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| United States Patent |
5,991,058
|
|
Feuer
, et al.
|
November 23, 1999
|
Method and apparatus for a network comprising a fourier plane photonics
package
Abstract
A photonics package, and methods for its use are disclosed. In one
configuration, a collimating lens is disposed between a photonics device
and a ferrule containing two optical fibers. Preferably, one of the fibers
delivers an optical signal to the photonics device, and the other fiber
receives an optical signal from the photonics device. The fibers within
the dual-fiber ferrule are located off of the optical axis of the lens so
that light emanating from the signal-delivering fiber will be imaged onto
the photonics device at a slight angle from the normal and may be
reflected at the same angle for coupling into the signal-receiving fiber
Preferably, the photonics device is situated at the Fourier plane to
facilitate coupling reflected light into the signal-receiving fiber. The
function of the photonics package varies with the included photonics
device. For example, the package can function as a data receiver, a data
transmitter and a data transceiver by incorporating, respectively, a
photodetector, an optical modulator, and a transceiver. The photonics
package, which can be integrated in optical communications networks,
allows for incoming and outgoing signals to be handled on separate fibers,
obviating the need for a splitter as required in one fiber systems. A
decrease in signal loss throughout the optical communications system can
thus be realized.
| Inventors:
|
Feuer; Mark D. (Colts Neck, NJ);
Ford; Joseph E. (Oakhurst, NJ)
|
| Assignee:
|
Lucent Technologies, Inc. (Murray Hill, NJ)
|
| Appl. No.:
|
178113 |
| Filed:
|
October 23, 1998 |
| Current U.S. Class: |
398/72; 385/33; 398/1; 398/49; 398/71; 398/125; 398/167.5 |
| Intern'l Class: |
H04J 014/02; H04B 010/00; H04B 010/02 |
| Field of Search: |
359/125,152,173,157,167
|
References Cited [Referenced By]
U.S. Patent Documents
| 5552918 | Sep., 1996 | Krug et al. | 359/152.
|
| 5712864 | Jan., 1998 | Goldstein et al. | 372/50.
|
| 5767997 | Jul., 1998 | Bishop et al. | 359/152.
|
| 5790287 | Aug., 1998 | Darcie et al. | 359/110.
|
Primary Examiner: Chan; Jason
Assistant Examiner: Sedighian; Mohammad
Parent Case Text
STATEMENT OF RELATED APPLICATIONS
This application is a division of application Ser. No. 08/712,530,filed
Sep. 11, 1996, now U.S. Pat. No. 5,857,048.
The present application is related to "METHODS AND ARRANGEMENTS FOR DUPLEX
FIBER HANDLING", filed Jul. 26, 1996 as Ser. No. 08/688,178, inventors
Mark D. Feuer and Joseph E. Ford; "WAFER LEVEL INTEGRATION OF AN OPTICAL
MODULATOR AND III-V PHOTODETECTOR", filed Jul. 23, 1996 as Ser. No.
08/685,294, inventors John E. Cunningham, Joseph E. Ford, Keith Wayne
Goossen and James A. Walker; and, "METHOD AND ARRANGEMENT FOR A COMBINED
MODULATOR/PHOTODETECTOR", filed Jul. 5, 1996 as Ser. No. 08/675,980,
inventors David J. Bishop, Keith Wayne Goossen and James A. Walker. Each
of the aforementioned applications is assigned to the present assignee.
Claims
We claim:
1. An optical communications network having reduced signal loss,
comprising:
a head end terminal;
a transmitter for launching optical signals, intended for at least one of a
plurality of individual subscribers, into a first optical medium;
at least one receiver for receiving an optical signal on a second optical
medium from the one subscriber; and
a plurality of optical network units, each of said optical network units
including a photonics package, the photonics package including:
a first optical fiber for receiving a first optical signal from the first
optical medium and a second optical fiber for delivering a second optical
signal to the second optical medium; and
a passively-alignable optical system comprising:
a dual fiber ferrule comprising a retaining member having a longitudinal
bore therethrough disposed along a longitudinal symmetry axis thereof, the
bore sized for receiving the first and a second optical fiber in tight
fitting contact therein, each optical fiber having an optical core and a
cladding layer, the bore having a shape that symmetrically offsets the
optical cores from the longitudinal symmetry axis;
a transceiver disposed on a device mount, wherein the transceiver receives
the first optical signal from the first optical fiber, encodes information
on to the first optical signal thereby creating the second optical signal
and delivers said second optical signal to the second optical fiber;
an imaging device disposed between the dual fiber ferrule and the
transceiver, wherein the imaging device places the first and second
optical fibers and the transceiver in optical communication; and
a sleeve for receiving the dual fiber ferrule, the imaging device and the
mounted transceiver, the sleeve having a size suitable for passively
aligning the optical fibers and the transceiver.
2. The optical communications network of claim 1 wherein the transceiver is
located in a Fourier plane.
3. The optical communications network of claim 1 further comprising a
wavelength filter.
4. The photonics package of claim 1, wherein the first and second optical
fibers are single-mode fibers.
5. The photonics package of claim 1, wherein the retaining member and the
sleeve comprise ceramic.
6. The photonics package of claim 1, wherein the transceiver comprises an
optical modulator.
7. The photonics package of claim 2, wherein the transceiver further
comprises a photodetector in optical communication with the optical
modulator.
Description
FIELD OF THE INVENTION
The present invention relates generally to packaging photonics devices.
BACKGROUND OF THE INVENTION
Network architectures for two-way optical fiber communications to the home
have been proposed. Cost targets must be achieved for such architectures
to be implemented. Wavelength-Division-Multiplexed (WDM) network
architectures, for example, have been proposed that use optical
modulators, rather than expensive wavelength-stabilized sources, at each
home. The optical modulators are powered by a shared laser source at a
central office.
Surface normal optical modulators operating in a reflection mode
("reflective modulators"), that is, modulators that operate by reflecting,
or not reflecting, an incident optical signal, may be used in such
networks. These modulators can be packaged by butt-coupling them to a
single mode fiber. In such an arrangement, the reflected data signal is
carried in the same fiber that supplied the incident optical signal. For
processing, the reflected data signal is separated from the incident
signal, such as by passing the signal carrying fiber through a 2.times.2
splitter. The splitter adds complexity to the system and can cause 6 dB of
intrinsic loss; 3 dB on each pass.
Thus, there is a need for a package for a reflective modulator that, in
conjunction with the network architecture, reduces power losses.
SUMMARY OF THE INVENTION
A photonics package, and methods for its use and fabrication, are
disclosed. In one illustrative embodiment, a lens is disposed between a
ferrule containing two optical fibers ("dual-fiber ferrule") and a
photonics device. Preferably, one of the fibers ("the input fiber")
delivers an optical signal to the photonics device, and the other fiber
("the output fiber") receives an optical signal from the photonics device.
The lens is appropriately spaced from the dual-fiber ferrule for
collimating light. The fibers within the dual-fiber ferrule are offset
from the optical axis of the lens so that light emanating from the input
fiber will be received by the modulator at a slight angle from the normal
to the modulator. The angled incidence of the optical signal upon the
photonics device results, in preferred embodiments, in the signal being
reflected toward and imaged onto the output fiber. Preferably, the
modulator is situated at the Fourier plane of the lens to facilitate
coupling reflected light into the output fiber.
A photonics package according to the present invention has a variety of
uses as a function of the specific photonics device included within the
package. Without limitation, the package can function as a data receiver,
a data transmitter and a data transceiver.
In addition, the package may be advantageously integrated in optical
communications systems. For example, in an illustrative embodiment, the
photonics package, which is incorporated into each one of a plurality of
network units, receives information transmitted from a central office to
each network unit and encodes information on an optical signal for
transmission back to the central office.
Conventional photonics packages use a single fiber for delivering a first
optical signal to a photonics device within the package, and for receiving
a second optical signal from the photonics device for transmission out of
the package. A photonics package according to the present invention,
however, allows for receiving a first signal through a first fiber, and
transmitting a second signal out of the package through a second fiber. As
such, when using a photonics package according to the present invention,
the signals do not have to be separated for processing. A splitter for
separating the signals, which is typically required in single fiber
systems, is therefore not required in optical communications systems using
the present photonics package. This results in a decrease in signal loss
throughout the communications system, and a decrease in system complexity
and cost.
BRIEF DESCRIPTION OF THE DRAWINGS
Further features of the invention will become more apparent from the
following detailed description of specific embodiments thereof when read
in conjunction with the accompanying drawings, in which like elements have
like reference numerals and in which:
FIG. 1 is a first illustrative embodiment of a photonics package 1a
according to the present invention;
FIG. 2A shows an exemplary dual-fiber ferrule;
FIG. 2B illustrates the path of an optical signal through the photonics
package of FIG. 1;
FIG. 3 is a second illustrative embodiment of a photonics package 1b
according to the present invention;
FIG. 4 is a cross-sectional side view of an exemplary embodiment of a
micromechanical optical modulator suitable for use in conjunction with the
present invention;
FIG. 5 is a top-view of the modulator of FIG. 4;
FIG. 6 is an exemplary embodiment of a combined optical
modulator/photodetector for use in conjunction with the present invention;
FIG. 7 is an exemplary embodiment of a wafer-level-integrated optical
modulator/photodetector for use in conjunction with the present invention;
FIGS. 8a-8c show three exemplary embodiments of using a filter for
wavelength selection in conjunction with the present invention; and
FIG. 9 illustrates an embodiment of an optical communications system using
a photonics package according to the present invention.
DETAILED DESCRIPTION
FIG. 1 shows a first illustrative embodiment of a photonics package 1a
according to the present invention. In the illustrative embodiment, the
photonics package 1a includes a rigid, impact resistant sleeve 3 formed
from a precisely shapeable material. In a preferred embodiment, the sleeve
3 is ceramic. The sleeve can have any convenient shape, e.g., cylindrical,
rectangular, and so forth. In an alternate embodiment, the sleeve 3 can be
configured similarly to sleeves used for rotary slices, which typically
include a beryllium copper sleeve shaped as a triangular prism with three
glass rods in the creases as guide pins. The sleeve 3 receives, at a first
end 4, a first optical fiber 7 and a second optical fiber 9. As shown in
detail in a later Figure, the optical fiber 7 can be used to deliver an
optical signal 25 to the package 1a, and more specifically to a photonics
device 15, while the fiber 9 can be used for receiving an optical signal
26 from the photonics device 15.
It will be appreciated that the optical fibers 7 and 9 must be retained in
a specific location with respect to other optical components within the
system, as described in more detail below. According to an illustrative
embodiment of the present invention, such positioning is achieved by a
dual-fiber ferrule 5.
As shown in FIG. 2a, the dual-fiber ferrule 5 consists of a bore 82 located
along the longitudinal symmetry axis C--C of a retaining member 80. The
retaining member 80 is made from a rigid, stable material capable of being
precisely formed into a desired shape. Preferably, the retaining member 80
is a ceramic. Optical fibers 7 and 9, with plastic coating layers removed,
i.e., the fibers 7 and 9 as received comprise only a fiber core 7a, 9a and
a cladding layer 7b, 9b, are received by the bore 82.
In the dual-fiber ferrule 5 shown in FIG. 2A, the bore 82 is shown to be
ellipsoidal in cross section. Such a shape provides a single defined
rotational orientation of the fiber cores. In the exemplary photonics
package 1a, such definition is not required, so that the bore 82 can be
round, as well. The size of the bore 82 is large enough to accept the two
fibers in a tight fit.
Further embodiments and description of a dual-fiber ferrule suitable for
use in conjunction with the present invention is described in "METHODS AND
ARRANGEMENTS FOR DUPLEX FIBER HANDLING", filed Jul. 26, 1996 as Ser. No.
08/688,178, assigned to the present assignee. That patent application, and
any other patents, patent applications or publications mentioned in this
specification are incorporated by reference herein.
The sleeve 3 receives, at a second end 6, the photonics device 15, which is
preferably disposed on a device mount 13. The device mount 13 can be an
electrical header, for example, which provides electrical connection
between the photonics device 15 and processing electronics, not shown,
located outside the package 1a. Electrical connection is provided by
electrical contacts 19. In the case of an electrical header, the contacts
19 are typically pins.
It will be appreciated that the optical signal 25 from the optical fiber 7
cannot be directed along a path normal to the photonics device 15. In such
a case, the reflected signal 26 would be returned to the fiber 7. The
optical signal 25 can, however, be directed to the photonics device 15 at
an appropriate angle so that the reflected optical signal 26 is imaged
into the fiber 9. Thus, disposed within the sleeve 3 between the optical
fibers 7 and 9 and the photonics device 15 is an imaging device. In the
illustrative photonics package 1a, the imaging device is a single lens
11a. The lens 11a is used for imaging the optical fiber 7 into the fiber
9. Suitable lenses 11a include, without limitation, gradient index (GRIN)
lenses, ball lenses and molded lenses, such as, for example, injection
molded lenses.
As shown in FIG. 2B, the lens 11a is positioned a distance, d, from the
optical fibers 7 and 9, equal to the focal length of the lens 11a. When so
positioned, the lens 11a will collimate the optical signal 25. The fibers
cores 7a and 9a are equidistant from the optical axis A--A of the lens
11a. The photonics device 15 is located at the Fourier plane B--B. As will
be appreciated by those skilled in the art, the Fourier plane is
essentially the back focal plane of a lens. A collimated beam entering a
lens would be focused to a point on a surface located at the Fourier
plane. See Goodman, Introduction to Physical Optics, Chapter 5, "Fourier
Transforming and Imaging Properties of Lenses," (McGraw-Hill, 1968) for a
mathematical definition.
It is particularly advantageous to place a reflective photonics device 15
in the Fourier plane; doing so creates a telecentric optical system upon
two passes through the lens. A telecentric system is defined as one in
which the entrance pupil and/or the exit pupil is located at infinity. See
Smith, Modern Optical Engineering, Chapter 6, Section 6, (McGraw-Hill,
1990). In the context of a fiber optic system, telecentricity means that
the optical beam incident on the output fiber will match the optimum
incidence angle, resulting in optimized coupling. Thus, the reflected
optical signal 26 will be imaged, via the lens 11a, into the optical fiber
9 with high efficiency.
Preferably, the device for retaining the optical fibers 7 and 9, such as
the dual-fiber ferrule 5, the photonics mount 13 and the sleeve 3 are
formed so that they provide passive alignment for the optical fibers 7, 9
and the photonics device 15. That is, the aforementioned components are
designed such that when the photonics package 1a is assembled, the optical
signal 25 from the optical fiber 7 will be optically aligned with the
optical fiber 9.
In other embodiments, a photonics package according to the present
invention can be actively aligned, such as by tilting the modulator or
moving the lens 11a and the photonics device 15 with respect to the
optical fibers 7, 9. In such embodiments, the various components are held
in fixtures so they can be moved as described above. Once the components
are optically aligned, they can be retained in position by various optical
packages known to those skilled in the art. It will be appreciated that
the sleeve 3 of the photonics package 1a is not used in such embodiments.
There are relatively stringent tolerances on lens centration and fiber
positioning. These tolerances are achievable due to the symmetry of the
dual-fiber ferrule 5 and GRIN or ball lens fabrication. Grin lens polish
angle tolerance, which is expected to be much less than 1 degree, may not
be achievable using standard techniques, such as setting a batch of lenses
in wax and group polishing the lenses. Achieving such tolerances may
require using a polishing jig with holes drilled to accept a GRIN lens and
for holding the lens perpendicular to the optic axis. Using a spherical
ball lens guarantees lens centration and eliminates the concern with the
polish angle of the GRIN lens. Device positioning and tilt tolerances are
achievable using a conventional header mounting technique with a
sufficiently large device die size. The gap tolerances between the
dual-fiber ferrule 5 and the lens 11a, and the photonics device 15 and the
lens 11a are on the order of several microns (.mu.m) and are readily
achievable.
A second illustrative embodiment of a photonics package 1b according to the
present invention is shown in FIG. 3. In the package 1b, the imaging
device consists of two microlenses 12a and 12b. The microlenses 12a and
12b are separated from the ends of the optical fibers 7 and 9 by a small
gap. It is within the capabilities of those skilled in the art to
fabricated the microlenses 12a and 12b. For example, the microlenses can
be fabricated by depositing a refractive layer on a clear substrate and
forming appropriately spaced spherical surfaces in the refractive layer
using, for example, photolithographic techniques. See, for example, D. R.
Purdy, "Fabrication of Complex Micro-Optic Components using Halftone
Transmission Masks to Photosculpt Positive Resist," EOS Top. Mtg. Dig. S.,
Vol. 2, (1993). The substrate can then be diced and placed in close
proximity to the fiber ends. Precise alignment of each microlens 12a and
12b to the fibers is required. In preferred embodiments, aspheric
correction is used to reduce signal loss from microlens aberrations. Such
corrections are within the capabilities of those skilled in the art, and
may be accomplished by using a diffractive microlens. Chromatic
aberrations, especially in diffractive microlenses, may restrict the
usable wavelength bandwidth.
Photonics packages according to the present invention, such as the
illustrative packages 1a and 1b, have a variety of applications, depending
upon the particular photonics device 15 included within the package. In
one embodiment, the present photonics package functions as a data
transmitter. In preferred embodiments of the photonics package as a data
transmitter, the photonics device 15 is an optical modulator 15a. Either
semiconductor optical modulators, such as multiple quantum well
modulators, or micromechanical modulators may suitably be used. An
exemplary multiple quantum well modulator is described in Cunningham et
al., "Reflectivity from Multiple Quantum Well Modulators with Contrast
Ratio of 22:1 at 1.55 .mu.m," Conference on Lasers and Electro-Optics 9,
1996, OSA Tech. Digest Series, p. 487. An exemplary embodiment of a
micromechanical modulator 15a suitable for use in conjunction with the
present invention is shown in FIGS. 4 and 5.
As shown in FIG. 4, which is a cross-sectional view through line DD in FIG.
5, the modulator 15a comprises a substrate 10 and a membrane 14 having one
or more layers, such as the layers 14a and an optional layer 14b. The
membrane 14 and the substrate 10 are spaced from each other defining a gap
20. As shown in FIG. 5, which is a plan view of the modulator 15a, the
membrane 14 is suspended over the substrate 10 by support arms 24. The
supports arms 24 are in turn supported by a nonconductive support layer
16. In other embodiments, discrete support arms 24 are not present.
Rather, the membrane 14 itself overlaps the nonconductive support layer
16.
If the membrane 14 is not electrically conductive, a layer 28 of conductive
material, such as, without limitation, gold or other conductive metals or
alloys thereof, can be disposed on the membrane layer 14a. If the layer 28
is not transparent at the operating wavelength of the modulator 15a, then
an optical window 27 must be defined with the layer 28.
The membrane 14 and the substrate 10, which are electrically isolated from
one another, are electrically connected to a controlled voltage source 29.
Applying a voltage across the membrane 14 and substrate 10 generates an
electrostatic force that moves the membrane toward the substrate. As the
membrane 14 moves, the size of the gap 20 changes, and so does the
reflectivity of the modulator 15a. The change in reflectivity of the
modulator 15a alters the measured amplitude of an optical signal reflected
from the modulator. The changing reflectivity of the modulator 15a may
thus be used to modulate an optical signal.
In the modulator 15a, a large change in reflectivity can be obtained if the
following two conditions are met. First, the layer 14a has a thickness
that is one-quarter of a wavelength, .gamma., of the optical signal being
processed ("the operating wavelength"), as measured in the layer. And
second, the layer 14a has a refractive index, n.sub.m, that is about equal
to the square root of the refractive index, n.sub.s, of the substrate 10.
Given those parameters, the modulator 15a will be highly reflective when
the position of the membrane 14 is such that the gap 20 is an odd integer
multiple of one-quarter of the operating wavelength, that is, m.gamma./4
where m is odd. Conversely, the modulator 15a will exhibit minimal
reflectivity, i.e., be transmissive, when the gap 20 is zero or an even
integer multiple of one-quarter of the operating wavelength, that is,
m.gamma./4 where m is even or zero.
For maximum modulator contrast, the modulator 15a is fabricated, i.e., the
gap 20 is sized, so that in the absence of an applied voltage, the
modulator will exhibit its minimum or maximum reflectivity. As described
above, this occurs when the gap 20 is an integer multiple of .gamma./4.
When biased, the membrane 14 preferably moves a distance of .gamma./4, so
that the gap 20 is still at some multiple of .gamma./4. As such, the
modulator exhibits either maximum or minimum reflectivity in its biased
mode, as well.
Thus, in embodiments in which the photonics device 15 is the modulator 15a,
the modulator receives the optical signal 25 from the optical fiber 7 and
returns a reflected optical signal 26, or not, to the optical fiber 9,
depending upon the state of the modulator.
Further non-limiting descriptions of an optical modulator 15a suitable for
use in conjunction with the present invention, including methods for
making it and other embodiments thereof, are provided in U.S. Pat. No.
5,500,761, and co-pending U.S. patent applications Ser. No. 08/283,106
filed Jul. 29, 1994, Ser. No. 08/578,590 filed Jun. 7, 1995, Ser. No.
08/479,476 filed Jun. 7, 1995, Ser. No. 08/578,123 filed Dec. 26, 1995,
Ser. No. 08/565,453 and Ser. No. 08/597,003.
In another embodiment, a photonics package according to the present
invention can function as a receiver. In preferred embodiments of the
photonics package as a receiver, the photonics device 15 is a
photodetector. Suitable photodetectors for use in conjunction with the
present invention include, without limitation, photoconductors,
photodiodes, avalanche photodiodes, phototransistors, heterojunction
photodiodes, P-I-N multiple quantum well detectors and metal-insulator
III-V photodiodes. The operation and fabrication of such photodetectors
are known to those skilled in the art.
In embodiments wherein the photonics package is functioning only as a
receiver, the output fiber, i.e., the fiber 9, might not receive an
optical signal.
In an additional embodiment, a photonics package according to the present
invention can function as a data transceiver, including both a receiving
and a transmitting element. In such an embodiment, the photonics device 15
is preferably a combined optical modulator/photodetector 15c or a
wafer-level-integrated optical modulator/photodetector 15d. In such a
photonics package, the optical fiber 7 delivers the optical signal 25 to
the combined optical modulator/photodetector 15c or the
wafer-level-integrated optical modulator/photodetector 15d, and such
devices send a return signal, such as the optical signal 26, to the
optical fiber 9. An exemplary combined optical modulator/photodetector 15c
is illustrated in FIG. 6.
The exemplary combined optical modulator/photodetector 15c consists of a
modulator chip 30a attached to a photodetector chip 40a. The modulator
chip 30a includes a substrate 34a having a first surface 33a and a second
surface 35a. Preferably, the substrate 34a is silicon, but, as will be
appreciated by those skilled in the art, other semiconductors transparent
at the operating wavelengths may suitably be used. An optical modulator
32a, is located along the first surface 33a of the substrate 34a. Contacts
or wire bond pads 36a and 37a are in electrical contact with a controlled
voltage source, not shown, and are also in electrical contact,
respectively, with a feature of the modulator 32a and the substrate 34a.
The optical modulator 32a can suitably be embodied as the modulator 15a
described above.
The photodetector chip 40a includes a III-V substrate 44a having a first
surface 43a. The III-V substrate 44a is preferably indium phosphide (InP)
for optical communications applications, but may suitably be other III-V
semiconductors, such as gallium arsenide (GaAs) in other embodiments. A
photodetector 42a is located along the first surface 43a of the III-V
substrate. The photodetector 42a can suitably be embodied as the
photodetector 15b described above. The photodetector chip 40a can be
electrically connected to equipment, not shown, for processing and
receiving the electrical signal generated by the photodetector, through
contacts or wire bond pads 46a and 47a.
In operation, the combined optical modulator/photodetector 15c receives a
downstream information-carrying optical signal, such as the optical signal
25 from the fiber 7. During a first time period, the modulator 32a is
placed in at least partially transmissive mode so that a first portion of
the signal 25 is absorbed by the photodetector 42a. During a second time
period, the optical modulator 32a encodes upstream information upon the
signal 25 creating the optical signal 26 which is received by the fiber 9.
Such information encoding is accomplished by a controlled variation of the
reflectivity of the modulator 32a.
Further description of a combined optical modulator/photodetector 15c
suitable for use in conjunction with the present invention, including
methods for making it and other embodiments thereof, are provided in
"METHOD AND ARRANGEMENT FOR A COMBINED MODULATOR PHOTODETECTOR," filed on
Jul. 5, 1996 as Ser. No. 08/675,980.
An exemplary wafer-level integrated (WLI) optical modulator/photodetector
15d is shown in FIG. 7. The WLI modulator/photodetector 15d includes a
modulation region 32b and a photodetection region 42b that are formed on
opposed surfaces 38 and 39, respectively, of an off-axis silicon substrate
or wafer 40. The modulation region 32b can suitably be embodied as the
modulator 15a described above. A first and second wire from a controlled
voltage source, not shown, are bonded to bond pads or contacts 36b and 37b
to place the controlled voltage source in electrical connection with the
modulator region.
In a preferred embodiment, the photodetection region 42b is disposed on a
buffer layer 44 situated on the surface 39 of the wafer 40, rather than
directly on the surface 39. The buffer layer 44 provides a
lattice-mismatch relaxation region between the first III-V layer,
typically InP in communications applications, and the off axis substrate
40. The detection region 42b can suitably be embodied as the photodetector
15b mentioned above. A surface contact 46b on the photodetection region
42b provides electrical contact to the top layer of the photodetection
region, which, is typically either a n- or a p-doped layer. The other
contact can be provided by the substrate 40.
The WLI optical modulator/photodetector 15d operates in substantially the
same manner as the combined optical modulator/photodetector 15c.
Further description of a WLI optical modulator/photodetector 15d suitable
for use in conjunction with the present invention, including methods for
making it and other embodiments thereof, are provided in
"WAFER-LEVEL-INTEGRATION OF AN OPTICAL MODULATOR AND Ill-V PHOTODETECTOR,"
filed on Jul. 23, 1996 as Ser. No. 08/685,294.
In a further embodiment of a photonics package according to the present
invention, the photonics package also includes a filter 17 for wavelength
selection or wavelength drop. When placed between the lens 11a and the
photonics device 15 of the photonics package 1a, the filter 17 will allow
only light of a predetermined wavelength to reach the photonics device. As
is known to those skilled in the art, such as a filter can be embodied as
a planar reflective surface or dielectric mirror comprising a plurality of
dielectric layers selected to reflect spectral components having other
than a predetermined wavelength.
The filter 17 can be located in several positions within a photonics
package according to the present invention. In one embodiment, the filter
17 can be disposed on the imaging device 11 provided that the surface on
which the filter 17 is disposed is flat. As such, the filter 17 can be
suitably disposed on a GRIN lens. The filter is preferably located on the
end of GRIN lens closest to the photonics device 15, as shown in FIG. 8a.
In a second, presently preferred embodiment, the filter 17 is located near
the Fourier plane B--B, which can be accomplished by disposing the filter
on a thin transparent media positioned near the Fourier plane, as shown in
FIG. 8b.
In an additional embodiment, illustrated in FIG. 8c, the filter 17 can be
located on the photonics device 15. It will be appreciated that if the
photonics device 15 is a micromechanical device, such as the optical
modulator 15a, it is preferable not to locate the filter 17 on the
photonics device 15. Among other reasons, the additional mass of the
filter 17 would decrease modulator operating speed.
It is preferable to use the filter 17 in conjunction with the photonics
package 1a, rather than the package 1b having dual microlenses 12a, 12b.
If used in conjunction with the package 1b, the filter 17 should be
disposed as close as possible to the image plane, i.e., the photonics
device 15. If the photonics device 15 is a semiconductor device, the
microlenses should be disposed on it.
In an additional embodiment, the photonics device 15 can be a modulator for
modulating the optical phase or polarization of the optical signal, with
or without modulating its amplitude. As is known in the art, phase
modulation can be used to encode information onto the optical signal or to
suppress undesirable effects such as stimulated Brillouin scattering that
may occur in transmission media such as optical fiber. Since phase
modulation can be achieved by varying optical path length, the
previously-described micromechanical modulator 15a can function as a
reflective phase modulator, such as by coating the moving membrane with a
metal or another reflective material.
Photonics packages according to the present invention can be advantageously
used in optical communications systems, such as the passive optical
network (PON) 60 shown in FIG. 9. See U.S. pat. application Ser. No.
08/333,926, by T. E. Darcie, N. J. Frigo and P. D. Magill, assigned to the
present assignee.
The exemplary PON 60 includes a central office or head end terminal 62 that
has an active optical source 64, such as a multi-frequency laser or light
emitting diode (LED). The central office 62 sends information via an
optical signal 66, in wavelength-division-multiplexed (WDM) format, to a
plurality of optical network units (ONU) 72. Each ONU 72 receives such
information on a prescribed wavelength, .gamma..sub.n. A wavelength
routing device 70 demultiplexes or resolves the optical signal 66 into its
spectral components 66 .sup.1-N, and routes each of such spectral
components to the appropriate ONU 72, wherein the spectral component
having a wavelength matching the prescribed wavelength of the ONU is
routed to that ONU.
Each ONU 72 includes a photonics package 76, such as the illustrative
packages 1a or 1b described above. In a preferred embodiment, the package
1a or 1b includes the combined optical modulator/photodetector 15c or WLI
optical modulator/photodetector 15d.
Thus, the appropriate spectral component 66.sup.i of the optical signal 66
is received by the photonics package 76 in an ONU 72. Typically,
information is sent in "packets" via the optical signal 66. Each packet
contains a portion of downstream information for processing, as well as a
portion of continuous-wave (CW) light or "optical chalkboard" upon which
upstream information can be encoded.
As described above, the modulator portion of the device 15c or 15d is
placed in at least partially transmissive mode so that a portion of the
energy of the spectral component 66.sup.i is received by the photodetector
portion of the device 15c or 15d. Thus, the optical energy reaching the
photodetector portion is converted to an electrical signal, representative
of the downstream information, and routed to processing electronics.
During a second time period, the optical modulator portion encodes
upstream information on the optical chalkboard portion of the packet, and
returns upstream-information-carrying spectral component 67.sup.i, which
is received by the fiber 9.
The plurality of upstream-information-carrying spectral components
67.sup.1-N returned from the ONUs 72 are multiplexed by the wavelength
routing device 70 into a signal 67, which is routed to a receiver 68 in
the central office 62.
Although a number of specific embodiments of this invention have been shown
and described herein, it is to be understood that such embodiments are
merely illustrative of the many possible specific arrangements that can be
devised in application of the principles of this invention. Numerous and
varied other arrangements can be devised in accordance with these
principles by those of ordinary skill in the art without departing from
the scope and the spirit of the invention.
* * * * *
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