阅读说明：本技术 一种高耦合效率的to非球面透镜 (TO aspheric lens with high coupling efficiency ) 是由 张士永 秦华 贺可祯 于 2021-02-21 设计创作，主要内容包括：本发明公开了光纤通信领域中用于将LD发出的光耦合进单模光纤的高效耦合的单个TO非球面透镜,该TO非球面透镜从光发射端至光接收端依次为前凸非球面和后凸非球面,透镜材料为K-VC89玻璃。该TO非球面透镜将LD发射波长1.310μm、发光面积4μm×3μm、出射光束发散角Y方向为±35°、Z方向为±23.58°的激光,在距离发射端6.23mm的接收端面会聚成为9.0μm×6.75μm的光斑,与数值孔径NA=0.16的单模光纤耦合效率理论计算为89.8%,实验最大耦合效率88.63%。(The invention discloses a single TO aspheric lens for efficient coupling, which is used for coupling light emitted by an LD into a single-mode fiber in the field of fiber communication, wherein the TO aspheric lens is a front convex aspheric surface and a back convex aspheric surface in sequence from a light emitting end TO a light receiving end, and the lens material is K-VC89 glass. The TO aspheric lens converges laser with an LD emission wavelength of 1.310 μm, a light emitting area of 4 μm × 3 μm, an emergent beam divergence angle of +/-35 ° in the Y direction and +/-23.58 ° in the Z direction into a spot of 9.0 μm × 6.75 μm on a receiving end surface 6.23mm away from an emission end, the theoretical calculation of the coupling efficiency of the TO aspheric lens with a single-mode fiber with a numerical aperture NA =0.16 is 89.8%, and the experimental maximum coupling efficiency is 88.63%.)

1. An efficiently coupled TO aspheric lens, comprising: the TO aspherical lens comprises a front surface (21), a rear surface (22) and a side surface (23); the TO aspheric lens couples laser with the wavelength of 1.310 mu m, the size of a light emitting surface of 4 mu m multiplied by 3 mu m, the divergence angle of the laser beam of +/-35 degrees in the Y direction and +/-23.58 degrees in the Z direction, and single-mode optical fiber with the numerical aperture NA =0.16 at the optical fiber receiving end 6.23mm away from the emitting end.

2. A high-efficiency coupling TO aspherical lens as claimed in claim 1, wherein the front surface (21) and the rear surface (22) are convex and the side surface (23) is a cylindrical surface with a diameter of 1.8 mm.

3. A high efficiency coupled TO aspheric lens as claimed in claim 1 characterized in that: the front surface (21) and the back surface (22) of the aspheric surface are aspheric surfaces, and the surface shape of the aspheric surface is described by an even-order aspheric surface equation with the highest order of 8:

wherein the content of the first and second substances,xthe axial value along the optical axis direction with the intersection point of each aspheric surface and the optical axis as the starting point,a ₂is the coefficient of the quadric surface; c is the center curvature of the mirror surface, R = 1/C is the radius of curvature of the center of the mirror surface,is the vertical axis height of a point on the mirror surface;a ₄，a ₆，a ₈for high order coefficients in the aspheric surface formula, these coefficients take the values listed in table 1:

。

4. a high efficiency coupled TO aspheric lens as claimed in claim 1 characterized in that: the distance between the vertex of the front surface (21) and the vertex of the rear surface (22) of the lens, i.e., the center thickness of the lens, was 1.1019 mm.

5. A high efficiency coupled TO aspheric lens as claimed in claim 1 characterized in that: the clear aperture of the front surface (21) is 1.5mm, and the clear aperture of the rear surface (22) is 1.8 mm.

6. A high efficiency coupled TO aspheric lens as claimed in claim 1 characterized in that: the material is K-VC89 glass, and the refractive index of the material is 1.78331 for light waves with the wavelength of 1.310 mu m.

Technical Field

The invention belongs to the field of optical fiber communication, and particularly relates to a technology for coupling light emitted by a semiconductor laser chip into a single-mode optical fiber through a pipe cap aspheric lens.

Background

A Transistor package (TO) is an international industry standard name for some special conductive electronic package. The TO package contains two elements: a tube socket and a tube cap. In the field of photoelectron, the tube cap has two functions, namely, forming a closed space to protect the chip from being oxidized, and focusing and coupling light emitted by the semiconductor laser chip into the optical fiber to ensure the smooth transmission of optical signals. The optical properties of the window or lens mounted in the cap must therefore meet quite high requirements.

In the field of optical fiber communication, a semiconductor laser LD is generally used as a light source. In an LD used for optical communication, a light emitting surface of a light emitting chip is generally 4 μm × 3 μm, a divergence angle of an emitted light beam is ± 35 ° in a Y direction, ± 23.58 ° in a Z direction, and a light emitting spot is elliptical. The optical fiber used is a single-mode optical fiber, the mode field diameter MFD of the single-mode optical fiber is generally about 9um (the mode field diameter of the optical fiber for general communication is 8.2 μm), and the numerical aperture NA is about 0.16, that is, light incident on the end face of the optical fiber must be converged into a spot having a diameter of about 9um or less, and the incident angle is less than 9.2 ° to enter the optical fiber, so as to form stable propagation.

With the increasing requirement on the optical communication speed, especially the development of the 5G communication technology, a higher requirement is put on the coupling efficiency of the coupling lens in the TO package optical module. The coupling lens in the TO cap evolved from a spherical lens TO an aspherical lens. TO cap lenses used in fiber optic communications are typically 3 types, spherical lenses 1.5mm and 2.0mm in diameter, and aspherical lenses 2.0mm in diameter. The spherical lens with the diameter of 1.5mm is commonly called a small spherical lens, and the effective numerical aperture is about 0.125; the spherical lens with the diameter of 2.0mm is commonly called a large spherical lens, the effective numerical aperture is about 0.16, and the coupling efficiency of the two tube cap spherical lenses is 5-15%. The effective numerical aperture of the tube cap non-spherical lens is about 0.16, and the coupling efficiency is 40% -50%.

Factors influencing the coupling efficiency of the pipe cap spherical lens are approximately (1) precision errors of a mechanical structure, including a transverse offset error, a longitudinal offset error and an angle; (2) limitation of machining accuracy; (3) absorption and fresnel loss of the material; (4) lens aberrations, mainly spherical aberrations. The first two factors are problems during processing and assembly, the third factor is determined by the nature of the material, and the fourth factor is a problem during lens design. Here, the present invention considers only the fourth factor. Because a single spherical lens cannot correct spherical aberration, the diameter of a light spot focused on the end face of the optical fiber is larger than the diameter of an optical fiber mode field, most of optical signals cannot enter the optical fiber, and loss of optical energy is caused. The single aspheric lens can correct spherical aberration, and the spherical aberration can be corrected to be minimum or even zero by optimizing aspheric parameters, so that the numerical aperture of the coupling lens is greatly expanded, the diameter of a light spot emitted by an LD and focused on the end face of an optical fiber through the lens is greatly reduced, and the coupling efficiency is greatly increased.

The invention designs a high-order aspheric lens, gives out high-order aspheric coefficients, simulates the coupling process by ray tracing, verifies the design result on zemax software, and carries out experimental verification on the design result, wherein the calculated coupling efficiency is 89.8%, the experimental maximum coupling efficiency is 88.63%, and the experimental average coupling efficiency is 79.39%.

Disclosure of Invention

The invention aims TO provide a special TO aspheric lens, which couples laser with the emitting wavelength of 1.310 mu m, the emitting beam divergence angle of +/-35 degrees in the Y direction and +/-23.58 degrees in the Z direction into single-mode optical fiber with numerical aperture NA =0.16 at an optical fiber receiving end 6.23mm away from an emitting end through the TO aspheric lens TO form stable optical fiber transmission.

According TO some possible embodiments, the single TO aspheric lens, which is a front surface and a back surface in order from the light beam incidence side TO the light beam exit side, both the front surface and the back surface are convex aspheric surfaces, i.e. biconvex aspheric lenses, and the lens material is K-VC89 glass, which has a refractive index of 1.78331 for a light wave with a wavelength of 1.310 μm. The aspherical surface profile is characterized by an even-order aspherical equation with the highest order of 8, and the aspherical coefficient is preferred.

Aiming at a specific light emitting surface and a light beam divergence angle, the single biconvex aspheric lens is adopted to efficiently couple emergent light into the single-mode optical fiber, so that the structure size is small, and the assembly is simple; the theoretical calculation of the fiber coupling efficiency of the outgoing laser with the numerical aperture NA =0.16, the emission surface of 4 μm × 3 μm, the divergence angle of the outgoing beam of ± 35 ° in the Y direction, and ± 23.58 ° in the Z direction, is 89.8%, the experimental maximum coupling efficiency is 88.63%, and the experimental average coupling efficiency is 79.39%.

The invention is further illustrated with reference to the following figures and examples:

FIGS. 1(A) and 1(B) are generalized diagrams of exemplary embodiments described herein;

FIG. 2(A) is a two-dimensional plot of the coupled optical path simulated by Zemax software for the examples described herein;

FIG. 2(B) is a three-dimensional view of the coupled optical path simulated by the example described herein using the self-programming matlab program;

FIG. 3(A) is a two-dimensional illustration of a focused spot at simulated light reception by the example computer described herein;

FIG. 3(B) is a three-dimensional graphical representation of a focused spot at an exemplary computer-simulated light reception described herein;

the coordinate unit of the relevant length in fig. 3(a) and 3(B) is μm;

in the figure: 1. light emitting surface, 2, aspheric lens, 3, light receiving surface, 4, TO cap, 5, TO package centerline.

Detailed Description

The following detailed description of example embodiments refers to the accompanying drawings

The optical axis (x-axis) of the aspheric lens 2 in the laser diode 1, the TO cap 4, the single mode fiber core is aligned with the TO package centerline 5. The TO cap supports the aspherical lens and encapsulates the aspherical lens 2 in a TO cap 4 as shown in fig. 1 (a).

As described above, the TO cap 4 specification shown in fig. 1(a) is provided only as an example. Other examples are possible and may differ from the TO cap 4 specifications described with respect TO FIG. 1 (A).

As shown in fig. 1(B), the laser beam is guided from the Laser Diode (LD) at the light emitting point 1 toward the light receiving point 3 and toward the SMF via the lens 2. The light emitting end of the laser diode is far away from the lens 2 along the optical axis by a distance of 0.975 mm. The rear surface 22 of the lens 2 is disposed with its apex away from the light receiving point 4.1531mm along the optical axis.

The lens 2 focuses the laser beam emitted from the laser diode toward the light receiving point 3 at the light emitting point 1, as shown in detail in fig. 1 (B).

The TO aspheric lens is coupled with a single-mode optical fiber with numerical aperture NA =0.16 at an optical fiber receiving end 6.23mm away from a light emitting end aiming at laser with the emitting wavelength of 1.310 μm, the size of a light emitting surface of 4 μm multiplied by 3 μm, the divergence angle of an emitting light beam in the Y direction of +/-35 DEG and the divergence angle of the emitting light beam in the Z direction of +/-23.58 deg.

Referring TO fig. 1(B), the TO aspheric lens includes a lens front surface (21) and a lens rear surface (22) in order from a light emitting end TO a light receiving end. Wherein the x-axis is the optical axis of the lens, and the front surface and the back surface of the lens are rotationally symmetric about the x-axis.

The TO aspheric lens is made of K-VC89 glass and has a refractive index of 1.78331 for light waves with a wavelength of 1.310 mu m.

Preferably, the distance between the vertex of the front surface (21) and the vertex of the rear surface (22) of the TO aspheric lens is 1.1019mm，The clear aperture of the front surface (21) is 1.5mm, the clear aperture of the rear surface (22) is 1.8mm, and the side surface is a cylindrical surface with the diameter of 1.8 mm.

Referring TO fig. 1(B), fig. 2(a) and fig. 2(B), the front surface 21 and the back surface 22 of the TO aspheric lens are both convex surfaces and are aspheric surfaces, and the surface shapes thereof are described by even aspheric equations with the highest order of 8:

wherein the content of the first and second substances,xthe axial value along the optical axis direction with the intersection point of each aspheric surface and the optical axis as the starting point,a ₂is the coefficient of the quadric surface; c is the center curvature of the mirror surface, R = 1/C is the radius of curvature of the center of the mirror surface,is the vertical axis height of a point on the mirror surface;a ₄，a ₆，a ₈preferred anterior surface 21 and posterior surface 22 aspheric coefficients for the highly polynomial coefficients in the aspheric equation are listed in Table 1

Referring TO fig. 2(a) and 2(B), the TO aspheric lens converges the emitted light at 1 TO the light receiving site 3. Fig. 2(a) is a 2-dimensional optical path diagram obtained by substituting the optimized related Data of the present invention into a corresponding position of Lens Data Editor in Zemax software, and the optical paths of 3 light-emitting points are shown in the diagram, wherein the light-emitting points are respectively a light-emitting point at 0 μm, namely, an on-axis light-emitting point, a light-emitting point at a vertical-axis height of 1.0 μm, and a light-emitting point at a vertical-axis height of 2.0 μm, and the Zemax shows a vertical-axis magnification of 2.24495. Fig. 2(B) is a three-dimensional optical path diagram of the TO aspherical lens of the present invention simulated by the self-compiled matlab program, where laser light with a light emitting surface of 4 μm × 3 μm, an outgoing light beam divergence angle of ± 35 ° in the Y direction and ± 23.58 ° in the Z direction is converged at a light receiving position.

Referring to fig. 3(a) and 3(B), two-dimensional and three-dimensional representations of the focused spots at the simulated light reception of the example computer are shown. Is obtained by tracing 32969025 ten thousand rays. It can be seen from FIGS. 3(A) and 3(B) that the shape of the light spot is consistent with that of the light-emitting surface, the light spot is about 9.0 μm × 6.75 μm, and most of the light falls within the diameter of the core of the optical fiber: (). This speckle pattern also illustrates that the coupling lens not only performs the coupling function, but also has imaging characteristics with a vertical axis magnification of about 2.25, which is approximately equal to the vertical axis magnification 2.24495 shown in Zemax.