The present disclosure relates to optical networks and in particular to optical distribution networks and optical devices comprised therein.
The number of subscribers of communication networks is constantly increasing. The distribution of these subscribers may vary substantially. There are subscribers located in distant rural areas and there are subscribers in areas of very high concentration of subscribers, e.g. in buildings, such as office buildings.
Different techniques may be suitable to provide services to different subscribers depending on the concentration of subscribers, the amount of traffic the subscribers generate and the accessibility of the area in which the subscribers are located.
One example of a technique is in e.g. an office building where a Radio Base Station, RBS may be located in a central office. The central office is connected to a fibre network comprising Optical Network Terminations, ONTs connected to e.g. radio heads in different places of the office building. In this manner, subscribers may communicate wirelessly to a communication network via the radio heads, the fibre network and the RBS.
Any network, fibre based, wireless or wire based, should provide a high level of reliability. In case a fault or failure occurs somewhere in/on the network, measures should be defined that can be taken in order to overcome the fault or failure. Such measures should be cost effective and efficient. One obvious solution of duplicating every component in a communication network may be very reliable but very expensive hence such a solution is often even an option.
The object is to obviate at least some of the problems outlined above. In particular, it is an object to provide an optical device and a method performed by an optical device for partitioning a received signal and outputting the partitions via two outputs. A further object is to provide an optical distribution network comprising a Central Office, CO, connected to a fibre ring structure and at least two Optical Network Terminations, ONTs, the ONTs being connected to the CO by the fibre ring structure, wherein each ONT is connected to the fibre ring structure by means of a respective optical device and a method performed by the optical distribution network. These objects and others may be obtained by providing an optical device and a method performed by the optical device according to the independent claims attached below. These objects and others may be obtained by providing an optical distribution network and a method performed by the optical distribution network according to the independent claims attached below.
According to an aspect an optical device having three ports, each port being operable as both an input and an output interface, and the optical device receives an input signal on one of the three ports and splits the received input signal into two partitions and outputs the respective partition on the two other ports is provided. The optical device has a first port, a second port and a third port, each port being operable as both an input and an output interface. The first port is adapted to receive an input signal, to split the signal and to output a first portion, A, of the received signal through the second port and to output a second portion, B, of the received signal through the third port, wherein the first portion, A, of the received signal is larger than the second portion, B, of the received signal. The second port is adapted to receive an input signal, to split the received signal and to output a first portion, C, of the signal through the first port and to output a second portion, D, of the received signal through the third port, wherein the first portion, C, of the received signal is larger than the second portion, D, of the received signal. The third port is adapted to receive an input signal, to split the signal and to output a first portion, E, of the received signal through the first port and to output a second portion, F, of the received signal through the second port.
According to an aspect, an optical distribution network comprising a CO connected to a fibre ring structure and at least two ONTs, the ONTs being connected to the CO by the fibre ring structure, wherein each ONT is connected to the fibre ring structure by means of a respective optical device is provided. The optical distribution network comprises the CO connected to a fibre ring structure and at least two ONTs, the ONTs being connected to the CO by the fibre ring structure, wherein each ONT is connected to the fibre ring structure by means of a respective optical device. The CO is adapted to transmit a signal to the ONTs in either direction of the fibre ring structure, wherein the optical devices are adapted to receive the signal from the CO, to direct a fraction of the signal to the respective ONT and to direct a remaining portion of the signal to the ring structure.
According to an aspect, a method performed by an optical device is provided. The optical device has a first, a second and a third port, each port being operable as both an input and an output interface. The method comprises receiving an input signal on one of the three ports and splitting the received signal into two portions and transmitting each of the respective two portions of the received signal on the other two ports, wherein when the input signal is received on the first port, the method comprises splitting the received signal and outputting a first portion, A, of the signal through the second port and outputting a second portion, B, of the received signal through the third port, wherein the first portion A of the received signal is larger than the second portion B of the received signal. When the input signal is received on the second port, the method comprises splitting the signal and outputting a first portion, C, of the received signal through the first port and outputting a second portion, D, of the received signal through the third port, wherein the first portion C of the received signal is larger than the second portion D of the received signal. When the input signal is received on the third port, the method comprises splitting the received signal and outputting a first portion, E, of the received signal to the first port and outputting a second portion, F, of the received signal to the second port.
According to an aspect, a method performed by an optical distribution network is provided. The optical distribution network comprises a CO connected to a fibre ring structure and at least two ONTs, the ONTs being connected to the CO by the fibre ring structure, wherein each ONT is connected to the fibre ring structure by means of a respective optical device. The method comprises the CO transmitting a signal to the ONTs in either direction of the fibre ring structure, the optical devices respectively receiving the signal from the CO, directing a fraction of the received signal to the respective ONT and directing a remaining portion of the signal to the ring structure.
Embodiments will now be described in more detail in relation to the accompanying drawings, in which:
Briefly described, an optical device and a method performed by the optical device for receiving a signal, partitioning the signal and outputting the partitions of the signal are provided. Further, an optical distribution network and a method performed by the optical distribution network are provided for communicating between a central office and optical network terminations connected to the central office by optical terminals, all comprised in the optical distribution network are provided. The optical device has three ports, each port being operable as both an input and an output interface, and the optical device receives an input signal on one of the three ports and splits the received input signal into two partitions and outputs the respective partition on the two other ports.
An exemplifying embodiment of such an optical device will now be described with reference to
The optical device thus has three ports, port 1, port 2 and port 3. Each of these ports may operate as an input and an output meaning that the optical device 100 may receive an input signal on either one of the three ports. Depending on which port receives the signal, the signal may be split in different ways. As stated above, if the input signal is received on the first port 110, the signal is split in two portions, A and B and portion A of the signal is outputted from the optical device on the second port 120 and the portion B of the signal is outputted on the third port, wherein portion A is larger than portion B. A portion of a signal will be described in more detail below. In this manner, a received input signal being received on port 1 is split such that a larger portion of the signal is outputted from the optical device via the second port 120 and a smaller portion of the signal is outputted from the optical device via the third port 130. Similarly a received input signal being received on port 2 is split such that a larger portion of the signal is outputted from the optical device via the first port 110 and a smaller portion of the signal is outputted from the optical device via the third port 130. An input signal being received by the optical device on port 3 is split in two portions and outputted the first port 110 and second port 120. If the input signal is received on the third port, there is no limitation on how the input signal shall be split, or in other words, the size of portions E and F are arbitrary. Hence, portion E and F of the received input signal may be of the same size, portion E may be larger than portion F or portion F may be larger than portion E of the received input signal.
The optical node may have several advantages. When used in e.g. an optical distribution network connecting a node to an optical fibre, the optical device is enabled to receive a downlink transmission to the node, the downlink transmission being transmitted in any direction on the optical fibre. By splitting a received input signal such that a fraction of the received input signal is outputted on one port and a remaining portion of the signal is outputted to another port, the optical device is flexible and may be designed to optimise communication in the optical distribution network. Further, in case the optical network in which the optical device is employed changes transmission direction on the optical fibre, the optical device is still enable to receive a transmission and divert a fraction thereof to the third port and the remaining portion to the other port.
According to an embodiment, illustrated in
For simplicity, assume that the signal power is 100 watt, this signal power could alternatively be expressed in percent e.g. 100%. Then out of this 100 watt or %, a fraction of the signal power is directed to the second portion B, D or F, and the remaining signal power out of the 100 Watt is directed to the first portion A, C or E. The power of the fraction of the signal power directed to the second portion B or D is smaller than the power of the remaining signal power directed to the first portion A or C. In other words, maximum 49 watt or 49% of the signal power may be directed to portion B or D, i.e. maximum 49 watt or 49% of the received signal is outputted from the optical device via the third port and minimum 51 watt or 51% of the received signal power is outputted from the optical device via the first port or the second port respectively.
In an example, the second portion B or D of the signal or the fraction of the signal power directed to the second portion B or D is maximum 40% of the received signal power, wherein the first portion A or C of the signal or the remaining signal power directed to the first portion A or C is minimum 60% of the received signal power.
In another example, the second portion B or D of the signal or the fraction of the signal power directed to the second portion B or D is maximum 10% of the received signal power, wherein the first portion A or C of the signal or the remaining signal power directed to the first portion A or C is minimum 90% of the received signal power.
Of course other examples of the relationship between the first portion A or C and the second portion B or D are possible. It shall also be pointed out that the relationship between portion A and B may be the same or other than the relationship between portion C and D. For example, if the optical device receives the input signal on port 1, 5% of the signal is outputted on port 3 and 95% of the signal is outputted on port 2, but if the optical device receives the input signal on port 2, 11% of the signal is outputted on port 3 and 89% of the signal is outputted on port 1,
According to an embodiment, illustrated in
In an example, the number of wavelengths directed to the second portion B or D is at least 1.
To exemplify such scenarios, a received signal comprises a plurality of wavelengths. Merely as an example, assume the received input signal comprises wavelengths λ1, λ2, λ3, λ4, λ5, λ6 and λ7. In this example, if the input signal is received on port 1 or 2, i.e. the first port 110 or the second port 120, then wavelength λ4 being portion B or D respectively is directed to port 3, i.e. the third port 130, and the remaining wavelengths, λ1, λ2, λ3, λ5, λ6 and λ7 being portion A or C are directed to the other port, i.e. port 2 (if the signal is received on port 1) or port 1 (if the signal is received on port 2) respectively. It shall be pointed out that this is merely an example and in another example, if the input signal is received on port 1 or 2, i.e. the first port 110 or the second port 120, then wavelengths λ2 and λ3 being portion B or D are directed to port 3, i.e. the third port 130, and the remaining wavelengths, λ1, λ4, λ5, λ6 and λ7 being portion A or C are directed to the other port, i.e. port 2 (if the signal is received on port 1) or port 1 (if the signal is received on port 2) respectively.
Embodiments herein also relate to an optical distribution network comprising a Central Office, CO, connected to a fibre ring structure and at least two Optical Network Terminations, ONTs, the ONTs being connected to the CO by the fibre ring structure, wherein each ONT is connected to the fibre ring structure by means of a respective optical device.
Such embodiments of an optical distribution network will now be described with reference to
The CO 210 is illustrated being connected to the fibre ring structure 215 via a switch 240. The switch 240 illustrates that the CO may transmit signals in clockwise direction, counter clockwise direction or in both directions simultaneously. This means also that the CO is enabled to receive signals in either direction. Merely as an example, assume that the CO 210 transmits a signal in counter clockwise direction so that the first optical device to receive the signal is the first optical device 200-1. also denoted OD 1. The first optical device 200-1 thus directs a fraction of the received signal to the ONT connected to it, that is the first ONT 230-1, also denoted ONT 1. The first optical device 200-1 directs the remaining portion of the signal to the ring structure, towards the second optical device 200-2, also denoted OD 2. The second optical device 200-2 directs a fraction of the received signal to the ONT connected to it, that is the second ONT 230-2, also denoted ONT 2. The second optical device 200-2 directs the remaining portion of the signal to the ring structure, towards the third optical device 200-3, and so on. It shall be pointed out that each optical device may have an individual ratio between the fraction of the received signal to be directed to a respective ONT and the remaining signal which is re-introduced to the fibre ring structure, or forwarded to a neighbouring optical device and ONT.
In this manner, the signal transmitted by the CO 210 (also referred to as a downlink signal) may be distributed to all ONTs 230-1 to 230-n on the fibre ring structure. Again it shall be pointed out that the CO 210 may alternatively transmit the signal in the opposite direction such that optical device 200-n is the first optical device to receive the signal transmitted from the CO 210. Alternatively, the CO 210 may transmit one signal in one the direction and simultaneously, or consecutively, transmit one signal in the opposite direction.
A signal transmitted by an ONT 230230-1 to 230-n (also referred to as an uplink signal) will be received by its respective optical device 200-1 to 200-n. The optical devices will split the uplink signal received from respective ONTs and output a first part of the uplink signal on its first port and a second part of the uplink signal on its second port. Hence, uplink signals transmitted from the ONT may propagate in both directions, clockwise and counter clockwise, to be received by the CO 210.
The optical distribution network may have several advantages. The optical devices are enabled to receive a downlink transmission to a node (ONT), the downlink transmission being transmitted in any direction on the optical fibre. By splitting a received input signal such that a fraction of the received input signal is outputted on one port and a remaining portion of the signal is outputted to another port of the optical device. the optical device is flexible and may he designed to optimise communication in the optical distribution network. Further, in case the optical network in which the optical device is employed changes transmission direction on the optical fibre, the optical device is still enable to receive a transmission and divert a fraction thereof to the third port and the remaining portion to the other port.
According to an embodiment, at least one of the optical devices 200-1, 200-2, 200-n corresponds to the optical device 100 described above in conjunction with
In an example, the first port and the second port of the optical device are connected to the fibre ring structure 215 and the third port of the optical device is connected to a respective ONT 230-1, 230-2, 230-n.
The optical device 100 described above enable flexible design of the optical distribution network. Merely as an example, assume that there are seven optical devices and hence seven ONTs comprised in the fibre ring structure 215. Assume that the CO 210 sends a signal comprising seven wavelengths and that the CO 210 sends the signal in counter-clockwise direction so that the first optical device 200-1 receives the signal first. The signal comprises wavelengths λ1, λ2, λ3, λ4, λ5, λ6 and λ7. In this example, the input signal is received on the first port of the first optical device 200-1. The first optical device directs a first portion of the wavelengths to the second ports to be outputted from the optical device and a second portion of the wavelengths to the third port to be outputted to the first ONT 230-1. The second portion comprises wavelength λ1 and the second portion comprises wavelengths λ2, λ3, λ4, λ5, λ6 and λ7. This means that λ1 and is outputted from the first optical device 200-1 to the first ONT 230-1 and the remaining wavelengths λ2, λ3, λ4, λ5, λ6 and λ7 are outputted by the second port of the optical device to the fibre ring 215 in direction towards the second optical device 200-2. The second optical device receives the signal comprising wavelengths λ2, λ3, λ4, λ5, λ6 and λ7 on its first port, directs wavelength λ2 to the second ONT 230-2 and directs the remaining wavelengths λ3, λ4, λ5, λ6 and λ7 to its second port to be outputted from the second optical device 200-2 on the fibre ring structure 215 in direction towards the third ONT and so on. Hence, each optical device in this example directs one wavelength to a respective ONT being connected to it and forwards the remaining wavelengths to a neighbouring optical device and ONT. The seventh optical device will however only receive one wavelength, λ7, which it will direct to its ONT and there will be no remaining wavelength to output via its second port to the fibre ring structure 215. Thus the CO 210 may send one signal comprising all wavelengths to be delivered to a plurality of ONTs 230.
Should the CO 210 however change transmission direction so that the seventh optical device receives the signal comprising all wavelengths λ1, λ2, λ3, λ4, λ5, λ6 and λ7, the seventh optical device receives the signal on its second port. The seventh optical device may then direction a fraction of the wavelengths, i.e. the signal, to its third port for outputting to its ONT, the fraction being λ7 and output the remaining portion of the signal, i.e. wavelengths λ1, λ2, λ3, λ4, λ5 and λ6 from its first port to be received by the sixth optical device on its second port. The sixth optical device hence receives the signal comprising wavelengths λ1, λ2, λ3, λ4, λ5 and λ6 on its second ports, directs a fraction of the signal, i.e. λ6, to its third port for outputting to its ONT and the remaining signal comprising wavelengths λ1, λ2, λ3, λ4 and λ5 to its first port for outputting towards the fifth optical device, and so on. The first optical device 200-1 will however only receive one wavelength, λ1, which it will direct to its ONT 230-1 and there will be no remaining wavelength to output via its first port to the fibre ring structure 215.
In yet another example, the CO 210 outputs a signal comprising wavelengths λ1, λ2 and λ3 in a counter clockwise direction and a signal comprising wavelengths λ4, λ5, λ6 and λ7 in a clockwise direction. Hence, first optical device 200-1 receives, on its first port, the input signal comprising wavelengths λ1, λ2 and λ3. The first optical device directs a first portion of the wavelengths to the second ports to be outputted from the optical device and a second portion of the wavelengths to the third port to be outputted to the first ONT 230-1. The second portion comprises wavelength λ1 and the second portion comprises wavelengths λ2 and λ3. This means that λ1 and is outputted from the first optical device 200-1 to the first ONT 230-1 and the remaining wavelengths λ2 and λ3 are outputted by the second port of the optical device to the fibre ring 215 in direction towards the second optical device 200-2, and so on. The seventh optical device receives, on its second port, the input signal comprising wavelengths λ4, λ5, λ6 and λ7. The seventh optical device may then direction a fraction of the wavelengths, i.e. the signal, to its third port for outputting to its ONT, the fraction being λ7 and output the remaining portion of the signal, i.e. wavelengths λ4, λ5 and λ6 from its first port to be received by the sixth optical device on its second port, and so on.
According to an embodiment, the CO 210 is adapted to detect a fault or failure on the fibre ring structure 215, and in response to detecting the fault or failure, to change the transmission direction of at least a part of the signal on the fibre ring structure.
In an example, the CO 210 is adapted to, in response to detecting the fault or failure, transmitting a first part of the signal in a first direction of the fibre ring structure and transmitting a second part of the signal in the opposite direction on the fibre ring structure 215.
Looking at
Any ONT 230-1 to 230-4 transmitting an uplink signal to the CO 210 will still be able to do so successfully since each respective optical device splits the uplink signal and outputs a first part to its first port and a second part to its second port. In this example, all respective parts of an uplink signal from an ONT being outputted on the first port of a respective optical device will be lost, but all parts of an uplink signal from an ONT being outputted on the second port of a respective optical device will be received by the CO, since each uplink signal will propagate successfully from the second port in the counter clockwise direction towards the CO 210.
Assume that the CO 210 is transmitting only in clockwise direction so that the fourth optical device 200-4 is the first optical device to receive the signal. If a fault occurs at e.g. location F5, then no optical device may be able to receive the signal and hence the whole optical distribution network fails. If a fault occurs at location F5, the CO 210 may switch transmission direction of the whole signal so that the whole signal is transmitted in counter clockwise direction. Then all optical devices may be able to receive a signal from the CO 210.
Any ONT 230-1 to 230-4 transmitting an uplink signal to the CO 210 will still be able to do so successfully since each respective optical device splits the uplink signal and outputs a first part to its first port and a second part to its second port. In this example, all respective parts of an uplink signal from an ONT being outputted on the second port of a respective optical device will be lost, but all parts of an uplink signal from an ONT being outputted on the first port of a respective optical device will be received by the CO 210, since each uplink signal will propagate successfully from the second port in the clockwise direction towards the CO 210.
In case a fault occurs at any other possible location, F2, F3 or F4, then the CO may transmit a first part of the signal in a first direction of the fibre ring structure and transmitting a second part of the signal in the opposite direction on the fibre ring structure. Assume for example that the CO 210 is transmitting in either the clockwise direction or the counter clockwise direction. Assume a fault occurs at any of fault locations F2, F3 or F4. Then, by transmitting a first part of the signal in a first direction, e.g. counter clockwise direction and a second part of the signal in a second direction, e.g. clockwise direction, each optical device, and consequently each ONT, may receive the signal. Merely as an example, assume that a fault occurs at fault location F2. Then the CO 210 transmits a first part of the signal in the counter clockwise direction, which is received by the first optical device 210-1. The CO 210 transmits a second part of the signal in the clockwise direction, which is received by the forth, third and second optical device 210-4, 200-3 and 200-2. Any uplink transmission from the first ONT 230-1 will be split by the first optical device 200-1, and the part of the uplink signal outputted on its first port may be successfully received by the CO 210. Any uplink transmission from ONT 2, ONT 3 or ONT 4 will likewise be split at respective optical device 200-2, 200-3 and 200-4, wherein parts outputted on respective first ports of the optical devices may be lost due to the fault or failure at F2. However, parts outputted on respective second ports of the optical devices, propagating in the counter clockwise direction, may be successfully received by the CO 210.
According to an embodiment, the signal is transmitted with an original transmission power before detection of the fault or failure and in the first direction, wherein transmitting the first part of the signal in the first direction of the fibre ring structure corresponds to transmitting the signal at a fraction of the original transmission power in the first direction and transmitting the second part of the signal in the opposite direction on the fibre ring structure corresponds to transmitting the signal with a transmission power equal to the original transmission power minus the fraction of the original transmission power in the opposite direction on the fibre ring structure.
Assume again that the original signal is transmitted at a transmission power of 100 watt or 100% and in the first direction. In case a fault or failure is detected, the CO 210 may transmit a first part of the signal, e.g. 40 watt or 40% in the first direction and transmit 60 watt or 60% in the opposite direction on the fibre ring structure. Assume that the optical distribution network comprises four ONTs as illustrated in
According to an embodiment, the signal transmitted before detection of the fault or failure comprises a plurality of wavelengths and the signal is transmitted in the first direction, wherein transmitting the first part of the signal in the first direction on the fibre ring structure corresponds to transmitting some of the wavelengths of the plurality of wavelengths in the first direction and transmitting the second part of the signal in the opposite direction on the fibre ring structure corresponds to transmitting the remaining wavelengths of the plurality of wavelengths in the opposite direction on the fibre ring structure.
Referring again to
According to still an embodiment, the CO further is adapted to locate where on the fibre ring structure the fault or failure has occurred; and determining the size of the fraction of the original transmission power to be sent in the first direction and the size of the original transmission power minus the fraction of the original transmission power to be sent in the opposite direction or determining which wavelengths should be transmitted in the first direction and which remaining wavelengths should be transmitted in the opposite direction based on the location of the fault or failure.
By locating the fault or failure, the CO 210 is enabled to determine the size of the fraction of the original transmission power to be sent in the first direction and the size of the original transmission power minus the fraction of the original transmission power to be sent in the opposite direction or determining which wavelengths should be transmitted in the first direction and which remaining wavelengths should be transmitted in the opposite direction based on the location of the fault or failure.
Looking at
In case a fault or failure occurs at F2, then the CO 210 may decide to transmit only wavelength λ1 of a downlink signal comprising wavelengths λ1, λ2, λ3 and λ4 in the counter clockwise direction and the remaining wavelengths λ2, λ3 and λ4 in the clockwise direction. Alternatively, the CO may decide to transmit an original signal of 100 watt or 100% with 25 watt or 25% in the counter clockwise direction and transmit 75 watt or 75% of the original signal of 100 watt or 100% in the clockwise direction.
In case a fault or failure occurs at F4, then the CO 210 may decide to transmit wavelengths λ1 and λ2 of a downlink signal comprising wavelengths λ1, λ2, λ3 and λ4 in the counter clockwise direction and the remaining wavelengths λ3 and λ4 in the clockwise direction. Alternatively, the CO may decide to transmit an original signal of 100 watt or 100% with 75 watt or 75% in the counter clockwise direction and transmit 25 watt or 25% of the original signal of 100 watt or 100% in the clockwise direction.
The embodiments described above address the optical backhaul/fronthaul area as well as fixed access. All of them are further described with most generic term Fibre-To-The-X (FTTX), where X states for any placement of the fibre termination at the downstream/downlink side. So X could be C for Curb, B for Building, A for Antenna, Rh for Radio Head etc. The transmission may be analogue or digital, Common Public Radio Interface CPRI or packet. The embodiments are directed towards the physical, PHY, layer of the optical distribution network.
The embodiments improve reliability of the optical distribution network and therefore the complete access/backhaul/fronthaul system. This is achieved through ring structure of the optical distribution network and special optical devices. The optical devices are fully passive, simple and cheap.
The optical distribution network may be a Passive Optical Network (PON) employing Time Division Multiplexing, TDM-PON, or Wavelength Division Multiplexing, WDM-PON. A WDM-PON may be supported by optical distribution network s with in-field filtering, e.g. Arrayed Waveguide Gratings, AWGs, or with optical power splitters followed by filtering capability at the ONT side. On the other hand, TDM-PON can be only realized on splitter-based optical distribution network.
Cascades of splitters as well as different mixes of the above are also possible. The presented embodiments are applicable to both WDM and TDM transmission, but for the sake of clarity and simplicity, only WDM transmission has been described above. WDM transmission provides wavelength point-to-point connectivity on a shared fibre plant, so no special time synchronisation is needed.
It shall be noted that power splitters (illustrated in
The switch 240 illustrated in
In case the optical device comprises add-drop filters as illustrated in
Embodiments herein also relate to a method performed by the optical device. The method has the same technical features, objects and advantages as the optical device. The method performed by the optical device will only be described in brief in order to avoid unnecessary repetition.
The method performed by the optical device has the same advantages as the optical device. When the optical device is used in e.g. an optical distribution network connecting a node to an optical fibre, the optical device is enabled to receive a downlink transmission to the node, the downlink transmission being transmitted in any direction on the optical fibre. By splitting a received input signal such that a fraction of the received input signal is outputted on one port and a remaining portion of the signal is outputted to another port, the optical device is flexible and may be designed to optimise communication in the optical distribution network. Further, in case the optical network in which the optical device is employed changes transmission direction on the optical fibre, the optical device is still enable to receive a transmission and divert a fraction thereof to the third port and the remaining portion to the other port.
According to an embodiment, the received signal has a signal power, wherein splitting the signal into the first portion A, C or E and the second portion B, D or F comprises directing a fraction of the signal power to the second portion B, D or F and the remaining signal power to the first portion A, C or E, wherein the power of the fraction of the signal power directed to the second portion B or D is smaller than the power of the remaining signal power directed to the first portion A or C.
According to still an embodiment, the second portion B or D of the signal or the fraction of the signal power directed to the second portion B or D is maximum 40% of the received signal power, wherein the first portion A or C of the signal or the remaining signal power directed to the first portion A or C is minimum 60% of the received signal power.
According to yet an embodiment, the second portion B or D of the signal or the fraction of the signal power directed to the second portion B or D is maximum 10% of the received signal power, wherein the first portion A or C of the signal or the remaining signal power directed to the first portion A or C is minimum 90% of the received signal power.
According to an embodiment, the received signal comprises a plurality of wavelengths, wherein splitting the signal into the first portion A, C or E and the second portion B, D or F comprises directing some of the wavelengths of the signal to the first portion A, C or E and the remaining wavelengths of the signal to the second portion B, D or F, wherein the number of wavelengths in portion A and C are higher than the number of wavelength in portion B and D.
According to still an embodiment, the number of wavelengths directed to the second portion B or D is at least 1.
Embodiments herein also relate to a method performed by the optical distribution network. The method has the same technical features, objects and advantages as the optical distribution network. The method performed by the optical distribution network will only be described in brief in order to avoid unnecessary repetition.
The method performed by the optical distribution network has the same advantages as the optical distribution network. The optical devices are enabled to receive a downlink transmission to a node (ONT), the downlink transmission being transmitted in any direction on the optical fibre. By splitting a received input signal such that a fraction of the received input signal is outputted on one port and a remaining portion of the signal is outputted to another port of the optical device, the optical device is flexible and may be designed to optimise communication in the optical distribution network. Further, in case the optical network in which the optical device is employed changes transmission direction on the optical fibre, the optical device is still enable to receive a transmission and divert a fraction thereof to the third port and the remaining portion to the other port.
According to an embodiment, at least one optical device performs the method described above in conjunction with
According to still an embodiment illustrated in
According to still an embodiment, the method further comprises the CO, in response to detecting the fault or failure, transmitting a first part of the signal in a first direction of the fibre ring structure and transmitting a second part of the signal in the opposite direction on the fibre ring structure.
According to yet an embodiment, the signal is transmitted with an original transmission power before detection of the fault or failure and in the first direction, wherein transmitting the first part of the signal in the first direction of the fibre ring structure corresponds to transmitting the signal at a fraction of the original transmission power in the first direction and transmitting the second part of the signal in the opposite direction on the fibre ring structure corresponds to transmitting the signal with a transmission power equal to the original transmission power minus the fraction of the original transmission power in the opposite direction on the fibre ring structure.
According to an embodiment, the signal transmitted before detection of the fault or failure comprises a plurality of wavelengths and the signal is transmitted in the first direction, wherein transmitting the first part of the signal in the first direction on the fibre ring structure corresponds to transmitting some of the wavelengths of the plurality of wavelengths in the first direction and transmitting the second part of the signal in the opposite direction on the fibre ring structure corresponds to transmitting the remaining wavelengths of the plurality of wavelengths in the opposite direction on the fibre ring structure.
According to still an embodiment, the method further comprises the CO further locating 455 where on the fibre ring structure the fault or failure has occurred; and determining the size of the fraction of the original transmission power to be sent in the first direction and the size of the original transmission power minus the fraction of the original transmission power to be sent in the opposite direction or determining which wavelengths should be transmitted in the first direction and which remaining wavelengths should be transmitted in the opposite direction based on the location of the fault or failure.
While the embodiments have been described in terms of several embodiments, it is contemplated that alternatives, modifications, permutations and equivalents thereof will become apparent upon reading of the specifications and study of the drawings. It is therefore intended that the following appended claims include such alternatives, modifications, permutations and equivalents as fall within the scope of the embodiments and defined by the pending claims.
Filing Document | Filing Date | Country | Kind |
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PCT/SE2013/050598 | 5/24/2013 | WO | 00 |