JP2005222083A - Optical pulse generating apparatus and method for generating optical pulse - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To obtain an optical pulse position detection circuit which detects the pulse position without using a complicated operational circuit. <P>SOLUTION: The pulse generator includes: a light source 26 to output an optical signal; an oscillator 5 to output an electric clock signal; a first optical modulator 3a to modulate the intensity of the optical signal by the electric clock signal; a phase shifter 4 to shift the phase of the electric clock signal; a second optical modulator 3b to modulate the intensity of the optical signal from the first optical modulator by the phase-shifted electric clock signal; an optical demultiplexer 2 to demultiplex the output of the second optical modulator; an photodetector 8 to convert the demultiplexed optical signal into an electric signal; a dither signal generating circuit 11 to output a dither signal; a phase comparator 12 to synchronously detect the output of the photodetector and the dither signal; and a phase shifter controlling circuit 9 to control the phase shift degree of the phase shifter. The phase shifter control circuit receives the dither signal and the output of the phase comparator and controls the phase shifter to maximize the output of the photodetector. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to an optical communication system, and more particularly to an optical time division multiplexing technique. The present invention can be applied to a measurement system, particularly a temperature sensor and a pressure sensor.

  In a conventional optical communication system, a transmission apparatus generates a high-speed signal by time-division multiplexing (TDM: Time Division Multiplexing) of a plurality of low-speed signals by processing of an electronic circuit. Similarly, a receiving apparatus or node re-divides a high-speed signal into a low-speed signal (DEMUX: Demultiplexing) by processing of an electronic circuit. Up to now, transmission systems of 10 Gb / s (bits per second) class have been realized by TDM technology using electronic circuits, but it is expected that the processing speed of electronic circuits will become a bottleneck in future large-capacity communication systems. Therefore, time-division multiplexing technology (optical TDM technology) using optical processing has been actively studied. The optical TDM technique is a technique for processing an optical signal without converting it into an electric signal, and a technique for multiplexing optical pulse trains input from different paths in synchronization is required. However, the time for which the optical pulse train propagates through the transmission line changes depending on the environment such as temperature, and the pulse position (phase) of the input optical pulse train changes from time to time. Therefore, means for detecting the pulse position is indispensable. . The pulse position here means the relative time relationship between the reference clock signal having the repetition frequency of the optical pulse train and the input pulse.

Conventional Example 1
A technique disclosed by Daiki et al. Is known as a technique for detecting a pulse position.
FIG. 43 is a rewrite of the block diagram shown in the 1996 IEICE General Conference B-1118 “Optical Time Multiplexing Circuit Based on the Modulation Signal to the Optical Modulator”.
In FIG. 43, 1 is an optical pulse train input terminal, 2 is an optical demultiplexer, 3 is an optical modulator that modulates the intensity of light, 4 is a phase shifter, 5 is an oscillator, and 6a and 6b detect the intensity of an optical signal. An optical power meter 7 is a transmittance detector. The optical pulse train is input from the optical pulse train input terminal 1 and is demultiplexed into two paths by the optical demultiplexer 2. The first output of the optical demultiplexer is input to the first optical power meter 6 a, and the second output of the optical demultiplexer is input to the optical modulator 3. The reference clock signal output from the oscillator 5 drives the optical modulator 3 through the phase shifter 4. The optical signal output from the optical modulator 3 is input to the second power meter 6b. The transmittance detector 7 detects the transmittance of the pulse in the optical modulator by comparing and calculating the outputs of the first optical power meter 6a and the second power meter 6b. Even if the light intensity of the input optical pulse train changes, the outputs of the first optical power meter 6a and the second power meter 6b are compared and calculated, so that the transmittance of the optical modulator 3 can be measured. The pulse transmittance in the optical modulator is determined by the phase of the clock signal that drives the optical modulator and the position (phase) of the optical pulse train input to the optical modulator as described below. I can know. The phase shifter 4 is manually adjusted so as to increase the transmittance value. Thus, the phase of the input optical pulse and the reference clock signal can be synchronized.

The operation of FIG. 43 will be described with reference to FIG.
44A schematically shows the pulse position of the optical pulse train input to the optical modulator 3. FIG. 44B shows the relationship between time and the transmittance of the optical modulator 3, and corresponds to the clock signal that drives the optical modulator 3. FIG. FIG. 44 (c) shows the relationship between time and pulse transmittance.
In FIG. 44 (a), when the positions of the three optical pulse trains are pulse 1, pulse 2, and pulse 3, respectively, the transmittance of the pulse is the transmittance 1, transmittance 2, and transmittance of FIG. 44 (c). Corresponds to 3. Thus, since the pulse position corresponds to the transmittance, the pulse position can be known by detecting the transmittance.

Conventional example 1 is based on the premise that the pulse position detection unit is used as an error signal detection circuit used for pulse position control. Therefore, it is not necessary to accurately detect the pulse position itself, and the measurement result of the pulse position and the pulse position are not detected. If only the sign relationship of the target position A (the left-right positional relationship with the position A in FIG. 44) can be detected, the purpose is achieved. However, when it is necessary to accurately detect the pulse position itself, there are the following problems. As is clear from FIG. 44, the pulse positions corresponding to transmittance 1, transmittance 2, and transmittance 3 are not only pulse 1, pulse 2, and pulse 3, but also pulse 1 ′, pulse 2 ′, and pulse 3 ′. For this reason, the position detection range is limited to the region T in FIG. That is, since the transmittance of the optical modulator corresponds to two phase shift amounts, there is a problem that it is difficult to optimize the phase shift amount. Further, as shown in FIG. 44 (c), the relationship between the transmittance and the pulse position is a sinusoidal function and not a linear relationship. Therefore, a complicated arithmetic circuit is required to accurately detect the pulse position. Is required.
Accurate detection of the pulse position is required not only for the simplification of the pulse position control circuit but also when performing more complicated optical processing. In addition, accurate detection of the pulse position is indispensable for various sensors that use changes in propagation delay time of the transmission path.

Conventional Example 2
Another technique for detecting the pulse position is disclosed in Japanese Patent Application Laid-Open No. 2-1828.
FIG. 45 is a rewrite of FIG. 1 disclosed in JP-A-2-1828.
In FIG. 45, 1 is an optical pulse train input terminal, 33 is an optical multiplexer, 43 is an all-optical optical modulator that modulates an optical pulse train with an optical clock pulse, 8 is a photodetector, 34 is an optical delay control circuit, 44 Is an optical clock pulse generation circuit, 24 is an optical delay device, and 10 is a phase shift amount output terminal. The optical signal input from the optical pulse train input terminal 1 is input to the photodetector 8 through the all-optical optical modulator 43. With the output signal of the photodetector 8 as an input, the optical clock pulse generation circuit 44 outputs an optical clock pulse. The optical clock pulse is delayed by the optical delay device 24 and then input to the all-optical optical modulator 43 by the optical multiplexer 33. Since the all-optical optical modulator 43 is designed to have high transmittance when the input optical signal intensity is strong, the phase of the optical signal input from the optical pulse train input terminal 1 and the optical clock pulse are synchronized. In this case, the light intensity detected by the photodetector 8 becomes the maximum. Therefore, the optical clock pulse is synchronized with the input optical pulse by controlling the optical delay device 24 so that the output of the photodetector 8 is maximized. By monitoring the delay amount of the optical delay device 24 at this time from the phase shift amount output terminal 10, the pulse position of the input optical pulse train can be detected.

  In Conventional Example 2, an accurate pulse position can be detected, but a complicated optical clock pulse generation circuit 44 is required. In Conventional Example 2, since one of the purposes is to output an optical clock pulse synchronized with the input optical signal, an optical clock pulse generation circuit 44 is prepared, but only the detection of the pulse position is performed. For the purpose, it is not preferable to require a complicated optical clock pulse generation circuit 44. The all-optical light modulator 43 is not easily procured from the market although several examples of implementation are known. Further, the optical delay device 24 is difficult to manufacture a device that satisfies both a control range that allows a long delay time and a high control accuracy, as compared with an electrically operated delay device (phase shifter). There's a problem.

Conventional Example 3
Next, the importance of realizing a short pulse generation circuit in the optical TDM technology will be described. Here, the short pulse means an optical pulse having a short pulse width.
The reason why short pulses are regarded as important in the optical TDM technology is that the pulse width of a necessary optical pulse becomes narrower as the transmission capacity increases. For example, a 20 Gb / s class transmission system using optical TDM technology requires a pulse width of 20 to 10 ps (pico second) or less, but a 100 Gb / s class transmission system has a pulse width of 4 to 2 ps or less. A pulse width is required. As a method for generating a pulse, a method using an optical modulator having a pulse type gate is known. In this method, in order to generate a short pulse, there is a method of narrowing the effective gate width by connecting optical modulators having pulse-type gates in multiple stages. Technology, Chapter 2.2, "Maruzen Co., Ltd. In order to obtain short pulses by connecting optical modulators in multiple stages, the phase of the electrical signal that drives each optical modulator is matched to the phase of the optical pulse that is input to each optical modulator. There is a need. However, since it is necessary to compensate for the insertion loss of the optical modulator, it is common to insert an optical amplifier between the optical modulator and the optical modulator. However, the time for which the optical signal propagates through the optical amplifier and the transmission line varies depending on the environmental temperature. Therefore, it is difficult to achieve phase matching between the electrical signal and the optical signal without providing means for absorbing fluctuations in the delay time of the optical signal.

As a technique for solving the phase matching problem as described above, one disclosed by Tomioka et al. Is known.
FIG. 46 is a rewrite of the block diagram shown in the 1996 IEICE General Conference B-1121 “Consideration on Optical Pulse-Data Phase Detection Method During Optical Pulse Train Data Modulation”.
In FIG. 46, 26 is a light source, 3a is a first optical modulator, 29 is an optical amplifier, 3b is a second optical modulator, 28a and 28b are RF (Radio Frequency) amplifiers, 4 is a phase shifter, and 5 is an oscillator. 32 is a 2: 1 multiplexing circuit, 31 is a pulse pattern generator, 2 is an optical demultiplexer, 30 is a modulated light output terminal, and 6 is an optical power meter.

Next, the operation will be described.
The clock signal output from the oscillator 5 is branched into two, one being input to the pulse pattern generator 31 and the other being input to the phase shifter 4. The clock signal whose phase is shifted by the phase shifter 4 is amplified by the RF amplifier 28a and input to the optical modulator 3a. Since the optical modulator 3a modulates the optical signal emitted from the light source 26 with the clock signal supplied by the RF amplifier 28a, an optical pulse is output from the optical modulator 3a. The optical pulse output from the optical modulator 3a is amplified by the optical amplifier 29 and then input to the second optical modulator 3b. The output of the pulse pattern generator 31 is RZ (Return to Zero) encoded by the multiplexing circuit 32 and then amplified by the RF amplifier 28b. The RZ signal synchronized with the clock signal output from the oscillator 5 from the RF amplifier 28b is supplied to the second optical modulator 3b. In the second optical modulator 3b, the optical pulse output from the optical amplifier 29 is modulated by the RZ signal output from the RF amplifier 28b. At this time, the optical pulse input to the optical modulator 3b and the RZ signal need to be synchronized.

Part of the output of the optical modulator 3 b is branched by the optical demultiplexer 2 and input to the optical power meter 6.
The operation principle will be described with reference to FIG.
FIG. 47B shows the relationship between the phase shift amount of the phase shifter 4 and the transmittance of the optical modulator 3b.
47B, when the optical pulse input to the optical modulator 3b and the RZ signal are synchronized, the phase shift amount is the phase shift amount 2, and the phase shift amount is too small (phase shift amount). Even when the phase shift amount is too large (phase shift amount 3), the transmittance of the optical modulator 3b decreases. For this reason, by manually controlling the phase shift amount of the phase shifter 4 so that the output light intensity of the optical power meter 6 is maximized, the phase relationship between the optical pulse input to the optical modulator 3b and the RZ signal is obtained. It can be controlled to an optimum value.

  Conventional example 3 is not intended to generate a short pulse but is intended to generate an RZ-modulated optical signal. Therefore, the optical modulator 3b is driven by the RZ signal. However, if the RZ signal for driving the optical modulator 3b is an ideal rectangular wave, there is a problem that the phase shift amount cannot be measured from the transmittance of the optical modulator 3b. Even if the purpose is to generate an appropriate pulse waveform, the relationship between the transmittance and the pulse position is a sinusoidal function and not a direct relationship, so the optimum phase shift amount (phase shift amount 2) is near. However, there is a problem that the change (ΔP) in the transmittance of the optical modulator 3b with respect to the change (ΔΦ) in the phase shift amount is reduced, and the control accuracy is lowered. Further, since the transmittance of the optical modulator as in Conventional Example 1 corresponds to two phase shift amounts, there is a problem that optimization control of the phase shift amount is difficult. Further, as shown in the prior art example 1, since the outputs of the first optical power meter 6a and the second power meter 6b are not configured to be compared, the output light intensity of the light source 26, the optical modulator 3a There is a problem that the transmittance of the optical modulator 3b cannot be measured when either the transmittance of the optical amplifier 29 or the gain of the optical amplifier 29 changes.

Conventional Example 4
In long-distance optical amplifying and repeating transmission systems, it is known that the optical signal-to-noise ratio (Optical Signal Noise Ratio) deteriorates or fluctuates due to polarization hole burning of the optical amplifying repeater or polarization dependent loss of the transmission line. ing. In order to improve this, polarization scrambling is performed. Polarization scrambling is a method of sending signals by temporally switching two independent polarizations. Polarization switching is performed at least once for a 1-bit signal. In particular, in order to average the latter fluctuation (signal fading) of the optical S / N ratio, it is necessary to perform polarization scrambling at a speed at least equal to or higher than the signal bit rate. For polarization scrambling, a lithium niobate optical phase modulator is generally used. Polarization scrambling is characterized by phase modulation occurring at the same time as polarization modulation. Polarization scrambling is used to compensate for waveform degradation due to transmission path dispersion (difference in optical propagation speed due to frequency based on transmission path characteristics). It can be used in Japanese Patent Application Laid-Open No. 8-111162. According to this, it is necessary to drive the polarization scrambler with a data clock synchronized with the bit of data modulation. It has been discussed to bring about. In other words, if the phase of the drive signal of the polarization scrambler is in a predetermined relationship with the phase of the data, the receiving terminal may be affected by fiber dispersion (difference in light propagation speed due to frequency based on fiber characteristics) or nonlinear refractive index change. Even with amplitude fluctuations, the eye opening can be made larger so that signal identification is advantageous.
JP-A-2-1828 Japanese Patent Laid-Open No. 8-111162 1996 IEICE General Conference B-1118 "Optical Time Multiplexing Circuit Based on Modulation Signal to Optical Modulator" 1996 IEICE General Conference B-1121 "A Study on Optical Pulse-Data Phase Detection Method for Optical Pulse Train Data Modulation"

  Conventional Example 1 discloses a technique in which light intensity is used to adjust the phase between optical modulators. However, since there are two pulse positions estimated from the transmittance, there is a problem that the direction of the phase shift cannot be determined only by the information of the light intensity. Further, since the phase shifter is manually adjusted, it is difficult to automatically control the phase between the optical modulators due to a change in the transmission path length between the optical modulators that changes with time. Further, since the relationship between the transmittance and the pulse position is not a linear relationship, there is a problem that a complicated arithmetic circuit is required.

  Conventional example 2 discloses another technique for detecting a pulse position. However, there are problems that a complicated optical clock pulse generation circuit is required, an all-optical optical modulator that is difficult to obtain, and an optical delay device that is difficult to control with high accuracy. .

  Conventional Example 3 discloses a technique for solving the problem of phase matching caused by a variation in delay time when an optical pulse is generated. However, there is a problem that the control accuracy decreases near the optimum phase shift amount. There is another problem that the transmittance of the optical modulator cannot be measured when the optical signal intensity changes. Further, similarly to the conventional example 1, since there are two phase shift amounts estimated from the transmittance of the optical modulator, there is a problem that optimization control of the phase shift amount is difficult.

  In the conventional example 4, the effect of synchronizing the drive signal and data of the polarization scrambler is described, but a countermeasure against a factor that impairs synchronization (for example, change in propagation delay time of the fiber due to temperature fluctuation) is disclosed. Not. That is, there has been no disclosure of a circuit configuration that can detect the phase of a data signal input to the polarization scrambler and drive the polarization scrambler with an optimum and synchronized phase.

The present invention has been made to solve the above-described problems, and a first object is to obtain an optical pulse position detection circuit that detects a pulse position without using a complicated arithmetic circuit.
A second object is to obtain an accurate optical pulse position detection circuit without using an optical clock pulse generation circuit, an optical optical modulator, or an optical delay device.
Furthermore, a third object is to provide an optical pulse generator that generates an optical pulse by optimizing control of the phase shift amount.
A fourth object is to obtain an optical pulse generator that simultaneously outputs a plurality of short pulses of different wavelengths.
A fifth object is to obtain a pulse generator capable of performing modulation in synchronization with an optical pulse.

An optical pulse position detection circuit according to the present invention includes an optical pulse train input terminal for inputting an optical pulse train having a predetermined repetition period,
An oscillator that outputs an electrical clock signal having the same frequency as the repetition period of the optical pulse train;
A phase shifter that inputs the electrical clock signal output from the oscillator, shifts the phase of the electrical clock signal, and outputs the phase shifter;
Light that inputs an electrical clock signal output from the phase shifter, inputs an optical pulse train input from the optical pulse train input terminal, modulates the optical pulse train based on the electrical clock signal, and outputs an optical signal A modulator,
A photodetector that converts the optical signal output from the optical modulator into an electrical signal and outputs the electrical signal;
A phase control circuit that inputs the output of the photodetector and controls the phase shift amount of the phase shifter so that the output of the photodetector is maximized;
And a phase shift amount output terminal for outputting a phase shift amount of the phase shifter.

The phase control circuit includes:
A dither signal generation circuit for outputting a dither signal;
A phase comparator that inputs an output of the photodetector and a dither signal output from the dither signal generation circuit, and outputs an error signal by synchronous detection;
A phase shifter control circuit that inputs and superimposes the dither signal output from the dither signal generation circuit and the error signal output from the phase comparator and outputs a control signal for controlling the phase shift amount of the phase shifter; It is characterized by that.

The optical pulse position detection circuit further includes:
An optical pulse train generating light source driven by an electrical clock signal output from the oscillator;
A transmission path connected between the optical pulse train generation light source and the optical pulse train input terminal,
The oscillator has means for outputting two or more types of frequencies,
A propagation time detection circuit that receives a phase shift amount output from the phase shift amount output terminal and detects a time during which an optical pulse propagates through the transmission line based on the frequency of an electrical clock signal output from the oscillator It is characterized by having.

  The optical modulator is a semiconductor electroabsorption optical modulator.

An optical pulse generator according to the present invention includes a light source that outputs an optical signal having a predetermined wavelength,
An oscillator that outputs an electrical clock signal of a predetermined frequency;
A first optical modulator connected to the oscillator for intensity-modulating the optical signal with an electrical clock signal and outputting the modulated optical signal;
A second optical modulator for intensity-modulating an optical signal output from the first optical modulator with an electrical clock signal, and
One of the optical signal input to the second optical modulator and the optical signal output from the second optical modulator is input, a part of the optical signal is output, and a part is branched An optical demultiplexer,
A photodetector that converts the optical signal demultiplexed by the optical demultiplexer into an electrical signal;
A phase changing unit for changing the phase of the optical signal;
And a control circuit that controls the phase change amount of the phase change unit so that the output of the photo detector is inputted and the output of the photo detector is maximized.

The control circuit includes:
A dither signal generation circuit for outputting a dither signal;
A phase comparator that inputs an output of the photodetector and a dither signal output from the dither signal generation circuit and outputs an error signal by synchronous detection;
A circuit that inputs and superimposes the dither signal output from the dither signal generation circuit and the error signal output from the phase comparator and outputs a control signal for controlling the phase change amount of the phase change unit. Features.

The phase changing unit is
A phase shifter that shifts and outputs the phase of the electrical clock signal output from the oscillator to either the first optical modulator or the second optical modulator;
The control circuit includes:
A phase shifter control circuit for controlling a phase shift amount of the phase shifter is provided.

The phase changing unit is
An optical delay device that delays the optical signal output from the first optical modulator and outputs the optical signal to the second optical modulator;
The control circuit includes:
And a delay control circuit for controlling a delay amount of the optical delay device.

The phase changing unit is
A phase shifter that shifts and outputs the phase of the electrical clock signal output from the oscillator to either the first optical modulator or the second optical modulator;
An optical delay device that delays the optical signal output from the first optical modulator and outputs the delayed optical signal to the second optical modulator;
The control circuit includes a delay control circuit that controls a delay amount of the optical delay device,
The phase shifter receives a dither signal and shifts the phase of an electrical clock signal output from the oscillator.

The first and second optical modulators are composed of one optical modulator,
The light source outputs an optical signal in a first polarization state;
The optical pulse generator further comprises:
A first polarization multiplexer / demultiplexer connected between the light source and the optical modulator;
A second polarization multiplexer / demultiplexer connected between the optical modulator and the optical delay;
A polarization state converter that inputs the optical signal output from the optical delay device, converts the polarization state of the optical signal, and outputs it to the second polarization multiplexer / demultiplexer;
The optical demultiplexer is a polarization output from the first polarization multiplexer / demultiplexer via the second polarization multiplexer / demultiplexer, the optical modulator, and the first polarization multiplexer / demultiplexer. A part of the optical signal whose state has been converted is output and a part is branched.

The optical pulse generator as a light source,
A first light source that outputs an optical signal of a first wavelength;
A second light source that outputs an optical signal of a second wavelength,
Corresponding to the first light source and the second light source, the first and third light modulators,
And an optical multiplexer that multiplexes the optical signals output from the first and third optical modulators and outputs them to the second optical modulator.

The optical pulse generator is
A temperature detection circuit for detecting the temperature in the apparatus;
A reference voltage generator;
A temperature drift detection circuit that receives the output signal of the temperature detection circuit and the output signal of the reference voltage generator, generates a compensation signal that compensates for the amount of phase change, and outputs the compensation signal to the control circuit. To do.

The optical pulse generator is
A wavelength detection circuit for detecting a wavelength of an optical signal output from the light source;
A reference voltage generator;
A wavelength drift detection circuit that receives the output signal of the wavelength detection circuit and the output signal of the reference voltage generator, generates a compensation signal that compensates for the amount of phase change, and outputs the compensation signal to the control circuit. To do.

  The optical modulator is a semiconductor electroabsorption optical modulator.

The second light modulator;
The phase change unit;
The photodetector;
A plurality of sets of the control circuits are provided in parallel, and the optical signal output from the first optical modulator is branched and processed in parallel.

The second light modulator;
The phase change unit;
The photodetector;
The control circuit is provided in a plurality of sets serially, and the optical signals output from the first optical modulator are serially processed in order.

An optical pulse position detection method according to the present invention includes an optical pulse train input step of inputting an optical pulse train having a predetermined repetition period,
An oscillation step of outputting an electrical clock signal having the same frequency as the repetition period of the optical pulse train;
A phase shift step of inputting the electrical clock signal output from the oscillator, shifting the phase of the electrical clock signal and outputting it;
The electrical clock signal output from the phase shift step is input, the optical pulse train input from the optical pulse train input step is input, the optical pulse train is modulated based on the electrical clock signal, and the optical signal is output. A light modulation process;
A light detection step of converting the optical signal output from the light modulation step into an electrical signal and outputting the electrical signal;
A phase control step for inputting the output of the light detection step and controlling the phase shift amount of the phase shift step so that the output of the light detection step is maximized;
A phase shift amount output step of outputting the phase shift amount of the phase shift step.

The phase control step includes
A dither signal generation step for outputting a dither signal;
A phase comparison step of inputting an output of the light detection step and a dither signal output from the dither signal generation step and synchronously detecting and outputting an error signal;
A phase shifter control process for outputting a control signal for controlling the phase shift amount of the phase shift process by inputting and superimposing the dither signal output from the dither signal generation process and the error signal output from the phase comparison process; It is characterized by having.

An optical pulse generation method according to the present invention includes a step of outputting an optical signal having a predetermined wavelength,
An oscillation process for outputting an electrical clock signal of a predetermined frequency;
A first optical modulation step of modulating the intensity of the optical signal with an electrical clock signal and outputting the modulated signal;
A second light modulation step of intensity-modulating the optical signal output from the first light modulation step with an electrical clock signal and
One of the optical signal input to the second optical modulation step and the optical signal output from the second optical modulation step is input, a part of the optical signal is output, and a part is branched Optical demultiplexing process;
A light detection step of converting the optical signal demultiplexed by the light demultiplexing step into an electric signal;
A phase changing step for changing the phase of the optical signal;
And a control step of controlling the phase change amount of the phase change step so that the output of the light detection step is inputted and the output of the light detection step is maximized.

The control step includes
A dither signal generation step for outputting a dither signal;
A phase comparison step of inputting an output of the light detection step and a dither signal output from the dither signal generation step and synchronously detecting and outputting an error signal;
A step of inputting and superimposing the dither signal output from the dither signal generation step and the error signal output from the phase comparison step, and outputting a control signal for controlling the phase change amount of the phase change step. Features.

An optical pulse generator according to the present invention includes a light source that outputs an optical signal having a predetermined wavelength,
An oscillator that outputs an electrical clock signal of a predetermined frequency;
A first optical modulator connected to the oscillator for intensity-modulating the optical signal with an electrical clock signal and outputting the modulated optical signal;
A second optical modulator for intensity-modulating an optical signal output from the first optical modulator with an electrical clock signal, and
One of the optical signal input to the second optical modulator and the optical signal output from the second optical modulator is input, a part of the optical signal is output, and a part is branched An optical demultiplexer,
A photodetector that converts the optical signal demultiplexed by the optical demultiplexer into an electrical signal;
A phase changing unit for changing the phase of the optical signal;
The phase change amount of the phase change unit so that the electrical signal output from the photodetector and the electrical clock signal output from the oscillator are input and the phases of the electrical signal and the electrical clock signal match. And a control circuit for controlling.

The control circuit includes:
A clock recovery circuit for recovering a clock signal from an electrical signal output from the photodetector;
And a phase comparator that compares the phases of the clock signal regenerated by the clock regenerating circuit and the electrical clock signal and outputs an error signal to the phase changing unit.

The phase changing unit is
A phase shifter that shifts and outputs the phase of the electrical clock signal output from the oscillator to either the first optical modulator or the second optical modulator;
The control circuit includes:
A phase shifter control circuit for controlling a phase shift amount of the phase shifter is provided.

The phase changing unit is
An optical delay device that delays the optical signal output from the first optical modulator and outputs the optical signal to the second optical modulator;
The control circuit includes:
And a delay control circuit for controlling a delay amount of the optical delay device.

  The optical pulse generator further receives an electrical clock signal input to one of the first and second optical modulators as a clock signal, and a data signal that is synchronized with the clock signal by inputting the data signal. And a modulation signal generation circuit for outputting the signal as a modulation signal to one of the first and second optical modulators.

  The second modulator is a polarization scrambler.

An optical pulse generation method according to the present invention includes a step of outputting an optical signal having a predetermined wavelength,
An oscillation process for outputting an electrical clock signal of a predetermined frequency;
A first optical modulation step of modulating the intensity of the optical signal with an electrical clock signal and outputting the modulated signal;
A second light modulation step of intensity-modulating the optical signal output from the first light modulation step with an electrical clock signal and
One of the optical signal input to the second optical modulation step and the optical signal output from the second optical modulation step is input, a part of the optical signal is output, and a part is branched Optical demultiplexing process;
A light detection step of converting the optical signal demultiplexed by the light demultiplexing step into an electric signal;
A phase changing step for changing the phase of the optical signal;
The phase change amount of the phase change step is set so that the electrical signal output from the light detection step and the electrical clock signal output from the oscillator are input and the phases of the electrical signal and the electrical clock signal match. And a control step for controlling.

The control step includes
A clock recovery step of recovering a clock signal from the electrical signal output from the light detection step;
And a phase comparison step of comparing the phase of the clock signal regenerated in the clock recovery step with the electrical clock signal and outputting an error signal to the phase change step.

  The optical pulse position detection circuit and method therefor according to the present invention are configured as described above. The optical pulse train is input to the optical modulator, and the phase of the electrical clock signal for driving the optical modulator is determined by the optical modulator. The optical signal intensity output from the optical modulator is controlled to be maximized, and the phase shift amount when the optical signal intensity output from the optical modulator is maximized is output, so the position of the optical pulse is accurately detected. Can do.

  The optical pulse position detection circuit and method according to the present invention are configured as described above, and an optical pulse train is input to an optical modulator, and a dither signal is superimposed on the phase of an electrical clock signal that drives the optical modulator. Then, the dither signal component extracted from the optical signal output from the optical modulator and the dither signal superimposed on the phase of the electrical clock signal are synchronously detected, and the synchronous detection output is fed back to the phase shifter, thereby optical modulation. In order to control the phase shift amount of the phase shifter so that the light intensity output from the optical device becomes maximum, and to output the phase shift amount when the optical signal intensity output from the optical modulator becomes maximum, the optical pulse Can be detected with high accuracy.

  The optical pulse position detection circuit according to the present invention is configured as described above, and the optical pulse train is transmitted through the transmission line by changing the repetition cycle of the optical pulse train and calculating the relationship between the optical pulse train repetition cycle and the phase shift amount. Can be detected with a wide dynamic range.

  The optical pulse position detection circuit according to the present invention is configured as described above. Since the semiconductor electroabsorption optical modulator is used as the optical modulator, the pulse position can be detected with higher accuracy.

  The optical pulse generator and method according to the present invention are configured as described above, and the phase of the optical signal is changed so that the output of the photodetector is maximized. Therefore, the amount of phase change is always an optimum value. Feedback control is applied so that At this time, since the first optical modulator and the second optical modulator operate synchronously, an optical pulse with a short pulse width can be output.

  The optical pulse generator and method according to the present invention are configured as described above, and add a dither signal component to the phase change amount, and extract the dither signal component and dither signal extracted from the optical signal output from the optical modulator. Since the synchronous detection output is fed back and the synchronous detection output is fed back, the intensity of the optical signal output from the optical modulator is maximized.

The optical pulse generator according to the present invention is configured as described above, and the phase shifter control circuit receives the dither signal and the phase comparator output as inputs, and the second optical signal is output so that the output of the photodetector is maximized. Since the phase shifter that gives a phase shift to the signal for driving the modulator is controlled, feedback control is applied so that the phase shift amount always becomes an optimum value. At this time, since the first optical modulator and the second optical modulator operate synchronously, an optical pulse with a short pulse width can be output.
Further, when the operation is performed so as to compensate for the variation in the propagation delay time of the optical pulse signal input to the second optical modulator, the phase of the output optical pulse can be always constant.

The optical pulse generator according to the present invention is configured as described above, and the optical delay control circuit receives the dither signal and the phase comparator output as inputs, and the second output so that the output of the photodetector is maximized. Since the optical delay device that gives a delay to the optical signal input to the optical modulator is controlled, feedback control is applied so that the delay time always becomes an optimum value. At this time, since the first optical modulator and the second optical modulator operate synchronously, an optical pulse with a short pulse width can be output.
In addition, since the operation is performed so as to compensate for the variation in the propagation delay time of the optical pulse signal input to the second optical modulator, the phase of the output optical pulse can always be constant.

  The optical pulse generator according to the present invention is configured as described above, and the dither signal is superimposed on the phase of the signal for driving the first or second optical modulator, so that the output of the photodetector is maximized. In this manner, the optical delay device that gives a delay to the optical signal input to the second optical modulator is controlled. Since the dither signal is superimposed on the phase shifter, a device having a slow response can be used as the optical delay device.

  The optical pulse generator according to the present invention is configured as described above, and the optical signal reciprocates in the optical modulator, and the optical pulse input to the optical modulator and the driving signal of the optical modulator are synchronized. Therefore, an optical pulse with a short pulse width can be output. In the present invention, since only one optical modulator is required, the configuration can be simplified.

  The optical pulse generator according to the present invention is configured as described above, and can simultaneously shorten the optical signals output from the first light source and the second light source, so that an optical pulse having two wavelengths can be output. .

  The optical pulse generator according to the present invention is configured as described above, and feeds the phase shift amount of the phase shifter based on the output signal of the temperature drift detection circuit so as to compensate for the variation in the predicted delay time. Since forward control can be performed, an optical pulse with a short pulse width can be output with higher accuracy. It can also operate over a wide temperature range.

  The optical pulse generator according to the present invention is configured as described above, and feeds the phase shift amount of the phase shifter based on the output signal of the wavelength drift detection circuit so as to compensate for the variation in the predicted delay time. Since forward control can be performed, an optical pulse with a short pulse width can be output with higher accuracy.

  The optical pulse generator according to the present invention is configured as described above. Since the semiconductor electroabsorption optical modulator is used as the optical modulator, an optical pulse having a shorter pulse width can be output. .

  Since the optical pulse generator according to the present invention is configured as described above and processes optical signals in parallel, it can output a plurality of optical pulse trains.

  The optical pulse generator according to the present invention is configured as described above and serially processes an optical signal, so that a short pulse optical pulse train can be output.

  The optical pulse generation apparatus and method according to the present invention are configured as described above, and the recovered clock signal extracted from the optical signal input to the first or second optical modulator, and the first or second The phase is controlled so that the phase of the electrical clock signal for driving the optical modulator is the same. Thus, since the first optical modulator and the second optical modulator operate in synchronization with high accuracy, an optical pulse with a short pulse width can be output.

  The optical pulse generation apparatus and method according to the present invention are configured as described above, and the delay time variation is detected by comparing the phase of the recovered clock signal and the electrical clock signal, so that a highly accurate and simple structure can be used. A control circuit can be realized.

  The optical pulse generator according to the present invention is configured as described above, and the phase shifter control circuit receives the phase comparator output and controls the phase shifter that gives a phase shift to the signal that drives the optical modulator. The phase shift amount is always controlled so as to be an optimum value.

  The optical pulse generator according to the present invention is configured as described above, and the optical delay control circuit includes an optical delay device that receives the phase comparator output and delays the optical signal input to the optical modulator. Since the control is performed, the delay time is always controlled to be an optimum value.

  The optical pulse generator according to the present invention is configured as described above, and can output an optical pulse modulated by modulating an optical modulator with a data signal.

  The optical pulse generator according to the present invention is configured as described above, and can synchronize the phase of the electrical clock signal that drives the polarization scrambler with the data phase in a predetermined relationship. In addition, even if the amplitude variation occurs at the receiving terminal due to nonlinear refractive index change, the eye opening can be made larger so that it is advantageous for signal identification.

Embodiment 1 FIG.
FIG. 1 is a block diagram showing the configuration of an optical pulse position detection circuit according to an embodiment of the present invention.
In FIG. 1, 1 is an optical pulse train input terminal for inputting an optical pulse train in which an optical pulse is generated in a predetermined repetitive synchronization, 3 is an optical pulse train input, and modulates the intensity of light based on an electrical clock signal. An optical modulator that outputs an optical signal, 4 is a phase shifter that shifts the phase of the electrical clock signal, and 5 is an oscillator that generates an electrical clock signal having the same frequency as the repetition synchronization of the optical pulse train as a drive signal for the optical modulator, 8 is a photodetector that converts the light intensity of the optical signal into an electrical signal, 90 is a phase control circuit that outputs a control signal that controls the phase shift amount of the phase shifter 4, and 10 is a phase that outputs the phase shift amount of the phase shifter Shift amount output terminal.
As the optical modulator 3, an optical modulator capable of controlling the output light intensity by an electric signal such as a lithium niobate (LiNbO 3) Mach-Zehnder type optical modulator can be used. The phase shifter 4 is a device that can control the phase shift amount by an electric signal.
FIG. 2 shows an example of implementation of the phase shifter 4.
In FIG. 2, 13 is a phase shifter input terminal, 14 is a circulator, 15 is a phase shifter output terminal, and 16 is a varactor diode. Utilizing the fact that the capacitance of the varactor diode varies with voltage, the microwave reflection phase in the varactor diode is voltage controlled by a control signal output from the phase control circuit 90. There are many other types of phase shifters such as a phase shifter that switches the path length by digital control, an analog phase shifter that uses a balanced modulator, a phase shifter that switches the path length, or a motor that switches with a motor. Can be purchased from the market. In these phase shifters, since the control voltage indicates the phase shift amount of the phase shifter, the phase shift amount, that is, the pulse is monitored by monitoring the control voltage output from the phase control circuit 90 from the phase shift amount output terminal 10. The position can be detected. As the photodetector 8, a photodiode (PD) that converts an optical signal into an electrical signal can be used.

Next, the operation will be described with reference to FIG.
The pulse position obtained by the present invention is the phase relationship between the inputted optical pulse train and the reference electric clock signal which is the output of the oscillator 5. The optical pulse input from the optical pulse train input terminal 1 is input to the optical modulator 3. The optical modulator 3 is driven by an electrical clock signal output from the oscillator 5. The frequency of the electrical clock signal output from the oscillator 5 is equal to the repetition period of the optical pulse train input from the optical pulse train input terminal 1. The phase shifter 4 is controlled by the phase control circuit 90 so that the light intensity output from the optical modulator 3 is maximized. When the phase shifter is controlled so that the output of the optical modulator is maximized as shown in FIG. 3, the phase shift amount corresponds to the pulse position.
In FIG. 3, when the pulse positions of the three optical pulse trains are pulse 1, pulse 2, and pulse 3, the corresponding phase shift amounts are phase shift amount 1, phase shift amount 2, and phase shift amount 3. That is, no matter what optical pulse train is input, the phase of the electrical clock signal is automatically shifted by the phase shifter, and the optical intensity of the optical signal output from the optical modulator 3 is maximized. Become.

FIG. 4 shows an example of a method for controlling the phase shifter 4 so that the light intensity output from the optical modulator 3 is maximized.
The phase control circuit 90 controls the phase shift amount of the phase shifter while monitoring the output of the photodetector 8. When the phase is increased by ΔΦ (S2), if the output of the photodetector increases (YES in S3 and S4), the phase is further increased by ΔΦ (S8, S2). If the output of the photodetector does not increase even if the phase is increased by ΔΦ (NO in S3 and S4), the phase is once decreased by ΔΦ and restored (S5). Then, the phase is further decreased by ΔΦ (S6), and the output of the photodetector is increased. If the output of the photodetector increases by reducing the phase by ΔΦ, the operation is repeated to decrease the phase by ΔΦ, so that the light intensity output from the optical modulator 3 is maximized. The shifter 4 can be controlled.
FIG. 5 is a diagram showing a specific operation.
The phase of the electrical clock signal is shifted in the order of arrows 1, 2, 3, 4, 5, 6, and 7, and the pulse position and the target position A of the electrical clock signal coincide with each other. The algorithm shown in FIG. 4 detects the shift direction in which the light intensity increases by increasing / decreasing the phase by ΔΦ. Therefore, even if two phase shift amounts correspond to one light intensity, the pulse position and The target position A can be matched. The algorithm shown in FIG. 4 only needs to compare the intensity of the light intensity before and after the phase is increased or decreased by ΔΦ, so that it is not necessary to obtain the transmittance of the optical modulator. The phase control circuit 90 of this embodiment can be realized by using a simple logic circuit or a CPU and software. An algorithm other than the algorithm shown in FIG. 4 may be used.

  The detection result of the pulse position obtained by the present invention can be used, for example, when signal processing synchronized with the phase of the input optical pulse train is required. Examples of signal processing synchronized with the phase of the input pulse include signal modulation, time division multiplexing by optical processing, and time division separation by optical processing.

Embodiment 2. FIG.
FIG. 6 is a block diagram showing the configuration of an optical pulse position detection circuit according to an embodiment of the present invention.
In FIG. 6, 1 is an optical pulse train input terminal, 3 is an optical modulator, 4 is a phase shifter, 5 is an oscillator, 8 is a photodetector for converting an optical signal into an electrical signal, and 9 is a phase shift amount of the phase shifter 4. A phase shifter control circuit to be controlled, 10 is a phase shift amount output terminal for outputting the phase shift amount of the phase shifter, 11 is a dither signal generation circuit, 12 is a phase comparator for performing synchronous detection, and 90 is a phase control circuit. The phase shifter control circuit 9 includes an adder 20 and an amplifier 21. Both the adder 20 and the amplifier 21 can be easily realized by an operational amplifier. The phase comparator 12 includes a mixer 17, an amplifier 18, and a low-pass filter 19. The phase control circuit 90 includes a dither signal generation circuit 11, a phase comparator 12, and a phase shifter control circuit 9.
The dither signal generation circuit 11 outputs a dither signal D having a small amplitude f of about 1 kHz to 15 kHz and a small amplitude. The dither signal D that is an AC component is added to the error signal E that is a DC component output from the phase comparator 12 by the adder 20, and is applied to the phase shifter 4 as a control voltage V. The electric signal P and dither signal D output from the photodetector 8 are synchronously detected by the phase comparator 12. A feedback circuit is configured by inputting the output signal of the phase comparator 12 to the adder 20 as an error signal E.

The basic operation is the same as in FIG. The difference from FIG. 1 is that synchronous detection is performed in order to detect the phase shift amount that maximizes the light intensity of the optical signal output from the optical modulator. The operation principle will be described with reference to FIGS.
7 and 8 show the operation when the phase shift amount of the phase shifter 4 is a value that maximizes the output of the optical modulator. When the transmittance of the optical modulator 3 is as shown in FIG. 7B, the phase of the drive signal of the optical modulator is minutely modulated by the dither signal D having the frequency f shown in FIG. FIG. 7C shows a low frequency signal component of the optical signal output from the optical modulator. As shown in FIG. 8, (c) in FIG. 7 showing the output of the optical modulator is a low-frequency signal component of the frequency 2f, and the component of the frequency f does not exist, so that the output of the optical modulator 3 is shown. 7 (c) and FIG. 7 (a) showing the dither signal, the output of the synchronous detection by the phase comparator 12 becomes zero, and the error signal E from the phase comparator 12 becomes zero.

9 and 10 show the operation when the phase shift amount of the phase shifter is larger than the value that maximizes the output of the optical modulator.
When the transmittance of the optical modulator is as shown in FIG. 9B, the light when the phase of the drive signal of the optical modulator is minutely modulated by the dither signal D of the frequency f shown in FIG. The low frequency signal component output from the modulator is shown in FIG. As shown also in FIG. 10, since the phase of (c) of FIG. 9 which shows the output of an optical modulator and the phase of (a) of FIG. 9 which shows a dither signal are inverted, the output of synchronous detection becomes negative, The comparator 12 outputs a negative error signal E. The error signal E is a direct current component, and a phase shift amount (control voltage V) corresponding to the value of the error signal E is generated and output by the phase shifter control circuit 9. When a negative error signal E is output, the phase shift amount is decreased.

  11 and 12 show the operation when the phase shift amount of the phase shifter is smaller than the value that maximizes the output of the optical modulator. When the transmittance of the optical modulator is as shown in FIG. 11B, the light when the phase of the drive signal of the optical modulator is minutely modulated by the dither signal D of the frequency f shown in FIG. A low-frequency signal component output from the modulator is shown in FIG. As shown in FIG. 12, since the phase of (c) in FIG. 11 showing the output of the optical modulator and the phase of (a) in FIG. 11 showing the dither signal are in phase, the output of the synchronous detection becomes positive, and the phase comparison An error signal E having a positive value is output from the unit 12. When a positive error signal E is output, the phase shift is increased.

  The present invention has an advantage that a highly accurate feedback circuit can be realized with a relatively simple configuration since synchronous detection is used. Since synchronous detection is employed, the dither signal can be made extremely small and the sensitivity is high. Since the frequency of the dither signal used for the synchronous detection is independent of the repetition frequency of the input optical pulse train, it is possible to select a low frequency of about 1 kHz that is easy to process. Further, since the dither signal is an AC component, it does not constitute an error with respect to the control voltage V indicating the phase shift amount that is a DC component output from the phase shifter control circuit 9.

Embodiment 3 FIG.
FIG. 13 is a block diagram showing the configuration of an optical pulse position detection circuit according to an embodiment of the present invention.
The difference from FIG. 6 is that an optical pulse train generation light source 22, a transmission line optical fiber 23, a propagation time detection circuit 25, and a propagation time output terminal 52 are provided. The optical pulse train generation light source 22 is driven by the output of the oscillator 5 that generates an electrical clock signal. As the optical pulse train generation light source 22, a gain switching operation, a mode lock operation, a mode lock operation by an external resonance structure, etc. of a semiconductor laser can be used. It is assumed that the oscillator 5 can generate electrical clock signals having two or more frequencies. In the propagation time detection circuit 25, the frequency of the electrical clock signal of the oscillator 5 is changed, and the change in the output of the phase shift amount output terminal 10 at that time is memorized and calculated. Measure the pulse propagation time. The measured propagation time is output from the propagation time output terminal 52 to various sensors.

Next, the operation will be described.
The propagation time of the optical pulse of the optical fiber 23 for the transmission line is T (sec), and the frequency of the electrical clock signal of the oscillator 5 is f (Hz) (however, the frequency f is different from the frequency f of the dither signal D described above). If the relative pulse delay time calculated from the output of the phase shift amount output terminal 10 is t (sec),
T = N / f + t (1)
This relationship is established. Here, N is a natural number and represents the number of optical pulses simultaneously present in the optical fiber 23 for the transmission path. Differentiating equation (1) by f,
N = f ² · (dt / df) (2)
Is obtained. That is, the time T during which an optical pulse propagates through an optical fiber for a transmission line is
T = f ² · (dt / df) + t (3)
It becomes. Equation (3) shows that the frequency f (Hz) of the electrical clock signal of the oscillator 5, the relative pulse delay time t (sec) calculated from the output of the phase shift amount output terminal 10, and dt / df If it is known, it shows that the time T (sec) during which the optical pulse of the optical fiber 23 for transmission line propagates can be obtained. By measuring the amount of change dt of the pulse delay time t when the output clock frequency f of the oscillator 5 is changed by df, dt / df is calculated. In this way, the time T during which the optical pulse propagates through the transmission line optical fiber 23 can be measured by the expression (3) obtained by developing the expression (1). The propagation time detection circuit 25 changes the frequency of the electrical clock signal output from the oscillator 5 by df, inputs the change amount dt of the output of the phase shift amount output terminal 10 at that time, and outputs the light according to the equation (3). This is a circuit having a function of calculating a time T during which a pulse propagates. Alternatively, the propagation time detection circuit 25 can be easily realized by a computer.

  Since the speed at which the optical pulse propagates through the transmission line optical fiber 23 is generally known, measuring the time T during which the optical pulse propagates through the transmission line optical fiber is the length of the transmission line optical fiber 23. This corresponds to measuring the thickness W. The present invention measures the length W of the optical fiber 23 for the transmission path by measuring the time T during which the optical pulse propagates through the optical fiber for the transmission path. In addition, the present invention provides a method for measuring the length of a transmission line with high accuracy in an extremely wide dynamic range. The transmission path may be other than an optical fiber as long as an optical pulse propagates, and a waveguide, space, or the like can be used.

  In the present invention, since the length W of the transmission path can be measured with high accuracy, it can be applied to a sensor. For example, since the fiber length and refractive index of an optical fiber change depending on the environmental temperature, the environmental temperature at which the optical fiber is placed can be measured by measuring the time of propagation through the optical fiber. Similarly, it can be applied to measurement of pressure applied to an optical fiber. The present invention can also be applied to an optical pulse tester (OTDR: Optical Time Domain Reflectometer) that measures the propagation time of an optical pulse from a fault in a transmission path.

Embodiment 4 FIG.
FIG. 14 is a block diagram showing the configuration of an optical pulse position detection circuit according to an embodiment of the present invention.
The difference from FIG. 6 is that a semiconductor electroabsorption optical modulator 42 is used as the optical modulator. The semiconductor electroabsorption optical modulator 42 is a device whose light absorption coefficient changes depending on an applied voltage.

Next, the operation will be described.
The basic operation is the same as in FIG.
In the semiconductor electroabsorption optical modulator 42, as shown in FIG. 15, the transmittance of the optical modulator greatly decreases as the applied voltage increases. In general, the transmittance expressed as a logarithm is proportional to the applied voltage. For this reason, as shown in FIG. 15, the semiconductor electroabsorption optical modulator driven by a sine wave electric clock signal becomes a pulsed steep gate.
FIG. 16 is a rewrite of the principle of operation shown in FIG. 3 to explain the operation when a semiconductor electroabsorption optical modulator is used.
Since the transmittance of the optical modulator becomes a steep gate, if the phase shift amount of the phase shifter slightly changes by ΔΦ, the light intensity transmitted through the optical modulator changes greatly by ΔP. For this reason, it is possible to detect with high sensitivity the amount of phase shift that maximizes the intensity of light passing through the optical modulator.

Embodiment 5 FIG.
FIG. 17 is a block diagram showing the configuration of an optical pulse generator according to an embodiment of the present invention.
In FIG. 17, 26 is a light source that oscillates an optical signal having a predetermined wavelength, 3a is a first optical modulator, 29 is an optical amplifier, 3b is a second optical modulator, 2 is an optical demultiplexer, and 27 is an optical pulse. The output terminal, 5 is an oscillator, 4 is a phase shifter which is an example of a phase changing unit of the present invention, 8 is a photodetector, 12 is a phase comparator, 9 is a phase shifter control circuit, 11 is a dither signal generation circuit, 90 is It is a phase control circuit which is an example of the control circuit of this invention. The phase shifter control circuit 9 includes an adder 20 and an amplifier 21. Both the adder 20 and the amplifier 21 can be easily realized by an operational amplifier. The phase comparator 12 includes a mixer 17, an amplifier 18, and a low-pass filter 19. The phase control circuit 90 includes a phase shifter control circuit 9, a dither signal generation circuit 11, and a phase comparator 12.
The dither signal generation circuit 11 outputs a dither signal D having a small amplitude f of about 1 kHz to 15 kHz and a small amplitude. The dither signal D is added to the error signal E output from the phase comparator 12 by the adder 20 and applied to the phase shifter 4. The electric signal P and dither signal D output from the photodetector 8 are synchronously detected by the phase comparator 12. By inputting the output signal of the phase comparator 12 as an error signal E to the adder 20, a feedback circuit is configured.

  As the light source 26, a semiconductor laser diode, a fiber laser, a solid laser, or the like can be used. As the optical modulators 3a and 3b, those capable of controlling the light intensity by an electric signal, such as a lithium niobate (LiNbO3) Mach-Zehnder type optical modulator, can be used. The phase shifter 4 is a device that can control the amount of phase shift by an electric signal, and many types of devices can be purchased from the market as described in the first embodiment. As the optical amplifier 29, a fiber amplifier using a fiber doped with rare earth, a semiconductor optical amplifier using a semiconductor, an optical amplifier using a nonlinear effect such as a Raman effect, or the like can be used.

The optical signal output from the light source 26 is intensity-modulated by the electrical clock signal output from the oscillator 5 by the optical modulator 3 a to become an optical pulse signal, and then the power level is amplified by the optical amplifier 29. The optical pulse signal output from the optical amplifier 29 is intensity-modulated again by the optical modulator 3b. At this time, since the optical modulator 3b is controlled by the phase shifter 4 so as to perform a modulation operation in synchronization with the input optical pulse signal, the optical pulse output from the optical modulator 3b is the optical modulator 3b. The pulse width is shorter than the optical pulse input to (W1> W2). The phase shifter control circuit 9 receives the dither signal and the output of the phase comparator 12 as inputs, and controls the phase shifter 4 so that the output of the photodetector 8 is maximized. This operation will be described with reference to FIG. 18, FIG. 19, and FIG.
FIG. 18 shows a state when the phase shift amount of the phase shifter is optimum. At this time, as shown in FIG. 18B, the phase shift amount is set so that the transmittance of the optical modulator 3b is maximized. As shown in FIG. 18A, the phase shift amount of the phase shifter 4 is minutely modulated with a dither signal of frequency f, and is output from the optical modulator 3b when the dither signal is superimposed on the drive signal of the optical modulator 3b. The low frequency signal component of the optical signal is shown in FIG. The low-frequency signal component output from the optical modulator 3b is a low-frequency signal component having the frequency 2f, and there is no frequency f component in the diagram showing the signal. Therefore, the output signal of the optical modulator 3b shown in FIG. The synchronous detection output of (c) and (a) of FIG. 18 showing the dither signal is zero, and the error signal is zero.

FIG. 19 shows the operation when the phase shift amount of the phase shifter is larger than the optimum value.
At this time, the transmittance of the optical modulator 3b is as shown in FIG. FIG. 19C shows a low-frequency signal component output from the optical modulator when the drive signal of the optical modulator 3b is minutely modulated with the dither signal having the frequency f shown in FIG. Since the phase of FIG. 19C showing the output signal of the optical modulator 3b and the phase of FIG. 19A showing the dither signal are inverted, the synchronous detection output becomes negative and an error signal having a negative value is output. Is done.

FIG. 20 shows the operation when the phase shift amount of the phase shifter is smaller than the optimum value.
At this time, the transmittance of the optical modulator 3b is as shown in FIG. FIG. 20C shows a low-frequency signal component output from the optical modulator when the drive signal of the optical modulator 3b is minutely modulated with the dither signal having the frequency f shown in FIG. Since the phase of FIG. 20 (c) showing the output signal of the optical modulator 3b and the phase of FIG. 20 (a) showing the dither signal match, the synchronous detection output becomes positive, and a positive error signal is output. Is done.

In this way, feedback control is applied so that the phase shift amount is always the optimum value. Therefore, even if there is a variation in the propagation delay time of the optical signal in the optical amplifier 29 or the transmission path, the two optical modulators 3a, 3a, The drive signal 3b is always synchronized with the optical signal. Since the two optical modulators operate in synchronization, a short pulse is output from the optical pulse output terminal 27.
Since synchronous detection is used, the present invention has an advantage that a highly accurate feedback circuit can be realized with a relatively simple configuration. Since the frequency of the dither signal used for the synchronous detection is independent of the input optical pulse train repetition frequency, a low frequency of about 1 kHz to 15 kHz that can be easily processed can be selected. Further, since the dither signal is an alternating current component with a minute amplitude, it does not constitute an error with respect to the phase shift amount that is a direct current component.

  The use of an RF amplifier to amplify the electrical clock signal that drives the optical modulators 3a and 3b does not interfere with the application of the present invention. It is also possible to multiply the electrical clock signal that drives the optical modulator 3a or 3b. Further, even if the optical amplifier 29 is not present, there is a propagation delay of the optical signal through the transmission path between the optical modulator 3a and the optical modulator 3b, which does not hinder the application of the present invention. Further, the phase control circuit 90 may be configured using an algorithm as shown in FIG. 4 of the first embodiment.

Embodiment 6 FIG.
FIG. 21 is a block diagram showing the configuration of an optical pulse generator according to an embodiment of the present invention.
The difference from FIG. 17 is that the output signal of the optical modulator 3a is branched into two by the optical demultiplexer 2a. 3a is a first optical modulator, 29a is a first optical amplifier, 3b is a second optical modulator, 2b is a second optical demultiplexer, 27a is a first optical pulse output terminal, 5 is an oscillator, 4a is a phase shifter, 8a is a photodetector, 12a is a phase comparator, 9a is a phase shifter control circuit, 11 is a dither signal generation circuit, 90a is a first phase control circuit, and 90b is a second phase control circuit. . The phase shifter control circuit 9a includes an adder 20a and an amplifier 21a. The phase comparator 12a includes a mixer 17a, an amplifier 18a, and a low-pass filter 19a. 29b is a second optical amplifier, 3c is a third optical modulator, 2c is a third optical demultiplexer, 27b is a second optical pulse output terminal, 4b is a second phase shifter, and 8b is a photodetector. , 12b are phase comparators, and 9b is a phase shifter control circuit. The phase shifter control circuit 9b includes an adder 20b and an amplifier 21b. The phase comparator 12b includes a mixer 17b, an amplifier 18b, and a low-pass filter 19b.
The dither signal generation circuit 11 outputs a dither signal having a low frequency and a small amplitude.
The optical signal demultiplexed by the optical demultiplexer 2a and inputted to the optical amplifier 29a is shortened by the same principle as in the fifth embodiment and outputted from the optical pulse output terminal 27a. Similarly, the optical signal demultiplexed by the optical demultiplexer 2a and input to the optical amplifier 29b is shortened and output from the optical pulse output terminal 27b. In this embodiment, it is possible to provide two optical pulse output terminals 27a and 27b by branching an optical signal and processing it in parallel. In this embodiment, the first and second phase control circuits 90a and 90b receive the dither signal from one dither signal generation circuit 11, but the characteristics of the first and second optical amplifiers 29a and 29b are the same. If they are different or have different transmission path lengths, the dither signal generation circuit 11 may be provided individually for the first and second phase control circuits 90a and 90b.

  It is apparent from the present embodiment that the number of branches of the optical demultiplexer 2a can be increased and the number of optical pulse output terminals can be increased as necessary.

Embodiment 7 FIG.
FIG. 22 is a block diagram showing the configuration of an optical pulse generator according to an embodiment of the present invention.
In FIG. 22, 26 is a light source, 3a is a first optical modulator, 29a is a first optical amplifier, 3b is a second optical modulator, 2a is a first optical demultiplexer, and 29b is a second light. An amplifier, 3c is a third optical modulator, 2b is a second optical demultiplexer, and 27 is an optical pulse output terminal. 5 is an oscillator, 4a is a phase shifter, 8a is a photodetector, 12a is a phase comparator, 9a is a phase shifter control circuit, 11a is a dither signal generation circuit, 90a is a first phase control circuit, and 90b is a second phase. It is a control circuit. The phase shifter control circuit 9a includes an adder 20a and an amplifier 21a. The phase comparator 12a includes a mixer 17a, an amplifier 18a, and a low-pass filter 19a. 4b is a second phase shifter, 8b is a photodetector, 12b is a phase comparator, 9b is a phase shifter control circuit, and 11b is a dither signal generation circuit. The phase shifter control circuit 9b includes an adder 20b and an amplifier 21b. The phase comparator 12b includes a mixer 17b, an amplifier 18b, and a low-pass filter 19b.
The difference from FIG. 17 is that a third optical modulator 3c is provided to process the optical signal serially, and the optical detector is used to optimize the phase of the electrical clock signal that drives the optical modulator 3c. 8b, a dither signal generation circuit 11b, a phase comparator 12b, a phase shifter control circuit 9b, and a phase shifter 4b are used.

  The operating principle is the same as in the fifth embodiment, but since three optical modulators connected in series are driven synchronously, an optical pulse signal having a shorter pulse width than that of the optical pulse generator of FIG. Can be output. In FIG. 22, since the phase shifter 4a and the phase shifter 4b need to be controlled independently, the dither signal generation circuit 11a and the dither signal generation circuit 11b used for feedback control output dither signals having different frequencies. For example, the frequency of the dither signal output from the dither signal generation circuit 11a can be 10 kHz, and the frequency of the dither signal output from the dither signal generation circuit 11b can be 15 kHz.

  In the configuration shown in FIG. 22, the fourth and fifth optical modulators are further connected in cascade, and the same feedback control is performed, so that an optical pulse signal with a shorter pulse width can be output.

Embodiment 8 FIG.
FIG. 23 is a block diagram showing the configuration of an optical pulse generator according to an embodiment of the present invention.
23 is different from FIG. 17 in that the phase shifter 4 controls the phase of the electrical clock signal that drives the optical modulator 3a. In order to control the phase of the optical pulse signal output from the optical modulator 3a so as to compensate for the variation in the propagation delay time of the optical signal generated in the optical amplifier 29, the phase of the optical pulse input to the optical modulator 3b, The phase of the optical pulse output from the optical pulse output terminal 27 does not change. Therefore, as in FIG. 17, not only can an optical pulse signal with a short pulse width be generated, but also the phase of the optical pulse output from the optical pulse output terminal 27 can be made constant.

Embodiment 9 FIG.
FIG. 24 is a block diagram showing the configuration of an optical pulse generator according to an embodiment of the present invention.
In FIG. 24, reference numeral 24 denotes an optical delay device that is an example of the phase changing unit of the present invention, 34 is an optical delay device control circuit, and 91 is a delay control circuit that is an example of the control circuit of the present invention. The optical delay device control circuit 34 includes an adder 20 and an amplifier 21. Both the adder 20 and the amplifier 21 can be easily realized by an operational amplifier. The delay control circuit 91 includes the dither signal generation circuit 11, the phase comparator 12, and the optical delay device control circuit 34. The delay control circuit 91 may be configured using an algorithm as shown in FIG.

  The optical delay device 24 is a device that can control the propagation delay time of an optical signal by a control signal output from the optical delay device control circuit 34. The optical delay device 24 is a device that changes the optical propagation path length by a step motor, a device that controls the propagation delay time by applying stress to the optical fiber by a piezo element, and makes the delay time variable by switching different paths with a switch. Devices etc. can be used.

  The basic operation is the same as in FIG. 17, and feedback control is applied so that the optical delay amount of the optical delay device 24 always becomes the optimum value. Therefore, the optical amplifier 29 has a fluctuation in the propagation delay time of the optical signal. Even so, the drive signals of the two optical modulators 3a and 3b are always synchronized with the optical signal. Since the two optical modulators operate in synchronization, a short pulse is output from the optical pulse output terminal 27. In order to control the phase of the optical pulse signal output from the optical modulator 3a so as to compensate for the variation in the propagation delay time of the optical signal generated in the optical amplifier 29, the phase of the optical pulse input to the optical modulator 3b, The phase of the optical pulse output from the optical pulse output terminal 27 does not change. For this reason, the phase of the optical pulse output from the optical pulse output terminal 27 can be made constant.

Embodiment 10 FIG.
FIG. 25 is a block diagram showing the configuration of an optical pulse generator according to an embodiment of the present invention.
In FIG. 25, 91a is a delay control circuit which is an example of the control circuit of the present invention. The phase changing unit of the present invention includes the phase shifter 4 and the optical delay device 24. The optical delay device control circuit 34 is configured by the amplifier 21.

  The difference from FIG. 24 is that the dither signal is superimposed on the phase shift amount of the phase shifter 4. Since the signal detected by the photodetector 8 is the same in the case of FIG. 24 in which the dither signal is superimposed on the optical delay device 24 and in the case of FIG. 25 in which the dither signal is superimposed on the phase shifter 4, the operation is the same. However, it is generally easier to superimpose the dither signal on the phase shifter than to superimpose the dither signal on the optical delay device 24. Many realized optical delay devices include a movable part with a relatively low response frequency, such as a step motor and a piezo element, and therefore respond to a dither signal having a low-frequency AC component. This is because often occurs. In the present embodiment, the low-frequency dither signal is not input to the optical delay device 24, and the DC component control signal generated from the error signal E is input to the optical delay device 24. Devices with slow response can be used.

Embodiment 11 FIG.
FIG. 26 is a block diagram showing the configuration of an optical pulse generator according to an embodiment of the present invention.
In this embodiment, a case where the first and second optical modulators described above are replaced with one optical modulator will be described.
In FIG. 26, 35a is a first polarization multiplexer / demultiplexer, 35b is a second polarization multiplexer / demultiplexer, and 45 is a polarization state converter.

The polarization state of the optical signal output from the light source 26 is adjusted to a predetermined polarization state (P wave). The optical signal output from the light source 26 is intensity-modulated by an electrical clock signal output from the oscillator 5 by the optical modulator 3 to become an optical pulse signal, and then the power level is amplified by the optical amplifier 29. The polarization multiplexers / demultiplexers 35a and 35b are devices that output different ports depending on the polarization state (P wave or S wave) of the input optical signal, and are commercially available as polarization beam splitters and polarization prisms. Since the polarization state of the optical signal output from the light source 26 is adjusted to a predetermined polarization state (P wave), the polarization multiplexer / demultiplexer 35 a sends the optical signal output from the light source to the optical modulator 3. Output. The optical signal output from the optical modulator 3 is output to the optical delay device 24 by the polarization multiplexer / demultiplexer 35b. The optical signal given a predetermined delay by the optical delay device 24 is amplified in power level by the optical amplifier 29 and input to the polarization state converter 45. The polarization of the optical signal is orthogonalized by the polarization state converter 45 (P wave → S wave) and input to the polarization multiplexer / demultiplexer 35b. This optical signal is output to the optical modulator 3 again. The optical pulse modulated again by the optical modulator 3 is output to the optical demultiplexer 2 by the polarization multiplexer / demultiplexer 35a. At this time, the optical pulse is not output to the light source 26 because the polarization state (S wave) is orthogonal to the polarization state (P wave) when it is output from the light source 26.
In this way, the optical signal reciprocates through the optical modulator 3 and is intensity-modulated twice. By controlling the optical delay device 24, the optical modulator 3 performs a modulation operation in synchronization with the input optical pulse signal, so that a pulse width having a short pulse width is output from the optical pulse output terminal 27. The control principle of the optical delay device is the same as in FIG.

  It is possible to replace the polarization multiplexers / demultiplexers 35a and 35b with optical multiplexers / demultiplexers. As the optical multiplexer / demultiplexer, an inexpensive device such as an optical coupler can be used. However, since optical couplers have a combining loss and a branching loss in principle, it is not preferable from the viewpoint of an optical S / N ratio (Optical Signal Noise Ratio).

Embodiment 12 FIG.
FIG. 27 is a block diagram showing the configuration of an optical pulse generator according to an embodiment of the present invention.
In FIG. 27, 26a is a first light source, 26b is a second light source, 3a is a first optical modulator, 3b is a second optical modulator, 33 is an optical multiplexer, 29 is an optical amplifier, and 3c is a first optical modulator. 3 is an optical modulator, 4a is a first phase shifter, and 4b is a second phase shifter.

The difference from FIG. 23 is that two light sources that output optical signals having different wavelengths are provided, and two short-wavelength pulses having different wavelengths can be output from the optical pulse output terminal. The optical signal output from the first light source is shortened by the first optical modulator 3a and the third optical modulator 3c. The optical signal output from the second light source 26b is shortened by the second optical modulator 3b and the third optical modulator 3c. The phase of the electrical clock signal that drives the optical modulator 3a is controlled by the first phase shifter 4a. The drive signal to the first phase shifter 4a is output by the first phase shifter control circuit 9a. The first dither signal generation circuit 11a outputs a dither signal having a low frequency and a small amplitude, and the dither signal is applied to the phase shifter 4a by the adder 20a. The electrical signal and dither signal output from the photodetector 8 are synchronously detected by the phase comparator 12a. A feedback circuit is configured by inputting the output signal of the phase comparator 12a as an error signal to the adder 20a.
Similarly, the phase of the electrical clock signal that drives the optical modulator 3b is controlled by the second phase shifter 4b. The drive signal to the second phase shifter 4b is output by the second phase shifter control circuit 9b. The second dither signal generation circuit 11b outputs a dither signal having a low frequency and a small amplitude, and the dither signal is applied to the phase shifter 4b by the adder 20b. The electric signal and dither signal output from the photodetector 8 are synchronously detected by the phase comparator 12b. A feedback circuit is configured by inputting the output signal of the phase comparator 12b to the adder 20b as an error signal. Here, the first dither signal generation circuit 11a and the second dither signal generation circuit 11b output dither signals having different frequencies. For example, the frequency of the dither signal output from the first dither signal generation circuit 11a can be 10 kHz, and the frequency of the dither signal output from the second dither signal generation circuit 11b can be 15 kHz.

  In addition, the third and fourth light sources are connected in parallel to the configuration shown in FIG. 27 and the same feedback control is performed, so that short pulses of three wavelengths and four wavelengths can be output.

Embodiment 13 FIG.
FIG. 28 is a block diagram showing the configuration of an optical pulse generator according to an embodiment of the present invention.
In FIG. 28, 92 is a delay control circuit. The phase shifter control circuit 9 includes adders 20a and 20b and an amplifier 21a. Reference numeral 41 is a temperature detection circuit, 37 is a reference voltage generator, 40 is a temperature drift detection circuit, 39 is a subtractor, and 21b is an amplifier.

  The difference from FIG. 17 is that a temperature detection circuit 41, a reference voltage generator 37, and a temperature drift detection circuit 40 are provided, and feedforward control is added. The temperature detection circuit 41 detects the temperature inside the apparatus, for example, the temperature of the optical amplifier 29. The temperature detection circuit 41 can use a thermistor element whose resistance value changes depending on the temperature, a temperature detection semiconductor element, or the like. The temperature change of the optical amplifier 29 can be detected by calculating the difference between the output signal of the temperature detection circuit 41 and the reference voltage output from the reference voltage generator. Variations in the delay time of the optical pulse input to the optical modulator 3 b are mainly caused by variations in the propagation delay time of the optical amplifier 29. Since the propagation delay time of the optical amplifier 29 is generated by the temperature change of the optical amplifier, it is possible to predict the fluctuation of the delay time of the optical pulse input to the optical modulator 3b by detecting the temperature change of the optical amplifier. is there. By inputting the output signal of the temperature drift detection circuit 40 to the adder 20b, the amount of phase shift generated in the phase shifter 4 can be feedforward controlled so as to compensate for the variation in the predicted delay time.

  By adding the feedforward control, it is possible to reduce the error that the feedback circuit should compensate, and thus it is possible to realize a more accurate process. Even if an extremely large error occurs and the feedback circuit pulls out of the range, the feedforward control can reduce the error to within the feedback control pull-in range, thereby realizing a wide dynamic range. . For this reason, the operating temperature range of the optical pulse generator can be expanded.

Embodiment 14 FIG.
FIG. 29 is a block diagram showing the configuration of an optical pulse generator according to an embodiment of the present invention.
In FIG. 29, 36 is a wavelength detection circuit, 37 is a reference voltage generator, 38 is a wavelength drift detection circuit, 39 is a subtractor, and 21b is an amplifier.

  The difference from FIG. 17 is that a wavelength detection circuit 36, a reference voltage generator 37, and a wavelength drift detection circuit 38 are provided, and feedforward control is added. The wavelength detection circuit 36 can use the output of the temperature control circuit of the light source 26 or a wavelength meter. By calculating the difference between the output signal of the wavelength detection circuit 36 and the reference voltage output from the reference voltage generator 37 by the subtractor 39, the wavelength change of the optical signal output from the light source 26 can be detected. Variation in the delay time of the optical pulse input to the optical modulator 3 b is mainly caused by variation in the propagation delay time of the optical amplifier 29. Since the propagation delay time of the optical amplifier 29 is generated by the change in the wavelength of the optical signal, the change in the delay time of the optical pulse input to the optical modulator 3b is detected by detecting the change in the wavelength of the optical signal input to the optical amplifier. Can be predicted. By inputting the output signal of the wavelength drift detection circuit 38 to the adder 20b, the amount of phase shift generated in the phase shifter 4 can be feedforward controlled so as to compensate for the variation in the predicted delay time.

  By adding the feedforward control, it is possible to reduce the error that the feedback circuit should compensate, and thus it is possible to realize a more accurate process. Even if an extremely large error occurs and the feedback circuit pulls out of the range, the feedforward control can reduce the error to within the feedback control pull-in range, thereby realizing a wide dynamic range. .

  Combining the feedforward control using the temperature drift detection circuit shown in FIG. 28 and the feedforward control using the wavelength drift detection circuit shown in FIG. 29 further improves the control accuracy. Further, the feedforward control using the temperature drift detection circuit shown in FIG. 28 and the feedforward control using the wavelength drift detection circuit shown in FIG. 29 can be used in combination with other embodiments of the present invention. is there.

Embodiment 15 FIG.
FIG. 30 is a block diagram showing the configuration of an optical pulse generator according to an embodiment of the present invention.
The difference from FIG. 17 is that the optical modulators 3a and 3b in FIG. 17 are replaced with semiconductor electroabsorption optical modulators 42a and 42b.

  As described with reference to FIG. 11, since the semiconductor electroabsorption optical modulator can realize a steep gate, it can output an optical pulse with a shorter pulse width. When the phase shift amount of the phase shifter slightly changes, the intensity of light transmitted through the optical modulator changes greatly, so that the optimum phase shift amount can be detected with high sensitivity. Since the semiconductor electroabsorption optical modulator provides a steep gate, the light intensity output from the semiconductor absorption optical modulator 42b decreases when the phase shift amount deviates greatly from the optimum value, resulting in an error. The signal may not be detected. In such a case, it is desirable to use the feedforward control using the temperature drift detection circuit shown in FIG. 28 or the feedforward control using the wavelength drift detection circuit shown in FIG.

Embodiment 16 FIG.
FIG. 31 is a block diagram showing the configuration of an optical pulse generator according to an embodiment of the present invention.
In FIG. 31, 26 is a light source that oscillates an optical signal of a predetermined wavelength, 3a is a first optical modulator, 29 is an optical amplifier, 3b is a second optical modulator, 2 is an optical demultiplexer, and 27 is an optical pulse. An output terminal, 5 is an oscillator that outputs an electrical clock signal of a predetermined frequency, 4 is a phase shifter that is an example of a phase changing unit of the present invention, 8 is a photodetector, 92 is a clock recovery circuit, 12 is a phase comparator, 9 is a phase shifter control circuit, 28a is a first RF (Radio Frequency) amplifier which is an example of a first modulation signal generation circuit of the present invention, and 28b is an example of a second modulation signal generation circuit of the present invention. 2 RF amplifiers. Reference numeral 99 denotes a phase control circuit which is an example of the control circuit of the present invention. The phase control circuit 99 inputs the electrical signal output from the photodetector 8 and the electrical clock signal output from the oscillator 5 so that the phases of the electrical signal and the electrical clock signal match. The phase change amount of the phase shifter 4 is controlled.
The clock recovery circuit 92 includes, for example, limiter amplifiers 93a and 93b and a bandpass filter 94. The phase shifter control circuit 9 includes an amplifier 21. The amplifier 21 can be easily realized by an operational amplifier. The phase comparator 12 includes a mixer 17, an amplifier 18, and a low-pass filter 19. The phase control circuit 99 includes a clock recovery circuit 92, a phase comparator 12, and a phase shifter control circuit 9.

  As the light source 26, a semiconductor laser diode, a fiber laser, a solid laser, or the like can be used. As the optical modulators 3a and 3b, those capable of controlling the light intensity by an electrical signal, such as a lithium niobate (LiNbO3) Mach-Zehnder optical modulator, a semiconductor electroabsorption optical modulator, and the like are used. Can do. The phase shifter 4 is a device that can control the amount of phase shift by an electric signal. As described in the first embodiment, many types of devices can be purchased from the market. As the optical amplifier 29, a fiber amplifier using a fiber doped with rare earth, a semiconductor optical amplifier using a semiconductor, an optical amplifier using a nonlinear effect such as a Raman effect, or the like can be used.

  The optical signal output from the light source 26 is intensity-modulated by the electrical clock signal output from the oscillator 5 by the optical modulator 3 a to become an optical pulse signal, and then the power level is amplified by the optical amplifier 29. The optical pulse signal output from the optical amplifier 29 is intensity-modulated again by the optical modulator 3b. At this time, since the optical modulator 3a is controlled by the phase shifter 4 via the phase control circuit 99 so as to perform a modulation operation in synchronization with the optical pulse signal input to the optical modulator 3b, the optical modulator 3b The pulse width of the optical pulse output from is shorter than that of the optical pulse input to the optical modulator 3b. This operation and effect are the same as in the fifth embodiment. The clock recovery circuit 92 receives the electrical signal output from the photodetector 8 and outputs a recovered clock signal. The phase comparator 12 receives the recovered clock signal output from the clock recovery circuit 92 and the electrical clock signal output from the oscillator 5, compares the phase of the recovered clock signal with the phase of the electrical clock signal, and generates an error. The phase shifter 4 is controlled so that becomes zero. This operation will be described with reference to FIGS. 32, 33, and 34. FIG.

FIG. 32 shows the operation when the phase shift amount of the phase shifter is larger than the optimum value.
The output signal of the photodetector 8 is as shown in FIG. The clock recovery circuit 92 extracts a recovered clock signal from the signal of the photodetector 8 as shown in FIG. The recovered clock signal output from the clock recovery circuit and the electrical clock signal input to the second modulation signal generation circuit (in this case, the RF amplifier 28b) shown in FIG. When input to, the output signal of the mixer 17 is as shown in FIG. When this signal is input to the low-pass filter 19, a positive error signal is output, and the phase shift amount of the phase shifter is reduced. That is, the phase of the electrical clock signal shown in (c) of FIG. 32 is shifted in the direction of the optimum pulse position (leftward in the figure).

FIG. 33 shows the operation when the phase shift amount of the phase shifter is smaller than the optimum value.
The output signal of the photodetector 8 is as shown in FIG. The clock recovery circuit 92 extracts the recovered clock signal from the signal of the photodetector 8 as shown in FIG. The reproduced clock signal output from the clock recovery circuit and the electrical clock signal input to the second modulation signal generation circuit (in this case, the RF amplifier 28b) shown in FIG. The output signal of the mixer 17 is as shown in FIG. When this signal is input to the low-pass filter 19, a negative error signal is output, and the phase shift amount of the phase shifter increases. That is, the phase of the electrical clock signal shown in (c) of FIG. 33 is shifted in the direction of the optimum pulse position (rightward in the figure).

  FIG. 34 shows a state when the phase shift amount of the phase shifter is optimum. The output signal of the photodetector 8 is as shown in FIG. The clock recovery circuit 92 extracts the recovered clock signal from the signal of the photodetector 8 as shown in FIG. The recovered clock signal output from the clock recovery circuit and the electrical clock signal input to the second modulation signal generation circuit (in this case, the RF amplifier 28b) shown in FIG. The output signal of the mixer 17 is as shown in (d) of FIG. When this signal is input to the low-pass filter 19, the output error signal becomes zero. That is, the phase of the electrical clock signal does not change.

In this way, since the phase shift amount is controlled so as to be always a constant value, the two optical modulators 3a and 3b can be used even if the propagation delay time of the optical signal varies in the optical amplifier 29 or the transmission path. The phase of the drive signal is always kept constant. The propagation delay time from the optical demultiplexer 2 to the second optical modulator 3b, the propagation delay time from the optical demultiplexer 2 to the mixer 17, the propagation delay time from the oscillator 5 to the mixer 17, and the oscillator The propagation delay time from 5 to the first optical modulator 3a is different from the propagation delay time from the oscillator 5 to the second optical modulator 3a. For this reason, even if the mixer 17 controls the error to be zero, the optical modulator 3a is not always synchronized. Therefore, as shown in FIG. 35, an adder that applies an appropriate offset voltage V to the output of the phase shifter control circuit 9 so that the phases of the modulation signals that drive the optical modulator 3a and the optical modulator 3b completely coincide with each other. By adding 100, the phase relationship may be adjusted. Since the two optical modulators operate in complete synchronization, a short pulse is output from the optical pulse output terminal 27.
Since the present invention uses synchronous detection, there is an advantage that a highly accurate control circuit can be realized with a relatively simple configuration. In addition, the present invention has an advantage of not requiring dither signal superimposition.

Since the present invention is not controlled to maximize the output as described in the fifth embodiment, there is an advantage that does not depend on the output waveforms of the optical modulators 3a and 3b. Therefore, in the sixteenth embodiment, RF amplifiers are used as the first modulation signal generation circuit and the second modulation signal generation circuit, but as the modulation signal generation circuit, a frequency multiplier, a waveform shaper, or a modulation is used. A vessel or the like can be used.
Even if the optical amplifier 29 is not present, there is a propagation delay of an optical signal through a certain transmission path between the optical modulator 3a and the optical modulator 3b, and thus does not hinder the application of the present invention.
Further, when the oscillator 5 generates an electric clock signal having sufficient power, the first modulation signal generation circuit and the second modulation signal generation circuit are not necessary.
Also, as shown in FIG. 36, the use of the phase shifter 4 as the input of the second modulation signal generation circuit does not hinder the application of the present invention.
The configuration shown in FIG. 36 can be regarded as a kind of feedforward circuit because it does not detect a change generated in the controlled object (here, the phase shifter 4) and feed back to the controlled object. The inventor has confirmed through experiments that the object of the invention can be sufficiently achieved even with such a feedforward circuit.
As shown in FIG. 37 or FIG. 38, the optical demultiplexer 2 may be on the output side instead of the input side of the optical modulator 3b. Also in FIG. 17 described in the fifth embodiment, the optical demultiplexer 2 may be on the output side instead of the input side of the optical modulator 3b.

Embodiment 17. FIG.
FIG. 39 is a block diagram showing the configuration of a pulse generator according to one embodiment of the present invention.
The discriminator 97 can be realized by, for example, a D-type flip-flop. The D type flip-flop delays the data input from the data input D by the clock signal input from the clock input C and outputs it to the output Q. That is, data input from the data signal input terminal 98 is output to the optical modulator 3b in synchronization with the clock signal. That is, the optical signal input to the optical modulator 3b can be synchronized with the modulation signal that drives the optical modulator 3b. Other operating principles are the same as those in FIG.
In the case shown in FIG. 39, a signal in RZ (Return to Zero) format is modulated with a signal in NRZ (Non Return to Zero) format.
Note that the phase relationship between the modulation signals that drive the optical modulator 3a and the optical modulator 3b is such that an adder 100 that applies an appropriate offset voltage V to the output of the phase shifter control circuit 9 is added, as shown in FIG. Can be adjusted. The phase relationship between the two is kept constant by adjusting the offset voltage V even if the amount of phase fluctuation generated by the optical amplifier 29 or other transmission line or circuit changes.
In this embodiment, since the optical pulse generated by the optical modulator 3a is modulated by the data signal input from the data signal input terminal 98, an optical pulse generator that generates a modulated pulse can be provided. As the modulation method, an intensity modulation method, a phase modulation method, a frequency modulation method, a polarization plane modulation method, or the like can be used.
It should be noted that the discriminator 97 shown in FIG. 39 may be used in the configuration shown in FIGS.

Embodiment 18 FIG.
FIG. 40 is a block diagram showing the configuration of a pulse generator according to one embodiment of the present invention.
In FIG. 40, 26 is a light source that oscillates an optical signal having a predetermined wavelength, 3a is a first optical modulator, 24 is an optical delayer, 29 is an optical amplifier, 3b is a second optical modulator, and 2 is an optical demultiplexer. , 27 is an optical pulse output terminal, 5 is an oscillator, 8 is a photodetector, 92 is a clock recovery circuit, 12 is a phase comparator, 34 is an optical delay circuit control circuit, and 28 is a first modulation signal generator of the present invention. A first RF amplifier which is an example of a circuit, 97 is a discriminator which is an example of a second modulation signal generation circuit of the present invention, 98 is a data signal input terminal, and 101 is a delay control which is an example of a control circuit of the present invention. Circuit.
The clock recovery circuit 92 includes, for example, limiter amplifiers 93a and 93b and a bandpass filter 94. The optical delay device control circuit 34 is configured by the amplifier 21. The amplifier 21 can be easily realized by an operational amplifier. The phase comparator 12 includes a mixer 17, an amplifier 18, and a low-pass filter 19. The delay control circuit 101 includes a clock recovery circuit 92, a phase comparator 12, and an optical delay control circuit 34.

The basic operation is the same as in FIG. By inputting the error signal output from the phase comparator 12 to the optical delay device 24, the optical modulator 3a and the optical modulator 3b can be synchronized.
The optical delay device 24 can be connected to the output of the optical amplifier 29 instead of the input of the optical amplifier 29.
Further, as shown in FIG. 37 or FIG. 38, the optical demultiplexer 2 can be connected to the output of the optical modulator 3b instead of the input of the optical modulator 3b.

Embodiment 19. FIG.
FIG. 41 is a configuration block diagram showing a bit synchronization circuit using a polarization scrambler according to an embodiment of the present invention.
In FIG. 41, 26 is a light source that outputs an optical signal of a predetermined wavelength, 3 is an optical modulator, 97 is a discriminator that is a first modulation signal generation circuit, 98 is a data signal input terminal, 5 is an oscillator, and 29 is light. An optical amplifier that compensates for the loss of the modulator 3, 95 is a polarization scrambler that is a form of the optical modulator, 2 is an optical demultiplexer, 27 is an optical signal output terminal, and 28 is a second modulation signal generation circuit. In one embodiment, an RF amplifier, 8 is a photodetector, 92 is a clock recovery circuit, 12 is a phase comparator, 9 is a phase shifter control circuit, and 102 is a phase control circuit that is an example of the control circuit of the present invention.
The clock recovery circuit 92 includes, for example, limiter amplifiers 93a and 93b, a multiplier 96, and a band pass filter 94. The phase shifter control circuit 9 includes an amplifier 21. The amplifier 21 can be easily realized by an operational amplifier. The phase comparator 12 includes a mixer 17, an amplifier 18, and a low-pass filter 19.

The operation will be described.
The optical signal emitted from the light source 26 is intensity-modulated by the optical modulator 3. As a modulation format, NRZ (Non Return to Zero) is generally used. The drive signal for the optical modulator 3 is generated by the discriminator 97 from the clock signal output from the oscillator 5 and the data signal input from the data signal input terminal 98. The output of the discriminator 97 is generally amplified by a voltage amplification circuit (not shown) as necessary. The intensity-modulated light is compensated for loss by the optical amplifier 29. Similar to the embodiments described so far, the optical amplifier 29 is composed of optical fibers of several meters to several tens of meters, and therefore, propagation delay time fluctuation due to environmental temperature cannot be ignored. The intensity-modulated optical signal incident on the polarization scrambler 95 is polarization scrambled by the clock signal output from the RF amplifier 28, but the phase relationship between the data signal D and the polarization scramble signal S must be constant. Don't be. A part of the light output from the polarization scrambler is branched by the optical demultiplexer 2, and the optical signal is converted into an electric signal by the photodetector 8. At this time, since the intensity change due to the polarization scrambling has not occurred, the electrical signal detected by the photodetector 8 is the same electrical signal as the electrical signal detected from the intensity modulation signal applied by the optical modulator 3. is there. A recovered clock signal is recovered by the clock recovery circuit 92 from the converted electrical signal. The clock recovery circuit 92 can be configured by a multiplier 96 configured by a mixer, a band pass filter 94 and an amplifier, or a limiter. The same effect can be obtained by using a phase-locked loop circuit for the clock recovery circuit 92. The phase of the recovered clock signal and the electrical clock signal output from the oscillator 5 are compared by the mixer 17. A voltage signal corresponding to the relationship between the phase of the electrical clock signal in the mixer 17 and the phase (data phase) of the clock signal regenerated from the electrical signal detected by the photodetector 8 is converted to a predetermined reference voltage by the amplifier 21. Compared to generate an error signal. The phase shifter 4 is driven by this error signal, and the phase of the data signal D and the phase of the polarization scramble signal S in the polarization scrambler are synchronized. For example, as shown in FIG. 42, the polarization scramble signal S can be controlled to be at the zero level at the center of each bit of the data signal D. When the polarization scramble signal S crosses the zero level, the polarization is switched at the center of each bit by switching the polarization. The phase relationship between the two can be changed by changing the reference voltage of the amplifier 21 described above.

  Here, it is assumed that the optical amplifier 29 causes indefinite phase fluctuations, and that the other optical signal connection lines and the optical path from the polarization scrambler output to the photodetector are sufficiently short, and these fluctuations are ignored. It is assumed that it is possible. Therefore, even if the optical signal input to the polarization scrambler 95 is branched by the optical demultiplexer 2 and input to the photodetector 8, the same effect can be obtained. If these fluctuations cannot be ignored, an adder 100 may be added to input the offset voltage V as shown in FIG.

It is a block diagram which shows the basic composition of the optical pulse position detection circuit concerning Embodiment 1 of this invention. It is a figure which shows the phase shifter of the optical pulse position detection circuit concerning Embodiment 1 of this invention. It is operation | movement explanatory drawing of the optical pulse position detection circuit concerning Embodiment 1 of this invention. It is operation | movement explanatory drawing of the optical pulse position detection circuit concerning Embodiment 1 of this invention. It is operation | movement explanatory drawing of the optical pulse position detection circuit concerning Embodiment 1 of this invention. It is a block diagram which shows the basic composition of the optical pulse position detection circuit concerning Embodiment 2 of this invention. It is operation | movement explanatory drawing in case the phase shift amount of the optical pulse position detection circuit concerning Embodiment 2 of this invention is optimal. It is operation | movement explanatory drawing in case the phase shift amount of the optical pulse position detection circuit concerning Embodiment 2 of this invention is optimal. It is operation | movement explanatory drawing when the amount of phase shifts of the optical pulse position detection circuit concerning Embodiment 2 of this invention is large. It is operation | movement explanatory drawing when the amount of phase shifts of the optical pulse position detection circuit concerning Embodiment 2 of this invention is large. It is operation | movement explanatory drawing when the amount of phase shifts of the optical pulse position detection circuit concerning Embodiment 2 of this invention is small. It is operation | movement explanatory drawing when the amount of phase shifts of the optical pulse position detection circuit concerning Embodiment 2 of this invention is small. It is a block diagram which shows the basic composition of the optical pulse position detection circuit concerning Embodiment 3 of this invention. It is a block diagram which shows the basic composition of the optical pulse position detection circuit concerning Embodiment 4 of this invention. It is operation | movement explanatory drawing of the optical pulse position detection circuit concerning Embodiment 4 of this invention. It is operation | movement explanatory drawing of the optical pulse position detection circuit concerning Embodiment 4 of this invention. It is a block diagram which shows the basic composition of the optical pulse generator concerning Embodiment 5 of this invention. It is operation | movement explanatory drawing in case the amount of phase shifts of the optical pulse generator concerning Embodiment 5 of this invention is optimal. It is operation | movement explanatory drawing when the amount of phase shifts of the optical pulse generator concerning Embodiment 5 of this invention is large. It is operation | movement explanatory drawing when the amount of phase shifts of the optical pulse generator concerning Embodiment 6 of this invention is small. It is a block diagram which shows the basic composition of the optical pulse generator concerning Embodiment 6 of this invention. It is a block diagram which shows the basic composition of the optical pulse generator concerning Embodiment 7 of this invention. It is a block diagram which shows the basic composition of the optical pulse generator concerning Embodiment 8 of this invention. It is a block diagram which shows the basic composition of the optical pulse generator concerning Embodiment 9 of this invention. It is a block diagram which shows the basic composition of the optical pulse generator concerning Embodiment 10 of this invention. It is a block diagram which shows the basic composition of the optical pulse generator concerning Embodiment 11 of this invention. It is a block diagram which shows the basic composition of the optical pulse generator concerning Embodiment 12 of this invention. It is a block diagram which shows the basic composition of the optical pulse generator concerning Embodiment 13 of this invention. It is a block diagram which shows the basic composition of the optical pulse generator concerning Embodiment 14 of this invention. It is a block diagram which shows the basic composition of the optical pulse generator concerning Embodiment 15 of this invention. It is a block diagram which shows the basic composition of the optical pulse generator concerning Embodiment 16 of this invention. It is operation | movement explanatory drawing when the amount of phase shifts of the optical pulse generator concerning Embodiment 16 of this invention is small. It is operation | movement explanatory drawing in case the amount of phase shifts of the optical pulse generator concerning Embodiment 16 of this invention is large. It is operation | movement explanatory drawing when the amount of phase shifts of the optical pulse generator concerning Embodiment 16 of this invention is optimal. It is a block diagram which shows the basic composition of the optical pulse generator concerning Embodiment 16 of this invention. It is a block diagram which shows the basic composition of the optical pulse generator concerning Embodiment 16 of this invention. It is a block diagram which shows the basic composition of the optical pulse generator concerning Embodiment 16 of this invention. It is a block diagram which shows the basic composition of the optical pulse generator concerning Embodiment 16 of this invention. It is a block diagram which shows the basic composition of the optical pulse generator concerning Embodiment 17 of this invention. It is a block diagram which shows the basic composition of the optical pulse generator concerning Embodiment 18 of this invention. It is a block diagram which shows the basic composition of the optical pulse generator concerning Embodiment 19 of this invention. It is a block diagram which shows the phase relationship of the data signal D and the polarization scramble signal S concerning Embodiment 19 of this invention. It is a block diagram which shows the prior art example 1. FIG. It is a figure explaining the prior art example 1. FIG. It is a block diagram which shows the prior art example 2. It is a block diagram which shows the prior art example 3. It is a figure explaining the prior art example 3. FIG.

Explanation of symbols

  1 optical pulse train input terminal, 2 optical demultiplexer, 3 optical modulator, 4 phase shifter, 5 oscillator, 6a, 6b optical power meter, 7 transmittance detector, 8 optical detector, 9 phase shifter control circuit, 10 phase Shift amount output terminal, 11 dither signal generation circuit, 12 phase comparator, 13 phase shifter input terminal, 14 circulator, 15 phase shifter output terminal, 16 varactor diode, 17 mixer, 18 amplifier, 19 low-pass filter, 20 adder , 21 Amplifier, 22 Optical pulse train generation light source, 23 Optical fiber, 24 Optical delay device, 25 Propagation time detection circuit, 26 Light source, 27 Optical pulse output terminal, 28 RF amplifier, 29 Optical amplifier, 30 Modulated light output terminal, 31 pulses Pattern generator, 32 multiplexing circuit, 33 optical multiplexer, 34 optical delay control circuit, 35 Polarization multiplexer / demultiplexer, 36 wavelength detection circuit, 37 reference voltage generator, 38 wavelength drift detection circuit, 39 subtractor, 40 temperature drift detection circuit, 41 temperature detection circuit, 42 semiconductor electroabsorption optical modulator, 43 Optical light modulator, 44 optical clock pulse generation circuit, 45 polarization state converter, 90 phase control circuit, 91 delay control circuit, 92 clock recovery circuit, 93a, 93b limiter, 94 band pass filter, 95 polarization scrambler , 96 multiplier, 97 discriminator, 98 data input terminal, 99 phase control circuit, 100 adder, 101 delay control circuit.

Claims (23)

A light source that outputs an optical signal of a predetermined wavelength;
An oscillator that outputs an electrical clock signal of a predetermined frequency;
A first optical modulator connected to the oscillator for intensity-modulating the optical signal with an electrical clock signal and outputting the modulated optical signal;
A second optical modulator for intensity-modulating an optical signal output from the first optical modulator with an electrical clock signal, and
One of the optical signal input to the second optical modulator and the optical signal output from the second optical modulator is input, a part of the optical signal is output, and a part is branched An optical demultiplexer,
A photodetector that converts the optical signal demultiplexed by the optical demultiplexer into an electrical signal;
A phase changing unit for changing the phase of the optical signal;
An optical pulse generator, comprising: a control circuit that inputs an output of the photodetector and controls a phase change amount of the phase change unit so that the output of the photodetector is maximized. The control circuit includes:
A dither signal generation circuit for outputting a dither signal;
A phase comparator that inputs an output of the photodetector and a dither signal output from the dither signal generation circuit and outputs an error signal by synchronous detection;
A circuit that inputs and superimposes the dither signal output from the dither signal generation circuit and the error signal output from the phase comparator and outputs a control signal for controlling the phase change amount of the phase change unit. The optical pulse generator according to claim 1, wherein: The phase changing unit is
A phase shifter that shifts and outputs the phase of the electrical clock signal output from the oscillator to either the first optical modulator or the second optical modulator;
The control circuit includes:
3. The optical pulse generator according to claim 1, further comprising a phase shifter control circuit for controlling a phase shift amount of the phase shifter. The phase changing unit is
An optical delay device that delays the optical signal output from the first optical modulator and outputs the optical signal to the second optical modulator;
The control circuit includes:
3. The optical pulse generator according to claim 1, further comprising a delay control circuit that controls a delay amount of the optical delay device. The phase changing unit is
A phase shifter that shifts and outputs the phase of the electrical clock signal output from the oscillator to either the first optical modulator or the second optical modulator;
An optical delay device that delays the optical signal output from the first optical modulator and outputs the delayed optical signal to the second optical modulator;
The control circuit includes a delay control circuit that controls a delay amount of the optical delay device,
2. The optical pulse generator according to claim 1, wherein the phase shifter receives a dither signal and shifts a phase of an electrical clock signal output from the oscillator. The first and second optical modulators are composed of one optical modulator,
The light source outputs an optical signal in a first polarization state;
The optical pulse generator further comprises:
A first polarization multiplexer / demultiplexer connected between the light source and the optical modulator;
A second polarization multiplexer / demultiplexer connected between the optical modulator and the optical delay;
A polarization state converter that inputs the optical signal output from the optical delay device, converts the polarization state of the optical signal, and outputs it to the second polarization multiplexer / demultiplexer;
The optical demultiplexer is a polarization output from the first polarization multiplexer / demultiplexer via the second polarization multiplexer / demultiplexer, the optical modulator, and the first polarization multiplexer / demultiplexer. 5. The optical pulse generator according to claim 4, wherein a part of the optical signal whose state has been converted is output and a part thereof is branched. The optical pulse generator as a light source,
A first light source that outputs an optical signal of a first wavelength;
A second light source that outputs an optical signal of a second wavelength,
Corresponding to the first light source and the second light source, the first and third light modulators,
2. An optical pulse generator according to claim 1, further comprising: an optical multiplexer that multiplexes the optical signals output from the first and third optical modulators and outputs them to the second optical modulator. . The optical pulse generator is
A temperature detection circuit for detecting the temperature in the apparatus;
A reference voltage generator;
A temperature drift detection circuit that receives the output signal of the temperature detection circuit and the output signal of the reference voltage generator, generates a compensation signal that compensates for the amount of phase change, and outputs the compensation signal to the control circuit. The optical pulse generator according to any one of claims 1 to 6. The optical pulse generator is
A wavelength detection circuit for detecting a wavelength of an optical signal output from the light source;
A reference voltage generator;
A wavelength drift detection circuit that receives the output signal of the wavelength detection circuit and the output signal of the reference voltage generator, generates a compensation signal that compensates for the amount of phase change, and outputs the compensation signal to the control circuit. The optical pulse generator according to any one of claims 1 to 6.   10. The optical pulse generator according to claim 1, wherein a semiconductor electroabsorption optical modulator is used as the optical modulator. The second light modulator;
The phase change unit;
The photodetector;
2. The optical pulse generator according to claim 1, wherein a plurality of sets of the control circuits are provided in parallel, and the optical signal output from the first optical modulator is branched and processed in parallel. The second light modulator;
The phase change unit;
The photodetector;
2. The optical pulse generator according to claim 1, wherein a plurality of sets of the control circuits are serially provided, and optical signals output from the first optical modulator are serially processed in order. Outputting an optical signal of a predetermined wavelength;
An oscillation process for outputting an electrical clock signal of a predetermined frequency;
A first optical modulation step of modulating the intensity of the optical signal with an electrical clock signal and outputting the modulated signal;
A second light modulation step of intensity-modulating the optical signal output from the first light modulation step with an electrical clock signal and
One of the optical signal input to the second optical modulation step and the optical signal output from the second optical modulation step is input, a part of the optical signal is output, and a part is branched Optical demultiplexing process;
A light detection step of converting the optical signal demultiplexed by the light demultiplexing step into an electric signal;
A phase changing step for changing the phase of the optical signal;
An optical pulse generation method comprising: a control step of inputting an output of the light detection step and controlling a phase change amount of the phase change step so that the output of the light detection step is maximized. The control step includes
A dither signal generation step for outputting a dither signal;
A phase comparison step of inputting an output of the light detection step and a dither signal output from the dither signal generation step and synchronously detecting and outputting an error signal;
A step of inputting and superimposing the dither signal output from the dither signal generation step and the error signal output from the phase comparison step, and outputting a control signal for controlling the phase change amount of the phase change step. The optical pulse generation method according to claim 13, wherein: A light source that outputs an optical signal of a predetermined wavelength;
An oscillator that outputs an electrical clock signal of a predetermined frequency;
A first optical modulator connected to the oscillator for intensity-modulating the optical signal with an electrical clock signal and outputting the modulated optical signal;
A second optical modulator for intensity-modulating an optical signal output from the first optical modulator with an electrical clock signal, and
One of the optical signal input to the second optical modulator and the optical signal output from the second optical modulator is input, a part of the optical signal is output, and a part is branched An optical demultiplexer,
A photodetector that converts the optical signal demultiplexed by the optical demultiplexer into an electrical signal;
A phase changing unit for changing the phase of the optical signal;
The phase change amount of the phase change unit is set so that the electrical signal output from the photodetector and the electrical clock signal output from the oscillator are input and the phases of the electrical signal and the electrical clock signal match. An optical pulse generator comprising a control circuit for controlling. The control circuit includes:
A clock recovery circuit for recovering a clock signal from an electrical signal output from the photodetector;
16. The optical pulse according to claim 15, further comprising: a phase comparator that compares the phases of the clock signal regenerated by the clock regenerating circuit and the electrical clock signal and outputs an error signal to the phase changing unit. Generator. The phase changing unit is
A phase shifter that shifts and outputs the phase of the electrical clock signal output from the oscillator to either the first optical modulator or the second optical modulator;
The control circuit includes:
17. The optical pulse generator according to claim 15, further comprising a phase shifter control circuit that controls a phase shift amount of the phase shifter. The phase changing unit is
An optical delay device that delays the optical signal output from the first optical modulator and outputs the optical signal to the second optical modulator;
The control circuit includes:
17. The optical pulse generator according to claim 15, further comprising a delay control circuit that controls a delay amount of the optical delay device.   The optical pulse generator further receives an electrical clock signal input to one of the first and second optical modulators as a clock signal, and a data signal that is synchronized with the clock signal by inputting the data signal. 16. The optical pulse generation device according to claim 15, further comprising: a modulation signal generation circuit that outputs a modulation signal to any one of the first and second optical modulators.   16. The optical pulse generator according to claim 15, wherein the second modulator is a polarization scrambler. Outputting an optical signal of a predetermined wavelength;
An oscillation process for outputting an electrical clock signal of a predetermined frequency;
A first optical modulation step of modulating the intensity of the optical signal with an electrical clock signal and outputting the modulated signal;
A second light modulation step of intensity-modulating the optical signal output from the first light modulation step with an electrical clock signal and
One of the optical signal input to the second optical modulation step and the optical signal output from the second optical modulation step is input, a part of the optical signal is output, and a part is branched Optical demultiplexing process;
A light detection step of converting the optical signal demultiplexed by the light demultiplexing step into an electric signal;
A phase changing step for changing the phase of the optical signal;
The phase change amount of the phase change step is set so that the electrical signal output from the light detection step and the electrical clock signal output from the oscillator are input and the phases of the electrical signal and the electrical clock signal match. An optical pulse generation method comprising a control step of controlling. The control step includes
A clock recovery step of recovering a clock signal from the electrical signal output from the light detection step;
22. The optical pulse according to claim 21, further comprising a phase comparison step of comparing the phase of the clock signal regenerated in the clock recovery step with an electrical clock signal and outputting an error signal to the phase change step. How it occurs. A light source that outputs an optical signal of a predetermined wavelength;
An oscillator that outputs an electrical clock signal of a predetermined frequency;
A first optical modulator connected to the oscillator for intensity-modulating the optical signal with an electrical clock signal and outputting the modulated optical signal;
A second optical modulator for intensity-modulating an optical signal output from the first optical modulator with an electrical clock signal, and
One of the optical signal input to the second optical modulator and the optical signal output from the second optical modulator is input, a part of the optical signal is output, and a part is branched An optical demultiplexer,
A photodetector that converts the optical signal demultiplexed by the optical demultiplexer into an electrical signal;
A phase changing unit for changing the phase of the optical signal;
A control circuit that controls the phase change amount of the phase change unit so that the output of the photodetector is input and the output of the photodetector is maximized;
The control circuit includes:
A dither signal generation circuit for outputting a dither signal;
A phase comparator that inputs an output of the photodetector and a dither signal output from the dither signal generation circuit and outputs an error signal by synchronous detection;
A dither signal output from the dither signal generation circuit and an error signal output from the phase comparator are input and superimposed, and a control signal for controlling the phase change amount of the phase change unit so that the error signal becomes zero is provided. And an optical pulse generator.

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