The present invention relates to a novel class of equalizers for use in the receivers of digital communication systems.
In the receiver of a contemporary digital communication system, an equalizer operates to compensate for various forms of distortion introduced by the propagation medium. In wireless communication systems for example, an important source of such distortion is time-varying multipath propagation, whereby the transmitted signal travels through multiple paths en route to the receiver due to reflections off objects in the propagation environment. In wireline communication, such as twisted copper wire pair or co-axial cable, such distortion arises due to the frequency response characteristics of the physical medium, referred to herein as the “channel”, or of other system hardware in the network.
Absent some form of correction or compensation, such distortion can cause streams of transmitted bits or symbols to interfere with one another, a phenomenon generally referred to as intersymbol interference. In certain code-division multiple-access (CDMA) communication systems, distortion may further give rise to a phenomenon referred to as inter-chip interference. Intersymbol interference (ISI) is used herein to refer to both forms of interference. Precursor ISI is caused by the strictly anticausal portion of the equivalent discrete-time channel impulse response, whereby a current symbol affects symbols in the past. Postcursor ISI is caused by the stricly causal portion of the equivalent discrete-time channel impulse response, whereby a current symbol affects symbols in the future. ISI can lead to severe degradation in system performance, especially in wireless settings. Equalizers, designed to compensate for, and to mitigate the effects of, such interference, have been under development for more than three decades and have evolved to become essential components in virtually all modern communication systems.
It is well known in theory that receivers that realize maximum-likelihood sequence detection (MLSD) are asymptotically optimal in bit-error rate at high signal-to-noise ratios (SNR), as observed in G. D. Forney, Jr., “Maximum-likelihood sequence estimation of digital sequences in the presence of intersymbol interference,” IEEE Trans. Inform. Theory, vol. IT-18, pp. 363-378, May 1972. However, even when implemented efficiently using the Viterbi algorithm, the computational requirements of such receivers are prohibitive for even small signal constellations and channels whose ISI spans only a modest number of symbols. Indeed, although the complexity of MLSD is independent of block-length, it does grow as ML−1 where M is the size of the symbol alphabet and L is the length of the impulse response of the equivalent discrete-time channel. As a result, practical equalizers rarely employ MLSD.
Two approaches have become popular in practice: linear equalizers (LEs) and decision-feedback equalizers (DFEs). LEs were developed in the 1960's, and employed linear filters to compensate for distortion. Later, in the late 1960's and early 1970's, the inherently non-linear DFEs were introduced. In both cases, the computational complexity is dramatically lower than the theoretically superior MLSD approach—it is essentially independent of the size of the symbol alphabet M and proportional to the length of the channel impulse response L.
Like the LE, the DFE processes the received signal using a linear filter and makes symbol decisions using a slicer, as disclosed in C. A. Belfiore and J. H. Park, Jr., “Decision-feedback equalization,” Proc. IEEE, vol. 67, pp. 1143-1156, August 1979. However, each time a decision is to be made, a linear, strictly causal filter forms a weighted linear combination of previous symbol decisions, assumed to be correct, to cancel the postcursor ISI at the slicer input. The slicer then generates a decision for the current symbol. Note that once a symbol decision is made, it does not change and is used to cancel postcursor ISI when making decisions for future symbols.
Another equalizer approach, referred to as the “ISI canceler”, processes the received signal using a linear filter and makes symbol decisions using a slicer, as disclosed in Gersho and T. L. Lim, “Adaptive cancellation of intersymbol interference for data transmission,” Bell Syst. Tech. J., vol. 60, pp. 1997-2021, November 1981. However, each time a decision is to be made, a linear noncausal filter forms a weighted linear combination of both previous and future tentative symbol decisions made by some other equalizer, typically a linear equalizer, to cancel ISI at the slicer input. The slicer then generates a final decision for the current symbol.
LEs are widely used, but often suffer from excessive noise enhancement, even when minimum mean-square error (MMSE) design criteria are used. DFEs are capable of better performance, particularly at higher SNR, because postcursor ISI is suppressed nonlinearly. However, noise enhancement is still an issue in DFEs because precursor ISI is only suppressed linearly, and the sequential structure of DFE algorithms make them generally incompatible with error-control channel coding due to decoding delay issues, despite numerous attempts to merge the two; see, for example, (a) J. G. Proakis, Digital Communications. New York, N.Y.: McGraw-Hill, 2nd ed., 1989. (b) V. M. Eyuboglu, “Detection of coded modulation signals on linear, severely distorted channels using decision-feedback noise prediction with interleaving,” IEEE Trans. Commun., vol. COM-36, April 1988. (c) K. Zhou and J. G. Proakis, “Coded reduced-bandwidth QAM with decision-feedback equalization,” in Proc. Int. Conf. Commun., pp. 12.6.1-12.6.5, June 1988. (d) K. Zhou, J. G. Proakis, and F. Ling, “Decision-feedback equalization of fading dispersive channels with trellis-coded modulation,” in Proc. Int. Conf. Commun. Techn., November 1987. Since error-control coding is required to approach channel capacity, an equalizer compatible with this feature is highly desirable.
The present invention represents a major improvement over existing equalizers, and its advantages are the result of a fundamentally new equalizer architecture.
The novel class of equalizers presented herein are configured in a block-iterative structure, i.e., they are implemented by a multiple-pass algorithm. An illustrative example of the operation of the new class of equalizers is as follows. Let x[n] denote an uncoded transmitted symbol stream and r[n] denote a received data stream corresponding to the equivalent discrete-time baseband model. On the first pass, this received data is processed by a linear filter, and the resulting output is passed on to a slicer, which makes a first set of tentative symbol decisions {circumflex over (x)}1[n]. This initial pass is then followed by a second pass in which the same received data is processed by a linear filter, and the tentative decisions made in the previous pass are used to construct and subtract out an estimate of the ISI. The ISI-reduced data is then passed on to the slicer, which makes a new second set of tentative decisions {circumflex over (x)}2[n]. The process repeats in this manner, until adequately reliable decisions are obtained.
Unlike the conventional DFEs, the novel equalizers of the present invention suppress virtually all of the ISI, including precursor and postcursor ISI, in a nonlinear manner, significantly enhancing system performance. In fact, theory and simulations have demonstrated that the new class of equalizers can achieve a given level of reliability (as measured by bit-error rate) using significantly less received signal power than conventional equalizers.
Additionally, unlike the DFE, the equalizers of the present invention can be deployed in conjunction with systems employing error-control coding, making them attractive for channels operating near capacity.
A further advantageous feature of the equalizers of the present invention is extremely low computational complexity. The order of complexity is comparable to that of the DFE, and the adaptive implementation is much less computationally complex.
In a first embodiment, the present invention is directed to an apparatus and method for iteratively equalizing received data transmitted over a data channel in a data communication system. At each iteration, a first filter, for example a “feed-forward” filter, filters received data according to first filter parameters to generate first-filtered data. A combiner modifies the first-filtered data with second-filtered data to generate modified data. A decision device, for example a digital slicer generates modified tentative decisions based on the modified data, the modified tentative decisions being modified with respect to tentative decisions of a previous iteration. A second filter, for example a “feed-back” filter, filters tentative decisions from a previous iteration according to second filter parameters to generate said second-filtered data. The first and second filter parameters are based on the received data, and are preferably modified at each iteration.
In a preferred embodiment, the received data is sampled at a rate higher than a symbol rate associated with the received data. The received data may comprise symbol data.
The first and second parameters may be modified at each iteration according to channel parameters that are re-estimated at each iteration based on the received data.
The received data may optionally be encoded for error correction coding, in which case the decision device comprises an error-correction decoder, and wherein the equalizer further comprises an encoder for encoding the tentative decisions from a previous iteration.
The feed-forward and feed-back filters may comprise linear, non-linear, time-variant, time-invariant, infinite-impulse-response (IIR) and finite-impulse-response (FIR) types.
In alternative embodiments, the received data may comprise a plurality of received signals received over a plurality of data channels, in which case the equalizer further comprises a like plurality of first filters corresponding to the plurality of channels. The received data may further comprise combined data for a plurality of users, in which case the equalizer further comprises a like plurality of second filters corresponding to the plurality of users.
The foregoing and other objects, features and advantages of the invention will be apparent from the more particular description of preferred embodiments of the invention, as illustrated in the accompanying drawings in which like reference characters refer to the same parts throughout the different views. The drawings are not necessarily to scale, emphasis instead being placed upon illustrating the principles of the invention.
The present invention is directed to a novel equalizer system suitable for use in modern communication systems. A block-iterative configuration is employed to efficiently process received data, in a manner that is reliable and computationally inexpensive.
During each iteration, a set of tentative decisions are made as to the transmitted data, with the help of tentative decisions from a previous iteration. Reliability of the tentative decisions improves during each iteration, and therefore the tentative decisions from the previous iterations become more useful. The iterations continue until further iterations do not significantly change the set of tentative decisions.
Unlike conventional DFEs, the novel equalizers of the present invention suppress virtually all of the ISI, including precursor and postcursor ISI, in a nonlinear manner, significantly enhancing system performance. In fact, theory and simulations have demonstrated that the new class of equalizers can achieve a given level of reliability (as measured by bit-error rate) using significantly less received signal power than conventional equalizers. In particular, the new class of equalizers is capable of achieving a given bit error rate with 2.5 dB less received signal power as compared to a conventional system employing a minimum mean-square error DFE on severe ISI channels, even for uncoded systems.
As an example,
In the transmitter, a stream of binary data is typically mapped into a sequence x[n] of complex numbers selected from a discrete symbol set. Multiple bits may be mapped into a single data symbol. The sequence of symbols is then combined with the transmit pulse shape PTF(t) to produce the complex-valued continuous-time signal
where T is the modulation or baud interval. The real and imaginary components of s(t) amplitude-modulate in-phase and quadrature-phase carrier waves respectively, which combine to form the passband PAM signal transmitted to the receiver 30.
At the receiver 30, the received signal r(t) is applied to an input circuit comprising several components in series, the order of which may vary from system to system. Typically, the input circuit includes a bandpass filter 32 in order to suppress energy in the received signal r(t) outside the transmission frequency band. The filtered signal 33 is next processed by a phase splitter 34 that rejects negative frequencies and has two real-valued outputs representing a complex-valued signal. Alternatively, the functionality of the bandpass filter 32 and the phase splitter 34 can be replaced by an analytic passband filter, implemented using two physical filters, each with a real-valued output. An automatic gain control (AGC) 36 typically follows the passband filtering, which compensates for slow amplitude variations in the received signal caused by the channel. A demodulator 38 multiplies the complex-valued signal 37 by ej(ω
r[n] =Σkx[k]a[n−k]+w[n]
where a[n] is the equivalent discrete-time baseband model of the PAM communication system and where w[n] is additive noise. The demodulator function 38 may optionally follow the sampler 42 to allow the demodulator 38 to be implemented in discrete time rather than continuous time. Additionally, both carrier recovery and timing recovery may be decision directed, in which case feedback from the output of the receiver is needed. The received samples r[n] are next passed to an equalizer system 44 configured in accordance with the present invention.
The equalizer 44 processes the received data r[n] in a block-iterative fashion. Specifically, during each iteration or “pass”, a linear filter processes the received data, and tentative decisions made during a previous iteration are used to construct and subtract out an estimate of the ISI. The resulting ISI-reduced data is then passed on to a slicer, which generates a new set of tentative decisions. With each successive iteration, increasingly refined hard decisions (i.e., decisions made by the slicer 58 of
[n]=Σkbl[kP]r[n−kP]
where P and Q are preferably prime integers with P<Q. (If a symbol-spaced equalizer is to be implemented, then P=Q=1. If, however, a fractionally-spaced equalizer is to be implemented, then P=1 and Q=2 in most cases when there is not more than 100% excess bandwidth.) The output of a second filter, referred to herein as a “feed-back filter” dl[n] 52 and the input to a decision device, for example a slicer 58, are preferably both at the baud rate, so [n] 51 is downsampled at downsampler 54 by a factor of Q to provide downsampled signal {tilde over (r)}l[n] 55. Next, an appropriately constructed estimate {tilde over (z)}l[n] 53 of the ISI is subtracted from downsampled signal {tilde over (r)}l[n] 55 at subtractor 56 to produce signal {tilde over (x)}l[n] 57, where
{tilde over (x)}l[n]={tilde over (r)}l[n]−{tilde over (z)}l[n],
and where
{tilde over (z)}l[n]=Σkdl[k]{tilde over (x)}l−1[n−k].
Since {tilde over (z)}l[n] is intended as an ISI estimate, the zero-delay tap of the feedback filter dl[n] 52 is set at zero. The slicer 58 then generates the new set of hard decisions {tilde over (x)}l[n] 59 from {tilde over (x)}l[n] using, for example, the well-known minimum-distance rule. Note that alternative functions are equally applicable to the present invention. For example, the subtractor 56 may comprise an adder or other means for combining the filtered signals from the feed-forward and feed-back filters 54, 52.
Further details of the invention depend on whether the channel is known at the receiver, partially known at the receiver, or unknown at the receiver. The known case determines the filter parameters using a fixed set of channel parameters, for example a known transfer function of a specific channel (wire, fiber optic, air, etc.). In the unknown case, the channel parameters are unknown, and the invention instead determines the filter parameters from the received data, using, for example, predetermined training symbols. In the partially-known case, an initial estimate of the channel parameters is used, and the iterative nature of the equalizer of the present invention is used to improve the channel estimate at the end of each pass. In each of the known, unknown and partially-known cases, during each pass, the feed-forward and feed-back filter parameters 50, 52 are modified.
Known Channel
When the channel is known at the receiver and P=Q=1, one possibility is to select the feed-forward filter bl[n] 50 and the feed-back filter dl[n] 52 during the l th pass to maximize the signal-to-interference+noise ratio (SINR) at the slicer input, in which case the discrete-time Fourier transforms of the feed-forward filter bl[n] 50 and the feed-back filter dl[n] 52 are respectively
where A(ω) is the Fourier transform of the equivalent discrete-time baseband model of the PAM communication system, εs is the energy of the transmitted symbols, N0 is the variance of the additive noise due to the channel, E[·] is the expectation operator (alternatively, the expectation E[·] can be replaced by a frequency average
and ρxl−1 is the normalized correlation between the transmitted data sequence x[n] 59 and the previous set of tentative decisions made on the previous iteration {tilde over (x)}l−1[n] 60, i.e., ρxl−1≈E[x*[n]·{tilde over (x)}l−1[n]]/εs. A possible method for computing the set of correlation coefficients ρxl in the special case of M-PSK data symbols is the following iterative technique:
1. Set ρx0=0 and let l=1.
2. Compute the SINR γl at the slicer 58 input on the l th decoding pass from ρxl−1 via
and
ξl=N0[εs<|A(ω)|2>(1−(ρxl−1)2)−1.
Optionally, γl can be computed (and in some cases more accurately) from ρxl−1 via
3. Compute the normalized correlation coefficient ρxl between the symbols x[n] and the decisions {circumflex over (x)}l[n] 59 generated at the slicer 58 via
4. Increment l and go to step 2.
Partially Known Channel
When the channel is partially known at the receiver, the performance of the receiver may become particularly sensitive to the accuracy of the channel estimate used by the equalizer. To prevent such sensitivity, the equalizer can be modified to use an estimate of the channel impulse parameters with some degree of uncertainty as opposed to a fixed estimate of the channel parameters (as in the known-channel case). When P =Q=1, one possibility is to use the techniques for the known-channel case described above, except that the fixed channel A(ω) is replaced by the channel estimate Â(ω),and the noise variance N0is replaced by N0+εs<|A(ω)−Â(ω)2 |>. Furthermore, it is possible to exploit the iterative nature of the equalizer to improve the channel estimate at the end of each pass, thus leading to a higher SINR in the slicer 58, which in turn lowers the probability of symbol error. At the end of the l th pass, the equalizer has knowledge of the received sequence r[n] and the decisions {circumflex over (x)}l[n] of the current pass, for n=0, 1, . . . , N−1. For the purpose of estimating the channel impulse response a[n], it may be assumed that r[n] and {circumflex over (x)}l[n] are zero prior to n=0 and after n=N−1. Furthermore, for illustrative purposes, it is assumed here that a[n] is nonzero for n =0, 1, . . . , N−1. If two vectors are defined
âl=[âl[0]âl[1]. . . âl[l−1]]*
{circumflex over (x)}l[n]{circumflex over (x)}l[n]{circumflex over (x)}l[n−1]. . . {circumflex over (x)}l[n−L+1]]T
(where the superscript “*” denotes the conjugate-transpose operation for vectors and the conjugation operation for scalars, and where the superscript “T” denotes transposition), then the difference between the received data symbols and the response of the channel to the most recent set of decisions; i.e.,
is minimized when
ãoptl=[Φl]−1ul,
where
For M-PSK symbols, the variance of the error in the channel estimate el[n]=a[n]−âl[n]made at the end of the l th pass is approximately
If, at the l th pass, the variance (σel−1)2 of the channel estimate made at the end of the previous pass is smaller than the variance of the channel estimate used for the (l−1) th pass, then the former should be used. If, on the other hand, the variance (σel−1)2 is larger than the variance of the channel estimate used for the (l−1) th pass, then the estimate used for the (l−1) th pass is used again for the l th pass.
Unknown Channel
When the channel is unknown at the receiver, an adaptive version of the present invention is required, in which optimal FIR filter coefficients are selected automatically (from the received data) without explicit knowledge of the channel characteristics.
The multipass equalizer of the present invention is designed to process received data in a block-iterative fashion, so it is ideally suited for packet communication in which the packet size is chosen small enough that the channel encountered by each packet appears linear time-invariant. As is typically the case with other adaptive equalizers, the adaptive iterated-decision equalizer makes use of training symbols sent along in the packet with the data symbols. Suppose that a block of white M-ary PSK symbols x[n] for n=0,1, . . . N−1 is transmitted; some of the symbols (not necessarily at the head of the packet) are for training, while the rest are data symbols.
The feed-forward filter bl[n] 50 and the feed-back filter dl[n] 52 for the l th iteration preferably comprise finite-length filters. Specifically, the feed-forward filter bl[n] 50 has J1 strictly anticausal taps and J2 strictly causal taps plus a center tap, while the feed-back filter dl[n] 52 has K1, strictly anticausal taps and K2 strictly causal taps with no center tap.
Prior to the first pass (l=1), the hard decisions {circumflex over (x)}0[n] are initialized. Since the locations and values of the training symbols in x[n] are known at the receiver, the hard decisions are initialized as {circumflex over (x)}0[n] =x[n] for the n corresponding to those locations. For all the other n between 0 and N−1 inclusive, {circumflex over (x)}^0[n] is set to a “neutral” value; as an example, for white PSK symbols, this value should be zero.
On the l th pass of the equalizer where l=1, 2, 3, . . . the slicer 58 input {tilde over (x)}l[n] can be expressed as
{tilde over (x)}l[n]=cl*ql[n]
where
and
bl=[bl[−J1P]. . . bl[−P]bl[0]bl[P]. . . bl[J2P]]*
dl=[dl[−K1]. . . dl[−1]bl[1]. . . dl[K2]]*
r[n]=[r[nQ+J1P]. . . r[nQ+P]r[nQ]r[nQ−P]. . . r[nQ−J2P]]T
{circumflex over (x)}l−1[n]=[{circumflex over (x)}l−1[n÷K1]. . . {circumflex over (x)}l−1[n÷1]{circumflex over (x)}l−1[n−1]. . . {circumflex over (x)}l−1[n−K2]]T.
Using, for example, a minimum-distance rule, the slicer 58 next generates the hard decisions {circumflex over (x)}l[n] from {tilde over (x)}l[n] for all n between 0 and N−1 inclusive, except for those n corresponding to the locations of training symbols in x[n]. For those n, the hard decisions are set to {circumflex over (x)}l[n]=x[n].
During the l th iteration, there are two sets of data available to the receiver: the received data r[n] and tentative decisions from the previous iteration {circumflex over (x)}l−1[n], n=0,1, . . . , N−1. If it is assumed that x[n]≈{circumflex over (x)}l−1[n] for the purpose of determining the optimal filters (as is similarly done in the adaptive DFE in decision-directed mode), then it is reasonable to choose the feed-forward filter parameters bl[n] 50 and the feed-back back filter parameters dl[n] 52 so as to minimize the sum of error squares:
Since this is a linear least-squares estimation problem, the optimum cl is represented by:
coptl=[Φl]−1ul,
where
The resulting equalizer lends itself readily to practical implementation, even for large filter lengths. In particular, the matrix Φl can be efficiently computed using correlation functions involving r[n] and {circumflex over (x)}l−1[n]. Specifically, if the following deterministic correlation functions are defined as:
then Φl can be expressed as
Note that in general, none of the matrices β, Θl, or Ψl is Toeplitz. However, Θl is a (K1+K2+1)×(K1+K2+1) Toepl itz matrix with its (K1+1) th row and (K1+1) th column deleted, and β exhibits cyclostationary properties with each diagonal having a period of Q. Moreover, depending on the values of P and Q, the matrix Ψ1 may have a significant number of entries that have the same value. Thus, the special structure in Φl can be exploited so that the redundant computation of repeated entries is avoided. Furthermore, since Φl is a Hermitian matrix, it is only necessary to compute half of the distinct entries. In the special case of P=Q=1, β is a Toeplitz matrix, and Ψl can be thought of as originating from a (J1+J2+1)×(K1+K2+1) matrix with the elements on each diagonal being equal, but now with the (K1+1) th column deleted. In this special case, the computation of Φl requires only 2(J1+J2 +K1+K2 +1) of the (J1+J2 +K1+K2 +1)2 entries, as there are only that many distinct entries. If the total number of taps in the equalizer is 100, then the computation of Φl has been made approximately 50 times more efficient! The computation of [Φl]−1 can also be made more efficient. Specifically, since Φl can be expressed as a partitioned matrix in which β and Θl are square, [Φl]−1 can be partitioned into
where {tilde over (β)}l, {tilde over (Θ)}l, and {tilde over (Ψ)}l have the same sizes as β, Θ, and Ψl respectively. Note that this takes advantage of the fact that the inverse of a Hermitian matrix is also Hermitian. Then, the matrices {tilde over (β)}l, {tilde over (Θ)}l and {tilde over (Ψ)}l can be computed either by the formulas
{tilde over (β)}l=(β−Ψl[Θl]−1Ψl
{tilde over (Ψ)}l=−(β−Ψl[Θl]−1Ψl
{tilde over (Θ)}l=[Θl]−1÷(Ψl[Θl]−1)t·(β−Ψl[Θl]−1Ψl
or by the equivalent formulas
{tilde over (β)}l=β−1+(β−1Ψl)·(Θl−Ψl
{tilde over (Ψ)}l=−(β−1Ψl)·(Θl−Ψl
{tilde over (Θ)}l=(Θl−Ψl
(See H. Lütkepohl, Handbook of Matrices. Chichester, England: Wiley, 1996.) The factors within parentheses in the two above sets of equations indicate quantities that need to be computed only once for a given l. So if the first set of formulas is used, then
[Θl]−1, (β−Ψl[Θl]−1Ψl
should be computed in that order during each iteration. Similarly, if the second set is used, then
β−1, (β−1Ψl), (Θl−Ψl
should be computed in that order during each iteration. In either case, the task of computing [Φl]−1 has been modified into a task involving the computation of an inverse matrix the size of β and another inverse matrix the size of Θl. One advantage of using the second set of formulas is that the same β−1 is used during all iterations, so it only needs to be computed once during the whole multipass process. Thus, the only matrix inverse that needs to be computed during each iteration (except for the first iteration) is
(Θl−Ψl*β−1Ψl)−1.
and the original task of computing the inverse of a (J1+J2+K1+K2+1)×(J1+J2+K1+K2+1) matrix has been converted into a task involving the computation of the inverse of a (K1+K2)×(K1+K2) matrix. If J1 is large, and J1=J2 =K1=K2, then a reduction of computation by an order of magnitude is plausible. We now turn to a couple of implementation issues. First, when P=Q =1, the finite-length adaptive filters ideally approximate
which are infinite in length. The optimal feed-forward filter bl[n] includes a filter matched to a[n], and the optimal dl[n] includes a cascade of a[n] and the corresponding matched filter, suggesting that a reasonable rule of thumb is to select J1, J2, K1, K2 such that each FIR filter covers twice the span of the channel impulse response. Second, the block-iterative nature of the equalizer allows the training symbols to be located anywhere in the packet. Since (in contrast to the DFE ) the locations do not appear to affect equalizer performance, the training symbols are arbitrarily chosen to have uniform spacing within each packet.
Error-Control Coding
In most communication systems, it is preferred to have the ability to apply error-control coding (ECC) to the data prior to modulation and transmission. Examples of error-control codes include block codes, convolutional codes, and trellis-coded modulation. The present invention includes two implementations of the equalizer that allow such coding to be explicitly taken into account at the receiver. In one version, equalization and error-correction decoding are performed separately. This implementation is obtained by processing the final decisions of the equalizer using a decoder placed after the equalizer in
Implementation for Transmitter Antenna Arrays
Many communication systems, especially wireless ones, use a transmitter antenna array, whereby the data to be transmitted are sent from each of a set of different antenna elements. One possible transmitter structure which uses m antennas to exploit spatial diversity is depicted in
The present invention includes an implementation of the block-iterative equalizer that is designed for use with a transmitter antenna array like the one described above. If the channel can be described by a nonselective fading model, shown in
where w[n] 84 is additive noise and a1, a2, . . . , am 80 are fading coefficients. Alternatively, the received signal can be expressed in the form
is the impulse response of the “effective” channel generated by the antenna precoder. The channel has a frequency response of
so the antenna precoding effectively transforms the original nonselective fading channel into a frequency-selective fading channel, and the implementation of the block-iterative equalizer corresponding to
Multichannel Implementation
In many communication systems, especially wireless ones, multiple copies of the transmitted waveform are received, each being distorted differently. Such is the case, for example, when the transmission is received by a multiple element array. In such cases, it is common to use an equalizer with what is referred to as a multichannel implementation for jointly processing the received streams. For such applications, the present invention includes an efficient multichannel implementation of the block-iterative equalizer, which can enhance performance over the single channel implementation.
The structure of a multichannel, fractionally spaced iterated-decision equalizer is depicted in
where x[n] is the sequence of transmitted symbols, ai[n] is the equivalent discrete-time baseband model of the i th channel, and wi[n] is the additive noise of the i th channel. Therefore, in this embodiment, the main difference in the equalizer is that instead of one fractionally-spaced feed-forward filter, there are now m such filters 90. The operation of the equalizer remains essentially the same, except that the output of the feedback branch 92 is now subtracted from the sum of the feedforward branch outputs, rather than from just a single feedforward branch output.
If the multiple channels are unknown at the receiver, the technique employed in the single channel case can be generalized. Thus, the slicer input {tilde over (x)}l[n] can be expressed in vector form as
{tilde over (x)}l[n]=cl* ql[n]
where
and
bil=[bil[−J1P]. . . bil[−P]bil[0]bil[P]. . . bil[J2P]]*
dl=[dl[−K1]. . . dl[−1]dl[1]. . . dl[K2]]*
ri[n]=[ri[nQ÷J1P]. . . ri[nQ÷P]ri[nQ]ri[nQ−P]. . . ri[nQ−J2P]]T
{circumflex over (x)}l−1[n]=[{circumflex over (x)}l−1[n÷K1]. . . {circumflex over (x)}l−1[n÷1]{circumflex over (x)}l−1[n−1]. . . {circumflex over (x)}l−1[n−K2]]T.
If b1l[n], b2l[n], . . . ,bmll[n], and dl[n] are chosen so as to minimize the sum of error squares:
then the optimum clis
coptl=[Φl]−1ul,
where
The computation of the matrix Φl can be made more efficient by first defining the following deterministic correlation functions
Thus , for m channels, the matrix Φl may be rewritten as
Note that in general, none of the matrices βij, Θl, or Ψil is Toeplitz. However, Θl is a (K1+K2+1)×(K1+K2+1) Toeplitz matrix with its (K1+1) th row and (K1+1) th column deleted, and βij exhibits cyclostationary properties with each diagonal having a period of Q. Moreover, depending on the values of P and Q, the matrix Ψil may have a significant number of entries that have the same value. Thus, the special structure in Φl can be exploited so that the redundant computation of repeated entries is avoided. Furthermore, since Φl is a Hermitian matrix, it is only necessary to compute half of the distinct entries.
As in the single-channel case, the computation of [Φl]−1 for the multichannel equalizer can be made more efficient by partitioning Φl into four submatrices such that the upper left and lower right submatrices are square, and then applying the formulas for the inverse of a partitioned matrix. Since these formulas involve computing the inverses of two matrices with the same sizes as the upper left and lower right submatrices, it is usually best to partition Φl into submatrices of approximately the same size so that computation of a large matrix inverse is avoided.
Multiuser Implementation
The present invention further comprises a block-iterative multiuser equalizer that jointly takes into account multiple-access, co-channel, and extra-network interference, which are generally experienced in communication networks, especially wireless networks. For multiple-access interference in particular, the invention jointly suppresses intersymbol and multiple-access interference in a manner generalizing the structure of
The signal at the receiver is typically modelled as
where p is the number of users, xi[n] is the sequence of symbols transmitted by the i th user, ai[n] is the equivalent discrete-time baseband model of the channel encountered by the ith user, and w[n] represents additive noise and interference.
The multiuser, fractionally spaced iterated-decision equalizer consists of p main branches, with each branch designed to decode the symbol stream of a different user. The structure of the i th branch, shown in
If the channels are unknown at the receiver, the approach for the single-user case can be generalized for the multiple-user case. Thus, for the i th user, the slicer input {tilde over (x)}il[n] can be expressed in vector form as
{tilde over (x)}il[n]=cil* qil[n]
where
where j=1,2, . . . p. If bil[n], d1il[n], d2il[n], . . . dpil[n] are chosen so as to minimize the sum of error squares:
then the optimum cil for the i th user is
ci,optl=[Φil]−1uil,
where
Joint Transmitter and Receiver Design
The present invention is further directed to an embodiment in which the transmitter has available at least partial information about the channel state (for example, via a low-delay feedback path from receiver to transmitter). In this situation, significant performance enhancements can be achieved. For example, if the transmitter has exact knowledge of the channel characteristics, part of the equalization can be performed at the transmitter so that noise enhancement and/or error propagation can be avoided. This idea is analogous to Tomlinson-Harashima preceding; see (a) M. Tomlinson, “New automatic equalizer employing modulo arithmetic,” Electon. Lett., vol. 7, pp. 138--139, March 1971. (b) H. Miyakawa and H. Harashima, “A method of code conversion for a digital communication channel with intersymbol interference,” Trans. Inst. Electron. Commun. Eng. Japan, vol 52-A, pp. 272--273, June 1969. (c) H. Harashima and H. Miyakawa, “Matched-transmission technique for channel with intersymbol interference,” IEEE Trans. Commun., vol. COM-20, pp. 774--780, August 1972.
While this invention has been particularly shown and described with references to preferred embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.
For example the first and second filters specified above may comprise linear, non-linear, time-variant, time-invariant, infinite-impulse response, and finite impulse response filters. Although the above description of the preferred embodiment of the present invention pertains to equalization of digital signals, the principles of the present invention apply equally well to equalization of analog signals, using, for example, analog equivalents of the first and second filters, the combiner, and the slicer.
The Government has rights in this invention pursuant to Contract Number N00014-96-1-0930, awarded by the Office of Naval Research.
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