JP4612529B2 - Communication device and redundant system switching method - Google Patents

Description

  The present invention relates to a communication apparatus and a redundant system switching method, and relates to a redundant system switching technique applicable to various communication devices used in a circuit switching system and a mobile communication system, and in particular, using a CPRI (Common Public Radio Interface). The present invention is preferably applied to the radio management apparatus and the radio apparatus.

  Here, “CPRI” is an open interface inside the radio base station, and is for an architecture that separates the radio unit and the control unit in the radio base station and connects them with an open interface. As a result, infrastructure vendors can flexibly design and build equipment for each functional unit in the radio base station, including the incorporation of third-party products and partial emphasis and differentiation of their technology. (For CPRI, see http://www.cpri.info/jp/index.html)

  FIG. 5 shows a configuration example of redundant system switching in the radio management apparatus and radio apparatus. In the figure, 100 is a radio management apparatus (REC: Radio Equipment Control), and 200 is a radio apparatus (RE: Radio Equipment Control).

  In the radio management apparatus (REC) 100, 101 is a call control / call processing apparatus (card) that performs general call control / call processing in accordance with 3GPP (3rd Generation Partnership Project) standards, and 102 is A common control device (card) that performs maintenance and monitoring of each functional unit and device in the device. Reference numerals 103 and 104 denote active and standby standby terminal devices that terminate the CPRI protocol, and reference numeral 105 denotes a selector used for switching the redundant devices of the terminal devices 103 and 104.

  In the radio apparatus (RE) 200, 202 and 203 are active and standby standby terminal apparatuses that terminate the CPRI protocol, and 201 is a selector used for switching the redundant systems of the terminal apparatuses 202 and 203. Reference numerals 204 and 205 denote a wireless transmitter (card) and a wireless receiver (card) that transmit and receive general wireless signals in accordance with 3GPP standards.

  In the apparatus shown in FIG. 5, the control signal (message) from outside and the main signal of user data (voice data, packet data, etc.) are (A) → (B) → (C) → (D) → It flows in the order of (E) → (F) → (G) (or the reverse order). The loss of this signal has a great influence on the system operation and the user, and does not cause a signal loss in each signal route (between (A)-(B), (C)-(D),...)). It is necessary to guarantee the operation.

  The present invention switches from the protocol terminator 103 to the protocol terminator 104 in the radio management apparatus 100, or from the protocol terminator 104 to the protocol terminator 103, or from the protocol terminator 202 in the radio apparatus 200 to the protocol terminator. The present invention relates to improvement of signal loss between signal routes (C)-(D)-(E) when switching to the device 203 or switching from the protocol termination device 203 to the protocol termination device 202.

  Switching from the protocol terminator 103 to the protocol terminator 104 (or the protocol terminator 104 to the protocol terminator 103) in the signal route (C)-(D)-(E) between the devices shown in FIG. Since switching from the device 202 to the protocol termination device 203 (or from the protocol termination device 203 to the protocol termination device 202) is performed by switching by the selector 105 or the selector 201, line disconnection (layer 1 disconnection) occurs.

  Therefore, the upper layer connection is also disconnected. Then, after the line is physically connected to another system to establish the layer 1 connection, reconnection (layer 2 and layer 3 link establishment processing) in the signal route (C)-(D)-(E) is performed. Done.

  FIG. 6 shows a conventional operation for switching a redundant system of signal routes (C)-(D)-(E). (A) of the figure shows that the protocol termination device 103 and the protocol termination device 202 are connected by the selectors 105 and 201 between the radio management device (REC) 100 and the radio device (RE) 200, and the layer 3 Indicates that the link is in operation.

  Here, as shown in FIG. 6B, when the active protocol termination device 103 of the radio management device (REC) 100 is switched to the standby protocol termination device 104, the radio management device temporarily The layer 1 link between the (REC) 100 and the wireless device (RE) 200 is disconnected.

  Then, as shown in FIG. 6C, after the selector 105 and the protocol terminator 104 are physically connected in the radio management device (REC) 100, the protocol terminator of the radio management device (REC) 100 is obtained. The connection processing for establishing the link of the layer 1, the layer 2 and the layer 3 is performed between the wireless communication device 104 and the protocol termination device 202 of the wireless device (RE) 200.

  After the connection processing up to the layer 3 is completed, as shown in FIG. 6D, between the protocol termination device 104 of the radio management device (REC) 100 and the protocol termination device 202 of the radio device (RE) 200. Thus, communication is enabled through the layer 3 link, and the protocol termination device 104 operates as an active system, and is in operation.

  The redundant system switching shown in FIGS. 5 and 6 is an example of switching in a redundant configuration in which protocol termination devices are duplicated. However, the wireless management device (REC) 100, the wireless device (RE) 200, and the protocol are switched. Even in the case of a redundant configuration in which the lines connecting the terminating devices are duplicated, the same thing occurs when the system is switched.

  The same applies to a configuration in which the protocol termination devices of the radio management device (REC) 100 and the radio device (RE) 200 are respectively N (N> 2) redundant, that is, an N-to-N redundant configuration. Happens. FIG. 7A shows a configuration example of a line redundancy configuration, and FIG. 7B shows a configuration example when the radio management apparatus (REC) 100 and the radio apparatus (RE) 200 have an N-to-N redundancy configuration. Show.

  FIG. 8 shows a processing flow for establishing a link between the radio management apparatus (REC) 100 and the radio apparatus (RE) 200. As shown in the figure, the radio management apparatus (REC) 100 and the radio apparatus (RE) 200 establish the layer 3 (L3) link after the layer 1 (L1) link establishment and the layer 2 (L2) link establishment. Is performed over the state A to the state F.

  As a prior art document related to the present invention, the following Patent Document 1 describes a switching method of a line control apparatus having a line termination unit of N + 1 redundant configuration, and at the time of system switching, the switching source line termination A second link number that is different from the first link number during normal operation performed between each line termination unit of the active system is added to the switching source takeover data, and transfer control is performed to this second link number. Information is added and transferred via the system bus, and when the switching destination line termination unit receives the second link number, it determines that the data following the second link number is transfer control information, and this transfer control information By storing the succeeding data following to the memory, it is not necessary to rewrite the data buffer pointer and offset value for each data buffer when switching the system, and the system is switched quickly. There is described switching method that can and.

Further, in Patent Document 2 below, in a call path automatic switching method for switching a call path when a failure occurs, a standby connection indicating a detour path is established in advance, and an operation indicating a path during a call is performed. It describes a call path automatic switching method in which, when a failure occurs in a connection, this operational connection is switched to a standby connection established in advance.
JP-A-8-149180 JP 2001-298461 A

  In the conventional redundant system switching configuration, it is necessary to perform reconnection processing to establish links of each layer as the line is disconnected at the time of switching. During switching operation, communication between devices becomes impossible. Control signals (messages) and user data (speech data, packet data, etc.) have a drawback of signal loss.

  Furthermore, in the connection method in CPRI, the connection speed between devices (signal route (C)-(D)-(E) in FIG. 6) is as low as 960 kbps, and it takes a long time for reconnection processing for link establishment of each layer. The signal route (D) between the selector 105 and the selector 201 can be used with a cable of up to 10 km, and if a failure or the like occurs in the link establishment between the devices, the maintenance person can contact the opposite device. However, maintenance work has become difficult, such as having to perform maintenance.

  The present invention provides a high-speed reconnection process for establishing a link in a higher layer after disconnection of a physical connection between devices when switching a redundant protocol termination device or a redundant line connecting the protocol termination device to a partner device. It is an object of the present invention to provide a communication apparatus and a redundant system switching method that can be performed in the same manner.

  The communication apparatus of the present invention has (1) a self-device protocol terminator that transmits / receives a signal to / from a protocol terminator of another communication device via a line. One of them is selected and connected to the line, or the protocol terminating device in the own device is a communication device connected to one of the redundant lines via a selector, and functions of the protocol terminating device of the other communication device. A self-device protocol terminator and the protocol pseudo-simulator after switching the active-system protocol terminator or line connection from the active system to the standby system using a selector. The connection processing for establishing a link is performed between the two devices, and after the link establishment is completed, the internal protocol termination device is connected to the other communication device. Characterized in that incorporated into the line connected to the Tokoru terminator.

  Also, (2) the protocol pseudo-simulator acquires the connection data and status information necessary for link establishment connection processing at the time of switching of the redundant system in the active system own apparatus when communication with another communication apparatus is established. A connection data / state information holding unit is provided for receiving or notifying the transmission / reception signal between the protocol termination device and the protocol termination device of another communication device or intercepting and holding the transmission / reception signal.

(3) When the other communication device is a wireless management device, a protocol pseudo simulator for simulating the function of the protocol termination device of the wireless management device is provided in the own device, and the other communication device is a wireless device. In this case, a protocol simulation simulator for simulating the function of the protocol termination device of the wireless device is provided in the device itself.
(4) The protocol termination device terminates a transmission / reception number of a CPRI (Common Public Radio Interface) link protocol.

  The redundant system switching method according to the present invention includes (5) a protocol termination device in its own device that transmits / receives a signal to / from a protocol termination device of another communication device via the line, and the protocol termination device in its own device is redundant. In the redundant system switching method of a communication device in which one of them is configured and is selected by a selector and connected to a line, or the local protocol termination device is connected to one of redundant lines via a selector. A protocol pseudo simulator for simulating the function of the protocol termination device of the communication device is provided in the own device, and after switching the connection of the protocol termination device or the line in the own device from the active system to the standby system by a selector, A connection process for establishing a link is performed between the protocol termination device and the protocol pseudo simulator. The Tokoru termination device, characterized in that incorporated into the line connected to the protocol termination unit of another communication device.

  According to the present invention, at the time of switching a redundant configuration protocol termination device or a redundant line connecting the protocol termination device to a partner device, between the devices (signal routes (C)-(D)-(E) in FIG. 5) The link establishment process of the upper layer after the physical connection is disconnected is performed in the own device using the protocol pseudo simulator in the own device, so that it is performed via a low-speed line with the remote partner device. In addition, it is possible to eliminate the communication time and processing waiting time of the reconnection process for link establishment in each layer, and the reconnection process for link establishment can be processed at high speed.

  In addition, since reconnection processing is completed in the radio management apparatus (REC) or in the radio apparatus (RE), there is a problem that occurs in the counterpart device when switching the redundant system such as a terminating device or a line between the counterpart devices. The maintenance work can be performed in the own apparatus, and the maintenance work can be reduced.

  In addition, by receiving and holding connection data and status information necessary for link establishment connection processing at the time of switching of redundant systems when communication with other communication devices is established, other communication devices of different types Necessary connection data and status information can be individually stored, and a plurality of types of other communication devices can be dynamically handled.

  FIG. 1 shows a redundant system switching configuration according to the present invention. In the figure, the same components as those shown in FIG. 5 are denoted by the same reference numerals. In the present invention, the protocol management simulators 106 and 206 that simulate the protocol termination device of the counterpart device are installed in the radio management device (REC) 100 and the radio device (RE) 200, respectively.

  Then, in the redundant system switching of the signal route via the protocol termination device 103 or 104 and 202 or 203, the connection between the wireless management device (REC) 100 and the wireless device (RE) 200 is performed in the link establishment connection process of each layer. Asynchronously, the radio management apparatus (REC) 100 and the radio apparatus (RE) 200 each perform reconnection processing for link establishment for each layer between the protocol termination apparatus of the own apparatus and the protocol pseudo simulator in the own apparatus. After the connection processing is completed, the connection is made to the actual line with the partner apparatus.

  By doing so, it is possible to save the communication time and processing waiting time of the reconnection process of the link establishment of each layer that has been performed with the remote partner apparatus through the low-speed line, and the re-establishment of the link establishment. The connection process can be performed at high speed in order to perform the connection process within its own device. Especially when the device is connected to the other device with an optical transmission device, it is physically disconnected instantaneously at the time of switching. The upper layer can be switched without disconnecting the apparent connection.

  FIG. 2 shows the redundant system switching operation according to the present invention. (A) of the figure shows that the protocol termination device 103 and the protocol termination device 202 are connected by the selectors 105 and 201 between the radio management device (REC) 100 and the radio device (RE) 200, and the layer 3 Indicates that the link is in operation.

  Here, as shown in FIG. 2B, when the active protocol terminator 103 of the radio management device (REC) 100 is switched to the standby protocol terminator 104, the radio management device temporarily The layer 1 link between the (REC) 100 and the wireless device (RE) 200 is disconnected.

  Then, as shown in FIG. 2C, after the selector 105 and the protocol termination device 104 are physically connected in the radio management device (REC) 100, the radio device (RE) with the protocol termination device 104 is connected. A connection process is established for establishing link between layer 1, layer 2, and layer 3 with the protocol pseudo simulator 106.

  After the connection processing up to the layer 3 is completed, as shown in FIG. 2D, between the protocol termination device 104 of the radio management device (REC) 100 and the protocol termination device 202 of the radio device (RE) 200. Thus, communication is enabled through the layer 3 link, and the protocol termination device 104 is in an operational state in which it operates as the active system.

  FIG. 3 shows an operation when the line between the radio management apparatus (REC) 100 and the radio apparatus (RE) 200 is made redundant and the redundant line is switched. As shown in the figure, the connection between the selector and protocol terminator 107 in the radio management apparatus (REC) 100 and the selector and protocol terminator 207 in the radio apparatus (RE) 200 is changed from the working line 301 to the protection line 302. The radio management apparatus (REC) 100 establishes link of each layer between the selector and protocol termination apparatus 107 and the protocol pseudo simulator 106 of the radio apparatus (RE), and the radio apparatus (REC) ) 200, link establishment of each layer is performed between the selector / protocol terminating device 207 and the protocol pseudo simulator 206 of the radio management device (REC).

  The connection process for establishing a link for each layer between the protocol termination device and the protocol simulation simulator can be configured as follows. In the first connection processing method, necessary connection data and state information at the time of switching are fixedly stored in advance in the protocol simulation simulator.

  That is, data and status information necessary for connection processing for each layer with the radio management apparatus (REC) 100 are stored in the radio apparatus (RE) protocol pseudo simulator 106 in advance. Further, data and state information necessary for connection processing for each layer with the radio apparatus (RE) apparatus 200 are stored in the radio management apparatus (REC) protocol pseudo simulator 206 in advance.

  When the protocol termination devices 103 and 104 in the radio management apparatus (REC) 100 are switched between the active system and the standby system, the standby system protocol termination apparatus 104 and the radio apparatus (RE) protocol pseudo simulator 106 are connected to the signal route. The selector 105 is set so as to be connected via (H)-(I). After that, as shown in FIG. 2C, the standby protocol termination device 104 and the radio device (RE) protocol pseudo simulator 106 perform connection processing for link establishment for each layer.

  The second connection processing method of the connection processing for establishing a link for each layer between the protocol termination device and the protocol pseudo simulator is to store necessary connection data and state information at the time of switching at the initial startup of the device. .

  That is, each layer connection process is performed between devices in the first connection between devices, and the connection data / state information at that time is notified to the protocol pseudo simulator, or the connection data / state information is intercepted by the protocol pseudo simulator. The protocol simulation simulator saves connection data / state necessary for each layer connection process.

  When the protocol termination devices 103 and 104 in the radio management apparatus (REC) 100 are switched between the active system and the standby system, the standby system protocol termination apparatus 104 and the radio apparatus (RE) protocol pseudo simulator 106 communicate with each other. The selector 105 is set so as to be connected via (H)-(I), and then, as shown in FIG. 2C, the standby protocol terminator 104 and the radio device (RE) protocol pseudo simulator 106 are set. Then, connection processing for link establishment for each layer is performed.

  The third connection processing method of the connection processing for establishing the link for each layer between the protocol termination device and the protocol simulation simulator stores connection data / state information in the protocol simulation simulator in the second connection processing described above. At this time, a simple logic is notified by omitting an omissible connection sequence, and the connection process itself is simplified.

  FIG. 4 shows an example of a flow of link establishment processing using the protocol simulator of the present invention. As shown in the figure, the protocol termination device (standby system) in the radio management device (REC) 100 extends from state A to state F after the layer 1 (L1) link establishment and the layer 2 (L2) link establishment. Layer 3 (L3) link establishment is performed with the radio apparatus (RE) protocol pseudo simulator 106 in the local apparatus, and after the link establishment is completed, the connection destination is incorporated into the actual line.

  Note that the link establishment sequence of the layer 1 (L1) and layer 2 (L2) indicated by the broken line in the example of FIG. 4 is omitted, and the link establishment sequence between the protocol termination device (standby system) and the protocol pseudo simulator 106 is 3 (L3).

It is a figure which shows the structural example for redundant system switching by this invention. It is a figure which shows the operation | movement of the redundant system switching of the protocol termination | terminus apparatus by this invention. It is a figure which shows the operation | movement of the redundant system switching of the line | wire by this invention. It is a figure which shows the link establishment process flow by the protocol pseudo simulator of this invention. It is a figure which shows the structural example of the redundant system switching in a radio | wireless management apparatus and a radio | wireless apparatus. It is a figure which shows the operation | movement at the time of the redundant system switching of the conventional signal route. It is a figure which shows the example of a line redundant structure, and the example of a redundant structure of N to N by a radio | wireless management apparatus (REC) and a radio | wireless apparatus (RE). It is a figure which shows the link establishment process flow between a radio | wireless management apparatus (REC) and a radio | wireless apparatus (RE).

Explanation of symbols

100 Radio management device (REC)
101 Call control / call processing device (card)
102 Common control device (card)
DESCRIPTION OF SYMBOLS 103 CPRI protocol termination apparatus of working system 104 CPRI protocol termination apparatus of standby system 105 Selector 200 Radio | wireless apparatus (RE)
201 Selector 202 Active CPRI Protocol Terminator 203 Backup CPRI Protocol Terminator 204 Radio Transmitter (Card)
205 Wireless receiver (card)

Claims (5)

It has its own protocol termination device that sends and receives signals to and from other communication device's protocol termination device, and this own device's protocol termination device is made redundant, and one of them is selected by the selector and connected to the line Or, in the communication apparatus connected to one of the redundant lines via a selector,
A protocol simulation simulator that simulates the function of the protocol termination device of the other communication device is provided in the own device,
After switching the local protocol termination device or line connection from the active system to the standby system by the selector, a link establishment connection process is performed between the local protocol termination device and the protocol pseudo simulator, and the link A communication apparatus characterized in that, after the establishment is completed, the in-device protocol terminator is incorporated in a line connected to the protocol terminator of another communication apparatus.   The protocol simulator simulates connection data and status information necessary for link establishment connection processing at the time of switching of the redundant system, when the communication with another communication device is established, The communication apparatus according to claim 1, further comprising a connection data / state information holding unit that receives a notification of a transmission / reception number of the communication apparatus with a protocol termination device or intercepts and holds the transmission / reception number.   When the other communication device is a wireless management device, a protocol pseudo simulator that simulates the function of the protocol termination device of the wireless management device is provided in the own device, and the other communication device is a wireless device. 3. The communication apparatus according to claim 1, further comprising a protocol simulation simulator that simulates a function of a protocol termination apparatus of the wireless apparatus.   4. The communication apparatus according to claim 3, wherein the protocol termination apparatus terminates a transmission / reception number of a CPRI (Common Public Radio Interface) link protocol. It has its own protocol termination device that sends and receives signals to and from other communication device's protocol termination device, and this own device's protocol termination device is made redundant, and one of them is selected by the selector and connected to the line Or, in the self-device protocol termination device, in the redundant system switching method of the communication device connected to one of the redundant lines via a selector,
A protocol simulation simulator for simulating the function of the protocol termination device of the other communication device is provided in the own device, and after switching the connection of the protocol termination device or the line in the own device from the active system to the standby system by the selector, A connection process for establishing a link is performed between an in-device protocol terminator and the protocol pseudo simulator, and after the establishment of the link, the in-device protocol terminator is connected to the protocol terminator of another communication device. A redundant system switching method characterized by being incorporated into the system.

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