JPH11218628A - Light dispersion compensating element, and semiconductor laser device and optical communication system using the element - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a small-sized transmission type light dispersion compensating element which is suitably integrated and coupled well with other devices and a short- pulse semiconductor laser device and optical communication system which use it. SOLUTION: The light dispersion compensating element is composed of an optical waveguide grating router 1 which demultiplexes light pulses made incident on one input optical waveguide 2 into frequency components having equal frequency intervals and outputs them from different output waveguides 6, a dispersion compensating optical waveguide 7 consisting of different-length optical waveguides for generating phase differences between respective frequency components, and an optical waveguide grating router 9 which multiplexes frequency components from the dispersion compensating optical waveguide 7 into light pulses again. The very small-sized short-pulse semiconductor laser device (light source) can be actualized by combining this light dispersion compensating element with a semiconductor laser element and further this dispersion compensating element is arranged in an optical transmission line to obtain the optical communication system with good performance.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical dispersion compensating element, a semiconductor laser device using the element, and an optical communication system, and more particularly to a time division multiplex communication system or a hybrid of a time division multiplex communication and a wavelength division multiplex communication system. Optical pulse waveform shaping element in a long-distance large-capacity optical communication system having a communication system as a pillar, or an optical dispersion compensating element used in such a communication system or an ultrashort optical pulse generator indispensable for ultra-high-speed optical measurement, and the like. The present invention relates to a semiconductor laser device using an element and an optical communication system using the same.

[0002]

2. Description of the Related Art Generally, an optical pulse from a pulse light source or an optical pulse propagating in an optical fiber is affected by a material or a structural dispersion (caused by a wavelength dependence of a group velocity of light). Above, the pulse width spreads,
Or, the waveform deteriorates. This degradation of the optical pulse can cause communication errors in a long-distance, large-capacity optical communication system based on a time division multiplex communication system using optical pulse transmission or a hybrid communication system of time division multiplex communication and wavelength division multiplex communication. It is not preferable because it may cause it.

The solution to this problem is to compensate for the effects of dispersion, and the element that does so is an "optical dispersion compensating element".
Called. Various types of “light dispersion compensating elements” have been conventionally known. Typical examples include an optical fiber dispersion compensator, a diffraction grating dispersion compensator, a dielectric multilayer film dispersion compensator, and a grating optical fiber dispersion compensator (references: Tadashi Sueda, Takeshi Kamiya, "Ultra High Speed"). Optoelectronics, Chapter 2, "Laser Pulse Compression-Effects of Dispersion and Chirp" (June 1991)
15th, Baifukan) and Kawaja et al., IEEE
Photonics Technology Letter, ”Vol. 7, 158
Pp. (1995)).

FIG. 6 shows an optical fiber dispersion compensator, a diffraction grating dispersion compensator, a dielectric multilayer film dispersion compensator,
FIG. 3 is a diagram illustrating the principle of a grating optical fiber dispersion compensating element. The “optical fiber dispersion compensating element”, as shown in FIG. 2A, inputs and propagates a short optical pulse 66 into an optical fiber 67 used for normal transmission, and “refractive index dispersion” of the optical fiber. Pulse 6 dispersion-compensated using
6 'is a transmission type light dispersion compensating element for obtaining 6'.
The "diffraction grating dispersion compensating element" is composed of two opposing diffraction gratings 68 and 68 'as shown in FIG. 2B, and the incident light pulse 66 is converted by the diffraction gratings 68 and 68'. This is a transmission type dispersion light compensating element for obtaining an output light pulse 66 'after being reflected twice. In this element, dispersion compensation is performed using "wavelength dependence" of a delay time (or propagation distance) generated by two reflections.

The "dielectric multilayer film dispersion compensating element" is a reflection type dispersion compensating element in which an optical pulse is reflected by a dielectric multilayer film 69 to obtain an output optical pulse, as shown in FIG. is there. In this element, a multilayer film of a high-refractive-index dielectric film and a low-refractive-index dielectric film is used, and dispersion is compensated for by utilizing the wavelength dependence of multi-wave interference due to multiple reflection from the boundary between the films. The “grating optical fiber dispersion compensating element” partially changes the refractive index of the optical fiber as shown in FIG.
0), the input light pulse 66 is reflected at the boundary between different refractive indexes to obtain the output light pulse 66 '.
This is based on the same principle as the above-mentioned "dielectric multilayer film dispersion compensating element", and the dispersion is compensated by utilizing the wavelength dependence of multi-wave interference due to multiple reflection from the boundary of the refractive index. The “dielectric multilayer film dispersion compensator” and “grating optical fiber dispersion compensator” are reflection-type devices that perform dispersion compensation by using the large dispersion effect in the high reflection region with a wide spectral width caused by multiple reflection of light. It is a light dispersion compensating element.

[0006] The "optical fiber dispersion compensating element" requires an optical fiber having a length of 100 m to several km due to the minute dispersion effect of the optical fiber. There are drawbacks such as high price.
In the "diffraction grating dispersion compensating element", it is difficult to set the alignment of two diffraction gratings and the like, which causes unstable operation. On the other hand, "dielectric multilayer film dispersion compensator" and "grating optical fiber dispersion compensator"
Is stable because it is ultra-small and monolithic, but is not suitable for integration because it is reflective.

[0007]

[Problems to be Solved by the Invention] Femtosecond (10 ⁻¹⁵⁾
In order to realize a short pulse laser device in the second) range, it is essential to use a dispersion compensating element. Considering the stability and miniaturization of the short-pulse laser device, the dispersion compensating element is desirably a small-sized and transmission-type (since alignment or integration is easy) dispersion compensating element. .

[0008] None of the dispersion compensating elements described in the section of the prior art described above satisfies the above conditions. That is, the optical fiber dispersion compensating element and the diffraction grating dispersion compensating element are transmission type but large and lack stability, and the “dielectric multilayer film dispersion compensating element” and the “grating optical fiber dispersion compensating element” are small-sized. Although it is stable, it is not suitable for integration because it is a reflection type, it has poor coupling with other devices, and does not satisfy the above conditions. SUMMARY OF THE INVENTION In view of the above circumstances, an object of the present invention is to provide a small and transmission type optical dispersion compensator suitable for integration and good coupling with other devices, a short pulse semiconductor laser device using the same, and an optical communication system. Is to provide.

[0009]

In order to achieve the above object, an optical dispersion compensating element which is a basic configuration of the present invention is realized by two optical waveguide grating routers and optical waveguides having different lengths provided therebetween. Is what you do. More specifically, the optical dispersion compensating element of the present invention provides an optical waveguide that splits an optical pulse incident on one input optical waveguide into frequency components having equal frequency intervals and outputs them from a plurality of different output optical waveguides. The waveguide grating router (1) includes a plurality of optical waveguides having different lengths for inputting the output optical pulses of the respective frequency components, generating a phase difference between the optical pulses of the respective frequency components, and outputting the generated optical pulses. It comprises a dispersion compensating optical waveguide (7) and an optical waveguide grating router (9) for combining the outputted optical pulses of a plurality of frequency components into one optical pulse again (see FIG. 1).

Further, the short-pulse semiconductor laser device of the present invention is applicable to various semiconductor laser devices (active mode-locked semiconductor laser device, passive mode-locked semiconductor laser device, hybrid mode-locked semiconductor laser device, gain switch type semiconductor laser device, etc.). The output is input to the optical dispersion compensating element according to claim 1, and a short pulse laser is output from the optical dispersion compensating element (see FIGS. 2 to 4). Further, the optical communication system of the present invention uses the short pulse semiconductor laser device as a light source and an optical repeater circuit using the optical dispersion compensating element (61) as an optical pulse waveform shaping element in an optical propagation path. (See FIG. 5).

[0011]

BEST MODE FOR CARRYING OUT THE INVENTION An optical dispersion compensating element, which is a basic configuration of the present invention, makes an optical pulse incident on a (1: N) optical waveguide grating router having one input port and N output ports. The input light pulse is split into N frequency components having equal frequency intervals, and each frequency component is output from different N output optical waveguides. Next, optical waveguides having different lengths are coupled to the N output optical waveguides, and a phase difference is generated between the respective frequency components to perform dispersion compensation. Finally, the light is passed through an (N to 1) optical waveguide grating router and is again synthesized into an optical pulse. The above process is
All are performed in a transmission type. Also, this optical dispersion compensating element
SiO ₂ is formed on a Si substrate or In ₂ is formed on an InP substrate.
For example, GaAsP can be formed as an integrated device using a semiconductor material, and the size can be reduced. The use of the above-described elements makes it possible to realize a small-sized transmission-type light dispersion compensation element.

Hereinafter, embodiments of the optical dispersion compensating element according to the present invention will be described in detail with reference to the drawings. <Embodiment 1> This embodiment is an embodiment of an optical dispersion compensating element which is the basis of the present invention. FIG. 1 is a diagram for explaining the structure of the optical dispersion compensating element according to the present embodiment.
(A) is a top view (plan view) and (b) is a diagram showing a cross section thereof. As shown in FIG. 3A, the optical dispersion compensating element of this embodiment is roughly divided into a (1: N) optical waveguide grating router 1 and a dispersion compensating optical waveguide 7.
And an (N to 1) optical waveguide grating router 9.

First, the (1: N) optical waveguide grating router 1 includes one input optical waveguide 2, a free space region 3,
It is composed of N coupling optical waveguides 4, a free space region 5, and N output optical waveguides 6. Here, the optical pulse 15 incident on the input optical waveguide 2 is split into N frequency components having equal frequency intervals in the free space region 3, and the N frequency components thus split are N Are output from N different output optical waveguides 6 through the coupled optical waveguide 4 and the free space region 5.

Next, the dispersion compensating optical waveguide 7 is connected to each of the N output optical waveguides 6 and has a different length.
The optical waveguides 8 are constituted. In this dispersion compensating optical waveguide 7, a phase difference is given to each frequency component demultiplexed by the (1: N) optical waveguide grating router 1 by the optical waveguides 8 having different lengths, and dispersion compensation, for example, the phase of the high frequency component is performed. Is delayed and the phase of the low frequency component is advanced to compensate for dispersion.

Finally, the (N to 1) optical waveguide grating router 9 includes N input optical waveguides 10 connected to the N optical waveguides 8, a free space region 11, a coupling optical waveguide 12, The space region 13 includes one output optical waveguide 14. The (N to 1) optical waveguide grating router 9 combines the dispersion-compensated frequency components into the optical pulse 16 again. By using the optical dispersion compensating element of the present embodiment, the pulse width of the synthesized optical pulse 16 is
The pulse width can be smaller than the pulse width of the incident light pulse 15.

In the optical dispersion compensating element of this embodiment, for example, as shown in FIG. 1B, InGaAsP is grown on an InP substrate and an optical waveguide (2, 4, 6, 8, 10, 12, 1) is formed.
4) and the portions other than the free space regions (3, 5, 11, 13) are formed by photolithography and chemical etching techniques.
It can be formed by removing GaAsP. InP may be further formed on an optical waveguide or a free space region formed of InGaAsP. In the above configuration, an optical dispersion compensating element having the same function can be realized by forming an optical waveguide or a free space region of SiO ₂ on a Si substrate instead of growing InGaAsP on an InP substrate. Can be.

<Embodiment 2> This embodiment is an embodiment of a short-pulse semiconductor laser device realized by using an optical dispersion compensating element having the configuration as shown in the above-mentioned embodiment 1 on the output side of an active mode-locked semiconductor laser element. It is an example. FIG. 2 is a diagram for explaining the configuration of the short-pulse semiconductor laser device according to the present embodiment. The active mode-locked semiconductor laser device 17 and the optical dispersion compensating device 29 shown in FIG.
Consists of In the short-pulse semiconductor laser device of this embodiment, the active mode-locked semiconductor laser element 17 is driven by the voltage pulse power supply 27 and outputs an optical pulse 28. The outputted optical pulse 28 is applied to the optical dispersion compensating element 29.
Is incident on. In the optical dispersion compensating element 29, the incident optical pulse 28 is dispersion-compensated, and an optical pulse 30 having a smaller pulse width is output.

Next, a method for fabricating the active mode-locked semiconductor laser device 17 used in this embodiment will be described in detail with reference to FIG. In order to manufacture the active mode-locked semiconductor laser device 17 used in this embodiment, first, n-InP (λg = 0.92 μm, donor concentration:
N _D = 2 × 10 ¹⁸ cm ⁻³ ) Metalorganic vapor phase epitaxy (MOVP)
E: Undoped InGaAsP cladding layer (λg = 1.45 μm) 19 by Metal Organic Vapor Phase Epitaxy (19)
Grow. Note that λg represents the forbidden bandwidth wavelength (where 禁止 g = hc / Eg, and the same hereinafter, where the forbidden bandwidth is Eg, h is the Planck constant, and c is the speed of light).

Next, an InGaAsP quantum well layer (λg = 1.5
A five-period multiple quantum well layer 20 composed of a barrier layer of 5 μm, thickness of 3.5 nm and InGaAsP (λg = 1.15 μm, thickness of 15 nm) is grown. Subsequently, an undoped InGaAsP clad (λg =
1.45 μm) layer 21, p-InP (acceptor concentration: N _A = 5 ×
10 ¹⁸ cm ⁻³ ) The cap layer 22 is grown. Finally, Au
By depositing GeNi / Au and Au / AuZn, the n-side electrode 23 and the p-side electrode 24 are respectively cleaved to form mirrors 25 and 26.

When the active mode-locked semiconductor laser device 17 is operated, the voltage pulse power supply 27 supplies an electrode of the amplification region to the optical waveguide grating router (reference numeral 1 in FIG. 1) included in the optical dispersion compensating device 29. An electric signal having a frequency equal to the transmission peak frequency interval Δf is applied (here, Δf is equal to the repetition frequency of the mode-locked semiconductor laser device), and mode-locking is actively applied between the respective frequencies. generate. According to the short-pulse semiconductor laser device of the present embodiment, by using the optical dispersion compensating element, which is the basic configuration of the present invention, light having a pulse width smaller than the pulse width generated by the active mode-locked semiconductor laser element that is the light emitting body is obtained. It becomes possible to output a pulse.

<Embodiment 3> This embodiment is an implementation of a short pulse semiconductor laser device realized by using an optical dispersion compensating element having the structure as shown in the above-mentioned embodiment 1 on the output side of a passively mode-locked semiconductor laser element. It is an example. FIG. 3 is a diagram for explaining the configuration of the short-pulse semiconductor laser device according to the present embodiment. The passive-mode-locked semiconductor laser device 31 and the optical dispersion compensating device 45 as shown in FIG.
Consists of

In the short-pulse semiconductor laser device of the present embodiment, the passive mode-locked semiconductor laser element 31 is connected to the forward constant voltage power supply 43 connected to the electrode 38 in the amplification region and to the electrode 39 in the saturable absorption region. It is driven by the inverted constant voltage power supply 42 and outputs an optical pulse 44. This light pulse 44 is incident on the light dispersion compensating element 45. In the optical dispersion compensating element 45, the incident optical pulse 44 is dispersion-compensated, and an optical pulse 46 having a smaller pulse width is output. According to the short-pulse semiconductor laser device of the present embodiment, by using the optical dispersion compensating element which is the basic configuration of the present invention, light having a pulse width smaller than the pulse width generated by the passive mode-locked semiconductor laser element which is the light emitting body is obtained. It becomes possible to output a pulse.

Next, the passive mode-locked semiconductor laser device 3
1 will be described in detail with reference to FIG. In order to fabricate the passive mode-locked semiconductor laser device 31 used in this embodiment, first, the n-InP (λg =
0.92 μm, donor concentration: N _D = 2 × 10 ¹⁸ cm ⁻³ ) MOVPE: Metal Organic Vapor Phase Epi on the substrate 32
taxy) undoped InGaAsP cladding layer
(λg = 1.45 μm) 33 is grown. Next, InGaAs
P quantum well layer (λg = 1.55μm, thickness 3.5nm) and InGaAs
A multi-period multiple quantum well layer 34 composed of a P (λg = 1.15 μm, thickness 15 nm) barrier layer is grown.

Subsequently, undoped InGaAsP (λg =
1.45 μm) layer 35, p-InP (acceptor concentration: N _A = 5 ×
10 ¹⁸ cm ⁻³ ) The cap layer 36 is grown. The p-InP
The cap layer 36 is separated by etching, and Au / AuZn is deposited on each region, so that
A p-side electrode 39 is formed in the side electrode 38 and the saturable absorption region. Further, the n-type electrode 37 is formed by evaporating AuGeNi / Au. Finally, in the present embodiment in which the mirrors 40 and 41 are formed by cleavage, the semiconductor laser device thus manufactured is connected to the electrode 38 in the amplification region by the forward voltage source 43 and the electrode 39 in the saturable absorption region.
Is connected to a reverse constant voltage power supply 42, thereby operating as a passively mode-locked laser device.

<Embodiment 4> Embodiment 3 uses a passive mode-locked semiconductor laser device in which a reverse constant voltage power supply 42 is applied to the electrode 39 in the saturable absorption region. A hybrid mode-locked semiconductor laser device in which an electric signal having a frequency equal to the transmission peak frequency interval Δf of the optical waveguide grating router included in the optical dispersion compensating element is applied to the electrode 39 in the saturable absorption region. (Where Δf is equal to the repetition frequency of the mode-locked semiconductor laser device). Other configurations are the same as those of the third embodiment. By adopting this configuration,
Hybrid mode locking (active mode locking + passive mode locking) is applied, and it becomes possible to output an optical pulse having a pulse width smaller than the pulse width generated by the hybrid mode-locked semiconductor laser device that is the light emitting body.

<Embodiment 5> This embodiment is an embodiment of a short-pulse semiconductor laser device realized by using the optical dispersion compensating element having the configuration as shown in the above-mentioned embodiment 1 on the output side of the gain switch semiconductor laser element. It is. FIG. 4 is a diagram for explaining the configuration of the short-pulse semiconductor laser device according to the present embodiment, which comprises a gain-switched semiconductor laser element 47 and an optical dispersion compensating element 59 as shown in FIG. Is done. In the short-pulse semiconductor laser device of the present embodiment, an optical pulse 58 generated by driving the gain switch semiconductor laser element 47 with a voltage pulse power supply enters an optical dispersion compensating element 59. The incident optical pulse 58 is dispersion-compensated by the optical dispersion compensating element 59 and is output as an optical pulse 60 having a smaller pulse width.

Next, the gain switch semiconductor laser device 47
Will be described in detail with reference to FIG. In order to manufacture the gain-switched semiconductor laser device 47 used in this embodiment, first, n-InP (λg = 0.92)
μm, donor concentration: N _D = 2 × 10 ¹⁸ cm ^-3 ) MOVPE: Metal Organic Vapor Phase Epitax
y) method, an undoped InGaAsP cladding layer (λ
g = 1.45 μm). Next, an InGaAsP quantum well layer (λg = 1.55 μm, thickness 3.5 nm) and InGaAsP
(λg = 1.15 μm, thickness 15 nm) A five-period multiple quantum well layer 50 composed of a barrier layer is grown.

Subsequently, undoped InGaAsP (λg =
A 1.45 μm) cladding layer 51 and a cap layer 52 of p-InP (acceptor concentration: N _A = 5 × 10 ¹⁸ cm ⁻³ ) are grown. Finally, AuGeNi / Au and Au / AuZn are vapor-deposited to form the n-side electrode 53 and the p-side electrode 54, and the mirrors 55 and 56 are formed by cleavage. A voltage pulse is applied between the electrodes 53 and 54 by the voltage pulse power supply 57 to operate the gain switch. According to the short-pulse semiconductor laser device of the present embodiment, by using the optical dispersion compensating element which is the basic configuration of the present invention, the optical pulse having a pulse width smaller than the pulse width generated by the gain switch semiconductor laser element which is the light-emitting body. Can be output.

<Embodiment 6> This embodiment relates to an optical communication system. The optical dispersion compensating element of Embodiment 1 and an active mode-locked semiconductor laser element, a passive mode-locked semiconductor laser element, a hybrid mode-locked semiconductor laser element, or A short-pulse semiconductor laser device (see Examples 2 to 5) configured by combining gain-switched semiconductor laser elements is used as a light source. According to this embodiment, since an optical pulse having a small pulse width can be used, an optical communication system having good performance can be realized.

<Embodiment 7> This embodiment is an embodiment of an optical communication system provided with an optical repeater circuit using the optical dispersion compensating element as shown in the first embodiment as an optical pulse waveform shaping element. As is clear from the description of the first embodiment, FIG.
By adjusting the lengths of the N optical waveguides 8 of the dispersion compensating optical waveguides 7 constituting the optical dispersion compensating element shown in FIG. 1, the output waveform can be shaped. Therefore, by incorporating an optical repeater circuit using the optical dispersion compensating element of the first embodiment as an optical pulse waveform shaping element in an optical propagation path, an optical pulse (for example, a short pulse) having a waveform close to a desired shape is used. An optical communication system can be realized.

FIG. 5 is a diagram for explaining the present embodiment. As shown in the figure, in the configuration of the optical communication system, an optical dispersion compensating element 61 is inserted as an optical pulse waveform shaping element in a path (optical fiber 62) for propagating an optical pulse. When the optical pulse 63 propagates through the optical fiber 62, the optical pulse 64 spreads due to the dispersion of the optical fiber. According to the configuration of the present embodiment, dispersion is compensated for by the inserted optical dispersion compensating element 61, and the optical pulse waveform is shaped (for example, shortened pulse). The shaped light pulse 65 is transmitted to the next optical fiber 62 '. In this way, by inserting the optical dispersion compensating element at various points in the optical pulse propagation path, the propagating optical pulse can be maintained in a substantially desired shape. As a result, it is possible to prevent the pulse width of the optical pulse from expanding and the waveform from deteriorating, and as a result, it is possible to reduce the communication error probability.

As is apparent from the above description, the optical dispersion compensating element of the present invention is a long-distance, large-capacity optical communication system based on a time division multiplex communication system or a hybrid communication system of time division multiplex communication and wavelength division multiplex communication. It can be used in a wide range as an optical pulse waveform shaping element for a communication system or as a dispersion compensating element for an ultrashort optical pulse semiconductor laser device indispensable for these communication systems and ultrahigh-speed optical measurement.

[0033]

According to the present invention, a small and transparent light dispersion compensating element suitable for integration and having good coupling with other devices,
Also, a short pulse semiconductor laser device and an optical communication system using the same can be realized.

[Brief description of the drawings]

FIG. 1 is a diagram for explaining a structure of an optical dispersion compensating element according to a first embodiment of the present invention.

FIG. 2 is a diagram illustrating a configuration of a short-pulse semiconductor laser device according to a second embodiment of the present invention.

FIG. 3 is a diagram illustrating a configuration of a short-pulse semiconductor laser device according to a third embodiment of the present invention.

FIG. 4 is a diagram for explaining a configuration of a short pulse semiconductor laser device according to a fifth embodiment of the present invention.

FIG. 5 is a diagram for explaining a seventh embodiment of the present invention.

FIG. 6 is a configuration diagram of a conventional light dispersion compensation element.

[Explanation of symbols]

1: (1: N) optical waveguide grating router, 2: input optical waveguide, 3, 5, 11, 13: free space region, 4, 12: coupling optical waveguide, 6: output optical waveguide, 7: dispersion compensation optical waveguide 8: optical waveguide, 9: (N to 1) optical waveguide grating router, 10: input optical waveguide, 14: output optical waveguide, 15: input optical pulse, 16: output optical pulse, 17: active mode-locked semiconductor laser device 18, 32, 48: n-type InP substrate, 19, 21, 33, 35, 49, 51: InGaAsP
Cladding layer, 20, 34, 50: InGaAsP multiple quantum well layer, 22, 36, 52: p-type InP cap layer, 23, 37, 53: n-side electrode, 24, 38, 39, 54: p-side electrode, 25 , 26, 40, 41, 55, 56: mirror, 27: voltage pulse power supply, 28, 30, 44, 46, 58, 60, 63, 64, 6
5, 66, 66 ': optical pulse, 29, 45, 59, 61: optical dispersion compensating element, 31: passive mode-locked semiconductor laser element, 42: reverse constant voltage source, 43: forward constant voltage source, 47: gain switch Semiconductor laser device, 57: voltage pulse power supply, 62, 62 ': optical fiber, 67: optical fiber, 68, 68': diffraction grating, 69: dielectric multilayer film, 70: grating optical fiber.

──────────────────────────────────────────────────の Continued on front page (51) Int.Cl. ⁶ Identification code FI H04B 10/28

Claims (5)

[Claims] 1. An optical waveguide grating router for demultiplexing an optical pulse incident on one input optical waveguide into frequency components having equally spaced frequency intervals and outputting them from a plurality of different output optical waveguides, and said optical waveguide Each of the optical pulses of each frequency component output from a plurality of different output optical waveguides of the grating router is input, and a phase difference is generated between the optical pulses of each frequency component to output from a plurality of optical waveguides of different lengths. A dispersion-compensating optical waveguide,
An optical waveguide grating router that combines optical pulses of a plurality of frequency components output from a plurality of optical waveguides having different lengths of the dispersion compensating optical waveguide into one optical pulse and outputs the combined optical pulse. Light dispersion compensating element. 2. A short-pulse semiconductor laser device comprising a semiconductor laser element and the optical dispersion compensating element according to claim 1, wherein an output of said semiconductor laser element is used as an input of said optical dispersion compensating element. A short-pulse semiconductor laser device characterized in that a short-pulse laser is output from the semiconductor laser. 3. The semiconductor laser device according to claim 1, wherein said semiconductor laser device is one of an active mode-locked semiconductor laser device, a passive mode-locked semiconductor laser device, a hybrid mode-locked semiconductor laser device, and a gain-switched semiconductor laser device. 3. The short-pulse semiconductor laser device according to 2. 4. An optical communication system using the short-pulse semiconductor laser device according to claim 2 as a light source. 5. An optical communication system comprising an optical repeater circuit using the optical dispersion compensating element according to claim 1 as an optical pulse waveform shaping element in an optical propagation path.