JPH0818541A - Optical communication equipment - Google Patents

Abstract

PURPOSE:To allow the system itself to countermeasure a fault on the occurrence of a fault at a receiver side by detecting a signal light not detected by an extract means and providing an extract replacement means extracting the signal light in place of the extract means corresponding to the detected signal light to the communication equipment. CONSTITUTION:When an optical reception section 85 detects the occurrence of a fault in an optical band pass filter 37 or an optical reception unit 81, a control signal representing it is outputted to a local oscillation light source 89. The light source 89 outputs an optical lambdai oscillation light 93 of the same wavelength as that of a fault occurrence signal light and an optical distributer 82 synthesizes the light with a light 83 distributed in excess and the synthesized light is received by an optical reception section 84. The optical reception section 84 detects a light passing through an optical band pass filter 94 and the optical reception section 84 outputs a synchronizing signal 95 used to make a wave front of the distributed wave 83 in matching with that of a locally oscillated wave 93 to the light source 89. As a result, the wave front of the signal light 83 and that of the local oscillation light 93 are in matching with each other. Since the filter 94 does not pass the beat frequency light, a wavelength lambdai is obtained from the synthesized light after passing through the filter. The light whose wavelength is lambda1 is outputted at an optical changeover device in place of an output from the light receiving section 85 due to the fault to obtain light whose the wavelength is lambda1, that has not been extracted.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical communication apparatus for performing communication by using an optical signal obtained by multiplexing light beams each having a unique wavelength. For example, the present invention relates to an optical communication apparatus effective against a line abnormality.

[0002]

2. Description of the Related Art An optical fiber used for optical communication has a characteristic that a signal transmission band is wide. In order to make effective use of this feature, in the field of optical communication, it is common practice to multiplex a plurality of optical signals having different wavelengths onto one optical fiber and transmit the multiplexed optical signals. Such a communication system is a wavelength division multiplexing optical communication system or a frequency division multiplexing (FDM).
This is called an optical communication system.

According to this communication method, a large amount of information can be transmitted at one time by one optical fiber.
Nowadays, demands for large-capacity optical communication are increasing, and even if the transmission band of the optical fiber is wide, the wavelength interval of the multiplexed optical signal must be narrowed. Therefore, various publications such as Japanese Patent Laid-Open No. 62-122344 have proposed various transmission methods capable of sufficiently demodulating signals even if the wavelength interval is narrow.

By the way, in an optical communication system in which a large number of signal lights are transmitted at a time due to multiplexing, the structure of the optical communication device becomes complicated and the number of constituent parts increases. If even some of the components fail, a circuit abnormality may occur in which a signal cannot be extracted from light of a certain wavelength. In particular, in the highly computerized modern age, since some of these line abnormalities cause the entire system to stop, it is important to provide a redundant configuration for the communication device. Therefore, conventionally, a standby communication device is prepared separately from the current communication device, and when an abnormality occurs, the line is switched to the standby communication device to ensure communication reliability.

FIG. 2 shows an example of such a conventional frequency division multiplexing optical communication device. First, the configuration on the transmitting side will be described. ,..., 13 to which the signal lights λ ₁ , λ ₂ , λ _n having different wavelengths are input, respectively, are connected to the optical switch 14. Have been.

FIG. 3 shows such signal lights λ ₁ , λ ₂ , λ _n.
It shows an example of. Optical switching device 1 shown in FIG.
4 are provided with corresponding optical switching devices 15, 16, ... 17 respectively, and the first, second ,.
Each of the optical signals input from 1, 12,..., 13 is switched to one of two output destinations. That is, the optical switch 15 sends an optical signal input from the optical fiber 11 to the optical fiber 18 or 19, the optical switch 16 sends an optical signal input from the optical fiber 12 to the optical fiber 20 or 21, and the optical switch 17 Is the optical fiber 1
The optical signal input from 3 is switched to 22 or 23. The output side of the optical switching device 14 is connected to two systems of optical transmitters 24 and 25 for multiplexing the signal light input through n optical fibers. The optical transmitter 24 is an active system, and the optical transmitter 25 is a standby system. The outputs of these optical transmitters 24 and 25 are optical fibers 26 and 2 respectively.
7, and is input to the optical switch 28. The optical switching device 28 selects one of these and sends it to the optical fiber 29 of the active system or the optical fiber 30 of the standby system.

Next, the configuration of the receiving side will be described. On the receiving side, the optical fibers 29 and 30 of the respective systems are connected to the corresponding optical receiving units 31 and 32. In the active optical receiving unit 31, the optical distributor 29 is connected to the optical fiber 29.
3 are connected and distribute these to n multiplexed optical signals. The distributed n optical signals 34, 35, ..., 3
Reference numeral 6 denotes n optical band-pass filters 38, 39,..., 40 for extracting light having specific wavelengths of λ ₁ , λ ₂ , and λ _n , respectively.
Is input to. The light having the unique wavelengths of λ ₁ , λ ₂ , and λ _n obtained as described above is input to the light receiving units 45, 46,... Optical receiver 45, 4
,..., 47 and the light whose signal level has been adjusted are transmitted to the corresponding n optical fibers 48, 49,.
Sent to 0. These optical fibers 48, 49, ...
, 50 are connected to an optical switching device 69. The optical fibers 48, 49, ..., 50 are input to corresponding ones of the optical switching devices 70, 71 ,.
One of the lights input from 6, 67, ..., 68 is selected. The light of each selected wavelength is sent to a device (not shown) in the subsequent stage through the corresponding n optical fibers 73, 74, ..., 75.

Since the configuration of the standby optical receiving unit 32 is the same as that of the working optical receiving unit 31, the description of that part is omitted.

In such an optical communication apparatus, signal light having unique wavelengths λ ₁ , λ ₂ ,..., Λ _n is input to each of n optical fibers 11, 12,. You. The optical switching device 14 normally selects the active system, and transmits the optical transmitter 24 via the optical fibers 18, 20,.
These signal lights are input to the. The optical transmitter 24 multiplexes these signal lights and sends them to the optical fiber 26. If any abnormality occurs in this system, signal light processing via the optical transmitter 25 is performed.

The multiplexed signal light transmitted from the optical fiber 26 or the optical fiber 27 is selected by the optical switch 28, and is usually transmitted to the working optical receiving unit 31 via the optical fiber 29. You. In the optical receiving unit 31, the optical distributor 33 distributes these signal lights into n pieces, and n pieces of optical bandpass filters 38, 39, ...
Respectively, and the corresponding signal light is extracted. These extracted signal lights are transmitted to the optical receivers 45 and 46,
, 47 and optical fibers 48, 49, ..., 50 to reach the optical switching device 69, from which they are sent to the corresponding n optical fibers 73, 74 ,. Will be. Standby optical receiving unit 32
The description of the operation is omitted.

As described above, the conventional optical communication apparatus is provided with a transmitter and a receiver having exactly the same configuration, which is composed of two systems, that is, a working system and a standby system. By switching the optical signal transmission line to a spare device, optical communication was enabled even when a line abnormality occurred.

[0012]

However, in such an optical communication device, an abnormality of the device is detected by the optical receiving units 31, 32.
Occur relatively often. The reason is as follows.
First, the transmitter multiplexes the signal light of each wavelength. Even if the number of signal lights to be processed is increased, a similar signal processing portion is simply added. That is, the configuration of the transmitter is simpler than that of the receiver, and the signal light of a specific wavelength to be transmitted is rarely lost. Even in an optical fiber that is an optical signal transmission line, there is a case where only a specific wavelength is not transmitted in the middle of the transmission. However, on the receiver side, a filter and many other circuit devices are required to extract the target signal light from the multiplexed signal light. For this reason, the probability of failure as a whole increases, and a relatively large number of cases in which signal light of some wavelengths cannot be extracted occur. Of course, considerable reliability can be ensured by duplicating the communication system as shown in FIG. 2, but it has been desired to further increase the reliability as the importance to optical communication increases.

SUMMARY OF THE INVENTION It is an object of the present invention to provide an optical communication device capable of taking measures against a failure in the system itself when a failure occurs on the receiving side for receiving the multiplexed signal light.

[0014]

According to a first aspect of the present invention, there are provided: (a) extracting means for extracting each of these unique signal lights from an optical signal obtained by multiplexing the respective unique signal lights; The optical communication device is provided with a detecting means for detecting the signal light not extracted by the extracting means, and (c) an extracting alternative means for extracting the signal light instead of the extracting means corresponding to the signal light detected by the detecting means. .

That is, according to the first aspect of the present invention, when these unique optical signals are extracted from the optical signals obtained by multiplexing the unique optical signals, if there is any signal light that is not extracted due to a failure, this signal is extracted. Detected by the detection means,
Instead of the extracting means corresponding to the signal light detected by the detecting means, the extracting alternative means for extracting the signal light is prepared in the optical communication device. For example, even when the light having the wavelength of λ ₁ is not extracted by the original extracting means, the light is extracted by the extracting alternative means. In the invention according to claim 1, the term "multiplexing" includes not only frequency multiplexing but also time division multiplexing.

According to the second aspect of the invention, (a) an optical band prepared for each wavelength for extracting the light of each of the unique wavelengths from the optical signal obtained by frequency-dividing and multiplexing the lights of the respective unique wavelengths. A pass filter, (b) detection means for detecting light of a specific wavelength corresponding to each of these optical band pass filters prepared for each wavelength, and (c) frequency division multiplexed light The optical communication device is provided with an optical bandpass filter alternative means for inputting a signal and extracting the light of its specific wavelength instead when the detection means detects it.

That is, in the invention described in claim 2, when the signal light is extracted from the frequency-multiplexed signal light by using the corresponding optical bandpass filters, the corresponding signal light is not extracted. In this case, the same frequency-multiplexed signal light is input and the corresponding optical signal is obtained instead by the optical bandpass filter alternative means.

According to the third aspect of the invention, (a) a first signal prepared for each wavelength for extracting light of these unique wavelengths from an optical signal obtained by frequency-dividing and multiplexing light having unique wavelengths. Optical band pass filter, and (b) detection means for detecting an abnormality in the light of the specific wavelength extracted from the optical band pass filters prepared for each wavelength, and (c) this detection When an anomaly is detected by the means, a light output means for outputting a light of the same wavelength as the light of which the abnormality is detected, and (d) the light output from the light output means is frequency-division multiplexed. An optical communication device is provided with a second optical band pass filter for inputting light and extracting light of a wavelength having an abnormality in the optical band pass filter instead.

That is, according to the third aspect of the invention, in the case of extracting the signal light of the frequency-division-multiplexed signal light by using the corresponding first optical bandpass filters,
When the corresponding signal light is not extracted, the light output means outputs the light of the same wavelength, and the signal light frequency-multiplexed with this is used to output the same wavelength by the second optical bandpass filter. Is extracted from this frequency-multiplexed signal light.

Such alternative extraction can be performed, for example, by optical heterodyne reception having a local oscillation light source in the receiving section. Here, the optical heterodyne reception is to receive the signal light sent from the optical transmission device by multiplexing the light of the local oscillation light source built in the optical reception device under a predetermined condition. Incidentally, the frequency control of the locally oscillated light, which greatly influences the reception state in the optical communication utilizing the optical heterodyne reception, is described in JP-A-62-18157.

According to the invention described in claim 4, (a) an optical band prepared for each wavelength for extracting the light of each unique wavelength from the optical signal obtained by frequency-dividing and multiplexing the light of each unique wavelength. A pass filter, and (b) photoelectric conversion means for converting light of a specific wavelength extracted from the optical band pass filter prepared for each wavelength into an electric signal,
(C) Detection means for detecting an abnormality when an abnormality occurs in the electric signal obtained by these photoelectric conversion means,
(D) A light emitting means for outputting light of the same wavelength as the light of the wavelength before the electric signal in which the abnormality is detected is photoelectrically converted when the abnormality is detected by the detecting means, and (e) the light emitting means. Second photoelectric conversion means for inputting the output light and the frequency-division-multiplexed light, selecting the light of the same wavelength as the light of the abnormal wavelength from the latter light, and obtaining the electric signal thereof; Are provided in the optical communication device.

That is, in the invention described in claim 4, when the signal light is extracted by using the corresponding first optical bandpass filters for the frequency-divided signal light,
The signal light is converted into an electric signal by using the photoelectric conversion means, and the abnormality is also detected by using the electric signal. The alternative means is the second photoelectric conversion means, and similarly, the necessary signal light is photoelectrically converted and obtained as an electric signal.

The invention according to claim 5 indicates that the optical communication apparatus according to any one of claims 1 to 4 described above may be duplicated on the receiving side. It goes without saying that the duplexing further improves the reliability. It is also free to duplicate the sender side as well.

[0024]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail below with reference to embodiments.

FIG. 1 shows the configuration of an optical communication apparatus according to one embodiment of the present invention. First, the configuration on the transmitting side will be described. The same parts as those in FIG. 2 are designated by the same reference numerals, and the description thereof will be appropriately omitted. Signal light λ ₁ , λ with different wavelengths
_2, first, second to lambda _n is inputted, ..., n-th
, 13 are connected to the optical switch 14. The optical switching device 14 includes corresponding optical switches 15, 16,..., 17, and the first, second,..., N-th optical fibers 11, 12,.
The optical signal input from 13 is switched to one of two output destinations (however, the standby system is not necessarily required in the present invention, and is not shown). The output side of the optical switching device 14 is connected to an optical transmitter 24 that multiplexes the signal light input through n optical fibers. The output of the optical transmitter 24 is input to the optical switch 28 via the optical fiber 26.

Next, the configuration of the receiver will be described. In the optical receiving unit 81, the optical fiber 29 is connected to the optical distributor. The optical distributor 82 distributes more input signal lights than the number (n) of multiplexed signal lights. 1 in the figure
The number of distributions depends on how much redundancy is to be increased, and is not limited to this. Of the light distributed by the optical distributor 82, the signal lights 34, 35,.
, 36 are the corresponding optical bandpass filters 38,
39,..., 40. On the other hand, the signal light 83 allocated extra is input to the optical receiver 84. The signal lights 41, 4 of the specific wavelengths λ ₁ , λ ₂ , λ _n extracted by the optical band-pass filters 38, 39,.
2 and 43 are input to the optical receiving units 86, 87 and 88. .., 50 and the optical switching device 69, and the n optical fibers 73, 74,.
, 75 are sent to the corresponding ones.

By the way, the optical receiving unit 8 of this embodiment
In 1, a local oscillation light source 89 is prepared in case one of the optical receiving units 85 cannot receive a predetermined optical signal. Signal lines 90, 91, and 92 for transmitting a light emission control signal for driving the local oscillation light source 89 are drawn from the respective light receiving units 86, 87, and 88 of the light receiving unit 85, and are output from the local oscillation light source 89. It is connected to the. As described above, the optical receiving unit 85 outputs the signal light and also detects the abnormality of the light extracted by the optical band-pass filter 37. Local oscillation light 9 output from local oscillation light source 89
3 is input to the optical receiver 84. The light receiving unit 84 is provided with a band-pass filter that allows light of specific wavelengths λ ₁ , λ ₂ ,..., Λ _n to pass. A synchronization signal 95 for synchronizing the signal light 83 and the local oscillation light 93 is input to the local oscillation light source 89 from the optical receiver 84. When light of a predetermined wavelength is extracted in synchronization, the extracted light 96 is output to the optical switching device 69.

The operation of the optical communication device will be described below. The frequency-division-multiplexed optical signal is input from the optical fiber 29 to the optical distributor 82 of the optical receiving unit 81. The optical distributor 82 further outputs a signal light 83 in addition to the n signal lights 34, 35,... N signal lights 3 of them
.., 36 are optical bandpass filters 3 respectively.
The light 41, 42, ..., 43 having specific wavelengths of λ ₁ , λ ₂ , and λ _n are extracted and inputted to 8, 39, and 40. The extracted light 41 of wavelengths λ ₁ , λ ₂ , and λ _n ,
42 and 43 are input to the optical receivers 45, 46 and 47.
These lights are converted into electric signals by a photoelectric converter (not shown) in this embodiment, the signal level is adjusted, and then converted into signal lights again to be output to the optical fibers 48, 49 and 50. When the extracted lights 41, 42, ..., 43 having wavelengths of λ ₁ , λ ₂ , ..., λ _n are output as they are, the optical receiving unit 85 uses the optical bandpass filter 37 to output signal light of a predetermined wavelength. It is sufficient if there is an element (for example, a normal light receiving element) for detecting whether or not is actually input.

Normally, communication is performed in this manner. However, an abnormality occurs in the optical receiving unit 81, for example, the optical band-pass filter 37 or the optical receiving unit 85, and signal light of a specific wavelength cannot be extracted. An abnormality such as loss of frame synchronization may occur in the received signal. In such a case, the optical receiver 84 extracts an optical signal that could not be acquired due to an abnormality due to the optical heterodyne reception.
First, when any of the optical receivers 85 detects the occurrence of an abnormality, a control signal to that effect is output to the local oscillation light source 89. Upon receiving this signal, the local oscillation light source 89 outputs light having the same wavelength as that of the abnormal signal light, for example, λ _i .
Then, the oscillating light 93 and the light 83 extraly distributed by the optical distributor 82 are multiplexed, and the multiplexed light is received by the optical receiver 84. On the other hand, the wavelengths λ ₁ , λ
₂ , ..., There is an optical bandpass filter 94 that matches λ _n .

At first, the combined light received by the optical receiver 84 does not match the wavefront with the signal light 83 because the oscillation of the local oscillation light 93 is random, and a predetermined signal light cannot be obtained.
By detecting the light passing through the optical band-pass filter 94, a synchronization signal 95 for matching the wavefront of the distribution wave 83 and the local oscillation wave 93 is output from the optical receiving unit 84 to the local oscillation light source 89. As a result, the wavefronts of the signal light 83 and the local oscillation light 93 coincide with each other. At this time, the signal light of another wavelength is canceled by the beat component due to the frequency difference from the local oscillation light 93, and the optical band-pass filter 94 does not allow the light of the beat frequency to pass. As the wave light, a signal light having a wavelength λ _i is obtained. By switching the output from the optical receiving unit 85, which has failed to extract the signal light due to an abnormality, and the optical switching device 69, the light having the wavelength λi that cannot be extracted due to the abnormality can be obtained.

Therefore, the redundancy of communication can be increased even when the conventional dual system configuration is not employed. In particular, when extremely high reliability is not required, components such as the optical switches 11 and 12 and other spare transmitters become unnecessary, so that an inexpensive communication device having almost the same reliability as the conventional one can be obtained. it can.

In the above-described embodiment, the frequency multiplexed optical signal is handled. However, when a failure occurs on a receiving side in a part of each frequency-divided signal light, the multiplexing is similarly performed. By providing alternative means for extracting the corresponding signal light from the obtained optical signal, the reliability of the optical communication device can be improved.

[0033]

As described above, claims 1 to 5 are as follows.
According to the invention described above, even if some trouble occurs in the processing of a part of the signal light on the receiving side, this signal light can be reproduced by the alternative means. Therefore, it is easy to duplicate the communication system. The configuration can maintain reliability.

Further, according to the invention of claim 5, the communication system is duplicated, so that the reliability can be further enhanced.

[Brief description of drawings]

FIG. 1 is a block diagram showing an overall configuration of an optical communication device in an embodiment of the present invention.

FIG. 2 is a block diagram showing a configuration of a conventional duplex optical communication device.

FIG. 3 is an explanatory diagram showing an example of each signal light input to the optical communication device.

[Explanation of symbols]

 14, 69 Optical switching device 28 Optical switching device 29, 48-50 Optical fiber 37-40 Optical bandpass filter 81 Optical receiving unit 82 Optical distributor 84-88 Optical receiving unit 89 Local oscillation light source

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification code Internal reference number FI technical display area H04L 1/22

Claims (5)

[Claims] 1. Extraction means for respectively extracting these unique signal lights from an optical signal obtained by multiplexing the respective unique signal lights, detection means for detecting the signal light not extracted by this extraction means, and this detection means An optical communication device comprising: an extraction substituting means for extracting the signal light instead of the extraction means corresponding to the detected signal light. 2. An optical bandpass filter prepared for each wavelength for extracting light of these unique wavelengths from an optical signal obtained by frequency-dividing and multiplexing light of each unique wavelength, and for each of these wavelengths. Detecting means for detecting the light of a specific wavelength corresponding to them from the optical bandpass filter, and the characteristic when the detecting means detects the frequency-division multiplexed optical signal. An optical communication device, comprising: an optical bandpass filter alternative means for extracting light of a wavelength instead. 3. A first optical bandpass filter prepared for each wavelength for extracting lights of these unique wavelengths from an optical signal obtained by frequency-dividing and multiplexing lights of respective unique wavelengths, and these wavelengths. A detecting means for detecting an abnormality in the light of the specific wavelength extracted from the separately prepared optical bandpass filter, and the wavelength at which the abnormality is detected when the detecting means detects the abnormality. Light output means for outputting light having the same wavelength as that of the light, and the light output from the light output means and the frequency-division-multiplexed light are input and the An optical communication device, comprising: a second optical bandpass filter for extracting light instead. 4. An optical bandpass filter prepared for each wavelength for extracting light of these unique wavelengths from an optical signal obtained by frequency-dividing and multiplexing light having respective unique wavelengths, and for each of these wavelengths. A photoelectric conversion means for converting light of a specific wavelength extracted from the optical bandpass filter into an electric signal, and a detection means for detecting the abnormality when the electric signal obtained by these photoelectric conversion means has an abnormality, When an abnormality is detected by the detection means, an optical output means for outputting the light of the same wavelength as the light of the wavelength before the electric signal in which the abnormality is detected is photoelectrically converted, and the light output from the optical output means Second photoelectric conversion means for inputting the frequency-division-multiplexed light and selecting light of the same wavelength as the light of the abnormal wavelength from the latter light to obtain its electric signal. Optical communication apparatus according to claim. 5. The means for receiving the multiplexed optical signals and extracting the respective signal lights, and the means for extracting the signal lights in which a failure has occurred instead are duplicated. ~ The optical communication device according to claim 4.