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Claims  |
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We claim:
1. A radio receiver having an antenna input terminal, an RF signal
amplifier, and an RF signal path formed by at least the antenna input
terminal and the RF signal amplifier characterized by:
(a) an adjustable attenuator coupled in the RF signal path,
(b) processing means for controlling the adjustable attenuator by
developing a control signal indicative of the presence of intermodulation
distortion after processing of a desired signal by the radio receiver.
2. A method for use with a radio receiver having an antenna input terminal,
an RF signal amplifier, a mixer, processing means for controlling a first
adjustable attenuator and for controlling a second adjustable attenuator,
wherein the first adjustable attenuator is coupled between the antenna
input terminal and the RF signal amplifier, and wherein the second
adjustable attenuator is coupled between the RF signal amplifier and the
mixer, the method including the steps of:
(a) the receiver receiving a received signal comprising noise and a
plurality of signals including a desired signal,
(b) the processor adjusting the attenuation of the first attenuator to
improve reception of the desired signal by developing a control signal
indicative of the presence of intermodulation interference after
processing of the desired signal by the radio receiver; and
(c) the processor using the control signal to adjust the attenuation of the
second attenuator to improve reception of the desired signal.
3. The method of claim 2 wherein step (c) is performed before step (b).
4. The method of claim 2 wherein steps (b) and (c) are performed
substantially simultaneously.
5. A method for use with a radio receiver having an antenna input terminal,
an RF signal amplifier, a mixer, processing means for controlling a first
adjustable attenuator and for controlling a second adjustable attenuator,
wherein the first adjustable attenuator is coupled between the antenna
input terminal and the RF signal amplifier, and wherein the second
adjustable attenuator is coupled between the RF signal amplifier and the
mixer, the method including the steps of:
(a) the receiver receiving noise and a plurality of signals including a
desired signal;
(b) the processor adjusting the attenuation of the first attenuator to
minimize the symbol error rate (SER) of the desired signal by developing a
control signal indicative of the presence of intermodulation interference
after processing of the desired signal by the radio receiver; and
(c) the processor using the control signal to adjust the attenuation of the
second attenuator to minimize the symbol error rate (SER) of the desired
signal.
6. The method of claim 5 wherein step (c) is performed before step (b).
7. The method of claim 5 wherein steps (b) and (c) are performed
substantially simultaneously.
8. The method of claim 5 wherein magnitude and direction of changes in
symbol error rate (SER) are determined by dithering the attenuations of
the first and/or second attenuators.
9. The method of claim 8 wherein the dithering is performed by incrementing
and/or decrementing the attenuations of the first and/or second
attenuators, such that the increments and/or decrements of the first and
second attenuators are proportional to the sensitivity of the SER to
incremental changes in, respectively, the attenuations of the first and
second attenuators.
10. The method of claim 5 wherein the processor adjusts the third-order
intercept point of the radio receiver based upon the symbol error rate
(SER) of the radio receiver.
11. The method of claim 5 wherein the processor adjusts the third-order
intercept point of the radio receiver based upon the signal-to-noise ratio
of the desired signal as received by the radio receiver.
12. The method of claim 5 wherein the processor adjusts the third-order
intercept point of the radio receiver based upon a set of logical rules
applied to the signal-to-noise ratio of the desired signal.
13. The method of claim 5 wherein the processor adjusts the third-order
intercept point of the radio receiver based upon a set of logical rules
applied to the symbol error rate (SER) of the desired signal.
14. A method for use with a radio receiver having an antenna input
terminal, an RF signal amplifier, a mixer, processing means for
controlling a first adjustable attenuator and for controlling a second
adjustable attenuator, wherein the first adjustable attenuator is coupled
between the antenna input terminal and the RF signal amplifier, and
wherein the second adjustable attenuator is coupled between the RF signal
amplifier and the mixer, the method including the steps of:
(a) the receiver receiving a received signal comprising, noise and a
plurality of signals including a desired signal;
(b) the processor adjusting the attenuating of the first attenuator to
maximize the signal-to-noise (C/N) ratio of the desired signal by
developing a control signal indicative of the presence of intermodulation
interference after processing of the desired signal by the radio receiver;
and
(c) the processor using the control signal to adjust the attenuation of the
second attenuator to maximize the signal-to-noise (C/N) ratio of the
desired signal.
15. The method of claim 14 wherein step (c) is performed before step (b).
16. The method of claim 14 wherein steps (b) and (c) are performed
substantially simultaneously.
17. The method of claim 14 wherein magnitude and direction of changes in
signal-to-noise ratio of the desired signal are determined by dithering
the attenuations of the first and/or second attenuators.
18. The method of claim 17 wherein the dithering is performed by
incrementing and/or decrementing the attenuations of the first and/or
second attenuators, such that the increments and/or decrements of the
first and/or second attenuators are proportional to the sensitivity of the
signal-to-noise ratio to incremental changes in, respectively, the
attenuations of the first and second attenuators.
19. The method of claim 14 herein the processor adjusts the third-order
intercept point of the radio receiver based upon the symbol error rate
(SER) of the radio receiver.
20. The method of claim 14 wherein the processor adjusts the third-order
intercept point of the radio receiver based upon the signal-to-noise ratio
of the desired signal as received by the radio receiver.
21. The method of claim 14 wherein the processor adjusts the third-order
intercept point of the radio receiver based upon a set of logical rules
applied to the signal-to-noise ratio of the desired signal.
22. The method of claim 14 wherein the processor adjusts the third-order
intercept point of the radio receiver based upon a set of logical rules
applied to the symbol error rate (SER) of the desired signal.
23. A method of estimating the amount of intermodulation distortion present
in a radio receiver having an RF signal amplifier, an antenna input
terminal, a mixer, a first adjustable attenuator coupled between the
antenna input terminal and the RF signal amplifier, a second adjustable
attenuator coupled between the RF signal amplifier and the mixer, and a
processor for adjusting the first and second adjustable attenuators, for
measuring the signal-to-noise ratio of the desired signal, and for
measuring the signal strength of the desired signal, the method including
the steps of:
(a) the processor measuring the received signal strength and the
signal-to-noise ratio of the desired signal and developing a control
signal indicative of the presence of intermodulation interference;
(b) the processor estimating the amount of the receiver-generated thermal
noise based on the present amounts of attenuation provided by the first
and the second adjustable attenuators, and the present gain state of any
other variable gain component in the receiver, and using the control
signal to adjust the first and second adjustable attenuators in response
to the measurements of received signal strength and signal-to-noise ratio.
24. The method of claim 23 wherein the radio receiver is adapted for use
with a CDMA (code division multiple access) wireless telephone system and
the processor includes means for measuring the neighbor pilot strength of
a CDMA RF carrier signal, the method further including the step of the
processor estimating intermodulation distortion performance based upon
measurements of the neighbor pilot strength.
25. The method of claim 24 wherein the radio receiver includes a rake
receiver having a plurality of rake fingers, each rake finger including
signal strength measuring means for measuring the signal strength of the
desired signal during a corresponding time duration, the method further
including the step of the processor estimating intermodulation distortion
performance based upon measurements of signal strength at each of a
plurality of rake fingers.
26. A method of RF interference rejection as set forth in claim 23 and for
use with a radio receiver having an RF signal amplifier, an antenna input
terminal, a mixer, a first adjustable attenuator coupled between the
antenna input terminal and the RF signal amplifier, a second adjustable
attenuator coupled between the RF signal amplifier and the mixer, and a
processor for adjusting the first and second adjustable attenuators, for
measuring the signal-to-noise ratio of the desired signal, and for
measuring the signal strength of the desired signal, THE METHOD INCLUDING
THE STEPS OF the processor adjusting the intermodulation distortion
performance of the radio receiver by:
(a) the processor measuring the received signal strength and the
signal-to-noise ratio of the desired signal;
(b) estimating receiver-generated thermal noise;
(c) the processor adjusting first and second adjustable attenuators in
response to the measurements of received signal strength and
signal-to-noise ratio.
27. The method of claim 26 wherein the radio receiver is adapted for use
with a CDMA (code division multiple access) wireless telephone system and
the processor includes means for measuring the neighbor pilot strength of
a CDMA RF carrier signal, the method further including the step of the
processor estimating intermodulation distortion performance based upon
measurements of the neighbor pilot strength.
28. The method of claim 26 wherein the radio receiver includes a rake
receiver having a plurality of rake fingers, each rake finger including
signal strength measuring means for measuring the signal strength of the
desired signal during a corresponding time duration, the method further
including the step of the processor estimating intermodulation distortion
performance based upon measurements of signal strength at each of a
plurality of rake fingers. |
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Claims |
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Description |
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BACKGROUND
1. Field of the Invention
The invention relates generally to radio receivers, and more specifically
to radio receivers that are used for wireless telephone communications.
2. Description of Related Art
The field of wireless communications is experiencing rapid growth. In order
to increase the capacity of existing cellular communications systems,
present efforts are being directed towards new modulation schemes, such as
CDMA and TDMA. One characteristic of CDMA is that relatively broadband
radio receiver designs must be employed. At the same time that these
modulation schemes are enjoying more widespread acceptance, new cell sites
and other radio communications systems are being constructed at an
ever-increasing pace. Consequently, wireless telephone receivers must be
able to effectively discriminate against many sources of interference.
The extent to which a wireless telephone receiver is immune to RF
interference from nearby transmitters is determined by the intermodulation
distortion characteristics of the receiver. As a general matter, broadband
receivers are more susceptible to intermodulation distortion than
narrowband receivers. These intermodulation distortions occur at the
receiver front-end when the front end is exposed to strong undesired
out-of-band signals as, for example, when the receiver is in close
proximity to a cell site transmitter other than that from which the
receiver is currently receiving a radio signal.
One conventional technique for improving intermodulation distortion
problems addresses the design of the receiver front end. As a general
matter, intermodulation performance can be improved by increasing the
quiescent operating current of the active RF device or devices in the
receiver front end. In order to obtain acceptable intermodulation
performance in many real-world environments, the quiescent operating
current must often be increased to an undesirably high level. In the case
of stationary equipment connected to a 120-volt mains supply, the use of
such a high current generally poses no great problem. However, a different
situation exists with respect to portable equipment, where such a high
current drain would very quickly deplete a set of fresh batteries. The
user is inconvenienced by having to frequently change and/or recharge
batteries. Such batteries may be expensive, and, if not, the frequent
purchase of inexpensive batteries may also prove costly. Moreover, the
user may be faced with a set of dead batteries in an emergency situation.
What is needed is a technique for improving intermodulation performance
while, at the same time, not significantly increasing the current
consumption of the receiver.
SUMMARY OF THE INVENTION
Improved radio receiver designs are disclosed that can be used in the
operational environment of wireless telephone communications. The radio
receiver includes a signal input terminal, an RF signal amplifier, an
input variable attenuator coupled between the signal input terminal and
the input of the RF signal amplifier, an output variable attenuator
coupled to the output of the RF signal amplifier, and a controller coupled
to the input variable attenuator, the output variable attenuator, and the
RF signal amplifier. The received signal, including any noise and/or
interference, is coupled to the signal input terminal. The controller
controls the amount of attenuation provided by the input variable
attenuator and/or the output variable attenuator, in response to signals
received by the RF signal amplifier. The controller adjusts the output
variable attenuator, and/or the input variable attenuator, to achieve at
least a minimum acceptable signal-to-interference ratio for a desired
signal, while the Noise Figure is not degraded any more than is necessary
to achieve a minimum acceptable signal-to-interference ratio at any given
time. In this manner, the input variable attenuator and/or the output
variable attenuator are adjusted to obtain a required amount of
intermodulation performance for a given set of receiving conditions. This
technique saves operating current and maintains fade margins because, in
practice, interference conditions do not persist all of the time, and are
usually of temporary duration. A first alternate embodiment uses an input
variable attenuator but does not employ an output variable attenuator, and
a second alternate embodiment uses an output variable attenuator but does
not employ an input variable attenuator.
According to a further embodiment, the controller operates in the
environment of an existing control loop, and provides a novel additional
control loop. The existing control loop includes a mixer coupled to the
output variable attenuator and/or to the RF signal amplifier, an IF
amplifier coupled to the mixer, and a rake receiver coupled to the IF
amplifier. The rake receiver includes an A-to-D converter and a rake
correlator, and may, but need not, include an I/Q separator and an
IF-to-baseband downconverter. The output of the rake correlator may be
compared with the output of the A-to-D converter to determine a signal C/N
(carrier-to-noise) ratio. The existing control loop adjusts the gain of an
adjustable gain element in the receiver as, for example, an AGC (automatic
gain control) line of the IF amplifier, to maintain a constant
(Signal+Noise) level at the A-to-D converter.
The novel additional control loop controls the amount of attenuation
provided by the input variable attenuator and/or the output variable
attenuator, in order to maintain the received signal quality above a
nominal level and the current consumption as close as possible to a low
nominal level. The controller uses the additional control loop to maintain
the symbol error rate (SER) and/or the carrier to noise ratio (C/N) at a
desired level. This embodiment is useful for improving the overall signal
handling capability of a receiver, in that a strong desired signal is
often accompanied by the presence of relatively strong undesired RF
signals (i.e., interfering signals). Under these circumstances, additional
attenuation improves receiver performance, irrespective of the
intermodulation distortion characteristics of the RF signal amplifier.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a hardware block diagram setting forth an illustrative embodiment
of the invention disclosed herein.
FIG. 2 is a graph depicting the relative magnitude of a desired signal, and
the relative magnitudes of various sources of noise and interference,
versus time, for a typical radio receiving environment.
FIG. 3 is a graph depicting the relative signal-to-noise ratio of a
received signal versus the settings of the attenuators of FIG. 1 for two
illustrative values of RF signal amplifier current.
FIG. 4 is a table that describes a first method for selecting appropriate
values for the attenuators of FIG. 1 using an illustrative set of fuzzy
controller rules which the controller of FIG. 1 is programmed to
implement.
FIG. 5 is a software flowchart illustrating a second method for selecting
appropriate values for the first and second attenuators of FIG. 1, and for
selecting an appropriate value for the RF signal amplifier current of FIG.
1.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
FIG. 1 is a hardware block diagram setting forth an embodiment of the
invention disclosed herein. Although the hardware configuration of FIG. 1
may be conceptualized as representing a receiver in a wireless telephone,
the techniques disclosed herein are applicable to virtually any type of
receiver. For example, the present invention encompasses not only
receivers that are used in wireless telephone devices, but also receivers
used by law enforcement agencies, public safety organizations, businesses,
aircraft pilots, maritime operators, and the public at large, including
consumer products such as stereos, car radios, shortwave radios, AM/FM
radios, or the like.
In practical, real-world environments, the receiver of FIG. 1 receives a
desired signal along with a certain amount of noise. Therefore, the input
of a receiver may be conceptualized as a summer 105 that receives two
inputs: a first input 101 that represents the sum of all sources of noise
and interference including intermodulation interference, and a second
input 103 that represents a desired signal. The intermodulation
interference is actually generated in the receiver, but is shown here as
already present at the input of the receiver for conceptual
simplification. This conceptualization, known as "referring to the input",
implies that a component, such as noise or interference, normally
generated within the receiver, is shown as being applied to the input of
the receiver, while the receiver is assumed to generate none of that
component. The output of the summer is fed to the input of a first
attenuator 107 having an adjustable attenuation denoted as .alpha., and
the output of the first attenuator is fed to the input of an RF signal
amplifier 111. The attenuation of the first attenuator 107 is adjusted via
an attenuation control 109 input. The current consumed by the RF signal
amplifier 111 may be adjusted to a desired level via an amplifier current
(I.sub.C) regulator 113 that is placed in series with a voltage source
V.sub.CC 115 that supplies DC power to the RF signal amplifier. The RF
output of the RF signal amplifier 111 is coupled to a second attenuator
117 having an adjustable attenuation denoted as .beta.. The attenuation of
the second attenuator 117 is adjusted via an attenuation control 119
input.
The output of the second attenuator 117 is fed to a first input port of a
mixer 121, and the output of a frequency synthesizer 123 is fed to a
second input port of the mixer 121. Conventional devices well-known to
those skilled in the art may be employed for mixer 121 and frequency
synthesizer 123. In general, frequency synthesizer 123 includes a
voltage-controlled oscillator, a phase comparator, a phase-lock loop, a
buffer amplifier, and one or more multipliers/dividers. The function of
frequency synthesizer 123 is to generate an RF carrier at a certain
frequency such that, when the carrier and the desired signal are mixed at
mixer 121, a specified frequency component appears at the output of mixer
121.
The output of mixer 121 is fed to the input of an intermediate frequency
(IF) amplifier 125 having a gain control input 144 line which is used to
control the gain, gamma, of the IF amplifier 125. Since the IF amplifier
125 output is typically fed to some type of detector (demodulator) stage,
it is desirable for the output of the IF amplifier to be held at a
relatively constant value. For example, if the IF amplifier 125 is used in
a CDMA (code division multiple access) wireless telephone device, this
detector stage is present in the form of a rake processor 127. One
function of the gain control input 144 line is to permit the adjustment of
IF amplifier 125 gain, such that a relatively constant signal level is
present at the output of the IF amplifier, irrespective of the actual
signal level at the output of mixer 121. In this manner, the receiver
compensates for signal fluctuations in the total received
(signal+noise+distortion) power at the output of summer 105 by adjusting
the gain of the IF amplifier 125 to track received power changes. The
received power can change due several reasons such as, for example,
multipath fading, moving the receiver through an area having various
terrain obstructions, moving the receiver towards, or away from, the cell
site, and/or changing signal propagation or interference conditions. Note
that the gain control input 144 line may be used to maintain the level of
the desired signal, denoted as C, substantially at a constant level.
Alternatively, the gain control input 144 line may be used to maintain a
constant level of (desired signal+noise), denoted as (C+N).
The rake processor 127 is a digital signal processor designed to demodulate
digitally-modulated signals such as CDMA spread spectrum signals. Note
that, since the output of IF amplifier 125 is generally in analog form, an
A/D converter is used at the output of the IF amplifier 125 to convert
these analog signals to digital form. The A-to-D converter may be preceded
by an IF-to-baseband downconverter and/or an I/Q separator. For purposes
of the present example, the A/D converter, as well as any components
between the A-to-D converter and the IF amplifier, are considered to be a
part of the rake processor 127. The function and construction of rake
processor 127 are well known to those skilled in the art and do not
require additional explanation.
The output of rake processor 127, including noise components, denoted as N,
along with desired signal components, denoted as C, is fed to both a
Viterbi decoder 131 and a (C, N) meter 129. The Viterbi decoder 131
retrieves the digital information included in the desired signal
components C, and the (C, N) meter 129 measures the level of C, as well as
the level of N, present at the output of the rake processor 127. The
output of Viterbi decoder 131 is passed to a signal error rate (SER) meter
133 which measures the error rate of the digital information decoded by
Viterbi decoder 131. The signal error rate can be obtained from the
Viterbi decoder 131 by re-encoding the decoded packets and comparing the
resulting symbols with the received symbols.
The output of SER meter 133 and/or the output of (C, N) meter 129 are
coupled to respective inputs of controller 135. Controller 135 includes a
processing device, such as a microprocessor, and may optionally include
logic gates, flip-flops, buffers, comparators, operational amplifiers,
and/or resistive networks. The function of controller 135 is to monitor
the outputs of (C, N) meter 129 and/or SER meter 133 and, in response to
these outputs, generate a group of first control signals and a second
control signal. The group of first control signals may be a function of
the (C, N) meter 129 output only, the SER meter 133 output only, or a
function that includes both the (C, N) meter 129 output and the SER meter
133 output. The second control signal keeps the received power level
constant at the input to the rake receiver 127.
The controller 135 places the group of first control signals on a group of
output lines termed the slow optimization outputs 137. The second control
signal is placed on an output line termed the fast signal tracking output
139. To this end, the controller 135 generates the group of first control
signals to compensate for relatively slow variations in the interference
which generates intermodulation distortion.
A first output of the slow optimization outputs 137 is coupled to the first
attenuator 109, and is used to control the amount of attenuation, alpha,
provided by the first attenuator. A second output of the slow optimization
outputs 137 is coupled to the I.sub.C regulator 113, and is used to
control the amount of current drawn by the RF signal amplifier 111. A
third output of the slow optimization outputs 137 is coupled to the second
attenuator 117, and is used to control the amount of attenuation, beta,
provided by the second attenuator. In this manner, controller 135 adjusts
first attenuator 107, second attenuator 117, and current regulator 113 in
response to signals received from (C, N) meter 129 and/or SER meter 133.
A first control loop includes the output of the (C, N) meter 129, and/or
the output of the SER meter 133, coupled to controller 135, where
controller 135 uses one or both of these outputs to control the slow
optimization outputs 137 that are applied to the first attenuator 107, the
second attenuator 117, and the I.sub.C regulator 113 for RF signal
amplifier 111. The function of the second control loop, which could also
be termed an AGC loop, is to react fast to changing signal values. The
function of the first control loop, which could also be termed an
optimizing loop, is to react to changing signal conditions. In operation,
controller 135 adjusts the values of the attenuators and the RF signal
amplifier current to optimize receiver performance for the present set of
receiving conditions as reflected in the outputs of the SER meter 133
and/or the (C, N) meter 133. In one preferred implementation, a fuzzy
logic controller is used in controller 135. A simple and robust control is
obtained based on a few predefined rules which the controller 135 uses in
the receiver optimization process. The values of attenuation and amplifier
current are optimized for a given set of receiving conditions,
irrespective of receiver component variations due to manufacturing
processes and temperature excursions.
The following principles are applicable to the first and second attenuators
107, 117. In general, attenuators may be employed to reduce the
signal-to-high-order-interference (C/Ni ratio).
##STR1##
Note that the output third-order intercept point of the attenuator is much
higher than the input third-order intercept point of circuitry, such as an
amplifier or a mixer, which follows the attenuator. This characteristic
commonly occurs in conjunction with pin diode or switched-resistor
attenuators which have very high third-order intercept points. As the
attenuation of an adjustable attenuator is increased, an increase of X dB
attenuation produces greater than X dB improvement in C/Ni at the output
of an active device which follows the attenuator. Commonly, an increase of
1 dB in the attenuator would produce a 2 dB improvement in C/Ni, where Ni
is the 3rd order intermodulation product. As attenuation is increased, the
Noise Figure of the radio receiver increases, but this increase occurs at
a slower rate than the rate of decrease of Ni.
The receiver of FIG. 1 may be employed in a mobile environment where the
field strength of the signal to be received, as well as the received
noise, fluctuates with time and/or distance. Refer to FIG. 2 which
illustrates typical variations of received signal strength and received
noise components. In the operational environment of CDMA, these noise
components include:
Self induced noise from other users of the same CDMA channel--Ns. Note that
this noise tracks the received signal power.
Noc--Noise from other CDMA cells which are relatively far away, but at the
same frequency as the desired signal; this noise is subject to fading in
the same way as the desired signal. However, these variations are not
correlated with the variations in the desired signal.
Nt--thermal noise from the receiver front-end; this value is determined by
the receiver noise figure (NF) which, in turn, depends upon the amounts of
attenuation, .alpha. and .beta., applied by first and second attenuators
107, 117, respectively (FIG. 1), and is also determined, to a somewhat
lesser degree, by the amount of current drawn by RF signal amplifier 111
and controlled by Ic regulator 113.
Ni--intermodulation products caused by strong-out-of-band signals and
nonlinearities in the front-end. The levels of these intermodulation
products depend upon .alpha., .beta., and Ic. Ni is referenced to the
antenna input.
Most of these components are varying relatively fast when the receiver is
in motion, such as, for example, in a car. However, the signal and noise
conditions (average values, Doppler frequency etc.) are relatively
slow-varying.
FIG. 3 sets forth an illustrative relationship between receiver
intermodulation performance and the values for parameters .alpha., .beta.,
and Ic. This FIG. is useful for the purpose of developing illustrative
methods by which controller 135 selects appropriate values for the
parameters .alpha. and .beta., when a given value of I.sub.C is specified.
I.sub.C represents a desired design value of RF signal amplifier current
selected within the permissible range of operating currents of the RF
signal amplifier 111. In practice, the system designer selects a suitable
value of I.sub.C as a compromise between current drain and intermodulation
performance. As I.sub.C increases, the current drain increases, but the
intermodulation distortion performance also increases. At a certain amount
of intermodulation interference and a set value of Ic, there exists a set
of values .alpha..sub.0, .beta..sub.0, for which the receiver performance
is the best. In other words, even though a further increase in attenuation
beyond these values will decrease intermodulation distortion, the
resultant increase in noise figure will outweigh any benefit from reduced
intermodulation distortion. However, even if the "optimum" values of
attenuation are selected, additional improvement in intermodulation
distortion reduction is possible if the RF signal amplifier 111 current is
increased. In this case the third-order intercept point, denoted as IP3,
of the RF signal amplifier 111 itself is increased. Consequently, the
attenuator value .alpha. for the first attenuator 107 can now be
decreased; the noise figure will then be reduced, and the IP3 will be
increased. In effect, the optimum operating point of the attenuators
changes to .alpha..sub.1, .beta..sub.1. Therefore, in this example,
controller 135 is programmed to set the attenuation of the attenuators at
.alpha..sub.n, .beta..sub.n, when the operating current of the RF signal
amplifier 111 is set at a corresponding desired design value I.sub.C,n.
In a typical application, the third-order intercept point of RF signal
amplifier 111 (referred to at a common reference point such as the antenna
input), and at an RF signal amplifier 111 current Ic of Icnom, is only
slightly better than the third-order intercept point of the mixer 121
(referred to at the same reference point). If strong interference is
present along with a strong desired signal, the attenuators .alpha.,
.beta., can be adjusted to increase the receiver IP3 at the expense of
noise figure. If the signal is strong, this tactic may prove acceptable.
The following considerations are relevant in determining a desired design
value for I.sub.C. Note that, in some receiving environments, strong
interference may exist along with a weak desired signal. In such a case,
the RF signal amplifier third-intercept point (IP3) is improved by
increasing its operating current Ic. At the same time, the attenuation a
of first attenuator 107 can be lowered because the RF signal amplifier
does not need as much "protection" as before, and the attenuation .beta.
of the second attenuator 117 is increased in order to maintain the level
of mixer 121 intermodulation products at the previous level. When compared
with the strong-signal, strong-interference situation, there is a net gain
in noise figure with IP3 intact at the expense of RF signal amplifier 111
current.
FIG. 4 is a table that describes an illustrative set of fuzzy controller
rules which controller 135 may be programmed to implement for dynamically
selecting values for .alpha. and .beta. based upon present receiving
conditions. Although the example of FIG. 4 uses fuzzy control rules, this
is for purposes of illustration only, and it is to be understood that
non-fuzzy control rules may alternatively be employed. FIG. 4 may also be
used by the system designer to select a suitable value of RF signal
amplifier 111 operating current I.sub.C. In FIG. 4, the symbols
S.sub..alpha., and S.sub..beta., and S.sub.Ic denote the sensitivity of a
specified control parameter to changes in the parameters .alpha., .beta.,
and Ic, respectively. These sensitivities are defined as:
Sx=Sign(.DELTA.x)*{SER(x.sub.0)-SER(x.sub.0 +.DELTA.x)}; where x denotes
the changing parameter (.alpha., .beta., or Ic). S.sub..alpha..beta. is
one of the two:
SER(.alpha..sub.0, .beta..sub.0)-SER(.alpha..sub.0
+.DELTA..alpha.,.beta..sub.0 -.DELTA..beta.) or SER(.alpha..sub.0,
.beta..sub.0)-SER(.alpha..sub.0 -.DELTA..alpha.,.beta..sub.0
+.alpha..beta.).
Pursuant to a first embodiment, symbol error rate (SER) is used as the
control parameter. The SER meter 133 (FIG. 1) obtains SER from the Viterbi
decoder 131 by re-encoding the decoded packets and comparing the resulting
symbols with the received symbols. Alternatively, pursuant to a second
embodiment, signal-to-noise ratio (C/N) is used as the control parameter.
The signal-to-noise ratio is measured by the (C, N) meter 129 at the rake
processor 127 output.
As used in FIG. 4, the symbol+means positive sensitivity,--means negative
sensitivity, and x means "don't care". The sensitivity, Sx, is obtained by
perturbing the parameter x and measuring the resulting difference in SER.
Due to signal fluctuation, filtering (e.g. averaging) is performed to
obtain Sx. In effect, the parameter x is dithered around its current
nominal value. The amount of dither (.DELTA.x) is an important value which
is carefully determined in order to optimize the response time of the
controller 135 (FIG. 1). Note that controller 135 response can be improved
if the changes made to x are proportional to the sensitivity Sx.
The open-loop method described in FIG. 5 is useful in some special
circumstances, such as when there is a sudden increase in interference, or
when the receiver has just been turned on in a high interference
environment. The controller response can be improved if the present amount
of intermodulation distortion (the IM value) is estimated, and the
attenuators are preset to suppress exactly this value of IM, before the
recursive optimization begins. This method can be used in conjunction with
the fuzzy controller method described above as a way to quickly estimate
the initial values of .alpha. & .beta. before beginning the optimization
procedure that uses the control rules of FIG. 4. This will speed up the
response time of controller 135 in the aforementioned set of
circumstances. The method of FIG. 5 may be employed without using the
optimization procedure that uses the control rules of FIG. 4, but could
yield less accurate results in such a case.
Referring now to FIG. 5, an illustrative method by which controller 135 may
estimate a value for the parameter Ni is described. The flowchart of FIG.
5 commences at block 401, where the controller 135 (FIG. 1) estimates the
magnitude of Nt from the IF amplifier 125 gain .gamma., .alpha. and .beta.
(attenuation of the attenuators). There is exactly one value of Nt for
each combination of .gamma., .alpha., .beta. (ignoring temperature
variations and component tolerances). This value is known apriori from the
system design and can be stored in a look up table or obtained from a
mathematical expression.
Next, at block 402, the controller 135 obtains the magnitude of C (desired
signal) at the output of the rake receiver 127. Program control continues
to block 403, where the controller 135 estimates the magnitude of Noc. In
a CDMA system, this estimate is based on the current relative power of the
Neighbor Pilots. Note that the current IS-95 interoperability standard
requires CDMA mobiles to continually monitor these values. Noc is
estimated as that fraction of the Total Received Power by taking the ratio
of the Neighbor Pilots Power to the Total received Power. In case the
Neighbor Pilot strength is not available, a constant can be substituted
for the estimated value of Noc.
At block 404, the controller 135 estimates the magnitude of Ns based on the
number of rake fingers used at rake receiver 127, and the relative power
of signal in each rake finger. A value of Ns can be assigned apriori for
each range of values. Next (block 405), the controller estimates Ni=(Total
received power)-C-Nt-Noc-Ns.
Now that the magnitude of the interference component Ni is known,
controller 135 can now select the values of the attenuators which were
preprogrammed into the phone based on the theoretical analysis of Ni
rejection vs. .alpha. & .beta. (block 406).
Although the examples described above in connection with FIG. 1 utilize
adjustable attenuators and a RF signal amplifier with a fixed gain, the
invention also encompasses other structural topologies. For example, the
aforementioned combination of attenuators and RF signal amplifier with
fixed gain is functionally equivalent to a RF signal amplifier with
adjustable gain. Moreover, the use of two attenuators was described for
illustrative purposes, it being understood that the invention may
encompass the use of a greater or lesser number of adjustable attenuators
in the RF signal path, and/or structures which are functionally equivalent
to the use of one or more adjustable attenuators. For example, a third
adjustable attenuator could be employed between the mixer and the IF
amplifier. Alternatively, one of the two described adjustable attenuators
could be eliminated from the receiver design. Although some of the
examples described herein operate in the environment of CDMA wireless
telephony, these techniques are also applicable to radio receivers other
than CDMA.
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