JP2016144041A - Switching equipment and control method therefor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide switching equipment capable of efficiently accommodating a line between transmission equipment and switching equipment.SOLUTION: The switching equipment includes: line connection means for connecting to the transmission equipment through a line and terminating the line; layer-2 termination means for terminating a signal in the layer 2; layer-3 termination means for terminating a signal in the layer 3; and control means. The line connection means forms a communication path to connect a bearer channel to the layer-3 termination means, and a communication path to connect a control signal channel to the layer-2 termination means. The layer-2 termination means forms a communication path to connect the control signal channel to the layer-3 termination means. The control means manages line information, and identifies a line associated with a received control signal to control the identified line.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a switching apparatus and a method for controlling the switching apparatus, and can be applied to, for example, a private branch exchange apparatus that employs a V5.2 interface.

  As an interface of the private branch exchange network, for example, a V5.2 interface is known. As the V5.2 interface, G.I. 964 and the G. There are those specified in 965.

  The V5.2 interface is configured by using one private branch exchange (LE) and a plurality of terminal-side devices (AN; Access Network). The private branch exchange apparatus and the terminal side apparatus are arranged at a long distance and are connected by a transmission path (E1 line). Each terminal-side device accommodates a plurality of subscriber terminals (see Patent Document 1). By placing the AN remotely from the LE, a single LE can provide telephone service to a wide range of subscribers.

  In the V5.2 standard, the number of E1 lines between AN and LE can be connected from a minimum of 2 to a maximum of 16. The LE controls and manages the 16 E1 lines as a unit. A single LE can be connected to multiple ANs.

  The control between the AN and the LE is realized by performing control signal communication using a specific time slot of a specific E1 line called a C channel. In other words, since the V5.2 interface is a standard for controlling up to 16 E1 lines by a control signal communicated on the C channel, in a system having a conventional LE function, a bundle of 16 E1 lines is used. The control is performed in units of.

  For example, the conventional LE has a configuration in which an E1 line terminator for connecting an E1 line and an L2 terminator that terminates a signal at a layer 2 defined in the V5.2 standard (that is, an E1 line terminator). And each L2 termination unit is connected / terminated to a single L3 termination unit that terminates a signal in layer 3.

JP 2006-261972 A

  Here, according to the above-mentioned V5.2 standard, 16 E1 lines are the maximum number. For example, when a configuration that accommodates 3 E1 lines per AN is taken, Five ANs can be connected to the L2 termination.

  However, as described above, in the conventional LE function deployment in which the E1 line termination unit and the L2 termination unit are deployed as a single processing unit in the unit of 16 E1 lines, the control of the E1 line is performed by the L2 termination unit. Since the function sharing is via, inconvenience occurs when 16 management units are straddled. In other words, the straddled line is connected to a different AN at the L2 terminal portion and is outside the control range. In other words, the conventional LE cannot take the form of E1 line accommodation that straddles the L2 termination.

  For example, the E1 line accommodated in one AN cannot be distributed and connected to a plurality of L2 termination units.

  That is, when the LE accommodates 15 E1 lines, the remaining one E1 line accommodating portion is an unusable line because at least two E1 lines are required according to the V5.2 standard.

  Therefore, a switching apparatus and a switching apparatus control method that can efficiently accommodate the line between the transmission apparatus and the switching apparatus are desired.

  The switching apparatus according to the first aspect of the present invention includes a plurality of line connection means for connecting to one or a plurality of transmission apparatuses via a plurality of lines and terminating each of the lines, and a layer 2 corresponding to each of the line connection means. A layer 2 termination unit that terminates the line signal, a layer 3 termination unit that terminates the line signal at layer 3, and a control unit. (1) The line connection unit is included in the line. Forming a communication path for connecting a bearer channel to the layer 3 termination means and a communication path for connecting a control signal channel for transmitting and receiving a control signal included in the line to the layer 2 termination means, 2) The layer 2 termination means forms a communication path for connecting the control signal channel to the layer 3 termination means, and (3) the control means corresponds to a line corresponding to each control signal. Manage multicast, to identify the line corresponding to the received control signal, characterized in that to the control of the identified line in the layer 3 terminator.

  The switching apparatus control method of the second aspect of the present invention corresponds to a plurality of line connection means for connecting to one or a plurality of transmission apparatuses via a plurality of lines and terminating each of the lines, and to each of the line connection means. Layer 2 termination means for terminating the signal on the line at layer 2, layer 3 termination means for terminating the signal on the line at layer 3, and control means. (1) The line connection means includes: A communication path for connecting a bearer channel included in a line to the layer 3 termination means and a communication path for connecting a control signal channel for transmitting and receiving a control signal included in the line to the layer 2 termination means are formed. (2) the layer 2 termination means forms a communication path for connecting the control signal channel to the layer 3 termination means, and (3) the control means is connected to each control signal. To manage the line information, it identifies the line corresponding to the received control signal, characterized in that to the control of the identified line in the layer 3 terminator.

  ADVANTAGE OF THE INVENTION According to this invention, the line | wire between a transmission apparatus and a switching apparatus can be accommodated efficiently.

It is the block diagram shown about the functional structure of the local exchange which concerns on 1st Embodiment, and its peripheral connection structure. It is explanatory drawing which showed matching with V5 link number and E1 line number for every AN which concerns on 1st Embodiment. It is explanatory drawing which showed the information of the E1 line which concerns on 1st Embodiment. It is the sequence figure which showed the example (example where the bundle of E1 line straddles L2 termination | terminus part) which controls an E1 line | wire by the control signal which concerns on 1st Embodiment It is the sequence figure which showed the example (example where the bundle of E1 line does not straddle the L2 termination | terminus part) which controls an E1 line with the control signal which concerns on 1st Embodiment. FIG. 5 is a sequence diagram illustrating an example in which an E1 line is directly controlled other than the exchange of control signals according to the first embodiment. It is the block diagram shown about the functional structure of the local exchange which concerns on 2nd Embodiment, and its peripheral connection structure.

(A) First Embodiment Hereinafter, a first embodiment of an exchange apparatus and a control method for the exchange apparatus according to the present invention will be described with reference to the drawings.

(A-1) Configuration of the First Embodiment FIG. 1 is a block diagram showing a functional configuration of a local exchange (hereinafter also referred to as “LE”) 1 according to the first embodiment and a connection configuration around it. FIG.

  In FIG. 1, LE1 includes an L3 termination unit 10, a system management unit 20, two L2 termination units 30 (30-1 to 30-2), and two E1 termination units 40 (40-1 to 40-2). . In addition, the number of E1 termination | terminus part 40 and L2 termination | terminus part 30 arrange | positioned at LE1 is not limited. However, it is assumed that one L2 termination portion 30 is arranged as a set in one E1 termination portion 40. That is, in LE1, description will be made assuming that the number of E1 termination units 40 arranged is the same as that of L2 termination units 30. The L3 termination unit 10 of LE1 is assumed to be connected to the upper network N. Although the communication system of the network N is not limited, for example, an IP communication network or the like can be applied. LE1 is assumed to be connected to three AN2s (2-1 to 2-3) via 32 E1 lines 3 (3-0 to 3-31). AN2 (2-1 to 2-3) is a subscriber transmission device, and accommodates (connects) a plurality of (any number up to the number that can be accommodated by E1 lines connected by each AN2) subscriber terminals 4 ) Note that the number of AN2s connected to LE1 and the number of E1 lines 3 are not limited to the above example. Here, it is assumed that ten E1 lines 3-0 to 3-9 are connected to AN2-1. It is assumed that ten E1 lines 3-10 to 3-10 are connected to AN2-2. Also, it is assumed that 12 E1 lines 3-20 to 3-31 are connected to AN2-3.

  It is assumed that an E1 line number is assigned to each E1 line as an identifier for identifying with the layer of the E1 termination unit 40. Further, it is assumed that a V5 link number is assigned to each E1 line as an identifier on the V5.2 interface (protocol). In the following, it is assumed that 0 to 31 are assigned to the E1 lines 3-0 to 3-31 as E1 line numbers. In the following, it is assumed that V1 link numbers 0 to 31 are assigned to the E1 lines 3-0 to 3-31, respectively. Here, in order to simplify the explanation, the E1 line number assigned to each E1 line and the V5 link number are the same numbers, but may actually be different numbers. Note that the correspondence between the E1 line number and the V5 link number is managed by LE1, and details will be described later.

  LE1 is a switching device that can be connected through the V5.2 interface as seen from AN2.

  The LE 1 performs control processing of a plurality of E1 lines as one unit (hereinafter referred to as “E1 line management unit”) according to the V5.2 interface. However, the line management unit must be configured to include a minimum of 2 to a maximum of 16 E1 lines in accordance with the specifications of the V5.2 interface. In this embodiment, a description will be given on the assumption that one E2 line of one E1 line management unit is connected to one AN2.

  The E1 line constituting the E1 line management unit on the V5.2 interface is roughly divided into two channels, a C channel and a bearer channel. The C channel is a channel for transmitting and receiving control signals for controlling a plurality of E1 lines constituting the E1 line management unit. The bearer channel is a channel that transmits and receives user data (for example, voice data transmitted and received by a subscriber terminal). Due to the specifications of the V5.2 interface, it is possible to mix bearer channels and C channels in one E1 line. In addition, due to the specifications of the V5.2 interface, it is necessary to form C channels for at least two E1 lines in one E1 line management unit.

  The L3 termination unit 10 terminates the E1 line at the layer 3 on the V5.2 interface (that is, terminates for each E1 line management unit), and performs communication control in the E1 line management unit.

  The L3 termination unit 10 includes a signal processing unit 11 and a termination unit 12.

  The signal processing unit 11 performs an exchange process between the E1 line terminated by the L3 termination unit 10 and the network N controlled by a predetermined protocol. For example, the signal processing unit 11 may adopt SIP (Session Initiation Protocol) as a protocol for processing call control on the network N. Further, the signal processing unit 11 may employ RTP / RTCP (Real-time Transport Protocol / RTP Control Protocol) as a protocol for performing media communication on the network N. In this embodiment, the device (unit) that executes the call control processing and the media communication processing is configured by a single signal processing unit 11, but each processing may be configured by separate devices. Good.

  The termination unit 12 terminates the E1 line (that is, terminates for each E1 line management unit) based on the V5.2 protocol, and performs line control for each terminated E1 line.

  The system management unit 20 manages information related to the connection configuration of the E1 line for each E1 line management unit, and has a function of controlling the termination unit 12 and the like based on the managed information. In this embodiment, each E1 line management unit may be configured to be connected across a plurality of E1 termination units 40 and L2 termination units 30. Therefore, the system management unit 20 manages information related to the connection configuration of the E1 line for each E1 line management unit, and controls the termination unit 12 based on the information. As a result, the termination unit 12 can perform E1 line control for each E1 line management unit (that is, E1 line control based on V5.2 protocol).

  The system management unit 20 of this embodiment stores and manages the AN connection information management table T1 and the E1 line management table T2 as information related to the connection configuration of the E1 line in each E1 line management unit. Detailed configurations of the AN connection information management table T1 and the E1 line management table T2 will be described later.

  Next, the internal configuration of the E1 termination units 40-1 and 40-2 will be described.

  The E1 termination units 40-1 and 40-2 respectively have AN side interfaces 41-1 and 41-2, L2 side interfaces 42-1 and 42-2, and L3 side interfaces 43-1 and 43-2.

  The AN-side interface 41-1 is an interface that communicates with AN2-1 and AN2-2. In this embodiment, each of the AN side interfaces 41-1 and 41-2 includes 16 interface IFs that connect one E1 line. Hereinafter, the 16 interface IFs included in the AN-side interface 41-1 are referred to as IF0 to IF15. The 16 interface IFs provided in the AN-side interface 41-2 are referred to as IF16 to IF31. Here, it is assumed that E1 lines 3-0 to 3-15 (E1 lines with E1 line numbers 0 to 15) are connected to the interfaces IF0 to IF15 of the AN side interface 41-1. It is also assumed that E1 lines 3-16 to 3-31 (E1 lines with E1 line numbers 16 to 31) are connected to the interfaces IF16 to IF31 of the AN side interface 41-2.

  The L2 side interfaces 42-1 and 42-2 are interfaces for connecting to the L2 termination units 30-1 and 30-2, respectively. The L3 side interfaces 43-1 and 42-2 are interfaces for connecting to the L3 termination unit 10, respectively.

  The E1 terminators 40-1 and 40-2 send the C channel signals (control signals) included in the connected E1 line 3 via the L2 side interfaces 42-1 and 42-2. 1 and 30-2 are formed as communication paths. Further, the E1 termination units 40-1 and 40-2 use the L3 side interfaces 43-1 and 42-2 for the bearer channel included in the communication of the E1 line 3 (including signals related to the line control of the bearer channel). Thus, a communication path to be directly connected to the L3 terminal unit 10 (not through the L2 terminal units 30-1 and 30-2) is formed. Accordingly, the E1 termination units 40-1 and 40-2 receive the control directly from the L3 termination unit 10 (the L2 termination units 30-1 and 30-2) for the control of each E1 line (control of each bearer channel). It is configured to receive control without going through).

  Specifically, for example, when a signal arrives from the ANs 2-1 and 2-2, the AN side interface 41-1 identifies the signal (identifies whether it is a C channel signal or a bearer channel signal). However, in the case of a C channel signal, it may be distributed to the L2 side interfaces 42-1 and 42-2, and the bearer channel signal may be distributed to the L3 side interfaces 43-1 and 43-2. Further, for example, the AN-side interfaces 41-1 and 41-2 may identify whether the signal is a C channel signal or a bearer channel signal based on the header of the incoming signal, the interface IF from which the signal has arrived, or the like. Good.

  Next, a detailed configuration of the system management unit 20 will be described.

  The system management unit 20 stores an AN connection information management table T1 and an E1 line management table T2 as information related to the E1 line connection configuration of each E1 line management unit (hereinafter also referred to as “line information”).

  The AN connection information management table T1 is configured as shown in FIG.

  As shown in FIG. 2, the AN connection information management table T1 has a configuration in which a V5 link number and an E1 line number are registered in association with each AN2. In other words, in the AN connection information management table T1, identifiers (E1 line number and V5 link number) of the E1 line connected to each AN2 are registered.

  The AN connection information management table T1 shown in FIG. 2 includes items of “connection destination AN”, “V5 link number”, and “E1 line number”.

  “Destination AN” indicates an identifier of any AN2. In FIG. 2, the identifiers of AN2-1, 2-2, and 2-3 are illustrated as “AN2-1”, “AN2-2”, and “AN2-3”, respectively. The format is not limited.

  “V5 link number” is an item to which a link number is input as an identifier controlled and managed by the V5.2 interface. “E1 line number” is an item in which an E1 line number is input. The E1 line numbers 0 to 31 of this embodiment correspond to the IFs 0 to 31 of the E1 termination unit 40 and the E1 lines 3 to 0 to 3-31. In FIG. 2, for example, it can be read that the connection destination AN 2-1 accommodates (connects) 10 E1 lines (E1 line numbers 0 to 9 and V5 link numbers 0 to 9). The contents of the AN connection information management table T1 will be described on the assumption that the contents corresponding to the actual connection configuration are registered (for example, registered by an operator in charge of maintenance operation).

  The system management unit 20 identifies the E1 line (E1 line number and V5 link number corresponding to each E1 line) belonging to the E1 line management unit corresponding to each AN2 by referring to this AN connection information management table T1. can do.

  FIG. 3 is an explanatory diagram showing a configuration example of the E1 line management table T2.

  As shown in FIG. 3, the E1 line management table T2 includes items of “E1 line number”, “connection destination AN”, “E1 line type”, and “notification destination function unit”. The E1 line management table T2 manages information indicating communication paths (communication paths) of channels (bearer channels and C channels) corresponding to each E1 line (each E1 line number).

  “Destination AN” indicates an identifier of AN2 to which the E1 line is connected. The content of “connection destination AN” needs to match the content of the AN connection information management table T1.

  “E1 line type” indicates the type of the E1 line. When the “E1 line type” is “C channel / bearer channel”, it indicates that the E1 line includes a C channel and a bearer channel. Further, when the “E1 line type” is “bearer channel”, it indicates that the E1 line does not include the C channel (that is, only the bearer channel is included). As described above, according to the V5.2 interface specification, one E1 line management unit (one AN2) needs to include two E1 lines whose “E1 line type” is “C channel / bearer channel”. There is.

  The item “notification destination function unit” is an item indicating a direct connection destination (notification destination) when viewed from the L3 termination unit 10 for each communication channel (each bearer channel and each C channel) of each E1 line. . That is, the item “notification destination function unit” indicates a communication path (communication path) in the LE 1 related to each communication channel of each E1 line.

  The item “notification destination functional part” of the E1 line whose “E1 line type” is “bearer channel” is an identifier indicating the E1 termination part 40-1 (in FIG. 3, the characters “E1 termination part 40-1”). Column) or an identifier (character string “E1 termination 40-2” in FIG. 3) indicating the E1 termination 40-2 is registered.

  In addition, the “notification destination function part” item of the E1 line whose “E1 line type” is “C channel / bearer channel” includes the notification destination function part of “C channel” and the notification destination function of “bearer channel”. Part is described (two notification destination function parts are written together). As the notification destination function unit of “bearer channel”, “E1 termination unit 40-1” or “E1 termination unit 40-2” is registered as described above. In addition, as a notification destination function unit of “C channel”, an identifier indicating the L2 termination unit 30-1 (character string “L2 termination unit 30-1” in FIG. 3) or an identifier indicating the L2 termination unit 30-2 (In FIG. 3, a character string “L2 termination 30-2”) is registered. For example, for an E1 line whose E1 line number is “0”, the E1 line type is “C channel / bearer channel”, and the notification destination functional unit is “L2 termination unit 30-1 / E1 termination unit 40-1”. Yes. Therefore, for the E1 line whose E1 line number is “0”, the C channel notification destination function unit is “L2 termination unit 30-1”, and the bearer channel notification destination function unit is “E1 termination unit 40-1.” It shows that it has become.

  In addition, if the value input to “E1 line type” or “notification destination function part” identifies “E1 line type” or “notification destination function part”, for example, a character as shown in FIG. It may be a row or a number.

  By referring to the E1 line management table T2, the system management unit 20 (termination unit 12) can obtain detailed line information for the E1 line specified by the above-mentioned AN connection information management table T1. In particular, if the system management unit 20 (termination unit 12) can know the “notification destination functional unit” to which the E1 line (bearer channel) is connected, one E1 line management unit can be assigned to a plurality of E1 termination units 40. Even when they are connected, direct control instructions for the E1 line can be issued.

  As described above, the line connection means for terminating the line 3 between AN2 and LE1 is realized in the LE1 by the E1 termination unit 40. In the switching apparatus 1, the L2 termination unit 30 realizes a layer 2 termination unit that terminates the signal included in the E1 line 3 at the layer 2. Further, in the switching apparatus 1, the termination unit 12 realizes a layer 3 termination unit that terminates a signal included in the E1 line 3 at the layer 3. Furthermore, in the switching apparatus 1, a control unit that identifies and controls the line corresponding to the control signal is realized by the L3 termination unit 10 including the system management unit 20.

(A-2) Operation of the First Embodiment Next, the operation of the LE 1 of the first embodiment having the above configuration will be described with reference to the drawings.

  In the following description, it is assumed that the contents of the AN connection information management table T1 and the E1 line management table T2 are registered in advance with the contents of FIGS. 4 and 5 are sequence diagrams illustrating an example in which the L3 termination unit 10 controls the E1 line based on a control signal transmitted from the AN 2 (a control signal transmitted via the C channel). FIG. 4 shows a case where one E1 line management unit E1 line is distributed and connected to a plurality of E1 termination units 40 and L2 termination units 30 (ie, one AN2 to a plurality of E1 termination units 40 (L2 terminations). FIG. 11 is a sequence diagram showing the operation of the case of being distributed and connected to the unit 30). On the other hand, FIG. 5 shows a case where one E1 line management unit E1 line is connected to one E1 termination unit 40 (L2 termination unit 30) (that is, one AN2 to E1 termination unit 40 (L2 termination unit 30). It is a sequence diagram showing the operation of (when connected to).

  First, an operation based on the sequence diagram of FIG. 4 will be described.

  FIG. 4 shows an operation when the AN 2-2 transmits a control signal using the C channel of the E1 line 3-10 (E1 line number: 10). In this case, the control signal transmitted by the AN 2-2 from the C channel of the E1 line 3-10 (E1 line number: 10) is the E1 line 3-10 to the E1 line 3 belonging to the E1 line management unit corresponding to the control signal. -19 (E1 line numbers 10 to 10) are bundled and controlled (a control signal based on the V5.2 protocol).

  First, since the control signal transmitted from the AN 2-2 is transmitted using the C channel of the E1 line 3-10, the control signal passes through the E1 termination unit 40-1 and the L2 termination unit 30-1. As a result, the L3 terminal part 10 (terminal part 12) is reached (S101).

  The control signal received by the termination unit 12 is relayed to the system management unit 20 (S102).

  Next, the system management unit 20 specifies an E1 line (E1 line to be controlled instructed on the V5.2 protocol) belonging to the E1 line management unit to be controlled by the received control signal (S103). Specifically, for example, the system management unit 20 extracts the V5 link number (10) of the transmission source of the control signal from the received control signal, and uses the V5 link number as a key to set the AN connection information management table. The connection source AN is specified from T1 (AN2-2 corresponds). Then, the system management unit 20 specifies the E1 line to be controlled using the AN2-2 specified from the AN connection information management table T1 as a key (E1 lines with E1 line numbers 10 to 20 correspond). Further, the system management unit 20 obtains information of the notification destination function unit using each E1 line number specified from the E1 line management table T2 as a key (for each E1 line number, the E1 termination unit 40-1 or the E1 termination unit 40). -2).

  The system management unit 20 instructs the L3 termination unit 10 to control the E1 line specified in step S103 (S104). The E1 lines to be controlled are E1 lines with E1 line numbers 10 to 20. At this time, the system management unit 20 also provides the L3 termination unit 10 with information on the notification destination function unit of each channel (C channel and bearer channel) of each line. Accordingly, the L3 termination unit 10 can also grasp the control result notification destination (notification destination E1 line number and notification destination function unit) corresponding to the control signal received in step S101.

  The L3 termination unit 10 controls the E1 line to be controlled according to the control instruction of the system management unit 20 (S105). In FIG. 4, for the E1 lines with E1 line numbers 10 to 15, the notification destination function unit is “E1 termination unit 40-1”, and therefore, the E1 line numbers 10 to 15 are controlled via this E1 termination unit 40-1. It is shown. For the E1 lines with E1 line numbers 16 to 19, the notification destination function unit is “E1 termination unit 40-2”, which indicates that the E1 line is controlled via the E1 termination unit 40-2. ing.

  Then, the L3 termination unit 10 generates a control result of the E1 line control performed in step S106 (for example, a message indicating the success or failure of the control), and the E1 line and notification destination function according to the control of the system management unit 20 Section (C channel of E1 line 3-10; the notification destination function section transmits to L2 termination section 30-1) (returns) to AN2-2 (S106).

  Next, an operation based on the sequence diagram of FIG. 5 will be described.

  FIG. 5 shows an operation when the AN 2-1 transmits a control signal using the C channel of the E1 line 3-0 (E1 line number: 0). In this case, the control signal transmitted by the AN 2-1 from the C channel of the E1 line 3-0 (E1 line number: 0) is the E1 line 3-0 to E1 line 3 belonging to the E1 line management unit corresponding to the control signal. It is assumed that it is a control signal (control signal based on V5.2 protocol) that controls -9 (E1 line numbers 0 to 9) in a bundle.

  Since the control signal sent from the AN 2-1 is sent using the C channel of the E1 line 3-0, the control signal passes through the E1 termination unit 40-1 and the L2 termination unit 30-1. , The L3 terminal part 10 (terminal part 12) is reached (S201).

  The control signal received by the termination unit 12 is relayed to the system management unit 20 (S201).

  Next, the system management unit 20 specifies an E1 line (E1 line to be controlled as instructed on the V5.2 protocol) belonging to the E1 line management unit to be controlled by the received control signal (S202). Specifically, for example, the system management unit 20 extracts the V5 link number (0) of the transmission source of the control signal from the received control signal, and uses the V5 link number as a key to set the AN connection information management table. The connection source AN2 is identified from T1 (AN2-1 corresponds). Then, the system management unit 20 specifies the E1 line to be controlled by using the AN2-1 specified from the AN connection information management table T1 as a key (E1 lines with E1 line numbers 0 to 9 correspond). Further, the system management unit 20 obtains information on the notification destination function unit using each E1 line number specified from the E1 line management table T2 as a key (the E1 termination unit 40-1 is applicable to all E1 line numbers). (S203).

  The system management unit 20 instructs the L3 termination unit 10 to control the E1 line specified in step S203 (S204). The E1 lines to be controlled are E1 lines with E1 line numbers 0-9. At this time, the system management unit 20 also provides the L3 termination unit 10 with information on the notification destination function unit of each channel (C channel and bearer channel) of each line. As a result, the L3 termination unit 10 can also grasp the notification destination (the E1 line number of the notification destination and the notification destination function unit) of the control result corresponding to the control signal received in step S201.

  The L3 termination unit 10 controls the E1 line to be controlled according to the control instruction of the system management unit 20 (S205). In FIG. 5, for the E1 lines with E1 line numbers 0 to 9, the notification destination function unit is “E1 termination unit 40-1”, so that the E1 line number is controlled via this E1 termination unit 40-1. It is shown.

  Then, the L3 termination unit 10 generates a control result of the E1 line control performed in step S205 (for example, a message indicating the success or failure of the control), and the E1 line and the notification destination function according to the control of the system management unit 20 Unit (the C channel of the E1 line 3-0; the notification destination function unit is the L2 termination unit 30-1) is used to transmit (reply) the control signal related to the processing result to the AN 2-1 through the C channel (S206).

  FIG. 6 is a sequence diagram illustrating an example in which the L3 termination unit 10 controls individual E1 lines in addition to the exchange of control signals.

  When an event for directly controlling the E1 line occurs, the L3 termination unit 10 requests the system management unit 20 to acquire data of the E1 line to be controlled for the connection destination AN2 (S301). For example, it is assumed that the L3 termination unit 10 inquires about data of the E1 line based on the V5 link number. The L3 termination unit 10 may be configured to make an inquiry based on the E1 line number.

  Next, the system management unit 20 specifies an E1 line to be controlled (E1 line to be controlled instructed on the V5.2 protocol) (S302). For example, the system management unit 20 specifies the E1 line number of the corresponding E1 line using the V5 link number inquired from the AN connection information management table T1 as a key (for example, when the V5 link number is 12, E1 line number 12). Further, the system management unit 20 obtains information on the notification destination function unit using each E1 line number specified from the E1 line management table T2 as a key.

  The system management unit 20 returns the acquired E1 line data to the L3 termination unit 10 (S303).

  The L3 termination unit 10 issues a control instruction for the E1 line (bearer channel) via the corresponding E1 termination unit 40 (that is, not via the L2 termination unit 30) according to the returned E1 line data ( S304). FIG. 6 shows that the E1 line of E1 line number 12 is controlled via the E1 termination unit 40-1 because the notification destination function unit is “E1 termination unit 40-1”. ing.

  Upon receiving the instruction, the E1 termination unit 40 controls the designated E1 line, and notifies the L3 termination unit 10 of the processing result.

  As described above, the L3 termination unit 10 directly controls individual E1 lines depending on the event. However, when controlling a plurality of lines (including the E1 line management unit), the above-described steps S301 to S304 are performed. This can be done by repeating the process.

(A-3) Effects of First Embodiment According to this embodiment, the following effects can be achieved.

  In LE1, the system management unit 20 manages the connection information data of the E1 line (in this embodiment, managed by the AN connection information management table T1 and the E1 line management table T2). By controlling the E1 line, the L3 termination unit 10 directly controls the E1 line (E1 termination unit 40). That is, LE1 controls the E1 line (bearer channel) without going through the L2 termination unit 30. In other words, LE1 controls the E1 line which cannot be controlled because it is outside the control range of the L2 termination unit 30 in the existing system. Thereby, in LE1, even when an E1 line of one E1 line management unit is connected to a plurality of E1 termination units 40 (L2 termination unit 30), the termination unit 12 controls the system management unit 20 (AN connection information management). Based on the table T1 and the E1 line management table T2), the E1 line can be controlled.

  For example, when only one E1 line of the E1 termination unit 40 connected to the AN2 is available, the conventional LE cannot be used for the connection with the AN2 due to the specification, and the accommodation efficiency of the E1 line decreases. Was. However, in the LE 1 of the first embodiment, if there is another E1 termination unit 40, the above-described one E1 line can be used as an additional line with only a bearer line, and E1 can be more efficiently performed. A line can be accommodated.

(B) Second Embodiment Hereinafter, a second embodiment of the exchange apparatus and the exchange apparatus control method according to the present invention will be described with reference to the drawings.

(B-1) Configuration of the Second Embodiment FIG. 7 is a block diagram showing the configuration of the LE 1 according to the second embodiment. The same and corresponding parts as those in FIG. 1 according to the first embodiment are shown in FIG. The same and corresponding reference numerals are attached.

  The difference from FIG. 1 is that the system management unit 20 is provided outside the LE 1 via a network M (for example, an IP network).

(B-2) Operation of Second Embodiment The operation of the second embodiment is the same as that of the first embodiment, except that the L3 termination unit 10 communicates with the system management unit 20 via the network M using existing technology. Since the operation is the same as that in FIG.

(B-3) Effects of Second Embodiment In addition to the effects of the first embodiment, the system management unit 20 is arranged outside, so that a more flexible system operation can be performed.

(C) Other Embodiments In addition to the above-described embodiments, modified embodiments exemplified below can be given.

  (C-1) In each of the above embodiments, the case where the present invention is applied to an exchange device that can be connected through the V5.2 interface as viewed from the AN 2 is not limited to this. For example, other V5 .2 It may be applied to an exchange device that can be connected by an interface similar to the two interfaces.

  (C-2) In each of the above-described embodiments, an example in which the switching apparatus according to the present invention is adapted to the V5.2 interface has been described. However, the configuration includes a line connection unit (E1 termination unit 40), L2 termination unit, and L3 termination unit. It may be applied to other interfaces. In each of the above embodiments, the minimum number of lines in each E1 line management unit has been described as 2 lines (the minimum number of lines required for the C channel) in conformity with the V5.2 interface. You may make it set the minimum number of lines beyond it on design.

  DESCRIPTION OF SYMBOLS 1 ... LE, 2 (2-1 to 2-3) ... AN, 3 (3-0 to 3-31) ... E1 line, 10 ... L3 termination | terminus part, 11 ... Signal processing part, 12 ... Termination part, 20 ... System management unit, 30, 30-1, 30-2 ... L2 termination unit, 40, 40-1, 40-2 ... E1 termination unit, 41, 41-1, 41-2 ... AN side interface, 42, 42- DESCRIPTION OF SYMBOLS 1, 42-2 ... System L2 side interface, 43, 43-1, 43-2 ... L3 side interface, T1 ... AN connection information management table, T2 ... E1 line management table, N, M ... Network.

Claims (5)

A plurality of line connection means for connecting to one or a plurality of transmission apparatuses via a plurality of lines and terminating each of the lines; and a layer 2 for terminating the signal of the line at layer 2 corresponding to each of the line connection means Termination means, layer 3 termination means for terminating the signal of the line at layer 3, and control means,
The line connection means connects a communication path for connecting a bearer channel included in the line to the layer 3 termination means and a control signal channel for transmitting and receiving control signals included in the line to the layer 2 termination means. Forming a communication channel for
The layer 2 termination means forms a communication path for connecting the control signal channel to the layer 3 termination means,
The switching means manages line information corresponding to each control signal, specifies a line corresponding to the received control signal, and causes the layer 3 termination means to control the specified line. .   2. The switching apparatus according to claim 1, wherein the control unit manages the line information by controlling the line information with a plurality of lines as one line management unit.   3. The switching apparatus according to claim 1, wherein a minimum number of lines equal to or greater than 2 is set for the number of lines included in the line management unit.   4. The switching apparatus according to claim 1, wherein the line information includes information on a notification destination for each line as viewed from the layer 3 termination unit. The switching apparatus control method includes a plurality of line connection means for connecting to one or a plurality of transmission apparatuses via a plurality of lines, and terminating each of the lines, and the line in layer 2 corresponding to each of the line connection means. A layer 2 termination unit that terminates the signal, a layer 3 termination unit that terminates the signal of the line in layer 3, and a control unit.
The line connection means connects a communication path for connecting a bearer channel included in the line to the layer 3 termination means and a control signal channel for transmitting and receiving control signals included in the line to the layer 2 termination means. Forming a communication channel for
The layer 2 termination means forms a communication path for connecting the control signal channel to the layer 3 termination means,
The switching means manages line information corresponding to each control signal, specifies a line corresponding to the received control signal, and causes the layer 3 termination means to control the specified line. Control method.

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