JP3874242B2 - Optical clock regenerator - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an optical clock recovery device, and particularly relates to a clock recovery technology that is generally used in communication technology, as an apparatus that extracts a clock signal component from an input optical signal and outputs a continuous optical pulse train corresponding to the clock signal. It is useful.
[0002]
[Prior art]
A regenerative repeater used in optical communication needs a function of extracting a clock frequency of an encoded input signal in order to receive and retransmit the transmitted optical signal without error. FIG. 5 shows an example of the configuration of a conventional optical repeater. In the figure, 30 is an optical demultiplexer, 31 and 32 are light receiving elements, 33 is a clock extraction circuit, 34 is an optical pulse train generator for continuous light, 35 is a coding device, and 36 is an optical amplifier. The input optical signal demultiplexed by the optical demultiplexer 30 is converted into an electric signal by the light receiving element 32, and the continuous optical pulse train generated by the optical pulse train generator 34 is encoded again using the encoder 35. Is amplified by the optical amplifier 36 and retransmitted. This is a so-called 3R function (re-timing, re-shaping, re-genetating) of the repeater. Here, in order to perform encoding without error by the encoding device 35, it is necessary that the continuous optical pulse train generated by the optical pulse train generator 34 is synchronized with the input signal electrically converted by the light receiving element 32. Therefore, it is necessary to supply a “clock signal” to the optical pulse train generator 34. This is because the other optical input signal demultiplexed by the optical demultiplexer 30 is converted into an electric signal by the light receiving element 31, and the clock frequency of the input signal is extracted from this electric signal by the clock extracting circuit 33, and This is achieved by adjusting the phase difference and inputting it to the clock signal input terminal of the optical pulse train generator 34.
[0003]
In such a regenerative repeater, with the recent increase in communication capacity, the demand for higher bit rates has been increasing, and in order to cope with higher-speed signals, the above-described element devices, There was a problem that further speeding up of the element was necessary.
[0004]
In addition, a reception and signal separation (DEMUX) apparatus used in optical communication also needs a function of extracting a clock frequency of an input signal in order to receive and separate a transmitted optical signal without error. FIG. 6 shows a configuration of a conventional receiver. In the figure, 40 is an optical demultiplexer, 41 and 42 are light receiving elements, 43 is a clock extraction circuit, and 44 is a so-called DEMUX circuit that drops the input signal to a lower bit rate. Here, a four-to-one DEMUX circuit 44 is illustrated. The input optical signal demultiplexed by the optical demultiplexer 40 is converted into an electric signal by the light receiving element 42 and is divided into a lower bit rate signal by the 44 DEMUX circuit. At that time, the other optical input signal demultiplexed by the optical demultiplexer 40 is converted into an electric signal by the light receiving element 41, the clock frequency of the input signal is extracted by the clock extraction circuit 43, and the phase difference is adjusted. Are input to the clock signal input terminal of the DEMUX circuit 44. Even in such a configuration, there is a problem that it is necessary to further increase the speed of each element device and element in order to cope with a higher-speed signal.
[0005]
These element elements and devices are desired to be stable, small, and easy to adjust, and therefore are required to be configured using semiconductor-based elements that are industrially important. Due to advances in semiconductor integrated circuit technology in recent years, the performance of the clock extraction circuit has already reached a level that can handle an input signal of 40 Gbit / s.
[0006]
However, there is a physical limit in improving the performance of the transistor, and there is a problem that it is extremely difficult to further speed up the clock extraction circuit even with the most advanced technology.
[0007]
On the other hand, an element that performs clock recovery with a configuration of optical input and optical output has also been proposed. FIG. 7 shows an example in which an injection-locked semiconductor mode-locked laser is used for optical clock recovery. 51 is a semiconductor mode-locked laser having an optical input terminal, and a light transmittance modulator 52 and a gain region 53 which are supersaturated absorption regions Consists of. The semiconductor mode-locked laser 51 normally oscillates in a self-excited manner. However, when a modulation signal close to the self-excited oscillation frequency is applied to the light transmittance modulation unit 52 from the outside, the self-excited oscillation frequency is drawn into that frequency. Have.
[0008]
Normally, such external modulation is performed by applying an electrical signal to the light transmittance modulator 52, but the same can be done by modulating the light transmittance of the light transmittance modulator 52 or the gain in the gain region with external input light. Is obtained (light injection mode synchronization). Utilizing this, the light injection mode locking is realized by modulating the light transmittance of the light transmittance modulation unit 52 which is a supersaturated absorption region by making an input optical signal incident from one end face of the semiconductor mode-locked laser 51. A continuous optical pulse train synchronized with the clock frequency of the signal can be reproduced. In the case of signal separation, it is necessary to generate a clock having a low frequency corresponding to the signal speed after separation (here, 1 / n of the original signal speed, n is a natural number) and supply it to the signal separation device. However, if the semiconductor mode-locked laser 51 having a self-oscillation frequency close to 1 / n of the clock frequency is used, a continuous optical pulse train synchronized with the frequency of 1 / n of the clock frequency can be directly obtained.
[0009]
However, when synchronizing a clock with a frequency of 1 / n to an input signal, it is possible to take n phases depending on which pulse of the input signal is synchronized with the input signal. A phase jump may occur when the signal is interrupted. If a phase jump occurs in this way, the signal separation of a predetermined channel cannot be performed, so that it cannot be used in a realistic system.
[0010]
As an apparatus for solving this problem, an apparatus using two semiconductor mode-locked lasers 61 and 63 and one optical gate element 62 has been proposed as shown in FIG. In this apparatus, a pulse train synchronized with the signal frequency is generated by the first-stage semiconductor mode-locked laser 61 having a self-excited oscillation frequency close to the signal frequency, and this pulse train is transmitted through the optical gate element 62 to 1 / n of the signal frequency. Injection into a second-stage semiconductor mode-locked laser 63 having a self-excited oscillation frequency. Further, the phase jump is suppressed by driving the optical gate element 62 using the optical output pulse train of the semiconductor mode-locked laser 63 at the second stage. Further, in order to drive the optical gate element 62, an optical amplifier 64 is essential because a high-output optical signal is required as an optical gate signal.
[0011]
[Problems to be solved by the invention]
However, in the configuration shown in FIG. 8, it is necessary to separately use a semiconductor mode-locked laser 61 and an optical gate element 62 having a self-excited oscillation frequency close to the signal frequency. There was a problem.
[0012]
An object of the present invention is to provide a high-speed optical clock regenerator having a simple configuration in view of the above-described prior art.
[0013]
[Means for Solving the Problems]
The configuration of the present invention that achieves the above object is characterized by the following points.
[0014]
1) In an optical clock regenerator that outputs a continuous optical pulse train synchronized with an encoded optical input signal,
A semiconductor mode-locked laser having at least a light transmittance modulator;
An optical demultiplexer for branching the optical output signal of this semiconductor mode-locked laser;
An optical amplifier for amplifying one of the optical output signals branched by the optical demultiplexer;
A light receiving element that converts an optical signal amplified by the optical amplifier into an electrical signal;
A band-pass filter electrically connected to the light-receiving element and the light transmittance modulator of the semiconductor mode-locked laser, and having a center frequency substantially equal to the self-oscillation frequency of the semiconductor mode-locked laser;
The light transmittance modulation unit is driven by an electric signal corresponding to the light output signal of the semiconductor mode-locked laser and photoelectrically converted by the light receiving element.
[0015]
2) In the optical clock recovery device described in 1) above,
A monolithically integrated ring-type semiconductor mode-locked laser with a light transmittance modulator using a semiconductor high-mesa waveguide, a multimode interference coupler as an optical demultiplexer, an SOA as an optical amplifier, and a light-receiving region that functions as a light-receiving element It became.
[0016]
3) In an optical clock regenerator that outputs a continuous optical pulse train synchronized with an encoded optical input signal,
A semiconductor mode-locked laser having at least a light transmittance modulator;
An optical demultiplexer for branching the optical output signal of this semiconductor mode-locked laser;
A light receiving element that converts one optical output signal branched by the optical demultiplexer into an electrical signal;
An electric amplifier for amplifying the output of the light receiving element;
A band transmission filter electrically connected to the output terminal of the electric amplifier and the light transmittance conversion unit of the semiconductor mode-locked laser, and having a center frequency substantially equal to the self-oscillation frequency of the semiconductor mode-locked laser;
A phase-locked loop is configured by driving the light transmittance modulation unit with an electrical signal photoelectrically converted by the light receiving element while corresponding to the optical output signal of the semiconductor mode-locked laser.
[0017]
4) In an optical clock regenerator that outputs a continuous optical pulse train synchronized with an encoded optical input signal,
A semiconductor mode-locked laser having at least a light transmittance modulation unit and a light receiving region which is a photoelectric conversion unit;
An electrical amplifier that amplifies an electrical signal corresponding to the optical output signal of the semiconductor mode-locked laser converted in the light receiving region;
A band transmission filter electrically connected to the output terminal of the electric amplifier and the light transmittance modulator of the semiconductor mode-locked laser, and having a center frequency substantially equal to the self-excited oscillation frequency of the semiconductor mode-locked laser;
A phase-locked loop is configured by driving the light transmittance modulation unit with an electrical signal photoelectrically converted in the light receiving region while corresponding to the optical output signal of the semiconductor mode-locked laser.
[0018]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
[0019]
<First Embodiment>
FIG. 1 is a block diagram showing an optical clock recovery apparatus according to the first embodiment of the present invention. In the figure, 1 is an InP / InGaAsP semiconductor mode-locked laser, 2 is an optical amplifier composed of a fiber amplifier, 3 is a light receiving element, 4 is a band pass filter, and 5 is a light transmittance modulation of the semiconductor mode-locked laser 1. This is an electroabsorption modulator, and has an electrode electrically separated from the gain region 6 of the semiconductor mode-locked laser 1. Here, part of the output light of the semiconductor mode-locked laser 1 is branched by the optical demultiplexer 7, amplified by the optical amplifier 2, and then input to the light receiving element 3. In this embodiment, a photodiode (Japanese Patent Laid-Open No. 9-275224) called InP / InGaAs UTC-PD (Uni-Traveling-Carrier Photodiode), which is excellent in high speed and high output performance, is used as the light receiving element. The output electrode of the light receiving element 3 is electrically connected to the light transmittance modulator 5 via the band pass filter 4. The self-excited oscillation frequency of the semiconductor mode-locked laser 1 is substantially the same as the center frequency of the band pass filter 4 within a range where the frequency can be drawn.
[0020]
In such an optical clock recovery device, when an input optical signal is incident on the semiconductor mode-locked laser 1, the transmittance of the light transmittance modulator 5 or the gain of the gain region 6 is modulated in accordance with the input optical signal. Here, the self-excited oscillation frequency of the semiconductor mode-locked laser 1 is designed to be approximately equal to 1/4 of the repetition frequency of the input optical signal, and is exactly 1 / of the repetition frequency of the input optical signal by injection light mode locking. An optical pulse train having a repetition frequency of 4 is output. Needless to say, when the input optical signal is a continuous pulse train, similar light injection mode locking occurs in the case of a return-to-zero (RZ) signal modulated by random data, and clock optical pulse regeneration is achieved. The However, this alone is not different from a configuration in which a conventional injection-locked semiconductor mode-locked laser is used for optical clock recovery, and a phase jump occurs when the input signal is interrupted.
[0021]
Therefore, in this embodiment, a part of the optical output of the semiconductor mode-locked laser 1 is cut out by the optical demultiplexer 7, amplified by the optical amplifier 2, and then converted into an electric signal by the light receiving element 3. The output electrode of the light receiving element 3 is electrically connected to the light transmittance modulator 5 via the band pass filter 4. Here, the center frequency of the band-pass filter 4 is approximately the same as the self-oscillation frequency of the semiconductor mode-locked laser 1 within a range where the frequency can be drawn. Furthermore, it is possible to generate a high-output electric pulse by using UTC-PD for the light receiving element 3. Since it is possible to directly drive the light transmittance modulation unit 5 without using an electric amplifier, the light transmittance modulation unit 5 of the semiconductor mode-locked laser 1 is used with the photoelectrically converted light output signal as described above. Is driven to form a phase-locked loop. The band pass filter 4 eliminates noise in the loop and is used to selectively feed back only frequency components close to the self-excited oscillation frequency of the semiconductor mode-locked laser 1.
[0022]
The optical clock regeneration apparatus according to the present embodiment is different from the conventional apparatus in that the phase of the optical output pulse train can be suppressed when the input signal is interrupted when the clock having the 1 / n frequency is synchronized with the input signal. Is a point. That is, by configuring the phase-locked loop as described above, the optical output signals of the semiconductor mode-locked laser 1 are integrated within the loop, and the influence of input fluctuations is greatly mitigated. It is suppressed. Furthermore, the intensity noise generated as a result of the light injection mode locking by the random signal can be largely removed by the effect of the filter in the loop.
[0023]
In this embodiment, in order to adjust the phase of the signal fed back with respect to the input optical signal, a method of adjusting the optical path length between the optical demultiplexer 7 and the light receiving element 3, and the light transmittance from the light receiving element 3. There is a method of adjusting the length of the electric line up to the modulation unit 5, which can be realized by using either or both appropriately. In addition, by providing a variable optical delay line in the optical path between the optical demultiplexer 7 and the light receiving element 3, the phase can be adjusted after the device is manufactured, and a margin for design and device manufacturing can be increased. . A similar effect can be obtained by providing a phase shifter in the electric line between the light receiving element 3 and the light transmittance modulator 5 instead of the optical delay line.
[0024]
In FIG. 1 showing the above-described embodiment, the DC bias capacitor, inductor, resistor, electrode, wiring, and the like that are normally used are not shown in order to avoid complication of the drawing. In the above embodiment, UTC-PD which is a kind of photodiode is used as the light receiving element 3, but other light receiving elements such as a pin photodiode and a phototransistor can also be used. As the form of the photodiode, an end face incident type is used, but other forms such as a back face incident type can also be used. In the above embodiment, an electroabsorption modulator is used as the light transmittance modulator 5, but a supersaturated absorption region produced by separating a part of the gain region from an electrode can also be used.
[0025]
In the above embodiment, the center frequency of the band-pass filter 4 is ¼ of the clock frequency of the input optical signal, but other natural numbers other than 1 may be used, and the order signal separation according to each natural number. Function is realized. Further, the optical amplifier 2 can be preferably configured with a fiber amplifier, but is not limited thereto, and other amplifiers such as a semiconductor optical amplifier (SOA) can be used. In addition, the branched light waveguide can be preferably configured by an optical fiber, but can also be configured by an optical waveguide manufactured using a semiconductor, glass, or polymer on a semiconductor substrate. Furthermore, these can be mounted monolithically or hybridly on the same substrate.
[0026]
<Second Embodiment>
FIG. 2 is a plan view showing a second embodiment of the present invention. As shown in the figure, in this embodiment, a semiconductor high-mesa waveguide 11 is used on a semiconductor substrate 10, a ring-type semiconductor mode-locked laser 12, a multimode interference coupler as an optical demultiplexer 13, an SOA 14 as an optical amplifier, The light receiving region 15 is monolithically integrated.
[0027]
In general, there are two types of resonator configuration when a mode-locked laser is monolithically integrated with other optical elements: a method using a ring resonator and a method using a Bragg reflector, but using a Bragg reflector This is disadvantageous for generating short pulses because the bandwidth in the optical spectrum is limited. Therefore, in this embodiment, a ring-type semiconductor mode-locked laser in which the gain region 16, the electro-absorption modulator as the light transmittance modulator 17 and the multimode interference coupler as the optical multiplexer / demultiplexer 18 are connected by a semiconductor high mesa waveguide. 12 was used. The band-pass filter 19 is a short stub using a capacitor that can be easily integrated on a semiconductor substrate. However, a filter composed of a capacitor and an inductor, or λ / 2 composed of a planar circuit. It is also possible to use a known filter such as a side-coupled bandpass filter.
[0028]
By integrating monolithically using a semiconductor waveguide as in this embodiment, an optical clock recovery device can be configured very compactly. In addition, as in the case of using an optical fiber, there is no need for alignment when optically connecting the components, so that there is an advantage that the mounting cost can be greatly reduced.
[0029]
In the above embodiment, UTC-PD, which is a kind of photodiode, is used as the light receiving region 15, but other light receiving regions such as pin photodiodes and phototransistors can also be used. The form of the photodiode is not limited to the waveguide type, and other forms such as an end face incident type can also be used.
[0030]
Although the electroabsorption modulator is used as the light transmittance modulator 17 in the above embodiment, a saturable absorption region produced by separating a part of the gain region 16 from an electrode can also be used. In the above embodiment, the components are monolithically integrated on the semiconductor substrate. However, it is also possible to hybridly integrate the components on a planar lightwave circuit (PLC) substrate.
[0031]
<Third Embodiment>
FIG. 3 is a block diagram showing a third embodiment of the present invention. In the first embodiment shown in FIG. 1, a high output electric signal is generated by photoelectrically converting the signal amplified by the optical amplifier 2 by the high output light receiving element 3, but in the present embodiment, FIG. As shown in FIG. 2, the optical signal is photoelectrically converted by the light receiving element 3 and then amplified using the electric amplifier 28. However, since the frequency of the electrical signal is 1 / n compared to the frequency of the input signal, the electrical circuit is appropriately designed so as not to limit the high speed.
[0032]
<Fourth embodiment>
FIG. 4 is a block diagram showing a fourth embodiment of the present invention. As shown in the figure, the optical clock recovery device according to the present embodiment differs from the configuration of the optical clock recovery device according to the third embodiment shown in FIG. 3 in that the light receiving element 3 of the third embodiment. However, in this embodiment, the light receiving region 29 is monolithically integrated in the semiconductor mode-locked laser 1. As a result, according to this embodiment, the optical demultiplexer 7 in the third embodiment, and the fiber or waveguide connecting the optical demultiplexer 7 and the light receiving element 3 can be omitted.
[0033]
Here, the light receiving region 29 is designed to absorb a part of the optical signal that circulates in the resonator of the mode-locked laser with a sufficient reverse bias applied and to transmit the rest. Here, a waveguide type UTC-PD excellent in high speed is used as the light receiving region 29, but other light receiving elements such as a pin photodiode can also be used. In addition, when an electroabsorption modulator is used as the light transmittance modulator 5, the characteristics are slightly inferior, but the light receiving region can be configured with the same layer structure as the electroabsorption modulator. The center frequency of the band-pass filter 4 substantially matches the self-excited oscillation frequency of the mode-locked laser 1 within a range where the frequency can be drawn.
[0034]
In this embodiment, the phase of the input optical signal and the signal fed back to the light transmittance modulator 5 can be adjusted by adjusting the length of the electric line from the light receiving region 29 to the light transmittance modulator 5. . The same can be realized by providing a phase shifter in the electric line from the light receiving region 29 to the light transmittance modulator 5, and in this case, the phase is adjusted after the optical clock recovery device is manufactured. Thus, a large margin for design and device fabrication can be obtained.
[0035]
【The invention's effect】
As described in detail in conjunction with the above embodiments, according to the present invention, an apparatus for reproducing a high-speed continuous optical pulse train synchronized with the clock frequency of incident signal light with a simple configuration that does not use a conventional clock extraction circuit is realized. There is an effect that can be done. Furthermore, using this apparatus, it is possible to realize a regenerative repeater and a reception / signal separation apparatus having a high speed and a simple configuration that are required in a broadband optical communication system.
[Brief description of the drawings]
FIG. 1 is a block diagram showing an optical clock recovery device according to a first embodiment of the present invention.
FIG. 2 is a plan view showing an optical clock recovery device according to a second embodiment of the present invention.
FIG. 3 is a block diagram showing an optical clock recovery device according to a third embodiment of the present invention.
FIG. 4 is a block diagram showing an optical clock recovery device according to a fourth embodiment of the present invention.
FIG. 5 is a block diagram showing a configuration of a conventional optical signal repeater.
FIG. 6 is a block diagram showing a configuration of a conventional optical signal DEMUX device.
FIG. 7 is a block diagram showing a conventional optical clock recovery device.
FIG. 8 is a block diagram showing a conventional optical clock recovery device.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Semiconductor mode locked laser 2 Optical amplifier 3 Light receiving element 4 Band transmission filter 5 Light transmittance modulation | alteration part 6 Gain area | region 7 Optical demultiplexer 10 Substrate 11 Semiconductor high mesa waveguide 12 Ring type semiconductor mode synchronous laser 13 Optical demultiplexer 14 SOA
DESCRIPTION OF SYMBOLS 15 Light reception area | region 16 Gain area | region 17 Optical transmittance modulation | alteration part 18 Optical multiplexer / demultiplexer 19 Band transmission filter 28 Electric amplifier 29 Light reception area | region

Claims (4)

In an optical clock regenerator that outputs a continuous optical pulse train synchronized with an encoded optical input signal,
A semiconductor mode-locked laser having at least a light transmittance modulator;
An optical demultiplexer for branching the optical output signal of this semiconductor mode-locked laser;
An optical amplifier for amplifying one of the optical output signals branched by the optical demultiplexer;
A light receiving element that converts an optical signal amplified by the optical amplifier into an electrical signal;
A band-pass filter electrically connected to the light-receiving element and the light transmittance modulator of the semiconductor mode-locked laser, and having a center frequency substantially equal to the self-oscillation frequency of the semiconductor mode-locked laser;
An optical clock that corresponds to the optical output signal of the semiconductor mode-locked laser and that configures a phase-locked loop by driving the light transmittance modulation unit with an electric signal photoelectrically converted by the light receiving element. Playback device. In the optical clock recovery device according to claim 1,
A monolithically integrated ring-type semiconductor mode-locked laser with a light transmittance modulator using a semiconductor high-mesa waveguide, a multimode interference coupler as an optical demultiplexer, an SOA as an optical amplifier, and a light-receiving region that functions as a light-receiving element An optical clock regenerator characterized in that In an optical clock regenerator that outputs a continuous optical pulse train synchronized with an encoded optical input signal,
A semiconductor mode-locked laser having at least a light transmittance modulator;
An optical demultiplexer for branching the optical output signal of this semiconductor mode-locked laser;
A light receiving element that converts one optical output signal branched by the optical demultiplexer into an electrical signal;
An electric amplifier for amplifying the output of the light receiving element;
A band transmission filter electrically connected to the output terminal of the electric amplifier and the light transmittance conversion unit of the semiconductor mode-locked laser, and having a center frequency substantially equal to the self-oscillation frequency of the semiconductor mode-locked laser;
An optical clock that corresponds to the optical output signal of the semiconductor mode-locked laser and that configures a phase-locked loop by driving the light transmittance modulation unit with an electric signal photoelectrically converted by the light receiving element. Playback device. In an optical clock regenerator that outputs a continuous optical pulse train synchronized with an encoded optical input signal,
A semiconductor mode-locked laser having at least a light transmittance modulation unit and a light receiving region which is a photoelectric conversion unit;
An electrical amplifier that amplifies an electrical signal corresponding to the optical output signal of the semiconductor mode-locked laser converted in the light receiving region;
A band transmission filter electrically connected to the output terminal of the electric amplifier and the light transmittance modulator of the semiconductor mode-locked laser, and having a center frequency substantially equal to the self-excited oscillation frequency of the semiconductor mode-locked laser;
An optical clock that corresponds to the optical output signal of the semiconductor mode-locked laser and that configures a phase-locked loop by driving the light transmittance modulator with an electrical signal photoelectrically converted in the light receiving region. Playback device.

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