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| United States Patent |
5,880,865
|
|
Lu
, et al.
|
March 9, 1999
|
Wavelength-division-multiplexed network having broadcast capability
Abstract
A Wavelength-Division-Multiplexed (WDM) network provides delivery of both
switched services and broadcast analog video over optical facilities
through an intermediate optical apparatus (e.g., Passive Optical Network
(PON)) splitter to a plurality of remote optical apparatuses (e.g.,
optical-network units (ONUs)). The broadcast signal is provided to only a
selected ONU, together with the switched service signal for that selected
ONU, the selected ONU then distributes the broadcast signal to other ONUs
over a separate distribution facility interconnecting the ONUs.
| Inventors:
|
Lu; Xiaolin (Matawan Township, Monmouth County, NJ);
Woodward; Sheryl Leigh (Holmdel Township, NJ)
|
| Assignee:
|
Lucent Technologies Inc. (Murray Hill, NJ)
|
| Appl. No.:
|
759743 |
| Filed:
|
December 3, 1996 |
| Current U.S. Class: |
398/72; 398/66 |
| Intern'l Class: |
H04J 014/02 |
| Field of Search: |
359/124,125,127-128
455/6.1-3.1
348/6,10,12
|
References Cited [Referenced By]
U.S. Patent Documents
| 5202780 | Apr., 1993 | Fussganger | 359/125.
|
| 5694234 | Dec., 1997 | Darcie et al. | 359/125.
|
Other References
Video Services Delivery in Fiber in the Loop Systems Using MPEG Encoding
and ATM Transport by J. R. Jones, published in IEEE Lasers and
Electro-Optics Society 1993 Annual Meeting, Nov. 15-18, 1993.
|
Primary Examiner: Negash; Kinfe-Michael
Claims
We claim:
1. A Wavelength-Division-Multiplexed (WDM) optical network comprising
a first optical apparatus, including an optical splitter, for communicating
each of a first set of optical switched services signals over a separate
optical facility to each of a plurality of Optical Network Units (ONUs)
and for communicating an optical broadcast signal to a selected one of the
plurality of ONUs and
said selected ONU connected to a distribution facility which interconnects
to one or more of the plurality of ONUs, said selected ONU including means
for communicating the optical broadcast signal over the distribution
facility to the other one or more of the ONUs.
2. The WDM network of claim 1 wherein the optical splitter includes
a splitter which sends signals over the separate optical facility to the
ONUs and
a combiner which combines the first optical signal being transmitted to the
selected ONU with the optical broadcast signal.
3. The WDM network of claim 2 wherein the combiner is a wavelength-division
multiplexer and wherein the first optical signal is transmitted to the
selected ONU is transmitted using a different wavelength than the
wavelength used to transmit the optical broadcast signal.
4. The WDM network of claim 1 wherein the selected ONU includes a splitter
for separating the received broadcast and switched services.
5. The WDM network of claim 1 wherein the optical broadcast signal is
transmitted to the selected ONU by modulating a Radio Frequency (RF)
sub-carrier on a wavelength used for transporting the optical switched
services signal to the selected ONU.
6. The WDM network of claim 1 wherein the selected second optical apparatus
sends power over the distribution facility to one or more of the other
second optical apparatuses.
7. The WDM network of claim 1 wherein the path for carrying broadcast
signals is used to provide a backup path for the transmission of switched
services signal over the distribution facility to one or more of the other
second optical apparatuses, in the event of a failure in any of the
optical facilities which connect to the one or more of the other second
optical apparatuses.
8. The WDM network of claim 1 wherein a separate optical facility to the
selected second optical apparatus is used to provide a backup path for the
transmission switched services signal over the distribution facility to
one or more of the other second optical apparatuses, in the event of a
failure in any of the optical facilities which connect to the one or more
of the other ONUs.
9. The WDM network of claim 1 wherein each of the first set of signals and
the optical broadcast signal use different wavelengths.
10. The WDM network of claim 9 wherein the first optical apparatus includes
a coarse splitter for separating the different optical wavelength used for
the switched services signals from the wavelength used for the optical
broadcast signal,
a second splitter for dividing the switched services signals wavelengths
for communication to each of the plurality of second optical apparatuses,
and
a multiplexer for combining the optical broadcast signal from the coarse
splitter with an optical wavelength switched services signal from the
second splitter for communication to the selected second optical
apparatus.
11. The WDM network of claim 10 wherein the second splitter is a power
splitter which divides the optical power of the first set of signals
communicated to each of the plurality of second optical apparatuses.
12. The WDM network of claim 10 wherein the second splitter is a fine
wavelength-division demultiplexer for separating different optical
wavelength switched services signals for communication to each of the
plurality of second optical apparatuses.
13. The WDM network of claim 1 wherein the first set of signals use a first
wavelength and the optical broadcast signal uses a different second
wavelength.
14. A Wavelength-Division-Multiplexed (WDM) network comprising
a first optical apparatus, including a Dragone router, for communicating
each of a first set of optical signals, transmitted using different
optical wavelengths, over a separate optical facility to each of a
plurality of second optical apparatuses and for communicating an optical
broadcast signal to a selected one of the plurality of second optical
apparatuses and
said selected second optical apparatus connected to a distribution facility
which interconnects to one or more of the plurality of second optical
apparatuses, said selected second optical apparatus including means for
communicating the optical broadcast signal over the distribution facility
to the other one or more of the second optical apparatuses.
15. A method of operating a Wavelength-Division-Multiplexed (WDM) network
comprising the steps of:
communicating, from a first optical apparatus including an optical
splitter, each of a set of optical switched services signals over a
separate optical facility to each of a plurality of Optical Network Units
(ONUs) and communicating an optical broadcast signal to a selected one of
the plurality of ONUs and
receiving, at a selected ONU of the plurality of ONUs, the broadcast signal
and communicating the optical broadcast signal over a separate
distribution facility which interconnects the selected ONU to the other
one or more of the ONUs.
16. A first optical apparatus for use in a Wavelength-Division Multiplexed
(WDM) network comprising
first means, including an optical splitter, for communicating at one
optical wavelength, switched services signals over a separate optical
facility to each of a plurality of Optical Network Units (ONUs) of the WDM
network and
second means, including an optical combiner, for communicating a different
optical wavelength signal to a selected one of the plurality of ONUs for
distribution over a distribution facility to one or more of the ONUs.
17. A first optical apparatus for use in a Wavelength-Division Multiplexed
(WDM) network comprising
first means, including an optical splitter, for communicating switched
services signals over a separate optical facility to each of a plurality
of Optical Network Units (ONUs) of the WDM network, using a different
wavelength for each ONU and
second means, including an optical combiner, for communicating a different
optical wavelength signal to a selected one of the plurality of ONUs for
distribution over a distribution facility to one or more of the ONUs.
Description
TECHNICAL FIELD OF THE INVENTION
This invention relates to wavelength-division-multiplexed networks and,
more particularly, to a wavelength-division-multiplexed network having
broadcast capability.
BACKGROUND OF THE INVENTION
It is expensive to provide analog broadcast TV over a passive-optical
network (PON) because of the high carrier-to-noise ratio (CNR) required of
these signals(.about.50 dB/4 MHz). To achieve this high CNR performance,
very linear transmitters must be used, and the transmission power level
should be such to ensure that enough signal power (i.e. 0.2 mW) reaches
the optical receiver. Since the output power of transmitters is limited, a
single transmitter can only serve a limited number of receivers (unless
expensive optical amplifiers are used). Because the optical receiver is
not shared by many users in a fiber-to-the-home (FTTH) or
fiber-to-the-curb (FTTC) systems, the cost of the transmitter will not be
shared among many users. It therefore is quite expensive to provide
broadcast analog video over a PON.
This problem is present in both wavelength-division-multiplexed PONs (where
the light's wavelength determines which ONU receives the signal) and
power-splitting PONs (where the light is split at a power-splitter, and
all the ONU's receive the same signals).
One illustrative switched digital video system which broadcasts analog
video signals is described in the article entitled "Video Services
Delivery in Fiber in the Loop Systems Using MPEG Encoding and ATM
Transport" by J. R. Jones, published in IEEE Lasers and Electro-Optics
Society 1993 Annual Meeting, Nov. 15-18, 1993. This system is basically a
hybrid-fiber-coax (HFC) system combined with a FTTC-PON. The broadcast
signal is sent to a fiber-node, which then transmits the broadcast signals
over coaxial cable serving many users (hundreds). The PON provides
switched services to each ONU. The coaxial cable provides the ONU with
power, and from the ONU the switched signals and the broadcast signals are
transmitted to the home.
Undesirably, the prior art has not fully integrated the two systems (HFC
and PON). Transmitting the broadcast signals to the neighborhood over a
PON should lower the cost of deployment, operations and maintenance.
SUMMARY OF THE INVENTION
The present invention solves the problem of providing cost effective
delivery of both switched services and broadcast analog video over a
Wavelength-Division-Multiplexed (WDM) network through an intermediate
optical apparatus (e.g., the splitter of a Passive Optical Network (PON))
to a plurality of remote optical apparatuses (e.g., optical-network units
(ONUs)). In accordance with the present invention, the problem is solved
by interconnecting the ONUs, using a separate distribution facility, and
sending the broadcast signal to only one selected ONU. This selected ONU
then relays the broadcast signals to the other ONUs over the distribution
facility.
According to one aspect of the invention, the WDM network includes a
power-splitting PON and the wavelength of the optical broadcast signal is
transmitted at a different wavelength than the wavelengths of the optical
switched services' signals used by the ONUs, so that only the selected ONU
receives the optical broadcast signal. In another arrangement the PON is a
WDM PON and the splitter is a Dragone router. According to another aspect,
the optical broadcast signal is transmitted to the selected ONU by
modulating a Radio Frequency (RF) sub-carrier of the optical wavelength
used to send the optical switched services signal to the selected ONU.
BRIEF DESCRIPTION OF THE DRAWING
In the drawings,
FIG. 1 shows a simplified illustrative switched services and broadcast
analog video distribution system in accordance with the teachings of the
previously-referenced Jones article,
FIG. 2 shows a simplified illustrative wavelength-division-multiplexed
(WDM) network for providing switched services and broadcast analog video
distribution in accordance with the present invention,
FIG. 3 shows an illustrative optical network unit (ONU) for use in the
network of FIG. 2,
FIG. 4 shows an illustrative WDM router for use in the network of FIG. 2,
FIG. 5 shows an alternative WDM router for use in the network of FIG. 2,
FIG. 6 shows another illustrative WDM network in accordance with the
present invention, and
FIG. 7 shows yet another illustrative WDM network, in accordance with the
present invention, which uses subcarrier modulation to carry the broadcast
signal.
DETAILED DESCRIPTION
In the following description, each item or block of each figure has a
reference designation associated therewith, the first number of which
refers to the figure in which that item is first located (e.g., 105 is
located in FIG. 1).
With reference to FIG. 1, there is shown a simplified illustrative switched
services and broadcast analog video distribution system in accordance with
our interpretation of the previously-referenced Jones article. Switched
signals are transmitted to and received from a central location 101, e.g.,
a Central Office (CO), for distribution over separate fibers 102 to a
plurality of Remote Nodes (RN) 103. As shown, one or more of the RNs may
further distribute the signals to other locations. The broadcast
television signals, typically a CATV signal is received at a Distribution
Network (DN) 104 for broadcast, along with electrical power, over a
coaxial cable network 105 to the RNs 103. Power and signal taps 106
located along the coaxial cable network 105 drop the broadcast TV signal
and power to the RNs 103.
With reference to FIG. 2, there is shown a simplified illustrative
wavelength-division-multiplexed (WDM) network 200, in accordance with the
present invention, for providing switched services signals and for
broadcasting the analog CATV video signal to a plurality of Optical
Network Units (ONUs). The WDM network 200 may be implemented using any of
a variety of well-known arrangements. One illustrative PON that may be
used is the "RITE-net" described in the article entitled "A
Wavelength-Division Multiplexed Passive Optical Network with Cost Shared
Components," published in Photonics Technology Letters, pp. 1365-1367,
November, 1994, by N. J. Frigo et. al..
At Central Office (CO) location 201, both the electrical broadcast CATV
signal 202 (in either analog format or digital baseband or passband
format) and switched signals 203 are used to modulate different optical
carriers, each carrier having a different wavelength, to form a
wavelength-division-multiplexed (WDM) signal in modulator/combiner 204.
The resulting modulated WDM signal including the switched signal modulated
optical carriers at wavelengths .lambda..sub.1, .lambda..sub.2, . . .
.lambda..sub.N, and the broadcast CATV modulated signal at wavelength
.lambda..sub.B are sent over path 205 and through a splitter 206 to remote
Optical Network Units ONU1-ONUN. The splitter 206 may be a
wavelength-division demultiplexer, such as the "Dragone" router, as
described in U.S. Pat. No. 5,136,671, entitled "Optical Switch Multiplexer
and Demultiplexer," issued on Aug. 4, 1992, and incorporated by reference
herein. Unless otherwise stated, in the remainder of this description the
splitter 206 will be assumed to be a WDM router.
As shown WDM router 206 places both the switched signal at wavelength
.lambda..sub.1 and the broadcast CATV signal at wavelength .lambda..sub.B
onto the optical facility 207, e.g., optical fiber and associated
circuits, to ONU1 while each of the remaining switched signals at
wavelengths .lambda..sub.2, . . . .lambda..sub.N are sent over a different
optical facility to their respective remote ONU2-ONUN.
Splitter 206 directs each optical carrier to a single ONU based on the
wavelength of the optical carrier. .lambda..sub.1 and .lambda..sub.B are
chosen such that both are transmitted to ONU1. If splitter 206 is a
Dragone router, then this can be done easily, without altering the design
of splitter 206 from the design used to implement RITE-Net without this
invention. This is because the Dragone Router has a cyclic response, such
that each output port of the router transmits a different set of
wavelengths: .lambda..sub.i +k.increment..lambda. where k is an integer,
and .lambda..sub.i is different for each output port (.increment..lambda.
depends on the design of the Dragone router used). Therefore, if
.lambda..sub.B =.lambda..sub.1 +.increment..lambda., then both the
broadcast signal, and the switched signal at wavelength .lambda..sub.1
will be transmitted to ONU1.
Each of the ONUs operate in a well known manner to convert the
switched-signal optical carrier received from splitter 206 into electrical
signals and modulate optical carriers with received electrical switched
signals for transmission to CO 201. The ONU1 additionally splits the
received switched signal transmitted at wavelength .lambda..sub.1 and the
broadcast signal transmitted at wavelength .lambda..sub.B into separate
signals. The ONU1 converts the switched signal on the optical carrier
received from splitter 206 into an electrical signal for the User and also
uses the received electrical switched signals from the User to modulate an
optical carrier for transmission to CO 201. The ONU1 additionally converts
the received broadcast signal into an electrical signal suitable for
transmission over the facility 210 which interconnects all of the ONUs. In
accordance with the present invention, the broadcast signal may be analog
or digital and the distribution facility 210 may be the existing cable TV
distribution facilities (e.g., coaxial cable) that already connect to
users (typical locations of the ONUs). In other implementations the
distribution facilities may be coaxial cable, twisted pair, optical fiber,
or wireless. When the distribution facility 210 is twisted pair or coaxial
cable, ONU1 can also provide for power distribution to the other ONUs. The
arrangement of FIG. 2 thus solves the problem of providing cost effective
delivery of both switched services and an analog-video broadcast over a
PON.
According to one aspect of the present invention, the WDM network of FIG. 2
provides route diversity, in the event of a failure in one or all of the
primary signal paths to the ONUs. In such a circumstance, the
broadcast-signal's path, or another primary switched-signal's optical
carrier may be used with the distribution facility to provide a backup
path for the transmission of a switched-services signal from the CO to one
or more of the other ONUs, in the event of a failure in any of the optical
facilities which connect to the one or more of the other ONUs.
FIG. 2 also shows a second WDM network (or PON network) 220 which
distributes its own switched signal modulated wavelengths .lambda..sub.1,
. . . .lambda..sub.N over different optical fibers to their respective
remote ONUs. As shown, the ONUs of PON network 220 may receive the
broadcast analog video (and power) over the distribution facility 210
which has been extended to connect thereto. The distribution facility 210
also provides route diversity for network 220.
FIG. 3 shows an illustrative optical network unit ONU1 for use in the
network of FIG. 2. As shown, a coarse WDM router 301 can be used in ONU1
to separate the switched signal modulated wavelength .lambda..sub.1 and
the broadcast CATV modulated wavelength .lambda..sub.B from the received
signals .lambda..sub.1, .lambda..sub.B. The switched signal at wavelength
.lambda..sub.1 goes to optical transceiver 302. It is used for
bidirectional communications between the users associated with ONU1 and
the CO 101. The broadcast signals at wavelength .lambda..sub.B is received
and converted, if necessary, to a signal format compatible for
transmission over distribution facility 210 in distribution module 303.
Shown in FIG. 4, is another embodiment of the present invention based on
network 200. As shown, the illustrative optical splitter/conbimer 401
includes a WDM router 402 and a combiner 403. The illustrative optical
splitter/combiner 401 receives the switched signal modulated optical
wavelengths .lambda..sub.1, .lambda..sub.2, . . . .lambda..sub.N, and the
broadcast CATV modulated signal .lambda..sub.B. The WDM router 402
separates the received switched signals at wavelengths .lambda..sub.1,
.lambda..sub.2, . . . .lambda..sub.N into separate optical wavelength
signals. The combiner 403 combines the optical wavelength .lambda..sub.1
out of WDM router 401 with the broadcast CATV modulated signal
.lambda..sub.B to form the combined optical signal .lambda..sub.1,
.lambda..sub.B for ONU1. In one illustrative arrangement, described later
in FIG. 6, the wavelengths .lambda..sub.1, .lambda..sub.2, . . .
.lambda..sub.N may be closely spaced around a wavelength of 1.5 microns,
while the broadcast CATV modulated signal .lambda..sub.B, illustratively,
occurring at a wavelength of 1.3 microns. In another illustrative
arrangement, also described in FIG. 6, wavelengths .lambda..sub.1,
.lambda..sub.2, . . . .lambda..sub.N are replaced with a single optical
carrier at wavelength .lambda..sub.1, and the splitter 402 is a power
splitter. The broadcast CATV modulated signal .lambda..sub.B, is combined
with the optical carrier carrying signals to ONU1 at combiner 403.
FIG. 5 shows an alternative WDM router to ONUs connection arrangement 501.
As shown the WDM router 502 splits the combined optical signal
.lambda..sub.1, .lambda..sub.2, . . . .lambda..sub.N, and .lambda..sub.B
into separate wavelengths, each wavelength being sent to an ONU over a
separate optical fiber. In such an arrangement, 501 connects to ONU1 using
two fibers, a separate fiber for each of the two different wavelengths
.lambda..sub.1 and .lambda..sub.B. Such an arrangement eliminates the need
for a wavelength demultiplexer at ONU1.
FIG. 6 shows another illustrative WDM network in accordance with the
present invention. As shown, each of the switched signals could be
modulated onto different wavelengths .lambda..sub.1, .lambda..sub.2, . . .
.lambda..sub.N, all near 1.5 micron. Alternatively they could be
transmitted using one optical carrier with wavelength .lambda..sub.1. The
broadcast signal, illustratively, is transmitted using a 1.3 micron
wavelength optical carrier. These signals are then multiplexed together in
a combiner 601 (or multiplexer). The splitter/combiner circuit 602
includes a "coarse" 1.3/1.5 micron demultiplexer (or router) 603 to
produce separate 1.3 and 1.5 micron wavelength optical signals. When
multple optical carriers are used to transmit the switched signals then
splitter 604 is either a "fine" demultiplexer or router which separates
the closely spaced wavelengths .lambda..sub.1, .lambda..sub.2, . . .
.lambda..sub.N. When a single optical carrier is used to transmit the
switched signals then splitter 604 is a power splitter. A combiner 605
combines the approximately 1.5 micron wavelength signal .lambda..sub.1,
with the broadcast signal .lambda..sub.B at 1.3 microns. The resulting
optical signal is then sent to ONU1 610. At ONU1 a demultiplexer 611
separates the 1.5 micron switched signal from the 1.3 micron broadcast
signal. As previously described, the optical broadcast signal is
demodulated and converted by distribution module (DM) 612 into the type of
signal needed for distribution over facility 620 to the other ONUs. The
1.5 micron switched signal is received and demodulated at receiver 613 and
outputted to the users.
FIG. 7 shows yet another illustrative WDM network, in accordance with the
present invention, which uses Radio Frequency (RF) subcarrier(s) in the
frequency band 701 to carry the broadcast signal over the same wavelength
.lambda..sub.1 used to carry the switched signals. If necessary, the
broadcast signal is frequency converted from its original band into
frequency band 701 to insure frequency separation from the switched
signals 702. The switched and broadcast signals are combined and modulate
the optical carrier at wavelength .lambda..sub.1 in modulator 703. The
other switched signals are used to modulate the optical carriers at
wavelengths .lambda..sub.2, . . . .lambda..sub.N. These optical carriers
are summed in combiner 703a with the optical carrier at wavelength
.lambda..sub.1 from modulator 703. The resulting signal is then sent to
WDM router 704 which separates the wavelengths for transmission over
different fibers to the respective ONUS, as previously described. At ONU1
705, the signal at .lambda..sub.1 is converted into an electrical signal
and using standard RF techniques, separated into the switched signal and
the broadcast signal. As previously described, the broadcast signal is
converted into the type of electrical signal needed for transmission over
broadcast distribution facility 706 to the other ONUs. The demodulated
switched signal is outputted to the users associated with ONU1.
What has been described is merely illustrative of the application of the
principles of the present invention. Other arrangements and methods can be
implemented by those skilled in the art without departing from the spirit
and scope of the present invention.
* * * * *
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