RU2279702C2 - Collimating optical system for semiconductor lasers - Google Patents

Abstract

FIELD: optical engineering.

SUBSTANCE: collimating optical system has objective disposed in series along beam path, which objectives are mounted in opposition to semiconductor lasers, and first group of prisms. Ribs of refracting two-faced angles of lasers are oriented in parallel to planes of semiconductor junctions. First positive component is mounted one after another along beam path behind group of prisms. Second group of prisms is disposed close to back focal plane of first positive component. The group of prisms separates input light beam along line being perpendicular to planes of semiconductor junction to two bundles. Polarization prism is disposed on the way of mentioned light beams to bring them into coincidence to one common light beam. Second positive component of the system has front focal plane brought into coincidence with back focal plane of first positive component.

EFFECT: increased brightness of output bundle of beams.

2 cl, 4 dwg

Description

The invention relates to collimating optical systems with refractive elements and can be used in optical location systems, optical communications, control and monitoring devices.

Known collimating optical system containing sequentially arranged along the rays of the first negative optical component, the first group of prisms, the positive optical component, the second group of prisms and the second negative optical component, in which the aperture angle of the optical components is selected within 20-40 °, refracting the angle of the prisms is selected within the range of 10–40 °, and the angle β of the orientation of the prisms with respect to the optical axis is related to the refracting angle α by the ratio β = (2–3) α (USSR Author's Certificate No. 1624392, cl. 6 G 02 B 27/30, declaration 26.12.88, publ. 30.01.91, bull. No. 4).

As follows from the description, the most effective is the use of the indicated optical system for collimating the radiation of semiconductor lasers. This eliminates the need for a first optical component.

The disadvantage of this optical system is the insufficiently high energy brightness of the output beam. The reason for the insufficiently high energy brightness is the limited energy brightness of the luminescence body of semiconductor lasers.

The closest in technical essence to the claimed optical system is a collimating optical system for a semiconductor laser, containing a lens and a group of prisms sequentially located along the rays, the edges of the refracting dihedral angles of which are oriented parallel to the plane of the semiconductor transition, the refractive angles of the prisms are selected within 25-40 °, the angular increase G of the prism group is selected from the following relation:

G = θ _⊥ / θ _|| ,

where θ _⊥ , θ _|| - the divergence angles of the radiation of the semiconductor laser at a level of 0.5 in the planes parallel and perpendicular to the plane of the semiconductor junction, respectively, the front focal plane of the lens is offset relative to the subject plane by a distance δ ₀ , defined by the relation:

δ ₀ = (a _|| -G · a _⊥ ) / ( _5/6 · D · θ _⊥ / θ _|| ),

where a _|| , a _⊥ are the dimensions of the luminous body of the semiconductor laser in planes parallel and perpendicular to the plane of the semiconductor transition, respectively, and the longitudinal spherical aberration δ (u) of the lens is selected from the following relation:

δ (u) = - 2/3 · δ ₀ · (u / θ _⊥ ) ² ,

where u is the aperture angle of the lens (RF Patent No. 2107743, class 6 G 02 B 27/30, application. 12.01.95, publ. 10.01.98, bull. No. 1).

As follows from the description, a collimating optical system can be used to obtain a collimated beam from several semiconductor lasers. In this case, instead of a single lens, several lenses are used that are opposite the semiconductor lasers, and the angular increase in the G group of prisms is selected from the following relation:

G = k · θ _⊥ / θ _|| ,

where θ _|| , θ _⊥ are the divergence angles of the radiation of semiconductor lasers in planes parallel and perpendicular to the plane of the semiconductor junction, respectively, k is the number of semiconductor lasers.

The disadvantage of this optical system is the insufficiently high energy brightness of the output beam. The reason for the insufficiently high energy brightness is the limited energy brightness of the luminescence body of semiconductor lasers.

An object of the invention is to increase the energy brightness of the output beam.

The technical result is achieved by the fact that in a collimating optical system for semiconductor lasers containing lenses sequentially located along the rays, mounted opposite the semiconductor lasers, and the first group of prisms, the edges of the refracting dihedral angles of which are oriented parallel to the planes of the semiconductor junctions, introduced sequentially in the direction of the rays behind the first group of prisms is the first positive component, the second group of prisms located near the rear focal plane the first positive component and dividing the incoming light beam along a line perpendicular to the planes of the semiconductor junctions into two beams, a polarizing prism placed in the path of these light beams and combining them in space into one common light beam, and the second positive component, whose front focal plane is aligned with the back focal plane of the first positive component.

An increase in the energy brightness of the output beam is ensured by combining in space two light beams from two parts of the luminescence body of each of the semiconductor lasers using a polarizing prism.

In a particular case, in a collimating optical system for semiconductor lasers, the second group of prisms is made in the form of two prisms, the first of which is installed near the rear focal plane of the first positive component and has four reflecting faces, while the input and output faces are oriented perpendicular to the light beam incident on the prism and parallel to the input face of the polarization prism for p-polarization, the first and fourth reflective faces are oriented at an angle of 45 ° to the light beam incident on the prism and perpendicular to the planes of the semiconductor junctions, the second and third reflecting faces are oriented parallel to the light beam incident on the prism and at an angle of 45 ° to the planes of the semiconductor junctions, the boundaries of the input and first reflecting faces from the edge of the dihedral angle formed by these faces are oriented perpendicular to the planes of the semiconductor junctions and are located at the intersection with the axis of the light beam incident on the prism, and the second prism is installed in the path of the rays passing by the first prism and has e reflecting faces, while the input face is oriented perpendicular to the light beam incident on the prism, the output face is oriented parallel to the light beam incident on the prism and parallel to the input face of the polarization prism for s-polarization, the first reflecting face is oriented at an angle of 45 ° to the light beam incident on the prism and at an angle of 45 ° to the plane of semiconductor junctions, the second reflecting face is oriented parallel to the light beam incident on the prism and at an angle of 45 ° to the planes of semiconductor lines exits.

The implementation of the second group of prisms in the form of two prisms in the simplest way ensures the separation of two beams from two sections of the luminescence bodies of each of the semiconductor lasers and their combination in space using a polarizing prism.

Figure 1 shows a collimating optical system for semiconductor lasers, a cross-section in a plane perpendicular to the plane of semiconductor junctions, figure 2 is the same in a plane parallel to the plane of semiconductor junctions. Figure 3 shows a second group of prisms, a view from the entrance of the rays. Figure 4 shows the image of the body of the glow of semiconductor lasers, two types - before passing and after passing the rays through the second group of prisms and a polarizing prism.

The collimating optical system comprises collimating lenses 2 arranged in series along the rays of the beam, mounted opposite the semiconductor lasers 1, a first group of prisms, a first positive component 7, a second group of prisms, a polarizing prism 10 and a second positive component 11.

The first group of prisms is formed by four prisms 3, 4, 5 and 6, each of them has two refracting faces. The edges of the dihedral angles formed by the refracting faces of the prisms are oriented parallel to the planes of the semiconductor junctions of the semiconductor lasers 1.

In the coordinate system shown in FIGS. 1-2, the semiconductor junction planes are oriented parallel to the YZ plane, the optical axes of the lenses are oriented parallel to the Z axis, and the edges of the refracting dihedral angles of the prisms are parallel to the Y axis.

The second group of prisms is located near the rear focal plane of the first positive component 7 and divides the incoming light beam along a line perpendicular to the planes of semiconductor junctions into two beams. A polarizing prism 10 is placed in the path of these light beams and combines them in space into one common light beam.

In the coordinate system shown in FIGS. 1-3, the line dividing the incoming light beam is parallel to the X axis. The input face of the polarization prism 10 for p-polarization is perpendicular to the Z axis, the input face for s-polarization is perpendicular to the Y axis.

The front focal plane of the second positive component 11 is aligned with the rear focal plane of the first positive component 7, so that these components make up the telescopic system.

In a particular case, the second group of prisms is formed by two prisms 8 and 9.

Prism 8 is installed near the rear focal plane of the first positive component and has four reflective faces. The input and output faces of prism 8 are oriented perpendicular to the light beam incident on the prism and parallel to the input face of the polarization prism 10 for p-polarization. The first and fourth reflecting faces are oriented at an angle of 45 ° to the light beam incident on the prism and perpendicular to the planes of the semiconductor junctions. The second and third reflecting faces are oriented parallel to the light beam incident on the prism and at an angle of 45 ° to the planes of semiconductor junctions. The boundaries of the input and first reflective faces from the side of the edge of the dihedral angle formed by these faces are oriented perpendicular to the planes of the semiconductor junctions and are located at the intersection with the axis of the light beam incident on the prism.

Prism 9 is installed in the path of the rays passing by the first prism, and has two reflective faces. The input face of the prism 9 is oriented perpendicular to the light beam incident on the prism. The output face is oriented parallel to the light beam incident on the prism and parallel to the input face of the polarization prism 10 for s-polarization. The first reflecting face is oriented at an angle of 45 ° to the light beam incident on the prism and at an angle of 45 ° to the plane of semiconductor junctions. The second reflecting face is oriented parallel to the light beam incident on the prism and at an angle of 45 ° to the planes of semiconductor junctions.

In the coordinate system shown in FIGS. 1-3, the input and output faces of prism 8 are perpendicular to the Z axis. The first and fourth reflecting faces are perpendicular to the bisector of the angle formed by the Y and Z axes. The second and third reflecting faces are parallel to the bisector of the dihedral angle formed by the XZ planes and YZ. The boundaries of the input and first reflective faces from the side of the edge of the dihedral angle formed by these faces are parallel to the X axis and are located at the intersection with the Z axis.

The input face of prism 9 is perpendicular to the Z axis, the output face is perpendicular to the Y axis. The first reflecting face is perpendicular to the bisector of the angle formed by the X and Z axes. The second reflecting face is parallel to the bisector of the dihedral angle formed by the XZ and YZ planes.

The collimating optical system operates as follows. The light beam from each of the semiconductor lasers is converted by the corresponding collimating lens into a collimated light beam whose axis is parallel to the Z axis. In the XZ plane, all these beams are combined into a common beam that passes through the first group of prisms. The first group of prisms transforms the light beam in the XZ plane, reducing its transverse size and increasing its angular divergence.

The resulting collimated light beam is focused by the first positive component 7. In the focal plane of the first positive component 7, an image of the luminescence body of semiconductor lasers is formed, which in shape is a rectangle elongated in the direction of the Y axis. This image of the body is divided into a second group of prisms along a line parallel to the axis X, in two parts. Accordingly, the light beam is divided into two light beams.

Since the radiation of a semiconductor laser is polarized, these light beams are also polarized. The polarization vector is parallel to the Y axis.

These light beams pass through the second group of prisms along different optical paths and fall on the polarizing prism 10. In this case, one of the beams passes the polarizing prism 10 without reflection, and the other is reflected on its inner face. As a result of this, after the polarizing prism, these beams are combined with each other in space.

The resulting light beam is converted by the second positive component 11 into a collimated light beam.

When light beams are separated, energy losses can occur due to light scattering at the interfaces. These losses will be practically eliminated if the luminescence body of each of the semiconductor lasers is made in the form of two identical emitting sections with a gap between them. In this case, the image of the luminous body in the focal plane of the first positive component 7 will be two rectangles with a gap between them.

Figure 4 shows such a case. Here, the rectangles ABCD and EFGH represent the image of the luminous body of semiconductor lasers before the rays pass through the second group of prisms, and the rectangles A'B'C'D 'and E'F'G'H' are the same after the rays pass through the second group of prisms and polarizing prism 10.

In a particular case, the image of the luminescence body of semiconductor lasers is formed near the input faces of prisms 8 and 9. The portion ABCD of the image of the luminescence falls on prism 8, and the section EFGH on prism 9. The light beam from section ABCD passes through prism 8 along path O ₁ O ₂ O ₃ O ₄ O ₇ , and the light beam from the EFGH section through prism 9 along the path O ₁ O ₅ O ₆ O ₇ . After the passage of the rays, the ABCD section is converted to the A'B'C'D 'section, and the EFGH section to the E'F'G'H' section. The sections A'B'C'D 'and E'F'G'H' are superimposed on each other, the optical axes of both beams are parallel to the Z axis. Consequently, these beams are combined in space into one common light beam.

Thus, in a collimating optical system, the energy brightness of the output beam is doubled. This additionally provides a more uniform illumination of the image field. All this expands the possibilities of using a collimating optical system in optical location systems, optical communications, control, and observational instruments operating in the field.

In addition, if the first group of prisms is performed in accordance with the RF patent №2148850, cl. 7 G 02 B 27/30, 27/09, claimed July 28, 1998, publ. 05/10/00, bull. No. 13, it is ensured that the spatial position of the output collimated beam is constant when exposed to low and high ambient temperatures, which further expands the functionality of the collimating optical system.

Claims (2)

1. A collimating optical system for semiconductor lasers, containing lenses arranged in series along the rays of the beam, mounted opposite the semiconductor lasers, and a first group of prisms, the edges of the refracting dihedral angles of which are oriented parallel to the planes of the semiconductor junctions, characterized in that they are sequentially along the rays behind the first group of prisms the first positive component is installed, the second group of prisms located near the rear focal plane of the first positive component This separates the incoming light beam along a line perpendicular to the planes of the semiconductor junctions into two beams, a polarizing prism placed in the path of these light beams and combining them in space into one common light beam, and a second positive component, the front focal plane of which is aligned with the back the focal plane of the first positive component. 2. The collimating optical system for semiconductor lasers according to claim 1, characterized in that the second group of prisms is made in the form of two prisms, the first of which is installed near the rear focal plane of the first positive component and has four reflective faces, while the input and output faces are oriented perpendicular to the light beam incident on the prism and parallel to the input face of the polarization prism for p-polarization, the first and fourth reflecting faces are oriented at an angle of 45 ° to the light incident on the prism to the beam and perpendicular to the planes of semiconductor junctions, the second and third reflecting faces are oriented parallel to the light beam incident on the prism and at an angle of 45 ° to the planes of semiconductor junctions, the boundaries of the input and first reflecting faces from the edge of the dihedral angle formed by these faces are oriented perpendicular to the planes of semiconductor junctions and are located at the intersection with the axis of the light beam incident on the prism, and the second prism is installed in the path of the rays passing by the first prism , and has two reflecting faces, while the input face is oriented perpendicular to the light beam incident on the prism, the output face is oriented parallel to the light beam incident on the prism and parallel to the input face of the polarization prism for s-polarization, the first reflecting face is oriented at an angle of 45 ° to the incident prism of the light beam and at an angle of 45 ° to the planes of semiconductor junctions, the second reflecting face is oriented parallel to the light beam incident on the prism and at an angle of 45 ° to the planes of semiconductor nicknames transitions.

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