TW581896B - Precision fiber ferrules - Google Patents

Precision fiber ferrules Download PDF

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Publication number
TW581896B
TW581896B TW91120101A TW91120101A TW581896B TW 581896 B TW581896 B TW 581896B TW 91120101 A TW91120101 A TW 91120101A TW 91120101 A TW91120101 A TW 91120101A TW 581896 B TW581896 B TW 581896B
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Taiwan
Prior art keywords
fiber
error
optical
ferrule
filter
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TW91120101A
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Chinese (zh)
Inventor
Marc Georges Brun
Scott Michael Hellman
Heinrich Gottfried-Otto Muller
Paul Andrew Townley-Smith
Michael Uschitsky
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Corning Inc
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Priority claimed from US09/945,314 external-priority patent/US6960026B2/en
Application filed by Corning Inc filed Critical Corning Inc
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Publication of TW581896B publication Critical patent/TW581896B/en

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Abstract

A multiple-port optical device uses improved fiber ferrules comprising various capillary designs and shapes to precisely position optical fibers and, in particular, the optical fiber cores. The fibers are screened for geometric characteristics which further aide in precisely positioning the fiber cores. The ferrules, capillaries, fibers, and adhesives are combined to reduce adverse thermal effects and maintain the position of the fibers over a broad range of environmental conditions in which DWDM packages and modules are required to operate.

Description

581896 五、發明說明(1) 發明背景: 1 ·發明領域 —^發明是關於光學通訊系統,特別是關於製造應用 足類、訊系統中之光學裝置的設備和方法。 2 ·技術背景 夕到三個端埠的濾波器和隔離包裝廣泛地使用在局 =通訊網路中。這些網路包含各種頻譜成‘ / 9 η $,丨9子且&作為密集波長區分多工系統的部分。這類 •^钟可年壽命期間,容易受到各種熱和機械負載的系統 二型學装置的需求是相當重要的。這類光學裝置 =ΓΛΛ學遽波器組件。典型的光學遽波器組件包 中以提二纖光學玻璃光纖被插入雙毛細管的套圈 器組件的ΐ i元:Λ組件:GRIN透鏡,*據波器。此渡波 、二;在典型的三端埠包裝中,上面的雙光 出準直組件結合變為單-光纖。這些遽 系統或模电敕;ζ'ί現比預期逛高的插入損耗,導致此通訊 動“ΐϊΐΓ效能的降低。此問題在曝露到周圍溫度變 勒的作業條件期間會顯得特別顯著。 』门因 .典型的輪入玻璃套圈應用兩種 使用的有適人田卡—人4里口又a的其中一種。已經 每條光繃璃光纖的單—毛细管或是 母條先纖具有分開的圓形毛細管,其中备—、目’飞= = (0.7-1.2毫米)的承受光纖之 種都具有相备 類輸入套圈氺她六& ^ μ门, 弓丨線端部。使用這 I圈,先纖在此短的圓錐形末端部分會產生一個弘581896 V. Description of the invention (1) Background of the invention: 1. Field of invention — The invention relates to optical communication systems, and in particular, to equipment and methods for manufacturing and applying optical devices in football and telecommunication systems. 2 · Technical background Filters and isolation packages with three port ports are widely used in communication networks. These networks contain a variety of spectrums as' / 9 η $, 丨 9 sub-amps and & as part of the dense wavelength distinguishing multiplexing system. During this type of clock life, the need for type 2 devices that are susceptible to various thermal and mechanical loads is important. This type of optical device = ΓΛΛ academic wave filter component. A typical optical chirped wave component package contains two optical fiber optical fibers that are inserted into a ferrule of a double-capillary ferrule. The element: a component: a GRIN lens, and a wave filter. This crossing wave, two; in a typical three-terminal port package, the above dual light output collimation assembly is combined into a single-fiber. These systems or modules have higher insertion loss than expected, leading to a decrease in the efficiency of this communication. This problem can be particularly significant during exposure to ambient operating conditions. Because of the typical application of the wheel-in glass ferrule, there are two types of suitable field cards-one of the 4th mouth and the other. The single-capillary or mother fiber of each optical fiber has separate Circular capillaries, in which the type of fiber that can withstand the fiber— = '(0.7-1.2 mm) with fiber-optic input ferrules have corresponding input ferrules, such as gates and bow ends. Use this I Loop, the first fiber will produce a hong at this short conical end

第6頁 581896 五、發明說明(2) 彎曲,其在大約6到10倍直徑長度的間距上該末端部分通常 超過光纖直徑的50%(對於直徑為125微米的光纖)。此過多 的微彎曲會增加插入損耗。雖然跟橢圓的單一毛細管設計 作較起來,多毛細管設計可以降低光纖互連的橫向偏移,但 是這類套圈的短長度圓錐形末端無法降低光纖的微彎曲和 它固有的插入損耗。應用這類套圈的光纖—套圈次组件是 由底下的步驟製造出:將剝掉主要塗層的光纖插入各別的 套圈毛細官中,用環氧樹脂將光纖黏附到包含圓錐形末端 部分的套圈毛細管中;在光纖—套圈上研磨並磨成一個角度 之截面;並且在此磨光表面上沉積一層抗反射塗層。一旦 完成之後,此光纖-套圈會被對準並且跟準直⑽^透鏡组一合 在一起,然後被嵌入隔離玻璃空心管中,接下來由金屬外殼 來保護。 上兩個不同的技術方案用於固定光學組合之元件的接合 ϊ ΐ亡二ί ίΞ匹配的玻璃光纖和玻璃套圈之間低順應 Q疋二'^以d所普遍使用的方式。所使用的粘合劑是 含有高Young 模數(E> 1〇〇 〇〇〇 · w > (βη 1η_6/〇ολ U,UUU PS1)以及中到而熱膨脹係數 (cn〜40_60xl0 / C)白ί]u·· 0…、固化%乳樹脂。典型的範例是 353 ND EP0-TEK環氧榭炉杜人切 ,t w疋 虱鲥月曰拈a劑。此外,所使用的接合厚 度非常小。 矽粘合劑被用來接合熱^ 殼,以及玻璃光學元件和+屬±加 ▲ l ^ m ^ 1干和金屬支架。在這些接合中栋用离 順應的設計。這些矽# p ° π七叫m π甘,’械树月曰在濕度存在下可以在20-150 C之間固化’其 '一般的胜Μ: 0 □必,,, 特丨生疋相§低的Y〇ung模數(E<5〇〇Page 6 581896 V. Description of the invention (2) Bend, the end portion of which is usually more than 50% of the fiber diameter at a pitch of about 6 to 10 times the diameter length (for a fiber of 125 microns in diameter). This excessive microbend increases insertion loss. Although compared with the elliptical single capillary design, the multi-capillary design can reduce the lateral offset of the fiber interconnect, but the short-length conical end of this type of ferrule cannot reduce the microbending of the fiber and its inherent insertion loss. Fibers using this type of ferrule—The ferrule subassembly is manufactured by the following steps: insert the fiber with the primary coating stripped into the respective ferrule capillaries, and use epoxy to attach the fiber to the end containing the cone Part of the ferrule capillary; Grind and grind the fiber-ferrule into an angular section; and deposit an anti-reflective coating on the polished surface. Once completed, the fiber-ferrule will be aligned and combined with the collimating lens assembly, and then embedded in an insulating glass hollow tube, which is then protected by a metal housing. The above two different technical solutions are used for the bonding of the components of the fixed optical combination. Ϊ 二 二 二 Ξ Low matching between the matched glass fiber and the glass ferrule. The adhesive used contains a high Young's modulus (E > 100000 · w > (βη 1η_6 / 〇ολ U, UUU PS1) and a medium to high thermal expansion coefficient (cn ~ 40_60xl0 / C) white ί] u ·· 0, curing% milk resin. A typical example is 353 ND EP0-TEK epoxy resin furnace, and tw 疋 疋 鲥 拈 鲥 a agent. In addition, the thickness of the joint used is very small. Silicon adhesive is used to join the thermal ^ case, as well as the glass optics and + gen + plus ▲ l ^ m ^ 1 dry and metal brackets. In these joints, a compliant design is used. These silicon # p ° π 七It's called m πgan, and it can be cured between 20-150 C in the presence of humidity. Its general victory is: 0 □ Must ,,, Special § Low Yung modulus (E < 5〇〇

581896 五、發明說明(3) __ PSi),和高的熱膨脹係數(α=18〇 為支架和GRIN透鏡。 至屬先孥濾波 电件ΐ:ϊ ϊ ί以及接下來的銲接或焊接被用來將滹” :卜封成密集波長區分多工模組的三端蟑包c ii 在遽波器初始組合期間所達到的精準對準了, 這些元件最終包裝期間銲接或焊接所上二 物質之間熱收縮的不匹西己在j人中丄低“由於玻璃和金屬 學元件上所造成力接所引起的結構限制而在光 件產生幾個問胃。這些;力口;生的元 , 0. 3 ,π ΛΓΛ Λ? ^ # ^ ^φ6ί,]8" -^^ 耗時的對準Μ這些誤差需要精準的加工, J立丁平,以及經常重做的怛垃。 士 , 旎的規定被降低而使成本增加 ::光學效 器頻譜效能的移動。使用這類4先子7°件再疋位和慮波 解焊:和/或助焊劑的直接接二二於, 然而對於作夕戍印+上、 、取尤子凡件的巧'染。 具有低插入損I二:s : ^為了獲得相當便宜可靠並且 的。此外以,的;\準;1度熱補償光學多端琿包裝是必要 卜,匕破攻计應該不只適合用來機械式地保護易碎581896 V. Description of the invention (3) __ PSi), and high thermal expansion coefficient (α = 180) is the bracket and GRIN lens. It belongs to the first filter element ΐ: ϊ ϊ ί and the subsequent welding or welding is used滹 ”: Sealed into a three-terminal cockroach package with dense wavelength-division multiplexing module c ii The precise alignment achieved during the initial assembly of the oscillator, these components are soldered or welded between the two substances during the final packaging The heat-shrinkable non-dimethicone was lowered in the "J people" due to the structural constraints caused by the force connection on the glass and metal elements, there were several problems in the light parts. These; force mouth; raw yuan, 0 3, π ΛΓΛ Λ? ^ # ^ ^ Φ6ί,] 8 "-^^ Time-consuming alignment errors These errors require precise processing, J Li Dingping, and often repeated redo. 怛, 旎 regulations Reduced and increased cost :: the shift of the spectral efficiency of the optical effector. Using this type of 4 first 7 ° pieces, then positioning and wave desoldering: and / or direct connection of the flux, but for the evening戍 印 + 上 、 , 取 取 子 凡 的 巧巧 染。 Have a low insertion loss I two: s: ^ In order to obtain equivalent Cheap and reliable. In addition, the; \ quasi; 1 degree thermal compensation optical multi-terminal 珲 packaging is necessary. ,, dagger attack should not only be suitable for mechanically protecting fragile

兔明說明(4) 立 :光m而且也要補償並降低熱所引起的頻” 1 $^需要的,因為它們可以進一牛2土,例如六端痒包 =可以產生降低的插入損進耗。步因降 可靠之長時間運作二置作起來很便宜,而且可以產生 發明大要: 本發明提供具有低插人招 學濾波器組件),並且利用接人人:進$學組件(例如光 元件例如輸入套圈,準直透鏡°和;::某種方式提供光學 各別元件相對於彼此精確地對;;及=合;此方式將 沒有達到=可能。到目前為止還 波器支架,可以允許經由紫外線广:门改進的輸入套圈和濾 主動對準並接合;以及改進的=^固化粘合劑的使用以 之次組件中的相關内應力。對;'大大降低如此形成 本發明一方面提供了光纏鲞 粘合劑固化,銲接焊接釦严p為叹计了以抵杬先纖在 技術使用塾圈以= 平疋位毛細官中的光纖。本發明另一 581896 五、發明說明(5) 項是根據幾何特性你| & γ β Θ、 IB Μ) ^ ^ ^ η 外(包覆層)直徑,包覆層的圓度(橢 圓度八和〜焱同心度 Μ又、仰 如何匹配光纖之門沾、擇先4。本發明的另一項揭示出 的關係。所槎供0 、S隔距離,以及跟光學濾波器入射角 jmr隔距離的誤差,使得含有五,六,或更 加時,光學對而準/Λ的Λ業製造變得可能。當埠的數目增 方法用來處理此%^曰變得更重要而複雜,因此本發明提供 二 此更硬雜的對準。本發明亦提供選擇輸出準 、,:施本發明的方法包括底下的步驟:將濾波 濾波益主動地對準到安裝有GRIN,非球面,或^他準木〇 的準直器組件;將濾、波器支架和透鏡軸向地分隔在可移動 :對於此遽波器支架對準,同時監視;透2;: t 輸入和”訊號,使得插入損耗小於大約"透二之= 由濾波為支架的濾波器末端施加紫、,2 、、-工 化此對準的次組件。在本發明的-個實= 經ΐϊίϊΐ”化程序進行熱固化,接著為高溫之二 在本發明另一貫施例中,將紫外線輻射經 器支架與透鏡重疊之側邊上的一或多個孔施/成在j慮波 ,透鏡介面上。此紫外線光源可以被震:得;外:支 射均句地投射於渡波器支架和透鏡外表面間“= 。在本發明又另-實施例中,經由監視光 yi 訊號,同時調整X]位置以得到最大的檢測訊號輸在Tu Ming explained (4) Li: light m but also to compensate and reduce the frequency caused by heat "1 $ ^ required, because they can enter a cow and two soils, such as six-terminal itch bag = can reduce the insertion loss of the loss The step-by-step operation is cheap and reliable because it can be installed for a long time, and it can produce the main points of the invention: The present invention provides a low-insertion recruitment filter module), and uses access: to learn components (such as light Components such as input ferrules, collimating lenses, and :: some way to provide precise pairs of optical individual elements with respect to each other; and = combined; this way will not reach = possible. So far wave holders, Wide range of ultraviolet rays can be allowed: Active input ferrules and filters are actively aligned and joined by the door; and improved internal stresses in the assembly are followed by the use of improved curing adhesives. Right; 'Significantly reduced so formed the present invention On the one hand, it provides the curing of the optical entangled adhesive, and the tightness of the welding p is a measure of the optical fiber used in the technical use of the loop to = the flat capillary capillary. Another 581896 of the present invention Note (5) term is root Geometric characteristics you | & γ β Θ, IB Μ) ^ ^ ^ η Outer (cladding layer) diameter, roundness of the cladding layer (ellipse eight and ~ 焱 concentricity M, how to match the fiber door stain First, choose 4. The relationship revealed by another aspect of the present invention. The error of the distance between 0 and S, and the distance from the incident angle jmr of the optical filter, makes it contain five, six, or more. And quasi / Λ manufacturing becomes possible. As the number of ports increases, the method used to deal with this% ^ becomes more important and complicated, so the present invention provides two more difficult alignments. The present invention also provides options. Output calibration: The method of the present invention includes the following steps: actively aligning the filtering filter to a collimator assembly equipped with a GRIN, aspheric surface, or other collimator; aligning the filter, waver bracket, and The lens is axially separated at the movable: for this wave holder bracket alignment, simultaneous monitoring; through 2: t input and "signal, so that the insertion loss is less than about " through two = the end of the filter from filtering to the bracket Apply purple, 2 ,,,-to chemically align this subassembly. In the present invention- Gesture = heat curing through the 化 ίϊΐ "process, followed by high temperature. In another embodiment of the present invention, one or more holes on the side of the side where the ultraviolet ray holder overlaps with the lens are applied / formed at j. Consider the wave, the lens interface. This ultraviolet light source can be shaken: get; outside: the projection is projected between the bracket and the outer surface of the lens "=. In another embodiment of the present invention, the monitoring light yi Signal, adjust X] position at the same time to get the maximum detection signal.

第10頁 581896 五、發明說明(6) 合劑之前將濾波器和透鏡預先對準。 在本發明優先製造方法中,在紫外線固化處理之後經 由在40-50。(:下2到4小時的應力釋放周期,接下來經由大約 9 5到1 1 0 C下1到2小時的熱固化周期以固化此組件。 在本發明的實施例中,所應用的輸入套圈含有軸向長 度大於大約2 · 5毫米的輸入圓錐體以降低輸入光纖的S-彎 曲,如此來降低所產生的插入損耗。在本發明的另一個實 轭,中,、一^般為圓柱體的濾波器支架一端具有環狀基座以 承受濾波器;而相對端部具有透鏡承受孔徑,其内部尺寸允 許濾波器支架相對於透鏡作微小傾斜,此濾波器支架被提 供此遽波器跟透鏡中心轴之對準角度為小於大約i度。此 ,,,之濾波器支架的橫向表面上包含細槽或開口,使得 明:二進入而固化透鏡和濾波器支架之間的粘合劑。 本务月之一個優先實施例的光學組 和/或遽波器支架,彼此對準轉合在適合的;改進套圈 =裡所描述的方法和裝置可 置的製造而產生幾個得赴^ L丄μ 丨口夕細坪光學裝 兩對光纖的六端在輸入準直組件中含有 束,如此可以降低和兩個透射光 殼單元。如此,例如相π &丄&:心/裔,準直透鏡,和外 併串級多個埠包裝之密集波長區分多工'以用於合 工運作中。一個典型的密集波長區分多工模组:和解多 六端埠包裝。在此情況下滹 準古、乐〇 3到8個 「,德疫杰日日片,準直透鏡,和光纖Page 10 581896 V. Description of the invention (6) Align the filter and lens in advance before mixing. In the preferred manufacturing method of the present invention, it is 40-50 after the ultraviolet curing treatment. (: 2 to 4 hours of stress relief cycle, followed by a thermal curing cycle of about 1 to 2 hours at about 95 to 110 ° C to cure this component. In the embodiment of the present invention, the input sleeve applied The ring contains an input cone with an axial length greater than about 2.5 mm to reduce the S-bend of the input fiber, thus reducing the insertion loss. In another solid yoke of the present invention, the 、 and ^ are generally cylindrical The filter holder of the body has a ring base at one end to support the filter; and the opposite end has a lens bearing aperture. Its internal size allows the filter holder to be slightly tilted relative to the lens. This filter holder is provided with this waver The alignment angle of the central axis of the lens is less than approximately i degrees. Therefore, the lateral surface of the filter holder includes a slot or an opening, so that the two enter and solidify the adhesive between the lens and the filter holder. An optical group and / or an oscillating wave holder of a preferred embodiment of this month, aligned with each other and turned in a suitable one; improved methods and devices described in Ferrule = can be made to produce a few ^ L 丄 μ The six ends of the two pairs of optical fibers of Kou Xiping contain a beam in the input collimation assembly, which can reduce the two transmitted light shell units. In this way, for example, phase π & 丄 &: heart / yellow, collimating lens, Intensive wavelength division multiplexing of multiple port packages in parallel with the outside is used for joint operation. A typical dense wavelength division multiplexing module: reconciling multiple six-terminal port packaging. In this case, Zungu,乐 〇3 ~ 8 ", German epidemic day, collimating lens, and optical fiber

HIM· 五、發明說明(7) 套圈的數目’跟使用三端埠包裝相比較可以降低一半。 &的:^本人發明的製造方法和光學元件組合提供改進1 其,曝的輪入套圈,滤波器支架,= 、且口 /以提供提供低成本,高可靠性和改進效< 光學元件組合,例如二被殖進古、占 . 把之 加h j ★一》而埠丰直濾波器或六端埠準直嗆★ 器組件,以及將這也組厶佬用.叮mτ组2 且4波 < 一、、且口便用在可用於光學通訊糸统的@ 集波長區分多工模組中。 凡的谂 ^ ^明的裝置可應用於使用在密集波長區分多工# 的早模光纖;以及使用在以晶體為主之隔離器,循琿” 偏極分裂器,及其類似物中的保持偏極光纖。 本發明的其他特色及優點將會在底下的詳細描一 明。對於那些熟悉此技術的人,將可以從此敘述中或况 據底:的詳細說明,"專利範圍及附圖所描述的本乂 以做貫際操作而清楚地了解到這些特色及優點。 必須要明白的是,前面的描述只是本發明的範例,是用 二為在申請專利範圍中所定義之本發明的本質及特色提供 全盤的了解。附圖是用來對本發明提供更進一步的了解,、 在此併入而且構成了此份說明書的一部分。這些附圖說 月了本發明的各種特性和實施例,加上對它們的描述共同 來解釋本發明的原理及運作。 洋細說明: )^ $百先參考圖1和圖2,最先呈現的是光學元件(如濾波器 事人組件1 〇的簡要說明。本項發明利用一個三端埠濾波器 、置作為範例來描述及說明,然而本發明也可運用到諸如 581896 五、發明說明(8) 六端埠裝置的多端埠裝置。以多端埠裝置來說,套圈丨6中 光纖的個數和位置也要據此而改變。雙光纖準直及濾波器 次組件1 〇包括外部圓柱形的金屬外殼1 2,其分別地接合於 圖1輸入及反射光纖1 8和2 0附近的位置1 3。外殼1 2包圍隔 離的圓柱形硼矽酸鹽或熔融矽石套管1 4 (圖2 ),在這裡安裝 雙毛細管套圈16以承受輸入光纖18和反射光纖2〇。套圈16 中的光纖1 8和2 0末端面對準直透鏡2 2,譬如像是在輸入端 具有光滑面的GRIN透鏡,如圖2所示,面對並對準固定在套 圈16的光纖18和20末端。透鏡22將來自輸入光纖18的光線 準直成平行的光束,傳輸至一個光學元件,該元件可以是薄 膜濾波器,雙折射晶體,或其它合適的光學元件。最接近濾 波器24的準直透鏡22末端被稱為準直透鏡22的輸出端。依 據本發明的方法,濾波器器支架2 6安裝在準直透鏡2 2的末 端2 1上包括軸向孔徑2 7以允許光線從透鏡2 2投射在濾波器 2 4上,並引導反射光線至反射光纖2 〇。濾波器支架2 6也保 護延伸在濾波器2 4和透鏡2 2之間的孔徑2 7和準直透鏡2 2對 準的渡波器或晶體2 4。光纖套圈1 6,透鏡2 2和隔離套管1 4 一起被稱為輸入準直組件3 5。準直組件3 5也可以包括圓柱 形的金屬外殼1 2。類似單一光纖準直組件結構一起被稱為 輸出準直組件35’,其顯示於圖3。 在描述形成整個三端埠濾波器一部份的次組件丨〇的製 造之前,簡短地描述三端埠濾波器3 〇。圖3也是代表一多端 璋裝置,然而以多端埠装置來說,套圈16和39中的光纖個數 和位置也要據此而改變。如圖3所示,三端埠濾波器3 〇包括HIM · 5. Description of the invention (7) The number of ferrules can be reduced by half compared with the use of three-terminal port packaging. &: ^ The combination of the manufacturing method and the optical element invented by me provides an improvement. The exposed ring-in ferrule, the filter holder, =, and the opening / to provide low cost, high reliability and improved efficiency < optical Component combination, such as two colonies in ancient times, accounting. Add hj ★ one "and port Feng straight filter or six-terminal port collimation unit ★, and also use this group of guys. Ding mτ group 2 and 4-Wave < First, and easy-to-use is used in the @ set wavelength division multiplexing module that can be used in optical communication systems. Every device can be applied to the use of early-mode fiber that distinguishes multiplexed # at dense wavelengths; and it can be used in crystal-based isolators, recirculating "polar splitters, and the like. Polarized fiber. Other features and advantages of the present invention will be described in detail below. For those who are familiar with this technology, it will be from this description or the basis: detailed description, " patent scope and drawings The described book clearly understands these features and advantages through interoperability. It must be understood that the foregoing description is only an example of the present invention, and is used for the invention defined in the scope of the patent application. The nature and characteristics provide a comprehensive understanding. The drawings are used to provide a further understanding of the present invention, are incorporated herein and constitute a part of this specification. These drawings illustrate various features and embodiments of the present invention, plus The above descriptions together explain the principle and operation of the present invention. Western detailed description:) ^ $ 100 first refer to Figure 1 and Figure 2, the first presented is an optical element (such as the filter personnel component 1 Brief description of this invention. This invention uses a three-terminal port filter and device as an example to describe and explain, but the invention can also be applied to multi-terminal port devices such as 581896 V. Invention Description (8) Six-terminal port device. For the port device, the number and position of the optical fibers in the ferrule 6 should also be changed accordingly. The dual-fiber collimation and filter subassembly 1 10 includes an outer cylindrical metal housing 12 which is respectively joined in the figure 1 Input and reflective fiber positions 1 near 8 and 2 0 1 3. Housing 1 2 encloses an isolated cylindrical borosilicate or fused silica sleeve 1 4 (Figure 2), where a double capillary ferrule 16 is installed to The input fiber 18 and the reflective fiber 20 are supported. The ends of the optical fibers 18 and 20 in the ferrule 16 are aligned with the straight lens 22, such as a GRIN lens with a smooth surface at the input end, as shown in FIG. Align and align the ends of the optical fibers 18 and 20 fixed on the ferrule 16. The lens 22 collimates the light from the input optical fiber 18 into a parallel beam and transmits it to an optical element, which can be a thin film filter, a birefringent crystal, Or other suitable optical components. Most connected The end of the collimator lens 22 near the filter 24 is referred to as the output end of the collimator lens 22. According to the method of the present invention, the filter holder 26 is mounted on the end 21 of the collimator lens 2 2 and includes an axial aperture 2 7 to allow light to be projected from the lens 2 2 onto the filter 2 4 and guide the reflected light to the reflective fiber 2 0. The filter holder 2 6 also protects the aperture 2 7 and 7 extending between the filter 2 4 and the lens 2 2. The collimator lens 2 2 is aligned with the wave finder or crystal 2 4. The fiber ferrule 16, the lens 2 2 and the isolation tube 1 4 are collectively referred to as the input collimation component 3 5. The collimation component 3 5 may also include a cylinder The shape of the metal housing 12 is similar to the structure of a single fiber collimation assembly, which is called an output collimation assembly 35 ', which is shown in FIG. Before describing the fabrication of the sub-modules that form part of the entire three-terminal port filter, the three-terminal port filter 3 is briefly described. Figure 3 also represents a multi-port 璋 device. However, for multi-port devices, the number and position of the optical fibers in the ferrules 16 and 39 must be changed accordingly. As shown in FIG. 3, the three-terminal filter 3 includes:

第13頁 刈 1896 五、發明說明(9) 外部圓柱形的金屬套管32,次組件1〇安裝於此 如圖3示意圖的銲接逵接、,精著運用在 ^人+接連接點的銲接和/或焊接材皙Ή沾m ^ 3; Π ί保護。銲接和/或銲接材質31可以經由:屬套: 酸鹽或熔㈣石玻璃套㈣之内保護的對Τ圍直; 介面在外保護套管32的内部安裝此金屬套管37。 套圈39,玻璃套管36和金屬套管37形成輸出準^組件、兄 。輸出光纖38從三端埠濾波器30到安裝三端埠濾波哭 3〇的通訊連結,耦合所要的波長輸出訊號。因此,譬〜如說π可 運用二端埠濾波器3〇從輸入光纖丨8接收多個波長,傳遞單 一輸出波長至輸出光纖38,然後回傳其餘的訊號波長至反 射光纖20。組合次組件及其結構元件的方法是獨特的以 下將詳細描述。更進一步,在金屬套管32之内對準輸出準 直組件3 5的特定方法也會在底下描述。 曰和先鈾技術的套圈有關的問題以圖4來說明,圖4所示 =先前技術輸入套圈40的垂直斷面示意圖。套圈4〇是由像 疋熔融矽石或硼矽酸鹽玻璃的傳統玻璃材質製成,包括一 對刀隔開的毛細管4 2和4 4,有足夠的直徑以承受直徑約1 2 5 U米裸露的輸入和反射光纖1 8和2 〇。然而光纖丨8和2 〇整個 直徑包括一層保護用的聚合物的包層,因此直徑大約是2 5〇 Μ米。光纖1 8和2 0在先前技術的套圈4 〇之圓錐形輸入區段 4 6内利用熱固化環氧樹脂粘合劑黏接,其提供玻璃套圈内 塗層光纖1 8和2 0應變釋除之連結。當裸露的光纖丨8和2 〇離Page 13 刈 1896 V. Description of the invention (9) The outer cylindrical metal sleeve 32, the subassembly 10 is installed here as shown in the welding joint shown in Fig. 3, and it is used in the welding of the connection point of the person + joint. And / or welding contamination ^ 3; Π ί protection. The welding and / or welding material 31 can be protected by: metal sleeve: acid salt or fused vermiculite glass sleeve. The metal sleeve 37 is installed inside the outer protective sleeve 32 on the interface. The ferrule 39, the glass sleeve 36 and the metal sleeve 37 form an output quasi-component, brother. The output fiber 38 couples the desired wavelength output signal from the three-terminal filter 30 to the communication link where the three-terminal filter 30 is installed. Therefore, for example, π can use a two-terminal port filter 30 to receive multiple wavelengths from the input fiber 8 and pass a single output wavelength to the output fiber 38, and then return the remaining signal wavelengths to the reflection fiber 20. The method of combining subassemblies and their structural elements is unique and will be described in detail below. Furthermore, a specific method of aligning the output collimation assembly 35 within the metal sleeve 32 will be described below. The problems related to the ferrule of the prior uranium technology are illustrated in FIG. 4. FIG. 4 is a schematic vertical sectional view of the input ferrule 40 of the prior art. Ferrule 40 is made of traditional glass materials such as fused silica or borosilicate glass, and includes a pair of capillary tubes 4 2 and 4 4 separated by a knife. It has a sufficient diameter to withstand a diameter of about 1 2 5 U. M. Bare input and reflective fibers 18 and 20. However, the entire diameter of the optical fibers 8 and 20 includes a protective polymer cladding, so the diameter is approximately 250 m. The optical fibers 18 and 20 are bonded in the conical input section 46 of the ferrule 40 of the prior art with a thermosetting epoxy adhesive, which provides a glass ferrule coated optical fiber 18 and 20 strain. Release link. When the bare fiber

第14頁Page 14

581896 五、發明說明(10) 4。的光纖二;::的在區域47處彎曲。交互連結至套圈 ^ m V致光纖超過光纖直徑50%的偏移。^ μ581896 V. Description of invention (10) 4. Optical fiber II; ::: is bent at area 47. Interconnecting to the ferrule ^ m V causes the fiber to shift by more than 50% of the fiber diameter. ^ μ

V = : = :由於套圈4°的幾何特性增加了施= 延鏡“上矾號的插入損耗。 4中先套十圈片的太毛、細官42和44如圖4A所示,以距離D1隔開,圖 和產生别插入套紅圈提供的圓錐長度導致光纖過多的微彎曲 受邻、斤沾上Γ 另一個套圈結構提供橢圓的毛細管以承 問i為了、: ί ί類似的輸入圓錐結構所遭遇更多彎曲的 中ΐ=,二發:,用一種改進的套圈16,形成蒙 件1 0的部份,並在圖5和5 Α中說明。 超過2 Λ5!’:入套圈具有軸向長度在較佳的實施範例中 ΪΓ入圓=輸:圓錐體17,優先⑴ 大:2倍的長度。輸入圓錐體17的輸入直徑D2 5 0 0/以谷納輸入光纖1 8和反射光纖20組合的直徑 鄰近用、^ ΐ邊有空間讓環氧樹脂接合圓錐體17内的光纖。 Λ和保護其内的光纖18和2°的毛細管19和21的 回錐體17,其出口直徑D3最好決定為: D3 = 2 fd + D1 或 D3 = 2 50//m + Dl ,裡=fd是移除包層材質的光纖直徑。 皂半=I谷納任何光纖和每個裸露的輸入和反射光纖1 2 5 直U的隔開距離Dl,也允許在輸人至毛細管19和21V =: =: Due to the geometrical characteristics of the ferrule at 4 °, the insertion loss of the cast iron is increased. The ten hairs, fine features 42 and 44 of the first set of ten turns are shown in Figure 4A. The distance D1 is separated, and the cone length provided by the red circle of the inserted ferrule leads to excessive microbending of the optical fiber, and it is attached to Γ. Another ferrule structure provides an elliptical capillary in order to: ί similar The input cone structure encountered more curved middle ΐ =, second round :, using a modified ferrule 16, forming part of the mask 10, and illustrated in Figures 5 and 5 Α. Over 2 Λ5! ': The ferrule has an axial length. In the preferred embodiment, ΪΓcircle = loss: cone 17, priority ⑴ large: 2 times the length. Input diameter of the cone 17 D2 5 0 0 / input optical fiber with a trough The diameter of the combination of the 8 and the reflective fiber 20 is adjacent, and there is space on the side for the epoxy resin to join the fiber in the cone 17. Λ and the cone 17 that protects the fiber 18 and the 2 ° capillary 19 and 21 inside it , Its exit diameter D3 is best determined as: D3 = 2 fd + D1 or D3 = 2 50 // m + Dl, where = fd is the fiber diameter from which the cladding material is removed = I is satisfied that half soap any input fiber and each of the exposed optical fibers 125 and reflected straight U spaced distance Dl, also allows the input to the capillary 19 and 21

第15頁 581896 五、發明說明(π) -- 處約一耄米的間隙,好讓環氧樹脂保護位於套圈丨6内的輸 入和反射光纖。二種重要的特性和理想的誤差是丨2 5毫米 ± 〇·2毫米的外包覆層直徑,低於〇·2%的包覆層非圓度/和 低於0· 2毫米的心蕊對包覆層同心性。藉由擴大圓錐體i 7 的軸向長度L到幾近先前技術輸入套圈的兩倍就可真正避 /免S形彎曲以提供輸入和反射光纖真正近乎相等的光學路 乜長度,並減低插入相耗。這種技術也可運用在有超過兩 條光纖的套圈和具有一個或多個毛細管的套圈。 套圈1 6内的光纖施用環氧樹脂粘合劑後在約丨丨〇下 固化一個半小時,所用的環氧樹脂粘合劑可以是Ep〇xy Technology, Billerica, MassachuseUs 公司的 353 腳 EPO-TEK環氧樹脂粘合劑。優先地以125 —13(pc的溫度後固 化此組合半個小時以減少水分吸收。用來插入和接合光纖 白^套圈末端面28被研磨並磨光以產生與套圈中心軸約為8 度角的橢圓面。套圈16然後在圍繞熱隔離玻璃套管14(見 圖2)内黏結,形成輸入準直組件35。在插入套圈16至套管 μ之前,μ置並固定好透鏡22。套圈先與透鏡22端和套 圈間約1到1.5毫米的間隙G對準,藉著旋轉套管“之内的套 圈並軸向定位以放置透鏡22在約為7. 8度到8· i度範圍的表 面角度而允許套圈軸向和旋轉的主動對準。對於三端埠組 件來說,施加訊號至輸入光纖18,並監控套管14之^^^透 鏡的輸出。對於多端埠組件來說,譬如用在六端埠裝置對 準過程是類似的,然而訊號施加於每一輸入光纖,套圈是軸 向和旋轉定位以使所有訊號的對準最佳化。這樣一來不但Page 15 581896 V. Description of the invention (π)-A gap of about one meter is allowed for the epoxy resin to protect the input and reflective fibers located in the ferrule 6. Two important characteristics and ideal errors are 25 mm ± 0.2 mm outer cladding diameter, less than 0.2% cladding non-roundness / and stamen less than 0.2 mm Concentricity to the cladding. By enlarging the axial length L of the cone i 7 to almost twice the input ferrule of the prior art, S-bends can be truly avoided / avoided to provide a truly nearly equal optical path length of the input and reflective fibers and reduce insertion Phase consumption. This technique can also be applied to ferrules with more than two fibers and ferrules with one or more capillaries. The optical fiber in the ferrule 16 is cured for about one and a half hours with epoxy resin applied. The epoxy resin used may be Epox Technology, Billerica, MassachuseUs' 353-pin EPO- TEK epoxy adhesive. This combination is preferably cured at a temperature of 125-13 (pc) for half an hour to reduce moisture absorption. The end face 28 for inserting and joining the optical fiber ^ ferrule end surface 28 is ground and polished to produce about 8 with the central axis of the ferrule Angled elliptical surface. The ferrule 16 is then glued around the thermally insulated glass sleeve 14 (see Figure 2) to form the input collimation assembly 35. Before inserting the ferrule 16 into the sleeve μ, μ sets and secures the lens 8 度 The ferrule is first aligned with the gap G between the end of the lens 22 and the ferrule about 1 to 1.5 mm, by rotating the ferrule "within the ferrule and positioned axially to place the lens 22 at about 7.8 degrees A surface angle in the range of 8.5 degrees allows active alignment of the ferrule axially and rotationally. For a three-terminal port assembly, a signal is applied to the input fiber 18 and the output of the lens 14 of the sleeve 14 is monitored. For multi-port components, for example, the alignment process for a six-port device is similar, but the signal is applied to each input fiber, and the ferrule is axially and rotationally positioned to optimize the alignment of all signals. Not only

581896 五、發明說明(12) 入Λ耗和光纖與輸入準直透鏡22間極大的信 描=接者承^波器支架以及在其中之濾、波器,如 現在茶考圖6,接下來描述濾波器24 位至透鏡22的末端21。匹配遽波器24的入射角: ===重要的。在組㈣中選== :二角準直組件的套,具有 量,優先地在〇,5毫=,二 入準直組件35上。用在六端瑝驻罢aa y 在ι疋的輸 τ,, ^ Λ ;〇 τ4 # ^^ 與滤波器的人射角相匹配。1'/;;#/纖的分隔距離 構誤差時,第二對光纖自動產田生滿對足準上之=細管#錢的結 纖的分隔距離大致相等是报重要 义因此母對光 隔距離誤差是在0.5毫米疋Λ重要我的們//地每對光纖的分 進-步討論誤差。 ^將在以下的圖14和^ 在透如二6^波Λ支架26的下端具有圓柱形的孔徑25 τ m r, ^ t, ^ ^ f' F":G1 ° ^ " 確對準滤波器24和透鏡22,並容έ用,22的微傾斜以精 到透鏡22的接合枯合劑。支^用/保護濾、波器支架 由―Η不錢鋼製成的單元。在組 第17頁 581896 五、發明說明(13) 透鏡2 2之則,濾波器2 4安裝在具有圓柱形孔徑2 g的濾波器 支架26之内,基座50的角度1傾斜(圖6)約1 5度到2度,優先 地約1 · 8度以容納在典型的濾波器晶片24的前後表面間約 〇·3度到0·7度角度的誤差。基座5〇的傾斜在降低支架26相 對鏡22的傾斜角度有很好的效果。濾波器24利用傳統 的環氧树知或甚至石夕有機樹脂結合粘合劑,諸如% 5 7 7或 CV3 20 0 0之類保護在圓柱形孔徑29之内,濾波器晶片24可 以是任何商用薄膜濾波器。譬如在這說明的實施範例中, 所,用的商用濾波器大小是丨· 4乘4乘丨· 5毫米。這種濾 波器商業上可由Corning Incorporated公司供應。本發明 的組合和方法也可使用其他光學裝置,諸如各種^晶體X為 主的元件取代濾波器2 4。 濾波器2 4置於濾波器支架2 6上,支架夾緊在垂直(見圖 6)可移動的夾具上,其也可以旋轉而可移進移出和透鏡22 接t,並且旋轉和傾斜以主動對準濾波器的光軸和透鏡22 的橫向表面來減低插入損耗。主動對準是指在對準光學元 件的過程,運用輸入光線訊號至裝置同時監控輸出訊號。 而相對的被動對準是指在對準光學元件的過程中並 光線訊號。 本發明的實施範例中,藉著使用約1 530奈米的訊號至 輸入光纖18(圖1-3),而同時監控光纖20上的反射訊號〜以達 動對準。濾波器支架26然後以垂直方向為傾斜/也根 小‘控輸入和反射訊號,以2度到5增量加以旋轉以達到最 夕的插入損耗。濾波器支架26可相對於透鏡22自由地轉動 五、發明說明(14) 6旋度韓。這些包括圖6的xz平面和XY平面上的微傾斜,繞著z軸 =轉,沿著X和Υ軸橫向移動,沿著Ζ軸升高和降低支芊。通 吊只有沿著ΧΖ和ΥΖ平面上的旋轉和微傾斜足以對準元件。 ,佳的實施範例使用自動重複過程,監控每次傾斜或 日守每對S、纖的插入損耗。重複過程不停地言周整遽波器 =t監控輸入輸出訊號,最後根據預定的誤差定位最佳 =^位置。在多料系統中,增加越多^纖 ΓΛ程^Λ度。對㈣較佳方式包括個㈣準每對光 蟑/晉=t對準位置或中數位置的步驟。對於六端 日對準方式是當對準第二對反射和輸入光纖 明實和Λ入光纖可以稍稍向下。由於依據本發 頦#、>·二1 =疋、块差,在六端埠裝置的情況下,我們也發 ί日?Λ常短(即很少次重複)。當第-對光纖光學對 對域和第—對域具有4的分隔距離, 可料m過,士中:透鏡22和套管12架設在傳統結構的χγζ 一;旦決:了 d。撐支架26的空腔25中的透鏡22投射端。 器;s轴:l :支架26和透鏡22最佳的角度位置,濾波 接觸到透鏡2°2的^:!^依:維持角度關係)以能夠 和:梭卞,丨—A — * 板刀隔時優先地用四滴或以上的接合 末端21的外圓周表面上,同時要注意 鏡22上降低^ 3 m到透^末端的表面。然後在透 空間内的黏接劑了。去空腔25和透鏡22之間環形 接耆,孤控運用在輸入和反射光纖丨8和 581896 五、發明說明(15) 號步調整架上的0轴以確保最少的插 入相耗。同樣地,也可以在監控訊號以達 =過約0.3dB最少的插入損耗時,調整架上的ΥΖ軸我們 ==各Λ熱固_匕環氧樹脂,結果認為商用_卜⑷〇 丄率最'疋一種Breckenridge,c〇l〇rad“ie ! 劑。 勺务外線和熱固化充填黏接 藉著提供遽波器支㈣的圓柱形孔徑25的 鏡22的外直徑之間糊毫米的間隙, 透 ==和遽波器24的光學中心轴對準。二 加以調整使角2少於約U度,如圖6所示。5 用軚準的槭疋位器,藉著移動以和以平面上的透鏡22可以 ==濾波器支架26的主動對準。在本項發明的一 Η貝用—個或多個紫外線光源,諸如光源60 輻射,以充分固化接合黏接劑,固定住透鏡w 的關係,持續到黏接劑最後真正固化。 4波抑24間 如圖7的示意圖所示,從光源6〇投射紫外線輻射至 益24的暴露端,紫外線輻射(標示為63)隨著紫外線軤射^ 至黏接劑層55(圖6)而擴散,由於紫外線傳: 濾波裔而導致黏接劑的前端聚合。在很多範例中 广0:八由濾、波器24的紫外線輻射63,在光源和濾波器Μ間 固距Λ暴露約20秒將會導致黏接劑充分的固化而 疋濾波為支罙和透鏡。除了利用紫外線光源60經由濾波581896 V. Description of the invention (12) The maximum signal between the input λ loss and the optical fiber and the input collimator lens 22 = the receiver support wave filter bracket and the filter and wave filter in it, as shown in Figure 6 of the tea, next Describe the filter 24 bits to the end 21 of the lens 22. Matching the angle of incidence of the chirped waver 24: === important. In the group 选 ==: the set of two-angle collimation components, with a quantity, preferably at 0.5 mm, the two-in-one collimation components 35. Used at the six-terminal 瑝 aaa y in ι 疋 's loss τ ,, ^ Λ; 〇 τ4 # ^^ matches the angle of incidence of the filter. 1 '/ ;; # / fiber separation distance structure error, the second pair of optical fiber automatically produces a full pair of pairs = thin tube # money knot fiber separation distance is approximately equal, so the mother to the optical separation The distance error is important at 0.5mm 疋 Λ // ground for each pair of fiber-to-step discussion errors. ^ Will have a cylindrical aperture 25 τ mr, ^ t, ^ ^ f 'F ": G1 ° ^ " at the lower end of the transparent stent 26 in Figure 14 and ^ 24 and the lens 22 are used together, and the slight incline of 22 is fine to the bonding mixture of the lens 22. Support / protection filter, waver bracket Unit made of steel. On page 17, 581896 V. Description of the invention (13) Lens 2 2 The filter 2 4 is installed in a filter holder 26 with a cylindrical aperture 2 g, and the angle 1 of the base 50 is inclined (Figure 6) About 15 degrees to 2 degrees, preferably about 1.8 degrees to accommodate an error of about 0.3 degrees to 0.7 degrees between the front and rear surfaces of a typical filter wafer 24. The inclination of the base 50 has a good effect in reducing the inclination angle of the bracket 26 relative to the mirror 22. The filter 24 utilizes a conventional epoxy resin or even Shixi organic resin bonding adhesive, such as% 5 7 7 or CV3 2 0 0, which is protected within the cylindrical aperture 29. The filter wafer 24 can be any commercial Thin film filter. For example, in the illustrated embodiment, the size of a commercial filter used is 4 × 4 × 5 mm. Such filters are commercially available from Corning Incorporated. The combination and method of the present invention can also use other optical devices such as various crystal X-based elements instead of the filters 24. The filter 24 is placed on the filter holder 26. The holder is clamped on a movable fixture that is vertical (see Figure 6). It can also be rotated to move in and out and connect the lens 22 to t, and rotate and tilt to take the initiative The optical axis of the filter and the lateral surface of the lens 22 are aligned to reduce insertion loss. Active alignment refers to the process of aligning optical components by using input light signals to the device while monitoring output signals. The relative passive alignment refers to the ray signal in the process of aligning the optical components. In the embodiment of the present invention, by using a signal of about 1 530 nanometers to the input optical fiber 18 (FIGS. 1-3), the reflected signal on the optical fiber 20 is simultaneously monitored to achieve alignment. The filter holder 26 is then tilted / reduced with the vertical control input and reflected signal and rotated in 2 to 5 increments to achieve the latest insertion loss. The filter holder 26 can rotate freely with respect to the lens 22. V. Description of the invention (14) 6-degree rotation. These include the slight inclination on the xz plane and the XY plane of Fig. 6, around the z-axis = rotation, moving laterally along the X and Υ axes, and raising and lowering the support 芊 along the Z-axis. Only the rotation and slight tilt along the XZ and YZ planes of the suspension are sufficient to align the components. The best implementation example uses an automatic repeat process to monitor the insertion loss of each pair of S and fiber for each tilt or day watch. The repeating process keeps saying that the whole wave filter = t monitors the input and output signals, and finally locates the best = ^ position according to a predetermined error. In a multi-feed system, the more ^ fibers ΓΛprocess ^ Λ degrees are added. The preferred method of confrontation includes the steps of collimating each pair of light cocks or calibrating positions or the median position. For the six-terminal solar alignment method, when aligning the second pair of reflective and input fibers, the clear and Λ-in fibers can be slightly downward. According to this issue 颏 #, > · 2 1 = 疋, block is poor, in the case of a six-terminal port device, we also ίday? Λ is often short (i.e., rarely repeated). When the pair-pair optical fiber pair pair domain and the pair-pair domain have a separation distance of 4, it can be expected that the lens 22 and the sleeve 12 are erected at χγζ of the traditional structure; once determined: d. The projection end of the lens 22 in the cavity 25 of the support bracket 26. S-axis: l: The optimal angular position of the bracket 26 and the lens 22, the filter contacts the lens 2 ° 2 ^:! ^ By: maintaining the angular relationship) to be able to: Shuttle, 丨 —A — * 刀 刀At regular intervals, four or more drops are preferably used to join the outer peripheral surface of the end 21, and at the same time, it is necessary to pay attention to the surface of the mirror 22 that is reduced by 3 m to the end of the end. Then the adhesive is in the transparent space. The ring connection between the cavity 25 and the lens 22 is used, and the solitary control is applied to the input and reflection fibers. 8 and 581896 V. Description of the invention (15) The 0 axis on the step adjustment frame to ensure the minimum insertion phase consumption. Similarly, we can also monitor the signal to reach the minimum insertion loss of about 0.3dB, the ΥZ axis on the adjustment frame we == each Λ thermosetting epoxy resin, the result is that the commercial_bu⑷〇 丄 rate is the most 'A Breckenridge, coradar'ie! Agent. A gap of millimeters between the outer diameter of the external line of the spoon and the heat-cured filling bond by the cylindrical diameter 25 of the cylindrical aperture 25 providing the support of the wave filter, Transparency == is aligned with the optical central axis of the oscillating wave device 24. Second, adjust it so that the angle 2 is less than about U degrees, as shown in Figure 6. 5 Use a standard maple positioner to move the plane to and from the plane. The lens 22 on the top can be actively aligned with the filter holder 26. One or more ultraviolet light sources, such as the light source 60, are radiated in the present invention to fully cure the bonding adhesive and fix the lens w The relationship lasts until the adhesive is finally cured. As shown in the schematic diagram of Fig. 7, the 4 wave suppression rooms 24 project the ultraviolet radiation from the light source 60 to the exposed end of the benefit 24, and the ultraviolet radiation (labeled 63) follows the ultraviolet radiation. It spreads to the adhesive layer 55 (Fig. 6) and diffuses. Due to the transmission of ultraviolet rays: the filter leads to adhesion. The front-end polymerization of the adhesive. In many examples, the ultraviolet radiation 63 of the filter 0 and the wave filter 24, and the exposure of the fixed distance Λ between the light source and the filter M for about 20 seconds will cause the adhesive to fully cure and 疋The filter is a support and a lens. In addition to using the ultraviolet light source 60 through the filter

第20頁Page 20

581896 五、發明說明(16) 器24暴露黏接劑55之外,也可利用匕 導紫外線輻射63經由濾波器支架26 一紫/卜線光源61以引 的上環形表面之間的間隙G 2作紫外綠下缞形端部和套管1 2 鐘的40秒暴露,以固化濾波器支架2r輻射總暴露約1〇〇秒 中的黏接劑。在紫外線固化之後,备I螭間隙G1環形區域 常約20 0到3 0 〇psi或更高的應力,熱 人組件中所導致通 供的固化將在底下說明。然而在這應力的釋放和所提 入和輸出訊號以確保反射插入損耗二化之前,要監控輸 插入損耗的熱改變也在約〇· 〇5 dB以、在低於約0· 3dB,而 外線可以在後續的暴露中沿著次組。光n發出的紫 ,可循著形成濾波器支架22側邊的】J :傳紫外線 底下的說明。 曰及開口而傳达,如 如圖8顯示紫外線光源60和61具有頻譜 里 銀燈光源的頻譜。圖9顯示試驗性定‘:择,:水 +从啫、士 口口 〇 a α丄 丨,开疋该先源經過圖6所 =的^波為24所使用大滤波器晶片 < 紫外、線透射頻譜。這 嫉$拉入成 兄切数里的系外線頻譜經由濾波器24傳 播至接a層’以及紫外線固化週期產生從63〇秒到7〇〇秒週 ?之插入損耗近乎零的改變。由於聚合作用之收縮,紫外 線初始的固化所導致起始應力。就典型有效收縮體積(〇·2 %的等級)的咼填充環氧樹脂黏接劑而言,所導致應力可能 高達300到600psi。因紫外線固化所導致,可用來固定滹波 器和準直透鏡22對準的應力被減輕,於次組件丨〇的熱固化 期間進一步固化接合黏接劑55,在傳統的爐内控制以提供 如圖1 0所示的應力釋除和熱固化循環。 581896581896 V. Description of the invention (16) In addition to exposing the adhesive 55 to the device 24, the ultraviolet radiation 63 can also be used to guide the ultraviolet radiation 63 through the filter holder 26 and the purple / bull light source 61 to guide the gap G2 between the upper annular surfaces. The UV green mandrel-shaped end and the sleeve were exposed for 40 seconds for 12 seconds to cure the adhesive of the filter holder 2r for a total exposure of about 100 seconds. After UV curing, the annular area of the gap G1 is usually about 20 to 300 psi or higher stress, and the curing caused by the heating in the module will be explained below. However, before this stress is released and the input and output signals are raised to ensure that the reflected insertion loss is reduced, the thermal change of the input insertion loss to be monitored is also about 0.5 dB, below about 0.3 dB, and the outside line Subgroups can be followed in subsequent exposures. The purple emitted by the light n can follow the formation of the side of the filter holder 22] J: the description of the transmission of ultraviolet rays. In short, it is conveyed, for example, as shown in FIG. 8, the ultraviolet light sources 60 and 61 have the spectrum of the silver light source. FIG. 9 shows the experimental determination of ': selection,: water + from 啫, Shikoukou 〇a α 丄 丨, opening the source through the ^ wave shown in FIG. 6 = 24 large filter chip used < UV, Linear transmission spectrum. The external spectrum of the line drawn into the tangent number is transmitted to the layer A through the filter 24 and the ultraviolet curing cycle produces a change in insertion loss of approximately zero from 630 seconds to 7000 seconds. Due to the shrinkage of the polymerization, the initial curing of the UV rays causes the initial stress. For rhenium-filled epoxy adhesives with typical effective shrinkage volumes (grades of 0.2%), the resulting stress can be as high as 300 to 600 psi. Due to the UV curing, the stress that can be used to fix the alignment of the wave filter and the collimator lens 22 is reduced, and the bonding adhesive 55 is further cured during the thermal curing of the subassembly, which is controlled in a traditional furnace to provide, for example, The stress relief and thermal curing cycles shown in Figure 10. 581896

k圖1 曲線圖顯示在烘箱中加速以及熱輔助應力釋除狀 悲,该狀悲加以控制以提供數個短的熱循環,其所在提高溫 度優先地並不超過熱固化最小溫度之50%。’周期通常是3由1 室溫開始,溫度增加在約4 〇 °c和6 〇 °c間之循環,每小時是j 〇 到1 5循環,總期間大約一個半小時到4小時。熱循環將導致 在玻璃,金屬濾波器支架,和黏接劑内不匹配的應力。雖然 黏接劑中應力釋放的速率會隨著不匹配應力的增加而增加 ,這種應力值受限於允許的彈性限制值。這些溫度循環變 化導致黏接劑的潛變特性而造成額外加速之應力釋除。如 圖1 〇所示,藉著溫度的循環一般丨2到24小時的室溫無照射 固化,小到約1到2小時。在這種情形下,任何光學元件(如 濾波器)的熱所導致再定位是可徹底減少的。 如圖ίο所示,在熱輔助應力釋除(TASR,Thermally Assisted Stress Relaxation)階段之後,使用較佳的 EMI — 3 41 0。黏接劑的情況,組件受制於最後的熱固化在約8 5。〇到 1 0 0 C的溫度約二到二個半小時。利用圖丨〇所示的熱固化 循環,提升溫度將導致熱不匹配的應力以及現存的收縮應 力。當合併應力低於黏接劑材質同步的彈性限制時,在接 合中$發生不可逆的變形地之加速的應力釋除。這種效應 會隨著熱固化循環的TASR起始階段的熱循環數目增加而改 雖然利用彖外線光源6 0引導輻射6 3通過濾波器2 3提供 濾波器支架和準直透鏡間黏接劑接合所需的起始紫外線固 化,如圖11和12所示,也可修改濾波器支架以提供額外的徑The graph in Figure 1 shows acceleration and thermally-assisted stress relief in the oven, which is controlled to provide several short thermal cycles where the elevated temperature preferably does not exceed 50% of the minimum thermal curing temperature. The cycle is usually 3 cycles starting from 1 room temperature, and the temperature increases between about 40 ° C and 60 ° C. The cycle is from j0 to 15 cycles per hour, and the total period is about one and a half hours to 4 hours. Thermal cycling will cause mismatched stresses in glass, metal filter holders, and adhesives. Although the rate of stress release in the adhesive increases with increasing mismatched stress, this stress value is limited by the allowable elastic limit. These temperature cycling changes cause the adhesive's creep properties to cause additional accelerated stress relief. As shown in Figure 10, the cycle by temperature is generally 2 to 24 hours without curing at room temperature, as small as about 1 to 2 hours. In this case, the repositioning caused by the heat of any optical element (such as a filter) can be completely reduced. As shown in Fig. Ο, after a thermally assisted stress relaxation (TASR) phase, a better EMI is used-3 410. In the case of adhesives, the components are subject to a final heat cure at about 8-5. The temperature of 0 to 100 C is about two to two and a half hours. Utilizing the thermal curing cycle shown in Figure 丨 〇, increasing the temperature will cause thermally mismatched stresses and existing shrinkage stresses. When the combined stress is below the synchronous elastic limit of the adhesive material, irreversible deformation and accelerated stress release occur during the joining. This effect will change as the number of thermal cycles in the initial stage of the TASR of the thermal curing cycle increases. Although the external light source 6 is used to guide the radiation 6 3 through the filter 2 3 to provide an adhesive bond between the filter holder and the collimating lens Required initial UV curing, as shown in Figures 11 and 12, filter holders can also be modified to provide additional diameter

五、發明說明(18) __ 向暴露端埠以暴露在 以改善通過玻璃接合圖6)的紫外線輻射 如圖! !所示,戶斤顯的±紫外線輕射之色散。 ^^γ,,:^^6,\ ί26^-« 杈以,來調整濾波器支力木 ^猎著其下方圓柱形孔 方端部包括多個孔經链然而據波器支架26,的下 7〇分隔於濾波器支架:;:向:二伸徑向地向内凸出細槽 :】-,互通。我:發 ;=:,安如裝/^ 範例的…高透鏡貫及 波器2“然而光源61^;.=,器支架26’内的滤 外線輻射到界定為向下支木26’架的周圍,引導紫 隔的支架72將使紫外線r 一細槽7〇,這些細槽間之分 板以進一步在含接人對=射尚頻振動至透鏡22圓柱形的壁 線輕射。藉Ϊ;Ϊ;=的環形空間内均勾擴散紫外 延伸至遽波向延伸加長的細槽7〇,或其它 高光線路徑作為紫外線幸二:知壁 '合適形狀的孔徑,而提 杈形孔徑25’ 。在一項每曰 承受透鏡22末端的内部圓 份㈣度間隔的四個中提/遽波器支㈣’下方部 照射,使黏接劑5 5的紫外線;^致/改進的均勾紫外線 不需要利用光源60通過濾读哭/侍奋易。在這實施例中 合黏接劑是利用光源61的麵二二,射,合黏接劍,因為接 —旦次組件]〇完成,就會曰 t勻照射。如圖1 2所示, 傳、為方式組合至合成的三端埠 581896V. Description of the invention (18) __ To expose the port to expose to improve the ultraviolet radiation through the glass junction (Figure 6). !! As shown, the dispersion of the ± UV light emission shown by households. ^^ γ ,,: ^^ 6, \ ί26 ^-«To adjust the filter support force ^ hunting the cylindrical hole below the square end includes multiple holes through the chain, but according to the bottom of the wave holder 26, 7 〇Separated from the filter holder:;: to: two extensions protruding radially inwardly from the thin groove:]-, intercommunication. I: 发; = :, Anruqi / ^ Example of ... High lens penetrating wave device 2 "However, the light source 61 ^;. =, The filter outer line in the device bracket 26 'radiates to the 26' frame defined as the downward branch Around, the bracket 72 that guides the purple septum will make the ultraviolet rays r a small groove 70, and the sub-plates between these small grooves will be further shot at the wall line that contains the vibration of the pair of lenses and the frequency of vibration to the cylindrical shape of the lens 22. Borrow Ϊ; Ϊ; = Annular space in the annular space is diffused to extend the ultraviolet rays to the narrow grooves 70 extending in the direction of the chirped wave, or other high light paths are used as ultraviolet rays. Fortunately, the wall has a proper shape of the aperture, and a branch-shaped aperture of 25 ' .Illuminate the lower part of the four middle lift / wave waver brackets that each receive the inner circle of the end of the lens 22, and make the ultraviolet rays of the adhesive 5 5; There is no need to use the light source 60 to read and cry through the filter. In this embodiment, the bonding agent is to use the face of the light source 61 to shoot and bond the sword, because the connection is done once. It will illuminate evenly at t. As shown in Fig. 12, it is combined to the synthesized three-terminal port 581896 by way of transmission.

五、發明說明 (19)V. Description of Invention (19)

濾波器包裝3 0, 以上的說明通常適用的光學裝置範圍為三端 :車裝置或更多端埠裝置。製造光學裝置的困難度隨著光: 和端埠數目的增加而增加。底下的討論是本項發 個或以上光學端埠的一些特性。 本發明實施範例有許多的五個,六個或以上光學埠的 使用和應用。例如,可能多端埠薄膜濾波器,分裂器^循環 器和隔離器的設備包括··由一條光纖和四條光纖套圈組合 形成的六端埠裝置,由二條四光纖套圈組合形成的八璋^ 置,和由一個光纖套圈組合和四光纖套圈組合形成的五端 埠裝置。 多端埠裝置一個重要的特性是光纖套圈1 6中光纖位置 的誤差度。光纖的心爲直控只有約9 · 5毫米。所以光纖位 置1毫米的移位或誤差可能導致不可接受的插入損耗。因 此必須很注意確保光纖定位的總誤差度。為了達到此誤差 度,應該預選光纖以提供心蕊同心度優先地在約1 · 0毫米的 誤差度之内,更優先地約0 · 5毫米的誤差度,最優先地約〇 · 1 毫米的誤差度;而橢圓度誤差優先地低於約〇 · 8%,更優先地 約〇 · 4%,最優先地約0 · 1 2%。同心度是指光纖心蕊的中心和 光纖的中心的偏差度。橢圓度定義為光纖最大和最小直徑 的差除以光纖的平均直徑,亦即(D1 -D2) *2>/(Dl+D2)。為 了 一種或以上的這些特性而預先篩選光纖產生了意想不到 的結果,所提供的組合以一種在商業應用上可靠重複製造 的方式組合和對準光纖和其他組件之零件。在實現這意想The filter package is 30. The above description usually applies to three-terminal optical devices: car devices or more port devices. The difficulty of making optical devices increases with the number of light: and ports. The discussion below is about some of the features of this or more optical ports. The embodiments of the present invention have many uses and applications of five, six or more optical ports. For example, the equipment of multi-port thin film filters, splitters, circulators and isolators may include a six-terminal port device formed by a combination of one optical fiber and four fiber ferrules, and an eight-port device formed by a combination of two four fiber ferrules ^ And a five-terminal port device formed by one fiber ferrule combination and four fiber ferrule combinations. An important characteristic of a multi-port device is the error in the position of the fiber in the fiber ferrule 16. The heart of the fiber is only about 9.5 mm for direct control. So a 1 mm shift or error in fiber position can cause unacceptable insertion loss. Care must therefore be taken to ensure the total degree of error in fiber positioning. In order to achieve this degree of error, the fiber should be pre-selected to provide a concentricity of the core that is preferably within an error of about 1.0 mm, more preferably an error of about 0.5 mm, and most preferably about 0.1 mm The degree of error; and the ellipticity error is preferably lower than about 0.8%, more preferably about 0.4%, and most preferably about 0.1%. Concentricity refers to the deviation between the center of the fiber core and the center of the fiber. Ovality is defined as the difference between the maximum and minimum diameters of the fiber divided by the average diameter of the fiber, which is (D1-D2) * 2> / (Dl + D2). Pre-screening optical fibers for one or more of these characteristics yielded unexpected results, and the combinations provided provided the ability to combine and align optical fiber and other component parts in a manner that is reliably reproducible for commercial applications. Realizing this idea

第24頁 581896 五、發明說明(20) --------- :”結果之前’並沒有大於三個端埠的商業用光學包裝, 更〉又有商業用之六端埠包裝。至於套圈毛細管誤差产 :單的方形毛細管套圈在兩平行邊之間的距離,毛細-管輸 +出^的誤差優先地是252毫米± 2毫米,更優先地是251毫米 :未,最優先地是250毫米± 0.5毫米。其它毛細管形狀 和设備優先地也是類似的誤差度。更者,在整個製造,包裝 和設備必須遭遇的環境條件下,必須維持光纖位置的誤差、 。達到此誤差度的方法和設備是本項發明的主題,其將 底下討論。 ’ a 雖然一些先前技術的裝置在開始時可以達到光纖位 所需要的誤差度,但當裝置受制於應力,張力和環境條件而 導致光纖移位到超過誤差度,這些技術就失敗了。這些應 力的產生原因包括:1)有關光纖黏接劑的黏滯性流動,1)1 合光纖和套圈的黏接劑固化,3)由於最終包裝操作或環产 測試條件的熱應力。在製造期間,裝置受制於例如來【= 用銲接包裹保護金屬套管32内的裝置所產生的熱。在 時裝置遭遇外界環境條件,以及必須維持在_4〇艺到85 理溫度下運作(工業標準溫度範圍)。因而,本項發明的、一σ 個特性疋關於滿足前述誤差度的四光纖套圈。 套圈通常是具有,二,三或多毛細管以承受光纖的 形硼矽酸鹽或熔融矽石組件。在前面的圖2和3中,我們 論了套圈1 6,然而六端埠裝置的毛細管優先地是不同的°。' 抽拉毛細管的形狀和顯示的製造技巧可讓光纖不只對疒°八 隔套圈的中央軸,還可適當地加以引導以及加以限制。4這77Page 24 581896 V. Description of the invention (20) ---------: "Before the result", there were no commercial optical packages with more than three port ports, and there were also six-port port packages for commercial use. As for the ferrule capillary error production: the distance between a single square capillary ferrule between two parallel sides, the error of capillary-tube output + output ^ is preferably 252 mm ± 2 mm, and more preferably 251 mm: not, most It is preferentially 250 mm ± 0.5 mm. Other capillary shapes and equipment are also preferably similar in error. Furthermore, under the environmental conditions that the entire manufacturing, packaging and equipment must encounter, the error in the position of the fiber must be maintained. The method and equipment of the degree of error are the subject of this invention and will be discussed below. 'A Although some prior art devices can achieve the degree of error required for the fiber position at the beginning, when the device is subject to stress, tension and environmental conditions As a result, the fiber shifted beyond the tolerance, and these techniques failed. The causes of these stresses include: 1) the viscous flow of the fiber optic adhesive, 1) the curing of the fiber optic and ferrule adhesive 3) Due to the thermal stress of the final packaging operation or environmental test conditions. During manufacturing, the device is subjected to heat generated by, for example, [= using a welded package to protect the device inside the metal sleeve 32. At that time the device encountered external environmental conditions , And must be maintained at -40 ° to 85 ° C (industrial standard temperature range). Therefore, a σ characteristic of this invention is about a four-fiber ferrule that satisfies the aforementioned degree of error. Ferrules usually have , Two, three or more capillaries to support fiber-shaped borosilicate or fused silica components. In the previous Figures 2 and 3, we discussed the ferrule 16, however the capillaries of the six-port device are preferentially different °. 'The shape of the drawn capillaries and the manufacturing techniques shown allow the fiber to not only guide the central axis of the 八 ° eight spacers, but also to properly guide and limit them. 4 This 77

第25頁 581896 五、發明說明(21) 將使黏接劑流動以及兩對輸入和反射光纖間之分隔距離熱 引起的變化所導致之再定位減為最低。毛細管提供在套圈、 和光纖接合内精準的平行定位,因而使光纖產生可靠性的 限制。優先地是光纖碰觸最近鄰的光纖,或光纖間具有不 超過約0· 5毫米的間隙。這將幫助固定光纖的位置。'優先 地在光纖進入套圈以減少應力和/或光纖重定位之前,在前 1 〇到1 5微米處不要互相纏繞。一個說明的組合過程包括^ 列步驟。光纖被剝離保護塗層並清潔長約5公分的光纖端 部。光纖浸入黏接劑,譬如Epo —Tek 35 3 ND。剝離的光^ j部,然後放入毛細管,直到光纖塗層剛到達套圈的圓錐形 端的部份。如需要的情況下,光纖可使用額外的黏接劑,黏 合劑可通達整個毛細管。可使用例如353 ND的黏接劑,’其^ 室溫下的黏滯性約3 〇 〇 〇 cPs (厘泊),或其他適合的黏接劑 。毛細管中顯示的預估間隙相對應於該黏滯性。如果間隙 猶大,可使用更高黏性的黏接劑(5〇〇〇。當在 毛、、、田言内插入光纖時,溫度的增加會減少黏接劑的黏性。 因此具有不同的黏滯性和溫度,我們可提供光纖較佳的定 位和大幅減少其在固化後的重定位。通常,適合的黏滯性 I以利用Hagen-P〇iseui丨le方程式模擬毛細管内黏滯性 流動以及毛細管内定位的光纖來決定。 、、組合固化後,以一個8度角度磨光套圈,並且塗覆抗反 射塗層。光纖和周圍套圈間的連接層非常的薄(優先地少 於約1 -1 · 5耄米),以減少熱應力和移動。本項發明套圈毛 細官的各式實施範例在圖丨3A到1 3H和1 4A到1 4E中說明。Page 25 581896 V. Description of the invention (21) Minimize the relocation caused by the change in heat caused by the adhesive flow and the separation distance between the two pairs of input and reflective fibers. Capillary tubes provide precise parallel positioning within the ferrule, and fiber splice, thus limiting the reliability of the fiber. It is preferable that the optical fiber touches the nearest-neighbor optical fiber, or there is a gap of not more than about 0.5 mm between the optical fibers. This will help secure the position of the fiber. 'Preferably do not entangle each other at the first 10 to 15 microns before the fiber enters the ferrule to reduce stress and / or fiber relocation. A illustrated combination process includes ^ steps. The fiber was stripped of the protective coating and the end of the fiber was cleaned about 5 cm in length. The fiber is dipped in an adhesive such as Epo-Tek 35 3 ND. The stripped light ^ j is then placed in the capillary until the fiber coating has just reached the conical end of the ferrule. If needed, the fiber can use additional adhesives that can reach the entire capillary. An adhesive such as 353 ND may be used, its viscosity at room temperature is about 3,000 cPs (centipoise), or other suitable adhesive. The estimated gap shown in the capillary corresponds to this viscosity. If the gap is too large, you can use a more viscous adhesive (500. When the fiber is inserted into the wool ,,, and Tian Yan, the increase in temperature will reduce the viscosity of the adhesive. Therefore it has a different viscosity Hysteresis and temperature, we can provide better positioning of the fiber and greatly reduce its relocation after curing. Generally, suitable viscosity I is used to simulate the viscous flow in the capillary using the Hagen-Poiseui equation. The fiber positioned inside the capillary is determined. After the combination is cured, the ferrule is polished at an 8-degree angle and coated with an anti-reflection coating. The connection layer between the fiber and the surrounding ferrule is very thin (preferably less than about 1 -1 · 5 mm) to reduce thermal stress and movement. Examples of various embodiments of the capillaries of the present invention are illustrated in Figures 3A to 1 3H and 1 4A to 1 4E.

第26頁 581896 五、發明說明(22) 圖1 3A顯示套圈1 6的斷面圖,其具有圓形化形或圓形化 長方形毛細管130,並緊密排列光纖131a,131b,131c,131d 。圓形化形毛細管提供固定的分隔距離,而圓形化長方形 毛細管可以使分隔距離是變動的。圓角和緊密包紮光纖的 良好設計有數個理由。毛細管形狀和緊密包紮光纖丨3 1可 有效防止固化之前的光纖移動,也可降低固化後光纖上的 熱應力。圓角130a的彎度優先地有比光纖131的外表面更 小的半徑。優先地角13〇a是9〇度的角,因而形成真正方形 或長方形的毛細管。因此,就此規格的目的而言,真正長方 形是指毛細管斷面角的半徑小於或等於包裹的光纖半徑。 間隙G4是光纖最接近或碰觸毛細管1 30壁板的地方。間隙 Gj優先地是小於約〇 · 5毫米,更優先地是小於約〇 · 1毫米,最 優先地是0(亦即光纖碰觸毛細管壁)。在最接近光纖131 a 和131b(也是光纖131c和131(1)的間隙G6也是一樣小(優先 地小於約0. 5毫米,〇· 1毫米或0毫米)。間隙G5優先地也很 ^ (、優先地小於約〇·5毫米,0.1毫米或〇毫米),然而遠端相 鄰光纖131a和131(1的間隙G5可以比較大,以達到所需要的 ^ I列數予所示的分隔距離。緊密包紮的光纖還提供第二 Γ t,,即在毛細管13 〇内只需要一點枯合劑,由於光纖和 2 ^劑間不相等的熱膨脹係數(CTE),因此在光纖131上產 A ^的熱應力。即使在大間隙G5的钻合劑也因為熱膨脹 縮^對所導致光纖的應力或移位具有極小的影響。毛 &的叹计會防止光纖的移位傾向以及避免光纖的旋 、 、U化之前粘合劑流動所致(譬如光纖131d不可能旋Page 26 581896 V. Description of the invention (22) Figure 13A shows a cross-sectional view of the ferrule 16, which has a rounded shape or a rounded rectangular capillary 130, and the optical fibers 131a, 131b, 131c, 131d are closely arranged. Rounded capillaries provide a fixed separation distance, while rounded rectangular capillaries can vary the separation distance. There are several reasons for the good design of rounded and tightly packed fibers. Capillary shape and tightly packed fiber 丨 3 1 can effectively prevent the fiber from moving before curing, and can reduce the thermal stress on the fiber after curing. The curvature of the fillet 130a preferably has a smaller radius than the outer surface of the optical fiber 131. The angle 130a is preferably an angle of 90 degrees, thus forming a true square or rectangular capillary. Therefore, for the purposes of this specification, a true rectangular shape means that the radius of the capillary section angle is less than or equal to the radius of the wrapped fiber. Gap G4 is where the fiber is closest to or touching the wall of the capillary 130. The gap Gj is preferably less than about 0.5 mm, more preferably less than about 0.1 mm, and most preferably 0 (i.e., the fiber touches the capillary wall). The gap G6 that is closest to the optical fibers 131 a and 131b (also the optical fibers 131c and 131 (1) is also as small (preferably less than about 0.5 mm, 0.1 mm or 0 mm). The gap G5 is also preferentially ^ ( , Preferably less than about 0.5 mm, 0.1 mm, or 0 mm), but the far-end adjacent fibers 131a and 131 (the gap G5 of 1 can be relatively large to achieve the required number of ^ I columns given the separation distance shown The tightly packed optical fiber also provides a second Γ t, that is, only a little desiccant is needed in the capillary 13 〇, due to the unequal thermal expansion coefficient (CTE) between the optical fiber and 2 ^ agent, so A ^ Thermal stress. Even in the large gap G5, the bonding agent has a small effect on the stress or displacement of the fiber due to thermal expansion. The hair & sigh meter will prevent the fiber's tendency to shift and avoid fiber rotation, Caused by the adhesive flow before Uification (for example, fiber 131d is impossible to spin

第27頁 581896 五、發明說明(23) ' 轉至光纖131&的位置,光纖131a也不可ι 的位置)。 〜旋轉至光纖131b 一旦光纖固定在毛細管130内,就得選擇哪些光纖可以 形成一對(即輸入和反射)。通常,光纖對的位置是互在對 角線上。例如參考圖13A,對角分開的光纖(如^“及“卜 可以選配成對。移動通過對角分開光纖的光線訊號可能在 光纖24的中心同-點上父會。這可能會導致訊號間的一些 干擾。假使訊號干擾是一個問題,那麼使用光纖對的固定 矛口變動分隔距離的毛細管設計將可減少干擾。數種可能的 毛細管設計將在以下討論。 數種其它範例的毛細管設計包括雙橢圓毛細管(圖uB ),四葉首稽或四圓形毛細管(圖13C),六光纖長方形毛細管 (圖13D),二晶片套圈(圖13E和13F),四光纖長方形毛細管( 圖13J)’雙長方形毛細管(圖13K),變動雙長方形毛細管(圖 13L),雙橢圓毛細管(圖13Μ),混合毛細管(圖13Ν)和對準的 墊圈設計(圖14Α*14Β)。為了簡化起見,在每個圖中的相 關特性都使用同樣的參考編號。 毛細管設計之間的重要差別在於有些在固定分隔距離 的設計上是有用的,而有些則是在變動分隔距離的設計上 是有用的。例如,圖13Α到13D說明了固定分隔距離的設計( 即分隔距離並不改變)。而圖13Ε到13Η說明了變動分隔距 離的設計。通常在想要較大的分隔距離時會使用變動分隔 距離的設計。 請參考圖13Β,雙橢圓毛細管132的形狀類似兩個相鄰Page 27 581896 V. Description of the invention (23) 'Go to the position of the optical fiber 131 & also the position of the optical fiber 131a). ~ Rotate to fiber 131b Once the fiber is fixed in the capillary 130, it is necessary to choose which fibers can form a pair (i.e. input and reflection). Generally, the positions of the fiber pairs are diagonal to each other. For example, referring to FIG. 13A, diagonally-divided optical fibers (such as ^ "and" bu can be optionally paired. The light signals moving through the diagonally-divided optical fiber may be at the same point on the center of the optical fiber 24. This may cause a signal If signal interference is a problem, then capillary designs that use a fixed spear of a fiber pair to change the separation distance will reduce interference. Several possible capillary designs are discussed below. Several other examples of capillary designs include Double elliptical capillaries (Figure uB), four-leaf head or quadrangular capillaries (Figure 13C), six-fiber rectangular capillaries (Figure 13D), two-chip ferrules (Figures 13E and 13F), four-fiber rectangular capillaries (Figure 13J) ' Double rectangular capillary (Figure 13K), variable double rectangular capillary (Figure 13L), double oval capillary (Figure 13M), mixed capillary (Figure 13N) and aligned gasket design (Figure 14A * 14B). For simplicity, in The relevant characteristics in each figure use the same reference number. The important difference between capillary designs is that some are useful in designs with fixed separation distances, while These are useful in designs with variable separation distances. For example, Figures 13A to 13D illustrate designs with fixed separation distances (that is, the separation distance does not change). Figures 13E to 13Η illustrate designs with variable separation distances. Generally The design of variable separation distance is used when larger separation distance is desired. Please refer to FIG. 13B, the shape of the double elliptical capillary 132 is similar to two adjacent ones.

第28頁 581896 五、發明說明(24) 的橢圓形,而且毛細管1 3 2包圍住光纖1 3 1。毛細管1 3 2的部 分圍繞光纖131形成大約][2〇度到18〇度約束弧132&。光纖 131表面和毛細管132鄰壁之間的間隙〇4優先地少於約丨.5 毫米,更優先地是少於約1 · 〇毫米,最優先地是少於約〇. 5毫 米。同樣地,相鄰光纖G6間的間隙在最近點優先地少於約 1 · 5毫米,更優先地是少於約丨· 〇毫米,最優先地是少於約〇, 5毫米。變動距離鄰近光纖G5的間隙G5範圍優先地為〇· 5毫 米到約3 0 0 *米,根據兩個橢圓毛細管的位置而定。對角線 上的一對例如1 3 1 a和1 3 1 c形成輸入和反射光纖對。如果需 要的情況下,雙橢圓毛細管可以擴展成三或甚至四個相鄰 橢圓形,以形成多橢圓毛細管。然而,在多橢圓毛細管中, 對角線上的光纖對是優先地的。 ’ 圖13C說明包圍住光纖131的四圓形毛細管133。毛細 管133的部分圍繞光纖131形成大約180度到24〇度約束弧 1 3 3a。光纖和毛細管鄰壁之間的間隙以優先地少於約丨.5 毫米,更優先地是少於約1. 〇毫米,最優先地是少於約〇· 5毫 米。同樣地,緊鄰光纖間的間隙也優先地少於約丨· 5毫米, 更優先地疋少於約1 · 0毫米,最優先地是少於約〇 5毫米。 圖1 3 D說明包圍住六條光纖1 3 1的長方形毛細管丨3 〇。 同樣地,間隙G4, G5和G6優先地儘可能的小,以避免光纖的 移動>。因此間隙優先地少於約1· 5毫米,更優先地是少於約 1 · 0毫米,更更優先地是少於約〇 · 5毫米。在此實施例中,光 纖有兩種分隔距離。對角線上的光纖對(即131a l31c以及 131b,131d)具有匹配的分隔距離。然而,光纖對’Ule以及Page 28 581896 V. Description of the invention (24) The oval shape, and the capillary 1 3 2 surrounds the optical fiber 1 3 1. The portion of the capillary 1 3 2 is formed around the optical fiber 131 approximately] [20 ° to 180 ° confinement arc 132 &. The gap between the surface of the optical fiber 131 and the adjacent wall of the capillary tube 132 is preferably less than about 1.5 mm, more preferably less than about 1.0 mm, and most preferably less than about 0.5 mm. Similarly, the gap between adjacent optical fibers G6 is preferably less than about 1.5 mm at the nearest point, more preferably less than about 1.7 mm, and most preferably less than about 0.5 mm. The range G5 of the fluctuation distance from the adjacent optical fiber G5 preferably ranges from 0.5 mm to about 300 * m, depending on the positions of the two elliptical capillaries. A pair on the diagonal, such as 1 3 1 a and 1 3 1 c, form the input and reflection fiber pairs. If desired, a double elliptical capillary can be expanded into three or even four adjacent ovals to form a multi-elliptical capillary. However, in polyelliptic capillaries, pairs of fibers on the diagonal are preferred. 13C illustrates a quadrangular capillary 133 surrounding the optical fiber 131. A portion of the capillary tube 133 forms a constraining arc 1 3 3a of about 180 to 240 degrees around the optical fiber 131. The gap between the optical fiber and the adjacent wall of the capillary is preferably less than about 1.5 mm, more preferably less than about 1.0 mm, and most preferably less than about 0.5 mm. Similarly, the gap between adjacent optical fibers is also preferably less than about 1.5 mm, more preferably less than about 1.0 mm, and most preferably less than about 0.5 mm. FIG. 13D illustrates a rectangular capillary tube 301 surrounding six optical fibers 131. Similarly, the gaps G4, G5, and G6 are preferably as small as possible to avoid fiber movement>. The gap is therefore preferably less than about 1.5 mm, more preferably less than about 1.0 mm, and even more preferably less than about 0.5 mm. In this embodiment, the optical fiber has two separation distances. The fiber pairs on the diagonals (ie 131a l31c and 131b, 131d) have matching separation distances. However, the fiber pair ’Ule and

581896 五、發明說明(25) 1 3 1 f有較小的分隔距離。雖 a 組件上較少使用,但在以特定裝置可能在薄膜濾波器 器是很有用的。 曰曰體為主的裝置上,譬如隔離 r你丨上ί : 1圈和毛細官設計都是固定分隔距離毛細管的 右::=改交或變動分隔距離。例如,假如薄膜濾波器具 二& 、、入射角,那麼光纖變動的分隔距離對應所需要的 就為很有用的。以下的套圈和毛細管設計提供可達 1 =的分隔距離部又維持先前設計同樣精準定位的方法 :通吊這種設計在光纖間維持固定垂直的分隔,一方面卻 水平的(如圖所不)距離。我們也發現可變動水平距離 最有用的範圍是從5毫米到7 5毫米。 變動的分隔距離和毛細管的實施範例以圖丨3 Ε所示的 =晶=毛細管來做說明,這裡的四光纖131(兩對)的橫斷面 f & μ ν由一個加長矽片(晶片)1 3 5 a和1 3 5 b中相匹配凹槽所 iimi34“°i34b内部。石夕晶片以v形槽触刻, 二:又為0. 5笔米。結晶學的排列方向提供很好的角度再 ^。上者,f :报容易利用現行的蝕刻技術大量生產。 二片135母一個提供四個優先地對稱的凹槽。兩個中央凹 槽(即光纖凹槽)用Φ + a u μ χ 134h。4 a來在日日片格起時形成毛細管13“和 圮種5又计的特性是V形槽可隨著所需要的定彳亲 到光纖131之間任何所需要的分隔距離。: = 護其中光纖m。對準曰YA///合劑到間隙中以保 了旱曰曰片中的凹槽形成兩個對準毛細管581896 V. Description of the invention (25) 1 3 1 f has a smaller separation distance. Although a component is less commonly used, it may be useful in thin film filters in certain installations. On the body-based device, such as the isolation rYou 丨 上 ί: 1 ring and the capillary design are fixed to the capillary of the fixed separation distance Right :: = change or change the separation distance. For example, if a thin-film filter has two & angles of incidence, then the separation distance of the fiber variation corresponding to what is needed is very useful. The following ferrule and capillary design provides a separation distance of up to 1 = and maintains the same precise positioning method as the previous design: This design maintains a fixed vertical separation between the optical fibers, but it is horizontal (as shown in the figure). )distance. We also found that the most useful range for variable horizontal distances is from 5 mm to 75 mm. The example of the variable separation distance and capillary is illustrated in Figure 丨 3. E = crystal = capillary. The cross section f & μ ν of the four optical fibers 131 (two pairs) is composed of an elongated silicon chip (chip ) 1 3 5 a and 1 3 5 b inside the matching grooves iimi34 "° i34b. Shi Xi wafers are engraved with v-shaped grooves, two: again 0.5 pen meters. The crystallographic arrangement direction provides a good The angle is ^. The former, f: It is easy to mass-produce using the current etching technology. Two pieces of 135 females each provide four preferentially symmetrical grooves. Two central grooves (that is, optical fiber grooves) use Φ + au μ χ 134h. 4 a to form capillaries 13 ″ and 5 in the day-to-day frame. The characteristic is that the V-shaped groove can follow any required separation distance from the fiber to the fiber 131. . : = Protect the fiber m. Align the YA /// mixture into the gap to ensure that the grooves in the dry sheet form two alignment capillaries

第30頁 581896Page 581 896

136以對準晶片135。優先地將直#約3〇〇毫米的玻璃球或 桿件U7插入有適當大小,最多約3〇2毫米直徑以包含 m的對準毛細管136而保持料。桿件137優先地有2 〇毫 米的誤差度,更優先地有丨.0毫米的誤差度,最優先地有〇. 5 毫米的誤差度。假如桿件太大了,光纖將會有多餘的空間 移動到相對其個別的凹#。因此玻璃桿優先地先行篩選以 ”誤差度。施用紫外線固化定位粘合劑和熱固化結構 2劑以提供組合的結構完整性。較佳的晶片套 示於 圖 1 3 Η 到 1 3 F。 圖13F中的晶片使用小型V形槽138以支撐光纖131和對 準桿件/針銷137。小型V形槽可避免晶片的接觸。這項嗖 =將允許光纖碰觸鄰近光纖,因而防止光纖131的移動、或重 =位。在此實施例中,大型v形槽(即對準凹樽)138a支撐對 準針銷137,而小型V形槽(即光纖凹槽)138b支撐光纖丨^工。 =型v形槽i38a在其最寬點優先地是246毫米。而小型乂形 才曰在其最寬點優先地是120毫米。使用這項設計, 131的V形槽可依所需定位來變動光纖131的分隔距離。利 用已知的蝕刻技術,V形槽定位的誤差度約〇. 2毫米。〇要 3触刻更多纖維的更多V形槽,此項設計很容易擴展於更 二巧纖。即使晶片不碰觸,相匹配凹槽所形成的溝槽 可稱為此相規格的毛細管。 對準和接合的晶片套圈16然後被切割蝕刻或加工 Πΐ或4圓? i型或其它所需形狀,使套圈可插入保護的玻璃 各B 14裡面。這說明於圖13G中。末端表面的處理方式和136 至 Align the wafer 135. A straight glass ball or rod U7 of approximately 300 mm in diameter is preferably inserted with a suitable size, up to approximately 302 mm in diameter, to hold the material with an alignment capillary 136 containing m. The rod 137 preferably has a degree of error of 20 mm, more preferably has a degree of error of 0.1 mm, and most preferably has a degree of error of 0.5 mm. If the rod is too large, the fiber will have extra space to move to its respective concave #. Therefore, glass rods are preferentially screened for "error". UV curing positioning adhesive and thermal curing structure 2 are applied to provide combined structural integrity. The preferred wafer sleeves are shown in Figures 1 3 to 1 3 F. Figures The wafer in 13F uses a small V-shaped groove 138 to support the optical fiber 131 and the alignment rod / pin 137. The small V-shaped groove avoids the contact of the wafer. This 嗖 = will allow the optical fiber to touch the adjacent optical fiber, thus preventing the optical fiber 131 In this embodiment, the large V-shaped groove (ie, the alignment groove) 138a supports the alignment pin 137, and the small V-shaped groove (ie, the fiber groove) 138b supports the optical fiber. The = type v-shaped groove i38a is preferentially 246 mm at its widest point. The small 乂 shape is preferably 120 mm at its widest point. With this design, the 131 V-shaped groove can be positioned as required. To change the separation distance of the optical fiber 131. Using known etching techniques, the V-groove positioning error is about 0.2 mm. 〇 If you want to touch more V-grooves with more fibers, this design can be easily extended to More dimple fiber. Even if the wafer does not touch, the groove formed by the matching groove can be called Capillary for this phase. The aligned and bonded wafer ferrule 16 is then cut, etched or machined ΐ or 4 circles? I-shaped or other desired shape so that the ferrule can be inserted into each of the protective glass B 14. This description In Figure 13G, the end surface treatment and

581896 五、發明說明(27) 其它套圈一樣,末端面被研磨成8?角府, 材質塗層。熟悉此像技術的人成將從角這^光並以抗反射⑽ 他類似的毛細管設計,以約0.5毫二中了解還有其 纖的定位。 卞的决差度同樣地支撐光 通常V形槽的過度钱刻並不是問θ 刻,只要引起晶片中均句地垂直移:=借形槽過度敍 過度蝕刻,光纖和對準針銷就可能有移動 。圖1 3H說明光纖和對準針銷和¥形槽關重^位的二間 V形槽很容易限制光纖的移動。而右 、疋位。左邊的 常少的限制’因此較^需要 右相^槽提供光纖非 雖然晶片套圈設計有數種優點,但a 造費用可能很高,適度對準光纖至V曰曰口、,、’干的‘ 時。現在將H日日a I、^ ^槽的過程也可能很耗 ; 在將要况明減少缺點卻仍利用V形样&古4 f & 4士581896 V. Description of the invention (27) Like other ferrules, the end surface is ground into 8? Corners, and the material is coated. The person who is familiar with this imaging technology will take the light from the corner and use anti-reflection, similar to the capillary design, and understand the position of the fiber in about 0.5 milliseconds. The resolution of 卞 also supports light. Generally, the excessive money engraving of the V-shaped groove is not an θ engraving. As long as it causes the wafer to move vertically in one sentence: = excessive etching by borrow grooves, optical fibers and alignment pins are possible. There is movement. Figure 1 3H illustrates the two V-shaped grooves of the optical fiber and the alignment pin and the ¥ -shaped groove. It is easy to restrict the movement of the optical fiber. And right, niches. There are often few restrictions on the left side. Therefore, it is necessary to provide optical fiber instead of the right phase. Although the chip ferrule design has several advantages, the manufacturing cost may be very high, and the fiber is properly aligned to V. ' Time. Now the process of a day I, ^ ^ groove on H day may also be very consuming; in the future, we will reduce the disadvantages, but still use the V shape & ancient 4 f & 4

巧。利用這項方法可使用值絲&太Α ί曰的问效率的技 l7 次,J便用傳統的套圈和毛細管钍人曰H 並以圖131來說明。多個光纖】 :4理過耘如下, 充份的县库β 夕尤、截131插入套圈16。光纖131要 說明圈16的末端。兩”晶片以前面 1 31 ^ ^ ^! 1 V /1 ! # ° ^ ^ ^ 1 3 9 ^ ^ ^ ^ 彈簧决姑Ϊ ί 定位於如上所述之V形槽中。以 2失掊或類似褒置將晶片139夾在 二:以 造ΐ::ί;Γ樹的位置。利用這項技巧,就可製 比美前述的二晶片設計。圈、精準度地定位光纖, 塗覆黏接劑至所有毛細管的較佳方式包括使用一小部 581896 五、發明說明(28) 份的黏接劑l、44a和144b至光纖131,剛好在套圈16的外面以 阻斷接I來塗覆的液體黏接劑。這種黏接劑在塗覆額外黏 合劑之前先加以固化。塗覆黏接劑144c至光纖及套圈16 = 末端,並允許沾附經由毛細管13〇。經由毛細管作用的處理 ,液體黏接劑被拉引通過毛細管13〇,並出現在套圈之端部 在該處由固化黏接劑144b封閉。黏接劑14处固化後,移’ 晶片139。光纖131和套圈16再依所需要情況加以切割以及 磨光。 、f有另二種技術可在插入至套圈之前塗覆黏接劑至光 纖。这種技術的優點是藉由毛細管作用的液體黏接劑,使 光纖固定在一起。液體黏接劑的使用可藉著將光纖浸入至 黏接劑,或優先地施以小量的黏接劑至光纖。 達到變動分隔距離的另一種設計於圖丨3J中說明。 這項設計中,長方形的毛細管130支撐四條光纖m。定位 在毛細管130的壁板上,因而分隔距離是由毛細管13 度來控制。間隙G4和GM憂先地小於約15毫米是 少於約1.0毫米,最優先地是少於約〇 5毫 缺 ^ 的水平間隙G5寬度可以隨需要而定1句話說 鄰近光纖131b和131c的包覆層間最短或最小的距離、。疋 然而還有另-種雙長方形毛細管的設 中。利用已知的技術,可製造毛細fl3G至低於ι 〇毫 誤差’因此光纖間的分隔距離可以精確地控制。毛細管⑽ 的,小標不為比光纖131還寬和高2。毫米。毛細管13〇誤 差是2. 0宅米。因此’有空間可讓光纖插入毛細管,並仍限 581896 五、發明說明(29) 制光纖的重定位。 還有另一實施例說明於圖1 3L中。如圖所示,該實施例 允許光纖1 3 1在水平和垂直位置變動地定位。該實施例在 設計和誤差度上都類似圖1 3K。雖然圖1 3L的設計可用來達 到光纖1 3 1間更大的分隔距離,由於例如黏接劑固化和熱改 變所致之應力,光纖可以很容易在毛細管丨3 〇内重定位。應 該要注意的是必須在毛細管1 3 0間提供合理的分隔。我們 發現小的分隔會導致毛細管間玻璃的裂痕和破碎。在該實 施例中,間隙G 6是鄰近光纖1 3 1 c和1 3 1 d的包覆層表面間最 短或最小的距離。 圖1 3 Μ說明另一種類似於圖1 3 κ的雙毛細管設計。然而 在這個範例中毛細管是橢圓形而不是長方形。同樣的製造 技術和誤差度也適用於該實施例。 圖1 3 Ν中說明的是固定和變動分隔距離光纖的混合設 計。此混合設計合併了各種前述討論的特性。這種設計的 優點是適合將眾多數目之光纖放入單一套圈(例如實施例 所示範例8)。然而,光纖的分隔距離不相等。在毛細管中 間的四條光纖1 3 1 a- 1 3 1 d具有較小的分隔距離,而外部光纖 1 3 1 e _ 1 3 1 h具有較大的分隔距離。在該實施例中,光纖的配 對優先地如下:光纖1 3 1 a和1 3 1 c ;光纖1 3 1 b和1 3 1 d ;光纖 131e和131g;光纖I31f和131h。由於兩種不同的分隔距離, 這種設計通常不好使用於薄膜濾波器上。這種設計適合作 為隔離器或其他對入射角不敏感的光學元件上。 又有另一種定位套圈内光纖的處理過程和設備是使用Coincidentally. Using this method, the technique of value efficiency can be used 17 times. J will use traditional ferrules and capillaries to describe H and use Figure 131 to illustrate. [Multiple optical fibers]: The following steps are taken, and a sufficient county library β Xiyou, cut 131 is inserted into the ferrule 16. The optical fiber 131 indicates the end of the loop 16. Two "wafers with front 1 31 ^ ^ ^! 1 V / 1! # ° ^ ^ ^ 1 3 9 ^ ^ ^ ^ The spring spring is positioned in the V-shaped groove as described above. It is lost by 2 or similar The device clamps the chip 139 in two: to create the position of the Γ tree. Using this technique, the two-chip design can be made better than the previous one. The fiber is positioned in a circle and accurately, and the adhesive is coated to The preferred method for all capillaries includes the use of a small portion of 581896 V. Invention Description (28) parts of the adhesive l, 44a and 144b to the fiber 131, just outside the ferrule 16 to block the liquid coated by I Adhesive. This adhesive is cured before applying additional adhesive. Apply adhesive 144c to the fiber and ferrule 16 = end and allow adhesion through the capillary 13. Treatment by capillary action, The liquid adhesive is drawn through the capillary 13 and appears at the end of the ferrule where it is closed by the cured adhesive 144b. After the adhesive 14 is cured, the wafer 139 is moved. The optical fiber 131 and the ferrule 16 Cut and polish as needed. There are two other techniques for applying adhesive before inserting into the ferrule. To the optical fiber. The advantage of this technology is that the optical fiber is held together by the capillary adhesive liquid adhesive. The use of the liquid adhesive can be by immersing the optical fiber into the adhesive, or preferentially by applying a small amount of Adhesive to fiber. Another design to achieve a variable separation distance is illustrated in Figure 丨 3J. In this design, a rectangular capillary 130 supports four optical fibers m. It is positioned on the wall of the capillary 130, so the separation distance is determined by the capillary 13 degrees to control. The gap G4 and GM are less than about 15 mm, less than about 1.0 mm, and most preferably less than about 0.05 mm. The horizontal gap G5 width can be determined as needed. The shortest or smallest distance between the cladding layers of 131b and 131c. 疋 However, there is another type of double rectangular capillary. Using known techniques, the capillary fl3G can be manufactured to less than ι 0 millimeters error. The separation distance can be accurately controlled. Capillary ⑽, the small label is not wider and higher than the fiber 131. 2. mm. The error of the capillary 130 is 2.0 square meters. So 'there is room for the fiber to be inserted into the capillary, It is still limited to 581896. V. Description of the invention (29) Relocation of optical fiber. There is another embodiment illustrated in FIG. 13L. As shown in the figure, this embodiment allows the optical fiber 1 3 1 to be positioned in a horizontal and vertical position in a variable manner. This embodiment is similar in design and error to FIG. 13K. Although the design of FIG. 13L can be used to achieve greater separation distances between optical fibers 131, due to stress caused by, for example, curing of the adhesive and thermal changes, The optical fiber can be easily relocated within the capillary tube. It should be noted that reasonable separation must be provided between the capillary tubes. We found that small separations can cause cracks and breaks in the glass between the capillary tubes. In this embodiment, the gap G 6 is the shortest or smallest distance between the surfaces of the cladding layers adjacent to the optical fibers 1 3 1 c and 1 3 1 d. Figure 13M illustrates another dual capillary design similar to Figure 13K. However in this example the capillary is oval rather than rectangular. The same manufacturing technique and degree of error are applicable to this embodiment. Figure 1 3N illustrates a hybrid design of fixed and variable separation distance fibers. This hybrid design combines various features discussed previously. The advantage of this design is that it is suitable for putting a large number of optical fibers into a single loop (for example, Example 8 shown in the embodiment). However, the separation distances of optical fibers are not equal. The four optical fibers 1 3 1 a-1 3 1 d in the middle of the capillary have a smaller separation distance, and the outer optical fibers 1 3 1 e _ 1 3 1 h have a larger separation distance. In this embodiment, the optical fiber pairing is preferentially as follows: optical fibers 1 3 1 a and 1 3 1 c; optical fibers 1 3 1 b and 1 3 1 d; optical fibers 131e and 131g; optical fibers I31f and 131h. Due to two different separation distances, this design is usually not good for thin film filters. This design is suitable for use as an isolator or other optical element that is not sensitive to the angle of incidence. There is another process and equipment for positioning the optical fiber in the ferrule.

第34頁 581896Page 581 896

對準墊圈以精準定位光纖。這種處理過程說明在圖丨4a和 圖14B中。使用對準墊圈140的處理過程顯示於圖uA。所 顯示墊圈140具有四個孔徑141以承受光纖,然而卻很容易 應用於較多數目的光纖。對準墊圈14〇使用簡單及高製造 率的元件,使光纖精準地置入套圈16中。可利用光石版印 刷法技術製造具有精準定位孔徑丨4 i和其間分隔的墊圈14〇 孔位的直瓜優先地約1 2 6耄米以提供光纖和孔徑壁之間 約〇·5毫米的間隙。對每對輸入和反射光纖而言,孔徑位置 ,誤差度也優先地少於約Κ 〇毫米,更優先地是少於約〇. 5 毫米。例如,孔徑141d和141b之間距離D4的誤差度優先地 是約〇·5毫f。孔徑141a*141c之間的距離的也同樣適用 。然而,像是1 4 1 a和1 4 1 b鄰近孔徑之間距離d 6的誤差優先 地少於約1 · 0毫米,更優先地是少於約是約〇 · 5毫米。可使 用抗光材質來製造墊圈14〇。只要能達到需要的誤差,也可 使用其他技術來形成墊圈。使用墊圈丨4〇來作為光纖引導 和限制的設置。前述的毛細管通常會造成少於約〇· 5毫米 光纖移動或移位的限制。 再看到圖14B中顯示的墊圈14〇,光纖142和套圈16。光 纖142先插入第一個墊圈14〇a,通過套圈16,再通過第二個 塾圈140b。套圈16可能有以傳統的圓柱形毛細管13〇。然 而’本項务明可採用更多的毛細管而不管其形狀。在該處 理步驟,先將組件預先加熱以幫助光纖丨42的安裝和精確1立 置將會是有益的。然後冷卻組件到室溫,以在塗覆黏接劑 時固定光纖142的位置。墊圈140接合到套圈16的末端面"。Align the washer to pinpoint the fiber. This process is illustrated in Figures 4a and 14B. A process using the alignment washer 140 is shown in FIG. UA. The gasket 140 is shown with four apertures 141 to support the optical fiber, but it can be easily applied to a larger number of optical fibers. The alignment washer 14 uses a simple and high-manufactured component to accurately place the optical fiber into the ferrule 16. Light lithography technology can be used to manufacture a straight melon with a precisely positioned aperture, 4 i and a spacer with a space of 14 between them, preferably about 1 2 6 mm to provide a gap of about 0.5 mm between the optical fiber and the aperture wall . For each pair of input and reflective fibers, the position of the aperture, the degree of error is also preferably less than about KO mm, more preferably less than about 0.5 mm. For example, the error degree of the distance D4 between the apertures 141d and 141b is preferably about 0.5 mF. The same applies to the distance between the apertures 141a * 141c. However, errors such as the distance d 6 between the adjacent apertures of 1 4 1 a and 1 4 1 b are preferably less than about 1.0 mm, and more preferably less than about 0.5 mm. The gasket 14 can be made of a light-resistant material. As long as the required error is achieved, other techniques can be used to form the gasket. Use gaskets 4 and 4 for fiber guide and limit settings. The aforementioned capillaries generally cause restrictions on movement or displacement of the optical fiber of less than about 0.5 mm. Look again at the washer 14o, the fiber 142, and the ferrule 16 shown in FIG. 14B. The optical fiber 142 is inserted into the first washer 14a, passes through the ferrule 16, and then passes through the second loop 140b. The ferrule 16 may have a conventional cylindrical capillary 130. However, 'this item shows that more capillaries can be used regardless of their shape. In this processing step, it would be beneficial to pre-heat the assembly to assist in the installation and precise positioning of the optical fiber 42. The assembly is then cooled to room temperature to secure the position of the optical fiber 142 when the adhesive is applied. The washer 140 is joined to the end face of the ferrule 16 ".

第35頁 五、發明說明(31) 在塾圈具有圓錐形 14〇優先地在圓錐开/立以承受光纖(見圖5)的情況下,塾圈 圓錐形部份。經由>叙°卩份的基底接合,好讓毛細管130符合 液體黏接劑填充套ΐ圈140的扁平部份143所建的間隙,以 固化。在固化黏接ΐϊϋ管13〇,接著進行紫外線固化或熱 個套圈末端的光纖可,也可使用爲平部份143對準在每 對準。&忐的έ §兩個扁平部份對準後,然後光纖也 度角,進二亍磨光且ΐ ί理方式和套圈一樣;末端面研磨成約8 纖分隔距離將在抗反射塗層。遽波器入射角和光 到精ΐ 光纖毛細管而言,很重要的是達 論的渡波器入射Γ1ΓΛ離:二準確地符合底下所討 大致相等(約0·5毫米的誤差)是很重 & S使侍主動對準過程更容易也更成功。 分隔距::探討特性是濾波器入射角(A01)和光纖 的光線替在二的關係。#隔距離精確的誤差使得引導 纖心蕊中央的約°.5毫米之内。在討 滹波哭1鼾=離之前,優先地先定義一些專有名詞。 冗長的說明。通常滤沽%、斛岛产^田鉍 的,並不而要 央波長(叫是报有V的。每一角二=皮器至所需要中 央波長和入射角。入:备二/Λ 特性是根據其中 入射角声^ τ .射角的值代表濾波器最佳效能所需的 射角又。為了適當運作和低插入損耗 具有相對分隔距離的光纖對。 ,…υ 3匹配Page 35 V. Description of the invention (31) In the case where the loop has a conical shape, it is preferred that the cone be conical to open / stand to support the optical fiber (see FIG. 5). Through the bonding of the substrates, the capillary tube 130 is allowed to conform to the gap created by the liquid adhesive filling the flat portion 143 of the ferrule 140 to be cured. The optical fiber at the end of the curing adhesive tube 130, followed by UV curing or heating the ferrule, can also be used to align the flat portion 143 at each alignment. & 忐 的 § After the two flat parts are aligned, the optical fiber is also angled, polished and polished in the same way as the ferrule; the end surface is ground to about 8 fibers, and the separation distance will be in the anti-reflective coating . In terms of the incident angle of the chirped wave and the light to the refined fiber capillary, it is very important that the wavelet incident of the theory is Γ1ΓΛ away from it: the two exactly match what is discussed below (the error of about 0.5 mm) is very heavy & S makes the active alignment process easier and more successful. Separation distance :: Explore the relationship between the incident angle of the filter (A01) and the ray substitution of the fiber. # The precise error of the separation distance leads to within about 0.5 mm of the center of the core. Before discussing 滹 波 哭 1 鼾 = Li, define some proper nouns first. Long description. Normally, the percentage of bismuth produced by Hundo Island does not depend on the central wavelength (called V. Each angle is two = skinner to the required central wavelength and angle of incidence. Into: preparation two / Λ characteristics are According to the incident angle sound ^ τ. The value of the angle of incidence represents the angle of incidence required for the best performance of the filter. For proper operation and low insertion loss, a pair of optical fibers with relatively separated distances, ... υ 3 matching

第36頁 ^1896 五、發明說 為了此項規格,分隔距離定義A ; a :心距離。這個名詞通常是指光纖對::条j纖的光纖ί f)之間分隔距離。在本發明較佳iρ輸入光纖反射光 抵圍從約125毫米到約250毫米。如列中屬距離的 該範圍的分隔距離相對的人射Μ 2 =寸論的(圖1 5), 我們發現遽'波器組件1〇4=約為2度到3度。 穩定對準可藉著選擇具有匹=,成本競爭性以及並 濾波器組件之元件包括光纖套圈16二件而達成。例如’ 2“這些所需要匹配的特性?6’準直透鏡22和渡波器 鏡的入射角,和光纖的分隔距離盗的入射角,準直透 為人了解,而製造GRIN透鏡以^ f的光學特性已 。匹,皮器入射角和光纖的分隔所二入 建立器入射角和光纖分隔距離的ί作是,由 據中央波長和入射角測量2^組合的資料庫。首先,根 量如下。喝波波器特徵化。可以實施測 光線訊號引導進入光:。=皮器組件10或類似褒置,使 過準直透鏡22傳輸至減波哭2汛唬傳輸至輸入光纖1 8,經 決定通過頻率或遽波㈣的輪出,並 的光線訊號角度,持續到為清、'長凋玉杈射相關濾波器 通常商用的薄膜渡波、二為皮器24所需要的輸出訊號。 之間。 為和產生的入射角是約為1.8度和3度 當濾波器2 4達到所雷i 的分隔距離資料決定出相f+、入射角度,可根據套圈組合 出相對的分隔距離。Page 36 ^ 1896 V. Invention In order to this specification, the separation distance is defined as A; a: Heart distance. This term usually refers to the separation distance between a pair of optical fibers :: f). The reflected light in the preferred iρ input fiber of the present invention ranges from about 125 mm to about 250 mm. For example, if the separation distance of the range in the column is relative to the distance between the human shot and M 2 = inch theory (Fig. 15), we find that the wave component 104 is about 2 to 3 degrees. Stable alignment can be achieved by selecting two pieces of fiber-optic ferrule, which are competitive, cost-competitive, and filter assembly components. For example, '2', what are the characteristics that need to be matched? 6 'The angle of incidence of the collimator lens 22 and the wave filter lens, and the angle of incidence of the separation distance of the fiber, the collimation is known, and the manufacture of GRIN lenses with ^ f The optical characteristics have been obtained. The skin angle of the skin and the separation of the fiber are incorporated into the builder's angle of incidence and the separation distance of the fiber. The database is based on a combination of the central wavelength and the angle of incidence measurement. First, the root volume is as follows .Characteristics of the wave wave device. Light measurement signals can be implemented to guide the light into the light: = = leather component 10 or similar set, so that it is transmitted through the collimator lens 22 to the wave reduction 2 and transmitted to the input fiber 1 8 Decide on the frequency or the rotation of the wave signal, and the angle of the light signal continues to clear, the 'long withered jade shoot correlation filter' is usually commercially used thin film wave, and the output signal required for the leather 24. The phase angle f + and the incident angle are determined when the incident angles of the and are about 1.8 degrees and 3 degrees when the filter 24 reaches the separation distance data of the lightning i, and the relative separation distance can be combined according to the ferrule.

第37頁 、-發明說明(33) - 重複地測試和測量不同的濾波器入射角產生精確的資 :庫用以關聯遽波器入射角和套圈相關的分隔距離。熟悉 匕=技術的人知道,這些測量會因濾波器組件特定設計的 ^ =特性而有所變動,因此應該在特定裝置上 優先的效果。 μ 而產ί = t貢料庫建立之後’可以特定包裝誤差精碟性 所_ 濾 匹配輸入準直組件的誤差。可產生如圖15 離二表=顯示可匹配相關渡波器入射角範圍的分隔距 快且=4 了分類的兀件並加以標示,使匹配的部份可以很 圍優地完成。如圖15所示’每個分隔距離分類的範 3-4毫^約為3 —4毫米。為達到最終的毫米誤差,這種 補償這種^差是令人滿意的’ ®為遽^皮器24可小量傾斜以 的中失隔距離上的小變動,而不會顯著地改變濾波器 在-Ϊ Ϊ Ϊ要的情況下,該表格也安排為更精確的誤差。 的,因為Vj皮長必須非常精確的情況下,這可能是很需要 理想上ί入射角的改變會影響濾波器的中央波長。 在約2毫ί入組件内每一對光纖的分隔距離將是相同的或 類中。、之内,因此將此輸入組合放在圖1 5所示的預定分 波器24〜插選&匹配的輸入準直組件(4璋或多端埠)35和濾 輸入和Λ可如上面所討論的組合成“器組件1G。4端蟓 以及利2纖輸出準直組件將對準以得到最大的傳輸; _^用外部套管32(圖3)銲接,精確地固定這些準】 581896Page 37,-Description of the invention (33)-Repeatedly testing and measuring different filter incident angles to generate accurate data: The library is used to correlate the incident angle of the wave filter and the separation distance related to the ferrule. Those familiar with dagger = technology know that these measurements can vary due to the ^ = characteristics of the particular design of the filter assembly and should therefore be prioritized on a particular device. μ 而 产 ί = After the establishment of the tributary database, the packaging error can be specified. Filter the error of the input collimation component. As shown in Figure 15, the second table = the separation distance that shows the range of incident angles of the relevant wavelet is fast and = 4 classified elements are marked and marked, so that the matching part can be completed in a good range. As shown in FIG. 15, the range of each separation distance is 3-4 millimeters, which is about 3-4 millimeters. In order to achieve the final millimeter error, this compensation for this difference is satisfactory. It is a small change in the separation distance of the leather 24 which can be tilted by a small amount without significantly changing the filter. Where -Ϊ Ϊ Ϊ is required, the table is also arranged for more accurate errors. Because the Vj skin length must be very accurate, this may be very desirable. Ideally, a change in the angle of incidence will affect the center wavelength of the filter. The separation distance for each pair of fibers in the module will be the same or within about 2 millimeters. , So this input combination is placed in the predetermined demultiplexer 24 ~ interpolation & matching input collimation component (4 璋 or multi-port) 35 and filter input and Λ shown in Figure 15 as shown above. The combination discussed is "1G. 4 terminal and 2 fiber output collimation components will be aligned to get the maximum transmission; _ ^ Welded with the outer sleeve 32 (Figure 3) to accurately fix these standards." 581896

之間的相互關係 論0 完整的多端埠裝置30的組合將在底下討 輸入和輸出準直和浦古 。輸出光纖套圈準直組^35,°。以s疋m管32之内 似的方式製造。然而,根:5不入準直組件35相 以代替在輸出準直組=中模鑄非球面透鏡) 比較,非球面透鏡在六端蟑和】G;:=:GRIN透鏡作 儡赴。苦止.. 干不又夕‘埠裝置的應用上有苴 優”、、百先,非球面透鏡有較長的工作距離定義為义隹赴 :]f°^^,^ /Λ;;Τ 直組件應該具有剛好在同一 輸出丰 。該點也應該剛好與渡波器的員耗最佳化 於滤波器基質邊上的多端痒塗工層表= 表面上。假如只二:ίΓ::,波器的據波器塗層 ti、y須非〆ι松 透鏡卩麼渡波器的薄骐和基質 就必/頁“薄(專於襯底折射率貝 在該厚度下,渡波器薄膜和基質具有盘薄膜位)。 制以及在製造期間也較容易破边::f ”力相關之限 鏡的工作距離等於2微平允、#衣痕專。非球面透 挪、隹必+ 。 卡,允許使用約1. 5微米(和以η从 軚準濾波為和基質厚度。因此,較好 上)的 套圈,GR I Ν或非球面透鏡帶、g r # 4、°又冲匕括四個光纖 e ^ ^ X面透鏡,通(溥膜濾波器)塗層,基皙韭 和雙光纖套圈。底下構造亦為可能的同:二非 為最佳化插1損耗:四個光纖套圈,非球面透鏡,基: (薄膜遽波器)塗層,GRI^t非球面,和雙光纖套圈。、’ π通Interrelationships 0 The complete combination of multi-port devices 30 will be discussed below with input and output collimation and Pugu. Output fiber ferrule collimation group ^ 35, °. Manufactured in a similar manner to the s 疋 m tube 32. However, the root: 5 does not enter the collimation component and 35 phases instead of the output collimation group = middle die cast aspheric lens) In comparison, aspheric lenses are used at the six ends and G;: =: GRIN lenses. Suffering .. There is no better application of "Bu device", Baixian, aspheric lens has a longer working distance is defined as meaning: go to f] ^^, ^ / Λ ;; Τ Straight components should have exactly the same output abundance. This point should also be exactly the same as the power consumption of the wave filter on the surface of the multi-terminal itchy coating layer on the side of the filter substrate = on the surface. If only two: ίΓ ::, the wave The ti, y coating of the wave filter of the device must be a loose lens. The thickness of the wave filter and the substrate must be thin. (Specifically, the refractive index of the substrate is at this thickness. The wave film and the substrate have Disk film bit). It is also easier to break edges during manufacturing and during manufacturing :: f ”The working distance of the force-related limit mirror is equal to 2 micro-level allowance, # 衣纹 专. Aspheric surface shift, 隹 + +. Card, about 1.5 Ferrules in micrometers (and η from the quasi-filtered and matrix thickness. Therefore, better), GR IN or aspherical lens belt, gr # 4, ° and four optical fibers e ^ ^ X plane Lens, through (diaphragm filter) coating, base and double fiber ferrule. The underlying structure is also the same: two non-optimized insertion loss: four fiber ferrules, aspheric lens, base : (Thin film chirp) coating, GRI ^ t aspheric, and dual fiber ferrule., 'Π 通

581896 五、發明說明(35) 另—非球面透鏡的優點是焦距具有彈柯。炎 波器低的入射角,就需要透鏡較長的焦距相、丄保持濾 -個非球面透鏡完成。也可以低成本 ?虽各易以 模鑄非球面透鏡。膽! N透鏡而言,為很焦距之 改=射率分佈,這也表示和標準換雜過匕差T 。侍到任何焦距的GRIN透鏡為困難的以及耗費者々差異 所述都使得非球面透鏡在此項應用上更引人注目。。以上 方式m Κ Γ差一樣的 直摩中相對應的;的 隔::的特徵。假使光纖對沒有使用在輸出準 直,、w W中,那麼就要作分隔距離的估計。輸出準直組件 m著λ傾斜,旋轉和軸向調整組合35,以得到最大的傳 波器24光學地對準。這是因為保護套管32内部的 密;r : f t於輸出組件35’外部大小。也可藉著微傾斜裝 置“保護套管32和從保護套管32延伸出的輸出組件35’ 的末端以達到微傾斜。優先實施例提供約5〇_ι〇〇毫米的間 隙,足夠使套管32内的輪出組件35,得到微傾斜。一旦完成 輸出準直組件35’的主動對準,就使用插入至準直組件35, 外:和保濩套官3 2之間隙的銲接和粘合劑3 3以固定住輸出 準直組件3 5,。 、以上的討論和如何製造諸如四光纖套圈以及六和八埠 遽波包裝的多端淳裝置有關。而以下的討論則和這些裝置 進一步的應用和本發明其它的優點有關。581896 V. Description of the invention (35) Another-the advantage of aspheric lens is that the focal length has elasticity. The low incident angle of the wave filter requires the lens to have a longer focal length phase and maintain a filter-an aspheric lens. Can it also be low cost? Although it is easy to mold aspherical lenses. Dare! In the case of N lenses, the change for a very long focal length = the emissivity distribution, which also means that the difference T from the standard is changed. GRIN lenses that serve any focal length are difficult and costly. Differences make aspheric lenses more compelling in this application. . In the above manner, the difference between m κ and Γ is the same as that in the direct friction; If the fiber pair is not used in output collimation, w W, then the separation distance must be estimated. The output collimation assembly m is tilted at λ, and the combination of rotation and axial adjustment 35 is obtained to obtain the largest optical waveguide 24 alignment. This is because r: f t is smaller than the outer diameter of the output assembly 35 '. The micro-tilt device "protective sleeve 32 and the end of the output assembly 35 'extending from the protective sleeve 32 can also be used to achieve micro-tilt. The preferred embodiment provides a clearance of about 50 mm, which is sufficient for the sleeve The wheel-out component 35 in the tube 32 is slightly tilted. Once the active alignment of the output collimation component 35 'is completed, it is inserted into the collimation component 35. Outside: Welding and gluing with the gap between the security guard 32 Mixture 3 3 is used to fix the output collimation component 3 5. The above discussion is related to how to make multi-terminal devices such as four-fiber ferrules and six- and eight-port cymbals. The following discussion is further with these devices. The application is related to other advantages of the invention.

581896581896

五'發明說明(36) 首先參閱圖1 6A,其顯示出四埠濾波器組件的示意圖, /、包括第一輸入光纖16〇a,第一反射光纖禺合至第二 輸入光纖160c和第二反射光纖16〇4。此外也顯示了套圈16 ,透鏡22和濾波器24。在運作上,光線訊號輸入通過第一輸 入光纖160a,由透鏡22加以準直,並由濾波器24部分反射。 反射的訊號被第—反射光纖1 β 〇 b接收,並傳送到第二輸入 光纖s160c。訊號再經由透鏡22準直,並由濾波器24部分反 射,最後再由弟一反射光纖16 〇 d接收,還可傳送訊號到光學 通讯系統,網路或所需的終點站。這種裝置的特性提供了 加強的效能,在光通訊系統中是很有幫助的。 首 需要兩 反射的 器裝置 而該設 陡峭截 由薄膜 從同一 種裝置 改 入光纖 纖形成 耦合裝 置也因 先’每一次使用同樣的濾波器以反射訊號。該優點 個濾ί器的裝置以實施該功能。更者,因為每-次 ,波器特性是—樣的而提高效能。在使用兩個遽波 ^皮器通常有類似但不相等的濾波器特性。因 ΐ Ζ ΐ產生改善的濾波器特性,譬如像是較銳尖及 使用11種裝置的範例是缺口濾波器。通常 的一次反射將提供12到15分貝的分隔。 =可:用ί —次反射將產生24到30分貝的分隔。這 ^ Ηζ 各式其它形狀的濾波器。 160c間的轉人。= ί ~反射光纖1601)至第二輸 。這去ϋ ·Τ 〇 k兩條光纖可能從一條未斷裂的光 置通常且古?個分割光纖間光學耦合裝置的需求。 使用相關之插入損耗。消除麵合裝 而汉善了四埠濾波器161的效 月bFifth invention description (36) First refer to FIG. 16A, which shows a schematic diagram of a four-port filter assembly, including a first input fiber 160a, a first reflective fiber coupled to a second input fiber 160c and a second Reflective fiber 160. Also shown are the ferrule 16, lens 22, and filter 24. In operation, the light signal input passes through the first input fiber 160a, is collimated by the lens 22, and is partially reflected by the filter 24. The reflected signal is received by the first-reflection optical fiber 1 β 0 b and transmitted to the second input optical fiber s160c. The signal is then collimated by the lens 22, and partially reflected by the filter 24, and finally received by the first reflective fiber 16Od. The signal can also be transmitted to the optical communication system, the network or the desired terminal. The characteristics of this device provide enhanced efficiency and are very helpful in optical communication systems. First, a two-reflector device is required, and the device is cut sharply from the same device to a fiber. The fiber-forming coupling device also uses the same filter every time to reflect the signal. The advantage is a filter device to perform this function. Furthermore, because the wave characteristics are the same every time, the efficiency is improved. When using two chirps, skin filters usually have similar but not equal filter characteristics. Ϊ́ Ζ ΐ produces improved filter characteristics, such as sharper tips and an example using 11 types of devices is a notch filter. A typical reflection will provide a separation of 12 to 15 decibels. = Available: With ί-the reflection will produce a separation of 24 to 30 dB. There are various other shapes of filters. Transfer between 160c. = ί ~ Reflective fiber 1601) to the second input. This eliminates the need for two optical fibers that may be common from an unbroken light and an optical coupling device between the split fibers. Use the relevant insertion loss. Elimination of surface mounting and Hanshan's effectiveness of four-port filter 161

第41頁 581896 五、發明說明(37) 另一種四埠濾波器1 6 1實施例很適合共同地作為與光 學放大器相關之增益平整濾波器。如圖丨6B所示,由第一輸 入光纖160a輸入訊號,再由增益平整濾波器24反射至第一 反射光纖1 6 0 b。放大器1 6 2放大訊號後傳送到第二輸入光 纖16 0c。訊號又再由增益平整濾波器24反射至第二反射光 纖 1 6 0 d 〇 在另一個實施範例中,可以使用單一濾波器組件丨6 1增 益平整二個放大器1 62發出的訊號。圖丨6c所示是濾波器組 件161搞合至二個放大器162a和162b的示意圖。光線訊號 輸入通過第一輸入光纖16〇a,由增益平整濾波器24反射。 反射訊號穿過第一反射光纖1 6 〇 b到第一放大器1 6 2 a。放大 訊號在經由第二輸入光纖丨6 0c傳回濾波器組件丨6丨,在該處 再由增盈平整濾波器2 4反射,經由第二反射光纖丨6 〇 d輸出 至第二放大器162b。 圖16D是一個五端埠濾波器163光學-機械之示意圖。 濾波器的運作非常類似圖丨6A的組件,然而這種五端埠濾波 器包括用來接收傳送經濾波器24訊號的輸出準直組件。濾 波器24可以是任何種類的薄膜濾波器,諸如說明之用窄帶 通的濾波器。光線訊號從第一輸入光纖16〇a輸入,由透鏡 22準直,並由濾波器24部分反射。選擇的訊號窄頻帶部份 經由滤波器24傳送至傳輸光、m6Qe。訊號的反射部份通過 第-反= m60b和第二輸入光纖16〇c,並由遽波器24反 射。兩射訊號然後由第二反射光纖16〇d輸出,傳輸頻 率的隔離兩達24-30分貝。Page 41 581896 V. Description of the invention (37) Another four-port filter 1 6 1 embodiment is very suitable for use as a gain flattening filter related to an optical amplifier. As shown in FIG. 6B, the signal is input from the first input fiber 160a, and is reflected by the gain flattening filter 24 to the first reflection fiber 16 0b. The amplifier 1 62 amplifies the signal and transmits it to the second input fiber 160c. The signal is reflected by the gain-flattening filter 24 to the second reflective fiber 1660 d 〇 In another embodiment, a single filter component 6 1 can be used to gain-smooth the signals from the two amplifiers 1 62. Figure 6c shows a schematic diagram of the filter assembly 161 coupled to the two amplifiers 162a and 162b. The light signal input passes through the first input fiber 16a and is reflected by the gain smoothing filter 24. The reflected signal passes through the first reflective fiber 16b to the first amplifier 162a. The amplified signal is transmitted back to the filter assembly 6o through the second input fiber 6c, where it is reflected by the gain smoothing filter 24, and is output to the second amplifier 162b through the second reflective fiber 6od. FIG. 16D is a schematic diagram of a five-terminal port filter 163 optical-mechanical. The operation of the filter is very similar to that of Figure 6A. However, this five-terminal filter includes an output collimation component to receive the 24 signal transmitted by the filter. The filter 24 may be any kind of thin-film filter, such as a narrow-band-pass filter as illustrated. The light signal is input from the first input fiber 16a, collimated by the lens 22, and partially reflected by the filter 24. The narrow-band portion of the selected signal is transmitted to the transmission light, m6Qe through the filter 24. The reflected portion of the signal passes through the first-reflection = m60b and the second input fiber 16oc, and is reflected by the chirper 24. The two shot signals are then output by the second reflective fiber 16Od, and the transmission frequency is separated by up to 24-30 dB.

第42頁 581896 五、發明說明(38) 端埴'Ϊ : 2「個實施範例中,遽波器包裝搞合至散執拇 鈿埠或終鈿165以驅散過多的訊號能量。 ]、、、槽 如圖1 6 E所示,滹波哭2 4可s 乂 人、乾例中 λ册、x、/上二 可以是任何種類的薄膜濾波哭& 如通濾波态或增益平整、、廣念 °。,諸 輸入光纖! _,由透丄"V直:Λ第“輸9入訊號傳八第〜 分傳輸。傳輸的部份是經由透=波反射和部 :裡假設麵合至通訊系、统。第-輸入訊號反射部::0由% 鏡22反射回到第一反射光纖祕,並搞合至第一終端16由透 。終端165是此項技術上眾所皆知的熱驅散裝置,無: 散廢棄之能量。一條類似的路徑是沿著第二輸入訊二 至第二輸入光纖160c。訊號傳輸的部份被傳送至第二= 光纖160f,而反射的廢棄能量部份經由第二反射光纖丨别 到達第二終端165b。 圖16F說,了另一整體廢棄能量散熱槽端埠的實施例 。然而,在該實施例散熱槽終端165耦合至傳輸光纖16(^和 160f。反射訊號輸出到反射光纖16〇b和16〇(1,並假設連接 至通訊系統。 圖1 6G是利用本發明增加/去除包裝的示意圖。渡波器 2 4是薄膜帶通濾波器,在波長λ處通過光線並反射所有其 它波長。透鏡22和34優先地是準直GRIN透鏡。第一光線信 號經由輸入光纖11以波長λ 1 ··· λ η進入。波長λ 1傳輸至 光纖Τ1,波長λ 2 ··· λ η反射至光纖R1,因此一個頻道或波 長被去除,或者由輸入訊號解多工。相反地,另一訊號以波 長;12··· λη輸入至光纖12,而第三訊號以波長輸入至Page 581 896896 V. Description of the invention (38) Terminals: 2 "In one embodiment, the waver packaging is coupled to the fan terminal or terminal 165 to dissipate excessive signal energy.] ,,, The slot is shown in Figure 16E. The wave wave 2 4 can be stunned. In the dry example, the λ book, x, / upper two can be any kind of thin film filter. For example, the pass filter state or gain leveling, Speak °., The input optical fiber! _, By the transmission " V straight: Λ first "input 9 into the signal to the eighth ~ minute transmission. The transmission part is transmitted through the wave reflection and the reflection part: the assumption is that the surface is connected to the communication system and system. The first-input signal reflection part: 0 is reflected by the% mirror 22 back to the first reflection fiber, and is coupled to the first terminal 16 through transmission. The terminal 165 is a heat dissipating device which is well known in the art, without: Dissipating waste energy. A similar path follows the second input signal to the second input fiber 160c. The part of the signal transmission is transmitted to the second = optical fiber 160f, and the reflected waste energy part reaches the second terminal 165b via the second reflective fiber. FIG. 16F illustrates another embodiment of the end port of the overall waste energy heat sink. However, in this embodiment, the heat sink slot terminal 165 is coupled to the transmission fibers 16 (^ and 160f. The reflected signals are output to the reflection fibers 160b and 160 (1), and it is assumed to be connected to the communication system. Fig. 16G is added using the present invention. / Schematic diagram of removing the package. The wave filter 24 is a thin-film band-pass filter that passes light at a wavelength λ and reflects all other wavelengths. The lenses 22 and 34 are preferably collimated GRIN lenses. The first light signal passes through the input fiber 11 to The wavelength λ 1 ··· λ η enters. The wavelength λ 1 is transmitted to the optical fiber T1, and the wavelength λ 2 ··· λ η is reflected to the optical fiber R1, so one channel or wavelength is removed or multiplexed by the input signal. Conversely, The other signal is at wavelength; 12 ... λη is input to fiber 12, and the third signal is at wavelength

581896 五、發明說明(39) ,纖13。波長;12·: λη由濾波器24反射至光纖R2。除 波長A 1經由濾波器24至傳輸至光纖R2。因此以, 長又1··· h離開包裝171,因此增加了一個頻道或波長波 者從光纖12多工化為原始訊號。 〆 、或 圖16H是八埠包裝166的示意圖。該實施例包括η· ::輸入光纖,經由輸入準直透鏡22,光學元件Μ和輸出 準直透鏡34,耦合至四個傳輸光纖Τ1· · ·Τ4。光學元件 疋任何形狀的濾波為,諸如增益平整濾波器或帶通濾波哭、 ::而該實施例特別適合用在晶體元件諸如隔離器:& 選擇之光學元件。 卜馬 日最後光學包裝之實施例是八埠增加/去除裝置。圖丨6 ! 是包裝的示意圖,可以增加和去除兩個各別光線訊號的一 個頻道。、其運作方式如下,[光線訊號以波長λΐ· . “ 、’二由光纖11輸入。濾波器2 4是帶通濾波器,只能通過波長 j 1的光線,並反射其它波長。因此,波長λ i傳輸至光纖 ,而_剩餘波長;I 2· · ·又η則反射至光纖R1。具有波長入i ^第二訊號經由光纖I 2輸入。光纖12是和光纖以光學對 因此訊號經由濾波器24,並耦合至光纖R1,光纖R1上產 ^ Λ號包έ波長又j ••又n。因此加入波長為又1之原始 k和波長為;11之新頻道。對光纖13, 14, R2和72也作 樣的運作。 然而在另一實施例中,建立了精簡的⑽⑽模組,如圖i 7 不5亥圖"兒明了在通訊系統上很有用的四頻道增加/去 除模組。結合四個六端埠濾波器包裝171(諸如關於圖16(ί 581896 五、發明說明(40) =描述的)在一起以建立該模組。開始是解多工(即去 =,含有波長;U · · ·又n的解多工訊號經由第一包裝工7 1 :輪入光纖II進入包裝,並由輸入透鏡22加以準直。又 ,一部份傳送通過濾波器24a,並經由傳輸光纖η傳送二 、=。剩餘波長;12· · · λη則反射至反射光纖R1,並傳送至二 jl7lb的第一輸入光纖。包裝17lb内的濾波器傳輸匕 ί二至光纖T2’並反射剩餘波長又3... λ"'ι]反射至 = 纟傳送訊號至包裝mc的第一輸入光纖。繼續這 ^1^然*後波長入3傳輸至包裝171〇内的光纖73。同樣地 ,波長;u傳輸至包裝171(1内的光纖T4。 也 纖12:'組170也可將訊號多工化。由包裝171a第二光 τί並搞人=訊號經由滤波器…傳送至傳輸光纖 ,並耗ό至包裝171b。在包步ιγι^φ 因而導致兩種波長被多工化以及連η匕 傳輸至包裝π… 對於那些熟悉此項枯 a ,項=的最佳實施 不迷U利靶圍明所界定之本發明的精神和範疇。581896 V. Description of invention (39), fiber 13. Wavelength; 12 ·: λη is reflected by the filter 24 to the optical fiber R2. The division wavelength A 1 is transmitted to the optical fiber R 2 through the filter 24. Therefore, long and 1 · h leave the package 171, so an additional channel or wavelength wave is multiplexed from the optical fiber 12 to the original signal. 、, Or Figure 16H is a schematic diagram of the eight-port package 166. This embodiment includes an η · :: input fiber coupled to four transmission fibers T1 ··· T4 via an input collimating lens 22, an optical element M, and an output collimating lens 34. Optical element: Filters of any shape are, for example, gain flattening filters or band-pass filters, and this embodiment is particularly suitable for use in crystal elements such as isolators: & selected optical elements. The embodiment of the last optical package of Bu Ma Ri is the eight-port add / remove device. Figure 丨 6! Is a schematic diagram of the package, which can add and remove two channels of two separate light signals. The operation mode is as follows: [The light signal is input with the wavelength λΐ ·. 'And' 2 are input by the optical fiber 11. The filter 24 is a band-pass filter, which can only pass the light of the wavelength j 1 and reflect other wavelengths. Therefore, the wavelength λ i is transmitted to the optical fiber, and _ the remaining wavelength; I 2 · · · and η is reflected to the optical fiber R1. The second signal with a wavelength input i ^ is input through the optical fiber I 2. The optical fiber 12 is optically paired with the optical fiber so the signal is filtered. The optical fiber R1 is coupled to the optical fiber R1, and the optical fiber R1 produces ^ Λ package wavelengths of j • • and n. Therefore, the original k with a wavelength of 1 and a new wavelength of 11 are added. For the optical fibers 13, 14, R2 and 72 also perform the same operation. However, in another embodiment, a streamlined module is built, as shown in Figure i 7 and 5 of the picture. "The four-channel add / remove module that is useful in communication systems is clear. Group. Combine four six-port filter packages 171 (such as those described in Figure 16 (ί 581896 V. Invention Description (40) =)) to build the module. It starts with demultiplexing (ie, goes =, contains Wavelength; U · · · and n demultiplexing signals pass through the first packer 7 1: Turn-in fiber II Into the package and collimated by the input lens 22. In addition, a part is transmitted through the filter 24a and transmitted through the transmission optical fiber η == the remaining wavelength; 12 ··· λη is reflected to the reflection optical fiber R1 and transmitted The first input fiber to two jl7lb. The filter in the package 17lb transmits two to the fiber T2 'and reflects the remaining wavelength and 3 ... λ "' ι] reflects to = 反射 sends a signal to the first input of the package mc Optical fiber. Continuing this ^ 1 ^ then * the wavelength in 3 is transmitted to the fiber 73 in the package 1710. Similarly, the wavelength; u is transmitted to the fiber 171 in the package 171 (1. The fiber 12: 'group 170 can also be Signal multiplexing. The second light from the package 171a is inductive and the signal is transmitted to the transmission fiber through the filter ... and consumed to the package 171b. In the packet step, the two wavelengths are multiplexed and connected. η is transmitted to the packaging π ... For those who are familiar with this subject, the best practice of the term = will not obscure the spirit and scope of the present invention as defined by the target.

第45頁 581896Page 581 896

附圖簡要說明: 第一圖(圖1)Brief description of the drawings: The first figure (Figure 1)

是本發明實施例之濾波器次 組件的透視 第二圖(圖2 )是圖1所示之次組件This is a perspective view of the filter sub-assembly of the embodiment of the present invention. The second figure (FIG. 2) is the sub-assembly shown in FIG. 1.

的部分垂直斷面示意 組件的 第三圖(圖3 )是本發明實施例之三端埠濾波器 垂直斷面示意圖; 第四圖和第四圖A (圖4和4 A)分別是應用於先前技術淚 波器組合中之先前技術套圈的放大垂直斷面,和右端圖; 第五圖和第五圖A (圖5和5 A)分別是應用在圖1和2之渡 波器次組件,和圖3之濾波器中之套圈的放大垂直斷面,和 右端圖; 第六圖(圖6)是本發明改良濾波器支架的放大垂直斷 面示意圖,同時顯示它的組合方法; 第七圖(圖7)顯示當紫外光線如圖6所示橫向傳播過遽 波器時,紫外線或熱固化接合粘合劑之前方聚合作用示意 圖; 第八圖(圖8 )顯示水銀光源的頻譜,其顯示出此紫外光 頻譜之主要部分; 第九圖(圖9)是使用於圖1,2,3和6的結構中之商用薄 膜濾波器所測得的紫外線透射頻譜; 第十圖(圖1 0)是圖6所示之次組件的加速無照射固化 和熱固化圖; 第Η 圖(圖11)是根據本發明一項之一個滤波器支架The third diagram (Fig. 3) of a schematic assembly of a part of the vertical cross-section is a schematic diagram of a vertical section of a three-terminal filter according to an embodiment of the present invention; the fourth diagram and the fourth diagram A (Figs. 4 and 4 A) are respectively applied Enlarged vertical cross section of the prior art ferrule in the prior art tear waver assembly, and right end view; Figures 5 and 5 A (Figures 5 and 5 A) are the waver sub-assemblies applied to Figures 1 and 2, respectively , And the enlarged vertical section of the ferrule in the filter of FIG. 3, and the right end diagram; the sixth diagram (FIG. 6) is a schematic diagram of the enlarged vertical section of the improved filter bracket of the present invention, and simultaneously shows its combination method; Figure 7 (Figure 7) shows the front polymerization of ultraviolet or heat-curing bonding adhesives when ultraviolet light travels through the chirped wave as shown in Figure 6. Figure 8 (Figure 8) shows the spectrum of the mercury light source. It shows the main part of this ultraviolet light spectrum; Figure 9 (Figure 9) is the ultraviolet transmission spectrum measured by the commercial thin-film filter used in the structure of Figures 1, 2, 3 and 6; Figure 10 (Figure 1 0) is the accelerated non-irradiation curing and thermal curing diagram of the subassembly shown in FIG. 6 FIG Η section (FIG. 11) is a filter of a stent according to the present invention

581896 圖式簡單說明 另一個實施例的透視圖; 第十二圖(圖1 2)是應用圖11所示之濾波器支架的三端 埠濾波器之垂直斷面示意圖; 第十三圖A(圖13A)是光纖套圈組合的斷面圖,其顯示 出圓形化方形毛細管; 第十三圖B(圖13B)是光纖套圈組合的斷面圖,其顯示 出雙橢圓形毛細管; 第十三圖C(圖13C)是光纖套圈組合的斷面圖,其顯示 出四個圓形毛細管; 第十三圖D(圖13D)是含有長方形毛細管的六光纖套圈 斷面圖; 第十三圖E(圖13E)是光纖套圈組合的斷面圖,其顯示 由形成在雙矽晶片中之對稱凹槽所形成的毛細管; 第十三圖F(圖13F)是由兩個晶片形成之光纖套圈的另 一個實施例; 第十三圖G(圖13G)是完成之雙晶片套圈在玻璃套管内 的斷面示意圖; 第十三圖Η(圖13H)顯示優先的V-凹槽和對準桿件之結 構; 第十三圖1(圖131)是光纖套圈的斷面圖,其顯示光纖 跟兩個晶片對準,以及塗覆液體粘合劑; 第十三圖J (圖1 3 J )是具有不同分隔距離之長方形毛細 管的光纖套圈斷面圖; 第十三圖J(圖13Κ)是具有不同分隔距離之雙長方形虹581896 is a perspective view briefly illustrating another embodiment; FIG. 12 (FIG. 12) is a schematic vertical sectional view of a three-terminal port filter using the filter bracket shown in FIG. 11; FIG. 13 (A 13A) is a cross-sectional view of an optical fiber ferrule assembly, which shows a rounded square capillary; FIG. 13B (FIG. 13B) is a cross-sectional view of an optical fiber ferrule assembly, which shows a double oval capillary; Thirteenth Figure C (Figure 13C) is a cross-sectional view of the fiber optic ferrule assembly, which shows four circular capillaries; Thirteenth Figure D (Figure 13D) is a cross-sectional view of a six-fiber ferrule containing a rectangular capillary; Thirteenth Figure E (Figure 13E) is a cross-sectional view of the fiber ferrule assembly, which shows a capillary formed by a symmetrical groove formed in a double silicon wafer; Thirteenth Figure F (Figure 13F) is composed of two wafers Another embodiment of the formed fiber ferrule; Thirteenth Figure G (Figure 13G) is a schematic cross-sectional view of the completed dual-chip ferrule in a glass sleeve; Figure Thirteen (Figure 13H) shows the preferred V- The structure of the groove and the alignment rod; Figure 13 (Figure 131) is a cross-sectional view of the optical fiber ferrule, which shows the optical fiber and two crystals Alignment of the wafers, and coating with liquid adhesive; Thirteenth Figure J (Figure 1 3 J) is a cross-sectional view of a fiber optic ferrule with rectangular capillary tubes with different separation distances; Thirteenth Figure J (Figure 13K) Double rectangular rainbows with different separation distances

第47頁 581896 圖式簡單說明 吸管的光纖套圈斷面圖; 第十三圖L(圖13L)是具有加長雙長方形毛細管的光纖 套圈斷面圖; 第十三圖Μ(圖13M)是具有雙橢圓形毛細管之光纖套圈 的斷面圖; 第十三圖Ν(圖13Ν)是具有三個毛細管之光纖套圈的斷 面圖; 第十四圖Α(圖14Α)是對準墊圈的圖形; 第十四圖B(圖14B)是使用對準墊圈之光纖套圈組合的 斷面分解圖; 第十五圖(圖1 5)是用來匹配光纖分隔距離和濾波器入 射角之範例表; 第十六圖A(圖16A)是四埠濾波器組件的示意圖; 第十六圖B(圖16B)是耦合到放大器之四埠濾波器組件 的示意圖; 第十六圖C(圖1 6C)是耦合到二個放大器之四璋濾波器 組件的不意圖; 第十六圖D(圖16D)是五埠濾波器包裝的示意圖; 第十六圖E(圖1 6E)是耦合到廢棄能源終端的六端埠濾 波為'包裝的不意圖; 第十六圖F (圖1 6F)是耦合到廢棄能源終站的六端埠濾 波器包裝的另一示意圖; 第十六圖G(圖16G)是六端埠增加/去除包裝的示意圖; 第十六圖Η(圖16H)是八埠光學包裝的示意圖;Page 581 896 is a schematic illustration of a cross section of an optical fiber ferrule with a straw; Thirteenth figure L (Fig. 13L) is a cross section of an optical fiber ferrule with an elongated double rectangular capillary; Thirteenth figure M (Fig. 13M) is Sectional view of a fiber ferrule with a double oval capillary; Figure 13N (Figure 13N) is a cross-sectional view of a fiber ferrule with three capillaries; Figure 14A (Figure 14A) is an alignment washer Figure 14 (Figure 14B) is an exploded cross-sectional view of a fiber ferrule assembly using an alignment washer; Figure 15 (Figure 15) is used to match the fiber separation distance and the incident angle of the filter Example table; Figure 16 (Figure 16A) is a schematic diagram of a four-port filter component; Figure 16 (B) is a schematic diagram of a four-port filter component coupled to an amplifier; Figure 16 (C) 16C) is the unintentional coupling of a four-channel filter assembly to two amplifiers; Figure 16D (Figure 16D) is a schematic diagram of a five-port filter package; Figure 16E (Figure 16E) is coupled to The six-terminal port filtering of the waste energy terminal is not intended for packaging; Figure 16F (Figure 16F) is a six-terminal coupling to the waste energy terminal Another schematic port filter package; sixteenth graph G (FIG. 16G) is a six-port end add / remove a schematic view of the package; FIG sixteenth [eta] (FIG. 16H) is a schematic view of the optical package eight ports;

第48頁 581896 圖式簡單說明 第十六圖1(圖161)是八埠增加/去除包裝的示意圖; 第十七圖(圖17)是連結六端埠包裝以形成DWDM模組的 示意圖。 附圖元件數字符號說明: 雙光纖準直及濾波器次組件1 0 ;金屬外殼1 2 ;位置 13;套管14;套圈16;輸入圓錐體17;輸入光纖18;毛細 管19 ;反射光纖20 ;毛細管21 ;準直透鏡22 ;濾波器24 ; 空腔2 5 ;濾波器支架2 6 ;軸向孔2 7 ;圓柱形孔2 9 ;三端埠 濾波器30;焊接材質31;金屬套管32;孔徑32A;輸出透 鏡34;準直組件35;玻璃套管36;金屬套管37;輸出光纖 38 ;套圈39, 40 ;毛細管42 ;毛細管44 ;圓錐形輸入段46 ; 區域4 7 ;基座5 0 ;黏接劑層5 5 ;光源6 0,6 1 ;紫外線輻射 63;細槽70;支架72;長方形毛細管130;光纖131;雙橢 圓毛細管1 3 2 ;四圓形毛細管1 3 3 ;毛細管1 3 4 ;晶片1 3 5 ; 對準毛細管136;對準桿件/針銷137;V形槽138;晶片 1 3 9 ;墊圈1 4 0 ;孔徑1 4 1 ;光纖1 4 2 ;扁平部份1 4 3 ;黏接劑 144;光纖160;四埠濾波器161;放大器162;五埠濾波器 163;終點站165;八埠包裝166;六端埠濾波器包裝171。Page 48 581896 Brief description of the drawings Figure 16 (Figure 161) is a schematic diagram of the eight-port adding / removing package; Figure 17 (Figure 17) is a schematic diagram of connecting the six-port package to form a DWDM module. Description of the numerical symbols of the attached elements: dual-fiber collimation and filter subassembly 10; metal shell 12; position 13; sleeve 14; ferrule 16; input cone 17; input fiber 18; capillary 19; reflective fiber 20 Capillary tube 21; Collimating lens 22; Filter 24; Cavity 2 5; Filter holder 2 6; Axial hole 2 7; Cylindrical hole 2 9; Three-terminal port filter 30; Welding material 31; Metal sleeve 32; aperture 32A; output lens 34; collimation assembly 35; glass tube 36; metal tube 37; output fiber 38; ferrules 39, 40; capillary 42; capillary 44; conical input section 46; area 4 7; Base 50; adhesive layer 5 5; light source 60, 6 1; ultraviolet radiation 63; fine groove 70; stent 72; rectangular capillary 130; optical fiber 131; double elliptical capillary 1 3 2; quadrangular capillary 1 3 3; capillary 1 3 4; wafer 1 3 5; alignment capillary 136; alignment rod / pin 137; V-groove 138; wafer 1 3 9; washer 1 40; aperture 1 4 1; fiber 1 4 2 Flat part 1 4 3; Adhesive 144; Fiber 160; Four-port filter 161; Amplifier 162; Five-port filter 163; Terminal 165; Eight-port package 166; Six-port filter package 171.

第49頁Page 49

Claims (1)

581896 六、申請專利範圍 1. 一種光學組件,其包含: 套圈,其具有至少一個毛細管軸向地延伸通過該套圈; 一組多條光纖,每一光纖具有心蕊及包層,放置在至少一 個毛細管内,每一條光纖之心蕊中心位置相對於一組多條 光纖之另外一條光纖心蕊中心滿足預先決定之誤差。 2. 依據申請專利範圍第1項之光學組件,其中心蕊中心位置 之誤差包含光纖橢圓率之誤差。 3. 依據申請專利範圍第1項之光學組件,其中心蕊中心位置 之誤差包含在光纖内心蕊同心圓之誤差。 4. 依據申請專利範圍第1項之光學組件,其中心蕊中心位置 之誤差包含光纖外徑之誤差。 5. 依據申請專利範圍第3項之光學組件,其中心蕊同心圓誤 差為$ 1. 0微米。 6. 依據申請專利範圍第4項之光學組件,其中光纖直徑誤差 為S 1. 0微米。 7. 依據申請專利範圍第2項之光學組件,其中光纖橢圓率誤 差為$0· 8%。 8. 依據申請專利範圍第3項之光學組件,其中心蕊同心圓誤 差為$ 0. 5微米。 9. 依據申請專利範圍第4項之光學組件,其中光纖直徑誤差 為$ 0. 5微米。 10. 依據申請專利範圍第2項之光學組件,其中光纖橢圓率 誤差為S0. 4%。 11. 依據申請專利範圍第3項之光學組件,其中心蕊同心圓581896 VI. Application for patent scope 1. An optical component comprising: a ferrule having at least one capillary extending axially through the ferrule; a set of multiple optical fibers, each optical fiber having a core and a cladding, placed on Within at least one capillary, the center position of the core of each fiber is relative to the center of the core of the other fiber of a group of multiple fibers to meet a predetermined error. 2. According to the optical component of the first patent application scope, the error of the central position of the center core includes the error of the ellipticity of the optical fiber. 3. According to the optical component according to the first patent application scope, the error of the center position of the center core includes the error of the concentric circle of the core core in the optical fiber. 4. For the optical component according to item 1 of the scope of patent application, the error of the center position of the central core includes the error of the outer diameter of the optical fiber. 5. The optical component according to item 3 of the patent application scope has a concentric circle error of $ 1.0 micron. 6. The optical component according to item 4 of the patent application scope, wherein the error of the fiber diameter is S 1.0 micron. 7. The optical component according to item 2 of the patent application scope, wherein the optical fiber ellipticity error is $ 0 · 8%. 8. The optical component according to item 3 of the scope of patent application has a concentric circle error of $ 0.5 micron. 9. The optical component according to item 4 of the scope of patent application, wherein the fiber diameter error is $ 0.5 micron. 10. The optical component according to item 2 of the scope of patent application, wherein the error of the ellipticity of the optical fiber is S 0.4%. 11. The optical component according to item 3 of the scope of patent application, the center core of which is concentric 第50頁 581896 六、申請專利範圍 誤差為$ 0. 1微米。 12.依據申請專利範圍第4項之光學組件,其中光纖直徑誤 差為S 0. 1微米。 1 3.依據申請專利範圍第2項之光學組件,其中光纖橢圓率 誤差為$0. 12%。 1 4.依據申請專利範圍第1項之光學組件,其中心蕊中心位 置之誤差包含光纖橢圓率之誤差以及光纖内心蕊同心圓之 誤差。 1 5.依據申請專利範圍第1項之光學組件,其中心蕊中心位 置之誤差包含光纖橢圓率之誤差以及光纖外徑之誤差。 1 6.依據申請專利範圍第1項之光學組件,其中心蕊中心位 置之誤差包含光纖外徑之誤差以及光纖内心蕊同心圓之誤 差。 1 7.依據申請專利範圍第1項之光學組件,其中心蕊中心位 置之誤差包含光纖橢圓率之誤差,光纖外徑之誤差,以及光 纖内心蕊同心圓之誤差。 1 8. —種光學組件,其包含: 套圈,其具有毛細管軸向地延伸通過該套圈,該毛細管滿 足毛細管尺寸之預先決定的誤差;以及 至少四條光纖放置於毛細管内,每一光纖具有心蕊及包 層,該光纖滿足心蕊同心圓以及包層外部尺寸之預先決定 誤差。 19. 一種組裝光學裝置之方法,其包含: 提供套圈,其具有至少一個毛細管轴向地延伸通過該套Page 50 581896 VI. Patent Application Range The error is $ 0.1 micron. 12. The optical component according to item 4 of the scope of patent application, wherein the error of the fiber diameter is S 0.1 micron. 1 3. The optical component according to item 2 of the scope of patent application, in which the optical fiber ellipticity error is $ 0.12%. 1 4. According to the optical component of the scope of the patent application, the error of the central position of the central core includes the error of the ellipticity of the fiber and the error of the concentric circle of the core inside the fiber. 1 5. According to the optical component of the first patent application scope, the error of the central position of the center core includes the error of the ellipticity of the fiber and the error of the outer diameter of the fiber. 1 6. According to the optical component of the scope of the patent application, the error of the central position of the central core includes the error of the outer diameter of the optical fiber and the error of the concentric circle of the inner core of the optical fiber. 1 7. According to the optical component of the first patent application scope, the error of the central position of the central core includes the error of the ellipticity of the fiber, the error of the outer diameter of the fiber, and the error of the concentric circle of the core inside the fiber. 1 8. An optical assembly comprising: a ferrule having a capillary tube extending axially through the ferrule, the capillary tube meeting a predetermined error in capillary size; and at least four optical fibers placed in the capillary tube, each optical fiber having Core and cladding, the fiber satisfies the predetermined error of the core concentric circle and the outer dimension of the cladding. 19. A method of assembling an optical device, comprising: providing a ferrule having at least one capillary tube extending axially through the ferrule 第51頁 581896 六、申請專利範圍 圈; 選擇一組多條光纖,每一光纖具有預先決定限制内之製 造誤差,製造誤差包含心蕊/包層同心圓誤差,光纖直徑誤 差,以及光纖橢圓率誤差之組合;以及 將光纖插入至少一個套圈毛細管中。 2 0.依據申請專利範圍第18項之方法,其中選擇一組多條光 纖使得每一心蕊/包層同心圓誤差小於1. 0微米。 2 1.依據申請專利範圍第1 8項之方法,其中選擇一組多條光 纖使得每一光纖直徑小於1. 0微米。 2 2.依據申請專利範圍第18項之方法,其中選擇一組多條光 纖使得每一光纖之橢圓率小於0. 8%。Page 51 581896 6. Patent application circle; select a group of multiple optical fibers, each of which has a manufacturing error within a predetermined limit. The manufacturing error includes the core / clad concentric circle error, the fiber diameter error, and the fiber ellipticity. A combination of errors; and inserting the optical fiber into at least one ferrule capillary. 0. The method according to item 18 of the scope of patent application, wherein a group of multiple optical fibers is selected so that the concentric circle error of each core / cladding is less than 1.0 micron. 2 1. The method according to item 18 of the scope of patent application, wherein a group of a plurality of optical fibers is selected such that the diameter of each optical fiber is less than 1.0 microns. 2 2. The method according to item 18 of the scope of patent application, wherein a plurality of optical fibers is selected such that the ellipticity of each optical fiber is less than 0.8%. 第52頁Page 52
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