CN1971324A - A single fiber three-way wave separator/wave combination device - Google Patents
A single fiber three-way wave separator/wave combination device Download PDFInfo
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- CN1971324A CN1971324A CN 200610036400 CN200610036400A CN1971324A CN 1971324 A CN1971324 A CN 1971324A CN 200610036400 CN200610036400 CN 200610036400 CN 200610036400 A CN200610036400 A CN 200610036400A CN 1971324 A CN1971324 A CN 1971324A
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Abstract
The invention relates to field of partial wave/combining wave elements in optical fibre communication area; it aims at overcoming defects of current technique and providing a monofilament three-dimensional partial wave/wave joiner with depolarization cut-off low- depolarization related loss. The design features are it is equipped with fibre-optic interface, 1310 waveband transmitter interface, 1490 waveband receiver interface and 1550 waveband receiver interface; TTR filter with 45 degree and TRR filter with 45 are mounted in the inner, the reflective direction of TTR filter is aiming at the interface of 1550 waveband receiver, the reflective direction of TRR filter is aiming at the interface of 1490 waveband receiver; RTR filter with 0 degree is mounted in inner side of the 1490 waveband receiver interface, RRT filter with 0 degree is mounted in inner side of the 1550 waveband receiver interface, the innovation of the invention is that the coating structur4e of the TTR filter is G(half coupling layer, reflection, wall, reflecting layer, half coupling layer)sA which possesses effect of depolarization.
Description
Technical field
The present invention relates to be used in the optical-fibre communications field wave splitting/composing components and parts field, a kind of single fiber three-way wave splitting/composing device of saying so more specifically with low Polarization Dependent Loss that depolarization ends.
Background technology
Fiber to the home (FTTH) is state-of-the-art network communications technology, with promoting the great development of national yield-power, is the embodiment of national information degree and competitive power, is the needs of development advanced culture, and FTTH arrives at last.FTTH based on EPON (PON) technology as cost the minimum and the most comprehensive cut-in method of function, the bandwidth that is positioned between 1.5Mb/s and the 155Mb/s provides (and the ADSL maximum bandwidth is 8Mb/s), in the integrated transmission of audio of user side, data, vision signal, be the final solution that covers " last kilometer ".
Along with the rise of user terminal video program request, ecommerce, novel business such as end-to-end, then inevitable requirement is carried out integrated audio frequency, video, data transmission at user side.The single fiber three-way technology is one of major technique that realizes at the optical access network of EPON (PON) (OAN) audio frequency, video, data integration transmission, is the optical communication technology focus of developing in the world at present.Emphasis is that the three-dimensional partial wave of an optical access network single fiber closes ripple, light signal is sent to ONT Optical Network Terminal (ONT) from optical line terminal (OLT) in the prior art, 1490nm wave band carry data signals wherein, 1550nm carries cable TV signal, 1310nm carries up feedback signal, requires in ONT Optical Network Terminal (ONT) these three wave bands to be realized that partial wave closes ripple.
General technology is to realize the wavelength-division multiplex of EPON with optical thin film.Realize that by optical filter it is 45 degree that the separation of the light of different wave length, the receiver module of optical access network system require the angle of incidence of light degree of some optical filter.And the oblique incidence meeting causes the characteristic generation of S polarized light and P polarized light to separate, and causes natural light unsmooth, not precipitous to this section of rest position curve from the passband position.Particularly to the 1st three partial wave optical filters, the 1500nm at the 1540nm at rest position edge and edge, passband position is only at a distance of 40nm when 45 ° of wide-angle incident, the spectral characteristic of optical filter is except satisfying optical access network system to the requirements such as Insertion Loss, isolation, also want the special requirement transmittance curve very steep, so manufacture difficulty is very high.Have only several companies that PON wave filter product can be provided at present in the world, but have the big and problem of unstable of Polarization Dependent Loss more; Analyze after tested, main cause is that 45 degree TTR optical filters do not solve the problem that the polarization rest position is separated fully.
Summary of the invention
The objective of the invention is to overcome the shortcoming of prior art, improve a kind of single fiber three-way wave splitting/composing device with low Polarization Dependent Loss that depolarization ends.
The present invention is achieved through the following technical solutions its goal of the invention.
The invention discloses a kind of single fiber three-way wave splitting/composing device, design feature is for being provided with optical fiber interface, 1310 wave band sender interface, 1490 wave band receiver interfaces and 1550 wave band receiver interfaces on single fiber three-way wave splitting/composing device; 45 degree TTR optical filters and 45 degree TRR optical filters are installed between optical fiber interface and 1310 wave band sender interface, and 45 degree TTR optical filter reflection directions are over against 1550 wave band receiver interfaces, and 45 degree TRR optical filter reflection directions are over against 1490 wave band receiver interfaces; In 1490 wave band receiver interface installed inside 0 degree RTR optical filter is arranged, in 1550 wave band receiver interface installed inside 0 degree RRT optical filter is arranged, creation point of the present invention is that the coating structure of described 45 degree TTR optical filters is: G (wall reflection horizon, half coupling layer reflection horizon half coupling layer)
sA, wherein G represents substrate, and A represents air, and s represents the plated film cycle.The TTR optical filter of having improved film structure is a kind ofly can satisfy that transmittance curve is very precipitous, Insertion Loss is low, eliminates the optical filter of polarization influence.Overcome S component and P component rest position do not overlap under wide-angle incident polarization by separation problem, eliminated the polarization separation influence, satisfied the requirement of optical access network single fiber three-way system.
In concrete plated film, the concrete coating structure of 45 degree TTR optical filters of the present invention is:
Anterior layer: G|2.65H 1.65L 1.28H 0.39L 0.8H 1.63L 1.55H 1.64L 0.31H L 1.62H0.5L (0.5LH4L0.5L) ^
310.39L 1.57H 0.9L 0.17H 1.86L 1.61H 2.17L 2.36H 2.08L0.44H 1.83L|A,
Back layer G|0.43L 2.88H 2.05L 3.12H 1.45L 0.74H 0.8L 1.27H 2.03L|A,
Wherein H represents high-index material, and L represents low-index material, the central wavelength lambda of coating structure design
0=986nm, the refractive index n of described high-index material
h=2.135, material is Ta2O5, the refractive index n of low-index material
1=1.456, material is SiO2.
Other three tablet filters have also adopted the film system design that is different from prior art:
The concrete coating structure of described 45 degree TRR optical filters is:
Anterior layer: G|2H1.5L (2HL) ^
132H1.4L1.6H0.8L|A,
Back layer: G|0.4H1.6L|A,
The central wavelength lambda of coating structure design
0=1130nm, material is identical with 45 degree TTR optical filters.
The concrete coating structure of 0 degree RTR optical filter is:
Anterior layer:
G|H4LHLHLH2LHLHL(HLH4LHLHL)^
4HLH2LHLHLH4L0.636H0.703H|A
The back layer: G|H L|A,
The central wavelength lambda of coating structure design
0=1460nm, material is identical with 45 degree TTR optical filters.
The concrete coating structure of 0 degree RRT optical filter (8) is:
Anterior layer: G|0.36H 1.18 L 1.16 H 1.21L (0.5H L 0.5H) ^
22L H L 2H|A
Back layer: G|2H 2L H 3.5L|A
The central wavelength lambda of coating structure design
0=1358nm, material is identical with 45 degree TTR optical filters.
Device of the present invention can be realized the optical information of uplink 1490nm, 1550nm wave band well at this section of Access Network fiber-to-the-home, and downlink transfer 1310nm wave band light wave is as feedback information, in the optical line terminal that can be widely used in spreading out in the optical access network construction, the ONT Optical Network Terminal.
Description of drawings
Fig. 1 is the system architecture synoptic diagram of EPON;
Fig. 2 is the structural representation of single fiber three-way wave splitting/composing device;
Fig. 3 is that the depolarization of 45TTR optical filter ends design curve;
Fig. 4 is 0 degree RTR optical filter, 0 a degree incident light spectrum design curve;
Fig. 5 is 0 degree RRT optical filter, 0 a degree incident light spectrum design curve;
Fig. 6 is 45 degree TRR optical filters, 45 degree incident light spectrum design curves;
Fig. 7 A is that the polarized light transmission under the 45 degree TTR45 degree incidents is measured curve;
Fig. 7 B is 0 degree RTR0 degree incident transmission measurement curve;
Fig. 7 C is 0 degree RRT0 degree incident transmission measurement curve;
Fig. 7 D is 45 degree TRR45 degree incident transmission measurement curves.
Embodiment
Below in conjunction with accompanying drawing these people are described further.
FTTH based on EPON (PON) technology as cost the minimum and the most comprehensive cut-in method of function, the bandwidth that is positioned between 1.5Mb/s and the 155Mb/s provides (and the ADSL maximum bandwidth is 8Mb/s), in the integrated transmission of audio of user side, data, vision signal, be the final solution that covers " last kilometer ".Fig. 1 is the synoptic diagram of PON.After Fiber to the home, PON will provide integrated audio frequency, video, data output to the user, and PON will realize wave splitting/composing to the wave band of 1550nm, 1490nm, 1310nm.The synoptic diagram of a kind of wave splitting/composing device wherein is provided with optical fiber interface 1,1310 wave band sender interface, 2,1490 wave band receiver interfaces 3 and 1550 wave band receiver interfaces 4 as shown in Figure 2 on single fiber three-way wave splitting/composing device; 45 degree TTR optical filters 5 and 45 degree TRR optical filters 6 are installed between optical fiber interface 1 and 1310 wave band sender interface 2,45 degree TTR optical filters, 5 reflection directions are spent TRR optical filters 6 reflection directions over against 1490 wave band receiver interfaces 3 over against 1550 wave band receiver interfaces 4,45; In 1490 wave band receiver interfaces, 3 installed inside 0 degree RTR optical filter 7 is arranged, 0 degree RRT optical filter 8 is arranged in 1550 wave band receiver interfaces, 4 installed inside.
Following table is that the spectral characteristic of each optical filter requires:
The optical filter model | Spectral |
45 |
45 degree incidents, 1490 ± 10nm/1310 ± 50nm, high saturating; 1550 ± 10nm is high anti-; |
0 degree RTR | 0 degree incident, 1490 ± 10nm, high saturating; 1310 ± 50nm/1550 ± 10nm is high anti-; |
0 degree RRT | 0 degree incident, 1550 ± 10nm, high saturating; 1490 ± 10nm/1310 ± 50nm is high anti-; |
45 |
45 degree incidents, 1310 ± 50nm, high saturating; 1490 ± 10nm/1550 ± 10nm is high anti-; |
The transport process of light signal is described below in conjunction with Fig. 1 and Fig. 2.
1490nm wave band carry data signals as shown in Figure 1,1550nm wave band carrying cable TV signal, the 1310nm wave band carries up feedback signal, light signal is sent to ONT Optical Network Terminal (ONT) from optical line terminal (OLT), requirement realizes that to these three wave bands partial wave closes ripple by wavelength division multiplexer at ONT Optical Network Terminal (ONT), be sent to ONT Optical Network Terminal (ONT) by Optical Distribution Network (ODN) and by wavelength division multiplexer these three wave bands realized that partial wave closes ripple again, wherein the core of wavelength division multiplexer is exactly a single fiber three-way wave splitting/composing device of the present invention.As shown in Figure 2, wavelength division multiplexer with ONT Optical Network Terminal (ONT) is an example, the optical signals optical fiber of 1490nm wave band and 1550nm wave band is introduced from optical fiber interface 1, light signal 1550nm wave band on 45 degree TTR optical filters 5 is reflected, and is received by the receiver that is installed on the 1550 wave band receiver interfaces 4.The signal of 1490nm wave band sees through 45 degree TTR optical filters 5 to be continued to propagate, and enters the receiver that is installed on the 1490 wave band receiver interfaces 3 by 6 reflections of 45 degree TRR optical filters and receives.The 1310nm wave band is sent by the transmitter that is installed on the 1310 wave band sender interface 2, enters optical fiber through 45 degree TRR optical filters 6 and 45 degree TTR optical filters 5 successively.Can further filter undesired signal at 1490 wave band receiver interface 3 installed inside, 0 degree RTR optical filters 7 with at 1550 wave band receiver interfaces, 4 installed inside, 0 degree RRT optical filter 8, improve signal to noise ratio (S/N ratio).
In the prior art, when the light oblique incidence, because the p polarization state equivalent refractive index η of optically thin membrane system
pEquivalent refractive index η with the s polarization state
sDifference, the optical interference film optical filter just produces polarization effect.Under a variety of situations, particularly in some optical communication wavelength-division multiplex systems and liquid crystal projection display systems, this polarization effect is to eliminate and to reduce.As the degree of 45 among Fig. 2 TTR optical filter 5, because incident angle is very big, very big separating takes place at passband to the wave band (1500-1540nm) by transition with S light in P light, and the natural light that causes S light and P light to be synthesized is unsmooth at the transmission curve of 1500-1540 wave band, not precipitous.
For overcoming above shortcoming, the present invention adopts brand-new coatings structure to 45 degree TTR optical filters 5.
Its concrete structure is as follows:
Anterior layer: G|2.65H 1.65L 1.28H 0.39L 0.8H 1.63L 1.55H 1.64L 0.31H L 1.62H0.5L (0.5LH4L0.5L) ^
310.39L 1.57H 0.9L 0.17H 1.86L 1.61H 2.17L 2.36H 2.08L0.44H 1.83L|A.
Back layer G|0.43L 2.88H 2.05L 3.12H 1.45L 0.74H 0.8L 1.27H 2.03L|A.
Wherein H represents high-index material, adopts Ta2O5, refractive index n
h=2.135; L represents low-index material, adopts SiO2, refractive index n
l=1.456, the central wavelength lambda of coating structure design
0=986nm.Fig. 3 is that the depolarization of 45TTR optical filter 5 ends design curve, Fig. 7 A is for being coated with on the precious machine of Lay, optical filter curve after the preparation is tested with spectrophotometer, contrast two width of cloth figure as can be seen test curve very near theoretical curve, and level and smooth, precipitous at the transmission curve of 1500-1540 wave band.
The present invention is further improvement also
The concrete coating structure of 0 degree RTR optical filter 7 is:
Anterior layer:
G|H4LHLHLH2LHLHL(HLH4LHLHL)^
4HLH2LHLHLH4L0.636H0.703H|A
The back layer: G|H L|A,
Material is identical with 45 degree TTR optical filters 5, the central wavelength lambda of coating structure design
0=1460nm.
The concrete coating structure of 0 degree RRT optical filter 8 is:
Anterior layer: G|0.36H 1.18L 1.16H 1.21L (0.5H L 0.5H) ^
22L H L 2H|A
Back layer: G|2H 2L H 3.5L|A
Material is identical with 45 degree TTR optical filters 5, the central wavelength lambda of coating structure design
0=1358nm.
The coating structure of 45 degree TRR optical filters 6 is:
Anterior layer: G|2H1.5L (2HL) ^
132H1.4L1.6H0.8L|A,
Back layer: G|0.4H1.6L|A,
Material is identical with 45 degree TTR optical filters 5, the central wavelength lambda of coating structure design
0=1130nm.
Shown in Fig. 4,5,6, the curve that spectrophotometer is tested after being coated with on the precious machine of Lay is shown in Fig. 7 B, 7C, 7D respectively for the Design Theory curve of this three tablet filter, and the effect of plated film is very near theoretical value as can be seen.
The present invention further tests the wave splitting/composing device, the isolation of 4 wave splitting/composing device samples, Polarization Dependent Loss test result such as following table.
| Unit | 1 | 2 | 3 | 4 | ||
1310 transmitters | Output power | uw | 2090 | 2019 | 1741 | 1654 | |
Threshold current | mA | 4.7 | 5.2 | 5.1 | 5.2 | ||
Monitor current | uA | 165 | 181 | 164 | 168 | ||
Behaviour does voltage | v | 1.09 | 1.1 | 1.1 | 1.09 | ||
1550 receivers | Responsiveness | A/W | 0.94 | 0.93 | 0.98 | 0.92 | |
Responsiveness under the maximum Polarization Dependent Loss | A/W | 0.93 | 0.92 | 0.97 | 0.92 | ||
Polarization Dependent Loss | dB | =0.15 | =0.15 | =0.15 | =0.15 | ||
Isolation/1490nm | dB | 42 | 40 | 40 | 41 | ||
Isolation/1310nm | dB | 52 | 52 | 52 | 51 | ||
Return loss | dB | 46 | 47.2 | 45.8 | 47.5 | ||
Dark current | nA | 4.1 | 5.9 | 6.3 | 6.6 | ||
1490 receivers | Responsiveness | A/W | 1.01 | 0.99 | 1.03 | 0.93 | |
Responsiveness under the maximum Polarization Dependent Loss | A/W | 0.99 | 0.98 | 1.02 | 0.90 | ||
Polarization Dependent Loss | dB | =0.15 | =0.15 | =0.15 | =0.15 | ||
Isolation/1550nm | dB | 53 | 52 | 52 | 52 | ||
Isolation/1310nm | dB | 53 | 52 | 53 | 52 | ||
Return loss | dB | 45.1 | 40.3 | 38.4 | 38.3 | ||
Dark current | nA | 3.8 | 4 | 4.1 | 4.3 |
Through test, the wave splitting/composing device Polarization Dependent Loss of the present invention's development is less than 0.15dB as can be seen.The wave splitting/composing device also has high channel isolation, high responsiveness.
Claims (7)
1. a single fiber three-way wave splitting/composing device is provided with optical fiber interface (1), 1310 wave band sender interface (2), 1490 wave band receiver interfaces (3) and 1550 wave band receiver interfaces (4) on single fiber three-way wave splitting/composing device; 45 degree TTR optical filters (5) and 45 degree TRR optical filters (6) are installed between optical fiber interface (1) and 1310 wave band sender interface (2), 45 degree TTR optical filter (5) reflection directions are over against 1550 wave band receiver interfaces (4), and 45 degree TRR optical filter (6) reflection directions are over against 1490 wave band receiver interfaces (3); In 1490 wave band receiver interface (3) installed inside 0 degree RTR optical filter (7) is arranged, 0 degree RRT optical filter (8) is arranged, it is characterized in that the coating structure of described 45 degree TTR optical filters (5) is in 1550 wave band receiver interface (4) installed inside:
G (wall reflection horizon, half coupling layer reflection horizon half coupling layer)
sA,
Wherein G represents substrate, and A represents air, and s represents the plated film cycle.
2. single fiber three-way wave splitting/composing device according to claim 1 is characterized in that the concrete coating structure of described 45 degree TTR optical filters (5) is:
Anterior layer: G|2.65H 1.65L 1.28H 0.39L 0.8H 1.63L 1.55H 1.64L 0.31H L 1.62H0.5L (0.5LH4L0.5L) ^
310.39L 1.57H 0.9L 0.17H 1.86L 1.61H 2.17L 2.36H 2.08L0.44H 1.83L|A,
Back layer G|0.43L 2.88H 2.05L 3.12H 1.45L 0.74H 0.8L 1.27H 2.03L|A,
Wherein H represents high-index material, and L represents low-index material, the central wavelength lambda 0=986nm of coating structure design.
3. single fiber three-way wave splitting/composing device according to claim 2 is characterized in that the refractive index n of described high-index material
h=2.135, the refractive index n of low-index material
l=1.456.
4. single fiber three-way wave splitting/composing device according to claim 3 is characterized in that described high-index material is Ta2O5, and low refractive material is SiO2.
5. according to claim 1 or 2 or 3 or 4 described single fiber three-way wave splitting/composing devices, it is characterized in that the concrete coating structure of described 45 degree TRR optical filters (6) is:
Anterior layer: G|2H1.5L (2HL) ^
132H1.4L1.6H0.8L|A,
Back layer: G|0.4H1.6L|A,
Wherein H represents high-index material, and L represents low-index material, the central wavelength lambda of coating structure design
0=1130nm.
6. according to claim 1 or 2 or 3 or 4 described single fiber three-way wave splitting/composing devices, it is characterized in that the concrete coating structure of described 0 degree RTR optical filter (7) is:
Anterior layer:
G|H4LHLHLH2LHLHL(HLH4LHLHL)^
4HLH2LHLHLH4L0.636H0.703H|A
The back layer: G|H L|A,
Wherein H represents high-index material, and L represents low-index material, the central wavelength lambda of coating structure design
0=1460nm.
7. according to claim 1 or 2 or 3 or 4 described single fiber three-way wave splitting/composing devices, it is characterized in that the concrete coating structure of described 0 degree RRT optical filter (8) is:
Anterior layer: G|0.36H 1.18 L 1.16 H 1.21L (0.5H L 0.5 H) ^
22L H L 2H|A
Back layer: G|2H 2L H 3.5L|A
Wherein H represents high-index material, and L represents low-index material, the central wavelength lambda of coating structure design
0=1358nm.
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CNB2006100364003A CN100414333C (en) | 2006-07-07 | 2006-07-07 | A single fiber three-way wave separator/wave combination device |
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CNB2006100364003A CN100414333C (en) | 2006-07-07 | 2006-07-07 | A single fiber three-way wave separator/wave combination device |
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Cited By (5)
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CN102436044A (en) * | 2011-12-28 | 2012-05-02 | 武汉电信器件有限公司 | Plug type single-fiber three-way photoelectric component |
CN102854580A (en) * | 2011-07-28 | 2013-01-02 | 索尔思光电(成都)有限公司 | Apparatuses for reducing the sensitivity of an optical signal to polarization and methods of making and using the same |
CN104965268A (en) * | 2015-07-28 | 2015-10-07 | 福州宏旭科技有限公司 | Multi-wavelength optical transmit-receive module element |
WO2016127376A1 (en) * | 2015-02-12 | 2016-08-18 | Source Photonics (Chengdu) Co., Ltd. | Integrated lens with multiple optical structures and/or surfaces, optical module and transceiver including the same, and methods of making and using the same |
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US6091870A (en) * | 1998-02-20 | 2000-07-18 | Corning Incorporated | Wavelength division multiplexer/demultiplexer optical device |
CN2387549Y (en) * | 1999-06-18 | 2000-07-12 | 中国科学院上海技术物理研究所 | 8 micron long-wave filter |
JP2003043245A (en) * | 2001-07-31 | 2003-02-13 | Canon Inc | Optical filter |
CN1570688A (en) * | 2004-04-26 | 2005-01-26 | 武汉电信器件有限公司 | Single fiber three way photoelectric assembly |
CN2710258Y (en) * | 2004-06-10 | 2005-07-13 | 上海昂泰通讯技术有限公司 | Multi-function low-cost single-fibre three-phase component |
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CN102436044A (en) * | 2011-12-28 | 2012-05-02 | 武汉电信器件有限公司 | Plug type single-fiber three-way photoelectric component |
CN102436044B (en) * | 2011-12-28 | 2013-11-13 | 武汉电信器件有限公司 | Plug type single-fiber three-way photoelectric component |
WO2016127376A1 (en) * | 2015-02-12 | 2016-08-18 | Source Photonics (Chengdu) Co., Ltd. | Integrated lens with multiple optical structures and/or surfaces, optical module and transceiver including the same, and methods of making and using the same |
US9869818B2 (en) | 2015-02-12 | 2018-01-16 | Source Photonics (Chengdu) Co., Ltd. | Integrated lens with multiple optical structures and vent hole |
CN104965268A (en) * | 2015-07-28 | 2015-10-07 | 福州宏旭科技有限公司 | Multi-wavelength optical transmit-receive module element |
CN115166911A (en) * | 2021-04-01 | 2022-10-11 | 讯芸电子科技(中山)有限公司 | Transistor outline package optical transceiver |
US11616577B2 (en) | 2021-04-01 | 2023-03-28 | Shunyun Technology (Zhong Shan) Limited | Optical transceiver in transistor outline package |
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