The present invention relates generally to communication systems, and more particularly to techniques for mitigating, suppressing or otherwise controlling interference between communication channels in such systems.
Multi-channel communication systems are often susceptible to interference between the various channels, also referred to as crosstalk or inter-channel crosstalk. For example, digital subscriber line (DSL) broadband access systems typically employ discrete multi-tone (DMT) modulation over twisted-pair copper wires. One of the major impairments in such systems is crosstalk between multiple subscriber lines within the same binder or across binders. Thus, signals transmitted over one subscriber line may be coupled into other subscriber lines, leading to interference that can degrade the throughput performance of the system. More generally, a given “victim” channel may experience crosstalk from multiple “disturber” channels, again leading to undesirable interference.
Different techniques have been developed to mitigate, suppress or otherwise control crosstalk and to maximize effective throughput, reach and line stability. These techniques are gradually evolving from static or dynamic spectrum management techniques to multi-channel signal coordination.
By way of example, certain of the above-noted techniques allow active cancellation of inter-channel crosstalk through the use of a precoder. In DSL systems, the use of a precoder is contemplated to achieve crosstalk cancellation for downstream communications between a central office (CO) or another type of access node (AN) and customer premises equipment (CPE) units or other types of network terminals (NTs). It is also possible to implement crosstalk control for upstream communications from the NTs to the AN, using so-called post-compensation techniques implemented by a postcoder. Such pre-compensation and post-compensation techniques are also referred to as “vectoring,” and include G.vector technology, which was recently standardized in ITU-T Recommendation G.993.5.
One known approach to estimating crosstalk coefficients for downstream or upstream crosstalk cancellation in a DSL system involves transmitting distinct pilot signals over respective subscriber lines between an AN and respective NTs of the system. Error feedback from the NTs based on the transmitted pilot signals is then used to estimate crosstalk. Other known approaches involve perturbation of precoder coefficients and feedback of signal-to-noise ratio (SNR) or other interference information.
Crosstalk estimates are commonly utilized in situations where one or more inactive lines are being activated in a DSL system. The lines that are being activated are referred to as “activating lines” or “joining lines.” For example, it may become necessary to activate one or more inactive lines in a synchronization group that already includes multiple active lines, where synchronization in this context refers to alignment in time of the DMT symbols for the different lines. Such activating of an additional line may require that the crosstalk compensation be adjusted accordingly in order to optimize system performance. Exemplary techniques for controlling crosstalk associated with a joining line are disclosed in European Patent Application Publication No. EP 1936825A1, entitled “A Transient Crosstalk Controlling Device,” which is incorporated by reference herein. Crosstalk estimates are also used in other situations, e.g., as a means to track changes in crosstalk over time.
In conventional DSL systems, it can be difficult to generate sufficiently accurate crosstalk estimates in the presence of impulse noise. Impulse noise is known to have an adverse impact on data reception, and standardized channel codes, such as Reed-Solomon codes, are typically utilized to alleviate this adverse impact. Nonetheless, impulse noise remains a significant problem in pilot signal aided estimation of crosstalk. For example, even a single impulse occurring during crosstalk estimation can degrade the estimates so severely that there is a significant SNR loss caused when the estimates are used for vectoring. Crosstalk estimates based on error feedback techniques are particularly vulnerable to such impulse noise. Standard error feedback techniques transmit the above-noted distinct pilot signals using sync symbols which occur 16 times per second. If even a single sync symbol is corrupted by impulse noise, the resulting crosstalk estimates may be extremely poor.
Illustrative embodiments of the invention provide improved techniques for generating crosstalk estimates in the presence of impulse noise.
In one aspect of the invention, an access node of a communication system is configured to control crosstalk between channels of the system. A set of L distinct and linearly independent pilot signals is generated, with each pilot signal having length n, where n>L such that L−n linearly independent n-tuples are available for use in detection and correction of impulse noise. The L pilot signals are transmitted over respective ones of the channels, and one or more of the pilot signals as received over their respective channels are processed to detect the presence of impulse noise. A crosstalk estimate corrected for the detected impulse noise is generated and utilized to control crosstalk between two or more of the channels. The access node may comprise, for example, a DSL access multiplexer of a DSL system.
In an illustrative embodiment, the set of L distinct and linearly independent pilot signals comprises a set of L mutually orthogonal pilot signals, such that L−n orthogonal n-tuples are available for use in detection and correction of impulse noise. Thus, the L linearly independent pilot signals may, but need not, be mutually orthogonal.
Advantageously, the illustrative embodiments provide substantial impulse noise immunity in DSL systems that utilize vectoring. Such impulse noise immunity may be provided in joining, tracking or other crosstalk control applications. The disclosed techniques for detection and correction of impulse noise are simple and efficient, do not cause any significant additional delay in the generation of crosstalk estimates, and can be readily implemented within the structure of existing standards such as G.vector. Simulation results indicate that a considerable improvement in expected estimation error can be achieved by detecting and correcting impulse noise using the disclosed techniques.
These and other features and advantages of the present invention will become more apparent from the accompanying drawings and the following detailed description.
The present invention will be illustrated herein in conjunction with exemplary communication systems and associated techniques for crosstalk control in such systems. The crosstalk control may be applied substantially continuously, or in conjunction with activating of subscriber lines or other communication channels in such systems, tracking changes in crosstalk over time, or in other line management applications. It should be understood, however, that the invention is not limited to use with the particular types of communication systems and crosstalk control applications disclosed. The invention can be implemented in a wide variety of other communication systems, and in numerous alternative crosstalk control applications. For example, although illustrated in the context of DSL systems based on DMT modulation, the disclosed techniques can be adapted in a straightforward manner to a variety of other types of wired or wireless communication systems, including cellular systems, multiple-input multiple-output (MIMO) systems, Wi-Fi or WiMax systems, etc. The techniques are thus applicable to other types of orthogonal frequency division multiplexing (OFDM) systems outside of the DSL context, as well as to systems utilizing higher order modulation in the time domain.
As indicated previously herein, in an embodiment in which system 100 is implemented as a DSL system, the AN 102 may comprise, for example, a central office (CO), and the NTs 104 may comprise, for example, respective instances of customer premises equipment (CPE) units. The channels 106 in such a DSL system comprise respective subscriber lines. Each such subscriber line may comprise, for example, a twisted-pair copper wire connection. The lines may be in the same binder or in adjacent binders, such that crosstalk can arise between the lines. Portions of the description below will assume that the system 100 is a DSL system, but it should be understood that this is by way of example only.
In an illustrative DSL embodiment, fewer than all of the L lines 106-1 through 106-L are initially active lines, and at least one of the L lines is a “joining line” that is to be activated and joined to an existing set of active lines. Such a joining line is also referred to herein as an “activating line.” A given set of lines may be, for example, a synchronization group, which may also be referred to as a precoding group or a vectored group, or any other combination of active and/or inactive lines.
Communications between the AN 102 and the NTs 104 include both downstream and upstream communications for each of the active lines. The downstream direction refers to the direction from AN to NT, and the upstream direction is the direction from NT to AN. Although not explicitly shown in
The AN 102 in the present embodiment comprises a crosstalk estimation module 110 coupled to a crosstalk control module 112. The AN utilizes the crosstalk estimation module to obtain crosstalk estimates for respective ones of at least a subset of the lines 106. The crosstalk control module 112 is used to mitigate, suppress or otherwise control crosstalk between at least a subset of the lines 106 based on the crosstalk estimates. For example, the crosstalk control module may be utilized to provide pre-compensation of downstream signals transmitted from the AN to the NTs, and additionally or alternatively post-compensation of upstream signals transmitted from the NTs to the AN. A more detailed example of a pre-compensation technique implemented in an illustrative embodiment of the invention will be described below in conjunction with
The crosstalk estimation module 110 may be configured to generate crosstalk estimates from error samples, SNR values or other types of measurements generated in the AN 102 based on signals received from the NTs 104, or measurements generated in the NTs 104 and fed back to the AN 102 from the NTs 104. It should be noted that the term SNR as used herein is intended to be broadly construed so as to encompass other similar measures, such as signal-to-interference-plus-noise ratios (SINRs).
In other embodiments, crosstalk estimates may be generated outside of the AN 102 and supplied to the AN for further processing. For example, such estimates may be generated in the NTs 104 and returned to the AN for use in pre-compensation, post-compensation, or other crosstalk control applications. The term “crosstalk estimates” as used herein should be understood to encompass, for example, crosstalk channel coefficients, which may also be referred to crosstalk cancellation coefficients, or simply crosstalk coefficients.
The crosstalk estimation module 110 may incorporate interpolation functionality for generating interpolated crosstalk estimates. Examples of interpolation techniques that may be utilized with the present invention are disclosed in U.S. Patent Application Publication No. 2009/0116582, entitled “Interpolation Method and Apparatus for Increasing Efficiency of Crosstalk Estimation,” which is commonly assigned herewith and incorporated by reference herein.
The AN 102 may also or alternatively be configured to implement a technique for channel estimation using linear-model interpolation. In implementing such a technique, the AN transmits the pilot signals over respective ones of the lines 106. Corresponding measurements such as error samples or SNR values are fed back from the NTs to the AN and utilized to generate crosstalk estimates in crosstalk estimation module 110. The AN then performs pre-compensation, post-compensation or otherwise controls crosstalk based on the crosstalk estimates. Additional details regarding these and other similar arrangements are described in U.S. patent application Ser. No. 12/493,328, filed Jun. 29, 2009 and entitled “Crosstalk Estimation and Power Setting Based on Interpolation in a Multi-Channel Communication System,” which is commonly assigned herewith and incorporated by reference herein.
The crosstalk estimation module 110 may incorporate denoising functionality for generating denoised crosstalk estimates. Examples of crosstalk estimate denoising techniques suitable for use with embodiments of the invention are described in U.S. Patent Application Publication No. 2010/0177855, entitled “Power Control Using Denoised Crosstalk Estimates in a Multi-Channel Communication System,” which is commonly assigned herewith and incorporated by reference herein. It is to be appreciated, however, that the present invention does not require the use of any particular denoising techniques. Illustrative embodiments to be described herein may incorporate denoising functionality using frequency filters as part of a channel coefficient estimation process.
The AN 102 further comprises a processor 115 coupled to a memory 120. The memory may be used to store one or more software programs that are executed by the processor to implement the functionality described herein. For example, functionality associated with crosstalk estimation module 110 and crosstalk control module 112 may be implemented at least in part in the form of such software programs. The memory is an example of what is more generally referred to herein as a computer-readable storage medium that stores executable program code. Other examples of computer-readable storage media may include disks or other types of magnetic or optical media.
It is to be appreciated that the AN 102 as shown in
In the illustrative embodiment of
Each of the NTs 104 may be configurable into multiple modes of operation responsive to control signals supplied by the AN 102 over control signal paths, as described in U.S. Patent Application Publication No. 2009/0245081, entitled “Fast Seamless Joining of Channels in a Multi-Channel Communication System,” which is commonly assigned herewith and incorporated by reference herein. Such modes of operation may include, for example, a joining mode and a tracking mode. However, this type of multiple mode operation is not a requirement of the present invention.
An implementation of the system 100 of
Referring now to
In the
The vectoring signal processing unit 212 in DSLAM 202 is configured under control of the VCE 210 to implement pre-compensation for signals transmitted in the downstream direction and post-compensation for signals received in the upstream direction. Effective implementation of these and other crosstalk control techniques requires accurate crosstalk estimates. However, as indicated previously, conventional techniques for generating these crosstalk estimates can be unduly susceptible to impulse noise. Illustrative embodiments of the present invention overcome this problem by providing techniques for generating accurate crosstalk estimates in the presence of impulse noise and other similar degradations.
The term “impulse noise” as used herein is intended to be broadly construed, so as to encompass, for example, impulses or other short bursts of noise that impact only a single tone or a limited number of tones of a given DSL transmission. Various assumptions may be made regarding impulse noise in illustrative embodiments of the invention. For example, it may be assumed that impulses can be treated as being equal in a given tone and at least one tone adjacent to the given tone, or only equal in amplitude for such adjacent tones. As another example, it may be assumed that impulses occur only once during the transmission of a pilot signal, or that multiple impulses affect the same pilot signal. The techniques disclosed herein therefore do not require sophisticated modeling of the impulse noise.
It will be assumed, consistent with standard practice in DSL systems, that separate pilot signal components for lines 1-4 of
v
1=(1,1,1,1), v2=(1,−1,1,−1), v3=(1,1,−1,−1), v4=(1,−1,−1,1)
are mutually orthogonal and one can not add another 4-tuple that would be orthogonal to v1, . . . , v4. Denote by L the number of DSL lines for which we would like to estimate crosstalk channel coefficients. For this purpose we have to have L distinct pilots. Hence the pilots should be n-tuples with nL. We call the parameter n the pilot length. To perform detection and correction of impulse noise in the present embodiment, we incorporate redundancy, that is, we use a value of n that is greater than L. Accordingly, of the n orthogonal n-tuples, L of them are used as pilots, and the remaining n−L are used for detection and correction of impulses, as will be described.
It should be noted that alternative embodiments of the invention may more generally utilize a set of L distinct and linearly independent pilot signals, with each pilot signal having length n, where n>L such that L−n linearly independent n-tuples are available for use in detection and correction of impulse noise. However, for purposes of illustration only, the L linearly independent pilot signals are assumed without limitation to be mutually orthogonal in the description that follows.
Let A={a1, . . . , aL} be a set of L orthogonal pilots of length n>L, where vectors aj are considered column vectors, and so A is an n×L matrix. Denote by
the vector of crosstalk coefficients from lines 1, . . . , L to line 1, where h1,1 is the direct gain coefficient and in a typical DSL system can be assumed to be known. At the output of line 1 we receive the n×1 vector
x
1
=Ah
1
+z+s, (1)
where z is additive noise and s is a vector of impulse noise. Typically only very few (e.g., one or two) entries of s are not zeros.
For a vector x denote by x† its Hermitian conjugate, that is
where * denotes the operation of complex conjugation. It follows from basic facts of linear algebra that we can find a set B={b1, . . . , bn−L} of L−n orthogonal pilots that are also orthogonal to pilots a1, . . . , aL, that is b†jai=0 for all 1jn−L and 1iL.
For detection of a nonzero vector s we compute
y
1
=B
†
x
1
=B
†
Ah
1
+B
†(z+s)=B†(z+s).
Note that y1 does not depend on the crosstalk coefficients h1, but only on the additive noise and possible impulse noise.
We assume that the statistics of additive noise z are known. Using the known statistics of z we apply well-known statistical methods to distinguish between the following two hypotheses:
For example, using the known statistics of z we can find the value s* that maximizes the likelihood
(y1|∥s∥=s*),
and compare s* with the threshold. The value of s* can be found using well-known statistical techniques, such as those disclosed in, for example, S. M. Kay, “Fundamentals of Statistical Signal Processing,” Prentice Hall PTR, 1993, and P. J. Bickel and K. A. Doksum, “Mathematical Statistics: Basic Ideas and Selected Topics,” Holden Day Series in Statistics, 1977.
As another example, we can find s*, s*=∥s*∥ that maximizes the log likelihood as a function of s*
(y|s)=−∥y−s∥2+C
where C is a constant and the statistics of z are N(0,1) independently in each component, that is, Gaussian complex random variables with zero mean, unit expected squared magnitude, and independent and identically distributed real and imaginary parts.
If the hypothesis H1 is determined to be correct, then the estimate may be discarded or a request may be made for a retransmission. Correction is also an option but involves determining when the impulses took place, as will be described in detail below. Thus, embodiments of the invention may utilize detection with an option to correct, or detection and identification of the impulse epoch(s). It is generally preferred to correct, at least under the assumption of a single impulse. The disclosed techniques can be used to optionally correct on the basis of estimates of the impulse noise magnitudes using hypothesis testing.
It is to be appreciated that the particular process steps in the
A more detailed example based on the
Let us choose
Note that [AB] is a 8×8 Hadamard matrix. We compute y1 according to Equation (1):
y
1
=B
†
x
1
=B
†
z+B
†
s=u+w,
where u=B†z and w=B†s. In a typical communications scenario the entries of z are independent identically distributed (iid) complex Gaussian variables with zero mean and variance V. The rows of B† are mutually orthogonal and therefore we have that the entries of u are iid complex Gaussian random variables with zero mean and variance nV. Using this fact and well-known statistical techniques we can find the value w* that maximizes the likelihood
(y1|∥w∥=w*).
Since we assume that only one impulse occurred during pilot transmission we have
∥s∥2=∥w∥2/(L−n)
and therefore s*=√{square root over (w*/(L−n))}. Now comparing s* with the threshold we make a decision whether the impulse noise was sufficiently small or too large for accurate estimation of h1. In the latter case we may request a retransmission of the pilots A.
Note that the described technique does allow one to uniquely identify the time instances at which impulses occurred.
In the following we describe a method for identifying the time instances in which impulses occurred and a method for their correction.
DSL systems generally use orthogonal frequency division multiplexing (OFDM) transmission, and therefore data is transmitted in multiple frequency tones. We assume that pilots are transmitted in tones with indices f1, f2, . . . , fK. For instance, in a typical situation we will have
f
1=1, f2=f1+Δ, f3=f1+2Δ, . . . .
We again denote by L the number of DSL lines. We partition the tones in which pilots are transmitted into pairs (f1, f2), (f3, f4), (f5, f6), and so on. We use different sets A1 and A2 of orthogonal pilots of length n>L in the tones from these pairs (e.g., to A1 in the tone f1 and A2 in the tone f2; A1 in the tone f3 and A2 in tone f4, and so on).
For any such A1 and A2 one can find n×(L−n) matrices B1 and B2 with the following properties. The columns of B1 are mutually orthogonal and they are also orthogonal to all columns of A1. Similarly the columns of B2 are mutually orthogonal and they are also orthogonal to all columns of A2.
Without loss of generality we consider below only one pair of tones, say tones f1 and f2. After transmission of pilots A1 and A2 we receive in tones f1 and f2 vectors
x
1
=A
1
h
1
+z+s, and x2=A2h2+w+r,
where vectors z and w are additive noise in tones f1 and f2 respectively, and vectors s and r are vectors of impulse noise that affect the tones f1 and f2 respectively.
We compute
y
1
=B
1
†
x
1
=B
1
†
A
1
h
1
+B
1
†(z+s)=B1†(z+s), (2)
and
y
2
=B
2
†
x
2
=B
2
†
A
2
h
2
+B
1
†(w+r)=B2†(w+r). (3)
We then perform the following operations:
1. Use y1 and y2 to identify positions (e.g., time instances), say j1, . . . , jl, of impulses.
2. Obtain estimates ŝj
3. Compute the n×1 vector {circumflex over (x)}1 from x1 by subtracting the estimates ŝj
4. Compute the n×1 vector {circumflex over (x)}2 from x2 by subtracting the estimates {circumflex over (r)}j
5. Use the vectors {circumflex over (x)}1 and {circumflex over (x)}2 to estimate h1 and h2 using a standard linear regression.
Below we consider one embodiment of the proposed method. In this embodiment we assume that n is a power of 2 and denote by Hn the Hadamard matrix obtained by Sylvester's construction, as described in F. J. MacWilliams and N. J. A. Sloane, “The Theory of Error-Correcting Codes,” Horth-Holland, Chapter 2, 1977. For example, if n=8 we have
We form A1 by the columns of Hn in which odd and even entries have alternating signs and B1 by the columns of Hn whose odd and even entries have the same signs. For instance for n=8 we have
We form A2 and B2 by the cyclic shift of the rows of A1 and B1 respectively. In the case of n=8 we have
Using A1, B1, A2, and B2 we compute y1 and y2 according to Equations (2) and (3) respectively. We further compute vectors
u=H
n/2
y
1 and g=Hn/2y2.
It can be seen that
In particular, in the case n=8 we have
Let us again assume that at most one impulse can occur during transmission of the pilots. We can identify the location of the impulse in the following way. Compute the vector
q=(|u1|+|g1|,|u1|+|g2|,|u2|+|g2|,|u2|+|g3|, . . . , |un/2|+|gn/2|,|un/2|+|g1|).
In the case n=8 we will have
q=(|u1|+|g1|,|u1|+|g2|,|u2|+|g2|,|u2|+|g3|,|u3|+|g3|,|u3|+|g4|,|u4|+|g4|,|u4|+|g1|).
The largest entry of q indicates the time instance at which the impulse was most likely to have occurred, that is, if qj is larger than all other entries of q it is mostly likely that the impulse occurred at time instance j. Indeed, if for example the impulse occurred at time instance 1 (that is |s1|>0 and |r1|>0 and all other entries of s and r are zeros) then in a typical situation the values |u1| and |g1| will be larger then |ul| and |gl| for l≠1. Hence q1=|u1|+|g1| will be larger than all other entries of q. If the impulse occurred at time instance 2 then typically |u1| will be larger than |u1| for l≠1, and |g2| will be larger than |g1| for l≠2. Hence q2=|u1|+|g2| will be larger than other entries of q. Similar results are obtained for impulses occurring in the other time instances.
Note that in order to further improve the probability of correct identification of the time instance in which an impulse occurred we compute vectors q, denote them by q(1), q(2), q(3), . . . , for each pair of tones (f1, f2); (f3, f4); (f5, f6), . . . , and further compute
q=q
(1)
+q
(2)
+q
(3)+ . . . . (4)
Then the index of the largest entry of q will again identify the mostly likely time instance at which impulse could occur. Let us assume that, using this procedure, we determined that the impulse occurred at time j. We can estimate the value sj of the impulse in tone f1 by um, m=┌j/2┐. For example, if j=1 we get ŝ1=u1, and if j=2 we again have ŝ2=u1.
Similarly we can estimate the value rj of the impulse in tone f2 by gm, where m=┌j/2┐+(j mod 2) and if we get m>n/2 then we replace it by m=1. For example, if j=1 we get {circumflex over (r)}1=g1 and if j=2 we get {circumflex over (r)}2=g2.
Now subtracting the estimates ŝj and {circumflex over (r)}j of the impulses from the corresponding values of x1 and x2 we can further estimate h1 and h2 using standard statistical methods, such as linear regression.
The presence of more than one impulse can be detected by more complex analysis of the vectors u, g, and q. To further improve the detection and correction of multiple impulses we partition pairs (f1, f2), (f3, f4), (f5, f6) into two sets T1 and T2. For example, we can choose
T
1
={f
(1)
, f
(2)
, f
(5)
, f
(6)
, f
(9)
, f
(10), . . . },
and
T
2
={f
(3)
, f
(4)
, f
(7)
, f
(8)
, f
(11)
, f
(12), . . . }.
We use pilots A1, A2 for pairs of tones from T1 and different orthogonal pilots A3, A4 for pairs of tones from T2. We further compute vector q according to Equation (4) for the set T1 and compute a similar vector, say p, for pairs of tones from T2. We then use vectors q and p to identify the locations of possible impulses.
The particular signal processing examples given above should not be construed as limiting in any way, but is instead intended merely to illustrate possible sets of signal processing operations that may be performed in implementing the
where (·) denotes the expected value operator.
As is apparent from plot 500, the expected estimation error (err2) is less than about 2.65×10−9 for all values of impulse amplitude squared in the range shown. In the simulation used to generate plot 500, only one pair of tones f1 and f2 is used to compute vector q, although it is expected that even better results could be obtained if multiple pairs of tones are used to compute vector q in accordance with Equation (4). We assume for this simulation that one impulse occurred at a random time instance j and that |sj|=|rj|=s. It is further assumed that the variance of additive noise is var(zl)=var(wl)=10−8, l=1, . . . , n. No particular assumption is made as to the size of the impulse, but instead performance is determined over all reasonable values.
In the simulation used to generate plot 502, a standard linear regression is used to estimate h1 and h2 without any attempt to detect or correct impulse noise. It can be seen that the expected estimation error in this case increases rapidly for values of impulse amplitude squared above about 10−8.
The simulation results plotted in
Advantageously, the illustrative embodiments can provide substantial impulse noise immunity in DSL systems that utilize vectoring. Such impulse noise immunity may be provided in conjunction with the joining of an additional line to a set of active lines, as in the illustrative embodiment of
Embodiments of the present invention may be implemented at least in part in the form of one or more software programs that are stored in a memory or other processor-readable medium of AN 102 of system 100. Such programs may be retrieved and executed by a processor in the AN. The processor 115 may be viewed as an example of such a processor. Of course, numerous alternative arrangements of hardware, software or firmware in any combination may be utilized in implementing these and other systems elements in accordance with the invention. For example, embodiments of the present invention may be implemented in a DSL chip or other similar integrated circuit device. Thus, elements such as transceivers 208, VCE 210 and vectoring signal processing module 212 may be collectively implemented on a single integrated circuit, or using multiple integrated circuits. As another example, illustrative embodiments of the invention may be implemented using multiple line cards of a DSLAM or other access node. Examples of access nodes having multiple line card arrangements that can be adapted for use in implementing embodiments of the present invention are disclosed in European Patent Application No. 09290482.0, filed Jun. 24, 2009 and entitled “Joint Signal Processing Across a Plurality of Line Termination Cards.” The term “vectoring circuitry” as used herein is intended to be broadly construed so as to encompass integrated circuits, line cards or other types of circuitry utilized in implementing operations associated with crosstalk cancellation in a communication system.
It should again be emphasized that the embodiments described above are presented by way of illustrative example only. Other embodiments may use different communication system configurations, AN and NT configurations, communication channels, crosstalk estimate generation and crosstalk control process steps, depending on the needs of the particular communication application. Also, other types of linearly independent pilot signals may be used in place of the mutually orthogonal pilot signals used in certain of the illustrative embodiments. Alternative embodiments may therefore utilize the techniques described herein in other contexts in which it is desirable to control crosstalk between multiple channels of a communication system.
It should also be understood that the particular assumptions made in the context of describing the illustrative embodiments should not be construed as requirements of the invention. The invention can be implemented in other embodiments in which these particular assumptions do not apply.
These and numerous other alternative embodiments within the scope of the appended claims will be readily apparent to those skilled in the art.