Optical transmission terminal device

An optical transmission terminal device including a printed wiring board and an optical module mounted on the printed wiring board. The optical module includes an optical component mounting substrate, a photoelectric converter mounted on the substrate, a first optical fiber having one end optically coupled to the photoelectric converter, and a ferrule mounted on the substrate so as to partially project from the substrate. The other end portion of the first optical fiber is inserted and fixed in the ferrule. A wiring pattern formed on the printed wiring board and a feed electrode formed on the substrate are connected together by wire bonding. An optically coupled portion between the photoelectric converter and the first optical fiber and a connected portion between the wiring pattern and the feed electrode are commonly covered with a transparent resin. The optical transmission terminal device further includes an optical fiber connector housing mounted on the optical module for allowing connection of the first optical fiber to a second optical fiber.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
The present invention relates generally to an optical transmission terminal 
device used in an optical communication field, and more particularly to a 
package structure of an optical module for performing conversion from an 
optical signal to an electrical signal or conversion from an electrical 
signal to an optical signal. 
2. Description of the Related Art 
In a recent information communication field, high-speed large-capacity 
computing and high-speed data transmission are required in response to 
advance of information. To meet this requirement, optical transmission is 
indispensable and it is now being prepared for an expansion and 
proliferation of optical communication networks. 
As a device used at various sites in an optical transmission system, there 
exists an optical transmission terminal device including an optical 
circuit and an electrical circuit in combination to perform conversion 
from an optical signal to an electrical signal or conversion from an 
electrical signal to an optical signal. At present, the scale of 
production of the optical transmission terminal device per manufacture is 
about a hundred thousand a year. However, it is said that the production 
scale required in the future will become a million or more a year in 
response to a proliferation of optical communication networks and that the 
manufacturing cost will have to be reduced to 1/10 or less of the present 
level. To this end, it is strongly desired to develop a form of the 
optical transmission terminal device which can realize mass production and 
low cost by minimizing the number of parts and simplifying the fabrication 
process and can also ensure high reliability and long life. 
A component mounted on a printed wiring board incorporated in communication 
equipment is generally classified into a surface mount type and a 
through-hole mount type. A typical example of the surface mount type 
component is an LSI, which has a form called a flat package. This 
component is soldered by a reflow soldering process. This process is 
carried out by printing a solder paste on a printed wiring board, 
attaching the surface mount type component to the printed solder paste, 
and soldering the component to the printed wiring board in a conveyor 
furnace giving a solder surface temperature of 220.degree. C. or higher. 
On the other hand, a typical example of the through-hole mount type 
component is a large-capacity capacitor or an LSI having a large number of 
terminals (200 or more terminals). The LSI having a large number of 
terminals has a terminal form called a PGA (Pin Grid Array). Such a 
through-hole mount type component is soldered by a flow soldering process. 
This process is carried out by inserting the terminals of the through-hole 
mount type component into through holes of a printed wiring board, dipping 
the printed wiring board into a solder bath at about 260.degree. C. from 
the side opposite to the component mounted side, and soldering the 
component to the printed wiring board in the solder bath. 
In the case of mounting an optical module on a printed wiring board by 
soldering similar to that used in mounting the surface mount type 
component or the through-hole mount type component, a so-called pigtail 
type optical module with an optical fiber cord is unsuitable. Usually, the 
optical fiber cord has a nylon coating, which has a low heat-resisting 
temperature of about 80.degree. C. Accordingly, the optical fiber cord is 
melted in the soldering process. Further, the optical fiber cord itself is 
inconvenient for storage and handling at a manufacturing site, causing a 
remarkable reduction in mounting efficiency to a printed wiring board. 
Accordingly, to allow the use of soldering for an optical module and 
reduce a manufacturing cost, the application of a so-called receptacle 
type optical module is essential. 
A conventional receptacle type optical module allowing the use of soldering 
is described in IEICE, General Meeting, papers C-184, 1996 (Reference 1). 
The receptacle type optical module described in Reference 1 has a 
structure such that a photoelectric converter and an optical fiber with a 
ferrule are held on a silicon substrate, and this assembly is packaged by 
a ceramic. 
In this optical module structure, a cover is mounted on the ceramic package 
and fixed by a thermoplastic resin adhesive to achieve hermetic sealing of 
an optically coupled portion, so as to prevent corrosion of the 
photoelectric converter due to moisture, oxygen, etc. and condensation at 
the optically coupled portion. Further, a block as an optical fiber 
holding member is mounted on the ceramic package to allow connection and 
disconnection of the ceramic package to a second optical fiber. Flat leads 
extending from the ceramic package are soldered to a printed wiring board 
by reflow soldering, thereby achieving mounting of the optical module on 
the printed wiring board. 
Another conventional receptacle type optical module is described in IEICE, 
General Meeting, papers C-207, 1996 (Reference 2). The receptacle type 
optical module described in Reference 2 has a structure such that a 
photoelectric converter and an optical fiber with a ferrule are held on a 
silicon substrate and covered with a silicon cap for the purpose of 
hermetic sealing an optically coupled portion, and this assembly is fully 
molded with an epoxy resin. A commercially available MU type connector 
housing is mounted on an optical fiber connecting portion of the optical 
module to allow connection and disconnection of the optical module to a 
second optical fiber. Further, leads extending from the molded package are 
soldered to a printed wiring board by flow soldering, thereby achieving 
mounting of the optical module to the printed wiring board. 
The most significant challenge in the optical transmission terminal device 
is to achieve low cost. Much of the cost is related with an optical module 
having a photoelectric conversion function. It is therefore essential both 
to ensure high performance, high reliability, and long life of the optical 
module and to simplify and make efficient the fabrication process of the 
optical module and the mounting method for the optical module to a printed 
wiring board. However, the above-mentioned prior art has the following 
problems. 
In the optical module described in Reference 1, the package and the cover 
cooperate with each other to form a structure for hermetically sealing the 
optically coupled portion. However, a side wall of the package is formed 
with a slit for taking the optical fiber out of the package, so that a gap 
in the slit must be closed to realize the hermetic sealing. Accordingly, a 
step of filling the gap with an adhesive is required, and this step is 
unavoidably manually performed, causing a reduction in fabrication 
efficiency. 
Further, the optical fiber with the ferrule is constructed by using a bare 
fiber and a ferrule as separate components, partially inserting the bare 
fiber into the ferrule, and fixing them together by an adhesive. 
Accordingly, a stress is readily applied to a root portion of the optical 
fiber (i.e., a boundary portion between the bare fiber and the ferrule), 
and the optical fiber possibly cannot ensure a load in connection or 
disconnection of an optical fiber connector to the optical module. 
Further, this optical module requires the package for hermetically sealing 
the optically coupled portion, and an expensive ceramic package is used as 
this package. Accordingly, there is a limit from the viewpoints of 
reduction in parts count and reduction in material cost. 
On the other hand, the fabrication of the optical module described in 
Reference 2 requires the step of molding the optically coupled portion 
hermetically sealed by the silicon substrate and the silicon cap with an 
epoxy resin having a low coefficient of thermal expansion. In this molding 
step, a pressure as high as 80 kgf/cm.sup.2 is applied to the optically 
coupled portion in injecting a molten resin into a mold. In the case that 
the optical module is a semiconductor laser module, a tolerable 
misalignment between the semiconductor laser and the optical fiber is 
usually very exact such as .+-.1 .mu.m or less, and it is accordingly very 
difficult to maintain the position accuracy between the photoelectric 
converter and the optical fiber in the resin molding step involving 
application of the above-mentioned injection pressure. As a result, the 
optical modules manufactured exhibit large variations in optical coupling 
loss, which lead to a reduction in yield. Further, since the semiconductor 
laser is surrounded by the resin material having low heat conductivity, a 
deterioration in characteristics of the semiconductor laser module 
requiring heat dissipation is unavoidable. 
Each of the optical modules described in References 1 and 2 has a form such 
that an optical fiber connector is plugged into the optical module toward 
its side surface in one direction. Further, the connection or 
disconnection of the optical fiber connector is carried out after 
soldering the optical module to the printed wiring board. Accordingly, 
when connecting or disconnecting the optical fiber connector, a stress is 
concentrated at a soldered portion between the optical module and the 
printed wiring board via the leads. As a result, there is a possibility of 
electrical contact failure caused by solder separation due to the stress 
or lead break due to metal fatigue, for example. 
SUMMARY OF THE INVENTION 
It is therefore an object of the present invention to provide an optical 
transmission terminal device having a package structure suitable for mass 
production and achieving low cost and high reliability. 
In accordance with an aspect of the present invention, there is provided an 
optical transmission terminal device comprising a printed wiring board; an 
optical module mounted on said printed wiring board, said optical module 
having an optical component mounting substrate, a photoelectric converter 
mounted on said substrate, a first optical fiber having one end optically 
coupled to said photoelectric converter, a ferrule mounted on said 
substrate so as to partially project from said substrate, the other end 
portion of said first optical fiber being inserted and fixed in said 
ferrule, and feed electrodes formed on said substrate and connected to 
said photoelectric converter; means for connecting said printed wiring 
board and said feed electrodes; a transparent resin for commonly covering 
said connecting means and an optically coupled portion between said 
photoelectric converter and said first optical fiber; and an optical fiber 
connector housing mounted on said optical module so as to surround said 
ferrule, for allowing connection of said first optical fiber to a second 
optical fiber. 
Preferably, the optical component mounting substrate has a groove for 
receiving the ferrule and a groove for receiving the first optical fiber. 
The optical module has a cover fixed to the optical component mounting 
substrate from the upper side thereof, for holding the ferrule and the 
first optical fiber. 
In accordance with another aspect of the present invention, there is 
provided an optical transmission terminal device comprising a printed 
wiring board; an optical module mounted on said printed wiring board, said 
optical module having an optical component mounting substrate, a 
photoelectric converter mounted on said substrate, a first optical fiber 
having one end optically coupled to said photoelectric converter, a 
ferrule mounted on said substrate so as to partially project from said 
substrate, the other end portion of said first optical fiber being 
inserted and fixed in said ferrule, feed electrodes formed on said 
substrate and connected to said photoelectric converter, and a cover fixed 
to said substrate for hermetically sealing said photoelectric converter 
and said first optical fiber; means for connecting said printed wiring 
board and said feed electrodes; an optical fiber connector housing fixed 
to said printed wiring board so as to surround said optical module, for 
allowing connection of said first optical fiber to a second optical fiber, 
said optical fiber connector having an opening at a portion corresponding 
to said connecting means; and a resin for filling said opening so as to 
cover said connecting means. 
In accordance with still another aspect of the present invention, there is 
provided an optical transmission terminal device comprising a casing 
having an end wall formed with an opening and having an open top; an 
optical module fixed in said casing, said optical module having an optical 
component mounting substrate, a photoelectric converter mounted on said 
substrate, a first optical fiber having one end optically coupled to said 
photoelectric converter, a ferrule mounted on said substrate so as to 
partially project from said opening of said casing, the other end portion 
of said first optical fiber being inserted and fixed in said ferrule, and 
feed electrodes formed on said substrate and connected to said 
photoelectric converter; a transparent resin for filling said casing; and 
an optical fiber connector housing mounted on said casing so as to close 
said opening, for allowing connection of said first optical fiber to a 
second optical fiber. 
Preferably, the optical fiber connector housing comprises a body and a pair 
of connector holding members pivotably mounted to the body. By engaging 
these connector holding members with an optical fiber connector connected 
to the second optical fiber, the first optical fiber is optically coupled 
to the second optical fiber. Accordingly, it is possible to prevent the 
occurrence of stress concentration at a soldered portion between lead 
terminals of the optical module and the printed wiring board when 
connecting or disconnecting the optical fiber connector. 
In accordance with a further aspect of the present invention, there is 
provided an optical transmission terminal device comprising a printed 
wiring board; an optical module mounted on said printed wiring board, said 
optical module having an optical component mounting substrate having an 
optical waveguide, a photoelectric converter mounted on said substrate so 
as to be optically coupled to one end of said optical waveguide, a first 
optical fiber having one end optically coupled to the other end of said 
optical waveguide, a ferrule mounted on said substrate so as to partially 
project from said substrate, the other end portion of said first optical 
fiber being inserted and fixed in said ferrule, and feed electrodes formed 
on said substrate and connected to said photoelectric converter; means for 
connecting said printed wiring board and said feed electrodes; a 
transparent resin for covering an optically coupled portion between said 
photoelectric converter and said optical waveguide and an optically 
coupled portion between said optical waveguide and said first optical 
fiber; and an optical fiber connector housing mounted on said optical 
module so as to surround said ferrule, for allowing connection of said 
first optical fiber to a second optical fiber. 
The above and other objects, features and advantages of the present 
invention and the manner of realizing them will become more apparent, and 
the invention itself will best be understood from a study of the following 
description and appended claims with reference to the attached drawings 
showing some preferred embodiments of the invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
Some preferred embodiments of the present invention will now be described 
with reference to the drawings. In the following description of the 
preferred embodiments, substantially the same parts will be denoted by the 
same reference numerals. Referring to FIGS. 1 and 2, there is shown an 
optical module 2 applied to a first preferred embodiment of the optical 
transmission terminal device according to the present invention. The 
optical module 2 has an optical component mounting substrate 4 formed of 
silicon. The upper surface of the substrate 4 is formed with grooves 6 and 
8 for respectively receiving a ferrule 18 and a bare fiber 20. The grooves 
6 and 8 are formed by anisotropic etching. 
The substrate 4 is not limited to a silicon substrate, but a semiconductor 
substrate, ceramic substrate, glass substrate, etc. may be adopted. The 
ferrule 18 is a cylindrical ferrule formed of zirconia and having an outer 
diameter of 1.25 mm, for example. The bare fiber 20 is inserted and fixed 
in the ferrule 18, and one end portion of the bare fiber 20 projects from 
the ferrule 18. The front end of the bare fiber 20 is cleaved, and one end 
surface of the ferrule 18 opposite to the front end of the bare fiber 20 
is polished. The cylindrical surfaces of the ferrule 18 and the bare fiber 
20 are preliminarily metallized to allow soldering. 
A photoelectric converter 10 such as a laser diode is mounted on the 
substrate 4, and a pair of feed electrodes 12 and 14 are formed on the 
substrate 4. The feed electrode 12 and the photoelectric converter 10 are 
connected by a gold wire 16. The term of "photoelectric converter" used in 
this specification means a device having both an opto-electric conversion 
function and an electro-optic conversion function. After the ferrule 18 
and the bare fiber 20 are inserted into the grooves 6 and 8 of the 
substrate 4, respectively, a holder cover 22 formed of silicon is fixed by 
soldering to the upper surface of the substrate 4. Soldering portions of 
the substrate 4 and the holder cover 22 are preliminarily metallized. 
Referring to FIG. 3, there is shown an exploded perspective view of an 
optical transmission terminal device 24 according to the first preferred 
embodiment of the present invention. FIG. 4 is a perspective view of the 
optical transmission terminal device 24 in the condition where an optical 
fiber connector housing 36 is mounted on the optical module 2. The optical 
module 2 is fixedly mounted on a printed wiring board 26 at a given 
position by an epoxy adhesive, for example. The feed electrodes 12 and 14 
of the optical module 2 are connected through gold wires 30 and 32, 
respectively, to wiring patterns 28 formed on the printed wiring board 26. 
A silicone resin 34 is applied so as to cover an optically coupled portion 
between the photoelectric converter 10 and the optical fiber 20 and an 
electrically connected portion between the feed electrodes 12 and 14 and 
the wiring patterns 28 by the gold wires 30 and 32. The silicone resin 34 
applied is cured by heating at about 150.degree. C. Although not shown, an 
electrical component such as an LSI is also mounted on the printed wiring 
board 26 in a similar manner. The optical fiber connector housing 36 
corresponds to a commercially available MU type optical connector, and it 
is fixedly mounted to the optical module 2 as shown in FIG. 3. The optical 
fiber connector housing 36 is fixed to the optical module 2 by an epoxy 
adhesive, for example. 
As shown in FIG. 5, a C-shaped sleeve 44 formed of zirconia is inserted and 
fixed in the optical fiber connector housing 36. The optical fiber 
connector housing 36 is integrally formed with a pair of hooks 46 for 
holding an optical fiber connector 38. The optical fiber connector 38 has 
a housing 48 formed with a pair of notches 50 for engaging the hooks 46. A 
ferrule 42 is movably inserted in the housing 48, and an optical fiber 40 
is inserted and fixed in the ferrule 42. A coil spring 52 is interposed 
between the ferrule 42 and the housing 48. As shown in FIG. 6, when the 
optical fiber connector 38 is inserted into the optical fiber connector 
housing 36, the hooks 46 come into engagement with the notches 50, and the 
end surfaces of the ferrules 18 and 42 come into pressure contact with 
each other by a biasing force of the coil spring 52. 
Referring to FIG. 7, there is shown an exploded perspective view of an 
optical module 54 applied to a second preferred embodiment of the optical 
transmission terminal device according to the present invention. FIG. 8 is 
a perspective view of the optical module 54 in its assembled condition. 
The optical module 54 is different from the optical module 2 shown in 
FIGS. 1 and 2 in the configuration of a holder cover 56. The holder cover 
56 is formed of silicon, and it is formed with grooves 58 and 60 for 
receiving a ferrule 18 and a bare fiber 20, respectively, and a recess 62 
for encapsulating a photoelectric converter 10. These grooves and recess 
are formed by anisotropic etching. An insulating thermoplastic resin is 
preliminarily applied to a lower bonding surface 64 of the holder cover 
56. The lower surface of the substrate 4 is preliminarily metallized. 
After the ferrule 18 and the bare fiber 20 are inserted into the grooves 6 
and 8 of the substrate 4, respectively, the holder cover 56 is fixedly 
mounted on the substrate 4 by the thermoplastic resin adhesive so that the 
ferrule 18 and the bare fiber 20 are received in the grooves 58 and 60, 
respectively, and the photoelectric converter 10 is received in the recess 
62. Accordingly, the holder cover 56 is fixed to the substrate 4, and 
simultaneously the photoelectric converter 10 is hermetically sealed in 
the recess 62 by the thermoplastic resin. 
Referring to FIG. 9, there is shown an exploded perspective view of an 
optical transmission terminal device 66 according to the second preferred 
embodiment of the present invention. FIG. 10 is a perspective view of the 
optical transmission terminal device 66 in its assembled condition. A 
pattern of PbSn solder paste is preliminarily printed by a screen printing 
process on a printed wiring board 26 at given device mounting positions. 
The optical module 54 and an electrical component such as an LSI (not 
shown) are placed on the given solder pattern of the printed wiring board 
26. Thereafter, the optical module 54 and the electrical component are 
soldered by reflow soldering in a conveyor furnace, thereby being 
simultaneously fixed to the printed wiring board 26. Thereafter, the feed 
electrodes 12 and 14 of the optical module 54 and the wiring patterns 28 
on the printed wiring board 26 are connected together by gold wires 30 and 
32. The printed wiring board 26 is formed with a plurality of holes 68 for 
mounting an optical fiber connector housing 70. 
The optical fiber connector housing 70 has an opening 72 for receiving an 
electrically connected portion between the optical module 54 and the 
printed wiring board 26, and a plurality of hooks 74 for engaging the 
holes 68 of the printed wiring board 26. By inserting the hooks 74 into 
the holes 68, the optical fiber connector housing 70 is mounted on the 
printed wiring board 26. As shown in FIG. 10, the opening 72 of the 
optical fiber connector housing 70 mounted on the printed wiring board 26 
is filled with an epoxy resin 76 to thereby simultaneously carry out resin 
molding of the electrically connected portion and fixing of the optical 
fiber connector housing 70 to the printed wiring board 26. 
Referring to FIGS. 11 to 14, there is shown an optical transmission 
terminal device 78 according to a third preferred embodiment of the 
present invention. In this preferred embodiment, an optical module 2' is 
similar to the optical module 2 shown in FIGS. 1 and 2, but different 
therefrom in that a feed electrode 14' is located laterally farther than 
the feed electrode 14 and that a ferrule 18' projects from the substrate 4 
longer than the ferrule 18. Reference numeral 80 denotes a casing formed 
of a heat-resisting resin. A plurality of lead terminals 82 are mounted on 
both side walls of the casing 80, and an opening 84 is formed through one 
end wall of the casing 80. A metal sheet 86 is mounted on the bottom 
surface of the casing 80, and is connected to at least one of the lead 
terminals 82, thereby forming a heat dissipation path. 
The optical module 2' is received in the casing 80 so that the ferrule 18' 
projects from the opening 84, and an LSI chip 88 is also received in the 
casing 80. Both the optical module 2' and the LSI chip 88 are mounted on 
the metal sheet 86 of the casing 80. As shown in FIG. 12, the casing 80 is 
formed with a pair of projections 90 and a pair of recesses 92 adjacent to 
the opening 84. Reference numeral 94 denotes an optical fiber connector 
housing having a body 96. The body 96 is formed with a pair of recesses 98 
for engaging the projections 90 of the casing 80 and a pair of projections 
100 for engaging the recesses 92 of the casing 80. A pair of connector 
holding members 102 and 104 are pivotably mounted to the body 96 through 
pins 106 and 108, respectively. 
By engaging the projections 100 of the optical fiber connector housing 94 
with the recesses 92 of the casing 80 and engaging the projections 90 of 
the casing 80 with the recesses 98 of the optical fiber connector housing 
94, the optical fiber connector housing 94 is mounted to the casing 80 in 
such a manner as to close the opening 84. The feed electrodes 12 and 14' 
of the optical module 2' and electrode pads of the LSI chip 88 are 
connected through gold wires to the lead terminals 82 of the casing 80. As 
shown in FIG. 13, the inside space of the casing 80 is filled with a 
silicone resin 110, and the silicone resin 110 is cured to thereby 
simultaneously carry out resin molding of the optically coupled portion 
and the electrically connected portion and fixing of the ferrule 18' for 
reinforcement. Thereafter, the lead terminals 82 of the casing 80 are 
connected by flow soldering to a printed wiring board (not shown). 
Referring to FIG. 15, there is shown a sectional view of an optical fiber 
connector 112 to be connected to the optical module 2'. An optical fiber 
114 is inserted and fixed in a ferrule 116. The ferrule 116 is movably 
inserted in a C-shaped sleeve 118. The C-shaped sleeve 118 is inserted 
through a sleeve 122 in a housing 120 formed of a synthetic resin. A coil 
spring 124 is interposed between the ferrule 116 and the housing 120 so as 
to bias the ferrule 116 leftward as viewed in FIG. 15. The housing 120 is 
formed with projections 126 and 128 for respectively engaging the 
connector holding members 102 and 104 of the optical fiber connector 
housing 94. 
By jointing the optical fiber connector 112 to the ferrule 18' of the 
optical module 2' and pivoting the connector holding members 102 and 104 
about the pins 106 and 108 to engage them with the projections 126 and 128 
of the housing 120, the ferrule 18' of the optical module 2' and the 
ferrule 116 of the optical fiber connector 112 come into pressure contact 
with each other by a biasing force of the coil spring 124, thereby 
achieving optical connection. According to this preferred embodiment, the 
optical connection of the ferrules 18' and 116 can be achieved by engaging 
the connector holding members 102 and 104 with the projections 126 and 128 
of the housing 120, respectively. Accordingly, it is possible to prevent 
the occurrence of stress concentration at a soldered portion between the 
lead terminals 82 of the optical module and the printed wiring board when 
connecting or disconnecting the optical fiber connector 112. 
Referring to FIGS. 17 to 21, there is shown an optical transmission 
terminal device 130 according to a fourth preferred embodiment of the 
present invention. In this preferred embodiment, an optical module 54' is 
similar to the optical module 54 shown in FIGS. 7 and 8, and a casing 132 
is similar to the casing 80 shown in FIG. 11 in such a manner that the 
casing 132 has a plurality of lead terminals 136 and an opening 134 for 
allowing projection of a ferrule 18'. A metal block 138 having radiation 
fins 158 (see FIG. 20) on the lower surface is mounted through the bottom 
surface of the casing 132. 
As similar to the third preferred embodiment, the optical module 54' is 
received in the casing 132 in such a manner that the ferrule 18' projects 
from the opening 134, and is fixedly mounted on the metal block 138 by an 
epoxy resin. The casing 132 is formed with a pair of projections 140 and a 
pair of recesses 142 adjacent to the opening 134. Reference numeral 144 
denotes a optical fiber connector housing having a body 146. The body 146 
has a pair of recesses 148 for engaging the projections 140 of the casing 
132 and a pair of projections 150 for engaging the recesses 142 of the 
casing 132. A pair of connector holding members 152 and 154 each formed 
from a steel wire are pivotably mounted to the body 146. 
By engaging the projections 150 of the optical fiber connector housing 144 
with the recesses 142 of the casing 132 and engaging the projections 140 
of the casing 132 with the recesses 148 of the optical fiber connector 
housing 144, the optical fiber connector housing 144 is mounted to the 
casing 132 so as to close the opening 134. Feed electrodes of the optical 
module 54' are connected through gold wires to the lead terminals 136 of 
the casing 132. As shown in FIG. 19, the inside space of the casing 132 is 
filled with an epoxy resin 156, and the epoxy resin 156 is cured to 
thereby simultaneously carry out resin molding of the electrically 
connected portion and fixing of the ferrule 18' for reinforcement. 
Thereafter, the casing 132 is reversed in such a manner that the radiation 
fins 158 face the upper side as shown in FIG. 20, and the lead terminals 
136 of the casing 132 are connected by flow soldering to a printed wiring 
board (not shown). Reference numeral 160 denotes an optical fiber 
connector including a ferrule 162 and an H-shaped flange 166 fixed to the 
ferrule 162. An optical fiber 164 is inserted and fixed in the ferrule 
162. 
By jointing the ferrule 162 of the optical fiber connector 160 through a 
C-shaped sleeve 168 to the ferrule 18' of the optical module 54' and 
engaging the connector holding members 152 and 154 with the H-shaped 
flange 166 of the optical fiber connector 160, the optical fiber connector 
160 is connected to the optical module 54'. An elastic restoring force of 
the connector holding members 152 and 154 formed from steel wires is 
generated by the engagement of the members 152 and 154 with the H-shaped 
flange 166, acting in a direction where the ferrule 162 comes into 
pressure contact with the ferrule 18', thereby achieving optical 
connection of the ferrules 18' and 162. Accordingly, it is possible to 
prevent the occurrence of stress concentration at a soldered portion 
between the lead terminals 136 of the optical module 54' and the printed 
wiring board. 
Referring to FIGS. 22 and 23, there is shown an optical module 168 applied 
to a fifth preferred embodiment of the optical transmission terminal 
device according to the present invention. Reference numeral 170 denotes 
an optical component mounting substrate. A waveguide substrate 172 formed 
with optical waveguides 174 is mounted on the substrate 170. The substrate 
170 has two grooves 6 for receiving two ferrules 18 and two grooves 8 for 
receiving two bare fibers 20. Two photoelectric converters 10 are mounted 
on the substrate 170, and feed electrodes 12 and 14 for each photoelectric 
converter 10 are formed on the substrate 170. 
After the ferrules 18 and the bare fibers 20 are inserted into the grooves 
6 and 8, respectively, a holder cover 176 is fixed to the substrate 170 by 
soldering so as to cover the ferrules 18 and the bare fibers 20. The 
substrate 170 and the holder cover 176 are formed of silicon, for example. 
As shown in FIG. 23, a silicone resin 178 is applied to optically coupled 
portions between the optical waveguides 174 and the photoelectric 
converters 10, and a silicone resin 180 is applied to optically coupled 
portions between the optical waveguides 174 and the optical fibers 20. The 
silicone resins 178 and 180 applied are cured to thereby achieve hermetic 
sealing. 
Referring to FIGS. 24 and 25, there is shown an optical transmission 
terminal device 182 according to the fifth preferred embodiment of the 
present invention. The optical transmission terminal device 182 includes 
the optical module 168 shown in FIG. 23. A pattern of PbSn solder paste is 
preliminarily printed by a screen printing process on a printed wiring 
board 184 at given device mounting positions. The optical module 168 and 
an LSI chip 188 are placed on the given solder pattern of the printed 
wiring board 184, and thereafter soldered by reflow soldering. Then, the 
feed electrodes 12 and 14 of the optical module 168 and electrode pads of 
the LSI chip 188 are connected through gold wires to wiring patterns 186 
formed on the printed wiring board 184. Thereafter, the LSI chip 188 and 
electrically connected portions between the feed electrodes 12 and 14 and 
the wiring patterns 186 are sealed commonly by an epoxy resin 190. 
Reference numeral 192 denotes an optical fiber connector housing having a 
structure such that two optical fiber connector housings 36 shown in FIG. 
5 are laterally joined. The optical fiber connector housing 192 is fixed 
to the optical module 168 mounted on the printed wiring board 184 by an 
epoxy resin. Reference numeral 194 denotes an optical fiber connector 
having a structure similar to that of the optical fiber connector 38 shown 
in FIG. 5 such that two ferrules are laterally arranged. Two optical 
fibers 196 and 198 are inserted and fixed in the two ferrules of the 
optical fiber connector 194. 
Referring to FIGS. 26 and 27, there is shown an optical module 200 applied 
to a sixth preferred embodiment of the optical transmission terminal 
device according to the present invention. Reference numeral 202 denotes 
an optical component mounting substrate formed preferably of silicon. The 
silicon substrate may be replaced by a ceramic substrate, glass substrate, 
etc. An optical fiber 208 is fully inserted and fixed in a ferrule 206. 
The ferrule 206 with the optical fiber 208 may be fabricated by inserting 
the optical fiber 208 into a glass capillary and thereafter polishing both 
end faces of the glass capillary. 
The optical component mounting substrate 202 has a slot 204 for holding the 
ferrule 206. The ferrule 206 is fixedly mounted in the slot 204 of the 
substrate 200, and a holder cover 210 is mounted on the substrate 202 so 
as to cover the ferrule 206 and soldered to the substrate 202. By 
optimally setting the width of the slot 204 and the diameter of the 
ferrule 206, optical coupling between the photoelectric converter 10 and 
the optical fiber 208 in the ferrule 206 is achieved. The optical module 
200 is mounted on a printed wiring board (not shown) as in the optical 
transmission terminal device 24 shown in FIGS. 3 and 4. 
In the case that the substrate 202 is formed of silicon, the slot 204 can 
be formed by a process shown in FIGS. 28A to 28G. A silicon substrate 212 
having a thickness of 400 .mu.m is selected to obtain a depth 350 .mu.m of 
contact between the ferrule 206 and the slot 204. SiO.sub.2 films 214 and 
216 each having a thickness of about 2 .mu.m are formed on the upper and 
lower surfaces of the silicon substrate 212 by thermal oxidation. 
As shown in FIGS. 28A and 28B, a photoresist mask having a slot pattern 218 
is formed on the upper surface of the silicon substrate 212 by 
photolithography. Then, a portion of the SiO.sub.2 film 214 corresponding 
to the slot pattern 218 is removed by reactive ion etching using a 
CF.sub.4 gas, and the photoresist mask is next removed by ashing. 
Similarly, a portion of the SiO.sub.2 film 216 shown by a broken line 220 
on the lower surface of the silicon substrate 212 is removed. 
Then, the silicon substrate 212 is subjected to wet etching (anisotropic 
etching) using a 40% aqueous solution of KOH with the SiO.sub.2 films 214 
and 216 left on the silicon substrate 212 used as a mask (FIGS. 28C and 
28D) to form a sectionally V-shaped slot 222 as shown in FIG. 28E. Then, 
the photoelectric converter 10 and the ferrule 206 having an outer 
diameter of 1.25 mm and enclosing the optical fiber 208 are mounted on the 
substrate 212 in such a manner that the ferrule 206 is positioned in the 
slot 222 in alignment with the photoelectric converter 10, thus achieving 
optical coupling between the photoelectric converter 10 and the optical 
fiber 208. A remaining portion 216a of the SiO.sub.2 film 216 can be 
easily removed in mounting the ferrule 206, so that the portion 216a has 
no influence on the positioning of the ferrule 206. FIG. 28G is a cross 
section taken along the line 28G--28G in FIG. 28F. 
Referring to FIGS. 29A to 29G, there is shown another forming method for 
the ferrule holding slot by use of the silicon substrate. A silicon 
substrate 224 having a thickness of 800 .mu.m is selected to obtain a 
depth 350 .mu.m of contact between the ferrule 206 and the slot 204. 
SiO.sub.2 films 214 and 216 each having a thickness of about 2 .mu.m are 
formed on the upper and lower surfaces of the silicon substrate 224 by 
thermal oxidation. Then, slot patterns 218 and 220' are formed on the 
upper and lower surfaces of the silicon substrate 224 by using a 
photoresist mask, and portions of the SiO.sub.2 films 214 and 216 
corresponding to slot patterns 218 and 220' are removed by reactive ion 
etching. Thereafter, the photoresist mask is removed by ashing (FIGS. 29A 
and 29B). 
Then, the silicon substrate 224 is subjected to wet etching (anisotropic 
etching) using an aqueous solution of KOH to form a slot 226 as shown in 
FIGS. 29C and 29D. In the next step, a pointed portion 228 of the silicon 
substrate 225 is cut by using a dicing saw 230 to form a flat surface 232 
to be opposed to a front end face of the ferrule 206 in parallel to each 
other, thus forming a final slot 229 for holding the ferrule 206. As shown 
in FIG. 29F, the photoelectric converter 10 and the ferrule 206 having an 
outer diameter of 1.25 mm and enclosing the optical fiber 208 are mounted 
on the substrate 224 in such a manner that the ferrule 206 is positioned 
in the slot 229 in alignment with the photoelectric converter 10, thus 
achieving optical coupling between the photoelectric converter 10 and the 
optical fiber 208. FIG. 29G is a cross section taken along the line 
29G--29G in FIG. 29F. 
Referring to FIGS. 30A to 30J, there is shown still another forming method 
for the ferrule holding slot by use of the silicon substrate. A silicon 
substrate 234 having a thickness of 1 mm is selected to obtain a depth 350 
.mu.m of contact between the ferrule 206 and the slot 204. SiO.sub.2 films 
214 and 216 each having a thickness of about 2.5 .mu.m are formed on the 
upper and lower surfaces of the silicon substrate 234. First, a slot 
pattern 236 is formed on the lower surface of the silicon substrate 234 by 
using a photoresist mask, and a portion of the SiO.sub.2 film 216 
corresponding to the slot pattern 236 is removed as shown in FIGS. 30A and 
30B. Then, the lower surface of the silicon substrate 234 is 
anisotropically etched to form a V-shaped (trapezoidal) groove 238 having 
a depth of about 200 .mu.m. 
As shown in FIGS. 30D and 30E, a V-shaped (trapezoidal) groove pattern 218 
is formed on the upper surface of the silicon substrate 234 by using a 
photoresist mask, and a portion of the SiO.sub.2 film 214 corresponding to 
the V-shaped groove pattern 218 is removed. Then, the V-shaped groove 
pattern 218 and the V-shaped groove 238 formed on the upper and lower 
surfaces of the silicon substrate 234 are simultaneously etched by 
anisotropic etching (FIG. 30F) to obtain a sectionally V-shaped slot 248 
as shown in FIG. 30G. In the next step, a pointed portion 240 of the 
silicon substrate 234 is cut by using a dicing saw 230 to form a flat 
surface 242 to be opposed to a front end face of the ferrule 206 in 
parallel to each other, thus forming a final slot 249 for holding the 
ferrule 206 (FIG. 30H). As shown in FIG. 30I, the photoelectric converter 
10 and the ferrule 206 having an outer diameter of 1.25 mm and enclosing 
the optical fiber 208 are mounted on the substrate 234 in such a manner 
that the ferrule 206 is positioned in the slot 249 in alignment with the 
photoelectric converter 10, thus achieving optical coupling between the 
photoelectric converter 10 and the optical fiber 208. FIG. 30J is a cross 
section taken along the line 30J--30J in FIG. 30I. 
FIGS. 31A and 31B show another mounting method for a ferrule 250 enclosing 
an optical fiber. The ferrule 250 is held between two glass substrates 252 
and 254 each formed with a ferrule holding groove. Reference numeral 256 
denotes an optical component mounting substrate. An optical waveguide 258 
is formed on the substrate 256 so as to be exposed to one end surface of 
the substrate 256. A photoelectric converter (not shown) is mounted on the 
substrate 256. 
The ferrule 250 is located in such a manner that the upper holding 
substrate 252 comes into contact with the upper surface of the substrate 
256, and is positioned with respect to the substrate 256, monitoring the 
optically coupled the state so that the optical fiber in the ferrule 250 
is optically coupled to the optical waveguide 258 formed on the substrate 
256. Finally, an ultraviolet curable adhesive preliminarily applied to a 
contact surface between the substrate 256 and the ferrule holding 
substrates 252 and 254 is exposed to ultraviolet radiation from the upper 
side, thereby fixing the ferrule holding substrates 252 and 254 to the 
substrate 256. The optical module manufactured by this process is mounted 
on a printed wiring board (not shown) as in the optical transmission 
terminal device 24 shown in FIGS. 3 and 4. 
FIGS. 32 to 34 show an optical module 259 according to another preferred 
embodiment of the present invention. The optical module 259 is composed 
generally of a silicon substrate 260, an optical component mounting 
substrate 274, and a holder substrate 282 for holding a ferrule 18 in 
which an optical fiber 20 is inserted and fixed. The silicon substrate 260 
is formed with a groove 262 for receiving the ferrule 18, a groove 264 for 
receiving the optical fiber 20, markers 266 and 268, a groove 270 for 
receiving an adhesive, and a groove 272 for receiving a projection on the 
substrate 274. These grooves and markers are formed by anisotropic 
etching. The optical component mounting substrate 274 is formed of 
silicon. An optical waveguide 276 and markers 278 and 280 formed by 
anisotropic etching are formed on one surface of the substrate 274. 
As shown in FIG. 32, the substrate 274 is placed on the ferrule holding 
substrate 260 in such a manner that the surface of the substrate 274 on 
which the optical waveguide 276 is formed, and the substrate 274 is 
positioned with respect to the substrate 260 so that the markers 278 and 
280 are aligned with the markers 266 and 268, respectively. Thereafter, 
the substrate 274 is fixed to the substrate 260 by an adhesive 
preliminarily applied to the surface of the groove 270. As shown in FIG. 
33, the holder cover 282 is also formed with a groove 284 for receiving 
the ferrule 18 and a groove 286 for receiving the optical fiber 20. The 
ferrule 18 and the optical fiber 20 are received in the grooves 262 and 
264 of the ferrule holding substrate 260, respectively, and the holder 
cover 282 is fixedly mounted on the ferrule holding substrate 260 by an 
adhesive in such a manner that the ferrule 18 and the optical fiber 20 are 
received into the grooves 284 and 286, respectively. Although not shown, a 
photoelectric converter optically coupled to the optical waveguide 276 is 
mounted on the optical component mounting substrate 274. 
According to the present invention, it is possible to provide an optical 
transmission terminal device having a package structure suitable for mass 
production and achieving low cost and high reliability.