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Description  |
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FIELD OF THE INVENTION
This invention relates generally to differential microphones and more
specifically to adjusting the frequency response of differential
microphones to provide a desired response.
BACKGROUND OF THE INVENTION
Directional microphones offer advantages over omnidirectional microphones
in noisy environments. Unlike omnidirectional microphones, directional
microphones can discriminate against both solid-borne and air-borne noise
based on the direction from which such noise emanates, defined with
respect to a reference axis of the microphone. Differential microphones,
sometimes referred to as gradient microphones, are a class of directional
microphones which offer the additional advantage of being able to
discriminate between sound which emanates close to the microphone and
sound emanating at a distance. Since sound emanating at a distance is
often classifiable as noise, differential microphones have use in the
reduction of the deleterious effects of both off-axis and distant noise.
Differential microphones are microphones which have an output proportional
to a difference in measured quantities. There are several types of
differential microphones including pressure, velocity and displacement
differential microphones. An exemplary pressure differential microphone
may be formed by taking the difference of the output of two microphone
sensors which measure sound pressure. Similarly, velocity and displacement
differential microphones may be formed by taking the difference of the
output of two microphone sensors which measure particle velocity and
diaphragm displacement, respectively. Differential microphones may also be
of the cardioid type, having characteristics of both velocity and pressure
differential microphones.
As a general matter, differential microphones exhibit a frequency response
which is a function of the distance between the microphone and the source
of sound to be detected (e.g., speech). For example, when a pressure
differential microphone is located in the near field of a speech source
(that area of the sound field exhibiting a large spatial gradient and a
large phase shift between acoustic pressure and particle velocity, e.g.,
less than 2 cm. from the source), its frequency response is essentially
flat over some specified frequency range. At somewhat greater distances
from the speech source, the frequency response tends to over-emphasize
high frequencies. When a velocity differential microphone is in the near
field of a speech source, its frequency response tends to over-emphasize
low frequencies, while at somewhat greater distances, its response is
essentially flat for some specified frequency range.
Because their frequency response varies with distance, differential
microphones are ideally suited for use at a constant distance from a
source, for example, at a distance where microphone response is flat. In
practice, however, users of pressure differential microphones often vary
the distance between microphone and mouth over time, causing the
microphone to exhibit an undesirable, variable gain to certain frequencies
present in speech. For a pressure differential microphone, unless a close
constant distance is maintained, high frequencies present in speech will
be emphasized. For a velocity differential microphone, unless somewhat
greater distances are maintained, lower frequencies will be emphasized.
SUMMARY OF THE INVENTION
A method and apparatus are disclosed for providing a desired frequency
response of a differential microphone of order n. A desired response is
provided by operation of a controller in combination with an adjustable
filter. The controller determines a filter frequency response needed to
provide any desired response. For example, the controller may determine a
filter frequency response which equals or approximates the inverse of the
microphone response to provide an overall flat response. Alternatively, an
exemplary response could be provided which is optimal for telephony. The
determination by the controller can include a complete definition of the
filter response (including absolute output level) or a definition of just
those parameters used in modifying one or more aspects of a given or
quiescent response. The filter is adjusted by the controller to exhibit
the determined frequency response thereby providing a desired response for
the microphone.
In an illustrative embodiment of the present invention for a pressure
differential microphone, the controller makes an automatic determination
of distance between microphone and sound source (this distance being
referred to as the "operating distance") and adjusts a low-pass filter to
compensate for the gain to high frequencies exhibited by the microphone at
or about the determined distance. The operating distance may be determined
one or more times (e.g., periodically) during microphone use. Automatic
distance determination may be accomplished by comparing observed
microphone output at an unknown operating distance to known outputs at
known distances.
In the illustrative embodiment, the frequency response of the low-pass
filter is dependent upon the frequency response of the pressure
differential microphone as a function of operating distance and microphone
order. Pressure differential microphones have a frequency response which
is flat at close operating distances and at large operating distances
increases at a rate of 6n dB per doubling of frequency (i.e, per octave),
where n is an integer equal to the order of the pressure differential
microphone. For a given determined distance, the filter frequency response
is adjusted, and this may include an adjustment to absolute output level.
In the case of the illustrative embodiment for use with a first or second
order pressure differential microphone, the filter is a first or second
order Butterworth low-pass filter, respectively, with a half-power
frequency adjustable to the microphone's 3 dB gain frequency, which is a
function of operating distance.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 presents an exemplary block diagram embodiment of the present
invention.
FIG. 2 presents a relative frequency response plot of first through fifth
order pressure differential microphones as a function of kr, where k is
the acoustic wave number and r is the operating distance to a source.
FIG. 3 presents a schematic view of a first order pressure differential
microphone in relation to a point source of sound.
FIG. 4 presents a relative frequency response plot for a first order
pressure differential microphone as a function of kr.
FIG. 5 presents a schematic view of a second order pressure differential
microphone in relation to a point source of sound.
FIG. 6 presents a relative frequency response plot for a second order
pressure differential microphone as a function of kr.
FIG. 7 presents a schematic view of a first order pressure differential
microphone in relation to an on-axis point source of sound.
FIG. 8 presents sound pressure level ratio plots for two zeroth order
pressure differential microphones which form a first order pressure
differential microphone.
FIG. 9 presents a schematic view of a second order pressure differential
microphone in relation to an on-axis point source of sound.
FIG. 10 presents sound pressure level ratio plots for two first order
pressure differential microphones which form a second order pressure
differential microphone.
FIG. 11 presents a detailed exemplary block diagram embodiment of the
present invention.
DETAILED DESCRIPTION
Introduction
FIG. 1 presents an illustrative embodiment of the present invention. In
FIG. 1, a differential microphone 1 of order n provides an output 3 to a
filter 5. Filter 5 is adjustable (i.e., selectable or tunable) during
microphone use. A controller 6 is provided to adjust the filter frequency
response. The controller 6 can be operated via a control input 9.
In operation, the controller 6 receives from the differential microphone 1
output 4 which is used to determine the operating distance between the
differential microphone 1 and the source of sound, S. Operating distance
may be determined once (e.g., as an initialization procedure) or multiple
times (e.g., periodically). Based on the determined distance, the
controller 6 provides control signals 7 to the filter 5 to adjust the
filter to the desired filter frequency response. The output 3 of the
differential microphone 1 is filtered and provided to subsequent stages as
filter output 8.
Frequency Response of Pressure Differential Microphones
One illustrative embodiment of the present invention involves pressure
differential microphones. In general, the frequency response of a pressure
differential microphone of order n ("PDM(n)") is given in terms of the nth
derivative of acoustic pressure, p=P.sub.o e.sup.-jkr /r, within a sound
field of a point source, with respect to operating distance, where P.sub.o
is source peak amplitude, k is the acoustic wave number (k=2.pi./.lambda.,
where .lambda. is wavelength and .lambda.=c/f, where c is the speed of
sound and f is frequency in Hz), and r is the operating distance. That is,
##EQU1##
FIG. 2 presents a plot of the magnitude of Eq. 1 for n=1 to 5. The figure
shows the gain exhibited by a PDM(n), n=1 to 5, at high frequencies and
large distances, i.e., at increasing values of kr.
For purposes of this discussion, it is instructive to examine the frequence
response of a PDM as a function of kr. Therefore, two illustrative
developments are provided below. The developments address the frequency
response of both first and second order PDMs as functions of kr, and are
made in terms of a finite difference approximation for d.sup.n P/dr.sup.n.
In light of Eq. 1 and the developments which follow, it will be apparent
to the ordinary artisan that the analysis can be extended in a
straight-forward fashion to any order PDM. Also, because the response of
velocity and displacement microphones is related to that of a pressure
differential microphone by factors of 1/j.omega. and 1/(j.omega.).sup.2,
respectively, the ordinary artisan will recognize that Eq. 1 and the
developments which follow are adaptable to systems employing velocity and
displacement differential microphones, as well as cardioid microphones.
First Order Pressure Differential Microphones
A schematic representation of a first order PDM in relation to a source of
sound is shown in FIG. 3. The microphone 10 typically includes two sensing
features: a first sensing feature 11 which responds to incident acoustic
pressure from a source 20 by producing a positive response (typically, a
positively tending voltage), and a second sensing feature 12 which
responds to incident acoustic pressure by producing a negative response
(typically, a negatively tending voltage). These first and second sensing
features 11 and 12 may be, for example, two pressure (or "zeroth" order)
microphones. The sensing features are separated by an effective acoustic
distance 2d, such that each sensing feature is located a distance d from
the effective acoustic center 13 of the microphone 10. A point source 20
is shown to be at an operating distance r from the effective acoustic
center 13 of the microphone 10, with the first and second sensing features
located at distances r.sub.1 and r.sub.2, respectively, from the source
20. An angle .theta. exists between the direction of sound propagation
from the source 20 and the microphone axis 30.
For a spherical wave generated by source 20 at operating distance r from
the center 13 of the microphone 10, the acoustic pressure incident on the
first sensing feature 11 is given by:
##EQU2##
The acoustic pressure incident on the second sensing feature 12 is given
by:
##EQU3##
The distances r.sub.1 and r.sub.2 are given by the following expressions:
##EQU4##
If r>>d (when the microphone is in the far field of source 20) or
.theta..apprxeq.0.degree. (when source 20 is located near microphone axis
30), then
r.sub.1 .apprxeq.r-d cos .theta. (4a)
and
r.sub.2 .apprxeq.r+d cos .theta.. (4b)
The response of the microphone can then be approximated by a first-order
difference of acoustic pressure, .DELTA.p, and is given by:
##EQU5##
The magnitude of .DELTA.p, .vertline..DELTA.p.vertline.,is:
##EQU6##
For kd<<1,
sin (kd cos .theta.).apprxeq.kd cos .theta., (7)
and
cos (kd cos .theta.).apprxeq.1. (8)
Therefore,
##EQU7##
and
##EQU8##
For a near-field source, i.e., kr<<1,
##EQU9##
and for a far-field source, i.e., kr>>1 and r>>d,
##EQU10##
Note that Eq. 11 contains no frequency dependent terms. That is, Eq. 11 is
independent of the wave number, k (wave number is proportional to
frequency, i.e., k=2 .pi./c f, where f is frequency in Hz and c is the
speed of sound). As such, a first order PDM in the near field of a point
source 20 has a frequency response which is substantially flat. On the
other hand, Eq. 12 does depend on the acoustic wave number, k. FIG. 4
shows the frequency dependence of the first order PDM for values of kr
from 0.1 to 10. For values of kr<0.2 the response is substantially uniform
or flat. Above kr=1.0 the response rises at 6 dB per doubling kr. (For
this figure, kd<<1 and r>>d.)
Second Order Pressure Differential Microphones
A second order PDM is formed by combining two first order PDMs in
opposition. Each first order PDM can have a spacing of 2d.sub.1 and an
acoustic center 65,67. The PDMs can be arranged in line and spaced a
distance 2d.sub.2 apart as shown in FIG. 5. The response of the second
order PDM can be approximated by a second order difference of acoustic
pressure, .DELTA..sup.2 p, in a sound field of a spherical radiating
source 70 at operating distance r from the acoustic center 60 of the
microphone 35:
.DELTA..sup.2 p=p.sub.1 -p.sub.2 -p.sub.3 +p.sub.4 (13)
where
##EQU11##
and r.sub.i, for i=1 to 4 are:
##EQU12##
and
##EQU13##
Ifr>>d.sub.3 and r>>d.sub.4 or .theta..apprxeq.0.degree., then:
r.sub.1 .apprxeq.r-d.sub.4 cos .theta.; (19)
r.sub.2 .apprxeq.r-d.sub.3 cos .theta.; (20)
r.sub.3 .apprxeq.r+d.sub.3 cos .theta.; (21)
and
r.sub.4 .apprxeq.r+d.sub.4 cos .theta.. (22)
Therefore,
##EQU14##
For kd.sub.4 <<1,
##EQU15##
and
sin (kd.sub.4 cos .theta.).apprxeq.kd.sub.4 cos .theta.. (25)
Equations similar to Eqs. 24 and 25 can be written for cos(kd.sub.3 cos
.theta.) and sin(kd.sub.3 cos .theta.) when kd.sub.3 <<1. For kd.sub.4 <<1
and kd.sub.3 <<1 then:
##EQU16##
and
##EQU17##
For a near-field source (kr<<1),
##EQU18##
and for a far-field source (kr>>1; r>>d.sub.3 ; r>>d.sub.4),
##EQU19##
As is the case with Eq. 11, Eq. 28 contains no frequency dependent terms.
Thus, a second order PDM 35 in the near field of a point source 70 has a
frequency response which is flat. Like Eq. 12, Eq. 29 does depend on
frequency. However, Eq. 29 exhibits a rise in response at high frequencies
at twice the rate of that exhibited by Eq. 12.
FIG. 6 shows the relative frequency response of a second order PDM versus
kr. For kr<1, the response is substantially flat. Above kr=1, the response
rises at 12 dB per doubling of kr. (For this Figure, kd.sub.3 <<1 and
kd.sub.4 <<1 and r>>d.sub.3 and r>>d.sub.4, for a far field source, or
.theta..apprxeq.0.degree..)
Automatic Distance Determination
The illustrative embodiment of the present invention includes an automatic
determination of operating distances by the controller 6. This embodiment
facilitates determining operating distance continuously or at periodic or
aperiodic points in time.
For a first order PDM, the controller 6 can use ratios of output levels
from two zeroth order PDMs (of the first order PDM) to estimate the
operating distance between source and microphone. This approach involves
making a predetermined association between ratios of zeroth order PDM
output levels and operating distances at which such ratios are found to
occur. At any time during microphone operation, a ratio of zeroth order
PDM output levels can be compared to the predetermined ratios at known
distances to determine the then current operating distance.
Consider the first order PDM 75 which comprises zeroth order PDMs A 11 and
B 12 shown in FIG. 3. The response of zeroth order PDMs A 11 and B 12 can
be written (from Eqs. 2a and 2b) as
##EQU20##
and
##EQU21##
Using Eqs. 4a,b, Eqs. 30 and 31 can be rewritten as follows:
##EQU22##
and
##EQU23##
The magnitude of the response of the microphones A 11 and B 12 (for
r>d.vertline.cos.theta..vertline.) is therefore:
##EQU24##
and
##EQU25##
For an illustrative configuration of FIG. 7, .theta.=0 and the ratio of
Eqs. 34 and 35 is:
##EQU26##
Ratio A.sub.r is a function of operating distance r (between source 73 and
microphone acoustic center 78) and d, a physical parameter of the PDM
design. For a given first order PDM, the parameter d is fixed such that
A.sub.r varies with r only.
A plot of A.sub.r (Eq. 36) for two exemplary first order PDM array
configurations (d=1 cm and d=2 cm) is shown in FIG. 8. The figure shows
that changes in A.sub.r are sizeable for a range of r. With knowledge of
this data, operating distances for measured A.sub.r values may be
determined.
In determining operating distance, the controller of the illustrative
embodiment makes a determination of the ratio of observed microphone
output levels. This ratio represents an observed value for A.sub.r :Ar. By
rewriting Eq. 36, an estimate for r as a function of the observed ratio
A.sub.r is:
##EQU27##
Eq. 37 could be implemented by the controller 6 of the illustrative
embodiment in either analog or digital form, or in a form which is a
combination of both. For example, the controller 6 may use a
microprocessor to determine r either by scanning a look-up table
(containing precomputed values of r as a function of A.sub.r), or by
calculating r directly in a manner specified by Eq. 37, to provide control
for analog or digital filter 5. Distance determination by the controller 6
can be performed once or, if desired, continually during operation of the
PDM.
For a second order PDM, the controller 6 can use ratios in output levels
between two first order PDMs (of the second order PDM) to estimate the
operating distance between source and microphone. If a predetermined
association is made between ratios of first order PDM output levels and
operating distances at which such ratios are found to occur, an observed
ratio of first order PDM output levels can be compared to the
predetermined ratios at known distances to determine the then current
operating distance.
Consider the second order PDM which comprises first order PDMs A and B
shown in FIG. 9 for .theta.=0. The response of first order PDMs A 80 and B
90 can be written (from Eq. 10) as
##EQU28##
and
##EQU29##
respectively, for kd.sub.1 <<1, and where r.sub.A and r.sub.B are
operating distances from source 100 to the acoustic centers, 81 and 91, of
PDMs A and B, respectively. If the signal from each of the microphones A
and B is low-pass filtered by the controller 6, then kr.sub.A <<1 and
kr.sub.B <<1, and:
##EQU30##
and
##EQU31##
Since,
r.sub.A =r-d.sub.2 (42)
and
r.sub.B r.sub.2, (43)
then
##EQU32##
and
##EQU33##
where r is the operating distance from source 100 to the acoustic center
95 of the second order PDM.
The ratio of Eq. 44 to Eq. 45 is:
##EQU34##
Ratio A.sub.r is a function of operating distance r and other physical
parameters of the PDM design. For a given second order PDM the parameters
d.sub.1 and d.sub.2 are fixed such that A.sub.r varies with r only.
A plot of A.sub.r (Eq. 46) for two exemplary second order PDM array
configurations (d.sub.2 =0.5 cm, d.sub.2 =1.0 cm, and d.sub.1 =0.5 cm) is
shown in FIG. 10. The figure shows that changes in A.sub.r are quite
sizeable for the range of r. With knowledge of this data, operating
distances may be determined.
In determining an operating distance, the controller 6 of the illustrative
embodiment makes a determination of the ratio of observed microphone
output levels (after low pass filtering). This ratio represents an
observed value for A.sub.r :A.sub.r. By rewriting Eq. 46, an estimate for
r as a function of the observed ratio A.sub.r is:
##EQU35##
As with the case above, Eq. 47 could be implemented by the controller 6 of
the illustrative embodiment in either in analog or digital form, or in a
form which is a combination of both. Again, distance determination by the
controller 6 can be performed once or, if desired, continually during the
operation of the PDM.
Regardless of which order PDM an embodiment uses, it is preferred that the
controller 6 determine operating distance only when the source of sound to
be detected is active. Limiting the conditions under which calibration may
be performed can be accomplished by calibrating only when the PDM output
signal equals or exceeds a predetermined threshold. This threshold level
should be greater than the PDM output resulting from the level of expected
background noise.
The low-pass filtering performed by the controller 6 on the outputs of each
microphone insures that, as a general matter, only those frequencies for
which the microphone's response is flat are considered for the
determination of distance. This has been expressed as kr<<1 in the
developments above. The cutoff frequency for this filter can be determined
in practice by, for example, determining an outer bound operating distance
and then solving for the frequency below which the microphone response is
flat. Thus, with reference to FIG. 2, the frequency response of various
microphones is flat for kr less than 0.5, approximately. Given an outer
bound distance, r.sub.OB, the cutoff frequency should be less than 0.5c/2
.pi.r.sub.OB (Hz.).
Filter Selection
Once distance determination by the controller 6 is performed, a filter 5 is
selected. As discussed above, the filter 5 provides a frequency response
which provides the desired frequency response of the PDM(n). So, for
example, the combination of the microphone and a selected filter 5 may
exhibit a frequency response which is substantially uniform (or flat).
In the illustrative embodiment for pressure differential microphones,
filter 5 exhibits a low-pass characteristic which equals or approximates
the inverse (i.e., mirror image) of PDM(n) frequency response. Such a
filter characteristic may be provided by any of the known low-pass filter
types. Butterworth low-pass filters are preferred for first and second
order PDMs since the frequency response of a first or second order PDM
exhibits a Butterworth-like high-pass characteristic.
In selecting a filter, the half-power frequency and roll-off rate of the
pass band should be determined. In the illustrative embodiment, the
half-power frequency, f.sub.np, of filter 5 should match the 3 dB gain
point of the frequency characteristic of the PDM(n). Half-power frequency
can be determined directly from the equation for the frequency response of
the PDM(n), .vertline..DELTA.np.vertline., with knowledge of r from the
distance determination procedures described above. For example, the 3 dB
frequency of a first order PDM is determined with reference to Eq. 10 by
solving for the value of frequency for which:
##EQU36##
(all parameters on the right hand side of Eq. 10 other than
.sqroot.1+k.sup.2 r.sup.2 for a given microphone configuration and
therefore contain no frequency dependence). Since k=2 .pi./c f, an
expression for the half-power frequency of the filter 5 (3 dB frequency),
f.sub.hp, as a function of distance is:
##EQU37##
where c is the speed of sound and r is the determined distance.
For a second order PDM, the 3 dB frequency is determined with reference to
Eq. 27 by solving for the value of frequency for which:
##EQU38##
Since k=2 .pi./c f, an expression for the half-power frequency of the
filter 5, f.sub.hp, as a function of distance is:
##EQU39##
where c is the speed of sound and r is the determined distance.
Regarding low-pass filter 5 roll-off, a rate should be chosen which closely
matches (in magnitude) the rate at which the PDM high frequency gain
increases. In the illustrative case of low-pass Butterworth filters for
use with first and second order PDMs, this is accomplished by choosing a
filter of order equal to that of the microphone (i.e., a first order
filter for a first order PDM; a second order filter for second order PDM).
Roll-off rate may be fixed for filter 5, or it may be selectable by
controller 6.
In light of the above discussion, it will be apparent to one of ordinary
skill in the art that either analog or digital circuitry could be utilized
to implement the filter 5. Of course, if a digital filter is employed,
additional analog-to-digital and digital-to-analog converter circuitry may
be needed to process the microphone output 3. Moreover, control of an
adjustable filter 5 by the controller 6 can be achieved by any of several
well-known techniques such as the passing of filter constants from the
controller 6 to a finite impulse response or infinite impulse response
digital filter, or by the communication of signals from the controller 6
to drive voltage-controlled devices which adjust the values analog filter
components. Also, the division of tasks between the controller 6 and the
filter 5 described above is, of course, exemplary. Such division could be
modified, e.g., to require the controller 6 to determine distance, r, and
pass such information to the filter 5 to determine the requisite frequency
response.
Like relative frequency response, the absolute output level of a
differential microphone varies with operating distance r, as can be seen
in general from the magnitude of Eq. 1, and in particular, for first and
second order PDMs, from Eqs. 10 and 27, respectively. Since an estimate of
operating distance is already obtained by an embodiment of the present
invention for the purpose of adjusting the filter's relative frequency
response, this information can be employed for the purpose of determining
a gain to compensate for absolute output level variations.
The gain can be derived for any differential microphone of given order. For
the illustrative embodiments previously discussed, the first and second
order gain adjustment is determined as the inverse of the
frequency-invariant portion of Eqs. 10 and 27, respectively. For example,
if the source is located on-axis, then .theta.=0 and cos .theta.=1. In
this case, Eq. 10 shows that for the first order PDM, the gain would be
set proportional to
G.sub.1 =r.sup.2 -d.sup.2. (52)
An estimate of G.sub.1, G.sub.1, can be obtained by using the estimate r
previously obtained from Eq. 37, and d, a fixed design parameter.
Likewise, for the second order PDM, Eq. 27 implies an on-axis gain
proportional to
G.sub.2 =(r.sup.2 -d.sub.4.sup.2)(r.sup.2 -d.sub.3.sup.2)/r,(53)
where an estimate of G.sub.2, G.sub.2, can be obtained using an operating
distance estimate r obtained from Eq. 47, and where d.sub.3 and d.sub.4
are fixed design parameters.
The embodiment of the present invention presented in FIG. 1 is redrawn in
FIG. 11 showing additional illustrative detail for the case of a pressure
differential microphone. Microphone 1 is a PDM and is shown comprising two
individual microphones, 1a and 1b, which can be, e.g., two zeroth or first
order PDMs. The outputs of PDMs are subtracted at node 1c and this
difference 3 is provided to filter 5. Individual outputs 4 of the PDMs are
provided to controller 6 where they are processed as follows.
Each output 4 is low-pass filtered as indicated above by low-pass filters
6a. Note this filtering implements the conditions under which Eqs. 40 and
41 were derived from Eqs. 38 and 39; this filtering is not required in the
case of a first order PDM, as Eq. 36 contains no frequency components.
Next, each output has its root mean square (rms) value determined by rms
detector 6b. The rms values represent the magnitude of the response of
each microphone, as used in Eqs. 36 and 46. The ratio of the magnitudes as
specified by Eqs. 36 and 46 is determined by an analog divider circuit 6c
(a ratio may also be obtained by taking the difference of the log of such
magnitudes). The output from device 6c, i.e., the observed ratio of
magnitudes, A.sub.r, is provided to parameter computation 6e.
Parameter computation 6e determines control signals 7 useful to adjust the
frequency response of filter 5 based on A.sub.r in a manner according to
Eqs. 37 and 49 or 47 and 51. Gain adjustment may be used in conjunction
with the relative frequency response adjustment to provide additional
compensation for the effects of varying operating distance as detailed in
Eqs. 52 or 53. In the illustrative embodiment, the parameter computation
6e comprises analog comparators and one or more look-up tables which
provide appropriate control signals 7 to one or more operational
transconductance amplifiers in filter 5 to adjust its frequency response
based on the value of A.sub.r.
Parameter computation 6e also receives as input an inhibit (INH) signal
from threshold computation 6d which when true indicates that the output
level of the PDM does not meet or exceed a threshold level of expected
background noise. Thus, when INH is true, no new control signals 7 are
passed to filter 5.
Parameter computation 6e further receives manual control signals 9 from a
user which specify automatic one-shot (i.e., aperiodic) distance
determinations, periodic determinations, or continuous determinations. To
provide for periodic determinations, the parameter computation 6e includes
a time base with a period which can be set with manual control signals 9.
The time base signal then controls a sample and hold function which
provides values of A.sub.r to the analog comparators. Periodic distance
determination by the controller 6 should be at a frequency such that the
low-pass filter 5 frequency response accurately follows changes in
microphone response due to movement.
In FIG. 11, filter 5 is presented as comprising a relative response filter
5a and an amplifier 5b under the control of parameter computation 6e.
Signal 7a controls the relative response filter 5a. Parameter computation
6e provides control signal 7b to control the gain of amplifier 5b. The
combination of filter 5a and amplifier 5b provides the overall frequency
response of the filter 5.
It will be apparent to the ordinary artisan that PDM 1 can comprise several
configurations in the context of an illustrative embodiment. For example,
in addition to those already discussed, the PDM 1 may comprise a first
order PDM and a second order PDM. In this case, constituent first order
PDMs of the second order PDM can serve to supply outputs to the controller
6 for the purpose of distance determination and filter adjustment, while
the first order PDM is coupled to filter 5. If PDM 1 comprises a second
order PDM, itself comprising two first order PDMs, then both first order
PDMs can supply output for distance determination by the controller 6,
with only one supplying output filter 5. Naturally, in either case, filter
5 provides a desired response for a first order microphone, even though
distance was determined with output from a second order microphone.
Other configurations are also possible. For example, if the PDM 1 comprises
a first order PDM and a second order PDM, the output of the second order
PDM may be provided for filtering while the outputs from constituent
zeroth order PDMs of th | | |
