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Claims  |
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We claim:
1. Apparatus for processing a received quadrature-amplitude-modulated (QAM)
signal comprised of first and second trains of data symbol components
having predetermined values, said components being modulated onto
respective carriers which are in quadrature relation, said apparatus
comprising,
means (11d) for forming a succession of line samples of said QAM signal at
a predetermined sampling frequency which is equal to at least twice the
highest frequency component of said QAM signal,
means (122) for forming first and second passband equalizer output
components in response to said line samples,
means (25) for demodulating said first and second passband equalizer output
components to form first and second passband equalizer output components,
and
means (31) for identifying as the value of a first data symbol component
which is in said first train the one of a plurality of predetermined
reference values which is closest to the value of said first baseband
equalizer output component and for identifying as the value of a second
data symbol component which is in said second train the one of said
reference values which is closest to the value of said second baseband
equalizer output component,
characterized in that
said first passband equalizer output component is equal to the sum of the
products of at least individual ones of a predetermined number of the most
recently formed ones of said line samples with respective ones of a first
ensemble of coefficients and said second passband equalizer output
component is equal to the sum of the products of said ones of said line
samples with respective ones of a second ensemble of coefficients.
2. The invention of claim 1 wherein said QAM signal is of the transmitter
form
##EQU4##
where a.sub.m and a.sub.m are real numbers the values of which are the
values of said first and second data symbol components, g(t) is a
predetermined real function, T is the time between successive data symbol
components in each of said trains, and .omega..sub.c is the radian
frequency of said carriers.
3. The invention of claim 2 further comprising means (35, 38, 123) for
updating the values of said first and second ensembles of coefficients in
a decision-directed manner.
4. The invention of claim 2 further comprising means (35, 38) for updating
the values of said first and second ensembles of coefficients as a
function of first and second error signal components, respectively, said
first error signal component being equal to the difference between said
first passband equalizer output component and a remodulated version of the
identified value of said first data symbol component and said second error
signal component being equal to the difference between said second
passband equalizer output component and a remodulated version of the
identified value of said second data symbol component.
5. Apparatus for use in a receiver to which is transmitted a signal s(t) of
the form
##EQU5##
where a.sub.m and a.sub.m are real numbers, g(t) is a real function, T is
a predetermined symbol period and .omega..sub.c is a selected radian
carrier frequency, said apparatus comprising
means (11d) for forming a succession of line samples of the received
version of said signal at a predetermined sampling frequency which is at
least twice the highest frequency component of said signal,
means (122) operative during the m.sup.th one of a succession of T second
intervals for forming first and second passband equalizer outputs of
u.sub.m and u.sub.m given by
u.sub.m =c.sub.m.sup.T p.sub.m
u.sub.m =d.sub.m.sup.T p.sub.m
wherein p.sub.m is a vector of M previously formed ones of said samples, M
being a predetermined number, and c.sub.m.sup.T and d.sub.m.sup.T are
transposes of respective vectors c.sub.m and d.sub.m each comprised of M
tap coefficients having values associated with said m.sup.th interval, and
means (25, 31) for forming decisions a.sub.m * and a.sub.m * as to the
values of a.sub.m and a.sub.m, respectively, in response to the values of
u.sub.m and u.sub.m, respectively.
6. The invention of claim 5 wherein said decision forming means is
comprised of
means (25) for forming first and second baseband equalizer outputs y.sub.m
and y.sub.m given by
y.sub.m =u.sub.m cos .theta..sub.m *+u.sub.m sin .theta..sub.m *
y.sub.m =-u.sub.m sin .theta..sub.m * +u.sub.m cos .theta..sub.m *,
where .theta..sub.m * is a demodulating carrier phase estimate having a
value associated with said m.sup.th interval, and
means (31) for determining the value of a.sub.m * to be the one of a
plurality of predetermined values to which y.sub.m is the closest and for
determining the value of a.sub.m * to be the one of said plurality to
which y.sub.m is the closest.
7. The invention of claim 6 further comprising means (35, 38, 123) for
updating said coefficients to generate the values thereof associated with
the (m+1).sup.st of said intervals, the updated coefficient values being
given by
c.sub.m+1 =c.sub.m -.alpha.p.sub.m e.sub.pm,
d.sub.m+1 =d.sub.m -.alpha.p.sub.m e.sub.pm,
where .alpha. is a predetermined constant, where
e.sub.pm =u.sub.m -a.sub.pm *
e.sub.pm =u.sub.m -a.sub.pm *,
and where
a.sub.pm *=a.sub.m * cos .theta..sub.m *-a.sub.m * sin .theta..sub.m *
a.sub.pm *=a.sub.m * sin .theta..sub.m *+a.sub.m * cos .theta..sub.m *.
8. A method for processing a received quadrature-amplitude-modulated (QAM)
signal comprised of first and second trains of data symbol components
having predetermined values, said components being modulated onto
respective carriers which are in quadrature relation, said method
comprising the steps of
forming a succession of line samples of said QAM signal at a predetermined
sampling frequency which is equal to at least twice the highest frequency
component of said QAM signal,
forming first and second passband equalizer output components in response
to said line samples,
demodulating said first and second passband equalizer output components to
form first and second baseband equalizer output components,
identifying as the value of a first data symbol component which is in said
first train the one of a plurality of predetermined reference values which
is closest to the value of said first baseband equalizer output component,
and
identifying as the value of a second data symbol component which is in said
second train the one of said reference values which is closest to the
value of said second baseband equalizer output component,
characterized in that said first passband equalizer output component is
equal to the sum of the products of at least individual ones of a
predetermined number of the most recently formed ones of said line samples
with respective ones of a first ensemble of coefficients and said second
passband equalizer output component is equal to the sum of the products of
said ones of said line samples with respective ones of a second ensemble
of coefficients.
9. The invention of claim 8 wherein said QAM signal is of the transmitted
form
##EQU6##
where a.sub.m and a.sub.m are real numbers the values of which are the
values of said first and second data symbol components, g(t) is a
predetermined real function, T is the time between successive data symbol
components in each of said trains and .omega..sub.c is the radian
frequency of said carriers.
10. The invention of claim 9 comprising the further step of updating the
values of said first and second ensembles of coefficients in a
decision-directed manner.
11. The invention of claim 9 further comprising the further step of
updating the values of said first and second ensembles of coefficients as
a function of first and second error signal components, respectively, said
first error signal component being equal to the difference between said
first passband equalizer output component and a remodulated version of the
identified value of said first data symbol component and said second error
signal component being equal to the difference between said second
passband equalizer output component and a remodulated version of the
identified value of said second data symbol component.
12. A method for use in a receiver to which is transmitted a signal s(t) of
the form
##EQU7##
where a.sub.m and a.sub.m are real numbers, g(t) is a real function, T is
a predetermined symbol period and .omega..sub.c is a selected radian
carrier frequency, said method comprising the steps of
forming a succession of line samples of the received version of said signal
at a predetermined sampling frequency which is at least twice the highest
frequency component of said signal,
forming during the m.sup.th one of a succession of T second intervals first
and second passband equalizer outputs of u.sub.m and u.sub.m given by
u.sub.m =c.sub.m.sup.T p.sub.m
u.sub.m =d.sub.m.sup.T p.sub.m
wherein p.sub.m is a vector of M previously formed ones of said samples, M
being a predetermined number, and c.sub.m.sup.T and d.sub.m.sup.T are
transposes of respective vectors c.sub.m and d.sub.m each comprised of M
tap coefficients having values associated with said m.sup.th interval, and
forming decisions a.sub.m * and a.sub.m * as to the values of a.sub.m and
a.sub.m, respectively, in response to the values of u.sub.m and u.sub.m,
respectively.
13. The invention of claim 12 wherein said decision forming step is
comprised of the steps of
forming first and second baseband equalizer outputs y.sub.m and y.sub.m
given by
y.sub.m =u.sub.m cos .theta..sub.m *+u.sub.m sin .theta.m*
y.sub.m =-u.sub.m sin .theta..sub.m *+u.sub.m cos .theta..sub.m *,
where .theta..sub.m * is a demodulating carrier phase estimate having a
value associated with said m.sup.th interval, and
determining the value of a.sub.m * to be the one of a plurality of
predetermined values to which y.sub.m is the closest and for determining
the value of a.sub.m * to be the one of said plurality to which y.sub.m is
the closest.
14. The invention of claim 13 comprising the further step of updating said
coefficients to generate the values thereof associated with the
(m+1).sup.st of said intervals, the updated coefficient value being given
by
c.sub.m+1 =c.sub.m -.alpha.p.sub.m e.sub.pm
d.sub.m+1 =d.sub.m -.alpha.p.sub.m e.sub.pm,
where .alpha. is a predetermined constant, where
e.sub.pm =u.sub.m -a.sub.pm *
e.sub.pm =u.sub.m -a.sub.pm *
and where
a.sub.pm *=a.sub.m * cos .theta..sub.m *-a.sub.m * sin .theta..sub.m
a.sub.pm *=a.sub.m * sin .theta..sub.m *+a.sub.m * cos .theta..sub.m *. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
The present invention relates to automatic equalizers which compensate for
the distorting effects of bandlimited channels on transmitted data
signals.
Automatic equalizers are necessary for accurate reception of high-speed
data signals transmitted over bandlimited channels with unknown
transmission characteristics. The equalizer, which forms a part of an
overall data receiver, is generally in the form of a transversal filter in
which successive line samples of a previously-filtered incoming data
signal are multiplied by respective tap coefficients. The resulting
products are added together to generate an equalizer output which is then
demodulated and/or quantized to recover the transmitted data. In addition,
an error signal is formed equal to the difference between the equalizer
output and a reference signal which represents the transmitted data
symbol. The value of the symbol that was transmitted may be known at the
receiver a priori, as is the case in many equalizer start-up arrangements.
Alternatively, in the so-called adaptive type of automatic equalizer, the
reference signal is derived from the decision made in the receiver (on the
basis of the equalizer output value) as to what data symbol was
transmitted. In either case, the error signal is used to update the tap
coefficient values in accordance with an algorithm which minimizes a
measure of the distortion--assumed to be primarily intersymbol
interference--introduced by the channel.
In some applications, the equalization process entails specialized kinds of
signal processing. In particular, as shown in U.S. Pat. No. 3,755,738
issued Aug. 28, 1973, to R. D. Gitlin et al, for example, recovery of the
data contained in a quadrature-amplitude-modulated (QAM) signal
conventionally involves generation of two versions of the received
passband signal--a so-called Hilbert transform pair. These may be
generated, for example, by a "phase splitter" comprised of analog filter
sections. While generally satisfactory in operation, the analog phase
splitter is relatively bulky, must be manufactured to close tolerances,
and must be individually tested at the factory. Its parameters are also
subject to variation due to such effects as temperature drift and
component aging.
The above problems can be ameliorated by realizing the phase splitter with
integrated circuit active filters. These, however, are sensitive to radio
frequency interference created by static discharges. The phase splitter
could also be realized with digital circuitry. The principal drawback to
this approach is that it substantially increases the time required to
begin forming the data decisions.
SUMMARY OF THE INVENTION
The principal object of the present invention is thus to provide a simple
and inexpensive alternative to the phase splitter used in prior art QAM
receivers.
The invention is founded on the following recongition: If a QAM signal is
sampled at a high enough rate, i.e., at at least the Nyquist frequency,
the phase splitter could be implemented via a non-recursive transversal
filter. The Hilbert transform pair outputs of such a phase splitter would
each be comprised of linear combinations of the line samples applied to
the phase splitter. These could then be applied to a conventional
transversal filter equalizer, the outputs of which would, again, be
comprised of linear combinations of the signals applied to it.
This being so, we have furtther recognized that the transfer characteristic
of the above-postulated cascade of distinct phase-splitter and equalizer
filters can be realized by a single transversal filter which, when an
appropriate tap coefficient updating algorithm is used, will provide
substantially the same mapping of input signal to equalizer outputs as the
two-filter cascade. Indeed, the function of the bandpass filter which
generally proceeds the phase-splitter is likewise automatically provided
by this arrangement.
A receiver designed in accordance with the present invention requires fewer
multiplications than the above suggested all-digital cascade. The
invention will not, in general, provide a reduction in the number of
multiplications over the more conventional analog filter arrangement.
However, as an all-digital approach, it avoids many of the drawbacks
attendant to the use of the analog filters.
BRIEF DESCRIPTION OF THE DRAWING
In the drawing:
FIG. 1 is a block diagram of a prior art quadrature-amplitude-modulaton
(QAM) receiver;
FIGS. 2 and 3 are alternate input circuits for use in the receiver of FIG.
1; and
FIG. 4 is a block diagram of a QAM receiver embodying the principles of the
present invention.
DETAILED DESCRIPTION
FIG. 1 depicts a prior art receiver 10 for data signals transmitted from a
transmitter (not shown) over a bandlimited channel, e.g., voiceband
telephone circuit. The data signals are illustratively
quadrature-amplitude-modulated (QAM) data signals wherein four paralleled
information bits are transmitted during each of a succession of symbol
intervals of duration T=1/2400 sec. The symbol rate is thus 2400 baud,
yielding a binary transmission rate of 9600 bits per second. The four bits
to be transmitted during successive symbol intervals are encoded into two
trains of data symbol components. The latter are modulated onto respective
carriers which are in quadrature relation, i.e., have a 90 degree phase
difference. In particular, the four bits to be transmitted during the
m.sup.th symbol interval are encoded into two data symbol components
a.sub.m and a.sub.m, each of which can take on one of the four values [+1,
-1, +3, -3]. Components a.sub.m and a.sub.m respectively comprise the real
and imaginary components of a complex data symbol A.sub.m. Components
a.sub.m and a.sub.m amplitude modulate respective 1800 Hz in-phase and
quadrature-phase carrier waves. The modulated signals, when added
together, form a QAM signal s(t) which is of the form
##EQU1##
where g(t) is a real function and .omega..sub.c is the radian carrier
frequency. Signal s(t) is then transmitted to receiver 10.
In receiver 10, the received version of signal s(t), s.sub.r (t), passes
through automatic gain control circuit 8 where it emerges as signal
s.sub.r '(t). The latter is applied to an input circuit 11 comprised of
analog bandpass filter 12, analog phase splitter 14, analog-to-digital
(a/d) converter 17 and sample clock 19. The function of filter 12 is to
filter out any energy in signal s.sub.r '(t) outside of the transmission
band of interest--in this example the band 300-3000 Hz. Phase splitter 14
responds to the output signal q(t) of filter 12 to generate two versions
of signal q(t). One of these is q.sub.1 (t). The other, represented as
q.sub.1 (t), is the Hilbert transform of q.sub.1 (t).
Signals q.sub.1 (t) and q.sub.1 (t) are passed to a/d converter 17. The
latter, operating under the control of clock 19, generates an equalizer
input sample Q.sub.m during the m.sup.th receiver symbol interval of
duration of T seconds. Q.sub.m has components q.sub.m and q.sub.m, which
are respective samples of signals q.sub.1 (t) and q.sub.1 (t).
Equalizer input sample components q.sub.m and q.sub.m pass out of input
circuit 11 and on to transversal filter euqalizer 22. The output of the
latter is complex passband equalizer output U.sub.m having components
u.sub.m and u.sub.m. Equalizer 22 generates its outputs by forming linear
combinations of the equalizer input sample components in accordance with
the relations
u.sub.m =c.sup.T.sub.m r.sub.m +d.sub.m.sup.T r.sub.m
u.sub.m =c.sub.m.sup.T r.sub.m -d.sub.m.sup.T r.sub.m
In these expressions r.sub.m and r.sub.m are (N.times.1) matrices, or
vectors, respectively comprised of the N most recent real and imaginary
equalizer input sample components, N being a selected integer. That is
##EQU2##
In addition, c.sub.m and d.sub.m are (N.times.1) vectors each comprised of
an ensemble of N tap coefficients having values associated with the
m.sup.th receiver interval. (The superscript "T" used in the above
expressions indicates the matrix transpose operation wherein the
(N.times.1) vectors c.sub.m and d.sub.m are transposed into (1.times.N)
vectors for purposes of matrix multiplication.) The values of the
coefficients in these vectors are determined in the manner described
below.
Passband equalizer output U.sub.m is demodulated by demodulator 25 to yield
baseband equalizer output Y.sub.m. The latter and passband equalizer
output U.sub.m respectively represent baseband and passband versions of
transmitted symbol A.sub.m. Baseband equalizer output Y.sub.m has real and
imaginary components y.sub.m and y.sub.m, the demodulation process being
expressed as
y.sub.m =u.sub.m cos .theta..sub.m *+u.sub.m sin .theta..sub.m *
y.sub.m =-u.sub.m sin .theta..sub.m *+u.sub.m cos .theta..sub.m *,
.theta..sub.m * being an estimate of the current carrier phase. For
purposes of generating y.sub.m and y.sub.m in accordance with the above
expressions, demodulator 25 receives representations of cos.theta..sub.m *
and sin.theta..sub.m * from a carrier source 27.
Baseband equalizer output Y.sub.m is quantized in decision circuit 31. The
resulting output A.sub.m * is a decision as to the value of the
transmitted symbol A.sub.m. In particular, the real and imaginary parts of
A.sub.m *, a.sub.m * and a.sub.m *, are decisions as to the data signal
values represented by the real and imaginary components a.sub.m and
a.sub.m of transmitted symbol A.sub.m. Decision circuit 31, more
particularly, forms decision a.sub.m *(a.sub.m *) by identifying the one
of the four possible data signal values [+1, -1, +3, -3] which is closest
to the value of equalizer output component y.sub.m (y.sub.m).
Decision A.sub.m * is also used to generate an error signal for use in
updating coefficient vectors c.sub.m and d.sub.m. In particular, decision
components a.sub.m * and a.sub.m * are combined in decision remodulator 35
with sin.theta..sub.m * and cos.theta..sub.m * from carrier source 27 to
form remodulated, or passband, decision A.sub.pm *. The real and imaginary
components of A.sub.pm *, a.sub.pm * and a.sub.pm *, are formed in
accordance with
a.sub.pm *=a.sub.m * cos .theta..sub.m *-a.sub.m * sin .theta..sub.m *
a.sub.pm *=a.sub.m * sin .theta..sub.m *+a.sub.m * cos .theta..sub.m *.
Passband decision A.sub.pm * is subtracted from passband equalizer output
U.sub.m in subtractor 38 to yield passband error E.sub.pm having
components e.sub.pm and e.sub.pm given by
e.sub.pm =u.sub.m -a.sub.pm *
e.sub.pm =u.sub.m -a.sub.pm *.
Error signal components e.sub.pm and e.sub.pm are extended to equalizer 22
for purposes of updating the values of the coefficients in coefficient
vectors c.sub.m and d.sub.m in preparation for the next, (m+1).sup.st,
symbol interval. The so-called mean-squared error stochastic updating
algorithm is illustratively used, yielding the updating rules
c.sub.m+1 =c.sub.m -.alpha.[r.sub.m e.sub.pm +r.sub.m e.sub.pm ]
d.sub.m+1 =d.sub.m -.alpha.[r.sub.m e.sub.pm -r.sub.m e.sub.pm ],
.alpha. being a predetermined constant.
The principle underlying the present invention will now be explained with
reference to FIG. 2. Assume that input circuit 11 were replaced by input
circuit 11a shown in FIG. 2. Circuit 11a includes analog bandpass filter
12a, which receives signal s.sub.r '(t) and which is illustratively
identical to filter 12 in input circuit 11. Output signal q(t) of filter
12a is extended to a/d converter 17a. The latter is operated by sample
clock 19a n times per symbol interval to form samples of signal q(t). More
particularly, a/d converter 17a generates a sample q.sub.k in response to
the k.sup.th clock pulse from clock 19a. The parameter n is selected such
that the frequency n/T with which the samples of signal q(t) are formed is
at least euqal to the Nyquist frequency, i.e., at least twice the highest
frequency component of q(t). With this criterion met, the function of
phase splitter 14 can be realized in input circuit 11a by digital phase
splitter 14a. The latter, in turn, is illustratively realized as a pair of
non-recursive transversal filters. Each of the transversal filters
generates one of the phase splitter outputs in response to the samples
provided by a/d converter 17a.
Unlike the coefficients used in equalizer 22, the coefficients used in
phase splitter 14a are time-invariant since the filter characteristic is
time-invariant. Moreover, equalizer 22, which follows phase splitter 14a,
requires a Hilbert transform pair derived from signal q(t) only once per
symbol interval. Thus, even though phase splitter 14a receives n line
samples per symbol interval, it generates an equalizer input sample only
once per symbol interval. The equalizer input samples generated by phase
splitter 14a are substantially identical to those generated by a/d
converter 17 of input circuit 11. Hence, the Hilbert transform components
generated by the former during the m.sup.th receiver symbol interval, like
those generated by the latter, are represented as q.sub.m and q.sub.m.
Since phase splitter 14a is comprised of a pair of nonrecursive transversal
filters, components q.sub.m and q.sub.m generated thereby are comprised of
respective linear combinations of some finite number of previous outputs
of a/d converter 17a. As previously noted, passband equalizer output
components u.sub.m and u.sub.m, in turn, are comprised of respective
linear combinations of the components applied to equalizer 22. Components
u.sub.m and u.sub.m are thus also comprised of linear combinations of some
finite number of previous outputs of a/d converter 17a. This being so, we
have recognized that the transfer characteristic of the cascade comprised
of phase splitter 14a and equalizer 22 can be realized in accordance with
the invention by a single transversal filter pair. The coefficients used
in the latter, which will be nonlinear functions of the time-invariant
coefficients of filter 14a and the adaptively updated coefficients of
equalizer 22, can be readily arrived at in the conventional adaptive,
decision-directed manner by using an appropriate tap coefficient updating
algorithm.
Indeed, since a bandpass filter can also be realized as a nonrecursive
transversal filter, input circuit 11a could be replaced by input circuit
11b of FIG. 3. Here, input signal s.sub.r '(t) is applied to a/d converter
17b which operates n times per symbol interval under the control of clock
19b to generate sample s.sub.k of signal s.sub.r '(t) in response to the
k.sup.th clock pulse. Bandpass filter 12b, now a nonrecursive transversal
filter, responds by generating the sample q.sub.k. The latter, as in
circuit 11a, is applied to digital phase splitter 14b which, in turn,
generates equalizer input sample components q.sub.m and q.sub.m. Following
the same reasoning as before, it will be seen that passband equalizer
output components u.sub.m and u.sub.m are respective linear combinations
of some finite number of previous a/d converter output samples. This being
so, the transfer function of the cascade comprised of filter 12b,
phase-splitter 14b and equalizer 22 can be realized in accordance with the
invention, with but a single transversal filter pair using an appropriate
coefficient updating algorithm.
FIg. 4 shows a receiver 40 embodying the principles of the invention as
discussed above. Receiver 40 is similar to receiver 10 except that circuit
11 and equalizer 22 have been replaced by input circuit 11d and equalizer
122.
Input circuit 11d includes only a/d converter 17d and sample clock 19d. The
latter operates the former once every T/n seconds, forming equalizer input
sample s.sub.k in response to the k.sup.th clock pulse. Sample s.sub.k
extends to transversal equalizer 122. Once every T seconds, equalizer 122
generates passband equalizer output components u.sub.m and u.sub.m in
accordance with the invention, those outputs being given by
u.sub.m =c.sub.m.sup.T p.sub.m
u.sub.m =d.sub.m.sup.T p.sub.m.
Here, p.sub.m is an (M.times.1) vector comprised of the M most recent a/d
converter output samples. That is,
##EQU3##
(In order to obtain equalization comparable to that obtained in receiver
10, M should be equal to n.times.N.) In addition, c.sub.m and d.sub.m are
(M.times.1) vectors (transposed for matrix multiplication) each comprised
of an ensemble of M tap coefficients having values associated with the
m.sup.th receiver interval. The above expressions thus indicate that
u.sub.m (u.sub.m) is equal to the sum of the products of the M most recent
a/d converter output samples with respective ones of the coefficients in
vector c.sub.m (d.sub.m).
The processing of equalizer output U.sub.m in receiver 40 is identical to
that in receiver 10, while coefficient updating is performed in accordance
with
c.sub.m+1 =c.sub.m -.alpha.p.sub.m e.sub.pm
d.sub.m+1 =d.sub.m -.alpha.p.sub.m e.sub.pm.
The values of the coefficients arrived at via this updating process are, of
course, different from the coefficient values arrived at in receiver 10 of
FIG. 1. A coefficient store and update unit 123 within equalizer 122 is
shown explicitly in FIG. 4. Such a unit would, of course, also be provided
in equalizer 22.
Since equalizer 122 receives a plurality of samples per symbol interval, it
has the properties of the so-called fractionally spaced equalizer. Among
the significant advantages of the fractionally spaced equalizer over the
more conventional baud, or synchronous, equalizer, is insensitivity to
channel delay distortion, including sampling phase errors. There is,
however, at least one significant problem unique to the
fractionally-spaced equalizer. In a synchronous equalizer, one set of tap
coefficients is clearly optimum, i.e., provides the smallest mean-squared
error. By contrast, many sets of coefficient values provide approximately
the same mean-squared error in the fractionally-spaced equalizer. As a
consequence of this property, the presence of small biases in the
coefficient updating processing hardware--such as biases associated with
signal value roundoff--can cause at least some of the coefficient values
to drift to very large levels, or "blow-up", even though the mean-squared
error remains at, or close to, its minimum value. The registers used to
store the coefficients or other signals computed during normal equalizer
operation can then overflow, causing severe degradation, or total
collapse, of the system response.
This phenomenon is suppressed in receiver 40 via the technique disclosed in
the commonly-assigned, copending U.S. patent application of J. J. Werner,
Ser. No. 84,857, filed of even date herewith, hereby incorporated by
reference. In accordance with that technique, signal energy is added to
the received signal at frequencies within the band (0-n/2T) Hz at which
the received signal has negligible energy.
In receiver 40, in particular, the additional signal energy is provided
from a sweep generator 43 and is added to signal s.sub.r '(t) via adder
47. The output signal of sweep generator 43, signal n(t), is
illustratively a sine wave, the frequency of which is swept across
substantially all of the band extending from just above the highest
frequency component of s.sub.r '(t) to the frequency n/2T. The output
signal of adder 47, signal s.sub.r '(t) is what is applied to a/d
converter 17d. The amplitude of signal n(t) should be sufficiently large
to suppress the tap drifting tendency, which amplitude can be readily
ascertained by trial and error. As taught in the above-referenced patent
application, the added signal energy may take other forms, in which case
it may be more convenient to introduce it in digital form after a/d
converter 17d. In either case, it is important that the additional signal
energy be introduced after any automatic gain control circuitry.
Although a specific embodiment of the invention is shown and described
herein, other arrangements are possible. For example, it is possible to
first generate two baseband versions of the received passband signal by
multiplying it in an orthogonal demodulator by sin(.omega..sub.c
t+.theta.*) and cos(.omega..sub.c t+.theta.*) (.theta.* being an estimate
of the carrier phase), convert these to digital form at n/T samples per
second and then equalize at baseband. Such an approach is advantageous in
that it simplifies the demodulation process. On the other hand, it would
require twice the number of multiplications as the passband equalization
arrangement of FIG. 4; with such baseband equalization, the equalizer
outputs would be formed in accordance with expressions similar to those
used by equalizer 22 in receiver 10. Moreover, the baseband equalization
approach introduces a delay between the demodulation and error-generation
circuitry. This complicates the determination of .theta.*.
Alternatively, the received passband signal could be sampled at n/T samples
per second and then passed through an equilizer which forms only one of
the equalizer output components, e.g., u.sub.m. This would then be passed
through an orthogonal demodulator and the two outputs of the latter passed
through respective fixed lowpass filters. The lowpass filters need not be
distortion free but must be identical. The equalizer will compensate for
any distortion introduced by the lowpass filters since they are within the
tap coefficient adjustment loop. Although this structure is more
complicated than that of FIG. 4, it may be advantageous in applications in
which processing speed is a problem since it requires half the
multiplications.
Various other arrangements embodying the principles of the invention will
be able to be devised by those skilled in the art without departing from
their spirit and scope.
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