JP2004297502A - Optical transmission network designing device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a network designing device capable of optimally locating a linear repeater and a regenerating repeater by combining automatically unnecessary segments. <P>SOLUTION: The optical transmission network designing device comprises a locating section, an 1R target value calculator, and a first connection judging section. The locating section locates either of the regenerating repeater and linear repeater between each point based on an amount of loss between a transmission terminal station and the neighboring points, between two adjacent points and between a receiving terminal station and the neighboring points when a plurality of points is established between design target zones. With regard to a 3R zone, the 1R target value calculator calculates, as the 1R target value, the amount of the loss that is transmittable without amplifying by the linear repeater, light signals transmitted by the transmission terminal station or the regenerating repeater that is arranged at a transmitting side between both ends of the 3R zone. Further, in the 3R zone, the first connection judging section adds cumulatively and sequentially the amount of segment loss in the direction away from the transmission terminal station at a transmitting end to compare the amount of the cumulative loss and the 1R target value, and judges whether two segments are coupled to one segment without arranging the linear repeater or not. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a network design apparatus for a wavelength-division multiplexing (WDM) optical transmission system.
[0002]
[Prior art]
At present, with the rapid spread of the broadband environment, a transmission device capable of long-distance and large-capacity optical transmission is required. As a method for efficiently realizing the long distance and the large capacity, a WDM method capable of increasing the transmission capacity without changing the transmission path is rapidly developing. With the needs of this market, it is necessary to efficiently design a WDM optical transmission network having high performance and reliability for various networks. The WDM optical transmission system includes a linear repeater (1R) or a regenerative repeater (3R) disposed between a transmitting terminal station and a receiving terminal station. The linear repeater amplifies the received optical signal with a predetermined gain to compensate for the fiber loss of the optical signal. The regenerative repeater performs optical-to-electric conversion, signal regeneration, reproduction signal amplification, and electro-optical conversion of the optical reception signal. The signal is reproduced in order to prevent noise from being mixed into the main signal due to signal amplification, amplifying the noise, deteriorating the signal-to-noise ratio, and making it impossible to reproduce on the receiving side. The network design device is a device in which a linear repeater or a regenerative repeater is arranged by a computer at stations installed at a plurality of points in a design target section connecting a transmitting terminal station and a receiving terminal station. Patent Document 1 has been proposed in order to reduce the equipment cost by arranging optimal 3Rs.
[0003]
FIG. 11 is a functional block diagram of a program in a conventional network design apparatus. FIG. 12 is a flow chart of the network design. FIG. 13 is a diagram showing a conventional network design example. 13 (a), the loss (noise) of each segment 1, 2,..., 14 between the transmitting terminal 20 and the receiving terminal 22 to be designed is 20 dB, 20 dB, as shown in FIG. ,..., 17 dB are input. The loss amount is the loss due to the fiber transmission of the main signal, and the transmitting terminal station and the linear repeater amplify the optical signal with a predetermined gain to compensate for this loss, but the larger the gain, the larger the noise. Therefore, loss and noise are considered to be equivalent. In step S2, the total normalized noise amount calculation unit 4 calculates the normalized noise amount from the loss amounts 20 dB, 20 dB,..., 17 dB of the segments 1, 2,. Calculate the noise amount.
[0004]
As shown in FIG. 13 (b), the normalized noise amount is defined as a value obtained when a signal transmitted from a transmitting terminal station or a regenerative repeater can be transmitted without a regenerative repeater. Is standardized by the noise amount corresponding to the determination value. As shown in FIG. 13B, normalized noise amounts at segment losses of 20 dB, 17 dB, and 16 dB are 0.20, 0.17, 0.16, and 0.15, respectively. In the optical transmission network shown in FIG. 13A, the total normalized noise amount is 2.40. In step S4, the regenerator calculation unit 6 calculates the number of regenerators required for transmission. For example, in the optical transmission network shown in FIG. 13A, the number of regenerative repeaters required between the terminal stations 20 and 22 is two.
[0005]
In step S6, the noise amount determination value calculation unit 8 calculates a noise amount determination value in each of the three sections. As shown in FIG. 13C, the noise amount (3R noise amount determination value) assigned to each 3R = 2.40 (total normalized noise amount) / (2 + 1) (the number of 3R sections) = 0.80 It becomes. The arranging unit 10 performs the processing of steps S8 to S24, and arranges the linear repeaters / regenerative repeaters. In step S8, the temporary regenerative repeater is arranged at the node reception position, and the normalized noise amount in the temporary 3R section is accumulated. In step S10, it is determined whether or not the accumulation of the normalized noise amount has exceeded a noise amount determination value. If the accumulation of the normalized noise amount exceeds the noise amount determination value, the process proceeds to step S12. If the accumulation of the normalized noise amount does not exceed the noise amount determination value, the process proceeds to step S18.
[0006]
In step S12, if the previous node is a temporary linear repeater, it is formally determined, and if the previous node is a transmitting terminal station or a regenerative repeater, nothing is performed. In step S14, it is determined whether the current node position is the receiving terminal station. If the current node position is the receiving terminal, the process ends. If the current node position is not the receiving terminal station, the process proceeds to step S16. In step S16, the current node position is set as the temporary linear repeater, the node reception position is moved to the next node, and the process returns to step S8. In step S18, it is determined whether the previous node is a temporary linear repeater. If the previous node is a temporary linear repeater, the process proceeds to step S20. If the previous node is not a temporary linear repeater, the process proceeds to step S22. In step S20, the temporary linear repeater of the previous node is determined as a regenerative repeater, but the node reception position is not changed. In step S22, the difference between the determined noise amount determination value in the 3R section and the accumulated normalized noise amount is carried over to the noise amount determination value in the next 3R section, and the process returns to step S8.
[0007]
By the above steps, as shown in FIG. 13A, the normalized noise amount of the segments 1 to 4 is 0.76, the normalized noise amount of the segments 1 to 5 is 0.82, and the receiving side 24 of the segment 4 3R is allocated to # 4, and 1R is allocated to the receiving sides 24 # 1, 24 # 2, and 24 # 3 of the segments 1, 2, and 3. As shown in FIG. 13A, the next noise amount determination value is 0.80 (the calculated noise amount determination value) +0.80 (the noise amount determination value) −0.76 (the normalized noise of the segments 1 to 4). Amount) = 0.84. As shown in FIG. 13A, the normalized noise amount of the segments 5 to 9 is 0.83, and the normalized noise amount of the segments 5 to 10 is 0.99. 1R is arranged on the receiving side 24 # 5, 24 # 6, 24 # 7, 24 # 8 of the segments 5, 6, 7, and 8. As shown in FIG. 13A, the next noise amount determination value is 0.80 (the calculated noise amount determination value) + the current noise amount determination value (0.84) −0.83 (for the segments 5 to 9). (Normalized noise amount) = 0.81. As shown in FIG. 13A, the normalized noise amounts of the segments 10 to 14 are 0.81, and the receiving sides 24 # 10, 24 # 11, 24 # 12, 24 # 13 of the segments 10, 11, 12, and 13 are set. 1R.
[0008]
Patent Document 2 discloses a method and system for optical transmission that easily optimizes the arrangement of a dispersion compensator and the distribution of a dispersion compensation amount.
[0009]
[Patent Document 1]
Japanese Patent Application No. 14-204461
[0010]
[Patent Document 2]
JP 2000-236297 A
[0011]
[Problems to be solved by the invention]
However, the conventional network design apparatus has the following problems. Since the arrangement of the linear repeater and the regenerative repeater is performed using the conventional network design apparatus, an unnecessary linear repeater or regenerative repeater may be arranged when a segment having a small fiber loss exists. FIG. 14 is a diagram illustrating an example in which unnecessary linear repeaters are arranged. As shown in FIG. 14A, the noise amount determination value that can be transmitted without a regenerator is 1.00, and as shown in FIG. 14B, the network information is a segment 1 between the terminal stations 20 and 22. , 2, and 3 are 20 dB, 5 dB, and 25 dB, and their normalized noise amounts are 0.30, 0.20, and 0.40. According to the above-described network design, as shown in FIG. 14C, linear repeaters are arranged on the receiving sides 24 # 1 and 24 # 2 of the segments 1 and 2. However, as shown in FIG. 14D, the network design result in which the linear repeaters are optimally arranged does not require the linear repeaters to be arranged on the receiving side of the segment 1 and the receiving side 24 # of the segment 2 2 may be provided with a linear repeater. That is, in the network design result shown in FIG. 14C, an unnecessary linear repeater is arranged on the receiving side of the segment 1.
[0012]
In this case, it is guaranteed that the design result can be transmitted, but the optimal network design which is one of the requirements of the network design device cannot be performed. For this reason, in order to obtain an optimal design result, it is necessary to take measures such as providing a network design device with network information coupled with an adjacent segment in advance for a segment having a small fiber loss. Also, regarding the segment combination, it is necessary to consider which of the segments to be combined can provide more optimal results. Therefore, the advantage of another purpose, that is, automatic network design implementation is lost.
[0013]
Patent Document 2 discloses a technique for optimizing the arrangement of the dispersion compensator and the distribution of the amount of dispersion compensation. However, since the technique cannot be applied to the optimal arrangement of the linear repeaters, the problem of the present invention is solved. Can not do it.
[0014]
SUMMARY OF THE INVENTION An object of the present invention is to provide a network design apparatus that can automatically combine unnecessary segments and optimally arrange linear repeaters and regenerative repeaters.
[0015]
[Means for Solving the Problems]
According to one aspect of the present invention, there is provided an optical transmission network designing apparatus for an optical transmission network in which a section to be designed from a transmitting terminal to a receiving terminal is connected by an optical fiber, wherein a plurality of points are set in the section to be designed. Based on the segment loss between the transmitting terminal and the adjacent point of the transmitting terminal, between two adjacent points, and between the receiving terminal and the adjacent point of the receiving terminal. Arranging any one of a repeater and a linear repeater, between the transmitting terminal station and the regenerative repeater arranged closest to the transmitting terminal station, the regenerative repeater and the regenerator arranged closest to the regenerative repeater For a 3R section between a repeater and any one of the receiving terminal station and a regenerative repeater disposed closest to the receiving terminal station, the 3R section is disposed on the transmitting side among both ends of the 3R section. The transmitting end station or the playing A 1R target value calculation unit for calculating an amount of loss that can be transmitted without amplifying the optical signal transmitted by the optical transmitter by the linear repeater as a 1R target value, and moving away from the transmitting terminal station from a transmitting end in the 3R section. Cumulatively adding the loss amounts of the segments sequentially in the direction, comparing the cumulative loss amount with the 1R target value, and determining whether to combine the two segments into one segment without disposing the linear repeater. An optical transmission network designing apparatus, comprising: one coupling determination unit.
[0016]
According to another aspect of the present invention, there is provided an optical transmission network designing apparatus of an optical transmission network in which a section to be designed from a transmitting terminal to a receiving terminal is connected by an optical fiber, wherein a plurality of points are located in the section to be designed. Based on the segment loss between the transmitting terminal station and the adjacent point of the transmitting terminal station, between two adjacent points, and between the receiving terminal station and the adjacent point of the receiving terminal station, reproduction is performed at each of the points. An arrangement section for arranging any of a repeater and a linear repeater, between the transmitting terminal station and the regenerative repeater arranged closest to the transmitting terminal station, arranged closest to the regenerative repeater and the regenerative repeater; For a 3R section between the regenerative repeater and any one of the receiving terminal station and the regenerative repeater arranged closest to the receiving terminal station, the 3R section is arranged on the transmitting side among both ends of the 3R section. Said transmitting terminal or said reproducing A 1R target value calculation unit for calculating a transmittable loss amount as an 1R target value without amplifying the optical signal transmitted by the repeater by the linear repeater; and in the 3R section, from the receiving terminal to the receiving end from the receiving end. Cumulatively add the loss amounts of the segments in the direction away from each other, compare the cumulative loss amount with the 1R target value, and determine whether to combine the two segments into one segment without disposing a linear repeater. An optical transmission network design device, comprising: a second connection determination unit for determining.
[0017]
BEST MODE FOR CARRYING OUT THE INVENTION
Before describing embodiments of the present invention, the principle of the present invention will be described. FIG. 1 is a diagram illustrating the principle of the present invention. As shown in FIG. 1A, the network design device includes an arrangement unit 50, a 1R target value calculation unit 52, and a first connection determination unit 54. As shown in FIG. 1B, a plurality of points 74 # 1, 74 # 2,..., 74 # n are set in a design target section from the transmitting terminal station 70 to the receiving terminal station 72. The arranging unit 50 includes a transmitting terminal station 70 and an adjacent point 74 # 1, two adjacent points 74 # (i-1), 74 # i (i = 2,..., N), and a receiving terminal station 72 and an adjacent point 74 #. On the receiving side of each point 74 # i (i = 1,...), either 3R or 1R is arranged based on the loss amount of each of the segments 1 to (n + 1) connecting n. The 1R target value calculation unit 52 is configured to transmit a signal between the transmitting terminal 70 and the 3R disposed closest to the transmitting terminal 70, between the 3R and the 3R disposed closest to the 3R, and between the receiving terminal 72 and the received terminal 72. For any 3R section between the 3R section closest to the terminal station 72 and the 3R section, the optical signal transmitted by the transmitting terminal station 70 or 3R disposed at the transmitting end point among the both end points of the 3R section is transmitted. The amount of loss that can be transmitted without amplification by 1R is calculated as a 1R target value. The first combination determination unit 54 cumulatively adds the loss amounts of the segments in a direction away from the transmitting end station from the transmitting end point in the 3R section, compares the cumulative loss amount with the 1R target value, and To determine whether or not to join two segments into one segment without passing through. As a result, the 1R is not disposed at an unnecessary point, and the cost of the optical transmission network is reduced.
[0018]
FIG. 2 is a configuration diagram of the network design device according to the embodiment of the present invention. As shown in FIG. 2, the network design device is realized by a computer such as a personal computer or a workstation having an input unit such as a keyboard 100, an output unit such as a display device 102, a processing unit 104, a storage device 106, and a bus 108. Have been. The keyboard 100 inputs design information relating to network design from a user, and outputs the design information to the processing unit 104 via the bus 108. The network design information includes, for a plurality of stations installed between the transmitting terminal station and the receiving terminal station, the segment loss (dB) of the segment between the transmitting terminal station and the adjacent station, and the segment loss between the adjacent stations. (DB), and the segment loss (dB) between the receiving terminal station and the adjacent station.
[0019]
The display device 102 is an output device such as a display. The processing device 104 is a CPU that reads the program 110, the database 112, and the like stored in the storage device 106 into the main memory and executes the program 110. The storage device 106 is a hard disk, a ROM, or the like that stores the program 110 and the database 112. The bus 108 is a bus connecting the keyboard 100, the display processing 102, the storage device 110, and the processing unit 104. The program 110 describes the network design method of the present invention. The database 112 is a standardized noise amount database and a 1R target value database. The normalized noise amount database is a database that stores the normalized noise amount corresponding to the segment loss amount (dB). The 1R target value database is a database that stores the difference between the initial 1R target value (dB) and the loss amount (dB) of the combined segment and the IR target value of the next 1R section from the current 1R target value. The initial 1R target value is the maximum segment loss (dB) that can be transmitted without amplifying the WDM signal transmitted from the transmitting terminal station or the regenerative repeater by the linear repeater.
[0020]
FIG. 3 is a functional block diagram of the program 110 in FIG. 2, and substantially the same components as those in the diagram are denoted by the same reference numerals. As shown in FIG. 3, the program 110 includes an input / output control unit 2, a total normalized noise amount calculation unit 4, a number of regenerators 6, a noise amount determination value calculation unit 8, an arrangement unit 10, and a rearrangement unit 150. Of the processing program. The input / output control unit 2 manages a man-machine interface with a user, and inputs a segment loss or the like of a design target section from the user. The total standardized noise amount calculation unit 4 refers to the database 112 from the segment loss amounts from the transmitting terminal to the receiving terminal of the network to be designed to determine the corresponding standardized noise amount, and obtains the normalized noise of the segment. The sum of the amounts (total normalized noise amount) is calculated.
[0021]
The number of regenerative repeaters 6 calculates the number of regenerative repeaters required in the network to be designed (the number of total normalized noise amounts rounded down to the decimal point) from the total normalized noise amount. Based on the total normalized noise amount and the number of regenerative repeaters, the noise amount determination value calculation unit 8 calculates the amount of noise between the transmitting terminal station and adjacent regenerative repeaters, between adjacent regenerative repeaters, and between the receiving terminal station and adjacent regenerative repeaters. The noise amount determination value is calculated so that each segment loss amount becomes equal. The placement unit 10 places the linear repeater or the regenerative repeater at the location where each station is installed by performing the processing of steps S2 to S24 in the figure.
[0022]
The segment connection unit 150 includes a 1R target value calculation unit 160, a joint connection determination unit 162, and a two-way design determination unit 164. The 1R target value calculation section 160 calculates an initial 1R target value and a next IR target value. The initial 1R target value is the maximum segment loss that can be transmitted without amplifying the WDM optical signal transmitted by the transmitting terminal or the regenerative repeater by the linear repeater, and is stored in the database 112. The next 1R target value is a 1R target value for the next 1R section (a section to be subjected to segment connection), and is a difference between the segment loss amount after the segment connection processing by the joint connection determination unit 162 described later and the initial 1R target value. The 1R target value stored in the database 112 corresponding to the difference and the current 1R target value.
[0023]
The 1R target value is made variable instead of being fixed at the initial target value for the following reason. This is because the gain of the linear repeater is small if the segment loss is small. As a result, the noise generated by the repeater is reduced, and it is possible to bring the repeater to the next 1R target. Therefore, the 1R target value for the next 1R section is calculated from the difference between the initial 1R target value and the segment loss amount after the combination and the current 1R target value.
[0024]
The join coupling determination unit 162 performs the following processing for each 3R section. Here, the 3R section means between the transmitting terminal station and the adjacent regenerative repeater, between two adjacent regenerative repeaters, and between the receiving terminal station and the adjacent regenerative repeater. The direction from the transmitting terminal to the receiving terminal is called a downstream direction, and the direction from the receiving terminal to the transmitting terminal is called an upstream direction. (I) A point located on the downstream side of the largest segment whose cumulative value of the segment loss amount in the downstream direction does not exceed the current 1R target value, starting from either the transmitting terminal station or the regenerative repeater on the upstream side of the 3R section. (Transmit end) is the end point, the section from the start point to the end point is 1R section, the segments from the start point to the end point are combined into one segment, the linear repeater at the point except the end point is eliminated, and the linear repeater is set at the end point. Deploy. (Ii) Calculate the segment loss amount of the segment-combined 1R section by adding the segment loss amount before the combination. (Iii) Referring to the database 112, calculate a normalized noise amount corresponding to the combined segment loss amount. (Iv) The processing of (i) to (iii) is performed from the end point of the 1R section of (i) as the start point and the 1R target value of the next 1R section calculated by the 1R target value calculation section 160. (V) The processes (i) to (iv) are performed until the end point matches the receiving terminal station. (Vi) When the accumulated value of the normalized noise amount of the segment after the 3R section combining process is smaller than the 3R noise determination value, the above-described segment combining is adopted. If the accumulated value is larger than the 3R noise determination value, the 1R target value is changed to a smaller target value, and (i) to (vi) are performed. (Vii) In (i), the transmitting terminal is read as the receiving terminal, the receiving terminal is referred to as the transmitting terminal, and the downstream is referred to as upstream, and in (v), the receiving terminal is read as the transmitting terminal, and (i) to (vi) I do.
[0025]
Note that the initial 1R target value is set to a value smaller than the above-mentioned initial 1R target value, and the joint connection unit 162 jointly connects the segments in the range in which the cumulative loss amount of the segment exceeds the current 1R target value to one segment. The 1R target value calculation unit 164 calculates the 1R target value of the next section by subtracting from the current 1R target value according to the difference when the cumulative value of the loss amounts of the joint-coupled segments is larger than the 1R target value. You may.
[0026]
The two-way design determination unit 164 compares the 1R number after the upstream segment combining process with the 1R number after the downstream segment combining process, and determines which one has the smaller number, select.
[0027]
4 and 5 are flowcharts showing a network design method. In step S100, steps S2 to S24 in FIG. 12 are performed. In step S102, the process from step S104 in FIG. 4 to step S134 in FIG. 5 is looped for the number of 3R sections. In step S104, the process from step S106 in FIG. 4 to step S130 in FIG. 5 is looped for the downstream direction and the upstream direction. In step S106, an initial 1R target value is calculated. For example, assume that the initial 1R target value is 25 dB. In step S108, the current segment loss is compared with the 1R target value. If the current segment loss is smaller than or equal to the 1R target value, the process proceeds to step S110. If the current segment loss is larger than the 1R target value, the process proceeds to step S116 in FIG. In step S110, the current segment loss and the next segment loss in any one of the downstream direction and the upstream direction are added. In step S112, the two-segment loss is compared with the 1R target value. If the loss of the two segments is smaller or equal to the 1R target value, the process proceeds to step S114. If the loss of the two segments is larger than the 1R target value, the process proceeds to step S116 in FIG. In step S114, the current segment and the next segment are jointly joined to make the current segment, and the process returns to step S110.
[0028]
In step S116 in FIG. 5, the 1R target value of the next 1R section is calculated from the difference between the segment loss and the initial 1R target value and the current 1R target value, and the difference between the segment loss and the initial 1R target value is set as the 1R target. reflect. In step S118, a normalized noise amount is calculated from the segment loss of the current segment after the combination. In step S120, the normalized noise amount of the combined segment is added to the noise accumulation value. In step S122, the noise accumulation value is compared with the 3R noise determination value. If the noise accumulation value is larger than the 3R noise determination value, the process proceeds to step S124. If the noise amount accumulated value is equal to or smaller than the 3R noise determination value, the process proceeds to step S126. In step S124, the 1R target value is changed to a smaller value, the current segment position is returned to the initial state, and the process returns to step S108.
[0029]
In step S126, it is determined whether the current segment is the last segment of the 3R section. If the current segment is not the last segment of the 3R section but has another segment, the process proceeds to step S128. If the current segment is the last segment of the 3R section, the process proceeds to step S130. In step S128, the current segment position is moved to the next segment in any one of the downstream direction and the upstream direction, and the process returns to step S108. In step S130, the process from step S106 in FIG. 4 to step S128 in FIG. 5 is looped for the downstream direction and the upstream direction for the 3R section. In step S132, for the 3R section, the design result of the smaller number of 1Rs after the segment combining process in the downstream direction and the upstream direction is selected, and if the same, any one is selected. In step S134, the process from step S104 in FIG. 4 to step S132 in FIG. 5 is looped for the number of 3R sections.
[0030]
FIG. 6 is a diagram illustrating a network design example. As shown in FIG. 6A, in a transmission network to be designed, stations 24 # 1 to 24 # 13 are installed between a transmitting terminal station 20 and a receiving terminal station 22. It is assumed that each segment loss of the segments 1 to 14 is 5 dB to 15 dB. As shown in FIG. 6B, the determination value of the amount of noise that can be transmitted without a regenerator is 1.00, and the normalized noise amount at a segment loss of 25 dB, 20 dB, 15 dB, 10 dB, and 5 dB is 0.25. , 0.20, 0.15, 0.10, 0.05, and 1R target value is assumed to be 25 dB. In this case, when the network design in step S100 in FIG. 4 is performed, as shown in FIG. 6A, the receivers 24 # 1 to 24 # 5 of 1 segments 1 to 5 have 1R and the receiver of segment 6 as 1R. 3R is assigned to 24 # 6 and 1R is assigned to the receiving sides 24 # 7 to 24 # 13 of the segments 7 to 13. The 3R noise amount determination value of the segments 1 to 6 is 0.75, and the 3R noise of the segments 7 to 14 is 0.75. The amount determination value becomes 0.95.
[0031]
As shown in FIG. 6C, the total loss value of the segments 1 to 4 is 40 dB, which is larger than the 1R target value, and the total loss value of the segments 1 to 3 is 25 dB, which is equal to the 1R target value. Therefore, the segments 1 to 3 are jointed. Since the joint-coupled segment loss is 25 dB, which is equal to the 1R target value, the 1R target value remains at 25 dB. As shown in FIG. 6D, the total loss value of the segments 4 to 6 is 50 dB, which is larger than the 1R target value, and the total loss value of the segments 4 to 5 is 25 dB, which is equal to the 1R target value. Therefore, segments 4 and 5 are jointly connected, and 1R is arranged at the receiving end 24 # 3 of segment 3. Since the loss of the jointed segment is 25 dB, which is equal to the 1R target value, the 1R target value remains at 25 dB. As shown in FIG. 6E, since the loss value of the segment 6 is 25 dB, no joint connection is performed. The normalized noise amounts of the joint-coupled segment losses 25 dB, 25 dB, and 25 dB are 0.25, 0.25, and 0.25, the noise accumulation value is 0.75, and the 3R noise determination values of the segments 1 to 6 are The same is true, and since the last segment of the 3R section has been reached, network design in the downstream direction of the 3R section is completed.
[0032]
As shown in FIG. 7A, since the total loss value of the segments 7 and 8 is 30 dB, 1R is arranged on the receiving side 24 # 7 of the segment 7 without performing joint coupling. The 1R target value is 27 dB in consideration of the difference 5 dB between 25 dB and 20 dB. As shown in FIG. 7B, since the total loss value of the segments 8 to 11 is 35 dB, the segments 8 to 10 are joint-joined, and 1R is arranged on the receiving side 24 # 10 of the segment 10. The 1R target value is 30 dB in consideration of the difference 5 dB between 25 dB and 20 dB and the current 1R target value 27 dB. As shown in FIG. 7C, since the total loss value of the segments 11 to 12 is 30 dB, joint coupling is performed, and 1R is arranged on the receiving side 24 # 12 of the segment 12. The 1R target value returns to 25 dB. Since the total loss value of the segments 13 and 14 is 25 dB, joint coupling is performed. Since the accumulated noise value is 0.95, which is the same as the 3R noise determination value, and the final segment of the 3R section has been reached, the downstream network design of the 3R section is completed.
[0033]
FIG. 8 and FIG. 9 are diagrams showing an example of a review design of the 1R target value. As shown in FIG. 8 (a), the determination value of the noise amount at which the segments 1 to 6 between the transmitting terminal station 20 and the receiving terminal station 22 can be transmitted at 15 dB, 15 dB,... 1.00, the 3R noise determination values of segments 1 to 6 are 0.95, the segment loss is 0.40, 0.25, 0.20, and the normalized noise amounts at 25 dB, 20 dB, 15 dB, 10 dB, and 5 dB, respectively. 0.15, 0.10, and 0.05. It is assumed that the 1R target value is 30 dB, and 25 dB after reviewing the 1R target value.
[0034]
As shown in FIG. 8B, the joint connection is performed because the total loss value of the segments 1 and 2 is 30 dB. The 1R target value remains at 25 dB. Since the total loss value of the segments 3 and 4 is 30 dB, joint coupling is performed. The 1R target value remains at 25 dB. Since the total loss value of the segments 5 and 6 is 35 dB, 1R is arranged on the receiving sides 24 # 5 and 24 # 6 of the segments 5 and 6 without joint coupling. At this time, since the accumulated noise value is 1.15, which exceeds the 3R noise determination value 0.95, the present design result is discarded, the 1R target value is changed to 25 dB, and the following redesign is performed. .
[0035]
As shown in FIG. 9A, since the total loss value of the segments 1 and 2 is 30 dB, 1R is arranged on the receiving side 24 # 1 of the segment 1 without performing joint coupling. The 1R target value is changed to 27 dB. As shown in FIG. 9B, the joint connection is performed because the total loss value of the segments 2 and 3 is 25 dB. The 1R target value remains at 27 dB. As shown in FIG. 9C, since the total loss value of the segments 4 and 5 is 30 dB, 1R is arranged on the receiving side 24 # 4 of the segment 4 without joint coupling. The 1R target value is changed to 29 dB in consideration of the difference 5 dB between 25 dB and 20 dB. As shown in FIG. 9D, since the total loss value of the segments 5 and 6 is 35 dB, no joint connection is performed, and the 1Rs are arranged as they are on the receiving sides 24 # 5 and 24 # 6 of the segments 5 and 6. In addition, since the accumulated noise value is 0.95, which is the same as the 3R noise determination value, and has arrived at the last segment of the 3R section, this design result is adopted.
[0036]
FIG. 10 is a diagram illustrating an example of an upstream network design. The network design conditions shown in FIG. 10A are the same as those in FIGS. 6A and 6B. As shown in FIG. 10B, since the total loss value of the segments 14 and 13 is 25 dB, joint coupling is performed, and 1R is arranged on the receiving side 24 # 12 of the segment 13. The 1R target value remains at 25 dB. As shown in FIG. 10C, since the total loss value of the segments 12 and 11 is 30 dB, 1R is arranged on the receiving side 24 # 11 of the segment 11 without performing joint coupling. The 1R target value is 29 dB in consideration of the difference between 25 dB and 15 dB.
[0037]
As shown in FIG. 10D, since the total loss value of the segments 11 to 9 is 25 dB, the joint coupling of the segments 11 to 9 is performed, and 1R is arranged on the receiving side 24 # 8 of the segment 8. The 1R target value remains at 29 dB. As shown in FIG. 10E, since the total loss value of the segments 8 and 7 is 30 dB, 1R is arranged on the receiving side 24 # 7 of the segment 7 without performing the joint coupling of the segments 8 and 7. The 1R target value is 35 dB in consideration of 5 dB in consideration of the difference between 25 dB and 10 dB. As shown in FIG. 10F, the last segment is reached in the segment 7. Since the accumulated noise amount is 0.95, which is the same as the 3R noise determination value, and the final segment of the 3R section has been reached, the network design in the upstream direction of the segments 14 to 7 is terminated. Then, as shown in FIG. 7D, the number of 1Rs in the downstream direction of the segments 7-14 is three (4 spans), and as shown in FIG. 10F, the number of 1Rs in the upstream direction is Since there are four units (5 spans) and the number of units in the downstream direction is smaller than that in the upstream direction, a downstream design is adopted in the 3R section of the segments 7-14.
[0038]
The present invention includes the following supplementary notes.
[0039]
(Supplementary Note 1) An optical transmission network designing apparatus for an optical transmission network in which a section to be designed from a transmitting terminal station to a receiving terminal station is connected by an optical fiber,
A plurality of points are set in the design target section, and between the transmitting terminal station and the adjacent point of the transmitting terminal station, between two adjacent points, and between the receiving terminal station and the adjacent point of the receiving terminal station, the loss amount of the segment. An arrangement unit that arranges any of a regenerative repeater and a linear repeater at each of the points,
Between the transmitting terminal station and the regenerative repeater arranged closest to the transmitting terminal station, between the regenerative repeater and the regenerative repeater arranged closest to the regenerative repeater, and between the receiving terminal station and the receiving terminal station The optical signal transmitted by the transmitting terminal station or the regenerative repeater disposed on the transmitting side among the both ends of the 3R section for any 3R section between the regenerative repeater and the regenerative repeater arranged closest to A 1R target value calculation unit that calculates a loss amount that can be transmitted without being amplified by the linear repeater as a 1R target value;
In the 3R section, the segment loss amounts are sequentially added in a direction away from the transmitting terminal from the transmitting end, and the cumulative loss amount is compared with the 1R target value. A first combination determination unit that determines whether to combine two segments into one segment;
An optical transmission network designing device, comprising:
[0040]
(Supplementary Note 2) An optical transmission network designing apparatus for an optical transmission network in which a section to be designed from a transmitting terminal station to a receiving terminal station is connected by an optical fiber,
A plurality of points are set in the design target section, and between the transmitting terminal station and the adjacent point of the transmitting terminal station, between two adjacent points, and between the receiving terminal station and the adjacent point of the receiving terminal station, the loss amount of the segment. An arrangement unit that arranges any of a regenerative repeater and a linear repeater at each of the points,
Between the transmitting terminal station and the regenerative repeater arranged closest to the transmitting terminal station, between the regenerative repeater and the regenerative repeater arranged closest to the regenerative repeater, and between the receiving terminal station and the receiving terminal station The optical signal transmitted by the transmitting terminal station or the regenerative repeater disposed on the transmitting side among the both ends of the 3R section for any 3R section between the regenerative repeater and the regenerative repeater arranged closest to A 1R target value calculation unit that calculates a loss amount that can be transmitted without being amplified by the linear repeater as a 1R target value;
In the 3R section, the cumulative loss amounts of the segments are sequentially added in a direction away from the receiving end station from the receiving end, and the cumulative loss amount is compared with the 1R target value, without disposing a linear repeater. A second combination determination unit that determines whether to combine two segments into one segment;
An optical transmission network designing device, comprising:
[0041]
(Supplementary Note 3) In the 3R section, the cumulative loss amounts of the segments are sequentially added in a direction approaching the transmitting terminal from a receiving end point different from the transmitting end, and the cumulative loss amount is compared with the target value. Then, a second combination determination unit that determines whether to combine two segments into one segment without disposing a linear repeater, and a determination result by the first combination determination unit and the second combination determination unit 2. The optical transmission network designing apparatus according to claim 1, further comprising: a bidirectional design determination unit that selects a smaller number of linear repeaters in the 3R section and selects a determination result.
[0042]
(Supplementary Note 4) When the first combination determination unit determines that a plurality of segments are to be combined into one segment, the first combination determination unit may calculate a loss amount of one segment after the combination by adding a loss amount of the plurality of segments before the combination. The optical transmission network design device according to attachment 1, wherein the optical transmission network design device is characterized in that:
[0043]
(Supplementary Note 5) The arranging unit sets the noise amount determination value that can be transmitted without a regenerator to 1 and the segment of the normalized noise amount corresponding to the loss amount of each segment based on the noise amount determination value. 3. The optical transmission network designing apparatus according to claim 1, wherein a linear repeater and a regenerative repeater are arranged based on the sum of the normalized noise amounts of the above and the 3R noise determination value divided by the required number of regenerative repeaters.
[0044]
(Supplementary Note 6) When the first combination determination unit determines that the plurality of segments are to be combined into one segment, the first combination determination unit calculates a loss amount of one segment after the combination by adding a loss amount of the plurality of segments before the combination. The normalized noise amount corresponding to the loss amount of the subsequent segment is calculated, and the sum of the normalized noise amount of the segment after the combination of the 3R sections is compared with the sum of the normalized noise amounts of the segment before the combination, 6. The optical transmission network designing apparatus according to claim 5, wherein it is determined whether to adopt the network design after the connection.
[0045]
(Supplementary Note 7) In a case where the network design after the combination is not adopted, the first combination determination unit changes the value to a value smaller than the 1R target value and determines whether to combine the segments. 7. The optical transmission network design device according to supplementary note 6, wherein
[0046]
(Supplementary Note 8) The first combination determination unit combines the segments until the accumulated value of the loss amounts of the segments in the 3R section becomes the maximum that does not exceed the current 1R target value as one segment, and the 1R target value calculation unit The optical transmission network design according to claim 4, wherein the 1R target value for the next section is calculated by adding the 1R target value to the current 1R target value based on the difference between the initial 1R target value and the loss amount of the one segment. apparatus.
[0047]
(Supplementary Note 9) The first combination determination unit combines the segments until the accumulated value of the loss amounts of the segments in the 3R section becomes a minimum exceeding the current 1R target value as one segment, and the 1R target value calculation unit 5. The 1R target value for the next section is calculated by subtracting the current 1R target value based on the difference between the loss amount of one segment, the initial 1R target value, and the loss amount of the one segment. Optical transmission network design equipment.
[0048]
(Supplementary Note 10) An optical transmission network design program for an optical transmission network in which a design target section from a transmitting terminal station to a receiving terminal station is connected by an optical fiber,
A plurality of points are set in the design target section, and between the transmitting terminal station and the adjacent point of the transmitting terminal station, between two adjacent points, and between the receiving terminal station and the adjacent point of the receiving terminal station, the loss amount of the segment. An arrangement program for arranging any of a regenerative repeater and a linear repeater at each of the points,
Between the transmitting terminal station and the regenerative repeater arranged closest to the transmitting terminal station, between the regenerative repeater and the regenerative repeater arranged closest to the regenerative repeater, and between the receiving terminal station and the receiving terminal station The optical signal transmitted by the transmitting terminal station or the regenerative repeater disposed on the transmitting side among the both ends of the 3R section for any 3R section between the regenerative repeater and the regenerative repeater arranged closest to A 1R target value calculation program for calculating, as a 1R target value, a loss amount that can be transmitted without being amplified by the linear repeater;
In the 3R section, the segment loss amounts are sequentially added in a direction away from the transmitting terminal from the transmitting end, and the cumulative loss amount is compared with the 1R target value. A first combination determination program for determining whether to combine two segments into one segment;
An optical transmission network design program characterized by including:
[0049]
【The invention's effect】
According to the present invention described above, by using the network designing apparatus according to the present invention, it is possible to design a network realizing an automatic segment combining function. As a result, an optimized network design with lower cost can be automatically performed without knowledge of the network design. In addition, network design can be performed more easily and quickly, and it is possible to further improve the responsiveness to customer network design requirements.
[Brief description of the drawings]
FIG. 1 is a principle diagram.
FIG. 2 is a diagram illustrating a network design apparatus according to an embodiment of the present invention.
FIG. 3 is a functional block diagram of a program in FIG. 2;
FIG. 4 is a flowchart showing a network design method of the present invention.
FIG. 5 is a flowchart showing a network design method of the present invention.
FIG. 6 is a diagram showing a network design example (downstream direction).
FIG. 7 is a diagram illustrating a network design example (downstream direction).
FIG. 8 is a diagram showing an example of a review design of a 1R target value.
FIG. 9 is a diagram showing a review design example of a 1R target value.
FIG. 10 is a diagram illustrating a network design example (upstream direction).
FIG. 11 is a functional block diagram of a program in a conventional network design device.
FIG. 12 is a flowchart showing a conventional network design method.
FIG. 13 is a diagram showing a conventional network design example.
FIG. 14 is a diagram illustrating an example in which unnecessary linear repeaters are arranged.
[Explanation of symbols]
50 placement part
52 1R target value calculation unit
54 First Combination Determination Unit

Claims (5)

An optical transmission network designing apparatus for an optical transmission network in which a section to be designed from a transmitting terminal to a receiving terminal is connected by an optical fiber,
A plurality of points are set in the design target section, and between the transmitting terminal station and the adjacent point of the transmitting terminal station, between two adjacent points, and between the receiving terminal station and the adjacent point of the receiving terminal station, the loss amount of the segment. An arrangement unit that arranges any of a regenerative repeater and a linear repeater at each of the points,
Between the transmitting terminal station and the regenerative repeater arranged closest to the transmitting terminal station, between the regenerative repeater and the regenerative repeater arranged closest to the regenerative repeater, and between the receiving terminal station and the receiving terminal station The optical signal transmitted by the transmitting terminal station or the regenerative repeater disposed on the transmitting side among the both ends of the 3R section for any 3R section between the regenerative repeater and the regenerative repeater arranged closest to A 1R target value calculation unit that calculates a loss amount that can be transmitted without being amplified by the linear repeater as a 1R target value;
In the 3R section, the segment loss amounts are sequentially added in a direction away from the transmitting terminal from the transmitting end, and the cumulative loss amount is compared with the 1R target value. A first combination determination unit that determines whether to combine two segments into one segment;
An optical transmission network designing device, comprising: An optical transmission network designing apparatus for an optical transmission network in which a section to be designed from a transmitting terminal to a receiving terminal is connected by an optical fiber,
A plurality of points are set in the design target section, and between the transmitting terminal station and the adjacent point of the transmitting terminal station, between two adjacent points, and between the receiving terminal station and the adjacent point of the receiving terminal station, the loss amount of the segment. An arrangement unit that arranges any of a regenerative repeater and a linear repeater at each of the points,
Between the transmitting terminal station and the regenerative repeater arranged closest to the transmitting terminal station, between the regenerative repeater and the regenerative repeater arranged closest to the regenerative repeater, and between the receiving terminal station and the receiving terminal station The optical signal transmitted by the transmitting terminal station or the regenerative repeater disposed on the transmitting side among the both ends of the 3R section for any 3R section between the regenerative repeater and the regenerative repeater arranged closest to A 1R target value calculation unit that calculates a loss amount that can be transmitted without being amplified by the linear repeater as a 1R target value;
In the 3R section, the cumulative loss amounts of the segments are sequentially added in a direction away from the receiving end station from the receiving end, and the cumulative loss amount is compared with the 1R target value, without disposing a linear repeater. A second combination determination unit that determines whether to combine two segments into one segment;
An optical transmission network designing device, comprising: In the 3R section, the cumulative loss amounts of the segments are sequentially added in a direction approaching the transmitting terminal from a receiving end point different from the transmitting end, and the cumulative loss amount is compared with the target value. A second combination determination unit that determines whether to combine two segments into one segment without disposing a repeater, and compares the determination results by the first combination determination unit and the second combination determination unit. 2. The optical transmission network designing apparatus according to claim 1, further comprising: a bidirectional design judging unit for selecting a judgment result of a smaller number of linear repeaters in the 3R section. The arrangement unit sets a noise amount determination value that can be transmitted without a regenerative repeater to 1, and a normalized noise amount for the segment with a normalized noise amount corresponding to the loss amount of each segment based on the noise amount determination value. When the linear repeater and the regenerative repeater are arranged based on the 3R noise determination value obtained by dividing the sum of the amounts and the required number of regenerative repeaters, the first combination determining unit determines that a plurality of segments are combined into one segment Calculate the loss amount of one segment after the combination by adding the loss amounts of the plurality of segments before the combination, calculate the normalized noise amount corresponding to the loss amount of the segment after the combination, Comparing the sum of the normalized noise amounts in the 3R section with the sum of the normalized noise amounts in the 3R section of the segment before combining, and adopting the network design after combining Optical transmission network designing apparatus according to claim 1, wherein the determining. The first combination determination unit combines the segments until the cumulative value of the loss amounts of the segments in the 3R section reaches the maximum value that does not exceed the current 1R target value as one segment, and the 1R target value calculation unit calculates the initial 1R target value. The optical transmission network designing apparatus according to claim 4, wherein a 1R target value for the next section is calculated by adding the 1R target value to the current 1R target value based on a difference between the current 1R target value and the loss amount of the one segment.

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