The present invention is related to optical fiber amplifiers, and in particular to controlling the gain profile of erbium doped fiber amplifiers (EDFA), Raman Amplifiers (RA), and hybrid EDFA-RA amplifiers.
In a wavelength division multiplexing optical transmission system, various information channels are encoded into light at different wavelengths, which is combined using a multiplexor. The combined light is transmitted through an optical fiber and, or an optical fiber network to a receiver end of the optical fiber. At the receiver end, the signal is separated, or demultiplexed, back into the individual optical channels through a de-multiplexor, whereby each optical channel can be detected by an optical detector such as a photodiode, and the information can be reconstructed, channel by channel.
While propagating through the optical fiber, light tends to lose power due to the losses related to the physics of how the light interacts with the optical fiber. Yet some minimal level of optical channel power is required at the receiver end in order to decode information encoded in the optical channel. In order to boost the optical signal propagating in the optical fiber, optical amplifiers are deployed at multiple locations, known as nodes, along the transmission link. The optical amplifiers extend the maximum possible length of the link, in some instances, from a few hundred kilometers to several thousand kilometers, whereby after each fiber span, the optical signal is amplified to power levels close to the original levels of the transmitter. Unfortunately, during the amplification process some amount of noise is introduced into the optical signal which effectively limits the amount of optical amplifiers a transmission link can have.
Modern optical communication systems employ erbium doped fiber amplifiers (EDFAs), Raman Amplifiers (RAs) and hybrid EDFA-RAs as means to boost the optical signal power and thus to extend the communication system reach. Nowadays, optical communication systems have become more agile and reconfigurable. Reconfiguration of the optical communication system leads to variation of the signal load at the input of the amplifier. At the same time, the goal of the amplifier is to provide constant gain, which should not depend on the power or wavelength loading condition; otherwise, some channels will not have sufficient power and signal-to-noise level at the receiver end, resulting in information being lost.
The control electronics of EDFAs partially solves the problem of the variable signal load. More particularly, the total optical power at the input and at the output of the amplifier is measured, and the average optical signal gain of the amplifier is calculated. The amplifier control electronic circuitry adjusts the amplifier's pump powers through a feedback loop in such a way that the measured optical gain equals to the desired or “set” optical gain and is not varied significantly in time.
However, it is desired not only to have average gain of the amplifier to be constant, but also to have the gain of the individual channel constant and independent from the other channels' presence or absence, that is, independent from the channel load. At the same time, due to the spectroscopy of the erbium doped fiber, namely due to the spectral hole burning (SHB) effect, the gain shape of EDFA does depend on the input load. Hence even if the average gain of an EDFA is held constant, the gain of the individual channels will vary, leading to undesirable effects, such as increased bit error rate of the transmission system.
One way in which to address the problem is to check the channel powers at a location in the transmission system, using an optical channel monitor (OCM). The collected information is then used by the system control circuitry to adjust a dynamic gain equalizer (DGE) in the transmission link in such a way that the transmitted spectrum is flattened. The OCM and DGE need not necessarily be at a same location in the system. The advantage of this approach that it compensates for all gain change inducing impairments of the system, such as stimulated Raman scattering (SRS) induced tilt, not only EDFA SHB.
However the above approach has several disadvantages. First, because the DGE and OCM are expensive components, they are not generally installed at each amplifier node, thus they compensate several amplifiers at once, which is not optimal. Second, both OCM and DGE are comparatively slow devices, and thus the correction usually takes a few seconds. This is undesirable for agile communication systems where a typical requirement for the adjustment for a transient event such as a change of the channel load is on the order of 100 μs, which is 10,000 times shorter than for a DGE/OCM approach.
To address the disadvantage of this compensating technique it has been suggested by Zhou et al. in an article entitled “Fast control of inter-channel SRS and residual EDFA transients using a multiple-wavelength forward-pumped discrete Raman amplifier”, OMN4, OFC 2007, which is incorporated herein by reference, to measure channel powers of a limited number of channels that are located at specific wavelengths, 1528.6 nm, 1544.4 nm, and 1559.6 nm in the published example. Subsequently, the Raman pump powers of the Raman amplifier are adjusted using linear feed-forward control. The work is based on RAs having 3 different wavelengths of Raman pumps. Again, similar to the aforementioned DGE/OCM approach, this compensates not only EDFA SHB, but SRS tilt as well.
The main disadvantage of this technique is the requirement of the constant presence of those three channels the power of which is constantly monitored. This is a very limiting requirement for modern agile communication systems. Another potential disadvantage is the requirement to have three additional detectors. Finally, relatively good SHB compensation is possible only in the presence of three Raman pumps—the reduction of number of pumps will lead to the reduction of the amount of compensation.
Further, in U.S. Pat. No. 7,359,112 by Nishihara et al. which is incorporated herein by reference, a control apparatus is described which adjusts the gain of an EDFA based on an amount of wavelengths which is calculated on the basis of optical power measured in two or three separate spectral bands by dedicated photodetectors. One disadvantage of this approach is that only one control parameter, specifically the EDFA gain, is adjusted which limits the degree to which both the SHB and SRS can be compensated. Another disadvantage stems from the fact that certain load change patterns, for example the patterns which leave the total optical power measured in a single spectral band unchanged, will not be detected by the apparatus of Nishihara et al. and therefore will not be compensated for by said apparatus.
It is an object of the present invention to provide an apparatus and method for controlling a gain profile of an optical amplifier suitable for suppression of sub-millisecond scale transient variations of gain caused by changes in the amplifier load which would not require dedicated spectral channels in order to monitor the gain profile. In this context, “controlling” means stabilizing the gain profile of an optical amplifier at varying load conditions. This invention extends the technique that was suggested by Bolshtyansky et al. in an article entitled “Dynamic Compensation of Raman Tilt in a Fiber Link by EDFA during Transient Events”, JThA15, OFC 2007, where instead of measuring the actual gain change, the device measures some property of the transmitted signal, and adjusts the gain profile based on the measured property of the signal.
The apparatus of the present invention branches off a small portion of a transmitted optical signal, splits this portion into a plurality of sub-portions, passes the sub-portions through a set of characteristic optical filters, and measures the resulting optical powers. Based on the measurements, the apparatus adjusts the pump power of an erbium doped fiber amplifier (EDFA) and, or the pump power(s) of a Raman amplifier (RA), and, or the attenuation setting of a fast variable optical attenuator, according to a pre-defined set of response functions chosen to control a gain profile of an optical amplifier, so as to lessen power variation of an amplified optical signal at varying amplifier load conditions.
Thus, in accordance with the invention there is provided an apparatus for controlling a gain profile G(λ) of an optical amplifier comprising an erbium doped fiber amplifier for amplifying a stream of optical signals, the apparatus comprising:
a detection device arranged to receive a tapped portion of the stream of optical signals in the form of N+1 sub-portions and to provide N+1 output signals P0 . . . PN in dependence upon said tapped portion, wherein N is an integer positive number, the detection device comprising: N spectral filters having respective transmission functions F1(λ) . . . FN(λ) including at least one transmission function having two separate transmission regions; and N+1 photodetectors for producing the N+1 output signals P0 . . . PN in response to a light impinging thereon, wherein the first sub-portion of the tapped portion of the stream of optical signals is coupled to the first photodetector for producing the signal P0, and each one of remaining N of said sub-portions of the tapped portion of the stream of optical signals is coupled to one of the N spectral filters coupled to one of the remaining N photodetectors for producing the signals P1 . . . PN;
a controller arranged to receive said signals P0 . . . PN from the detection device and suitably programmed to provide M control signals x1 . . . xM in dependence upon said signals P0 . . . PN, wherein M is an integer positive number and xm=ƒm(Ck, P0 . . . PN), wherein ƒm is a pre-determined function and Ck are pre-determined constants, for each m=1 . . . M; and
M spectral actuators S1 . . . SM arranged to receive said control signals x1 . . . xM, respectively, and modify the gain profile G(λ) by a value ΔG(λ) according to the equation
wherein Am(λ) is a fraction of said modification caused by the mth actuator Sm upon receiving a unitary control signal by said actuator;
wherein the functions ƒ1 . . . ƒM and F1 . . . FN are chosen so as to stabilize the gain profile G(λ) at varying load conditions of the optical amplifier.
In accordance with another aspect of the invention there is further provided a method for controlling a gain profile G(λ) of an optical amplifier comprising an erbium doped fiber amplifier for amplifying a stream of optical signals, the method comprising:
splitting a tapped portion of the stream of optical signals in the form of N+1 sub-portions, wherein N is an integer positive number;
measuring optical power value P0 of the first said sub-portion;
spectral filtering remaining N sub-portions through N filters having respective transmission functions F1(λ) . . . FN(λ) including at least one transmission function having two separate transmission regions, and measuring optical power values P1 . . . PN of the respective filtered sub-portions of the tapped portion;
generating M control signals x1 . . . xM based on the formula xm=ƒm(Ck, P0 . . . PN), wherein ƒm is a pre-determined function and Ck are pre-determined constants, for each m=1 . . . M;
applying said M control signals x1 . . . xM to M spectral actuators S1 . . . SM, respectively, wherein said actuators modify the gain profile G(λ) by a value
wherein
Am(λ) is a fraction of said modification caused by the mth actuator Sm upon receiving a unitary control signal by said actuator;
wherein the functions ƒ1 . . . ƒM and F1 . . . FN are chosen so as to stabilize the gain profile G(λ) at varying load conditions of the optical amplifier.
Exemplary embodiments will now be described in conjunction with the drawings in which:
While the present teachings are described in conjunction with various embodiments and examples, it is not intended that the present teachings be limited to such embodiments. On the contrary, the present teachings encompass various alternatives, modifications and equivalents, as will be appreciated by those of skill in the art.
Referring to
In order to correct dynamic gain tilt caused by variations in amount and, or optical power of signals at individual wavelengths comprising incoming multi-wavelength signal 824, a compensation circuit is implemented in the prior art amplifier 800 comprising three signal sources 828 at wavelengths λ1, λ2, and λ3 coupled to multiplexor 802, an output tap 830, a demultiplexor 832 having outputs corresponding to the wavelengths λ1, λ2, and λ3, which are coupled to three separate photodetectors 834, and a controller 836 arranged to receive signals from the photodetectors 834 and adjust drive currents of power supplies 814 supplying the drive currents to three Raman pump diode lasers 816.
In operation, light at three wavelengths λ1, λ2, and λ3 is used to probe the gain profile of amplifier 800 in real time. When a transient change of the amplifier gain appears as a result of a change in the amplifier loading conditions, the ratio of optical power values of light at these three wavelengths changes which prompts the controller 836 to change the ratio of drive currents of Raman pumps accordingly, so as to reduce transient effects and flatten the gain profile of amplifier 800.
All possible locations of gain adjuster 19, tap 94, and EDFA 5 will work with respect to the present invention, but some configurations are easier to implement than others. For example, in
Turning now to
Once the powers P1 . . . PN at photodetectors 213-1 . . . 213-N are measured, the controller generates a vector of numbers x=x1 . . . xM, where M is the amount of independently adjustable parameters of gain adjuster 19 in
where each Am(λ) is the gain modification by a single “actuator”, that is, by the element of the gain adjuster 19 that is controlled by one of the component of the vector x. In other words, Am(λ) is a fraction of the gain modification caused by a mth actuator upon receiving a unitary control signal by said actuator. In equation (1), the gain modifications are expressed in dB units.
In the preferred embodiment the controller calculates vector x using the following equation:
Here, Cm,n are some constant coefficients obtained during system design, Pn is the power measured at n-th detector in linear units such as in milliwatt, and P0 is the power measured at detector 212 of
Even though equation (2) gives very good results for SHB compensation, other formulas can be used for xi calculation. The most generic formula is xm=ƒm(Ck, P0 . . . PN), wherein ƒm is a pre-determined function and Ck are some pre-determined constants.
During system design one needs to optimize the coefficients Cm,n together with filter shapes F1(λ) . . . FN(λ) in such a way that the overall gain change is minimal for different loading conditions. This can be done via simulation when optimization procedure runs through randomly generated signal loading conditions while adjusting coefficients Cm,n and filter shapes F1(λ) . . . FN(λ). Upon each adjustment, the optimization procedure calculates resulting gain change and, out of all filter shapes and coefficients Cm,n tried, it chooses the ones corresponding to the minimal perturbation of the original gain profile. The calculated coefficients Cm,n are then stored in the memory of control unit 533 to generate vector x. Since coefficients Cm,n are pre-calculated, the response time of the control unit 533 can be in sub-microsecond domain which is fast enough to compensate for most transients caused by changes of loading conditions of amplifiers 200A-200C of
The apparatus of present invention will work using different numbers of detectors and actuators. While increasing the number of detectors and actuators generally improves the degree of achieved gain profile flatness of amplifiers 200A-200C of
In case of optimization involving more than one filter, the transmission functions of the filters may have common regions of non-zero transmission. Thus, the different filters are not just different bandpass filters used to obtain optical powers in different areas of the spectrum of multi-wavelength optical signal to be amplified, as it is in the case of, for example, an apparatus of U.S. Pat. No. 7,359,112. Advantageously, the spectral shapes F1(λ) . . . FN(λ) of the filters of the present invention are optimized using the abovementioned optimization procedure, so as to ensure that the filters 214-1 . . . 214-N filter out signals which are most representative of transient perturbations of the amplifier gain profile caused by spectral variations in optical signal 201 of
Further, tap 94 and 1×(N+1) splitter 211 of the detection device of
Turning now to
The filter transmission function F1(λ) of filter 214 of
Turning now to
An example of the actuator functions Am(λ) is shown in
It should be noted that even though a distributed counter-propagation Raman amplifier topology is described in the preferred embodiment of
Simulations over 520 randomly generated cases have shown that actuator functions shown in
This application is a continuation of and claims priority to U.S. patent application Ser. No. 12/235,041, filed Sep. 22, 2008, and in turn claims priority to U.S. Patent Appl. No. 60/978,253, filed Oct. 8, 2007. The entireties of such patent applications are hereby incorporated by reference.
Number | Name | Date | Kind |
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6088152 | Berger et al. | Jul 2000 | A |
6275313 | Denkin et al. | Aug 2001 | B1 |
7236294 | Takeyama et al. | Jun 2007 | B2 |
7359112 | Nishihara et al. | Apr 2008 | B2 |
7969647 | Bolshtyansky et al. | Jun 2011 | B2 |
20060187539 | Zhou et al. | Aug 2006 | A1 |
20080040057 | Fujimura et al. | Feb 2008 | A1 |
Entry |
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Xiang Zhou et al, “Fast control of inter-channel SRS and residual EDFA transients using a multiple-wavelength forward-pumped discrete Raman amplifier”, OMN4, OFC 2007. |
Maxim Bolshtyansky et al, “Dynamic Compensation of Raman Tilt in a Fiber Link by EDFA during Transient Events”, JThA15, OFC 2007. |
Number | Date | Country | |
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20110292497 A1 | Dec 2011 | US |
Number | Date | Country | |
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60978253 | Oct 2007 | US |
Number | Date | Country | |
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Parent | 12235041 | Sep 2008 | US |
Child | 13113059 | US |