Photoelectronic device with an electromagnetic shielding member for electromagnetically isolating a light emitting element from a light receiving element

A photoelectronic device including an electromagnetic shield and an optical transmitter. The electromagnetic shield includes a shield member which is interposed between a light emitting element and a light receiving element or device for electromagnetically isolating a conductor for applying a signal to the light emitting element and a conductor for extracting an electric signal from the light receiving element. The optical transmitter includes a transparent member disposed in the shield member for guiding the light emitted from the light emitting element to the light receiving element.

BACKGROUND OF THE INVENTION 
The present invention relates to a photoelectronic device for optical 
communications. 
Optical communications are rapidly developing as a new communication 
system. Optical communications use light as an information transmitting 
medium and optical fibers are used as paths for transmitting the light. 
Optical communications are also called "optical fiber communications" and 
can effect communications with lower loss, wider band, longer distance and 
higher capacity than those of communications using coaxial cables of the 
prior art. A semiconductor laser element is generally used as a light 
source and is one of the light sources, which is not only small and light 
weight, but is also capable of performing direct, high-speed modulation 
and high-capacity communication with a low-voltage drive. 
For realizing long-distance communications, an optical repeater is often 
required, which repeater serves to amplify d.c. power which attenuates in 
an optical fiber. The optical repeater is also required to have another 
function of monitoring whether or not the frequency of the light input 
from the optical fiber to the optical repeater is equal to that of the 
light output from the optical repeater to another optical fiber. For this 
function, a semiconductor laser device is required for optical 
communications, which is equipped with a light emitting element and a 
light receiving element in a common package. 
As a semiconductor laser device, a laser module for communications has been 
proposed as described in "Hitachi Review", Vol. 33, No. 4, pp 193 to 198 
(1984). This semiconductor laser device is assembled into a directly 
opposed package, in which the leading end of an optical fiber is opposed 
to face the end face of an oscillator of a semiconductor laser element. 
This package is provided as a box-shaped, flattened module. This 
semiconductor laser device has a recess at a central portion of the 
principal plane of a metallic stem of the module. The recessed portion is 
sealed with a cap which is made of a metal plate. The sealed module is 
provided with a semiconductor laser element (or a laser chip) and a light 
receiving element which is made operative to detect the power or frequency 
of a laser beam emitted from the end face of the oscillator of the laser 
element or chip. In the recess, there also exists a conductor for applying 
an a.c. signal to the semiconductor laser element and a conductor for 
extracting an electric signal from the light receiving element. The 
aforementioned laser module for optical communications exhibits a 
sufficient function as a semiconductor laser device for optical 
communications. Despite this fact, however, this laser module is required, 
like other devices, to have higher performance characteristics. 
At the present stage of development of optical communications, the 
information transmission rate is about 140 to 200 Mbits/sec, but is 
expected to be 560 Mbits/sec or several Gbits/sec in the future, in 
accordance with the expected drastic increase in the amount of information 
to be transmitted. 
SUMMARY OF THE INVENTION 
It is an object of the present invention to provide a photoelectronic 
device which enables optical communication at a high information 
transmission rate. 
It is another object of the present invention to provide photoelectronic 
device which includes means for preventing electromagnetic coupling 
between conductor for a light emitting element and a conductor for 
extracting an electric signal from a light receiving element while 
enabling optical transmission between the light emitting element and the 
light receiving element so as to enable precise and accurate monitoring of 
the frequency of the emitted light beam. 
In accordance with the present invention, a photoelectronic device includes 
an electromagnetic shield member and an optical transmitter. The 
electromagnetic shield member serves for electromagnetically isolating a 
first conductor for applying an a.c. (e.g., RF) signal to a light emitting 
element and a second conductor for extracting an electric signal from a 
light receiving element. The optical transmitter includes a transparent 
member which is disposed through the electromagnetic shield member to 
guide the light from the light emitting element to the light receiving 
element. The electromagnetic shield member prevents the electromagnetic 
induction phenomena caused by an a.c. signal applied to the first 
conductor, from occurring in the second conductor. Moreover, the 
transparent member improves the optical coupling between the light 
emitting element and the light receiving element. As a result, a high 
accuracy monitor, which is required of the photoelectronic device, can be 
obtained to improve the information transmission rate. 
According to features of the present invention, the shield member is made 
of conductive material and the shield member is made of the same material 
as that of a sealing member of the photoelectronic device so that the same 
thermal coefficient is provided. Additionally, the shield member is made 
of an iron alloy to improve the electromagnetically shield effect with the 
shield member being fixed on sealing member of a package forming the 
photoelectronic device by a conductive adhesive to facilitate assembly. 
According to other features of the present invention, the transparent 
member is made of glass and is constructed as a lens to improve the 
efficiency of introducing the light into the light receiving element. 
Further, the transparent member, in accordance with a feature, is made as 
thick as the shield member but does not extend beyond the surface of the 
latter so as to prevent breakage or damage to the surface thereof during 
assembly. On the other hand, the transparent member, in accordance with 
another feature, is constructed so as to extend from the shield member and 
to have opposite end faces close to the light emitting element and the 
light receiving element so that the light may be efficiently extracted 
from the light emitting element to irradiate the light receiving element. 
The photoelectronic device in accordance with the present invention is 
constructed as a package having an outer wall forming a part of the shield 
member, and the transparent member is attached to a portion of the shield 
member. Moreover, the light receiving member is built in that outer wall 
to provide the photoelectronic device in which the light emitting element 
and the light receiving element are integrally formed. Since the outer 
wall of the package can be used commonly as the shield member, according 
to this construction, the cost of the package can be reduced.

DESCRIPTION OF THE PREFERRED EMBODIMENTS 
FIG. 1 is a schematic illustration of an optical repeater A which converts 
a light L.sub.1 coming from an optical fiber F1 into an electric signal by 
the action of a light receiving element PDI and drives a semiconductor 
element in a photoelectronic device B through a semiconductor laser 
element driver LD Driver on the basis of that electric signal so that a 
laser beam L.sub.2 may be introduced as optical information into an 
optical fiber F2. The optical repeater is formed with a feedback loop so 
as to monitor the optical power of the laser beam L.sub.2. This feedback 
loop is provided for the d.c. component and frequency component of the 
laser beam L.sub.2 and includes, as shown, a light receiving element PD2 
for converting a laser beam L.sub.3 corresponding to the laser beam 
L.sub.2 and emitted by the semiconductor laser element LD in the 
photoelectronic device B, into an electric signal, and a comparator COM. 
For a higher information transmission rate, the frequency of the drive 
signal from the LD driver for the semiconductor laser element LD is higher 
and this RF drive signal is applied to a line l.sub.1 connected with the 
semiconductor laser element LD. In the photoelectronic device B, there is 
provided a line l.sub.2 for transmitting the electric signal from the 
light receiving element PD2 to the comparator COM. The comparator COM is 
also supplied with the electric signal from the light receiving element 
PD1 and compares the frequencies of the two electric signals input thereto 
to thereby provide as an output thereof the compared result as a signal to 
the semiconductor laser driver LD Driver. The semiconductor laser driver 
LD Driver drives the semiconductor laser at the desired frequency in 
response to the signal from the comparator COM. The lines l.sub.1 and 
l.sub.2 are not electromagnetically isolated in the photoelectronic device 
B. If the RF signal is applied to the line l.sub.1, it exerts an influence 
upon the line l.sub.2 by the electromagnetic induction phenomena. More 
specifically, the lines l.sub.1 and l.sub.2 are electromagnetically 
coupled so that the two kinds of signals, i.e., an electrical signal 
caused by the emitted laser beam L.sub.3 and an electrical signal caused 
by the electromagnetic coupling phenomena are applied to the line l.sub.2. 
Thus, it is not possible to accurately monitor the frequency of the laser 
beam L.sub.2 emitted from the semiconductor laser element LD. The 
electromagnetic coupling phenomena occurs at an information transmission 
rate about 140 MHz. 
EMBODIMENT 1 
FIG. 2 is a schematic illustration of an optical repeater utilizing a 
photoelectronic device 1 according to the present invention. As shown, the 
photoelectronic device 1 is equipped, between a line 5 to be fed with an 
RF signal from the LD Driver for driving a semiconductor laser element 9 
and a line 6 for extracting an electric signal from a light receiving 
element 21, with a shield member 20 which acts as an electromagnetic 
shield for preventing electromagnetic coupling between the two lines 5 and 
6, thereby preventing the occurrence of the electromagnetic phenomena 
between the two lines 5 and 6. 
Between the light receiving element 21 and the semiconductor laser element 
9, there is also interposed a transparent member 22 which acts a an 
optical transmitter for improving the optical coupling between the two 
elements 9 and 21. A monitor light beam 18B emitted from the semiconductor 
laser element 9 and corresponding to the laser beam 18A is always 
introduced into the light receiving element 21. 
This arrangement provides a state in which only the electric signal 
generated from the monitor beam 18B by the light receiving element 21 is 
present in the line 6 so that the frequency of a corresponding laser beam 
18A emitted by the semiconductor laser element 9 for introduction into an 
optical fiber 17 can be monitored highly accurately via the comparator COM 
and the LD Driver. As a result, a light L.sub.1 input from an optical 
fiber F1 to the optical repeater A has the same frequency as that of the 
laser beam 18A introduced from the semiconductor laser 9 into the optical 
fiber 17. This is because the frequency of the laser beam 18A is 
controlled by the feedback loop on the basis of the electric signal on the 
line 6 which is immune to electromagnetic influence. As in the FIG. 1 
illustration, reference character PD1 indicates a light receiving element 
for converting the light L.sub.1 from the optical fiber F1 into an 
electric signal. 
FIG. 3 is a partially cut-away perspective view showing an essential 
portion of the photoelectronic device 1 according to one embodiment of the 
present invention, and FIG. 4 is a graph for explaining the effects of the 
photoelectronic device of the present invention. The photoelectronic 
device 1 (or the semiconductor laser device) according to this embodiment 
is formed as a flattened module package, as shown in FIG. 3. The package 
which is a sealed package is constructed of a box-shaped metallic stem 2 
having its principal surface formed with a recess in which individual 
parts are assembled and a metallic cap 3 hermetically closes and seals the 
recess of the stem 2. This stem 2 is made of KOIVAR whereas the cap 3 is 
made of KOVAR or stainless steel. From the package thus constructed, there 
protrudes one optical fiber 4 and two pairs of leads 5A and 5B, and 6A and 
6B. The stem 2, as shown, is provided with mounting holes 7A, 7B, 7C and 
7D at the four corners thereof. 
A laser chip 9 is fixed on a mount 8 which is placed at the center of the 
recess of the stem 2. The laser chip 9 is fixed on the mount 8 through a 
small support member or submount 10 which is made of a conductive material 
such as silicon. In addition to the laser chip 9, a pedestal 11 is fixed 
on small support member 10. That pedestal 11 is a small member which is 
constructed so as to enable characteristic test preceding the attachment 
of the laser chip 9 to the mount 8 and which is formed as an insulating 
member having a conductive surface. As a result, the small support member 
10 can be removed at the stage when it is fixed on the mount 8. 
A cylindrical fiber guide 12 is fitted and hermetically fixed on the 
circumferential wall of the stem 2 by means of solder. The fiber guide 12 
is constructed of a long sleeve 13 inserted into the stem 2, a radially 
enlarged stopper 14 abutting against the side face of the stem 2, and a 
caulked portion 15 thinner than the stopper 14. The sleeve 13 is made to 
have an external diameter of 0.4 mm and internal diameter of 0.2 mm, for 
example. Moreover, a portion of the optical fiber 4 is inserted into the 
fiber guide 12 and the inserted portion includes a jacket 16, and a cable 
17 in which the jacket 16 at the leading end, within the recess, is peeled 
away to expose the core and cladding. The cable 17 has its leading end 
formed into a conical shape to make the leading end core face the end (or 
light emitting) face of one resonator of the laser chip 9 so that the 
laser beam 18A emitted from the laser chip 9 is efficiently introduced 
into the core. For optical alignment, the leading end portion of the cable 
17 is inserted into an opening formed in a stationary post 19 fixed on the 
stem 2 and the leading end portion is fixed therein by a fixing agent. As 
a result, the leading end of the cable 17 is immovable with respect to the 
light emitting portion of the laser chip 9 so that it is always held in an 
excellently aligned state. 
At a position opposed to the fiber guide 12, there is arranged an 
electromagnetic shield member 20 which acts as the electromagnetic shield. 
The shield member 20 is disposed for preventing electromagnetic coupling 
between the lead 5a and a wire 30 for applying an RF signal to the laser 
chip 9 provided on one side of the shield and conductors 24, 25 and a wire 
27 for extracting an electric signal from a light receiving element 21 
provided on the other side of the shield. The shield member 20 is made of 
the same material such as a ferromagnetic iron alloy or KOVAR as that of 
the package 1. Additionally, the shield member 20 is electrically 
connected to the package 1 so that the light receiving element 21 is 
electromagnetically shielded during operation of the laser chip 9. 
The shield member 20 and the package 1 are made of identical material in 
the above construction so as to have equal coefficients of thermal 
expansion. In this manner, the position of a glass member 22, attached to 
the shield member 20, is prevented from fluctuating from the optical axis 
of the laser chip 9 and the light receiving element 21 during the 
operation of the laser chip 9. This ensures that the light emanating from 
the laser chip 9 always reaches the light receiving element 21. 
The shield member 20 may be formed integrally with the package 1. 
Considering the ease of assembly, however, it is preferred that the 
package 1 and the shield member 20 be prepared separately and assembled in 
the package 1 by means of a conductive adhesive such as a silver solder. 
Th shield member 20 is also electrically connected with the cap 3 and is 
separated spatially and electromagnetically from the light receiving 
element 21 and the laser chip 9. The shield member 20 and the cap 3 may be 
electrically connected by means of an adhesive. More preferably, the 
shield member 20 may have a construction in which it is held in uniform 
contact with the cap 3 and this arrangement is preferred since it does not 
require an additional production step. 
Within the electromagnetic shield member 20, the glass member 22 is fixed 
and is made of a transparent material so as to act as an optical 
transmitter for guiding a laser beam 18B emitted from the laser chip 9 
into the light receiving element 21. The glass member 22 should be as 
thick as the shielding member 22 such that it does not extend beyond the 
surface of the shield member 20. This thickness facilitates the assembly 
of the shield member 20 with the glass member 22 in the limited recess of 
the package 1 and prevents the glass member 22 from being folded and 
having its exposed surface damaged during the assembly. 
The shield member 20 with the glass member 22 is preferably fixed in the 
package 1 before the laser chip 9 and the light receiving element 21 are 
assembled in the package 1. This assembly prevents the heat treatment 
involved in the assembly of the shield member 20 from being influenced by 
the characteristic fluctuations of the laser chip 9 and the light 
receiving element 21. 
If the glass member 22 is constructed as a lens, moreover, the optical 
power capable of reaching the light receiving element is increased to make 
the monitoring operation more reliable and accurate. 
A block 23 of insulating material is attached to the inner ends of the two 
leads 6A and 6B opposed to the fiber guide 12. The leads 6A and 6B are 
connected by means of solder 26 to portions of conductors 24 and 25 which 
extend from the principal surface to the sides of the block 23. The light 
receiving element 21 is fixed to one conductor 24, and a wire 27 which has 
one end connected to the electrode of the light receiving element 21 and 
has the other end connected to the other conductor 25. The leads 6A and 
6B, the conductors 24 and 25 and the wire 27 form together a second 
conductor. As a result, the paired leads 6A and 6B provide the output 
terminals of the light receiving element 21, from which the electric 
signal is extracted. The paired leads 6A and 6B are fixed to the stem 2 
through insulators 28A and 28B, respectively. 
Like the leads 6A and 6B, one lead 5A for the laser chip 9 is fixed in the 
stem 2 through an insulator 29 and connected to the surface electrode of 
the laser chip 9 through the wire 30. The lead 5A and the wire 30 form 
together a first conductor. The other lead 5B for the laser chip 9 
provides a third conductor and is fixed directly to the stem 2. This lead 
5B is electrically connected with the lower electrode of the laser chip 9 
through the stem 2 and the small support member 10. As a result, when a 
predetermined voltage is applied between the paired leads 5A and 5B, the 
laser beams 18A and 18B are emitted from the light emitting surface of the 
laser chip 9. 
In the photoelectronic device (or the semiconductor laser device) thus 
constructed with the optical fiber the laser beams 18A and 18B are emitted 
from the end faces of the resonator of the laser chip 9 when a 
predetermined voltage is applied between the paired leads 5A and 5B. The 
optical information carried by the laser beam 18A is transmitted to 
desired place through the optical fiber 4 acting as the transmitting 
medium. On the other hand, the optical power and frequency of the laser 
beam 18B are monitored at all times by the light receiving element 21 so 
that they may be maintained constant. 
In this photoelectronic device, the wire 30 for feeding the RF signal to 
the laser chip 9, the lead 5A' extending in the package 1 to that wire 30, 
the wire 27 extending in the package 1 for extracting the electric signal 
from the light emitting element 21, and the conductors 23 and 24 are 
isolated by the electromagnetic shield member 20. As a result, no 
electromagnetic coupling occurs even for an information transmission rate 
of 560 Mbits/sec so that the frequency of the laser beam 18B can be 
monitored accurately and highly precisely by the light receiving element 
21. 
The relative intensity RI (in dB) of the monitor signal is plotted for 
examination against the frequency f (in Hz) of the laser beam 18B, as 
shown in the graph of FIG. 4. The relative intensity RI is indicated by a 
solid curve I in the case of electromagnetic coupling and by a 
double-dotted curve II in the case of the optical and electromagnetic 
coupling. As a result, any frequency over 600 MHz will make it absolutely 
impossible to detect the variation in the frequency of the optical power 
due to the effect of electromagnetic coupling. The ordinate is scaled at a 
rate of 5dB/div. More specifically, the difference of the curve II from 
the curve I implies the intensity exclusively of the optical coupling, and 
the frequency of the laser beam 18B can be monitored by the light 
receiving element so long as the difference becomes zero. The optical d.c. 
power of the laser beam 18A can be accurately monitored even if 
electromagnetic coupling occurs. This is because electromagnetic coupling 
is a phenomenon peculiar to alternating current. 
In the case of the photoelectronic device according to this embodiment, the 
electromagnetic shield member 20 is interposed between the wire 30 and the 
lead 5A', and the wire 27 and the conductors 24 and 25 so that 
consideration is taken to prevent electromagnetic coupling. The laser beam 
18B reaches the light receiving element 21 through the glass member 22 
arranged in and through the shield member 20 so that its frequency can be 
detected accurately and reliably. Since the photoelectronic device of the 
embodiment is constructed to be free of the electromagnetic coupling, the 
signal oscillated from the laser chip 9 can be monitored so long as its 
frequency is within the range of the shielding frequency of about 1 GHz of 
the light receiving element 21 or within the modulatable range of the 
frequency (e.g., 1 to several GHz) to 600 MHz of the semiconductor laser. 
EMBODIMENT 2 
FIG. 5 is an enlarged view showing an essential portion of the 
photoelectronic device according to another embodiment of the present 
invention. In this embodiment, the transparent member has a shape 
different from that of Embodiment 1. A glass member 31 acting as the 
transparent member is constructed as an elongated glass rod (e.g., a 
SELFOC lens). The glass member 31 is fixed within an electromagnetic 
shield member 32 made of a conducting material (e.g., KOVAR) to guide a 
beam 34 emitted from a laser chip 33 acting as a light emitting element to 
a light receiving element 35. The electromagnetic shield member 32 is held 
in electrical contact with a cap 36 and is fixed to a stem 37 by means of 
a conductive adhesive 38 such as silver solder. The shielding member 32 
thus constructed provides effects similar to those of the Embodiment 1 by 
isolating the laser chip 33 and the light receiving element 35 
electromagnetically and spatially from each other. Since the transparent 
member 31 of the elongated glass rod has its two opposite ends close to 
the laser chip 33 and the light receiving element 35, it can efficiently 
receive the beam 34 emitted from the laser chip 33 and irradiate the light 
receiving element 35 with the beam 34. 
The laser chip 33 is fixed on a submount 39 made of silicon by means of 
solder 42, and the submount 39 is in turn fixed on a mount 43 placed on 
the stem 37. The light receiving element 35 is fixed on a conductor 41 
which is attached to an insulating block 40. That stem 37 is fixed at the 
ground potential providing a first operation potential of the laser chip 
33 to electromagnetically shield the laser chip 33 and the light receiving 
element 35. 
EMBODIMENT 3 
FIG. 6 is a sectional view showing still another embodiment of the present 
invention wherein a shield member 44 acting as the electromagnetic shield 
is formed as part of the outer wall of a sealing package 45 and a light 
receiving device is built in the outer wall. 
Within the package 45, there is fixed through a submount 47 a laser chip 46 
which acts as a light emitting element so that one of emanating beams is 
guided through a transparent member 48 disposed in the shield member 44 so 
as to optically transmit the beam to a light receiving element 50 disposed 
in a light receiving device 49 attached to the package 45 and acting as a 
light receiver. The other beam emitted from the laser chip 46 is 
introduced into an optical fiber 52 which extends through a fiber guide 51 
disposed in the package 45. The optical fiber 52 is protected by a plastic 
jacket 52a. 
In the package 45, there is fixed a lead 53 which is provided for applying 
a signal to the laser chip 46 and which has its leading end portion 
connected with the electrode of the laser chip 46 through a wire 55. 
Moreover, a lead 56 for applying a potential to the package 45 is 
connected with the package 45 so that the laser chip 46 may emit the beam 
by applying a predetermined potential between the leads 53 and 56. The 
light receiving device fixed in the outer wall of the package 45 is 
equipped with the leads 57 and 58 for extracting an electric signal from 
the light receiving element 50, which includes a cap 59 and a glass member 
60 attached to the cap 59. 
In the photoelectronic device of the present embodiment, like the foregoing 
Embodiments 1 and 2, the laser chip 46 and the light receiving element 50 
are electromagnetically isolated due to the presence of the 
electromagnetic shield member 44 so that electromagnetic coupling 
therebetween is prevented. Moreover, due to the presence of the 
transparent member 48, the optical coupling between the laser chip and the 
light receiving device can be improved so that highly accurate monitoring 
of the frequency of the beams emitted from the laser chip 46 can be 
achieved even for an information transmission rate of 560 Mbits/sec. 
As illustrated, the photoelectronic device of the present embodiment has a 
construction in which the light receiving device 49 is attached to the 
outer wall of the package 45. This makes it simple to replace the light 
receiving device 49 so that a light receiving element for matching the 
information transmission rate can be easily selected and mounted, thereby 
reducing production cost. Moreover, since the outer wall of the package 45 
is used to form a part of the electromagnetic shield member 44, the 
necessity for forming the electromagnetic shield member separately and 
attaching it to the package 45 can be eliminated to further reduce the 
production cost. 
The following effects can be attained from the aforedescribed embodiments: 
(1) Since the line for driving the light emitting element and the line for 
extracting the signal are isolated by the electromagnetic shielded member, 
the photoelectronic device of the present invention is free from 
electromagnetic coupling between the two lines even for an information 
transmission rate of 560 Mbits/sec. This construction provides an effect 
that the frequency of the laser beam can be monitored by the light 
receiving element accurately and highly precisely. 
(2) Since the photoelectronic device of the present invention is 
constructed to establish no electromagnetic coupling, according to the 
above effect (1), the frequency monitoring can be conducted within either 
the shielding frequency range of the light receiving element or the 
modulatable range of the semiconductor laser to provide an effect that the 
photoelectronic device can be used for remarkably rapid optical 
communications having an information transmission rate as high as 600 
Mbits/sec to provide high capacity communications. 
(3) Since the laser chip and the light receiving element are attached to a 
single stem and are hermetically sealed by means of the cap, according to 
the above effect (2), the photoelectronic device of the present invention 
can enjoy an effect that it is highly resistant to humidity so as to have 
a high reliability. 
(4) Due to the above effects (1) to (3), according to the present 
invention, there can be attained a combination of effects which make it 
possible to provide a photoelectronic device which has high information 
transmission capacity and reliability. 
While we have shown and described several embodiments in accordance with 
the present invention, it is understood that the same is not limited 
thereto but is capable of numerous changes and modifications as known to 
those skilled in the art and we therefore do not wish to be limited to the 
details shown and described herein but intend to cover all such changes 
and modification as are encompassed by the scope of the appended claims.