阅读说明：本技术 一种用于光传输信道调度的光分插复用器 (Optical add-drop multiplexer for optical transmission channel scheduling ) 是由 李朝晖 潘竞顺 冯耀明 于 2021-06-30 设计创作，主要内容包括：本发明提出一种用于光传输信道调度的光分插复用器,解决了当前可重构光分插复用器件对于复杂多维光传输信道调度操控的灵活性差的问题,包括均采用硫系材料制备而成的主波导、微环腔、带隙聚焦光源、非带隙聚焦光源及热光开关,利用每个微环腔的正上方的带隙聚焦光源与非带隙聚焦隙光源分别定向照射,带隙聚焦光源引起微环腔输出光谱峰波长通道的蓝移,非带隙聚焦光源引起微环腔输出光谱峰波长通道的红移,实现光传输信道的调度,另外利用热光开关基于热光特性,实现了下行输入光信号与上行输入光信号的光路灵活切换。本发明利用了硫系材料的光敏漂白特性,结合热光开关,实现对复杂波分复用通道更为多维的操控,灵活性高,调配性能强。(The invention provides an optical add-drop multiplexer for scheduling an optical transmission channel, which solves the problem of poor flexibility of the current reconfigurable optical add-drop multiplexer for scheduling and controlling a complex multidimensional optical transmission channel, and comprises a main waveguide, micro-ring cavities, band-gap focusing light sources, non-band-gap focusing light sources and a thermo-optic switch which are all made of chalcogenide materials. The invention utilizes the photosensitive bleaching characteristic of chalcogenide materials and combines a thermo-optical switch to realize more multidimensional control on complex wavelength division multiplexing channels, and has high flexibility and strong allocation performance.)

1. An optical add/drop multiplexer for scheduling optical transmission channels, comprising: the device comprises a main waveguide, K micro-ring cavities, K band-gap focusing light sources, K non-band-gap focusing light sources and K/2 thermo-optical switches, wherein K is a positive integer; the K micro-ring cavities are sequentially arranged on the main waveguide one by one at equal intervals and coupled with the main waveguide to form an array micro-cavity structure; a band-gap focusing light source and a non-band focusing gap light source are sequentially suspended and arranged right above each micro-ring cavity, and the main waveguide, the K micro-ring cavities and the K/2 thermo-optic switches are all made of chalcogenide materials; downlink input optical signals are transmitted through the main waveguide, the main waveguide is coupled with the array micro-cavity structure, an output waveguide is arranged on the same side of each micro-ring cavity, and the output waveguides of the micro-ring cavities output free spectrums; a band-gap focusing light source and a non-band-gap focusing light source which are arranged right above each micro-ring cavity respectively irradiate in a directional mode, the band-gap focusing light source causes a blue shift of a spectral peak wavelength channel output by the micro-ring cavity, and the non-band-gap focusing light source causes a red shift of the spectral peak wavelength channel output by the micro-ring cavity; the output ends of the output waveguides of two adjacent micro-ring cavities are coupled through a thermo-optical switch, and the thermo-optical switch realizes the optical path switching from the downlink input optical signal to the uplink input optical signal based on the thermo-optical characteristic when the uplink input optical signal needs to be loaded.

2. The optical add/drop multiplexer for optical transmission channel scheduling according to claim 1, wherein said optical add/drop multiplexer for optical transmission channel scheduling further comprises a partition panel, wherein the ith non-bandgap focused light source and the (i + 1) th bandgap focused light source are separated by the partition panel, wherein i-1, …, K-1.

3. The optical add/drop multiplexer according to claim 2, wherein the micro-ring cavities have a radius of 1 μm to 500 μm, and when the radii of the micro-ring cavities are different, the free spectral ranges output by the micro-ring cavities are different, and the downlink input optical signal is transmitted through the main waveguide, and is coupled with the array micro-cavity structure through the main waveguide, thereby realizing the selective output of the resonant wavelengths of the micro-ring cavities.

4. The optical add/drop multiplexer according to claim 2, wherein the micro-cavity array outputs equally spaced resonance spectra at a radius of 50 μm, resulting in equally spaced optical channels.

5. The optical add/drop multiplexer according to claim 4, wherein the bandgap focused light source outputs short wavelength light having a wavelength ranging from 206nm to 805 nm; the non-band gap focusing light source outputs long-wavelength light with the wavelength range of 2-10 mu m.

6. The optical add/drop multiplexer according to claim 5, wherein when the initialization state is set, the input wavelengths of the downlink input optical signals are distributed from short to long in order as follows: lambda [ alpha ]_in1、λ_in2、λ_in3、…、λ_ini、…、λ_inkThe channels through which the input wavelengths of the downlink input optical signals sequentially pass are respectively: n is a radical of_out1、N_out2、N_out3、…、N_outi、…、N_outk，N_out1、N_out2、N_out3、…、N_outi、…、N_outkAnd the input wavelengths of the downlink input optical signals and the channels through which the input wavelengths of the downlink input optical signals sequentially pass are in one-to-one correspondence.

7. Optical add/drop multiplexer for optical transmission channel scheduling in accordance with claim 6 characterized in that the input wavelength λ of the downstream input optical signal_iniAnd channel N_outiCorrespond when necessaryTo an input wavelength lambda_iniWhen blocking is performed, channel N is determined_outiSetting the irradiation power of a band-gap focusing light source right above the corresponding micro-ring i, utilizing the band-gap focusing light source to irradiate the micro-ring i in a directional manner, and enabling the channel N to be a channel N_outiIs blue-shifted from the input wavelength lambda_iniWavelength range of (1), input wavelength lambda_iniDecay until blocking.

8. Optical add/drop multiplexer for optical transmission channel scheduling in accordance with claim 6 characterized in that the input wavelength λ of the downstream input optical signal_iniAnd channel N_outiCorrespondingly, when the input wavelength λ is required_iniWhen blocking is performed, channel N is determined_outiSetting the irradiation power of a non-band-gap focusing light source right above the corresponding micro ring i, utilizing the non-band-gap focusing light source to irradiate the micro ring i in a directional manner, and enabling the channel N to be a channel N_outiIs red-shifted from the input wavelength lambda_iniWavelength range of (1), input wavelength lambda_iniDecay until blocking.

9. Optical add/drop multiplexer for optical transmission channel scheduling in accordance with claim 6 characterized in that the input wavelength λ of the downstream input optical signal_iniAnd channel N_outiCorresponding when the input wavelength λ_iniWhen the channel needs to be replaced for output, the channel is replaced to the channel N_outjDetermining a channel N_outiSetting the irradiation power of a band-gap focusing light source right above the corresponding micro-ring i, utilizing the band-gap focusing light source to irradiate the micro-ring i in a directional manner, and enabling the channel N to be a channel N_outiOffset to an out-of-band region; determining channel N_outjSetting the irradiation power of the band gap focusing light source above the corresponding micro ring j, and utilizing the band gap focusing light source to irradiate the micro ring j directionally to ensure that the channel N_outjBlue-shift to λ_iniAt the corresponding wavelength, the input wavelength λ_iniChange to channel N_outjAnd (6) outputting.

10. The optical add/drop multiplexer according to claim 3, wherein when the uplink input optical signal needs to be loaded, the time for the thermal optical switch to switch the optical path from the downlink input optical signal to the uplink input optical signal is not more than 100 ms.

Technical Field

The invention relates to the technical field of photonic integrated devices, in particular to an optical add/drop multiplexer for scheduling optical transmission channels.

Background

In the field of current optical fiber communication, the appearance of the ultra-long-distance dense wavelength division technology (DWDM) gradually solves the bottleneck problem of network transmission service, so that more operators need to adapt to the new requirements of the optical transmission network in the aspect of dynamic networking.

The traditional dense wavelength division multiplexing technology as the most common optical physical layer networking technology has the defects that point-to-point transmission can be realized only, and flexible network scheduling is difficult to realize. An Optical Add and Drop Multiplexing (OADM) technology that has been developed along with this technology can implement ring networking for an optical communication network, but the OADM has a fixed wavelength channel interval and a fixed channel number, cannot implement real flexible network service deployment, and is difficult to implement the operation requirement of packetization.

Furthermore, researchers at home and abroad research that Reconfigurable Optical Add-Drop Multiplexer (ROADM) devices are applied to a Wavelength Division Multiplexing (WDM) Optical network system, 12.1.2020, and a communication site, an Optical communication system and a data transmission method based on Reconfigurable Optical Add-Drop Multiplexer (ROADM) devices are disclosed in chinese patent publication No. CN112019262A, which is connected with a first ROADM device and a second ROADM device through Optical protection devices respectively to form two transmission links in different directions between the communication sites, thereby protecting service communication between the communication sites. And, because two ROADM devices are included in the communication site, when the ROADM device fails, service communication is continued through another ROADM device, so that flexible scheduling of services can be realized according to the needs of a network, wherein the ROADM device includes a flexible grid optical wavelength selective switch WSS, and dynamic adjustment of wavelength channel intervals is realized to receive and transmit service optical signals of different wavelengths, but an input port and an output port included in the wavelength selective switch type ROADM are mechanically straight and white, and when the ROADM device is used for a complex wavelength division multiplexing channel, flexible control of more-dimensional optical transmission channel scheduling is difficult to realize.

Disclosure of Invention

In order to solve the problem that the current reconfigurable optical add/drop multiplexer has poor flexibility for the scheduling and control of the complex multidimensional optical transmission channel, the invention provides the optical add/drop multiplexer for the scheduling of the optical transmission channel, which has high flexibility and strong scheduling performance.

In order to achieve the technical effects, the technical scheme of the invention is as follows:

an optical add/drop multiplexer for optical transmission channel scheduling, comprising: the device comprises a main waveguide, K micro-ring cavities, K band-gap focusing light sources, K non-band-gap focusing light sources and K/2 thermo-optical switches, wherein K is a positive integer; the K micro-ring cavities are sequentially arranged on the main waveguide one by one at equal intervals and coupled with the main waveguide to form an array micro-cavity structure; a band-gap focusing light source and a non-band focusing gap light source are sequentially suspended and arranged right above each micro-ring cavity, and the main waveguide, the K micro-ring cavities and the K/2 thermo-optic switches are all made of chalcogenide materials; downlink input optical signals are transmitted through the main waveguide, the main waveguide is coupled with the array micro-cavity structure, an output waveguide is arranged on the same side of each micro-ring cavity, and the output waveguides of the micro-ring cavities output free spectrums; a band-gap focusing light source and a non-band-gap focusing light source which are arranged right above each micro-ring cavity respectively irradiate in a directional mode, the band-gap focusing light source causes a blue shift of a spectral peak wavelength channel output by the micro-ring cavity, and the non-band-gap focusing light source causes a red shift of the spectral peak wavelength channel output by the micro-ring cavity; the output ends of the output waveguides of two adjacent micro-ring cavities are coupled through a thermo-optical switch, and the thermo-optical switch realizes the optical path switching from the downlink input optical signal to the uplink input optical signal based on the thermo-optical characteristic when the uplink input optical signal needs to be loaded.

Preferably, the optical add/drop multiplexer for scheduling optical transmission channels further comprises a partition panel, and the ith non-bandgap focused light source and the (i + 1) th bandgap focused light source are separated by the partition panel, wherein i is 1, …, and K-1, so as to avoid mutual interference between the non-bandgap focused light source and the bandgap focused light source.

Preferably, the radius of the micro-ring cavity is 1 μm to 500 μm, when the radii of the micro-ring cavities are different, the free spectral ranges output by the micro-ring cavities are different, and a downlink input optical signal is transmitted through the main waveguide and coupled with the array microcavity structure through the main waveguide, so that the selective output of the resonance wavelengths of the micro-ring cavities is realized.

Preferably, when the radius of the micro-ring cavity is 50 μm, the array micro-cavity structure outputs equally spaced resonance spectra, so as to obtain equally spaced optical channels.

Preferably, the band gap focusing light source outputs short-wavelength light with the wavelength range of 206nm to 805 nm; the non-band gap focusing light source outputs long-wavelength light with the wavelength range of 2-10 microns, and the short-wavelength light and the long-wavelength light can respectively control the output wave of the micro-ring cavity.

Preferably, when the initialization state is set, the input wavelengths of the downlink input optical signals are distributed from short to long in sequence as follows: lambda [ alpha ]_in1、λ_in2、λ_in3、…、λ_ini、…、λ_inkThe channels through which the input wavelengths of the downlink input optical signals sequentially pass are respectively: n is a radical of_out1、N_out2、N_out3、…、N_outi、…、N_outk，N_out1、N_out2、N_out3、…、N_outi、…、N_outkAnd the input wavelengths of the downlink input optical signals and the channels through which the input wavelengths of the downlink input optical signals sequentially pass are in one-to-one correspondence.

Preferably, the input wavelength λ of the downstream input optical signal_iniAnd channel N_outiCorrespondingly, when the input wavelength λ is required_iniWhen blocking is performed, channel N is determined_outiSetting the irradiation power of a band-gap focusing light source right above the corresponding micro-ring i, utilizing the band-gap focusing light source to irradiate the micro-ring i in a directional manner, and enabling the channel N to be a channel N_outiIs blue-shifted from the input wavelength lambda_iniWavelength range of (1), input wavelength lambda_iniAttenuation until blocking, thereby achieving the input wavelength lambda_iniBlocking in one direction of the optical transmission channel.

Preferably, the input wavelength λ of the downstream input optical signal_iniAnd channel N_outiCorrespondingly, when the input wavelength λ is required_iniWhen blocking is performed, channel N is determined_outiSetting the irradiation power of a non-band-gap focusing light source right above the corresponding micro ring i, utilizing the non-band-gap focusing light source to irradiate the micro ring i in a directional manner, and enabling the channel N to be a channel N_outiIs red-shifted from the input wavelength lambda_iniWavelength range of (1), input wavelength lambda_iniAttenuation until blocking, thereby achieving the input wavelength lambda_iniBlocking in the other direction of the optical transmission channel.

Preferably downstreamInput wavelength lambda of an input optical signal_iniAnd channel N_outiCorresponding when the input wavelength λ_iniWhen the channel needs to be replaced for output, the channel is replaced to the channel N_outjDetermining a channel N_outiSetting the irradiation power of a band-gap focusing light source right above the corresponding micro-ring i, utilizing the band-gap focusing light source to irradiate the micro-ring i in a directional manner, and enabling the channel N to be a channel N_outiOffset to an out-of-band region; determining channel N_outjSetting the irradiation power of the band gap focusing light source above the corresponding micro ring j, and utilizing the band gap focusing light source to irradiate the micro ring j directionally to ensure that the channel N_outjBlue-shift to λ_iniAt the corresponding wavelength, the input wavelength λ_iniChange to channel N_outjOutput to thereby realize an input wavelength λ_iniScheduling at different optical transmission channels.

Preferably, when the uplink input optical signal needs to be loaded, the time for the thermo-optical switch to realize the optical path switching from the downlink input optical signal to the uplink input optical signal is not more than 100 ms.

Here, with the continuous input of downlink input optical signal light energy, the non-band-gap focusing light source absorbs and produces the photothermal effect, the thermo-optic switch adopts the chalcogenide material, under the condition of raising the temperature, the refractive index rises, can cause the phase place of light to change, and there is a straight-through link in the optical link, the input light can directly transmit through, also some need descend down after, go up again through some data processing, just so need switch over the passageway, consequently, when needing to load the uplink input optical signal, the thermo-optic switch can realize the optical path switching of downlink input optical signal to uplink input optical signal.

Compared with the prior art, the technical scheme of the invention has the beneficial effects that:

the invention provides an optical add-drop multiplexer for scheduling an optical transmission channel, which comprises a main waveguide, micro-ring cavities, band-gap focusing light sources, non-band-gap focusing light sources and a thermo-optic switch, wherein the main waveguide, the micro-ring cavities, the band-gap focusing light sources, the non-band-gap focusing light sources and the thermo-optic switch are all prepared from chalcogenide materials; a band-gap focusing light source and a non-band-gap focusing light source are sequentially suspended over each micro-ring cavity, the band-gap focusing light source and the non-band-gap focusing light source over each micro-ring cavity are used for respectively and directionally irradiating, the band-gap focusing light source causes blue shift of a spectrum peak wavelength channel output by the micro-ring cavity, the non-band-gap focusing light source causes red shift of the spectrum peak wavelength channel output by the micro-ring cavity, and scheduling of optical transmission channels is achieved. The invention utilizes the photosensitive bleaching characteristic of chalcogenide materials, combines a thermo-optical switch, realizes more multidimensional control on complex wavelength division multiplexing channels, has high flexibility and strong allocation performance, can be applied to an optical transmission network building network, and provides a brand new direction and thought for operators to build a fully intelligent, flexible and adjustable optical transmission network.

Drawings

Fig. 1 is a schematic structural diagram of an optical add/drop multiplexer for scheduling an optical transmission channel according to an embodiment of the present invention;

FIG. 2 is a schematic diagram showing the variation of refractive index of chalcogenide material with the irradiation time of a band-gap focusing light source and a non-band-gap focusing light source;

fig. 3 is a diagram showing an up-down optical path in an optical path device board formed by the optical add/drop multiplexer according to the present invention;

fig. 4 is a schematic diagram of an input wavelength and a channel of a downlink input optical signal in an initialization state according to an embodiment of the present invention;

fig. 5 is a schematic diagram illustrating states of an input wavelength and a channel of a downlink input optical signal when blocking of the input wavelength of the downlink input optical signal is implemented according to an embodiment of the present invention;

fig. 6 is a schematic diagram illustrating states of input wavelengths and channels of downlink input optical signals when switching of the input wavelength channels of the downlink input optical signals is implemented according to an embodiment of the present invention.

Detailed Description

The drawings are for illustrative purposes only and are not to be construed as limiting the patent;

for better illustration of the present embodiment, certain parts of the drawings may be omitted, enlarged or reduced, and do not represent actual dimensions;

it will be understood by those skilled in the art that certain well-known descriptions of the figures may be omitted.

The positional relationships depicted in the drawings are for illustrative purposes only and are not to be construed as limiting the present patent;

the technical solution of the present invention is further described below with reference to the accompanying drawings and examples.

Examples

The optical add/drop multiplexer for scheduling optical transmission channels as shown in fig. 1 has a schematic structure, referring to fig. 1, and includes: the device comprises a main waveguide 1, K micro-ring cavities 2, K band-gap focusing light sources 3, K non-band-gap focusing light sources 4 and K/2 thermo-optic switches 5, wherein K is a positive integer; referring to fig. 1, K micro-ring cavities 2 are sequentially arranged on a main waveguide 1 one by one at equal intervals and coupled with the main waveguide 1 to form an array micro-cavity structure 21; a band-gap focusing light source 3 and a non-band focusing gap light source 4 are sequentially suspended over each micro-ring cavity 2, the main waveguide 1, the K micro-ring cavities 2 and the K/2 thermo-optical switches 5 are all made of chalcogenide materials, the chalcogenide materials are metastable short-range, medium-range, ordered and long-range disordered materials, and can be subjected to photoinduced change under the irradiation of near-band-gap light, and the internal atomic structures of the materials are recombined, wherein the photoinduced bleaching phenomenon is included. For the chalcogenide thin film integrated photonic device requiring broadband tuning, a band gap focusing light source 3 is used for directional irradiation, and the refractive index of the thin film is reduced due to the photobleaching effect of the chalcogenide thin film. The rate and amount of change of the refractive index of the film is related to the band gap optical power density and illumination time, and the change is irreversible without the influence of other external conditions. And for the case of reconstruction, the device is irradiated by using a non-band-gap infrared focusing light source, and the energy source of the irradiation photons is smaller than the band gap, so that the atomic structure of the material cannot be changed. When light energy is continuously input, a photothermal effect is generated due to non-band gap absorption, and the refractive index of the chalcogenide thin film is increased under the condition of temperature rise. The refractive index change is related to the power density of the irradiated non-bandgap light, but when the light source stops irradiating, the photothermal effect disappears, the temperature of the film is reduced to room temperature, and the refractive index returns to the state before the non-bandgap light irradiation.

In this embodiment, a schematic diagram of a curve change of a refractive index of a chalcogenide material along with a change of irradiation time of a band gap focusing light source and a non-band gap focusing light source is shown in fig. 2, wherein: (i) represents a curve change diagram of a refractive index of a chalcogenide material gradually decreasing when irradiated by a band gap focusing light source 3; ② the refractive index of the chalcogenide material is kept unchanged when the band-gap focusing light source 3 is turned off. Due to the photobleaching action of the chalcogenide material, the refractive index is reduced and the change is irreversible without the influence of other external conditions. The refractive index is increased when the non-band gap focusing light source 4 is turned on, and the refractive index of the material is reduced to the state before the refractive index is reduced when the non-band gap focusing light source is turned off.

In this embodiment, taking transmission of a downlink input optical signal as an example, the transmission of the uplink input optical signal is the same as that of the downlink input optical signal, referring to fig. 1, the downlink input optical signal is transmitted through the main waveguide 1, and is coupled with the array microcavity structure 21 in the main waveguide 1, and the output waveguide 22 is disposed on the same side of each micro-ring cavity 2, in actual implementation, under the frequency sweep of the broadband light source, according to the phase matching condition of the micro-ring cavity 2, the periodic wavelength propagated in the main waveguide 1 has a light absorption effect, and at the same time, the other side of the micro-ring cavity 2 can realize output of the periodic wavelength due to the phase matching condition, so that a lorentz-type absorption spectrum curve and a transmission spectrum curve occur, that is, the output waveguide 22 of the micro-ring cavity 2 outputs a free spectrum; a band-gap focusing light source 3 and a non-band-gap focusing light source 4 which are right above each micro-ring cavity 2 respectively irradiate in a directional mode, the band-gap focusing light source 3 causes a blue shift of a spectrum peak wavelength channel output by the micro-ring cavity 2, and the non-band-gap focusing light source 4 causes a red shift of the spectrum peak wavelength channel output by the micro-ring cavity 2;

referring to fig. 1, taking two adjacent micro-ring cavities in the frame in fig. 1 as an example, output ends of output waveguides of the two adjacent micro-ring cavities are coupled through a thermo-optic switch 5, and a non-band-gap focusing light source 4 absorbs light energy of a downlink input optical signal to generate a photo-thermal effect, the thermo-optic switch 5 is made of a chalcogenide material, and a refractive index is increased under a temperature rise condition to change a phase of light, in a specific optical link, as shown in fig. 3, a through link is arranged in the optical link, input light can be directly transmitted through, or after some downlink input optical signals need to be dropped, the downlink input optical signals are re-uplinked through some data processing, so that channels need to be switched, and therefore, based on thermo-optic characteristics, the thermo-optic switch 5 realizes optical path switching from the downlink input optical signals to the uplink input optical signals when the uplink input optical signals need to be loaded, and the time for the thermo-optic switch 5 to realize optical path switching from the downlink input optical signals to the uplink input optical signals does not exceed 100 ms.

In this embodiment, the optical add/drop multiplexer for scheduling the optical transmission channel further includes a partition panel 6, where the ith non-bandgap focused light source and the (i + 1) th bandgap focused light source are separated by the partition panel 6, where i is 1, …, K-1, so as to avoid mutual interference between the non-bandgap focused light source 4 and the bandgap focused light source 3, and specifically, referring to fig. 1, the first non-bandgap focused light source 4 and the second bandgap focused light source 3 are separated by the partition panel 6.

In this embodiment, the radius of the micro-ring cavity 2 is 1 μm to 500 μm, when the radii of the micro-ring cavities 2 are different, the free spectral ranges output by the micro-ring cavities 2 are different, and the downlink input optical signal is transmitted through the main waveguide 1 and coupled with the array micro-cavity structure 21 through the main waveguide 1, so as to realize the selective output of the resonant wavelengths of the micro-ring cavities 2.

In the design process, the radius of the micro-ring cavities 2 is reasonably designed to be 1 μm, 500 μm or 250 μm, so that the Free Spectral Range (FSR) of the micro-ring cavities 2 has slight deviation, and therefore, when the micro-ring cavities are coupled through the main waveguide 1, the selective output of the resonance wavelengths of different micro-ring cavities 2 can be realized. In the present embodiment, the radius of each micro-ring cavity 2 is designed to be 50 μm, and the array micro-cavity structure 21 outputs resonance spectra with equal intervals, so as to obtain optical channels with equal intervals, similar to DWDM with fixed intervals.

In the embodiment, the band-gap focusing light source 3 outputs short-wavelength light with a wavelength range of 206nm to 805 nm; the non-band gap focusing light source 4 outputs long-wavelength light with the wavelength range of 2-10 μm, and the short-wavelength light and the long-wavelength light can respectively realize the control of the output wave of the micro-ring cavity 2.

In this embodiment, the default thermo-optic switch 5 is switched to the downlink input optical signal path, and when the initialization state is set, as shown in fig. 4, the input wavelengths of the downlink input optical signal are distributed from short to long in the following order: lambda [ alpha ]_in1、λ_in2、λ_in3、…、λ_ini、…、λ_inkThe channels through which the input wavelengths of the downlink input optical signals sequentially pass are respectively: n is a radical of_out1、N_out2、N_out3、…、N_outi、…、N_outk，N_out1、N_out2、N_out3、…、N_outi、…、N_outkAnd the input wavelengths of the downlink input optical signals and the channels through which the input wavelengths of the downlink input optical signals sequentially pass are in one-to-one correspondence.

Input wavelength lambda of downstream input optical signal_iniAnd channel N_outiCorrespondingly, when the input wavelength λ is required_iniWhen blocking is performed, channel N is determined_outiSetting the irradiation power of a band-gap focusing light source right above the corresponding micro-ring i, and directionally irradiating the micro-ring i by using the band-gap focusing light source (N can be irradiated to the micro-ring i)_outiThe corresponding micro-ring cavity irradiates pulse/continuous light of a band-gap focusing light source, the irradiation power of the incident light is in direct proportion to the speed of frequency shift), and a channel N_outiIs blue-shifted from the input wavelength lambda_iniWavelength range of (1), input wavelength lambda_iniAttenuation until blocking, thereby achieving the input wavelength lambda_iniBlocking in one direction of the optical transmission channel, in this embodiment, specifically requires the input wavelength λ_in1When light blocking is implemented, by controlling channel N_out1Irradiating by band gap focusing light source above the corresponding micro-ring cavity to make channel N_out1Offset from the input wavelength lambda_in1In the wavelength range of (1), the process from light attenuation to light blocking is realized, fig. 5 is for the input wavelength λ_in1In an optical transmission channel N_out1The one direction (right side) of the block diagram. Directionally irradiating the micro-ring i by using a non-band gap focusing light source and a channel N_outiRed shift, shift of wavelength ofInput wavelength lambda_iniWavelength range of (1), input wavelength lambda_iniAttenuation until blocking can be realized, and input wavelength lambda can be realized_iniBlocking in the other direction of the optical transmission channel.

In this embodiment, the input wavelength λ of the downstream input optical signal_iniAnd channel N_outiCorresponding when the input wavelength λ_iniWhen the channel needs to be replaced for output, the channel is replaced to the channel N_outjDetermining a channel N_outiSetting the irradiation power of a band-gap focusing light source right above the corresponding micro-ring i, utilizing the band-gap focusing light source to irradiate the micro-ring i in a directional manner, and enabling the channel N to be a channel N_outiOffset to an out-of-band region; determining channel N_outjSetting the irradiation power of the band gap focusing light source 3 above the corresponding micro ring j, and utilizing the band gap focusing light source 3 to irradiate the micro ring j directionally to ensure that the channel N_outjBlue-shift to λ_iniAt the corresponding wavelength, the input wavelength λ_iniChange to channel N_outjOutput to thereby realize an input wavelength λ_iniScheduling at different optical transmission channels.

In this embodiment, the specific requirement is to input the wavelength λ_in2In channel N_out5When outputting, firstly, the channel N is paired_out2The corresponding micro-ring cavity is irradiated by a band gap focusing light source, so that the channel N_out2Wavelength shifted to the out-of-band region and then channel N_out5The corresponding micro-ring cavity is irradiated by a band gap focusing light source 3, so that a channel N is formed_out5Blue-shifted to the input wavelength lambda_in2At the corresponding wavelength, realizing the input wavelength lambda_in2In channel N_out5To output of (c). FIG. 6 is a graph of the wavelength λ of the input light_in2Switching to optical transmission channel N_out5Schematic diagram of the output.

The positional relationships depicted in the drawings are for illustrative purposes only and are not to be construed as limiting the present patent;

it should be understood that the above-described embodiments of the present invention are merely examples for clearly illustrating the present invention, and are not intended to limit the embodiments of the present invention. Other variations and modifications will be apparent to persons skilled in the art in light of the above description. And are neither required nor exhaustive of all embodiments. Any modification, equivalent replacement, and improvement made within the spirit and principle of the present invention should be included in the protection scope of the claims of the present invention.