JPH063514B2 - Tunable optical multiplexer stabilizer - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial field of application] The present invention is used for optical frequency division multiplexing transmission. In particular, it relates to a stabilizing device that automatically stabilizes the transmission frequency of a tunable optical multiplexer.

The present invention changes the tuning frequency of each tunable optical filter of a tunable optical multiplexer composed of a plurality of tunable optical filters, and at that time, changes the intensity of transmitted light from an output terminal different from that for output. Based on this, the tuning frequency of the tunable optical multiplexer is controlled to stabilize the tuning frequency.

[Conventional technology]

Since frequency-multiplexed optical signals with different frequencies,
2. Description of the Related Art A tunable optical multiplexer is conventionally used in which a tunable optical filter for tunably multiplexing two optical signals and outputting them to one of two output terminals is connected in a tournament type.

As a tunable optical filter, Mach-Zehnder interferometer,
Ring resonators, Fabry-Perot resonators and others are known. In order to stabilize the tuning frequency of such a tunable optical filter, it is necessary to control the optical path length depending on its temperature and the like.

FIG. 5 shows a conventional tunable optical multiplexer stabilizing device.
This device is based on
Volume 1.23, No. 15 (1987), page 788. The figure shows an 8-channel tunable optical multiplexer having a multiplexing frequency interval of 5 GHz, which uses seven periodic optical filters as tunable optical filters, and a device for stabilizing the tunable optical multiplexer.

The tunable optical multiplexer / demultiplexer is configured by connecting Mach-Zehnder interferometers in three stages. The periodic optical filter FL1 has a multiplexing frequency interval of 5 GHz, and the periodic optical filters FL2, FL
L3 has a multiplexing frequency interval of 10 GHz and is a periodic optical filter F
L4 to FL7 have a multiplexing frequency interval of 20 GHz. Heater electrodes H1 to H7 are attached to these periodic optical filters FL1 to FL7, respectively. The periodic optical filters FL2, FL4, FL5 and the periodic optical filters FL3, FL6, FL7 are respectively formed on the same substrate.

The electrode 15 has a 7-channel structure and supplies constant power to each of the heater electrodes H1 to H7 to control the tuning frequency of the tunable optical multiplexer by the thermo-optic effect.

The temperature stabilizing circuit 16 includes a periodic optical filter FL1, periodic optical filters FL2, FL4 and FL5, a periodic optical filter FL3,
The substrate temperature of each of FL6 and FL7 is kept constant, thereby stabilizing the transmission frequency of the tunable optical multiplexer.

FIG. 6 shows the structure of a Mach-Zehnder type periodic optical filter.

Two frequencies with frequency interval Δf coupled to input terminal 17
The light including f ₁ and f ₂ is branched by the directional coupler 18 having a branching ratio of 1: 1 into two optical waveguides 19 and 20 having different lengths of ΔL. The light passing through the two optical waveguides 19 and 20 is recombined by the directional coupler 21 having a branching ratio of 1: 1 and the two frequencies f ₁ and f ₂ are separated to output terminals 22 and 23, respectively. Is output to. A heater electrode 24 for controlling the tuning frequency is provided on one of the optical waveguides 19.

This periodic optical filter can be used as an optical multiplexer by reversing the input terminal and the output terminal. That is, the frequencies f ₁ and f ₂ are applied to the output terminals 22 and 23, respectively.
When two lights are incident, these two lights are combined and the incident terminal
It is output from 17.

FIG. 7 shows an example of using the conventional stabilizing device.

The information signals S _{1 to} S n from the information signal sources 1-1 to _{1- n} are output as optical signals by the semiconductor lasers 2-1 to 2-n, respectively. The semiconductor lasers 2-1 to 2-n oscillate at optical frequencies f _{1 to} f _n , respectively. The frequency stabilization circuit 4 is a semiconductor laser 2-
The oscillation frequencies of 1 to 2-n are controlled so as to always have a constant frequency interval Δf.

The output lights of the semiconductor lasers 2-1 to 2-n are multiplexed by the tunable optical multiplexer 4 and input to the tunable optical demultiplexer 27 on the receiving side via the optical fiber 26. The tunable optical demultiplexer 27 demultiplexes light having a desired frequency f _i and makes the light incident on the light receiving element 28. The output of the light receiving element 28 is supplied to the demodulation circuit 30 via the amplifier 29.

The stabilizing device 25 includes a power source and a temperature stabilizing circuit as shown in FIG. 5, and stabilizes the tuning frequency of the tunable optical multiplexer 4.

[Problems to be solved by the invention]

However, in the conventional stabilization device, when setting the tuning frequency of the tunable optical multiplexer, the electric power applied to each heater electrode is changed little by little, and the multiplexing characteristics are measured each time, and The tunable filter must be iteratively processed to find the optimum power. For this reason, (1) it takes a long time to adjust as the number of tunable optical filter connections increases, (2) it is necessary to make another adjustment when switching the tuning frequency, and (3) switching the tuning frequency. In this case, if the amount of power applied to each heater electrode is changed, the tuning frequency drifts until the substrate is in a thermal equilibrium state, and it takes time to complete the tuning.

The present invention solves the above problems, and even if the number of connection stages of the tunable optical filter is increased, the adjustment is easy and the stability is excellent, the tuning frequency can be easily switched, and the switching can be completed in a short time. An object of the present invention is to provide a stabilizing device for a tuned optical multiplexer.

[Means for solving problems]

The stabilizing device of the tunable optical multiplexer according to the present invention controls the tuning frequency adjusting means of the tunable filter to modulate the tuning frequency of each tunable filter by the frequency C _j (j is 1 to m). Tuning frequency modulation means, means for measuring the amplitude change of light output from one of the two output terminals of each tunable optical filter, which is different from the output terminal, and the above-mentioned adjustment so that this amplitude change is optimal. And means for controlling the means for controlling.

Of the two output terminals of the tunable optical filter, the actual output terminal is hereinafter referred to as "signal output terminal". Further, the other output terminal is hereinafter referred to as "control output terminal".

As the tunable filter, one having two terminals through which light is transmitted and output, for example, a periodic filter or a ring filter is used.

[Action]

When the power applied to the electrodes of the tunable optical filter is frequency-modulated, the optical path length changes due to the thermo-optic effect, and the transmittance to the two output terminals of the tunable optical filter changes. There is a complementary relationship between the transmittance to the signal output terminal and the transmittance to the control output terminal such that when one is maximum, the other is minimum. Therefore, by monitoring the transmittance of the control output terminal, the transmittance of the signal output terminal can be optimally controlled.

When the frequency at which the transmittance to the signal output terminal becomes maximum is incident on the tunable optical filter, regardless of whether the tuning frequency of the tunable optical filter deviates from the incident light frequency, either on the high frequency side or the low frequency side. , The transmittance to the signal output terminal is reduced. At this time, the intensity of the output light is maximum when the frequency shift is zero, and the intensity of the output light is minimum when the frequency shift is maximum in the positive direction and the negative direction. That is, output light amplitude-modulated at a frequency twice the modulation frequency can be obtained. When the transmittance deviates from the maximum value, the transmittance changes as the frequency shift increases or decreases, and the same frequency component as the modulation frequency appears.

Therefore, the tuning frequency of each tunable optical filter is controlled such that the frequency component equal to the modulation frequency at the signal output terminal is minimized or the frequency component twice the modulation frequency is maximized. That is, the tuning frequency is controlled so that the frequency component equal to the modulation frequency at the control output terminal is maximized or the frequency component twice the modulation frequency is minimized. Thereby, each tunable optical filter can be optimally adjusted, and the tunable optical multiplexer can be optimally adjusted.

〔Example〕

FIG. 1 is a block diagram of an optical signal transmission device including a stabilizing device for a tunable optical multiplexer according to an embodiment of the present invention.

The information signals S _{1 to} S n from the information signal sources 1-1 to _{1- n} are output as optical signals by the semiconductor lasers 2-1 to 2-n, respectively. The semiconductor lasers 2-1 to 2-n oscillate at optical frequencies f _{1 to} f _n , respectively, and the oscillation frequencies are respectively information signals S _{1 to} S _n.
Is frequency-modulated by. In order to frequency-modulate the oscillation frequency of the semiconductor lasers 2-1 to 2-n, the resonator super is changed thermally or by the piezo effect, or the refractive index of the resonator is electrically changed.

The frequency stabilizing circuit 3 controls the oscillation frequencies of the semiconductor lasers 2-1 to 2-n so that the oscillation frequency is always a constant frequency interval Δf.

The tunable optical multiplexer 4 is a tunable optical filter that tunably couples two optical signals and outputs them to one of two output terminals.
For example, m (where m is an integer of 1 or more) periodic optical filters are included, and the output lights of the semiconductor lasers 2-1 to 2-n are frequency-multiplexed.

The stabilizer 5 is connected to the tunable optical multiplexer 4 and comprises means for adjusting the tuning frequency of each tunable optical filter in the tunable optical multiplexer 4.

FIG. 2 is a block diagram showing the details of the tunable optical multiplexer 4 and the stabilizing device 5.

The tunable optical multiplexer 4 has a structure in which a Mach-Zehnder type tunable optical filter is connected in a tournament type with m = 2 ^X -1 and X stages, and n series (n is an integer of 1 or more) optical waves. Frequency multiplex signals.

The stabilizing device 5 includes control circuits 7-11 to 7-X1 provided corresponding to the tunable optical filter, and a temperature stabilizing circuit 6. The temperature stabilization circuit 6 stabilizes the temperature of the entire substrate.

FIG. 3 is a block diagram showing the details of the control circuit.
Here, a control circuit connected to the j-th (j is 1 to m) tunable optical filter will be described as an example.

This control circuit is provided with an amplification substrate 12 that supplies control power to the electrodes of the tunable optical filter as a means for adjusting the tuning frequency of the tunable optical filter, and controls the amplifier 12 to adjust the tuning frequency of the tunable optical filter to frequency. Variable low-frequency oscillator 13 and adder as tuning frequency modulation means for modulation by C _j
The light receiving element 8, the multiplier 9 and the phase adjuster 14 are provided as means for measuring the amplitude change of the light output from one of the two output terminals of the tunable optical filter other than the one for output.
And a low-pass filter 10 as a means for controlling the amplifier 12 so that the amplitude change is optimum.

Light from the control output terminal of the tunable optical filter is input to the light receiving element 8. The multiplier 9 multiplies the output of the light receiving element 8 by a signal obtained by phase-adjusting the output of the variable low-frequency oscillator 13 by the phase adjuster 14. As a result, the output of the light receiving element 8 is synchronously detected at the frequency C _j . The synchronous detection output passes through the low-pass filter 10, is superimposed on the output of the low-frequency oscillator 13, and is supplied to the electrode of the tunable optical filter via the amplifier 12.

When the synchronization frequency deviates from the desired frequency, a signal amplitude-modulated at the frequency C _j appears at the output of the light receiving element 8. Therefore, a signal obtained by synchronously detecting the output of the light receiving element 8 is used as an error signal, and power is supplied to the heater electrode of the tunable filter.
This power produces heat, and the thermo-optic effect controls the tuning frequency.

FIG. 4 shows the relationship between the transmittance T _j of the tunable optical filter, the modulation frequency C _j, and the error signal output e _j . Figure 4 (a) shows the transmittance T
It indicates the relationship between the _j and the modulation frequency C _j, Fig. 4 (b) transmittance T _j
The error signal output e _j when modulating is shown.

The modulation frequency C _j of each tunable optical filter is set differently for filters of different connection stages in order to prevent interference during control.

〔The invention's effect〕

As described above, the stabilizer for a tunable optical multiplexer according to the present invention can individually control each tunable optical filter included in the tunable optical multiplexer, so that the number of connection stages of the tunable optical filter is increased. Even so, it has an effect that it can be adjusted in a short time and is easily stabilized. Further, even when the tuning frequency is switched, it is possible to tune in a short time.

[Brief description of drawings]

FIG. 1 is a block diagram of an optical signal device according to an embodiment of the present invention. FIG. 2 is a block diagram showing the details of the tunable optical multiplexer and the stabilizing device. FIG. 3 is a block diagram showing the details of the control circuit. FIG. 4 is a diagram showing the relationship between the transmittance T _j of the tunable optical filter, the modulation frequency C _j, and the error signal output e _j . FIG. 5 is a diagram showing a stabilizing device for a tunable optical multiplexer according to a conventional example. FIG. 6 is a diagram showing the structure of a Mach-Zehnder type periodic optical filter. FIG. 7 is a block diagram showing a usage example of the conventional stabilizing device. 1-1 to 1-n ... Information signal source, 2-1 to 2-n ... Semiconductor laser, 3 ...
Frequency stabilizing circuit, 4 ... Tunable optical multiplexer, 5, 25 ... Stabilizing device, 6 ... Temperature stabilizing circuit, 7-11 to 7-X1 ... Control circuit,
8 ... Light receiving element, 9 ... Multiplier, 10 ... Low-pass filter, 11
... Adder, 12 ... Amplifier, 13 ... Variable low frequency oscillator, 14 ... Phase adjuster, 15 ... Power supply, 16 ... Temperature stabilizing circuit, 17 ... Input terminal, 18, 21 ... Directional coupler, 19, 20 ... Optical waveguide, 22, 23 ...
Output terminal, 24, H1 to H7 ... Heater electrode, 26 ... Optical fiber, 2
7 ... Tunable optical demultiplexer, 28 ... Photodetector, 29 ... Amplifier, 30 ...
Demodulation circuit, FL1 to FL7 ... Periodic optical filter.

Claims (1)

[Claims] 1. M tunable optical filters for tunably multiplexing two optical signals and outputting them to one of two output terminals.
Is a integer greater than or equal to 1), and is provided with a means for adjusting the tuning frequency of each tunable optical filter in the stabilizer of the tunable optical multiplexer, the adjusting means is adjusted. Tuning frequency modulating means for modulating the tuning frequency of each tunable optical filter by frequency C _j (j is 1 to m), and output from a terminal other than the output terminal of the two output terminals of each tunable optical filter. A stabilizing device for a tunable optical multiplexer, comprising: a means for measuring the amplitude change of the generated light; and a means for controlling the adjusting means so that the amplitude change is optimum.