CN106154443A - A kind of light transmit-receive integrated device - Google Patents

Abstract

The invention discloses a kind of light transmit-receive integrated device, be arranged on a mainboard, and described mainboard connects optical fiber by described light transmit-receive integrated device.Described optical transceiving device includes a body, a LD pin, a PD pin, a fibre-optical splice and a soft board.Described body is connected to described mainboard by described LD pin.Described PD pin is positioned at described LD pin offside and is connected with described body, and simultaneously described PD pin is connected to described mainboard by described soft board.Described body connects optical fiber by described fibre-optical splice.The LD pin length of described light transmit-receive integrated device is short, and the electrical crosstalk under high frequency state is little, and transmission performance is good.

Description

A kind of light transmit-receive integrated device

Technical field

The present invention relates to optical communication field, be specifically related to a kind of light transmit-receive integrated device.

Background technology

Passive optical network (pon) network (Passive Optical Network is called for short PON) is that one does not contains any electronics The intelligent acess network of device and electronic power supply, compared with Active Optical Fiber access network, passive optical network (pon) network is easy to maintenance, Reliability is high and cost is relatively low.In recent years, with the development of fiber optic communication, passive optical network (pon) network is also outstanding by it Characteristic obtained widely universal.In order to control the cost of passive optical network (pon) network, the commonly used BOSA of current each manufacturer On Board (being called for short BOB) technology, will light transmit-receive integrated device (Bi-direction Optical Sub-assembly, letter Claim BOSA) it is directly installed on mainboard, reduce product cost by reducing institute's spent material amount.

Being illustrated in figure 1 existing frequently-used light transmit-receive integrated device architecture schematic diagram, light transmit-receive integrated device includes one Body 1, a laser diode (LaserDiode is called for short LD) pin the 2nd a, photodiode (Photo Diode is called for short PD) pin 3 and a fibre-optical splice 4, wherein, described body 1 is connected to mainboard 5 by described LD pin 2 and described PD pin 3.Described LD Pin 2 one end is connected with described body 1, and the other end is connected to described mainboard 5, concrete, and described LD pin 2 is perpendicular to described master Plate 5 is connected with described mainboard 5, and described LD pin is connected with described body 1 after 90 ° of bendings in the horizontal direction.Described PD pin 3 vertically connects described body 1 and described mainboard 5.Described fibre-optical splice 4 is connected with described body 1, and institute State fibre-optical splice 4 axis direction consistent with the axis direction that described LD pin 2 accesses described body 1.It can be seen that it is existing frequently-used The described LD pin 2 of light transmit-receive integrated device be connected with described body 1 mutual vertically with described PD pin 3.In order to be formed Said structure, described LD pin 2 needs to carry out 90 ° of bendings, and manufacturing process is complex, improves whole light transmit-receive integrated device Cost.LD pin 2 length of existing light transmit-receive integrated device is longer, works under light transmit-receive integrated device is in high frequency condition When, described LD pin 2 can produce very big electrical crosstalk, and longer needs of present optical device works under high frequency condition, and light is received and dispatched Integrally the transmission performance of device can be severely impacted.

In sum, existing frequently-used light transmit-receive integrated device cannot meet present industry interior focusing device low cost Demand, and there is under high frequency condition very big electrical crosstalk, transmission performance is not good.

Content of the invention

It is an object of the invention to provide a kind of light transmit-receive integrated device, the LD pin of described light transmit-receive integrated device and PD Pin is back-to-back to be arranged on its body, and one of LD pin and PD pin are directly plugged in mainboard, and another passes through soft Plate is connected with mainboard, and LD pin length is short, effectively reduces the electrical crosstalk under high frequency state, promotes transmission performance.

Further object is that a kind of light transmit-receive integrated device of offer, the LD pipe of described light transmit-receive integrated device Pin is arranged on its body with PD pin is back-to-back, and one of LD pin and PD pin are directly plugged in mainboard, another Being connected with mainboard by soft board, LD pin, without carrying out bending process, simplifies the processing technology of light transmit-receive integrated device, reduces raw Produce cost.

In order to achieve the above object, the present invention provides a kind of light transmit-receive integrated device, is arranged on a mainboard, and described master Plate connects optical fiber by described light transmit-receive integrated device, comprising:

One body；

One soft board；

One LD pin, described LD pin is connected to described body, and described body is connected to described by described LD pin Mainboard；

One PD pin, the offside that described PD pin is positioned at described LD pin is connected with described body, and described PD pin leads to Cross described soft board and be connected to described mainboard；And

One fibre-optical splice, described fibre-optical splice is connected to described body, and described body is connected by described fibre-optical splice Described optical fiber.

Preferably, described mainboard is by the described LD pin transmission signal of telecommunication to described body, and described body carries out electricity to it Light is changed, and the optical signal that conversion is formed passes through described fibre-optical splice incident optical, and the light completing described light transmit-receive integrated device is sent out Penetrate.

Preferably, optical signal is by the incident described body of described fibre-optical splice, and described body carries out opto-electronic conversion to it, turns The signal of telecommunication changing formation is transferred to described mainboard by described PD pin and described soft board, completes described light transmit-receive integrated device Light-receiving.

Preferably, described LD pin is connected with described body abreast with described PD pin axis, and described fibre-optical splice It is connected with described body with intersecting vertically with described LD pin and described PD pin axis.

Preferably, described body is cuboid, and described LD pin is installed on the lower surface of described body, and described PD pin is pacified It is loaded on the upper surface of described body.

Preferably, described body interior includes a light emission component, and described mainboard transmits the signal of telecommunication by described LD pin To described light emission component, described light emission component carries out electro-optic conversion to it, and the optical signal that conversion is formed passes through described optical fiber Joint incident optical, the light completing described light transmit-receive integrated device is launched.

Preferably, described body interior includes a light-receiving assembly, and optical signal is by the incident described light of described fibre-optical splice Receiving unit, described light-receiving assembly carries out opto-electronic conversion to it, and the signal of telecommunication that conversion is formed is transferred to by described PD pin Described mainboard, completes the light-receiving of described light transmit-receive integrated device.

Preferably, described light emission component includes a LD chip, a smooth diversing lens and a speculum, described light-receiving Assembly includes a PD chip, an optical receiver lens and a filter plate, and wherein, described LD chip is arranged under described inner body wall Portion, and described LD chip electrically connects with described LD pin, described smooth diversing lens is installed on described body near described LD chip Inside, and the luminous light shaft coaxle of described smooth diversing lens optical axis and described LD chip, described speculum 123 and described LD chip Being arranged at described body interior in 45 °, described PD chip is arranged on described inner body wall top, and described PD chip and described PD Pin electrically connects, and described optical receiver lens is installed on described body interior, and described optical receiver lens 132 near described PD chip Optical axis and the receipts light light shaft coaxle of described PD chip, described filter plate and described PD chip are 45 ° and are arranged at described body interior.

Preferably, described LD pin is positioned at described main body one end away from described fibre-optical splice, and described PD pin is positioned at institute Stating main body close to one end of described fibre-optical splice, described LD pin 20 is coaxial with the cross section of described pin, and connects with described optical fiber The axis coaxle of head.

Preferably, described LD pin is positioned at described main body one end away from described fibre-optical splice, and described PD pin is positioned at institute State main body close to one end of described fibre-optical splice, and the different axle in cross section of described LD pin and described PD pin.

Brief description

In order to be illustrated more clearly that the embodiment of the present invention or technical scheme of the prior art, below will be to embodiment or existing In having technology to describe, the accompanying drawing of required use is briefly described, it should be apparent that, the accompanying drawing in describing below is only this Some embodiments of invention, for those of ordinary skill in the art, on the premise of not paying creative work, all right Obtain other accompanying drawing according to these accompanying drawings.

Fig. 1 is the structural representation of existing light transmit-receive integrated device.

Fig. 2 is the schematic diagram that a kind of light transmit-receive integrated device of the present invention is arranged on mainboard.

Fig. 3 is the schematic perspective view of a kind of light transmit-receive integrated device of the present invention.

Fig. 4 is the optical module schematic diagram within a kind of light transmit-receive integrated device body of the present invention.

Fig. 5 is LD pin and the PD pin schematic diagram relative to position of a kind of light transmit-receive integrated device of the present invention.

Fig. 6 is the schematic diagram of a kind of variant of a kind of light transmit-receive integrated device of the present invention.

Detailed description of the invention

Being illustrated in figure 2 the structural representation of a kind of light transmit-receive integrated device of the present invention, described optical transceiving device is installed On a mainboard 60, and described mainboard 60 connects optical fiber by described light transmit-receive integrated device.Described optical transceiving device includes One body the 10th, a LD pin the 20th, a PD pin the 30th, a fibre-optical splice 40 and a soft board 50.Described body 10 passes through described LD Pin 20 is connected to described mainboard 60.The offside that described PD pin 30 is positioned at described LD pin 20 is connected with described body 10, with Shi Suoshu PD pin 30 is connected to described mainboard 60 by described soft board 50.Described fibre-optical splice 40 is connected to described body 10, And described body 10 connects optical fiber by described fibre-optical splice 40.Described mainboard 60 transmits the signal of telecommunication extremely by described LD pin 20 Described body 10, described body 10 carries out electro-optic conversion, the optical signal that conversion is formed by optical module mounted therein By described fibre-optical splice 40 incident optical, the light completing described light transmit-receive integrated device is launched；Optical signal passes through described optical fiber The incident described body 10 of joint 40, described body 10 carries out opto-electronic conversion by optical module mounted therein, changes shape The signal of telecommunication becoming is transferred to described mainboard 60 by described PD pin 30 and described soft board 50, completes described light transmit-receive integrated device Light-receiving.The length of described LD pin 20 and described PD pin 30 is all shorter, when described light transmit-receive integrated device is at high frequency bar When working under part, bigger electrical crosstalk will not be produced, thus ensure that the signal transmission performance of described light transmit-receive integrated device.Institute State LD pin 20 and be linear pattern with described PD pin 30, it is not necessary to carry out bending process, in adding of described light transmit-receive integrated device In work processing procedure, technique is relatively simple, can effectively reduce production and processing cost.

As it is shown on figure 3, described LD pin 20 is connected with described body 10 abreast with described PD pin 30 axis, and described Fibre-optical splice 40 is connected with described body 10 with described LD pin 20 and described PD pin 30 axis with intersecting vertically.Described body 10 is cuboid, and described LD pin 20 is installed on the lower surface of described body 10, and described PD pin 30 is installed on described body 10 Upper surface, and described LD pin 20 is parallel but not coaxial with described PD pin 30 axis.Described fibre-optical splice 40 is installed on institute Stating the side surface of body 10, and described fibre-optical splice 40 one end being connected with described body 10, the other end connects optical fiber, from described Optical signal within body 10 is through described fibre-optical splice 40 incident optical, and from the optical signal of described Optical Fiber Transmission through described The incident described body 10 of fibre-optical splice 40 is internal.

Being illustrated in figure 4 the optical module schematic diagram within described body 10, described body 10 is internal includes that a light is launched Assembly 12 and a light-receiving assembly 13.In Fig. 4, A show the light path schematic diagram of described light emission component 12, and in Fig. 4, B show The light path schematic diagram of described light-receiving assembly 13.Described light emission component 12 includes a LD chip the 121st, a smooth diversing lens 122 And a speculum 123.Described light-receiving assembly includes a PD chip the 131st, an optical receiver lens 132 and a filter plate 133. The luminescence of described LD chip 121 forms converged light after the convergence of described smooth diversing lens 122, and converged light is through described speculum 123 Pass through described filter plate 133 again, finally by described fibre-optical splice 40 incident optical after reflection.Wherein, described LD chip is installed At described body 10 inner wall lower, and described LD chip 121 electrically connects with described LD pin 20, and described LD chip 121 passes through institute State LD pin 20 and receive the signal of telecommunication sending from described mainboard 60, and described LD chip 121 is according to the signal of telecommunication receiving Adjust its luminance.It is internal and described that described smooth diversing lens 122 is installed on described body 10 near described LD chip 121 Light diversing lens 122 optical axis and the luminous light shaft coaxle of described LD chip 121, described LD chip 121 sends diverging light, incident institute Form converged light after stating light diversing lens 122 and converging through described smooth diversing lens 122.Described speculum 123 and converged light Optical axis is 45 ° and is arranged at described body 10 inside, and converged light produces the deviation of 90 ° through described speculum 123, through reflection Converged light again by reaching described optical fiber interface 40 after described filter plate 133, and final incident optical, it is achieved light launches work( Energy.Described PD chip 131 is arranged on described body 10 upper inside wall, and described PD chip 131 electrically connects with described PD pin 30, Described PD chip 131 receives the optical signal from optical fiber, and is passed to described mainboard 60 by described PD pin and described soft board 50 Pass the signal of telecommunication.It is internal that described optical receiver lens 132 is installed on described body 10 near described PD chip 131, and described light-receiving Lens 132 optical axis and the receipts light light shaft coaxle of described PD chip 131.Described filter plate 133 sets in 45 ° with described PD chip 131 It is placed in described body 10 internal.Reach described filter plate 133 from the light of described optical fiber interface 40 outgoing, through described filter plate After the reflection of 133, incident described optical receiver lens 132 forms converged light, and final incident described PD chip 131, it is achieved light-receiving Function.Described light emission component 12 and described light-receiving assembly 13 position staggered relative, form " back-to-back " structure, realize simultaneously Light launches the function with light-receiving.

The upper and lower relation that it should be noted that described body 10 is to describe described LD chip 121 and described PD for convenience The direction that the relative position of chip 131 and described LD pin 20 are manually set with the relative position of described PD pin 30.When Shi Suoshu body 10 is directly connected with described mainboard 60 by described PD pin 30, and described LD pin 20 passes through described soft board 50 When being connected with described mainboard 60, described PD pin 30 is i.e. positioned at the bottom of described body 10, and described LD pin 20 is i.e. positioned at described The top of body 10, accordingly, described PD chip 131 is i.e. positioned at described body 10 inner wall lower, and described LD chip is i.e. positioned at institute State body 10 upper inside wall.When described PD pin 30 is positioned at described body 10 bottom, described LD pin 20 is positioned at described body 10 During top, the length of described LD pin 30 does not changes, and described soft board 50 will not produce electrical crosstalk under high frequency condition, Transmission performance is unaffected, and i.e. no matter described LD pin 20 is directly to connect described body 10 and described mainboard 60, still passes through Described soft board 50 is connected with described mainboard 60, and described light transmit-receive integrated device is all without producing electrical crosstalk, and transmission performance is all preferable.

Being illustrated in figure 5 the relative position view of described LD pin 20 and described PD pin 30, wherein, Fig. 5 (a) is institute Stating the schematic diagram of body 10 bottom, Fig. 5 (b) is the schematic diagram on described body 10 top.Described LD pin 20 is positioned at described body 10 away from one end of described fibre-optical splice 40, and described PD pin 30 is positioned at described body 10 close to the one of described fibre-optical splice 40 End, described LD pin 20 is coaxial with the cross section of described PD pin 30, and the axis coaxle with described fibre-optical splice 40, thus described LD chip 121 is also coaxial with the cross section of described PD chip 131 and axis coaxle with described fibre-optical splice 40.Thus light launches light Road and light-receiving light path are coaxial at one section coaxial with described optical fiber interface 40.LD pin 20 described above and described PD pipe The relative positional structure of pin 30 makes described body 10 be chosen the structure of elongated shape, when described mainboard 60 area is relatively big or In the case that the installation direction length of described light transmit-receive integrated device is longer, be suitable for using LD pin 20 described above with described The described light transmit-receive integrated device of the relative positional structure of PD pin 30, but when described mainboard 60 area is less, be not suitable for Use the described light transmit-receive integrated device of the relative positional structure with described PD pin 30 for the LD pin 20 described above.

Being illustrated in figure 6 the schematic diagram of a kind of variant of described light transmit-receive integrated device, wherein, Fig. 6 (a) is described body The schematic diagram of 10A bottom, Fig. 6 (b) is the schematic diagram on described body 10A top.Described optical transceiving device include a body 10A, One LD pin 20A, an a PD pin 30A and fibre-optical splice 40A.Described LD pin 20A is parallel with described PD pin 30A axis Ground is connected with described body 10A, and described fibre-optical splice 40A and described LD pin 20A and described PD pin 30A is perpendicularly to the axis It is connected with described body 10A.Described body 10A is cuboid, and described LD pin 20A is installed on the lower surface of described body 10A, Described PD pin 30A is installed on the upper surface of described body 10A, and described LD pin 20A is parallel with described PD pin 30A axis But it is not coaxial.Described fibre-optical splice 40A is installed on the side surface of described body 10A, and described fibre-optical splice 40A one end with described Body 10A connects, and the other end connects optical fiber, incident through described fibre-optical splice 40A from the optical signal within described body 10A Optical fiber, and from the optical signal of described Optical Fiber Transmission inside the incident described body 10A of described fibre-optical splice 40A.Described LD manages Pin 20A is positioned at described body 10A one end away from described fibre-optical splice 40A, and described PD pin 30A is positioned at described body 10A and connects One end of nearly described fibre-optical splice 40A, and the different axle in cross section of described LD pin 20A and described PD pin 30A.Thus light launches light Road and light-receiving light path are different axles.LD pin 20A described above makes described with the relative positional structure of described PD pin 30A Body 10A is chosen the shorter structure of length, when described mainboard 60 area is less or in the peace of described light transmit-receive integrated device It in the case that dress direction length is shorter, is suitable for using the relative positional structure of LD pin 20A described above and described PD pin 30A Described light transmit-receive integrated device.

Described above to the disclosed embodiments, makes professional and technical personnel in the field be capable of or uses the present invention. Multiple modifications to these embodiments will be apparent from for those skilled in the art, as defined herein General Principle can realize without departing from the spirit or scope of the present invention in other embodiments.Therefore, the present invention It is not intended to be limited to the embodiments shown herein, and be to fit to and principles disclosed herein and features of novelty phase one The scope the widest causing.

Claims (10)

1. a light transmit-receive integrated device, is arranged on a mainboard, and described mainboard is connected by described light transmit-receive integrated device Optical fiber, it is characterised in that include:

One body；

One soft board；

One LD pin, described LD pin is connected to described body, and described body is connected to described mainboard by described LD pin；

One PD pin, the offside that described PD pin is positioned at described LD pin is connected with described body, and described PD pin passes through institute State soft board and be connected to described mainboard；And

One fibre-optical splice, described fibre-optical splice is connected to described body, and described body is connected described by described fibre-optical splice Optical fiber.

2. light transmit-receive integrated device as claimed in claim 1, it is characterised in that described mainboard is by described LD pin transmission electricity Signal is to described body, and described body carries out electro-optic conversion to it, and the optical signal that conversion is formed is incident by described fibre-optical splice Optical fiber, the light completing described light transmit-receive integrated device is launched.

3. light transmit-receive integrated device as claimed in claim 2, it is characterised in that optical signal is by the incident institute of described fibre-optical splice Stating body, described body carries out opto-electronic conversion to it, and the signal of telecommunication that conversion is formed passes through described PD pin and the transmission of described soft board To described mainboard, complete the light-receiving of described light transmit-receive integrated device.

4. light transmit-receive integrated device as claimed in claim 1, it is characterised in that described LD pin is put down with described PD pin axis Row ground is connected with described body, and described fibre-optical splice and described LD pin and described PD pin axis intersect vertically with described Body connects.

5. light transmit-receive integrated device as claimed in claim 4, it is characterised in that described body is cuboid, described LD pin Being installed on the lower surface of described body, described PD pin is installed on the upper surface of described body.

6. light transmit-receive integrated device as claimed in claim 3, it is characterised in that described body interior includes a light transmitting group Part, described mainboard is by the described LD pin transmission signal of telecommunication to described light emission component, and described light emission component carries out electricity to it Light is changed, and the optical signal that conversion is formed passes through described fibre-optical splice incident optical, and the light completing described light transmit-receive integrated device is sent out Penetrate.

7. light transmit-receive integrated device as claimed in claim 6, it is characterised in that described body interior includes a light-receiving group Part, optical signal is by the incident described light-receiving assembly of described fibre-optical splice, and described light-receiving assembly carries out opto-electronic conversion to it, turns The signal of telecommunication changing formation is transferred to described mainboard by described PD pin, completes the light-receiving of described light transmit-receive integrated device.

8. light transmit-receive integrated device as claimed in claim 7, it is characterised in that described light emission component include a LD chip, One smooth diversing lens and a speculum, described light-receiving assembly includes a PD chip, an optical receiver lens and a filter plate, Wherein, described LD chip is arranged on described inner body wall bottom, and described LD chip electrically connects with described LD pin, and described light is sent out Penetrate lens and be installed on described body interior, and the luminescence of described smooth diversing lens optical axis and described LD chip near described LD chip Light shaft coaxle, described speculum 123 is 45 ° with described LD chip and is arranged at described body interior, and described PD chip is arranged on institute Stating inner body wall top, and described PD chip electrically connecting with described PD pin, described optical receiver lens is pacified near described PD chip It is loaded on described body interior, and the receipts light light shaft coaxle of described optical receiver lens 132 optical axis and described PD chip, described filter plate It is 45 ° with described PD chip and be arranged at described body interior.

9. light transmit-receive integrated device as claimed in claim 1, it is characterised in that described LD pin is positioned at described main body away from institute Stating one end of fibre-optical splice, described PD pin is positioned at described main body close to one end of described fibre-optical splice, described LD pin 20 with The cross section of described pin is coaxial, and the axis coaxle with described fibre-optical splice.

10. light transmit-receive integrated device as claimed in claim 1, it is characterised in that described LD pin be positioned at described main body away from One end of described fibre-optical splice, described PD pin is positioned at described main body close to one end of described fibre-optical splice, and described LD pin The different axle in cross section with described PD pin.