The present invention relates to an apparatus and method for a Passive Optical Network, for example a Passive Optical Network employing Wave Division Multiplexing (WDM-PON), and in particular to an apparatus and method for performing monitoring functions (for example Operations, Administration and Maintenance monitoring functions), in a Passive Optical Network. The OAM monitoring functions may be configured to monitor the synchronization characteristics of timing critical signals (for example Common Public Radio Interface, CPRI signals).
There are a number of applications in telecommunication networks that require accurate frequency and/or time synchronization references in order to operate properly, for example mobile technologies such as GSM, WCDMA and in the future LTE.
In the case of frequency synchronization the traditional solution is to obtain synchronization from a synchronous stream of data, for example as used in Time Division Multiplexing (TDM) based networks. However, the migration of networks from TDM to packet based technologies (such as Ethernet and Internet protocol) requires a different approach.
One solution is to use a packet based method, in which timing information is carried across a packet network (i.e. physical layer) by sending packets that contain timestamp information. The timestamps are generated by a master (server) that has access to an accurate reference, for example a Primary Reference Clock (PRC) that utilises GPS technologies.
When time synchronization is requested, a two-way timing protocol is mandatory in applications such as Network Time Protocol (NTP) and Precision Time Protocol (PTP) where the transfer delay from master to slave is calculated.
One fundamental assumption with a two-way timing protocol approach is that the delay from master to slave and from slave to master shall be identical. This is because the mean path delay is calculated as half of the round trip delay. As a consequence, this has the disadvantage that any asymmetry in the network (that causes a different delay from master to slave compared to slave to master) will have a significant impact on the performance of the delivered time synchronization reference.
In some cases radio access can be implemented using an architecture where the radio control is separated from the remote radio access. This architecture can be based, for instance, on the Common Public Radio Interface (CPRI) Specification as illustrated in
The following assumptions are made in the CPRI Specifications:
Time synchronisation is delivered from a Radio Equipment Controller (REC) to Radio Equipment (RE) via a 2-way exchange (similar to the IEEE1588 standard).
To support the most stringent applications a requirement is defined in the order of a few nano seconds. This is mainly related to internal measurement accuracy (and the assumption of an ideal connection).
Additional latency requirements are applicable in the case of CPRI in order to optimize the design of the REC (but this is not specified in the CPRI specification). The exact figure is not standardized but may be in the order of 100-200 microseconds (round trip delay).
The architecture shown in
Alongside the developments above, Optical Transport Networks (OTNs) are currently being considered (for example to provide CPRI over OTN), but due to the stringent synchronization requirements the existing OTN does not generally allow the stringent requirements mentioned above to be met.
In order to transport the CPRI over standardized transport technologies, one possible solution is to use new optimized OTN solutions with high timing accuracy, for example controlling asymmetries in the mapping and Forward Error Correction (FEC) process, and automatically compensating for asymmetries in the system that may be caused by the use of different fiber wavelengths and the use of different fiber lengths.
A disadvantage of such an approach is the significant upgrade required to OTN nodes, which increases complexity and cost. Furthermore, it is not clear whether such solutions provide the synchronization performance that is required.
It is an aim of the present invention to provide a method and apparatus which obviate or reduce at least one or more of the disadvantages mentioned above.
According to a first aspect of the present invention there is provided a method in a passive optical network. The method comprises the steps of using a particular wavelength for both an uplink transmission and a downlink transmission to provide a symmetrical bi-directional communication channel over an optical link. At least one monitoring measurement is performed in the symmetrical bi-directional communication channel. Monitoring information, comprising the at least one monitoring measurement, is provided in a monitoring channel of the passive optical network.
The invention has the advantage of enabling an accurate monitoring of synchronization to be performed. This is because the use of a particular wavelength for both the uplink and the downlink of an optical link (or optical fiber) ensure a symmetrical channel (hence not affecting mean time-delay calculations), while the provision of a monitoring channel enables performance measurements to be made visible to a user or operator.
According to another aspect of the invention there is provided a passive optical network comprising a first node configured to transmit a downlink data signal over a communication channel of an optical link, the communication channel having a first wavelength, and a second node configured to transmit an uplink data signal over the optical link using the communication channel having the first wavelength. The first node and/or the second node is adapted to perform at least one monitoring measurement on the communication channel having the first wavelength, and provide monitoring information, comprising the at least one monitoring measurement, in a monitoring channel.
According to another aspect of the present invention, there is provided a method of transporting common public radio interface (CPRI) traffic over an optical transport network (OTN). The method comprises the steps of using a frequency reuse technique to provide a symmetrical bi-directional communication link between a first node and a second node over an optical link, and using a frame structure of the optical transport network to provide a monitoring channel.
According to another aspect of the present invention, there is provided an optical network unit for a passive optical network. The optical network unit comprises a downlink optical receiver configured to receive a downlink data signal over a communication channel of an optical link, the communication channel having a first wavelength. The optical network unit also comprises an uplink optical transmitter configured to transmit an uplink data signal over the optical link using the communication channel having the first wavelength. A monitoring module is configured to perform at least one monitoring measurement on the communication channel having the first wavelength, and provide monitoring information, comprising the at least one monitoring measurement, in a monitoring channel.
For a better understanding of the present invention, and to show more clearly how it may be carried into effect, reference will now be made, by way of example only, to the following drawings in which:
The embodiments of the present invention relate to an apparatus and method for a Passive Optical Network, for example a Passive Optical Network employing Wave Division Multiplexing (WDM-PON). The embodiments are concerned with performing monitoring functions (for example Operations, Administration and Maintenance, OAM, monitoring functions) in a Passive Optical Network. The OAM monitoring functions may be configured to monitor the synchronization characteristics if timing critical signals (for example Common Public Radio Interface, CPRI, signals). It is noted, however, that other measurements are also intended to be embraced by the embodiments of the invention.
The various embodiments provide an enhanced point to point transport technique that is inherently accurate from a synchronization and asymmetry point of view. The provision of OAM and performance monitoring has advantages when timing critical services such as CPRI are being carried, as will be explained further below.
According to one embodiment the at least one monitoring measurement comprises a synchronization related measurement for determining the accuracy of synchronization, for example when using a precise measurement of one-way delay. It is noted, however, that the embodiments are intended to embrace other measurements being made, for example round trip delay.
The step of using a particular wavelength for both an uplink and a downlink transmission over the same optical link to build the bi-directional channel results in a symmetrical channel that enables the monitoring of the synchronization functions to be optimized.
According to one embodiment, using the same optical link and same wavelength for bi-directional communication is accomplished using the techniques described by the present Applicant in patent application WO2010/025767, which is being incorporated herein by reference. It is noted, however, that the invention is intended to embrace other techniques for providing symmetrical bi-directional communication.
The use of a standard framing structure defined for OTN can also be used to simplify the implementation of embodiments of the invention, such as the provision of the monitoring channel.
Therefore, as shown in
In general the following information could be sufficient and made available with the proposed approach, for monitoring the quality of the transport technology used for CPRI:
As described in the following section this can be made possible by making use of the solution described in WO2010/025767, for example, and using a standardized framing option, for example the framing option for OTN, as described in Recommendation G.709. Other wavelength reuse mechanisms may also be used.
The downlink Tx array 754 comprises a plurality of optical carrier signal sources in the form of lasers 756. The resulting plurality of IRZ line coded downstream data signals are multiplexed through an arrayed waveguide grating (AWG) 758 and coupled via the optical circulator (OC) 724 into a single mode feeder fiber 766, having a length of 20 km, for example, which forms the first part of the optical link.
The uplink Rx array 760 comprises a corresponding plurality of photodiodes 762. Upstream data signals are coupled to the photodiodes 762 from the feeder fiber 766 through the circulator 724 and a demultiplexed in a second AWG 764. The WDM-PON 700 comprises an Optical Network Unit (ONU) 730. The optical link in this embodiment comprises the single mode feeder fiber 766, a distribution fiber 770 and a third AWG 768 coupled between the feeder fiber 766 and the distribution fiber 770. In this example, the distribution fiber is a long reach distribution fiber having a length of 60 km, for example. The third AWG 768 acts to demultiplex the plurality of downstream data signals and route each to their respective distribution fiber 770 and ONU 26, or fiber 782 and short reach TDMA sub-network 781.
The ONU 726 comprises a downlink optical receiver 728 (comprising a photodiode 728a and a digital receiver 728b) configured to receive a first portion of a downstream data signal, and an uplink optical remodulator configured to receive a second portion of the downstream data signal and to both remodulate and amplify it to generate a return-to-zero (RZ) line coded upstream data signal. The ONU 726 further comprises a local clock signal source (not shown) associated with the downstream receiver 728.
The uplink optical remodulator comprises an electro-optic modulator in the form of a reflective semiconductor optical amplifier (R-SOA) 732, an RZ electronic data signal source 734. The R-SOA 732 in this example comprises a commercially available device providing 21 dB of small signal gain at 50 mA bias current, 2 dBm output saturation power, 1 dB polarization dependent gain and 8 db noise figure, and is biased at 70 mA. The R-SOA 732 is operated outside of its saturation regime. The seed signal received at the R-SOA 732 has a power level of not greater than P=G−15 P(max), where P is in dBm, G is the gain of the R-SOA in dB, and P(max) is the maximum optical output power of the R-SOA in dBm. In this example, the seed signal has a power of between −15 dBm and −35 dBm. The RZ data signal source generates a 7V peak-to-peak 1.25 Gb/s RZ data signal. An optical delay line (not shown) coupled to the output of the R-SOA 732 acts to synchronize the upstream data signal (i.e. the RZ data signal) with the downstream data signal, in conjunction with the local clock source, so that the upstream data signal is interleaved by one-half bit with respect to the incoming downstream data signal. This means that the RZ data signal is applied (i.e. the R-SOA remodulates and amplifies) only when the seed signal comprises a CW signal, as follows.
When the downstream data signal, comprises a dark pulse (a logical 1), the seed signal comprises the dark pulse tail, which is suppressed by the R-SOA 732 to form a logical 0 for the upstream data signal or is amplified by the R-SOA 732 to form a logical 1. When the downstream data signal comprises a light pulse (a logical 0), the seed signal comprises a CW light pulse having a duration equal to the full 30 clock cycle, one-half of the light pulse is suppressed by the R-SOA 732 to form a logical 1 or the whole pulse is suppressed by the R-SOA 732 to form a logical 0.
The third AWG 768 acts to multiplex a plurality of upstream data signals received from the ONU 726 or short reach TDMA sub-network 781 into the feeder fiber 766 for transmission upstream to the OLT 752.
One or more of the carrier signal wavelengths is used for a short reach TDMA sub-network 781 from the third AWG 768 (only 1, As, is shown for clarity). The TDMA sub-network 781 comprises a short reach distribution fiber 782, a 1×N (in this example 1×6) optical power splitter 784 and six ONUs 726.
Although
In order to provide round trip measurements with precision of a few nano seconds, preferably, a free running oscillator having an accuracy of at least 5 ppm, for example, or a frequency locked oscillator are provided at the ONT.
The particular embodiment of
According to one embodiment, the monitoring channel (for example providing an Operations, Administration and Maintenance connection) is embedded in a standard OTN framing architecture. For example, the OAM data can be carried over the overhead.
It is noted that a Delay Measurement of a round trip delay could also make use of the predefined bits in the ODUk PM delay measurement (DMp) as per ITI-T recommendation G.709, for example.
By making the measurement on the same optical link, and using the same wavelength, this ensures that an accurate one-way delay measurement is obtained.
The embodiments described above can be optimized further, if desired, in order to control the possible asymmetries due to mapping and FEC in the two directions. This can be done by the OLT and ONU, for example, by monitoring a buffer position in the OLT and communicating this information to the ONU so that it can compensate for possible differences between the two mapping logic.
An advantage of the proposed method is that WDM PON is enhanced with OAM functionality and a monitoring channel, which are especially important when timing critical services such as CPRI are carried.
A dedicated monitoring channel per ONT allows resources to be optimized and measurements to be simplified. This is made possible by using the same lambdas (wavelength) in the upstream and downstream, and/or using the same cable/optical link used for traffic. Due to this it is possible to achieve accurate latency and asymmetry measurements.
The use of the same optical link also allows for optimized use of the resources, and the use of the same wavelength allows for a fully symmetric channel which is required in order to monitor some critical synchronization parameters.
It is noted that embodiments of the invention utilise a combination of a wavelength reuse mechanism and a standard framing structure of OTN, for example, such that the wavelength reuse allows a symmetrical channel, which enables an accurate path delay to be determined, while the structure of OTN enables OAM information to be conveyed.
The embodiments of the invention also have the advantage of allowing OAM functions to be managed from a central office. This is because the embodiments provide an additional monitoring capability that allows data to be collected, that eventually may be collected and analysed in a central location.
The embodiments of the invention enable common public radio interface (CPRI) traffic to be transported over an optical transport network (OTN), by sing a frequency reuse technique to provide a symmetrical bi-directional communication link between a first node and a second node, and using a frame structure of the optical transport network to provide a monitoring channel.
It should be noted that the above-mentioned embodiments illustrate rather than limit the invention, and that those skilled in the art will be able to design many alternative embodiments without departing from the scope of the appended claims. The word “comprising” does not exclude the presence of elements or steps other than those listed in a claim, “a” or “an” does not exclude a plurality, and a single processor or other unit may fulfil the functions of several units recited in the claims. Any reference signs in the claims shall not be construed so as to limit their scope.
Number | Date | Country | Kind |
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111173418.2 | Jul 2011 | EP | regional |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2011/072951 | 12/15/2011 | WO | 00 | 2/12/2014 |