step S1101 (step S1101: Yes), it can be determined that the received defect information is defect information (A1) for notifying the defect. In this case, the RE 700 superimposes the defect information (A1) on the CPRI frame (step S1102). Next, the CPRI frame on which the defect information (A1) is superimposed in step S1102 is transmitted to the REC connected to the RE 700 (step S1103).

  Also, the RE 700 replaces the notification bit of the defect information (A1) from “0” to “1” (step S1104). Thereby, defect information (A1) turns into defect information (A2) for notifying receipt of defect information (A1). Next, the RE 700 starts radio transmission of the defect information (A2) using the common CH (step S1105). The RE 700 ends the process at the time of receiving a series of other RE defect information after steps S1103 and S1105.

  If the notification bit is not “0” in step S1101 (step S1101: No), it is determined that the received defect information is that UE 201 has transferred the defect information (A2) for which wireless transmission is started in step S1105. be able to. In this case, the RE 700 stops wireless transmission of the defect information (A2) started in step S1105 (step S1106), and ends the process when receiving a series of other RE defect information.

(Processing by UE)
FIG. 12 is a flowchart illustrating an example of processing by the UE. For example, the UE 800 executes the steps illustrated in FIG. First, the UE 800 receives a common CH (step S1201). Next, the UE 800 determines whether or not there is defect information in the common CH received in step S1201 (step S1202).

  In step S1202, when there is no defect information (step S1202: No), the UE 800 returns to step S1201. When there is defect information (step S1202: Yes), the UE 800 determines whether or not the notification bit included in the defect information is “0” (step S1203).

  If the notification bit is “0” in step S1203 (step S1203: Yes), it can be determined that the received defect information is defect information (A1) for notifying the defect. In this case, UE 800 determines whether or not it is within an RE range other than the RE indicated by the cell ID included in the received defect information (A1) (step S1204). If it is not within the range of another RE (step S1204: No), the UE 800 returns to step S1201.

  In step S1204, when it is in the range of other RE (step S1204: Yes), UE800 starts the radio transmission by RACH of the received malfunction information (A1) (step S1205). Further, UE 800 determines whether or not there is a call being connected to RE indicated by the cell ID included in the received defect information (A1) (step S1206).

  In step S1206, when there is a connected call (step S1206: Yes), the UE 800 performs a reconnection sequence to another RE (step S1207). When there is no connected call (step S1206: No), the UE 800 does not perform the reconnection sequence of step S1207. After steps S1205 to S1207, UE 800 returns to step S1201.

  In step S1203, when the notification bit is not “0” (step S1203: No), it may be determined that the received defect information is defect information (A2) for notifying receipt of the defect information (A1). it can. In this case, the UE 800 stops wireless transmission of the defect information (A1) started in step S1205 corresponding to the cell ID included in the received defect information (A2) (step S1208).

  Next, the UE 800 determines whether or not it is within the RE range indicated by the cell ID included in the received defect information (A2) (step S1209). When the cell ID is not within the RE range indicated by the cell ID (step S1209: No), the UE 800 returns to step S1201.

  In step S1209, if the cell ID is within the RE range indicated by the cell ID (step S1209: Yes), the UE 800 wirelessly transmits the received defect information (A2) by RACH (step S1210), and returns to step S1201.

  As described above, according to the second embodiment, when the RE 211 detects a communication failure with the REC 231, the failure information (A1) can be wirelessly transmitted using the common CH. Thereby, defect information (A1) can be transmitted to the remote monitoring apparatus 240 via UE201, RE212, and REC232.

  Therefore, since the failure information (A1) from the RE 211 can be transmitted to the remote monitoring device 240 even in a situation where a failure occurs in the communication between the RE 211 and the REC 231, the remote monitoring device 240 can acquire the failure information without omission. become. For this reason, it is possible to reduce the time required to identify the cause of the failure.

  Further, by transmitting the defect information (A1) via the UE 201 capable of communicating with the network via the RE 211, it is possible to add a communication device for transferring the defect information (A1). The defect information (A1) can be transmitted to the remote monitoring device 240.

  Also, by transmitting the defect information (A1) via the UE 201 that can communicate with the REC 231 via the RE 211, the defect information (A1) can be transmitted without adding a communication device for transferring the defect information (A1). A1) can be transmitted to the remote monitoring device 240.

  Also, by transmitting the defect information (A1) wirelessly using the common channel, the UE 201 can receive the defect information (A1) even if the UE 201 is not wirelessly connected to the RE 211.

  Further, when the UE 201 is wirelessly connected to the RE 211 when receiving the defect information (A1) from the RE 211, the UE 201 switches the wireless connection to a base station device (for example, the RE 212) different from the RE 211. As a result, the UE 201 can switch the wireless connection with the RE 211 that has failed in communication with the network side to the wireless connection with another base station apparatus, and can shorten the period during which communication with the network side is disabled. . The switching destination of the wireless connection is not limited to the transmission destination RE 212 of the defect information (A1), and may be a base station device different from the RE 211 and RE 212.

  In addition, when the UE 201 receives the defect information (A1) from the RE 211, switching of the wireless connection of the UE 201 may be performed by control from the RE 211.

  The UE 201 wirelessly transmits the defect information (A1) from the RE 211 using, for example, a random access channel. Thereby, even if the UE 201 is not wirelessly connected to the RE 212, the defect information (A1) can be wirelessly transmitted to the RE 212.

  The UE 201 receives the defect information (A2) from the RE 212 for the defect information (A1) wirelessly transmitted through the common channel, and wirelessly transmits the received defect information (A2) to the RE 211. Thereby, it is possible to notify the RE 211 that the defect information (A1) has been received by the other base station device (RE 212).

  Moreover, the radio | wireless transmission of the malfunction information (A2) by UE201 can be performed using a random access channel, for example. Thereby, even if the UE 201 is not wirelessly connected to the RE 211, the defect information (A2) can be wirelessly transmitted to the RE 211.

  Further, UE 201 repeats wireless transmission of defect information (A1) from RE 211 until it receives defect information (A2) from a base station apparatus (for example, RE 212) different from RE 211. Thereby, wireless transmission of defect information (A1) can be continued until defect information (A1) is received by RE212.

  Also, the RE 211 repeats wireless transmission of the defect information (A1) until response information wirelessly transmitted by the UE 201 is received. Thereby, the wireless transmission of the defect information (A1) from the RE 211 can be continued until the defect information (A1) is received by the RE 212 via the UE 201.

  As described above, according to the base station apparatus and the radio access system, it is possible to reduce the time required for identifying the cause of the failure.

  For example, in a mobile communication system, a technique for dividing the function of a base station apparatus into REC and RE connected via CPRI is known. In such a mobile communication system, an RE having a radio wave transmission / reception function with a mobile communication terminal and a REC having a baseband function for performing communication with the core network side while controlling the RE have, for example, a redundant configuration. They are connected to each other by a single optical cable.

  Then, full-duplex bidirectional optical communication is performed between the RE and the REC using different light wavelengths. For this reason, when a communication failure occurs between the RE and the REC, the service area covered by the RE falls into a service stop state.

  In the future, as the number of users increases and the demand for higher-speed communication increases, it is expected that the number of base station configurations called small cell solutions, in which the service area covered by one RE becomes smaller, will increase. For this reason, it is assumed that the number of REs will further increase in the future, and the impact of such service suspension will increase.

  Since most REs are installed outdoors such as on the rooftops of buildings or on steel towers, they have a sealed housing, and, for example, the RE is replaced when a failure occurs. For this reason, since replacement at the time of failure of RE becomes work which goes up to a steel tower etc., it is assumed that the work man-hour until recovery is also increased.

  When a failure occurs in the communication between the RE and the REC, the root cause of the failure that has occurred may have a plurality of possibilities, for example, C1 to C4 below.

C1: REC side transmission function, reception function, electrical / optical conversion function failure C2: RE side transmission function, reception function, electrical / optical conversion function failure C3: Optical cable halfway disconnection C4: Optical cable and RE device or REC Improper fitting of optical connector to device

  However, since the remote monitoring of the base station device is performed, for example, via REC, the cause in the REC device such as C1 can be specified, but the root cause such as C2 to C4 can be specified remotely. Is often difficult.

  Therefore, for fault recovery, after preparing spare parts and equipment that can be exchanged for as many faults as possible, maintenance personnel rush to the site (the rooftop of the building, the top of the steel tower, etc.) After arrival, root cause identification and recovery will be carried out. Since each of these operations takes time, it can be considered as one of the causes that takes a long time to recover.

  On the other hand, according to each embodiment described above, defect information that can be detected on the RE side can be transmitted to the remote monitoring device using a method other than via the CPRI. Here, when a radio base station uses another radio transmission / reception function provided by the RE to pass through another normal operating RE, for example, the radio base station uses different frequency divisions of FDD (Frequency Division Duplex: frequency division duplex). In other words, it is difficult for other REs to receive radio waves transmitted by REs. Therefore, in each of the above-described embodiments, defect information can be transmitted to the remote monitoring device via another RE by using a general mobile communication terminal (user terminal) as a relay device.

  As a result, when a communication failure between REC and RE occurs, it becomes possible to narrow down and identify the root cause of the failure before entering the site. This leads to advance preparation and shortening of the work time at the site, and as a result, shortening of the service stop period and optimization of man-hours required for recovery are possible. In addition, since a communication failure between REC and RE can be detected, reconnection with the next candidate base station is immediately started, so that it is possible to shorten the period during which wireless communication is disabled.

  The following additional notes are disclosed with respect to the above-described embodiments.

(Appendix 1) A communication unit that relays communication between the wireless terminal device and the wireless control device by wireless communication with the wireless terminal device and communication with the wireless control device;
A detection unit for detecting a failure in communication with the wireless control device by the communication unit;
A control unit that causes the communication unit to wirelessly transmit the failure information indicating the failure on a common channel that can be received by a wireless terminal device when the failure is detected by the detection unit;
A base station apparatus comprising:

(Supplementary Note 2) The control unit wirelessly transmits the failure information from the common channel, thereby causing the wireless terminal device that has received the failure information from the common channel to wirelessly transmit the failure information to another base station device. The base station apparatus according to appendix 1, wherein the other base station apparatus transmits the failure information to a remote monitoring apparatus.

(Supplementary Note 3) When the failure is detected by the detection unit, and the wireless terminal device that has received the failure information is wirelessly connected to the own device, the control unit The base station apparatus according to appendix 1 or 2, wherein the wireless connection is switched to another base station apparatus.

(Appendix 4) When communication between the wireless terminal device and the wireless control device is relayed by wireless communication with the wireless terminal device and communication with the wireless control device, and a communication failure with the wireless control device is detected A first base station device that wirelessly transmits failure information indicating the failure on a common channel;
A wireless terminal device that receives the failure information from the common channel and wirelessly transmits the received failure information to a second base station device different from the first base station device;
A wireless access system comprising:

(Supplementary Note 5) The wireless terminal device that has received the failure information transmits the failure information to the second base station device by wirelessly transmitting the received failure information to the second base station device. The wireless access system according to appendix 4, wherein

(Supplementary note 6) The wireless terminal device that has received the failure information switches wireless connection to a base station device different from the first base station device when wirelessly connected to the first base station device. The wireless access system according to appendix 4 or 5.

(Supplementary note 7) The wireless terminal device that has received the failure information wirelessly transmits the failure information to the second base station device through a random access channel. Wireless access system.

(Supplementary Note 8) The wireless terminal device that has received the failure information receives response information from the second base station device to the wirelessly transmitted failure information through a common channel, and receives the received response information in the first base station device. The wireless access system according to any one of appendices 4 to 7, wherein the wireless access system performs wireless transmission.

(Supplementary note 9) The wireless access system according to supplementary note 8, wherein the wireless terminal device that has received the failure information repeats wireless transmission of the failure information until the response information is received.

(Supplementary note 10) The wireless access system according to Supplementary note 8 or 9, wherein the wireless terminal device that has received the failure information wirelessly transmits the response information to the first base station device through a random access channel.

(Supplementary note 11) The radio access system according to any one of Supplementary notes 8 to 10, wherein the first base station apparatus repeats wireless transmission of the failure information until the response information is received.

(Supplementary note 12) The wireless access system according to any one of supplementary notes 4 to 11, wherein the wireless terminal device that has received the failure information is a user terminal.

DESCRIPTION OF SYMBOLS 100 Radio access system 110,140 Base station apparatus 111 Communication part 112 Detection part 113 Control part 121,122 Radio | wireless terminal apparatus 130 Radio | wireless control apparatus 150,240 Remote monitoring apparatus 200 Communication system 201,800 UE
211, 212, 700 RE
221 and 222 Service area 231 and 232 REC
301 Restoration work 400 Defect information 500,600 Table 701, 801 Antenna unit 702, 802 Antenna sharing unit 703, 803 Reception filter unit 704, 804 Wireless reception unit 705, 805 Analog / digital conversion unit 706, 806 Demodulation unit 707 CPRI transmission unit 708 Electrical / optical conversion unit 709 Optical transmission / reception shared unit 710 Optical / electrical conversion unit 711 CPRI reception unit 712, 813 Modulation unit 713, 814 Digital / analog conversion unit 714, 815 Wireless transmission unit 715, 816 Transmission filter unit 716 Defect detection unit 717 RACH reception unit 718 Other RE defect extraction unit 719 Common CH transmission unit 720 Operation mode control unit 730, 830 Digital circuit 807, 812 Call processing control unit 808 Output unit 809 Signal determination unit 810 RACH transmission unit 8 First input unit

Claims (7)

A communication unit that relays communication between the wireless terminal device and the wireless control device by wireless communication with the wireless terminal device and communication with the wireless control device;
A detection unit for detecting a failure in communication with the wireless control device by the communication unit;
A control unit that causes the communication unit to wirelessly transmit the failure information indicating the failure on a common channel that can be received by a wireless terminal device when the failure is detected by the detection unit;
A base station apparatus comprising:   The control unit wirelessly transmits the failure information from the common channel, thereby causing the wireless terminal device that has received the failure information from the common channel to wirelessly transmit the failure information to another base station device. The base station apparatus according to claim 1, wherein the base station apparatus transmits the failure information to a remote monitoring apparatus.   The control unit, when the failure is detected by the detection unit and the wireless terminal device that has received the failure information is wirelessly connected to its own device, The base station apparatus according to claim 1, wherein the base station apparatus is switched to another base station apparatus. The communication between the wireless terminal device and the wireless control device is relayed by wireless communication with the wireless terminal device and communication with the wireless control device, and the failure is detected when a communication failure with the wireless control device is detected. A first base station device that wirelessly transmits failure information to be indicated on a common channel;
A wireless terminal device that receives the failure information from the common channel and wirelessly transmits the received failure information to a second base station device different from the first base station device;
A wireless access system comprising:   The wireless terminal device that has received the failure information switches wireless connection to a base station device different from the first base station device when wirelessly connected to the first base station device. The radio access system described in 1.   The radio access system according to claim 4 or 5, wherein the radio terminal device that has received the failure information wirelessly transmits the failure information to the second base station device through a random access channel.   The wireless terminal device that has received the failure information receives response information from the second base station device to the wirelessly transmitted failure information through a common channel, and wirelessly transmits the received response information to the first base station device. The wireless access system according to claim 4, wherein the wireless access system is a wireless access system.

Images