JP2567776B2 - Optical transmission system - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention is used in an optical transmission system for multiplexing and transmitting a large number of signals using an optical fiber as a transmission medium and extracting a desired signal from the transmitted multiplexed signals.

[0002]

2. Description of the Related Art Multiplexing of signals in a conventional optical transmission system has been performed by TDM (time domain multiplexing) or WDM (wavelength multiplexing).

In TDM, the band of the light source and the light receiving element,
The transmission signal rate is limited by the band of the electric circuit system and the dispersion characteristics of the optical fiber, and the transmission rate reported up to now has been about 30 Gb / s at the maximum.

In WDM, in principle, the number of wavelength division multiplexes is determined by the transmission bandwidth of the optical fiber and the occupied bandwidth of the signal light, but it is determined in advance by a large number of light sources whose absolute wavelengths of light are guaranteed. A high-precision narrow-band optical filter that can be set to a different signal wavelength is required.
It remains in multiplex 00.

[0005]

As described above, the conventional optical transmission system has a drawback that the transmission speed is limited in TDM and the number of multiplexes is limited in WDM, so that the system cannot be sufficiently economical.

It is an object of the present invention to eliminate the above-mentioned drawbacks to significantly reduce the band limitation in the TDM transmission system and the wavelength accuracy of the light source system and the demultiplexing filter in the WDM transmission system, thereby significantly reducing the wavelength multiplexing number. An object of the present invention is to provide an optical transmission method that enables expansion and makes the system economical.

[0007]

The present invention is an optical transmission system comprising means for wavelength-multiplexing signal light from a transmitting end station to a receiving end station and transmitting the signal light through a fiber, wherein the transmitting end station is an N line ( N ≧ 1) data strings are wavelengths λ1, λ2, ...
Means for transmitting a wavelength-multiplexed optical signal wavelength-multiplexed using λN as a carrier through a signal light transmission fiber, and as a reference light train, light of each wavelength having a wavelength related to wavelengths λ1, λ2, ... At a finite time within τ _ref , the reference light of a certain wavelength is sequentially transmitted in a time series that is pre-allocated so that it exists independently on the transmitting side or the receiving side,
Further, a first transmission means including a means for forming a reference light train having a frame time T (τ _ref + τ0) by providing a time window τ0 for not sending the reference light and sending it to the reference light transmission fiber is provided. The receiving terminal station synchronizes the reference light train with a frame, extracts reference light having a wavelength corresponding to a pre-assigned time window from the reference light train using each frame as a reference, and receives the reference light as a reference. The circuit is tuned, and an arbitrary J (J
It is characterized in that it is provided with a first receiving means for extracting a signal of ≦ N).

According to the present invention, the first transmitting means is
An optical amplifier, an optical switch, an optical multiplexer, an optical branching device, an optical delay line and a wavelength conversion element connected in a loop, and a period T
A reference light generating circuit including means for injecting pulsed light from outside the loop via the optical multiplexer, and means for controlling the injected pulsed light to take out reference light of an arbitrary wavelength from the optical branching device. And a means for synchronizing the local light from the local light source based on the reference light train output from the reference light generating circuit.

According to the present invention, the first receiving means is
A narrow band optical filter in which the reference light train is input from one side and the wavelength division multiplexed optical signal is input from the opposite direction thereof,
Means for detecting the time window τ0 from the reference light train before passing through the narrow band optical filter to establish frame synchronization, and extracting reference light of a desired wavelength from the reference light train after passing through the narrow band optical filter. Means for tuning the narrow band optical filter in accordance with the reference light.

Further, the present invention is an optical transmission system comprising means for wavelength-multiplexing signal light from a transmitting end station to a receiving end station and transmitting the signal light through a fiber, wherein the transmitting end station uses a wavelength as a reference light train. λ1, λ2, ..., the light of each wavelength of a wavelength that is associated with .lambda.N, a finite time in the time window tau _ref, the reference light of a certain wavelength is assigned in advance to exist solely in the transmitting side or the receiving side A means for sequentially transmitting in time series, and a wavelength-multiplexed optical signal in which data strings of N lines (N ≧ 1) are multiplexed using wavelengths λ1, λ2, ..., λN as carriers, respectively, are transmitted to a time window τs for signal transmission. , A time window τ0 that does not send the reference light is further provided, and the frame time T
A second transmitting means including means for forming a transmission light train of (τ _ref + τ0 + τs) and sending it to the fiber is provided, and the receiving terminal station synchronizes the light receiving train with a frame and pre-assigns each frame on the basis of each frame. A reference light having a wavelength corresponding to the specified time window is extracted, the light receiving circuit is tuned with this reference light as a reference, and an arbitrary J is output from the wavelength-multiplexed optical signal.
It is characterized in that it is provided with a second receiving means for extracting (J ≦ N) signals.

According to the present invention, the second receiving means is
A narrowband optical filter in which the reference light train and the wavelength-multiplexed optical signal are input from the same side in a time division manner, and a time window τ0 is detected from the reference light train before passing through the narrowband light filter to detect frame synchronization. And a means for extracting reference light of an arbitrary wavelength from the reference light train after passing through the narrow band optical filter and tuning the narrow band optical filter in accordance with the reference light. .

Further, according to the present invention, the signal light is wavelength-multiplexed from the transmitting end station to the receiving end station via the relay station, and the maximum N lines (N ≧ N) are obtained.
1) In the optical transmission system including means for transmitting a signal light transmission fiber capable of data transmission and transmitting a reference light through the reference light transmission fiber, in the transmission terminal station, the transmission terminal stations have wavelengths λ1 and λ
2, ..., Means for transmitting M data strings as wavelength division multiplexed optical signals by the signal transmission optical fiber by wavelength multiplexing using any M number (0 ≦ M ≦ N) in λN as a carrier, and as reference light , Wavelengths λ1, λ2, ..., λN are assigned beforehand so that the reference light of a certain wavelength exists independently on the transmitting side or the receiving side for a finite time within the time window τ _ref . Means for transmitting to the reference light transmission fiber by referring to the reference light train of the frame time Τ (τ _ref + τ0) by providing the time window τ0 in which the reference light is not transmitted. A third transmitting means including, the repeater branches a part of the reference light from the reference light transmission fiber and transfers it to a repeater at a subsequent stage, and also a wavelength division multiplexed optical signal from the signal light transmission fiber. Part of The means for transferring to the repeater in the subsequent stage, the frame synchronization of the reference light train, the reference light of the wavelength corresponding to the pre-allocated time window is extracted from the reference light train on the basis of each frame, and this reference is performed. Means for separating an arbitrary J (J ≦ N) signals from the wavelength-multiplexed optical signal by tuning a light receiving circuit with light as a reference;
Also, with reference light extracted from the branched reference light train as a reference, the local light source is synchronized with any wavelength not used for signal transmission within the transmission wavelengths λ1, λ2, ..., λN, and this wavelength is used as a carrier. Information is superposed as k waves (0 ≦ K ≦ N
-M) is provided with a first relay means including means for sending the wavelength-multiplexed optical signal to the signal light transmission fiber, and the receiving terminal station synchronizes the frame of the reference light train with each frame as a reference. Reference light having a wavelength corresponding to a pre-assigned time window is extracted from the reference light train, the light receiving circuit is tuned with the reference light as a reference, and arbitrary J (J It is characterized in that it is provided with a first receiving means for extracting a signal of ≦ N).

Further, according to the present invention, the signal light is wavelength-multiplexed from the transmitting end station to the receiving end station via the relay station, and the maximum N lines (N ≧ N) are obtained.
1) In the optical transmission system provided with a means for transmitting with a fiber capable of data transmission, the transmitting end station, as a reference optical train, transmits light of each wavelength having a wavelength related to wavelengths λ1, λ2, ..., λN. , A means for sequentially transmitting, in a finite time within a time window τ _ref , a reference light of a certain wavelength in a time series preassigned so that the reference light exists independently on the transmitting side or the receiving side, and N lines (N ≧ 1) , ΛN are used as carriers to transmit wavelength-division-multiplexed optical signals in a time window τs for signal transmission, and a time window τ0 in which reference light is not transmitted is provided.
The second repeater includes means for forming a transmission light train of (τ _ref + τ0 + τs) and sending it to the fiber, and the repeater branches a part of the transmission light train from the fiber and A means for transferring to a repeater, frame synchronization is taken from the branched transmission light train, reference light of a wavelength corresponding to a time window pre-assigned with each frame as a reference is extracted, and a light receiving circuit with this reference light as a reference Of the wavelength-division-multiplexed optical signal, and
N) means for separating the signals, and reference wavelengths of the reference light extracted from the branched transmission light train, the transmission wavelengths λ1, λ2,
..., wavelength-multiplexed light by k waves (0 ≦ K ≦ NM) by synchronizing the local light source with an arbitrary wavelength not used for signal transmission within λN, superimposing information using this wavelength as a carrier A second relay means including means for sending a signal to the signal light transmission fiber in a time window τs for signal transmission is provided, and the receiving terminal station synchronizes the light receiving column with a frame and uses each frame as a reference. A reference light having a wavelength corresponding to a time window assigned in advance is extracted, a light receiving circuit is tuned with the reference light as a reference, and an arbitrary J signal is extracted from the wavelength-multiplexed optical signal.
It is characterized in that it is provided with a second receiving means for extracting (J ≦ N) signals.

[0014]

The principle of the present invention is shown in FIGS. 1 (a) and 1 (b).
Will be described with reference to. The description will be made in the case of using an independent reference light transmission fiber (FIG. 1A) and in the case of transmitting the reference light and the signal light through the same fiber (FIG. 1).
(B)) is performed separately.

(In the case where there is an independent reference light transmission fiber) At the transmitting terminal station, each of the N-line data strings is transmitted using the signal light transmission fiber by wavelength multiplexing using the wavelengths λ1, λ2, ..., λN as carriers. . At this time, as shown in FIG.
2, ..., λN are used as reference lights, and the time window τ
The reference light of a certain wavelength is sent out to the reference light transmission fiber in a time series pre-allocated so that the reference light of a certain wavelength exists independently on the transmitting side or the receiving side within a finite time within _ref . Further, by providing a time window τ0 in which the reference light is not transmitted, the reference light train gives a specified point of the frame time T (= τ _ref + τ0).

In the configuration example of FIG. 1A, the pulse width of each reference light is τ, and the reference light train is configured so that there is no overlap between the pulses. When the dispersion characteristic of the transmission line cannot be ignored, the transmission timing may be adjusted so that the pulses do not overlap each other at the receiving end.

At the receiving terminal station, frame synchronization information is obtained from the reference light train. That is, since the reference light train includes the time window τ0 without reference light, it is possible to establish frame synchronization by direct detection with a simple circuit configuration. Note that the time window τ0 without reference light does not necessarily mean that there is no light energy, and dummy light different from the reference light may be transmitted. With such a configuration for transmitting the dummy light, the reference light train without power fluctuation can be configured, so that, for example, when the optical amplifier is applied to the system configuration, its pattern effect or the like can be prevented. In this case, it is possible to obtain a frame synchronization signal by direct detection by removing the dummy light with the optical filter.

An optical pulse of (i-1) τ to iτ time having a wavelength of λi is extracted as a reference light from the reference light train on the basis of each frame. The light receiving circuit is tuned based on this reference light. Therefore, it is possible to easily extract the signal of the arbitrary wavelength λj from the wavelength-multiplexed optical signal of the wavelengths λ1, λ2, ..., λN transmitted by the signal light transmission fiber.

Further, by installing J (1 ≦ J ≦ N) receiving circuits in parallel, arbitrary J (J ≦ N) signals can be generated from the wavelength-multiplexed optical signals of wavelengths λ1, λ2, ..., λN. It is possible to take it out.

Further, when the heterodyne detection technique is applied to the receiving system, the reference light having the wavelengths λ1 ″, λ2 ″, ..., λK ″ having a wavelength offset with respect to the signal light is transmitted as the reference light. The local light source for reception can be synchronized with the reference light, and desired signal light can be easily separated.

Further, by making the number of wavelengths of the reference light larger than the number of multiplexed signal lights, the tuning can be more easily performed when the receiving system is largely detuned from the desired wavelength.

As described above, in the present invention,
The reference signal is always transmitted as time division information, and the receiving side always uses the reference light and tunes to the signal light. Therefore, the transmission system does not require a light source whose absolute wavelength is stabilized, and the reception system does not require a narrow band optical filter or a local light source with high stability and guaranteed tuning wavelength. As a result, according to this configuration, it is possible to easily increase the number of wavelength division multiplexing.

(When transmitting the reference light and the multiplexed signal light using the same fiber) In the transmitting terminal station, as shown in FIG.
In the time window τs allocated for signal transmission based on the frame structure shown in, each of the N-line data strings has a wavelength λ.
, ΛN are used as carriers to perform wavelength-division multiplexing, and reference lights of wavelengths λ1, λ2, ..., λN are time-division multiplexed in a time window τ _ref allocated for reference light transmission.
It is transmitted by the same fiber.

At the receiving terminal station, frame synchronization is established from the light receiving column. At this time, since the light receiving column includes the time window τ0 without the reference light and the wavelength-multiplexed optical signal, it is possible to obtain the signal for frame synchronization by direct detection with a simple circuit configuration.

An optical pulse of (i-1) τ to iτ time having a wavelength of λi is extracted as a reference light from the reference light train with each frame as a reference. The light receiving circuit is tuned based on this reference light. Therefore, it is possible to easily extract the signal of the arbitrary wavelength λj from the wavelength-multiplexed optical signal of the wavelengths λ1, λ2, ..., λN transmitted by the signal light transmission fiber.

In this configuration, time-series data needs to be transmitted in the time window τs and demodulated after reception, but this can be easily realized by the time-base compression modulation (TCM) technique.

By installing J (1 ≦ J ≦ N) receiving circuits in parallel, arbitrary J (J ≦ N) signals can be generated from the wavelength-multiplexed optical signals of wavelengths λ1, λ2, ..., λN. It is possible to take it out.

When the heterodyne detection technique is applied to the receiving system, the reference light of λ1 ″, λ2 ″, ... It is possible to synchronize the local light source for use with the reference light and easily separate the desired signal light.

Further, by increasing the number of wavelengths of the reference light rather than the number of multiplexed signal lights, the tuning can be more easily performed when the receiving system is largely detuned from the desired wavelength.

As described above, in the present invention,
The reference signal is always transmitted as time division information using the same fiber as the transmission fiber of the wavelength division multiplexed optical signal,
On the receiving side, the narrow band optical filter for wavelength demultiplexing is always tuned to the signal light based on the time information. Therefore, the transmission system does not require a light source whose absolute wavelength is stabilized, and the reception system does not require a narrow band optical filter or a local light source with high stability and guaranteed tuning wavelength. As a result, it becomes possible to easily increase the number of wavelength division multiplexing with one fiber.

[0031]

Embodiments of the present invention will be described below with reference to the drawings.

First, a case where reference light is transmitted from a transmitting end station to a receiving end station by using a reference light transmission fiber will be described as a first embodiment with reference to FIGS. 2 to 6.

FIG. 2 is a block diagram showing an example of a reference light generating circuit as the first transmitting means in the transmitting terminal station, which is a feature of the present invention. FIG. A chart, FIG. 7B shows the circuit, and FIG. 7C shows the waveform of the reference light train.

The reference light generating circuit 10 includes a wavelength conversion element (optical frequency conversion element) 11, an optical amplifier 12, and an optical multiplexer 1.
3, optical switch 14, optical branching device 15, and optical delay line 1
6 constitutes a loop system, in which the single wavelength light from the single wavelength light source 17 is incident on the optical multiplexer 13 via the optical switch 18, and the optical branching device 15 outputs a predetermined reference light. is there.

The optical switch 18 has a cycle T as a basic cycle,
When the delay time of the loop system was tau _d, constitute a loop system becomes closed in the time window nτ _d, the time window (τ-nτ _d) is controlled to open.

A single-wavelength light having a pulse width τ _p , which has a period Τ emitted by the single-wavelength light source 17 as a basic period, is injected into the loop system by the optical multiplexer 13. The optical branching device 15 takes out a part of the light from the loop system to the outside. At this time, the optical delay line 16 is set so that the delay time in the loop is τ _d, and the gain of the optical amplifier 12 is set so as to compensate for the loss of the loop system.

Therefore, the wavelength λ of the injected optical pulse is
Every time the loop goes around, Δλ changes due to the action of the wavelength conversion element 11 realized by AOD (acousto-optical deflector) or MOD (magneto-optical deflector). When the number of turns is n, the wavelength of the nth time is λn, λn = λ + n × Δ
It becomes λ and is output from the optical branching device 15 after nτ time has elapsed. This operation is reset by opening the optical switch 14 in the loop and is repeated in the cycle T. In this way, it is possible to obtain the reference light train having the pattern shown in FIG.

When the incident pulse width τ _p is τ _p <τ _d , there is a period of no light between the output reference light pulses, and when τ _d <τ _p <2τ _d , the reference light pulse is Some overlap between the lights occurs. When the closing time Τ _s of the optical switch 18 is (N-1) τ _d <Τ _s <nτ _d , part of the n-th reference light pulse is cut,
When the closing time Τ _s of the optical switch 18 is nτ _d <Τ _s <(n + 1) τ _d , a part of the (n + 1) th reference light pulse is output.

In the reference light generating circuit 10, the optical delay line 16 can be omitted by using an optical fiber amplifier that also serves as an optical delay line instead of the optical amplifier 12, and the circuit configuration can be simplified.

As the wavelength conversion element 11, an AOD is used.
(Acousto-optical deflector) or MOD (magneto-optical deflector)
The optical switch 18 can be omitted and the circuit configuration can be simplified by applying the above-mentioned method and also serving as the optical switch in the loop.

FIG. 3 shows an example of a signal light generating circuit for obtaining a signal light for wavelength multiplexing that is tuned to the reference light, as a first transmitting means in the transmitting terminal station, which is a feature of the present invention. In the block diagram, FIG. 1A shows a sequence of a control signal and a waveform of a reference light train, and FIG. 1B shows a reference light generation circuit 10 and a signal light generation circuit 2 connected thereto.
Indicates 0.

The signal light generating circuit 20 includes a multiplexer 21, a narrow band optical filter 22, a photodetector 23, an electric switch 24,
25 and 26, time measuring circuit (ΔT) 27, averaging circuits 28 and 29, CPUs 30 and 31, local light source 3
2, including an optical switch 33, and a modulator 34.

Then, based on the pulsed reference light train 19 from the reference light generating circuit 10, the local light source 32 is synchronized through the narrow band optical filter 22 to generate continuous light of an arbitrary wavelength. Using the continuous light as a carrier, a signal light output 36 modulated by the data input 35 is obtained in the modulator 34.

That is, the reference light train and the local light are input to the narrow band optical filter 22 by time division so as not to overlap each other, and the output thereof is detected by the photodetector 23 and converted into an electric signal. The electric switch 24 operates as a time window for passing only the reference light train. The optical switch 14 operates as a time window in which the reference light train and the local light do not overlap. Then, the narrow band optical filter 22 is tuned. Next, the local light source 32 is connected via the electric switch 26, the averaging circuit 29 and the CPU 31 so that the output of the local light from the narrow band optical filter 22 tuned to an arbitrary wavelength in the reference light becomes maximum. By controlling, the local oscillation light source 32 can be tuned to the reference light wavelength.

The details of how to tune the narrow band optical filter 22 will be described later in the receiving circuit.

FIG. 4 is a block diagram showing another example of the signal light generating circuit which is a feature of the present invention.

The signal light generating circuit 40 includes a multiplexer 41,
Photodetector 42, rectifier 43, time measuring circuit (ΔT) 4
4, a frequency measuring circuit (ΔF) 45, a CPU 46, a local light source 47, an optical switch 48, and a modulator 49.

The signal light generating circuit 40 is adapted to synchronize a local light source with a coherent light receiving technique to generate continuous light of an arbitrary wavelength. The time measuring circuit 44 detects the detection time of the reference light and the pulsed beat signal of the local light obtained from the photodetector 42 with the frame of the reference light as a reference.
And the frequency is also measured by the frequency measuring circuit 45. At this time, a set of measured data (time,
_{Frequency) (t 1, f 1)} , when the (t _2, f _2), the optical frequency of the local light F _L, f _1, f ₂ and F _{L is, f 1 = | F 1 -F} L | There is a relationship of f ₂ = | F ₂ −F _L |. Here, F ₁ is the optical frequency of the reference light corresponding to t ₁ , and F ₂ is the optical frequency of the reference light corresponding to t ₂ . F _L is determined as a solution to satisfy the above equation at the same time.
Therefore, by controlling the wavelength by feeding back the local light source 47, it is possible to set an arbitrary value with reference light as a reference.

A signal light output 51 is obtained by modulating the obtained signal light as a carrier with the data input 50 by the optical switch 48 and the modulator 49.

FIG. 5 is a block diagram showing another example of the signal light generating circuit, which is a feature of the present invention.

The signal light generating circuit 60 is composed of an optical switch 6
1 and a modulator 62, the reference light train 19 from the reference light generation circuit 10 is switched by the optical switch 61,
A signal light of a desired wavelength is taken out, and this signal light is used as a carrier to be modulated by a data input 63 by a modulator 62 to obtain a signal light output 64.

FIG. 6 is a block diagram showing an example of a receiving circuit as the first receiving means in the receiving terminal station, which is a feature of the present invention.

The receiving circuit 70 includes an isolator 71,
Optical branching device 72, narrow band optical filter 73, optical branching device 74,
Isolator 75, photodetector 76, frame extraction circuit 7
7, control pulse generating circuit 78, photodetector 79, electric switch 80, time measuring circuit (ΔT) 81, averaging circuit 8
2, and the reference light transmission fiber 1 including the CPU 83
The reference light train 3 is input from one side of the narrow band optical filter 73 via the optical fiber, and the wavelength-multiplexed optical signal 4 is input from the other side of the narrow band optical filter 73 via the signal light transmitting fiber 2. It is configured to obtain the desired selection signal light 5 from the branching device 72.

The reference light train 3 and the wavelength-division multiplexed optical signal 4 are input from the opposite directions of the narrow band optical filter 73, and the passing lights are branched by the optical branching devices 72 and 74, respectively. The reference light train 3 that has passed through the narrow band optical filter 73 has an optical splitter 74.
And is converted into an electric signal by the photodetector 79. On the other hand, the frame period is extracted by the photodetector 76 and the frame extraction circuit 77 from the reference light train 3 branched by the optical branching device 72 before passing through the narrow band optical filter 73. Control pulse generating circuit 78 with this frame as a reference
The time measuring circuit 81 measures the appearance time ΔΤ of the photocurrent pulse of the reference light detected after passing through the narrow-band optical filter 73 in accordance with the control signal generated by.

Since the appearance time ΔΤ of the photocurrent pulse corresponds to the reference light pulse that has passed through the narrow band optical filter 73,
Since the tuning frequency of the narrow band optical filter 73 can be known from the time measurement, it is possible to tune to the desired wavelength by configuring the feedback system by the CPU 83.

Further, the electric switch 80 shown in FIG.
Is controlled so as to open the time window (i−1) τ to iτ of the reference light of the tuning target, and the output of the electric switch 80 is averaged by the averaging circuit 82 between frames so that this value becomes maximum. In addition, the narrow band optical filter 73 is controlled. With the addition of this circuit, the narrow band optical filter 73 can be tuned to the reference light more accurately than the circuit for time measurement alone. In this way, since the narrow band optical filter 73 is tuned to the reference light, it becomes possible to extract only the selected signal light 5 of the desired λj from the wavelength division multiplexed optical signal 4.

Next, as a second embodiment, a case of transmitting the reference light and the wavelength division multiplexed optical signal from the transmitting end station to the receiving end station using the same fiber will be described with reference to FIGS. 7 and 8. .

FIG. 7 is a block diagram showing an example of a signal light generation circuit for obtaining a signal light for wavelength division multiplexing that is tuned to the reference light, as second transmitting means in the transmitting terminal station, which is a feature of the present invention. 1A shows a sequence of control signals and a waveform of a reference light train, and FIG. 1B shows a reference light generation circuit 10 and a signal light generation circuit 20 connected thereto.
a is shown.

This signal light generating circuit 20a is obtained by omitting the optical switch 33 in the signal light generating circuit 20 of FIG. 3 and providing a code conversion circuit 37, an optical branching device 38 and an optical switch 39 instead.

In this signal light generating circuit 20a, the modulator 34 is installed in the control loop of the local oscillation light in this configuration example, and it also operates as a time window so that the reference light train 19 and the local oscillation light do not overlap. I am letting you. The code conversion circuit 37 compresses the data input 35 on the time axis so as to fit the transmission frame, that is, compresses the data string of the frame time T at the time τs allocated for signal transmission. As a result, the local light is modulated, and the signal light output 36 for wavelength multiplexing corresponding to the transmission format is obtained.

Also in this signal light generation circuit 20a, the signal light generation circuits 40 and 60 shown in FIGS. 4 and 5 can be modified and used in the same manner.

FIG. 8 is a block diagram showing an example of a receiving circuit as a second receiving means, which is a feature of the present invention.

This receiving circuit 70a corresponds to the receiving circuit 7 of FIG.
0, the isolators 71 and 75 are omitted, and the reference light train / wavelength multiplexed optical signal 7 transmitted from one side of the narrow band optical filter 73 through the fiber 6 is input, and further, the reference light selection switch. 84 is provided and can be controlled by a control signal from the control pulse generation circuit 78.

The reference light train / wavelength multiplexed optical signal 7 is input to the narrow band optical filter 73, and the light passing through the narrow band optical filter 73 is branched by the optical branching device 74 and converted into an electric signal by the photo detector 79. On the other hand, the frame extraction circuit 77 extracts the frame period from the reference light train branched by the optical branching device 72 and detected by the photodetector 76 before passing through the narrow band optical filter 73.

Then, the reference light selection switch 84 is opened / closed on the basis of the frame, only the photocurrent pulse corresponding to the reference light train is passed, and the appearance time ΔΤ of the photocurrent pulse is measured by the time measuring circuit 81. Since the tuning wavelength of the narrow band optical filter 73 corresponds to ΔΤ, by configuring a feedback system via the CPU 83, the narrow band optical filter 73 can be tuned to a desired wavelength from time measurement.

Further, the electric switch 80 has a time window (i-
1) The electric switch 80 is controlled to open τ to iτ.
Averages the output of the
The narrow band optical filter 73 is controlled so that this value becomes maximum. By adding this circuit, the time measuring circuit 81
The narrow band optical filter 73 can be tuned to the reference light more accurately than the above.

Since the narrow band optical filter 73 is tuned to the reference light in this way, it becomes possible to extract only the signal light of the desired wavelength λj from the wavelength multiplexed optical signal to obtain the selected signal light 5.

In FIG. 8, the reference light selection switch 84 is opened and closed to prevent the signal light component from being mixed into the tuning circuit system, but it is not always necessary.

Next, as a third embodiment, the signal light is wavelength-multiplexed from the transmitting end station to the receiving end station via the relay station, and the maximum N is obtained.
A case will be described with reference to FIGS. 9, 10 and 11 in which a signal light transmission fiber capable of data transmission on a line (N ≧ 1) is used and reference light is transmitted using the reference light transmission fiber.

FIG. 9 is a block diagram showing an example of a relay transmission system, which is a feature of the present invention.

This repeater transmission system comprises a reference light branch repeater 94 for branching and amplifying a reference light train between the transmitting terminal stations 91a and 91b and the receiving terminal stations 92a and 92b, and branching and inserting of wavelength multiplexed optical signals. It is configured to perform data transmission via the add / drop optical repeater 95 for performing the above. Here, the reference light is generated by the reference light generating circuit 93, transmitted by the reference light transmitting fiber, and input to each add / drop optical repeater 95 by each reference light add / drop repeater 94.

FIG. 10 is a block diagram showing an example of the add / drop optical repeater 95 included in the first repeater, which is a feature of the present invention. The optical adder 101 and the optical amplifier 10 are shown in FIG.
2, an optical multiplexer 103, an optical signal selection circuit 104, and an insertion optical signal generation circuit 105.

Here, the optical signal selection circuit 104 receives the reference light with the same configuration as the receiving circuit 70 shown in FIG.
The output signal of the desired wavelength is taken out.

The inserted optical signal generation circuit 105 is shown in FIG.
Is configured as shown in FIG.

This insertion optical signal generation circuit 105, optical branching device 111, optical multiplexer 112, narrow band optical filter 113, photodetector 114, frame extraction circuit 115, photodetector 11
6, electric switches 117, 118 and 119, a time measuring circuit (ΔΤ) 120, averaging circuits 121 and 12
2, CPUs 123 and 124, control pulse generation circuit 1
25, the local light source 126, the modulators 127 and 128, and the optical branching device 129. The operation is as follows.

The reference light train and the light from the local light source 126 are time-divisionally input to the same narrow band optical filter 113. The narrow band optical filter 113 is tuned to a desired wavelength in the reference light by a means similar to the method described for the receiving circuit 70a in FIG. Next, in the time window τ0 where the reference light is interrupted, the local light source 12
Since the timing is such that the light from 6 is input to the narrow band optical filter 113, the narrow band optical filter 1
The local oscillation light source 126 can be tuned to the reference light by controlling the local oscillation light source 126 so that the passing output of 13 is maximized. The local oscillation light thus obtained is modulated with data by the modulator 128 to be insertion light.

As described above, each repeater always receives the reference signal as the time division information, and the narrow band optical filter for wavelength demultiplexing and the local light source are always tuned to the reference light. ing. Therefore, it is possible to configure a transmission system with large wavelength multiplexing without the need for a highly stable wavelength-guaranteed narrow band optical filter and a local light source.

Next, as a fourth embodiment, a case of transmitting a reference light train and a wavelength division multiplexed optical signal from the transmitting end station to the receiving end station via the relay station using the same fiber will be described with reference to FIG.
2, with reference to FIGS. 13 and 14.

FIG. 12 is a block diagram showing another example of the relay transmission system, which is a feature of the present invention.

This repeater transmission system is an add / drop optical repeater 95 that drops and adds the wavelength division multiplexed optical signal between the transmitting end stations 141a and 141b and the receiving end stations 142a and 142b.
The reference optical train and the wavelength division multiplexed optical signal are transmitted via the same fiber via a.

FIG. 13 is a block diagram showing an example of an add / drop optical repeater 95a as a second repeater, which is a feature of the present invention. This add / drop optical repeater 95a
In the optical add / drop repeater 95 of FIG. 10, the optical signal selection circuit 104 is replaced with an optical signal selection circuit 104a, and the insertion optical signal generation circuit 105 is replaced with an insertion optical signal generation circuit 105a.

Here, the optical signal selection circuit 104a has the same configuration as the reception circuit 70a shown in FIG. 8, receives the reference light, and takes out the signal light of the desired wavelength as the output signal.

Then, the inserting optical signal generating circuit 105a is
As shown in FIG. 14, the insertion optical signal generation circuit 10 of FIG.
5, the modulator 128 is omitted, and the code conversion circuit 130
And an optical switch 131.

The operation of the inserted optical signal generation circuit 105a is as follows. The narrow-band optical filter 113 is tuned to the desired wavelength in the reference light by means equivalent to the method described for the receiving circuit 70a in FIG. 8 using the input light including the reference light train.
Next, the light of the local light source 126 is input to the narrow band optical filter 113 in the time window τs for signal transmission, the local light source 126 is controlled so that its output becomes maximum, and the local light source 126 is used as the reference light. Tune in to. The local oscillation light thus obtained is modulated with data by the code conversion circuit 130 and the modulator 127, and is output as an insertion optical signal via the optical switch 131. The electric switch 117 is a switch that opens a time window for reference light, the electric switch 118 is a switch that opens a time window only for reference light of a desired wavelength, the electric switch 119 is a switch that opens a time window for signal transmission, and the optical switch 131. Is a switch for connecting to the transmission line after the inserted optical signal is tuned to the wavelength to be set.

As described above, each repeater always receives the reference signal as time division information, and has a configuration in which the wavelength demultiplexing narrow band optical filter and the local light source are always tuned to the reference light. There is. Therefore, it is possible to configure a transmission system with a large number of wavelength multiplexes, without requiring a highly stable and narrow-band optical filter with a guaranteed wavelength and a local light source.

[0086]

As described above, according to the present invention, the reference light train is always transmitted as time division information, and the receiving side always outputs the wavelength demultiplexing narrow band optical filter to the signal light based on the time information. It is configured to synchronize. Therefore, the transmission system does not require a light source whose absolute wavelength is stabilized, and the reception system does not require a highly stable narrow band optical filter whose pass wavelength is guaranteed. As a result, it is possible to easily increase the number of wavelength multiplexes, and also to easily configure an add / drop optical repeater based on the wavelength multiplexing technology, which enables the number of wavelength multiplexes to be expanded and to make the system economical. It has an excellent effect.

[Brief description of drawings]

FIG. 1 is a frame configuration diagram of a reference light train and a wavelength division multiplexed optical signal for explaining the principle of the present invention.

FIG. 2 is a block configuration diagram showing an example of a reference light generation circuit in the first embodiment of the present invention.

FIG. 3 is a block configuration diagram showing a first example of a signal light generation circuit in the first embodiment.

FIG. 4 is a block configuration diagram showing a second example of the signal light generation circuit in the first embodiment.

FIG. 5 is a block configuration diagram showing a third example of the signal light generation circuit in the first embodiment.

FIG. 6 is a block diagram showing an example of a receiving circuit in the first embodiment.

FIG. 7 is a block configuration diagram showing an example of a signal light generation circuit in a second embodiment of the present invention.

FIG. 8 is a block diagram showing an example of a receiving circuit according to the second embodiment.

FIG. 9 is a block diagram showing an example of a relay transmission system according to a third embodiment of the present invention.

FIG. 10 is a block diagram showing an example of an add / drop optical repeater in the third embodiment.

FIG. 11 is a block diagram showing an example of an insertion optical signal generation circuit in the third embodiment.

FIG. 12 is a block diagram showing an example of a relay transmission system according to a fourth embodiment of the present invention.

FIG. 13 is a block diagram showing an example of an add / drop optical repeater according to the fourth embodiment.

FIG. 14 is a block diagram showing an example of an insertion optical signal generation circuit in the fourth embodiment.

[Explanation of symbols]

 1 fiber for reference light transmission 2 fiber for signal light transmission 3 reference light train 4 wavelength multiplexed light signal 5 selection signal light 7 reference light train / wavelength multiplexed light signal 10 reference light generation circuit 11 wavelength conversion element 12 optical amplifier 13 optical multiplexer 14 optical switch 15 optical branching device 16 optical delay line 17 single wavelength light source 18 optical switch 19 reference light train 20, 20a signal light generation circuit 21 multiplexer 22 narrow band optical filter 23 photodetector 24, 25, 26 electrical switch 27 Time measurement circuit (ΔΤ) 28, 29 Averaging circuit 30, 31 CPU 32 Local light source 33 Optical switch 34 Modulator 35 Data input 36 Signal light output 37 Code conversion circuit 38 Optical splitter 39 Optical switch 40 Signal light generation circuit 41 multiplexer 42 photodetector 43 rectifier 44 time measuring circuit (ΔΤ) 45 frequency measuring circuit (ΔF) 46 CP 47 Local light source 48 Optical switch 49 Modulator 50 Data input 51 Signal light output 60 Signal light generation circuit 61 Optical switch 62 Modulator 63 Data input 64 Signal light output 70, 70a Receiver circuit 71, 75 Isolator 72, 74 Optical splitter 73 Narrow band optical filter 76 Photodetector 77 Frame extraction circuit 78 Control pulse generation circuit 79 Photodetector 80 Electric switch 81 Time measurement circuit (ΔΤ) 82 Averaging circuit 83 CPU 84 Reference light selection switch 91a, 91b Transmission terminal station 92a , 92b Receiving terminal station 93 Reference light generating circuit 94 Reference light branching repeater 95, 95a Add / drop optical repeater 101 Optical branching device 102 Optical amplifier 103 Optical multiplexer 104 Optical signal selecting circuit 105, 105a Inserting optical signal generating circuit 111 Optical Divider 112 Optical multiplexer 113 Narrow band optical fiber 114 photodetector 115 frame extraction circuit 116 photodetector 117, 118, 119 electric switch 120 time measuring circuit (ΔΤ) 121, 122 averaging circuit 123, 124 CPU 125 control pulse generating circuit 126 local light source 127, 128 modulation 129 Optical branching device 130 Code conversion circuit 131 Optical switch 141a, 141b Transmission terminal station 142a, 142b Reception terminal station

Claims (7)

(57) [Claims] 1. An optical transmission system comprising means for wavelength-multiplexing signal light from a transmitting end station to a receiving end station and transmitting the signal light through a fiber, wherein the transmitting end station has N lines (N ≧ 1) of data strings, respectively. , ΛN are used as carriers for transmitting wavelength-division-multiplexed optical signals through a signal light transmission fiber, and reference light trains have wavelengths λ1, λ2, ..., λ.
Light of each wavelength having a wavelength related to N is sequentially transmitted in a pre-allocated time series so that the reference light of a certain wavelength exists independently on the transmitting side or the receiving side at a finite time within the time window τ _ref . , And by further providing a time window τ0 for not transmitting the reference light, the frame time T (τ _ref + τ
0) comprises a first transmission means including a reference light train and sending it to a reference light transmission fiber, wherein the receiving terminal station synchronizes the frame of the reference light train,
From the reference light train with each frame as a reference, a reference light having a wavelength corresponding to a pre-assigned time window is extracted, and a light receiving circuit is tuned with this reference light as a reference. An optical transmission system comprising a first receiving means for extracting J (J ≦ N) signals. 2. The first transmission means includes an optical amplifier, an optical switch, an optical multiplexer, an optical branching device, an optical delay line and a wavelength conversion element connected in a loop, and pulsed light with a cycle T outside the loop. Reference light generation circuit including means for injecting the pulsed light through the optical multiplexer, and means for extracting the reference light of an arbitrary wavelength from the optical brancher by controlling the injected pulsed light, and the reference light generation circuit. The optical transmission system according to claim 1, further comprising a signal light generation circuit including means for synchronizing local light from a local light source based on a reference light train output from the circuit. 3. The narrowband optical filter, to which the reference light train is input from one side and the wavelength division multiplexed optical signal is input from the opposite direction, and the first receiving means passes through the narrowband optical filter. Means for detecting the time window τ0 from the previous reference light train to establish frame synchronization, and extracting reference light of a desired wavelength from the reference light train after passing through the narrow band optical filter, and matching the reference light with the reference light. The optical transmission system according to claim 1, further comprising means for tuning a narrow band optical filter. 4. An optical transmission system comprising means for wavelength-multiplexing signal light from a transmission end station to a reception end station and transmitting the signal light with a fiber, wherein the transmission end station has wavelengths λ1, λ2, as reference light trains. ..., light of each wavelength having a wavelength related to λN is sequentially assigned in advance in a time series such that reference light of a certain wavelength exists independently on the transmitting side or the receiving side for a finite time within the time window τ _ref . Means for sending out, and a wavelength-multiplexed optical signal in which a data string of N lines (N ≧ 1) is multiplexed using wavelengths λ1, λ2, ..., λN as carriers, and is transmitted to a time window τs for signal transmission, and further, reference light Is provided, and a second transmission means including means for forming a transmission light train of a frame time T (τ _ref + τ0 + τs) and sending it to the fiber is provided, wherein the receiving terminal station is Frame synchronization, each A reference light having a wavelength corresponding to a time window pre-allocated based on the frame is extracted, the light receiving circuit is tuned based on the reference light, and arbitrary J (J ≦ N) from the wavelength-multiplexed optical signal are extracted. An optical transmission system characterized by comprising a second receiving means for extracting the signal. 5. The narrow band optical filter in which the reference light train and the wavelength division multiplexed optical signal are input from the same side in a time division manner, and the second receiving means before passing through the narrow band optical filter. Means for detecting the time window τ0 from the reference light train to establish frame synchronization, and extracting reference light of an arbitrary wavelength from the reference light train after passing through the narrow band optical filter and matching the narrow band to the reference light. The optical transmission system according to claim 4, further comprising means for synchronizing the optical filter. 6. A reference light is obtained by wavelength-multiplexing signal light from a transmitting terminal station to a receiving terminal station via a relay station and transmitting the signal light with a signal light transmission fiber capable of transmitting data of up to N lines (N ≧ 1). In the optical transmission system provided with a means for transmitting with a reference light transmission fiber, the transmitting terminal station is any M number (0 ≦ M ≦ within wavelengths λ1, λ2, ..., λN).
Means for transmitting M data strings as wavelength-multiplexed optical signals by the signal-optical transmission fiber using N) as a carrier, and wavelengths λ1, λ2, ...
Light of each wavelength having a wavelength related to λN is sequentially transmitted in a time series preassigned so that the reference light of a certain wavelength exists independently on the transmitting side or the receiving side for a finite time within the time window τ _ref . , And by further providing a time window τ0 for not transmitting the reference light, the frame time T (τ _ref + τ
0) The reference light train is referred to, and a first transmission unit including a unit that sends out to the reference light transmission fiber is provided, and the repeater branches a part of the reference light from the reference light transmission fiber. Then
A means for branching a part of the wavelength-multiplexed optical signal from the signal light transmission fiber to the repeater at the subsequent stage and transferring it to the repeater at the subsequent stage, frame synchronization of the reference light train, and using each frame as a reference Reference light having a wavelength corresponding to a pre-assigned time window is extracted from the reference light train, the light receiving circuit is tuned with the reference light as a reference, and arbitrary J (J ≦ J N) means for separating the signal, and local oscillation at any wavelength not used for signal transmission within the transmission wavelengths λ1, λ2, ..., λN with reference light extracted from the branched reference light train as a reference. The sources are synchronized, information is superimposed using this wavelength as a carrier, and k-wave (0
≦ K ≦ N−M), a first relay unit including a unit for sending a wavelength-multiplexed optical signal according to (K−N−M) to the signal light transmission fiber, wherein the receiving terminal station synchronizes the reference light train with a frame,
From the reference light train with each frame as a reference, a reference light having a wavelength corresponding to a pre-assigned time window is extracted, and with this reference light as a reference, the light receiving circuit is tuned,
An optical transmission system comprising a first receiving means for extracting arbitrary J (J ≦ N) signals from the wavelength-multiplexed optical signal. 7. An optical transmission system provided with means for wavelength-multiplexing signal light from a transmission terminal station to a reception terminal station via a relay station and transmitting the signal light through a fiber capable of transmitting data for up to N lines (N ≧ 1). in the transmitting end station, as the reference light train, the wavelength .lambda.1, .lambda.2, ..., the light of each wavelength of a wavelength that is associated with .lambda.N, a finite time in the time window tau _ref, the reference light of a certain wavelength transmission side Alternatively, a means for sequentially transmitting in time series pre-allocated so as to exist independently on the receiving side, and a wavelength obtained by multiplexing data lines of N lines (N ≧ 1) with wavelengths λ1, λ2, ..., λN as carriers, respectively. A means for transmitting a multiplexed optical signal in a time window τs for signal transmission, further providing a time window τ0 for not transmitting reference light, forming a transmission light train of a frame time Τ (τ _ref + τ0 + τs), and transmitting it to the fiber is provided. Including a second transmission means The repeater splits a part of the transmission optical train from the fiber and transfers it to a repeater at a subsequent stage, and synchronizes the branched transmission optical train with a frame and pre-assigns each frame as a reference. A reference light having a wavelength corresponding to the time window is extracted, the light receiving circuit is tuned with the reference light as a reference, and an arbitrary J (J
≦ N), the transmission wavelengths λ1, λ based on the reference light extracted from the branched transmission light train as a reference.
2, ..., λN, the local oscillation light source is synchronized with an arbitrary wavelength that is not used for signal transmission, information is superimposed using this wavelength as a carrier, and a wavelength of k waves (0 ≦ K ≦ NM) is generated. A second relay means including means for sending the multiplexed optical signal to the signal optical transmission fiber in a time window τs for signal transmission is provided, and the receiving terminal station synchronizes the frames of the light receiving column to obtain each frame. A reference light having a wavelength corresponding to a time window pre-allocated as a reference is extracted, the light receiving circuit is tuned with the reference light as a reference, and arbitrary J (J ≦ N) signals from the wavelength-multiplexed optical signal are extracted. An optical transmission system characterized by comprising a second receiving means for taking out.