CN102520509B - photonic crystal optical fiber splicing imaging system - Google Patents

Abstract

The invention discloses a photonic crystal optical fiber splicing imaging system, comprising a first imaging unit and a second imaging unit which are respectively used for obtaining the images of the end surfaces of two spliced photonic crystal fibers arranged oppositely. The first imaging unit comprises a light source module and a microscopy imaging module, wherein the light source module is arranged on one side of the end surface of a first photonic crystal fiber to be spliced, and irradiates the emitted light on the end surface, and the microscopy imaging module is positioned on one side on which the light source module is arranged, and is used for receiving the light reflected by the end surface and obtaining the image of the end surface; the structure of the second imaging unit is the same as that of the first imaging unit, the set positions of the all modules included by the second imaging unit, relative to the end surface of a second photonic crystal fiber to be spliced, are the same as those of the all modules included by the first imaging unit, relative to the end surface of the first photonic crystal fiber. The photonic crystal fiber splicing imaging system fully considers the influences of the factors such as stray light, reflected light, coherent light and the like, simultaneously obtains the images of the end surfaces of the two spliced fibers due to the design ofa transition light path, is simple in structure, has a clear image, and meets the splicing demands.

Description

The photon crystal optical fiber fusion splicing imaging system

Technical field

The present invention relates to the photon crystal optical fiber fusion splicing technology, particularly relate to a kind of photon crystal optical fiber fusion splicing imaging system.

Background technology

PCF(Photonic Crystal Fiber, photonic crystal fiber) claim HF(Holey Fiber, porous optical fiber again) or MOF (Microstructure Optical Fibers, microstructured optical fibers), coming out from it just causes various countries scholar's extensive concern.PCF has the unexistent unusual characteristic of a lot of ordinary optic fibres, as high non-linearity, chromatic dispersion controllable characteristics, high birefringence rate, unlimited unimodular property, big single mode mould field etc., can be widely used in fields such as communication, imaging, spectroscopy and biomedicine.Along with the further investigation to PCF characteristic and production technology, people begin its application of extensive exploratory development, as exploitation PCF sensor, PCF laser instrument, PCF nonlinear application and the application of photonic crystal polarization maintaining optical fibre etc.All be faced with the fusion techniques problem of PCF in these are used, this has caused a lot of scholars' very big concern.The geometry of PCF complexity makes fusion process become more complicated, when welding, and the accurate aligning of two optical fiber, the power that welding system provides, the time of welding, low-loss calculating etc. all need to obtain the end face information of PCF.But, the imaging system that adopts the conventional optical fibers heat sealing machine is during to the photonic crystal fiber imaging, the sharpness of image is lower, and because the existence of PCF covering airport, make imaging system be difficult to find the fibre core of optical fiber, adopt the PCF outward flange can increase deviation of the alignment again as alignment fiducials, the welding quality is reduced, can not satisfy the welding demand.So, at PCF, need have specific imaging system to satisfy the needs of its welding.

Summary of the invention

(1) technical matters that will solve

The technical problem to be solved in the present invention provides a kind of photon crystal optical fiber fusion splicing imaging system, and to overcome prior art in the photon crystal optical fiber fusion splicing process, image definition is low, can not satisfy the defective of welding demand.

(2) technical scheme

In order to solve the problems of the technologies described above, the invention provides a kind of photon crystal optical fiber fusion splicing imaging system, it comprises: first image-generating unit and second image-generating unit are respectively applied to obtain the end view drawing picture over against two photonic crystal fibers that are fused of placing;

Described first image-generating unit comprises: light source module, be arranged on the first photonic crystal fiber end face, one side that is fused, and be used for the light that sends is radiated at described end face; The micro-imaging module is positioned at the side at described light source module place, is used for receiving the light of described end face reflection, and obtains described end view drawing picture;

The structure of described second image-generating unit is identical with the structure of described first image-generating unit, it each module that comprises with respect to the second photonic crystal fiber end face that is fused arrange position and each module of first image-generating unit with respect to the first photonic crystal fiber end face that the position is set is identical.

Wherein, described light source module comprises:

Illuminating source;

Collimation lens is arranged on described illuminating source the place ahead, is used for the light that described illuminating source the sends processing that collimates;

Polarization splitting prism is arranged on described collimation lens the place ahead, is used for the collimated ray after handling through described collimation lens is carried out light-splitting processing, is divided into P light and S light, the transmission of P light, S light total reflection;

Catoptron is arranged on described first photonic crystal fiber end face the place ahead, and its reflecting surface and P light light and the first photonic crystal fiber axis be angle at 45 all, is used for P light reflection back is shone to the first photonic crystal fiber end face;

Quarter wave plate is arranged between the described first photonic crystal fiber end face and the catoptron, be used for to see through P light, and the P light that sees through for twice is converted to S light.

Wherein, described micro-imaging module comprises:

Amplification module is arranged on described polarization splitting prism one side, is used for amplifying carrying out optics through the S light that has the first photonic crystal fiber end face information of quarter wave plate, catoptron and polarization splitting prism successively behind the described first photonic crystal fiber end face reflection;

Image-forming module links to each other with described amplification module, is used for the described first photonic crystal fiber end face is carried out imaging.

Wherein, described amplification module comprises object lens and the eyepiece of coaxial setting.

Wherein, described image-forming module is CCD(Charge-coupled Device, charge coupled cell) the micro-imaging module.

Wherein, described system also comprises: control module, link to each other with quarter wave plate with described catoptron, and be used for after the micro-imaging module is obtained the first photonic crystal fiber end view drawing picture, catoptron and quarter wave plate being removed.

Wherein, described catoptron and quarter wave plate are encapsulated on the platform.

Wherein, described catoptron is double mirror, two reflecting surface respectively with the axis angle at 45 of two photonic crystal fibers that are fused.

Wherein, described illuminating source is LED(Light Emitting Diode, light emitting diode) light source.

Wherein, described polarization splitting prism is Glan-Taylor's polarization splitting prism.

(3) beneficial effect

Photon crystal optical fiber fusion splicing imaging system of the present invention, take into full account the influence of factors such as parasitic light, reflected light, coherent light, utilized the selection trafficability characteristic of polarized light, can reduce optical energy loss on the one hand, also can avoid simultaneously the generation of interference, improve image quality; Control module can be realized the control to catoptron and quarter wave plate, behind the end view drawing picture that gets access to optical fiber fusion, it is removed, for ensuing aligning and welding work are prepared; CCD micro-imaging module adopts numeral to amplify again through after Liar and the eyepiece amplification, and integral body can reach the enlargement factor more than 1500 times, can satisfy the needs of the follow-up identification of fiber end face image.Photon crystal optical fiber fusion splicing imaging system of the present invention can obtain to be melted the end face information of optical fiber in real time, for photon crystal optical fiber fusion splicing provides sufficient parameter foundation.

Description of drawings

Fig. 1 is the schematic diagram of a kind of photon crystal optical fiber fusion splicing imaging system of the embodiment of the invention.

Wherein, 1: the PCF; 2: the two PCF; 3: the first collimation lenses; 4: the first polarization splitting prisms; 5: double mirror; 6: the first quarter wave plates; 7: the first object lens; 8: the first eyepieces; 9: the second collimation lenses; 10: the second polarization splitting prisms; 11: the second quarter wave plates; 12: the second object lens; 13: the second eyepieces.

Embodiment

Below in conjunction with drawings and Examples, the specific embodiment of the present invention is described in further detail.Following examples are used for explanation the present invention, but are not used for limiting the scope of the invention.

The schematic diagram of a kind of photon crystal optical fiber fusion splicing imaging system of the embodiment of the invention as shown in Figure 1, described system comprises first image-generating unit and second image-generating unit, is respectively applied to obtain over against the end view drawing picture of two photonic crystal fibers that are fused of placing.In the present embodiment, the molten photonic crystal fiber of two velamens is designated as a PCF1 and the 2nd PCF2 respectively, and imaging system is obtained the end view drawing picture of a PCF1 and the 2nd PCF2 simultaneously.The structure of image-generating unit of end view drawing picture that is used for obtaining two optical fiber is identical, in first image-generating unit each module with respect to a PCF1 arrange each module in position and second image-generating unit with respect to the 2nd PCF2 that the position is set is identical.Be example with first image-generating unit below, introduce its structure and principle of work in detail.

First image-generating unit mainly comprises light source module and micro-imaging module, light source module is used for its light that sends is shone the molten end face of quilt of a PCF1, the micro-imaging module is used for receiving the light by molten fiber end face reflection, obtains by molten fiber end face image.In the present embodiment, light source module specifically comprises the led light source as illuminating source; Coaxial first collimation lens, 3, the first collimation lenses 3 of the light that is arranged on led light source the place ahead and sends with led light source are used for the light that led light source the sends processing that collimates; First collimation lens, 3 the place aheads are provided with first polarization splitting prism 4, are used for the collimated ray after 3 processing of first collimation lens is carried out light-splitting processing, are divided into the P with respect to 4 transmissions of first polarization splitting prism ₁The S of light and total reflection ₁Light; In first polarization splitting prism, 4 the place aheads, also be provided with double mirror 5, double mirror 5 is positioned at the place ahead that a PCF1 is melted end face simultaneously, and its reflecting surface respectively with P through 4 transmissions of first polarization splitting prism ₁Light light and PCF1 axis angle at 45 make that shining the light that a PCF1 melted on the end face can return according to former road; Double mirror 5 and a PCF1 are melted also to be provided with first quarter wave plate, 6, the first quarter wave plates 6 and can to see through P between the end face ₁Light, and can be with the double P that sees through ₁Light is converted to S ₂Light makes S ₂Light is through double mirror 5 reflections, again through 4 total reflections of first polarization splitting prism, in the side ejaculation of first polarization splitting prism 4.

Corresponding with above-mentioned light source module structure, the micro-imaging module specifically comprises amplification module and the image-forming module of being made up of first object lens 7 and first eyepiece 8; Amplification module is arranged on first polarization splitting prism 4 and transmits and have the S that a PCF1 is melted end face information ₂One side of light is used for S ₂Light carries out optics and amplifies; Image-forming module links to each other with amplification module, is carried out imaging so that a PCF1 melts end face, and image-forming module is CCD micro-imaging module among the embodiment.

In the present embodiment, select led light source as illuminating source, be because led light source has characteristics such as energy-saving and environmental protection, the life-span is long, volume is little, the more important thing is, led light source has considerable characteristic concerning image is handled, be that it is direct drive, luminance brightness can keep constant for a long time, and common halogen family all is to exchange driving with fluorescent light, luminance brightness also can corresponding one-tenth sinusoidal variation, particularly when the frequency of high speed camera collection has been higher than the frequency of light source, just is difficult to when gathering image obtain consistent illumination, even " black " can occur.The lighting system of led light source is selected coaxial front light-source lighting system for use, this kind lighting system, light source and camera lens are equidirectional goes out, at first blush, camera lens itself is a light source seemingly, use a semi-permeable mirror to place video camera the place ahead with 45, beat diffusion light from the next door of mirror, the light of half can be via specularly reflected to object, and second half then passes mirror and disappears, as for the light that reflects from object, half is sent back and passes mirror, and imaging on video camera, second half then passes mirror and disappears, this principle is described just as above-mentioned light source module structure, adopts polarization splitting prism and catoptron to realize coaxial front light-source lighting system.

In the present embodiment, first polarization splitting prism 4 is selected Glan-Taylor's polarization splitting prism for use, because Glan-Taylor's polarization splitting prism when the light that led light source can be sent is divided into the S light of the P light of transmission and total reflection, has wideer wave band and the higher light beam transmitance of seeing through.It sees through wavelength and may extend to ultraviolet band, because the incident angle of its incident ray on air interface be near Brewster angle, it is minimum to make reflection loss drop to.Carrying out the light reflection, make in the design that light returns according to former road, present embodiment is selected double mirror 5 for use, its effect is to utilize an optical element, realize the reflection function of light in first image-generating unit and second image-generating unit simultaneously, reduce the quantity of optical element set between the molten fiber end face of two velamens, make the molten fiber end face of two velamens under situation about approaching as far as possible, obtain its end view drawing picture, realize its aligning and welding; Certainly adopt two single face catoptrons also to be fine as the catoptron of first image-generating unit and second image-generating unit respectively.

In the present embodiment, the selection of first quarter wave plate 6, be based on following principle: when linearly polarized light with the fast axle clamp of quarter wave plate angle be after 45 impinges perpendicularly on wave plate, when this left circularly polarized light process reflection, again vertically by behind the quarter wave plate, emergent ray is linearly polarized light, and this emerging ray polarized light is with respect to former incident ray polarized light, and direction of vibration turns over

Based on this, twice of the P light of being told by first polarization splitting prism 4 is vertical by after first quarter wave plate 6, conversion is for S light, when the former road of S light is back to first polarization splitting prism 4, realize total reflection, become 90 ° of angles to depart from initial light by led light source directive first polarization splitting prism 4, the space of abundance is provided for the setting of micro-imaging module.

In the present embodiment, under the situation that approaches as far as possible, obtain its end view drawing picture in order to satisfy the molten optical fiber of two quilts, to reduce the error of follow-up alignment procedures, reduce splice loss, splice attenuation, completely reflecting mirror 5, two quarter wave plates 6 and 11 need be encapsulated on the chain-wales, by control module control chain-wales in the position at optical fiber fusion place, behind the end view drawing picture that gets access to optical fiber fusion, it is removed, for ensuing aligning and welding work are prepared.

After imaging system built according to said structure, namely can be used for obtaining by molten fiber end face image in the photon crystal optical fiber fusion splicing process, its course of work is: the led light source of first image-generating unit and second image-generating unit is luminous respectively, the light that the led light source of first image-generating unit sends becomes a branch of directional light through first collimation lens 3 with beam collimation, is divided into P by first polarization splitting prism 4 then ₁Light and S ₁Light, the effect of Amici prism herein is to P ₁Light is realized transmission, S ₁Light total reflection; P after the beam splitting ₁Light by shining on the PCF1 end face behind first quarter wave plate 6, has the P that a PCF1 is melted end face information by double mirror 5 reflections ₁Light is again by shining on the double mirror 5 (P light through twice quarter wave plate then become S light) behind first quarter wave plate 6; The S that returns ₂Light enters the imaging of CCD micro imaging system after double mirror 5 and 4 reflections of first polarization splitting prism.

Equally, the light that the led light source of second image-generating unit sends becomes a branch of directional light through second collimation lens 9 with beam collimation, is divided into P by second polarization splitting prism 10 then ₁Light and S ₁Light, the effect of Amici prism herein is to P ₁Light is realized transmission, S ₁Light total reflection; P after the beam splitting ₁Light by shining on the 2nd PCF2 end face behind second quarter wave plate 11, has the P that the 2nd PCF2 is melted end face information by double mirror 5 reflections ₁Light is again by shining on the double mirror 5 S that returns behind second quarter wave plate 11 ₂Light enters the imaging of CCD micro imaging system after double mirror 5 and 10 reflections of second polarization splitting prism.Two micro imaging systems to being looked like to carry out imaging by molten photonic crystal fiber end view drawing, further obtain the end face image information by image processing and identification system simultaneously again, for aligning and the welding of photonic crystal fiber provides reference frame.

As can be seen from the above embodiments, the embodiment of the invention has taken into full account the influence of factors such as parasitic light, reflected light, coherent light, utilizes the selection trafficability characteristic of polarized light, can reduce optical energy loss on the one hand, also can avoid simultaneously the generation of interference, improve image quality; Control module can be realized the control to catoptron and quarter wave plate, behind the end view drawing picture that gets access to optical fiber fusion, it is removed, for ensuing aligning and welding work are prepared; CCD micro-imaging module adopts numeral to amplify again through after Liar and the eyepiece amplification, and integral body can reach the enlargement factor more than 1500 times, can satisfy the needs of the follow-up identification of fiber end face image.Photon crystal optical fiber fusion splicing imaging system of the present invention can obtain to be melted the end face information of optical fiber in real time, for photon crystal optical fiber fusion splicing provides sufficient parameter foundation.

The above only is preferred implementation of the present invention; should be pointed out that for those skilled in the art, under the prerequisite that does not break away from the technology of the present invention principle; can also make some improvement and replacement, these improvement and replacement also should be considered as protection scope of the present invention.

Claims (9)

1. the photon crystal optical fiber fusion splicing imaging system is characterized in that, described system comprises first image-generating unit and second image-generating unit, is respectively applied to obtain the end view drawing picture over against two photonic crystal fibers that are fused of placing;

Described first image-generating unit comprises: light source module, be arranged on the first photonic crystal fiber end face, one side that is fused, and be used for the light that sends is radiated at described end face; The micro-imaging module is positioned at the side at described light source module place, is used for receiving the light of described end face reflection, and obtains described end view drawing picture;

The structure of described second image-generating unit is identical with the structure of described first image-generating unit, it each module that comprises with respect to the second photonic crystal fiber end face that is fused arrange position and each module of first image-generating unit with respect to the first photonic crystal fiber end face that the position is set is identical;

Described light source module comprises:

Illuminating source;

Collimation lens is arranged on described illuminating source the place ahead, is used for the light that described illuminating source the sends processing that collimates;

Polarization splitting prism is arranged on described collimation lens the place ahead, is used for the collimated ray after handling through described collimation lens is carried out light-splitting processing, is divided into P light and S light, the transmission of P light, S light total reflection;

Catoptron is arranged on described first photonic crystal fiber end face the place ahead, and its reflecting surface and P light light and the first photonic crystal fiber axis be angle at 45 all, is used for P light reflection back is shone to the first photonic crystal fiber end face;

Quarter wave plate is arranged between the described first photonic crystal fiber end face and the catoptron, be used for to see through P light, and the P light that sees through for twice is converted to S light.

2. photon crystal optical fiber fusion splicing imaging system according to claim 1 is characterized in that, described micro-imaging module comprises:

Amplification module is arranged on described polarization splitting prism one side, is used for amplifying carrying out optics through the S light that has the first photonic crystal fiber end face information of quarter wave plate, catoptron and polarization splitting prism successively behind the described first photonic crystal fiber end face reflection;

Image-forming module links to each other with described amplification module, is used for the described first photonic crystal fiber end face is carried out imaging.

3. photon crystal optical fiber fusion splicing imaging system according to claim 2 is characterized in that, described amplification module comprises object lens and the eyepiece of coaxial setting.

4. photon crystal optical fiber fusion splicing imaging system according to claim 2 is characterized in that, described image-forming module is CCD micro-imaging module.

5. photon crystal optical fiber fusion splicing imaging system according to claim 1, it is characterized in that, described system also comprises: control module, link to each other with quarter wave plate with described catoptron, and be used for after the micro-imaging module is obtained the first photonic crystal fiber end view drawing picture, catoptron and quarter wave plate being removed.

6. photon crystal optical fiber fusion splicing imaging system according to claim 5 is characterized in that, described catoptron and quarter wave plate are encapsulated on the platform.

7. photon crystal optical fiber fusion splicing imaging system according to claim 1 is characterized in that, described catoptron is double mirror, two reflecting surface respectively with the axis angle at 45 of two photonic crystal fibers that are fused.

8. according to each described photon crystal optical fiber fusion splicing imaging system of claim 1 to 7, it is characterized in that described illuminating source is led light source.

9. according to each described photon crystal optical fiber fusion splicing imaging system of claim 1 to 7, it is characterized in that described polarization splitting prism is Glan-Taylor's polarization splitting prism.