KR0170329B1 - Optical wavelength division multiplexer for optical communication - Google Patents

Abstract

A photosynthesis splitter for optical communications that can be used for optical communications is disclosed.

The disclosed optical communication optical splitter includes: a body having a cylindrical hollow portion; A first ferrol coupled to one end of the body and having end portions of at least two first and second optical fibers for transmitting light; A second ferrule coupled to the other end of the body and having an end of at least one third optical fiber transmitting light; A lens holder installed in the hollow portion of the body; First and second hemispherical lenses coupled to the lens holder to focus light transmitted through the first to third optical fibers, the first and second hemispherical lenses having their respective planes facing each other; And an optical filter interposed between the first and second hemispherical lenses to selectively transmit or reflect the light transmitted through the first to third optical fibers according to the wavelength thereof, thereby converting a traveling path of the light. The light of different first and second wavelengths input through the optical fiber is summed and directed toward the second optical fiber, and the light incident from the second optical fiber is branched into the first and second wavelengths, respectively, so that the first and third optical fibers are respectively Characterized by facing to.

Description

Photosynthesis splitter for optical communication

1 is a schematic diagram showing a dual wavelength coupler (photosynthesis splitter) of the prior art.

FIG. 2 is a diagram showing a propagation path of an optical signal in the case of bidirectional communication in the dual wavelength coupler of FIG.

3 is a schematic diagram showing the configuration of another prior art photosynthetic splitter and the path of the optical signal.

Figure 4 is a schematic diagram showing the optical arrangement of the optical splitter for optical communication according to an embodiment of the present invention.

5 is a schematic diagram showing a path of an optical signal in an embodiment according to the present invention.

6 is a schematic diagram showing another path of an optical signal in an embodiment according to the present invention.

* Explanation of symbols for main parts of the drawings

1: first optical fiber 2: second optical fiber

3: first ferrule 4: lens holder

5-1: First hemispherical lens 5-2: Second hemispherical lens

6: filter coating layer 7: body

8: second ferrule 9: third optical fiber

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wavelength division multiplexer used for optical communication, and more particularly, to an optical communication optical splitter that can be easily adjusted and assembled during manufacturing.

In general, the optical splitter refers to a device for combining or separating two optical signals in order to transmit and receive two optical signals having different wavelengths through a single optical fiber in an optical communication using an optical fiber.

Structures for dual wavelength couplers used in such optical communications are disclosed in US Pat. No. 4,904,043. Here, a device is described which enables bidirectional communication (transmitter and receiver) and one-way communication (two transmitters or two receivers) over a single optical fiber. 1 shows a cross-sectional view of a conventional dual wavelength coupler as a whole. The dual wavelength coupler is another name for the photosynthetic splitter of the present invention. The main optical components included in the dual wavelength coupler include three lenses 10, 14 and 16, that is, one GRIN (gradient index) lens 10 and two spherical lenses 14. (16) and dichroic filter 30 are used. As shown, in relation to input and output, a positive-intrinsic-negative diode (PIN) 38, which is an optical sensing means for receiving an input signal, a light emitting element that is a light source for generating an optical signal of a predetermined wavelength, eg For example, the optical fiber 26 that transmits the LED 42 optical signal, etc. forms the basic basis of the dual wavelength coupler, and includes three lenses 10, 14, 16, filters 12, 32, and the like. It consists of a body 22 for receiving and supporting them.

The above structure description is for a bidirectional communication, i.e., when transmission and reception are performed at different wavelengths. For example, the transmission signal is made of a wavelength of λ ₁ and the reception is made of a wavelength of λ ₂ . This is the case. The outgoing signal is generated in the light emitting element 42 and the received signal is sensed in the PIN diode 38.

FIG. 2 relates to the dual wavelength coupler of FIG. 1 and shows an optical signal propagation path when reception and transmission are simultaneously performed through a single optical fiber in bidirectional communication. The received optical signal having a wavelength of λ ₂ becomes parallel light through the green lens 10, passes through a filter, is focused by the spherical lens 14, and is received by the PIN diode 38, which is a light sensing element. On the other hand, the light emitting device generates an optical signal having a wavelength of λ ₁ , which passes through the spherical lens 16 and becomes parallel light, and is reflected by the filter 12 to reflect the λ ₂ through the green lens 10. An optical signal having a wavelength is transmitted to the same superfiber as the incoming optical fiber. This allows optical signals of two different wavelengths to be received and transmitted over a single optical fiber. In the one-way communication, the dual wavelength coupler receives two signals simultaneously by using only two light sensing elements or using only two light emitting elements, instead of using one light sensing element and one light emitting element. Can also be used as a receiver or sender.

However, optical devices, especially small devices, are required to have very high precision, and the influence of the error is relatively high, and thus the precision of machining is inevitably increased. In addition, as the number of parts increases, the amount of error is likely to increase cumulatively. Therefore, it can be predicted that the dual wavelength coupler of the above-described patent suffers from factors of difficulty and price in actual fabrication. In addition, processing errors in the components used are also likely to increase the price. For example, in the case of an ultra-small spherical lens having a diameter of about 2 mm to 3 mm, processing is relatively difficult and difficulty in handling in an assembly or the like can be easily predicted.

Another conventional device is shown in FIG. As shown, three optical fibers 1a, 2a and 3a are used for input and output, and a support body 8a made of glass for supporting the optical fibers 1a and 2a and a glass for supporting the optical fiber 3a. And a support body 9a, lens assemblies 4a and 41a and lens assemblies 5a and 51a, and a filter 7a.

In such a configuration, light including optical signals of two different wavelengths λ ₁ and λ ₂ is incident on the filter 7a via the lens assemblies 4a and 41a. Light having an optical signal of wavelength λ ₁ is reflected by the filter 7a and again passes through the lens assemblies 4a and 41a, and then is focused on the optical fiber 2a, and light having an optical signal of the wavelength λ ₂ is filtered. After passing through 7a and passing through the lens assemblies 5a and 51a, the light is collected and focused on the optical fiber 3a.

The problem with the device is that the optical fiber and the lens are integrated, so that the adjustment of the focal length, optical axis, etc. must be made by the filter, which makes the structure complicated. In addition, since the number of lenses is large, there are problems of error and increase in manufacturing cost.

Accordingly, an object of the present invention is to provide a photosynthesis splitter having a simple structure and easy manufacture.

Optical communication optical splitter according to the present invention to achieve the above object,

A body having a cylindrical hollow portion; A first ferrule coupled to one end of the body and having end portions of at least two first and second optical fibers for transmitting light; A second ferrule coupled to the other end of the body and having an end of at least one third optical fiber transmitting light; A lens holder installed in the hollow portion of the body; First and second hemispherical lenses coupled to the lens holder to focus light transmitted through the first to third optical fibers, the planes of which face each other, and the first and second hemispherical lenses An optical filter interposed therebetween to selectively transmit or reflect the light transmitted through the first to third optical fibers according to the wavelength thereof, thereby converting a traveling path of the light;

The light of the first and second wavelengths inputted through the first and third optical fibers are summed and directed toward the second optical fiber, and the light incident from the second optical fiber is split into the first and second wavelengths. To be directed to each of the first and third optical fibers.

By the above configuration, a simple structure requiring no adjustment of the filter is achieved. In addition, since the number of lenses is small, a small sized photosynthesis splitter can be provided. The photosynthetic splitter is not only easy to adjust and align components in manufacturing but also to manufacture each component. In addition, since the signal light passes through five boundary surfaces and the pump light passes through six boundary surfaces, the number of two passing boundary surfaces is reduced, respectively, as compared with the prior art, thereby increasing efficiency.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

4 is a schematic view showing the configuration of a photosynthesis splitter according to the present invention. A cylindrical lens holder 4 is installed inside the body 7 having a cylindrical hollow portion, and the first and second hemispherical lenses 5-1 and 5-2 are coupled to the lens holder 4. It is installed as it is. An optical filter 6 is interposed between the hemispherical lenses 5-1 and 5-2. The optical filter 6 selectively transmits or semi-reflects the light transmitted through the first to third optical fibers 1, 2, and 9 according to its wavelength to convert the path of the light. Here, the optical filter 6 may be coated on any one of the planes facing each other of the first and second hemispherical lenses 5-1 and 5-1. Such a configuration itself is widely known, so a detailed description thereof will be omitted.

In addition, a part of the first ferrule 3 and the second ferrule 8 is formed on both sides of the first and second hemispherical lenses 5-1 and 5-2 in the hollow portion of the body 7, respectively. It is inserted to the position which abuts on the edge part of (4). The distance from the end of each of the first and second ferrules 3 and 8 to the opposing center planes of the first and second hemispherical lenses 5-1 and 5-2 is defined by the first and second hemispherical lenses 5. -1) to be twice the focal length of (5-2). In other words, since the first and second hemispherical lenses 5-1 and 5-2 are installed in the center of the lens holder 4, the length of the lens holder is approximately the focal length of the lens in consideration of the machining error and the assembly error. It is preferable that it is four times. Thus, when assembly is complete, the lens and optical fiber are automatically in focus.

The first optical fiber 1 and the second optical fiber 2 are embedded in the first ferrule 3. In addition, another optical fiber may be selectively embedded in the first ferrule 3 as needed. That is, three optical fibers may be embedded so that the angle formed by the center of the circle, which is the cross section of the ferrule, and the buried points of the optical fibers, is 120 °. The other is the optical fiber may be used as a substitute for the first optical fiber 1 or the second optical fiber 2, and may be used for transmitting a control signal. The third optical fiber 9 is embedded in the second ferrule 8.

5 shows the path of an optical signal in the photosynthesis splitter of the present invention. The signal light of wavelength λ ₁ emitted from the first optical fiber 1 is dispersed in the optical fiber cross section and passes through the first hemispherical lens 5-1. Thereafter, the light is reflected by the optical filter 6 and passes through the focal point of the lens to enter the second optical fiber 2. On the other hand, the pumping light of wavelength λ ₂ emitted from the third optical fiber 9 is dispersed in the cross section of the optical fiber and passes through the second hemispherical lens 5-2 and the optical filter 6 to enter the second optical fiber 2. . Therefore, the second optical fiber 2 proceeds with signal light having wavelengths λ ₁ and λ ₂ .

The assembly and adjustment of the photosynthetic splitter of the present invention will be described with reference to FIG. Each of the first and second hemispherical lenses 5-1 and 5-2 provided in the lens holder 4 has one plane, and the optical filter 6 is a plane of the first and second hemispherical lenses, that is, Since it is formed at the interface, it is not necessary to adjust the angle of the optical filter. Therefore, the optical adjustment is performed when the first and second hemispherical lenses 5-1 and 5-2 are cooked in the lens holder 4, that is, in a state in which the lens holder 4 is coupled to the body 7. Only the first ferrule 3 and the second ferrule 8 need to be adjusted. Assembly first filters the lens interface of one hemispherical lens and then combines the other hemispherical lenses to form one lens. Then, the combined lens is pressed into the lens holder 4, and the lens holder 4 with the lens pressed therein is coupled to the body 7.

In this state, the first ferrule 3 in which the first optical fiber 2 and the second optical fiber 2 are embedded is adjusted in the X-Y direction perpendicular to the optical axis. At this time, it is not necessary to adjust the ferrule in the circumferential direction, that is, the rotation direction. After the adjustment of the first ferrule 3, the second ferrule 8 in which the third optical fiber 9 is embedded is adjusted to complete the assembly and adjustment of the photosynthesis splitter.

In addition, in the case of an optical splitter used on the receiving side, it has an optical path as shown in FIG. That is, the signal light of wavelengths λ ₁ and λ ₂ proceeds from the second optical fiber 2, and the signal light of λ ₁ passes through the first hemispherical lens 5-1, is reflected by the optical filter 6, and is then returned to the first optical fiber 6. Proceeds through the hemispherical lens 5-1 to the first optical fiber 1. On the other hand, the signal light of λ ₂ passes through the first hemispherical lens 5-1 and the optical filter 6 and then passes through the second hemispherical lens 5-2 to enter the third optical fiber 9.

In the above embodiment, the devices connected to the terminals of the respective optical fibers are suitably connected to devices including light emitting devices for generating optical signals or devices including light receiving devices for detecting optical signals. Of course, one terminal is connected to the receiving or transmitting optical cable.

In addition to the embodiment described above, three optical fibers may be embedded in the first ferrule 3. One additional optical fiber can be used for various purposes. For example, the extra optical fiber may be used to apply a certain signal for modifying or modifying a specific optical signal for the purpose of communication security, etc., and may also be used for applying a specific control signal. Of course, further optical fibers may be embedded as needed, and positions optically symmetric with respect to the center of the cross section of the ferrule may be selected as the embedding positions.

As described above, since the number of lenses is basically reduced by the configuration of the photosynthesis spectrometer of the present invention, the structure is simplified and the number of parts used is also reduced. In addition, when the optical filter is interposed between the lenses, the adjustment of the filter is made by adjusting the optical axis of the lens during assembly, so that no separate adjustment of the filter is necessary. Accordingly, an optical splitter can be provided that is easy to assemble, the parts can be easily aligned, and the manufacturing of each part is easy.

Claims (3)

A body having a cylindrical hollow portion; A first ferrule coupled to one end of the body and having end portions of at least two first and second optical fibers for transmitting light; A second ferrule coupled to the other end of the body and having an end of at least one third optical fiber transmitting light; A lens holder installed in the hollow portion of the body; First and second hemispherical lenses coupled to the lens holder to focus light transmitted through the first to third optical fibers, the planes of which are disposed to face each other; An optical filter interposed between the first and second hemispherical lenses to selectively transmit or reflect the light transmitted through the first to third optical fibers according to the wavelength thereof to convert a traveling path of the light; The light of different first and second wavelengths input through the third optical fiber is added to face the second optical fiber, and the light incident from the second optical fiber is branched into the first and second wavelengths so that the first And an optical communication splitter for facing the third optical fiber. The optical splitter according to claim 1, wherein the length of the lens holder is approximately four times the focal length of the first and second hemispherical lenses. The optical splitter for optical communication according to claim 1, wherein the optical filter is coated on a plane of one of the first and second hemispherical lenses.