CN209280994U - A kind of the variable optical attenuation device and system of integrated light splitting detecting function - Google Patents

Abstract

The utility model relates to optical device fields, more particularly to the variable optical attenuation device and system of a kind of integrated light splitting detecting function, variable optical attenuation device includes cavity, input optical fibre, reflecting mirror, spectroscope, photodetector and output optical fibre, input optical fibre and output optical fibre are located inside cavity, optical signal directive reflecting mirror after the transmission of input optical fibre, optical signal is reflected into spectroscope by reflecting mirror, optical signal is divided into two bundles optical signal by spectroscope, wherein a branch of optical signal directive photodetector, optical power is detected by photodetector, in addition a branch of optical signal is emitted back towards reflecting mirror, optical signal is reflected into output optical fibre by reflecting mirror, by output optical fibre output optical signal.It can be realized the detection of optical power while realizing optical attenuation, so as to which the optical signal of input is adjusted, promoted horizontal to the precision controlling of optical power attenuation；Also, each device can be integrally disposed, greatly reduces volume.

Description

A kind of the variable optical attenuation device and system of integrated light splitting detecting function

Technical field

The utility model relates to optical device fields, and in particular to a kind of variable optical attenuation dress of integrated light splitting detecting function It sets and system.

Background technique

Optical attenuator is a kind of very important fibre optics passive device, it can be by the requirement of user by light signal energy Expectedly decayed, is usually used in the loss and various tests that absorb or reflect away optical power surplus, assessment system.Currently, Seriation optical attenuator is widely used to optical communication field, brings great convenience to user.

But there are mainly two types of the optical attenuators of existing integrated light splitting detecting function, the first is logical for two discrete devices It crosses optical fiber to be cascaded, can refer to Fig. 1 a: after light is input to the input terminal of wire jumper 2 by optical fiber 1,3 surface of lens is coated with one Layer spectro-film, light beam are projected from lens 3, enter back into photodetection 4, realize power detection, and another light beam is anti-from lens 3 It is mapped to wire jumper 2, using the output end of wire jumper 2, and passes through the input terminal that optical fiber 1 is emitted to next wire jumper 5, by another lens 6, and be incident on MEMS mirror as in chip 7, MEMS mirror reflects light back into lens 6 as chip 7, lens 6 using wire jumper 5 output End, and light output is carried out by optical fiber 1.But this kind of optical attenuator is realized by multiple devices in series, overall volume compared with Greatly, there are limitations in application environment.

Second is light-barrier type optical attenuator, can refer to Fig. 1 b, and the light of incident optical 10a output is light-blocking by MEMS To decay chip 20, is output to lens 30, is coated with spectro-film 30a on lens 30, light passes through after 30a, it is divided into two-beam, one Some light is reflected back optical fiber 10b, in addition a branch of to be transmitted through on photoelectric converter 40, wherein decaying chip 20 realizes declining for light Down control, photodetector 40 realize the detection to incident light optical power.But this kind of optical attenuator generallys use hot drive Dynamic, stability is poor.

Utility model content

The technical problem to be solved by the present invention is in view of the above drawbacks of the prior art, provide a kind of collection ingredient The variable optical attenuation device and system of optical detection function solve existing optical attenuator and need multiple devices in series compositions, integrate Property the difference and larger problem of volume.

To solve this technical problem, the utility model provides a kind of variable optical attenuation device of integrated light splitting detection, described Variable optical attenuation device includes cavity, input optical fibre, reflecting mirror, spectroscope, photodetector and output optical fibre, the input Optical fiber and output optical fibre are located inside cavity, and optical signal directive reflecting mirror after the transmission of input optical fibre, the reflecting mirror will Optical signal is reflected into spectroscope, and optical signal is divided into two bundles optical signal by the spectroscope, wherein a branch of optical signal directive photoelectricity is visited Device is surveyed, optical power is detected by photodetector, in addition a branch of optical signal is emitted back towards reflecting mirror, and optical signal is reflected by the reflecting mirror Output optical fibre, by output optical fibre output optical signal.

Wherein, preferred version is: the variable optical attenuation device further includes MEMS chip, and the reflecting mirror is located at MEMS core The surface of piece.

Wherein, preferred version is: the variable optical attenuation device further includes the first lens, and optical signal is by input optical fibre The first lens of directive after transmission, and through the first lens directive reflecting mirror；The optical signal for being emitted back towards reflecting mirror passes through the reflection of reflecting mirror The first lens of directive afterwards, and through the first lens directive output optical fibre.

Wherein, preferred version is: the axis of the reflecting mirror and the first lens is at an acute angle.

Wherein, preferred version is: the surface of the cavity is parallel with the surface of first lens, and the input optical fibre is penetrated Optical signal out injects the first lens.

Wherein, preferred version is: the variable optical attenuation device further includes the second lens, and second lens and photoelectricity are visited The neighbouring setting of device is surveyed, the second lens directive photodetector again is first passed through by spectroscopical optical signal.

Wherein, preferred version is: the surface of the second lens is arranged in the spectroscope.

Wherein, preferred version is: the cavity is capillary.

Wherein, preferred version is: the variable optical attenuation device further includes shell, first substrate and the second substrate, described First substrate and the second substrate are located at enclosure interior, and the reflecting mirror is placed on the first substrate, and the spectroscope and photoelectricity are visited Device is surveyed to be placed in the second substrate.

The utility model also provides a kind of variable optical attenuation system of integrated light splitting detecting function, the variable optical attenuation system System includes optical transmitting set, optical receiver and variable optical attenuation device as described above, and the optical transmitting set projects optical signal, light Optical signal is reflected into spectroscope, the spectroscope by signal directive reflecting mirror after the transmission of input optical fibre, the reflecting mirror Optical signal is divided into two bundles optical signal, wherein a branch of optical signal directive photodetector, the photodetector detects optical power, In addition a branch of optical signal is emitted back towards reflecting mirror, and optical signal is reflected into output optical fibre, the output optical fibre output light by the reflecting mirror Signal is to optical receiver.

The beneficial effects of the utility model are that compared with prior art, the utility model is by designing a kind of collection ingredient The variable optical attenuation device and system of optical detection function can be realized the detection of optical power while realizing optical attenuation, from And the optical signal of input can be adjusted, it is promoted horizontal to the precision controlling of optical power attenuation；Also, each device can collect At setting, single individual devices are constituted, rather than are connected in series by optical fiber, volume can be substantially reduced；And reflecting mirror is set On the surface of MEMS chip, MEMS chip usually by electrostatic drive, is able to ascend the stability of device.

Detailed description of the invention

Below in conjunction with accompanying drawings and embodiments, the utility model is described in further detail, in attached drawing:

Fig. 1 a is the schematic diagram of the light attenuation device of existing integrated light splitting detection；

Fig. 1 b is the schematic diagram of the light attenuation device of existing another integrated light splitting detection；

Fig. 2 a, 2b are the schematic diagrames of the variable optical attenuation device of the integrated light splitting detection of the utility model；

Fig. 3 is the schematic diagram for the variable optical attenuation device that the utility model is equipped with shell；

Fig. 4 is the schematic diagram for the variable optical attenuation device that the utility model right-angle prism substitutes the second prism.

Specific embodiment

Now in conjunction with attached drawing, elaborate to the preferred embodiment of the utility model.

As shown in Fig. 2 a to Fig. 4, the utility model provides a kind of variable optical attenuation device of integrated light splitting detecting function Preferred embodiment.

Specifically, with reference to Fig. 2 a, a kind of variable optical attenuation device of integrated light splitting detecting function, the variable optical attenuation dress It sets including cavity 13, input optical fibre 11, reflecting mirror 31, spectroscope 41, photodetector 43 and output optical fibre 12, the input Optical fiber 11 and output optical fibre 12 are located inside cavity 13, the reflecting mirror 31 and the neighbouring setting of spectroscope 41, the spectroscope 41 With the neighbouring setting of photodetector 43.Wherein, with reference to Fig. 2 a, the optical signal that outside generates is penetrated after the transmission of input optical fibre 11 To reflecting mirror 31, optical signal is reflected into spectroscope 41 by the reflecting mirror 31；Optical signal is divided into two bundles light by the spectroscope 41 Signal continues transmission and directive photodetector 43, the photoelectricity from spectroscope 41 wherein a branch of optical signal is used for Photoelectric Detection Detector 43 converts optical signals to electric signal, realizes the detection of optical power；In addition a branch of optical signal is used for optical attenuation, from light splitting Mirror 41 reflects reflective back mirror 31, and the reflecting mirror 31 again reflects optical signal, and optical signal is reflected into output optical fibre 12 Position, 12 output optical signal of output optical fibre.Then, with reference to Fig. 2 b, it is inclined that angle occurs in the position of the reflecting mirror 31 Turn, the optical signal of final directive output optical fibre 12 deviates from output optical fibre 12, to produce coupling loss, realizes light decay Subtract, the output optical fibre 12 again exports the optical signal after optical attenuation.Optical attenuation and Photoelectric Detection are all optical communication networks Basic device, especially in erbium-doped fiber amplifier, therefore, above-mentioned device is all extremely easy to get.The variable optical attenuation dress The detection that can be realized optical power while realizing optical attenuation by tilting mirror principle is set, so as to carry out to the optical signal of input It adjusts, is promoted horizontal to the precision controlling of optical power attenuation；Also, each device can be integrally disposed, constitutes single independence Device, rather than be connected in series by optical fiber, volume can be substantially reduced；In addition, optical signal actually have passed through reflecting mirror twice 31, in the case where 31 angles and positions of reflecting mirror are constant, the deflection angle that optical signal actually occurs is one times originally, is It says, under the same driving voltage of optical signal, the final device for receiving optical signal can obtain bigger attenuation, also Reduce the requirement to maximum drive voltage.

In the present embodiment, with reference to Fig. 2 a, the variable optical attenuation device further includes MEMS chip 32, and (English is complete by MEMS Referred to as Micro-Electro-Mechanical System) it is MEMS, size is at several millimeters or even smaller, is that collection is micro- The micro- energy of sensor, microactrator, micro mechanical structure, micro battery, signal processing and control circuit, high-performance electric sub-integrators Part, interface, communication etc. are located at the surface of MEMS chip 32 in the intelligent micro device of one, the reflecting mirror 31, it may also be said to, The reflecting mirror 31 is exactly a part of MEMS chip 32.Normally, the MEMS chip 32 therefore, is held by electrostatic drive Precision easy to control can also greatly improve stability.

Further, with reference to Fig. 2 a, the variable optical attenuation device further includes the first lens 21, and first lens 21 can For self-focusing lens, globe lens or non-spherical lens, first lens 21 are arranged between cavity 13 and reflecting mirror 31, outside The optical signal that portion generates first lens of directive 21 after the transmission of input optical fibre 11,21 refracted optical signal of the first lens, Optical signal is reflected into spectroscope 41 by directive reflecting mirror 31 again, the reflecting mirror 31, and optical signal is divided into two by the spectroscope 41 Beam optical signal, wherein light beam reflect reflective back mirror 31, the first lens of directive 21 after the reflecting mirror 31 again reflects optical signal, And the directive output optical fibre 12 after the collimation of the first lens 21, the output optical fibre 12 output optical signal again.Wherein, described anti- The axis of mirror 31 and the first lens 21 is penetrated in predetermined angle, i other words, the reflecting mirror 31 and the light for being incident on input optical fibre 11 Signal is in predetermined angle, and the predetermined angle is at an acute angle, and specifically, the predetermined angle is within the scope of 5 ° to 85 °.It is preferred that Ground, the surface of the cavity 13 and the surface of first lens 21 are parallel to each other, also, the two surface is neighboar lists Face, the optical signal that the input optical fibre 11 projects injects the first lens 21 along same straight line, then passes through the folding of the first lens 21 Penetrate rear directive reflecting mirror 31.

Still further, the variable optical attenuation device further includes the second lens 42, second lens 42 with reference to Fig. 2 a With the neighbouring setting of photodetector 43, it is specifically located between reflecting mirror 31 and photodetector 43, the spectroscope 41 separates Wherein a branch of optical signal directive photodetector 43, the photodetector 43 realize photoelectricity again after the second lens 42 Detection.Preferably, the surface of the second lens 42 is arranged in the spectroscope 41.Certainly, 42 surface of the second lens can also be with It directly is coated with first layer spectro-film, to substitute spectroscope 41.Second lens 42 can for self-focusing lens, globe lens or Non-spherical lens.Even, if the photosurface of photodetector 43 is sufficiently large, second lens 42 can also be by curvature half The plane mirror of diameter infinity is substituted.

Alternatively, the variable optical attenuation device further includes right-angle prism 45 with reference to Fig. 4, the right-angle prism 45 and photoelectricity The neighbouring setting of detector 43, is specifically located between reflecting mirror 31 and photodetector 43, the spectroscope 41 separates wherein A branch of optical signal passes through after right-angle prism 45, and optical signal is deflected 90 °, then directive photodetector by the right-angle prism 45 43, the photodetector 43 still can be realized Photoelectric Detection.Preferably, right-angle prism 45 is arranged in the spectroscope 41 Surface.From above-mentioned it can be seen that, herein without limiting the specific device between reflecting mirror 31 and photodetector 43, as long as final warp Cross spectroscope 41 light splitting optical signal can directive photodetector 43, guarantee realize photoelectric detection function.

In the present embodiment, the cavity 13 is preferably capillary, and capillary refers to that internal diameter is equal to or less than 1 millimeter Tubule, volume is very small, for penetrating optical fiber.

Again specifically, with reference to Fig. 3, the variable optical attenuation device further includes shell 51, first substrate 33 and the second substrate 44, the first substrate 33 and the second substrate 44 are located inside shell 51, and first lens 21 are fastened on shell 51, described Reflecting mirror 31 and MEMS chip 32 are placed on first substrate 33, the spectroscope 41, the second lens 42 and photodetector 43 It is placed in the second substrate 44.Seal chamber is formed inside the shell 51, can be reflecting mirror 31, the MEMS being placed in seal chamber Chip 32, spectroscope 41, the second lens 42 and photodetector 43 provide protective effect, and the first substrate 33 can be reflecting mirror 31 and MEMS chip 32 provide a supporting role, the second substrate 44 can be spectroscope 41, the second lens 42 and photodetector 43 provide a supporting role.

The utility model also provides a kind of preferred embodiment of the variable optical attenuation system of integrated light splitting detecting function.

Specifically, a kind of variable optical attenuation system of integrated light splitting detecting function, the variable optical attenuation system includes light Transmitter, optical receiver and variable optical attenuation device as described above, the optical transmitting set project optical signal, and optical signal passes through Optical signal is reflected into spectroscope 41, the spectroscope by directive reflecting mirror 31 after the transmission of input optical fibre 11, the reflecting mirror 31 Optical signal is divided into two bundles optical signal by 41, wherein a branch of optical signal directive photodetector 43, the photodetector 43 is detected Optical power, in addition a branch of optical signal is emitted back towards reflecting mirror 31, and optical signal is reflected into output optical fibre 12 by the reflecting mirror 31, described defeated 12 output optical signal of optical fiber is to optical receiver out.The driving voltage of the optical transmitting set is changeable, that is, is enter into input optical fibre The power of 11 optical signal changes, and optical signal continuation is transmitted according to above-mentioned flow direction, also, in the reflecting mirror 31 Angular deflection occurs for position, and the optical signal of final directive output optical fibre 12 deviates from output optical fibre 12, to produce coupling damage Consumption, realizes optical attenuation, the optical signal after optical attenuation is output to optical receiver again by the output optical fibre 12.

In conclusion the above is only the preferred embodiments of the present utility model only, it is not intended to limit the utility model Protection scope.Any modification made within the spirit and principle of the utility model, equivalent replacement, improve etc., it should all wrap Containing within the protection scope of the present utility model.

Claims (10)

1. a kind of variable optical attenuation device of integrated light splitting detecting function, it is characterised in that: the variable optical attenuation device includes Cavity, input optical fibre, reflecting mirror, spectroscope, photodetector and output optical fibre, the input optical fibre and output optical fibre are located at Optical signal is reflected into spectroscope by inside cavity, optical signal directive reflecting mirror after the transmission of input optical fibre, the reflecting mirror, Optical signal is divided into two bundles optical signal by the spectroscope, wherein a branch of optical signal directive photodetector, is examined by photodetector Optical power is surveyed, in addition a branch of optical signal is emitted back towards reflecting mirror, and optical signal is reflected into output optical fibre by the reflecting mirror, by output optical fibre Output optical signal.

2. variable optical attenuation device according to claim 1, it is characterised in that: the variable optical attenuation device further includes MEMS chip, the reflecting mirror are located at the surface of MEMS chip.

3. variable optical attenuation device according to claim 2, it is characterised in that: the variable optical attenuation device further includes One lens, optical signal first lens of directive after the transmission of input optical fibre, and through the first lens directive reflecting mirror；It is emitted back towards reflection The optical signal of mirror first lens of directive after the reflection of reflecting mirror, and through the first lens directive output optical fibre.

4. variable optical attenuation device according to claim 3, it is characterised in that: the axis of the reflecting mirror and the first lens It is at an acute angle.

5. variable optical attenuation device according to claim 4, it is characterised in that: the surface of the cavity is saturating with described first The surface of mirror is parallel, and the optical signal that the input optical fibre projects injects the first lens.

6. variable optical attenuation device according to claim 1, it is characterised in that: the variable optical attenuation device further includes The neighbouring setting of two lens, second lens and photodetector, first passes through the second lens by spectroscopical optical signal and penetrates again To photodetector.

7. variable optical attenuation device according to claim 6, it is characterised in that: the second lens are arranged in the spectroscope Surface.

8. variable optical attenuation device according to claim 1, it is characterised in that: the cavity is capillary.

9. variable optical attenuation device according to any one of claims 1 to 8, it is characterised in that: the variable optical attenuation device It further include shell, first substrate and the second substrate, the first substrate and the second substrate are located at enclosure interior, and the reflecting mirror is put It sets on the first substrate, the spectroscope and photodetector are placed in the second substrate.

10. a kind of variable optical attenuation system of integrated light splitting detecting function, it is characterised in that: the variable optical attenuation system includes Optical transmitting set, optical receiver and variable optical attenuation device as described in any one of claim 1 to 9, the optical transmitting set project Optical signal is reflected into spectroscope by optical signal, optical signal directive reflecting mirror after the transmission of input optical fibre, the reflecting mirror, institute It states spectroscope and optical signal is divided into two bundles optical signal, wherein a branch of optical signal directive photodetector, the photodetector inspection Optical power is surveyed, in addition a branch of optical signal is emitted back towards reflecting mirror, and optical signal is reflected into output optical fibre, the output light by the reflecting mirror Fine output optical signal is to optical receiver.