Optical pickup having optical waveguide device fixed on stem...

Details Optical pickup having optical waveguide device fixed on stem... Optical pickup having optical waveguide device fixed on stem...

1998-09-03

2001-07-03

Font, Frank G. (Department: 2877)

Optical waveguides

With disengagable mechanical connector

Optical fiber to a nonfiber optical device connector

C369S044120

Reexamination Certificate

active

06254284

ABSTRACT:

BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to an optical pickup used in an optical recording and reproducing apparatus for recording and reproducing of an optical recording medium such as a magneto-optical disk and a method of manufacturing the same. More specifically, the present invention relates to an optical pickup allowing easy and highly-precise positional adjustment of an optical waveguide device and a method of manufacturing the same.
2. Description of the Background Art
When a signal from a magneto-optical disk is to be detected by an optical pickup, a beam from a semiconductor laser is generally directed to the magneto-optical disk. The beam is reflected and split into a beam for detecting a servo error signal and a beam for detecting a magneto-optical signal, and these beams are used for their respective purposes.
FIG. 1
is a plan view of an optical pickup employing an optical waveguide for a magneto-optical disk disclosed in Japanese Patent Laying-Open No. 8-171747, as an example of a conventional optical pickup and its optical system.
A beam
103
emitted from a semiconductor laser
102
fixed on a stem
101
is divided into a main beam and a tracking beam by a grating
104
as a diffraction grating. The beam passes through a hologram
105
and enters a beam splitter
108
formed by adhering a plate glass
106
and a prism
107
. The entered incident beam is reflected by a mirror at an interface (surface a) between plate glass
106
and prism
107
, passed through a collimator lens
109
, reflected vertically by a 45° mirror
110
, and collected onto a magneto-optical disk (not shown) as an optical recording medium by an objective lens
111
. The beam reflected by the magneto-optical disk passes through objective lens
111
, 45° mirror
110
and collimator lens
109
and enters beam splitter
108
, where the beam is split into a beam
112
for detecting a servo error signal and a beam
113
for detecting a magneto-optical signal. Beam
112
for detecting a servo error signal enters from beam splitter
108
to hologram
105
, where the beam is diffracted, guided by receiving optics
114
, and detected as a servo error signal. Meanwhile, beam
113
for detecting a magneto-optical signal is reflected by a mirror surface on a rear surface (surface b) of plate glass
106
forming beam splitter
108
, and guided to a coupler portion of an optical waveguide device
115
without passing through hologram
105
. The beam coupled to the optical waveguide at this coupler portion is diffracted and divided into a TE (Transverse Electric field) wave and a TM (Transverse Magnetic field) wave in the optical waveguide, guided to an optical detector, and detected as a magneto-optical signal.
Receiving optics
114
and optical waveguide device
115
are fixed on stem
101
by adhesion, housed together with semiconductor laser
102
in one package, and sealed with a cap
116
in an airtight manner. Generally, the position and angle of incidence have to be strictly adjusted to couple a laser beam to an optical waveguide device.
FIG. 2
is a view for illustrating positional adjustment and assembling of the optical waveguide device in the above described optical pickup.
The operation for adjusting the position of optical waveguide device
115
is performed for correctly coupling beam.
113
for detecting a magneto-optical signal to optical waveguide device
115
. Optical waveguide device
115
is held so that the relative position of optical waveguide device
115
with respect to semiconductor laser
102
comes to have a prescribed position, and the position of optical waveguide device
115
is adjusted in three-dimensional directions of an optical axis direction Z and directions X and Y orthogonal to the optical axis. After the positional adjustment of optical waveguide device
115
is completed, optical waveguide device
115
is fixed on stem
101
by filling an adhesive
118
in a gap between optical waveguide device
115
and stem
101
while optical waveguide device
115
is held. Taking account of variation in the position for fixing semiconductor laser
102
and variation in the substrate thickness of optical waveguide device
115
, the gap is set to at least 100 &mgr;m in a normal state so that a variable range for adjustment can be set in optical axis direction Z.
In the conventional optical pickup, however, the position of the optical waveguide device was adjusted in three-dimensional directions of an optical axis direction and directions orthogonal to the optical axis so as to couple a laser beam to the optical waveguide device, and an adhesive was filled in such a gap between the optical waveguide device and the stem that was caused after adjustment so as to fix the optical waveguide device on the stem. As a result, the relative position of the optical waveguide device with respect to the semiconductor laser was offset by shrinkage of the adhesive when it was cured and expansion or shrinkage of the adhesive when temperature changed in the environment where the optical pickup was used. As a result, the laser beam was less likely to be coupled and, in the worst case, the laser beam was not coupled at all and reliability in the environment could not be achieved sufficiently.
After the position of the optical waveguide device was adjusted in three-dimensional directions of an optical axis direction and directions orthogonal to the optical axis, the adhesive was filled in the gap between the optical waveguide device and the stem. Accordingly, the gap between the optical waveguide device and the stem was varied by variation in the position for fixing the semiconductor laser, variation in the substrate thickness of the optical waveguide device, and so on. As a result, the amount of applying the adhesive was not enough to achieve sufficient strength for fixing, or the amount of applying the adhesive was excessive and the adhesive flowed to the surface of the optical waveguide device, reducing the efficiency of detecting a laser beam. Especially, when the optical waveguide device was to be held by sandwiching the side surfaces of the device, the adhesive flowed and attached to the device holding portion, preventing removal of the device. Thus, workability and productivity were lowered.
The optical waveguide device was a semiconductor device formed by laminating an optical waveguide layer on an silicon substrate on which an electric circuit and the like were formed. When the optical waveguide device was directly adhered on the stem, a photo-curing adhesive could not be used as an adhesive. When a heat-curing adhesive was used instead, the optical waveguide device was under thermal stress and therefore the optical characteristics of the optical waveguide device changed or degraded. When an anaerobe adhesive was used, the time for adjusting the position of the optical waveguide device was limited.
Since electric insulation of the optical waveguide device from the semiconductor laser and the receiving optics was unreliable, the optical waveguide device was influenced by other circuits, and the S/N ratio of a magneto-optical recording and reproducing signal was worsened.
SUMMARY OF THE INVENTION
An object of the present invention is to provide an optical pickup allowing easy and highly-precise positional adjustment of an optical waveguide device.
Another object of the present invention is to provide a method of manufacturing an optical pickup allowing easy and highly-precise positional adjustment of an optical waveguide device.
According to one aspect of the present invention, an optical pickup includes a light source, a stem that fixes the light source, an optical waveguide device that detects a beam emitted from the light source and reflected on a recording medium, a wedge-shaped device fixing member that fixes the optical waveguide device on the stem, and a conductive layer provided on the wedge-shaped device fixing member that connects a wire connected to an output terminal of the optical waveguide device and a wire connected to a lead of the

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