 |
Claims  |
|
|
I claim:
1. An adaptive cross-polarization interference cancellation arrangement
comprising:
an antenna (100) capable of receiving a signal which may include a first
desired signal (102) polarized in a first direction and a second
interfering signal (104) polarized in a second direction orthogonal to the
first direction and comprising cross-polarization components thereof;
means (105) coupled to the antenna capable of separating the received
signal into third and fourth signals comprising only components of the
received signal including the first and the second polarization
directions, respectively, and transmitting the third and fourth signals
along respective first (106) and second (107) paths;
means (114) capable of adjusting the phase and amplitude of the fourth
signal in the second path in response to control signals;
means (110) capable of combining the third and the adjusted fourth signals
to generate an output signal which primarily includes the first desired
signal; and
means (124) capable of generating the appropriate control signals to the
adjusting means to appropriately adjust the amplitude and phase of the
fourth signal
characterized in that
the generating means (124) comprises:
means (120, FIG. 1; 172, 179, 180, FIG. 5) coupled to the output of the
combining means capable of extracting a sample of the cross-polarization
components of the second interfering signal remaining in the output signal
from the combining means;
power detection means (123, FIG. 1; 181, FIG. 5) capable of generating an
output signal representative of the power envelope of the output signal of
said extracting means; and
a processor (124) capable of generating the appropriate control signals, in
response to the output signal from said power detection means, for
transmission to the adjusting means for appropriately adjusting the phase
and amplitude of the fourth signal to achieve maximum cancellation of
cross-polarization components of the second interfering signal in the
third signal at the output of the combining means.
2. An adaptive cross-polarization interference cancellation arrangement in
accordance with claim 1 wherein the first desired signal includes
information transmitted in a channel of a first frequency band and the
second interfering signal includes information transmitted in a channel of
a second frequency band which partially overlaps the first frequency band
characterized in that
said extracting means (120) comprises a band-pass filter which has a
pass-band that is outside the first frequency band but within the
non-overlapping portion of the second frequency band.
3. An adaptive cross-polarization interference cancellation arrangement in
accordance with claim 1 wherein the first desired signal includes
information transmitted in a channel of a first frequency band and the
second interfering signal includes information transmitted in a channel of
a second frequency band which partially overlaps the first frequency band
characterized in that
said extracting means (172, 179, 180, 190, 191, FIG. 5) comprises:
means (172) including a first and a second input terminal coupled to the
output of the combining means (110) and the separating means where the
fourth signal is transmitted, respectively, and capable of modulating
input signals at the first and second input terminals and generating an
output signal representative of such modulation;
a first band-pass filtering means (190, 191) which has a pass-band that is
outside the first frequency band but within the non-overlapping portion of
the second frequency band coupled to one input terminal of said modulating
means; and
low-pass filtering means (179, 180) capable of passing only signals in the
lower sideband of the output signal from said modulating means for
transmission to said power detection means.
4. An adaptive cross-polarization interference cancellation arrangement in
accordance with claim 3
characterized in that
said extracting means further comprises:
a second band-pass filtering means (190, 191) which has a pass-band that is
outside the first frequency band but within the non-overlapping portion of
the second frequency band coupled to the other input terminal of said
modulating means.
5. An adaptive cross-polarization interference cancellation arrangement in
accordance with claim 1 wherein the first desired signal and the second
interfering signal each include information transmitted in a channel in a
first frequency band
characterized in that
said extracting means (172, 179, 180, FIG. 5) comprises
means (172) capable of modulating the output signal from the combining
means with the fourth signal at the output of the separating means and
generating an output signal representative of such modulation; and
low-pass filter means (179, 180) capable of passing only signals in the
lower sideband of the output signal from said modulating means for
transmission to said power detection means.
6. An adaptive cross-polarization interference cancellation arrangement in
accordance with claim 5
characterized in that
said modulating means (172) comprises
means (174) capable of generating quadrature components of the fourth
signal received from the output of said separating means
means (176) capable of generating a pair of in-phase components of the
output signal from the combining means; and
a first and a second mixer (177, 178), each mixer being capable of
modulating a separate one of the quadrature components from said
quadrature components generating means with a separate one of said
in-phase components from said in-phase component generating means and
generating an output signal representative of each of such modulations for
transmission to said low-pass filtering means.
7. An adaptive cross-polarization interference cancellation arrangement in
accordance with claim 6
characterized in that
the low-pass filtering means comprises a first and a second low-pass
filter, each filter being disposed to filter the output signal from a
separate one of the first and second mixers; and
the power detection means comprises:
means (182-185, 188, 189) capable of generating signals representative of
the power envelope of each of the output signals from the first and second
low-pass filters; and
means (186) capable of adding the signals generated by said power envelope
generating means and generating a signal representative of such addition
for transmission to the processor.
8. An adaptive cross-polarization interference cancellation arrangement in
accordance with claim 1, 2, 3, or 5
characterized in that
the adjusting means (114) is further capable of deriving quadrature
components of the fourth signal at the output of the separating means and
adjusting the amplitude and phase of said quadrature components in
response to control signals from the processor; and
the processor (124) comprises a first (150) and a second (160) control
signal generating section, each section being capable of generating a
control signal in response to the output signals from the power detection
means for appropriately adjusting the phase and amplitude of a separate
one of the quadrature components in the adjusting means to cause said
adjusting means to generate an estimated cross-polarization interference
cancellation signal which maximally reduces the cross-polarization
interference at the output of the combining means.
9. An adaptive cross-polarization interference cancellation arrangement in
accordance with claim 8
characterized in that
each control signal generating section (150, 160) of the processor (124)
comprises:
a square wave generator (152, 162) capable of generating a square wave
output signal at a frequency band within a baseband frequency spectrum
which is different than the frequency band of the square wave generator in
the other control signal generating section;
means (154, 164) capable of multiplying together the instantaneous and
concurrent output signal values of said power detection means and said
square wave generator to generate an output signal representative of such
product;
means (155, 165) capable of providing an output signal representative of an
integration with time of the output signal of said multiplying means;
means (156, 166) capable of appropriately weighting the output signal of
said square wave generator to form a dither output signal; and
means (158, 168) capable of adding the output signals of said integration
means and said weighting means to generate the control signals for use in
the adjusting means. |
|
 |
|
 |
Claims |
|
|
|
Description |
|
|
TECHNICAL FIELD
The present invention relates to adaptive cross-polarization interference
cancellation arrangements and, more particularly, to adaptive
cross-polarization interference cancellation arrangements wherein a
desired polarized signal and an orthogonally polarized interfering signal
with cross-polarization components thereof are received at an antenna, the
orthogonally polarized components of the two signals are separated, the
separated main interfering signal is appropriately adjusted in amplitude
and phase and added to the separated desired signal components to effect
substantial cross-polarization cancellation, and a feedback path provides
appropriate feedback control signals to effect proper amplitude and phase
adjustment of the separated main interfering signal.
BACKGROUND ART
Cross-polarization interference, that is, interference due to signals whose
polarization is supposed to be orthogonal to the polarization of the
receiver, has created problems in terrestrial and satellite microwave
communication systems. In, for example, satellite communication systems,
larger earth stations include adaptive techniques for improving
cross-polarization isolation. These techniques tend to be systems which
mechanically rotate the antenna feed to compensate for changing
conditions. In this regard see, for example, the article "A Dual-polarized
4/6 GHz Adaptive Polarization Control Network" by A. E. Williams in Comsat
Technical Review, Vol. 7, No. 1, Spring 1977 at pp. 247-262.
Another arrangement is disclosed in U.S. Pat. No. 3,883,872 issued to J. C.
Fletcher et al. on May 13, 1975 which relates to a receiving system for
automatically selecting a desired one of two approximately orthogonally
polarized signals occupying the same bandwidth. The received signals are
provided by any orthomode antenna system at a pair of output ports and
then applied to the inputs of a hybrid junction to produce sum and
difference signals. The resulting sum signal at one output port comprises
components of the undesired one of two orthogonally polarized signals and
is used to coherently detect and dynamically balance out the undesired
signal components that are included at the difference signal port. The
desired one of two orthogonally polarized signals is thereby provided at
the difference port of the hybrid junction, and feedback loops are used to
effect dynamic balancing.
Still another arrangement is disclosed in U.S. Pat. No. 3,943,517 issued to
G. F. Vogt on Mar. 9, 1976 which relates to an adaptive polarization
receiving system wherein a polarization follower is employed to make the
system phase angle track the orientation angle of linear polarization of
the received carrier so that the receiver apparatus will follow
polarization changes in the information signal. This apparatus includes a
closed loop feedback network in which an error signal is generated
whenever the system phase angle differs from the incident polarization
angle, and in which a control voltage is developed for superimposition on
a signal which scans the receiving antenna at a constant frequency. At the
same time, the error voltage is used to optimize the reproduction of the
received message information in the presence of variations in incident
polarization angle by off-setting the signal fading which results.
Adaptive co-channel interference suppression systems have also been
designed but do not solve the problem of cross-polarization interference.
In this regard see, for example, "An Adaptive Co-channel Interference
Suppression System to Suppress High Level Interference in Satellite
Communication Earth Terminals" by E. D. Horton in National
Telecommunication Conference Record, Dallas, Tex., Nov. 29-Dec. 1, 1976,
Sect. 13.4, pp. 1-5 and "Suppression of Co-channel Interference with
Adaptive Cancellation Devices at Communications Satellite Earth Stations"
by P. D. Lubell et al in ICC 77 Conference Record, June 12-15, 1977,
Chicago, Ill., Vol. 3, pp. 49.3-284-49.3-289. In these disclosed systems,
an independent sample of the interfering signal is obtained, the phase and
amplitude of which is adjusted by an adaptive filter to provide an
estimate of the interference in the received signal. This estimate is then
subtracted from the received signal to give the undistorted desired signal
and a residue from the subtract operation. The response of the adaptive
filter depends on the correlation between this residue and the
interference sample.
Another co-channel interference suppression arrangement is disclosed in a
co-pending patent application Ser. No. 81,552 filed on the same day as the
present application for D. M. Brady and A. M. Gupta wherein a main antenna
picks up the desired signal and some interfering signal and a small
auxiliary antenna is pointed in the direction of the interfering source
and picks up a sample of the interfering signal. The interfering sample is
then put through a quadrature modulator for adjustment of its phase and
amplitude and for providing an estimated cancellation signal at the
output. This estimated cancellation signal is then combined with the main
antenna output to give a corrected signal. After down-converting, the
present system detects the power in the corrected signal and a processor
in response to such power detection generates a small dither signal which
is added to the control signals to vary the phase and amplitude in the
quadrature modulator of the residual interference in the corrected signal.
The problem remaining in the prior art is to provide an adaptive
cross-polarization cancellation arrangement which is both simple and
inexpensive and provides excellent isolation and response to changing
conditions in comparison with known arrangements.
SUMMARY OF THE INVENTION
The foregoing problem in the prior art has been solved in accordance with
the present invention which relates to adaptive cross-polarization
interference cancellation arrangements and, more particularly, to adaptive
cross-polarization interference cancellation arrangements wherein a
desired polarized signal and an orthogonally polarized interfering signal
with cross-polarization components thereof are received at an antenna, the
orthogonally polarized components of the two signals are separated, the
separated main interfering signal is appropriately adjusted in amplitude
and phase in a quadrature modulator in response to control signals, and
added to the separated desired polarized signal components to effect
appropriate cross-polarization cancellation, and a feedback path includes
means capable of measuring the power envelope of an output signal to
permit a processor to generate the proper control signals to the
quadrature modulator for properly adjusting the amplitude and phase of the
separated main interfering polarized signal.
It is an aspect of the present invention to provide arrangements capable of
providing substantial cross-polarization interference cancellation between
two or more orthogonally polarized signals occupying the same or adjacent
overlapping frequency channels.
Other and further aspects of the present invention will become apparent
during the course of the following description and by reference to the
accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWING
Referring now to the drawings, in which like numerals represent like parts
in the several views:
FIG. 1 illustrates a block diagram of an adaptive cross-polarization
interference cancellation arrangement in accordance with the present
invention for use in cancelling cross-polarization interference between
orthogonally polarized signals received in adjacent overlapping frequency
channels;
FIG. 2 illustrates a typical frequency response for the desired polarized
signal, one or more overlapping interfering channels orthogonally
polarized to the desired channel polarization, and the filters in the
output and feedback path in FIG. 1;
FIG. 3 illustrates a block diagram of an exemplary quadrature modulator for
use in the arrangements of FIGS. 1 and 5;
FIG. 4 illustrates a block diagram of a processor for use in the
arrangements of FIGS. 1 and 5;
FIG. 5 illustrates a block diagram of an adaptive cross-polarization
interference cancellation arrangement in accordance with the present
invention for use in cancelling cross-polarization interference between
orthogonally polarized signals received in the same frequency band; and
FIG. 6 illustrates an exemplary circuit diagram of a complex envelope power
detector for use in the feedback path of the arrangement of FIG. 5.
DETAILED DESCRIPTION
FIG. 1 is a block diagram of an adaptive cross-polarization interference
cancellation arrangement in accordance with the present invention for use
in cancellation of cross-polarization interference between a desired
polarized signal and interfering cross-polarization components from a
second orthogonally polarized signal received in adjacent overlapping
frequency channels.
The description which follows is directed to the use of the present
arrangements in a small earth station receiving terminal associated with a
satellite communication system for suppressing cross-polarization
components of an interfering linearly polarized signal concurrently
received from the same or a different direction with an orthogonally
polarized desired signal from the satellite. It is to be understood that
such description is exemplary only and is for purposes of exposition and
not for purposes of limitation. It can readily be appreciated that the
present arrangements can also be used with terrestrial microwave systems
for effecting cross-polarization interference cancellation.
In the arrangement of FIG. 1, an antenna 100 is directed to receive a
signal 102 transmitted from a satellite repeater (not shown), signal 102
being, for example, a desired linearly polarized signal in a first channel
of a frequency band f.sub.1, as shown in FIG. 2, which is shown with the
designation M(t) and is destined for the earth station including the
arrangement of FIG. 1. Due to the location of the present earth station or
the possibility that the present earth station also includes equipment
associated with orthogonally polarized signals from the same satellite
system or one or more terrestrial microwave systems, a second signal 104,
designated I(t) is also concurrently received at antenna 100, signal 104
being, for example, orthogonally polarized to signal 102 and transmitted
in a second channel of a frequency band f.sub.2, as shown in FIG. 2, and
comprising cross-polarization components which cause interference with the
desired signal 102.
The signals 102 and 104 received at antenna 100 are applied to the input of
a dual polarization coupler 105 which is capable of separating
orthogonally polarized components in a received signal and transmitting
such separated components over separate paths. More particularly, coupler
105 essentially functions to (1) transmit the desired signal 102 of a
first polarization and cross-polarization components of a second
orthogonally polarized interfering signal 104 over path 106, and (2)
transmit the interfering orthogonally polarized signal 104 and any
cross-polarization components from the desired signal 102 over path 107.
Therefore, the signal on lead 106 can be represented by the expression
M(t)+.alpha.I(t) while the signal on lead 107 can be represented by the
expression I(t)-.alpha.M(t). Coupler 105 can comprise any suitable circuit
known in the art.
The signal on lead 106 is amplified in a low noise type amplifier 108 and
applied to one input of a hybrid circuit 110. The signal on lead 107 is
amplified to a predetermined level in a low noise type amplifier 112 and
then transmitted through a quadrature modulator 114 for adjustment of the
phase and amplitude of each of the quadrature components as will be
explained in greater detail hereinafter. The adjusted signal from
quadrature modulator 114 is applied to a second input of hybrid circuit
110. Amplifiers 108 and 112, quadrature modulator 114 and hybrid circuit
110 can comprise any suitable circuit or arrangement capable of performing
the functions described.
The output signal from quadrature modulator 114 provides an estimated
cross-polarization interference cancellation signal which is combined with
the amplified signal on lead 106 in hybrid circuit 110 to provide a
corrected signal, which can be designated S(t), at the output thereof
which is substantially free of cross-polarization interference from signal
104. The corrected signal is demodulated to, for example, IF frequencies
in a down-converter 116. The desired polarized signal M(t) and any
remaining cross-polarization components from I(t) that may not have been
cancelled by the estimated cross-polarization interference cancellation
signal in the frequency band f.sub.1 is passed through a bandpass filter
118 for further processing in the receiver (not shown). The response of
filter 118 is shown in FIG. 2 by the curve F.sub.1.
The output of down-converter 116 is also applied to the input of a filter
120 having a passband which is just outside the frequency band f.sub.1 of
the desired signal 102 after down-conversion but near the center of the
frequency band of the orthogonally polarized interfering channel. For
example, if in FIG. 2 the channel N of interfering signal I(t) is received
at antenna 100, then filter 120 would be designed to include a response or
passband shown by the curve 121 so as to only pass any remaining
components of channel N at the output of down-converter 116, which
comprise frequency components in the passband shown by curve 121 and block
any components outside this passband which, of course, include components
of the desired polarized signal M(t). Similarly, if a second interfering
channel N+1 of interfering signal I(t) were also received at antenna 100
with, or instead of, the signals of channel N, then filter 120 would be
designed to include a passband as indicated by the curve 122 of FIG. 2 to
pass only remaining components of orthogonally polarized channel N+1 at
the output of down-converter 116 while blocking all signals outside this
passband which, of course, would block components of the desired polarized
signal M(t).
The output signal from filter 120 is applied to the input of a power
detector 123 whose output voltage is proportional to the magnitude of the
input signal squared. More particularly, power detector 123 obtains the
envelope of the power of the input signal from filter 120 which detected
output signal is at, for example, baseband frequencies and has lost
coherence with the desired or interfering signal. It is to be understood
that down-converter 116, filters 118 and 120 and power detector 123 can
comprise any suitable circuit which is known and functions as described.
The output signal from power detector 123 is applied to the input of a
processor 124 which generates control signals that are transmitted over
leads 126 and 127 to the quadrature modulator 114 to appropriately vary
the phase and amplitude of the interfering signal 104 sample received by
antenna 100. The processor 124 also generates a dither signal which is
added to the control signals to vary the phase and amplitude of the
residual interference in the corrected signal S(t) from hybrid circuit 110
to achieve maximal interference suppression.
FIG. 3 illustrates a typical quadrature modulator 114 which can be used for
adjusting the phase and amplitude of the interfering signal 104 received
at antenna 100. The exemplary quadrature modulator 114 comprises a
quadrature hybrid 130 which divides the interference signal sample I(t)
into two quadrature phased components which are transmitted as separate
outputs on leads 131 and 132. Each of the quadrature phased components on
leads 131 and 132 are modulated in mixers 134 and 136, respectively, by
control signals from processor 124 on respective leads 126 and 127. The
two components from mixers 134 and 136 are then recombined in a hybrid 138
to generate the estimated cancellation signal which is then combined with
the amplified signal on lead 106 in hybrid 110 to give the corrected
signal S(t). It is to be understood that the quadrature hybrid 130, mixers
134 and 136 and hybrid 138 of the exemplary quadrature modulator 114 shown
in FIG. 3 can comprise any suitable circuit which is known. Additionally,
any other suitable quadrature modulator which is known may also be used.
FIG. 4 illustrates a block diagram of processor 124 for use in the present
adaptive cross-polarization interference suppression arrangement to
generate the necessary control signals for appropriately adjusting the
phase and amplitude of the quadrature phased components in mixers 134 and
136 of exemplary quadrature modulator 114 of FIG. 3. Processor 124 is
described in the previously cited co-pending application, Ser. No. 81,552
filed for D. M. Brady and A. M. Gupta but is repeated here for
completeness. Processor 124 is shown as comprising a first and a second
control signal generating section designated 150 and 160, respectively.
First control signal section 150 includes a square wave generating source
152 which is capable of generating a square wave signal within a first
frequency band within the baseband frequency but less than the bandwidth
of the IF frequency band, which square wave signal is designated d.sub.1
(t). Square wave signal d.sub.1 (t) is applied to one terminal of a
multiplying circuit 154 which multiplies this signal d.sub.1 (t) with the
output from power detector 123 or 181 to generate an output signal which
is representative of such product. The output signal from multiplying
circuit 154 is integrated with respect to time in an integrator circuit
155 which generates an output signal representative of such integration
and is designated .beta..sub.1.
The square wave signal d.sub.1 (t) from generator 152 is also transmitted
through a variable attenuator 156 to generate a desired weighted output
signal which is designated kd.sub.1 (t). Adjustment of variable attenuator
156 in turn adjusts the weighting factor, k, introduced in the square wave
signal d.sub.1 (t) passing therethrough. The output signal .beta..sub.1
from integrator circuit 155 and the weighted square wave signal kd.sub.1
(t) from attenuator 156 are added in summing circuit 158 to generate a
control signal which has a small dither signal added thereto. This control
and dither signal are transmitted over lead 127 to quadrature modulator
114 for appropriately varying the amplitude and phase of the signal on
lead 132 being applied to mixer 136 in the exemplary modulator of FIG. 3.
Second control section 160 of processor 124 comprises an apparatus
arrangement which corresponds to that of first control section 150. In
second control section 160, a square wave generator 162 generates a square
wave signal d.sub.2 (t) at a second frequency band within the baseband
frequency but less than the bandwidth of the IF frequency band. It is to
be understood that the first frequency band and the second frequency band
generated by square wave generators 152 and 162, respectively, comprise
different frequency bands within the bandwidth of the baseband frequency.
The square wave signal from generator 162 and designated d.sub.2 (t) is
multiplied with the output signal from power detector 123 or 181 in a
multiplying circuit 164 which resultant signal is integrated over time in
integrator circuit 165. The square wave signal from generator 162 is
weighted by variable attenuator 166 to provide a weighted output signal
designated kd.sub.2 (t). The weighted output signal from variable
attenuator can be controlled by adjustment of the variable attenuator and
such desired signal is added to the output of integrator 165, designated
.beta..sub.2, in summing circuit 168. The output of summing circuit 168 is
a control signal with a small dither signal added which is applied over
lead 126 to quadrature modulator 114 for appropriately varying the
amplitude and phase of the signal on lead 131 being applied to mixer 134
in the exemplary modulator of FIG. 3. It is to be understood that square
wave generators 152 and 162, multipliers 154 and 164, integrators 155 and
165, variable attenuator 156 and 166 and summing circuits 158 and 168 can
comprise any suitable circuit for achieving the functions described
hereinbefore.
In operation, the received signals pass through the various circuits shown
in FIGS. 1-4 as outlined hereinbefore. Attenuators 156 and 166 of
processor 124 are then adjusted until the power level at the output of
filter 120 is at a minimum. Such minimum value indicates that the power
level of the interference signal has been substantially minimized to a
zero value and basically only the desired signal, M(t), forms the output
signal of the present adaptive cross-polarization interference
cancellation arrangement.
FIG. 5 illustrates an adaptive cross-polarization interference cancellation
arrangement in accordance with the present invention for use in cancelling
cross-polarization interference between a desired polarized signal M(t)
designated 102 and interfering cross-polarization components from a second
orthogonally polarized signal I(t) designated 104 received in the same
frequency band as the desired signal. In the arrangement of FIG. 5,
antenna 100, dual polarization coupler 105, low noise type amplifiers 108
and 112, quadrature modulator 114, hybrid 110, down-converter 116 and
processor 124 function as described previously for the correspondingly
numbered elements in the arrangement of FIG. 1. The primary difference
between the arrangements of FIGS. 1 and 5 lies in the structure of the
elements in the feedback path.
In the feedback path in FIG. 5, the output signal from amplifier 112, in
the received interference signal path 107, is also applied to a power
amplifier 170 which effectively acts as a local oscillator in supplying
its output signal to a circuit 172 which functions as a single sideband
modulator. In the exemplary single sideband modulator circuit 172 shown in
FIG. 5, the output signal from power amplifier 170 is split into two
quadrature signals by a quadrature hybrid 174, each quadrature output
signal being applied as one input to a separate one of mixers 177 and 178.
Concurrent therewith, the output signal from hybrid 110, which is at r-f
frequencies, is split into two in-phase component signals by an in-phase
hybrid 176, each in-phase output signal being applied as the other input
to a separate one of mixers 177 and 178. The baseband frequency signals
being generated by mixers 177 and 178 represent the in-phase and
quadrature components of the correlation between the orthogonally
polarized signals received at antenna 100 and are applied to low-pass
filters 179 and 180, respectively, which allow only signals in the
baseband frequencies to pass therethrough. The in-phase and quadrature
components represent the real and imaginary portions of the correlation.
The outputs from filters 179 and 180 are applied to separate inputs of a
complex envelope power detector 181 which functions to detect the power
envelope of each of the input signals from filters 179 and 180, which
detected envelopes are added in a summing circuit to produce an output
signal representative thereof. This output signal from power detector 181
is applied as the input to processor 124 which functions as described for
processor 124 shown in FIGS. 1 and 4 to complete the feedback path and
cause adjustment of the phase and amplitude of the interfering signal
samples in quadrature modulator 114 to maximally cancel the
cross-polarization interference at the output of hybrid 110.
An exemplary circuit diagram for use in complex envelope power detector 181
of FIG. 5 is shown in FIG. 6. In the exemplary circuit of FIG. 6, each of
the output signals from filters 179 and 180 are applied to one input of a
separate operational amplifier 182 and 183, respectively.
The output of each of the operational amplifiers 182 and 183 is applied via
properly poled diodes 184 and 188, and 185 and 189, respectively, to the
inputs of another operational amplifier 186, the output of amplifier 186
providing the input signal to processor 124. Effectively, diodes 184 and
188, together with operational amplifier 186, detect the power envelope of
the signals from filter 179, while diodes 185 and 189, together with
operational amplifier 186, detect the power envelope of the signals from
filter 180, which power envelopes are added together in amplifier 186 to
generate the appropriate signal to processor 124.
The arrangement of FIG. 5 can also be used when input signals 102 and 104
are received in separate channels including signals in a first and a
second overlapping frequency band as described for the arrangement of FIG.
1. Under such condition, optional filters 190 and/or 191 should be
inserted into the input paths of single sideband modulator 172 to permit
the passage of signals in the second frequency band but not in the first
frequency band. Filters 190 and/or 191 would have the same characteristic
passband as filter 120 of FIG. 1 and as shown in FIG. 2.
It is to be understood that the above-described embodiments are simply
illustrative of the principles of the invention. Various other
modifications and changes may be made by those skilled in the art which
will embody the principles of the invention and fall within the spirit and
scope thereof.
* * * * *
|
|
|
|
|
|
|
Description |
|
