The present invention generally relates to wireless communications, and more particularly to hybrid time-frequency domain iterative methods of equalizing and demodulating of received single-frequency wireless communication signals subjected to the multi-path interference, and to hybrid channel equalizers implementing such methods.
In any receiver system, the channel equalizer is an essential component, improving the bit error rate (BER) by correcting the received signal for the effects of the channel. The multi-path interference, which is commonly referred to in the art simply as the multipath, presents particular problems for wireless communication systems, where a transmitted signal my arrive at the receiver over multiple transmission paths. For example, in a system having a single transmitter, the multipath transmission of a signal may occur because of signal reflection, so that the receiver receives a transmitted signal and one or more reflections of the transmitted signal. As another example, the multipath transmission of a signal may occur in a system having plural transmitters that transmit the same signal to a receiver using the same carrier frequency. A network which supports this type of transmission is typically referred to as a single frequency network (SFN).
One example of wireless communication systems wherein the multi-path interference may present particular problems at the receiver is the broadcasting of digital television (DTV) signal. In the United States, the DTV broadcasting has been done using vestigial-sideband (VSB) modulation format in accordance with the Digital Television Standard, the latest edition of which published in December 2005 by the Advanced Television Systems Committee (ATSC) as Document A/53E. The ATSC-VSB data stream as specified by the ATSC has two modes. The first mode designed for terrestrial broadcasting, modulates data onto an RF data carrier frequency signal using 8 levels to represent data symbols of 3 bits each. This is known as 8 VSB. A second mode is available for higher band width cable transmissions which modulates the information using 16 levels of 4 bits each (16 VSB). Although the invention is described herein in connection with the 8 VSB mode, it is equally applicable for use 16 VSB mode. In a terrestrial DTV transmitter, the 8 VSB DTV signal is transmitted with a suppressed very-high-frequency (VHF) or ultra-high-frequency (UHF) natural carrier, with a fixed-amplitude pilot carrier corresponding in frequency and phase with the suppressed natural carrier.
As described in “ATSC Digital Television Standard” and illustrated in
Receiver performance in the presence of multipath has been considered as one of the main weaknesses of the 8-VSB modulation used in the ATSC system. The introduction of the single frequency network with multiple transmitters for delivering the DTV signal brings new challenges for the ATSC equalizer design, since the delay spread of a multipath channel under such scenario becomes significantly longer than in the traditional broadcasting practice of using one high power facility to cover a wide area, where the multipath distortion are from reflected echoes. This is illustrated in
The component of the broadcast DTV signal to which a DTV receiver synchronizes its operations is called the principal signal, and the principal signal is usually the strongest component of the broadcast DTV signal. The direct line-of-sight path from the closest transmitter is usually the path resulting in the strongest component of the broadcast DTV signal, if the direct line-of-sight path is not blocked by any intervening barrier to transmission; it is commonly referred to as the main path. Therefore, the multipath signal components of the broadcast TV signal received over other paths and from other transmitters are usually delayed with respect to the principal signal and appear as lagging multipath, signals resulting in the presence of echoes in the received signal. For the example shown in
It is possible however, that the direct or shortest path signal is not the signal to which the receiver synchronizes. When the receiver synchronizes its operations to a longer path signal that is delayed respective to the direct signal, there will be a leading multipath component caused by the direct signal. There may also be other leading signals caused by other reflected signals of lesser delay than the signal to which the receiver synchronizes. In the DTV art the multipath components of received signal are customarily referred to as “echoes”. The leading multipath components are referred to as “pre-echoes”, and the lagging multipath components are referred to as “post-echoes”. The echoes vary in number, amplitude and delay time from location to location and from channel to channel at a given location.
For a satisfactory reception of the ATSC signal, the overall channel impulse response must fit within a time window TEQ of the ASTC equalizer used in the receiver, TEQ being the time window inside which echoes can be ‘equalized’, i.e. compensated for so as not to affect the receiver performance. For the example shown in
The amplitudes of correctable echoes are a function of their time displacement from the main signal, and are quickly reduced as the relative time delay increases; i.e. the closer together the multi-path signal components are in time, the stronger they can be in amplitude, and the further apart they are in time, the lower in level the echoes must be for the equalizer to work. Currently, best commercially available ATSC receivers employ time-domain equalizers that can only handle −10 dB echoes from −29.5 μs to 38.5 μs. As the result, the propagation path difference corresponding to different echoes can only be up to around 10 km for the ATSC receivers based on the current time domain equalizer technology. Notably, reflected echoes in urban deployment may substantially increase the propagation path differences among the echoes. It would be thus advantageous to increase the capability of the receiver to handle channels with very long delay spread.
Frequency domain equalizers can be more efficient than time-domain equalizers in handling long delay spreads, and are presently employed in wireless systems based on the Orthogonal Frequency Domain Multiplexing (OFDM), or in wireline Discrete Multitone (DMT) modulation. In these transmission techniques, each N-sample encoded symbol is prefixed with a cyclic extension to allow signal recovery using the cyclic convolution property of the discrete Fourier transform (DFT). Alternatively, the extension may be appended to the end of the signal as well. If the length of the cyclic prefix is greater than or equal to the length of the impulse response, the linear convolution of the transmitted signal with the channel becomes equivalent to a circular, or cyclic convolution (disregarding the prefix). If the channel impulse response is shorter than the length of the periodic extension, the original symbols can then be recovered by transforming the received time domain signal to the frequency domain using the DFT (implemented using, e.g., the FFT), and performing equalization using a bank of single tap frequency domain equalizer (FEQ) filters. For the cyclically extended signals, the FEQ effectively deconvolves (circularly) the signal from the transmission channel response, effectively canceling the echoes and restoring the originally transmitted signal.
However, the cyclic prefix is not available in existing signal carrier modulated broadcast and communication systems, including ATSC and GSM. In addition, if such a cyclic prefix is to be used, its length would have to be longer than the duration of the channel impulse response, which would introduce excessive redundancy and would limit the system throughput when the channel duration is long.
An object of this invention is to provide a hybrid time-frequency domain equalizer for equalizing a signal transmitted in a single frequency network receiver without a cyclic prefix.
Another object of this invention is to provide an efficient hybrid time-frequency domain equalizer for use in ATSC receivers.
Another object of this invention is to provide an iterative hybrid-domain method of channel equalizing for single-carrier signals transmitted without a cyclic prefix.
In accordance with the invention, a method of channel equalizing is provided for use in a wireless receiver for receiving a signal via a communication channel subjected to multi-path interference, wherein said signal transmitted without a cyclic prefix using a single carrier frequency. The method comprises the steps of: a) receiving a sequence of samples of the transmitted signal, each sample representing a transmitted symbol subjected to channel distortions; b) based on an initial channel estimation, generating a frequency response transfer function (hf) for a block of transmitted symbols of a pre-defined length, and a time-domain channel echo response function (CT); c) iteratively equalizing blocks of samples from the received sequence of samples using a frequency-domain equalization in a feedforward path, and time-domain inter-block echo cancellation and cyclic echo correction in feedback paths.
In accordance with one embodiment of the invention, step (c) of the method comprises the following steps: A) updating a current block by subtracting from a first end portion thereof an estimated contribution of an inter-block echo, said inter-block echo produced from a portion of the transmitted signal preceding the current block; B) performing frequency-domain equalization for the updated current block using the frequency response transfer function to obtain a frequency-equalized block; C) generating symbol estimates for the current block by making decisions on samples of said frequency-equalized block; D) estimating an echo signal from the current block by applying the time-domain channel echo response function to the symbol estimates for the current block; E) updating the current block by cyclically adding the estimated echo signal from the current block to the first end portion of the current block; and, F) repeating steps (B) and (C) to update the symbol estimates for the current block.
Another aspect of the invention provides a hybrid domain channel equalizer for equalizing a signal received via a communication channel in the presence of multi-path interference, said equalizer comprising:
a forward circuit having an input port for receiving an input time-domain signal and an output port for outputting an equalized time-domain signal, said forward circuit comprising a frequency-domain equalizer and a decision circuit; and,
a feedback circuit connected between the output port and the input port for producing interference (echo) compensating signals from the equalized time-domain signal in the time domain, and for combining said interference compensating signals with the input time-domain signal at the input port for compensating channel generator echo components of the input signal at the input port.
In a preferred embodiment of this aspect of the invention, the hybrid domain channel equalizer further comprises an input S/P converter for providing the input time-domain signal to the input port in blocks of N signal samples, and the feedback circuit comprises a first feedback loop for inter-block echo cancellation, and a second feedback loop for intra-block cyclic echo addition.
The invention will be described in greater detail with reference to the accompanying drawings which represent preferred embodiments thereof, wherein:
a is a diagram illustrating three consecutive blocks of transmitted symbols;
b is a diagram illustrating a triangular impulse response of a multi-path channel;
c is a diagram illustrating the effect of the multipath channel shown in
The following notations are used in this specification: matrix quantities are denoted using upper-case bold characters, e.g. C, vector quantities are denoted using lower-case bold characters, e.g. x, scalar quantities are denoted in lower-case italics, with the notation x(n) or xn denoting an n-th element of a vector x, with ‘n’ representing a time sample. The notations DFT{x} and IDFT{x} denote a digital Fourier transform (DFT) operation on a vector x and a corresponding inverse operation, respectively, with FFT{x} and IFFT{x} denoting the fast Fourier transform (FFT) and its inverse operation (IFFT), respectively.
In addition, the following is a partial list of abbreviated terms and their definitions used in the specification:
The instant invention provides a method and apparatus for iterative hybrid-domain equalizing of a signal received via a communication channel with multipath interference characterized by long delay spread and long echoes. The multipath distortion in the received signal is first tentatively removed with a frequency domain equalizer on a block-by-block basis. A time domain interference cancellation algorithm is then used to cancel the inter-block interference (IBI) and intra-block interference (IABI) in the time domain, based on tentative decisions from the frequency domain equalizer. These two steps are iterated until desired receiver performance is achieved.
Exemplary embodiments of the method of signal equalization of the current invention and of the equalizer realizing this method will now be described with references to diagrams shown in
Furthermore, the invention will be described herein with reference to an ATSC DTV receiver 100 for receiving an 8-VSB modulated DTV signal, where 8-VSB denotes the vestigial sideband modulation with 8 discrete amplitude levels. However, one skilled in the art will appreciate that the invention can also be used for equalizing other types of communication signals, in particular those transmitted without the use of cyclic extension such as cyclic prefix via a communication channel subject to multipath interference.
As show in the simplified diagram of
In one embodiment, the SyncD unit 115 also performs preliminary blind channel estimation using one of the known in the art techniques, and generates at least a preliminary estimate for a time-domain channel impulse response (CIR) function, which for the purpose of this description will be represented as a vector h having L elements hn commonly referred to as CIR tap coefficients:
h=[h0, h1, . . . , hL−1]T, (1)
where the superscript ‘T’ denotes the operation of the matrix/vector transposition. In another embodiment, the CIR estimation is done in a central controller unit 130 of the IHDE 105, which includes functional blocks schematically shown in
The IDHE 105 of the present invention receives the sequence of signal samples {r[j]}, performs channel equalization and demodulation as described herein below, and provides a sequence of demodulated symbols as its output 180; the output 180 of the IDHE 105 is passed to a decoder, which in the case of the ASTC receiver customary includes a trellis decoder followed by a data de-interleaver, a Reed-Solomon decoder, and a data de-randomizer; all these elements are well known in the art and not shown in
The IHDE 105 includes a 1 to N serial-to-parallel (S/P) converter 120 at its input, and an N to 1 parallel-to-serial converter (P/S) 145 at the output; the S/P converter 120 connects to an adder/subtractor 122, which can be embodied as a subtractor followed by an adder, and which in turn connects to an input port 123 of a feed-forward equalizing circuit 152, the feed-forward equalizing circuit 152 having output port 144 that connects to an input port of the P/S converter 145. The adder/subtractor 122 adds signal 167 to signal 121, and subtracts signal 163 from signal 121, to form the time-domain input signal 123 for the forward circuit 152. The results of these adding/subtracting operations are provided to the CC 130 and stored in a buffer 136 therein for use in future iterations, as described hereinbelow. The feed-forward equalizing circuit 152 includes a frequency equalizer (FEQ) unit 135, and will also be referred to herinafter as the forward FEQ circuit 152, or simply as the forward circuit 152. Note that in
The feed-forward circuit 152 includes a DFT converter 125 for converting a time-domain signal received at the input port 123 into the frequency domain, the FEQ 135 and an IDFT converter 140 for converting the frequency-equalized signal from the frequency domain to the time domain. The IDFT converter 140 includes a decision device for making hard decisions on the frequency-equalized signal to obtain symbol estimates after said frequency-equalized signal is converted to the time domain. In a preferred embodiment, the DFT and IDFT converters 125, 140 use FFT and IFFT algorithms, respectively.
The IHDE 105 of the present invention further includes a time-domain echo-correcting feedback circuit 150, which is connected between the output port 144 of the forward circuit 152 to its input port 123 to provide a time-domain feedback to the forward frequency-equalizing circuit 152. The feedback circuit 150 includes a first feedback loop 142-143-155-160-163-122 for inter-block echo cancellation, and a second feedback loop 142-143-165-163-122 for performing cyclic echo correction, as described hereinafter. The first and second feedback loops of the feedback circuit 150 have a common input 143 which is coupled to the output port 144 of the forward FEQ circuit 152 by means of an iteration control unit (ICU) 142 for switching the output of the IDFT block 140 between the P/S controller 145 and the feedback circuit 150 in dependence on satisfying a pre-determined condition. A central control unit (CC) 130 performs iterative channel estimation and computes various control parameters as described hereinbelow, including the block size N which is then passed to the S/P converter 120; the CC 130 includes a buffer for storing block signals generated by functional units 120, 122, and 140, which are used in the iterative channel estimation.
In operation, the stream of signal samples {r[j]} is first received by the S/P converter 120, where said stream is converted to a sequence of signal blocks, which are then passed (arrow 121) to the adder block 122 at the input of the forward FEQ circuit 152. Each said block has N samples and is passed within the IHDE 105 using parallel connections. An i-th signal block can be conveniently represented by a vector ri of size N:
ri=[ri(0), ri(1), . . . , ri(N−1)]T, (2a)
where i=0,1, . . . denotes a sequence number of the block.
In the embodiment shown in
An i-th received block ri is related to a block of N transmitted symbols represented by a vector xi
xi=[xi(0),xi(1), . . . ,xi(N−1)]T (2b)
through an operation of convolution with the channel impulse response:
ri=h{circle around (×)}xi+wi (3a)
where vector wi represents an additive white Gaussian noise (AWGN) and has the same size as r and x. Relation (3a) can be equivalently expressed through the following matrix equation:
The matrix in the right-hand-side (RHS) of equation (3b), of size (N+L−1)×N, where L is the channel length, describes the effect of the channel including the multipath interference and is composed of the CIR coefficients hn, the subscript ‘i’ denoting the block's position in the transmitted sequence is omitted for simplicity.
a-4c illustrate graphically the effect of a static multi-path channel on three consecutive blocks of symbols xi−1, xi and xi+1. In
As can be seen from
For instance, if OP 225 is chosen for the demodulation of the i-th block, then both a post-echo 215 of the previously transmitted block 201, and a pre-echo 216 from the following symbol block 203 have to be estimated and cancelled. On the other hand, if an observation period 221, is chosen instead for the demodulation of the i-th block, then only the IBI associated with the post-echo 222 from the preceding block 201, needs to be cancelled.
Comparing OP 221 and OP 225, we find that there is slightly more IBI in OP 221 although the overall number of IBI corrupted samples is identical for the two OPs. However, a disadvantage of using OP 225 for demodulation of the i-th block 202 is that the IBI from the pre-echo 216 of the (i+1)-th block 203 has to be cancelled during the demodulation of the i-th block. This cancellation may not be accurate since information about the (i+1)-th block is not yet available at the time of demodulation of the i-th block 202. In addition, iterative IBI cancellation from two adjacent signal blocks is much more complicated than the IBI cancellation from only the preceding signal block. Based on the aforementioned observations, the method of the present invention in its preferred embodiment uses the OP 221 for the demodulation of the i-th block, so that only the post-echo from the preceding (i-1)st block needs to be cancelled.
The following description provides a mathematical foundation for the method of iterative hybrid-domain equalization of the present invention that the IHDE 105 implements.
First, we note that the rectangular matrix in the RHS of equation (3b) may be decomposed into two N×N matrices that are more convenient for analysis of the inter-block interference (IBI) and intra-block interference (IABI), wherein the later refers to inter-symbol interferences (ISI) for symbols within the same signal block x, which includes the aforedescribed multi-path induced echoes. The first matrix,
represents the effect of the communication channel 101 on a signal block, e.g. the block 202 in
The second matrix,
represents the tail end of the channel's impulse response that gives rise to the inter-block echoes, e.g. echoes 222 and 223 in
ei=CT·xi (6)
Using these two matrices, equation (3b) can be re-written in the following form
ri=C·xi+CT·xx−i+w, (7)
which expresses the i-th signal block received in the observation period 225 as a sum of the channel-distorted symbol block 201, which is represented by the first term in the RHS of equation (7), and the previous block echo signal ei−1=CT·xi−1.
Next, we note that the two matrices C and CT have a very useful property that their summation produces a cyclic matrix Ccycl,
C+CT=Ccycl. (8)
Advantageously, the cyclic matrix Ccycl is a matrix that generates the operation of a cyclic convolution of the transmitted signal with the channel when applied to a signal block vector:
yi=Ccycl·xi; (9)
Those skilled in the art will appreciate that, would the cyclic block vector yi on the RHS of equation (8) be known, the originally transmitted symbol block xi could be easily obtained using a frequency-domain equalizer with a single-tap frequency filter. Indeed, in the frequency domain the operation of the cyclic convolution in the RHS of eq. (9) corresponds to a simple element-by element multiplication of the channel frequency response transfer function
hf=DFT{h}, (10)
wherein the size of DFT in equation (10) is N, and the Fourier-transformed transmitted symbol block xi, so that:
DFT{yi}=hf·DFT{xi}. (11)
The following equation for the cyclic block vector yi can be obtained from equations (3b)-(9):
yi=ri−ei−1+ei, (12)
where the noise term w is omitted for the sake of clarity of the following description, and because the signal reception for the DTV networks is typically limited by the multipath distortions associated with the terms ei−1=CT·xi−1, and ei=CT·xi, rather than by noise.
Note that the operation (ri+ei) in the RHS of equation (12) can be described as a cyclic addition of an echo from a tail end portion of the current block, said echo corresponding in
Equation (11) provides a mathematical foundation for the iterative signal equalization method of the present invention and for the operation of the IHDE 105, wherein equalization and demodulation of the i-th received signal block can be described as substantially including the following three general steps:
I) performing inter-block echo cancellation by subtracting from the received i-the signal block ri the echo ei−1 from the previously received and demodulated block; an estimate for this inter-block echo can be computed as
ei−1=CT{circumflex over (x)}i−1 (13)
where {circumflex over (x)}i−1 is a previously obtained vector of decisions for the (i−1)st block;
II) performing cyclic echo correction by cyclically adding the echo ei of the current i-th block to the first, or leading end portion of the current block; and,
III) performing frequency equalization of the resulting vector yi to obtain an equalized “soft decisions” vector x|FEQ, and the ‘hard decisions’ vector {circumflex over (x)} according to the following equations (14a, b):
wherein the division in the RHS of equation (14a) is the element-by-element division, and D{x} denotes the operation, also referred herein as the demodulation, of making hard decisions on a ‘soft’ input vector x.
However, these steps, or at least the steps (II) and (II) have to be performed iteratively, since the step (II) of the cyclic echo addition requires at least an estimate of the symbols xi(n) for the current block xi, which is the block that is being currently equalized and demodulated.
Main steps of the iterative hybrid-domain equalization method of the present invention will now be described more in detail with reference to
We first assume that at the time instance when the previous, (i−1)st signal block ri−1 is received, neither a channel estimation, nor any information of the preceding signal is available, and therefore the (i−1)st signal block ri−1 has to be demodulated in the same iterative process that is used for demodulation of the current i-th block. This process is based on the following iterative equations (15)
where {circumflex over (x)}i−1(1) and {circumflex over (x)}i(I) are symbol estimates of xi−1 and xi after I iterations, zi(I) is an IBI-corrected i-th signal block, and xi(1) denotes the result of the frequency-domain equalization of the current signal block with cyclic echo correction yi(1) in the Ith iteration.
In this embodiment the method starts with receiving the (i−1)st and the i-th signal blocks ri−1 and ri by the IHDE 105 in steps 301 and 305, and passing copies thereof from the S/P converter 120 to the central controller 130 for storing in a buffer therein and for performing the initial, tentative channel estimation, e.g. using one of the known in the art methods. This results in an initial estimate for the CIR vector h, using which the controller 130 computes estimates of the frequency response transfer function hf and the echo response function CT. In an alternative embodiment, the step of the initial channel estimation can be performed outside of the IHDE 105, e.g. by the block 115, and the resulting estimate for the CIR h is passed to the CC block 130.
In one embodiment of the invention, the S/P converter 120 divides the received sequence of samples {r(n)} in overlapping blocks of samples, so that the leading portion of the i-th block ri is a copy of the trailing portion of the preceding (i−1) block ri−1, for all i=0,1, . . . . This block overlapping helps to avoid a decrease in the signal-to-noise ratio (SNR) at the beginning of each block after the removal of the inter-block echo as described hereinbelow. In a preferred embodiment, the length of the overlapping block portions is chosen to be substantially equal to the channel length L, a method for estimating thereof described hereinbelow; as a result. In this embodiment the first L elements ri(0), ri(1), . . . , ri(L−1) of the vector ri=[ri(0), ri(1), . . . , ri(N−1)] representing the i-th signal block repeat, i.e. are copies of, the last L elements ri−1(N−L), ri−1(N−L+1), . . . , ri−1(N−1) of the vector ri−1=[ri−1(0), ri−1(1), . . . , ri−1(N−1)] representing the i-th signal block, so that ri(n)=ri−1(N−L+n) for n=0, . . . , L−1. The block overlapping is advantageous for channels with very long duration, when there is a transient period at the beginning of the transmission before the received signal power reaches its peak. As a result, the tentative decisions for the first, leading portion of the current block may not be very reliable due to the signal-to-noise ratio (SNR) decrease in the IBI corrupted signal at the beginning of each block after the removal of the IBI echo.
Next, in a first iteration of the method, I=1, the (i−1)st signal block ri−1 is passed in step 310 through the forward FEQ circuit 152, which operation can be described by equations (12a, b). In this step, the FEQ unit 135 uses the current preliminary estimate hf(1) of the frequency response transfer function hf, which is provided by the CC 130, to tentatively equalize the (i−1)st signal block ri−1. This step results in a first-iteration estimate of the time-domain decision vector {circumflex over (x)}i−1(I) for the (i−1)st block.
Next, in a step 315 the decision vector estimate {circumflex over (x)}i−1(I) is used by the IBI estimator 160, which is also referred to herein as the inter-block echo estimator, to compute a 1st estimate (I=1) of the inter-block echo signal ei−1(I) using the initial estimate for the echo matrix CT provided by the CC 130, which we will denote CT(I), I=1:
ei−1(I)=CT(I){circumflex over (x)}i−1(I) (16)
The processing of the current, ith received signal block ri starts in a step 320, wherein said received current block is updated by subtracting therefrom the estimated inter-block echo ei−1I; this is done according to equation (15a), as the cyclic echo estimate for the current block is not yet available. The resulting updated signal block zi(I=1) in step 335 is frequency equalized to obtain a frequency-equalized block, which is demodulated by making decisions on samples of said frequency-equalized block to generate hard symbol estimates {circumflex over (x)}i(I) for the current i-th block; step 335 is performed using the forward FEQ circuit 152.
In a next step 340, an estimate ei(I) of the i-th block echo signal ei is computed by the cyclic echo estimator 165 according to
ei(I)=CTI−1{circumflex over (x)}i(I) , (17)
and then cyclically added in step 345 to the previously updated current block zi(I=1) in accordance with eq. (15b) to obtain a cyclically updated first block yi(I) in the first iteration of the method; a copy of this signal block is provided to the CC 130 for storing in the buffer 136 shown in
In a next step 350, vector yi(I) is frequency equalized according to equation (15c) and demodulated by passing thereof through the forward FEQ circuit 152 as described hereinabove, resulting in a ‘soft’ equalized vector xi(I), and a vector of hard symbol decisions {circumflex over (x)}i(I+1)=D{xi(I)}|; this step completes the first iteration of the method.
In step 360, the hard decisions vector {circumflex over (x)}i(I+1) is passed to the central controller 130, and used therein to update the channel response estimate, i.e. the CIR h, and therefrom obtain a new estimate hf(I+1) of the frequency response function hf, and a new estimate CT(I+1) of the echo response function CT. The new CIR estimate can be computed directly as a CIR that is required to transform the hard decisions vector {circumflex over (x)}i(I+1) into the cyclically updated current signal block vector yi(I), a copy of which is stored in the buffer 136 of CC 130. The updated frequency response function estimate hf(I+1) is provided to the FEQ unit 135, while the updated echo response function estimate CT(I+1) is provided to the IBI estimator 165, and the cyclic echo estimator 160.
Next, the iteration index I is increased by one, i.e. I→I+1, and the equalization process returns to step 315, wherein the IBI echo from the (i−1) signal block is re-estimated using the updated echo response estimate, and the result is subtracted from the stored i-th signal block ri in step 320 according to eq. (15a). Since for all iterations following the first one a decision vector estimate {circumflex over (x)}i(1) is available from previous iterations, e.g. stored in the buffer 136 of the CC 130, the processing continues with computing the cyclic echo in step 330, and adding thereof to the IBI-corrected signal block obtained in step 320 according to eq. (15b); the resulting cyclically updated i-th received signal block yi(I+1) is frequency equalized and demodulated in step 370 as described hereinabove with reference to step 350, resulting in an updated hard decisions vector {circumflex over (x)}i(1+2).
In a next step 355, a pre-determined iteration-end condition is checked, and if satisfied, the hard decisions vector {circumflex over (x)}i(1+2) is output from the IHDE 105 for decoding; otherwise, the steps 360-315-320-330-365-370-355 are iteratively repeated until the pre-determined iteration-end condition is satisfied.
In one embodiment, the predetermined iteration-end condition is reaching a predetermined maximum number of iterations. In other embodiments, step 355 involves computing an error function from the current hard decision vector {circumflex over (x)}i(1) obtained in the latest iteration. In one such embodiment the error function can be computed as a signal-to-decision error ratio (SDR) defined by a normalized Euclid distance between a current frequency-equalized “soft” block vector xi(1) and a respective estimated decision vector {circumflex over (x)}i(1):
In one embodiment of the IHDE 105, the SDR(I) at I-th iteration is computed by an SDR computer 133 shown in
The SDR computer 133 receives at each iteration the frequency-equalized signal block xi(I) and the vector of decisions {circumflex over (x)}i(1) from the IDFT/Decisions unit 140, and compares it with a pre-determined threshold value ε stored in a memory of the CC 130, e.g. in the buffer 136. If the threshold is reached, i.e. the iterative process converged so that
SDR(I)<ε, (18a)
the CC 130 sends a signal to the ICU 142, which switches the output of the IDFT unit 140 to the P/S controller 145 from forming a serial output signal in the form of a decoded symbols sequence. Otherwise, the ICU 142 directs the decision vectors to units 165 and 160 for the cyclic and IBI echo computation, respectively, to continue the iterations until either condition (18a) is satisfied, or a maximum number of iterations is reached.
The hereinabove described embodiment of the method of the present invention is designed to provide channel equalization iteratively, while simultaneously updating an initial tentative channel estimation. If the channel can be considered static at least within a certain time interval greatly exceeding the block length, the aforedescribed method results in a suitably accurate channel estimation after processing the first few blocks of the received signal, or even after processing just one block. In other embodiment, the initial channel estimation can be sufficiently accurate. In both cases, the aforedescribed iterative updating of the channel estimate is not required, as the initial estimates of the frequency response function hf, and the echo response function CT can be used throughout the iterations.
In this embodiment, the method is based on the equations
This simplified embodiment of the method is illustrated in
zi=ri−CT{circumflex over (x)}i−1=ri−ei−1 (20)
can now be computed only once and stored e.g. in the buffer 136 to be used in subsequent iterations of steps 330-365-370-355 for removing the effect of intra-block interference (IABI) by iterating the frequency-domain equalization in the forward path using the forward FEQ circuit 152, and the time-domain cyclic block correction/update in the feedback path using the IABI feedback loop 143-165-167 as shown in
According to one aspect of the invention, the block size N, which is used in the present invention and also referred to herein as the block length, is selected adaptively in dependence on the channel conditions, so as to provide guaranteed performance at a minimal complexity of the equalizer 105. The block length N determines the size of the DFT and IDFT operations performed by units 125 and 140 of the IHDE 105, and therefore to a large extent controls the computational load associated with the equalization method of the present invention. However, to ensure fast convergence of the iterative interference cancellation process described hereinabove and reduce the number of iterations, the block size N should be substantially greater than the channel length L.
At the beginning of the operation of the receiver 100, when channel conditions are not yet known, the block size N is set to a pre-determined value N0 which is preferably selected to be substantially, e.g. 20 times, longer than a maximum expected value Lexp of the CIR length L, depending on application.
With reference to
is the variance of the received ATSC signal, and is also an average normalized received signal energy per symbol Es. Ee is a total normalized echo signal energy within a current block that includes both the IBI and IABI signal components within the current received signal block ri; if the block length N is much longer than the impulse response of the channel (L),
For a satisfactory reception of the ATSC signal, the receiver 100 has to ensure that a pre-determined minimum value BT of the Bit Error Rate (BER) at the output of the receiver 100 is not exceeded. On the other hand, different applications may have different performance requirements, i.e. different target BER values. Accordingly, in one embodiment of the invention a pre-determined look-up table is stored in a memory of the CC130, e.g. in the buffer 136, that relates different target BER values to respective SIIR values; this look-up table can be obtain by varying the block size while receiving an ATSC signal under constant interference conditions, and measuring the BER values for the demodulated and decoded received signal at the output of the receiver 100. Obviously, if the receiver is to operate at a pre-determined constant BER requirement, the look-up table can store a single SIIR value.
By way of example,
The process starts with step 405, wherein the results of channel estimation performed by the channel estimator 132 are provided to the block computer 131 in the form of the CIR vector h.
Next, in step 410 the average normalized received signal energy per symbol Es is estimated using equation (22);
In step 415, the average normalized received signal energy per symbol Es is estimated using equation (22);
In step 420, a symbol-to-echo energy ratio (Es/Ee) is computed;
In step 452, a required SIR value is determined from the stored look-up table; and,
In step 430, the block size N is determined using the following equation (24):
N=SIIR·(Es/Ee) (24)
In a final step 435, the so determined block size N is passed back to the channel estimator 132, which then completes the procedure by computing estimates for hf and CT for the determined block size N. The so determined block size N is also passed to units 125, 135 and 140 of the forward FEQ circuit 152 to set the DFT/IDFT size, and to the S/P and P/S converters 120, 145 to adapt their size accordingly.
In one embodiment of the invention, the block size N is computed using the aforedescribed approach every time when a new CIR estimate is performed; however, the block size update performed in the last step 435 can be triggered if the newly determined block size N substantially differs from a currently used value.
As have been stated herein above, in preferred embodiments the DFT and IDFT converters 125 and 140 operate using computationally efficient (I)FFT algorithms; still, the (I)FFT operations used in steps 310, 335, 350, and 370 determine to a large extent the overall computational complexity of the above described method of the hybrid time-frequency domain equalization of the present invention.
However, computational efficiency of the method can be further significantly reduced by using pruning (I)FFT in iterations where the IBI and cyclic echoes ei−1, ei are computed. Indeed, as can be seen from equation (5) for the echo response function matrix CT and e.g. an equation ei−1=CT{circumflex over (x)}i−1 for the inter-block echo, only a fraction of the decision vector corresponding to the end portion of length (L−1) of the current or previous signal block is needed for computing the echo correction signals ei−1, ei in each iteration. Consequently, once the channel length L is known, the computational load can be substantially lighten by using the (I)FFT pruning technique, which is known in the art of digital Fourier transform, i.e. by eliminating operations in the FFT (unit 120) and IFFT (unit 140) that result in the generation of the last (N−L) elements of the frequency equalized signal blocks x(I). Each of the respective (I)FFT operations after pruning will only need
real multiplications and
real additions, where the function └ ┘ returns the integer part of an argument.
Accordingly, in another aspect of the invention the step 301 of initial channel estimation includes the step of channel length determination, which is then used in pruning the (I)FFTs performed by the units 125 and 140 in
In one embodiment, the channel length estimation is performed by estimating an autocorrelation function Rrr of the received ATSC signal r={rn}, which is defined as
Rrr(m)=E{r(n)r*(n+m)}, (24)
wherein E{a} denotes math expectation of a, and the superscript ‘*’ denotes the operation of complex conjugation.
Using the randomized nature of the transmitted ATSC signal s that results in the received signal r, it can be shown that the autocorrelation function Rrr(m) approximates a correlation function of the channel impulse response and its time domain inverted version
Rrr(m)≈Rhh,(m)≡h(m)*{circle around (×)}h(−m) (25)
where {circle around (×)} denotes the operation of convolution.
Therefore, in this embodiment of the invention the duration L of the channel impulse response h is estimated simply by computing the autocorrelation function of the received signal Rrr(m), which has a full length of (2N−1), and estimating an effective width of it central portion, e.g. by truncating a tail of Rrr(m) that has a small amplitude.
To begin the estimation of L, a time selection window with a pre-determined maximum expected channel length is weighted with the computed auto-correlation function of the received signal Rrr(m). The auto-correlation function is symmetrical and only one half of the function is needed for the channel length estimation. The window size is then gradually reduced sample by sample. If the amplitude of the sample is less than a pre-determined threshold, then the sample is discarded. This process continues until a first significant peak in the auto-correlation function is found. The channel length L is determined as the length from the central peak to this first significant non-zero peak.
Once the channel length L is determined, it is passed to the DFT and IDFT blocks 125, 140 for use in the pruning (I)FFT algorithms used by these blocks. In one embodiment, it is also passed to the S/P converter 120 for determining the block overlap size, as described herinabove with reference to steps 301 and 305 of
Advantageously, the iterative hybrid-domain block equalization method of the present invention enables efficient demodulation of received signals in the presence of multi-path interferences resulting in echoes with very long delay spreads. By way of example,
Other advantageous of the iterative hybrid-domain block equalization method and apparatus of the present invention include: i) no training sequence or statistical signal information, e.g. relating to the modulation scheme, needs to be included in the transmitted signal is needed; ii) the channel length estimation algorithm of the present invention can work at a very low SNR. The lower of the SNR in the received signal, the longer the received signal samples will need to be accumulated for an accurate channel estimation, limited by the channel coherence time; iii) the channel length estimation can be performed without or prior to signal synchronization or demodulation.
The preceding description has been directed towards a DTV communication system that uses the ATSC signal format. However, the method and apparatus of the present invention can be equally applied for iterative hybrid-domain equalization of other types of communication signals that can be subjected to sever multipath interference and do not have a cyclic prefix, with possibly minor modifications that would be apparent to those skilled in the art.
The present invention has been fully described in conjunction with the exemplary embodiments thereof with reference to the accompanying drawings. Of course numerous other embodiments may be envisioned without departing from the spirit and scope of the invention; it is to be understood that the various changes and modifications to the aforedescribed embodiments may be apparent to those skilled in the art. Such changes and modifications are to be understood as included within the scope of the present invention as defined by the appended claims, unless they depart therefrom.
The present invention claims priority from U.S. Provisional Patent Application No. 60/719,218 filed Sep. 22, 2005, entitled “A Hybrid Domain Block Equalizer With Iterative Interference Cancellation For ATSC 8-VSB Receiver”, which is incorporated herein by reference.
Number | Date | Country | |
---|---|---|---|
60719218 | Sep 2005 | US |