阅读说明：本技术 一种多波长激光器以及波长控制方法 (Multi-wavelength laser and wavelength control method ) 是由 赵壮 孙旭 赵臻青 曾金林 于 2019-08-30 设计创作，主要内容包括：本申请公开了一种多波长激光器以及波长控制方法。在一个具体实现中,多波长激光器包括波导、第一电极和第二电极。其中,第一电极和第二电极设置于波导上。第一电极与第二电极电隔离。第一电极包括多个子电极,且每两个相邻的子电极之间电隔离。第二电极用于通过加载电流放大波导内的光信号。至少一个子电极用于通过加载电流或电压调节波导内光信号的波长。在工作状态下第一电极长度的不同将使得波导内光场能量不同,进而使得波导内温度的不同,从而使得多波长激光器可以发射不同波长范围的光信号。此多波长激光器可以更快地调节波导内的温度,缩短了波长调节的时间。(The application discloses a multi-wavelength laser and a wavelength control method. In one particular implementation, a multi-wavelength laser includes a waveguide, a first electrode, and a second electrode. Wherein the first electrode and the second electrode are disposed on the waveguide. The first electrode is electrically isolated from the second electrode. The first electrode comprises a plurality of sub-electrodes, and every two adjacent sub-electrodes are electrically isolated. The second electrode is used for amplifying the optical signal in the waveguide by loading current. At least one sub-electrode is used for adjusting the wavelength of the optical signal in the waveguide by loading current or voltage. Under the working state, the different lengths of the first electrodes enable the different light field energies in the waveguide, and further enable the different temperatures in the waveguide, so that the multi-wavelength laser can emit light signals in different wavelength ranges. The multi-wavelength laser can adjust the temperature in the waveguide more quickly, and shortens the wavelength adjusting time.)

1. A multi-wavelength laser, comprising: waveguide, first electrode and second electrode, wherein:

the first electrode and the second electrode are arranged on the waveguide, the first electrode is electrically isolated from the second electrode, the first electrode comprises a plurality of sub-electrodes, and every two adjacent sub-electrodes are electrically isolated from each other;

the second electrode is used for amplifying the optical signal in the waveguide by loading current;

at least one of the sub-electrodes is used for controlling the wavelength range of the optical signal in the waveguide by loading current or voltage.

2. The multiwavelength laser of claim 1, wherein the length of each of the sub-electrodes is different.

3. The multiwavelength laser of claim 1 or 2, wherein the first electrode has a first length and the second electrode has a second length, the first length being the sum of the lengths of all the sub-electrodes, the ratio of the first length to a third length being less than or equal to 12%, the third length being the sum of the first length and the second length.

4. The multiwavelength laser of any of claims 1 to 3, wherein the first electrode is provided on one of the sides of the second electrode, or wherein the first electrode is provided on both sides of the second electrode.

5. The multiwavelength laser of any of claims 1 to 4, further comprising a controller, a plurality of switches, and a current source; the switches are in one-to-one correspondence with the sub-electrodes, one end of each switch is connected with the sub-electrode corresponding to each switch, the other end of each switch is connected with the current source, the second electrode is connected with the current source, and the controller is used for controlling each switch.

6. The multiwavelength laser of claim 5, further comprising a first voltage source, the current source comprising a first current source, the second electrode being connected to the first current source, the other terminal of each of the switches being connected to the first voltage source;

the controller is used for controlling each switch to be communicated with the first current source or the first voltage source.

7. The multiwavelength laser of claim 5, further comprising a plurality of second voltage sources, the plurality of second voltage sources being in one-to-one correspondence with the plurality of switches, the current sources comprising a first current source, the second electrode being connected to the first current source, the other end of each of the switches being connected to the second voltage source corresponding to each of the switches;

the controller is used for controlling each switch to be communicated with the first current source or the second voltage source corresponding to each switch.

8. The multiwavelength laser of claim 5, further comprising a plurality of second voltage sources, the plurality of second voltage sources being in one-to-one correspondence with the plurality of switches, the current sources comprising a first current source and a plurality of second current sources, the plurality of second current sources being in one-to-one correspondence with the plurality of switches, the second electrode being connected to the first current source, the other end of each of the switches being connected to the second current source corresponding to each of the switches, the other end of each of the switches being connected to the second voltage source corresponding to each of the switches;

the controller is used for controlling each switch to be communicated with the second current source corresponding to each switch or the second voltage source corresponding to each switch.

9. The multiwavelength laser of any of claims 1 to 8, wherein the material of the waveguide comprises at least one or more of: GaAs, InGaAs, or InP semiconductor quantum dots, quantum wires, or quantum wells.

10. A method of wavelength control, the method comprising:

acquiring the corresponding relation between the length of a first electrode and the wavelength of an optical signal in a waveguide, wherein the first electrode is arranged on the waveguide and comprises a plurality of sub-electrodes, and every two adjacent sub-electrodes are electrically isolated;

selecting at least one sub-electrode from the first electrodes according to the corresponding relation;

controlling a wavelength range of the optical signal by loading a current or voltage on the at least one sub-electrode, and amplifying the optical signal by loading a current on a second electrode disposed on the waveguide, the first electrode being electrically isolated from the second electrode.

11. The method of claim 10, wherein each of the sub-electrodes is connected to a first current source through a switch corresponding to each of the sub-electrodes, or each of the sub-electrodes is connected to a first voltage source through a switch corresponding to each of the sub-electrodes, and wherein controlling the wavelength range of the optical signal by loading a current or voltage on the at least one sub-electrode comprises:

and controlling the wavelength range of the optical signal by connecting the switch corresponding to the at least one sub-electrode with the first current source or the first voltage source.

12. The method of claim 10, wherein each of the sub-electrodes is connected to a second current source corresponding to each of the switches through a switch corresponding to each of the sub-electrodes, or each of the sub-electrodes is connected to a second voltage source corresponding to each of the switches through a switch corresponding to each of the sub-electrodes, and wherein controlling the wavelength range of the optical signal by loading a current or a voltage on the at least one sub-electrode comprises:

and controlling the wavelength range of the optical signal by connecting the switch corresponding to the at least one sub-electrode with the second current source or the second voltage source.

13. The method of any one of claims 10 to 12, wherein the length of each of the sub-electrodes is different.

14. The method of any one of claims 10 to 13, wherein the first electrode has a first length and the second electrode has a second length, the first length being the sum of the lengths of all of the sub-electrodes, the ratio of the first length to a third length being less than or equal to 12%, the third length being the sum of the first length and the second length.

15. The method of any one of claims 10 to 14, wherein the first electrode is disposed on one side of the second electrode, or wherein the first electrode is disposed on both sides of the second electrode.

16. The method of any one of claims 10 to 15, wherein the material of the waveguide comprises at least one or more of: GaAs, InGaAs, or InP semiconductor quantum dots, quantum wires, or quantum wells.

Technical Field

The present disclosure relates to the field of optical communications, and in particular, to a multi-wavelength laser and a wavelength control method.

Background

With the development of large-capacity optical fiber communication networks, multi-wavelength laser light sources for simultaneously providing light sources for a plurality of channels are increasingly used. The multi-wavelength laser light source can enable the design of the transmitting end to be more compact, greatly reduces the cost and the power consumption, and is the key for expanding the capacity of the optical fiber communication system.

A Mode-Locked Laser (MLL) is one of the multi-wavelength light sources. The mode-locked laser consists of a gain area and a saturable absorption area, the two areas share the same waveguide, and electrodes corresponding to the two areas are electrically isolated through an electrical isolation groove. When the multi-wavelength laser works, the gain region forms gain by adding forward current, the saturable absorption region controls the nonlinear saturable absorption characteristic in a laser cavity of the mode-locked laser by adding reverse bias, namely the absorption coefficient of the laser cavity to light is reduced along with the increase of light intensity, and absorption is stopped when absorption reaches saturation, so that the multi-wavelength laser realizes mode locking and outputs pulses with narrower width on a time domain, thereby displaying multi-wavelength output on a frequency domain. Wavelength tuning of mode-locked lasers is currently generally achieved through temperature control. Specifically, the package structure of the mode-locked laser includes a Thermoelectric Cooler (TEC). Changes in TEC temperature will affect the operating temperature of the mode-locked laser. For example, as temperature increases, the wavelength of the optical signal emitted by the mode-locked laser may become longer.

However, since heat transfer takes time, the operating temperature of the mode-locked laser does not change immediately as the TEC temperature changes, resulting in a longer time required to adjust the output wavelength of the laser.

Disclosure of Invention

The embodiment of the application provides a multi-wavelength laser and a wavelength control method, which shorten the time for adjusting the wavelength of an optical signal.

In a first aspect, embodiments of the present application provide a multi-wavelength laser including a waveguide, a first electrode, and a second electrode. Wherein the first electrode and the second electrode are disposed on the waveguide; the first electrode is electrically isolated from the second electrode; the first electrode comprises a plurality of sub-electrodes, and every two adjacent sub-electrodes are electrically isolated; the second electrode is used for amplifying the optical signal in the waveguide by loading current; at least one of the sub-electrodes is used for controlling the wavelength range of the optical signal in the waveguide by loading current or voltage.

In this embodiment, the first electrode is composed of a plurality of sub-electrodes, the working length of the first electrode is the total length of the sub-electrodes loaded with current or voltage, and different lengths can be selected according to needs. The change of the working length enables the light field energy in the waveguide to be different, and further enables the temperature in the waveguide to be different, so that the multi-wavelength laser can emit light signals in different wavelength ranges. The multi-wavelength laser can realize faster adjustment of the temperature in the waveguide, i.e. shorten the wavelength control time.

In some possible embodiments, the length of each sub-electrode is different. It is possible to make the working length of the first electrode more possible and thus the wavelength tunable range of the optical signal larger.

In some possible embodiments, the first electrode has a first length, the second electrode has a second length, the first length is the sum of the lengths of all the sub-electrodes, the ratio of the first length to the third length is less than or equal to 12%, and the third length is the sum of the first length and the second length. In this embodiment, since the longer the first length, the larger the drive current required for the multi-wavelength laser to generate laser light, such a design can reduce the drive power consumption of the multi-wavelength laser.

In some possible embodiments, the multiwavelength laser further includes a controller, a plurality of switches and a current source, the plurality of switches are in one-to-one correspondence with the plurality of sub-electrodes, one end of each switch is connected to the sub-electrode corresponding to each switch, the other end of each switch is connected to the current source, the second electrode is connected to the current source, and the controller is configured to control each switch. In this embodiment, a specific implementation manner of applying a current to the sub-electrode is provided, which improves the practicability of the scheme.

In some possible embodiments, the multi-wavelength laser further includes a first voltage source, the current source includes a first current source, the second electrode is connected to the first current source, the other end of each switch is connected to the first current source, and the other end of each switch is connected to the first voltage source. The controller is used for controlling each switch to be communicated with the first current source or the first voltage source. In the embodiment, each switch can be controlled to be connected with a current source or a voltage source, so that the expansibility of the scheme is improved.

In some possible embodiments, the multiwavelength laser further includes a plurality of second voltage sources, the plurality of second voltage sources are in one-to-one correspondence with the plurality of switches, the current source includes a first current source, the second electrode is connected to the first current source, the other end of each switch is connected to the first current source, and the other end of each switch is connected to the second voltage source corresponding to each switch. The controller is used for controlling each switch to be communicated with the first current source or the second voltage source corresponding to each switch. In this embodiment, since the magnitude of the voltage applied to each sub-electrode may affect the wavelength of the optical signal in the waveguide, each sub-electrode is connected to a different voltage source, so that the wavelength tunable range of the optical signal in the waveguide may be larger.

In some possible embodiments, the multiwavelength laser further includes a plurality of second voltage sources, the plurality of second voltage sources are in one-to-one correspondence with the plurality of switches, the current sources include a first current source and a plurality of second current sources, the plurality of second current sources are in one-to-one correspondence with the plurality of switches, the second electrode is connected to the first current source, the other end of each switch is connected to the second current source corresponding to each switch, and the other end of each switch is connected to the second voltage source corresponding to each switch. The controller is used for controlling each switch to be communicated with the second current source corresponding to each switch or the second voltage source corresponding to each switch. In this embodiment, the magnitude of the loading current on each sub-electrode also affects the wavelength of the optical signal in the waveguide, so that each sub-electrode is connected to a different current source, and the wavelength tunable range of the optical signal in the waveguide can be made larger, and each sub-electrode can be connected to both a current source corresponding thereto and a voltage source corresponding thereto, and the tuning manner is more flexible.

In some possible embodiments, the first electrode is disposed on one side of the second electrode, or the first electrode is disposed on both sides of the second electrode, so that the structure of the multi-wavelength laser has more possibilities.

In some possible embodiments, the material of the waveguide comprises at least one or more of: GaAs, InGaAs, or InP semiconductor quantum dots, quantum wires, or quantum wells. In this embodiment, several waveguide materials are provided, improving the realizability of the present solution.

In a second aspect, embodiments of the present application provide a wavelength control method. The method comprises the following steps.

The multi-wavelength laser acquires the corresponding relation between the length of a first electrode and the wavelength of an optical signal in a waveguide, wherein the first electrode is arranged on the waveguide and comprises a plurality of sub-electrodes, and every two adjacent sub-electrodes are electrically isolated. And then, the multi-wavelength laser selects at least one sub-electrode from the first electrodes according to the corresponding relation. Further, the multi-wavelength laser controls a wavelength range of the optical signal by applying a current or a voltage to at least one of the sub-electrodes, and amplifies the optical signal by applying a current to a second electrode, wherein the second electrode is disposed on the waveguide, and the first electrode is electrically isolated from the second electrode.

In some possible embodiments, each sub-electrode is connected to the first current source through a switch corresponding to each sub-electrode, or each sub-electrode is connected to the first voltage source through a switch corresponding to each sub-electrode, and controlling the wavelength range of the optical signal by applying a current or a voltage to at least one sub-electrode includes: the wavelength range of the optical signal is controlled by connecting a switch corresponding to at least one sub-electrode to a first current source or a first voltage source.

In some possible embodiments, each sub-electrode is connected to the second current source corresponding to each switch through the switch corresponding to each sub-electrode, or each sub-electrode is connected to the second voltage source corresponding to each switch through the switch corresponding to each sub-electrode, and adjusting the wavelength range of the optical signal by applying a current or a voltage to at least one sub-electrode includes: and controlling the wavelength range of the optical signal by connecting the switch corresponding to at least one sub-electrode with a second current source or a second voltage source.

In some possible embodiments, the length of each sub-electrode is different.

In some possible embodiments, the first electrode has a first length, the second electrode has a second length, the first length is the sum of the lengths of all the sub-electrodes, the ratio of the first length to the third length is less than or equal to 12%, and the third length is the sum of the first length and the second length.

In some possible embodiments, the first electrode is disposed on one side of the second electrode, or the first electrode is disposed on both sides of the second electrode.

The materials of the waveguide are described in detail in the first aspect, and are not described in detail here.

According to the technical scheme, the embodiment of the application has the following advantages: the first electrode is composed of a plurality of sub-electrodes, the working length of the first electrode is the total length of the sub-electrodes loaded with current or voltage, the wavelength range of the emitted optical signals is controlled by changing the working length of the first electrode, and the wavelength control time is effectively shortened.

Drawings

Fig. 1 is a schematic structural diagram of a first multi-wavelength laser provided in an embodiment of the present application;

FIG. 2 is a schematic diagram of the wavelength of the emission signal of the multi-wavelength laser as a function of the working length of the first electrode;

FIG. 3 is a diagram illustrating the relationship between the driving current and the first electrode ratio;

fig. 4 is a schematic structural diagram of a second multi-wavelength laser provided in the embodiment of the present application;

fig. 5(a) is a schematic structural diagram of a third multi-wavelength laser provided in the embodiments of the present application;

fig. 5(b) is a schematic structural diagram of a fourth multi-wavelength laser provided in the embodiment of the present application;

fig. 5(c) is a schematic structural diagram of a fifth multi-wavelength laser provided in the embodiment of the present application;

fig. 5(d) is a schematic structural diagram of a sixth multi-wavelength laser according to an embodiment of the present application;

fig. 5(e) is a schematic structural diagram of a seventh multi-wavelength laser according to an embodiment of the present application;

fig. 5(f) is a schematic structural diagram of an eighth multi-wavelength laser according to an embodiment of the present application;

fig. 6 is a flowchart illustrating a wavelength control method according to an embodiment of the present disclosure.

Detailed Description

The embodiment of the application provides a multi-wavelength laser and a wavelength control method, and the multi-wavelength laser can emit optical signals in different wavelength ranges in a voltage or current loading mode. Compared with the TEC temperature control technology, the technical scheme disclosed by the application can be used for adjusting the temperature in the waveguide more quickly, and the time for adjusting the wavelength of the optical signal is shortened. It should be noted that the multi-wavelength laser in the present application may specifically be a mode-locked laser. The wavelength range may also be referred to as a waveband.

It should be noted that the terms "first," "second," "third," and "fourth," etc. in the description and claims of this application and the above-mentioned drawings are used for distinguishing between similar elements and not necessarily for limiting a particular order or sequence. It is to be understood that the terms so described are interchangeable under appropriate circumstances such that the embodiments described herein are capable of operation in other sequences than described of illustrated herein. Furthermore, the terms "comprising" and "having," as well as any variations thereof, are intended to cover non-exclusive inclusions. For example, a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements explicitly listed, but may include other steps or elements not explicitly listed or inherent to such process, method, article, or apparatus.

Fig. 1 is a schematic structural diagram of a first multi-wavelength laser according to an embodiment of the present disclosure. The multi-wavelength laser includes: a waveguide 101, a first electrode 102 and a second electrode 103. The first electrode 102 and the second electrode 103 are disposed on the waveguide 101, and the first electrode 102 is electrically isolated from the second electrode 103, i.e., a gap is formed between the first electrode 102 and the second electrode 103. For example, the waveguide 101 may be covered with a complete electrode, and then the electrode may be grooved. One side of the slot is the first electrode 102 and the other side of the slot is the second electrode 103.

It should be noted that the first electrode 102 includes a plurality of sub-electrodes 1021, and every two adjacent sub-electrodes 1021 are electrically isolated. For example, as shown in fig. 3, the first electrode 102 may be divided into three sub-electrodes 1021 by forming two slots on the first electrode. It is understood that the number of the sub-electrodes 1021 in the first electrode 102 is not limited to the practical application. In addition, the size of the slot between the first electrode 102 and the second electrode 103 and the size of the slot between each sub-electrode 1021 in the first electrode 102 are subject to practical application, and are not limited herein.

The first electrode 102 and the second electrode 103 will be further described below. Specifically, the wavelength ranges of the optical signals within the waveguide 101 are controlled by loading a current or voltage on at least one sub-electrode 1021 in the first electrode 102, such that the multi-wavelength laser emits optical signals of different wavelength ranges. The working length of the first electrode 102 is the total length of the sub-electrode 1021 loaded with voltage or current. It should be noted that the difference in the working length of the first electrode 102 may cause the energy of the optical field in the waveguide 101 to be different, and further cause the temperature in the waveguide 101 to be different, so that the laser emits optical signals in different wavelength ranges. The second electrode 103 achieves population inversion by loading a current to amplify the optical signal within the waveguide 101.

It should be noted that the multi-wavelength laser can output multi-wavelength signals through a mode locking technique, that is, pulses with narrower widths are output in a time domain through mode locking, so that multi-wavelength output is presented in a frequency domain. It is understood that mode locking can be achieved by applying either a voltage or a current to the first electrode 102. In the first case, the voltage applied to the first electrode 102 may specifically be a reverse bias voltage, so as to implement the saturable absorption characteristic of the waveguide 101, that is, the absorption coefficient of the waveguide 101 to light decreases with the increase of light intensity, and when the absorption reaches saturation, the absorption is stopped, so that the mode locking of the multi-wavelength laser is implemented. In another case, a current is applied to the first electrode 102, and the multi-wavelength laser realizes mode locking due to the nonlinear effect of four-wave mixing.

Taking the multi-wavelength laser of the present application as an example, the first electrode corresponds to the saturable absorption region of the mode-locked laser, and the second electrode corresponds to the gain region of the mode-locked laser.

Fig. 2 is a schematic diagram of the wavelength of the emission signal of the multi-wavelength laser as a function of the working length of the first electrode. As can be seen from fig. 2, the center wavelength of the emission signal changes with the change in the working length of the first electrode. Specifically, when the working length of the first electrode 102 is 90 μm, the center wavelength of the emission signal is 1532 nm; when the working length of the first electrode 102 is 70 μm, the center wavelength of the emission signal is 1537 nm; when the working length of the first electrode 102 is 50 μm, the center wavelength of the emission signal is 1550 nm.

Taking the lengths of the three sub-electrodes 1021 shown in fig. 1 as a, b, and c as an example, the working length of the first electrode can be 7 possibilities, a, b, c, a + b, a + c, b + c, and a + b + c. Assuming that a is 50 μm, b is 20 μm, and c is 20 μm, then, corresponding to fig. 2, when the working length of the first electrode is a + b + c, the central wavelength of the emitted signal is 1532 nm; when the working length of the first electrode is a + b or a + c, the central wavelength of the emitted signal is 1537 nm; when the working length of the first electrode is a, the central wavelength of the emitted signal is 1550 nm.

It should be noted that the lengths of the sub-electrodes 1021 may be the same or different, and are not limited herein. Alternatively, setting the length of each sub-electrode 1021 to be different may make the working length of the first electrode more likely, and thus make the range over which the wavelength of the emitted signal can be adjusted larger.

Alternatively, the longer the working length of the first electrode 102, the larger the drive current required for the multi-wavelength laser to generate laser light. In order to reduce the driving current required for the laser light generated by the multi-wavelength laser, the ratio of the length of the first electrode 102 to the total length of the electrodes (including the first electrode 102 and the second electrode 103) is less than or equal to 12%, that is, the ratio of the first electrode is less than or equal to 12%.

FIG. 3 is a diagram illustrating the relationship between the driving current and the first electrode. It can be seen that the increase of the driving current is small in the process of increasing the first electrode ratio from 3% to 12%. When the occupancy of the first electrode is increased from 12% to 15% or even 19%, the increase of the driving current is significantly large, i.e. a large driving current is required to enable the multi-wavelength laser to generate laser light. Therefore, the ratio of the first electrode is less than or equal to 12%, and the driving power consumption of the multi-wavelength laser can be reduced.

It should be noted that the difference in the material of the waveguide 101 affects the ratio of the driving current to the first electrode. Therefore, in practical applications, the ratio of the first electrode can be designed according to requirements, for example, the ratio of the first electrode is less than or equal to 10%, and is not limited herein.

Alternatively, as shown in fig. 1, the waveguide 101 has a first end surface 1011 and a second end surface 1012, and the first end surface 1011 and the second end surface 1012 may be coated for enhancing resonance in the waveguide 101. Wherein, the first end surface 1011 can be plated with a high reflection film with a reflectivity of more than 99%. The optical signal in the waveguide 101 is output from the second end surface 1012, and the reflectivity of the thin film coated on the second end surface 1012 can be flexibly designed to adjust the threshold of the driving current of the laser generated by the multi-wavelength laser and the power of the output optical signal. It should be noted that the second end surface 1012 may be coated with a high-reflection film with a reflectivity greater than 99%, the optical signal in the waveguide 101 is output from the first end surface 1011, and the reflectivity of the film coated on the first end surface 1011 may be flexibly designed, which is not limited herein. It will also be appreciated that the optical signal is laser light generated within the waveguide 101.

Fig. 4 is a schematic structural diagram of a second multi-wavelength laser according to an embodiment of the present application. Unlike the multi-wavelength laser shown in fig. 1, the first electrode 102 is disposed on both sides of the second electrode 103. Specifically, the waveguide 101 is covered with a layer of electrode, two slots are disposed on the electrode, and the electrode located in the middle of the two slots is the second electrode 103. The electrodes on both sides of the second electrode 103 are the first electrodes 102. The number of the sub-electrodes 1021 of the first electrode 102 may be set as desired.

Optionally, the material of the waveguide 101 may include at least one or more of: gallium arsenide (GaAs), indium gallium arsenide (InGaAs), indium phosphide (InP) semiconductor quantum dots, semiconductor quantum wires, or semiconductor quantum wells. It should be noted that, in practical applications, the material of the waveguide 101 includes, but is not limited to, the above listed materials.

In practice, there are many different implementations for adjusting the wavelength of the optical signal in the waveguide 101, which will be described separately below.

The first implementation mode comprises the following steps: fig. 5(a) is a schematic structural diagram of a third multi-wavelength laser according to an embodiment of the present application. The multi-wavelength laser further comprises a controller 104, a plurality of switches 105 and a first current source 106. Each switch 105 corresponds to each sub-electrode 1021 in the first electrode 102, one end of each switch 105 is connected to the corresponding sub-electrode 1021, the other end of each switch 105 is connected to the first current source 106, and the first current source 106 is connected to the second electrode 103. The controller 104 can load the current of the first current source 106 on the corresponding sub-electrode 1021 by controlling the switch 105 to be closed.

The second implementation mode comprises the following steps: fig. 5(b) is a schematic structural diagram of a fourth multi-wavelength laser according to an embodiment of the present application. The multi-wavelength laser includes a first current source 106 and a plurality of second current sources (e.g., second current source 107a, second current source 107b, and second current source 107 c). The number of the second current sources is the same as the number of the switches 105, and the second current sources are in one-to-one correspondence, one end of each switch 105 is connected to the corresponding sub-electrode 1021, the other end of each switch 105 is connected to each second current source, and the first current source 106 is connected to the second electrode 103. The controller 104 can load the current of the second current source on the corresponding sub-electrode 1021 by controlling the switch 105 to be closed.

It should be noted that the magnitude of the current applied to each sub-electrode 1021 may affect the wavelength of the optical signal in the waveguide 101. Therefore, each sub-electrode is connected to a different second current source, which can make the wavelength tunable range of the optical signal in the waveguide 101 larger.

The third implementation mode comprises the following steps: fig. 5(c) is a schematic structural diagram of a fifth multi-wavelength laser according to an embodiment of the present application. The multi-wavelength laser includes a first current source 106 and a first voltage source 108. The first current source 106 is connected to the second electrode 103, one end of each switch 105 is connected to the corresponding sub-electrode 1021, and the other end of each switch 105 is connected to the first voltage source 108. The controller 104 applies the voltage of the first voltage source 108 to the corresponding sub-electrode 1021 by controlling the switch 105 to be closed.

The fourth implementation mode comprises the following steps: fig. 5(d) is a schematic structural diagram of a sixth multi-wavelength laser according to an embodiment of the present application. The multi-wavelength laser includes a first current source 106 and a first voltage source 108. Each switch 105 is a dual-control switch, that is, each switch 105 may connect its corresponding sub-electrode 1021 to the first current source 106, or may connect its corresponding sub-electrode 1021 to the first voltage source 108. Specifically, one end of each switch 105 is fixedly connected to the corresponding sub-electrode 1021, and the other end of each switch 105 can be switched over two contacts, which are respectively connected to the first current source 106 and the first voltage source 308. The controller 104 can apply the current of the first current source 106 or the voltage of the first voltage source 308 to the corresponding sub-electrode 1021 by controlling the switch 105 to switch between two contacts. In addition, the first current source 106 is connected to the second electrode 103. In this implementation, the sub-electrode 1021 can be loaded with both current and voltage, which improves the flexibility of this scheme. The two contacts may be referred to as the other end and the one end, respectively.

The fifth implementation manner: fig. 5(e) is a schematic structural diagram of a seventh multi-wavelength laser according to an embodiment of the present application. The multi-wavelength laser includes a first current source 106, a plurality of second current sources (e.g., second current source 107a, second current source 107b, and second current source 107c), and a plurality of second voltage sources (e.g., second voltage source 109a, second voltage source 109b, and second voltage source 109 c). The number of the second voltage sources is consistent with the number of the switches 105 and corresponds to one another. Each switch 105 is a dual-control switch, i.e., each switch 105 can connect its corresponding sub-electrode 1021 to one of the second current sources, or can connect its corresponding sub-electrode 1021 to one of the second voltage sources. Specifically, one end of each switch 105 is fixedly connected to the corresponding sub-electrode 1021, and the other end of each switch 105 can be switched over two contacts, which are respectively connected to one of the second current sources and one of the second voltage sources. The controller 104 can apply the current of the second current source or the voltage of the second voltage source to the corresponding sub-electrode 1021 by controlling the switch 105 to switch between the two contacts. In addition, the first current source 106 is connected to the second electrode 103. In this implementation, the magnitude of the voltage applied to each sub-electrode 1021 affects the wavelength of the optical signal within the waveguide 101. Therefore, each sub-electrode is connected with a different second voltage source, so that the wavelength tunable range of the optical signal in the waveguide 101 is larger, and the sub-electrode 1021 can be loaded with current or voltage, thereby improving the flexibility of the scheme.

The sixth implementation manner: fig. 5(f) is a schematic structural diagram of an eighth multi-wavelength laser according to an embodiment of the present application. The sub-electrodes 1021 are disposed on both sides of the second electrode 103. Similar to fig. 5(a), the multiwavelength laser further comprises a controller 104, a plurality of switches 105, and a first current source 106. Each switch 105 corresponds to each sub-electrode 1021 in the first electrode 102, one end of each switch 105 is connected to the corresponding sub-electrode 1021, the other end of each switch 105 is connected to the first current source 106, and the first current source 106 is connected to the second electrode 103. The controller 104 can load the current of the first current source 106 on the corresponding sub-electrode 1021 by controlling the switch 105 to be closed. It is understood that the above-mentioned implementations of fig. 5(b) -5 (e) are also applicable to the structure in which the sub-electrodes 1021 are disposed on both sides of the second electrode 103, and are not specifically listed here.

In practical applications, the manner of applying the current or the voltage to the sub-electrode 1021 of the first electrode 102 includes, but is not limited to, the above-listed six embodiments. It is understood that the controller 104 may be a Micro Controller Unit (MCU) specifically.

It should be noted that, the TEC may also be disposed in the package structure of the multi-wavelength laser, and since the temperature of the TEC may also affect the wavelength of the optical signal output by the multi-wavelength laser, the wavelength adjustment mode of the multi-wavelength laser may be more flexible by combining with temperature control.

In this embodiment, by changing the working length of the first electrode, the energy of the optical field in the waveguide is changed, and further the temperature in the waveguide is changed, so as to achieve the purpose of rapidly adjusting the wavelength range of the optical signal emitted by the multi-wavelength laser.

Based on the above description of the multi-wavelength laser, a wavelength control method corresponding to the laser is described below. It should be noted that the device structure corresponding to the wavelength control method described below can be as described in the above device embodiments. However, it is not limited to the multi-wavelength laser described above.

Fig. 6 is a flowchart illustrating a wavelength control method according to an embodiment of the present disclosure. In this example, the wavelength control method includes the following steps.

601. The correspondence between the length of the first electrode and the wavelength of the optical signal within the waveguide is obtained.

In this embodiment, since the working length of the first electrode 102 may affect the wavelength of the optical signal in the waveguide 101, the corresponding relationship between the length of the first electrode 102 and the wavelength of the optical signal in the waveguide 101 may be predetermined and stored by the multi-wavelength laser.

It should be noted that, the correspondence relationship is different between the currents or voltages applied to the sub-electrodes 1021. Thus, in the above examples of fig. 5(a) -5(f), the correspondence stored by the multi-wavelength laser is uniquely determined.

602. At least one sub-electrode 1021 is selected from the first electrodes according to the correspondence.

In this embodiment, the multi-wavelength laser may determine a target wavelength of an optical signal to be output, and then determine the length of the first electrode 102 corresponding to the target wavelength according to the corresponding relationship, so as to determine the sub-electrode 1021 to be used.

603. The wavelength range of the optical signal is controlled by applying a current or voltage to the at least one sub-electrode 1021, and the optical signal is amplified by applying a current to the second electrode.

Having determined the sub-electrodes 1021 that need to be used, the controller 104 of the multi-wavelength laser can control the wavelength range of the optical signal by applying a current or voltage to the selected sub-electrodes 1021, and amplify the optical signal by applying a current to the second electrode. The controller 104 may load the current or the voltage by controlling the switch 105 corresponding to the sub-electrode 1021 to be closed or switched, which may refer to the embodiments shown in fig. 5(a) -5(f) and will not be described again.

It should be noted that the above embodiments are only used for illustrating the technical solutions of the present application, and not for limiting the same. Although the present application has been described in detail with reference to the foregoing embodiments, it should be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions in the embodiments of the present application.