JPH05333384A - Spectroscopic optical switch - Google Patents

Abstract

PURPOSE:To obtain the spectroscopic optical switch provided with a function for optically exchanging plural splitted beams. CONSTITUTION:A slab waveguide 13 is formed on the surface of a base plate 11, and a pair of electrodes are provided on the rear face of the base plate 11 and the upper face of the slab waveguidc 13. A vertical diffraction grating 12 is provided in the shape of a circular arc on one end face of the slab waveguide 13. Plural input waveguides 14 and 15 and plural convergent waveguides 17 and 18 are provided on the other end face of the slab waveguide 13, and plural output waveguides 19 and 20 are formed on the surface of the base plate 11. Then, an optical waveguide network is formed for selectively supplying respective output beams from the plural convergent waveguides 17 and 18 to the plural output waveguides, and this optical waveguide network is formed so that the plural input beams of various wavelengths inputted to the plural input waveguides 14 and 15 can selectively optically be exchanged to the plural output waveguides 19 and 20 corresponding to the value of an inverse bias voltage impressed between the paired electrodes.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a frequency division optical transmission system, which is a small spectroscopic light having a function of demultiplexing an optical signal transmitted by frequency division and further exchanging the optical signal as it is. It is about switches.

[0002]

2. Description of the Related Art Conventionally, as an optical component in which a vertical diffraction grating and an optical waveguide are integrally formed, there is one that disperses light of 1.48 to 1.56 μm (Appl. Phys. Le.
tt. 58 (1991) pp. 1949-1951).
FIG. 5 is a plan view for explaining a conventional small spectroscope, in which 1 is a slab waveguide portion, 2 is a ridge waveguide, 3 is a vertical diffraction grating, and 4 is input light (λ ₁ , λ ₂ ... λ). _n ) and 5 are output lights. The frequency-multiplexed input light 4 enters the ridge waveguide 2 and spreads in the slab waveguide portion 1 to form a vertical diffraction grating 3
The light is dispersed by and is focused on different ridge waveguides 2. Since the vertical diffraction grating 3 is on the Rowland circle and the input part of the ridge waveguide 1 is on the ½ Rowland circle, light of each wavelength is transmitted to different ridge waveguides 2 without defocus. Collect light.

[0003]

However, this conventional example has a drawback that it has no optical switching function. Further, since the refractive index of the slab waveguide is fixed, there is a drawback that the demultiplexing angle cannot be adjusted, that is, the light wavelength suitable for each ridge waveguide cannot be adjusted.

An object of the present invention is to solve the above drawbacks of the prior art, to adjust the demultiplexing angles of a plurality of lights by controlling the refractive index by the electro-optic effect, and to provide an optical circuit of a ridge waveguide. By devising the above method, it is possible to provide a spectroscopic optical switch having a function of optically exchanging a plurality of lights with each other.

[0005]

In order to achieve this object, a spectroscopic optical switch according to the present invention has a slab waveguide formed on a front surface of a substrate, and a back surface of the substrate and the slab waveguide. An electrode paired with the upper surface is provided, a vertical diffraction grating has an arc shape on one end surface of the slab waveguide, and a direction of a groove of the vertical diffraction grating is perpendicular to a surface of the substrate, and An arcuate vertical diffraction grating is provided on a Rowland circle, and the other end surface of the slab waveguide has a plurality of input waveguides and a plurality of light-collecting waveguides, each of which has an incident portion of ½ Rowland circle. A plurality of output waveguides are formed on the surface of the substrate, and each output light from the plurality of focusing waveguides is selectively supplied to the plurality of output waveguides. To form an optical waveguide network for The network selectively exchanges a plurality of input lights input to the plurality of input waveguides with the plurality of output waveguides according to a value of a reverse bias voltage applied between the pair of electrodes. Is formed. Further, the diffraction grating is formed in a sawtooth shape so that the incident light and the diffracted light have a substantially regular reflection relationship with respect to the surface of the groove of the diffraction grating, and the end surface of the diffraction grating is formed. It is possible to form a highly reflective film including an insulating film and a metal film. By controlling the refractive index by the electro-optical effect, the demultiplexing angle of light is adjusted, and by devising the optical network of the ridge waveguide, it is possible to realize the function of exchanging a plurality of lights with each other. Different from technology.

[0006]

1 is a perspective view showing a first embodiment of the present invention, 11 is an n-InP substrate, 12 is a vertical diffraction grating,
Reference numeral 13 is a slab waveguide portion, 14 is an input waveguide I, 15 is an input waveguide II, 16 is a converging waveguide I, and 17 is a converging waveguide I.
I and 18 are collection waveguides III and 19 is output waveguides I and 20.
Is an output waveguide II, 21 is a total reflection mirror, 22 is a waveguide intersection, 23 is an n-electrode, 24 is a p-electrode, and 25 is a lead wire. The layer structure of the waveguide is omitted for simplification of the drawing.

FIG. 2 is a diagram for explaining the function of the first embodiment. The function of the first embodiment will be described with reference to FIG. First, in the case of the reverse bias voltage V = V ₁ , the input light λ ₁ incident on the input waveguide (I) 14 spreads in the slab waveguide portion 13 and is diffracted by the vertical diffraction grating 12 and then the condensing waveguide (II) 17 Focus on. The light of λ ₁ goes straight and is emitted from the output waveguide (II) 20. The input light λ ₂ incident on the input waveguide (II) 15 spreads in the slab waveguide portion 13, is diffracted by the vertical diffraction grating 12, and is condensed in the condensing waveguide (I) 16. The light of λ ₂ travels straight and is emitted from the output waveguide (I) 19. When the reverse bias voltage V = V ₂ , λ ₁
The light has a different diffraction angle and is condensed on the condensing waveguide (III) 18. The light path of λ ₁ is bent by the total reflection mirror 21 and is emitted from the output waveguide (I) 19. On the other hand, the light of λ ₂ changes in diffraction angle, is condensed on the condensing waveguide (II) 17, travels straight, and is emitted from the output waveguide (II) 20. That is, λ
Light of ₁ and λ ₂ is exchanged depending on the magnitude of the reverse bias voltage.

Next, a mechanism of changing the demultiplexing angle by applying a reverse bias voltage to the slab waveguide section 13 will be described. The refractive index change due to the electro-optic effect is given by the following equation. Δn = (1/2) n ³ r ₄₁ E Here, Δn is the refractive index change, n is the refractive index, E is the applied electric field, and r ₄₁ is the electro-optic coefficient, which is approximately 1.6 × 10.
It is about ^-12 (m / V). Assuming that the total thickness of the undoped layer is 0.5 μm = 5 × 10 ⁻⁷ (m), 100V
When applied, E = 2 × 10 ⁸ (V / m). n≈
If it is 3.3, Δn≈5.8 × 10 ⁻³ , which is 1.5
In the μm band, the shift of the light wavelength is about Δλ≈27Å. In the case of InP-based crystal for the slab waveguide core layer, I
nGaAs / InAlAs or InGaAs / In
If the P multiple quantum well layer is used, the electro-optic coefficient can be increased and the wavelength shift can be increased.

The resolution of the diffraction grating is given by the following equation. Δλ = λ / (mNn) where Δλ is resolution, λ is wavelength, m is order of diffraction, N
Is the number of diffraction gratings, and n is the effective refractive index of the slab waveguide. If the slab waveguide section is made sufficiently long, the number N of diffraction gratings becomes large, and it can be sufficiently used in the frequency multiplexing optical transmission system. Also, if the diffraction grating has a sawtooth shape,
The diffracted light of a specific order can be about 85 to 95%.

FIG. 3 is a plan view showing a second embodiment, in which 31 is a vertical diffraction grating, 32 is a slab waveguide portion, and 33 is a slab waveguide portion.
Is an input waveguide I, 34 is an input waveguide II, 35 is an input waveguide III, 36 is a collecting waveguide I, 37 is a collecting waveguide II, 3
8 is a condensing waveguide III, 39 is a condensing waveguide IV, 40 is a condensing waveguide V, 41 is an output waveguide I, 42 is an output waveguide II,
43 is an output waveguide III, 44 is a total reflection mirror, and 45 is a waveguide intersection.

FIG. 4 is a diagram for explaining the function of the second embodiment. When the reverse bias voltage V = V ₁ , the input light λ ₁ incident on the input waveguide (I) 33 is slab waveguide unit 3
2 spreads, is diffracted by the vertical diffraction grating 31,
(III) 38 is condensed and emitted from the output waveguide (III) 43. The input light λ ₂ incident on the input waveguide (II) 34 is condensed on the condensing waveguide (II) 37 and emitted from the output waveguide (II) 42. Input light λ incident on the input waveguide (III) 35
_The light beam ₃ is condensed on the condensing waveguide (I) 36 and emitted from the output waveguide (I) 41. When the reverse bias voltage V = V ₂ , the diffraction angle changes, and the input light λ ₁ is reflected by the condensing waveguide (IV).
The light is focused on 39, the optical path is bent by the total reflection mirror 44, and the light is emitted from the output waveguide (I) 41. The input light λ ₂ is collected by the collection waveguide (II
The light is focused on I) 38 and emitted from the output waveguide (III) 43.
When the reverse bias voltage V = V ₃ , the diffraction angle further changes, the input light λ ₁ is condensed on the condensing waveguide (V) 40, the optical path is bent by the total reflection mirror 44, and the output waveguide (I) is generated. Emit from 41. The input light λ ₃ is condensed in the condensing waveguide ((III) 38 and emitted from the output waveguide (III) 43. That is, three-wave light λ ₁ , λ ₂ , λ is generated by the change of the reverse bias voltage. ₃ can be optical exchanged.

As is clear from these results, compared with the conventional technique, by controlling the refractive index by the electro-optic effect,
By adjusting the demultiplexing angle of light and devising an optical circuit network, there was an improvement in that a plurality of lights can be exchanged with each other.

The slab waveguide is an n-type InP substrate, n
-Type InP clad layer, undoped InGaAsP core layer, undoped InP layer, p-type InP clad layer, p
Type InGaAsP contact layer, and a reverse bias voltage can be applied.

Further, the slab waveguide is an n-type InP
Substrate, n-type InP cladding layer, undoped InGaA
s / InP layer or InGaAs / InAlAs multiple quantum well core layer, undoped InP layer, p-type InP
It can be composed of a clad layer and a p-type InGaAsP contact layer.

The slab waveguide is made of n-type GaAs.
Substrate, n-type AlGaAs cladding layer, undoped Ga
As core layer, p-type AlGaAs cladding layer, p-type GaA
It may be composed of an s-contact layer.

The slab waveguide is an n-type GaAs substrate,
n-type AlGaAs cladding layer, undoped AlGaA
It may be composed of an s / GaAs multiple quantum well core layer, a p-type AlGaAs cladding layer, and a p-type GaAs contact layer.

[0017]

As described above in detail, according to the present invention, the demultiplexing angle of a plurality of lights is adjusted by controlling the refractive index by the electro-optic effect, and the optical circuit network of the waveguide is formed. By devising it, there is an advantage that a function of optically exchanging a plurality of lights can be realized.

[Brief description of drawings]

FIG. 1 is a perspective view of a spectral optical switch according to a first embodiment of the present invention.

FIG. 2 is a diagram illustrating a function of the first exemplary embodiment of the present invention.

FIG. 3 is a plan view of a spectroscopic optical switch according to a second embodiment of the present invention.

FIG. 4 is a diagram illustrating a function of a second exemplary embodiment of the present invention.

FIG. 5 is a plan view showing an example of a conventional small spectroscope.

[Explanation of symbols]

1 Slab Waveguide Part 2 Ridge Waveguide Part 3 Vertical Diffraction Grating 4 Input Light (λ ₁ , λ ₂ ... λ _n ) 5 Output Light 11 n-InP Substrate 12 Vertical Diffraction Grating 13 Slab Waveguide Part 14 Input Waveguide I 15 Input waveguide II 16 Condensing waveguide I 17 Condensing waveguide II 18 Condensing waveguide III 19 Output waveguide I 20 Output waveguide II 21 Total reflection mirror 22 Waveguide intersection 23 n-electrode 24 p-electrode 25 Lead wire 31 Vertical diffraction grating 32 Slab waveguide I 33 Input waveguide I 34 Input waveguide II 35 Input waveguide III 36 Collecting waveguide I 37 Collecting waveguide II 38 Collecting waveguide III 39 Collecting waveguide IV 40 Collecting waveguide V 41 Output Waveguide I 42 Output waveguide II 43 Output waveguide II1 44 Total reflection mirror 45 Waveguide intersection

Claims (7)

[Claims] 1. A slab waveguide is formed on a front surface of a substrate, and electrodes forming a pair are provided on a back surface of the substrate and an upper surface of the slab waveguide, and one end surface of the slab waveguide is provided. The vertical diffraction grating has an arc shape, and the direction of the groove of the vertical diffraction grating is perpendicular to the surface of the substrate, and the arc-shaped vertical diffraction grating is provided on the Rowland circle. A plurality of input waveguides and a plurality of light-collecting waveguides are provided on the other end face so that their incident portions are on a ½ Rowland circle, and a plurality of output waveguides are formed on the surface of the substrate. In addition, an optical waveguide network is formed to selectively supply each output light from the plurality of collection waveguides to the plurality of output waveguides, and the optical waveguide network includes the plurality of input waveguides. A plurality of input lights input to the space between the pair of electrodes A spectroscopic optical switch formed such that light is selectively exchanged with the plurality of output waveguides according to the value of an applied reverse bias voltage. 2. The vertical diffraction grating has a sawtooth shape,
The spectroscopic optical switch according to claim 1, wherein the incident light and the diffracted light are formed so as to have a substantially regular reflection relationship with respect to the surface of the groove of the diffraction grating. 3. The spectroscopic optical switch according to claim 1, wherein a highly reflective film made of an insulating film and a metal film is formed on an end face of the vertical diffraction grating. 4. The slab waveguide is an n-type InP substrate,
n-type InP clad layer, undoped InGaAsP core layer, undoped InP layer, p-type InP clad layer,
4. The spectroscopic optical switch according to claim 1, wherein the spectroscopic optical switch comprises a p-type InGaAsP contact layer and is configured to apply a reverse bias voltage. 5. The slab waveguide is an n-type InP substrate,
n-type InP clad layer, undoped InGaAs / I
4. An nP layer or an InGaAs / InAlAs multiple quantum well core layer, an undoped InP layer, a p-type InP clad layer, and a p-type InGaAsP contact layer, according to any one of claims 1, 2 and 3. The spectroscopic optical switch described. 6. The slab waveguide comprises an n-type GaAs substrate, an n-type AlGaAs cladding layer, and undoped GaA.
s core layer, p-type AlGaAs cladding layer, p-type GaAs
The spectroscopic optical switch according to claim 1, wherein the spectroscopic optical switch comprises a contact layer. 7. The slab waveguide comprises an n-type GaAs substrate, an n-type AlGaAs cladding layer, and undoped AlG.
aAs / GaAs multiple quantum well core layer, p-type AlGaA
4. The spectroscopic optical switch according to claim 1, comprising an s clad layer and a p-type GaAs contact layer.