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| United States Patent |
6,381,045
|
|
DiGiovanni
, et al.
|
April 30, 2002
|
Method and apparatus for bidirectional communication over a single optical
fiber
Abstract
Dual concentric core fiber is used for optical communication. Inbound
messages lying in a first wavelength channel are received from a terminal
portion of the fiber, and outbound messages lying in a second such channel
are injected into the terminal portion. The optical fiber has at least one
annular portion surrounding a central core portion. The inbound messages
are received from the annular portion, and the outbound messages are
injected into the central core portion. Alternatively, the inbound
messages are received from the central core portion, and the outbound
messages are injected into the annular portion.
| Inventors:
|
DiGiovanni; David John (Montclair, NJ);
Eichenbaum; Bernard Raymond (Basking Ridge, NJ);
Khan; Mujibun Nisa (Holmdel, NJ)
|
| Assignee:
|
Lucent Technologies Inc. (Murray Hill, NJ)
|
| Appl. No.:
|
103925 |
| Filed:
|
June 24, 1998 |
| Current U.S. Class: |
398/42; 385/127 |
| Intern'l Class: |
H04J 014/02; H04B 010/12; H04B 010/13; H04B 010/135 |
| Field of Search: |
359/173,114,116,153,152
385/123,127
|
References Cited [Referenced By]
U.S. Patent Documents
| 4134642 | Jan., 1979 | Karpon et al. | 350/96.
|
| 4232938 | Nov., 1980 | Dabby et al. | 350/96.
|
| 4279465 | Jul., 1981 | Vojvodich | 350/96.
|
| 4314740 | Feb., 1982 | Bickel | 350/96.
|
| 4650281 | Mar., 1987 | Jaeger et al. | 350/96.
|
| 4806289 | Feb., 1989 | Laursen et al. | 264/1.
|
| 4986629 | Jan., 1991 | Auge et al. | 350/96.
|
| 5283447 | Feb., 1994 | Olbright et al. | 257/85.
|
| 5418870 | May., 1995 | Kech et al. | 385/31.
|
| 5430817 | Jul., 1995 | Vengsarkar | 385/37.
|
| 5491712 | Feb., 1996 | Lin et al. | 372/50.
|
| 5604587 | Feb., 1997 | Che et al. | 356/246.
|
| 5659644 | Aug., 1997 | DiGiovanni et al. | 385/31.
|
| 5881196 | Mar., 1999 | Phillips | 385/127.
|
| 5920582 | Jul., 1999 | Byron | 372/6.
|
| 5963349 | Oct., 1999 | Norte | 359/116.
|
Other References
K.D. Choquette et al., "Detector-enclosed Vertical Cavity Surface Emitting
Lasers," Electronic Letters (29) 5, p. 466, (1993).
|
Primary Examiner: Pascal; Leslie
Claims
The invention claimed is:
1. A method for optical communication, comprising:
receiving inbound messages from a terminal portion of an optical fiber,
wherein said messages are received in the form of a modulated inbound
optical signal lying in a first wavelength channel; and
injecting outbound messages into the terminal portion of the optical fiber,
wherein said messages are injected in the form of a modulated outbound
optical signal lying in a second wavelength channel,
CHARACTERIZED IN THAT:
the receiving step comprises substantially receiving the inbound signal
from an annular portion of the optical fiber, said annular portion
surrounding a central core portion of said fiber; and
the injecting step comprises substantially injecting the outbound signal
into the central core portion of the fiber.
2. A method for optical communication, comprising:
receiving inbound messages from a terminal portion of an optical fiber,
wherein said messages are received in the form of a modulated inbound
optical signal lying in a first wavelength channel; and
injecting outbound messages into the terminal portion of the optical fiber,
wherein said messages are injected in the form of a modulated outbound
optical signal lying in a second wavelength channel,
CHARACTERIZED IN THAT:
the receiving step comprises substantially receiving the inbound signal
from a central core portion of the fiber, and
the injecting step comprises substantially injecting the outbound signal
into an annular portion of the optical fiber, said annular portion
surrounding said central core portion.
3. The method of claim 1 or claim 2, wherein the first and second
wavelength channels occupy separate and distinct portions of the
electromagnetic spectrum.
4. A method for optical communication, comprising:
receiving inbound messages from a terminal portion of an optical fiber,
wherein said messages are received in the form of a modulated inbound
optical signal lying in a first wavelength channel; and
injecting outbound messages into the terminal portion of the optical fiber,
wherein said messages are injected in the form of a modulated outbound
optical signal lying in a second wavelength channel spectrally separate
and distinct from the first wavelength channel,
CHARACTERIZED IN THAT:
the receiving step comprises substantially receiving the inbound signal
from a central core portion of the fiber, and
the injecting step comprises injecting at least a portion of the outbound
signal into said central core portion, and substantially out-coupling said
portion from a mode guided by the core portion into a mode guided by the
core portion in combination with an adjacent, surrounding, annular portion
of the optical fiber.
5. The method of claim 1, claim 2, or claim 4, wherein the injecting step
is carried out by operating an electro-optical emissive device juxtaposed
to an end of the fiber.
6. The method of claim 1, claim 2, or claim 4, wherein the receiving step
is carried out by operating an electro-optical receiver juxtaposed to an
end of the fiber.
7. The method of claim 1, claim 2, or claim 4, wherein the injecting and
receiving steps are carried out by operating, respectively, an
electro-optical emissive device and an electro-optical receiver, both
juxtaposed to an end of the fiber.
8. A method for operating an optical communication network that comprises
at least one optical fiber having a central core portion and an annular
portion surrounding said central core portion, the method comprising
transmitting signals in mutually opposing first and second directions
through said fiber, CHARACTERIZED IN THAT:
signals transmitted in the first direction are guided by the central core
portion; and
signals transmitted in the second direction are guided by the central core
portion in combination with an adjacent region of the annular portion.
9. Apparatus comprising an optical fiber having first and second ends, a
first source and a first detector optically coupled to the first end, and
a second source and a second detector optically coupled to the second end,
CHARACTERIZED IN THAT:
the optical fiber has a single-mode core;
the single-mode core is surrounded by a radially non-uniform cladding;
the single-mode core is adapted for guiding radiation in at least a first
wavelength channel;
an annular portion of the cladding adjacent the single-mode core is adapted
such that said annular portion and said single-mode core, in combination,
comprise a multi-mode core for guiding radiation in at least a second
wavelength channel;
the first source is optically coupled to the single-mode core at least with
respect to radiation in the first channel; and
the second source is optically coupled to the multi-mode core at least with
respect to radiation in the second channel.
10. Apparatus of claim 9, wherein the first source and first detector are
included in a concentric, integrated source-detector pair optically
coupled to an end of the optical fiber.
11. Apparatus of claim 10, wherein the first source occupies a central
portion of the source-detector pair, and the first detector occupies an
annular portion of the source-detector pair.
12. Apparatus of claim 9, wherein the second source and second detector are
included in a concentric, integrated source-detector pair optically
coupled to an end of the optical fiber.
13. Apparatus of claim 12, wherein the second source occupies an annular
portion of the source-detector pair, and the second detector occupies a
central portion of the source-detector pair.
14. Apparatus of claim 9, wherein:
the second source is optically coupled to the optical fiber such that
radiative emissions from said source are initially at least partially
coupled into the single-mode core; and
the optical fiber further comprises a grating effective for out-coupling
radiation of the second channel from the single-mode core to a mode or
modes guided by the multi-mode core.
Description
FIELD OF THE INVENTION
This invention relates to optical communication systems in which
electro-optical emitters and detectors are coupled to the ends of optical
fibers for sending and receiving signals along the fibers. More
specifically, this invention relates to those communication systems in
which individual fibers carry signals bidirectionally.
BACKGROUND OF THE INVENTION
Because optical fibers can transmit information at much greater rates than
copper wire, there is much interest in schemes for delivering
telecommunication services to customer premises, such as residential
homes, over optical fiber. These schemes fall into two general classes,
depending on whether each terminal location receives transmissions from
the central office over its own dedicated line, or whether multiplexing is
used to reduce the number of fibers that fan out from the central office.
The first scheme is said to have Point-to-Point (PTP) Architecture. When
passive optical components are used at intermediate locations to
demultiplex downstream signals (and, in some cases, to multiplex upstream
signals), the second scheme is said to have Passive Optical Network (PON)
architecture.
One problem encountered by designers of PTP networks is fiber congestion at
the central office or active remote node (ARN), where downstream signals
are placed on optical fibers. There is a need for line cards with
high-density electro-optical interfaces, to alleviate this congestion.
One problem encountered by designers of both PON and PTP networks is the
need for expensive equipment at the fiber terminations. That is,
bidirectional coupling of signals into and out of the end of an optical
fiber typically calls for optical splitters and couplers that are bulky
and expensive to manufacture. In PON networks in particular, this is a
problem for fiber installations within the customer premises. Typically, a
fiber extends from the on-premises optical network unit (ONU) to a network
PON fiber termination defining the physical interface between the network
and the customer premises. There is a strong economic incentive to reduce
the cost of the interfaces at the ends of this fiber.
SUMMARY OF THE INVENTION
We have discovered that these, and other, problems of bidirectional
communication in optical networks can be alleviated by using dual
concentric core fiber (DCCF) to carry optical signals bidirectionally. In
one broad aspect, our invention involves a method for communicating
messages, in the form of modulated optical signals, over an optical fiber.
Inbound messages lying in a first wavelength channel are received from a
terminal portion of the fiber, and outbound messages lying in a second
such channel are injected into the terminal portion. The optical fiber has
at least one annular portion surrounding a central core portion. The
inbound messages are received from the annular portion, and the outbound
messages are injected into the central core portion. In alternate
embodiments of the invention, the inbound messages are received from the
central core portion, and the outbound messages are injected into the
annular portion.
As used herein, the directions indicated by the terms "inbound" and
"outbound" are relative to the terminal device under discussion,
irrespective of whether the signals so described are directed toward or
away from the central office. Those directions are indicated,
respectively, by the terms "upstream" and "downstream".
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a schematic diagram of an illustrative dual concentric core fiber
(DCCF).
FIG. 2 is a schematic illustration of a DCCF in use for bidirectional
communication in accordance with the invention.
FIG. 3 is a schematic illustration of a DCCF in use within a residence or
other customer premises for coupling an ONU to an outside plant (OSP)
fiber.
FIG. 4A is a schematic drawing of an exemplary DCCF having a polymeric
outer cladding.
FIG. 4B is a schematic drawing of an exemplary DCCF having an outer
cladding of depressed-index glass.
DETAILED DESCRIPTION
FIG. 1 shows a typical DCCF useful for the practice of the invention. As
shown in the figure, DCCF 10 includes central, single-mode core 15,
annular, single-mode cladding 20, and annular, multimode cladding 25.
Although the refractive index may be constant within each of these three
portions, the DCCF is more generally described in terms of respective,
radially dependent refractive index profiles n.sub.1 (r), n.sub.2
(r),n.sub.3 (r) for core 15, cladding 20, and cladding 25, respectively.
The effective refractive index is greatest for core 15, and least for
cladding 25. The diameter of core 15 and the effective refractive index of
cladding 20 relative to that of core 15 are advantageously chosen in such
a way that only the fundamental mode TEM.sub.00 is guided within core 15.
On the other hand, core 15 and cladding 20, in combination, behave as a
core for guiding multiple modes. The number of modes guided within this
combination, serving as a multimode core, is determined by the outer
diameter of cladding 20 and the effective refractive index of this
combination, relative to that of cladding 25.
It should be noted in this regard that unlike single-mode propagation,
multimode propagation is subject to modal dispersion. As a consequence, a
multimode fiber generally has less transmission bandwidth than a
comparable single-mode fiber. However, we believe that DCCFs are readily
provided having a transmission bandwidth of 50 MHz-km or more. A
transmission bandwidth of 50 MHz-km is enough to be useful for downstream
transmissions over the distances encountered within residences and other
customer premises, since these typically call for data rates of 155 Mb/s
or less, over distances of 300 m or less. The same transmission bandwidth
is also enough to be useful for upstream transmissions, not only within a
residence, but also over the distances encountered within a distribution
area of the access plant, which typically calls for data rates of 50 Mb/s
or less over distances of a few kilometers or less.
One advantage of a DCCF is that it can be directly coupled to an
electro-optical source and detector without the need for passive splitting
and coupling elements. Advantageously, the source and detector are
integrated in a single, compact device with a spacing close enough for
both to be butted against the DCCF such that one is coupled to the
single-mode core, and the other is coupled to the multimode core.
Even more advantageously, the source and detector are integrated in a
concentric configuration in which the source occupies an annular region
about the detector, or the detector occupies an annular region about the
source. In such a device, it is desirable for the cross section of the
central device to match that of the single-mode core, and for the cross
section of the annular device to match that of the outer portion of the
multimode core (i.e., of the single-mode cladding).
Such an arrangement is shown in FIG. 2. As shown in the figure,
electro-optical device 30 at user terminal 35 includes annular,
face-emitting source 40 and central detector 45. As shown in expanded view
50 of the near end of DCCF 55, detector 45 butts against and aligns with
core 15, and source 40 butts against and aligns with cladding 20. (In all
of the figures, like reference numerals denote like elements.) At upstream
terminal 60, as shown in expanded view 65 of the near fiber end, central
source 70 butts against and aligns with core 15, and annular detector 75
butts against and aligns with cladding 20.
For even greater compactness, it is advantageous to fabricate the
concentric source-detector pairs in arrays, and to couple such arrays, in
unitary fashion, to multifiber cables such as ribbon cables.
We believe that concentric source-detector pairs useful for operation as
described above are readily made using conventional fabrication techniques
for light-emitting diodes (LEDs) and surface detectors. An example of
fabrication technology of this kind is provided by U.S. Pat. No.
5,283,447, issued on Feb. 1, 1994 to G. R. Olbright et al. under the title
"Integration of Transistors with Vertical Cavity Surface Emitting Lasers".
Described there are monolithically integrated optoelectronic circuits
including a vertical-cavity surface-emitting laser and a transistor, such
as a phototransistor.
It should be noted in this regard that capacitance in monolithically
integrated devices of this kind may in some cases be high enough to
preclude applications for high-speed data transmission. Alternate devices
are readily provided for use in such applications. For example, U.S. Pat.
No. 4,314,740, issued on Feb. 9, 1982 to G. W. Bickel under the title
"Optical Fiber Beam Splitter Coupler" describes a passive beam splitting
device that is readily interposed between the FTTH and one member of the
source/detector pair, while juxtaposed to the other member of the
source-detector pair. In particular, an array of such devices will be
useful for providing, in a very compact fashion, passive coupling between
an array of sources and detectors, and an FTTH fiber array.
Another passive coupling device, useful in this regard, is described in
U.S. patent application Ser. No. 08/897,195, filed on Jul. 21, 1997 by D.
J. DiGiovanni et al., and commonly assigned herewith. As described there,
a coupler is made from a bundle of multimode fibers packed around a
central fiber having a single-mode core. Coupling is effectuated by
heating and tapering the bundle, and fusion splicing it to a single-mode
main fiber (which, in the example given in the cited patent application,
is a cladding-pumped laser). Light in one wavelength region can be coupled
between the respective single-mode cores of the bundle and the main fiber.
Optoelectronic sources or emitters (according to the example described in
the cited patent application, they are semiconductor broad stripe
emitters) are coupled to the distal ends of the individual multimode
fibers, and through those fibers, to the cladding of the main fiber.
An exemplary application of the DCCF for a PTP network is conveniently
discussed with further reference to FIG. 2. In this application, terminal
60 is the central office or an active remote node (ARN). From there, the
downstream transmission signal is launched into core 15 and propagated as
a single-mode transmission to an ONU at the customer premises, which
includes source 40 and detector 45. At the ONU, source 40 launches the
upstream signal into the multimode core (i.e., core 15 and cladding 20 in
combination) for multimode transmission to terminal 60.
FIG. 3 shows an exemplary application of DCCF 55 within customer premises.
Downstream end 80 of the DCCF (shown in expanded view) is coupled to ONU
85, which includes a concentric source-detector pair or the like. Upstream
end 90 (also shown in expanded view) is coupled to network fiber
termination 95. Fiber termination 95 is the connector to network outside
plant (OSP) fiber 100. Fiber termination 95 is typically situated in a
Network Interface Device (NID) at the side of the residence or other
customer premises. OSP fiber 100 is a single-mode fiber such as standard
5D fiber. By way of example, fiber 100 supports 1.55 .mu.m downstream
transmission and 1.31 .mu.m upstream transmission.
In operation, DCCF 55 carries 1.31 .mu.m upstream transmissions from the
ONU via core 15 to OSP fiber termination 95. From there, the upstream
transmissions couple into the core of fiber 100 and propagate toward the
central office.
Downstream transmissions, at the longer wavelength of 1.55 .mu.m, are
initially coupled from fiber termination 95 into the core of DCCF 55.
However, in this application, a feature of the DCCF to be described below
causes the energy at this longer wavelength to escape from the single-mode
core and couple into cladding modes (with respect to core 15 and cladding
20). That is, the energy is guided in the multimode core described
earlier. Thus, the injection of the downstream transmission at fiber end
90 has the effect of injecting the transmission into both core 15 and
cladding 20. As a consequence, when downstream signals in DCCF 55 reach
ONU 85, they can be detected there by, e.g., an annular detector.
Although the 1.55 .mu.m downstream signals are to be coupled into cladding
modes, a DCCF effective for this purpose is readily made that will remain
an effective single-mode waveguide for the 1.31 .mu.m upstream signals.
Such a DCCF behaves as a directional coarse wavelength-division
multiplexer (CWDM) when used in conjunction with a concentric
source-detector pair.
One special feature that will effectuate the desired outcoupling of energy
into cladding modes is a long-period grating written into single-mode core
15. Techniques for writing these gratings using, e.g., actinic radiation
are well known, and need not be described here in detail. One useful
description of some such techniques may be found in U.S. Pat. No.
5,430,817, issued on Jul. 4, 1995 to A. M. Vengsarkar under the title
"Optical Systems and Devices Using Long Period Spectral Shaping Devices."
A long-period grating is a refractive index Bragg grating. The repeat
distance A of such a grating is selected such that forward-propagating
fundamental mode light is coupled into forward propagating
higher-order-mode light. Periods typically are several hundred
micrometers, and typical grating lengths are 1-5 cm. Index change induced
by actinic radiation is on the order of 10.sup.-4.
An alternative feature for effectuating the same purpose is provided by
tailoring the refractive index profile of the DCCF. That is, the .DELTA.n,
or relative refractive index difference, between core 15 and cladding 20
is selected such that 1.3 .mu.m signals are confined by the single-mode
core, but 1.55 .mu.m signals are not. This could be achieved, for example,
in a DCCF having core 15 and cladding 20 similar to the core and cladding
of standard non-dispersion-shifted fiber, dispersion shifted fiber, or
non-zero dispersion fiber, but in which one or both of the core diameter
and .DELTA.n are adjusted to make the fiber only weakly guiding at 1.55
.mu.m. For example, reducing the core index of Lucent 5D fiber from
.DELTA.n=0.0045 to .DELTA.n=0.0035 and keeping the same core diameter of
8.2 .mu.m leads to a fiber in which attenuation of the energy at 1.55
.mu.m is estimated to be greater than 30 dB over 100 m due to bends
induced during normal cabling or installation.
One exemplary design for a DCCF is shown in FIG. 4A. As shown in the
figure, DCCF 105 includes core 110 and cladding 115 of a standard Lucent
5D single-mode glass fiber. Polymer coating 120, which is chosen to have a
refractive index lower than that of cladding 115, serves as the multimode
cladding. This design is advantageous because the manufacturing process is
the same as for a standard product, except for the addition of a simple
polymer overcoating step to provide coating 120. Thus, production costs
are relatively small. Moreover, interconnection with other fibers, such as
an OSP fiber, is facilitated because the single-mode core and cladding are
a very close match to those of at least some standard fibers.
A second exemplary design for a DCCF is shown in FIG. 4B. To make the
preform from which this fiber is drawn, a standard core rod, such as a
Lucent 5D core rod, is first fabricated using MCVD (Modified Chemical
Vapor Deposition). The inner and outer portions of the standard core rod
are the precursors for single-mode core 125 and pure silica single-mode
cladding 130, respectively. According to conventional techniques, the
standard core rod would then be enclosed in an overclad tube of pure
silica. In our design, however, the overclad tube is not made of pure
silica. Instead, it is made from silica doped with fluorine to depress its
refractive index. When the fiber is drawn from the resulting preform, the
overclad tube provides multimode cladding 135. If the core rod and
overclad tube have the same dimensions as those for making 5D fiber, the
resulting DCCF is readily made to match 5D fiber in core diameter and
outer cladding diameter.
Alternatively, core and cladding portions of a preform are grown from
silica soot by VAD (Vapor Axial Deposition). In a subsequent growth step,
fluorine-doped silica is deposited to form the region that will ultimately
give rise to the multimode cladding.
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