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I claim as my invention:
1. In an acoustic system having an acoustic input transducer and an
acoustic output transducer, a circuit for suppressing oscillations due to
feedback between said acoustic input and output transducers, said circuit
comprising:
means for recognizing the presence of an oscillation due to said feedback
in a signal line between said acoustic input and output transducers, and
generating a signal upon recognition of said oscillation for as long as
said oscillation is present;
oscillatory frequency search means connected to said means for recognizing
for searching for, in the presence of said signal from said means for
recognizing, the frequency of said oscillation, and generating a signal
corresponding to said frequency;
oscillation modifying means connected to said signal line and to said
oscillatory frequency search means for suppressing said oscillation in
response to said signal from said oscillatory frequency search means; and
clamp-on means in said oscillatory frequency search means for continuing to
generate said signal corresponding to the frequency of said oscillation,
even upon the disappearance of said signal from said means for
recognizing, until a new oscillation due to said feedback is recognized by
said means for recognizing.
2. A circuit as claimed in claim 1, wherein said acoustic system has a
final amplifier preceding said acoustic output transducer, and wherein
said means for recognizing is connected between said final amplifier and
said acoustic output transducer.
3. A circuit as claimed in claim 1, wherein said oscillatory frequency
search circuit comprises:
means for generating a plurality of frequency defining signals during the
presence of said signal from said means for recognizing;
means for cycling through a plurality of frequencies supplied to said
oscillation modifying means in response to said frequency-defining
signals; and
wherein said means for generating said frequency-defining signals includes
said clamp-on means, said clamp-on means including means for retaining a
current frequency-defining signal present upon the disappearance of said
signal from said means for recognizing, said clamp-on means including
means for controlling said means for generating said frequency-defining
signals to continue to supply said last frequency-defining signal to said
means for cycling to hold said means for cycling at a frequency range
corresponding to said last frequency-defining signal.
4. A circuit as claimed in claim 3, wherein said oscillatory frequency
search means further includes means connected to said means for generating
said frequency-defining signals for causing said frequency-defining
signals to successively change at a selected rate.
5. A circuit as claimed in claim 4, wherein said means for generating said
frequency-defining signals includes a counter, and wherein said means for
causing said frequency-defining signals to successively change is an
oscillator which generates pulses at said selected rate to increment said
counter, each counter increment causing generation of a different
frequency-defining signal.
6. A circuit as claimed in claim 5, further comprising a AND gate having a
first input connected to said oscillator and a second input to which said
signal from said means for recognizing is supplied, and an output
connected to said counter such that said counter is incremented only in
the presence of said signal from said means for recognizing.
7. A circuit as claimed in claim 3, wherein said means for cycling has a
lowest frequency range with a lowest frequency limit of 1 kHz.
8. A circuit as claimed in claim 3, wherein said means for generating
frequency-defining signals is a means for generating eight
frequency-defining signals, and wherein said means for cycling is a means
for cycling through eight different frequencies respectively corresponding
to said frequency-defining signals.
9. A circuit as claimed in claim 3, wherein said frequency modifying means
includes a discretely variable resistor bank, said resistor bank assuming
a different discrete resistance value for each of said frequency-defining
signals.
10. A circuit as claimed in claim 3, wherein said means for cycling is a
decoder.
11. A circuit as claimed in claim 3, wherein said frequency ranges in
combination comprise a frequency spectrum having opposite ends, and
wherein said means for generating frequency-defining signals includes
means for preventing a skip in said means for cycling from one end of said
frequency spectrum to the other end.
12. A circuit as claimed in claim 11, wherein said means for generating
frequency-defining signals includes a counter, with the frequency-defining
signals corresponding to the count of said counter, and wherein said means
for preventing a skip is a count direction switch which reverses the
counting direction when selected limit counter readings corresponding to
each of said ends of said frequency spectrum are reached.
13. A circuit as claimed in claim 1, wherein said acoustic system includes
a final amplifier preceding said acoustic output transducer, and wherein
said circuit is connected as a feedback element across said final
amplifier.
14. A circuit as claimed in claim 1, wherein said oscillation modifying
means is a bandpass filter.
15. A circuit as claimed in claim 1, wherein said oscillation modifying
means is a C-R high pass filter.
16. A circuit as claimed in claim 3, wherein said means for generating
frequency-defining signals includes a counter, each counter increment
causing a change in said frequency-defining signals, and wherein said
means for recognizing includes means for generating pulses for
incrementing said counter as long as said oscillation is present.
17. In an acoustic system having an acoustic input transducer and an
acoustic output transducer, a circuit for suppressing oscillations due to
feedback between said acoustic input and output transducers, said circuit
comprising:
means for recognizing the presence of an oscillation due to said feedback
in a signal line between said acoustic input and output transducers, and
generating a signal upon the recognition of said oscillation for as long
as the oscillation is present;
oscillatory frequency search means connected to said means for recognizing
for cycling through, in the presence of said signal from said means for
recognizing, a plurality of frequency ranges and generating respective
signals corresponding to each frequency range;
filter means connected to said signal line and to said oscillatory
frequency search means for suppressing said oscillation, said filter means
including a resistor bank having a plurality of discretely selectable
resistance values, said resistance values being respectively selected by
said signals respectively corresponding to said frequency ranges; and
clamp-on means in said oscillatory frequency search means for causing said
oscillatory frequency search means to retain and continue to generate one
of said signals corresponding to a frequency range which successfully
suppresses said oscillation,
said clamp-on means causing said signals corresponding to said frequency
ranges to continue to be generated even upon the disappearance of said
signal from said means for recognizing, until a new oscillation due to
said feedback is recognized by said means for recognizing.
18. A circuit as claimed in claim 1, wherein said filter means is a
bandpass filter.
19. A circuit as claimed in claim 1, wherein said filter means is a C-R
high pass filter.
20. A circuit as claimed in claim 1, wherein said acoustic system includes
a final amplifier connected in said signal line preceding said acoustic
output transducer, and wherein said circuit is connected as a feedback
element across said final amplifier. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to a circuit arrangement for suppressing
oscillations, and in particular to such a circuit arrangement for
suppressing acoustic feedback in a hearing aid.
2. Related Application
The subject matter of the present application is related to the subject
matter of a co-pending application of the same inventor, filed
simultaneously herewith, entitled Circuit Arrangement For Suppressing
Oscillations, Ser. No. 152,390.
3. Description of the Prior Art
The risk of acoustic feedback is present in electronic systems having a
microphone and a speaker in relatively close proximity to each other.
Hearing aids are particularly susceptible to such feedback effects because
the acoustic transducers (microphones and earpieces, or receivers) are
disposed only a slight distance from each other. This results in
disturbing tones such as, for example, a whistling effect, to be
experienced by the wearer.
In hearing aids, efforts have been undertaken to reduce the susceptibility
of the hearing aid to feedback oscillation mainly by constructing the
auditory channel, and by improving the sound-insulating capability of the
plastic used to make the ear mold. Efforts have also been undertaken from
an electrical standpoint, however these have been limited to clipping or
shifting the frequency band, rather than attacking the oscillatory signal
itself. For example, constant attenuation of the output signal is
described in "A Feedback Stabilizing Circuit For Hearing Aids," by D.
Preves in "Hearing Instruments", Vol. 37, No. 4, pages 34, 36-41 and 51.
Other circuits have recently been developed (for example as offered by
RIM-Elektronik of Munich, West Germany, and the circuits described in U.S.
Pat. Nos. 4,232,192 and 4,079,199) which recognize oscillations, and take
steps to suppress the oscillations. Such circuits take the useful signal
between the input transducer and a final amplifier, which precedes the
output transducer, and amplify the signal with an additional amplifier.
The amplified signal is compared to a threshold voltage in a comparator
stage, and is supplied to a phase-locked loop (PLL). The PLL recognizes an
oscillation when it occurs, and forwards a suppress signal to a notch
filter, preceding the final amplifier. The notch filter suppresses the
frequency range of the oscillation, or reduces the gain, as in the case of
the circuit described in U.S. Pat. No. 4,079,199. As is known, however,
when the input signal falls off, a PLL becomes unstable and drifts. The
result of the drift is a periodic, acoustic noise signal.
Another oscillation-suppressing circuit is described in U.S. Pat. No.
4,091,236. In this known circuit, the filter used therein skips to a
prescribed frequency when the oscillation ceases. A risk of drift when the
input signal appears is also present in this circuit, however, because the
circuit generates oscillation recognition signals as soon as input signals
having irregular periods (the normal case) are no longer acquired
SUMMARY OF THE INVENTION
It is an object of the present invention to provide an
oscillation-suppressing circuit which recognizes the presence of an
oscillation in a useful signal, suppresses the oscillation, and remains
stable, i.e., does not begin to drift, when the input signal disappears
The above object is achieved in a circuit arrangement wherein an
oscillation-recognizing circuit identifies the presence of an oscillation
in a useful signal and an oscillatory frequency search circuit controls an
oscillation modifying circuit to suppress the oscillation by means of a
filter. Drift effects are avoided by a clamp-on sub-circuit in the search
circuit, which retains the frequency in the oscillation modifying circuit
of the recognized oscillation, even when the oscillatory signal at the
input of the search circuit disappears.
In accordance with the principles of the present invention, the oscillatory
frequency search circuit takes the place of the PLL in conventional
circuits, and further the oscillatory frequency search circuit includes a
clamp-on sub-circuit, which continues to generate an output signal after
the disappearance of the oscillation. This output signal holds the
oscilltion modifying circuit, for example, a notch filter, in a
permanently set condition. Acoustic noise signals which may arise in the
filter circuit, due to drifting thereof, therefore do not occur.
In one embodiment, the circuit arrangement is connected between the final
amplifier and the output transducer of an acoustic system, which
eliminates the need for the additional amplifier used in certain of the
prior art approaches. This permits the circuit arrangement to be
constructed economically and, as is particularly useful in hearing aids,
in a smaller volume than conventional circuits.
DESCRIPTION OF THE DRAWINGS
FIG. 1 is a schematic block diagram of an acoustic system, such as a
hearing aid, including a circuit arrangement for suppressing oscillations
constructed in accordance with the principles of the present invention.
FIG. 2 is a circuit diagram showing details of the oscillation recognition
circuit in the circuit arrangement constructed in accordance with the
principles of the present invention.
FIG. 3 is a schematic block diagram of an oscillatory frequency search
circuit for the circuit arrangement constructed in accordance with the
principles of the present invention.
FIG. 4 is a circuit diagram of a first embodiment of an oscillation
modifying circuit in a circuit arrangement constructed in accordance with
the principles of the present invention, in the form of a notch filter.
FIG. 5 is a circuit diagram of a further embodiment of the circuit
arrangement constructed in accordance with the principles of the invention
wherein the oscillation modifying circuit is in the form of a high pass
filter.
FIG. 6 shows a circuit diagram of further embodiments of an oscillation
recognition circuit and an oscillatory frequency search circuit connected
thereto, in a circuit arrangement constructed in accordance with the
principles of the present invention.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
An acoustic system, such as a hearing aid, is generally shown in FIG. 1
including a circuit arrangement constructed in accordance with the
principles of the present invention for suppressing oscillations, such as
feedback effects.
The oscillation-suppressing circuit is generally referenced at 4, and is
constructed in the manner of an electrical feedback circuit. The circuit
suppresses electrical signals which are generated as a consequence of
acoustic feedback effects, which usually result in unattenuated
oscillations in the remainder of the circuit. The feedback effect is
schematically indicated in FIG. 1 by the dashed line arrow between the
acoustic output transducer 2 and the microphone 1.
An acoustic useful signal SE, together with the acoustic feedback signal
SR, are converted into an electrical signal SO in the microphone 1. The
output signal S5 of the oscillation-suppressing circuit 4 is subtracted
from this signal SO in a subtraction element 5. The remaining signal S1 is
amplified in a non-inverting final amplifier 3 to form a signal S2. In the
output transducer 2, this signal S2 is converted into an acoustic signal
SA. At the same time, the signal S2 is supplied to the oscillation
suppressing circuit 4 as an input signal.
Analyzed in terms of function, the oscillation-suppressing circuit 4
includes an oscillation recognition circuit 6, an oscillatory frequency
search circuit 7, and an oscillation modifying circuit 8. In the
oscillation-suppressing circuit 4, the signal S2 is conducted to the
oscillation recognition circuit 6, and is also supplied to the modifying
circuit 8. A check is undertaken in the recognition circuit 6 to determine
whether the signal S2 contains an oscillation arising from acoustic
feedback effects. If an oscillation is present, the recognition circuit 6
generates an output signal S3. The signal S3 places the oscillatory
frequency search circuit 7 in operation, causing a sequence of signals S4
to be generated as an output by the serach circuit 7, until the signal S3
at the output of the recognition circuit 6 disappears. The signal S4 at
the output of the search circuit 7 when the signal S3 disappears is
maintained by the search circuit 7 until a new oscillation appears. The
signals S4 control the modifying circuit 8 such that frequency ranges in
the overall frequency spectrum of the signal SO, which are allocated to
the recognized oscillation, are substantially suppressed. As described
above, the signal S5 is the output signal of the oscillation-suppressing
circuit 4.
The details of the oscillation recognition circuit 6 are shown in FIG. 2.
Because oscillations are long-lasting alternating voltages having
relatively large amplitude and relatively high frequency, the recognition
circuit 6 checks the input signal S2 for these characteristics. In a first
stage, the amplitude of the input signal S2 is compared to a first
threshold voltage UT1 in a first comparator 9. If the amplitude of the
signal S2 upwardly exceeds the threshold UT1, a rectangular voltage signal
S21 is generated.
The following stage in the recognition circuit 6 includes an RC element
consisting of an ohmic resistor 10, a diode 10' and a capacitor 11, and
also includes a second comparator 12. The capacitor 11 is rapidly charged
by the signal S21 via the diode 10', and is in turn discharged via the
resistor 10 with a prescribed time constant. This time constant, together
with the threshold voltage UT2 of the second comparator 12, define the
minimum frequency to which the oscillation recognition 6 responds. If a
short time constant is selected, the recognition circuit 6 essentially
responds only to high-frequency signals. Given low-frequency signals, the
capacitor 11 has enough time to discharge below the threshold voltage UT2
of the second comparator 12. These low-frequency signals, therefore, are
not acquired. It is thus assured that the recognition circuit 6 only
reacts to signals which result from acoustic feedback effects, and signal
components appearing periodically with low frequency in the useful signal
(for example a voice signal) do not trigger a response in the recognition
circuit 6.
When the oscillation criteria of "high amplitudes" and "high frequencies"
have been met in the first and second stages of the recognition circuit 6,
output signals S23 are supplied to a third stage of the recognition
circuit 6. The output signals S23 are rectangular voltage signals having a
respective duration equal to the time which the signals S22 exceed the
threshold of the comparator 12. The signals S23 thus reflect the duration
of the large amplitude, high frequency input signal. The third stage of
the recognition circuit 6 includes a diode 13, an RC element consisting of
a resistor 14 and a capacitor 15, and a third comparator 16. The capacitor
15 is charged with the signal S23 via the resistor 14. The resistor 14 and
the capacitor 15 are dimensioned such that the charging time constant is
high, for example, 0.5 through 2 seconds. The capacitor 15 is immediately
discharged via the diode 13 when the output voltage S23 drops even
briefly. If, however, the rectangular signal S23 lasts for a longer time,
the capacitor 15 is charged to such an extent that the voltage upwardly
exceeds the threshold UT3 of the third comparator 16. In this instance,
the input signal S2 meets all of the oscillation recognition criteria, and
the signal S3 is generated by the comparator 16 as an output of the
recognition circuit 6, indicating the presence of an oscillation.
The details of an oscillatory frequency search circuit constructed in
accordance with the principles of the present invention are shown in FIG.
3. The search circuit 7 is connected between the recognition circuit 6 and
the modifying circuit 8, and controls the modifying circuit 8 so that
recognized oscillations are suppressed. A first stage 17 of the search
circuit 7 generates digital, frequency-defining signals S33, and is
controlled by the output signals S3 from the recognition circuit 6. The
main component of the first stage 17 is a counter unit 18 which includes a
counter 19, a counting direction switch 20, and a reset element 21, also
referred to as a "power-on reset." The first stage 17 also includes an
oscillator 22 and an AND gate 23. The counter 19 simultaneously serves as
a clamp-on means for the frequencies of the recognized oscillation, as
described in greater detail below.
When the search circuit 7 is energized, the reset element 21 sets all of
the output signals S32 at all four output lines of the counter 19 to zero
(also referred to as the "low" status). This 0000 status is digitally
incremented by 1 each time a pulse S32 ("high") is registered at the input
of the counter 19. When all four output lines have been switched to "high"
the original zero condition is produced again upon the occurrence of the
next pulse S31, and the incrementation sequence is repeated. A pulse S31,
however, is only generated if an output signal S3 from the recognition
circuit 6 is present at one input of the AND gate 22 preceding the counter
19. If such a signal is present, pulses S31', generated by the oscillator
22, are forwarded as the incrementation pulses S31. The oscillator 22
therefore defines the speed at which the counter 19 is incremented.
The counter 19 increments the output pulses S32 until the output signal S3
from the recognition circuit 6 disappears. (The signal S3 disappears when
the oscillation has been suppressed by the modifying circuit 8, as
described below). When the signal S3 disappears, the counter 19 receives
no further pulses S31, and remains in its current state, until a new
output signal S3 from the recognition circuit 6 appears. The counter 19
thus stores the state or condition which has been set, and together with
the AND gate 23, functions as a clamp-on means for retaining the frequency
of the recognized oscillation at the modifying circuit 8. It is preferable
to include such a clamp-on means in the search circuit 7 to prevent the
oscillation suppression circuit 4 from drifting, and thus avoiding the
reappearance of a previously suppressed oscillation.
The first stage 17 of the search circuit 7 also includes a count direction
switch 20 at the output of the counter 19. The switch 20 has three output
lines, and prevents a discontinuous "skip" from the count 111 to 000 in
the frequency-defining output signals S33. This is accomplished by
decrementing every second sequence from 111 to 000 by inverting the input
signals S32. Avoidance of such a "skip" is preferable so that the filter
in the modifying circuit 8 for suppressing the oscillatory frequency does
not jump from one end of the frequency spectrum to the other given a
reversal of the counting direction, but instead migrates back and forth in
the frequency spectrum.
A second stage in the search circuit 7 samples the frequency-defining
signals 33 from the first stage 17 (received from the switch 20) and
controls the modifying circuit 8 by output signals S4. The second stage 24
includes a decoder 25 which transfers the eight possible signal
combinations via the three incoming lines onto eight different output
lines. These eight signals S4 control the modifying circuit 8 to define
the frequency range in the selectable frequency spectrum which is to be
filtered by the modifying circuit 8.
The decoder 25 thus cycles through each of the frequency ranges, as long as
the frequency-defining signals S23 are continually changing by virtue of
the incrementing count of the counter 19, which increments as long as the
signal S3 is present. When the frequency range containing the unwanted
oscillation is cycled through, and thus that frequency range is
suppressed, as described below, and the oscillation is also suppressed,
the signal S3 disappears and the counter 19 is no longer incremented, so
the decoder 25 no longer cycles, but an output signal for the frequency
range which successfully suppressed the oscillation is retained, as
described above, by the clamp-on means.
The decoder 25 controls the modifying circuit 8 by means of a discretely
variable resistor bank 26, as shown in FIG. 4. Given an existing
oscillation, the signals S4 are conducted via one or more lines of the
resistor unit 26. Each line includes at least one transistor 27, one ohmic
resistor 28, and one inverter 29, the resistors 28 having respectively
different resistance values. If an oscillation is not present (i.e.,
signal S33 is 000), all transistors 27 are in a conducting state (by
inversion of the signals S4 in the inverters 29). Given a signal S33 of
111, by contrast, all of the transistors 27 are in a non-conducting, or
inhibiting, state. The resistance values of the resistors 28 are
preferebly selected so that the modifying circuit 8 selects eight adjacent
frequency ranges between 1 kHz through infinity. It is also preferable
that at least one transistor-resistor combination permits selection of a
frequency range above the acoustic limit of human hearing, so that only
this range is filtered after the apparatus is energized and before an
oscillation appears.
The modifying circuit 8 also includes a further ohmic resistors 30,
capacitors 31, and an amplifier 32, which are connected in the form of a
bandpass filter. Such a filter is known, for example, from the book
"Halbleiter-Schaltungs Technik," (Semiconductor Circuit Technique) by
Teitze and Schenk, 7th Edition (1985) at pages 419.varies.421. Because the
bandpass filter generates negative feedback for the final amplifier 3, the
modifying circuit 8 simulates a notch filter which forms an acceptor
circuit at the resonant frequency. The bandwidth and the gain of the
simulated filter are dependent on the discretely variable resistor unit
26. The resonant frequency can thus be varied by changing the values of
resistance in the resistor unit 26 without influencing the bandwidth or
gain. An output resistor 33 defines the weighting of the feedback signal
S5 at the subtraction element 5 (shown in FIG. 1).
Another embodiment of a modifying circuit 8' is shown in FIG. 5. In this
embodiment, a C-R high-pass filter is used instead of a bandpass filter.
By means of the discretely variable resistor 26, a resistor 24 and a
capacitor 25, this filter simulates a variable capacitor, and enables
smoothing of the acoustic feedback curve, and exhibits a low-pass effect.
The recognition circuit 6 and the search circuit 7 as described above can
be used with the further embodiment of the modifying circuit 8'.
Other embodiments of the modifying circuit 8 not described in detail herein
are also possible. The modifying circuit may alternatively be fashioned,
for example, as a phase shifter, a phase switcher, or a gain reducing
circuit.
The recognition circuit 6 and the search circuit 7 may also be modified.
Modified versions 6' and 7' of those circuits are shown in FIG. 6. In this
embodiment, the third stage (consisting of components 13 through 16 in
FIG. 2) of the recognition circuit 6 is replaced in the recognition
circuit 6' by a counter stage which includes an inverter 36, a digital
counter 37, and an AND gate 38.
In the same manner as described in connection with FIG. 2, the input signal
is examined for the oscillatory characteristics of "high amplitude" and
"high frequencies." An output signal S23, however, in the embodiment of 6'
is digitally processed to determine whether the large amplitude,
high-frequency input signal is long-lasting. The counter 37 compares two
signal inputs. One input is the rectangular voltage signals S21, and the
other input is a reset input which, in combination with the inverter 36,
constantly resets the counter 37 to zero except when a signal S23 appears.
The counter 37 counts the rectangular signals S21 as long as a signal S23
is present. After the occurrence of a selected number of signals S21, the
input signal is recognized as an oscillation. Together with the AND gate
38, the counter 37 generates incrementing pulses S3 in response thereto.
These incrementing pulses can be directly forwarded to the counter 19 of
the search circuit 7'. The search circuit 7' thus does not require an
oscillator, in contrast to the search circuit 7.
Although other modifications and changes may be suggested by those skilled
in the art it is the intention of the inventor to embody within the patent
warranted hereon all changes and modifications as reasonably and properly
come within the scope of his contribution to the art.
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