JP4976040B2 - Pulse light source and control method of pulse light source - Google Patents

Description

  The present invention relates to a pulse light source and a pulse light source control method for generating an ultrashort pulse by pulse-compressing an input light pulse using a nonlinear effect of an optical fiber.

  Development of a pulsed light source that generates ultrashort pulses in the picosecond and femtosecond range using optical fibers is a compact, low-cost, and stable, ultrahigh-speed optical communication, optical measurement technology, material processing, and bio-use light. It attracts attention in fields such as electronics and physics.

  2. Description of the Related Art Conventionally, there is an optical pulse train generator used in an optical transmission system as a pulse light source that generates ultrashort pulses (see Patent Document 1). This optical pulse train generator includes a two-mode beat light generator, a soliton converter, and a soliton compressor, and before the adiabatic soliton compression of the two-mode beat signal light in the soliton compressor, the two-mode beat signal light Is converted from a sin waveform to a soliton waveform by a soliton converter. With this optical pulse train generator, the compression efficiency of soliton adiabatic compression can be greatly improved, and an ultra-high-purity soliton train having a repetition frequency of 100 GHz or more and a time width in the sub-picosecond region can be generated.

In addition, an optical amplifier that optically amplifies an input optical pulse is used in a pulse light source that generates an ultrashort pulse or an optical transmission system. Optical amplifier control methods include APC (Automatic Current Control) for controlling the pump light of the optical amplifier, ALC control (Automatic Level Control) for maintaining the optical output at a constant level, and AGC control (Automatic Gain Control) for controlling the gain at a constant level. Etc. are known (see Patent Document 2).
WO 2004/049054 A1 JP 2005-150435 A

  The above-described conventional optical amplifier control method is effective for continuous light having a constant level or a pulse train in which the repetition frequency of the optical pulse train is fixed. In addition, in the pulse light source as described in Patent Document 1, it is desired to have a configuration in which the repetition frequency of the optical pulse train can be changed for the purpose of improving convenience. In this way, when the conventional optical amplifier control method is applied to a pulse light source in which the repetition frequency of the optical pulse train is variable, the output characteristics (pulse energy and pulse width) of the ultrashort pulse change when the repetition frequency changes. There is a problem of end.

  The present invention has been made paying attention to such conventional problems, and its purpose is that the output pulse characteristics (pulse energy and pulse width) are constant even if the repetition frequency of the input optical pulse train is changed. An object of the present invention is to provide a pulse light source and a pulse light source control method capable of generating ultrashort pulses and improving convenience.

  According to a first aspect of the present invention, an optical pulse generator that generates an optical pulse train having a variable repetition frequency, an optical amplifier that optically amplifies each optical pulse of the optical pulse train, and an optical amplifier that is optically amplified by the optical amplifier Optical pulse compression means for compressing each optical pulse by utilizing a nonlinear effect of an optical fiber, and excitation control means for controlling excitation of the optical amplification means, wherein the excitation control means is controlled by the optical amplification means. The pulse light source is characterized in that the excitation of the optical amplification means is controlled so that the average pulse energy of the optically amplified optical pulse is constant.

  Here, the “average pulse energy” is a value obtained by monitoring the average power of each optical pulse on the output side of the optical amplifying means and dividing the average power by the repetition frequency of the optical pulse train (see Expression (1)).

  In this configuration, when the optical pulse energy is optically amplified, the average pulse energy of the optically amplified optical pulse is constant in a pulsed light source that generates an ultrashort pulse by using the nonlinear effect of the optical fiber. The excitation of the optical amplification means is controlled so that According to this configuration, even if the pulse width of the optical pulse input to the optical pulse compression unit changes due to a change in the repetition frequency, the average pulse energy of the optical pulse that has been optically amplified becomes constant, The effect of pulse compression using a nonlinear effect becomes constant without depending on the repetition frequency of the optical pulse train.

  Therefore, even if the repetition frequency of the input optical pulse train is changed, an ultrashort pulse with a constant output pulse characteristic (pulse energy and pulse width) can be generated, and convenience can be improved.

  In the first aspect, the excitation control unit includes a semiconductor laser that excites the optical amplification unit, an optical power detection unit that detects an average power of the optical pulse after optical amplification by the optical amplification unit, and the semiconductor laser. A control unit for controlling the semiconductor laser, wherein the control unit acquires a repetition frequency of the optical pulse input to the optical amplifying means, and sets a current control initial value of the semiconductor laser according to the acquired repetition frequency In addition, the semiconductor laser is controlled so that an average pulse energy, which is a value obtained by dividing the average power detected by the optical power detection means by the repetition frequency, becomes constant.

  According to this configuration, the control unit acquires the repetition frequency of the optical pulse, sets the current control initial value of the semiconductor laser according to the acquired repetition frequency, and controls the semiconductor laser so that the average pulse energy is constant. To do. As a result, the pulse energy of the optical pulse input to the optical pulse compression means is adjusted according to the repetition frequency, so even if the pulse width of the optical pulse input to the optical pulse compression means changes as the repetition frequency changes. The effect of pulse compression using the nonlinear effect becomes constant without depending on the repetition frequency of the optical pulse train. Therefore, even if the repetition frequency of the input optical pulse train is changed, an ultrashort pulse with a constant output pulse characteristic can be generated, and convenience can be improved.

  In the first aspect, the optical pulse compression means includes a fiber compressor formed by connecting a pair of highly nonlinear fiber and single mode fiber in multiple stages, and is optically amplified by the optical amplification means by the fiber compressor. The optical pulse is compressed.

  According to this configuration, each optical pulse optically amplified by the optical amplifying means is transmitted by a fiber compressor formed by connecting a pair of highly nonlinear fiber (HNLF) and single mode fiber (SMF) in multiple stages. Compress. This fiber compressor has a profile having a shape with a nonlinear constant as well as dispersion, for example, a comb-like (comb-like) profile. Further, since an optical fiber having a small dispersion value and a large nonlinear constant is used as the nonlinear medium, an ideal nonlinear medium can be obtained and the fiber compressor can be shortened. In addition, since optical fibers having greatly different dispersion values are connected in multiple stages, it is excellent in suppressing stimulated Brillouin scattering. Furthermore, the fiber compressor is excellent in terms of manufacturing because the dispersion profile can be designed flexibly.

  In the first aspect, the optical pulse generator has a function of outputting an optical pulse train having a variable repetition frequency to the optical amplifier, and a function of outputting a digital signal representing the repetition frequency to the control unit. It is a generator.

  According to this configuration, the control unit can acquire the repetition frequency of the optical pulse from the digital signal output from the optical pulse generator.

  In the first aspect, the pulse generation means includes a distributed feedback semiconductor laser, and an electric pulse generator that outputs an electric pulse and drives the distributed feedback semiconductor laser with a gain switch, and the electric pulse generator includes: The distributed feedback semiconductor laser has a function of generating an electric pulse with a variable repetition frequency, and the distributed feedback semiconductor laser generates a gain switch oscillation by injection of an electric pulse output from the electric pulse generator to change the repetition frequency. A pulse is generated, and the electric pulse generator outputs a digital value representing a repetition frequency of the optical pulse directly to the control unit.

  According to this configuration, by changing the repetition frequency of the electric pulse output from the electric pulse generator, an optical pulse having a variable repetition frequency can be generated from the distributed feedback semiconductor laser. Further, the control unit can obtain the repetition frequency of the optical pulse by a digital signal directly output from the electric pulse generator.

  In the first aspect, the optical pulse generating means is an optical pulse generator having a function of outputting an optical pulse train having a variable repetition frequency to the optical amplifier, and the excitation control means is output from the optical pulse generating means. Optical pulse detection means for receiving each optical pulse of the optical pulse train, wherein the control unit performs fast Fourier transform on the time data of each optical pulse received by the optical pulse detection means to repeat the frequency of the optical pulse train. It is characterized by calculating | requiring.

  According to this configuration, the control unit obtains the repetition frequency of the optical pulse train by performing fast Fourier transform on the time data of each optical pulse received by the optical pulse detection means. An interface to acquire is unnecessary.

  In the first aspect, the optical pulse generation means further includes a dispersion compensation fiber that performs chirp compensation of an optical pulse output from the semiconductor laser when the distributed feedback semiconductor laser is driven by a gain switch, and the optical pulse compression The means includes a normal dispersion optical amplifier as the optical amplification means, the fiber compressor connected to the output side of the normal dispersion optical amplifier, a normal dispersion optical amplifier connected to the output side of the fiber compressor, and a single unit. One-mode fiber.

  According to this configuration, the optical pulse train chirp-compensated by the normal dispersion optical amplifier can be output from the pulse generating means. Further, the pulse width of the ultrashort pulse can be further reduced by performing the pulse compression by the fiber compressor and the pulse compression by the normal dispersion optical amplifier and the single mode fiber.

  According to a second aspect of the present invention, an optical pulse train having a variable repetition frequency is generated, each optical pulse of the optical pulse train is optically amplified by an optical amplifying means, and each optical pulse thus amplified is nonlinearly affected by an optical fiber. Is a pulse light source control method for generating ultrashort pulses by compressing pulses, and controlling the excitation of the optical amplifying means so that the average pulse energy of the optical pulse train optically amplified is constant This is a method for controlling a pulsed light source.

  According to this configuration, even if the repetition frequency of the input optical pulse train is changed, an ultrashort pulse having a constant output pulse characteristic (pulse energy and pulse width) can be generated, and convenience can be improved. .

  In the second aspect, the step of acquiring the repetition frequency of the optical pulse train input to the optical amplification means, and the current control initial value of the semiconductor laser that outputs the pumping light to the optical amplification means, the acquired repetition frequency A step of detecting the average power of the optical pulse on the output side of the optical amplifying means, and an average pulse energy that is a value obtained by dividing the average power by the repetition frequency is constant. Controlling the semiconductor laser.

  According to this configuration, since the pulse energy of the optical pulse input to the optical pulse compression means is adjusted according to the repetition frequency, even if the repetition frequency of the input optical pulse train is changed, the output pulse characteristics are constant and short. Pulses can be generated, and convenience can be improved.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the description of each embodiment, the same parts are denoted by the same reference numerals, and redundant description is omitted.
(First embodiment)
FIG. 1 shows a pulse light source 300A according to the first embodiment.

  The pulse light source 300A includes a pulse generator 301 as an optical pulse generation unit that generates an optical pulse train having a variable repetition frequency, and an optical amplification unit that optically amplifies each optical pulse of the optical pulse train output from the optical pulse generator 301. The optical fiber amplifier 302 is provided. Further, the pulse light source 300A includes an optical pulse compressor 303 as an optical pulse compression unit that compresses each optical pulse optically amplified by the optical fiber amplifier 302 using the nonlinear effect of the optical fiber, and excitation of the optical fiber amplifier 302. And an excitation control unit 304 as excitation control means for controlling the above.

  The pulse generator 301 has a function of outputting an optical pulse train having a variable repetition frequency to the optical fiber amplifier 302, and a function of outputting a digital signal representing the repetition frequency to the control unit 305 of the excitation control unit 304. (Optical Pulse Source: OPS) 306. The optical pulse generator 306 includes an optical circuit (not shown) for generating an optical pulse train and an electric circuit (not shown), and manually changes a frequency changeover switch (not shown) to change the repetition frequency of the optical pulse train. It is supposed to be. For example, as shown in FIGS. 2A to 2F, the optical pulse generator 306 can change the repetition frequency of the optical pulse train in six stages from 500 MHz to 1000 MHz at 100 MHz intervals. 2A to 2F, the horizontal axis indicates the wavelength [nm], and the vertical axis indicates the optical power [10 dB / div.].

  An erbium-doped fiber amplifier (EDFA) is used as the optical fiber amplifier 302. In FIG. 3, reference numeral 400 denotes an optical pulse before amplification input to the optical fiber amplifier 302, and reference numeral 401 denotes an optical pulse after amplification by the optical fiber amplifier 302. In FIG. 3, T is the period of the optical pulse 400 (T = 1 / f), and Δtout is the pulse width of the optical pulse 401.

  The optical pulse compressor 303 is a comb-like profiled fiber (CPF) as a fiber compressor formed by connecting a pair of a highly nonlinear fiber (HNLF) and a single mode fiber (SMF) in multiple stages. ) Compressor 310, and the comb-like fiber compressor 310 compresses the optical pulse optically amplified by the optical fiber amplifier 302. In FIG. 3, reference numeral 402 denotes an optical pulse (output light) after the optical pulse 401 after optical amplification is compressed by the comb fiber compressor 310.

  The excitation control unit 304 includes two semiconductor lasers 311 and 312 that excite the optical fiber amplifier 302, a photodiode 313 as an optical power detection unit that detects the average power of the optical pulse after optical amplification by the optical fiber amplifier 302, And a control unit 305 for controlling the semiconductor lasers 311 and 312. The semiconductor lasers 311 and 312 are provided with drive circuits 314 and 315 for supplying a drive current corresponding to a control signal from the control unit 305 to each semiconductor laser.

  In the pulse light source 300A of this embodiment, the pumping method of the optical fiber amplifier 302 is a bidirectional pumping method. That is, forward pumping in which light (pumping light) used for pumping the optical fiber amplifier 302 is incident on the optical fiber amplifier 302 in the same direction as the traveling direction of an optical pulse that is amplified light (signal light), and the traveling direction thereof The configuration is such that backward pumping in which pumping light is incident on the optical fiber amplifier 302 in the opposite direction is simultaneously used.

  Therefore, the pulsed light source 300A includes a pumping semiconductor laser 311 that makes the pumping light incident on the optical fiber amplifier 302 in the traveling direction of the optical pulse, and a pumping semiconductor that makes the pumping light incident on the optical fiber amplifier 302 in the opposite direction. A laser 312 is provided. The optical fiber 320 that propagates the optical pulse output from the optical pulse generator 306 to the optical fiber amplifier 302 includes an optical branching device 322 that branches the optical pulse to the photodiode 321, and the optical pulse from the semiconductor laser 311. A WDN optical fiber coupler 323 that combines the excitation light is provided.

  The optical pulse optically amplified by the optical fiber amplifier 302 propagates through the optical fiber 324 and enters the comb-like fiber compressor 310, and the optical pulse compressed by this compressor propagates through the optical fiber 325 and passes through the optical pulse compressor. 303 is output. The optical fiber 324 includes a WDN optical fiber coupler 326 that allows the pumping light from the semiconductor laser 312 to enter the optical fiber amplifier 302, and an optical branching device 327 that branches the optical pulse amplified by the optical fiber amplifier 302 to the photodiode 313. And are provided.

  The control unit 305 of the excitation control unit 304 includes a CPU 330 that performs various arithmetic processes, a ROM 331, a RAM 332, a D / A converter, an A / D converter, and the like that are not shown.

  The CPU 330 is configured to output a command A for obtaining the repetition frequency f of the optical pulse input to the optical fiber amplifier 302 to the optical pulse generator 306 at regular intervals. When receiving the command A, the optical pulse generator 306 outputs a digital signal B representing the repetition frequency to the control unit 305.

  The CPU 330 sets current control initial values of the semiconductor lasers 311 and 312 that output pumping light to the optical fiber amplifier 302 according to the acquired repetition frequency f and a drive signal corresponding to the set current control initial value. Is output to the drive circuits 314 and 315, and the drive control of the semiconductor lasers 311 and 312 is started. After this start, the CPU 330 calculates the average power from the power of the optical pulse after optical amplification detected by the photodiode 313, and calculates the average pulse energy that is a value obtained by dividing the average power by the repetition frequency f (1). See formula). The semiconductor lasers 311 and 312 are feedback-controlled so that the calculated average pulse energy is constant.

Eout = Pout / f (1 set)
Here, Eout is the average pulse energy, and Pout is the average power.

  By the way, the average power of the optical pulse input to the optical fiber amplifier 302 increases as the repetition frequency f increases. Since the gain of the average power of the optical pulse amplified by the optical fiber amplifier 302 must be constant, the higher the average power of the optical pulse, the more the pumping light output from the semiconductor lasers 311 and 312 to the optical fiber amplifier 302 becomes. It is also necessary to increase the required optical power. The characteristic (IL characteristic) of the pumping light power output value with respect to the input current value of each of the semiconductor lasers 311 and 312 is unique. Therefore, the current control initial values of the semiconductor lasers 311 and 312 are experimentally measured in advance for each of the semiconductor lasers 311 and 312, and optimum values corresponding to the repetition frequency f are stored in the RAM 332 as a data table, for example. . In this case, the CPU 330 sets a current control initial value corresponding to the repetition frequency f with reference to the data table. This data table includes current control initial values corresponding to all the frequencies f1 to fn whose repetition frequency is variable.

  As described above, in the present embodiment, the semiconductor lasers 311 and 312 are controlled so that the average pulse energy of the optical pulse is constant. This control is referred to as AEC (Auto Energy Control) control.

  Next, the processing procedure of AEC control executed by the CPU 330 of the control unit 305 will be described based on the flowchart shown in FIG.

  The AEC control process shown in FIG. 4 is repeatedly executed at regular intervals when the pulse light source 300A is turned on.

  First, in step S 1, the command A is output to the optical pulse generator 306 at regular intervals, and the repetition frequency f of the optical pulse input to the optical fiber amplifier 302 is acquired. At this time, when receiving the command A, the optical pulse generator 306 outputs a digital signal B representing the repetition frequency f to the control unit 305. The CPU 330 obtains the repetition frequency f from the digital signal B.

  In step S2, the current control initial values of the semiconductor lasers 311 and 312 that output pumping light to the optical fiber amplifier 302 are set according to the obtained repetition frequency f.

  Next, the process proceeds to step S3, and the semiconductor lasers 311 and 312 are driven with the current control initial value set in step S2. At this time, a drive signal corresponding to the current control initial value set in step S2 is output to the drive circuits 314 and 315, and drive control of the semiconductor lasers 311 and 312 is started.

  In step S4, the average power of the optical pulse after optical amplification is detected on the output side of the optical fiber amplifier 302. Here, based on the photoelectric output of the photodiode 313, the average power in the above equation 1 is calculated from the power of the optical pulse after optical amplification detected by the photodiode 313.

  Next, the average pulse energy, which is a value obtained by dividing the average power detected in step S5 by the repetition frequency f, is calculated by the above equation (1).

  Next, the semiconductor lasers 311 and 312 are respectively feedback controlled so that the average pulse energy calculated in step S5 is constant.

  Then, the process shown in FIG. 4 is once complete | finished.

  FIG. 5A and FIG. 5B show examples of the light output of ultrashort pulses generated by the pulse light source 300A by performing such AEC control. FIG. 5A is a graph showing the autocorrelation waveform of the output light pulse, and FIG. 5B is a graph showing the optical spectrum of the output light pulse.

  FIG. 6 shows the repetition frequency dependency of the pulse width and pulse energy in the pulse light source 300A. In FIG. 6, black circles and black squares respectively indicate the pulse energy and pulse width of the output light pulse when the repetition frequency f is 500 MHz, 600 MHz, 700 MHz, 800 MHz, 900 MHz, and 1000 MHz. It can be seen from FIG. 6 that even if the repetition frequency of the input optical pulse train 400 is changed, an ultrashort pulse having a constant output pulse characteristic (pulse energy and pulse width) can be generated.

  According to 1st Embodiment described above, there exist the following effects.

By the above AEC control, when the energy of the optical pulse 400 (see FIG. 3) is optically amplified by the optical fiber amplifier 302, the average pulse energy of the optical pulse 401 (see FIG. 3) amplified is constant. , Controlling the excitation of the optical fiber amplifier 302. As a result, the pulse width Δtout of the optical pulse 401 input to the optical pulse compressor 303.
However, even if the repetition frequency f changes, the effect of pulse compression using the nonlinear effect in the optical pulse compressor 303 becomes constant without depending on the repetition frequency of the optical pulse train. Therefore, even if the repetition frequency of the input optical pulse train 400 is changed, an ultrashort pulse with a constant output pulse characteristic (pulse energy and pulse width) can be generated, and convenience can be improved.

-As one adiabatic soliton compression technique, a method using a comb-like disprsion profiled fiber (CDPF) is known. This CDPF is manufactured by using a zero dispersion shifted fiber (DSF) as a nonlinear medium and a single mode fiber (SMF) as a dispersion medium, and fusing them together. In the present embodiment, each light optically amplified by the optical fiber amplifier 302 by a comb-like fiber (CPF) compressor 310 formed by connecting a pair of highly nonlinear fiber (HNLF) and single mode fiber (SMF) in multiple stages. Compress the pulse. Since the comb-like fiber compressor 310 uses HLNF instead of DSF, not only the dispersion but also the nonlinear constant has a comb-like (comb-like) profile. In addition, since an optical fiber having a small dispersion value and a large nonlinear constant is used as the nonlinear medium, an ideal nonlinear medium can be obtained and the comb fiber compressor 310 can be shortened. In addition, since optical fibers having greatly different dispersion values are connected in multiple stages like a step-like dispersion profiled fiber (SDPF), it is excellent in suppressing stimulated Brillouin scattering. Further, the comb-shaped fiber compressor 310 is excellent in terms of manufacturing because the dispersion profile can be designed flexibly.
(Second Embodiment)
Next, a pulse light source 300B according to a second embodiment of the present invention will be described with reference to FIG.

  The pulse light source 300B includes a pulse generator 301 serving as a pulse generating means, a distributed feedback laser diode (DFB-LD) 500, and a gain switch that outputs an electric pulse to the distributed feedback semiconductor laser 500. And an electric pulse generator (EPS) 501 for driving.

  The electric pulse generator 501 includes an electric pulse generator (pulse pattern generator: PPG) that generates an electric pulse having a variable repetition frequency, and an amplifier that amplifies the electric pulse.

  The pulse generator 301 applies an electric pulse modulation to the distributed feedback semiconductor laser 500 as a light source by the electric pulse generator 501 so that an optical pulse train having a variable repetition frequency f is output from the distributed feedback semiconductor laser 500. It has become. That is, the repetition frequency f of the optical pulse train output from the pulse generator 301 is controlled by the repetition frequency of the electrical pulse output from the electrical pulse generator 501 and driving the distributed feedback semiconductor laser 500 with a gain switch. It has become.

  In the pulse light source 300B, when the electric pulse generator 501 receives a command A for obtaining the repetition frequency f of the optical pulse from the CPU 330 of the control unit 305, the electric pulse generator 501 generates a digital signal representing the repetition frequency f. The data is output directly from the device 501 to the control unit 305.

  The other configuration of the pulse light source 300B is the same as that of the pulse light source 300A according to the first embodiment.

  According to 2nd Embodiment described above, in addition to the effect which the said 1st Embodiment show | plays, there exist the following effects.

  By changing the repetition frequency of the electric pulse output from the electric pulse generator 501 to the distributed feedback semiconductor laser 500, an optical pulse having a variable repetition frequency f can be generated from the distributed feedback semiconductor laser 500.

The control unit 305 can acquire the repetition frequency f of the optical pulse by a digital signal directly output from the electric pulse generator 501.
(Third embodiment)
Next, a pulse light source 300C according to a third embodiment of the present invention will be described with reference to FIG.

  The excitation control unit 305 as the excitation control unit includes the photodiode 321 as an optical pulse detection unit that receives each optical pulse of an optical pulse train with a variable repetition frequency f output from the optical pulse generator 306.

  The control unit 305 is configured to obtain the repetition frequency f of the optical pulse train by performing fast Fourier transform on the time data of each pulse received by the photodiode 321.

  The other configuration of the pulse light source 300C is the same as that of the pulse light source 300A according to the first embodiment.

  According to 3rd Embodiment described above, in addition to the effect which the said 1st Embodiment show | plays, there exist the following effects.

The control unit 305 obtains the repetition frequency f with the optical pulse generator 306 because the control unit 305 obtains the repetition frequency f of the optical pulse train by performing fast Fourier transform on the time data of each optical pulse received by the photodiode 321. No interface is required. That is, a signal line for sending a command A for acquiring the optical pulse repetition frequency f from the CPU 330 of the control unit 305 to the pulse generator 306 and a digital signal representing the repetition frequency f from the electric pulse generator 501 to the control unit 305. A signal line or the like to be sent to the mobile phone becomes unnecessary, and the cost can be reduced accordingly.
(Fourth embodiment)
Next, a pulse light source 300D according to a fourth embodiment of the present invention will be described with reference to FIG.

  In the pulse light source 300D, the pulse generator 301 includes a distributed feedback semiconductor laser 500, an electric pulse generator 502 that outputs an electrical pulse to drive the distributed feedback semiconductor laser 500 as a gain switch, and a distributed feedback semiconductor laser 500. A dispersion compensating fiber (DCF) 510 that performs chirp compensation of the optical pulse output from the laser.

  The electric pulse generator 502 includes an electric pulse generator (pulse pattern generator: PPG) that generates electric pulses with variable repetition frequency by applying electric pulse modulation (intensity modulation) to the distributed feedback semiconductor laser 500 that is a light source. .

  The pulse generator 301 applies an electric pulse modulation to the distributed feedback semiconductor laser 500 as a light source by the electric pulse generator 501 so that an optical pulse train having a variable repetition frequency f is output from the distributed feedback semiconductor laser 500. It has become. In other words, the repetition frequency f of the optical pulse train output from the pulse generator 301 is controlled by the repetition frequency of the electrical pulse output from the electrical pulse generator 502 and driving the distributed feedback semiconductor laser 500 with a gain switch. It has become.

  In the pulse light source 300B, when the electric pulse generator 502 receives a command A for obtaining the optical pulse repetition frequency f from the CPU 330 of the control unit 305, the electric pulse generator 502 generates a digital signal representing the repetition frequency f as an electric pulse generator. The data is output directly from 502 to the control unit 305.

  The optical pulse compressor 303 of the pulse light source 300D uses a normal dispersion optical amplifier (ND-EDFA) 340 as an optical amplifying means instead of the erbium-doped optical fiber amplifier 302 used in the first embodiment. Yes. In this optical pulse compressor 303, after the pulse energy of each optical pulse of the chirp-compensated optical pulse train output from the pulse generator 301 is amplified to the optimum pulse energy for CPF compression by the normal dispersion optical amplifier 340, It is input to the comb-like fiber compressor 310.

  The optical pulse compressor 303 further includes normal dispersion optical amplifiers 350 and 351 connected to the output side of the comb-shaped fiber compressor 310, and a single mode fiber 352. That is, the optical pulse compressor 303 performs pulse compression by the comb fiber compressor 310 and pulse compression by the two normal dispersion optical amplifiers 350 and 351 and the single mode fiber 352. The normal dispersion optical amplifiers 350 and 351 are excited by semiconductor lasers 600 and 601, respectively. In FIG. 9, reference numerals 602 and 603 denote drive circuits that supply drive currents corresponding to control signals from the control unit 305 to the semiconductor lasers 600 and 601.

  The optical fiber 610 connecting the comb-shaped fiber compressor 310 and the normal dispersion optical amplifier 350 is provided with a WDN optical fiber coupler 701 that combines pumping light from the semiconductor laser 600. The optical fiber 611 that connects the normal dispersion optical amplifier 350 and the normal dispersion optical amplifier 351 is provided with a WDN optical fiber coupler 702 that multiplexes pumping light from the semiconductor laser 601. The normal dispersion optical amplifier 351 and the single mode fiber 352 are connected by an optical fiber 612.

  Other configurations of the pulse light source 300D are the same as those of the pulse light source 300A according to the first embodiment.

  According to 4th Embodiment described above, in addition to the effect which the said 1st Embodiment show | plays, there exist the following effects.

  An optical pulse train chirp-compensated by the normal dispersion optical amplifier 340 can be output from the pulse generator 301.

In the optical pulse compressor 303, the pulse compression by the comb fiber compressor 310 and the pulse compression by the two normal dispersion optical amplifiers 350 and 351 and the single mode fiber 352 are performed, so that the first embodiment is concerned. An ultrashort pulse having a pulse width smaller than that of the pulse light source 300A can be generated.
(Fifth embodiment)
FIG. 10 is a block diagram schematically showing the configuration of a system using an ultrashort pulse light source according to the fifth embodiment of the present invention. In FIG. 10, element number 1 is an electric pulse source or an electronic device that outputs an electric pulse train, element number 2 is a pulse light source that receives an electric pulse train from element 1 and outputs a corresponding optical pulse, Element number 3 is an optical pulse compression device that receives an optical pulse from the pulse light source 2 and compresses the pulse width. The pulse light source 2 and the optical pulse compression device 3 may be integrally formed to form the ultrashort pulse light source 4 as a whole. In addition, when the electric pulse source or the electronic device 1 is a circuit that exclusively outputs an electric pulse for generating an ultrashort pulse and is formed in an integrated form with the ultrashort pulse light source 4, the entire FIG. Should be considered.

The optical pulse compression device 3 basically includes an optical amplifier 30 using an erbium-doped fiber (EDF) 32 that receives and amplifies an optical pulse from the pulse light source 2, and an optical amplifier 30 (or , EDF 32) and a comb-like dispersion profiled fiber (CDPF) 34 connected in series via an optical fiber. By combining the EDF 32 and the CDPF 34, the optical pulse from the pulse light source 2 is amplified by the EDF 32, and the pulse width is compressed by repeatedly receiving nonlinear effects and dispersion compensation by the CDPF 34, as is well known to those skilled in the art. . As the EDF 32, for example, a normal dispersion EDF (ND (normal dispersion) -EDF) can be used.

  According to the fifth embodiment, the optical pulse compression device 3 further includes a WDM (wavelength division multiplexing) coupler 42, 42a inserted immediately before the EDF 32, and a laser diode (LD) connected to a multiplexing terminal of the coupler 42. 44, an LD driving circuit 46 connected to the other end of the laser diode 44, a photodiode 42 connected to the turnable 42a, and arranged to be able to monitor the light emitted by the laser diode 44, the other end of the photodiode 48. Drive power detector 50, optical demultiplexer 52 inserted on the output side of EDF 32, average output power measuring instrument 54 optically coupled to the demultiplexing output terminal of optical demultiplexer 52, and LD A controller 60 in which a control input terminal of the drive circuit 46, an output terminal of the drive power detector 50, and an output terminal of the average output power measuring instrument 54 are connected. Et al constructed.

  The electric pulse source or electronic device 1 includes a control unit 12, and the control unit 12 outputs a repetition frequency f of the electric pulse output by the element 1. In particular, when the repetition frequency changes, it is preferable that the electric pulse source or the electronic apparatus 1 frequently outputs the frequency f following the change. This output f is supplied to the controller 60.

  The electric pulse source or the electronic device 1 may be anything such as various pulse generators, pulse pattern generators, or other electronic devices as long as they output an electric pulse train. The pulse light source 2 may be anything as long as it generates an optical pulse in response to an input electric pulse, such as a distributed feedback semiconductor laser (DFB-LD) driven by a gain switch. Composed. The average output power measuring device 54 obtains an average pulse power Ea from the photoelectric conversion signal obtained by photoelectrically converting the optical pulse signal branched from the output of the EDF 32 and passes it to the controller 60 as is well known in the art.

  The controller 60 includes a CPU (Central Information Processing Device) (not shown) as well known, and a nonvolatile memory 62 for storing a program 64 and data necessary for control. The nonvolatile memory 62 stores an initial value P that is a control target value of the drive power Pd from the drive power detector 50 at the time of startup, and a control target value Et of the pulse energy of each optical pulse that is output from the EDF 32 during operation. Assume that a data table 62 to be stored in association with the repetition frequency f is stored.

  FIG. 11 is a diagram showing a structure example of the data table 66 stored in the nonvolatile memory 62 of the controller 60 of FIG. 10 and the flow of data related thereto. The data table 66 shown in FIG. 11 is an example when three set values Etα, ETβ, and ETγ are prepared in advance as pulse energy. It is assumed that the user or the host system can set the pulse energy by selecting one of these or inputting a desired pulse energy value. The data table 66 includes repetition frequencies f1, f2,. . . Consists of a record for each of Each record fi (i = 1, 2,...) Includes an initial value Pi that becomes a control target value of the drive power Pd from the drive power detector 50 at the time of activation, selectable pulse energy target values Etαi, ETβi, and ETγi. Consists of

  In this way, the repetition frequencies f1, f2,. . . Control target values Etα1, Etα2,. . . Is required. This is necessary because when the pulse energy of the input pulse from the pulse light source 2 is, for example, 0.1 pJ and the pulse width is 10 ps, the pulse energy is compressed by the optical pulse compression device 3, for example, the pulse energy is 1 pJ. Considering the case of obtaining an ultrashort pulse with a pulse width of 1 ps, if the repetition frequency f is 500 MHz, the EDF 32 supplies a current of 100 nA to the laser diode 44 in order to amplify 50 μW input power to 500 μW output power. This is because, if f is 1 GHz, the EDF 32 needs to pass a current of 200 nA through the laser diode 44 in order to amplify the input power of 100 μW to the output power of 1000 μW.

  A random access memory (RAM) (not shown) of the controller 60 stores a repetition frequency f (referred to as a reception value f of the repetition frequency) supplied from an electric pulse source or an external device such as the electronic device 1 as described above. A storage location 682 for storing the pulse energy setting target value Et sent from the host system or the user, and a storage location for storing a copy of the repetitive frequency reception value f of the storage location 682 as the current value fc of the repetitive frequency. 682a and a storage location 684a that stores a copy of the set target value Et of the pulse energy of the storage location 684 as the current set target value.

  The operation of the optical pulse compression device 3 configured as described above will be described with reference to FIGS. The flowcharts of FIGS. 12 to 15 show the flow of processing of the program 64 stored in the nonvolatile memory 62 of the controller 60 of FIG.

  FIG. 12 shows pulse energy executed when the controller 60 receives a pulse energy control target value (set target value) Et supplied from a host system including the ultrashort pulse light source 4 or the optical pulse compression device 3 of FIG. It is a flowchart of a target value reception interrupt processing routine. In FIG. 12, when receiving the set target value Et, the controller 60 stores the received set target value Et in a predetermined storage location 684 in step 102, and returns to the main program (FIG. 14) described later.

  FIG. 13 is a flowchart of a repetition frequency reception interrupt processing routine that is called and executed when the controller 60 of FIG. 10 acquires the repetition frequency f (reception value). In FIG. 13, when the controller 60 acquires the repetition frequency f (in the example of FIG. 10, it is received from the electric pulse source or the electronic device 1), the controller 60 stores the acquired repetition frequency reception value f in the storage location 682, and FIG. Return to the main program.

  FIG. 14 is a flowchart showing a flow of processing of the main program of the amplifier control program 64 stored in the nonvolatile memory 62 of the controller 60 of FIG. The program shown in FIG. 14 is called and executed simultaneously with system startup.

  In FIG. 14, the controller 60 first clears the storage location 684 where the set target value Et is stored in step 110 as part of the initialization process. Next, in decision step 112, the repetition frequency reception value f is read from the storage location 682 (hereinafter simply referred to as “reading the repetition frequency reception value f682”), and whether or not the reception value f is in the table 66 is determined. Judgment is made (FIG. 11). When the received value f is in the table 66, in step 114, the laser diode 44 drive control corresponding to the received value f (in this case, fi (i = 1, 2,...)) (This control is performed by the LD drive circuit). 46, which is performed in a closed loop of the laser diode 44, the photodiode 48, the driving power detector 50 and the controller 60), is read out as the corresponding initial value P.

  At this time, it is desirable to store the received value f of the storage location 682 in the storage location 682a as the current value fc of the repetition frequency. Thereby, it is possible to determine whether or not a new received value f has been received by comparing the storage locations 682 and 682a in the subsequent processing.

  If there is no fi that matches the received value f in the determination step 112, the two initial values fi and fi + 1 (i + 1 is a subscript) that are closest to the received value f are complemented, and this complemented value is the corresponding initial value. Let P be the value. In order to perform feedback control at start-up using the initial value P as a target value, in step 118, the set value V of the LD drive circuit 46 is increased by a unit amount from a predetermined initial value (for example, bias value). The initial value P of the target value is compared with the drive power Pd sent from the drive power detector 50. In step 120, whether or not the drive power Pd has approached the initial value P to a predetermined range THp, that is, P-Pd. It is determined whether or not ≦ THp. Step 118 is performed until P-Pd ≦ TH, and when P-Pd ≦ THp, the initial setting of the LD drive circuit 46 is completed, so that the process proceeds to the next step 122 to be in an operating state. .

  In step 122, the storage location 684 of the pulse energy target value Et set by the user or the host system is read to determine whether or not the target value Et has been set. This can be determined by whether or not the clear value of step 110 remains in the memory location 684.

  When the target value Et is not set, in step 123, processing corresponding to reception of the repetition frequency f is performed. That is, by comparing the storage locations 682 and 682a, it is determined whether or not a new repetition frequency f has been received. If it has not been received, if it has received the same value as in step 112, nothing is done. However, if a new repetition frequency f is received, the corresponding initial value P is determined in the same manner as in step 114 or 116 so that the driving power Pd of the laser diode 44 converges to this initial value P. When feedback control is performed and | P−Pd | ≦ THp (the current initial value P may be smaller than the previous value, increase / decrease is performed by positive / negative of P−Pd), step 123 is ended. Regardless of whether or not a new repetition frequency f has been received, the process returns to step 122 after step 123 ends.

  As described above, according to the present invention, immediately after the start when the target value of the energy (pulse energy) of each pulse output from the EDF 32 or the optical amplifier 30 is not set, the initial value P corresponding to the repetition frequency is set. The drive control of the laser diode 44 is performed as a default target value, and is updated to the optimum initial value P every time the repetitive frequency reception value f is changed until the set target value is set. Therefore, the EDF 32 or the optical amplifier 30 The energy of the optical pulse output from the laser is kept constant regardless of the frequency.

In step 122, when the set target value is set in the storage location 684, the process proceeds to determination step 124. In step 124, the repetition frequency reception value f682 and the set target value Et684 are read out, and it is determined whether or not these are in the data table 66. If both are in the data table 66, in step 126, the corresponding target value Et _{j, i} (j = α, β, γ, i = 1, 2,. "Eta", and the values at the storage locations 682 and 694 (that is, the repetition frequency reception value f and the set target value Et) at this time are copied to the corresponding storage locations 682a and 684a, respectively.

On the other hand, if it is determined at the decision step 124 that the repetition frequency received value f682, the set target value Et684, or both of these are not present in the data table 66, the data table 66 is interpolated at step 128. That is, when there is Etj (j = α, β, γ) corresponding only to the set target value Et, the target value Et in the Etj field of the record of the two repetition frequencies f _i and f _{i + 1} closest to the repetition frequency reception value f. _An interpolation value is obtained using _{j, i} and Et _{j, i + 1} . When there is fi (i = 1, 2,...) Corresponding only to the repetitive frequency reception value f, the target values of the fi records in the two set target values Et _j and Et _{j + 1 that} are closest to the set target value Et An interpolation value is obtained using Et _{j, i} and Et _{j + 1, i} . Similarly, if both the repetition frequency received value f and the set target value Et are not in the data table 66, four target values Et _{j, i} , Et _{j, i + 1} , Et _{j + 1, i} and Interpolation is performed using Et _{j + 1, i + 1} to obtain an interpolation value. The interpolation value obtained in this way is set as the current target value Eta.

  As described above, according to the present invention, even if there is no data prepared in advance for the repetition frequency and the set target value, the target value can be set as long as it is within a range that can be complemented from the prepared data by performing complementation. Can be set in stages. Accordingly, the degree of freedom in setting the pulse energy or the pulse width is increased, so that it can be used for a wide range of applications. In addition, since interpolation can include extrapolation as well as interpolation, it should be considered that the range that can be complemented includes the range that can be complemented by extrapolation from the prepared data. .

  In both cases of steps 126 and 128, when the target value is determined, as shown in FIG. 2, the values in the storage locations 682 and 694 (that is, the repetitive frequency reception value f and the set target value Et) correspond to each other. Copy to storage locations 682a and 684a, respectively. After step 126 or 128, the process proceeds to step 130.

After step 130, the LD driving device 46, the laser diode 44, and the EDF 32
The feedback control is performed by a closed loop including the average output power measuring device 54 and the controller 60. In this case, a quotient (that is, energy per light pulse) E obtained by dividing the average output power Ea received from the average output power measuring instrument 54 by the repetition frequency f is obtained as pulse energy, and feedback control is performed based on the pulse energy E. Do.

  That is, in the determination step 130, the current target value Eta and the pulse energy E are compared, and whether or not the difference between Eta and E is equal to or smaller than a predetermined threshold value THe, that is, whether | Eta−E | ≦ THe. Judging. If the determination result is YES, an input check (step 134) described later is performed. If the difference between Eta and E exceeds a predetermined threshold value THe in determination step 130 (in the case of NO), it is determined in step 132 whether Eta-E is positive, and if YES (ie, Eta). -E exceeds THe), in step 136, the control value V of the LD driving device 46 is increased by a unit amount. In step 132, when the determination result is NO (when E-Eta exceeds THe), the control value V of the LD driving device 46 is increased by a unit amount. If the result of determination step 130 is YES, or if step 136 or 138 ends, the process proceeds to input check step 134.

  FIG. 15 is a flowchart showing details of the input check step 134 of FIG. In FIG. 15, in the determination step 140, it is determined whether the current value fc of the repetition frequency stored in the storage location 682 a is the same as the reception frequency f of the repetition frequency stored in the corresponding storage location 682. If they are the same, in a further determination step 142, it is determined whether the current set target value Etc stored in the storage location 684a is the same as the received set target value Et stored in the corresponding storage location 684. If they are the same, there is no change in the set value, so nothing is done and the process returns to step 130 in FIG. 3C.

  If NO in determination step 140 or 142, that is, if any set value is changed, the process returns to step 124 in FIG.

Thereafter, by repeating the processing from step 124 onward, instead of the average energy Ea of the optical pulse output from the optical amplifier 30 or the EDF 32, the pulse energy E per pulse of the optical pulse output from the optical amplifier 30 or the EDF 32 (= Ea / f), and control is performed so that the pulse energy E is constant regardless of the repetition frequency f. Needless to say, since the pulse energy E is constant, the pulse width is also constant.
<Modification of Fifth Embodiment>
In the fifth embodiment, the information of the repetition frequency f is obtained from the electric pulse source or the electronic device 1, but another form of acquiring the repetition frequency f from the outside is also conceivable.

  For example, FIG. 16 is a block diagram showing another form of the pulse light source 2 of FIG. As shown in the figure, the pulse light source 2 may include a control unit 22, and the control unit 22 may output a repetition frequency f of an optical pulse output by itself.

FIG. 17 is a block diagram showing a configuration example of an electro-optical device that can be used in place of the combination of the electric pulse source or electronic device 1 and the pulse light source 2 shown in FIG. As shown in FIG. 17, there may be a configuration in which the electro-optical device 1a includes the pulse light source 2 and the control unit 12a repeatedly outputs the frequency f.
(Sixth embodiment)
In the fifth embodiment described above and the modifications thereof, the controller 60 of the amplification controller 40 of the optical amplifier 30 of the optical pulse compressor 3 of the ultrashort pulse light source 4 repeatedly receives the frequency f from the outside. It is possible to obtain the repetition frequency f inside the amplification controller 40. FIG. 18 is a block diagram showing a configuration of an optical pulse compression device that obtains the repetition frequency f by calculation according to the sixth embodiment of the present invention. The amplification control unit 40a of FIG. 18 includes a conductive line 200 that transmits the output of the photoelectric conversion signal Se obtained by the average output power measuring instrument 54 to the controller 60a, and the program 64a of the nonvolatile memory 64a includes a repetition frequency f calculation routine 202. Except this, it is the same as the amplification control unit 40 of FIG. With this difference, in FIG. 18, the optical pulse compression device is changed from 3 to 3a, and the optical amplifier is changed from 30 to 30a. As is well known to those skilled in the art, the repetition frequency f calculation routine 202 performs a fast Fourier transform (FFT) on the photoelectric conversion signal Se corresponding to the output light pulse of the EDF 32, thereby repeating the repetition frequency of the light pulse. Find f.
<Modification of Sixth Embodiment>
However, in order to keep the pulse energy of the output light pulse constant by sufficiently following the change of the repetition frequency f, it may not be in time to calculate the repetition frequency f by software calculation. In such a case, it is preferable to calculate the repetition frequency not by software but by hardware. In this case, instead of providing the f calculation routine 202, a part (for example, FFT calculation) or all of the repetition frequency calculation processing is used as an FFT calculation unit (not shown) or a repetition frequency calculation unit (not shown). What is necessary is just to insert in the conducting wire 200.
(Seventh embodiment)
In the fifth and sixth embodiments and their modifications described above, the optical pulse compression device 3 includes only one optical amplifier 30. However, the optical pulse compression device can be realized in various forms using a plurality of optical amplifiers.

  FIG. 19 is a block diagram showing a configuration of an optical pulse compression apparatus using a plurality of optical amplifiers according to the seventh embodiment of the present invention. In FIG. 19, the optical pulse compression device 3b has a configuration in which two EDFs 32 and a single mode fiber (SMF) 36 disposed in the subsequent stage are added to the optical pulse compression device 3 of FIG. In such a case, the amplification controller 40 or 40a of the present invention may be provided for each EDF 32. As a result, the pulse energy E or the pulse width of the output light pulse can be kept constant for each optical amplifier based on the EDF 32.

  The above is merely an example of an embodiment for explaining the present invention. Accordingly, it is easy for those skilled in the art to make various changes, modifications, or additions to the above-described embodiments in accordance with the technical idea or principle of the present invention.

  For example, in the embodiment shown in FIG. 18, the repetition frequency f is obtained from an electrical signal obtained by photoelectrically converting the output light pulse of the EDF 32. However, it is also possible to obtain the repetition frequency f by photoelectrically converting the input light pulse of the EDF 32.

(Modification)
In addition, this invention can also be changed and embodied as follows.

  In the pulse generator 301 according to the second and fourth embodiments, the electric pulse generators 501 and 502 apply electric pulse modulation (direct intensity modulation) to the distributed feedback semiconductor laser 500 to change the repetition frequency. Is supposed to occur. Instead of such a direct intensity modulation method, an external modulation method in which continuous light from a light source is modulated by an external modulator such as an LN (LinbO3) intensity modulator may be used.

  In the first and third embodiments, the pulse generator (OPS) 306 is configured by either a direct intensity modulation method like the pulse generator 301 of the second or fourth embodiment or the external modulation method. You may do it.

  In the first, second and fourth embodiments, the CPU 330 refers to the data table stored in the memory and sets the current control initial value according to the repetition frequency f. In each of these embodiments, the output (gain) characteristics of the optical fiber amplifiers 302 and 340 are also unique as in the semiconductor laser, so that the current control initial value according to the repetition frequency f and the characteristics of the optical fiber amplifier to be used May be read with reference to the data table.

  In the first to fourth embodiments, as a fiber compressor formed by connecting a pair of highly nonlinear fiber (HNLF) and single mode fiber (SMF) in multiple stages, not only dispersion but also a nonlinear constant is a comb-like profile. However, the present invention is not limited to this. In place of the comb-like fiber compressor 310, the present invention is also applied to a case where a fiber compressor having a profile of dispersion and nonlinear constant other than the comb-like shape is used.

The block diagram which shows the structure of the ultrashort pulse light source which concerns on 1st Embodiment of this invention. (A)-(f) is a graph which shows the optical spectrum of the input optical pulse from which repetition frequency differs, respectively, (g)-(l) is a graph which shows the autocorrelation waveform of the input optical pulse from which repetition frequency differs, respectively. Explanatory drawing which shows a mode that an input optical pulse is amplified and pulse-compressed. The flowchart which shows the process sequence of AEC control performed with a control unit. (A) is a graph which shows the autocorrelation waveform of an output light pulse, (b) is a graph which shows the optical spectrum of an output light pulse. The graph which shows the repetition frequency dependence of the output characteristic of an output optical pulse. The block diagram which shows the structure of the ultrashort pulse light source which concerns on 2nd Embodiment of this invention. The block diagram which shows the structure of the ultrashort pulse light source which concerns on 3rd Embodiment of this invention. The block diagram which shows the structure of the ultrashort pulse light source which concerns on 4th Embodiment of this invention. The block diagram which shows the structure of the ultrashort pulse light source by 5th Embodiment of this invention. The figure which shows the structural example of the data table stored in the non-volatile memory of FIG. 10, and the flow of the data relevant to this. The flowchart of the interruption process routine performed at the time of reception of the pulse energy control target value (setting target value) supplied from a host system. The flowchart of the repetition frequency reception interruption process routine performed when a controller acquires a repetition frequency (reception value). 11 is a flowchart showing a flow of processing of a main program of an amplifier control program stored in the nonvolatile memory of the controller of FIG. The flowchart which shows the detail of the input check step of FIG. The block diagram which shows another form of the pulse light source of FIG. The block diagram which shows the structural example of the electro-optical apparatus which can be used instead of the combination of the electric pulse source of FIG. 10, or an electronic apparatus, and a pulse light source. The block diagram which shows the structure of the optical pulse compression apparatus which calculates | requires a repetition frequency by calculation by 6th Embodiment of this invention. The block diagram which shows the structure of the optical pulse compression apparatus using several optical amplifier from 7th Embodiment of this invention.

Explanation of symbols

  300A, 300B, 300C, 300D ... Pulse light source 300A, 301 ... Pulse generator, 302, 340 ... Optical fiber amplifier, 303 ... Optical pulse compressor, 304 ... Excitation controller, 305 ... Control unit, 306 ... Optical pulse generator , 310 ... Comb fiber compressor, 311, 312 ... Semiconductor laser, 312, 313 ... Photodiode, 350, 351 ... Normal dispersion optical amplifier, 352 ... Single mode fiber, 500 ... Distributed feedback semiconductor laser, 501 and 502 ... electric pulse generator, 510 ... dispersion compensating fiber.

Claims (4)

Optical pulse generating means for generating an optical pulse train having a variable repetition frequency;
An optical amplification means for optically amplifying each optical pulse of the optical pulse train;
An optical pulse compression means for compressing each optical pulse optically amplified by the optical amplification means using a nonlinear effect of an optical fiber;
An excitation control means for controlling the excitation of the light amplification means,
The excitation control means controls the excitation of the optical amplification means so that the average pulse energy of the optical pulse optically amplified by the optical amplification means becomes constant,
The excitation control means includes a semiconductor laser for exciting the optical amplification means, an optical power detection means for detecting an average power of the optical pulse after optical amplification by the optical amplification means, and a control unit for controlling the semiconductor laser; With
The control unit acquires a repetition frequency of the optical pulse input to the optical amplification unit, sets a current control initial value of the semiconductor laser according to the acquired repetition frequency, and uses the optical power detection unit. Controlling the semiconductor laser so that the average pulse energy, which is a value obtained by dividing the detected average power by the repetition frequency, becomes constant,
It said optical pulse compression means comprises an optical pulse compressor using adiabatic soliton compression, by said optical pulse compression unit, said optical pulse compression which is optically amplified by the optical amplifying means,
The optical pulse generator is an optical pulse generator having a function of outputting an optical pulse train having a variable repetition frequency to the optical amplifier and a function of outputting a digital signal representing the repetition frequency to the control unit. Characteristic pulse light source. Optical pulse generating means for generating an optical pulse train having a variable repetition frequency;
An optical amplification means for optically amplifying each optical pulse of the optical pulse train;
An optical pulse compression means for compressing each optical pulse optically amplified by the optical amplification means using a nonlinear effect of an optical fiber;
An excitation control means for controlling the excitation of the light amplification means,
The excitation control means controls the excitation of the optical amplification means so that the average pulse energy of the optical pulse optically amplified by the optical amplification means becomes constant,
The excitation control means includes a semiconductor laser for exciting the optical amplification means, an optical power detection means for detecting an average power of the optical pulse after optical amplification by the optical amplification means, and a control unit for controlling the semiconductor laser; With
The control unit acquires a repetition frequency of the optical pulse input to the optical amplification unit, sets a current control initial value of the semiconductor laser according to the acquired repetition frequency, and uses the optical power detection unit. Controlling the semiconductor laser so that the average pulse energy, which is a value obtained by dividing the detected average power by the repetition frequency, becomes constant,
It said optical pulse compression means comprises an optical pulse compressor using adiabatic soliton compression, by said optical pulse compression unit, said optical pulse compression which is optically amplified by the optical amplifying means,
The pulse generation means includes a distributed feedback semiconductor laser, and an electric pulse generator that outputs an electric pulse and drives the distributed feedback semiconductor laser with a gain switch.
The electric pulse generator has a function of generating an electric pulse with a variable repetition frequency,
The distributed feedback semiconductor laser generates an optical pulse having a variable repetition frequency by causing a gain switch oscillation by injection of an electric pulse output from the electric pulse generator,
The pulse light source, wherein the electric pulse generator outputs a digital value representing a repetition frequency of the optical pulse directly to the control unit. Optical pulse generating means for generating an optical pulse train having a variable repetition frequency;
An optical amplification means for optically amplifying each optical pulse of the optical pulse train;
An optical pulse compression means for compressing each optical pulse optically amplified by the optical amplification means using a nonlinear effect of an optical fiber;
An excitation control means for controlling the excitation of the light amplification means,
The excitation control means controls the excitation of the optical amplification means so that the average pulse energy of the optical pulse optically amplified by the optical amplification means becomes constant,
The excitation control means includes a semiconductor laser for exciting the optical amplification means, an optical power detection means for detecting an average power of the optical pulse after optical amplification by the optical amplification means, and a control unit for controlling the semiconductor laser; With
The control unit acquires a repetition frequency of the optical pulse input to the optical amplification unit, sets a current control initial value of the semiconductor laser according to the acquired repetition frequency, and uses the optical power detection unit. Controlling the semiconductor laser so that the average pulse energy, which is a value obtained by dividing the detected average power by the repetition frequency, becomes constant,
It said optical pulse compression means comprises an optical pulse compressor using adiabatic soliton compression, by said optical pulse compression unit, said optical pulse compression which is optically amplified by the optical amplifying means,
The optical pulse generator is an optical pulse generator having a function of outputting an optical pulse train having a variable repetition frequency to the optical amplifier,
The excitation control means further includes an optical pulse detection means for receiving each optical pulse of the optical pulse train output from the optical pulse generation means,
The optical pulse light source, wherein the control unit obtains a repetition frequency of the optical pulse train by performing fast Fourier transform on time data of each optical pulse received by the optical pulse detector. The optical pulse compression unit includes a fiber compressor formed by connecting a pair of a highly nonlinear fiber and a single mode fiber in multiple stages, and the optical pulse amplified by the optical amplification means by the fiber compressor. The optical pulse light source according to any one of claims 1 to 3, wherein the optical pulse light source is compressed.