JP2007047828A - Optical switch and optical waveform monitoring device utilizing optical switch - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a technique to materialize a high-speed switching with high switching efficiency and extending over a sufficiently wide wavelength range. <P>SOLUTION: The polarization direction of an optical signal is changed by a polarization controller 11 so as to be orthogonal to a main axis of a polarizer 15. A control pulse generator 12 generates control pulses from a control beam with a wavelength which is different from the wavelength of the optical signal. The optical signal and the control pulse are input to a nonlinear optical fiber 14. In the nonlinear optical fiber 14, the optical signal, during a time period in which the optical signal and the control pulse coincide, is amplified with optical parametric amplification around a polarization direction of the control pulse. The optical signal, during the time period in which the optical signal and the control pulse coincide, passes through the polarizer 15. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a technique for extracting a part of an optical signal, and in particular, a method for extracting an optical signal in which an optical pulse train is time-multiplexed or a part thereof, an optical switch using the method, and the optical switch. Related to the optical sampling oscilloscope.

  In recent years, with the increase in information capacity and the necessity of long-distance communication, devices or systems using optical technology have become widespread. Here, an optical switch that extracts a part of an optical signal composed of an optical pulse train is being researched and developed as one core technology. The following methods are known as conventional techniques for switching an optical signal composed of an optical pulse train.

  (1) A technique of converting a received optical signal into an electrical signal and switching it, and then converting the electrical signal into an optical signal using an optical modulator or a laser. This configuration is often called an OE / EO type.

(2) Technology for switching channels of an optical modulator such as a LiNbO ₃ modulator or an EA (Electro-Absorption) modulator by operating these modulators with an electrical signal synchronized with a desired channel.

(3) Technology that processes all at the optical level without using electrical signals. Specifically, the following method is known.
(3a) A method using a Mach-Zehnder interferometer set so that the phase difference of light passing through two arms is π (3b) Four-wave mixing (FWM) or three-wave mixing (TWM: (3c) Technology using non-linear light wave mixing such as Three Wave Mixing (3c) Technology utilizing optical Kerr effect such as self phase modulation (SPM) or cross phase modulation (XPM) (3d) A technique that utilizes a gain saturation effect such as gain modulation (XGM) or cross absorption modulation (XAM).

In addition, as patent documents related to these technologies, for example, there are the following. Non-Patent Documents 1 and 2 below describe techniques for performing 3R reproduction without converting input signal light into an electrical signal. In this 3R technology, the input signal light and the clock light regenerated from the input signal light are guided to an optical gate circuit including a highly nonlinear fiber, so that a reproduced signal having a good waveform that does not depend on jitter or the like of the signal light. It outputs light.
JP-A-7-98464 Patent 3494661 S. Watanabe, R. Ludwig, F. Futami, C. Schubert, S. Ferber, C. Boerner, C. Schmidt-Langhorst, J. Berger and HG Weber, “Ultrafast All-Optical 3R-Regeneration”, IEICE Trans. Election, Vol.E87-C, No.7, July 2004 Shigeki Watanabe, “Signal Reproduction Technology in the Optical Domain”, Optics, Vol. 32, No. 1, pp. 10-15, 2003

  The conventional technology described above has the following problems. In other words, the OE / EO type has already been put into practical use up to 10 Gbps, and research and development are currently being promoted toward the practical use of 40 Gbps. However, in addition to the need to prepare an electronic circuit for each bit rate, there is a limit to application to higher-speed signals due to the limitation of the operation speed of electronics. The technique (2) in which an electric signal is used as a drive signal or a control signal has the same problem with respect to the operation speed.

  Since the technique (3) does not use an electrical signal, the problem of the operation speed is solved. However, when applied to an ultrahigh-speed signal of 160 Gbps or more, a loss of 10 to 30 decibels is usually generated during switching. Or there is a problem that the wavelength band that can be switched is narrow. Here, if switching efficiency falls, optical S / N ratio will fall and signal quality will deteriorate. Further, when the operating band is narrowed, it is necessary to provide an optical switch individually for signal lights having different wavelengths.

  An object of the present invention is to provide a technique for switching an optical signal with high switching efficiency over a wide wavelength range.

  The optical switch of the present invention includes a first polarization controller that controls a polarization direction of signal light, a nonlinear optical medium that receives the signal light whose polarization direction is controlled by the first polarization controller, and the nonlinear A polarizer provided on the output side of the optical medium and having a polarization main axis orthogonal to the polarization direction of the signal light output from the nonlinear optical medium. The signal light is optically parametrically amplified in the nonlinear optical medium by the control light pulse in the polarization direction of the control light pulse. Alternatively, the signal light may be optically amplified in the polarization direction of the control light pulse by a nonlinear effect generated by the control light pulse in the nonlinear optical medium.

  When there is no control light pulse, the polarization direction of the signal light does not change in the nonlinear optical medium. Therefore, at this time, the signal light is completely blocked by the polarizer. On the other hand, when there is a control light pulse, the signal light is optically parametrically amplified in the nonlinear optical medium by four-wave mixing to a polarization in substantially the same direction as the polarization of the control light pulse. When a control light pulse is present, the polarization direction of the signal light is rotated by cross phase modulation in the nonlinear optical medium, and the signal light is optically parametric amplified by four-wave mixing. Therefore, at least a part of the optically parametric amplified signal light passes through the polarizer.

  In the optical switch described above, the angle between the polarization direction of the signal light and the polarization direction of the control light pulse may be set to about 45 degrees. According to this configuration, it is possible to obtain a good polarization rotation and to suppress a loss in the polarizer.

  Further, an optical fiber may be used as the nonlinear optical medium, and the average zero dispersion wavelength may coincide with or substantially coincide with the wavelength of the control light. According to this configuration, the efficiency of optical parametric amplification is good due to four-wave mixing.

  Furthermore, a waveform shaper that flattens the peak of the pulse of the signal light may be provided before the first polarization controller. Alternatively, the time width of the control light pulse may be shorter than the time width of the signal light pulse. If these structures are introduced, even if the signal transmitted by the signal light fluctuates in time, the timing of the signal is reproduced by the control light pulse used as the clock signal.

  The optical switch of the present invention can be switched while amplifying not only intensity modulated signal light but also phase modulated signal light or frequency modulated signal light. In this case, the modulated signal light is preferably an RZ signal.

  Further, if the input signal light is separated into a set of polarized signals orthogonal to each other and then combined with each other after being switched by an optical switch in the present invention, it is not necessary to control the polarization state of the input signal.

  According to the present invention, it is possible to switch optical signals with a wide usable wavelength range and with sufficiently high efficiency. Furthermore, this realizes a good optical S / N ratio.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a diagram showing a basic configuration of an optical switch 1 according to the present invention. In FIG. 1, a polarization controller (PC: Polarization Controller) 11 controls the polarization direction of input signal light. That is, the signal light is polarized in a predetermined direction by the polarization controller 11. Here, it is assumed that the wavelength of the signal light is “λs”. Moreover, the bit rate of the signal propagated (or carried) by the signal light is not particularly limited.

  The control light pulse generator 12 generates a control light pulse using the control light having the wavelength λp. Here, the wavelength λs of the signal light and the wavelength λp of the control light need to be appropriately separated, but the wavelength difference is not particularly limited. The wavelength λp may be larger or smaller than the wavelength λs.

  FIG. 2 is a diagram illustrating an example of signal light and control light pulses. Here, the signal light is signals s1, s2, s3,. . . Shall be transported. The control light pulse is generated in synchronization with the signal propagated by the signal light. In the example shown in FIG. 2, the frequency of the control light pulse is a quarter of the bit rate of the signal propagated by the signal light. The timings of the signal s1 and the control light pulse p1 coincide with each other, and the timings of the signal s5 and the control light pulse p2 coincide with each other.

  Although there is no particular limitation in order to synchronize the control light pulse with the signal propagated by the signal light, for example, the configuration shown in FIG. 3 can be considered. That is, the optical branching device 21 branches a part of the signal light and guides it to the control light pulse generation unit 12. Note that most of the signal light is guided to the polarization controller 11. The control light pulse generator 12 includes a clock regenerator 22 and regenerates a clock synchronized with a signal propagated by signal light. Here, the clock recovery unit 22 includes, for example, a PLL circuit. Further, the clock may be regenerated by using all the input signal light, or the pulse width of the regenerated clock signal may be expanded. A technique for regenerating a clock using all light from an optical signal as described above is described in, for example, Japanese Patent Application Laid-Open No. 2001-249371. Then, the control light pulse generation unit 12 generates a control light pulse using the regenerated clock. At this time, for example, if one pulse is generated for four clocks, the control light pulses p1 and p2 shown in FIG. 2 are obtained.

  The polarization controller 13 controls the polarization direction of the control light pulse. Here, the polarization direction of the control light pulse is set to a predetermined angle with respect to the polarization direction of the signal light. Preferably, the polarization direction of the control light pulse is set such that the angle between the polarization direction of the signal light and the polarization direction of the control light pulse is 40 to 50 degrees (for example, 45 degrees).

  Signal light and control light pulses are combined and input to the nonlinear optical fiber 14. Then, in the nonlinear optical fiber 14, the polarization direction of the signal light is rotated by the mutual phase modulation, and the signal light is amplified by optical parametric amplification by four-wave mixing. That is, as shown in FIG. 6C described later, the signal light is mainly amplified in the polarization direction of the control light pulse by optical parametric amplification by four-wave mixing. However, polarization rotation and optical parametric amplification do not occur for the entire signal light, but only in the time domain that overlaps with the control light pulse in time. For example, in the example shown in FIG. 2, polarization rotation and optical parametric amplification occur only for the signals s1 and s5. That is, the polarization direction does not change for the signals s2 to s4, s6, and s7.

  Although the optical parametric amplification has been described above, the wavelength λs of the signal light and the wavelength λp of the control light are different from each other, and the difference between them is the wavelength λp so that optical amplification (Raman amplification or Brillouin amplification) due to nonlinear effects is performed. The wavelength λs can also be set. Then, Raman amplification and bullian amplification by a non-linear effect can be performed. Broadband Raman amplification can also be performed by providing n wavelengths λp2 to λpn that are slightly different from the wavelength λp.

  The polarizer 15 is, for example, a polarization beam splitter PBS, a birefringent optical crystal, or the like, and allows light of the polarization main axis component to pass therethrough. Here, the polarization main axis of the polarizer 15 is set to be orthogonal to the polarization direction of the signal light. In other words, the polarization controller 11 controls the polarization direction of the signal light so as to be orthogonal to the polarization main axis of the polarizer 15.

  The optical bandpass filter (BPF) 16 allows only the wavelength of the signal light (here, λs) to pass and blocks light of other wavelengths. That is, the control light having the wavelength λp is blocked. Also, components outside the transmission band of the optical BPF are removed from spontaneous emission (ASE) light generated by an optical amplifier (not shown) or the like. When the wavelength of the control light is far away from the wavelength of the signal light, or when the power of the signal light passing through the polarizer 15 is sufficiently larger than the spontaneous emission light, the optical bandpass filter 16 need not be provided.

  As described above, the polarization direction of the signal light is orthogonal to the polarization main axis of the polarizer 15. Therefore, when there is no control light pulse, the polarization direction of the signal light does not change in the nonlinear optical fiber 14, so that the signal light is completely blocked by the polarizer 15. For example, in the example illustrated in FIG. 2, the signals s <b> 2 to s <b> 4, s <b> 6, s <b> 7 are blocked by the polarizer 15. However, when the signal light and the control light pulse are simultaneously present in the nonlinear optical fiber 14, the polarization direction of the signal light is rotated in the nonlinear optical fiber 14 by cross phase modulation. That is, the signal light is optically parametrically amplified in the nonlinear optical fiber 14 mainly in the polarization direction of the control light pulse. Then, the signal light output from the nonlinear optical fiber 14 has a component in the polarization main axis direction of the polarizer 15. As a result, part of the signal light passes through the polarizer 15. For example, in the example illustrated in FIG. 2, the signals s <b> 1 and s <b> 5 pass through the polarizer 15.

  Thus, according to the optical switch 1, a portion of the signal light that overlaps with the control light pulse in terms of time is selectively extracted and output. At this time, the wavelength of the output signal light is the same as the wavelength of the input signal light.

Next, the operation principle of the optical switch of the present invention will be described in detail. However, the principle of blocking the component (zero component of the switch light) in which the control pulse does not exist in the configuration and operation of the optical switch of the present invention is common to the operation of the optical Kerr switch using the optical Kerr effect. The operation of the optical Kerr switch is described in detail in the following document, for example.
“NONLINEAR FIBER OPTICS” page 180 -184, Govind P. Agrawal, ACADEMIC PRESS, INC.
Similar to the optical switch 1 shown in FIG. 1, the conventional optical Kerr switch includes a nonlinear optical fiber and a polarizer, and signal light and control light pulses are input to the nonlinear optical fiber. The polarization direction of the signal light is set so as to be orthogonal to the polarization main axis of the polarizer.

  In the optical Kerr switch, if the power of the control light pulse is zero, the polarization direction of the signal light does not rotate in the nonlinear optical fiber as shown in FIG. That is, the polarization direction of the signal light output from the nonlinear optical fiber is orthogonal to the polarization main axis of the polarizer. Therefore, in this case, the signal light is completely blocked by the polarizer.

  However, when the power of the control light pulse is increased with the signal light and the control light pulse overlapping in time, the phase of the signal light is proportional to the intensity of the control light pulse by cross-phase modulation (XPM). As shown in FIG. 4A, the polarization direction of the signal light is rotated. That is, as shown in FIG. 5 described later, the polarization state changes as the signal light travels through the nonlinear optical fiber, and the direction of the polarization main axis rotates. Thereby, as shown in FIG.4 (b), a part of signal light comes to pass a polarizer. When the phase of the signal light changes by π with respect to the input state to the nonlinear optical fiber by adjusting the power of the control light pulse, the polarization direction of the signal light is rotated 90 degrees from the initial state. become. That is, the linearly polarized light is rotated by 90 degrees. Then, the polarization direction of the signal light and the polarization main axis of the polarizer coincide with each other, and almost 100 percent of the signal light passes through the polarizer. At this time, as shown in FIG. 4B, the power of the output signal light is maximized. When the power of the control light pulse is further increased, the polarization direction of the signal light is further rotated, and the power of the output signal light is gradually reduced. That is, as shown in FIG. 5, the polarization state of the signal light further changes, and the polarization main axis direction rotates. As described above, in the optical Kerr switch, the output power of the signal light changes with a characteristic close to a sine curve with respect to the power of the control light pulse.

  Therefore, in the optical Kerr switch, the control light pulse for extracting the signal light is generally generated so as to have a power that rotates the polarization direction of the signal light by 90 degrees in the nonlinear optical fiber. However, in the optical Kerr switch, as is apparent from the operation principle, it is not possible to obtain output light having a power larger than the input power of the signal light. That is, there is a limit to improving the switching efficiency. For this reason, optical Kerr switches are often used with separately prepared optical amplifiers. Further, as apparent from the above operating principle, in the conventional optical Kerr switch, the optimum switching operation can be obtained only when the nonlinear phase shift becomes π, and therefore it is necessary to set the power of the control light with very high accuracy. There is.

  FIG. 5 is a diagram schematically illustrating the operation of the optical Kerr switch. The polarization direction of the signal light is rotated by cross phase modulation with the control light pulse in the nonlinear optical fiber. The power of the control light pulse is set so that the polarization direction of the signal light is rotated by 90 degrees in the nonlinear optical fiber. Thereby, the signal light in a region overlapping with the control light pulse in time passes through the polarizer most efficiently.

  The optical switch of the present invention uses the control light pulse as pumping light while effectively utilizing the polarization rotation by the above-described cross phase modulation, and thereby optical parametric amplification caused by four-wave mixing in the nonlinear optical fiber 14 shown in FIG. Utilizing the effect, an optical switch having high switching efficiency is realized. In the present invention, the pinpoint control of the control light required in the conventional optical Kerr switch is not required. Here, the four-wave mixing means that a substance (here, the nonlinear optical fiber 14) virtually absorbs two photons through the nonlinear polarization and emits two photons so as to conserve energy. It is a phenomenon. Then, when signal light having a wavelength different from the wavelength of the excitation light is input to a substance to which excitation light with high power is supplied, the signal light is amplified (optical parametric amplification) by the emitted photons.

  The optical switch of the present invention dramatically improves the switching efficiency by using this optical parametric amplification. Here, switching efficiency means the ratio of output signal light power to input signal light power. That is, according to the present invention, it is possible to dramatically increase the output power of the signal light component after the switch, thereby realizing a high-performance optical switch with very little deterioration in the optical S / N ratio. The

Now, let the length of the nonlinear optical fiber 14 used in the optical switch 1 be “L” and its loss be “α”. In addition, the input signal light and the output signal light of the nonlinear optical fiber 14 are “Es1” and “Es2”, respectively. Further, assuming that the phase matching condition for four-wave mixing is an ideal state, the switching efficiency ηs can be approximated by the following equation (1).
ηs ≡ | Es2 | ² / | Es1 | ² = exp (−αL) · G (1)
Here, “G” is an optical parametric gain, which can be approximated by the following equation (2).

Here, “P _p ” is the peak power of the control light pulse input to the nonlinear optical fiber 14.

Is a nonlinear effective interaction length, and is represented by “{1-exp (−αL)} / α”. “Γ” is a third-order nonlinear coefficient of the nonlinear optical fiber, and is represented by “ωn ₂ / cA _eff ”. “C”, “ω”, “n ₂ ”, and “A _eff ” mean the speed of light, light angular frequency, nonlinear refractive index, and effective mode cross-sectional area, respectively.

As is clear from the above equations (1) and (2), the switching efficiency of the signal light in the nonlinear optical fiber 14 is

As becomes larger, it grows with it. Further, once the characteristics and length of the nonlinear optical fiber 14 are determined, “γ” and

Is a fixed value. Then, it can be seen that the switching efficiency increases with “P _p ”. That is, when the peak power of the control light pulse is increased, the switching efficiency of the signal light is increased by optical parametric amplification.

  In the optical switch 1, the angle between the polarization direction of the signal light and the polarization direction of the control light pulse is set to about 45 degrees. Note that the polarization directions of the signal light and the control light pulse are appropriately set by the polarization controllers 11 and 13, respectively.

  In general, four-wave mixing (ie, optical parametric amplification) is most effective when the polarization directions of the interacting light waves coincide with each other, and almost occurs when the polarization directions are orthogonal to each other. do not do. Therefore, when the angle between the polarization direction of the signal light and the polarization direction of the control light pulse is set to about 45 degrees, the generation efficiency is greatly reduced as compared with the case where these directions coincide with each other. However, the polarization component in the same direction as the control light pulse is optically parametrically amplified in the polarization direction in the same direction as the control pulse, and optically switched as a signal light component in this polarization direction.

  On the other hand, as described with reference to FIG. 4A, the polarization direction of the signal light rotates according to the power of the control light pulse by cross phase modulation when the power of the control light is relatively small. As the amount of rotation of the signal light in the polarization direction approaches 45 degrees, the component due to the optical parametric gain increases. Further, when the rotation amount is about 45 degrees, the polarization directions of the signal light and the control light pulse coincide with each other, and the component due to the optical parametric gain becomes maximum. As described above, although the change in the polarization state of the signal light due to the mutual optical phase modulation depends on the intensity of the control light pulse, the effect of the present invention can also be achieved with respect to the mutual optical phase modulation used in the conventional optical Kerr switch. It does not inhibit.

  Here, amplification of signal light by four-wave mixing in a nonlinear optical fiber (that is, optical parametric amplification) is a phenomenon in which the same wavelength component as signal light is newly generated by a control light pulse supplied as pump light. Conceivable. In the optical switch 1 of the present invention, a control light pulse with very high power is supplied to the nonlinear optical fiber 14. For this reason, most of the signal light output from the nonlinear optical fiber 14 is a component newly generated by four-wave mixing. However, the signal light component newly generated by the four-wave mixing is not affected by the mutual phase modulation, and the polarization direction does not change by the mutual phase modulation. That is, no polarization rotation occurs. Therefore, in the region where the power of the control light pulse is very strong, the polarization direction of the signal light optically parametrically amplified in the nonlinear optical fiber 14 is fixed in the same direction as the polarization direction of the control light pulse. Therefore, the signal light switched by the nonlinear optical fiber of the present invention is output from the nonlinear optical fiber as polarized light having a direction substantially coincident with the polarization direction of the control light pulse. This switching is very different from the conventional optical Kerr switch.

  FIG. 6 is a diagram for explaining switching by the optical switch of the present invention. In addition, the direction and magnitude | size of the arrow corresponding to the signal beam | light shown to Fig.6 (a) and FIG.6 (b) represent the polarization direction and amplitude of the signal beam | light. Further, the polarization direction of the signal light is orthogonal to the polarization main axis direction of the polarizer 15 as shown in FIG. FIG. 6C schematically shows the switching operation by the optical switch of the present invention.

  In the present invention, signal light is output as linearly polarized light substantially in the polarization direction of the control light pulse at the output end of the nonlinear optical fiber by optical parametric amplification using the control light pulse.

  During the period when there is no control light pulse, optical parametric amplification and cross phase modulation do not occur in the nonlinear optical fiber 14. For this reason, the polarization direction of the signal light output from the nonlinear optical fiber 14 is the same as the polarization direction at the input end. That is, the polarization direction of the output signal light is orthogonal to the polarization main axis direction of the polarizer 15. Therefore, in this case, the signal light is completely blocked by the polarizer 15.

  On the other hand, when the control light pulse is given, the signal light is optically parametric amplified, and the polarization direction of the signal light is rotated by the mutual phase modulation as described with reference to FIG. However, the power of the control light pulse used in the optical switch 1 of the present invention is very large (for example, the peak power of the control light pulse is about several watts). For this reason, the signal light is amplified by optical parametric amplification resulting from four-wave mixing. As described above, the efficiency of this optical parametric amplification is maximized when the polarization direction of the control light pulse and the polarization direction of the signal light coincide with each other. In particular, for signal light in a polarization state that matches the polarization state of the control light, the signal light component newly generated by four-wave mixing is not affected by cross-phase modulation, and the polarization direction is changed by cross-phase modulation. It does not change. Therefore, as shown in FIG. 6B, the polarization direction of the signal light optically parametrically amplified in the non-linear optical fiber 14 is fixed to substantially the same direction as the polarization direction of the control light pulse, as in the conventional optical Kerr switch. The polarization direction does not rotate to an angle exceeding 90 degrees.

Here, the angle between the polarization direction of the signal light and the polarization direction of the control light pulse at the input end of the nonlinear optical fiber 14 is set to about 45 degrees. The angle between the polarization direction of the output signal light and the polarization main axis direction of the polarizer 15 is also about 45 degrees. Therefore, about 50 percent (= (1 / √2) ² ) of the power of the signal light output from the nonlinear optical fiber 14 passes through the polarizer 15.

Thus, in the optical switch 1 of the present invention, the power of the signal light is approximately halved when passing through the polarizer 15. However, the power of the signal light can be amplified by optical parametric amplification in the nonlinear optical fiber 14 so that the loss in the polarizer can be sufficiently compensated. Therefore, the power of the signal light output from the optical switch 1 is sufficiently larger than the power of the input signal light, although loss occurs in the polarizer 15, and the switching efficiency is greatly improved. Here, since the switching efficiency of the conventional optical Kerr switch is 1 at the maximum, the efficiency improvement effect according to the present invention is remarkable. In addition, the switching efficiency of the conventional four-wave mixing switch is

And the optical switch of the present invention exceeds this. In addition to the improvement in efficiency, the present invention has characteristics not found in conventional four-wave mixing switches in that it does not involve wavelength shift.
FIG. 7 is a diagram for explaining operation areas of the optical switch of the present invention and the existing optical Kerr switch. In the existing Kerr switch, a small control light pulse that rotates the polarization direction of the input signal light by 90 degrees is used. For this reason, optical parametric amplification does not occur (or hardly occurs), and the polarization state and polarization principal axis direction of the signal light change depending on the control light power. Further, the maximum power of the output signal light does not exceed the power of the input signal light. That is, the switching efficiency of the existing Kerr switch is 1 or less.

  On the other hand, in the optical switch 1 of the present invention, a control light pulse having a much stronger power than that of the existing Kerr switch is used. For this reason, in the nonlinear optical fiber 14, optical parametric amplification due to four-wave mixing occurs in the polarization direction of the control light pulse, and in the region where the power of the control light is relatively small, the polarization of the signal light due to cross-phase modulation rotates. As the polarization direction of the signal light gradually approaches that of the control light, optical parametric amplification by four-wave mixing occurs, the polarization direction of the signal light is fixed in a state close to the polarization direction of the control light, and the output signal light The power increases in proportion to the square of the power of the control light and becomes larger than the power of the input signal light. That is, one or more switching efficiencies can be obtained by appropriately selecting the peak power of the control light pulse. In other words, the optical switch 1 of the present invention is an optical switch having the function of an optical amplifier. In the prior art, there has been no optical switch having an optical amplifier function in an optical switch without a wavelength shift.

  In the optical switch 1 of the present invention, the polarization state of the signal light at the initial setting is orthogonal to the polarizer. For this reason, it cannot be realized without wavelength conversion in a normal switch, but in the optical switch 1 of the present invention, an off signal (zero level) can be suppressed with a very high extinction ratio. That is, according to the optical switch 1, a signal having a level higher than that of the input signal light can be output by the optical parametric gain for the ON signal (1 level), and always polarized for the OFF signal (zero level). A good suppression effect using the extinction ratio of the child can be realized. Therefore, the signal light after switching can have a good extinction ratio and S / N ratio (or a good signal reproduction effect).

  Furthermore, in the optical switch 1 of the present invention, an optical Kerr (third order nonlinear optical) effect including cross-phase modulation and four-wave mixing in a nonlinear optical fiber is used. These nonlinear effects are all in femtosecond order. This is a very fast phenomenon with a response speed. Therefore, the present invention has a transparent switching characteristic that does not depend on a bit rate or a pulse shape, and can be applied to an ultrahigh-speed signal of tera bps level.

  In the above-described embodiment, the angle between the polarization direction of the signal light and the polarization direction of the control light pulse is set to about 45 degrees. However, it is appropriately adjusted at another angle having the highest efficiency according to various setting conditions. It is also possible to do. However, the angle is preferably about 40 degrees to about 50 degrees at the input end of the nonlinear optical fiber by experiments and simulations. If this angle is too large, polarization rotation of signal light due to optical parametric amplification or cross phase modulation due to four-wave mixing hardly occurs, which is not preferable. Moreover, when this angle is too small, the loss in the polarizer 15 becomes large, which is not preferable.

Next, an embodiment of the optical switch 1 will be described.
FIG. 8 shows an embodiment in which optical 2R regeneration is performed using the optical switch of the present invention. Here, “light 2R” refers to timing reproduction (Re-timing) and amplitude reproduction (Re-amplification).

  In FIG. 8, the main circuit 100 corresponds to the polarization controllers 11 and 13, the nonlinear optical fiber 14, the polarizer 15, and the optical bandpass filter 16 shown in FIG. Further, the control light pulse generation unit 12 includes a clock regeneration unit 22 shown in FIG. 3 and generates a control light pulse using a clock regenerated from the input signal light.

  The input signal light is branched into two and supplied to the waveform shaper 101 and the control light pulse generator 12. The waveform shaper 101 converts the waveform of the signal light shown in FIG. 9A into an optical pulse having a flat peak as shown in FIG. 9B. Then, the optical pulse is input to the main circuit 100. On the other hand, the control light pulse generator 12 generates a control light pulse having a reference frequency (or an integer multiple of the reference frequency or a fraction of an integer) corresponding to the bit rate of the signal through which the signal light propagates. Then, the main circuit 100 regenerates a signal from the signal light pulse whose waveform has been shaped by the waveform shaper 101 using this control light pulse (light 2R regeneration).

  However, when the bit rate of the signal increases (for example, 160 Gb / s), the timing fluctuation (that is, jitter) of the data pulse occurs due to the influence of polarization dispersion, noise added by the optical amplifier, and the like. For example, in the example shown in FIG. 9A, the periods T1, T2, and T3 are different from each other. However, in the optical 2R reproduction shown in FIG. 8, if this jitter is within the flat region of the signal pulse, the jitter is suppressed by reproducing with the control light pulse. That is, as shown in FIG. 9C, the periods T1, T2, and T3 are substantially constant. Further, the amplitude of the reproduced signal light is sufficiently large due to the optical parametric amplification in the main circuit 100. Further, the frequency (wavelength) of the signal light output from the main circuit 100 is the same as the frequency (wavelength) of the input signal light.

  Waveform shaping by the waveform shaper 101 includes, for example, a method using a nonlinear chirp, a method using a difference in group velocity dispersion in two polarization principal axis directions in a constant polarization fiber (Non-Patent Documents 1 and 2 described above) Realized by a method using a gain saturation amplifier, a method using an optical modulator, a method of optical modulation using the signal processing when the signal light is subjected to O / E conversion and then subjected to electrical signal processing, etc. Is possible.

  In this way, if the optical 2R regeneration shown in FIG. 8 is performed using the optical switch of the present invention, fluctuations in the time axis direction are suppressed, so that a polarization dispersion compensator or the like is not required in the receiving apparatus. Is possible.

  FIG. 10 shows another embodiment of optical 2R reproduction. In FIG. 10, the control light pulse generation unit 102 is basically the same as the control light pulse generation unit 12 shown in FIG. 1 or FIG. However, the control light pulse generation unit 102 generates a control light pulse with a sufficiently small pulse width, as shown in FIG. That is, the pulse width Wc of the control light pulse generated by the control light pulse generator 102 is smaller than the half width Ws of the signal light pulse that is not affected by jitter.

  If optical 2R regeneration is performed using such a control light pulse, fluctuations in the time direction can be suppressed as in the configuration described with reference to FIGS. That is, it is possible to suppress time fluctuation (for example, fluctuation due to polarization mode dispersion) added to signal light in optical fiber transmission or the like. Therefore, if the above-described optical 2R regeneration is performed at the receiver or the optical repeater, the polarization mode dispersion is suppressed and the reception characteristics and transmission characteristics are improved without using a complicated polarization mode dispersion compensator. Can be made.

  When generating a control light pulse having a narrower time width than the signal light pulse, the control light pulse generation unit 102 generates an optical clock pulse slower than the bit rate of the signal light, and then converts the optical clock pulse to time. Control light pulses having a desired frequency may be generated by multiplexing (OTDM). For example, when the bit rate of the signal light is 160 Gb / s, an optical clock pulse of 10 GHz or 40 GHz may be generated and then multiplexed to generate a control light pulse of 160 GHz.

In addition, a technique for generating a pulse having an extremely narrow pulse width is obtained by using a regenerated optical clock signal in a method using a mode-locked laser, an EA (Electro-Absorption) modulator, or an LN (LiNbO ₃ ) intensity / phase modulator. Modulation method, regenerated optical pulse is linearly chirped and then pulse compressed using optical fiber, soliton adiabatic compression effect is used, and part of the spectrum of linearly chirped optical pulse is extracted with a bandpass optical filter This method is realized by a method using an optical switch using a second-order and third-order nonlinear optical effect, a method using an interferometer type optical switch, and the like.

  FIG. 12 is a diagram illustrating an embodiment in which an optical switch is used in a receiving apparatus of a communication system. Here, it is assumed that the signal light transmitted from the transmitter 31 carries a plurality of time-division multiplexed channels. For example, the bit rate of a signal propagated by signal light is 160 Gbps, and four 40 Gbps channels are time-division multiplexed. On the other hand, the receiver 32 receives a signal of a predetermined channel from the signal light.

  The optical switch 1 extracts a channel signal to be received by the receiver 32 from a signal propagated by the signal light. That is, the optical switch 1 operates as a DEMUX device. For example, in FIG. 2, signals s1, s2, s3. . . Are propagated, and signals s1, s5. . . Are transmitted, the optical switch 1 controls the control light pulses p1, p2,. . . Is supplied to the nonlinear optical fiber 14. As a result, the signals s1, s5. . . Is extracted. At this time, the extracted signal is optically parametric amplified. Further, during the period when the control light pulse is not generated, the output of the optical switch 1 is in the extinction state. Therefore, a good extinction ratio and S / N ratio are realized.

  FIG. 13A is a diagram illustrating an embodiment in which an optical switch is used in a relay node of a communication system. Here, it is assumed that the signal light transmitted from the transmitter 31 is the same as the signal light described in FIG. The optical relay node 41 includes an optical branching device 42 and outputs the signal light received via the optical transmission path 1 to the optical transmission path 2 as it is and guides the branched light to the optical switch 1. The optical switch 1 extracts a predetermined channel from a plurality of channels through which signal light propagates and guides it to the optical transmission line 3. That is, the optical relay node 41 drops a predetermined channel among the plurality of time-division multiplexed channels.

Similarly, two optical signals can be time-division multiplexed (OTDM) or temporal optical ADD circuit can be realized by the present invention. This configuration is shown in FIG.
The signal light 1 input through the optical transmission line 1 is guided to the optical switch 1a of the present invention. The optical switch 1a is given control light pulses of the same rate as the bit rate of the signal transmitted by the signal light 1 and all patterns. Thereby, the optical switch 1a amplifies and outputs the signal light 1 as it is. On the other hand, the signal light 2 input through the optical transmission line 2 is guided to the optical switch 1b of the present invention. The optical switch 1b is supplied with a control light pulse for selecting part or all of the signal transmitted by the signal light 2. Thereby, the optical switch 1b selects and outputs part or all of the signal light 2 while amplifying.

  The outputs of the optical switches 1a and 1b are multiplexed by an optical coupler and guided to the optical transmission line 3. Thereby, the signal light 3 obtained by time-division multiplexing the signal light 1 and the signal light 2 (or a part thereof) is obtained. A control system for matching the phases of the signal lights 1 and 2 may be provided between the optical switches 1a and 1b and the optical coupler.

  FIG. 14 is a diagram showing an optical transmission system using the optical switch of the present invention in an optical repeater. Here, it is assumed that the signal light transmitted from the transmitter 31 is amplified by the optical switch 1 provided in the optical repeater 33 and transmitted to the receiver 32. Note that the first and second transmission paths may be optical fibers or wireless transmission paths.

The optical signal propagating through the transmission path is attenuated according to the transmission distance, and the extinction ratio is deteriorated as shown in FIG. The signal light pulse has jitter.
In the system shown in FIG. 14, if the optical switch 1 performs the optical 2R regeneration shown in FIG. 8 or FIG. 10, the influence of jitter and polarization mode dispersion can be suppressed as described above. Further, in the optical switch 1, all signal light is blocked during a period in which no control light pulse exists. For this reason, even when the optical power is increased when the signal light is “OFF” due to noise addition or waveform deterioration due to transmission or the like (see FIG. 15A), the extinction ratio is improved. Signal light can be reproduced (see FIG. 15B).

  Further, in the optical 2R reproduction shown in FIG. 8, the peak of the signal light pulse is flattened, but as shown in FIG. 16, the peak of the control light pulse may be flattened. With such a configuration, amplification relaying that does not affect the pulse width and phase information of the signal light is possible. Further, this configuration is effective for the device that switches the optical DEMUX shown in FIG. 12, the optical ADM shown in FIG. 13, or the signal light subjected to phase modulation or frequency modulation. However, it is desirable that the control light pulse is synchronized with the control light pulse by using the optical clock regenerated from the input signal light by the clock regeneration unit 22 shown in FIG.

  FIG. 17 is a diagram illustrating an embodiment in which an optical switch is used in an optical sampling oscilloscope. Here, the bit rate of the signal propagated by the signal light to be observed is “fs”. Then, this signal light is input to the optical switch 1.

  The sampling pulse generator 51 includes a clock regenerator and regenerates the reference clock signal from the branched light of the input signal light. The frequency (ie, sampling rate) of this reference clock signal is “f ′s”. Then, an optical pulse train synchronized with a frequency “f ′s + Δfs (where Δfs << f ′s)” slightly different from the reference clock frequency is generated using a pulse light source. This optical pulse train is supplied to the optical switch 1 as the control light pulse described with reference to FIG. In an optical sampling oscilloscope, a low-speed sampling rate “for example, f ′s = fs / N (N = 1, 2,...)” Is generally used to simplify an electric circuit. At this time, when N ≧ 2, the frequency of the optical signal f ′s can be reduced to 1 / N. That is, the processing speed of the electric circuit can be reduced, and the design and manufacture of the electric circuit can be simplified. Further, since the number of sampling signals increases as N = 1, clearer waveform information can be obtained, but a high-speed electric circuit is required.

  The optical switch 1 outputs an optical pulse proportional to the light intensity of the signal light at every peak timing of the control light pulse. The light receiver 52 sequentially converts the optical pulses output from the optical switch 1 into electrical signals. The oscilloscope 53 detects the waveform of the signal propagated by the signal light by tracing the electrical signal obtained by the light receiver 52 in the time direction. At this time, since the frequency difference between the input signal and “N × f ′s” is “Δfs”, by setting a sampling rate “fs / N” that is sufficiently slower than the modulation speed of the input signal, the signal waveform is changed to the signal light. Is detected with a period Δfs which is sufficiently slow with respect to the bit rate of the signal propagated by the signal. Even ultra-fast pulses that exceed the operating speed limits of the oscilloscope's electronic circuits can be observed. In addition, the gain of the optical switch can output signal light with higher light intensity, and an optical sampling oscilloscope with high sensitivity can be realized. The operation of the optical sampling oscilloscope is described in, for example, Japanese Patent Application Laid-Open No. 2003-65857 or Japanese Patent Application Laid-Open No. 2004-214982.

  The above-described optical sampling oscilloscope can be used for examining the surface or internal configuration of an ultra-finely processed element or analyzing various materials. That is, as shown in FIG. 18, when a signal light pulse is input to the object to be measured and the reflected light or transmitted light is observed, depending on the non-uniformity of the internal state of the object to be measured or the distortion of the surface shape, The pulse waveform of the reflected light or transmitted light is broken. At this time, as the time width of the signal light pulse is shorter, the pulse waveform of the reflected light or transmitted light is more likely to collapse, and as a result, non-uniformity or distortion of the object to be measured is easily observed.

  FIG. 19 shows an embodiment of a material analyzing apparatus using the optical switch of the present invention. In FIG. 19, the main circuit 61 corresponds to the optical switch 1 and the sampling pulse generator 51 shown in FIG. The O / E converter 62 and the analysis device 63 correspond to the light receiver 52 and the oscilloscope 53 shown in FIG.

  In this material analyzer, a short-pulse probe light is used as the signal light described above. First, the probe light is directly input to the main circuit 61 to observe the waveform. Subsequently, the probe light is input to the object to be measured, and the measurement light (reflected light or transmitted light) output therefrom is input to the main circuit 61 to observe the waveform of the measurement light. Then, by comparing the two waveforms, the surface or internal state of the object to be measured can be examined.

  The measurement light is not limited to reflected light or transmitted light. When the measurement object emits light by inputting probe light, the light may be observed. In this case, even in a phenomenon in which weak light is emitted in a very short time, this light emission can be observed with high accuracy due to the high time resolution and good light amplification characteristics provided by the optical switch 1. Therefore, the material analysis apparatus according to the present invention greatly contributes to the analysis of the physical characteristics of the object to be measured.

  In addition, the wavelength which can apply this invention can be arbitrarily used from all the wavelength bands which can implement | achieve the nonlinear optical effect required for this invention from the 1.55 micrometer band for optical communications. Here, when an optical fiber is used as the nonlinear medium, for example, a single mode fiber is used in a feasible wavelength band. The optical fiber is not limited to a silica-based fiber, and an optical fiber with enhanced nonlinear effect such as a photonic crystal fiber or a bismuth-substituted fiber is effective. In particular, if a photonic crystal fiber is used, flexible design of chromatic dispersion is possible, and a non-linear optical fiber can be realized in the wavelength region from the visible light region to about 0.8 μm (M. Nakazawa et al , Technical Degest in CLEO2001), and even shorter wavelength ranges may be used.

Next, wavelength arrangement in the optical switch of the present invention and the widening of the switching wavelength will be described.
The optical switch 1 of the present invention utilizes both polarization rotation by cross-phase modulation in a nonlinear optical fiber and optical parametric amplification by four-wave mixing. Here, these nonlinear optical effects can be obtained over an extremely high speed and an extremely wide band. Therefore, according to the present invention, it is possible to perform switching for all signal lights arranged in a wavelength band used in an optical communication system or the like.

  In order to improve the characteristics of the optical switch 1, a configuration advantageous for the generation of four-wave mixing is required. Here, the occurrence of four-wave mixing strongly depends on the wavelength dispersion characteristics of the nonlinear optical fiber. Further, when signal light and control (excitation) light are incident on the nonlinear optical fiber, four-wave mixed light (idler light) is generated. Here, assuming that the frequencies of the signal light and the control light are “fs” and “fp”, respectively, the frequency of the idler light is “2fp−fs”. In order to efficiently generate the four-wave mixing, it is necessary to achieve phase matching between the signal light and the idler light.

In general, in order to efficiently generate optical parametric amplification by four-wave mixing, for example, as shown in FIG. 20, the wavelength of the control (pumping) light is made to coincide with the zero dispersion wavelength λ ₀ of the nonlinear optical fiber. Good. Further, a dispersion flat fiber (or a fiber having sufficiently small wavelength dispersion) may be used as the nonlinear optical fiber. However, these requirements can be relaxed depending on the length of the nonlinear optical fiber and the wavelength difference between the signal light and the control light.

In general, if the chromatic dispersion near the center wavelength of the control light is β ₂ , the amount of phase mismatch due to the wavelength difference between the signal light and the control light can be estimated as “β ₂ × (2πfp −2πfs) ² ”. it can. Therefore, when the wavelength of the control (pumping) light is matched with the zero dispersion wavelength of the nonlinear fiber (β ₂ = 0), the amount of phase mismatch due to this wavelength dispersion can be made almost zero. However, as in the present invention, when the intensity of the control light is high, it is also effective to optimize the entire wavelength arrangement in consideration of the phase mismatch due to nonlinear phase modulation due to nonlinear effects such as SPM and XPM. It is. Since the amount of phase mismatch when the nonlinear component is taken into account can be estimated to be approximately “β ₂ × (2πfp−2πfs) ² + 2γP _p ”, it is preferable to set this value to a minimum. A method is conceivable in which the wavelength of the excitation light is arranged on the anomalous dispersion side of the nonlinear fiber so that “β ₂ <0”.

  FIG. 21 is a diagram illustrating an example of the wavelength arrangement of the signal light and the control light. Here, a case where there are two usable wavelength bands is considered. The two wavelength bands correspond to, for example, a visible light band and an infrared band, or a C band (1530 nm to 1565 nm) and an L band (1568 nm to 1610 nm) for optical communication.

  When such two wavelength bands exist, the signal light is arranged in one band (band 1) and the control light pulse is arranged in the other band (band 2) as shown in FIG. The The optical switch 1 of the present invention does not involve wavelength conversion when switching signal light. Therefore, as shown in FIG. 21B, the wavelength of the output signal light is the same as the wavelength of the input signal light, and is arranged in the band 1.

  In general, in an optical communication system, an optical amplifier, an optical filter, a light receiver, an electronic circuit for amplifying a photoelectrically converted signal, and the like are provided, but in particular, an optical measurement tool is expensive, Preparing them for each wavelength band is a factor that increases costs. However, if the above-described wavelength arrangement is introduced, all signal lights arranged in the wavelength band to be switched can be switched with one set of tools. In general, an optical filter (for example, the optical bandpass filter 16 shown in FIG. 1) is used in order to separate and extract the signal light after the switching process from the control light or other light. At this time, if the above wavelength arrangement is introduced and, for example, an optical amplifier operating in each band of C band / L band is used, the light in one band where the signal light is arranged can be linearly amplified and the control light The light in the other band where the pulse is arranged can be cut.

  In the optical switch 1 of the present invention, the wavelength of the control light pulse needs to be different from the wavelength of the signal light. However, depending on the user, it may be difficult to prepare the wavelength of the control light for obtaining the control light pulse. For example, there may be a case where control light pulses arranged in the L band cannot be prepared when switching the signal light arranged in the most common C hand in optical communication. In such a case, for example, a configuration that generates control light pulses arranged in the L band by converting light in the C band into light in the L band is effective.

FIG. 22 is a diagram illustrating a configuration of an optical switch having a function of converting the wavelength of the control light pulse. Here, a configuration having a wavelength conversion function using four-wave mixing will be described.
In FIG. 22, the control light pulse generator 71 generates a control light pulse 1 having a wavelength λc1 in the C band. The wavelength converter 72 includes a light source 73 and a nonlinear optical fiber 74. The light source 73 generates probe light having a wavelength λp in the L band. The probe light is continuous wave light or an optical pulse train. Then, as shown in FIG. 23A, the control light pulse 1 and the probe light are input to the nonlinear optical fiber 74. Then, as shown in FIG. 23B, the control light pulse 2 is generated by the four-wave mixing in the nonlinear optical fiber 74. Here, the wavelength λc2 of the control light pulse 2 is a wavelength that satisfies “λc2−λc1 to λc1−λp”. Therefore, if the wavelength of the probe light is appropriately set, the control light pulse 2 in the L band can be obtained from the control light pulse 1 in the C band.

  The band pass filter 75 passes the wavelength λc2. Therefore, as shown in FIG. 23C, a control light pulse having a wavelength in the L band can be generated. If necessary, an optical amplifier for amplifying the output of the nonlinear optical fiber 74 may be provided.

In the above-described embodiment, the wavelength conversion function is provided using four-wave mixing, but the present invention is not limited to this. That is, for example, a method using _three- wave mixing, a method using cross-phase modulation, a method using self-phase modulation, a method using a LiNb ₃ modulator having a quasi-phase matching structure, a method using a semiconductor optical amplifier, A method using a saturable absorption modulator, a method using an interferometric optical switch, a method using a device such as a photonic crystal, and optical modulation using the light signal while converting the light signal into an electric signal. Wavelength conversion may be performed by a method of modulating the device.

  Note that the present invention is also applicable to a configuration in which both signal light and control light pulses are arranged in the same band. However, it is necessary to arrange the wavelengths so that the optical spectra of the two pulses are sufficiently separated from each other so that they do not inappropriately interfere with each other. When the signal light and the control light are arranged in the same wavelength band, phase matching is easy and the influence of pulse walk-off is reduced, so that more efficient optical switching is possible.

  The optical switch of the present invention can also switch WDM light in which a plurality of wavelengths are multiplexed together. However, in order to switch the WDM light in a batch, the signals of each channel of the WDM light need to be synchronized with each other. After comparing the timing of the signal light of each wavelength, a synchronization method based on a time adjustment method can be used by optical buffering using a delay circuit or the like. However, when monitoring the signal waveform of each channel of WDM light with an oscilloscope (see FIG. 17) using the optical switch of the present invention, the signals of each channel do not need to be synchronized with each other.

Next, an embodiment of the nonlinear optical fiber 14 used in the optical switch 1 will be described.
The nonlinear optical fiber 14 preferably has a chromatic dispersion variation of a certain value or less over the entire length range. Further, as the nonlinear optical fiber 14, for example, a nonlinear such as a photonic crystal fiber, a bismuth-substituted fiber (a nonlinear optical fiber in which the core is doped with bismuth), a germanium-substituted fiber (a nonlinear optical fiber in which the core is doped with germanium), or the like. An optical fiber with enhanced effect is effective. The germanium-substituted fiber is currently optimally structured to increase the efficiency of generating the third-order nonlinear optical effect per unit length by appropriately adjusting the refractive index ratio between the core and the cladding.

  When using a non-linear optical fiber, for example, in order to realize four-wave mixing over a sufficiently wide band covering two bands (for example, C band and L band), as described above, signal light (wavelength It is necessary to achieve phase matching between λs) and idler light (wavelength λc). Conditions for phase matching are described in, for example, Japanese Patent Application Laid-Open No. 7-98464 or Japanese Patent No. 3494661.

  As an example, as shown in FIG. 24, by alternately arranging an optical fiber having a positive chromatic dispersion and an optical fiber having a negative chromatic dispersion, a nonlinear optical fiber having an average dispersion of zero as a whole is obtained. Also good. In addition, when an optical fiber having a sufficiently large nonlinear effect (for example, a bismuth-substituted fiber) is used, four-wave mixing with sufficient efficiency can be generated even if the fiber length is short. However, such an optical fiber generally has a large chromatic dispersion. Therefore, in this case, it is preferable to compensate for the dispersion using a dispersion compensating fiber or the like. For example, in FIG. 24, N = 1, 3, 5,. . . , An optical fiber having a large nonlinear effect is arranged, and N = 2, 4, 6,. . . A fiber for compensating for the dispersion of the nonlinear optical fiber corresponding to the portion may be arranged.

In the optical switch 1 of the present invention, another nonlinear optical medium may be used instead of the nonlinear optical fiber. As other nonlinear optical media, for example, a semiconductor optical amplifier for four-wave mixing, a quantum dot optical amplifier, or a LiNbO ₃ waveguide (Periodically Poled LN) having a quasi-phase matching structure for three-wave mixing can be used. it can.

The control light pulse is not particularly limited, but for example, it is generated using a semiconductor laser, a fiber mode-locked laser, a saturable absorption optical modulator, a waveguide type modulator such as LiNbO _3, etc. I can do it.

  Furthermore, an optical amplifier that amplifies signal light and an optical filter that removes spontaneous emission (ASE) light from the output light of the optical amplifier may be further provided on the input side of the optical switch 1 shown in FIG.

  Next, an embodiment in which the present invention is applied to an optical communication system will be described. In the following, it is assumed that an optical signal transmitted from the transmitter 31 is transmitted to the receiver 32 via the optical repeater (or optical amplification repeater) 81. The operation status of the optical communication system is monitored or controlled by monitoring the waveform of the optical signal in the optical repeater 81.

  In this case, as shown in FIG. 25A, a monitor device 82 is connected to the optical repeater 81, and part of the signal light propagated through the first transmission path is guided to the monitor device 82. The monitor device 82 may be provided in the optical repeater 81. The monitor device 82 has, for example, a monitoring function equivalent to that of the optical sampling oscilloscope shown in FIG. 17, and can monitor the waveform of the signal light. Further, the monitor device 82 evaluates the waveform of the signal light, and the evaluation result is transmitted to the transmitter 31, the receiver 32, other repeaters, a network management system (Network Management System), and the like as necessary (hereinafter summarized). At least one of them). The evaluation of the waveform can be obtained, for example, by quantifying the opening of the eye pattern. Thereby, communication can be controlled in at least one communication apparatus.

  Further, as shown in FIG. 25B, the monitor optical signal sampled in the monitor device 82 (the optical pulse train output from the optical switch 1 shown in FIG. 17) is transmitted to at least one communication device, and the at least one You may make it evaluate a waveform in a communication apparatus. At this time, the sampled monitor light signal is transmitted superimposed on the signal light, for example. In this case, the light in which the signal light and the monitor light signal are multiplexed is converted into an electrical signal by the light receiver, and then only the monitor light signal is extracted by the band pass filter to monitor the waveform. Alternatively, the signal light may be temporarily stopped in the optical repeater 81 and only the monitor light signal may be transmitted to at least one communication device. Note that the sampled monitor light signal is a short pulse equivalent to the control light pulse, but the repetition period is, for example, several MHz to several hundred MHz, although degradation due to chromatic dispersion of the optical fiber or the like occurs in optical transmission. The compensation required to monitor the waveform is easy.

  In the above-described example, the information indicating the evaluation result of the signal waveform and the monitor optical signal are transferred to the transmitter and / or the receiver, but are transmitted to other devices (for example, a management server that manages the entire communication system). You may make it forward.

FIG. 26 is a diagram showing an example in which the present invention is applied to a nonlinear optical loop mirror (NOLM).
In FIG. 26, the signal light is branched into a set of branched signal lights having the same power by an optical coupler 91 having a branching ratio of 1: 1. One branched signal light is propagated clockwise through the loop of the nonlinear optical loop mirror, and the other branched signal light is propagated counterclockwise through the loop. Further, the control light pulse is supplied to the loop by the optical coupler 92 provided in the middle of the loop, and propagates in one direction (in this example, the clockwise direction). Here, the control light pulse has sufficient power to cause optical parametric amplification in the nonlinear optical fiber. Therefore, in the time domain where the control light pulse exists, the branch signal propagated in the clockwise direction is parametrically amplified and output. On the other hand, in the time domain where there is no control light pulse, the branched signal light propagated clockwise and the branched signal light propagated counterclockwise cancel each other, and the output becomes approximately zero.

  Similar to the optical Kerr switch, the nonlinear optical loop mirror can switch the signal light synchronized by the mutual phase modulation by the control light pulse. However, the signal light is blocked when there is no control light pulse when the signal lights propagating in the clockwise and counterclockwise directions with the same power return to the optical coupler 91 in the same polarization state. Realized by total internal reflection due to interference. In general, when a phase shift of π is given to signal light in one direction by cross phase modulation by a control light pulse, 100% transmission (that is, a switch) is obtained. In the present invention, as described above, signal light is parametrically amplified using a control light pulse with a much higher power. Thereby, although the reflected light by the optical coupler increases, it becomes possible to switch the signal light of higher power.

As described above, the present invention is not limited to the configuration including the polarization controller, the nonlinear optical fiber, and the polarizer as shown in FIG. 1, but can also be applied to a nonlinear optical loop mirror.
Furthermore, the present invention can be applied to an interferometer as shown in FIG. The interferometer (for example, a Mach-Zehnder interferometer) outputs the same signal as the signal light through the output port 1 and inverts the signal light through the output port 2 by controlling the mutual phase modulation of the nonlinear optical medium 93. A state of outputting a signal and a state of outputting the same signal as the signal light through the output port 2 and outputting an inverted signal of the signal light through the output port 1 are obtained.

  When the present invention is applied to this interferometer, the state of the nonlinear optical medium 93 is controlled using the above-described control light pulse. Further, the optical power of the control light pulse is sufficiently strong so that the signal light is optically parametric amplified in the nonlinear optical medium 93. Then, in the time domain where the control light pulse exists, the optical parametric amplified signal light is output from the output port 1, for example. In this case, the output port 1 is in the extinction state in the time region where no control light pulse exists. That is, even with an interferometer, optical amplification switching equivalent to the configuration shown in FIG. 1 is expected.

  As described above, the present invention is an optical switch including a nonlinear optical medium, and is characterized by optically parametrically amplifying the signal light by inputting the signal light and the control light pulse to the nonlinear optical medium. The invention includes all configurations that implement such operations.

  As the amplification effect used in the present invention, any nonlinear amplification effect that can be excited by the control light pulse can be used in the same manner as the optical parametric amplification. For example, when non-linear optical amplification (Raman amplification) by the Raman effect is generated using an optical fiber as a non-linear medium, this is achieved by using an optical pulse of about 12 THz higher frequency (short wavelength of about 100 nm) than the signal light as control light. The embodiments described above can be realized. However, in order to efficiently generate cross phase modulation and Raman amplification, it is necessary to reduce the Walk-off between the signal light pulse and the control light pulse. In order to reduce the walk-off, the chromatic dispersion of the nonlinear optical fiber is reduced and the slope of the chromatic dispersion is made extremely small (dispersion flat fiber), and the wavelengths of the signal light pulse and the control light pulse are nonlinear. A method of arranging them symmetrically with respect to the zero dispersion wavelength of the optical fiber is effective.

  Next, an optical switch that switches while amplifying phase modulation signal light or frequency modulation signal light will be described. In the above-described embodiments, the optical switch that switches the intensity-modulated signal light has been described. However, the optical switch of the present invention can also switch the phase-modulated signal light or the frequency-modulated signal light.

FIG. 28 is a diagram illustrating phase-modulated signal light and frequency-modulated signal light. Here, it is assumed that one symbol carries 1-bit data.
The phase-modulated signal light is RZ (Return-to-Zero) -PSK (Phase Shift Keying) signal light, and is obtained by optical phase modulation of an RZ pulse train in accordance with a data signal. Here, the RZ pulse train has substantially zero optical power between the symbols. In the example shown in FIG. 28, phase-modulated signal light in which the phase of the signal light changes to “ππ00π...” According to the data signal “11001. That is, modulation is performed so that the phase of the signal light is relatively shifted by “π” between the case where the data is “0” and the case where the data is “1”. Alternatively, when the data is “1”, the same phase as the immediately preceding bit may be assigned, and when the data is “0”, the phase obtained by adding “π” to the immediately preceding bit may be assigned. In any case, these phase modulations are realized by, for example, a method using a LiNbO ₃ modulator or cross phase modulation (XPM) in a nonlinear medium.

  In FIG. 28, BPSK in which 1 symbol carries 1-bit data is shown as the phase modulation method, but the present invention is applied to MPSK (M = 2, 4, 8, 16,...). Is possible. For example, as shown in FIG. 29, QPSK in which one symbol carries 2 bits of data is “π / 4”, “3π / 4”, “5π” for “00”, “10”, “11”, and “01”, respectively. / 4 "and" 7π / 4 "are assigned. The present invention is also applicable to CS (Carrier Suppress) RZ-DPSK signals.

  The frequency modulated signal light is RZ-FSK (Frequency Shift Keying) signal light, and is obtained by optical frequency modulating an RZ pulse train in accordance with a data signal. In the example shown in FIG. 28, frequency-modulated signal light is obtained in which the frequency of the signal light changes as “f2, f2, f1, f1, f2...” According to the data signal “11001. Such frequency modulation is performed using, for example, a semiconductor laser having excellent frequency conversion efficiency. The phase modulation signal light and the frequency modulation signal light are received by, for example, an optical heterodyne detection method or an optical homodyne detection method.

  FIG. 30A shows an embodiment of a demodulation circuit that demodulates DPSK (Differential PSK) signal light. In the DPSK system, the phase difference between adjacent bits is “0” or “π”. Therefore, the DPSK signal light can be demodulated using the 1-bit delay optical circuit 111. That is, if the phase difference between adjacent bits is “0”, the signal obtained by combining the input signal light and the 1-bit delayed signal light is “1 (with optical power)”. On the other hand, if the phase difference between adjacent bits is “π”, the signal obtained by combining the input signal light and the 1-bit delayed signal light is “0 (no optical power)”. Thereby, phase modulation signal light is converted into intensity modulation signal light. At present, a highly accurate 1-bit delay optical circuit has been put into practical use due to advances in optical waveguide technology. A receiver that detects a signal that has been conveyed by converting phase-modulated signal light into intensity-modulated signal light using such a 1-bit delay optical circuit has been developed.

  FIG. 30B shows an embodiment of a demodulation circuit that demodulates frequency modulated signal light. Here, it is assumed that the frequency-modulated signal light includes two frequencies f1 and f2. In this case, the frequency-modulated signal light can be converted into intensity-modulated light by using the optical bandpass filter 112-1 that transmits the frequency f1 or the optical bandpass filter 112-2 that transmits the frequency f2. The frequency-modulated signal light can be converted into an intensity-modulated signal using a Fabry-Perot resonator or an interferometer.

  FIG. 31A shows an embodiment of an optical switch that switches while amplifying the modulated signal light. Here, the optical switch 200 includes the polarization controllers 11 and 13, the nonlinear optical fiber 14, and the polarizer 15 shown in FIG. The modulated signal light is RZ phase modulated signal light or RZ frequency modulated signal light. Further, the control light pulse is generated from the control light having a wavelength different from that of the modulated signal light by using a clock regenerated from the modulated signal light. In the optical switch 200, the polarization state (polarization direction) of the control light pulse is set to a predetermined state (for example, about 45 degrees) with respect to the polarization state (polarization direction) of the modulated signal light. The operation of the optical switch 200 is basically as described with reference to FIGS.

  In this embodiment, as shown in FIG. 31B, the control light pulse is a flat pulse having a constant intensity over a time region in which the optical power of the modulated signal light is a predetermined value or more. Here, the predetermined value is, for example, zero (substantially zero), but may be another value (for example, ½ of the peak of the optical power of the modulated signal light). Here, if the optical power of the control light pulse is constant, the third-order nonlinear optical effect in the nonlinear optical fiber 14 is also constant. Therefore, when the control light pulse as described above is used, the modulated signal light is uniformly parametrically amplified. That is, the waveform of each pulse of the modulated signal light does not collapse.

  FIG. 32 shows another embodiment of the optical switch for switching the modulated signal light. In this embodiment, the time width of the control light pulse is shorter than the time width in which the optical power of the modulated signal light is a predetermined value or more. The method for generating such a control light pulse and the effect thereof are as described with reference to FIGS. That is, according to this optical switch, the time fluctuation of the modulated signal light caused by polarization mode dispersion (PMD) or the like is suppressed, so that the reception characteristics can be improved without providing a PMD compensator.

  In this way, in FIG. 31 or FIG. 32, the optical switch 200 switches the phase-modulated signal light or the frequency-modulated signal light while amplifying it before converting it into an intensity-modulated signal. The output of the optical switch 200 is given to the demodulator shown in FIG. 30 (a) or FIG. 30 (b).

  FIG. 33 shows an embodiment of an optical DEMUX using the optical switch of the present invention. Here, signal light obtained by time-division multiplexing the RZ-DPSK signal light or the RZ-FSK signal light is input to the optical switch 200. As an example, 160 Gbps multiplexed signal light obtained by multiplexing 4 channels of 40 Gbps signal light is input to the optical switch 200. The control light pulse is obtained by clock recovery from this signal light, and is applied to the nonlinear optical fiber included in the optical switch 200. At this time, the bit rate of the control light pulse is the bit rate of the channel to be extracted. Thereby, signal light of a desired channel is extracted from the multiplexed signal light.

  In the embodiments shown in FIG. 31 to FIG. 32, the optical switch according to the present invention is provided in the preceding stage of the demodulator that demodulates the modulated signal light. The frequency modulation signal light may be provided and used at the subsequent stage of the converter that converts the frequency modulation signal light into an intensity modulation signal.

  FIG. 34A shows an embodiment in which the DPSK signal light is switched after being converted into intensity modulated signal light. In this case, the DPSK signal light is converted into intensity modulated signal light using the 1-bit delay optical circuit 111 as described with reference to FIG. FIG. 34B shows an embodiment in which the FSK signal light is switched after being converted into intensity modulated signal light. In this case, as described with reference to FIG. 30B, the FSK signal light is converted into intensity-modulated signal light using the optical bandpass filter 112-1. If these configurations are introduced, jitter and PMD added to the signal light in the propagation path are suppressed and amplified, so that reception characteristics are improved.

  The optical switch of the present invention can be used as a main part of an optical sampling oscilloscope as described with reference to FIG. Here, by applying the optical switch of the present invention to the configuration shown in FIG. 34, it is possible to observe the data signal light waveform after the intensity modulation signal conversion. In this case, the optical sampling oscilloscope may observe the waveform of phase-modulated light or frequency-modulated light as shown in FIG. In this case, the eye pattern cannot be observed, but the quality of the signal light such as the S / N ratio of the signal light and the noise distribution can be measured.

Next, an optical switch using polarization diversity will be described.
In the optical switch 1 of the above-described embodiment, the polarization controller 11 is provided in front of the nonlinear optical fiber 14 and is controlled so that the polarization state (polarization direction) of the signal light is orthogonal to the polarization main axis of the polarizer 15. . On the other hand, the optical switch described below does not require a polarization controller for controlling the polarization state of the input signal light.

  FIG. 36 is a diagram illustrating a configuration of an optical switch using polarization diversity. In FIG. 36, the polarization separator 301 separates the input signal light into a first polarization signal (P polarization component) and a second polarization signal (S polarization component) that are orthogonal to each other. Each set of optical switches 302-1 and 302-2 includes the nonlinear optical fiber 14 and the polarizer 15 shown in FIG. 1, and the operations thereof are as described above. In the present embodiment, the polarization controller 13 may be omitted because a predetermined polarization signal is input to each of the optical switches 302-1 and 302-2 by the polarization separator 301. The control light pulse generation unit 303 includes a light source that generates control light having a wavelength different from the wavelength of the input signal light, and a clock regenerator that regenerates a clock from the input signal light. A control light pulse 2 is generated.

  In the optical switch 302-1, the first polarization signal and the control light pulse 1 are input to the nonlinear optical fiber 14, and the first polarization signal is parametrically amplified by the control light pulse 1. Similarly, in the optical switch 302-2, the second polarization signal is parametrically amplified by the control light pulse 2. The outputs of the optical switches 302-1 and 302-2 are combined by the polarization multiplexer 304. Thereby, the signal light can be switched without controlling the polarization state of the input signal light.

  Note that the optical gains in the optical switches 302-1 and 302-2 need to match each other. Here, the optical gains in the optical switches 302-1 and 302-2 are proportional to the product of the length of the nonlinear optical fiber 14, the nonlinear characteristic of the nonlinear optical fiber 14, and the optical power of the control light pulse, respectively. Further, the propagation delay of the path from the polarization separator 301 via the optical switch 302-1 to the polarization multiplexer 304 and the path of the path from the polarization separator 301 via the optical switch 302-2 to the polarization multiplexer 304 are illustrated. Propagation delays must match each other. In this case, the propagation delay can be adjusted by providing an optical delay circuit.

  FIG. 37 is a diagram for explaining the operation of the optical switch shown in FIG. FIG. 37A shows the state of the optical switch 302-1 and FIG. 37B shows the state of the optical switch 302-2.

  As described above, the first polarization signal and the second polarization signal are orthogonal to each other. As shown in FIG. 37A, the polarization state of the control light pulse 1 is set to a state rotated by 45 degrees with respect to the polarization state of the first polarization signal. In addition, the polarization main axis of the polarizer 15 of the optical switch 302-1 is set to be orthogonal to the polarization state of the first polarization signal. As a result, a part of the first polarization signal (a portion overlapping the control light pulse 1 in the nonlinear optical fiber 14 of the optical switch 302-1) is amplified and passes through the polarizer 15.

  Similarly, as shown in FIG. 37B, the polarization state of the control light pulse 2 is set to a state rotated 45 degrees with respect to the polarization state of the second polarization signal. Further, the polarization main axis of the polarizer 15 of the optical switch 302-2 is set to be orthogonal to the polarization state of the second polarization signal. A part of the second polarization signal (a part overlapping the control light pulse 2 in the nonlinear optical fiber 14 of the optical switch 302-2) is amplified and passes through the polarizer 15.

  FIG. 38 is a modification of the optical switch shown in FIG. In the configuration shown in FIG. 36, output switch light is obtained by combining the outputs of the optical switches 302-1 and 302-2 as optical signals. On the other hand, in the configuration shown in FIG. 38, the optical signals output from the optical switches 302-1 and 302-2 are converted into electrical signals using the light receivers 305-1 and 305-2, respectively, and the signal multiplexer 306 is used. To synthesize those electrical signals. In this configuration, the timing of the signals of the two paths can be adjusted using a variable length electric circuit.

  In the implementation of the present invention, it is necessary to set the polarization states of the signal light and the control light pulse input to the nonlinear optical fiber 14 to predetermined (for example, 45 degrees tilted) linearly polarized light. For example, as shown in FIG. 39, this setting is performed by monitoring the optical power of the signal output from the polarizer 15 using a light receiving element (PD) 401 and controlling the optical power to be optimum. The circuits 402 and 403 are realized by adjusting the polarization controllers 11 and 13, respectively. Here, in particular, the control light pulse often has a constant repetition frequency f. For this reason, in the feedback system that controls the polarization of the control light pulse, other frequency components (ie, noise) from the electrical signal obtained by the light receiving element 401 using the electrical band filter 404 that transmits the frequency f as the center frequency. It is desirable to remove. By providing this filter, the detection sensitivity is improved.

  Further, FIG. 39 shows a configuration for monitoring the output of the polarizer 15 provided on the output side of the optical switch. However, the signal light and the control light pulse input to the nonlinear optical fiber 14 are monitored, and the monitoring result is shown. The polarization controllers 11 and 13 may be adjusted according to the above.

FIG. 40 is a diagram showing the configuration of a system for testing the characteristics of the optical switch of the present invention. The test environment is as follows.
The highly nonlinear fiber HNLF corresponds to the nonlinear optical fiber 14 shown in FIG. 1, has a length of 20 m, a third-order nonlinear coefficient γ of 20.4 W ⁻¹ km ⁻¹ , a zero dispersion wavelength λ ₀ of 1579 nm, and a dispersion The slope is 0.03 ps / nm ² / km. The first mode-locked fiber laser (MLFL1) generates an optical pulse train of 10 GHz at a wavelength λs in the C band, and the optical pulse train is modulated by a LiNbO ₃ intensity modulator (LN, 10 Gbps, PRBS: 2 ²³ -1). Further, the modulated light is optical time division multiplexed (OTDM) to generate a data signal Es of 160 to 640 Gbps. The data signal Es is input to the highly nonlinear fiber HNLF together with a control pulse Ep generated by the second mode-locked fiber laser (MLFL2). The wavelength of the control pulse Ep is substantially the same as the highly nonlinear fiber HNLF zero dispersion wavelength λ ₀ and is arranged in the L band. The polarization direction of the control pulse Ep is 45 degrees.

  FIG. 41 is a diagram showing the switching gain when the peak power of the control pulse Ep is changed. The rate of the control pulse Ep is 10 GHz, and the wavelength λs of the data signal Es is 1550 nm. The pulse widths (FWHM) of the data signal Es and the control pulse Ep are 1.6 ps and 0.9 ps, respectively.

  The switching gain is defined as the power of the data signal Es output from the polarizer (Pol) with respect to the power of the data signal Es at the input of the highly nonlinear fiber HNLF. The power of the data signal Es increases approximately in proportion to the square of the peak power of the control pulse Ep by optical parametric amplification. When the peak power of the control pulse Ep is 15 W, 7.6 dB is obtained as the maximum switching gain.

  FIG. 42 is a diagram showing the switching gain when the wavelength of the data signal Es is changed. The peak power of the control pulse Ep is 15W. The switching gain is almost flat over the entire wavelength region of the C-band, thanks to good phase matching and a small walk-off in the 20 m highly nonlinear fiber HNLF. Note that by arranging the wavelength of the control pulse Ep in the C band, an optical switch that operates over the entire L band can be realized.

  The experimental result about the optical demultiplexer which isolate | separates the signal of 10Gbps from the optical time division multiplexing signal Es of 160Gbps, 320Gbps, and 640Gbps is shown. The pulse width of the signal Es is 1.6 ps at 160 Gbps, 0.75 ps at 320 Gbps, and 0.65 ps at 640 Gbps. The pulse width of the control pulse Ep is 0.9 ps.

Figure 43 is a diagram showing the measured BER when changing the reception power P _R of the separated signals. The average power of the control pulse is +21.8 dBm (equivalent to peak power = 15 W). The average power of the 160 Gbps signal Es input to the optical switch is −5 dBm.

At 160 Gbps, bit error rates were measured for signal wavelengths λs = 1535 nm, 1540 nm, 1550 nm, and 1560 nm, respectively. As a result, error-free operation (BER = 10 ⁻⁹ ) was realized with a power penalty of less than 0.2 dB over the entire wavelength band of the C band. Even for signals of 320 Gbps and 640 Gbps, error-free operation was realized with a slight increase in power penalty of 1.1 dB and 2.5 dB, respectively. This increase in power penalty is mainly due to residual crosstalk caused by the pulse width not being sufficiently narrow.

  The signal waveform observed with the oscilloscope after sampling using the optical switch of this invention is shown. 44A to 44E show eye patterns observed when the pulse width condition is the same as that in the second embodiment. The sampling rate is 311 MHz. Good eye patterns are obtained over 160 Gbps to 640 Gbps. Such excellent time resolution contributes to the realization of high-contrast optical sampling over the entire C band.

The above-described Examples 1 to 3 are described in the following papers.
S. Watanabe, et. Al. “Novel Fiber Kerr-Switch with Parametric Gain: Demonstration of Optical Demultiplexing and Sampling up to 640 Gb / s”, 30th European Conference on Optical Communication (ECOC), Stockholm, Sweden, September 2004, Post -deadline paper Th4.1.6, pp 12-13
<Others>
The embodiment including Examples 1 to 3 described above discloses the following invention.

(Supplementary note 1) a first polarization controller for controlling the polarization direction of the signal light;
A nonlinear optical medium to which signal light whose polarization direction is controlled by the first polarization controller is input;
A polarizer provided on the output side of the nonlinear optical medium and having a polarization main axis orthogonal to the polarization direction of the signal light output from the nonlinear optical medium;
The optical switch, wherein the signal light is optically parametrically amplified in the nonlinear optical medium by the control light pulse in a polarization direction of the control light pulse.

(Appendix 2) The optical switch according to Appendix 1,
Optical pulse generation means for generating the control light pulse with control light having a wavelength different from that of the signal light and supplying the control light pulse to the nonlinear optical medium.

(Appendix 3) The optical switch according to Appendix 1,
A second polarization controller provided between the optical pulse generation means and the nonlinear optical medium and configured to set the polarization direction of the control light pulse at a predetermined angle with respect to the polarization direction of the signal light; .

(Appendix 4) The optical switch according to Appendix 3,
The angle between the polarization direction of the signal light and the polarization direction of the control light pulse is 40 to 50 degrees.

(Appendix 5) The optical switch according to Appendix 3,
The angle between the polarization direction of the signal light and the polarization direction of the control light pulse is about 45 degrees.

(Appendix 6) The optical switch according to Appendix 1,
The power of the signal light output from the polarizer is greater than the power of the signal light input to the nonlinear optical medium.

(Appendix 7) The optical switch according to Appendix 1,
The wavelength of the signal light input to the nonlinear optical medium matches the wavelength of the signal light output from the polarizer.

(Appendix 8) The optical switch according to Appendix 1,
The nonlinear optical medium is an optical fiber having a chromatic dispersion variation of a certain value or less over the entire length range.

(Supplementary note 9) The optical switch according to supplementary note 1, wherein
The nonlinear optical medium is an optical fiber, and the average zero dispersion wavelength thereof matches or substantially matches the wavelength of the control light.

(Supplementary note 10) The optical switch according to supplementary note 1,
The nonlinear optical medium is a dispersion flat fiber in which chromatic dispersion is zero over the entire length range.

(Supplementary note 11) The optical switch according to supplementary note 8 or 9,
The optical fiber is a highly nonlinear optical fiber having a core doped with germanium or bismuth.

(Supplementary note 12) The optical switch according to any one of supplementary notes 8 to 11,
The optical fiber is a photonic crystal fiber.
(Supplementary note 13) The optical switch according to Supplementary note 1,
The nonlinear optical medium is a LiNbO ₃ waveguide having a quasi phase matching structure.

(Supplementary note 14) The optical switch according to supplementary note 1, wherein
The optical pulse generation means regenerates a clock from the branched light of the signal light, and generates a control light pulse that is synchronized with a signal propagated by the signal light using the regenerated clock.

(Supplementary note 15) The optical switch according to supplementary note 1, wherein
The control light is arranged in a wavelength band different from the wavelength band in which the signal light is arranged.

(Supplementary note 16) The optical switch according to supplementary note 1, wherein
An optical filter for removing spontaneous emission light provided on the output side of the polarizer;
(Supplementary note 17) The optical switch according to supplementary note 1, wherein
An optical amplifier that amplifies the signal light, and an optical filter that removes spontaneous emission light from the output light of the optical amplifier;
The output of the optical filter is provided to the first polarization controller.

(Supplementary note 18) The optical switch according to supplementary note 1, wherein
A waveform shaper for flattening the peak of the pulse of the signal light is further provided in front of the first polarization controller.

(Supplementary note 19) The optical switch according to supplementary note 1, wherein
The time width of the control light pulse is shorter than the time width of the signal light pulse.
(Supplementary note 20) The optical switch according to any one of supplementary notes 1 to 19,
A wavelength converter for converting light of the first wavelength into light of the second wavelength;
The control light pulse is generated from light having a second wavelength obtained by the wavelength converter.

(Supplementary note 21) The optical switch according to supplementary note 3,
A light receiving element for converting the output of the polarizer into an electrical signal;
A filter having a repetition frequency of the control light pulse as a center passing frequency, and filtering a signal output from the light receiving element;
And a control circuit for adjusting a polarization state of the control light pulse by the second polarization controller based on the output of the filter.

(Supplementary note 22) A control light pulse generated by a signal light having a predetermined polarization direction and a control light having a wavelength different from that of the signal light and a different polarization direction is input, and the control light pulse and the time are controlled by cross-phase modulation. A nonlinear optical medium that optically parametrically amplifies the signal light in the region to the polarization component in the polarization direction of the control light,
A polarizer provided on the output side of the nonlinear optical medium and having a polarization main axis orthogonal to the polarization direction of the signal light output from the nonlinear optical medium;
Having an optical switch.

(Supplementary Note 23) While the signal light whose polarization direction is controlled by the polarization controller is input to the nonlinear optical medium,
When there is no control light pulse having a wavelength different from the signal light and a different polarization component, the polarization of the signal light is orthogonal to the polarization main axis of the polarizer provided on the output side of the nonlinear optical medium by the polarization controller. Set as
An optical switch characterized in that, by supplying the control light pulse to the nonlinear optical medium, the signal light is optically parametrically amplified in the polarization direction of the control light pulse in the nonlinear optical medium.

(Supplementary Note 24) A polarization controller that controls the polarization direction of the signal light;
A nonlinear optical medium to which signal light whose polarization direction is controlled by the polarization controller is input;
A polarizer provided on the output side of the nonlinear optical medium and having a polarization principal axis orthogonal to the polarization direction of the signal light output from the nonlinear optical medium;
A receiver that converts the output of the polarizer into an electrical signal;
Monitoring means for monitoring the waveform of the signal light by tracing the electrical signal in the time direction,
The signal light is optically parametrically amplified in the polarization direction of the control light pulse by the control light pulse having a frequency different from the bit rate of the signal propagated by the signal light in the nonlinear optical medium.
An optical waveform monitor device characterized by the above.

(Appendix 25) A polarization controller for controlling the polarization direction of the signal light;
A nonlinear optical medium to which signal light whose polarization direction is controlled by the polarization controller is input;
A polarizer provided on the output side of the nonlinear optical medium;
A receiver that converts the output of the polarizer into an electrical signal;
Monitoring means for monitoring the waveform of the signal light by tracing the electrical signal in the time direction,
The signal light is optically parametrically amplified in the polarization direction of the control light pulse by the control light pulse having a frequency different from the bit rate of the signal propagated by the signal light in the nonlinear optical medium,
The polarization direction of the signal light in the absence of the control light is set by the polarization controller to be orthogonal to the polarization main axis of the polarizer.
An optical waveform monitor device characterized by the above.

(Supplementary note 26) An optical communication system having an optical repeater on a transmission line,
The optical repeater includes the optical waveform monitoring device described in appendix 24,
The optical waveform monitor device transmits an evaluation result on the waveform of the signal light propagating through the transmission path to a predetermined device.

(Supplementary note 27) An optical communication system having an optical repeater on a transmission line,
The optical repeater includes the optical waveform monitoring device described in appendix 24,
The optical waveform monitor device transmits an optical pulse train output from the polarizer when signal light propagating through the transmission path is input to the nonlinear optical medium, to a predetermined device,
In the predetermined apparatus, the waveform of the signal light is monitored based on the optical pulse train.

(Supplementary note 28) Control polarization direction of signal light,
A control light pulse is generated with control light having a wavelength different from that of the signal light,
The polarization direction of the control light pulse is set to a predetermined angle with respect to the polarization direction of the signal light,
The signal light and control light pulse are input to a nonlinear optical medium,
In the nonlinear optical medium, in the region overlapping with the control light pulse in time, the signal light optically parametrically amplified in the polarization direction of the control light pulse, the polarization direction of the signal light in the region where the control light pulse does not exist A portion of the signal light that overlaps in time with the control light pulse is extracted by passing a polarizer having a polarization main axis orthogonal to the optical switch method.

(Appendix 29) Controlling the polarization direction of the first signal light,
Generating a control light pulse with control light having a wavelength different from that of the first signal light,
Setting the polarization direction of the control light pulse to a predetermined angle with respect to the polarization direction of the first signal light;
Inputting the first signal light and the control light pulse to the nonlinear optical medium;
In the region overlapping with the control light pulse in time, the control light is converted into a first signal light whose polarization direction is changed by cross-phase modulation and optically parametrically amplified to a polarization component in the polarization direction of the control light. By passing through a polarizer having a polarization principal axis orthogonal to the polarization direction of the first signal light in the absence of the first signal light, to time-multiplex the second signal light that does not overlap in time with the first signal light;
An optical switch method.

(Supplementary note 30) The optical switch method according to supplementary note 29,
The optical switch has a nonlinear optical loop mirror configuration,
By inputting the first signal light to the first optical coupler constituting the loop mirror, the branched light of the first signal light is propagated with equal power in both directions of the loop, and is arranged in the middle of the loop. An optical switch method comprising: inputting the control light pulse from two optical couplers in one direction of a loop, and optically parametrically amplifying a component of the first signal light propagating in the same direction as the control light pulse.

(Supplementary Note 31) After shaping the waveform so that the peak of the optical pulse of the signal light is flat, the polarization direction of the signal light is controlled,
A control light pulse is generated with control light having a wavelength different from that of the signal light,
The polarization direction of the control light pulse is set to a predetermined angle with respect to the polarization direction of the signal light,
The signal light and control light pulse are input to a nonlinear optical medium,
In the non-linear optical medium, the signal light that is optically parametrically amplified to the polarization component in the polarization direction of the control light pulse in the time domain that overlaps the control light pulse in time is the signal in the absence of the control light pulse. An optical switch method characterized in that the signal light in the time domain overlapping the control light pulse is extracted by passing a polarizer having a polarization main axis orthogonal to the polarization direction of light.

(Supplementary Note 32) A control light pulse having a shorter time width than the optical pulse of the signal light is generated with the control light having a wavelength different from that of the signal light,
The polarization direction of the control light pulse is set to a predetermined angle with respect to the polarization direction of the signal light,
The signal light and control light pulse are input to a nonlinear optical medium,
In the non-linear optical medium, the signal light that is optically parametrically amplified to the polarization component in the polarization direction of the control light pulse in the time domain that overlaps the control light pulse in time is the signal in the absence of the control light pulse. An optical switch method characterized in that the signal light in the time domain overlapping the control light pulse is extracted by passing a polarizer having a polarization main axis orthogonal to the polarization direction of light.

  (Supplementary Note 33) Reflected light, transmitted light, or light emitted from the measured object obtained by inputting probe light to the device under test is used as signal light, and the signal waveform is monitored by the optical waveform monitor device according to Appendix 24. Measurement method for monitoring waveforms.

(Supplementary Note 34) Nonlinear optical medium to which signal light and control light pulse are input;
Optical means for outputting the signal light in the time domain overlapping with the control light pulse in the nonlinear optical medium, and blocking the signal light in the time domain in which the control light pulse does not exist in the nonlinear optical medium,
The optical switch is characterized in that the signal light is optically parametrically amplified in the nonlinear optical medium by the control light pulse in a polarization direction of the control light pulse.

(Supplementary Note 35) Nonlinear optical medium to which signal light and control light pulse are input;
Optical means for outputting the signal light in the time domain overlapping with the control light pulse in the nonlinear optical medium, and blocking the signal light in the time domain in which the control light pulse does not exist in the nonlinear optical medium,
The signal light is nonlinearly amplified by the control light pulse in the nonlinear optical medium substantially in the polarization direction of the control light pulse.
An optical switch characterized by that.

(Appendix 36) A polarization controller that controls the polarization direction of the signal light;
A nonlinear optical medium to which signal light whose polarization direction is controlled by the polarization controller is input;
A polarizer provided on the output side of the nonlinear optical medium and having a polarization main axis orthogonal to the polarization direction of the signal light output from the nonlinear optical medium;
The optical switch, wherein the signal light is optically amplified in a polarization direction of the control light pulse by a nonlinear effect generated by the control light pulse in the nonlinear optical medium.

(Supplementary note 37) The optical switch according to supplementary note 36,
The signal light is optically Raman amplified by the control light pulse in the nonlinear optical medium.

(Supplementary Note 38) A polarization controller for controlling the polarization direction of the phase modulation signal light or the frequency modulation signal light;
A nonlinear optical medium to which signal light whose polarization direction is controlled by the polarization controller is input;
A polarizer provided on the output side of the nonlinear optical medium and having a polarization main axis orthogonal to the polarization direction of the signal light output from the nonlinear optical medium;
The signal light is optically parametrically amplified by the control light pulse in the polarization direction of the control light pulse in the nonlinear optical medium.
An optical switch characterized by that.

(Supplementary note 39) The optical switch according to supplementary note 38,
The signal light is RZ phase modulation signal light or RZ frequency modulation signal light.
(Supplementary note 40) The optical switch according to supplementary note 39,
The control light pulse has a constant intensity over a time region in which the optical power of the signal light is a predetermined value or more.

(Supplementary note 41) The optical switch according to supplementary note 39,
The time width of the control light pulse is shorter than the time width in which the optical power of the signal light is a predetermined value or more.

(Supplementary Note 42) A phase-modulated signal light or frequency-modulated signal light having a predetermined polarization direction and a control light pulse generated by a control light having a wavelength different from that of the signal light and a different polarization direction are input and cross-phase modulated. A nonlinear optical medium that changes the polarization state of the signal light in a region overlapping with the control light pulse in time, and optically parametrically amplifies the signal light in the region substantially in the polarization direction of the control light pulse;
A polarizer provided on the output side of the nonlinear optical medium and having a polarization main axis orthogonal to the polarization direction of the signal light output from the nonlinear optical medium;
Having an optical switch.

(Appendix 43) A polarization controller for controlling the polarization direction of the phase modulation signal light or the frequency modulation signal light;
A nonlinear optical medium to which signal light whose polarization direction is controlled by the polarization controller is input;
A polarizer provided on the output side of the nonlinear optical medium and having a polarization principal axis orthogonal to the polarization direction of the signal light output from the nonlinear optical medium;
A receiver that converts the output of the polarizer into an electrical signal;
Monitoring means for monitoring the waveform of the signal light by tracing the electrical signal in the time direction,
The signal light is optically parametrically amplified in the polarization direction of the control light pulse by the control light pulse having a frequency different from the bit rate of the signal propagated by the signal light in the nonlinear optical medium.
An optical waveform monitor device characterized by the above.

(Supplementary Note 44) Control the polarization direction of the phase modulation signal light or the frequency modulation signal light,
A control light pulse is generated with control light having a wavelength different from that of the signal light,
The polarization direction of the control light pulse is set to a predetermined angle with respect to the polarization direction of the signal light,
The signal light and control light pulse are input to a nonlinear optical medium,
In the nonlinear optical medium, in the region overlapping with the control light pulse in time, the signal light optically parametrically amplified in the polarization direction of the control light pulse, the polarization direction of the signal light in the region where the control light pulse does not exist A portion of the signal light that overlaps in time with the control light pulse is extracted by passing a polarizer having a polarization main axis orthogonal to the optical switch method.

(Supplementary Note 45) The control light pulse generated from the control light having a wavelength different from that of the signal light with respect to the polarization direction of the signal light obtained by time-division multiplexing the phase modulation signal light or the frequency modulation signal light. Set the polarization direction to a predetermined angle,
The signal light and control light pulse are input to a nonlinear optical medium,
In the nonlinear optical medium, in the region overlapping with the control light pulse in time, the signal light optically parametrically amplified in the polarization direction of the control light pulse, the polarization direction of the signal light in the region where the control light pulse does not exist A portion of the signal light that overlaps in time with the control light pulse is extracted by passing a polarizer having a polarization main axis orthogonal to the optical switch method.

(Supplementary note 46) The optical switch according to supplementary note 1,
An optical converter for converting the phase modulation signal light or the frequency modulation signal light into the intensity modulation signal light;
The signal light is intensity modulated signal light obtained by the optical converter.

(Supplementary note 47) The optical switch according to supplementary note 46,
The optical converter includes a 1-bit delay optical circuit for converting phase-modulated signal light into intensity-modulated signal light.

(Appendix 48) The optical switch according to appendix 46,
The optical converter includes an optical filter for converting frequency modulation signal light into intensity modulation signal light.

(Supplementary note 49) The optical switch according to supplementary note 1, wherein
The signal light is RZ phase modulation signal light or RZ frequency modulation signal light.
(Supplementary Note 50) A polarization separator that separates signal light into first and second polarization signals orthogonal to each other;
First and second nonlinear optical media to which the first and second polarization signals are respectively input;
First and second polarizers respectively provided on the output side of the first and second nonlinear optical media, each having a polarization main axis orthogonal to the polarization direction of the first and second polarization signals;
Combining means for combining the outputs of the first and second polarizers,
The first polarization signal is optically parametrically amplified in the first nonlinear optical medium by the first control light pulse in the polarization direction of the first control light pulse, and the second polarization signal is In the nonlinear optical medium, the second control light pulse is optically parametrically amplified in the polarization direction of the second control light pulse.
An optical switch characterized by that.

It is a figure which shows the basic composition of the optical switch of this invention. It is a figure which shows an example of a signal light and a control light pulse. It is an example of the method of producing | generating a control light pulse. It is a figure explaining the principle of operation of an optical Kerr switch. It is a figure which shows typically operation | movement of an optical Kerr switch. It is a figure explaining the switching by the optical switch of this invention. It is a figure explaining the operation | movement area | region of the optical switch of this invention, and the existing optical Kerr switch. It is an Example which performs optical 2R reproduction | regeneration using the optical switch of this invention. It is a figure explaining optical 2R reproduction | regeneration shown in FIG. It is other embodiment of optical 2R reproduction | regeneration. It is a figure explaining the control light pulse produced | generated in optical 2R reproduction | regeneration shown in FIG. It is a figure which shows the Example by which an optical switch is used in a receiver. FIG. 3 is a diagram showing an embodiment in which an optical switch is used in a relay node. It is a figure which shows the optical transmission system which uses the optical switch of this invention in an optical repeater. It is a figure which shows a mode that an extinction ratio is improved. It is an Example of the optical switch using the flattened control light pulse. FIG. 6 illustrates an embodiment in which an optical switch is used in an optical sampling oscilloscope. It is a figure which shows the method of observing a to-be-measured object using a light pulse. It is an Example of the material analysis apparatus using the optical switch of this invention. It is a figure which shows an example of wavelength arrangement | positioning of control light. It is a figure which shows an example of wavelength arrangement | positioning of signal light and control light. It is a figure which shows the structure of the optical switch provided with the function which converts the wavelength of a control light pulse. It is a figure explaining wavelength conversion by four-wave mixing. It is a figure which shows an example of the dispersion compensation in an optical fiber. It is a figure which shows the optical communication system in which the optical waveform monitoring apparatus which concerns on this invention is used. It is a figure which shows the example which applied this invention to the nonlinear optical loop mirror. It is a figure which shows the interferometer to which this invention is applied. It is a figure which shows the signal light by which the phase modulation was carried out, and the signal light by which the frequency modulation was carried out. It is a figure explaining QPSK. (A) is an example of a demodulating circuit that demodulates DPSK signal light, and (b) is an example of a demodulating circuit that demodulates FSK signal light. It is an Example of the optical switch which switches modulation signal light. It is another Example of the optical switch which switches modulation signal light. It is an Example of optical DEMUX using the optical switch of this invention. It is an Example of the optical switch which switches, after converting phase modulation signal light or frequency modulation signal light into an intensity modulation signal. It is an Example of the optical sampling oscilloscope which monitors a phase modulation signal light or a frequency modulation signal light. It is an Example (the 1) of the optical switch using polarization diversity. It is a figure explaining operation | movement of the optical switch shown in FIG. It is an Example (the 2) of the optical switch using polarization diversity. It is a figure explaining the control system which controls the polarization of signal light and control light. It is a figure which shows the system configuration | structure for investigating the characteristic of the optical switch of this invention. It is a figure which shows the switching gain when changing the power of a control pulse. It is a figure which shows the switching gain when changing the wavelength of a data signal. It is a figure which shows the BER measured value when changing the receiving power of the isolate | separated signal. It is a figure which shows the eye pattern of the signal optically sampled using the optical switch of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Optical switch 11, 13 Polarization controller 12 Control light pulse production | generation part 14 Non-linear optical fiber 15 Polarizer 16 Optical band pass filter 21 Optical branching device 22 Clock regeneration part 31 Transmitter 32 Receiver 33 Optical repeater 41 Optical repeater node 42 Optical branching device 51 Sampling pulse generator 52 Light receiver 53 Oscilloscope 61 Main circuit 62 O / E converter 63 Analyzer 71 Control light pulse generator 72 Wavelength converter 73 Light source 74 Non-linear optical fiber 81 Optical repeater 82 Monitor device 91 92 Optical coupler 93 Nonlinear optical medium 100 Main circuit 101 Waveform shaper 102 Control light pulse generator 111 1-bit delay optical circuit 112-1 and 112-2 Optical bandpass filter 200 Optical switch 301 Polarization separator 302-1 and 302- 2 303 optical switches The light pulse generation unit 304 polarization multiplexer 305-1,305-2 photodetector

Claims (9)

A polarizer having a predetermined polarization principal axis;
A signal light having a predetermined polarization direction and a control light pulse having a wavelength different from that of the signal light and having a polarization direction that is not orthogonal to the polarization direction of the signal light and not the same as the polarization direction of the signal light are input. A nonlinear optical medium,
A light receiving element that converts the output of the polarizer into an electrical signal;
A filter having a repetition frequency of the control light pulse as a center passing frequency, and filtering an electric signal output from the light receiving element;
A control circuit for controlling the polarization state of the control light pulse based on the output of the filter;
In the non-linear optical medium, the signal light in a region overlapping with the control light pulse in time is changed in polarization direction to the polarization direction of the control light pulse by the control light pulse and is optically parametric amplified and output.
In the nonlinear optical medium, signal light in a region that does not overlap in time with the control light pulse is output in a polarization direction orthogonal to the polarization main axis of the polarizer,
The optical switch is characterized in that the same polarization component as the polarization main axis of the polarizer passes through the output light of the nonlinear optical medium. The optical switch according to claim 1,
The optical switch, wherein the control light pulse is an optical pulse generated with control light having a wavelength different from that of the signal light and having a shorter time width than the optical pulse of the signal light. A polarizer having a predetermined polarization principal axis;
Signal light having a predetermined polarization direction and a control light pulse having a wavelength different from that of the signal light and having a polarization direction that is not orthogonal to the polarization direction of the signal light and not the same as the polarization direction of the signal light are input. A nonlinear optical medium,
A light receiving element for converting the output of the polarizer into an electrical signal;
A filter having a repetition frequency of the control light pulse as a center passing frequency, and filtering an electric signal output from the light receiving element;
A control circuit for controlling the polarization state of the control light pulse based on the output of the filter;
A receiver that converts the output of the polarizer into an electrical signal;
Monitoring means for monitoring the waveform of the signal light by tracing the electrical signal output from the light receiver in the time direction,
The repetition frequency of the control light pulse is different from the bit rate frequency of the signal propagated by the signal light,
In the non-linear optical medium, the signal light in a region overlapping with the control light pulse in time is changed in polarization direction to the polarization direction of the control light pulse by the control light pulse and is optically parametric amplified and output.
In the nonlinear optical medium, signal light in a region that does not overlap in time with the control light pulse is output in a polarization direction orthogonal to the polarization main axis of the polarizer,
The optical waveform monitor device characterized in that the polarizer passes the same polarization component as the polarization main axis of the polarizer in the output light of the nonlinear optical medium. The optical waveform monitoring device according to claim 3,
The optical waveform monitoring apparatus, wherein the polarization direction of the signal light input to the nonlinear optical medium is set to be orthogonal to the polarization main axis of the polarizer. By inputting the signal light to the first optical coupler constituting the nonlinear optical loop mirror, the branched light of the signal light is propagated with equal power in both directions of the loop,
A control light pulse generated by a control light having a wavelength different from that of the signal light is input in one direction of the loop from a second optical coupler disposed in the middle of the loop,
An optical switch method characterized by optically parametrically amplifying a component of signal light propagating in the same direction as the control light pulse in an optical fiber constituting the nonlinear optical loop mirror. A nonlinear optical medium to which signal light and a control light pulse having a wavelength different from that of the signal light are input;
Optical means for outputting the signal light in the time domain overlapping with the control light pulse in the nonlinear optical medium, and blocking the signal light in the time domain in which the control light pulse does not exist in the nonlinear optical medium,
The nonlinear optical medium is provided on one arm of an interferometer including a pair of arms,
The optical switch is characterized in that the signal light is optically parametrically amplified in the nonlinear optical medium by the control light pulse in a polarization direction of the control light pulse. A nonlinear optical medium to which signal light and a control light pulse having a wavelength different from that of the signal light are input;
Optical means for outputting the signal light in the time domain overlapping with the control light pulse in the nonlinear optical medium, and blocking the signal light in the time domain in which the control light pulse does not exist in the nonlinear optical medium,
The nonlinear optical medium is provided on one arm of an interferometer including a pair of arms,
The optical switch, wherein the signal light is nonlinearly amplified in the nonlinear optical medium by the control light pulse substantially in a polarization direction of the control light pulse. A polarizer having a predetermined polarization principal axis;
Signal light having a predetermined polarization direction and a control light pulse having a wavelength different from that of the signal light and having a polarization direction that is not orthogonal to the polarization direction of the signal light and not the same as the polarization direction of the signal light are input. A nonlinear optical medium,
A light receiving element for converting the output of the polarizer into an electrical signal;
A filter having a repetition frequency of the control light pulse as a center passing frequency, and filtering an electric signal output from the light receiving element;
A control circuit for controlling the polarization state of the control light pulse based on the output of the filter;
In the nonlinear optical medium, the signal light in the region overlapping with the control light pulse in time is changed in the polarization direction to the polarization direction of the control light pulse by the control light pulse and nonlinearly amplified and output.
In the nonlinear optical medium, signal light in a region that does not overlap in time with the control light pulse is output in a polarization direction orthogonal to the polarization main axis of the polarizer,
The optical switch allows the same polarization component as the polarization main axis of the polarizer to pass through in the output light of the nonlinear optical medium. A polarization separator that separates the signal light into first and second polarization signals orthogonal to each other;
The first polarized signal light has a wavelength different from that of the first polarized signal light, is not orthogonal to the polarization direction of the first polarized signal light, and is the same as the polarization direction of the first polarized signal light. A first nonlinear optical medium to which a first control light pulse having a non-polarization direction is input;
A first polarizer provided on the output side of the first nonlinear optical medium;
The second polarization signal light has a wavelength different from that of the second polarization signal light, and is not orthogonal to the polarization direction of the second polarization signal light and is the same as the polarization direction of the second polarization signal light. A second nonlinear optical medium to which a second control light pulse having a non-polarization direction is input;
A second polarizer provided on the output side of the second nonlinear optical medium;
Combining means for combining the outputs of the first and second polarizers,
In each of the first and second nonlinear optical media, the polarization signal light in the region overlapping with the control light pulse in time is changed in polarization direction to the polarization direction of the control light pulse by the corresponding control light pulse. Optical parametric amplification and output,
In the first and second nonlinear optical media, signal light in a region that does not overlap in time with the control light pulse is output in a polarization direction orthogonal to the polarization main axis of the corresponding polarizer,
Each of the first and second polarizers transmits the same polarization component as the polarization main axis of the polarizer in the output light of the corresponding nonlinear optical medium.