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CN106899346A - Optical module, optical module control method and device - Google Patents

Optical module, optical module control method and device Download PDF

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Publication number
CN106899346A
CN106899346A CN201510964855.0A CN201510964855A CN106899346A CN 106899346 A CN106899346 A CN 106899346A CN 201510964855 A CN201510964855 A CN 201510964855A CN 106899346 A CN106899346 A CN 106899346A
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CN
China
Prior art keywords
light
wavelength
incident light
optical signal
unit
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Granted
Application number
CN201510964855.0A
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Chinese (zh)
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CN106899346B (en
Inventor
张笃飞
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ZTE Corp
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ZTE Corp
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Priority to CN201510964855.0A priority Critical patent/CN106899346B/en
Priority to PCT/CN2016/086910 priority patent/WO2016198018A1/en
Publication of CN106899346A publication Critical patent/CN106899346A/en
Application granted granted Critical
Publication of CN106899346B publication Critical patent/CN106899346B/en
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    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04BTRANSMISSION
    • H04B10/00Transmission systems employing electromagnetic waves other than radio-waves, e.g. infrared, visible or ultraviolet light, or employing corpuscular radiation, e.g. quantum communication
    • H04B10/07Arrangements for monitoring or testing transmission systems; Arrangements for fault measurement of transmission systems
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04BTRANSMISSION
    • H04B10/00Transmission systems employing electromagnetic waves other than radio-waves, e.g. infrared, visible or ultraviolet light, or employing corpuscular radiation, e.g. quantum communication
    • H04B10/25Arrangements specific to fibre transmission
    • H04B10/2589Bidirectional transmission
    • H04B10/25891Transmission components
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04BTRANSMISSION
    • H04B10/00Transmission systems employing electromagnetic waves other than radio-waves, e.g. infrared, visible or ultraviolet light, or employing corpuscular radiation, e.g. quantum communication
    • H04B10/27Arrangements for networking
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04BTRANSMISSION
    • H04B10/00Transmission systems employing electromagnetic waves other than radio-waves, e.g. infrared, visible or ultraviolet light, or employing corpuscular radiation, e.g. quantum communication
    • H04B10/40Transceivers

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  • Engineering & Computer Science (AREA)
  • Physics & Mathematics (AREA)
  • Electromagnetism (AREA)
  • Computer Networks & Wireless Communication (AREA)
  • Signal Processing (AREA)
  • Computing Systems (AREA)
  • Optical Communication System (AREA)
  • Optical Couplings Of Light Guides (AREA)

Abstract

The invention discloses a kind of optical module, including receive light unit, microprocessor, luminescence unit and be arranged at the reflector element of the light path of optical module, microprocessor is connected with receipts light unit and luminescence unit respectively, wherein;The incident light of reflector element reflection predeterminated frequency simultaneously transmits the launching light that luminescence unit sends;The wavelength information for receiving the incident light that light unit will be received is sent to microprocessor;Microprocessor is based on the wavelength information generation optical signal generation instruction for receiving;The wavelength information that luminescence unit is based in optical signal generation instruction sends optical signal.The invention also discloses a kind of optical module control method and device.The present invention is realized and controls luminescence unit to launch the launching lights different from the wavelength of incident light according to the wavelength information of incident light, and then realize launching light with incident light in same Optical Fiber Transmission, and enable the optical module of the application with any optical module while using, it is to avoid the limitation that BIDI optical modules must be used in pairs.

Description

Optical module, optical module control method and device
Technical field
The present invention relates to technical field of photo communication, more particularly to a kind of optical module, optical module control method and Device.
Background technology
In order to meet requirement of the people to network service high speed transmission data, optical fiber gradually substitute twisted-pair feeder and Cable application is in network service.In fiber optic communication, the biography of optical signal is generally improved using optical module Defeated distance, for example, being used cooperatively by optical fiber and optical module can make the transmission range of optical signal reach 80km More than.
At present, what optic communication was used is substantially compact package hot-pluggable optical fiber receiver-transmitter module (optical mode Block), including duplex optical module and BIDI (Bidirectional, single fiber bi-directional) optical module.Double fibres The optical signal sent and received in bidirectional optical module is transmitted by two different optical fiber.BIDI optical modes Block completes transmission on an optical fiber using the different wavelength of receiving-transmitting sides, for example, BIDI optical modules A The reception consistent wavelength for sending wavelength and BIDI optical modules B, the reception wavelength of BIDI optical modules A and The transmission consistent wavelength of BIDI optical modules B, therefore, need BIDI optical modules A and B to make in optical transport Used for a pair.Because BIDI optical modules must be used in pairs in use, cause BIDI optical modules There is certain limitation in actual applications.
The content of the invention
The present invention provides a kind of optical module, optical module control method and device, it is intended to solve BIDI optical modules The technical problem that must be used in pairs in use.
To achieve the above object, the present invention provide a kind of optical module, the optical module include receive light unit, Microprocessor, luminescence unit and be arranged at the optical module light path reflector element, the microprocessor Device is connected with the receipts light unit and luminescence unit respectively, wherein;
The reflector element, for reflecting the incident light of predeterminated frequency and transmiting what the luminescence unit sent Launching light;
The receipts light unit, the incident light for receiving the reflector element reflection, and the institute that will be received The wavelength information for stating incident light is sent to the microprocessor;
The microprocessor, for being instructed based on the wavelength information generation optical signal generation for receiving, and is sent The optical signal generation instruction includes the wavelength of launching light to luminescence unit in the optical signal generation instruction Information, and the wavelength of the launching light is different from the wavelength of the incident light;
The luminescence unit is used to receive the optical signal generation instruction that the microprocessor sends, and based on institute The wavelength information stated in optical signal generation instruction sends optical signal.
Preferably, the reflector element is set in parallel in the light path of the optical module including at least two Filter, each described filter towards the one side of incident light be provided with reflection predeterminated frequency incident light it is anti- Layer is penetrated, the filter is provided with the transmission layer through the launching light towards the one side of the luminescence unit, The wavelength of the reflecting layer reflection of each filter is different.
Preferably, it is described receipts light unit include with the one-to-one photo-detector of filter each described, it is described Photo-detector receives the incident light of corresponding filter reflection, and detects the wavelength of incident light to obtain incident light Wavelength information.
Preferably, the luminescence unit includes drive component and luminescence component;The drive component respectively with The microprocessor and luminescence component are connected;The drive component is used to receive what the microprocessor sent Optical signal generation instruction, and driven based on the wavelength information in optical signal generation instruction described luminous group Part sends optical signal.
Additionally, to achieve the above object, the present invention also provides a kind of optical module control method, is applied to The optical module stated, the optical module control method is comprised the following steps:
Receive the wavelength information for receiving the incident light that light unit sends;
When the wavelength information is received, the wavelength information generation optical signal life based on the incident light for receiving Into instruction, the ripple of the wavelength information comprising launching light in the optical signal generation instruction, and the launching light Length is different from the wavelength of the incident light;
The optical signal generation instruction is sent to luminescence unit, so that the luminescence unit sends and incident light The different launching light of wavelength.
Preferably, the wavelength information for receiving the incident light for receiving light unit transmission includes:
Real-time reception receives the wavelength information of the incident light that light unit sends, wherein, the receipts light unit is connecing When receiving the incident light of reflector element reflection, the wavelength of the incident light that detection is received is to obtain the incidence The wavelength information of light.
Additionally, to achieve the above object, the present invention also provides a kind of optical module control device, is applied to The optical module stated, the optical module control device includes:
Receiver module, the wavelength information of the incident light that light unit sends is received for receiving;
Generation module, for when the wavelength information is received, the wavelength based on the incident light for receiving to be believed Breath generation optical signal generation instruction, the wavelength information comprising launching light in the optical signal generation instruction, and The wavelength of the launching light is different from the wavelength of the incident light;
Sending module, for sending the optical signal generation instruction to luminescence unit, for the luminous list Unit's transmitting launching light different from the wavelength of incident light.
Preferably, the receiver module is additionally operable to the wavelength letter that real-time reception receives the incident light that light unit sends Breath, wherein, the light unit of receiving detects what is received when the incident light of reflector element reflection is received The wavelength of incident light is obtaining the wavelength information of the incident light.
The present invention receives the incident light that reflector element reflects by receiving light unit, and microprocessor is based on what is received The wavelength information generation optical signal generation instruction that light unit sends is received, luminescence unit is based on the micro- place for receiving The optical signal that reason device sends generates the instruction issue launching light different from the wavelength of incident light, realizes basis The wavelength information control luminescence unit of incident light launches the launching lights different from the wavelength of incident light, Jin Ershi Existing launching light and incident light enable the optical module and any light of the present embodiment in same Optical Fiber Transmission Module uses simultaneously, it is to avoid the limitation that BIDI optical modules must be used in pairs.
Brief description of the drawings
Fig. 1 is the structural representation of optical module of the present invention;
Fig. 2 is the schematic flow sheet of optical module control method of the present invention;
Fig. 3 is the high-level schematic functional block diagram of optical module control device of the present invention.
The realization of the object of the invention, functional characteristics and advantage will be done further referring to the drawings in conjunction with the embodiments Explanation.
Specific embodiment
It should be appreciated that the specific embodiments described herein are merely illustrative of the present invention, limit is not used to The fixed present invention.
The present invention provides a kind of optical module.Reference picture 1, Fig. 1 is the structural representation of optical module of the present invention.
In the present embodiment, the optical module includes:Including receiving light unit 1, microprocessor 2, luminescence unit 3 and be arranged at the optical module light path reflector element 4;The microprocessor 2 respectively with the receipts Light unit 1 and luminescence unit 2 are connected, wherein:
The reflector element 4 is used to reflect the incident light of predeterminated frequency and transmit what the luminescence unit sent Launching light.For example, being located towards the side use that incident light enters in reflector element 4 can reflect default frequency The reflecting layer of rate incident light, so that reflector element 4 reflects the incident light of preset wavelength, in reflector element 4 Positioned at the side for just entering to launching light using the transmission layer for being transmissive to any wavelength launching light, so that reflection Unit 4 transmits the launching light of any wavelength.Wherein, predeterminated frequency is corresponded with preset wavelength, is preset Frequency can need the incident light of reflection to determine by the reflector element 4.
The light unit 1 of receiving is used to receive the incident light of the reflection of the reflector element 4, and will receive The wavelength information of the incident light is sent to the microprocessor 2;Wherein, light unit 1 is received to receive instead When penetrating the incident light of the reflection of unit 4, the wavelength information of the incident light for receiving is detected.
The microprocessor 2, for being instructed based on the wavelength information generation optical signal generation for receiving, and is sent The optical signal generation instruction includes the wavelength of launching light to luminescence unit 3 in the optical signal generation instruction Information, and the wavelength of the launching light is different from the wavelength of the incident light;Certainly, microprocessor 2 can With the wavelength information by obtaining the optical signal that luminescence unit 3 can send, then with the incidence for receiving The wavelength information of the optical signal that the wavelength information of light can send with the luminescence unit 3 for obtaining is compared, Determine the wavelength information of launching light, when luminescence unit 3 can send the different various optical signals of wavelength, The wavelength information of launching light can be other in addition to the wavelength information of incident light in various optical signals Anticipate a kind of wavelength information.
The luminescence unit 3 is used to receive the optical signal generation instruction that the microprocessor sends, and is based on Wavelength information in the optical signal generation instruction sends optical signal.
Further, in other embodiments, as shown in figure 1, the reflector element 4 includes at least two The individual filter 41 being set in parallel in the light path of the optical module, each described filter 41 is towards incident light One side be provided with reflection predeterminated frequency incident light reflecting layer, the filter 41 is towards the luminous list The one side of unit is provided with the transmission layer through the launching light, the reflecting layer reflection of each filter 41 Wavelength is different.
Each filter 41 be arranged in parallel and reflects the incident light of different wave length, to ensure to transmit incidence in optical fiber Light can be received by the receipts light unit 1 that reflexes to of wherein some filter with by receipts light unit 1.
Preferably, refer to Fig. 1, in other embodiments, it is described receipts light unit 1 include with described in each The one-to-one photo-detector 11 of filter 41, the photo-detector 11 receives the reflection of corresponding filter 41 Incident light, and detect the wavelength of incident light to obtain the wavelength information of incident light.
The photo-detector 11 for receiving light unit 1 is corresponded with the filter 41 of reflector element 4 so that light is visited Surveying device 11 can accurately detect the wavelength of incident light of its correspondence reflection of filter 41, it is readily appreciated that, When known to the wavelength of the light that filter 41 can reflect, if photo-detector 11 detect its correspondence filter 41 it is anti- The incident light penetrated, then incident light necessarily includes the light of the wavelength, therefore carries out wavelength without photo-detector 11 Detection and directly determine the wavelength of the light that the photo-detector 11 is received, and then receipts light unit can be reduced 1 flow for carrying out lambda1-wavelength detection.Conveniently, the plane of each filter 41 with it is described The angle of incident light is 45 °.
Further, Fig. 1 is refer to, the luminescence unit 3 includes drive component 31 and luminescence component 32; The drive component 31 is connected with the microprocessor 2 and luminescence component 32 respectively;The drive component The 31 optical signal generation instructions for being used to receive the transmission of the microprocessor 2, and based on optical signal generation Wavelength information in instruction drives the luminescence component 32 to send optical signal.
Luminescence component 32 is driven by drive component 31, the stability of the operation of luminescence unit 3 is ensure that, Improve the efficiency of transmission of launching light.
In one embodiment, photo-detector 11 is additionally operable to detect the incident light of its correspondence reflection of filter 41 Luminous power, receives light unit 1 and transmits to microprocessor the first op-tical power information that photo-detector 11 is detected 2, microprocessor 2 be additionally operable to the first op-tical power information, the second op-tical power information, the 3rd op-tical power information and 4th op-tical power information, wherein, the second op-tical power information for luminescence component 32 the power for sending optical signal, 3rd op-tical power information be receive light unit 1 opposite end optical module receive optical assembly receive optical signal power, 4th op-tical power information is the power of optical signal that sends of luminescence component of the opposite end optical module for receiving light unit 1. Microprocessor 2 can be according to the first op-tical power information, the second op-tical power information, the 3rd smooth work(for receiving Rate information and the 4th op-tical power information calculate the power attenuation of correspondence optical link, optical signal transmission efficiency or Carry out optical link positioning etc..
In the present embodiment, the incident light that reflector element 4 reflects, microprocessor 2 are received by receiving light unit 1 Based on the wavelength information generation optical signal generation instruction that the receipts light unit 1 for receiving sends, the base of luminescence unit 3 The optical signal sent in the microprocessor 2 for receiving generates the instruction issue hair different from the wavelength of incident light Light is penetrated, is realized and the transmitting of luminescence unit 3 is controlled with the wavelength of incident light not according to the wavelength information of incident light Same launching light, and then launching light and incident light are realized in same Optical Fiber Transmission, and cause the present embodiment Optical module can simultaneously be used with any optical module, it is to avoid the limitation that BIDI optical modules must be used in pairs.
The present invention further provides a kind of optical module control method.Reference picture 2, Fig. 2 is optical module of the present invention The schematic flow sheet of control method.
In the present embodiment, the optical module control method is applied to the optical module of above-described embodiment, optical module Control method includes:
Step S100, receives the wavelength information for receiving the incident light that light unit sends;
In the present embodiment, microprocessor real-time reception receives the wavelength information of the incident light that light unit sends, its In, the light unit of receiving detects the incident light for receiving when the incident light of reflector element reflection is received Wavelength to obtain the wavelength information of the incident light, and the wavelength information of the incident light that will be got sends To microprocessor, certainly, the corresponding filter of the photo-detector is detected in the photo-detector for receiving light unit anti- During the incident light penetrated, receive light unit and directly send to microprocessor the corresponding wavelength information of the photo-detector, And then the step of reduce its wavelength detecting to incident light.
Step S200, when the wavelength information is received, the wavelength information life based on the incident light for receiving Generated into optical signal and instructed, the wavelength information comprising launching light in the optical signal generation instruction, and it is described The wavelength of launching light is different from the wavelength of the incident light;
The wavelength information generation optical signal life of the incident light that microprocessor sends according to the receipts light unit for receiving Into instruction, optical signal generation instruction sends what is included during optical signal generation is instructed for controlling luminescence unit The launching light of the wavelength information corresponding wavelength of launching light.Microprocessor can by obtaining luminescence unit The wavelength information of the optical signal for sending, then the wavelength information with the incident light for receiving is luminous with what is obtained The wavelength information of the optical signal that unit can send is compared, and determines the wavelength information of launching light, for example, When luminescence unit can send the different various optical signals of wavelength, the wavelength information of launching light can be should Other any one wavelength informations in various optical signals in addition to the wavelength information of incident light.
Step S300, sends the optical signal generation instruction to luminescence unit, so that the luminescence unit is sent out Go out the launching lights different from the wavelength of incident light.
The optical signal generation instruction that microprocessor will be generated is sent to luminescence unit, and luminescence unit is being received During the optical signal generation instruction that microprocessor sends, the hair into traveling optical signal is instructed according to optical signal generation Operation is penetrated, wherein, the wavelength of the launching light of luminescence unit transmitting is different from the wavelength of incident light.
In the present embodiment, the wavelength information of the incident light that light unit sends is received by receiving, be next based on The wavelength information generation optical signal generation instruction of the incident light of receipts, then sends the optical signal generation instruction To luminescence unit, so that the luminescence unit launches the launching lights different from the wavelength of incident light, realize According to incident light wavelength information control luminescence unit so that the wavelength of the launching light that luminescence unit sends with The wavelength of incident light is different, and then realizes launching light and incident light in same Optical Fiber Transmission, and causes this reality Apply optical module that example uses can be with any optical module while using, it is to avoid BIDI optical modules are in use The limitation that must be used in pairs.
The present invention further provides a kind of optical module control device.Reference picture 3, Fig. 3 is optical module of the present invention The high-level schematic functional block diagram of control device.
In the present embodiment, the optical module control device is applied to the optical module of above-described embodiment, the optical mode Block control device includes:
Receiver module 100, the wavelength information of the incident light that light unit sends is received for receiving;
Further, in other embodiments, receiver module 100 is additionally operable to real-time reception and receives light unit hair The wavelength information of the incident light for sending, wherein, the light unit of receiving is receiving the incidence of reflector element reflection Light time, the wavelength of the incident light that detection is received will be obtained with obtaining the wavelength information of the incident light To the wavelength information of incident light send to microprocessor, certainly, receiving the photo-detector detection of light unit To the reflection of the photo-detector corresponding filter incident light when, receive light unit directly by photo-detector correspondence Wavelength information send to microprocessor, and then the step of reduce its wavelength detecting to incident light.
Generation module 200, for when the wavelength information is received, the wavelength based on the incident light for receiving Information generation optical signal generation instruction, the wavelength information comprising launching light in the optical signal generation instruction, And the wavelength of the launching light is different from the wavelength of the incident light;
The wavelength information generation light letter of the incident light that generation module 200 sends according to the receipts light unit for receiving Number generation instruction, the optical signal generation instruction for control luminescence unit send optical signal generation instruction in wrap The launching light of the wavelength information corresponding wavelength of the launching light for containing.Generation module 200 can be luminous by obtaining The wavelength information of the optical signal that unit can send, then with the wavelength information of the incident light for receiving with obtain The wavelength information of the optical signal that the luminescence unit for taking can send is compared, and determines the wavelength letter of launching light Breath, for example, when luminescence unit can send the different various optical signals of wavelength, the wavelength letter of launching light Breath can be other any one wavelength letter in various optical signals in addition to the wavelength information of incident light Breath.
Sending module 300, for sending the optical signal generation instruction to luminescence unit, for described luminous Unit launches the launching lights different from the wavelength of incident light.
The optical signal generation instruction that sending module 300 will be generated is sent to luminescence unit, and luminescence unit is connecing When receiving the optical signal generation instruction of microprocessor transmission, instructed into traveling optical signal according to optical signal generation Transmitting operation, wherein, luminescence unit transmitting launching light wavelength it is different from the wavelength of incident light.
In the present embodiment, the wavelength information for receiving the incident light that light unit sends is received by receiver module 100, Then generation module 200 is based on the wavelength information generation optical signal generation instruction of the incident light for receiving, then Sending module 300 sends the optical signal generation instruction to luminescence unit, so that the luminescence unit is launched The launching light different from the wavelength of incident light, realizes and controls luminescence unit according to the wavelength information of incident light, So that the wavelength of launching light is different from the wavelength of incident light, and then realize launching light with incident light in same light Fibre transmission, and enable the optical module that the present embodiment is used with any optical module while using, it is to avoid The limitation that BIDI optical modules must be used in pairs in use.
For ease of the understanding of scheme, above-described embodiment is entered as a example by the incident light with wavelength as 1270nm below Row is illustrated, and wherein optical module is provided with an one side towards incident light and is provided with reflection 1270nm wavelength Incident light reflecting layer filter, the control flow of optical module is specific as follows:
Wavelength receives light unit for the incident light of 1270nm by entering after correspondence filter reflection;
When the photo-detector for receiving light unit detects the incident light of filter reflection, light unit will be received and received The wavelength information of incident light send to the microprocessor;
When the wavelength information is received, microprocessor is based on the wavelength information generation of the incident light for receiving Optical signal generation instruction, the wavelength information comprising launching light in the optical signal generation instruction, and the hair The wavelength for penetrating light is different from the wavelength of the incident light, and microprocessor sends the optical signal by iic bus Generation is instructed to luminescence unit;
When the optical signal for receiving microprocessor transmission in luminescence unit generates instruction, drive component drives hair Optical assembly sends the launching lights different from the wavelength of incident light, and then avoids same link from receiving and dispatching phase co-wavelength Light.
It should be noted that herein, term " including ", "comprising" or its any other variant Be intended to including for nonexcludability so that process, method, article including a series of key elements or Person's device not only includes those key elements, but also other key elements including being not expressly set out, or also Including being this process, method, article or the intrinsic key element of device.In the feelings without more limitations Under condition, the key element limited by sentence "including a ...", it is not excluded that the process including the key element, Also there is other identical element in method, article or device.
The embodiments of the present invention are for illustration only, and the quality of embodiment is not represented.
Through the above description of the embodiments, those skilled in the art can be understood that above-mentioned Embodiment method can add the mode of required general hardware platform to realize by software, naturally it is also possible to logical Cross hardware, but the former is more preferably implementation method in many cases.It is of the invention based on such understanding The part that technical scheme substantially contributes to prior art in other words can in the form of software product body Reveal and, the computer software product is stored in storage medium (such as ROM/RAM, magnetic disc, a light Disk) in, including some instructions are used to so that a station terminal equipment (can be mobile phone, computer, service Device, air-conditioner, or network equipment etc.) perform method described in each embodiment of the invention.
The preferred embodiments of the present invention are these are only, the scope of the claims of the invention is not thereby limited, it is every The equivalent structure or equivalent flow conversion made using description of the invention and accompanying drawing content, or directly or Connect and be used in other related technical fields, be included within the scope of the present invention.

Claims (8)

1. a kind of optical module, it is characterised in that the optical module includes receiving light unit, microprocessor, hair Light unit and be arranged at the optical module light path reflector element, the microprocessor respectively with it is described Light unit and luminescence unit connection are received, wherein;
The reflector element, for reflecting the incident light of predeterminated frequency and transmiting what the luminescence unit sent Launching light;
The receipts light unit, the incident light for receiving the reflector element reflection, and the institute that will be received The wavelength information for stating incident light is sent to the microprocessor;
The microprocessor, for being instructed based on the wavelength information generation optical signal generation for receiving, and is sent The optical signal generation instruction includes the wavelength of launching light to luminescence unit in the optical signal generation instruction Information, and the wavelength of the launching light is different from the wavelength of the incident light;
The luminescence unit is used to receive the optical signal generation instruction that the microprocessor sends, and based on institute The wavelength information stated in optical signal generation instruction sends optical signal.
2. optical module as claimed in claim 1, it is characterised in that the reflector element includes at least two The individual filter being set in parallel in the light path of the optical module, each described filter is towards the one of incident light Face be provided with reflection predeterminated frequency incident light reflecting layer, the filter towards the luminescence unit one Face is provided with the transmission layer through the launching light, and the wavelength of the reflecting layer reflection of each filter is different.
3. optical module as claimed in claim 2, it is characterised in that the receipts light unit includes and each The one-to-one photo-detector of filter, the photo-detector receives the incident light of corresponding filter reflection, And detect the wavelength of incident light to obtain the wavelength information of incident light.
4. optical module as claimed in claim 1, it is characterised in that the luminescence unit includes driving group Part and luminescence component;The drive component is connected with the microprocessor and luminescence component respectively;The drive Dynamic component is used to receive the optical signal generation instruction that the microprocessor sends, and based on optical signal life The luminescence component is driven to send optical signal into the wavelength information in instruction.
5. a kind of optical module control method, is applied to the optical module described in claim 1, it is characterised in that The optical module control method includes:
Receive the wavelength information for receiving the incident light that light unit sends;
When the wavelength information is received, the wavelength information generation optical signal life based on the incident light for receiving Into instruction, the ripple of the wavelength information comprising launching light in the optical signal generation instruction, and the launching light Length is different from the wavelength of the incident light;
The optical signal generation instruction is sent to luminescence unit, so that the luminescence unit sends and incident light The different launching light of wavelength.
6. optical module control method as claimed in claim 5, it is characterised in that light list is received in the reception The wavelength information of the incident light that unit sends includes:
Real-time reception receives the wavelength information of the incident light that light unit sends, wherein, the receipts light unit is connecing When receiving the incident light of reflector element reflection, the wavelength of the incident light that detection is received is to obtain the incidence The wavelength information of light.
7. a kind of optical module control device, is applied to the optical module described in claim 1, it is characterised in that The optical module control device includes:
Receiver module, the wavelength information of the incident light that light unit sends is received for receiving;
Generation module, for when the wavelength information is received, the wavelength based on the incident light for receiving to be believed Breath generation optical signal generation instruction, the wavelength information comprising launching light in the optical signal generation instruction, and The wavelength of the launching light is different from the wavelength of the incident light;
Sending module, for sending the optical signal generation instruction to luminescence unit, for the luminous list Unit's transmitting launching light different from the wavelength of incident light.
8. optical module control device as claimed in claim 7, it is characterised in that the receiver module is also The wavelength information of the incident light that light unit sends is received for real-time reception, wherein, the receipts light unit is connecing When receiving the incident light of reflector element reflection, the wavelength of the incident light that detection is received is to obtain the incidence The wavelength information of light.
CN201510964855.0A 2015-12-18 2015-12-18 Optical module, optical module control method and device Active CN106899346B (en)

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PCT/CN2016/086910 WO2016198018A1 (en) 2015-12-18 2016-06-23 Optical module and control method and device therefor

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