US9271058B2

US9271058B2 - Communications network

Info

Publication number: US9271058B2
Application number: US14/127,345
Authority: US
Inventors: Andrew Lord
Original assignee: British Telecommunications PLC
Current assignee: British Telecommunications PLC
Priority date: 2011-06-20
Filing date: 2012-06-18
Publication date: 2016-02-23
Anticipated expiration: 2032-06-18
Also published as: WO2012175913A1; EP2721751B1; EP2721751A1; US20140140695A1

Abstract

A communications network wherein first and second optical signals can be launched into an optical fiber in respective first and second regions of a transmission window such that controllable filters can be used to selectively recover the first and second optical signals. This partitioning of the transmission window allows two incompatible optical signals to coexist in the same optical fiber.

Description

PRIORITY CLAIM

The present application is a National Phase entry of PCT Application No. PCT/GB2012/000528, filed Jun. 18, 2012, which claims priority from EP Patent Application No. 11250602.7, filed Jun. 20, 2011, and GB Patent Application No. 1112713.1, filed Jul. 25, 2011, said applications being hereby incorporated by reference herein in their entireties.

TECHNICAL FIELD

The present application relates to an optical communications network and in particular to an optical communications network which can support optical signals of different formats.

BACKGROUND

Conventional optical communication networks operate by sending light pulses of a predetermined period, for example such that a pulse represents a ‘1’ and no pulse represents a ‘0’. This technique enables signals to be sent at data rates of up to 10 Gb/s and wavelength division multiplexing (WDM) techniques can be used to send multiple signals over a single fiber. Dense WDM (DWDM) enables up to 160 wavelengths to be used such that a single fiber can potentially carry 1.6 Tb/s of data. In order to enable compatibility between network components from different vendors, the ITU has specified a grid of wavelengths that are used in DWDM systems (see ITU-T G.694.1). One of the transmission phenomena present in optical fibers is chromatic dispersion, which causes the transmitted pulse to spread out, such that it becomes difficult to recover the transmitted signal at the receiver. The effects of dispersion can be mitigated by installing dispersion compensating modules (DCMs) into the network, but this adds to the cost and the complexity of the network.

Coherent optical transmission systems are thought to provide the best option for transmitting data at a rate in excess of 40 Gb/s. Coherent optical transmission systems are similar to the transmission systems used in wireless systems. Rather than turning an optical transmitter on and off to generate a pulse, an optical signal is modulated, for example in terms of phase or frequency, with a data signal. When the optical signal is received it is then recovered using a local oscillator and the transmitted data can be obtained by demodulating the optical signal. Dispersion is less of a problem and can be compensated for electronically during the demodulation of the optical signal, so it will be seen that coherent optical transmission systems do not require DCMs to be installed in the network, and in fact they work better without.

As data transmission rates increase further, for example beyond 100 Gb/s, then the optical signals required to transmit such data rates may not fit into the grid of wavelengths that are defined in the DWDM specifications. It is preferred, for reasons of flexibility and spectral efficiency, that for such high data rates, network operators are able to determine which regions of the optical transmission window are used to transmit specific signals. For example, one signal may extend across the space in the window that is reserved for multiple DWDM wavelengths.

SUMMARY

According to a first aspect there is provided an optical communications network comprising: a first optical source configured, in use, to generate a first optical signal in a first wavelength region; a second optical source configured, in use, to generate a second optical signal in a second wavelength region; combining means to launch the first optical signal and the second optical signal into an optical fiber; and a separation means which can be configured, in use, to selectively route optical signals in the first wavelength region to a first output port and optical signals in the second wavelength region to a second output port.

The first optical signals may have a first modulation and the second optical signals may have a second modulation. For example, the first optical signals may comprise amplitude-shift keying modulation and the second optical signals may comprise coherent modulation.

The separation means may comprise one or more tunable optical filters. Such tunable optical filters may have a cut off wavelength, the filters being configured, in use, to selectively route optical signals in the first wavelength region to a first output port and optical signals in the second wavelength region to a second output port.

Alternatively, the separation means may comprise one or more wavelength selective switches, the switches being configured, in use, to selectively route optical signals in the first wavelength region to a first output port and optical signals in the second wavelength region to a second output port.

Such an optical network enables different, and potentially incompatible, optical signals to be transmitted within the same optical fiber. This may enable network operators to ^ expand and upgrade their networks in a more flexible manner. For example, a portion of the transmission window could be used to deploy immediately a number of conventional wavelengths using DWDM and reserve a portion of the transmission window for coherent or flexgrid optical signals. In the medium to long term, these more advanced transmission technologies can be deployed in the second wavelength region. Over time, the size of the second wavelength region can be increased relative to the first wavelength region such that the information carrying capacity of the fiber can be increased by replacing 1 QGb/s DWDM signals with 40 Gb/s coherent signals or 100 Gb/s flexgrid signals. Embodiments flexible deployment path which enables a network operator to invest in new transmission capacity as technologies improve and customer demand increases. Without embodiments disclosed herein, a network operator has to install a network with a single type of transmission technology and hope that their forecasts are correct.

According to a second aspect of the present invention there is provided a method of operating a communications network, the method comprising: a) generating a first optical signal in a first wavelength region; b) generating a second optical signal in a second wavelength region; c) launching the first optical signal and the second optical signal into a first end of an optical fiber, and at a second end of the optical fiber: d) selectively routing optical signals in the first wavelength region to a first output port; and e) selectively routing optical signals in the second wavelength region to a second output port.

BRIEF DESCRIPTION OF THE DRAWINGS

Embodiments will now be described, by way of example only, with reference to the accompanying drawings in which:

FIG. 1 shows a schematic depiction of a communications network according to a first aspect of the present invention;

FIG. 2 shows a schematic depiction of a network according to a further embodiment of the present invention;

FIG. 3 shows a schematic depiction of a tunable splitter;

FIG. 4 shows a schematic depiction an example of a mesh network according to a yet further embodiment of the present invention;

FIG. 5 shows a schematic depiction of a first type of tunable splitter;

FIG. 6 shows a schematic depiction of an alternative first type of tunable splitter; and

FIG. 7 shows a schematic depiction of a second type of tunable splitter.

DETAILED DESCRIPTION

FIG. 1 shows a schematic depiction of a communications network 100 according to a first aspect of the present invention. The network comprises a single span of optical fiber 130 which connects a first location to a second location. At the first location a first optical transmitter 102 is connected to the optical fiber 130 via an optical coupler 120. There is also provided at the first location a second optical transmitter 104 which is also coupled to the optical fiber 130 via the optical coupler 120. At the second location a tunable splitter 200 connects the second end of the optical fiber 130 to first optical receiver 112 and second optical receiver 114.

The first optical transmitter operates in a first region of a fiber transmission window and the second optical transmitter operates in a second region of that fiber transmission window. For example, the first optical transmitter may generate a first set of optical signals between 1525 and 1543 nm and the second optical transmitter may generate a second set of optical signals between 1547 and 1565 nm. By providing a separation in the wavelength domain then the first optical signals should not interfere with the second optical signals. To provide flexibility in the operation of the network, then the cut-off point between the first region of the fiber transmission window and the second region of the fiber transmission window can be varied. For example, if the second optical transmitter needs a greater amount of wavelength then the cut-off point can be moved to 1540 nm such that the first region of the fiber transmission window is 1525-1538 nm and the second region of the fiber transmission window is 1542-1565 nm.

Both the first and the second optical signals will propagate to the end of the optical fiber where tunable splitter 200 will separate the first optical signals from the second optical signals such that the first optical signals are routed to the first optical receiver 112 and the second optical signals are routed to the second optical receiver 4. The structure of tunable splitter 200 is described below in more detail. The network operational support systems (not shown in FIG. 1) which can be used to determine the cut-off point between the first and second optical transmission windows can also be used to control the tunable splitter such that the first optical signal can be separated from the second optical signal.

Thus, the first optical signal is delivered to the first optical receiver and the second optical signal is delivered to the second optical receiver for decoding and subsequent and processing. Two different optical signals, which may be completely incompatible, can be transmitted over the same fiber by separating the signals in the wavelength domain.

For example, the first optical signal may comprise a number of non-coherent DWDM signals carrying data at 10 Gb/s and being transmitted at the wavelengths specified in G.694.1. The second optical signal may comprise one or more coherent optical signals, for example operating at 40 or 100 Gb/s, or one or more 100 Gb/s signals that are transmitted using a flexgrid arrangement, that is the signals are transmitted using a wavelength range that is convenient for the network operator, rather than using a wavelength that is specified by a body such as the ITU. By allowing the network operator to control the relative sizes of the first and second transmission windows the network operator can evolve the capacity of the network as technologies advance and data demands increase.

FIG. 2 shows a schematic depiction of an example of a network 100′ according to a further embodiment of the present invention. In this embodiment, the first and second locations are connected by two lengths of

optical fiber

130, 130′. It will be understood that the optical signals will need to be regenerated, or amplified, at the mid-point of the network. After the first and second optical signals have been transmitted along the first length of fiber 30, tunable splitter 200 will separate them and route the first optical signal to a first optical signal regenerator 142 and the second optical signal to a second optical signal regenerator 144. The regenerated signals are then combined in optical coupler 120′ and fed into second optical fiber 130′. At the end of the second optical fiber 130′ the tunable splitter 200′ separates the optical signals and routes the first optical signals to the first optical receiver 12 and the second optical signals to the second optical receiver 114. If the first optical signal were to comprise a number of non-coherent DWDM signals, then the first optical signal regenerator 142 would comprise, for example, an erbium-doped fiber amplifier and a DCM. If the second optical signal were to comprise a number of coherent optical signals then the second optical signal regenerator would comprise, for example, an erbium-doped fiber amplifier 144. It will be understood that a communications network according to the present invention could comprise multiple fiber links, with m fiber links being interspersed with m−1 sets of optical repeaters.

In the case where the first optical signal comprises a plurality of non-coherent DWDM signals and the second optical signal were to comprise a plurality of coherent optical signals then the network shown in FIG. 2 may be modified into that shown in FIG. 3. FIG. 3 shows a schematic depiction of an alternative embodiment of a network according to an embodiment in which an erbium doped fiber amplifier 135 is connected to the optical fiber, before the tunable splitter 200, such that both the first and second optical signals are amplified by the amplifier. This may then allow the first optical signal regenerator 142 to comprise solely a DC and for the second optical signal regenerator to be dispensed with. It will also be understood that the EDFA could alternatively be located just after the coupler 120 or that two EDFAs could be used.

FIG. 4 shows a schematic depiction of an example of a mesh network 100″ according to a yet further embodiment of the present invention. At a first location first optical transmitter 102 and second optical transmitter 104 are connected to optical fiber 130 a via optical coupler 120 a. The first and second optical signals propagate along optical fiber 130 a and are received at tunable splitter 200 a at a second location such that the first optical signal is routed to first optical apparatus 152 a and the second optical signal is routed to second optical apparatus 154 a. The first and second optical apparatuses comprise signal regeneration and switching technology which is appropriate to the associated optical signal.

For example, if the first optical signal comprises a plurality of non-coherent DWDM signals then the first optical apparatus may comprise an Optical regenerator (which may comprise an EDFA and a DCM) and a wavelength selective switch (WSS) which can selectively switch one or more of the DWDM signals to one or more output ports. If the second optical signal were to comprise a flexgrid signal then the second optical apparatus may comprise an EDFA and a flexgrid WSS.

The optical signals received at the first and second optical apparatuses 152 a 54 a may be destined to be routed to a further location or to be converted into the electrical domain and processed further at the second location. The first and second optical apparatuses can route optical signals selectively to

optical couplers

120 b, 120 c and 120 d. Each of these optical couplers is associated with a respective

optical fiber

130 b, 130 c & 130 d which connect to a respective

tunable filter

200 b, 200 c & 200 d. These tunable filters are located at third, fourth and fifth locations respectively. Each of the tunable splitters are connected to respective first and second optical apparatuses. For the sake of clarity, the connection between first and second

optical apparatuses

152 a and 154 a with optical coupler 120 b is shown with a solid line; the connection to optical coupler 120 c is shown with a dashed line; and the connection to optical coupler 120 d is shown with a dotted line.

Thus it can be seen that it is possible to route data from the first location to any of the other locations. It will be understood that the first and second optical apparatuses may comprise an appropriate OAD so that a portion of a wavelength region may be re-used after an optical signal has been received at a particular location.

FIG. 5 shows a schematic depiction of a first type of tunable splitter 200. The tunable splitter 200 comprises an input port 210, first and second output ports 220 230, first and second tunable filters 225 235 and control means 250. The optical signals received at the input port 210 are split into two parts, with a first part being routed to the first output port 220 and the second part being routed to the second output port 230. The optical signals routed to the first optical port 220 will pass through the first tunable filter 225 and the optical signals routed to the second optical port 230 will pass through the second tunable filter 235. The tunable filter characteristics of the first and second tunable filters are controlled by the control means 250 such that signals of the desired wavelength are routed to the appropriate output port such that they can be regenerated, switched or received by the appropriate equipment.

The tunable optical filters 225 & 235 may be formed using one of a number of different technologies. For example, the filters may be made in accordance with the teaching of U.S. Pat. No. 7,304,799 in which a thermally tunable thin-film optical filter is fabricated on top of a crystalline silicon layer. By controlling the temperature of the optical filters, for example by sending current to an electric heater or a Peltier cooler as required, it is possible to control the performance of the optical filters such that one of the filters operates as a band-pass filter in the first region of the transmission window and the other filter operates as a band-pass filter in the second region of the transmission window. Following the discussion above it can be seen that further control of the filter performance, for example shrinking the size of the first region of the transmission window whilst expanding the size of the second region of the transmission window, can be achieved by appropriate control of the filter temperature.

It will be understood that such tunable filters could be manufactured using other techniques. For example, suitable filters could be manufactured using, microelectromechanical systems (MEMS) or liquid crystal on silica (LCoS) technologies.

FIG. 6 shows a schematic depiction of an alternative first type of tunable splitter 200′. Although the preceding discussion has been focused on a network where the wavelength is divided into two regions, it will be understood that’ the wavelength could be divided into three or more regions, with tunable band-pass filters being used to define the limits of one or more of the wavelength regions. The tunable splitter 200′ of FIG. 6 comprises an input port 210, first, second third and output ports 220 230 240, first, second and second tunable filters 225 235 245 and control means 250. The optical signals received at the input port 210 are split into three parts, with a first part being routed to the first output port 220, a second part being routed to the second output port 230 and a third part being routed to the third output port 240.

The optical signals routed to the first optical port 220 will pass through the first tunable filter 225, the optical signals routed to the second optical port 230 will pass through the second tunable filter 235 and the optical signals routed to the third optical port 240 will pass through the third tunable filter 245. The tunable filter characteristics of tunable filters are controlled by the control means 250 such that signals of the desired wavelength are routed to the appropriate output port such that they can be regenerated, switched or received by the appropriate equipment. For example, as is shown in FIG. 6, the first tunable filter has a low-pass filter characteristic, the second tunable filter has a band-pass filter characteristic and the third tunable filter has a high-pass filter characteristic. It will be understood that the tunable splitter 200′ shown in FIG. 6 could be varied further such that the transmission window is divided into four or more different wavelength regions. The boundaries between each of the different wavelength regions are such that each of the regions can be used to carry the desired optical transmissions. The size of each of the regions need not be equal.

FIG. 7 shows a schematic depiction of a second type of tunable splitter which comprises a conventional 1× optical splitter 200 which comprises an input port. 210 and first and second output ports 220 230. The first output port 220 is connected to a first wavelength selective means 225 and the second output port 230 is connected to a second wavelength selective means 235. Both the first and second wavelength selective means are in communication with a control means 250. The first and second wavelength selective means may comprise the tunable filters described above, with reference to FIG. 5. Alternatively the wavelength selective means may comprise a wavelength selective switch (WSS), which is able to select and then switch one or more pre-defined optical wavelengths.

For example, if the first optical signal were to comprise non-coherent DWDM signals and the second optical signals were to comprise coherent signals transmitted at wavelengths specified by G.694.1 then it would be possible to use conventional 1×2 WSSs as the first and second wavelength selective means. The first wavelength selective means will switch all of the wavelengths in the first wavelength region to an appropriate output, and thus on to the rest of the network, and will switch all of the wavelengths in the second wavelength region to a different output. Conversely, the second wavelength selective means will switch all of the wavelengths in the second wavelength region to an appropriate output and on to the rest of the network and will switch all of the wavelengths in the first wavelength region to a different output. Furthermore, it could be possible to replace the optical splitter 200 and the first and second wavelength selective means with a single WSS. Examples of suitable WSSs include the Finisar DWP50, DWP100 & DWP100E, and the JDSU Mini 100 ROADM. If controllable wavelength selective means, such as wavelength selective switches, are used to form a tunable splitter then the first and second wavelength regions may comprise one or more sub-regions of the transmission window, which need not be contiguous. Further to the discussion above with regard to FIG. 6, then if controllable wavelength selective means are used to form a tunable splitter having three or more wavelength regions then each of these wavelength regions may comprise one or more sub-regions of the transmission window, which need not be contiguous.

Similarly, if the first optical signal were to comprise non-coherent DWDM signals and the second optical signals were, to comprise flexgrid signals then the first wavelength selective means may comprise a conventional WSS and the second wavelength selective means may comprise a flexgrid WSS. If a WSS is used to implement the tunable splitter then it may be possible to utilize spare ports on an existing WSS which is being used to switch optical signals between different locations, as is described above with reference to FIG. 4.

It will be readily understood from the above discussion that the tunable splitter might take a number of different forms and be fabricated using a number of different technologies. It will be readily apparent to those skilled in the art that the exact form and nature of the tunable splitter is not relevant to the operation of a network according to embodiments as long as the tunable splitter can perform the function of splitting the first optical signals in the first region of the transmission window from the second optical signals in the second region of the transmission window.

The definition of the transmission window that can be used will be dependent on the performance of the tunable filters. Wavelengths from approximately 1525 to 1610 nm can be amplified by erbium-doped fiber amplifiers so there is no need for a filter that is tunable over a larger wavelength range than this. It should be understood that it is not necessary for a filter to be tunable over the entirety of the transmission window. For example, if the transmission window extends from 1525-1565 nm then filters that are tunable over a range of 30 nm would allow the first region of the transmission window to be varied from a lower limit of 1525 up to 1555 nm whilst the second region could be varied accordingly from an upper limit of 1565 nm down to 1535 nm. If the transmission window is narrower, or if the filters are tunable over a greater wavelength range, then the first region may occupy the entirety of the transmission window with the second region not transmitting any wavelengths, or vice versa. It will be understood that these principles apply equally to tunable filters which support three or more wavelength regions.

In summary, embodiments provide a communications network wherein first and second optical signals can be launched into an optical fiber in respective first and second regions of a transmission window such that controllable filters can be used to selectively recover the first and second optical signals. This partitioning of the transmission window allows two incompatible optical signals to coexist in the same optical fiber.

Claims

The invention claimed is:

1. An optical communications network comprising:

a first optical source configured, in use, to generate a first optical signal in a first wavelength region, the first optical signal comprising one or more non-coherent optical signals being transmitted at wavelengths associated with a predetermined wavelength grid;

a second optical source configured, in use, to generate a second optical signal in a second wavelength region, the second optical signal comprising one or more coherent optical signals;

combining means to launch the first optical signal and the second optical signal into an optical fiber; and

a separation means which can be configured, in use, to selectively route optical signals in the first wavelength region to a first output port and optical signals in the second wavelength region to a second output port, wherein, in use, the separation means can be controlled to vary the wavelengths defined by at least one of the first wavelength region or the second wavelength region.

2. An optical communications network according to claim 1, wherein the separation means comprise one or more tunable optical filters.

3. An optical communications network according to claim 2, wherein the one or more tunable optical filters have a cut off wavelength, the filters being configured, in use, to selectively route optical signals in the first wavelength region to a first output port and optical signals in the second wavelength region to a second output port.

4. An optical communications network according to claim 1, wherein the separation means comprise one or more wavelength selective switches, the switches being configured, in use, to selectively route optical signals in the first wavelength region to a first output port and optical signals in the second wavelength region to a second output port.

5. A method of operating a communications network, the method comprising:

generating a first optical signal in a first wavelength region, the first optical signal comprising one or more non-coherent signals being transmitted at wavelengths associated with a predetermined wavelength grid;

generating a second optical signal in a second wavelength region, the second optical signal comprising one or more coherent optical signals;

launching the first optical signal and the second optical signal into a first end of an optical fiber; and at a second end of the optical fiber;

selectively routing optical signals in the first wavelength region to a first output port;

selectively routing optical signals in the second wavelength region to a second output port; and

varying the wavelengths defined by at least one of the first wavelength region or the second wavelength region.