JP2003247895A - Sonogram measuring apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a sonogram measuring apparatus capable of continuously changing output period of a reference short pulse light while the optical path length of the reference short pulse light is made constant. <P>SOLUTION: A short pulse light generating apparatus 2 comprises a fiber laser 11, an acoustooptic modulator 12, a polarization maintaining optical fiber F1, and an optical filter 15, etc. The soliton pulse of each short pulse light outputted from the short pulse light generating apparatus 2 is used as a reference short pulse light, which is superposed with a short pulse light, which is to be measured, whose spectrum is extracted using a wavelength selecting filter 42, on a PBS 32, and is then made incident on an avalanche photodiode 33. The signal from the avalanche photodiode 33 is observed with an oscilloscope 34. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a sonogram measuring device for measuring the time distribution of the spectrum of short pulse light having a picosecond or femtosecond pulse width.

[0002]

2. Description of the Related Art Conventionally, there is a cross-correlation measuring method as one of the methods for measuring the time waveform of short pulsed light. In this cross-correlation measurement method, on an optical receiver or a nonlinear crystal that has a nonlinear effect, the output time difference between the short pulse light for measurement and the short pulse light for reference is continuously changed while The pulsed light and the short pulsed light for reference are superposed, and at this time, due to the non-linear optical effect, a signal due to the component in which the short pulsed light for measurement and the short pulsed light for reference are overlapped is generated. By observing the signal, the time waveform of the short pulsed light to be measured is measured.

Therefore, if the pulse width of the short pulse light for reference is sufficiently shorter than that of the short pulse light to be measured, the time waveform of the short pulse light to be measured can be accurately and directly measured. Even if the intensity of the short pulse light to be measured is weak, the time waveform of the short pulse light to be measured can be measured by increasing the intensity of the short pulse light for reference.
Therefore, the cross-correlation measurement method is widely used to measure the time waveform of short pulsed light with a short time width.

On the other hand, in recent years, wavelength-multiplexed optical communication has attracted attention as a next-generation large-capacity optical communication, and in order to apply a technique such as pulse wavelength control by controlling chromatic dispersion,
It is becoming important to measure the time distribution of the spectrum of short pulsed light. In this respect, the sonogram measurement method is one of the methods for measuring the time distribution of the spectrum of the short pulse light. This sonogram measurement method obtains the time waveform of the wavelength component by measuring the short pulse light of the measurement object which has passed through the wavelength selection filter and has only a certain wavelength component in advance by the cross-correlation measurement method described above. It is a technique. Therefore, by using this sonogram measurement method, the time distribution of the spectrum of the short pulsed light can be measured with a relatively simple measurement system.

[0005]

However, in the cross-correlation measuring method carried out in the conventional sonogram measuring method, the output time difference between the short pulse light to be measured and the short pulse light for reference is continuously measured. To change, for example,
The optical path length of the reference short pulse light is changed by interposing a mirror or the like on the optical path of the reference short pulse light and mechanically moving the mirror or the like. There is a problem that the optical path of light is likely to shift.

Therefore, in recent years, from the viewpoint of avoiding the deviation of the optical path of the short-pulse light for reference, the output time of the short-pulse light for reference is not required without performing mechanical operation for moving the mirror or the like. It was desired to continuously change.

Therefore, the present invention has been made in order to solve the above-mentioned problems, and the output time of the reference short pulse light is kept constant while keeping the optical path length of the reference short pulse light constant. An object of the present invention is to provide a sonogram measuring device that can be continuously changed.

[0008]

The invention according to claim 1 made in order to solve this problem is a sonogram measuring device for measuring the time distribution of the spectrum of the short pulse light of the measuring object. Of the short pulse light is incident and transmitted, and a wavelength selection filter for extracting the spectrum of the short pulse light of the measuring object which is being transmitted, a short pulse light generation device for outputting the short pulse light for reference, and the wavelength selection filter By observing the cross-correlation signal generated by superimposing the short pulse light of the measurement target from the short pulse light and the reference short pulse light from the short pulse light generation device while continuously changing the output time, the wavelength A cross-correlation measuring device that measures the time waveform of the short pulsed light to be measured from the selection filter,
The short pulse light generation device, while repeatedly outputting each short pulse light at a constant interval, a short pulse light source for changing the wavelength of each short pulse light, each short pulse light from the short pulse light source. It is characterized by having an optical fiber for incident / propagation / output.

In the sonogram measuring apparatus of the present invention having such characteristics, the cross-correlation measuring apparatus (the short time of the measuring object while continuously changing the output time difference between the short pulse light of the measuring object and the short pulse light of the reference) is used. (The time waveform of the short pulse light to be measured is measured through the observation of the cross-correlation signal generated by superimposing the pulsed light and the short pulse light for reference.) The measured time distribution of the spectrum of the short pulse light of the measurement target is used by using the light output from the short pulse light generator as the short pulse light of the measurement target To do.

In this respect, in the short pulse light generator, each short pulse light repeatedly output from the short pulse light source at a constant interval is made incident on the optical fiber, propagated, and output. At this time, the dispersion value of the optical fiber changes depending on the wavelength, and the propagation velocity of each short pulse light in the optical fiber depends on the wavelength of the short pulse light. By changing the wavelength of each short pulsed light by the short pulsed light source when the light is made incident on, the output time of the short pulsed light output from the optical fiber can be adjusted.

That is, in the sonogram measuring device of the present invention, in the short pulse light generation device, when the short pulse light repeatedly output from the short pulse light source is made incident on the optical fiber, each short pulse light source is used. By changing the wavelength of the pulsed light, the output time of the short pulsed light output from the optical fiber can be adjusted, so that the one output from the short pulsed light generator is used as the short pulsed light for reference. By doing so, the output time of the short pulse light for reference can be continuously changed while keeping the optical path length of the short pulse light for reference constant. Further, the sonogram measuring device of the present invention is provided with a short pulse light generation device capable of continuously changing the output time of the short pulse light while keeping the optical path length of the short pulse light constant. Since each short pulse light output from the light generation device is used as the reference short pulse light, it is possible to avoid the occurrence of the deviation of the optical path of the reference short pulse light, and to wipe the weakness against mechanical vibration. Miniaturization is possible.

The invention according to claim 2 is a sonogram measuring apparatus for measuring the time distribution of the spectrum of the short pulsed light to be measured, wherein the short pulsed light to be measured is incident / transmitted and is being transmitted. A wavelength selection filter that extracts the spectrum of the short pulse light of the measurement target, a short pulse light generation device that outputs the short pulse light for reference, a short pulse light of the measurement target from the wavelength selection filter and the short pulse light generation By observing the cross-correlation signal generated by overlapping the reference short pulse light from the device while the output time difference is continuously changing, the time waveform of the short pulse light to be measured from the wavelength selection filter is obtained. A cross-correlation measuring device for measuring is provided, and the short pulse light generation device is a short pulse light source that repeatedly outputs each short pulse light at a constant interval,
Each short pulse light from the short pulse light source enters and transmits, and a light intensity adjuster that changes the intensity of each short pulse light being transmitted, and each short pulse light from the light intensity adjuster enters and propagates. An output optical fiber is provided.

In the sonogram measuring apparatus of the present invention having such characteristics, the cross-correlation measuring apparatus (the short time of the measuring object while continuously changing the output time difference between the short pulse light of the measuring object and the short pulse light of the reference) is used. (The time waveform of the short pulse light to be measured is measured through the observation of the cross-correlation signal generated by superimposing the pulsed light and the short pulse light for reference.) The measured time distribution of the spectrum of the short pulse light of the measurement target is used by using the light output from the short pulse light generator as the short pulse light of the measurement target To do.

In this respect, in the short pulse light generation device, each short pulse light repeatedly output from the short pulse light source at a constant interval is made incident on the optical fiber through the light intensity adjuster,
Propagate and output. At this time, the wavelength of each short pulse light propagating in the optical fiber shifts based on the intensity of the short pulse light, while the dispersion value of the optical fiber changes depending on the wavelength. Since the propagation velocity of the short pulse light depends on the wavelength of the short pulse light, when each short pulse light from the short pulse light source is incident on the optical fiber via the light intensity adjuster, each short pulse light is adjusted by the light intensity adjuster. By changing the intensity of, the output time of the short pulse light output from the optical fiber can be adjusted.

That is, in the sonogram measuring device of the present invention, in the short pulse light generation device, when each short pulse light from the short pulse light source is incident on the optical fiber via the light intensity adjuster, the light intensity adjuster is used. By changing the intensity of each short pulsed light, the output time of the short pulsed light output from the optical fiber can be adjusted. As a result, the output time of the short pulse light for reference can be continuously changed while keeping the optical path length of the short pulse light for reference constant. Further, the sonogram measuring device of the present invention is provided with a short pulse light generation device capable of continuously changing the output time of the short pulse light while keeping the optical path length of the short pulse light constant. Since each short pulse light output from the light generation device is used as the reference short pulse light, it is possible to avoid the occurrence of the deviation of the optical path of the reference short pulse light, and to wipe the weakness against mechanical vibration. Miniaturization is possible.

Further, the invention according to claim 3 is the sonogram measuring device according to claim 2, wherein the short pulse light generation device uses the light intensity adjuster to control the intensity of each short pulse light being transmitted. Changing based on an electrical signal,
Is characterized.

That is, in the sonogram measuring device of the present invention, in the short pulse light generation device, when each short pulse light from the short pulse light source is incident on the optical fiber via the light intensity adjuster, the light intensity adjuster is used. Since the intensity of each short pulsed light is changed based on the electrical signal, it is possible to make a continuous change in the output time of the short pulsed light for reference more finely and more accurately. Further, in the sonogram measuring device of the present invention, when a light intensity adjuster that changes the intensity of each short pulse light being transmitted based on an electric signal is used in the short pulse light generating device, Since the output time difference between the short pulse light and the reference short pulse light can be made more finely and more accurately,
It is possible to improve the resolution.

The invention according to claim 4 is the sonogram measuring device according to claim 3, wherein the short pulse light generation device is an optical filter through which each short pulse light from the optical fiber enters and transmits. The optical fiber separates each propagating short pulse light into a pump pulse and a soliton pulse, while the optical filter transmits only a soliton pulse in each short pulse light incident from the optical fiber. It is characterized by

That is, in the sonogram measuring device of the present invention, in the short pulse light generation device, when the wavelength of each short pulse light propagating in the optical fiber shifts based on the intensity of the short pulse light, the optical fiber By separating each short pulse light propagating in the inside into a pump pulse and a soliton pulse, even if each short pulse light is output from the optical fiber in a state where it is separated into a pump pulse and a soliton pulse, each short pulse light from the optical fiber In the optical filter that allows the pulsed light to enter / transmit, only the soliton pulse in each short pulsed light incident from the optical fiber is transmitted, so that only the soliton pulse can be output as the short pulsed light for reference. At the same time, the continuous change of the output time can be performed more finely and more accurately. Further, in the sonogram measuring device of the present invention, when the short pulse light generation device is provided with an optical filter for entering and transmitting each short pulse light from the optical fiber, it propagates in the optical fiber of the short pulse light generation device. Even if each short pulse light inside is separated into a pump pulse and a soliton pulse, only the soliton pulse of each short pulse light passes through the optical filter and becomes a short pulse light for reference. No noise will be generated.

Here, the pump pulse does not mean only the one completely separated from the soliton pulse, but also the remaining pumping light component which is not converted into soliton.

The invention according to claim 5 is the sonogram measuring device according to claim 3 or 4, wherein the short pulse light generation device includes an acousto-optic modulator as the light intensity adjuster. It is characterized by The invention according to claim 6 is the sonogram measurement device according to any one of claims 1 to 5, wherein the short pulse light generation device includes a fiber laser as the short pulse light source. , Is characterized. The invention according to claim 7 is the sonogram measuring device according to any one of claims 1 to 6, wherein the short pulse light generation device is a polarization maintaining type optical fiber. Is provided.

In the present invention, an acousto-optic modulator or the like is used as the light intensity adjuster. Also,
For example, a fiber laser is used as the short pulse light source. Further, as the optical fiber, for example, a polarization maintaining type is used.

The invention according to claim 8 is the sonogram measuring device according to any one of claims 1 to 7, wherein the short pulse light of the measuring object being transmitted is transmitted by the wavelength selection filter. Is extracted based on an electrical signal.

That is, in the sonogram measuring apparatus of the present invention, when the wavelength selection filter transmits the short pulse light of the measurement object, the spectrum of the short pulse light of the measurement object being transmitted by the wavelength selection filter is extracted. Since the change is made based on the electric signal, it is possible to make the continuous change of the spectrum of the short pulse light of the measurement object more finely and more accurately. Further, in the sonogram measuring device of the present invention, when using a wavelength selection filter that changes the extraction of the spectrum of the short pulse light of the measuring object being transmitted based on the electrical signal, the short measuring object Since the continuous change of the spectrum of the pulsed light can be performed more finely and more accurately, the resolution can be improved.

The invention according to claim 9 is the sonogram measuring apparatus according to claim 8, characterized in that the wavelength selection filter is an acousto-optic modulator.

In the present invention, an acousto-optic modulator or the like is used as the wavelength selection filter.

The invention according to claim 10 is the first aspect.
The sonogram measuring apparatus according to claim 9, wherein an optical device is installed before or after the wavelength selection filter.

That is, in the sonogram measuring apparatus of the present invention, if an optical device is installed before or after the wavelength selection filter, the time distribution of the spectrum of the short pulsed light of the measuring object transmitted through the optical device can be measured. Therefore, at this time, for example, by analyzing the wavelength-dependent characteristics such as the wavelength dispersion value of the optical device, the time response, and the like, it becomes possible to evaluate the optical device for the short pulse light to be measured.

However, when the evaluation of the optical device with respect to the short pulse light to be measured is performed by measuring the wavelength-dependent characteristics such as the wavelength dispersion value of the optical device, the optical device is placed before or after the wavelength selection filter. However, if the measurement is performed by measuring the time response of the optical device, the optical device must be installed before the wavelength selection filter.

The invention according to claim 11 is the first aspect.
The sonogram measurement device described in 0, characterized in that the short pulse light to be measured is supercontinuum light.

In particular, in recent years, it is expected that the supercontinuum light having a wide spectrum will be widely used in the fields of optical electronics and various spectroscopic measurements, including optical communication in which the broadband and high speed have been advanced. Therefore, in the sonogram measurement device of the present invention, if the supercontinuum light is the short pulse light of the measurement target, the effect of evaluating the optical device for the short pulse light of the measurement target can be greatly exerted. .

The invention according to claim 12 is the invention according to claim 1.
The sonogram measurement apparatus according to claim 11, wherein the cross-correlation measurement apparatus includes an amplifier for increasing the output of the cross-correlation signal,
Is characterized by.

That is, in the sonogram measuring apparatus of the present invention, if the cross-correlation measuring apparatus is provided with an amplifier for increasing the output of the cross-correlation signal, the one whose spectrum is extracted by the wavelength selection filter is a short object to be measured. By using it as pulsed light, the cross-correlation signal can be observed with high sensitivity even if the pulse energy of the short pulsed light to be measured is weak.

[0034]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings. First, a short pulse light generation device used in the sonogram measurement device of the present embodiment will be described. FIG. 6 shows a basic configuration diagram of the short pulse light generation device. As shown in FIG. 6, the short pulse light generation device 2 includes a fiber laser 11 that is a “short pulse light source”.
And an acousto-optic modulator 12, which is a “light intensity adjuster”, condenser lenses 13 and 14, a polarization-maintaining optical fiber F1, an optical filter 15, and the like.

In this respect, the fiber laser 11 is of a passive mode-locking type composed of an Er-doped fiber amplifier, and outputs short pulse light having a pulse width of 100 fs and a wavelength of 1.56 μm repeatedly at a cycle of 48 MHz. To do. The acousto-optic modulator 12 receives each short pulse light output from the fiber laser 11, and can change the intensity of each short pulse light based on an electrical signal.

Further, the optical fiber F1 is one in which each short pulse light transmitted through the acousto-optic modulator 12 is incident through the condenser lens 13, and is a polarization maintaining type having a small diameter. . In the optical fiber F1, each short pulse light from the acousto-optic modulator 12 propagates, so that each short pulse light is separated into a pump pulse and a soliton pulse as shown in FIG. Further, the optical filter 15 is one in which each short pulse light from the optical fiber F1 is incident through the condenser lens 14, and only the soliton pulse is transmitted by removing only the pump pulse of each short pulse light. It is a thing.

In the short pulse light generator 2 of FIG. 6, when the intensity of each short pulse light is changed by the acousto-optic modulator 12, the center wavelength of the soliton pulse of each short pulse light is the intensity of the short pulse light. Since it shifts depending on, the central wavelength of the soliton pulse of each short pulse light can be changed. On the other hand, the polarization-maintaining optical fiber F1 has characteristics of chromatic dispersion, and exhibits abnormal dispersion characteristics in which the group velocity is monotonically slower as the wavelength of the short pulse light being propagated is longer. Therefore, by increasing / decreasing the intensity of each short pulse light in the acousto-optic modulator 12 and shifting the central wavelength of the soliton pulse of each short pulse light, the time when the soliton pulse of each short pulse light is output from the optical filter 15 is reduced. Can be adjusted.

Here, FIG. 7 shows a short pulse light generation device 2
The basic block diagram of the system that observes the output of is shown. In the short pulse light generation device 2 in the observation system in FIG. 7, the personal computer 23 issues an electric signal for changing the intensity of each short pulse light in the acousto-optic modulator 12, and the microcomputer 24 and D / It is applied to the acousto-optic modulator 12 using the A converter 25. Further, in the short pulse light generation device 2 in the observation system of FIG. 7, the output time difference between the pump pulse and the soliton pulse of each short pulse light output from the polarization maintaining optical fiber F1 (see FIG. 8) is shown in FIG. To observe with the observation system,
The optical filter 15 is removed.

In the observation system of FIG. 7, the pump pulse and soliton pulse of each short pulse light output from the polarization maintaining type optical fiber F1 are received by the PIN photodiode 26 and observed by the sampling oscilloscope 28. To be done. At this time, the sampling oscilloscope 2
The trigger signal 8 is generated by splitting a part of the short pulse light output from the fiber laser 11 by the PBS 21 and receiving it by the PIN photodiode 27.

In the short pulse light generator 2 in the observation system shown in FIG. 7, the short pulse light output from the fiber laser 11 is easily split by the PBS 21 so that the short pulse light is separated by 1/2 between the fiber laser 11 and the PBS 21. A wave plate H1 is provided. In addition, the acousto-optic modulator 12
A half-wave plate H2 is provided between the acousto-optic modulator 12 and the optical fiber F1 in order to match the short pulse light from the optical fiber F1 with the polarization plane of the polarization-maintaining optical fiber F1. On the other hand, the condenser lenses 13 and 14 (see FIG. 6) are also used in the short pulse light generation device 2 in the observation system in FIG. 7, but are not shown in FIG.

FIG. 8 shows a typical time waveform of the short pulse light observed by the observation system of FIG. 7, and the output time difference between the pump pulse and the soliton pulse of the short pulse light output from the optical fiber F1 is , And varies depending on the intensity of the short pulse light incident on the optical fiber F1 and the length of the optical fiber F1.

For example, FIG. 9 shows an optical fiber F1 of the short pulse light generator 2 in the observation system of FIG.
Is the observation result of the observation system of FIG.
As shown in FIG. 9, when the electric signal applied to the acousto-optic modulator 12 (applied voltage on the horizontal axis in FIG. 9) is changed, the optical fiber F1 is changed.
It can be seen that the output time difference (vertical axis in FIG. 9) between the pump pulse and the soliton pulse of the short pulsed light output from the output changes. Furthermore, the output time difference between the pump pulse and the soliton pulse of the short pulse light output from the optical fiber F1 (see FIG.
It can be seen that the change in the vertical axis of (1) also depends on the intensity of the short pulse light output from the fiber laser 11 (parameter in FIG. 9).

Further, FIG. 10 shows the observation result of the observation system of FIG. 7 when the optical fiber F1 of the short pulse light generator 2 in the observation system of FIG. 7 is 25 m. When the electric signal applied to the container 12 (applied voltage on the horizontal axis in FIG. 10) is changed, the optical fiber F
It can be seen that the output time difference between the pump pulse and the soliton pulse of the short pulse light output from No. 1 (vertical axis in FIG. 10) changes. Furthermore, the change in the output time difference between the pump pulse and the soliton pulse of the short pulse light output from the optical fiber F1 (vertical axis in FIG. 10) is determined by the intensity of the short pulse light output from the fiber laser 11 (parameter in FIG. 10). It turns out that also depends on.

Comparing FIG. 9 and FIG. 10, when the optical fiber F1 of the short pulse light generator 2 is shortened, the output time difference between the pump pulse and the soliton pulse of the short pulse light output from the optical fiber F1 (see FIG. 9 and the vertical axis of FIG. 10)
It can be seen that changes more finely.

From this, the output time of the soliton pulse of each short pulse light output from the short pulse light generator 2 is
Although it depends on the intensity of the short pulsed light output from the fiber laser 11 and the length of the optical fiber F1, if these conditions are fixed, the electrical signal applied to the acousto-optic modulator 12 can be arbitrarily set. Can be changed.

FIG. 14 shows an example of the autocorrelation waveform of the soliton pulse of the short pulsed light output from the short pulsed light generator 2. In the autocorrelation waveform of FIG. 14, the full width at half maximum (FWHM) is 185 fs, and the corresponding time width (P
The pulse width is 120 fs. Further, FIG. 15 shows an example of a spectrum waveform of a soliton pulse of short pulse light output from the short pulse light generation device 2.
Both the autocorrelation waveform of FIG. 14 and the spectrum waveform of FIG. 15 have ideal sech ² type pulse waveform shapes. That is, the soliton pulse of the short pulse light output from the short pulse light generation device 2 has an ideal sec.
It is formed into an h ² -type pulse waveform.

From the above, in the short pulse light generator 2,
As shown in FIG. 7, short pulse light (having a pulse width of 100 fs and a wavelength of 1.56 μm) repeatedly output from the fiber laser 11 at regular intervals (cycle of 48 MHz) is passed through the acousto-optic modulator 12. Then, when it is incident on the polarization maintaining optical fiber F1, each short pulse light propagating through the polarization maintaining optical fiber F1 is separated into a pump pulse and a soliton pulse (see FIG. 8). Then, when each short pulse light separated into the pump pulse and the soliton pulse is made incident on the optical filter 15, only the soliton pulse of each short pulse light is transmitted, so only the soliton pulse of each short pulse light is output.

At this time, when the intensity of each short pulse light is changed by the acousto-optic modulator 12 based on the electric signal (voltage of triangular wave, etc.), each short pulse light is generated in the polarization maintaining optical fiber F1. The central wavelength of the soliton pulse generated from the above shifts depending on the intensity of the short pulse light. On the other hand, since the dispersion value of the polarization-maintaining optical fiber F1 changes depending on the wavelength, the propagation velocity of the soliton pulse of each short pulse light in the polarization-maintaining optical fiber F1 depends on the center wavelength of the soliton pulse. It will be.

That is, in the short pulse light generator 2,
When the short pulse light repeatedly output from the fiber laser 11 at regular intervals is incident on the polarization maintaining optical fiber F1, the intensity of each short pulse light is changed by the acousto-optic modulator 12 based on an electrical signal. By doing so, it becomes possible to change the output time of the soliton pulse of each short pulse light output from the polarization maintaining type optical fiber F1 via the optical filter 15, so that the electrical operation (from the personal computer 23 Command), the output time of each short pulsed light (soliton pulse) can be continuously changed (see FIGS. 9 and 10).

Next, the cross-correlation measuring device used in the sonogram measuring device of this embodiment will be described. However, for convenience of description, the description of the cross-correlation measuring device described later will be made in a form including the configuration of the short pulse light generation device 2 described above. FIG. 11 shows a basic configuration diagram of the cross-correlation measuring device. As shown in FIG.
In the cross-correlation measuring apparatus 100, the soliton pulse of each short pulse light output from the above-mentioned short pulse light generating apparatus 2 is used as the short pulse light for reference, and the PBS 32 is used.
On top of the
It is incident on the avalanche photodiode 33 which is a two-photon absorption detector. At this time, in the avalanche photodiode 33, the two-photon absorption characteristic strongly appears only when the short pulse light to be measured and the short pulse light for reference overlap, so that a cross-correlation signal can be obtained. Then, the cross-correlation signal from the avalanche photodiode 33 is observed by the oscilloscope 34.

Therefore, the cross-correlation measuring apparatus 100 of FIG.
In, the acousto-optic modulator 1 of the short pulse light generation device 2
If an electric signal having a triangular wave voltage is applied to 2, it is possible to continuously change the output time of the soliton pulse (reference short pulse light) of each short pulse light output from the short pulse light generation device 2. Therefore, by further synchronizing the output of the short pulse light to be measured with the output of the fiber laser 11, the time waveform of the short pulse light to be measured can be observed by the oscilloscope 34.

Further, in the cross-correlation measuring device 100 of FIG. 11, the fiber laser 1 of the short pulse light generating device 2 is used.
If the short pulse light output from 1 is branched into the short pulse light to be measured, the soliton pulse generated from the short pulse light of its own can be used as the reference short pulse light, so that it is self-correlated with each other. Correlation measurements can be performed.

In the short pulse light generator 2 in the cross-correlation measuring apparatus 100 of FIG. 11, the fiber laser 11 is used.
The fiber laser 11 and the acousto-optic modulator 1 are used to adjust the short pulsed light from the light to the polarization plane of the acousto-optic modulator 12.
A half-wave plate H1 is provided between the two. Further, in order to match the short pulse light from the acousto-optic modulator 12 with the polarization plane of the polarization-maintaining optical fiber F1, a half-wave plate H2 is provided between the acousto-optic modulator 12 and the optical fiber F1. ing. On the other hand, condenser lenses 13 and 14 (see FIG. 6)
Is also used in the short pulse light generation device 2 in the cross-correlation measuring device 100 of FIG. 11, but it is omitted in FIG. Further, the microcomputer 24 and the D / A converter 25 (see FIG. 7) are also used in the short pulse light generation device 2 in the cross-correlation measuring device 100 in FIG. 11, but they are omitted in FIG. 11.

Further, in the cross-correlation measuring apparatus 100, as shown in FIG.
The short-pulse light output from the optical fiber F2 is a polarization-maintaining optical fiber
It is possible to observe the pump pulse and the soliton pulse that separate during the propagation of. FIG. 13 shows an example of the observation result at this time. Further, FIG. 16 shows a spectrum waveform of the short pulse light (short pulse light to be measured) propagating through the optical fiber F2, which is measured by an analyzer, and the length of the pump pulse of the short pulse light is long due to the influence of Raman scattering. It captures the state where the wavelength side is amplified and begins to split.

In the short pulse light generating device 2 in the cross correlation measuring device 100 of FIG. 12, the fiber laser 11 is used.
A half-wave plate H1 is provided between the fiber laser 11 and the PBS 21 so that the short pulse light output from the PBS 21 can be easily branched by the PBS 21. In order to match the short pulsed light from the acousto-optic modulator 12 with the polarization plane of the polarization-maintaining optical fiber F1, the acousto-optic modulator 12
The half-wave plate H2 is provided between the optical fiber F1 and the optical fiber F1. On the other hand, the condenser lenses 13 and 14 (see FIG. 6) are also used in the short pulse light generation device 2 in the cross-correlation measuring device 100 in FIG. 12, but are not shown in FIG.

Further, in FIG. 12, in order to align the short pulsed light from the PBS 21 with the polarization plane of the polarization-maintaining optical fiber F2, 1 / PBS is provided between the PBS 21 and the optical fiber F2.
A two-wave plate H3 is provided. Further, in order to adjust the optical path length of the short pulse light to be measured, two mirrors 35 are used.
The adjusting means 35 composed of A and 35B has optical fibers F2 and P.
It is provided between BS32. Although not shown, condenser lenses are provided before and after the optical fiber F2.

Next, the sonogram measuring apparatus of this embodiment will be described. FIG. 1 shows a basic configuration diagram of the sonogram measuring apparatus according to the present embodiment. As shown in FIG. 1, the sonogram measuring apparatus 1 of the present embodiment includes a short pulse light generating apparatus 2, a cross correlation measuring apparatus 100, a wavelength selection filter (AOTF) 42 which is an acousto-optic modulator, and the like. And the cross-correlation measuring device 100 (the same as that of FIG. 11) that uses the soliton pulse of each short pulse light output from the short pulse light generation device 2 as the short pulse light for reference.
In the above, the light whose spectrum has been extracted by the wavelength selection filter 42 is used as the short pulse light to be measured.

In this respect, the wavelength selection filter 42 will be described. An electrical signal for extracting a specific spectrum of the short pulse light to be measured is the same as that used in the personal computer 23 (short pulse light generator 2). ) From the wavelength selection filter 42 via a microcomputer and a D / A converter (not shown).
Is being applied to. Further, in front of the wavelength selection filter 42, a ½ wavelength plate 41 is provided in order to match the short pulse light to be measured with the polarization plane of the wavelength selection filter 42.

Therefore, in the sonogram measuring apparatus 1 of FIG. 1, the acousto-optic modulator 12 of the short pulse light generator 2 has an electric signal of a triangular wave voltage (for example, as shown in FIG.
By applying a pulse having a period of 1 ms or less), the output time of the soliton pulse (short pulse light for reference) of each short pulse light output from the short pulse light generator 2 is continuously changed, and By applying an electric signal to the wavelength selection filter 42 while synchronizing the output of the short pulse light of the measurement target with the output of the fiber laser 11, each short pulse light entering the wavelength selection filter 42 (short pulse light of the measurement target 2), if only a specific spectrum is extracted and output from the wavelength selection filter 42, the time waveform of the specific spectrum can be observed by the oscilloscope 34 for the short pulse light to be measured. Further, here, if the spectrum of the short pulse light of the measurement target extracted by the wavelength selection filter 42 is swept (continuously changed),
The time distribution of the spectrum of the short pulse light to be measured can be measured.

In the sonogram measuring apparatus 1 of FIG. 1, in the cross-correlation measuring apparatus 100, a Lock-in amplifier 44 which is an "amplifier" is provided between the avalanche photodiode 33 and the oscilloscope 34. With this Lock-in amplifier 44, in the avalanche photodiode 33, the two-photon absorption signal (cross-correlation signal) that strongly appears only when the short pulse light to be measured and the short pulse light for reference overlap each other is highly sensitive. Can be detected with.

Further, the Lock-in amplifier 44 also has a function of removing the effect of the so-called "pedestal portion" of the soliton pulse of the reference short pulse light on the cross-correlation signal. That is, the intensity of the soliton pulse (reference short pulse light) of each short pulse light output from the short pulse light generation device 2 is the voltage of the triangular wave applied to the acousto-optic modulator 12 of the short pulse light generation device 2. Of the two-photon absorption signal (cross-correlation signal) from the avalanche photodiode 33, as shown by the solid line in FIG. It includes the above-mentioned "pedestal part". However, by using the Lock-in amplifier 44, the "pedestal portion" can be removed as shown by the solid line in FIG. 17 and 18 are observed with the oscilloscope 34, and the two-dot chain line in FIGS. 17 and 18 indicates the triangular wave voltage applied to the acousto-optic modulator 12 of the short pulse light generation device 2. The electric signals of are simultaneously observed and shown.

In the short pulse light generator 2 in the sonogram measuring device 1 of FIG. 1, the fiber laser 11 and the acousto-optical modulator are arranged to adjust the short pulse light from the fiber laser 11 to the polarization plane of the acousto-optical modulator 12. Bowl 12
The half-wave plate H1 is provided between the two. Further, in order to match the short pulse light from the acousto-optic modulator 12 with the polarization plane of the polarization-maintaining optical fiber F1, the acousto-optic modulator 1
2 and the optical fiber F1 are provided with a half-wave plate H2. On the other hand, the condenser lenses 13 and 14 (see FIG. 6) are
Although it is also used in the short pulse light generation device 2 in the sonogram measurement device 1 of FIG. 1, it is omitted in FIG. In addition, the microcomputer 24 and the D / A converter 2
5 (see FIG. 7) is also used in the short pulse light generation device 2 in the sonogram measurement device 1 in FIG. 1, but is not shown in FIG.

Further, in the sonogram measuring apparatus 1 of FIG. 1, if the short pulse light output from the fiber laser 11 of the short pulse light generating apparatus 2 is branched into the short pulse light to be measured, the short pulse of its own is obtained. Since the soliton pulse generated from light can be used as the short pulse light for reference, the time distribution of the spectrum of the short pulse light to be measured can be obtained by performing the autocorrelation cross correlation measurement method with the cross correlation measurement apparatus 100. Can be measured.

For example, in the sonogram measuring apparatus 1, as shown in FIG. 2, the pump pulse separated from the short pulse light output from the short pulse light generating apparatus 2 during the propagation of the polarization maintaining optical fiber F2. And the soliton pulse, the time distribution of the spectrum can be measured. FIG. 3 shows an example of the measurement result at this time. In FIG. 3, the intensity of the short pulse light is shown in shades, and the darker the color, the stronger the intensity of the short pulse light. In this respect, since the lower right component of FIG. 3 shows a clean striped pattern, it can be seen that it is a soliton pulse split from the pump pulse. Further, the upper left component of FIG. 3 is the remaining pump pulse that has not been converted into a soliton pulse. Therefore, in the sonogram measuring device 1 of FIG. 2, as shown in FIG. 3, the soliton pulse splits from the pump pulse.
The process of formation can be stably measured.

In the short pulse light generating device 2 in the sonogram measuring device 1 of FIG. 2, in order to make it easier for the short pulse light output from the fiber laser 11 to be branched by the PBS 21, there is 1 between the fiber laser 11 and the PBS 21. /
A two-wave plate H1 is provided. Further, in order to match the short pulsed light from the acousto-optic modulator 12 with the polarization plane of the polarization-maintaining optical fiber F1, a half-wave plate H2 is provided between the acousto-optic modulator 12 and the optical fiber F1. ing. On the other hand, the condenser lenses 13 and 14 (see FIG. 6) are also used in the short pulse light generation device 2 of the sonogram measurement device 1 of FIG. 2, but are not shown in FIG.

Further, in the sonogram measuring apparatus 1 of FIG. 2, in order to match the short pulsed light from the PBS 21 with the polarization plane of the polarization maintaining optical fiber F2, a half wavelength plate is provided between the PBS 21 and the optical fiber F2. H3 is provided.
A half-wave plate 41 is provided between the optical fiber F2 and the wavelength selection filter 42 in order to match the short pulsed light from the optical fiber F2 with the polarization plane of the wavelength selection filter 42.

FIG. 4 shows a short pulse to be measured when a highly nonlinear fiber F3 (see FIG. 5) is used in place of the polarization-maintaining optical fiber F2 in the sonogram measuring apparatus 1 of FIG. It is the result of measuring the time distribution of the spectrum of light. The component of FIG. 4 has a spectrum of about 1200n.
Since the measurement is performed in a wide band from m to about 2000 nm, it can be confirmed that the short pulse light incident, propagated, and output to the highly nonlinear fiber F3 is supercontinuum light. Here, since the upper left component of FIG. 4 is in a chirp state in which the intensities (output waveforms) of the time components are lined up neatly for each spectrum, it can be seen that it is suitable for compression / reproduction.

Further, FIG. 5 shows the optical device 4 in front of the half-wave plate 41 in the sonogram measuring apparatus 1 of FIG.
5 shows the one in which No. 5 is installed. In the sonogram measuring apparatus 1 of FIG. 5, the supercontinuum light generated by the highly nonlinear fiber F3 is made incident on the optical device 45, and the transmitted light of the optical device 45 is made incident on the wavelength selection filter 42. Since the time distribution of the spectrum of the 45 transmitted light can be measured, the optical device evaluation system for the supercontinuum light can be constructed.

As described in detail above, in the sonogram measuring apparatus 1 of the present embodiment, as shown in FIG. 1, FIG. 2 and FIG. The output of the short pulse light for measurement is continuously changed while the short pulse light for measurement and the short pulse light for reference are superposed on each other. (For measuring the time waveform of pulsed light), the one whose spectrum is extracted by the wavelength selection filter 42 is used as the short pulsed light to be measured, and the one output from the short pulsed light generator 2 is used for reference. By using it as short pulse light, the time distribution of the spectrum of the short pulse light to be measured is measured (see FIGS. 3 and 4).

In this respect, in the short pulse light generation device 2, as shown in FIGS. 6 and 7, each short pulse light (pulse width is 100 fs, which is repeatedly output from the fiber laser 11 at regular intervals (cycle of 48 MHz). And the wavelength is 1.56 μm
Via the acousto-optic modulator 12, and is incident on the polarization-maintaining optical fiber F1, propagated, and output. At this time, the wavelength of each short pulse light propagating in the polarization maintaining optical fiber F1 shifts based on the intensity of the short pulse light, while the dispersion value of the polarization maintaining optical fiber F1 is the wavelength. Since the propagation speed of each short pulse light in the polarization maintaining optical fiber F1 depends on the wavelength of the short pulse light (see FIG. 8), the fiber laser 1
When each short pulse light from No. 1 is incident on the polarization-maintaining optical fiber F1 via the acousto-optic modulator 12, by changing the intensity of each short pulse light by the acousto-optic modulator 12, The output time of the short pulsed light output from the holding type optical fiber F1 can be adjusted.

That is, in the sonogram measuring apparatus 1 of this embodiment, in the short pulse light generating apparatus 2, each short pulse light from the fiber laser 11 is converted into an acousto-optic modulator 12.
The intensity of each short pulse light is changed by the acousto-optic modulator 12 when it is incident on the polarization-maintaining optical fiber F1 via the optical fiber F1 and is output from the polarization-maintaining optical fiber F1. Since the light output time can be adjusted, by using the light output from the short pulse light generation device 2 as the reference short pulse light, the optical path length of the reference short pulse light remains constant. Thus, the output time of the short pulse light for reference can be continuously changed. In addition, in the sonogram measuring apparatus 1 of the present embodiment, as shown in FIG.
Alternatively, as shown in FIGS. 2 and 5, a short pulse light generation device 2 capable of continuously varying the output time of the short pulse light while keeping the optical path length of the short pulse light constant is provided. Since each short pulse light output from the short pulse light generation device 2 is used as the reference short pulse light, it is possible to avoid the occurrence of the deviation of the optical path of the reference short pulse light and to be vulnerable to mechanical vibration. It is possible to remove the fish and reduce the size.

Further, in the sonogram measuring apparatus 1 of the present embodiment, in the short pulse light generating apparatus 2, each short pulse light from the fiber laser 11 is transmitted through the acousto-optic modulator 12 to the polarization maintaining optical fiber F1. When it is incident on
Since the intensity of each short pulse light is changed by the acousto-optic modulator 12 based on the electric signal (command from the personal computer 23), the continuous change of the output time of the short pulse light is further improved. It can be performed in a fine and more accurate manner (see FIGS. 9 and 10). Further, the acousto-optic modulator 12 that changes the intensity of each short pulse light being transmitted on the basis of an electric signal (command from the personal computer 23) is used in the short pulse light generation device 2, and the short pulse light of the measurement target is used. Since the output time difference between the pulsed light and the reference short pulsed light can be made more finely and more accurately, the resolution can be improved.

Further, in the sonogram measuring apparatus 1 of the present embodiment, in the short pulse light generating apparatus 2, the wavelength of each short pulse light propagating in the polarization maintaining type optical fiber F1 is the intensity of the short pulse light. Since the short pulse light propagating in the polarization-maintaining optical fiber F1 is separated into the pump pulse and the soliton pulse (see FIG. 8), the short pulse light is converted into the pump pulse and the soliton. It is output from the polarization-maintaining optical fiber F1 in a state where it is separated from the pulse. In this respect, in the optical filter 15 into which each short pulse light from the polarization maintaining optical fiber F1 enters and transmits, only the soliton pulse is included in each short pulse light entering from the polarization maintaining optical fiber F1. Since the light is transmitted, only the soliton pulse of the short pulse light can be output, and the continuous change of the output time can be performed more finely and more accurately. Further, the short pulse light generation device 2 is provided with an optical filter 15 through which each short pulse light from the polarization maintaining type optical fiber F1 enters and transmits,
Even if each short pulse light propagating in the polarization maintaining optical fiber F1 of the short pulse light generation device 2 is separated into a pump pulse and a soliton pulse (see FIG. 8), only the soliton pulse of each short pulse light is generated. Since the short pulse light for reference is transmitted through the optical filter 15, noise due to the pump pulse of each short pulse light does not occur.

Further, in the sonogram measuring apparatus 1 of the present embodiment, as shown in FIG. 1, FIG. 2, and FIG. 5, the wavelength selection filter 42 selects the wavelength when transmitting the short pulse light to be measured. Since the extraction of the spectrum of the short pulse light of the measurement object being transmitted by the filter 42 is changed based on the electric signal (command from the personal computer 23), the spectrum of the short pulse light of the measurement object is continuously measured. It is possible to make detailed changes more accurately. Further, the wavelength selection filter 42 for changing the extraction of the spectrum of the short pulse light of the measurement object being transmitted based on the electric signal (command from the personal computer 23) is used in the sonogram measuring apparatus 1 of the present embodiment. Therefore, the continuous change in the spectrum of the short pulse light to be measured can be performed more finely and more accurately, so that the resolution can be improved.

Further, in the sonogram measuring apparatus 1 of the present embodiment, as shown in FIG. 5, if the optical device 45 is installed in front of the wavelength selection filter 42, the short pulse of the measuring object transmitted through the optical device 45 is transmitted. Since it is possible to measure the time distribution of the spectrum of light, at this time, for example, by analyzing the wavelength-dependent characteristics such as the wavelength dispersion value of the optical device 45 and the time response, the optical device for the short pulsed light to be measured It is possible to perform 45 evaluations.

However, when the evaluation of the optical device 45 with respect to the short pulse light to be measured is performed by measuring the wavelength dependence characteristics such as the chromatic dispersion value of the optical device 45, the optical device 45 is used as a wavelength selection filter. The optical device 45 may be installed before or after the optical device 45, but in the case of performing by measuring the time response of the optical device 45, the optical device 45 is installed in front of the wavelength selection filter 42 as shown in FIG. There is a need.

In particular, in recent years, the supercontinuum light having a wide spectrum has been widely used in the fields of optical electronics and various spectroscopic measurement including optical communication in which the wide band and high speed have been advanced. Therefore, as shown in FIG. 5, in the sonogram measuring apparatus 1 of the present embodiment, if the supercontinuum light is the short pulse light to be measured, the light for the short pulse light to be measured is The effect of evaluating the device 45 can be greatly exerted (see FIG. 4).

Further, in the sonogram measuring apparatus 1 of the present embodiment, as shown in FIG. 1, FIG. 2, and FIG. 5, in the cross-correlation measuring apparatus 100, the output of the cross-correlation signal (two-photon absorption signal) is increased. Lock-in amplifier 4 for
4 is used and the spectrum extracted by the wavelength selection filter 42 is used as the short pulse light of the measurement target, so that the cross-correlation signal (even if the pulse energy of the short pulse light of the measurement target is weakened) Two-photon absorption signal)
Can be observed with high sensitivity.

The present invention is not limited to the above embodiment, and various changes can be made without departing from the spirit of the present invention.

For example, in the short pulse light generator 2 used in the sonogram measuring device 1 of the present embodiment, the intensity of each short pulse light being transmitted is converted into an electric signal (personal computer) as a “light intensity adjuster”. Although the acousto-optic modulator 12 which is changed based on (command from 23) is used,
If, for example, an attenuator or the like is used instead of the acousto-optic modulator 12, the intensity of each short pulse light incident on the polarization maintaining optical fiber F1 can be changed without using an electrical signal. it can.

In the short pulse light generator 2 used in the sonogram measuring device 1 of the present embodiment, the fiber laser 11 outputs short pulse light having a pulse width of 100 fs and a wavelength of 1.56 μm at a cycle of 48 MHz. However, if the wavelength of each short pulse light can be changed for each short pulse light, the acousto-optic modulator 12 becomes unnecessary. This is because in the short pulse light generation device 2 having such characteristics, each short pulse light repeatedly output from the fiber laser 11 at regular intervals (cycle of 48 MHz) is used as the polarization maintaining optical fiber F.
1, the dispersion value of the polarization-maintaining optical fiber F1 changes depending on the wavelength, and the polarization-maintaining optical fiber F1 of each short pulse light is input.
Since the propagation speed in the inside depends on the wavelength of the short pulse light, when each short pulse light from the fiber laser 11 is incident on the polarization maintaining optical fiber F1, This is because the output time of the short pulsed light output from the polarization maintaining optical fiber F1 can be adjusted by changing the wavelength.

That is, in the sonogram measuring apparatus 1 of the present embodiment, even if the short pulse light generator 2 having such characteristics is used, each short pulse light from the fiber laser 11 is converted into a polarization maintaining type light. When the wavelength of each short pulse light is changed by the fiber laser 11 when the light is incident on the fiber F1, the output time of the short pulse light output from the polarization maintaining optical fiber F1 can be adjusted. By using the output from the short pulse light generation device having such characteristics as the reference short pulse light, the reference short pulse light is kept constant and the reference short pulse light is kept constant. The output time of the pulsed light can be continuously changed. Further, the short pulse light generation device 2 having such characteristics is capable of continuously changing the output time of the short pulse light while keeping the optical path length of the short pulse light constant. In the sonogram measuring apparatus 1 of the embodiment, even if each short pulse light output from the short pulse light generating apparatus 2 having such characteristics is used as the reference short pulse light, It is possible to avoid the deviation of the optical path, wipe the weakness against mechanical vibration, and reduce the size.

Further, in the sonogram measuring apparatus 1 of the present embodiment, in the cross-correlation measuring apparatus 100, as shown in FIG. 1, the short pulse light to be measured and the short pulse light for reference are placed on the PBS 32. Although they are superposed, they may be superposed on each other at this point, a beam splitter, or the like.

Further, in the sonogram measuring apparatus 1 of the present embodiment, in the cross-correlation measuring apparatus 100, as shown in FIG. 1, the short pulse light to be measured and the short pulse light for reference are superposed on the PBS 32. After the adjustment, in the avalanche photodiode 33 having a nonlinear optical effect,
The cross-correlation signal of the short pulse light of the measurement target is obtained. In this respect, the short pulse light of the measurement target and the short pulse light of the reference are superposed by the nonlinear crystal, and the wavelength conversion generated in the nonlinear crystal is obtained. A cross-correlation signal of the short pulse light to be measured may be obtained by detecting the light with a photodetector. Further, the short pulse light to be measured may be caused to interfere with the short pulse light for reference, and the cross-correlation signal of the short pulse light to be measured may be obtained from the intensity distribution.

[0085]

According to the sonogram measuring device of the present invention, in the short pulse light generation device, when the short pulse light repeatedly output from the short pulse light source at a constant interval is incident on the optical fiber, each short pulse light source is used. By changing the wavelength of the pulsed light, the output time of the short pulsed light output from the optical fiber can be adjusted, so that the one output from the short pulsed light generator is used as the short pulsed light for reference. By doing so, the output time of the short pulse light for reference can be continuously changed while keeping the optical path length of the short pulse light for reference constant. Further, in the sonogram measuring device of the present invention, while keeping the optical path length of the short pulse light constant,
It is equipped with a short pulse light generator that can continuously change the output time of the short pulse light, and each short pulse light output from the short pulse light generator is used as a reference short pulse light. It is possible to avoid the occurrence of the deviation of the optical path of the short pulsed light for use, wipe the weakness against mechanical vibration, and reduce the size.

Further, in the sonogram measuring device of the present invention,
In the short pulse light generation device, when each short pulse light from the short pulse light source is incident on the optical fiber through the light intensity adjuster, if the intensity of each short pulse light is changed by the light intensity adjuster, Since the output time of the short pulse light output from the fiber can be adjusted, by using the one output from the short pulse light generator as the short pulse light for reference, the short pulse light for reference is It is possible to continuously change the output time of the short pulse light for reference while keeping the optical path length constant. Further, the sonogram measuring device of the present invention is provided with a short pulse light generation device capable of continuously changing the output time of the short pulse light while keeping the optical path length of the short pulse light constant. Since each short pulse light output from the light generation device is used as the reference short pulse light, it is possible to avoid the occurrence of the deviation of the optical path of the reference short pulse light, and to wipe the weakness against mechanical vibration. Miniaturization is possible.

Further, in the sonogram measuring device of the present invention, in the short pulse light generation device, when each short pulse light from the short pulse light source is incident on the optical fiber via the light intensity adjuster, the light intensity adjuster is used. Since the intensity of each short pulsed light is changed based on the electrical signal, it is possible to make a continuous change in the output time of the short pulsed light for reference more finely and more accurately. Further, in the sonogram measuring device of the present invention, when a light intensity adjuster that changes the intensity of each short pulse light being transmitted based on an electric signal is used in the short pulse light generating device, Since the output time difference between the short pulse light and the reference short pulse light can be made more finely and more accurately,
It is possible to improve the resolution.

Further, in the sonogram measuring device of the present invention, in the short pulse light generation device, when the wavelength of each short pulse light propagating in the optical fiber shifts based on the intensity of the short pulse light, the optical fiber By separating each short pulse light propagating in the inside into a pump pulse and a soliton pulse, even if each short pulse light is output from the optical fiber in a state where it is separated into a pump pulse and a soliton pulse, each short pulse light from the optical fiber In the optical filter that allows the pulsed light to enter / transmit, only the soliton pulse in each short pulsed light incident from the optical fiber is transmitted, so that only the soliton pulse can be output as the short pulsed light for reference. At the same time, the continuous change of the output time can be performed more finely and more accurately. Further, in the sonogram measuring device of the present invention, when the short pulse light generation device is provided with an optical filter for entering and transmitting each short pulse light from the optical fiber, it propagates in the optical fiber of the short pulse light generation device. Even if each short pulse light inside is separated into a pump pulse and a soliton pulse, only the soliton pulse of each short pulse light passes through the optical filter and becomes a short pulse light for reference. No noise will be generated.

Further, in the sonogram measuring apparatus of the present invention, when the wavelength selection filter transmits the short pulse light of the measurement object, the spectrum of the short pulse light of the measurement object being transmitted by the wavelength selection filter is extracted. Since the change is made based on the electric signal, it is possible to make the continuous change of the spectrum of the short pulse light of the measurement object more finely and more accurately. Further, in the sonogram measuring device of the present invention, when using a wavelength selection filter that changes the extraction of the spectrum of the short pulse light of the measuring object being transmitted based on the electrical signal, the short measuring object Since the continuous change of the spectrum of the pulsed light can be performed more finely and more accurately, the resolution can be improved.

Further, in the sonogram measuring apparatus of the present invention, if an optical device is installed before or after the wavelength selection filter, it is possible to measure the time distribution of the spectrum of the short pulsed light of the measuring object transmitted through the optical device. So
At this time, for example, by analyzing the wavelength-dependent characteristics such as the wavelength dispersion value of the optical device and the time response, it becomes possible to evaluate the optical device with respect to the short pulse light to be measured.

In particular, in recent years, it is expected that the supercontinuum light having a wide spectrum will be widely used in the fields of optical electronics and various spectroscopic measurement including optical communication in which the wide band and high speed have been advanced. Therefore, in the sonogram measurement device of the present invention, if the supercontinuum light is the short pulse light of the measurement target, the effect of evaluating the optical device for the short pulse light of the measurement target can be greatly exerted. .

Further, in the sonogram measuring apparatus of the present invention, if the cross-correlation measuring apparatus is provided with an amplifier for increasing the output of the cross-correlation signal, the one whose spectrum is extracted by the wavelength selection filter is a short object to be measured. By using it as pulsed light, the cross-correlation signal can be observed with high sensitivity even if the pulse energy of the short pulsed light to be measured is weak.

[Brief description of drawings]

FIG. 1 is a basic configuration diagram of a sonogram measuring apparatus according to the present embodiment.

FIG. 2 shows a sonogram measuring device according to the present embodiment,
It is a basic block diagram when observing the pump pulse and the soliton pulse which the short pulse light output from the short pulse light generation device separates while propagating in the polarization-maintaining optical fiber by the cross-correlation measuring device.

FIG. 3 shows the measurement result of the time distribution of the spectrum of the short pulsed light to be measured when the optical fiber of the short pulsed light generator is 25 m and the maximum value of the fiber laser is 8 mW in the sonogram measuring device of FIG. is there.

FIG. 4 is a schematic diagram of the sonogram measurement device of FIG. 2, in which the optical fiber of the short pulse light generation device is replaced by a highly nonlinear fiber of 7 m, and the maximum value of the fiber laser is set to 12 mW. It is the measurement result of the time distribution of the spectrum of the supercontinuum light).

5 is a basic configuration diagram when a system for evaluating an optical device is constructed in the sonogram measuring apparatus of FIG.

FIG. 6 is a basic configuration diagram of a short pulse light generation device used in the sonogram measurement device of the present embodiment.

FIG. 7 is a basic configuration diagram of a system for measuring the output of the short pulse light generation device used in the sonogram measurement device of the present embodiment.

8 is a diagram showing a typical time waveform of short pulse light observed by the observation system of FIG.

9 is an observation result of the observation system of FIG. 7 when an optical fiber of the short pulse light generation device in the observation system of FIG. 7 is 220 m.

10 is an observation result of the observation system of FIG. 7 when an optical fiber of the short pulse light generation device in the observation system of FIG. 7 is 25 m.

FIG. 11 is a basic configuration diagram of a cross-correlation measuring device used in the sonogram measuring device of the present embodiment.

FIG. 12 is a cross-correlation device used in the sonogram measurement device of the present embodiment, in which short pulse light output from the short-pulse light generation device used in the cross-correlation measurement device is being propagated through a polarization-maintaining optical fiber. FIG. 3 is a basic configuration diagram when observing a pump pulse and a soliton pulse which are separated into 2 by a cross-correlation measuring device.

FIG. 13 is an example of the observation result of FIG.

FIG. 14 is a diagram showing an example of an autocorrelation waveform of a soliton pulse of short pulse light output from the short pulse light generation device used in the sonogram measurement device of the present embodiment.

FIG. 15 is a diagram showing an example of a spectrum waveform of a soliton pulse of short pulse light output from the short pulse light generation device used in the sonogram measurement device of the present embodiment.

FIG. 16 shows an example of the spectrum waveform of the short pulse light to be measured which is being split into a pump pulse and a soliton pulse in FIG.

FIG. 17 is a time waveform (solid line) of a cross-correlation signal including a so-called “pedestal part” and a triangular wave applied to the acousto-optic modulator of the short pulse light generation device in the oscilloscope of the sonogram measurement device of this embodiment. The electric signal (dashed-dotted line) of the voltage of is simultaneously observed and shown.

FIG. 18 is a time waveform (solid line) of a cross-correlation signal from which a so-called “pedestal part” is removed and an acousto-optic modulator of a short pulse light generation device, which is applied to the oscilloscope of the sonogram measurement device according to the present embodiment. The electric signal of the triangular wave voltage (two-dot chain line) is simultaneously observed and shown.

[Explanation of symbols]

1 Sonogram measuring device 2 Short pulse light generator 11 Fiber laser 12 Acousto-optic modulator 31 Optical filter 42 wavelength selection filter 44 amplifier 45 Optical device 100 Cross-correlation measuring device F1 polarization-maintaining optical fiber

Front page continuation (51) Int.Cl. ⁷ Identification code FI theme code (reference) H01S 3/00 H01S 3/00 G 3/06 3/06 B 3/098 3/098 (72) Inventor Hiroyuki Nagai Aichi 2-1-1 Asahi-cho, Kariya city, Aichi, Aisin Seiki Co., Ltd. (72) Inventor Toshio Goto 3-2110, Goshikinen, Nisshin City, Aichi Prefecture (72) Norihiko Nishizawa 2-4-43 Daiho, Atsuta-ku, Nagoya-shi, Aichi Prefecture Shirotori House 5-34 F term (reference) 2G020 BA20 CA12 CB23 CB56 CC26 CC30 CC31 CC47 CD15 CD16 CD24 CD52 2G065 AA04 AA12 AB09 AB14 AB23 BA02 BB02 BB14 BB19 BB27 BB31 BB33 BB38 BC28 BC35 BD01 BE03 DA05 DA07 A12 A12 A07 A12 A04 A12 A04 A12 A04 A12 A04 2K002 AB32 BA02 CA15 DA10 EA30 HA25 5F072 AB09 AK06 KK30 MM03 SS07 YY11

Claims (12)

[Claims] 1. A sonogram measuring device for measuring a time distribution of a spectrum of a short pulse light of a measurement target, wherein the short pulse light of the measurement target is incident and transmitted, and the spectrum of the short pulse light of the measurement target being transmitted. A wavelength selection filter for extracting, a short pulse light generation device for outputting a short pulse light for reference, a short pulse light to be measured from the wavelength selection filter and a short pulse for reference from the short pulse light generation device By observing the cross-correlation signal generated by overlapping the output time difference with the light continuously changing, the cross-correlation measuring device for measuring the time waveform of the short pulse light of the measurement target from the wavelength selection filter, The short pulse light generation device, while repeatedly outputting each short pulse light at a constant interval, a short pulse light source that changes the wavelength of each short pulse light, An optical fiber for injecting, propagating, and outputting each short pulse light from the short pulse light source. 2. A sonogram measuring device for measuring a time distribution of a spectrum of a short pulse light to be measured, wherein the short pulse light to be measured is incident and transmitted, and the spectrum of the short pulse light of the measurement target being transmitted. A wavelength selection filter for extracting, a short pulse light generator that outputs a short pulse light for reference, a short pulse light to be measured from the wavelength selection filter and a short pulse for reference from the short pulse light generator By observing the cross-correlation signal generated by overlapping the output time difference with light while continuously changing, a cross-correlation measuring device for measuring the time waveform of the short pulse light of the measurement target from the wavelength selection filter, The short pulse light generation device is a short pulse light source that repeatedly outputs each short pulse light at regular intervals, and each short pulse light from the short pulse light source is incident. A light intensity adjuster that changes the intensity of each short pulse light that is being transmitted, and an optical fiber through which each short pulse light from the light intensity adjuster enters, propagates, and outputs, A sonogram measuring device. 3. The sonogram measurement device according to claim 2, wherein the short pulse light generation device changes the intensity of each short pulse light being transmitted by the light intensity adjuster based on an electrical signal. A sonogram measuring device characterized by: 4. The sonogram measurement device according to claim 3, wherein the short pulse light generation device includes an optical filter through which each short pulse light from the optical fiber enters and transmits, and the optical fiber includes: While separating each propagating short pulse light into a pump pulse and a soliton pulse, the optical filter transmits only the soliton pulse in each short pulse light incident from the optical fiber, a sonogram measurement characterized by the following: apparatus. 5. The sonogram measurement apparatus according to claim 3 or 4, wherein the short pulse light generation apparatus includes an acousto-optic modulator as the light intensity adjuster. apparatus. 6. The sonogram measurement device according to claim 1, wherein the short pulse light generation device includes a fiber laser as the short pulse light source. Sonogram measuring device. 7. The sonogram measurement device according to claim 1, wherein the short pulse light generation device includes a polarization maintaining type optical fiber as the optical fiber. Characteristic sonogram measuring device. 8. The sonogram measuring apparatus according to claim 1, wherein the wavelength selective filter is used to determine the spectrum of the short pulsed light that is being transmitted and is to be measured based on an electrical signal. A sonogram measuring device, characterized in that 9. The sonogram measuring apparatus according to claim 8, wherein the wavelength selection filter is an acousto-optic modulator. 10. The sonogram measuring apparatus according to claim 1, wherein an optical device is installed before or after the wavelength selection filter. 11. The sonogram measuring device according to claim 10, wherein the short pulse light to be measured is a supercontinuum light. 12. The sonogram measurement apparatus according to claim 1, wherein the cross-correlation measurement apparatus includes an amplifier for increasing the output of the cross-correlation signal. , A sonogram measuring device.