The present application claims priority from Japanese application JP 2004-033151, filed on Feb. 10, 2004, the content of which is hereby incorporated by reference into this application.
1. Field of the Invention
The present invention relates to an optical transmission system for transmitting data by multiplexing a plurality of optical signals having different wavelengths. More specifically, the present invention relates to an optical add-drop multiplexer for dropping or adding an optical signal having a specific wavelength out of or to multiplexed optical signals.
2. Description of Related Art
Wavelength-division-multiplexed optical transmission systems for multiplexing optical signals having different wavelengths and transmitting the multiplexed signals through an optical fiber use an optical add-drop multiplexer. The optical add-drop multiplexer drops an optical signal having a specific wavelength to be received in a communication node, or adds an optical signal to be transmitted in this communication node to the above-described wavelength-division-multiplexed optical signals.
The communication node 12 needs the optical add-drop multiplexers for dropping an optical signal having a specific wavelength out of wavelength-division-multiplexed optical signals transmitted from an adjacent communication node, and for adding an optical signal to be transmitted from the communication node 12 to the wavelength-division-multiplexed optical signals. That is, the communication node 12 needs one optical add-drop multiplexer for each direction where a signal is transmitted (in
This communication node construction needs an optical add-drop multiplexer for each transmission direction (its example is described in Japanese Patent Laid-open No. 10-20143). Therefore, there arise problems in which the communication cost is increased due to this expensive device, the probability of failure doubles due to the complicated device, as a result, reliability of the communication system falls, and an office space is largely occupied.
A problem to be solved by the invention is that bidirectional transmission between communication nodes needs a plurality of optical add-drop multiplexers, which increases the communication cost.
Most principal characteristic of the present invention is that an optical circulator or an optical coupler is arranged at an input/output port of an optical add-drop multiplexer and wavelength-division-multiplexed optical signals are assembled for each direction.
The optical add-drop multiplexer of the present invention can realize a function of dropping or adding a wavelength-division-multiplexed optical signal for each direction in which an optical signal is transmitted by itself, so that the cost can be reduced to almost half as compared with that in the conventional construction. In addition, the multiplexer of the present invention has the advantages that its simplified construction enhances reliability and further, reduces its installation space.
In an optical transmission system where adjacent communication nodes are connected to each other through a plurality of optical fibers, add-drop multiplexing of an optical signal is realized in each communication node with minimum construction.
The optical add-drop multiplexer 3 in the communication node 12 drops an optical signal having a specific wavelength i addressed to the communication node 12 from wavelength-division-multiplexed optical signals and outputs it to an add-drop port 8-i or 9-i (i=1, 2, . . . n). Incidentally, notation “i” of, e.g., 8-i corresponds to a wavelength i. The optical add-drop multiplexer 3 in the communication node 12 adds the optical signal having the wavelength i to be transmitted to another communication node from the add-drop port 8-i or 9-i (i=1, 2 . . . n) to the wavelength-division-multiplexed optical signals. In the figure, only add-drop ports 8-1, 9-1, 8-n and 9-n are depicted; however, in practice, the add-drop ports for the other wavelengths are also provided. Needless to say, the maximum number of ports is equal to the number (n) of wavelength-division-multiplexed optical signals. A difference between the add-drop ports 8-i and 9-i is to be described. When an optical signal having a wavelength i is dropped out of wavelength-division-multiplexed optical signals inputted from the input/output port 2 of the optical add-drop multiplexer 3, the dropped optical signal having a wavelength i is output to the add-drop port 8-i. On the other hand, when an optical signal having a wavelength i is dropped out of wavelength-division-multiplexed optical signals inputted from an input/output port 4, the dropped optical signal having a wavelength i is outputted to the add-drop port 9-i. When an optical signal having a wavelength i is added from the add-drop port 8-i, the optical signal is wavelength-multiplexed with other wavelength-division-multiplexed optical signals in the optical add-drop multiplexer 3 and the multiplexed signals are outputted from the input/output port 2. When an optical signal having a wavelength i is added from the add-drop port 9-i, the optical signal is wavelength-multiplexed with other wavelength-division-multiplexed optical signals by the optical add-drop multiplexer 3 and the multiplexed signals are outputted from the input/output port 4. The ports 8-i and 9-i are defined as above.
Next, connection between the communication nodes is to be described. For example, as shown in
An optical signal to be transmitted from the communication node 12 to the communication node 12-1 in
Several examples of the specific internal construction of the optical add-drop multiplexer 3 are known.
For example, wavelength-division-multiplexed optical signals (having respective wavelengths of λ1, λ2, . . . , λn) inputted from the input/output port 2 are wavelength-demultiplexed into n optical signals having different wavelengths by the optical multiplexer/demultiplexer 17-1, and the optical signals of different wavelengths are outputted from the add-drop ports 8-1, . . . , 8-n, respectively. In this figure, only the add-drop ports 8-1 and 9-1 of the optical add-drop multiplexer for the wavelength λ1, and the add-drop port 8-n and 9-n for the wavelength λn are depicted; however, the add-drop ports 8-i and 9-i (i=1, 2, . . . , n) for n wavelengths λ1, λ2, . . . , λn in the wavelength-division-multiplexed optical signal are provided in practice.
If the add-drop ports 8-1 and 9-1 are connected to each other through a short optical fiber, an optical signal having a wavelength, e.g., λ1 passing through a communication node is wavelength-multiplexed with an optical signal having another wavelength by the optical multiplexer/demultiplexer 17-2 and the wavelength-multiplexed optical signals are transmitted from the input/output port 4. On the other hand, an optical signal having a wavelength, e.g., λn can be received by this communication node, if the add-drop port 8-n is connected to an optical receiver installed within the communication node. Further, when an optical signal having a wavelength, e.g., λn is transmitted from this communication node to another communication node, the add-drop port 9-n is connected to an optical transmitter installed within the communication node. This optical signal is wavelength-multiplexed with an optical signal having another wavelength by the optical multiplexer/demultiplexer 17-2 and the wavelength-multiplexed optical signals are transmitted from the input/output port 4.
The above example describes a case where wavelength-division-multiplexed optical signals are inputted from the input/output port 2. The same is true of a case where wavelength-division-multiplexed optical signals are inputted from the input/output port 4. That is, this optical add-drop multiplexer operates irrespective of a traveling direction of an optical signal.
The above example describes a case where wavelength-division-multiplexed optical signals are inputted from the input/output port 2. The same is true of a case where a wavelength-division-multiplexed optical signal is inputted from the input/output port 4. That is, this optical add-drop multiplexer operates irrespective of a traveling direction of an optical signal.
Operations of the optical add-drop multiplexer 3 in
On the other hand, the optical signal having the wavelength λn passes through the optical circulator 24-1, the fiber Bragg grating 23-1 and the optical circulator 25-1. Similarly, the optical signal passes through the optical circulators and fiber Bragg gratings for the other wavelengths and reaches the optical circulator 24-n. The optical signal that has passed through this optical circulator is reflected by the fiber Bragg grating 23-n, passes through the optical circulator 24-n again and is outputted to the add-drop port 8-n. Connected to this port 8-n, a receiver receives the optical signal having the wavelength λn.
When the optical signal having the wavelength λn is transmitted to another communication node (assuming 12-2 in
The above example describes a case where wavelength-division-multiplexed optical signals are inputted from the input/output port 2. The same is true of a case where wavelength-division-multiplexed optical signals are inputted from the input/output port 4. That is, this optical add-drop multiplexer operates irrespective of a traveling direction of an optical signal.
Now, arrangement of optical transmitters and receivers in a case of carrying out communication between the communication nodes each provided with the optical add-drop multiplexer in the first embodiment is described below.
A case where the communication node 12 and communication node 12-1 in
The optical signal having the wavelength i from the optical transmitter 26-i within the communication node 12 passes through the optical circulator 28-i, and is wavelength-division-multiplexed with optical signals having other wavelengths by the optical add-drop multiplexer 3. The multiplexed optical signals propagate through the optical fiber 6 for transmission through the optical circulator and reaches the communication node 12-1. Then, the optical signal having the wavelength i is dropped from the optical signals having the other wavelengths by the optical add-drop multiplexer 3-1, and is outputted from the add-drop port 9-i-1. After passing through the optical circulator 28-i-1, this optical signal having the wavelength i is received by the optical receiver 27-i-1.
Similarly, the optical signal having the wavelength i outputted from the optical transmitter 26-i-1 within the communication node 12-i is wavelength-division-multiplexed with the other wavelength-division-multiplexed optical signals by the optical add-drop multiplexer 3-1. The multiplexed optical signals propagate through the optical fiber 1 for transmission and reach the communication node 12. Then, the optical signal having the wavelength i is dropped from the optical signals having the other wavelengths by the optical add-drop multiplexer 3, and is outputted from the add-drop port 8-i. After passing through the optical circulator 28-i, this optical signal having the wavelength i is received by the optical receiver 27-i. As described above, the communication nodes 12 and 12-1 can perform communication therebetween using the optical signal having the wavelength i. In the above description of
When the optical circulator according to the first embodiment is used, an insertion loss of the optical circulator is on the order of 0.5 dB and therefore, a transmission loss of light is small, in particular, as compared with that in a second embodiment described later. Further, an optical circulator advantageously have the transmissive directivity of light, and therefore, it eliminates an optical isolator used in combination therewith, that is, it reduces the number of components.
Wavelength-division-multiplexed optical signals traveling in directions opposite to each other are combined by using optical couplers as below. For example, wavelength-division-multiplexed optical signals that are outputted from the input/output port 2 and travel toward a left communication node on the paper are about to propagate, from the optical coupler, through both the optical fibers 1 and 6 for transmission. For this reason, an optical isolator 15 is used so that the optical signals will not propagate through the optical fiber 1 in the opposite direction. Similarly, an optical isolator 16 is used so that wavelength-division-multiplexed optical signals transmitted from the port 4 to a right communication node on the paper will not be allowed to propagate through the optical fiber 11 in the opposite direction.
The optical add-drop multiplexer 3 in
The optical transmitter and receiver configuration where communication between the communication nodes is carried out concretely by the optical signal having the wavelength i according to the second embodiment may be the same as that described in the first embodiment. That is, the configuration is as shown in
According to the second embodiment, an insertion loss of the optical coupler is 3 dB or more; however, the optical coupler has an advantage that the component costs can be reduced as compared with the optical circulator for use in the first embodiment. Further, the optical coupler has an advantage that the device costs can be totally reduced to half even taking into consideration the component costs of an optical isolator used in combination with an optical coupler.
Lastly, reduction in the cost of an optical add-drop multiplexer as an object of the present invention is quantitatively estimated as compared with that in conventional example. The cost of optical components in a communication node is taken up among the costs. It is assumed that the number of multiplexed signals in wavelength-division-multiplexed optical signals is 16. The cost of optical components in a communication node is a function of the number of added or dropped optical signals in the communication node.
A second example of the cost comparison is shown in
As seen from the above-described two examples, the present invention can reduce the cost of communication nodes.
Incidentally, description of reference numerals used in the drawings of this application is as follows:
1, 1-1, 5, 5-1, 6, 6-1, 11, 11-1 . . . . Optical fibers for transmission connecting communication nodes, 2, 4, 2-A, 4-A, 2-B, 4-B . . . Input/output ports of optical add-drop multiplexer, 3, 3-A, 3-B . . . Optical add-drop multiplexers, 7, 10, 24-1, 24-n, 25-1, 25-n, 28-i, 28-i-1 . . . Optical circulators, 8-1, 8-n, 9-1, 9-n, 8-1-A, 8-n-A, 9-1-A, 9-n-A, 8-1-B, 8-n-B, 9-1-B, 9-n-B, 9-i-1 . . . Add/drop ports of optical of add-drop multiplexer, 12, 12-1, 12-2 . . . Communication nodes, 13, 14 . . . Optical couplers, 15, 16 . . . Optical isolators, 17-1, 17-2 . . . Optical multiplexers/demultiplexers, 20-1, 20-n . . . Optical switches having two inputs and two outputs, 21-1, 21-n, 22-1, 22-n . . . Optical switches having one input and two outputs, 23-1, 23-n . . . Fiber Bragg gratings, 26-i, 26-i-1 . . . Optical transmitters, 27-i, 27-i-1 . . . Optical receivers.
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