JP5986029B2 - Optical transmission equipment - Google Patents

Description

  The present invention relates to an optical transmission device in the field of optical communication.

  In recent years, research and development of digital coherent optical transmission technology using digital signal processing for modulation / demodulation of signal light has been energetically advanced. In the digital coherent optical transmission technology, it is possible to execute modulation / demodulation to generate various multilevel signal lights by utilizing a programmable electronic circuit without changing hardware. Therefore, it can be said that the digital coherent optical transmission technique is a transmission method suitable for controlling the multilevel of multilevel signal light.

  In recent years, a transmission technique has been proposed in which the transmission capacity is increased or decreased by controlling the multilevel degree of multilevel signal light (Non-Patent Document 1). With such a technique, an optical transmission apparatus having a function (Non-Patent Document 2) for multiplexing a plurality of client signals and accommodating them in a line signal, according to the amount of client signals accommodated in the line signal (line side interface ( It is possible to adaptively adjust the signal light bit rate of (I / F).

H. Y. Choi, T. Tsuritani, I. Morita, “Multi-format and multi-rate transmitter for flexible and elastic optical networks,” OECC2012, 6B4-3. ITU-T Recommendation G.709, “Interfaces for the Optical Transport Network (OTN),” 2012.

  However, in the conventional optical transmission apparatus, even if the signal optical bit rate (transmission speed) of the line-side I / F is increased, the number of client-side I / Fs adapted to the transmission speed is changed to the line-side I / F. There is a problem that it cannot be connected.

  The present invention has been made in view of the above-described problems. According to the present invention, in an optical transmission device capable of controlling the transmission speed of the line side I / F, a number of client side I / Fs adapted to the transmission capacity of the line side I / F can be connected to the line side I / F. The purpose is to provide technology.

  The present invention can be realized as an optical transmission device, for example. An optical transmission device according to one embodiment of the present invention includes a plurality of client-side interfaces (I / F) that transmit or receive client signals to and from corresponding counterpart devices on the client side, and A plurality of line side I / Fs that transmit or receive a line signal containing at least one of a plurality of client signals corresponding to the plurality of client side I / Fs with a corresponding device on the side; A cross-connect switch provided between the plurality of client-side I / Fs and the plurality of line-side I / Fs for switching a connection state between each client-side I / F and each line-side I / F; When increasing or decreasing the number of client side I / Fs connected to a specific line side I / F via the cross-connect switch, the increase is made. After the decrease, the connection so that the client signal corresponding to the client side I / F connected to the specific line side I / F can be accommodated in the line signal corresponding to the specific line side I / F. And control means for controlling the state and the transmission speed of the specific line side I / F.

  According to the present invention, in an optical transmission device capable of controlling the transmission speed of the line-side I / F, a number of client-side I / Fs adapted to the transmission capacity of the line-side I / F can be connected to the line-side I / F. It becomes. Further, since the number of client-side I / Fs suitable for the transmission capacity of the line-side I / F can be accommodated in the line-side I / F, the link utilization rate on the line side can be improved.

The block diagram which shows the structure of the transmission side in the optical transmission apparatus which concerns on embodiment of this invention. The block diagram which shows the structure of the receiving side in the optical transmission apparatus which concerns on embodiment of this invention. 6 is a flowchart illustrating a control procedure when increasing or decreasing a client-side I / F connected to a line-side interface (I / F) in the optical transmission apparatus according to the embodiment of the present invention. The block diagram which shows the specific structural example of the transmission side in an optical transmission apparatus. The block diagram which shows the specific structural example of the receiving side in an optical transmission apparatus.

  Hereinafter, exemplary embodiments of the present invention will be described with reference to the drawings. In the following drawings, components that are not necessary for the description of the embodiments are omitted from the drawings.

<Configuration of optical transmission device>
First, a basic concept according to an embodiment of the present invention will be described with reference to FIGS. 1 and 2 are block diagrams showing configurations on the transmission side and the reception side in the optical transmission apparatus according to the present embodiment, respectively. As shown in FIGS. 1 and 2, the optical transmission device 100 has the same configuration on the transmission side and the reception side.

  The optical transmission device 100 has a configuration on the transmission side (FIG. 1), k (k is an integer of 1 or more) client side interfaces (I / F) 102-1 to k, cross-connect switches 101, n (n is It includes an integer of 1 or more) line side I / Fs 103-1 to 103-n, a control unit 110, and a communication unit 120. Further, the optical transmission apparatus 100 has, as a receiving side configuration (FIG. 2), k client-side I / Fs 202-1 to 202-1 to k, a cross-connect switch 201, and n line-side I / Fs 203-1 to 203-1. A control unit 110 and a communication unit 120. As described above, the optical transmission apparatus 100 includes the control unit 110 and the communication unit 120 that are common to the transmission side and the reception side.

  Note that “transmission side” and “reception side” in FIG. 1 refer to line side I / Fs 103-1 to 10-n and opposing devices (optical transmissions) connected to the line side I / Fs 103-1 to 103-1, respectively. Communication with the device). That is, the configuration corresponding to communication from the optical transmission apparatus 100 to the line-side counter apparatus is “transmission side”, and the configuration corresponding to communication from the line-side counter apparatus to the optical transmission apparatus 100 is “reception side”.

(Client side I / F)
The k client I / Fs 102-1 to 10 (202-1 to k) are connected to the cross-connect switch 101 (201). The client-side I / Fs 102-1 to 102-1 to k and the client-side I / Fs 202-1 to 202-1 to k respectively receive and transmit a client signal with a corresponding opposite device (client device) on the client side. Each of the client-side I / Fs 102-1 to 102-k has a function of converting the format of a signal received from the opposite device and transmitted to the cross-connect switch 101 from a format of the client signal to a signal format handled by the cross-connect switch 101. The client-side I / Fs 202-1 to 202-1 to k have a function of converting the format of a signal received from the cross-connect switch 201 and transmitted to the opposite device from a signal format handled by the cross-connect switch 201 to a client signal format. Have.

(Cross-connect switch)
As shown in FIG. 1 (FIG. 2), the cross-connect switch 101 (201) includes client side I / Fs 102-1 to k (202-1 to k) and line side I / Fs 103-1 to 10-n ( 203-1 to n). On the line side of the cross-connect switch 101 (201), n line-side I / Fs 103-1 to n (203-1 to n) are connected.

Each of the line side I / Fs 103-1 to n (203-1 to n) is connected to at least one port included in the cross-connect switch 101 (201). In the present embodiment, the line-side I / F 103-1~n (203-1~n), respectively, m _x number (m _x included in the cross-connect switch is an integer of 1 or more, x is an integer of 1~n ) Port. Since there are n line-side I / Fs, the number of ports on the line side of the cross-connect switch 101 (201) is the sum of m _x (x = 1, 2,..., N).

  The cross-connect switch 101 (201) has a function of switching a signal from a certain input port to a certain output port. The cross-connect switch 101 (201) can be switched to any output port, regardless of the signal from any input port. Thus, the cross-connect switch 101 (201) has a function of switching the connection state between each client-side I / F and each line-side I / F.

(Line side I / F)
The line side I / Fs 103-1 to 103-n and the line side I / Fs 203-1 to 203-1 to n respectively transmit and receive line signals to and from corresponding devices (optical transmission devices) on the line side. The line-side I / Fs 203-1 to 203-n have a function of converting the format of a signal received from the opposite device and transmitted to the cross-connect switch 201 from a line signal format to a signal format handled by the cross-connect switch 201. The line side I / Fs 103-1 to 103-n have a function of converting the format of a signal received from the cross-connect switch 101 and transmitted to the opposite device from a signal format handled by the cross-connect switch 101 to a line signal format. Have.

  The line-side I / Fs 103-1 to 10-n (203-1 to n) further have a function of multiplexing a plurality of client signals and accommodating them in a line signal. At least one client side I / F is connected to the line side I / Fs 103-1 to 10-n (203-1 to n) via the cross-connect switch 101 (201). The line side I / Fs 103-1 to n (203-1 to n) are connected client side I / Fs among the client signals corresponding to the client side I / Fs 201-1 to k (201 to k). A line signal containing a client signal corresponding to is transmitted (received). The line side I / Fs 203-1 to 203-n take out each client signal accommodated in the line signal received from the opposite device, and connect to the client corresponding to the client signal connected via the cross-connect switch 101. To the side I / F.

The line side I / Fs 103-1 to 10-n (203-1 to n) can variably control the transmission rate of the line signal in accordance with the amount of client signals accommodated in the line signal. Control of the transmission rate of the line signal can be realized by controlling the multilevel (the number of modulation multilevel) of the line signal. In Figure 1, each line side I / F 103-1~n (203-1~n) is, m _x number of cross connects 101 (201) (x is an integer of 1 to n) is connected to the port of because you are, it can accommodate a connection from m _x number of client-side I / F. That is, each line side I / F 103-1~n (203-1~n) is a line signal containing the m _x number of client signals to line signal, transmit (receive) between the opposing device possible is there.

  In the following, for example, when “line side I / F accommodates client side I / F” is described, it means the following. That is, the line side I / F accommodates the connection from the client side I / F, and the client side I / F accommodates the client signal transmitted / received (that is, corresponding to the client side I / F). It shall mean handling line signals.

(Control part)
The control unit 110 controls the client side I / Fs 102-1 to 102-1 and 202-1 to k, the cross-connect switches 101 and 201, and the line side I / Fs 103-1 to n and 203-1 to n. It has a control function (as will be described later with reference to FIG. 3).

(Communication Department)
The communication unit 120 has a function of receiving a command from an external network (NW) management system and transmitting the received command to the control unit 110. The communication unit 120 has a function of outputting the alarm output from the control unit 110 to the outside (NW management system or the like).

  As described above, the optical transmission device 100 is an example of an optical transmission device capable of controlling the transmission speed of the line side I / Fs 103-1 to n (203-1 to n). In such an optical transmission device 100, for example, as described above, it is necessary to connect a number of client-side I / Fs suitable for the transmission speed of the line-side I / F to the line-side I / F. . More specifically, even when the number of client-side I / Fs connected to the (specific) line-side I / F is increased, the capacity of the line-side I / F (transmission speed, number of connection ports, etc.) It is necessary to appropriately control the number of client side I / Fs to be connected within the range.

  In order to achieve this, in the present embodiment, the control unit 110 increases or decreases the number of client-side I / Fs connected to a specific line-side I / F via the cross-connect switch 101. The connection state of the cross-connect switch 101 and the transmission speed of the line side I / Fs 103-1 to 103-1 are controlled as follows. Specifically, the control unit 110 determines that the client signal corresponding to the client side I / F connected to the specific line side I / F after the increase or decrease is a line corresponding to the specific line side I / F. Control is performed so that the signal can be accommodated. Note that the control unit 110 may similarly control not only the transmission side but also the reception side cross-connect switch 201 and the like.

<Control procedure in optical transmission device>
Below, with reference to FIG. 3, the specific control by the control part 110 in the optical transmission apparatus 100 which concerns on this embodiment is demonstrated. It is assumed that the transmission I / F and the reception I / F in the optical transmission apparatus 100 are paired. That is, the control unit 110 similarly controls each component on the transmission side (FIG. 1) and the reception side (FIG. 2). Therefore, hereinafter, the control on the transmission side will be described, but the same applies to the control on the reception side.

  When the optical transmission device 100 is activated and starts operating, the control unit 110 advances the process to S301. In S301, the control unit 110 determines the number of client side I / Fs 102-1 to 102-1 connected to the line side I / Fs 103-1 to 10-n based on a command received from the outside via the communication unit 120. Check instructions for increase / decrease. In the present embodiment, a case where such a command is received from the NW management system is assumed as an example. Further, the number of the specific line side I / F to be indicated by the received command is α (α is an integer of 1 to n), and the number of client side I / Fs connected to the line side I / F. Is β (β is an integer of 0 to k).

  In S301, based on the received command, the control unit 110 reduces the number β of client-side I / Fs connected to the line-side I / F 103-α via the cross-connect switch 101. When increasing to S304, the process proceeds to S302. In S301, when the command itself is not received, the control unit 110 waits in S301 until the command is received (repetition of the determination process).

(When increasing the number of client side I / Fs connected to the line side I / F)
In S302, the control unit 110 determines whether or not the increased β client-side I / Fs can be accommodated in the line-side I / F 103-α. If possible, the process proceeds to S303. That is, the control unit 110 can accommodate the client signals corresponding to β client-side I / Fs connected to the line-side I / F 103-α after the increase in the line signals corresponding to the line-side I / F. It is determined whether or not.

More specifically, the control unit 110 determines that the total capacity corresponding to the β client-side I / Fs connected to the line-side I / F 103-α after the increase is in advance with respect to the line-side I / F. It is determined whether the capacity is equal to or less than a predetermined maximum capacity. Here, the total volume corresponds to the sum of the transmission rate of the line-side I / F 103-alpha connected to the β-number of client signals corresponding to the client-side I / F after the increase _(BW client_β). The maximum capacity corresponds to the maximum transmission speed (BW _{line_α} ) of the line signal in the line side I / F 103-α. Note that the maximum transmission speed of the line-side I / F 103-α is set as an initial value in advance when the optical transmission device 100 is shipped from the factory, for example.

In S302, when the line side I / F 103-α does not have enough capacity to accommodate the β client side I / Fs (BW _{line_α} <BW _{client_β} ), the control unit 110 cannot be accommodated. judge. On the other hand, when the line-side I / F 103-α has a capacity for accommodating β client-side I / Fs (BW _{line_α} ≧ BW _{client_β} ), the control unit 110 determines that it can be accommodated. By such determination processing, the control unit 110 determines whether or not β client-side I / Fs can be accommodated in the line-side I / F within the range of the maximum transmission speed of the line-side I / F 103-α. Determine.

As shown in a second embodiment to be described later, the total capacity used for the determination processing in S302 is the number (β) of client-side I / Fs connected to the line-side I / F 103-α after the increase, and the maximum capacity May be the number of ports (m _α ) of the cross-connect switch 101 to which the line-side I / F 103-α is connected. That is, the capacity corresponding to the number of client side I / Fs (number of lines) that can be accommodated (connected) in the line side I / F 103-α via the cross-connect switch 101 may be used for the determination processing in S302. Good. Thus, the control unit 110 can accommodate β client-side I / Fs in the line-side I / F within the range of the number of client-side I / Fs connectable to the line-side I / F 103-α. Determine whether or not.

  When the processing proceeds from S302 to S303, the control unit 110 communicates an alarm indicating that the capacity for newly accommodating the client-side I / F is insufficient in the line-side I / F 103-α. The data is output to the outside (NW management system here) via the unit 120. That is, the alarm indicates that the number of client side I / Fs connected to the line side I / F 103-α cannot be increased. After outputting the alarm, control unit 110 returns the process to S301.

On the other hand, when the process proceeds from S302 to S306, the control unit 110 increases the transmission rate of the line-side I / F 103-α. Specifically, the control unit 110, the following BW _{Line_arufa,} and, as a BW _{Client_beta} more transmission rate, and sets the transmission rate of the line-side I / F 103-α. Further, in S307, the control unit 110 causes the cross-connect switch 101 to connect the client side I / F to be increased, which is newly connected to the line side I / F 103-α. At this time, the control unit 110 may specify the number (1 to k) of the client side I / F to be newly connected to the line side I / F 103-α with respect to the cross-connect switch 101. Thereafter, the control unit 110 returns the process to S301.

(When reducing the number of client side I / Fs connected to the line side I / F)
In step S304, the control unit 110 causes the cross-connect switch 101 to release the connection between the client-side I / F to be reduced and the line-side I / F 103-α. At this time, the control unit 110 may specify the number (1 to k) of the client side I / F that should release the connection with the line side I / F 103-α to the cross-connect switch 101. Further, in S305, the control unit 110 decreases the transmission speed of the line side I / F 103-α. For example, the control unit 110 may reduce the transmission speed of the line-side I / F 103-α by an amount corresponding to the transmission speed of the client signal corresponding to the client-side I / F that has released the connection. Thereafter, the control unit 110 returns the process to S301.

[Example 1]
Next, as specific examples for the above-described embodiment, Examples 1 and 2 will be described with reference to FIGS. 3 to 5. 4 shows a configuration example on the transmission side of the optical transmission apparatus 100, and FIG. 5 shows a configuration example on the reception side of the optical transmission apparatus 100. In both the first and second embodiments, the optical transmission device 100 includes six client-side I / Fs 102-1 to 102-1 and four line-side I / Fs 103-1 to 10, and the line-side I / F. An example in which the number of client-side I / Fs connected to 103-1 is increased stepwise will be described. Specifically, the control unit 110
(1) Client side I / Fs 102-1 and 102-2
(2) Client side I / Fs 102-3 and 102-4
(3) Client side I / F 102-5
In this order, an attempt is made to increase the number of client side I / Fs connected to the line side I / F 103-1. In the following, the control on the transmission side (FIG. 4) will be described, but the same applies to the control on the reception side (FIG. 5).

Here, the maximum transmission rate of the line side I / F 103-1 is _assumed to be BW _{line_1} . Therefore, the control unit 110 accommodates the client side I / Fs 102-1 to 10-6 in the line side I / F 103-1, within the range of the maximum transmission rate (BW _{line_1} ) of the line side I / F 103-1. Is possible. Also, as shown in FIGS. 4 and 5, the number of ports of the cross-connect switch 101 to which the line side I / F 103-1 is connected is four. For this reason, the control unit 110 can accommodate the client side I / Fs 102-1 to 10-6 in the line side I / F 103-1, within a maximum of four ranges.

(1) Connection of client side I / Fs 102-1 and 102-2 First, the control unit 110 should connect the client side I / Fs 102-1 and 102-2 to the line side I / F 103-1. Is received from the NW management system. In this case, the control unit 110 executes processing as follows according to the flowchart of FIG.

  In S301, the control unit 110 determines to increase the number of client-side I / Fs connected to the line-side I / F 103-1 via the cross-connect switch 101 based on the received command. The process proceeds to S302.

In S302, the control unit 110 determines whether or not the increased two client-side I / Fs 102-1 and 102-2 can be accommodated in the line-side I / F 103-1. Here, it is assumed that the sum of the transmission speeds of the client signals corresponding to the client side I / Fs 102-1 and 102-2 is _{equal to} or less than BW _{line_1} . As a result, the control unit 110 determines that the client side I / Fs 102-1 and 102-2 can be accommodated in the line side I / F 103-1, and advances the process to S306.

  In step S306, the control unit 110 increases the transmission rate of the line-side I / F 103-1, so that the client signals corresponding to the client-side I / Fs 102-1 and 102-2 can be accommodated in the line signal. Set. Further, in S307, the control unit 110 connects the client side I / Fs 102-1 and 102-2 with the line side I / F 103-1 through the cross-connect switch 101. Thereafter, the control unit 110 returns the process to S301.

  In S307, the control unit 110 uses an unused port among the ports of the cross-connect switch 101 connected to the line-side I / F 103-1, and uses the client-side I / F 102-1. And 102-2 and the line side I / F 103-1. Here, since ports 1 to 4 of the cross-connect switch 101 are not used, the ports 1 and 2 are used to connect the client side I / Fs 102-1 and 102-2 and the line side I / F 103-. 1 is connected.

(2) Connection of client side I / Fs 102-3 and 102-4 Next, the control unit 110 should connect the client side I / Fs 102-3 and 102-4 to the line side I / F 103-1. A command indicating this is received from the NW management system. Here, it is assumed that the client-side I / F 102-3 can be newly accommodated in the line-side I / F 103-1. In this case, in step S306, the control unit 110 sets the transmission rate of the line-side I / F 103-1 to a transmission rate that can accommodate the client signal corresponding to the client-side I / Fs 102-1 to 102-3 in the line signal. To do. That is, the transmission speed of the line side I / F 103-1 corresponds to the client side I / F 102-3 in addition to the client signals corresponding to the already accommodated client I / Fs 102-1 and 102-2. The client signal is set to a transmission rate that can be accommodated in the line signal. Further, in step S <b> 307, the control unit 110 connects the client side I / F 102-3 to the line side I / F 103-1 using the port 3 of the cross-connect switch 101. Thereafter, the control unit 110 returns the process to S301.

On the other hand, the client side I / F 102-4 cannot be newly accommodated in the line side I / F 103-1. Specifically, it is assumed that the sum of the transmission speeds of the client signals corresponding to the client side I / Fs 102-1 to _10-4 exceeds BW _{line_1} . As a result, the control unit 110 determines that the client-side I / F 102-4 cannot be accommodated in the line-side I / F 103-1, and advances the processing to S303.

  In S <b> 303, the control unit 110 issues an alarm indicating that the line-side I / F 103-1 has insufficient capacity for newly accommodating the client-side I / F 102-4 via the communication unit 120. Are output to the NW management system, and the process returns to S301. The capacity of the line-side I / F 103-1 is also received when a command indicating that the client-side I / F 102-5 should be connected to the line-side I / F 103-1 is subsequently received from the NW management system. It is assumed that processing similar to that in the case of the client-side I / F 102-4 described above is performed due to the shortage.

  In this embodiment, when increasing the number of client-side I / Fs connected to the line-side I / F 103-1, the client-side I to be connected is based on the maximum transmission rate of the line-side I / F 103-1. Control the number of / F. As a result, a number of client-side I / Fs adapted to the transmission speed of the line-side I / F can be connected to the line-side I / F. Further, since the number of client-side I / Fs adapted to the transmission speed of the line-side I / F can be accommodated in the line-side I / F, the link utilization rate on the line side can be improved.

[Example 2]
In the second embodiment, when the number of client-side I / Fs connected to the line-side I / F 103-1 is increased, the line-side I / F 103-1 is used as the capacity of the line-side I / F 103-1. An example of controlling the number of client-side I / Fs to be connected based on the number of client-side I / Fs (number of lines) that can be accommodated in the network will be described. In this embodiment, even when all the ports of the cross-connect switch 101 to which the line side I / F 103-1 is connected are used, the range of the maximum transmission rate (BW _{line_1} ) of the line side I / F 103-1 is used. The transmission speed of the line signal can be controlled. For simplification of description, description of portions common to the first embodiment may be omitted.

(1) Connection of client side I / Fs 102-1 and 102-2 First, the control unit 110 should connect the client side I / Fs 102-1 and 102-2 to the line side I / F 103-1. Is received from the NW management system. Here, the number (= 2) of client side I / Fs 102-1 and 102-2 connected to the line side I / F 103-1 is the client side I that can be accommodated in the line side I / F 103-1. / F number (= 4) or less. For this reason, in S302, the control unit 110 determines that the client side I / Fs 102-1 and 102-2 can be accommodated in the line side I / F 103-1.

  As a result, in S306, the control unit 110 sets the transmission rate of the line-side I / F 103-1 and the transmission rate capable of accommodating the client signals corresponding to the client-side I / Fs 102-1 and 102-2 in the line signal. Set to. Further, the control unit 110 connects the client side I / Fs 102-1 and 102-2 to the line side I / F 103-1 using the ports 1 and 2 of the cross-connect switch 101 in S307.

(2) Connection of client side I / Fs 102-3 and 102-4 Next, the control unit 110 should connect the client side I / Fs 102-3 and 102-4 to the line side I / F 103-1. A command indicating this is received from the NW management system. Here, the number of client side I / Fs 102-1 to 102-1 to 4 connected to the line side I / F 103-1 (= 4) is the client side I / F that can be accommodated in the line side I / F 103-1. Or less (= 4). For this reason, in S302, the control unit 110 determines that the client side I / Fs 102-3 and 102-4 can be accommodated in the line side I / F 103-1.

  As a result, in S306, the control unit 110 sets the transmission rate of the line-side I / F 103-1 to a transmission rate that can accommodate the client signals corresponding to the client-side I / Fs 102-1 to 10-4 in the line signal. To do. That is, in addition to the client signal corresponding to the already accommodated client I / Fs 102-1 and 102-2, the transmission rate of the line side I / F 103-1 is added to the client side I / Fs 103-3 and 102-2. -4 is set to a transmission rate capable of accommodating the client signal corresponding to the line signal. Further, in S307, the control unit 110 connects the client side I / Fs 102-3 and 102-4 to the line side I / F 103-1 using the ports 3 and 4 of the cross-connect switch 101. Thereafter, the control unit 110 returns the process to S301.

(3) Connection of Client Side I / F 102-5 Next, the control unit 110 sends an instruction indicating that the client side I / F 102-5 should be connected to the line side I / F 103-1 to NW management. Receive from the system. Here, the number of client side I / Fs 102-1 to 102-1 to 5 connected to the line side I / F 103-1 (= 5) is the client side I / F that can be accommodated in the line side I / F 103-1. Exceeds the number of (= 5). Therefore, in S302, the control unit 110 determines that the client-side I / F 102-5 cannot be accommodated in the line-side I / F 103-1, and advances the process to S303.

  In S303, the control unit 110 sends an alarm indicating that the capacity for newly accommodating the client-side I / F 102-5 is insufficient in the line-side I / F 103-1, via the communication unit 120. Are output to the NW management system, and the process returns to S301.

  In the present embodiment, when the number of client side I / Fs connected to the line side I / F 103-1 is increased, the number of client side I / Fs that can be accommodated in the line side I / F 103-1 (line Number) to control the number of client-side I / Fs to be connected. As a result, a number of client-side I / Fs adapted to the number of lines that can be accommodated by the line-side I / F can be connected to the line-side I / F.

It should be noted that the first and second embodiments described above can be implemented in combination as appropriate. Specifically, in S302, the control unit 110
The sum of the transmission rates of the client signals corresponding to the client-side I / F (after increase) connected to the line-side I / F 103-1 is less than or equal to the maximum transmission rate of the line-side I / F 103-1. The number of client-side I / Fs is equal to or less than the number of ports of the cross-connect switch 101 to which the line-side I / F 103-1 is connected;
When both of these are satisfied, it may be determined that the client side I / F can be accommodated in the line side I / F 103-1, and in other cases, it may be determined that the client side I / F cannot be accommodated.

  As described above, according to the above-described various embodiments (examples), the number of client-side I / Fs adapted to the transmission capacity of the line-side I / F, such as the transmission speed and the number of lines that can be accommodated, is set. It becomes possible to connect to the line side I / F. Further, since the number of client-side I / Fs suitable for the transmission capacity of the line-side I / F can be accommodated in the line-side I / F, the link utilization rate on the line side can be improved.

Claims (9)

An optical transmission device,
A plurality of client side interfaces (I / F) each transmitting or receiving client signals to and from corresponding counterpart devices on the client side;
A plurality of line sides each transmitting or receiving a line signal containing at least one of a plurality of client signals corresponding to the plurality of client side I / Fs with a corresponding opposite device on the line side I / F,
A cross-connect switch provided between the plurality of client-side I / Fs and the plurality of line-side I / Fs for switching a connection state between each client-side I / F and each line-side I / F;
When increasing or decreasing the number of client-side I / Fs connected to a specific line-side I / F via the cross-connect switch, the client-side I / F is connected to the specific line-side I / F after the increase or decrease The connection state and the transmission speed of the specific line side I / F are set so that the client signal corresponding to the client side I / F can be accommodated in the line signal corresponding to the specific line side I / F. An optical transmission device comprising: control means for controlling. The control means includes
When increasing the number of client side I / Fs connected to the specific line side I / F, the client signal corresponding to the client side I / F connected to the specific line side I / F after the increase is increased. Determining means for determining whether the signal can be accommodated in a line signal corresponding to the specific line side I / F,
When the determination unit determines that the data cannot be accommodated, the number of client side I / Fs connected to the specific line side I / F is not increased,
When the determination unit determines that the data can be accommodated, the transmission speed of the specific line-side I / F is increased and the client-side I / F to be increased is connected to the specific line-side I / F. The optical transmission device according to claim 1, wherein: The determination means includes
When the total capacity corresponding to the client side I / F connected to the specific line side I / F after the increase is equal to or less than the maximum capacity predetermined for the specific line side I / F 3. The optical transmission apparatus according to claim 2, wherein it is determined that the corresponding client signal can be accommodated in the line signal, and when the maximum capacity is exceeded, it is determined that the corresponding client signal cannot be accommodated. . The total capacity is a sum of transmission rates of client signals corresponding to the client side I / F connected to the specific line side I / F after the increase,
The optical transmission apparatus according to claim 3, wherein the maximum capacity is a maximum transmission rate of a line signal in the specific line side I / F. Each of the plurality of line-side I / Fs is connected to at least one port provided in the cross-connect switch,
The total capacity is the number of client side I / Fs connected to the specific line side I / F after the increase,
The optical transmission apparatus according to claim 3, wherein the maximum capacity is the number of ports of the cross-connect switch to which the specific line side I / F is connected. Each of the plurality of line-side I / Fs is connected to at least one port provided in the cross-connect switch,
The determination means determines in advance a sum of transmission rates of client signals corresponding to the client side I / F connected to the specific line side I / F after the increase with respect to the specific line side I / F. The number of client-side I / Fs that are equal to or less than the maximum transmission speed set and are connected to the specific line-side I / F after the increase is the cross to which the specific line-side I / F is connected It is determined that the corresponding client signal can be accommodated in the line signal when the number is less than or equal to the number of ports of the connect switch, and in other cases, it is determined that the corresponding client signal cannot be accommodated. The optical transmission device according to claim 2. The control means includes
When the determination unit determines that the corresponding client signal cannot be accommodated in the line signal, the number of client side I / Fs connected to the specific line side I / F cannot be increased. The optical transmission device according to claim 2, wherein an alarm indicating the error is output to the outside. The control means includes
When reducing the number of client side I / Fs connected to the specific line side I / F, the connection between the client side I / F to be reduced and the specific line side I / F is released. The optical transmission device according to claim 1, wherein a transmission speed of the specific line side I / F is reduced. The control means includes
2. The transmission rate of the specific line side I / F is controlled by controlling the number of modulation levels for a line signal transmitted or received by the specific line side I / F. 9. The optical transmission device according to claim 8.

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