JP5776976B2 - Optical transmission system - Google Patents

Description

  The present invention relates to an optical transmission system.

  Currently, due to the rapid expansion of the Internet, the number of network devices installed in communication network systems is also increasing rapidly. When a large number of network devices are operated, power consumption becomes enormous, and thus power saving is required.

  Accordingly, a working group of IEEE Energy Effective Ethernet (hereinafter referred to as EEE, which is a registered trademark) was established and standardized as IEEE 802.3az-2010 (see Non-Patent Document 1). According to the EEE technology standardized by IEEE 802.3az-2010, the port usage rate is controlled according to the communication status, and wasteful power is suppressed.

  The EEE technology is applied to a predetermined Ethernet (registered trademark) interface. Specifically, the EEE technology is based on the Ethernet (registered trademark) interface conforming to the standards of 10GBASE-T, 1000BASE-T, 100BASE-TX, 10BASE-T, 10GBASE-KX4, 10GBASE-KR, and 1000BASE-KX. Applied.

IEEE802.3az-2010

However, Non-Patent Document 1 does not discuss a power saving technique for a 40 GbE or 100 GbE interface. In other words, a power-saving technique for an interface that transmits and receives optical signals in parallel using a plurality of lanes has not been studied.
In particular, a power saving technique applied to a transmission apparatus that relays an optical signal over a long distance using a plurality of lanes has not been studied.
The present invention has been made based on the above-described circumstances, and an object of the present invention is to provide an optical transmission system capable of transmitting and receiving optical signals in parallel using a plurality of lanes and saving power. .

  To achieve the above object, according to one aspect of the present invention, in an optical transmission system including a master transmission device and a slave transmission device, each of the master transmission device and the slave transmission device transmits and receives data to be relayed. An access port, a distribution unit that distributes the data to one or more of a plurality of lanes, a plurality of optical transceivers arranged in each of the plurality of lanes, and the master transceiver An interconnection port used for connection between the transmission device and the slave transmission device, and a necessary traffic amount measurement unit that measures a necessary traffic amount that is a data amount per predetermined time received by the access port, and The slave transmission device measures the required traffic volume of the slave transmission device. A required traffic amount notifying means for notifying the master transmission device of the required traffic amount measured by a unit, and a target lane number that is a target number of lanes to be used among the plurality of lanes notified from the master transmission device. And a slave-side optical transceiver controller that individually activates or deactivates the optical transceiver of the slave transmission device, and the master transmission device is measured by the required traffic amount measurement unit of the master transmission device. Based on the required traffic volume and the required traffic volume notified from the slave transmission apparatus, a target lane number calculation unit that calculates the target lane number, and the target lane calculated by the target lane number calculation unit Target lane number notifying means for notifying the slave transmission device of the number; There is provided an optical transmission system comprising: a master side optical transceiver control unit that individually activates or deactivates the optical transceiver of the master transmission device based on the target lane number calculated by the target lane number calculation unit. The

  The present invention provides an optical transmission system capable of transmitting and receiving optical signals in parallel using a plurality of lanes and saving power.

It is a block diagram which shows the schematic structure of the network system which concerns on one Embodiment. FIG. 2 is a block diagram schematically showing a master transmission device applied to the network system of FIG. 1. 1 schematically shows the formats of (a) a negotiation frame, (b) a start notification frame (stop notification frame), and (c) a control frame transmitted and received between a master transmission device and a slave transmission device applied to the network system of FIG. FIG. FIG. 2 is a block diagram schematically showing a slave transmission device applied to the network system of FIG. 1. 3 is a flowchart schematically showing a main routine executed by the master transmission device of FIG. 2. 6 is a flowchart schematically showing a lane number adjustment subroutine in the main routine of FIG. 5. 7 is a flowchart schematically showing a lane number increase subroutine in the lane number adjustment subroutine of FIG. 6. 7 is a flowchart schematically showing a lane number reduction subroutine in the lane number adjustment subroutine of FIG. 6. 5 is a flowchart schematically showing a main routine executed by the slave transmission device of FIG. 4. 10 is a flowchart schematically showing a lane number adjustment subroutine in the main routine of FIG. 9. 11 is a flowchart schematically showing a lane number increasing subroutine in the lane number adjusting subroutine of FIG. 10. FIG. 11 is a flowchart schematically showing a lane number reduction subroutine in the lane number adjustment subroutine of FIG. 10. FIG.

Hereinafter, embodiments of the present invention will be described.
FIG. 1 shows a network system 10 according to an embodiment. The network system 10 includes a LAN (local area network) 12 installed by a user, for example, and the LAN 12 includes a terminal 14 and a user switch 16 connected to the terminal 14.

The network system 10 includes a wide area network 18 installed by, for example, a telecommunications carrier, and the wide area network 18 is an OSI (Open
The LANs 12 are connected at the layer 2 level using the Systems Interconnection (reference model) reference model.

The wide area network 18 includes an accommodation switch 20 connected to the user switch 16 and an optical transmission system 21 arranged between the accommodation switches 20.
The accommodation switch 20 and the user switch 16 are each formed of a switching hub, and the number of user switches 16 connected to the accommodation switch 20 is not limited to the number shown in the figure.

The optical transmission system 21 includes a pair of transmission devices, that is, a master transmission device 22M and a slave transmission device 22S.
Each of the master transmission device 22M and the slave transmission device 22S has an access port 24 connected to the accommodating switch 20 via a communication cable and an interconnection port 26 connected to each other via a communication cable. The access port 24 is a port for transmitting and receiving data to be relayed by the master transmission device 22M and the slave transmission device 22S. The interconnection port 26 is used to connect the master transmission device 22M and the slave transmission device 22S. The communication cable connecting the interconnection ports 26 is made of an optical fiber.

[Master transmission equipment]
Hereinafter, the configuration of the master transmission device 22M will be described. FIG. 2 is a block diagram schematically showing a physical and functional configuration of the master transmission apparatus 22M.
The master transmission device 22M includes a short-distance optical transceiver 28, a short-range PHY-LSI (physical layer large-scale integrated circuit) 30, a MAC-LSI (medium access control large-scale integrated circuit) 32, a long-distance PHY-LSI 34, A long-distance optical transceiver 36, an optical multiplexer / demultiplexer 38, a control device 40, and a storage unit 42 are included.

[Short distance optical transceiver]
The access port 24 is provided integrally with the short-distance optical transceiver 28. The short-distance optical transceiver 28 complies with, for example, the 40GBASE-SR4 standard. The short-distance optical transceiver 28 converts the optical signal received by the access port 24 into an electrical signal, and passes the electrical signal to the short-range PHY-LSI 30. The short-distance optical transceiver 28 converts the electrical signal received from the short-range PHY-LSI 30 into an optical signal and transmits the optical signal from the access port 24.

[Short distance PHY-LSI]
The short-range PHY-LSI 30 performs a process such as a decoding process on the transmission code of the electrical signal received from the short-range optical transceiver 28 and converts the transmission code into a frame. The short-range PHY-LSI 30 performs a process such as an encoding process on the frame of the electrical signal received from the MAC-LSI 32 and converts the frame into a transmission code.

Note that the short-range PHY-LSI 30 includes a reception buffer 46 and a necessary traffic amount measurement unit 48, and the reception buffer 46 temporarily stores the transmission code of the electrical signal received from the short-distance optical transceiver 28.
The required traffic amount measuring unit 48 periodically measures the required traffic amount Mt based on the amount of transmission code stored in the reception buffer 46 and notifies the control device 40 of it. The interval T1 at which the required traffic volume measuring unit 48 measures and notifies the required traffic volume Mt is, for example, 1 second.

  The required traffic amount Mt is the amount of transmission code received by the access port 24 of the master transmission apparatus 22M per predetermined time T2, and in this embodiment, the time T2 is 1 second. Hereinafter, a value obtained by dividing the required traffic amount Mt by the time T2 is also referred to as a required transmission rate Mt / T2.

[MAC-LSI]
The MAC-LSI 32 has a function of passing a frame received from the short distance PHY-LSI 30 to the long distance PHY-LSI 34 and conversely, a function of passing a frame received from the long distance PHY-LSI 34 to the short distance PHY-LSI 30. Have.

The MAC-LSI 32 includes a frame determination unit 50 and a frame insertion / extraction unit 52.
The frame determination unit 50 has a function of identifying the negotiation frame F1, the start notification frame F2, and the stop notification frame F3 transmitted from the slave transmission device 22S, respectively, and passing them to the control device 40.

  FIG. 3A shows the format of the negotiation frame F1. The slave transmission device 22S periodically transmits the negotiation frame F1. The interval T3 at which the slave transmission device 22S transmits the negotiation frame F1 is also an interval at which the master transmission device 22M receives the negotiation frame F1, and is, for example, 1 second.

  In the negotiation frame F1, the MAC address of the master transmission device 22M is stored as the destination MAC address, the MAC address of the slave transmission device 22S is stored as the transmission source MAC address, and a value representing the negotiation frame F1 as the type Is stored. The negotiation frame F1 may store the necessary traffic amount St and the stock data amount Sb, and may further store the number of support lanes.

  FIG. 3B shows a format of the start notification frame F2 and the stop notification frame F3. In the start notification frame F2 and the stop notification frame F3, the MAC address of the master transmission device 22M is stored as the destination MAC address, the MAC address of the slave transmission device 22S is stored as the source MAC address, and the type is as follows: Values representing the start notification frame F2 and the stop notification frame F3 are stored.

  Referring to FIG. 2 again, the frame insertion / extraction unit 52 has a function of passing the frame received from the short distance PHY-LSI 30 to the storage unit 42 in a predetermined case. The frame insertion / extraction unit 52 has a function of passing a frame stored in the storage unit 42 to the long-distance PHY-LSI 34 in a predetermined case.

[Long distance PHY-LSI]
The long-distance PHY-LSI 34 conforms to the IEEE 802.3ba 40/100 GbE standard, and corresponds to a communication speed of 40 Gbps in this embodiment.
Specifically, the long-distance PHY-LSI 34 includes a distribution unit 54, which performs encoding processing and scramble processing on the frame received from the MAC-LSI 32, and converts the frame into a block sequence including a plurality of blocks. Convert.
Then, the distribution unit 54 performs distribution processing that cyclically distributes the block sequence to 1 to 4 lanes in units of blocks, and passes the block to the long-distance optical transceiver 36 through each lane.

  When the long distance PHY-LSI 34 receives a block from the long distance optical transceiver 36 through one to four lanes, the long distance PHY-LSI 34 performs skew adjustment processing and then aligns the blocks to reproduce the block string. Perform alignment processing. Then, the long distance PHY-LSI 34 performs descrambling processing and decoding processing, converts the block sequence into a frame, and passes the frame to the MAC-LSI 32.

Here, the distribution unit 54 has a function of adjusting the number of lanes (hereinafter also referred to as the number of used lanes NL) to which the blocks are allocated based on a command from the control device 40. That is, the number of used lanes NL is variable. In the master transmission apparatus 22M, four lanes are provided as physical lanes for blocks. However, the number of lanes actually used is changed in accordance with the number of used lanes NL.
The lane includes a transmission side lane and a reception side lane. When the number of used lanes is changed, both the transmission side and the reception side lanes are changed.

When the number of used lanes is one, the communication speed from the master transmission apparatus 22M to the slave transmission apparatus 22S is 10 Gbps, and the communication speed increases by 10 Gbps every time the number of used lanes NL increases by one. That is, the communication speed S1 per lane is 10 Gbps.
The long-distance PHY-LSI 34 may support a communication speed of 100 Gbps, and in this case, a maximum of 4 or 10 physical lanes are used. That is, the number of physical lanes and the upper limit of the number of used lanes NL are not limited to four columns.

[Long-distance optical transceiver]
The master device 22M has four long-distance optical transceivers 36, and one long-distance optical transceiver 36 is arranged in one physical lane. Each of the long-distance optical transceivers 36 conforms to the IEEE 802.3ba 40/100 GbE standard, and corresponds to a communication speed S1 of 10 Gbps in this embodiment.

Specifically, the long-distance optical transceiver 36 includes an E / O (electro-optical conversion) unit 56 and an O / E (photo-electric conversion unit) 58. The E / O unit 56 includes a light emitting element, converts the electrical signal of the block received from the long distance PHY-LSI 34 through the lane into an optical signal, and transmits the optical signal to the optical multiplexer / demultiplexer 38. The O / E unit 58 includes a light receiving element, converts the optical signal received from the optical multiplexer / demultiplexer 38 into an electrical signal, and passes the electrical signal to the long distance PHY-LSI 34 through the lane.
In the present invention, a frame, a transmission code, a block string, and a block are also simply referred to as data without being distinguished.

The wavelength of the optical signal transmitted by the long-distance optical transceiver 36 differs between the long-distance optical transceivers 36, and also differs between the master transmission device 22M and the slave transmission device 22S.
The long-distance optical transceiver 36 includes a power supply control unit 60, and the power supply control unit 60 turns on the power supply to the E / O unit 56 and the O / E unit 58 based on a command from the control device 40. -Turn off. That is, the power supply control unit 60 controls the start and stop of the E / O unit 56 and the O / E unit 58, in other words, controls the start and stop of the long-distance optical transceiver 36 individually. .

[Optical multiplexer / demultiplexer]
The optical multiplexer / demultiplexer 38 multiplexes the optical signal received from the E / O unit 56. The multiplexed optical signal is transmitted from the interconnection port 26 toward the slave transmission device 22S. The optical multiplexer / demultiplexer 38 demultiplexes the multiplexed optical signal received by the interconnection port 26. The demultiplexed optical signal is passed to the O / E unit 58.
The interconnection port 26 is connected to the long-distance optical transceiver 36 via the optical multiplexer / demultiplexer 38.

〔Control device〕
The control device 40 is constituted by a CPU (Central Processing Unit), for example. When viewed in terms of functions, the control device 40 includes a target lane number calculation unit 62, a control frame generation unit 64, a used lane number control unit 66, an optical transceiver control unit 68, and a frame insertion / extraction control unit 70.

[Target lane number calculation section]
The target lane number calculation unit 62 periodically calculates the target number of lanes to be used (hereinafter referred to as target lane number Nc) based on a predetermined calculation formula. The interval T4 at which the target lane number calculation unit 62 calculates the target lane number Nc is, for example, 3 seconds.

[Target lane number formula]
Specifically, the following formula:
Nc = ROUNDUP (MAX (Mt + X + Mb, St + Y + Sb) / T2 / S1) (1)
Based on the above, the target lane number Nc is calculated.
However, the target lane number Nc is limited to a range between the minimum value NLmin and the maximum value NLmax of the used lane number NL. That is, when the value calculated by the equation (1) is less than the minimum value NLmin (Nc <NLmin), the minimum value NLmin is used as the target lane number Nc (Nc = NLmin), and the value calculated by the equation (1) is used. When the value exceeds the maximum value NLmax (Nc> NLmax), the maximum value NLmax is used as the target lane number Nc (Nc = NLmax). In the present embodiment, the minimum value NLmin is 1 and the maximum value NLmax is 4.

In Expression (1), ROUNDUP () is a function that rounds up the number in parentheses to the first decimal place to make an integer. MAX () is a function that selects the larger one of the two numerical values (Mt + X + Mb) and (St + Y + Sb) in parentheses.
Mt is a necessary traffic amount of the master transmission device 22M, and Mb is an amount of frames stored in the storage unit 42 of the master transmission device 22M (hereinafter also referred to as stock data amount). X is a suitable constant and may be 0.

  The control device 40 acquires the required traffic amount Mt and the stock data amount Mb from the required traffic amount measurement unit 48 and the storage device control unit 74 at a predetermined interval T1, respectively. The target lane number Nc is calculated using the necessary traffic amount Mt and the stock data amount Mb.

Also, St is a necessary traffic amount of the slave transmission device 22S, and Sb is a stock data amount of the slave transmission device 22S. Y is an appropriate constant and may be 0. By receiving the negotiation frame F1, the control device 40 repeatedly acquires the necessary traffic amount St and the stock data amount Sb at an interval T3 of 1 second, for example. The target lane number calculation unit 62 calculates the target lane number Nc using the latest necessary traffic amount St and stock data amount Sb.
Furthermore, S1 is a transmission rate per lane, for example, 10 Gbps.

[Control frame generator]
The control frame generation unit 64 generates a control frame F4 including the calculated target lane number Nc in a predetermined case, and transmits it to the slave transmission device 22S through the MAC-LSI 32, the long distance PHY-LSI 34, and the like.
Specifically, when the used lane number NL is changed based on the comparison result between the calculated target lane number Nc and the used lane number NL, the control frame generation unit 64 generates and transmits the control frame F4. To do.

  FIG. 3C shows the format of the control frame F4. In the control frame F4, the MAC address of the slave transmission device 22S is stored as the destination MAC address, the MAC address of the master transmission device 22M is stored as the transmission source MAC address, and a value representing the control frame F4 as the type Is stored. Further, the target frame number Nc is stored in the control frame F4.

[Used lane number control unit]
Referring to FIG. 2 again, the used lane number control unit 66 operates the distribution unit 54 so that the used lane number NL matches the calculated target lane number Nc.

[Optical transceiver controller]
The optical transceiver control unit 68 operates the power supply control unit 60 so that the number of activated long-distance optical transceivers 36 (hereinafter also referred to as activation number ND) matches the target lane number Nc. The transceiver 36 is activated or deactivated individually.

[Frame insertion / extraction control unit]
The frame insertion / extraction control unit 70 extracts a part of the frame in a predetermined case from the flow of the frame passing through the MAC-LSI 32 from the short-range PHY-LSI 30 to the long-distance PHY-LSI 34, and stores the storage unit. 42 is stored.
Specifically, the frame insertion / extraction control unit 70 determines the amount corresponding to the amount that is lower when the transmission speed NL · S1 defined based on the number of used lanes NL is lower than the required transmission speed Mt / T2. Then, the storage unit 42 stores the frame.

In addition, the frame insertion / extraction control unit 70 transmits a frame stored in the storage unit 42 to the MAC-LSI 32 in a predetermined case, and transmits a frame passing through the MAC-LSI 32 toward the long-distance PHY-LSI 34. Insert into the flow.
Specifically, the frame insertion / extraction control unit 70 determines the amount corresponding to the amount that exceeds the required transmission rate Mt / T2 when the transmission rate NL · S1 defined based on the number of used lanes NL exceeds the required transmission rate Mt / T2. Then, the frame stored in the storage unit 42 is transmitted to the slave transmission device 22S.

[Storage unit]
The storage unit 42 includes a storage device 72 and a storage device controller 74. The storage device 72 is for temporarily storing frames, and the storage device control unit 74 performs frame transmission / reception between the storage device 72 and the MAC-LSI 32 in accordance with instructions from the frame insertion / extraction control unit 70. Control.

[Slave transmission device]
Hereinafter, the configuration of the slave transmission device 22S will be described. Of the configuration of the slave transmission device 22S, the same or similar configuration as that of the master transmission device 22M is denoted by the same name or symbol, and the description thereof is simplified or omitted.
FIG. 4 is a block diagram schematically showing a physical and functional configuration of the slave transmission device 22S. The control device 40 of the slave transmission device 22S includes a negotiation frame generation unit 76 and a start / stop notification frame generation unit 78.

[Negotiation frame generator]
The negotiation frame generation unit 76 periodically generates the negotiation frame F1 and transmits it to the master transmission apparatus 22M through the MAC-LSI 32, the long distance PHY-LSI 34, and the like.
The negotiation frame generation unit 76 periodically acquires the necessary traffic amount St and the stock data amount Sb from the necessary traffic amount measurement unit 48 and the storage device control unit 74 immediately before the generation of the negotiation frame F1, respectively. The traffic amount St and the stock data amount Sb are stored in the negotiation frame F1.
The necessary traffic amount St is the amount of transmission code to be transmitted per predetermined time T2, and the stock data amount Sb is the amount of data stored in the storage unit.

[Start / stop notification frame generator]
The start / stop notification frame generation unit 78 generates a start notification frame F2 or a stop notification frame F3 in a predetermined case, and transmits it to the master transmission device 22M through the MAC-LSI 32, the long distance PHY-LSI 34, and the like.

[Operation of Master Transmission Device]
Hereinafter, a schematic configuration of a program (main routine) executed by the master transmission apparatus 22M will be described as an operation of the master transmission apparatus 22M with reference to FIG.

  The main routine is executed, for example, when the master transmission device 22M is activated. In the main routine, first, initialization is performed (S10). Specifically, in order to activate all the long-distance optical transceivers 36, the activation number ND is set to 4 which is the maximum value NDmax. Further, the number of used lanes NL is set to 4 which is the maximum value NLmax, and the number of repetitions n is set to 1.

  After the initial setting S10, the master transmission device 22M starts relaying the frame (S12), and then determines whether or not the negotiation frame F1 has been received (S14). In the present embodiment, since the master transmission device 22M receives the negotiation frame F1 at an interval T3 of 1 second, the determination result of step S14 becomes Yes at an interval of 1 second.

  When the master transmission device 22M receives the negotiation frame F1, the master transmission device 22M acquires the necessary traffic amount St and the stock data amount Sb included in the negotiation frame F1 (S16). The master transmission device 22M acquires the latest necessary traffic amount Mt and stock data amount Mb from the required traffic amount measurement unit 48 and the storage device control unit 74, respectively (S18).

After step S18, the master transmission apparatus 22M determines whether or not the frame is stored in the storage unit 42, that is, whether or not the stock data amount Mb is larger than 0 (S20).
When the determination result of step S20 is Yes, the master transmission apparatus 22M determines whether or not the transmission rate NL · S1 defined by the number of used lanes NL exceeds the required transmission rate Mt / T2 (S22). When the determination result in step S22 is Yes, the master transmission device 22M transmits a frame stored in the storage unit 42 to the slave transmission device 22S by a predetermined amount (hereinafter also referred to as a buffer transmission amount ΔMb). (S24).

Specifically, the buffer transmission amount ΔMb is expressed by the following equation:
ΔMb = NL · S1 · T2− (Mt + X) (2)
Is required.
Depending on the size of the constant X, the buffer transmission amount ΔMb may be a negative value, but in this case, the frame stored in the storage unit 42 is not transmitted.

After step S24, it is determined whether the number of repetitions n is 3 (S26). Step S26 is also executed when the determination result of step S20 or step S22 is No.
When the determination result of step S26 is No, the master transmission apparatus 22M increases the number of repetitions n by 1 (S28), and executes step S14 again.

[Lane number adjustment subroutine]
On the other hand, if the determination result in step S26 is Yes, after the number of repetitions n is returned to 1 (S30), the lane number adjustment subroutine SR32 shown in FIG. 6 is executed. In the lane number adjustment subroutine SR32, the target lane number Nc is calculated (S40). The calculated target lane number Nc is compared with the used lane number NL (S42).

  As a result of the comparison in step S42, when the target lane number Nc is equal to the used lane number NL (Nc = NL), the lane number adjustment subroutine SR32 ends, and step S14 is executed.

  On the other hand, as a result of the comparison in step S42, if the target lane number Nc is larger than the used lane number NL and smaller than the maximum value NLmax of the used lane number NL (NLmax> Nc> NL), the lane number increasing subroutine SR44 is executed. When the target lane number Nc is smaller than the used lane number NL and larger than the minimum value NLmin of the used lane number NL (NLmin <Nc <NL), the lane number decreasing subroutine SR46 is executed. .

[Lane increase subroutine]
FIG. 7 shows the lane number increasing subroutine SR44. In the lane number increasing subroutine SR44, it is determined whether or not the required transmission speed Mt / T2 is higher than the current transmission speed NL · S1 (S50).
If the determination result in step S50 is Yes, the master transmission device 22M extracts a part of the frame to be transmitted to the slave transmission device 22S by a predetermined amount (hereinafter referred to as an overflow amount ΔMt) and transfers it to the storage unit 42. The operation is started (S52).

The overflow amount ΔMt is expressed by the following formula:
ΔMt = Mt + X−NL · S1 · T2 (3)
Is required.
The frame transferred to the storage unit 42 is stored in the storage device 72. However, when the capacity of the storage device 72 is insufficient, the transferred frame is discarded.

After step S52 or when the determination result in step S50 is No, the control frame F4 is generated and transmitted toward the slave transmission device 22S (S54).
Then, the activation number ND is increased by a number corresponding to the difference between the target lane number Nc and the activation number ND (Nc−ND), and the long-distance optical transceiver 36 being stopped is activated (S56). That is, the number of activations ND is made equal to the target lane number Nc.

  After step S56, the master transmission apparatus 22M waits for the reception of the activation notification frame F2 (S58). Upon reception of the activation notification frame F2, the master transmission device 22M sets the used lane number NL to the difference between the target lane number Nc and the used lane number NL (Nc -NL) is increased by the number corresponding to (NL) (S60).

Note that an interval is provided between the start of activation of the long-distance optical transceiver 36 in step S56 and the change in the number of used lanes NL in step S60 for the time required for activation of the long-distance optical transceiver 36. . For example, when the time required from the start of activation of the long-distance optical transceiver 36 to the end of activation is 2000 ms, an interval of 2000 ms or more is provided.
After step S60, the frame transfer to the storage unit 42 is stopped (S62), and the lane number increasing subroutine SR44 ends.

[Lane reduction subroutine]
FIG. 8 shows a lane number reduction subroutine SR46. In the lane number decreasing subroutine SR46, a control frame F4 including the target lane number Nc is generated and transmitted to the slave transmission device 22S (S70).
After step S70, the master transmission apparatus 22M waits for reception of the stop notification frame F3 (S72). When the stop notification frame F3 is received, the master transmission device 22M sets the used lane number NL to the difference between the used lane number NL and the target lane number Nc (NL -Nc) is reduced by the number corresponding to (S74).

Then, the activation number ND is reduced by a number corresponding to the difference (ND−Nx) between the activation number ND of the long-distance optical transceiver 36 and the target lane number Nc (ND−Nx), and the activated long-distance optical transceiver 36 is stopped ( S76).
[Operation of slave transmission device]
Hereinafter, as an operation of the slave transmission device 22S, a schematic configuration of a program (main routine) executed by the slave transmission device 22S will be described with a focus on differences from the main routine of the master transmission device 22M with reference to FIG. To do.

  The slave transmission device 22S repeatedly acquires the required traffic amount St and the stock data amount Sb at the interval T1 (S84). Then, the negotiation frame F1 including the necessary traffic amount St and the stock data amount Sb is generated and transmitted to the master transmission device 22M (S86).

In steps S88, S90, and S92, the required traffic volume St, the stock data volume Sb, and the constant Y are used in place of the required traffic volume Mt, the stock data volume Mb, and the constant X, and the frame transmission destination is the master transmission device 22M. Except there are the same as steps S20, S22, and S24.
The buffer transmission amount ΔSb in the slave transmission device 22S is expressed by the following equation:
ΔSb = NL · S1 · T2− (St + Y) (4)
Is required.

  After step S92, it is determined whether the control frame F4 has been received (S94). If the result of determination in step S94 is that control frame F4 has been received, lane number adjustment subroutine SR96 is executed.

[Lane number adjustment subroutine]
FIG. 10 shows a lane number adjustment subroutine SR96 executed by the slave transmission device 22S.
When the lane number adjustment subroutine SR96 is executed, the slave transmission device 22S acquires the target lane number Nc included in the control frame F4 and compares it with the used lane number NL (S100).

As a result of the comparison in step S100, when the target lane number Nc is larger than the used lane number NL, the lane number increasing subroutine SR102 is executed. When the target lane number Nc is smaller than the used lane number NL, the lane number decreasing subroutine SR104 is executed. Executed.
Note that the master transmission device 22M transmits the control frame F4 only when the number of used lanes NL is changed, so that Nc = NL is not obtained in the comparison result of step S100.

[Lane increase subroutine]
FIG. 11 shows the lane number increasing subroutine SR102 executed by the slave transmission device 22S.
Steps S106 and S108 are the same as steps S50 and S52, except that the necessary traffic amount St, the stock data amount Sb, and the constant Y are used instead of the necessary traffic amount Mt, the stock data amount Mb, and the constant X. is there.
The overflow amount ΔSt in the slave transmission device 22S is expressed by the following equation:
ΔSt = St + Y−NL · S1 · T2 (5)
Is required.

Steps S110, S114, and S116 are the same as steps S56, S60, and S62, respectively. Between step S110 and step S114, the activation notification frame F2 is generated and transmitted to the master transmission apparatus 22M (step S112). The activation notification frame F2 has a role as a trigger for the master transmission device 22M and the slave transmission device 22S to perform Step S60 and Step S114 almost simultaneously at the same time.
Note that an interval is provided between the start of activation of the long-distance optical transceiver 36 in step S110 and the change in the number of used lanes NL in step S114 for the time necessary for activation of the long-distance optical transceiver 36. .

[Lane reduction subroutine]
FIG. 12 shows the lane reduction subroutine SR104 executed by the slave transmission device 22S.
Steps S120 and S122 are the same as steps S74 and S76, respectively. Before step S120, a stop notification frame F3 is generated and transferred to the master transmission device 22M.
The stop notification frame F3 has a role as a trigger for the master transmission device 22M and the slave transmission device 22S to perform Step S74 and Step S120 at substantially the same time.

The optical transmission system 21 according to the embodiment described above can transmit and receive optical signals in parallel using a plurality of lanes, and can realize a high transmission rate NL · S1.
On the other hand, in the optical transmission system 21 of the above-described embodiment, the master transmission device 22M and the slave transmission device 22S adjust the activation number ND of the long-distance optical transceiver 36 based on the target lane number Nc updated in a timely manner. To do. That is, the master transmission device 22M and the slave transmission device 22S use the minimum number of long-distance optical transceivers 36 to transmit and receive frames while stopping unnecessary long-distance optical transceivers 36. We are trying to save power.

  In the optical transmission system 21 of the above-described embodiment, the master transmission device 22M calculates the target lane number Nc based on the required traffic amounts Mt and St, and the master transmission device 22M and the slave transmission device 22S The activation number ND of the long-distance transceiver 36 is appropriately adjusted without excess or deficiency.

  Further, in the optical transmission system 21 of the above-described embodiment, when the required transmission speed exceeds Mt / T2 and St / T2 from the start to the end of startup of the long-distance transceiver 36, the transmission speed NL · S1 is exceeded. The frames are transferred to the storage unit 42 by the overflow amounts ΔMt and ΔSt. For this reason, even if it takes a certain amount of time to activate the long-distance transceiver 36, the discard of the frame due to overflow is prevented.

  Furthermore, in the optical transmission system 21 of the above-described embodiment, when the transmission rate NL · S1 exceeds the required transmission rate Mt / T2, St / T2, the frame stored in the storage unit 42 is converted into the buffer transmission amount ΔMb. , ΔSb are transmitted toward the slave transmission device 22S or the master transmission device 22M. For this reason, the frame stored in the storage unit 42 is promptly transmitted, and transmission / reception of the frame via the optical transmission system 21 is performed smoothly.

  Furthermore, in the optical transmission system 21 of the above-described embodiment, the master transmission device 22M calculates the target lane number Nc based on the required traffic amounts Mt and St and the stock data amounts Mb and Sb, and the storage device The frame stored in 72 is promptly transmitted. For this reason, smooth communication is ensured.

  In the optical transmission system 21 according to the embodiment described above, the number of used lanes NL is increased after the time required for starting the long-distance transceiver 36 has elapsed since the start of starting the long-distance transceiver 36. Data to be transmitted is not passed to the long distance transceiver 36, and frame loss in the long distance transceiver 36 is prevented.

  The present invention is not limited to the above-described embodiment, and includes a form obtained by modifying the above-described embodiment.

  For example, the master transmission device 22M and the slave transmission device 22S of the above-described embodiment have the optical multiplexer / demultiplexer 38. However, when they are connected to each other using a plurality of communication cables, the optical multiplexer / demultiplexer 38 is unnecessary.

Although the master transmission apparatus 22M of the above-described embodiment calculates the target lane number Nc based on the stock data amounts Mb and Sb in addition to the required traffic amounts Mt and Mb and the constants X and Y, the necessary traffic amount Mt , Mb and constants X and Y may be used to calculate the target lane number Nc.
Finally, the specific configuration and processing procedure of the apparatus used in the above-described embodiment are all preferable and of course not limited thereto.

DESCRIPTION OF SYMBOLS 10 Network 21 Optical transmission system 22M Master transmission apparatus 22S Slave transmission apparatus 24 Access port 26 Interconnection port 28 Short distance optical transceiver 36 Long distance optical transceiver 47 Required traffic amount measurement part 54 Distribution part 62 Target lane number calculation part 64 Control Frame generation unit 66 Use lane number control unit 68 Optical transceiver control unit 70 Frame insertion / extraction control unit 72 Storage device 76 Negotiation frame generation unit

Claims (5)

In an optical transmission system including a master transmission device and a slave transmission device,
Each of the master transmission device and the slave transmission device,
An access port for sending and receiving data to be relayed;
A distribution unit that distributes the data to one or more of a plurality of lanes;
A plurality of optical transceivers disposed in each of the plurality of lanes;
An interconnection port connected to the optical transceiver and used to connect the master transmission device and the slave transmission device;
A required traffic amount measuring unit that measures a required traffic amount that is a data amount per predetermined time received by the access port;
Have
The slave transmission device is
A required traffic amount notifying means for notifying the master transmission device of the required traffic amount measured by the required traffic amount measuring unit of the slave transmission device;
A slave-side optical transceiver controller for individually starting or stopping the optical transceiver of the slave transmission device based on the target number of lanes to be used among the plurality of lanes notified from the master transmission device; ,
Have
The master transmission device is
A target lane number calculation unit that calculates the target lane number based on the necessary traffic amount measured by the necessary traffic amount measurement unit of the master transmission device and the necessary traffic amount notified from the slave transmission device. When,
Target lane number notifying means for notifying the slave transmission device of the target lane number calculated by the target lane number calculating unit;
A master-side optical transceiver control unit for individually starting or stopping the optical transceiver of the master transmission device based on the target lane number calculated by the target lane number calculation unit;
Having
Optical transmission system. Each of the master transmission device and the slave transmission device,
A storage device;
A portion of the data received by the access port when the transmission rate realized by the activated optical transceiver is below the required transmission rate obtained by dividing the required traffic volume by the predetermined time Is stored in the storage device, and when the transmission rate exceeds the required transmission rate, a frame insertion / extraction control unit that transmits data stored in the storage device from the interconnection port,
Further having
The optical transmission system according to claim 1. The target lane number calculation unit further calculates the target lane number based on the amount of data stored in the storage device of the master transmission device and the slave transmission device.
The optical transmission system according to claim 2. When increasing the number of used lanes, the number of used lanes is increased after the time required for starting the optical transceiver has elapsed since the start of starting the optical transceiver.
The optical transmission system according to any one of claims 1 to 3. Each of the master transmission device and the slave transmission device conforms to the standard of IEEE 802.3ba 40/100 GbE.
The optical transmission system according to any one of claims 1 to 4.

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