U.S. patent application number 15/195529 was filed with the patent office on 2016-10-20 for optical network unit (onu) wavelength self-tuning.
The applicant listed for this patent is Futurewei Technologies, Inc.. Invention is credited to Frank J. Effenberger, Huafeng Lin, Feng Wang, Lei Zong.
Application Number | 20160309245 15/195529 |
Document ID | / |
Family ID | 51225084 |
Filed Date | 2016-10-20 |
United States Patent
Application |
20160309245 |
Kind Code |
A1 |
Effenberger; Frank J. ; et
al. |
October 20, 2016 |
Optical Network Unit (ONU) Wavelength Self-Tuning
Abstract
A remote node (RN) comprises a downstream port, a wavelength
multiplexer (WM) coupled to the downstream port and comprising
ports for passing optical waves, an optical rotator coupled to the
WM, and a mirror coupled to the optical rotator, wherein the WM,
the optical rotator, and the mirror are part of a wavelength tuning
scheme. An apparatus comprises a tunable transmitter, a
polarization beam splitter (PBS) coupled to the tunable
transmitter, a filter coupled to the PBS, a receiver coupled to the
filter, a photodiode (PD) coupled to the PBS, and a processor
coupled to the tunable transmitter and the PD. An apparatus
comprises a tunable transmitter configured to transmit a first
optical wave, a filter configured to receive a first reflected
optical wave associated with the first optical wave, and a
processor configured to tune the tunable transmitter based on the
first reflected optical wave.
Inventors: |
Effenberger; Frank J.;
(Colts Neck, NJ) ; Lin; Huafeng; (Santa Clara,
CA) ; Zong; Lei; (Ellicott City, MD) ; Wang;
Feng; (Jamestown, NC) |
|
Applicant: |
Name |
City |
State |
Country |
Type |
Futurewei Technologies, Inc. |
Plano |
TX |
US |
|
|
Family ID: |
51225084 |
Appl. No.: |
15/195529 |
Filed: |
June 28, 2016 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
|
|
14323641 |
Jul 3, 2014 |
9407395 |
|
|
15195529 |
|
|
|
|
61843140 |
Jul 5, 2013 |
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Current U.S.
Class: |
1/1 |
Current CPC
Class: |
H04J 14/02 20130101;
H04Q 2011/0016 20130101; H04Q 11/0005 20130101; H04B 10/27
20130101; H04B 10/572 20130101; H04J 14/0282 20130101; H04Q
2011/0022 20130101; H04J 14/0249 20130101 |
International
Class: |
H04Q 11/00 20060101
H04Q011/00; H04B 10/27 20060101 H04B010/27; H04J 14/02 20060101
H04J014/02 |
Claims
1. A remote node (RN) comprising: a downstream port; a wavelength
multiplexer (WM) coupled to the downstream port and comprising
ports for passing optical waves; an optical rotator coupled to the
WM; and a mirror coupled to the optical rotator, wherein the WM,
the optical rotator, and the mirror are part of a wavelength tuning
scheme.
2. The RN of claim 1, further comprising an upstream port coupled
to the mirror, wherein the WM is an arrayed waveguide grating
(AWG), wherein the optical rotator is a 45-degree)(.degree. Faraday
rotator (FR), wherein the mirror is a partial-reflection mirror
(PRM), and wherein the FR and the PRM form a Faraday rotator mirror
(FRM).
3. The RN of claim 1, further comprising: a coupler positioned
between the WM and the optical rotator; and an upstream port
coupled to the coupler, wherein the WM is an arrayed waveguide
grating (AWG), wherein the optical rotator is a 45-degree
(.degree.) Faraday rotator (FR), wherein the mirror is a
high-reflection mirror (HRM), and wherein the FR and the PRM form a
Faraday rotator mirror (FRM).
4. The RN of claim 3, wherein the coupler is a tap coupler
configured to forward at least part of an optical wave
upstream.
5. The RN of claim 1, wherein the WM is configured to multiplex a
first optical wave with second optical waves, wherein the optical
rotator is configured to rotate the first optical wave, and wherein
the mirror is configured to reflect at least part of the first
optical wave to create a reflected optical wave.
6. The RN of claim of claim 5, wherein the WM is configured to
forward the reflected optical wave downstream.
7. The RN on claim 5, wherein the first optical wave and the
reflected optical wave are orthogonal to each other.
Description
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001] This application is a divisional application of U.S. patent
application Ser. No. 14/323,641 filed on Jul, 3, 2014 by Frank
Effenberger, et al., and titled "Optical Network Unit (ONU)
Wavelength Self-Tuning," which claims priority to U.S. provisional
patent application No. 61/843,140 filed on Jul. 5, 2013 by Frank
Effenberger, et al., and titled "Self-Calibration of Optical
Networking Unit in Wavelength Division Multiplexed Passive Optical
Networks," which are incorporated by reference.
STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT
[0002] Not applicable.
REFERENCE TO A MICROFICHE APPENDIX
[0003] Not applicable.
BACKGROUND
[0004] A passive optical network (PON) is one system for providing
network access over the last mile, which is the final portion of a
telecommunications network that exchanges communication with
customers. A PON is a point-to-multipoint (P2MP) network comprised
of an optical line terminal (OLT) at a central office (CO), an
optical distribution network (ODN), and optical network units
(ONUs) at the customers' premises. PONs may also comprise remote
nodes (RNs) located between the OLTs and the ONUs, for instance at
the end of a road where multiple customers reside.
[0005] In recent years, time-division multiplexing (TDM) PONs such
as gigabit PONs (GPONs) and Ethernet PONs (EPONs) have been
deployed worldwide for multimedia applications. In TDM PONs, the
total capacity is shared among multiple users using a time-division
multiple access (TDMA) scheme, so the average bandwidth for each
user may be limited to below 100 megabits per second (Mbps).
[0006] Wavelength-division multiplexing (WDM) PONs are considered a
very promising solution for future broadband access services. WDM
PONs can provide high-speed links with dedicated bandwidth up to 10
gigabits per second (Gb/s). By employing a wavelength-division
multiple access (WDMA) scheme, each ONU in a WDM PON is served by a
dedicated wavelength channel to communicate with the CO or the
OLT.
[0007] Next-generation PONs may combine TDMA and WDMA to support
higher capacity so that an increased number of users can be served
by a single OLT with sufficient bandwidth per user. In such a time-
and wavelength-division multiplexing (TWDM) PON, a WDM PON may be
overlaid on top of a TDM PON. In other words, different wavelengths
may be multiplexed together to share a single feeder fiber, and
each wavelength may be shared by multiple users using TDMA.
SUMMARY
[0008] In one embodiment, the disclosure includes a remote node
(RN) comprising a downstream port, a wavelength multiplexer (WM)
coupled to the downstream port and comprising ports for passing
optical waves, an optical rotator coupled to the WM, and a mirror
coupled to the optical rotator, wherein the WM, the optical
rotator, and the mirror are part of a wavelength tuning scheme.
[0009] In another embodiment, the disclosure includes an apparatus
comprising a tunable transmitter, a polarization beam splitter
(PBS) coupled to the tunable transmitter, a filter coupled to the
PBS, a receiver coupled to the filter, a photodiode (PD) coupled to
the PBS, and a processor coupled to the tunable transmitter and the
PD.
[0010] In yet another embodiment, the disclosure includes an
apparatus comprising a tunable transmitter configured to transmit a
first optical wave, a filter configured to receive a first
reflected optical wave associated with the first optical wave, and
a processor configured to tune the tunable transmitter based on the
first reflected optical wave.
[0011] In yet another embodiment, the disclosure includes a method
comprising transmitting a first optical wave at a first wavelength,
receiving a first reflected optical wave at the first wavelength
and associated with the first optical wave, determining a first
power associated with the first reflected optical wave, and tuning
a transmitting wavelength based on the first power.
[0012] These and other features will be more clearly understood
from the following detailed description taken in conjunction with
the accompanying drawings and claims.
BRIEF DESCRIPTION OF THE DRAWINGS
[0013] For a more complete understanding of this disclosure,
reference is now made to the following brief description, taken in
connection with the accompanying drawings and detailed description,
wherein like reference numerals represent like parts.
[0014] FIG. 1 is a schematic diagram of an embodiment of a PON.
[0015] FIG. 2 is a schematic diagram of a portion of the PON in
FIG. 1 according to an embodiment of the disclosure.
[0016] FIG. 3 is a schematic diagram of a portion of the PON in
FIG. 1 according to another embodiment of the disclosure.
[0017] FIG. 4 is a schematic diagram of the ONU.sub.1 in FIG. 1
according to an embodiment of the disclosure.
[0018] FIG. 5 is a flowchart illustrating a method of wavelength
correction according to an embodiment of the disclosure.
[0019] FIG. 6 is a flowchart illustrating the coarse tuning step of
FIG. 5 according to an embodiment of the disclosure.
[0020] FIG. 7 is a flowchart illustrating the fine tuning step of
FIG. 5 according to an embodiment of the disclosure.
[0021] FIG. 8 is a graph of wavelength versus power for the
ONU.sub.1 in FIG. 1 according to an embodiment of the
disclosure.
[0022] FIG. 9 is a flowchart illustrating a method of wavelength
tuning according to an embodiment of the disclosure.
[0023] FIG. 10 is a schematic diagram of an embodiment of a network
device.
DETAILED DESCRIPTION
[0024] It should be understood at the outset that, although an
illustrative implementation of one or more embodiments are provided
below, the disclosed systems and/or methods may be implemented
using any number of techniques, whether currently known or in
existence. The disclosure should in no way be limited to the
illustrative implementations, drawings, and techniques illustrated
below, including the exemplary designs and implementations
illustrated and described herein, but may be modified within the
scope of the appended claims along with their full scope of
equivalents.
[0025] FIG. 1 is a schematic diagram of an embodiment of a PON 100.
The PON 100 may be suitable for implementing the disclosed
embodiments. The PON 100 may comprise an OLT 120 located in a CO
110, ONUs.sub.1-n 180.sub.1-n located at the customers' premises,
and an ODN 170 that couples the OLT 120 to the ONUs.sub.1-n
180.sub.1-n. N may be any positive integer. The PON 100 may provide
WDM capability by associating a downstream wavelength and an
upstream wavelength with each OLT port.sub.1-n 130.sub.1-n so that
a plurality of wavelengths is present, then combining those
wavelengths into a single optical fiber cable 150 via a wavelength
multiplexer/demultiplexer (WM) 140 and distributing the wavelengths
to the ONUs.sub.1-n 180.sub.1-n through an RN 160. The PON 100 may
provide TDM as well.
[0026] The PON 100 may be a communications network that does not
require any active components to distribute data between the OLT
120 and the ONUs.sub.1-n 180.sub.1-n . Instead, the PON 100 may use
passive optical components in the ODN 170 to distribute data
between the OLT 120 and the ONUs.sub.1-n 180.sub.1-n. The PON 100
may adhere to any standard related to multiple-wavelength PONs.
[0027] The CO 110 may be a physical building and may comprise
servers and other backbone equipment designed to service a
geographical area with data transfer capability. The CO 110 may
comprise the OLT 120, as well as additional OLTs. If additional
OLTs are present, then any suitable access scheme may be used among
them.
[0028] The OLT 120 may comprise the OLT ports.sub.1-n 130.sub.1-n
and the WM 140. The OLT 120 may be any device suitable for
communicating with the ONUs.sub.1-n 180.sub.1-n and another
network. Specifically, the OLT 120 may act as an intermediary
between the other network and the ONUs.sub.1-n 180.sub.1-n. For
instance, the OLT 120 may forward data received from the network to
the ONUs.sub.1-n 180.sub.1-nand may forward data received from the
ONUs.sub.1-n 180.sub.1-n to the other network. When the other
network uses a network protocol that differs from the PON protocol
used in the PON 100, the OLT 120 may comprise a converter that
converts the network protocol to the PON protocol. The OLT 120
converter may also convert the PON protocol into the network
protocol. Though the OLT 120 is shown as being located at the CO
110, the OLT 120 may be located at other locations as well.
[0029] The OLT ports.sub.1-n 130.sub.1-n may be any ports suitable
for transmitting waves to and receiving waves from the WM 140. For
instance, the OLT ports.sub.1-n 130.sub.1-n may comprise laser
transmitters to transmit waves and photodiodes to receive waves, or
the OLT ports.sub.1-n 130.sub.1-n may be connected to such
transmitters and photodiodes. The OLT ports.sub.1-n 130.sub.1-n may
transmit and receives waves in any suitable wavelength bands.
[0030] The WM 140 may be any suitable wavelength
multiplexer/demultiplexer such as an arrayed waveguide grating
(AWG). The WM 140 may multiplex the waves received from the OLT
ports.sub.1-n 130.sub.1-n, then forward the combined waves to the
RN 160 via the optical fiber cable 150. The WM 140 may also
demultiplex the waves received from the RN 160 via the optical
fiber cable 150.
[0031] The RN 160 may be any component positioned within the ODN
170 that provides partial reflectivity, polarization rotation, and
WDM capability. For example, the RN 160 may comprise a WM similar
to the WM 140. The RN 160 may exist closer to the ONUs.sub.1-n
180.sub.1-n than to the CO 110, for instance at the end of a road
where multiple customers reside, but the RN 160 may also exist at
any suitable point in the ODN 170 between the ONUs.sub.1-n
180.sub.1-n and the CO 110.
[0032] The ODN 170 may be any suitable data distribution network,
which may comprise optical fiber cables such as the optical fiber
cable 150, couplers, splitters, distributors, or other equipment.
The optical fiber cables, couplers, splitters, distributors, or
other equipment may be passive optical components and therefore not
require any power to distribute data signals between the OLT 120
and the ONUs.sub.1-n 180.sub.1-n. Alternatively, the ODN 170 may
comprise one or more active components such as optical amplifiers
or a splitter. The ODN 170 may typically extend from the OLT 120 to
the ONUs.sub.1-n 180.sub.1-n in a branching configuration as shown,
but the ODN 170 may be configured in any suitable P2MP
configuration.
[0033] The ONUs.sub.1-n 180.sub.1-n may comprise laser transmitters
to transmit waves and photodiodes to receive waves. The
ONUs.sub.1-n 180.sub.1-n may be any devices suitable for
communicating with the OLT 120 and customers. Specifically, the
ONUs.sub.1-n 180.sub.1-n may act as intermediaries between the OLT
120 and the customers. For instance, the ONUs.sub.1-n 180.sub.1-n
may forward data received from the OLT 120 to the customers and
forward data received from the customers to the OLT 120. The
ONUs.sub.1-n 180.sub.1-n may be similar to optical network
terminals (ONTs), so the terms may be used interchangeably. The
ONUs.sub.1-n 180.sub.1-n may typically be located at distributed
locations such as the customer premises, but may be located at
other suitable locations as well.
[0034] WDM PONs are promising because they may expand PON capacity
by tens to hundreds of wavelengths, improve a link budget by
reducing a splitting loss in the RN, and simplify media access
control (MAC) layer control and maintenance. In a WDM PON, a pair
of waves, one downstream wave and one upstream wave, may be
associated with each OLT port.sub.1-n 130.sub.1-n and corresponding
ONU.sub.1-n 180.sub.1-n. In a downstream direction, meaning from
the OLT ports.sub.1-n 130.sub.1-n to the ONUs.sub.1-n 180.sub.1-n,
the downstream waves from the OLT ports.sub.1-n 130.sub.1-n may
combine in the WM 140, propagate along the optical fiber cable 150,
demultiplex in the RN 160, and propagate to their respective
ONUs.sub.1-n 180.sub.1-n. In an upstream direction, meaning from
the ONUs.sub.1-n 180.sub.1-n to the OLT ports.sub.1-n 130.sub.1-n,
the upstream waves from the ONUs.sub.1-n 180.sub.1-n may combine in
the RN 160, propagate along the optical fiber cable 150,
demultiplex in the WM 140, and propagate to their respective OLT
ports.sub.1-n 130.sub.1-n. A typical WDM PON may use an AWG located
in the RN 160 to demultiplex, multiplex, and route waves. The AWG
may have individual ports, which may be arbitrarily assigned when a
worker physically connects a fiber from each ONU.sub.1-n
180.sub.1-n to a single AWG port. For that reason, the ONUs.sub.1-n
180.sub.1-n may not know which AWG port they are connected to.
Without knowing which AWG port they are connected to, the
ONUs.sub.1-n 180.sub.1-n may not know which wavelength their AWG
port may pass and thus at which wavelength the ONUs.sub.1-n
180.sub.1-n need to transmit.
[0035] The ONUs.sub.1-n 180.sub.1-n may be colorless, meaning that
they may transmit or receive waves at any wavelength. Colorless
ONUs.sub.1-n 180.sub.1-n are frequently used because they offer
flexible network installation, maintenance, and operation. The
transmitter of a colorless ONU.sub.1-n 180.sub.1-n may be a
colorless laser, which may be fitted to the wavelength of any AWG
port to which the ONU.sub.1-n 180.sub.1-n is connected. A tunable
laser is one type of colorless laser. For a WDM PON employing
tunable lasers, it is generally desirable to tune the tunable
lasers so that they transmit waves at the wavelengths associated
with their corresponding AWG ports. If a tunable laser does not
transmit waves at the associated wavelength, the waves may not
reach the OLT because the AWG may reject the waves or the waves may
suffer from high insertion loss or group delay ripples.
[0036] U.S. Pat. No. 6,567,198 titled "Wavelength Stabilizer in WDM
Optical Transmission System" to Yong-Hoon Kang, which is
incorporated by reference, describes setting and stabilizing a
laser wavelength locally in the ONU by monitoring and adjusting the
laser temperature. U.S. Patent Application Publication number
2011/0236017 titled "Methods and Devices for Wavelength Alignment
in WDM-PON" to Peter Ohlen, which is incorporated by reference,
describes setting and stabilizing a laser wavelength based on a
pre-measured data table and on a received wave power monitored at
the OLT. Those solutions, however, may not be accurate because they
may not consider wavelength drift due to laser aging. In addition,
those solutions may require OLT involvement, which may make the
wavelength tuning process slow and inefficient. Furthermore, merely
monitoring a laser wavelength and adjusting it to reach a specific
value does not guarantee that the ONU's upstream waves will pass
through the AWG port because the ONU may not know what wavelength
its associated AWG port will pass.
[0037] Disclosed herein are embodiments for ONU self-tuning, or
self-calibration, that may not require OLT involvement. The
embodiments may provide for an ONU sending an upstream wave, an RN
reflecting a portion of the wave, and the ONU receiving the
reflected wave for local monitoring. A reflector in the RN may
reflect the upstream wave. A PBS in the ONU may separate the
upstream wave and the reflected wave at a low insertion loss. An
AWG may be located in the RN. When the upstream wave aligns with
the associated wavelength of the AWG port, the ONU may detect a
significant power increase in the reflected wave. The ONU may
continue fine-tuning its laser by maximizing the reflected wave
power, and the ONU may continue that process during normal
operation in order to lock its wavelength.
[0038] As discussed above, a reflector may be placed in the RN 160.
The reflector may be placed between an AWG and the optical fiber
cable 150 to allow a portion of the upstream wave to proceed to the
OLT 120 and a portion of the upstream wave to reflect back to the
AWG. The AWG may demultiplex the reflected wave and any other
downstream waves, then direct those waves to their corresponding
ONUs.sub.1-n 180.sub.1-n. Embodiments of the RN 160 are described
more fully below.
[0039] FIG. 2 is a schematic diagram of a portion of the PON 100 in
FIG. 1 according to an embodiment of the disclosure. FIG. 2 may
focus on the OLT 120, the optical fiber cable 150, the RN 160, and
the ONU.sub.1 180.sub.1, but specifically the RN 160, in FIG. 1.
The RN 160 may comprise an upstream port 210, a partial-reflection
mirror (PRM) 220, a 45 degree (.degree.) Faraday rotator (FR) 230,
an AWG 250, and a downstream port 260. The FR 230 may be any
suitable optical polarization rotator. The PRM 220 may provide
about 30% to 80% reflection or any other suitable amount of
reflection. Together, the PRM 220 and the FR 230 may form a Faraday
rotator mirror (FRM) 240. The AWG 250 may be any suitable WM
suitable for multiplexing and demultiplexing waves at different
wavelengths. Though the downstream port 260 is shown for the
ONU.sub.1 180.sub.1 is shown, the RN 160 may also comprise
additional downstream ports for the other ONUs.sub.2-n 180.sub.2-n.
The components may be arranged as shown or in any other suitable
manner.
[0040] As shown, the ONU.sub.1 180.sub.1 may transmit an upstream
wave, .lamda..sub.u,0.degree., which may initially have a 0.degree.
polarization. .lamda..sub.u,0.degree. may travel from the ONU.sub.1
180.sub.1, though the downstream port 260, and to the AWG 250, and
.lamda..sub.u,0.degree. may be multiplexed with other upstream
waves from the other ONUs.sub.2-n 180.sub.2-n.
.lamda..sub.u,0.degree. may then travel through the FR 230 and
experience a 45.degree. polarization rotation to become
.lamda..sub.u,45.degree.. The PRM 220 may allow a portion of
.lamda..sub.u,45.degree. to proceed through the upstream port 210
and the optical fiber cable 150 to the OLT 120. The PRM 220 may
also reflect a portion of .lamda..sub.u, 45.degree. back to the FR
230 to experience another 45.degree. polarization rotation to
become .lamda..sub.u,90.degree.. .lamda..sub.r,90.degree. may
proceed back to the ONU.sub.1 180.sub.1. The polarization state of
.lamda..sub.r,90.degree., which is 90.degree., may be orthogonal,
or perpendicular, to the polarization state of
.lamda..sub.u,0.degree., which is 0.degree..
[0041] FIG. 3 is a schematic diagram of a portion of the PON 100 in
FIG. 1 according to another embodiment of the disclosure. Like FIG.
2, FIG. 3 may focus on the OLT 120, the optical fiber cable 150,
the RN 160, and the ONU.sub.1 180.sub.1, but specifically the RN
160, in FIG. 1. The RN 160 may comprise the upstream port 210, a
high-reflection mirror (HRM) 310, the FR 230, a tap coupler 330,
the AWG 250, and the downstream port 260. Together, the HRM 310 and
the FR 230 may form an FRM 320. The HRM 310 may provide about 90%
to 100% reflection or any other suitable amount of reflection. The
components may be arranged as shown or in any other suitable
manner.
[0042] Unlike FIG. 2, FIG. 3 may comprise the tap coupler 330. The
tap coupler 330 may be any optical coupler suitable for coupling
downstream waves and splitting upstream waves. With the presence of
the tap coupler 330, the AWG 250 and the FR 230 may be said to be
indirectly coupled. Two components, for instance the AWG 250 and
the FR 230, may be said to be indirectly coupled if at least one
other component is positioned between them, for instance if the tap
coupler 330 is positioned between them.
[0043] As shown, the ONU.sub.1 180.sub.1 may transmit an upstream
wave, .lamda..sub.u, 0.degree., which may initially have a
0.degree. polarization. .lamda..sub.u,0.degree. may travel from the
ONU.sub.1 180.sub.1, through the downstream port 260, and to the
AWG 250, and .lamda..sub.u,0.degree. may be multiplexed with other
upstream waves from the other ONUs.sub.2-n 180.sub.2-n.
.lamda..sub.u,0.degree. may then travel through the tap coupler
330. The tap coupler 330 may allow a portion of
.lamda..sub.u,0.degree. to proceed through the upstream port 210
and the optical fiber cable 150 to the OLT 120. In other words,
.lamda..sub.u,0.degree. may maintain its 0.degree. polarization all
the way from the ONU.sub.1 180.sub.1 to the OLT 120. The tap
coupler 330 may also allow a portion of .lamda..sub.u,0.degree. to
proceed to the FRM 320. That portion of .lamda..sub.u,0.degree. may
travel through the FR 230 and experience a 45.degree. polarization
rotation to become .lamda..sub.u,45.degree.. The HRM 310 may
reflect all or nearly all of .lamda..sub.u,45.degree. to experience
another 45.degree. polarization rotation to become
.lamda..sub.r,90.degree.. .lamda..sub.r,90.degree. may proceed back
through the tap coupler 330 to the ONU.sub.1 180.sub.1. The
polarization state of .lamda..sub.r,90.degree., which is
90.degree., may be orthogonal to the polarization state of
.lamda..sub.u,0.degree., which is 0.degree..
[0044] As described above, the reflection of .lamda..sub.u may
occur in the RN 160. The components of the RN 160 necessary for
that reflection may, however, be at other suitable locations in the
PON 100. Furthermore, the behavior of .lamda..sub.u and
.lamda..sub.r and embodiments of the ONUs.sub.1-n 180.sub.1-n are
described with respect to the ONU.sub.1 180.sub.1, but the same
concepts also apply to the other ONUs.sub.2-n 180.sub.2-n.
Additionally, .lamda..sub.u is described as having a 0.degree. or
45.degree. polarization, and .lamda..sub.r is described as having a
90.degree. polarization, but the respective polarizations may not
be exactly 0.degree., 45.degree., or 90.degree.. Rather, the
polarizations may be at approximately those angles, at any angles
that allow an orthogonal relation between .lamda..sub.u and
.lamda..sub.r, or at any angles that allow a separation between
.lamda..sub.u and .lamda..sub.r.
[0045] FIG. 4 is a schematic diagram of the ONU.sub.1 180.sub.1 in
FIG. 1 according to an embodiment of the disclosure. The ONU.sub.1
180.sub.1 may comprise a filter 410, a polarization beam splitter
(PBS) 420, a tunable transmitter 430, a processor 440, a PD 450,
and a receiver 460. The components may be arranged as shown or in
any other suitable manner. In general, the ONU.sub.1 180.sub.1 may
transmit upstream waves to the OLT 120, receive downstream waves
from the OLT 120, and receive reflected waves from the RN 160. In
particular, the ONU.sub.1 180.sub.1 may transmit
.lamda..sub.u,0.degree., an upstream wave with a 0.degree.
polarization; receive .lamda..sub.d, a downstream wave with an any
polarization; and receive .lamda..sub.r,90.degree., a reflected
wave with a 90.degree. polarization. .lamda..sub.u,0.degree. and
.lamda..sub.r,90.degree. may be at roughly the same wavelength or
may be intended to be at the same wavelength while .lamda..sub.d
may be at a different wavelength.
[0046] The filter 410 may be a bandpass filter or any suitable
filter that can separate downstream waves from upstream waves. The
filter 410 may separate waves based on wavelength. In particular,
the filter 410 may separate .lamda..sub.d on the one hand from
.lamda..sub.u,0.degree. and .lamda..sub.r,90.degree. on the other
hand. The filter 410 may be referred to as a band upstream/band
downstream (Bu/Bd) filter.
[0047] The PBS 420 may be any suitable polarization beam splitter
that can separate waves with similar wavelengths, but different
polarization states. In particular, the PBS 420 may separate
.lamda..sub.u,0.degree. from .lamda..sub.r,90.degree. because the
two waves may have approximately a 90.degree. difference in
polarizations. In other words, the two waves may be orthogonal to
each other. The PBS 420 may be used because the inputs and outputs
of the ONU.sub.1 180.sub.1 may be on the same fiber. In other
words, the ONU.sub.1 180.sub.1 may not be able to distinguish
between its inputs and outputs without additional components.
Instead of the PBS 420, the ONU.sub.1 180.sub.1 may use an optical
coupler, optical circulator, or partial reflection mirror. However,
optical couplers may have high insertion loss and may require an
accompanying optical isolator in order to block coherent feedback
from the tunable transmitter 430. Optical circulators may be
relatively expensive to use. Partial reflection mirrors may discard
part of the waves they are processing.
[0048] The tunable transmitter 430 may be any suitable tunable
transmitter that is colorless, or can transmit waves at any
wavelength. The tunable transmitter 430 may comprise a tunable
laser. As shown, the tunable transmitter 430 may transmit
.lamda..sub.u,0.degree., an upstream wavelength with a 0.degree.
polarization state.
[0049] The processor 440 may be any suitable processor that can
process signals received from the PD 450 and transmit instructions
to the tunable transmitter 430. The processor 440 may perform any
computational functions necessary to process those signals and
transmit those instructions.
[0050] The PD 450 may be any suitable PD that can convert optical
waves into electrical waves and monitor a received power. The PD
450 may be referred to as a monitoring PD because it may monitor a
reflected power. Specifically, the PD 450 may monitor and determine
a power associated with .lamda..sub.r.
[0051] The receiver 460 may be any suitable receiver that can
convert optical waves into electrical waves and provide those
electrical waves in a usable form for a customer. Specifically, the
receiver may receive .lamda..sub.d, convert .lamda..sub.d into an
electrical wave, and provide the electrical wave to the customer.
The receiver 460 may comprise a PD for converting optical waves
into electrical waves.
[0052] In the upstream direction, the tunable transmitter 430 may
transmit .lamda..sub.u,0.degree. to the PBS 420. The PBS 420 may
distinguish .lamda..sub.u,0.degree. from .lamda..sub.r,90.degree.
because the polarizations of the two waves may be orthogonal to
each other. The PBS 420 may then forward .lamda..sub.u,0.degree. to
the filter 410. The filter 410 may distinguish
.lamda..sub.u,0.degree. and .lamda..sub.r,90.degree. on the one
hand from .lamda..sub.d on the other hand because the wavelength of
.lamda..sub.u,0.degree. and .lamda..sub.u,90.degree. may be
different from the wavelength of .lamda..sub.d. The filter 410 may
then forward .lamda..sub.u,0.degree. to the RN 160 and eventually
the OLT 120.
[0053] In the downstream direction, the filter 410 may receive
.lamda..sub.r,90.degree. and .lamda..sub.d from the RN 160. The
filter 410 may distinguish .lamda..sub.u,0.degree. and
.lamda..sub.r,90.degree. on the one hand from .lamda..sub.d on the
other hand because the wavelength of .lamda..sub.u,0.degree. and
.lamda..sub.r,90.degree. may be different from the wavelength of
.lamda..sub.d. The filter 410 may forward .lamda..sub.d to the
receiver 460 for optical-to-electrical (OE) conversion and
processing. The filter 410 may also forward
.lamda..sub.r,90.degree. to the PBS 420. The PBS 420 may
distinguish .lamda..sub.u,0.degree. from .lamda..sub.r,90.degree.
because the polarizations of the two waves may be orthogonal to
each other. The PBS 420 may then forward .lamda..sub.u,90.degree.
to the PD 450 for OE conversion and power determination. The PD 450
may forward the converted wave to the processor 440 for
processing.
[0054] FIG. 5 is a flowchart illustrating a method 500 of
wavelength correction according to an embodiment of the disclosure.
After the ONU.sub.1 180.sub.1 turns on or at any other suitable
time, the ONU.sub.1 180.sub.1 may attempt to tune the tunable
transmitter 430 so that the tunable transmitter 430 transmits
.lamda..sub.u at the wavelength associated with the corresponding
AWG 250 port. The method 500 may be implemented in the ONU.sub.1
180.sub.1.
[0055] At step 510, coarse tuning may be performed. During coarse
tuning, the processor 440 may instruct the tunable transmitter 430
to adjust its transmitting wavelength across its entire tuning
range at a large step size, for instance at about 0.25-0.5 of its
channel spacing. Channel spacing may typically be about 20
nanometers (nm) for coarse WDM (CWDM) and about 12.5 gigahertz
(GHz) for dense WDM (DWDM). When the tunable transmitter 430 tunes
to a first threshold wavelength, the PD 450 may detect a power
increment for .lamda..sub.r that is above a first threshold,
threshold.sub.1, that may be predefined based on design, testing,
or other suitable means. The first threshold wavelength may roughly
match the wavelength associated with the corresponding AWG 250
port, but not be in the center of the corresponding AWG 250 port
passband, so .lamda..sub.u at the first threshold wavelength may
still experience high insertion loss in the AWG 250.
[0056] At step 520, fine tuning may be performed. During fine
tuning, the processor 440 may instruct the tunable transmitter 430
to adjust its transmitting wavelength across its entire tuning
range at a small step size, for instance at about 0.1 of its
channel spacing. When the tunable transmitter 430 tunes to a second
threshold wavelength, the PD 450 may detect a power increment for
.lamda..sub.r that is above a second threshold, threshold.sub.2,
that may be predefined based on design, testing, or other suitable
means. The second threshold wavelength may nearly precisely match
the wavelength associated with the corresponding AWG 250 port, so
.lamda..sub.u at the second threshold wavelength may experience no
or negligible insertion loss in the AWG 250. The ONU.sub.1
180.sub.1 may continuously perform step 520 during its normal
operation in order to keep the power of .lamda..sub.r at or near
its maximum and thus to keep .lamda..sub.u locked at the wavelength
associated with the corresponding AWG 250 port.
[0057] FIG. 6 is a flowchart illustrating the coarse tuning step
510 of FIG. 5 according to an embodiment of the disclosure. At step
605, .lamda..sub.u,0, an initial upstream wavelength of the tunable
transmitter 430, may be saved. The tunable transmitter 430 may then
transmit .lamda..sub.u at .lamda..sub.u,0, and the ONU.sub.1
180.sub.1 may receive .lamda..sub.r. At step 610, P.sub.0, an
initial reflected power associated with k may be measured and
saved. At decision diamond 615, it may be determined whether or not
.lamda..sub.u is at a maximum wavelength, for instance the maximum
wavelength that the tunable transmitter 430 may transmit at. If so,
then the method may proceed to step 640. If not, then the method
may proceed to step 620. At step 620, the wavelength of
.lamda..sub.u may be incremented by .DELTA..sub.80 .sub.1, a
relatively large step size that may be about 0.25-0.5 of the
channel spacing of the tunable transmitter 430. The tunable
transmitter 430 may then transmit .lamda..sub.u at the incremented
wavelength, and the ONU.sub.1 180.sub.1 may receive .lamda..sub.r
at the incremented wavelength. At step 625, P.sub.1, the current
reflected power of .lamda..sub.r at the incremented wavelength, may
be measured. At decision diamond 630, the quantity P.sub.1-P.sub.0
may be determined. If that quantity is greater than or equal to
threshold.sub.1, then the method may finish and proceed to step 520
of FIG. 5. If that quantity is less than threshold.sub.1, then the
method may proceed to step 635. At step 635, P.sub.1 may become the
new P.sub.0. The method may repeat steps 615 to 630 until the
quantity P.sub.1-P.sub.0 is greater than or equal to
threshold.sub.1.
[0058] At step 640, .lamda..sub.u,0 and P.sub.0 from steps 605 and
610, respectively, may be restored. At decision diamond 645, it may
be determined whether or not .lamda..sub.u is at a minimum
wavelength, for instance the minimum wavelength that the tunable
transmitter 430 may transmit at. If .lamda..sub.u is at a minimum
wavelength, then the method may proceed to step 670, where an error
may be recorded and the method may finish and proceed to step 520
of FIG. 5. An error may be recorded because the wavelength of
.lamda..sub.u may not be simultaneously at its maximum and minimum.
If .lamda..sub.u is not at a minimum wavelength, then the method
may proceed to step 650. At step 650, the wavelength of
.lamda..sub.u may be decremented by .DELTA..sub..lamda..sub.1. The
tunable transmitter 430 may then transmit .lamda..sub.u at the
decremented wavelength, and the ONU.sub.1 180.sub.1 may receive
.lamda..sub.r at the decremented wavelength. At step 655, P.sub.1,
the current reflected power of .lamda..sub.r at the decremented
wavelength, may be measured. At decision diamond 660, the quantity
P.sub.1-P.sub.0 may be determined. If that quantity is greater than
or equal to threshold.sub.1, then the method may finish and proceed
to step 520 of FIG. 5. If that quantity is less than
threshold.sub.1, then the method may proceed to step 665. At step
665, P.sub.1 may become the new P.sub.0. The method may repeat
steps 645 to 660 until the quantity P.sub.1-P.sub.0 is greater than
or equal to threshold.sub.1.
[0059] FIG. 7 is a flowchart illustrating the fine tuning step 520
of FIG. 5 according to an embodiment of the disclosure. At step
705, .lamda..sub.u,0', an initial upstream wavelength of the
tunable transmitter 430, may be saved. .lamda..sub.u,0' may be the
last wavelength used in step 510 where P.sub.1-P.sub.0 was greater
than or equal to threshold.sub.1. At step 710, P.sub.0', an initial
reflected power associated with .lamda..sub.r, may be measured and
saved. P.sub.0' may be the power associated with .lamda..sub.u,0'
and measured at step 510. At step 715, i, a reiteration counter,
may be initialized at 0. At decision diamond 720, it may be
determined whether or not .lamda..sub.u is at a maximum wavelength,
for instance the maximum wavelength that the tunable transmitter
430 may transmit at. If so, then the method may proceed to step
745. If not, then the method may proceed to step 725. At step 725,
i may be incremented by 1. At step 730, the wavelength of
.lamda..sub.u may be incremented by .DELTA..sub..lamda..sub.2, a
relatively small step size that may be about 0.1 of the channel
spacing of the tunable transmitter 430. The tunable transmitter 430
may then transmit .lamda..sub.u at the incremented wavelength, and
the ONU.sub.1 180.sub.1 may receive .lamda..sub.r at the
incremented wavelength. At step 735, P.sub.1, the current reflected
power of .lamda..sub.r at the incremented wavelength, may be
measured. At decision diamond 740, the quantity P.sub.1-P.sub.0'
may be determined. If the quantity P.sub.1-P.sub.0' is greater than
or equal to threshold.sub.2, then the method may proceed to step
750. At step 750, P.sub.1 may become the new P.sub.0', and the
method may proceed to decision diamond 720. Returning to decision
diamond 740, if the quantity P.sub.1-P.sub.0' is less than
threshold.sub.2, then the method may proceed to decision diamond
745. At decision diamond 745, it may be determined whether or not i
is equal to 0 or 1. If so, then the method may proceed to step 755.
If not, then the method may proceed to step 795. At step 795, the
wavelength of .lamda..sub.u may be restored to the wavelength from
the prior iteration, and the method 500 may finish.
[0060] At step 755, .lamda.u.sub.0' and P.sub.0' from steps 705 and
710, respectively, may be restored. At decision diamond 760, it may
be determined whether or not .lamda..sub.u is at a minimum
wavelength, for instance the minimum wavelength that the tunable
transmitter 430 may transmit at. If .lamda..sub.u is at a minimum
wavelength, then the method may proceed to decision diamond 785. At
decision diamond 785, it may be determined whether or not i is
equal to 0. If so, then the method 500 may finish. If not, then the
method may proceed to step 795, which is described above. Returning
to decision diamond 760, if .lamda..sub.u is not at a minimum
wavelength, then the method may proceed to step 765. At step 765, i
may be incremented by 1. At step 770, the wavelength of
.lamda..sub.u may be decremented by .DELTA..sub..lamda..sub.2. The
tunable transmitter 430 may then transmit .lamda..sub.u at the
decremented wavelength, and the ONU.sub.1 180.sub.1 may receive
.lamda..sub.r at the decremented wavelength. At step 775, P.sub.1,
the current reflected power of .lamda..sub.r at the decremented
wavelength, may be measured. At decision diamond 780, the quantity
P.sub.1-P.sub.0' may be determined. If the quantity
P.sub.1-P.sub.0' is greater than or equal to threshold.sub.2, then
the method may proceed to step 790. At step 790, P.sub.1 may become
the new P.sub.0', and the method may proceed to decision diamond
760. Returning to decision diamond 780, if the quantity
P.sub.1-P.sub.0' is less than threshold.sub.2, then the method may
proceed to decision diamond 785, which is described above.
[0061] FIG. 8 is a graph 800 of wavelength versus power for the
ONU.sub.1 180.sub.1 in FIG. 1 according to an embodiment of the
disclosure. As shown, the x-axis represents wavelength as constants
or arbitrary units, and the y-axis represents power as constants or
arbitrary units. Specifically, the x-axis may represent the
wavelength of .lamda..sub.u and thus .lamda..sub.r, and the y-axis
may represent the power of .lamda..sub.r. As can be seen, the power
spectrum of .lamda..sub.r may be relatively flat, except for a
relatively sharp spectrum peak centered around P.sub.max, the point
where the power is a maximum. Such a spectrum may be typical for
waves passing through an AWG port. As can also be seen,
.DELTA..sub.P.sub.1<.DELTA..sub.P.sub.2<.DELTA..sub.P.sub.3&l-
t;.DELTA..sub.P.sub.4.DELTA..sub.P.sub.5, which may indicate that
the power at wavelengths equally spaced by .DELTA..sub..lamda. may
increase more significantly as the wavelength approaches the point
where P.sub.max is reached. As a result, .DELTA..sub.P.sub.5 may be
greater than a predefined threshold, for instance threshold.sub.1
or threshold.sub.2, thus demonstrating the general strategy of
steps 510 and 520 for determining the wavelength associated with
the corresponding AWG 250 port.
[0062] While the graph 800 may demonstrate the general strategy of
steps 510 and 520, other methods may also determine the wavelength
associated with the corresponding AWG 250 port. For example, the
ONU.sub.1 180.sub.1 may simply transmit .lamda..sub.u at its known
minimum wavelength and measure the power of .lamda..sub.r, then
increase the wavelength of .lamda..sub.u by some predefined
increment and measure the power of .lamda..sub.r until the
ONU.sub.1 180.sub.1 transmits .lamda..sub.u at its known maximum
wavelength. The ONU.sub.1 180.sub.1 may then determine which
wavelength is associated with a maximum power of .lamda..sub.r,
then continue transmitting .lamda..sub.u at that wavelength.
Alternatively, the ONU.sub.1 180.sub.1 may simply transmit
.lamda..sub.u at its known maximum wavelength and measure the power
of .lamda..sub.r, then decrease the wavelength of .lamda..sub.u by
some predefined increment and measure the power of .lamda..sub.r
until the ONU.sub.1 180.sub.1 transmits .lamda..sub.u at its known
minimum wavelength. The ONU.sub.1 180.sub.1 may then determine
which wavelength is associated with a maximum power of
.lamda..sub.r, then continue transmitting .lamda..sub.u at that
wavelength. Alternatively, the ONU.sub.1 180.sub.1 may employ those
methods, but provide different wavelength increments, for instance
coarse wavelength increments followed by fine wavelength
increments. While those methods may be simpler, they may also be
less efficient. Nonetheless, those methods or any suitable method
for determining the wavelength associated with the corresponding
AWG 250 port may be used.
[0063] FIG. 9 is a flowchart illustrating a method 900 of
wavelength tuning according to an embodiment of the disclosure. The
method 900 may be implemented in the ONUs.sub.1-n 180.sub.1-n, for
instance the ONU.sub.1 180.sub.1. At step 910, a first wave at a
first wavelength may be transmitted. For instance, the tunable
transmitter 430 may transmit .lamda..sub.u. At step 920, a first
reflected wave at the first wavelength may be received. For
instance, the filter 410 may receive .lamda..sub.r. The first
reflected wave may be associated with the first wave. For instance
.lamda..sub.r may be the portion of .lamda..sub.u reflected at the
RN 160. At step 930, a first power associated with the first
reflected wave may be determined. For instance, the PD 450 may
determine P, the power of .lamda..sub.r. At step 940, a
transmitting wavelength may be tuned based on the first power. For
instance, the processor 440 may tune a wavelength of the tunable
transmitter 430 based on P.
[0064] FIG. 10 is a schematic diagram of an embodiment of a network
device 1000. The network device 1000 may be suitable for
implementing the disclosed embodiments, for instance the OLT 120,
the RN 160, and the ONUs.sub.1-n 180.sub.1-n. The network device
1000 may comprise ingress ports 1010 and receiver units (Rx) 1020
for receiving data; a processor, logic unit, or central processing
unit (CPU) 1030 to process the data; transmitter units (Tx) 1040
and egress ports 1050 for transmitting the data; and a memory 1060
for storing the data. The network device 1000 may also comprise OE
components and electrical-to-optical (EO) components coupled to the
ingress ports 1010, receiver units 1020, transmitter units 1040,
and egress ports 1050 for egress or ingress of optical or
electrical signals.
[0065] The processor 1030 may be implemented by hardware and
software. The processor 1030 may be implemented as one or more CPU
chips, cores (e.g., as a multi-core processor), field-programmable
gate arrays (FPGAs), application specific integrated circuits
(ASICs), and digital signal processors (DSPs). The processor 1030
may be in communication with the ingress ports 1010, receiver units
1020, transmitter units 1040, egress ports 1050, and memory
1060.
[0066] The memory 1060 may comprise one or more disks, tape drives,
and solid-state drives; may be used as an over-flow data storage
device; may be used to store programs when such programs are
selected for execution; and may be used to store instructions and
data that are read during program execution. The memory 1060 may be
volatile and non-volatile and may be read-only memory (ROM),
random-access memory (RAM), ternary content-addressable memory
(TCAM), and static random-access memory (SRAM).
[0067] At least one embodiment is disclosed and variations,
combinations, and/or modifications of the embodiment(s) and/or
features of the embodiment(s) made by a person having ordinary
skill in the art are within the scope of the disclosure.
Alternative embodiments that result from combining, integrating,
and/or omitting features of the embodiment(s) are also within the
scope of the disclosure. Where numerical ranges or limitations are
expressly stated, such express ranges or limitations may be
understood to include iterative ranges or limitations of like
magnitude falling within the expressly stated ranges or limitations
(e.g., from about 1 to about 10 includes, 2, 3, 4, etc.; greater
than 0.10 includes 0.11, 0.12, 0.13, etc.). For example, whenever a
numerical range with a lower limit, R.sub.1, and an upper limit,
R.sub.u, is disclosed, any number falling within the range is
specifically disclosed. In particular, the following numbers within
the range are specifically disclosed:
R=R.sub.1+k*(R.sub.u-R.sub.1), wherein k is a variable ranging from
1 percent to 100 percent with a 1 percent increment, i.e., k is 1
percent, 2 percent, 3 percent, 4 percent, 5 percent, . . . , 50
percent, 51 percent, 52 percent, . . . , 95 percent, 96 percent, 97
percent, 98 percent, 99 percent, or 100 percent. Moreover, any
numerical range defined by two R numbers as defined in the above is
also specifically disclosed. The use of the term "about" means
+/-10% of the subsequent number, unless otherwise stated. Use of
the term "optionally" with respect to any element of a claim means
that the element is required, or alternatively, the element is not
required, both alternatives being within the scope of the claim.
Use of broader terms such as comprises, includes, and having may be
understood to provide support for narrower terms such as consisting
of, consisting essentially of, and comprised substantially of
Accordingly, the scope of protection is not limited by the
description set out above but is defined by the claims that follow,
that scope including all equivalents of the subject matter of the
claims. Each and every claim is incorporated as further disclosure
into the specification and the claims are embodiment(s) of the
present disclosure. The discussion of a reference in the disclosure
is not an admission that it is prior art, especially any reference
that has a publication date after the priority date of this
application. The disclosure of all patents, patent applications,
and publications cited in the disclosure are hereby incorporated by
reference, to the extent that they provide exemplary, procedural,
or other details supplementary to the disclosure.
[0068] While several embodiments have been provided in the present
disclosure, it may be understood that the disclosed systems and
methods might be embodied in many other specific forms without
departing from the spirit or scope of the present disclosure. The
present examples are to be considered as illustrative and not
restrictive, and the intention is not to be limited to the details
given herein. For example, the various elements or components may
be combined or integrated in another system or certain features may
be omitted, or not implemented.
[0069] In addition, techniques, systems, subsystems, and methods
described and illustrated in the various embodiments as discrete or
separate may be combined or integrated with other systems, modules,
techniques, or methods without departing from the scope of the
present disclosure. Other items shown or discussed as coupled or
directly coupled or communicating with each other may be indirectly
coupled or communicating through some interface, device, or
intermediate component whether electrically, mechanically, or
otherwise. Other examples of changes, substitutions, and
alterations are ascertainable by one skilled in the art and may be
made without departing from the spirit and scope disclosed
herein.
* * * * *