JP2004104438A - Base station repeating apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a base station repeating apparatus which can continue communication even when a fault has occurred at a host channel. <P>SOLUTION: The base station repeating apparatus 100 repeats a communication between a control station of an uppermost side for constituting a tree-like rank link network and a communication terminal of a lowermost side. The apparatus includes an upper circuit interface unit 101 for returning an up signal from a lower station at an upper circuit fault time, a lower circuit interface unit 103, a radio circuit interface unit 105, and a controller 107 for holding control data sent from the control station before the fault occurs and sending the data to the upper circuit interface unit 101 when a fault of the upper circuit is detected. The upper circuit interface unit 101 includes a prefetch priority selector 111 for selecting one of signals of a predetermined line, a data processing unit 113 for generating returning data by processing the selected signal to a down format, and a signal returning unit 115 for returning and sending the returning data to a lower station. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
An object of the present invention is to minimize the influence on communication even if a failure occurs in an upper line (or an upper line interface unit) in a communication system constituting a tree-like multi-level digital link network, and to continue communication. The present invention relates to a base station relay device that can be used.
[0002]
[Prior art]
FIG. 1 shows an example of a hierarchical digital link network formed in a tree shape by a plurality of base stations that communicate with a communication terminal. As shown in the figure, in the digital link network, at least one base station 3 is communicably connected to the control station 1 as a vertex, and the other base stations 3 are also connected from the base station 3 in a tree shape. The communication terminal 5 exists at the end. Further, when focusing on a certain base station, there is only one upper station, whereas there are n lower stations (n ≧ 1), and a higher-order communication network capable of branching to a lower route. It is.
[0003]
The base station 3 includes an interface with the upper station and an interface with the lower station for relaying communication from the lower station to the upper station or from the upper station to the lower station. FIG. 5 is a block diagram showing the internal configuration of a conventional base station 3 constituting the above-described tree-shaped digital link network. As shown in FIG. 1, the conventional base station 3 includes an upper line interface 11, a lower line interface 13, a wireless line interface 15, a preemption priority selector 17, and a controller 19.
[0004]
The upper line interface unit 11 is an interface with an upper station, and is connected to a line (upper line) connected to the control station 1 or the upper base station 3. The lower line interface unit 13 is an interface with a lower station, and is connected to a line (lower line) connected to the lower base station 3. The wireless line interface unit 15 is an interface with the communication terminal 5 and transmits and receives signals to and from the communication terminal 5 by wireless communication.
[0005]
Further, the preemption priority selection unit 17 selects one signal of an arbitrary or predetermined priority route from signals transmitted from a plurality of lower stations and transmits the selected signal to the upper line interface unit 11. is there. The control unit 19 controls each component. The above components are connected by a data communication bus 21, and a signal from a lower station is transmitted to the upper line interface unit 11 via the data communication bus 21 and the prefetch priority selector 17, and a signal from the upper station is It is transmitted to the lower line interface unit 13 or the wireless line interface unit 15 via the communication bus 21.
[0006]
Note that signals transmitted on the upper line and the lower line are roughly divided into control signals for management systems and information signals such as voice, and the control signals are configured by control channels, broadcast channels, and individual control channels. The control signal is generally managed by the control station 1, and the control station 1 controls the entire tree configuration using the control signal. On the other hand, the base station 3 successively responds to the movement of the communication terminal 5 by constructing a tree structure by relaying the control signal transmitted from the upper station to the lower station.
[0007]
[Problems to be solved by the invention]
However, in the above-described conventional base station 3, when a failure occurs in the upper line, the control signal from the control station 1 which is the highest station is not sent, so that the control signal is relayed to the lower station. Can not. As a result, since the communication terminal 5 cannot receive the control signal, there is a problem that the communication including the upper line in which the failure has occurred in the communication path is interrupted. Similarly, when a failure occurs in the upper line interface unit 11 of the base station 3, the control signal transmitted from the control station 1 cannot be relayed to the lower station. There was a problem that the communication including it was interrupted.
[0008]
The present invention has been made in view of the above-mentioned conventional problems, and provides a base station relay device capable of continuing communication even if a failure occurs in an upper line (or an upper line interface unit). It is an object.
[0009]
[Means for Solving the Problems]
In order to achieve the above object, a base station relay device according to the present invention provides a base station that relays communication between a highest-order control station and a lowest-order communication terminal that constitute a tree-like tiered link network. A relay device for detecting a failure of an upper line connected to an upper station, and a line failure detecting means for detecting an uplink signal sent from the lower station when the upper line has a failure; Return means for processing the data into a format and transmitting the return data to the lower station. Therefore, even if a failure occurs in the upper line, data obtained by processing the uplink signal sent from the lower station is sent to the lower station, so that communication can be continued without interruption on the downstream side from the point where the failure occurred. it can.
[0010]
Further, the base station relay device according to the present invention includes control data holding means for holding data (hereinafter, referred to as “control data”) relating to a control signal sent from the control station before the occurrence of a failure in the upper line. The loopback unit processes the control data stored in the control data storage unit into the downlink frame format together with the uplink signal and transmits the control data to the lower station. Therefore, even if a failure occurs in the upper line, the lowest communication terminal can receive information necessary for communication as usual, and thus communication can be continued.
[0011]
Furthermore, the base station relay device according to the present invention includes a preemption priority selection unit that selects one signal of an arbitrary or predetermined priority route from among the uplink signals transmitted from the plurality of lower stations, It is preferable that the upstream signal sent from the lower station processed by the loopback unit is a signal selected by the preemption priority selection unit.
[0012]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of a base station relay device according to the present invention will be described in detail with reference to the drawings.
[0013]
First, FIG. 1 illustrates an example of a hierarchical digital link network configured in a tree shape by the base station relay device of the present embodiment that communicates with a communication terminal. As shown in the figure, in the digital link network, at least one base station relay apparatus 100 is communicably connected with the control station 1 as a vertex, and another base station relay apparatus 100 is also connected from the base station relay apparatus 100. Each is connected in a tree shape, and a communication terminal 5 exists at the end. Further, when focusing on a certain base station relay device, the number of upper stations is one, while the number of lower stations is n (n ≧ 1). It is a communication network. The communication connection between the control station 1, the base station relay device 100, and the communication terminal 5 may be wired or wireless.
[0014]
The base station relay device 100 includes an interface unit with the upper station and an interface unit with the lower station to relay communication from the lower station to the upper station or from the upper station to the lower station. FIG. 2 is a block diagram illustrating an internal configuration of the base station relay device 100 according to the present embodiment, which configures the above-described tree-shaped digital link network. As shown in the figure, the base station relay apparatus 100 of the present embodiment includes an upper line interface unit 101, a lower line interface unit 103, a wireless line interface unit 105, and a control unit 107. .
[0015]
These components are connected to each other by a data communication bus 109, a signal from the lower station is transmitted to the data communication bus 109 to the upper line interface unit 101, and a signal from the upper station is transmitted to the data communication bus 109. The data is transmitted to the lower line interface unit 103 or the wireless line interface unit 105 via the interface.
[0016]
Hereinafter, each component of the base station relay device 100 of the present embodiment will be described.
First, the upper line interface unit 101 will be described. The upper line interface unit 101 is an interface with an upper station, and is connected to a line (upper line) connected to the control station 1 or the upper base station relay device 100. As shown in FIG. 2, the upper line interface unit 101 has a prefetch priority selector 111, a data processing unit 113, and a signal return unit 115 provided therein. Has the function of folding back. The loopback means in the claims corresponds to the data processing section 113 and the signal loopback section 115, and the preemption priority selection section corresponds to the prefetch priority selection section 111.
[0017]
The preemption priority selection unit 111 selects one signal of an arbitrary or predetermined priority route from among the uplink signals transmitted from the plurality of lower stations and sends the signal to the data processing unit when a failure occurs. Sometimes it is transmitted to an upper line. Further, when a failure occurs, the data processing unit 113 processes the signal selected by the prefetch priority selection unit 111 into a frame format for downlink, generates return data, and sends the data to the signal return unit 115. Further, the signal return section 115 returns the data for return generated by the data processing section 113 to the lower station side and transmits it.
[0018]
The data processing unit 113 processes the data relating to the control signal held in the control data memory unit 143 described later and the signal selected by the prefetch priority selection unit 111 into a frame format for downlink, and returns the data. May be generated. The frame format and the return data in this case will be described with reference to FIG.
[0019]
Next, the lower line interface unit 103 will be described. The lower line interface unit 103 is an interface with a lower station, and is connected to a line (lower line) connected to the lower base station relay apparatus 100. Also, as shown in FIG. 2, the lower line interface unit 103 has a preemption priority selection unit 121 provided therein, and when a failure occurs in the upper line interface unit 101 in the same base station relay apparatus, a signal from the lower station is transmitted. It has the function of turning back. The preemption priority selection unit 121 selects one signal of an arbitrary or predetermined priority route from among the uplink signals transmitted from the plurality of base station relay apparatuses as lower stations, and selects the upper line interface unit 101 Is to be transmitted.
[0020]
Next, the wireless line interface unit 105 will be described. The wireless line interface unit 105 is an interface with the communication terminal 5, and transmits and receives signals to and from the communication terminal 5 by wireless communication. Also, as shown in FIG. 2, the radio line interface unit 105 is provided with a preemption priority selection unit 131 therein, and transmits a signal from a lower station when a failure of the upper line interface unit 101 in the same base station relay apparatus occurs. It has the function of turning back. The preemption priority selection unit 131 selects one signal of an arbitrary or predetermined priority route from among the uplink signals transmitted from the plurality of communication terminals 5 as lower stations, and sends the selected signal to the upper line interface unit 101. To be transmitted.
[0021]
The signals transmitted on the upper line and the lower line are roughly classified into control signals for the management system and information signals such as voice. The control signal is constituted by a control channel, a broadcast channel, and an individual control channel, and is, for example, wireless carrier frequency information or information on a communication system mapped to each carrier. The control signal is generally managed by the control station 1, and the control station 1 controls the entire tree configuration using the control signal. On the other hand, the base station relay apparatus 100 successively responds to the movement of the communication terminal 5 by constructing a tree structure by relaying the control signal transmitted from the upper station to the lower station in a normal state.
[0022]
Next, the control unit 107 will be described. The control unit 107 controls each component. Further, as shown in FIG. 2, the control unit 107 includes therein a line status detection unit 141, a control data memory unit 143, and a control data transmission / reception unit 145, which are sent from the control station 1 before a failure occurs. It has a function of holding data related to the control signal. The line fault detecting means in the claims corresponds to the line status detecting section 141, and the control data holding means corresponds to the control data memory section 143.
[0023]
The line status detection unit 141 periodically inquires of the upper line interface unit 101 about a failure of the upper line. When receiving a notification from the upper line interface unit 101 that the upper line is in a failure state, the line state detector 141 returns. It instructs the upper line interface unit 101 to perform the processing. Further, the control data memory unit 143 holds data (hereinafter, referred to as “control data”) related to a control signal transmitted from the control station 1 before the occurrence of a failure in the upper line. The control data includes service information of the system, information of self-station allocation for the communication terminal 5, and the like. The control data transmission / reception unit 145 receives control data transmitted via the higher-level line interface unit 101 and stores the control data in the control data memory unit 143, or transmits control data held in the control data memory unit 143 to the upper level. This is sent to the data processing unit 113 of the line interface unit 101.
[0024]
Next, the operation of the base station relay device 100 according to the present embodiment when a failure occurs in the upper line will be described with reference to FIG. FIG. 4 is a flowchart illustrating an operation of the base station relay device 100 according to the present embodiment when a failure occurs in the upper line.
[0025]
The line status detection unit 141 of the control unit 107 sends a failure inquiry of the upper line to the upper line interface unit 101. In a normal state where no failure has occurred, a normal state notification is sent from the upper line interface unit 101 to the line status detection unit 141. The upstream signal received from the lower station received by the lower line interface unit 103 or the wireless line interface unit 105 is sent to the upper line interface unit 101 via the data communication bus 109, and the signal selected by the prefetch priority selecting unit 111 is selected. Is sent to the upper line.
[0026]
When the line status detecting unit 141 sends a fault inquiry when a fault occurs in the upper line, a fault status notification is sent from the upper line interface unit 101 to the line status detecting unit 141. Then, the control unit 107 notifies the higher-level line interface unit 101 to perform the return processing. At this time, the upper line interface unit 101 sends the preselected signal to the data processing unit 113 without sending the signal to the upper line, processes the signal into a frame format for downlink, and returns the signal from the signal return unit 115 to the lower station. At the time of processing in the data processing unit 113, processing is performed by combining the signal selected in advance and the control data held in the control data memory unit 143 of the control unit 107, and this is returned to the lower station. good.
[0027]
Next, an operation of the base station relay device 100 according to the present embodiment when a failure occurs in the upper line interface unit 101 will be described.
[0028]
As described above, according to the base station relay apparatus 100 of the present embodiment, even if a failure occurs in the upper line, return data obtained by processing the uplink signal sent from the lower station is generated, and Therefore, the communication can be continued without interruption on the downstream side of the failure point. Furthermore, the control data received from the upper station during normal times is retained, and when a failure occurs, the control data is returned to the lower station together. Therefore, communication can be continued even if a failure occurs in the upper line.
[0029]
Also, even if a failure occurs in the upper line interface unit 101, the lower line interface unit 103 can return the upstream signal from the upper station and transmit it, so that even in this case, communication can be continued without interruption. it can.
[0030]
When the upper line or the upper line interface unit 101 is restored, the return to the lower station described above is stopped, and the upstream signal from the lower station is transmitted to the upper line again.
[0031]
【The invention's effect】
As described above, according to the base station relay apparatus of the present invention, even if a failure occurs in the upper line, data obtained by processing the uplink signal sent from the lower station is sent to this lower station, so that the failure occurs. Communication can be continued without interruption downstream of the point. Further, even if a failure occurs in the upper line, the lowest communication terminal can receive the information necessary for communication as usual, so that communication can be continued.
[Brief description of the drawings]
FIG. 1 is an explanatory diagram illustrating an example of a digital link network configured in a tree shape by a plurality of base station relay devices that communicate with a communication terminal; FIG. 2 is an embodiment of configuring a tree-shaped multi-level digital link network; FIG. 3 is a block diagram showing an internal configuration of a base station relay device according to an embodiment. FIG. 3 is an explanatory diagram showing a frame format for downlink and data for return. FIG. FIG. 5 is a flowchart for explaining the operation of the station relay apparatus. FIG. 5 is a block diagram showing the internal configuration of a conventional base station constituting a tree-like multi-level digital link network.
1 Control Station 5 Communication Terminal 100 Base Station Relay Device 101 Upper Line Interface Unit 103 Lower Line Interface Unit 105 Wireless Line Interface Unit 107 Control Unit 109 Data Communication Bus 111 Prefetch Priority Selection Unit 113 Data Processing Unit 115 Signal Return Unit 121 Prefetch Priority Selection Section 131 preemption priority selecting section 141 line status detecting section 143 control data memory section 145 control data transmitting / receiving section

Claims (3)

A base station relay device that relays communication between a highest-order control station and a lowest-order communication terminal that constitute a tree-like tiered link network,
A line failure detecting means for detecting a failure of an upper line connected to the upper station,
When a failure has occurred in the upper line, a return means for processing an uplink signal sent from a lower station into a frame format for downlink and transmitting the signal back to the lower station,
A base station relay device comprising: Control data holding means for holding data (hereinafter referred to as “control data”) related to a control signal sent from the control station before the occurrence of a failure in the upper line,
2. The control unit according to claim 1, wherein the return unit processes the control data held in the control data holding unit into the downlink frame format together with the uplink signal and transmits the control data to the lower station. 3. Base station relay device. A preemption priority selecting means for selecting one signal of an arbitrary or pre-determined route from among upstream signals transmitted from the plurality of lower stations,
3. The base station relay apparatus according to claim 1, wherein the upstream signal transmitted from the lower station processed by the loopback unit is a signal selected by the preemption priority selection unit.

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