JPH05347603A - Channel selection method in optical frequency division multiplex transmission - Google Patents

Abstract

PURPOSE:To enable the simple selection of a channel by inserting in advance an ID code to the idle bit of transmission data and identifying the ID code at a reception side. CONSTITUTION:The signal light of plural channels subjected to optical frequency division multiplex from an optical transmission line is made incident on a photocoupler 4 and superimposed on a local oscillation light from a local oscillation source 2. An output signal from the photocoupler 4 is subjected to a prescribed processing by a photodetection circuit 6, an amplifier 8 and a demodulator 10 respectively and the result is inputted to an identification synchronization circuit 12. The identification synchronization circuit 12 identifies, selects and reproduces transmission data and outputs the result. An ID code used for identifying a channel is inserted in the idle bit of the transmission data. An AFC circuit 14 applies feedback control to the local oscillation light source 2 so that the center frequency of an intermediate frequency corresponding to the signal light selectively received is constant. A control circuit 16 implements the switching of on/off of the AFC circuit 14 and the change of the frequency of the local oscillation light or the like based on the ID code inserted in the demodulated data to select the channel.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a channel selection method for optical frequency division multiplexing transmission in a coherent lightwave communication system.

The coherent lightwave communication system is improved in receiving sensitivity by 10 to 20 dB compared with the conventional intensity modulation / direct detection (IM / DD), and moreover, it is easy to perform optical frequency division multiplexing. It is expected to be put to practical use. For example, when laying an optical fiber in a subscriber system and performing CATV service by optical frequency division multiplexing,
There is a demand for a simple channel selection method to enable reception of a desired channel.

[0003]

2. Description of the Related Art In a heterodyne receiver for coherent lightwave communication, local light (local light) is superimposed on the received signal light, and the intermediate frequency signal is detected by photodetecting it with a photodiode having a square-law detection characteristic. can get. This intermediate frequency signal is demodulated into a baseband signal by a demodulator.

The frequency of the intermediate frequency signal corresponds to the difference between the frequency of the signal light and the frequency of the local light. Therefore, when multiple signal lights with different frequencies are being sent in optical frequency division multiplexing, the local oscillator frequency can be set to the frequency corresponding to the desired signal channel and only this channel can be received. It is necessary to incorporate it into the demodulator as an intermediate frequency component.

Conventionally, the following methods have been known as a method for selecting a desired channel from a plurality of optical frequency division multiplexed channels. This method scans the frequency of the local light from the low frequency side to the high frequency side, stores all the frequencies of the intermediate frequency signals that are sequentially obtained in the memory, and after finishing the identification for all the predetermined channels, The frequency of the local oscillator light corresponding to the required target channel is set and reception is started.

[0006]

However, in the case of the above-mentioned conventional channel selection method, it is necessary to enable reception for all channels in advance, so that there is a problem that channel selection is inconvenient.

The present invention has been made in view of the above circumstances, and an object thereof is to provide a simple channel selection method in optical frequency division multiplexing transmission.

[0008]

A channel selection method in optical frequency division multiplex transmission according to the present invention is a local light source for outputting local light whose frequency is variable, and a received signal light superimposed on the local light for output. An optical coupler, a photoelectric converter for opto-electrically converting the signal light and local light from the optical coupler to output an intermediate frequency signal, and a demodulator for reproducing transmission data based on the intermediate frequency signal. A method for selecting and receiving a signal light of a desired channel from a plurality of signal lights of optical channels subjected to optical frequency division multiplexing by using a heterodyne receiver for coherent lightwave communication, which is one of the signal lights of the plurality of channels. First to receive signal light of some channel
And a second step of identifying an ID code previously inserted in an empty bit of transmission data reproduced based on the received signal light, and the identified ID code is an ID code of a desired channel. A third step of determining whether or not there is a signal of the desired channel based on the intermediate frequency specified by the identified ID code when the identified ID code is not the ID code of the desired channel. The method further includes a fourth step of calculating the frequency variation amount of the local oscillation light required for receiving light, and a fifth step of changing the frequency of the local oscillation light based on the calculated value. It is characterized in that the above third to fifth steps are repeated until it is determined that the identified ID code is the ID code of the desired channel in the step.

[0009]

According to the method of the present invention, an ID code (identity code) is inserted in advance in an empty bit of transmission data and the ID code is identified on the receiving side. Choices become possible. The ID code can be inserted in the overhead bit in the transmission data.

[0010]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram of a heterodyne receiver for coherent lightwave communication to which the present invention can be applied. Reference numeral 2 represents a local light source that outputs local light.
Is equipped with a laser diode whose oscillation frequency is variable. The oscillation frequency of the laser diode can be changed by the bias current and temperature of the laser diode.

The signal light transmitted through an optical transmission line made of an optical fiber or the like (not shown) is superposed on the local light from the local light source 2 by the optical coupler 4. From the optical transmission line, signal light of a plurality of channels, which has been subjected to optical frequency division multiplexing, enters the optical coupler 4 through the same optical path.

The signal light and the local light from the optical coupler enter a photodetector circuit 6 having a light receiving element such as a photodiode, where they are photo-electrically converted and an intermediate frequency signal is output from the photodetector circuit 6. Is output.

The intermediate frequency signal output from the photodetector circuit 6 is amplified by the amplifier 8 and then input to the demodulator 10.
The intermediate frequency signal input to the demodulator 10 is converted into a baseband signal here, but since this signal has undergone waveform deterioration due to the transmission line, this is further input to the next identification synchronization circuit 12. The identification synchronization circuit 12 identifies and reproduces the transmission data. An ID code for identifying a channel is inserted in an empty bit of transmission data, for example, an overhead bit. The identification of the ID code will be described later.

AFC circuit (automatic frequency control circuit) 14
Includes, for example, a frequency discriminator, a voltage-current converter, and an operational amplifier. The AFC circuit 14 performs feedback control on the local light source 2 so that the center frequency of the intermediate frequency corresponding to the selectively received signal light becomes constant. AFC
The circuit 14 can be turned on and off, and the control circuit 1 can switch between a state in which the AFC circuit 14 is operating and a state in which the AFC circuit 14 is not operating.
Made by 6.

This is a frequency difference between channels in which the local oscillation frequency variable width by the AFC function is set at substantially equal intervals, and the main frequency setting is to select and select a frequency slot before operating the AFC function. This is for locking the signal frequency by operating the AFC function after that.

The control circuit 16 is for selecting a channel, and the control circuit 16 operates such as changing the frequency of local oscillation light based on the ID code inserted in the demodulated data. The details of the operation will be described later.

FIG. 2 is a flow chart of channel selection by the operation of the control circuit 16 of FIG. First, in step 101, a bias current applied to the laser diode of the local light source 2 is scanned to obtain an intermediate frequency signal corresponding to any one of a plurality of optical frequency division multiplexed signal lights. Set to receive status. When scanning the bias current of the laser diode of the local light source 2, the AF
The C circuit 14 is turned off.

Next, at step 102, the AFC circuit 14
Is turned on, and then in step 103, the ID inserted in the empty bit of the transmission data of the channel being received.
Identify the code.

In step 104, it is determined whether the ID code identified in step 103 is the ID code of the desired target channel. When it is determined that the identified ID code is the ID code of the target channel, this routine ends. On the other hand, when it is determined that the identified ID code is not the ID code of the target channel, the process proceeds to step 105.

In step 105, based on the intermediate frequency specified by the ID code identified in step 103,
The frequency variable amount of the local oscillation light required to receive the signal light of the target channel to be received is calculated. Then, in step 106, the AFC circuit 14 is turned off.

Then, in step 107, step 10
After changing the frequency of the local oscillation light by the bias current of the laser diode of the local oscillation light source 2 based on the calculated value of the frequency variable amount calculated in step 5, the AFC circuit 14 is turned on again in step 108.

When the frequency of the local oscillation light is changed in this way, the capture range of the AFC circuit 14 is always satisfied (corresponding to the frequency range between the signal channels set at equal intervals).
There is not always signal light inside. This is because unused channel slots may intervene. Therefore, in step 109, it is determined whether the signal light can be pulled in when the AFC circuit 14 is turned on in step 108.

When it is determined in step 109 that the signal light can be pulled in, the process returns to step 104,
After that, until it is determined in step 104 that the identification ID code is the ID code of the target channel, step 104
The operations of to 109 are repeated.

When it is determined in step 109 that the signal light cannot be pulled in, the process proceeds to step 110,
The AFC circuit 14 is turned off. Then, step 111
The bias current of the laser diode of the local oscillation light source 2 is changed to change the frequency of the local oscillation light. The change width of the frequency of the local light at this time is set to be smaller or larger than the change width of the frequency of the previous local light. Then, step 112
To turn on the AFC circuit 14 and return to step 109,
The operations of steps 109 to 112 are repeated. At this time,
The frequency variation range of the local light is controlled by the CPU so as to search all the time slots before and after.

FIG. 3 is a diagram for explaining the channel arrangement of the signal light multiplexed by optical frequency division, in which the horizontal axis represents frequency and the vertical axis represents optical power. In this example, channels CH1, CH2, CH3, CH4, CH from the low frequency side
5 are assigned in this order, of which channel CH4 is unset. Therefore, in this example, the multiplexing number is 4. The center frequency of the channel CH1 is f ₀ , and the channel interval (frequency slot) in each assigned channel is Δf.

A specific example of the transition in the flowchart of FIG. 2 will be described below with reference to FIG. First, step 1
In 01, for example, the channel CH1 is received. The target channel to be received is the channel CH5. Different ID codes are set to the respective channels.

When the ID code of CH1 is identified in step 103, this ID code is determined to be different from the ID code of the target channel in step 104, and step 1
In 05, the frequency variable amount of the local oscillation light necessary for receiving the signal light of the channel CH5 is calculated. Based on this calculated value, in step 107, the bias current of the laser diode of the local light source is changed, but the frequency variable amount per unit bias current change is not necessarily constant due to temperature characteristics. Here, for example, the frequency of local light is channel C
If the frequency reaches H4, there is no signal light here, so it is determined in step 109 that the signal light cannot be pulled in. As a result, in step 111, the bias current of the laser diode of the local light source is changed again, and the channel CH3, for example, is received.

The ID code of the channel CH3 is step 1
The determination is made in 04, and since this is also different from the ID code of the target channel, the bias current of the laser diode of the local oscillation light source is changed again. This time, since the frequency interval between the channel CH3 and the target channel CH5 is smaller than the frequency interval between the channel CH1 and the target channel CH5, the bias current of the laser diode of the local light source is stepped based on the frequency variable amount calculated in step 105. When changed at 107, the signal light of the target channel CH5 is drawn. The ID code of channel CH5 is step 10
2 is determined to be the ID code of the target channel.
Flow ends.

As described above, according to the present embodiment, it is not necessary to perform reception for all channels when performing channel selection in optical frequency division multiplexing transmission, so that the signal light of the target channel can be easily selected.

In the case of implementing the present invention, the capture range of the AFC circuit for each channel does not overlap in order to pull in the signal light of either channel when a certain local oscillator frequency is set. desirable. Further, after the reception of the signal light of the target channel is started, the circuit may be configured so that the capture range of the AFC circuit for the channel is expanded. In this case, there is no problem even when the laser frequency of the transmission system deviates relatively greatly after a long time.

In the embodiment described above, the bias current of the laser diode in the local oscillation light source is changed in order to change the frequency of local oscillation light, but instead of this, the temperature of the laser diode may be changed. Good. Further, both the bias current and the temperature of the laser diode may be controlled.

[0032]

As described above, according to the present invention,
It is possible to provide a simple channel selection method in optical frequency division multiplexing transmission.

[Brief description of drawings]

FIG. 1 is a block diagram of a heterodyne receiver for coherent lightwave communication to which the present invention can be applied.

2 is a flowchart of a channel selection operation in the receiver of FIG.

FIG. 3 is an explanatory diagram of channel arrangement of signal light.

[Explanation of symbols]

 2 Local light source 4 Optical coupler 6 Optical detection circuit 10 Bandpass filter 12 Demodulator 14 AFC circuit

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁵ Identification code Internal reference number FI technical display location H04Q 11/04 301 A 9076-5K

Claims (2)

[Claims] 1. A local light source (2) that outputs a local light whose frequency is variable, an optical coupler (4) that superimposes the received signal light on the local light and outputs the signal light, and a signal light from the optical coupler. And a photoelectric conversion means for opto-electrically converting local light to output an intermediate frequency signal, and a heterodyne receiver for coherent lightwave communication provided with a demodulation means for reproducing transmission data based on the intermediate frequency signal. A method of selecting and receiving signal light of a desired channel from signal light of frequency-division-multiplexed multiple channels, the method including receiving a signal light of any one of the signal lights of the plurality of channels. A second step of identifying an ID code previously inserted in an empty bit of the transmission data reproduced based on the received signal light, and the identified ID code is an ID code of a desired channel. And a third step of determining whether the desired channel is not the ID code of the desired channel, based on the intermediate frequency specified by the identified ID code. A fourth step of calculating the frequency variation amount of the local oscillation light required to receive the signal light; and a fifth step of changing the frequency of the local oscillation light based on the calculated value, In the step 3), the third ID is determined until the identified ID code is the ID code of the desired channel.
A channel selection method in optical frequency division multiplex transmission, characterized in that the fifth to fifth steps are repeated. 2. The fifth step is smaller than the change width of the frequency of the local oscillation light in the fifth step when an intermediate frequency signal is no longer obtained after changing the frequency of the local oscillation light, or 2. The channel selection method in optical frequency division multiplexing transmission according to claim 1, further comprising the step of further changing the frequency of the local oscillation light with a large change width.