KR20020096251A - Wavelength multiplexer - Google Patents

Abstract

PURPOSE: An apparatus for multiplexing a wavelength is provided to form a wavelength multiplexer adapted for a DWDM(Dense Wavelength Division Multiplexing) system by obtaining a wavelength-independent characteristic and a characteristic of low loss. CONSTITUTION: A wavelength multiplexing apparatus includes a plurality of input light collimators(210), a reflective body(220), and an output light collimator(230). The input light collimators(210) are used for converting the light having an unspecified wavelength received from an input optical fiber(212) to parallel light. The input light collimators(210) are arrayed on a concentric circle around the output light collimator(230) if a spheric mirror is used as the reflective body(220). The output light of the input light collimator(210) is condensed on one focus by the reflective body(220) if the input light collimator(210) is arrayed on the concentric circle around the output light collimator(230). The output light collimator(230) is used for transmitting the condensed light into an output optical fiber(232).

Description

Wavelength Multiplexing Device {WAVELENGTH MULTIPLEXER}

TECHNICAL FIELD The present invention relates to optical communication components, and more particularly, to a wavelength multiplexing device.

The development of the Internet and multimedia services require ultra-fast and high-capacity information transmission capability, and thus efforts are being made to maximize communication speed and communication capacity.

There are three ways to improve communication speed and communication capacity. First, to increase the speed of electronic circuits, such as TDM (Time Division Multiplexing), second, to make optically short pulses such as OTDM (Optical Time Division Multiplexing) and to multiplex them. This is a method of transmitting multiple wavelengths simultaneously through one optical fiber, such as WDM (Wavelength Division Multiplexing).

In particular, the wavelength division multiplexing scheme enables a plurality of wavelength bands to be transmitted through one common optical fiber, thereby enabling ultra-high speed and large-capacity information transmission without additional installation of optical fibers.

1 is a schematic diagram showing a general WDM system. As shown in FIG. 1, the WDM system 100 includes a multiplexer 110, an optical amplifier 120, an add / drop multiplexer 130, and a demultiplexer 140. And an optical fiber f that is an optical signal transmission medium between the components.

The multiplexer 110 is a device for synthesizing and outputting wavelengths of multiple channels, each of which is modulated at a transmitter, into one optical fiber. The optical amplifier 120 is a device for directly amplifying and outputting an input optical signal without changing it into an electrical signal. The add-drop multiplexer 130 is a device that separates the wavelength of a specific channel among the multiplexed optical signals and transmits the wavelength to a lower node. The demultiplexer 140 is an apparatus for separating and outputting optical signals of various channels for each wavelength.

2 is a block diagram showing a wavelength multiplexing apparatus according to a first embodiment of the prior art. As shown in FIG. 2, the wavelength multiplexing device according to the first exemplary embodiment is a method using a fiber coupler, and multiplexes multiple wavelengths by connecting 2 × 1 50:50 fiber couplers (OC) in multiple stages. .

However, the wavelength multiplexing device using the optical fiber coupler is independent of the input wavelength, but the loss is large such that 50% power loss occurs at each end, and thus can be used only for wavelength division multiplexing of 8 × 1 or less. The insertion loss of -9dB also occurs when the 8x1 wavelength division multiplexing is performed.

3 is a block diagram showing a wavelength multiplexing apparatus according to a second embodiment of the present invention. As shown in FIG. 3, the wavelength multiplexing apparatus according to the second exemplary embodiment uses an arrayed waveguide grating, and forms an optical waveguide grating (AWG) on a silicon wafer (SW) to form multiple channels. It is a method of combining or separating the wavelengths.

However, the wavelength multiplexing apparatus using the waveguide grating has the advantage of simultaneously combining and separating the wavelengths, but since each input channel is wavelength dependent, only an optical signal having a specified wavelength must be input to a predetermined channel. It has limitations and has a problem of enormous facility costs in the manufacturing process.

4 is a block diagram illustrating a wavelength multiplexing apparatus using an interference thin film filter according to a third exemplary embodiment. As shown in FIG. 4, the wavelength multiplexing apparatus according to the third exemplary embodiment uses an interference thin film filter (TF), and has been disclosed in US Pat. No. 5,786,915, etc., and transmits only a signal having a specific wavelength band and transmits the remaining band. The wavelength of is a method of combining or separating light of different wavelengths by forming a reflective interference thin film filter TF on both sides of the optical block OB and injecting an optical signal for each wavelength through the optical collimator C. .

However, the wavelength multiplexing device using the interference thin film filter has a limit of scalability that has a wavelength-dependent characteristic like the wavelength multiplexing device using the waveguide grating, and has an insertion loss of about -6 dB at 8 × 1 wavelength division multiplexing. The loss is relatively large. In addition, since the optical characteristics of each port depends on the interference thin film filter, there are many difficulties in the manufacture of the precise interference thin film filter, and it has a limit in increasing the uniformity of each port due to the progressive arrangement.

SUMMARY OF THE INVENTION In order to solve the above problems, an object of the present invention is to provide a wavelength multiplexing device suitable for a Dense Wavelength Division Multiplexing (DWDM) system by having a wavelength independent characteristic and a low loss characteristic.

In order to achieve the above object, the present invention provides a wavelength multiplexing apparatus, comprising: a plurality of input optical collimators arranged on concentric circles and converting light of an unspecified wavelength input from an input optical fiber into parallel light; A reflector reflecting light output from the plurality of input light collimators and condensing at one focal point; Located at the center of the concentric circle of the input optical collimator, and provides an optical multiplexing device comprising an output optical collimator for inserting the light collected by the reflector into the output optical fiber.

In addition, the present invention provides a wavelength multiplexing device, comprising: a plurality of input optical collimators arranged on concentric circles and converting light of an unspecified wavelength input from an input optical fiber into parallel light; A rod-shaped reflector having a reflective surface therein for reflecting light output from the plurality of input optical collimators and focusing at one focal point; A first output optical collimator positioned at the center of the concentric circle of the input optical collimator and converting the light collected by the reflecting surface of the rod-shaped reflector into parallel light; And a second output optical collimator for inserting parallel light output from the first output optical collimator into an output optical fiber.

In addition, the present invention provides a wavelength multiplexing device, comprising: a holder having openings at both ends; A plurality of input optical collimators arranged concentrically on one end of the holder and converting light of an unspecified wavelength input from an input optical fiber into parallel light and outputting the parallel light; A rod-shaped reflector installed at the other end of the holder and having a reflective surface therein for reflecting light output from the plurality of input optical collimators to focus at one focal point; A first output optical collimator positioned at the center of the concentric circle of the input optical collimator and converting the light collected by the reflecting surface of the rod-shaped reflector into parallel light; A second output optical collimator for inserting parallel light output from the first output optical collimator into an output optical fiber; It is provided on the outer circumferential surface of the input optical collimator, and provides a wavelength multiplexing device comprising a displacement generating unit for varying the axial position of the input optical collimator in accordance with the application of voltage.

1 is a schematic diagram showing a typical WDM system,

2 is a block diagram showing a wavelength multiplexing apparatus according to a first embodiment of the present invention;

3 is a block diagram showing a wavelength multiplexing apparatus according to a second embodiment of the present invention;

4 is a block diagram showing a wavelength multiplexing apparatus according to a third embodiment of the present invention;

5A to 5C are schematic diagrams showing the multiplexing principle of the wavelength multiplexing apparatus of the present invention;

6A to 6D are schematic diagrams showing the operating principle of the optical collimator used in the wavelength multiplexing apparatus of the present invention;

7 is a schematic diagram showing the configuration of a wavelength multiplexing apparatus according to a first preferred embodiment of the present invention;

8 is a configuration diagram showing an arrangement of an input optical collimator and an output optical collimator of a wavelength multiplexing apparatus according to a first preferred embodiment of the present invention;

9 is a schematic diagram showing the configuration of a wavelength multiplexing apparatus according to a second preferred embodiment of the present invention;

10 is a detailed block diagram of a wavelength multiplexing apparatus according to a second preferred embodiment of the present invention;

11 is a schematic diagram showing the configuration of a wavelength multiplexing apparatus according to a third preferred embodiment of the present invention;

12 is a schematic diagram showing the configuration of a wavelength multiplexing apparatus according to a fourth preferred embodiment of the present invention;

13 is a schematic diagram showing the configuration of a wavelength multiplexing apparatus according to a fifth embodiment of the present invention;

14 is a schematic diagram showing the configuration of a wavelength multiplexing apparatus according to a sixth preferred embodiment of the present invention;

15a and 15b is a view showing the principle of light attenuation by the displacement generator of the present invention,

16 is a schematic diagram showing the configuration of a wavelength multiplexing apparatus according to a seventh preferred embodiment of the present invention;

17 is a view showing an 8 × 1 wavelength multiplexing device according to an application of the present invention,

18 illustrates a 64 x 1 wavelength multiplexing device in accordance with an application of the present invention.

<Explanation of symbols for the main parts of the drawings>

210, 310: input optical collimator 220: reflector

230: output optical collimator 320: rod type reflector

330: first output optical collimator 340: second output optical collimator

950, 1050: displacement generator

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, if it is determined that detailed descriptions of related known functions or configurations may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted.

5A to 5C are schematic diagrams showing the multiplexing principle of the wavelength multiplexing apparatus of the present invention, and FIGS. 6A to 6D are schematic diagrams showing the operating principle of the optical collimator used in the wavelength multiplexing apparatus of the present invention.

The wavelength multiplexing apparatus of the present invention utilizes the reflection principle of a reflector such as a paraboloidal mirror or a spherical mirror and the parallel light output and light collection principle of an optical collimator.

As shown in FIG. 5A, each parallel light incident on the reflecting surface of the parabolic mirror 10 is reflected to form a single focal point. That is, each parallel light is condensed at one focal point F ₁ even if the distance H ₁ ≠ H ₂ from the parabolic mirror is different from each other.

In addition, as illustrated in FIG. 5B, parallel light having the same distance (H ₁ = H ₂ ) from the virtual central axis of the spherical mirror 20 is formed at one focal point F ₂ . That is, in the case of the spherical mirror, unlike the parabolic mirror, only parallel light having the same distance from the virtual center axis of the parabolic mirror is focused at one focal point, and parallel light having a different distance from the virtual center axis of the parabolic mirror is different from the parabolic mirror. Is focused at the focal points F ₁ and F ₃ .

In addition, the wavelength multiplexing apparatus of the present invention may use a rod type reflector 30 having a reflecting surface 32 therein as shown in FIG. 5C instead of a parabolic mirror or a spherical mirror. The rod-shaped reflector 30 has a parabolic reflective surface or a spherical reflective surface formed therein to focus the incident parallel light at one focal point. When the reflective surface of the rod-shaped reflector 30 is formed as a spherical reflective surface, only parallel light having the same distance (H ₁ = H ₂ ) with the virtual central axis is focused at one focal point F ₂ , and the spherical mirror Parallel light having a different distance from the virtual central axis of is focused at the focal points F ₁ and F ₃ at different positions.

The wavelength multiplexing apparatus of the present invention uses the principle of focusing at one focal point when parallel light is incident on the parabolic mirror and the spherical mirror or on the parabolic reflecting surface and the spherical reflecting surface as described above. Accordingly, the wavelength multiplexing apparatus of the present invention has a wavelength independent characteristic and a low loss characteristic independent of the wavelength or the wavelength spacing for each channel.

On the other hand, the spherical mirror and the spherical reflecting surface is easier to form the shape than the parabolic mirror and the parabolic reflecting surface, the price is cheap and economically advantageous, and can also reduce the angle of incidence to the focus, the wavelength multiplexing apparatus of the present invention Is preferred.

In other words, in order to receive the light focused at the focus, the light receiving angle of the optical collimator used as the light receiving means should be considered. When using a spherical mirror or a spherical reflecting surface, the light receiving angle has a smaller light receiving angle than a parabolic mirror or a parabolic reflecting surface. Since an optical collimator can be used, the selection range of the optical collimator applicable to this invention becomes wider.

On the other hand, an optical collimator is used as a means for injecting parallel light into a reflector such as a parabolic mirror and a spherical mirror or a parabolic reflecting surface and a spherical reflecting surface and receiving light focused at one focal point. The optical collimator attaches a lens to an optical fiber end, and when light is emitted from the optical fiber into the air, the optical collimator emits light in parallel, and simultaneously collects light incident in parallel and enters the optical fiber.

As shown in FIG. 6A, a lens for outputting light incident through the input optical fiber as parallel light is used as an input light collimator for injecting parallel light to the reflector. As the input optical collimator, a 0.23 pitch pitch lens or a 0.25 pitch pitch lens in which an input optical fiber is bonded may be used. The 0.23 pitch pitch lens or 0.25 pitch pitch lens converts the light incident through the input optical fiber into parallel light and outputs the parallel light.

As shown in FIGS. 6B and 6C, as an output light collimator for receiving light focused at one focal point, a lens that focuses converged or divergent light rather than parallel light is used. As the output optical collimator, a 0.50 pitch pitch lens or a 0.29 pitch pitch lens in which an output optical fiber is bonded may be used. The 0.50 pitch pitch lens injects light collected at one end into the output optical fiber. The 0.29 Pitch GRIN lens receives the light collected at a point spaced from the one surface by a predetermined distance and enters the output optical fiber.

As shown in FIG. 6D, two lenses for receiving the light focused at one focal point and incident the light into the output optical fiber are used to output the incident light as parallel light and to focus the output parallel light at the focal point. . As the means, two 0.23 pitch pitch lenses or 0.25 pitch pitch lenses may be used. That is, the first 0.23 Pitch GRIN lens or 0.25 Pitch GRIN lens converts the light condensed at one end into parallel light, and the second 0.23 Pitch GRIN lens or 0.25 Pitch GRIN lens outputs parallel light incident at one end Incident on the optical fiber.

7 is a schematic diagram showing the configuration of a wavelength multiplexing apparatus according to a first preferred embodiment of the present invention, and FIG. 8 shows an arrangement of an input optical collimator and an output optical collimator of the wavelength multiplexing device according to the first preferred embodiment of the present invention. It is a block diagram shown.

As shown in FIG. 7 and FIG. 8, the wavelength multiplexing apparatus 200 according to the first preferred embodiment of the present invention includes a plurality of input light collimators 210, reflectors 220, and output light collimators 230. .

The input optical collimator 210 is a means for converting light of an unspecified wavelength input from the input optical fiber 212 into parallel light and outputting the parallel light. When the input optical collimator 210 uses a spherical mirror as the reflector 220, the input optical collimator 210 is arranged on a concentric circle located within the same radius R about the output optical collimator 230. When the input optical collimator 210 is arranged on a concentric circle, parallel light output from the input optical collimator 210 is focused at one focal point. As the input optical collimator 210, it is preferable to use a lens that outputs parallel light, such as a 0.23 Pitch GRIN lens or a 0.25 Pitch GRIN lens.

The reflector 220 is a means for reflecting the light output from each of the plurality of input light collimator 210 to focus at one focal point. A parabolic mirror or a spherical mirror may be used as the reflector 220, and a spherical mirror is preferable for the above reasons. As the reflector 220, it is preferable to use a spherical mirror coated with an inorganic material. The inorganic coating spherical mirror is coated with an inorganic material such as SiO ₂ or TiO ₂ on spherical polished glass, and has a high reflectance in a wide wavelength range.

The output light collimator 230 is a means for inserting the light collected by the reflector 220 into the output optical fiber 232. The output optical collimator 230 is located at the center of the concentric circle of the input optical collimator arranged on the concentric circle when using a spherical mirror as a reflector. The output light collimator 230 receives the reflected light when the angle of incidence formed by the light reflected by the reflector and the virtual central axis of the reflector is smaller than an acceptance angle. That is, when the light receiving angle of the output optical collimator 230 is 55 °, when the incident angle is smaller than 22.5 °, the entire amount of light may be received. In addition, the angle of incidence of the output optical collimator 230 should be an angle smaller than the numerical aperture (NA) of the output optical fiber 232. For this purpose, the distance between the optical collimator and the reflecting surface of the reflector, the radius of curvature of the reflector, The distance between the lens and the fiber should be adjusted. As the output optical collimator 230, it is preferable to use a lens capable of collecting light that converges or diverges, such as a 0.29 Pitch GRIN lens or a 0.50 Pitch GRIN lens, and according to an application example, distortion in a GRIN lens Plano-convex GRIN lenses can be used to compensate.

9 is a schematic diagram showing a configuration of a wavelength multiplexing apparatus according to a second preferred embodiment of the present invention, and FIG. 10 is a detailed configuration diagram of a wavelength multiplexing apparatus according to a second preferred embodiment of the present invention.

9 and 10, the wavelength multiplexing apparatus 300 according to the second exemplary embodiment of the present invention includes a plurality of input optical collimators 310, a rod-shaped reflector 320, and a first output optical collimator 330. ) And a second output optical collimator 340, and includes a holder 350 to which the components are mounted. The holder 350 is bonded to the rod-shaped reflector 320 by applying an adhesive 352 to the bonding surface with the rod-shaped reflector 320.

The input optical collimator 310 is a means for converting light of an unspecified wavelength input from the input optical fiber 312 into parallel light and outputting the parallel light. When the input optical collimator 310 is formed as a spherical reflective surface 322 of the rod-shaped reflector 320, the input optical collimator 310 is arranged on a concentric circle located within the same radius around the second output optical collimator 340. As the input optical collimator 310, it is preferable to use a 0.23 pitch pitch lens or a 0.25 pitch pitch lens.

The rod-shaped reflector 320 is a reflector having a reflection surface 322 that reflects the light output from the plurality of input light collimator 310 to focus at one focal point. The rod-shaped reflector 320 is a reflector coated with an inorganic material on one end surface of the rod-shaped glass body. The reflective surface 322 may be formed in a parabolic or spherical shape, preferably formed in a spherical shape.

The first output light collimator 330 is a means for converting the light collected by the reflecting surface 322 of the rod-shaped reflector 320 into parallel light. When the first output optical collimator 330 is formed in the spherical shape of the reflective surface 322 of the rod-shaped reflector 320, the first output optical collimator 330 is located at the center of the concentric circle of the input optical collimator 310. As the first output optical collimator 330, it is preferable to use a 0.23 pitch pitch lens or a 0.25 pitch pitch lens.

The second output optical collimator 340 is a means for inserting parallel light output from the first output optical collimator 330 into the output optical fiber 342. As the second output optical collimator 340, it is preferable to use a 0.23 pitch pitch lens or a 0.25 pitch pitch lens.

On the other hand, in the wavelength multiplexing apparatus according to the first and second embodiments of the present invention, since the incidence angle of the light incident on the output optical collimator is relatively large, the output light is satisfied in order to satisfy the condition for injecting the multiplexed light into the output optical fiber. There is a possibility that the collimator lens combination will be somewhat complicated. An embodiment for solving this is disclosed in FIGS. 11 to 13.

11 is a schematic diagram showing the configuration of a wavelength multiplexing device according to a third preferred embodiment of the present invention. As shown in FIG. 11, the wavelength multiplexing device 600 according to the third exemplary embodiment of the present invention includes a plurality of input optical collimators 610, a planar mirror reflector 620, and an output optical collimator 630.

The input optical collimator 610 is a means for converting light of an unspecified wavelength input from the input optical fiber 612 into parallel light and outputting the parallel light. As the input optical collimator 610, it is preferable to use a 0.23 pitch pitch lens or a 0.25 pitch pitch lens.

The planar mirror reflector 620 is a means for refracting the light incident to the parallel light by a predetermined angle and then reflecting the light to the planar mirror 622 formed at one end thereof. The planar mirror reflector 620 includes a lens that refracts parallel light and a planar mirror 622 formed at one end of the lens. Since the plane mirror reflector 620 has the same angle of incidence and the angle of reflection of the light reflected by the plane mirror at all times, it has the effect of extending the lens length twice as much as the actual length and at the same time reducing the angle of the light incident to the output light collimator. give.

The output light collimator 630 is a means for inserting the light collected by the planar mirror reflector 620 into the output optical fiber 632. As the output light collimator 630, it is preferable to use a lens that can collect light that converges or diverges, and a 0.29 pitch pitch lens can be used. The incident angle of the output optical collimator 630 should be an angle smaller than the numerical aperture NA of the output optical fiber 632. The angle of incidence is obtained by Equation 1 below.

(θ = incidence angle of the output optical collimator, n ₁ is the core refractive index of the output optical fiber, n ₂ is the clad refractive index of the output optical fiber)

Therefore, when the center wavelength is 1550 nm, the numerical aperture of the optical fiber having the refractive index of the core of 1.4436 and the cladding of 1.4400 is 0.102, and θ is 5.845 °. That is, when the incident angle of the output optical collimator is smaller than 5.845 °, all the light is incident on the output optical fiber.

12 is a schematic diagram showing the configuration of a wavelength multiplexing apparatus according to a fourth preferred embodiment of the present invention. As shown in FIG. 12, the wavelength multiplexing apparatus 700 according to the fourth exemplary embodiment of the present invention includes a plurality of input optical collimators 710, concave mirror reflectors 720, and output optical collimators 730.

The input optical collimator 710 is a means for converting light of an unspecified wavelength input from the input optical fiber 712 into parallel light and outputting the parallel light. As the input optical collimator 710, it is preferable to use a 0.23 pitch pitch lens or a 0.25 pitch pitch lens.

The concave mirror reflector 720 is a means for refracting light incident to parallel light by a predetermined angle and then reflecting the concave mirror 722 formed at one end to output the light. The concave mirror reflector 720 includes a lens for refracting parallel light and a concave mirror 722 formed at one end of the lens. The concave mirror reflector 720 reflects the input parallel light through the lens axis at the concave mirror 722 to thereby determine the angle α of the light incident to the output light collimator 730 at a relatively short distance from the planar mirror reflector. It can be made small. The radius of curvature of the lens and the concave mirror and the length L of the lens can be appropriately changed according to the angle of light incident on the output light collimator.

The output light collimator 730 is a means for inserting the light collected by the concave mirror reflector 720 into the output optical fiber 732. As the output optical collimator 730, it is preferable to use a lens that can collect light that converges or diverges, and a 0.29 pitch pitch lens can be used.

13 is a schematic diagram showing the configuration of a wavelength multiplexing apparatus according to a fifth preferred embodiment of the present invention. As shown in FIG. 13, the wavelength multiplexing apparatus 800 according to the fifth exemplary embodiment of the present invention includes a plurality of input optical collimators 810, convex mirror reflectors 820, and output optical collimators 830.

The input optical collimator 810 is a means for converting light of an unspecified wavelength input from the input optical fiber 812 into parallel light and outputting the parallel light. As the input optical collimator 810, a 0.23 pitch pitch lens or a 0.25 pitch pitch lens is preferably used.

The convex mirror reflector 820 is a means for refracting light incident to parallel light by a predetermined angle and then reflecting the convex mirror 822 formed at one end to output the light. The convex mirror reflector 820 includes a lens for refracting parallel light and a convex mirror 822 formed at one end of the lens. The convex mirror reflector 820 reflects the input parallel light from the convex mirror 822 without passing through the lens axis, thereby reducing the angle of the light incident to the output light collimator 830 even at a short distance. The radius of curvature of the lens and the convex mirror and the length of the lens may be appropriately changed according to the angle of the light incident on the output light collimator 830.

The output light collimator 830 is a means for inserting the light collected by the convex mirror reflector 820 into the output optical fiber 832. As the output light collimator 830, it is preferable to use a lens that can collect light that converges or diverges, and a 0.29 pitch pitch lens can be used.

14 is a schematic view showing the configuration of a wavelength multiplexing apparatus according to a sixth preferred embodiment of the present invention, and FIGS. 15A and 15B are diagrams showing the principle of light attenuation by the displacement generator of the present invention.

As shown in FIGS. 14 to 15B, the wavelength multiplexing apparatus 900 according to the sixth exemplary embodiment of the present invention may adjust the amount of light incident on the output optical collimator by changing the position of the input optical collimator.

The wavelength multiplexing device 900 includes a plurality of input optical collimators 910, a rod type reflector 920, a first output optical collimator 930, a second output optical collimator 940, and a displacement generator 950. And a holder 960 to which the components are mounted.

The holder 960 is a cylindrical member, the opening of which a rod-shaped reflector is installed at one end, the opening at which a second output optical collimator is mounted at the center of the other end, and the opening at which the second output optical collimator is mounted. On the concentric circles, a plurality of openings on which the input optical collimator and the displacement generator are mounted are formed, respectively.

The input optical collimator 910 is a means for converting light of an unspecified wavelength input from the input optical fiber 910 into parallel light and outputting the parallel light. As the input optical collimator 810, it is preferable to use a 0.23 pitch pitch lens or a 0.25 pitch pitch lens. One side of the input optical collimator 910 is bonded to the displacement generating unit 950 by an adhesive b3.

The rod-shaped reflector 920 is a reflector having a reflective surface 922 for reflecting and focusing the light output from the plurality of input light collimators 810. The reflective surface 922 may be formed in a parabolic or spherical shape, preferably in a spherical shape.

The first output light collimator 930 is a means for collecting and outputting the light reflected on the reflective surface 922 of the rod-shaped reflector 920. The first output optical collimator 930 is bonded to the input / output surface of the rod-shaped reflector 930.

The second output optical collimator 940 is a means for inserting parallel light output from the first output optical collimator 930 into the output optical fiber 942. The second output light collimator 940 is bonded to the holder 960 by an adhesive b4.

The displacement generator 950 is a means for varying the axial position of the input optical collimator 910 according to the application of voltage. One side of the displacement generator 950 is bonded to the holder 960 by the adhesive (b2). The piezoelectric piezoelectric element may be used as the displacement generator 950. The piezoelectric piezoelectric element uses a reverse piezoelectric effect as a means for expanding the crystal plate when a voltage is applied to the crystal plate having piezoelectricity. When the displacement generator 950 varies the axial position of the input optical collimator 910, the height of the light output from the input optical collimator 910 is changed (that is, H _{1 as} shown in FIG. 15B becomes H ₂₎ . Change), and thus the focal length of the light incident on the output light collimator 930 is also changed, thereby changing the amount of light incident on the output light collimator 930. That is, the displacement generator 950 serves as a variable optical attenuator.

As shown in FIGS. 15A and 15B, the light output from the optical collimator is inclined by a predetermined angle α2 with the axis of the optical collimator, and when the optical collimator is moved horizontally (from position ① to position ②) in the axial direction, The distance between the light emitted from the optical collimator and the axis of the reflecting surface is changed from H ₁ to H ₂ . This phenomenon is caused by the refraction of light in the optical collimator, and the light output from the lens is inclined at a predetermined angle with the lens axis, so that the displacement with respect to the lens axis causes the height change of the output light. If the wave is incident and refracted from an isotropic medium to another isotropic medium, the incident surface and the refracting surface are in the same plane, and if the incident angle is i and the refractive angle is r, sin i / sin r = n (constant) is established. It comes from Snell's law. In addition, the optical collimator has a predetermined angle (α1, about 8 °) to prevent the reflected light A from being input back into the optical fiber in order to reduce the reflection loss, which is the loss reflected from the optical fiber and the GRIN lens junction. Form inclined.

16 is a schematic diagram showing the configuration of a wavelength multiplexing apparatus according to a seventh preferred embodiment of the present invention. As illustrated in FIG. 16, the wavelength multiplexing apparatus 1000 according to the seventh exemplary embodiment of the present invention may adjust the amount of light incident on the output optical collimator by varying the position of the input optical collimator installed at an inclined angle.

The wavelength multiplexing device 1000 includes a plurality of input optical collimators 1010, a concave mirror reflector 1020, a first output optical collimator 1030, a second output optical collimator 1040, and a displacement generator 1050. And a holder 1060 on which the components are mounted.

The holder 1060 is a cylindrical member, with one opening having a concave mirror reflector at one end thereof, an opening at which the second output optical collimator is mounted at the other end thereof, and an opening at which the second output optical collimator is mounted. On the concentric circles, a plurality of openings on which the input optical collimator and the displacement generator are mounted are formed, respectively.

The input optical collimator 1010 is a means for converting light of an unspecified wavelength input from the input optical fiber 1012 into parallel light and outputting the parallel light. As the input optical collimator 1010, it is preferable to use a 0.23 pitch pitch lens or a 0.25 pitch pitch lens. One side of the input optical collimator 1010 is bonded to the displacement generating unit 1050 by the adhesive (b3).

The concave mirror reflector 1020 is a means for refracting light incident to parallel light by a predetermined angle and then reflecting the concave mirror 1022 formed at one end to output the light. The concave mirror reflector 1020 includes a lens for refracting parallel light and a concave mirror 1022 formed at one end of the lens. The concave mirror reflector 1020 reflects the input parallel light from the concave mirror 1022 through the lens axis, thereby reducing the angle of the light incident to the output light collimator 1030 even at a relatively short distance from the planar mirror reflector. have.

The first output light collimator 1030 is a means for condensing and outputting the light reflected on the reflecting surface 1022 of the concave mirror reflector 1020. The first output optical collimator 1030 is bonded to the input / output surface of the concave mirror reflector 1030.

The second output optical collimator 1040 is a means for inserting parallel light output from the first output optical collimator 1030 into the output optical fiber 1042. The second output light collimator 1040 is bonded to the holder 1060 by an adhesive b4.

The displacement generator 1050 is a means for varying the axial position of the input optical collimator 1010 according to the application of voltage. One side of the displacement generator 1050 is bonded to the holder 1060 by the adhesive (b2). A piezoelectric piezoelectric element may be used as the displacement generator 1050. The displacement generator 1050 serves as a variable optical attenuator as described above in the sixth embodiment.

FIG. 17 is a view showing an 8 x 1 wavelength multiplexing device according to an application of the present invention, and FIG. 18 is a view showing a 64 x 1 wavelength multiplexing device according to an application of the present invention.

As shown in FIG. 17, the 8 × 1 wavelength multiplexing device 400 according to an application example of the present invention includes a cylindrical housing 410, an output optical collimator 420 installed at one end of the cylindrical housing 410, and Eight input optical collimators 430 arranged concentrically around the output optical collimator 420, a reflector 440 installed at the other end of the cylindrical housing 410, and a holder for fixing the output optical collimator and the input optical collimators ( 450).

The channel-specific light input to the eight input optical collimators 430 is converted into parallel light and emitted to the reflector, and the channel-specific light reflected by the reflector 440 is focused at one focal point and output light collimator 420. Incident. Light incident on the output optical collimator 420 is transmitted to the next node through the output optical fiber 422.

Since the 8 × 1 wavelength multiplexing device 400 according to the application example of the present invention generates a coupling loss of -1 dB or less, it has an excellent low loss characteristic compared to -9 dB at -6 dB, which is a coupling loss of the conventional wavelength multiplexing device. Able to know.

Although not shown, the 8 × 1 wavelength multiplexing apparatus 400 according to an application of the present invention may further include a displacement generator that varies an axial position of the input optical collimator according to voltage application. The displacement generator generates a displacement in the input optical collimator, thereby changing the amount of light incident on the output optical collimator.

In addition, as shown in FIG. 18, the 64 × 1 wavelength multiplexing apparatus 500 according to the application example of the present invention has a module housing 510 and nine 8 × 1 wavelength multiplexing embedded in the module housing 510. Unit 520, wherein the nine 8x1 wavelength multiplexing units 520 include eight 8x1 first-stage wavelength multiplexing units 520a and one 8x1 second-stage wavelength multiplexing units 520b. It consists of.

The 8 × 1 first stage wavelength multiplexing unit 520a multiplexes eight channels of light input through eight input optical fibers and outputs the same through one output optical fiber. In addition, the 8 × 1 second stage wavelength multiplexing unit 520b multiplexes the eight channel multiplexed lights respectively outputted from the eight 8 × 1 first stage wavelength multiplexing units 520a, and then through one output optical fiber. Output to the node.

The 64 x 1 wavelength multiplexing device 500 according to the application of the present invention has a coupling loss of -2 dB or less. That is, the 64 × 1 wavelength multiplexing apparatus 500 according to the application of the present invention is a two-stage 8 × 1 wavelength multiplexing, and only a coupling loss of -1dB or less occurs every time one stage, so overall Very small coupling losses below -2dB.

As described above, in the wavelength multiplexing apparatus according to the embodiment of the present invention, when multiplexing an optical signal of 8 channels to a single optical fiber, a coupling loss of -1 dB or less occurs, and only a very small loss is required when multiplexing an optical signal of multiple channels. As a result, the spacing between the channels is not only compact, but also suitable for a DWDM system requiring the transmission of a large number of optical signals of more than 32 to 64 channels.

In addition, unlike the conventional wavelength multiplexing apparatus, the wavelength multiplexing apparatus according to the embodiment of the present invention has a wavelength-independent characteristic that has no relation to the wavelength of the optical signal for each channel. There is an effect that it is not necessary to consider the wavelength of the input optical signal when repairing and expanding.

In addition, the wavelength multiplexing device according to the embodiment of the present invention can adjust the intensity of the input light and output light for each channel, it is possible to adjust the input / output value of the optical signal to the optimal light intensity value suitable for the corresponding optical communication system have.

Claims (14)

In the wavelength multiplexing device, A plurality of input optical collimators for converting and outputting light of an unspecified wavelength input from an input optical fiber into parallel light; A reflector reflecting light output from the plurality of input light collimators and condensing at one focal point; And an output optical collimator for inserting light focused at one focal point by the reflector into an output optical fiber. The method of claim 1, And a spherical mirror or a parabolic mirror as the reflector. The method of claim 1, And a 0.23 Pitch GRIN lens or a 0.25 Pitch GRIN lens as the input optical collimator, and a 0.29 Pitch GRIN lens or a 0.50 Pitch GRIN lens as the output optical collimator. In the wavelength multiplexing device, A plurality of input optical collimators arranged on concentric circles and converting light of an unspecified wavelength input from an input optical fiber into parallel light and outputting the parallel light; A spherical mirror reflecting light output from the plurality of input light collimators and condensing at one focal point; And an output optical collimator positioned at a concentric center of the input optical collimator, the output optical collimator inserting the light collected by the spherical mirror into the output optical fiber. The method of claim 4, wherein And a 0.23 Pitch GRIN lens or a 0.25 Pitch GRIN lens as the input optical collimator, and a 0.29 Pitch GRIN lens or a 0.50 Pitch GRIN lens as the output optical collimator. In the wavelength multiplexing device, A plurality of input optical collimators arranged on concentric circles and converting light of an unspecified wavelength input from an input optical fiber into parallel light and outputting the parallel light; A rod-shaped reflector having a reflecting surface for reflecting light output from the plurality of input light collimators and condensing at one focal point; And an output optical collimator positioned at the concentric center of the input optical collimator, the output optical collimator inserting the light collected by the planar mirror reflector into the output optical fiber. The method of claim 6, And the reflective surface of the rod-shaped reflector is formed of any one of a flat reflective surface, a concave reflective surface, and a convex reflective surface. The method of claim 6, And a 0.23 Pitch GRIN lens or a 0.25 Pitch GRIN lens as the input optical collimator, and a 0.29 Pitch GRIN lens or a 0.50 Pitch GRIN lens as the output optical collimator. In the wavelength multiplexing device, A plurality of input optical collimators arranged on concentric circles and converting light of an unspecified wavelength input from an input optical fiber into parallel light and outputting the parallel light; A rod-shaped reflector having a reflective surface therein for reflecting light output from the plurality of input optical collimators and focusing at one focal point; A first output optical collimator positioned at the center of the concentric circle of the input optical collimator and converting the light collected by the reflecting surface of the rod-shaped reflector into parallel light; And a second output optical collimator for inserting parallel light output from the first output optical collimator into an output optical fiber. The method of claim 9, And the reflective surface of the rod-shaped reflector is formed in a parabolic or spherical shape. The method of claim 9, And a 0.23 pitch pitch lens or a 0.25 pitch pitch lens as the input optical collimator, the first output optical collimator, and the second output optical collimator. In the wavelength multiplexing device, A holder having openings at both ends; A plurality of input optical collimators arranged concentrically on one end of the holder and converting light of an unspecified wavelength input from an input optical fiber into parallel light and outputting the parallel light; A rod-shaped reflector installed at the other end of the holder and having a reflective surface therein for reflecting light output from the plurality of input optical collimators to focus at one focal point; A first output optical collimator positioned at the center of the concentric circle of the input optical collimator and converting the light collected by the reflecting surface of the rod-shaped reflector into parallel light; A second output optical collimator for inserting parallel light output from the first output optical collimator into an output optical fiber; And a displacement generating unit disposed on an outer circumferential surface of the input optical collimator and configured to change an axial position of the input optical collimator according to voltage application. The method of claim 12, Wavelength multiplexing apparatus using a piezoelectric piezoelectric element as the displacement generating unit. The method of claim 12, The input optical collimator is installed to be inclined at a predetermined angle with respect to the central axis of the rod-shaped reflector, and the rod-shaped reflector is a concave mirror that refracts incident light by a predetermined angle and then reflects and outputs the concave mirror formed at one end thereof. A wavelength multiplexing device using a reflector.