CN205176327U - Novel integrated shimmer learn wavelength devision multiplex subassembly - Google Patents
Novel integrated shimmer learn wavelength devision multiplex subassembly Download PDFInfo
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- CN205176327U CN205176327U CN201520799171.5U CN201520799171U CN205176327U CN 205176327 U CN205176327 U CN 205176327U CN 201520799171 U CN201520799171 U CN 201520799171U CN 205176327 U CN205176327 U CN 205176327U
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Abstract
The utility model discloses a novel integrated shimmer learn wavelength devision multiplex subassembly, the subassembly includes new base plate, high reflection film, reflection reducing coating and light filter, high reflection film and reflection reducing coating have been plated to one of them side of new base plate, high reflection film sets up in the reflecting region, the reflection reducing coating sets up at the transmission area, it has the more than one filter plate to paste rather than relative another side, new base plate the width is (img file='dest_path_image002. TIF'wi='188'he='45' /), D is light outgoing interval, phi is the incident angle, N is new base plate refracting index, L' is new base plate width. Size design because of glass substrate leads to the pilot light to double by the reflection number of times in glass substrate. The reflected signal light that corresponds also can upgrade to 2 times by original 1 time at the light filter on the surface, requires down at same isolation, requires to decline to a great extent to the isolation of filter plate, and then the coating film cost of filter plate also can decline to a great extent, and the product volume nearly reduces half simultaneously.
Description
Technical field
The utility model discloses a kind of optical module, and particularly a kind of novel integrated micro-optical Interleave muiltiplexing component element, belongs to optical communication field.
Background technology
In 40G and 100G optical module, usually to carry out partial wave to the light of 2 roads or 4 road different wave lengths or close ripple, this wave splitting/composing assembly is built in optical module, little as far as possible to volume requirement, and optical property (as insertion loss, isolation etc.) also has high requirements simultaneously.The current Interleave muiltiplexing component element based on micro optical platform technology is the technical scheme of main flow, the basic structure of existing this kind of technical scheme is described below: please refer to accompanying drawing 1 to accompanying drawing 4, using glass substrate 1 as optical signal transmission carrier, a wherein side of glass substrate is coated with highly reflecting films 4(HR film respectively) and anti-reflection film 5(AR film), two optical filters are pasted in another side, first optical filter 2 and the second optical filter 3 difference selectivity are through the wavelength needed, and the light of other wavelength is reflected, the feature of this technical scheme is that optical filter only reflects a flashlight.
Light channel structure as shown in Figure 4, when light enters glass substrate 1 from left side AR film 5, transmits L0 light from the first optical filter 2, transmits L1 light from the second optical filter 3, thus realizes a point wave energy; Otherwise L0 light carries out light path by the first optical filter 2, L1 light carries out light path by the second optical filter 3, all penetrates from AR film 5 on the left of glass substrate 1 after this two-way light set, realizes closing wave energy.
The above-mentioned wave splitting/composing modular construction being a road light and being divided into two-way or two-way light compositing one tunnel, in conventional structure, also has the wave splitting/composing optical assembly on four tunnels, please refer to accompanying drawing 5, when light enters glass substrate 1 from left side AR film 5, L0 light is transmitted from the first optical filter 2, its remaining light is at the first optical filter 2 surface reflection meeting glass substrate 1, reflex to HR film 4 on the left of glass substrate 1 and carry out secondary reflection again, outgoing L1 light from the second optical filter 3, mode according to this, according to this outgoing L2 light and L3 light on the 3rd optical filter 7 and the 4th optical filter 8, thus realize a point wave energy; Otherwise, L0 light, L1 light, L2 light and L3 light can enter glass substrate 1 through the first optical filter 2, second optical filter 3, the 3rd optical filter 7 and the 4th optical filter 8 successively, and reflect in glass substrate 1 by HR film 4 on the left of glass substrate 1 and each optical filter, final all to penetrate from AR film 5 on the left of glass substrate 1 after four road light set, realize closing wave energy.
(1), the feature of this technical scheme is that optical filter only reflects a flashlight, therefore each road light signal just equals the corresponding light isolation of optical filter to the isolation of the light signal of adjacent wavelength;
(2), the width L of glass substrate 1 depends on the spacing d of the angle of light degree ¢ of glass substrate and two adjacent light (L0 and L1) of requirement, and glass substrate refractive index is n, glass tube substrate width
, suppose that angle of light degree ¢ adopts 8 degree, when the spacing d value of two adjacent light (L0 and L1) is 0.75mm, the width L of glass substrate 1 is about 4.05mm.
Summary of the invention
Lower for the above-mentioned wave splitting/composing assembly isolation performance of the prior art mentioned, the shortcoming that volume is larger, the utility model provides a kind of novel integrated micro-optical Interleave muiltiplexing component element, and its substrate adopting special size to design and optical filter, can effectively reduce its size.
The technical scheme that the utility model solves the employing of its technical matters is: a kind of novel integrated micro-optical Interleave muiltiplexing component element, this assembly comprises new substrate, highly reflecting films, anti-reflection film and optical filter, a wherein side of new substrate is coated with highly reflecting films and anti-reflection film, highly reflecting films are arranged on echo area, anti-reflection film is arranged on transmission area, another side is corresponding thereto pasted with more than one filter plate, and the width of new substrate is
, d is light outgoing spacing, and Φ is incident angle, and n is new substrate index, and L ' is new substrate width.
The technical scheme that the utility model solves the employing of its technical matters further comprises:
Described optical filter be a slice, two panels, three or four.
Described new substrate adopts glass material to make, or adopts the good material of other light transmissions to make.
Described from a highly reflecting films road light outgoing/incoming position farthest on the left of new substrate, adopt the glass sheet not plating filter coating system, or direct vacancy.
The beneficial effects of the utility model are: (1), because light beam realizes two secondary reflections on each optical filter, the light isolation of its adjacent two-beam can reach the twice of optical filter isolation, easily realizes the splitting/composing wave energy of high-isolation.Otherwise under same insulated degree requirement, decline to a great extent to the insulated degree requirement of optical filter, then the coating cost of optical filter also can decline to a great extent.(2), by light beam two secondary reflections on monolithic optical filter, when angle of light degree is identical with outgoing beam interval (centre distance of L0 and L1), the width L of glass substrate can reduce half, the volume differences of whole like this assembly seldom reduces half, easier in being integrated in optical module, this constructor converging module is to the needs of small-sized encapsulated future development.
Below in conjunction with the drawings and specific embodiments, the utility model is described further.
Accompanying drawing explanation
Fig. 1 is conventional wave splitting/composing assembly perspective view.
Fig. 2 is conventional wave splitting/composing assembly plan structure schematic diagram.
Fig. 3 is that structural representation faced by conventional wave splitting/composing assembly.
Fig. 4 is conventional wave splitting/composing assembly light channel structure schematic diagram.
Fig. 5 is the light channel structure schematic diagram of the wave splitting/composing assembly of conventional 4 road light.
Fig. 6 is perspective view of the present utility model.
Fig. 7 is plan structure schematic diagram of the present utility model.
Fig. 8 of the present utility modelly faces structural representation.
Fig. 9 is light channel structure schematic diagram of the present utility model.
Figure 10 is the perspective view of the utility model the second usage.
Figure 11 is the light channel structure schematic diagram of the utility model the second usage.
Figure 12 is the light channel structure schematic diagram of the wave splitting/composing assembly of the utility model 4 road light.
In figure, 1-substrate, 2-first optical filter, 3-second optical filter, 4-highly reflecting films, 5-anti-reflection film, the new substrate of 6-, 7-the 3rd optical filter, 8-the 4th optical filter.
Embodiment
The present embodiment is the utility model preferred implementation, and other its principles all are identical with the present embodiment or approximate with basic structure, all within the utility model protection domain.
The utility model is mainly 40G and 100G optical module and provides the micro-optic wave splitting/composing assembly that a kind of optical property is better, volume is less.Please refer to accompanying drawing 6 to accompanying drawing 9, the utility model mainly comprises new substrate 6, highly reflecting films 4, anti-reflection film 5, more than one optical filter 2, new substrate 6 adopts glass material to make, can be used as optical signal transmission carrier, during concrete enforcement, new substrate 6 also can adopt other materials with light transmission to make.A wherein side of new substrate 6 is coated with highly reflecting films 4 and anti-reflection film 5, in the present embodiment, highly reflecting films 4 and anti-reflection film 5 respectively account for only about half of area, during concrete enforcement, also can according to actual needs in design transmission area and echo area, arrange anti-reflection film 5 in transmission area, arrange highly reflecting films 4 in echo area, another side is corresponding thereto pasted with optical filter.In the present embodiment, the angle of light degree of new substrate 6 is 8 °.In the present embodiment, by design, when new substrate 6 angle of light degree ¢ and light outgoing spacing d remains unchanged, light is if desired made on optical filter, to realize two secondary reflections, according to formula
, d gets 0.75mm, and incident angle ¢ gets 8 degree, and glass substrate refractive index gets 1.5038, and glass substrate width L ' is reduced to about 2.02mm from original about 4.05mm, the size constancy of optical filter, thus realizes flashlight order of reflection in glass substrate and add one times.
Please refer to accompanying drawing 9, the utility model in use, light channel structure as shown in Figure 9, when light is from left side anti-reflection film 5(and AR film) enter after in new substrate 6, transmit L0 light from the first optical filter 2, the L0 light of L1 light and minute quantity reflexes to highly reflecting films 4(on the left of new substrate 6 and HR film) after, then be reflected back the first optical filter 2, now the L0 Transmission light of remnants will be gone out by the first optical filter 2 again, thus avoids L0 remaining light to form impact to L1 optical channel.Highly reflecting films 4(on the left of new substrate 6 and HR film is reflexed to through the first optical filter 2 second time) time, originally L0 and the L1 light only remaining L1 light of assembly was incident to, the highly reflecting films 4(of this L1 light on the left of new substrate 6 and HR film) after, transmit L1 light from the second optical filter 3, thus realize a point wave energy; Otherwise, then can realize closing wave energy.
Please refer in accompanying drawing 10 and accompanying drawing 11, figure is the utility model embodiment two structural representation, and relative accompanying drawing 6 to accompanying drawing 9, just eliminates the second optical filter 3.Its principle saved is, system needs just L0 and the L1 light of partial wave, L0 light has been filtered for twice by the first optical filter 2, and the light that therefore the first optical filter 2 second time reflects only is left L1 light, for this reason, the position of L1 light outgoing in accompanying drawing 9, second optical filter 3 just can not be installed, or directly replace, to reduce the production cost of product with a pure glass sheet, otherwise, then can realize closing wave energy.
Please refer to the light channel structure schematic diagram that accompanying drawing 12, Figure 12 is the wave splitting/composing assembly of the utility model 4 road light.When light is from left side anti-reflection film 5(and AR film) when entering new substrate 6, first time transmits the L0 light of the overwhelming majority from the first optical filter 2, remaining minute quantity L0 light and L1 light, L2 light, L3 light can be reflexed to highly reflecting films 4(on the left of new substrate 6 and HR film by the first optical filter 2) after, be reflected back the first optical filter 2 again, now the L0 Transmission light of remnants will be gone out by the first optical filter 2 again, thus avoids L0 remaining light to form impact to L1 optical channel.Its remaining light can new substrate 6 at the first optical filter 2 surface reflection, reflex to highly reflecting films 4(and HR film on the left of glass substrate 1) carry out secondary reflection again, outgoing L1 light from the second optical filter 3, mode according to this, according to this at superjacent air space outgoing L2 light and the L3 light of the 3rd optical filter 7 and the 3rd optical filter 7, thus realize a point wave energy; Otherwise, L0 light, L1 light, L2 light and L3 light can enter glass substrate 1 through the first optical filter 2, second optical filter 3, the 3rd optical filter 7 and the 4th optical filter 8 successively, and by highly reflecting films 4(on the left of glass substrate 1 and HR film) and each optical filter reflect in glass substrate 1, final after four road light set all from anti-reflection film 5(and AR film on the left of glass substrate 1) injection, realize closing wave energy.
Claims (3)
1. a novel integrated micro-optical Interleave muiltiplexing component element, it is characterized in that: described assembly comprises new substrate, highly reflecting films, anti-reflection film and optical filter, a wherein side of new substrate is coated with highly reflecting films and anti-reflection film, highly reflecting films are arranged on echo area, anti-reflection film is arranged on transmission area, another side is corresponding thereto pasted with more than one filter plate, and the width of new substrate is
d is light outgoing spacing, and Φ is incident angle, and n is new substrate index, and L ' is new substrate width.
2. novel integrated micro-optical Interleave muiltiplexing component element according to claim 1, is characterized in that: described optical filter be a slice, two panels, three or four.
3. novel integrated micro-optical Interleave muiltiplexing component element according to claim 1 and 2, is characterized in that: described new substrate adopts glass material to make, or adopts the good material of other light transmissions to make.
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Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN105158853A (en) * | 2015-10-16 | 2015-12-16 | 北极光电(深圳)有限公司 | Novel integrated micro-optical wavelength division multiplexing module, and method of multiplexing and demultiplexing by employing module |
CN108957612A (en) * | 2018-07-26 | 2018-12-07 | 北极光电(深圳)有限公司 | A kind of film filter component and preparation method thereof |
CN113960719A (en) * | 2021-10-26 | 2022-01-21 | 苏州众为光电有限公司 | Free space multiplex wavelength division multiplexing device and method of turning structure |
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2015
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Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN105158853A (en) * | 2015-10-16 | 2015-12-16 | 北极光电(深圳)有限公司 | Novel integrated micro-optical wavelength division multiplexing module, and method of multiplexing and demultiplexing by employing module |
CN105158853B (en) * | 2015-10-16 | 2018-08-24 | 北极光电(深圳)有限公司 | A kind of novel integrated micro-optical Interleave muiltiplexing component element and the partial wave using the component, multiplex method |
CN108957612A (en) * | 2018-07-26 | 2018-12-07 | 北极光电(深圳)有限公司 | A kind of film filter component and preparation method thereof |
CN113960719A (en) * | 2021-10-26 | 2022-01-21 | 苏州众为光电有限公司 | Free space multiplex wavelength division multiplexing device and method of turning structure |
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Denomination of utility model: Novel integrated micro-optical wavelength division multiplexing module, and method of multiplexing and demultiplexing by employing module Effective date of registration: 20170503 Granted publication date: 20160420 Pledgee: Shenzhen high tech investment and financing Company limited by guarantee Pledgor: Auxora (Shenzhen) Co., Ltd. Registration number: 2017990000371 |
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