KR20110114395A - Bidirectional optical transceiver module for wavelength division mulitiplexing system - Google Patents

Abstract

The bidirectional transmission optical transmission and reception module according to the present invention includes a stub through which light of A wavelength band and light of B wavelength band travel; A ferrule housing surrounding the stub; A prism having a total reflection surface for totally reflecting the light output from the stub on a reflecting surface to change the optical path in the direction of the light receiving portion, and a surface for total reflection of light incident from the light receiving portion direction; A wavelength band separation filter for reflecting light in the A wavelength band reflected by the prism and transmitting light in the B wavelength band toward the optical receiver; A transmission wavelength blocking filter for transmitting only light in the B wavelength band passing through the wavelength band separation filter; And an optical transmitter configured to inject by light of the A wavelength band reflected by the wavelength band separation filter and reflected back from the total reflection surface of the prism to output the light traveling to the stub.
According to the present invention, a bidirectional optical transmission module can be manufactured even when light having a narrow gap between two wavelength bands is used, and a miniaturized bidirectional transmission optical transmission / reception module can be manufactured by greatly reducing the distance between the optical transmitter and the ferrule housing by using a prism. Production is possible.

Description

Bidirectional Optical Transceiver Module for Wavelength Division Mulitiplexing System}

The present invention relates to a bidirectional transmission optical transmission and reception module, and more particularly, to a bidirectional transmission optical transmission and reception module suitable for optical transmission in the case where the distance between the transmission wavelength and the reception wavelength is narrow in the bidirectional transmission optical transmission / reception module for WDM.

The high-speed access network, which provides high-speed Internet, IPTV and telephone services, has expanded worldwide since 2000, and now reaches the era of FTTH, where fiber is connected to homes. Make up the largest market. The subscriber network has developed into ATM-PON, B-PON, G-PON and GE-PON based on the Passive Optical Network (PON) structure, and WDM-PON (Wavelength Division Multiplexing), which Korea has a patent on. A lot of research is being done as an alternative to the next generation subscriber network, and the domestic and foreign markets are gradually expanding. WDM is classified into coarse wavelength division multiplexing (CWDM) and dense wavelength division multiplexing (DWDM) by the interval between wavelengths transmitted through the same optical fiber.

The conventional optical transmission module for WDM-PON, in which the optical transmitter and the optical receiver are formed in independent forms, has difficulty in increasing the price and miniaturization of the optical transmitter module due to the fusion process of the optical fiber. Therefore, in consideration of the miniaturization of the optical transmission module, the bidirectional transmission optical transmission module (bi-directional module) integrating the above-described independent optical transmission module and optical reception module is mainly used in the WDM-PON system.

High-density, light-weight and economical optical transceivers are indispensable for the WDM-PON system to be built, and miniaturization and cost reduction of optical transmission / receiving modules are essential to meet the specifications of optical transceivers.

In the WDM-PON system, when the wavelength of the transmission light and the reception light are C bands (wavelengths 1530-1560 nm) and E bands (wavelengths 1360-1460 nm), respectively, the interval between the two wavelengths is wide. Bi-directional transmission optical transmission module such as is mainly used. This includes a light transmitting unit 110 and a light receiving unit 120 in one housing 100, specifically, the light of the B wavelength through the stub 160 A / B wavelength band separation filter 130 of the inclination of 45 degrees Is reflected by the transmission wavelength blocking filter 130 and is incident to the light receiving unit 120, the light of the A wavelength is transmitted through the A / B wavelength band separation filter 130 of 45 degrees inclination through the stub (160) Input to the optical transmitter 110 as a seed light. The optical transmitter 110 outputs light having the same wavelength as the A wavelength input to the seed light, passes through the A / B wavelength band separation filter 130 having a 45-degree slope, and is then transmitted to the stub 160.

In the configuration of FIG. 1, the A / B wavelength band separation filter 130 tilted at 45 degrees transmits and reflects light of A wavelength and light of B wavelength irrespective of polarization to separate each light according to the wavelength. shall. Therefore, the A / B wavelength band separation filter inclined at 45 degrees 130 has a guard band wide to separate transmission and reception light regardless of polarization. However, when the distance between the two wavelengths is small as about 10 nm, such as the case where the wavelength of the transmission light and the wavelength of the reception light are C band (wavelength 1530-1560 nm) and L band (wavelength 1570-1610 nm), respectively, an optical signal transmitted and received The polarization dependency of the wavelength band separation filter is suffered as it is. 2 illustrates the characteristics of the A / B wavelength band separation filter tilted at 45 degrees according to polarization. In this case, the L-wavelength band represents a transmission characteristic and the C-wavelength band represents a reflection characteristic. As shown in FIG. 2, the transmission characteristic changes by about 13 to 21 nm according to polarization, and a guardband of 21 nm, which is the maximum value, is required in order not to be affected by the polarization state. Therefore, the 45-degree A / B wavelength band separation filter with wide guard band functions as a normal filter because optical reflection and transmission characteristics are distorted due to polarization in the case of narrow wavelength intervals such as wavelength separation between C and L bands. Will be lost.

A structure for solving the wavelength separation problem in a narrow band appearing in the conventional optical transmission module as described above is disclosed in Republic of Korea Patent Registration 10-0670225 and Republic of Korea Patent Registration 10-0783753. The structure of the Republic of Korea Patent No. 10-0670225 is composed of an optical transmitter, an optical receiver, a C / L wavelength band separation filter, an L / C wavelength band separation filter, a reflector and a stub in the housing 300 as shown in FIG. The structure is characterized in that the optically separate the incident light and the reflected light by using the reflector 340 polished stub 360 to the gold coating or the polishing angle of the stub 360 and the surface of the reflector 340 Depending on the coating condition, an error in reflectance occurs, which causes a decrease in receiver performance. In addition, when a non-uniform gold coating of the reflector 340 occurs or a portion of the coated material is peeled off, light scattering may occur in the reflector 340, causing a decrease in the reception sensitivity of the light receiver 320. In addition, the cost of the polishing of the stub 360, the gold coating cost of the reflector 340 additionally occurs. In addition, when fabricating an optical transmission / reception module using the stub 370 having the reflector 340, the C / L wavelength band separation filter 350 and the reflector 370 attached to the stub 370 are inclined 8 degrees. Since the beam size and the direction of the incident light and the reflected light change according to the distance and angle of the light, the position of the stub is determined by an active alignment process that finds the proper position of the reflector 340 attached to the stub 360. The process of finding the best position occurs. Due to this, there is a problem in that standard time is increased and additional costs are generated during manufacturing.

Therefore, the technical problem to be achieved by the present invention is to incorporate the optical transmitter and the optical receiver in one housing, but the normal separation of the two bands is possible and miniaturized so that normal bi-directional transmission and reception even using light having a narrow gap between the bands To provide a bidirectional transmission optical transmission module for WDM.

WDM bidirectional transmission optical transmission module according to the present invention for achieving the above technical problem is characterized in that the optical transmission unit, optical reception unit, ferrule housing, prism, transmission wavelength blocking filter and wavelength band separation filter in one housing .

The light of wavelength A, which is the seed light of the light transmitting part, and the light of the wavelength B, which is the receiving light of the light receiving part, are incident to the inside of the housing and are reflected from one reflective surface of the prism, and the reflected light is incident to the B / A wavelength band separation filter. Thus, light in the B wavelength band that is the received light is transmitted, and light in the A wavelength band that is the transmitted light is reflected. The light of the B wavelength band passing through the B / A wavelength band separation filter passes through the transmission wavelength blocking filter and is incident to the optical receiver. The light of the A wavelength band, which is the transmitted light reflected by the B / A wavelength band separation filter, is reflected from the reflecting surface on the other side of the prism and sent to the optical transmitter. The optical transmitter receives light of A wavelength band as seed light and generates light of A wavelength band and proceeds in the reverse order of the path where the seed light is incident.

The inclination of the prism reflecting surface should be adjusted to allow separation of incident light and reflected light in the B / A wavelength band separation filter. Specifically, the angle between the vertical axis of the B / A wavelength band separation filter and the traveling direction of the light reflected from the prism may be within 10 degrees to allow separation of the transmission wavelength and the reception wavelength in the B / A wavelength band separation filter. The inclination of the reflecting surface of the prism is preferably 40 degrees or more and 45 degrees or less.

The prism obstructs the path of the transmission light and the reception light by considering a difference between the focal length of the photodetector of the light receiver (typically 3 to 4 mm) and the focal length of the laser diode of the optical transmitter (typically 7 to 10 mm). It is installed as close to the ferrule housing as possible. In consideration of the focal length of the optical receiver, the distance between the prism and the B / A wavelength band separation filter is preferably maintained at the shortest distance.

The optical transmitter may include an injection-type locked FP LD (Fabry-Perot Laser Diode), and in this case, the light is reflected from the B / A wavelength band separation filter and transmitted to the FP LD by light having a wavelength of A band sent to the optical transmitter. Injection is made and amplified so that light of a single wavelength is output from the FP LD.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention will be described in detail. The following embodiments are only presented to understand the contents of the present invention, and those skilled in the art may make many modifications within the technical spirit of the present invention. Therefore, the scope of the present invention should not be construed as limited to these embodiments.

4 shows a first embodiment of the present invention, in which the two surfaces of the prism are totally coated to be disposed at the center of the housing, thereby realizing the separation of the light of the A wavelength band and the light of the B wavelength band and narrowing the distance between the optical transmitter and the stub. It is a view for explaining a bidirectional optical transmission module that can realize the miniaturization of the housing. In detail, the reflection surface of the prism, the B / A wavelength band separation filter, and the transmission wavelength blocking filter are used to realize wavelength separation of the light of the A wavelength band and the light of the B wavelength band with a distance of about 10 nm between the two wavelengths. It is to shorten the distance between the stub and the optical transmitter by extending the path of the light output from the optical transmitter.

The light in the A wavelength band and the light in the B wavelength band output from the core 461 at the center of the stub are totally reflected on one side 451 of the prism 450 attached with epoxy to the ferrule housing 470. The prism 450 has a thin film coating on both surfaces 451 and 452 so as to totally reflect the light of the A wavelength band and the light of the B wavelength band to reflect the light of the A wavelength band and the light of the B wavelength band toward the light receiving part 420. It is attached to the ferrule housing 470 so as to. Light of the A wavelength band reflected from one surface 451 of the prism is reflected by the B / A wavelength band separation filter 440 and totally reflected by the reflecting surface 452 of the prism and input to the light transmitter 410. The light transmitter 410 receives the light of the A wavelength band input from the reflective surface 452 of the prism to the light transmitter 410 as the seed light to generate the light of the A wavelength band, and then returns to the reflective surface 452 of the prism. It is transmitted and reflected by the B / A wavelength band separation filter 440 and then reflected by the reflecting surface 451 of the prism to proceed to the core 461 at the center of the stub. The light of the B wavelength band transmitted through the B / A wavelength band separation filter 440 among the light of the A wavelength band and the light of the B wavelength band reflected from one surface 451 of the prism is the transmission wavelength blocking filter 430. The light is transmitted through and received by the light receiving unit 420.

The prism 450 has an optical path after light incident on the prism is reflected by the B / A wavelength band separation filter 440 when the reflection surfaces 451 and 452 of the prism 450 form an angle of 45 degrees or more. Can be disturbed by the edge 454 where both sides of the prism intersect, and the gap between the prism and the B / A wavelength band separation filter 440 to avoid intersection with the edge 454 where both sides of the prism intersect. If the width of the bidirectional optical transmission optical transmission module increases the problem occurs. On the contrary, when the angle between the reflection surfaces 451 and 452 on both sides of the prism 450 and the prism bottom 453 is 40 degrees or less, the vertical axis of the light reflected by the prism 450 and the B / A wavelength band separation filter 440 Since the angle formed is increased, the transmission and reflection characteristics of the B / A wavelength band separation filter 440 are deteriorated according to the polarization of the incident light. Therefore, a problem arises in that wavelength separation between the light of the A wavelength band and the wavelength of the B wavelength band becomes impossible. Accordingly, the prism 450 preferably has both reflective surfaces 451 and 452 at an angle of 40 degrees or more and 45 degrees or less with the bottom surface of the prism, and the laser diode of the optical transmitter 410 is controlled by adjusting the angle. The focal length can be adjusted.

FIG. 5 is a diagram for describing a bidirectional transmission optical transmission / reception module for a WDM-PON system in which a total reflection prism is attached to a stub in order to realize miniaturization of the bidirectional optical transmission / reception module according to the second embodiment of the present invention. In detail, the path of the light received by the optical receiver is intersected between the ferrule housing 580 and the A / B wavelength separation filter 550 to reduce the distance between the optical receiver 520 and the ferrule housing 580 to reduce bidirectional optical transmission and reception. Miniaturize module size

The A / B wavelength band separating filter 550 ferrule housing is formed by coating a thin film on the surface of the glass plate so that the A band wavelength of the light of the A wavelength band for light transmission and the light of the B wavelength band for light reception is transmitted and the light of the B band wavelength is reflected. 580 is attached. The stub 560 is installed to be inserted into the ferrule housing 580. An end portion of the ferrule housing 580 should be formed with an opening to expose the core 570 located in the center of the stub 560. Preferably, the end of the ferrule housing 580 is provided with an unevenness to the prism 540. ) May be secured to the top of the ferrule housing 580. At this time, the prism 540 is preferably attached to the ferrule housing 580 using an epoxy.

Among the light of the wavelength A and the wavelength B emitted from the core 570 of the stub, the light of the wavelength B for the light reception reflected by the prism 540 after being reflected by the A / B wavelength band separation filter 550 is The transmission wavelength blocking filter 530 passes through and is received by the light receiving unit 520. In this case, the transmission wavelength blocking filter 530 is preferably attached to the ferrule housing 580 using epoxy. The optical transmitter 510 transmits the A wavelength band inputted to the optical transmitter 510 through the A / B wavelength band separation filter 550 among the light of the A wavelength band and the light of the B wavelength band from the core 570 of the stub. Receives light as a seed light, generates light of A wavelength band, and transmits the light to A / B wavelength band separation filter 550. The light of A wavelength band passes through A / B wavelength band separation filter 550 again. It is output through the core 570 of the stub. The light of the A-band wavelength is the light of the C band, the light of the B-band wavelength is very effective when the light of the L band and the optical transmission unit preferably comprises an injection-locking FP LD.

In the conventional A / B wavelength band separation filter having a 45-degree slope, as described above with reference to FIG. 2, when the distance between two wavelengths of incident light is close to each other, such as a C band and an L band, it is impossible to separate light due to polarization. Therefore, the angle between the vertical axis and the incident light of the wavelength band separation filter should be adjusted to allow separation of the incident light and the reflected light in the wavelength band separation filter. Specifically, when the numerical aperture (NA) of the light emitted from the core of the stub is 0.1 and has an emission angle of about 5.7 degrees in one direction from the horizontal axis of the incident light, the vertical axis of the wavelength band separation filter is inclined within 10 degrees with respect to the incident axis. It is preferable to install. In addition, in consideration of the numerical aperture of the incident light and the beam width, it is preferable that the light of the B band wavelength reflected by the A / B band filter is provided at 0 degrees or more so that the light is not incident on the stub core. In addition, since the focal length of most photodetectors used in the optical receiver in the WDM-PON system is 3 to 4 mm, the wavelength band separation filter (550) has a maximum stub within the range where reflected light does not return to the path of incident light. It is preferred to be installed close to 570.

FIG. 6 shows a third embodiment of the present invention, in which the optical transmitter and the optical receiver face each other so that the difference between the bands between the light of the A wavelength band and the light of the B wavelength band is small, regardless of polarization. It is a structure that implements separation of light of B and light of B wavelength band. In detail, the light of the A wavelength band and the light of the B wavelength band emitted from the core 660 of the stub are totally reflected on the reflective surface 651 of the prism 650 having one surface totally coated, thereby changing the optical path. In this case, the changed light path maintains an angle within 10 degrees with the vertical axis of the B / A wavelength band separation filter 640 installed at the front end of the light receiving unit 620. The B / A wavelength band separation filter 640 reflects the light of the A wavelength band in the direction of the optical transmitter 610 and transmits the light of the B wavelength band in the direction of the light receiver 620 and is received by the light receiver 620. The A / B wavelength band separation filter 630 installed at the front end of the optical transmitter 630 transmits the light of the A wavelength band reflected by the B / A wavelength band separation filter 640 to be input to the optical transmitter 610. The optical transmitter 610 receives the light of the wavelength A transmitted through the wavelength band separation filter 630 as seed light to generate light of the wavelength A, and then transmits the light of the wavelength A to the wavelength band separation filter 630 and transmits the B / A wavelength. The light is reflected by the band separation filter 640 and then reflected by the reflecting surface 651 of the prism and proceeds to the core 660 at the center of the stub.

The prism 650 and the B / A wavelength band separation filter 640 are preferably attached to the ferrule housing 680 with epoxy to minimize the size of the bidirectional optical transmission / reception module.

The wavelength band separation filter used in the WDM system is effective to be used in the bidirectional optical transmission / reception module because the angle between the incident light and the wavelength separation filter is maintained at 45 degrees when the guard band spacing is wide, but the guard band spacing is 20 nm, In the case of 14 nm and 10 nm, the angle between the incident light and the wavelength band separation filter is reduced by 12 degrees, 8 degrees and 6 degrees, respectively. Therefore, in the case of the wavelength separation between the C band and the L band, since the wavelength interval between the two bands is 10 nm, the angle between the incident light and the wavelength band separation filter should be set to 6 degrees or less. Sufficient light separation is possible even if the distance between the wavelengths is as small as 10 nm, such as light of wavelength and light of L band wavelength.

As described above, according to the present invention, even in the case of using light having a narrow gap between two wavelength bands, it is possible to manufacture a bidirectional optical transmission module for WDM, and also to reduce the distance between the optical transmitter and the ferrule housing by using a prism and the number of light. By using a structure that reduces the distance between the bride and the ferrule housing, it is possible to manufacture a miniaturized bidirectional transmission optical transmission and reception module compared to the conventional bidirectional optical transmission and reception module, and the present invention provides two adjacent two adjacent CWDM communication systems having a wavelength interval of 20 nm. It is also applicable to bidirectional optical transmission optical transmission and reception module using wavelength.

1 is a view showing for explaining a bidirectional transmission optical transmission and reception module using a conventional 45-degree wavelength band separation filter.
FIG. 2 is a graph for explaining a difference between S-polarized light and P-polarized light for the case of FIG.
3 is a view showing for explaining a bidirectional transmission optical transmission and reception module using a conventional reflector
4 is a view illustrating a bidirectional transmission optical transmission and reception module according to Embodiment 1 of the present invention.
5 is a view illustrating a bidirectional transmission optical transmission and reception module according to Embodiment 2 of the present invention.
6 is a view showing for explaining the bidirectional transmission optical transmission and reception module according to the third embodiment of the present invention;

400: housing of the bidirectional transmission optical transmission and reception module 410: optical transmission unit
420: optical receiver 430: B / A wavelength band separation filter
440: B / A wavelength band separation filter 450: Prism
451: total reflection of light of A and B wavelength wavelengths in the prism
452: A surface that totally reflects light of wavelengths A and B in the prism
460: stub
461: the core of the light input from the optical fiber inside the stub
470: ferrule housing

Claims (13)

A stub through which light of A wavelength band and light of B wavelength band propagate; A prism that totally reflects the light output from the stub on one side in the direction of the light receiving unit and totally reflects the light reflected by the wavelength band separation filter on the other side; A wavelength band separation filter which receives the light reflected from the prism and transmits light in the B wavelength band toward the light receiving part and reflects light in the A wavelength band to the other side of the prism; A transmission wavelength cut-off filter for transmitting only light in the B wavelength band passing through the wavelength band separation filter, and light of the A-band wavelength reflected from a prism totally reflecting the light in the A wavelength band reflected by the wavelength band separation filter. And an optical transmission unit configured to perform injection and output light of A wavelength back to the optical prism.
A stub through which light of A wavelength band and light of B wavelength band propagate; The wavelength band separation filter is installed such that the vertical axis is inclined smaller than 10 degrees with respect to the incident axis to transmit the light of the wavelength A band among the light output from the stub and reflect the light of the wavelength B in a direction different from the incident path. ; A prism installed in the ferrule housing to receive light of the B wavelength band reflected by the wavelength band separation filter and reflect the light; A transmission wavelength blocking filter for transmitting only light in the B wavelength band reflected by the prism; An optical receiver receiving light of the B wavelength band passing through the transmission wavelength blocking filter; And an optical transmitter configured to inject by light having a wavelength of the A band transmitted through the wavelength band separation filter and output the light that passes through the optical filter to the optical fiber.
A stub through which light of A wavelength band and light of B wavelength band propagate; A prism that totally reflects the light output from the stub on one surface in the direction of the light receiver; A wavelength band separation filter which receives the light reflected from the prism and transmits light in the B wavelength band toward the light receiving part and reflects light in the A wavelength band; A transmission wavelength blocking filter for transmitting only light in the B wavelength band passing through the wavelength band separation filter, and an optical receiver for receiving light in the B wavelength band passing through the transmission wavelength blocking filter; And an optical transmitter configured to inject by light of the A wavelength band reflected by the wavelength band separation filter to output light of A wavelength back to the optical prism.
2. The bidirectional transmission optical transmitting / receiving module according to claim 1, wherein a prism having an angle between both reflective surfaces of the prism and the bottom surface of the prism is used from 40 degrees to 45 degrees. 2. The bidirectional transmission optical transmission / reception module according to claim 1, wherein the light of the wavelength A band is the light of the C band and the light of the wavelength B band is the light of the L band.
The optical transmitter of claim 1, wherein the optical transmitter includes an injection-type locked FP LD and is injected into the FP LD by light of an A-band wavelength transmitted through the wavelength band separation filter and sent to the optical transmitter, thereby amplifying a single wavelength. Bi-directional transmission optical transmission and reception module, characterized in that the light is output from the FP LD.
3. The bidirectional transmission optical transmission / reception module according to claim 2, further comprising a wavelength band separation filter inclined to 10 degrees or less with respect to the incident axis of the light in the B wavelength band to reflect the light in the B wavelength band to the prism.
3. The optical transmitter of claim 2, wherein the optical transmitter includes an injection-type locked FP LD, and is injected into the FP LD by light of an A-band wavelength transmitted through the wavelength band separation filter and sent to the optical transmitter, thereby amplifying the single wavelength. Bi-directional transmission optical transmission and reception module, characterized in that the light is output from the FP LD. 3. The bidirectional transmission optical transceiver module according to claim 2, further comprising a prism attached to the stub to extend a path of the light traveling to the optical receiver.
The bidirectional transmission optical transmission / reception module according to claim 2, wherein the light of the wavelength A band is the light of the C band and the light of the wavelength B band is the light of the L band.
4. The bidirectional transmission optical transmission / reception module according to claim 3, further comprising a prism for totally reflecting the light of the A wavelength band and the light of the B wavelength band to be incident on the wavelength band separation filter at an angle of 10 degrees or less.
4. The bidirectional transmission optical transmission / reception module according to claim 3, wherein the lens side of the optical receiver and the optical transmitter for receiving the light reflected by the prism face each other at an angle of 10 degrees or less.
4. The bidirectional transmission optical transmission / reception module according to claim 3, wherein the light of the wavelength A band is light of the C band and the light of the wavelength B band is light of the L band.

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