JPH0230484B2 - - Google Patents

Description

TECHNICAL FIELD OF THE INVENTION The present invention relates to optical transmission technology, and in particular to a polarization-maintaining optical fiber laser diode module (hereinafter also simply referred to as an "optical coupling module") that couples a polarization-maintaining optical fiber and a laser diode. (abbreviated)).

Background of the Technology The progress of optical transmission technology using optical fibers has been remarkable, and it has already reached the practical stage for communications, and its practical application in measurement and many other fields is also actively progressing.

However, conventional optical fiber transmission technology generally converts information signals and measured process quantities into light amplitudes, that is, light intensity signals, and transmits the converted signals through optical fibers. On the other hand, in recent years, research has been carried out on the practical application of so-called coherence optical transmission, which transmits information signals and measured process quantities on the phase, frequency, and polarization plane of light. Polarization-maintaining optical fibers that can stably transmit light are attracting attention and are being actively developed.

Currently, the most promising light source for such coherent light transmission is a semiconductor laser such as a laser diode. Laser diodes with various structures have been developed, but those with a so-called stripe structure in which the light emitting region is band-shaped are considered to be optimal in terms of stabilizing the transverse mode of the resonator. In a laser diode, it is ideal for the laser light to have a single polarization mode, so-called perfectly linear polarization, but in reality, due to the asymmetry of the laser structure, perfectly linear polarization cannot be obtained; for example, X polarization and Y polarization Polarized waves are generated with a ratio of about 20 dB. Therefore, for example, if it is desired to use only the X-polarized wave as a signal carrier, the Y-polarized wave becomes noise and must be removed before the laser beam enters the optical fiber.

On the other hand, polarization-maintaining optical fibers can stably transmit polarization and phase information if the optical fiber is uniform in the longitudinal direction, but it is practically difficult to make such a perfect optical fiber. The state of polarization easily changes due to disturbances (bending, twisting, etc.) and structural non-uniformity (fluctuations at the boundary between the core and cladding, etc.). Therefore, it is required to separate and detect only the necessary polarization components from the light emitted from the optical fiber.

Prior Art and Problems Various structures have been proposed in the past as optical coupling modules as described above.

One example is a single ball lens interposed between the laser diode and the optical fiber.
However, with this structure, it is not possible to separate and remove unnecessary polarization components as described above.

Another example is to arrange a ball lens for the laser diode and a ball lens for the optical fiber along the optical axis between the laser diode and the optical fiber, and further install a polarization separation plate such as a rotation prism between the two ball lenses. . In this structure, the polarization separation plate separates the X polarization and the Y polarization so that only the necessary polarization components enter the optical fiber, that is, the unnecessary polarization components are removed. . However, on the other hand, there is a drawback that noise and optical phase noise are generated due to deterioration of the degree of polarization separation due to multiple reflections and diffused reflections on the surface of the rotation prism and the end face of the optical fiber.

Yet another example is one in which the optical fiber is arranged at an angle with respect to the mechanical central axis in the structure of the first example. However, this structure has the drawback that the module has a bent shape and optical coupling loss is large.

Purpose of the Invention In view of the above-mentioned prior art, the present invention is capable of separating and removing unnecessary polarization components from a laser beam incident on an optical fiber from a laser diode in optical coupling between a polarization-maintaining optical fiber and a laser diode. The object of the present invention is to provide a polarization-maintaining optical fiber laser diode module with high coupling efficiency.

Another object of the present invention is to provide a polarization-maintaining optical fiber laser diode module that makes it possible to separate the returned light from the laser beam input end of the optical fiber into polarization components and detect them separately. be.

Structure of the Invention The polarization-maintaining optical fiber laser diode module according to the present invention generally includes a laser diode, a laser diode ball lens, an optical fiber ball lens, a polarization separation plate, and a polarization-maintaining optical fiber. and are arranged in this order so that the optical axis coincides with the mechanical center axis of the module, and the following formula: f _LD /f _F ≒ ω _LD / ω _F , where f _LD is the focal point of the laser diode ball lens. Distance f _F : Focal length of the optical fiber ball lens ω _LD : Gaussian beam spot size of the laser diode ω _F : Constructed to satisfy the Gaussian beam spot size of the optical fiber, and furthermore, the laser diode ball lens and the optical fiber A half mirror that reflects the light emitted from the polarization preserving optical fiber is arranged between the spherical lens and the polarization preserving optical fiber.

Embodiments of the Invention Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

FIG. 1 shows the basic configuration of an optical coupling module between a polarization maintaining optical fiber and a laser diode according to the present invention. In the figure, numeral 1 indicates a laser diode, and numeral 2 indicates a polarization-maintaining optical fiber (hereinafter simply abbreviated as "optical fiber"). Between the laser diode 1 and the optical fiber 2, a laser diode ball lens 3, an optical fiber ball lens 4, and a polarization separation plate 5 are arranged in the order shown. Note that reference numeral 1a indicates an external mirror of the laser diode 1.

Further, the reference numeral 6 indicates the mechanical center axis of the module, and the reference numeral 6 indicates the mechanical center axis of the module, and the reference numeral 6 indicates the mechanical center axis of the module.
The optical axes of 4 and 5 coincide with this mechanical center axis 6. Among these modular elements, a laser diode 1, an optical fiber 2, and both spherical lenses 3 and 4
are arranged so as to satisfy the following equation (1).

f _LD /f _F ≒ω _LD /ω _F …(1) However, f _LD : Focal length of ball lens for laser diode f _F : Focal length of ball lens for optical fiber ω _LD : Gaussian beam spot size of laser diode ω _F : Gaussian beam spot size of optical fiber The above f _LD and f _F are obtained from the following equations.

f _LD = n _LD・R _LD /2 (n _LD −1) f _F = n _F・R _F /2 (n _F −1) where, n _LD : refractive index of ball lens for laser diode R _LD : laser diode Radius of the ball lens for optical fiber n _F : Refractive index of the ball lens for optical fiber R _F : Radius of the ball lens for optical fiber The above ω _LD and ω _F can be obtained from the following equations.

ω _LD =√ _LD1・_LD2 ω _F =√ _F1・_F2 However, ω _LD1 and ω _LD2 are the major axis and minor axis of the beam spot of the laser diode 1, respectively, as shown in FIG. 2, and ω _F1 , ω _F2 is the major axis and minor axis of the beam spot of the optical fiber 2, respectively, as shown in FIG. In general, ω _LD = 4 μm,
ω _F =about 5 μm.

Next, the polarization separation plate 5 is made of, for example, rutile (TiO ₂ ).
As shown in FIG. 5 (a plan view viewed from the direction of arrow A in FIG. 4), it has a crystal axis 5a with an inclination angle θ to the optical axis 6, and the crystal axis 5a has a It exhibits different refractive indexes n〓 and n〓 for parallel normal rays and extraordinary rays perpendicular to the crystal axis 5a, respectively.
Due to this characteristic, as shown in FIG.
The laser light O incident on the laser beam O is separated into polarization components O ₁ and O ₂ . Separation width δ (angle) of polarization components O ₁ and O ₂
is determined by the following equation.

tanδ=tanθ・(n〓/n〓) ^2As an example, if θ=44°, n〓=2.726, and n〓=2.500, then δ=49°.

Of the polarized components separated in this way, O ₁
only the polarized wave component enters optical fiber 2, and the other polarized component
O ₂ is not introduced into the optical fiber 2 and is removed as an unnecessary polarized component. Incidentally, which polarized wave component is to be used or not can be determined arbitrarily by shifting the position of the optical fiber 2 so that only a desired single polarized wave component enters the optical fiber 2. Selectable.

As described above, in the optical coupling module of the present invention, before the laser light from the laser diode is incident on the optical fiber, it is separated into each polarization component by the polarization separation plate, and unnecessary polarization components are removed. Low-noise transmission of only a single polarization component becomes possible. Further, by configuring each module element so as to satisfy the above formula (1), high optical coupling efficiency can be obtained.

However, although the above basic configuration can be applied to unidirectional transmission of only sending, it cannot be applied to bidirectional transmission of sending and receiving. In the case of bidirectional transmission using the same optical fiber, even if unnecessary polarization components are removed from the light incident on the optical fiber, the light may still be affected by disturbances to the optical fiber or non-uniformity of the optical fiber structure as described above. This is because unnecessary polarization components are generated during fiber transmission.

Therefore, the present invention contemplates the realization of an optical coupling module that can be applied, for example, to a transmitting/receiving section when transmitting and receiving using the same optical fiber, or to an input/output section of an optical fiber coil. An example of this is shown in FIG. This embodiment further adds a half mirror 10 between both spherical lenses 3 and 4 to the basic configuration shown in FIG. It is designed to be able to receive. That is, the light emitted from the optical fiber 2 is separated into two polarization components M ₁ and M ₂ by the polarization separation effect of the polarization separation plate 5 as described above. These separated polarized components M ₁ and M ₂ are transferred to the half mirror 10.
It is partially reflected and output to the side of the module.
Therefore, by placing the photodetectors D ₁ and D ₂ at the respective output positions, it is possible to detect the required polarization components.

Next, FIGS. 7, 8, and 9 schematically show specific structural examples of the optical coupling module of the present invention. In FIG. 7, reference numeral 20 indicates an L-shaped metal fitting made of a material such as Super Invar, and the laser diode 1 and polarization separation plate 5 (not shown in FIG. 7) are fixed to the metal fitting 20 with, for example, adhesive. Further, the optical fiber 2 is held by the core 21, and the optical fiber 2 is held by the core 21.
is a wedge-shaped core holder 22 as shown in FIG.
It is positioned and held by the metal fitting 20 using two pieces. Furthermore, the ball lenses 3 and 4 (ball lens 4 is omitted in FIG. 7) are positioned and held on the metal fitting 20 using two V-groove wedge-shaped lens holders 23 as shown in FIG. In Fig. 9, A indicates lens holder 2.
3, and B and C are both end views thereof.

The structure described above is simple and provides high assembly accuracy, making it possible to realize a highly reliable optical coupling module.

Effects of the Invention As described above, according to the present invention, it is possible to separate and remove unnecessary polarization components from the laser light incident on the optical fiber from the laser diode in optical coupling between the polarization-maintaining optical fiber and the laser diode. A polarization-maintaining optical fiber laser diode module with high coupling efficiency can be realized.

Further, according to the present invention, a polarization-maintaining optical fiber laser diode module is realized, which has the advantage of being able to separate the return light from the optical fiber into each polarization component and detect them separately in addition to the above-mentioned advantages. be able to.

These polarization-maintaining optical fiber laser diode modules according to the present invention bring about great effects when applied to measurement techniques such as coherent communications and optical fiber coils.

[Brief explanation of drawings]

Figure 1 is a basic configuration diagram of a polarization-maintaining optical fiber laser diode module according to the present invention, Figures 2 and 3 are diagrams showing the beam spot of the laser diode and optical fiber, and Figure 4 is the function of the polarization separation plate. Explanatory diagram, FIG. 5 is a diagram showing the crystal axis direction of the polarization splitting plate when viewed from the arrow direction in FIG. 4, FIG. 6 is a schematic configuration diagram of an embodiment of the present invention, and FIG. 7 is a polarization plane according to the present invention. FIG. 8 is a schematic perspective view of a specific structural example of a preserved optical fiber laser diode module, FIG. 8 is a perspective view of an optical fiber core holder, and FIG. 9 is a plan view and both end views of a lens holder. DESCRIPTION OF SYMBOLS 1... Laser diode, 2... Polarization preserving optical fiber, 3... Ball lens for laser diode, 4... Ball lens for optical fiber, 5... Polarization separation plate, 6... Mechanical central axis of module, 10... Half mirror,
20... L-shaped metal fitting, 21... Optical fiber core, 22
... Core holder, 23... Lens holder.

Claims (1)

[Scope of Claims] 1. A polarization preserving optical fiber laser diode module for optically coupling a polarization preserving optical fiber and a laser diode, comprising: a laser diode, a ball lens for the laser diode, a ball lens for the optical fiber, and a polarization preserving optical fiber; The separation plate and the polarization-preserving optical fiber are arranged in this order so that the optical axis coincides with the mechanical center axis of the module, and the following formula f _LD /f _F ≒ω _LD /ω _F However, f _LD : Focal length of the ball lens for the laser diode f _F : Focal length of the ball lens for the optical fiber ω _LD : Gaussian beam spot size of the laser diode ω _F : Constructed to satisfy the Gaussian beam spot size of the optical fiber, A polarization-maintaining optical fiber laser diode, further comprising a half mirror arranged between the laser diode ball lens and the optical fiber ball lens to reflect the light emitted from the polarization-maintaining optical fiber. Module.