 |
Description  |
|
|
FIELD OF THE INVENTION
The present invention relates to audio mixing systems, and more
particularly, to electronic systems for controlling audio sound
reinforcement systems employing multiple microphones, as might be found in
conference rooms, churches, auditoriums, and the like.
BACKGROUND OF THE INVENTION
Consider a conference room in which a number of talkers, each with a
separate microphone, are to speak. If all of the microphones are allowed
to be active at the same time, problems associated with feedback and
extraneous noise pickup arise. Each active microphone that is not actually
being used picks up the amplified sounds from the microphone that is being
used by the current talker. As a result, the amount of amplification
available to the talker's microphone must be reduced to prevent feedback.
In addition, each active microphone acts as a noise source that further
reduces the quality of the audio from the microphone that is actually
being used by the current talker. Finally, destructive interference from
reinforced sound recirculated through the sound system from multiple open
microphones (commonly known as "comb filtering") can cause serious
aberrations in the system frequency response.
To avoid these problems, a number of prior art systems have been devised to
activate only those microphones in which there exists some desired signal.
One class of prior art system uses the sound level at each microphone to
determine whether that microphone should be on or off. Some of the systems
(e.g. Scrader, U.S. Pat. No. 4,090,032, Peters, U.S. Pat. No. 4,149,032,
and Ponto and Martin, U.S. Pat. No. 4,374,300) compare the instantaneous
signal level at any microphone to a reference. If the microphone level
exceeds the reference level, the microphone is assumed to have a desired
signal and is turned on. Systems of this type typically modulate the
reference in some manner that is proportional to the current active signal
level to prevent other microphones from coming on as a result of pickup of
sound from the system loudspeakers. Often, systems of this type change the
attenuation level of the microphone channel from the off state to the on
state in an instantaneous manner, which can give rise to audible switching
transients not harmonically related to the audio signal. In addition, a
single initial value of the reference threshold may not accurately reflect
the changes in ambient noise in an acoustic space under varying conditions
of use.
Other types of systems (e.g. Anderson, Bevan, Schulein, and Smith, U.S.
Pat. No. 4,489,442 and Dugan, U.S. Pat. No. 3,814,856) develop a reference
level based on a sensing microphone of some type. In the case of Anderson
et al., two directional microphones are placed back-to-back in a common
housing. One of the microphones is the system microphone, while the other
is the sensing microphone. The system microphone is oriented so as to
preferentially pick up the desired sound, while the sensing microphone is
oriented to pick up the background sounds. The signal at the system
microphone must exceed the level at the sensing microphone by 9.54 dB to
activate the system microphone. While this system solves the reference
threshold problem, there are still drawbacks. The system again switches
from the attenuated level to the unattenuated level instantaneously which
leads to the difficulties discussed above. In addition, the system is
restricted to the use of only specially manufactured microphones,
eliminating the choice of other microphones whose characteristics might be
better suited to the particular application.
The Dugan system, in contrast, uses a single sensing microphone situated in
such a way so as to receive a signal that is representative of the ambient
noise in the room. The effective threshold for other microphones is
proportional to the instantaneous signal value at the sensing microphone.
Also, rather than changing channel gain in an instantaneous manner, the
shift from fully attenuated to fully on happens over a 10 dB range above
threshold. This is accomplished via 2:1 expansion, i.e. for every 1 dB
that the microphone signal exceeds the threshold, channel gain increases 1
dB up to a total of 10 dB gain change, at which time the channel reaches
unity gain. Difficulties in the use of this system arise in finding an
appropriate place for the sensing microphone that accurately reflects the
ambient noise in the entire space. In addition, a localized increase in
the ambient noise near the sensing microphone can prevent activation of
microphones which have desired signals.
In another system (Dugan, U.S. Pat. No. 3,992,584), a comparison is made of
the level at each microphone preamp to the level of the overall mixed
signal. Each channel is attenuated by an amount that depends on the
difference between the two levels. For instance, if one microphone were
active, the level of that microphone and the level of the overall mix
would be equal (i.e. a difference of 0 dB), so that the channel would not
be attenuated. All other channels would be very much attenuated because of
the large difference between the mix level and the level of an inactive
microphone. If two microphones are active at the same level, the mix level
(assuming no correlation between the two inputs) will be 3 dB higher than
either active input. Thus, both microphones would be attenuated by 3 dB
(and again inactive microphones would be greatly attenuated as before).
The drawback to the Dugan scheme is that extraneous noise (whether
recirculated signal from the sound system or other noise) at "inactive"
microphones will compete with the active microphone for system gain. In
this way, the "active" signal is amplitude modulated by the extraneous
noise.
Broadly, it is the object of the present invention to provide an improved
audio mixing system.
It is a further object of the present invention to provide a mixing system
that does not instantaneously switch a microphone from the attenuated
level to the unattenuated level in response to level changes on the
microphone.
It is a still further object of the present invention to provide a mixing
system that is not limited to one type of microphone.
It is yet another object of the present invention to provide a mixing
system that does not depend on separate sensing microphones to determine
the background noise level.
It is a still further object of the present invention to provide a mixing
system in which the active signal is not amplitude modulated by extraneous
noise inputted through inactive microphones.
These and other objects of the present invention will become apparent to
those skilled in the art from the following detailed description of the
invention and the accompanying drawings.
SUMMARY OF THE INVENTION
The present invention is an audio mixing system for combining a plurality
of input signals to generate a mixed signal. The mixing system includes a
plurality of input channels. Each input channel includes an input circuit
receiving an input signal, and a variable attenuator for generating an
attenuated signal from the input signal. The output signal is obtained by
combining the attenuated signals. The level of attenuation applied to each
channel is determined by the average values of the input signals and the
attenuated signals over a first predetermined time interval. In one
embodiment of the present invention, the attenuation levels are set by
generating a channel signal corresponding to each input channel, the
channel signal depending on the input signal received by the channel and
the attenuated signal generated by said input channel. The ratio of the
channel signal for a given channel to the sum of the channel signals for
all channels is used to set the attenuation for the channel in question in
this embodiment.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a block diagram of a two channel audio mixing circuit according
to the present invention.
FIG. 2 is a block diagram of the preferred embodiment of an attenuator
controller according to the present invention.
FIG. 3 is a block diagram of one embodiment of a low-pass filter according
to the present invention.
DETAILED DESCRIPTION OF THE INVENTION
Refer now to FIG. 1 which is a block diagram of a two channel audio mixing
circuit 10 according to the present invention. The first channel includes
a preamp 11 and attenuator 13 for amplifying the output of a first
microphone 12. The second channel includes a preamp 15 and attenuator 17
for amplifying the output of a second microphone 14. The outputs of
attenuators 13 and 17 are input to a mixer 22 which feeds output amplifier
24. Mixer 22 adds the outputs of attenuators 13 and 17 in a fixed ratio.
The amount of attenuation applied by attenuators 13 and 17 is determined
by controller 20 which senses the output of preamps 11 and 15 as well as
attenuators 13 and 17. Denote the average output of preamp 11 by P.sub.1
and the average output of preamp 15 by P.sub.2. The manner in which the
"average" output of each preamp is generated will be discussed in more
detail below.
In prior art systems such as that taught by the Dugan '584 patent, the gain
of attenuator 13 would be set proportionally to log.sub.10 [P.sub.1
/(P.sub.1 +P.sub.2)]. As noted above, if microphone 12 is active and
microphone 14 inactive, noise on microphone 14 results in modulation of
the output of the channel connected to microphone 12, since the gain of
attenuator 13 decreases if P.sub.2 increases due to any sound source,
including noise. For example, consider the case in which a noise signal on
the second channel is 50% of the signal on the first channel. The quantity
[P.sub.1 /(P.sub.1 +P.sub.2)] can change by approximately 40% in this
case. The exact amount depends on the correlation between the signals on
the two channels. This change is sufficient to generate a modulation in
the gain that is easily detected by a human listener.
The present invention substantially reduces the modulation problem, and
provides other useful features. In the preferred embodiment of the present
invention, each channel's gain is determined by the ratio of a channel
signal associated with the channel and the sum of all of the channel
signals. Unlike the prior art system discussed above, the channel signal
depends on whether or not the channel is currently active. In the present
invention, the channel signal for an active channel is substantially
greater than that for an inactive channel having the same microphone input
signal. In the preferred embodiment of the present invention, the channel
signal is a mixture of the preamplified microphone signal and the
post-attenuator microphone signal. Denote the average post-attenuator 13
signal by A.sub.1 and the average post-attenuator 17 signal by A.sub.2. In
the preferred embodiment of the present invention, controller 20 sets the
level of attenuator 13 to L.sub.1 where
##EQU1##
and the level of attenuator 17 to L.sub.2 where
##EQU2##
where x.sub.1 and x.sub.2 may have values from 0 to 1 inclusive. For the
moment, assume that x.sub.1 =x.sub.2 =x. Consider the case in which the
channel servicing microphone 12 is on and the other channel is inactive.
In this case, the gain of attenuator 13 is nearly unity and that of
attenuator 17 is approximately zero. As a result,
P.sub.1 =A.sub.1
independent of the value of x,
##EQU3##
As a result, an inactive channel would have to be 20.sub.log10 (1-x) dB
higher in level than the active channel to gain equal access to the system
(or substantially modulate the amplitude of the active microphone). This
is an improvement of 20.sub.log10 (1-x) dB in modulation rejection
relative to the Dugan (U.S. Pat. No. 3,992,584) system. It should be noted
that as x is varied from 0 to 1 the immunity to unwanted amplitude
modulation is increased.
The above-described controller must compute a number of signal averages. An
analog circuit embodiment of the attenuator controller used in the
preferred embodiment of the present invention is shown in FIG. 2 at 100.
Controller 100 includes two circuits for generating the logarithms of
numerators of L.sub.1 and L.sub.2, respectively, and a circuit for
generating log (S.sub.t). L.sub.1 and L.sub.2 are then generated by
subtracting the relevant logarithmic signals using amplifiers 118 and 119.
The manner in which the logarithm of the numerator of L.sub.1 is generated
will now be explained. Variable resistor 102 determines the value of x. If
x is the fraction of the resistor between P.sub.1 and the center tap, the
potential at the center tap of this resistor will be proportional to
P.sub.1 (1-x)+A.sub.1 x. A buffer 121 having unity gain is provided to
isolate the variable resistors in the two channels. This signal is
filtered by speech filter 105 to improve noise rejection. The output of
filter 105 is input to a rectifier circuit whose output is the logarithm
of the output of filter 105. The average value of this signal is then
generated by low-pass filter 107.
The time interval over which the averaging takes place is determined by the
cut-off of low-pass filter 107. The output of low-pass filter 107
preferably tracks the voice envelope of the person speaking while removing
any ripple resulting from the fundamental frequency. Such a filter can be
constructed from a buffer amplifier 302, a rectifier 303, a capacitor 304,
and a resistor 306 as shown in FIG. 3 at 300. Capacitor 304 is charged by
buffer amplifier 302 which has sufficient current driving capacity to
follow the risetime of a talker's voice and still drive capacitor 304.
Rectifier 303 prevents the charge stored on capacitor 304 from leaving via
amplifier 302. Capacitor 304 and resistor 306 are chosen such that any
ripple from the lowest anticipated fundamental frequency of the voiced
speech is removed from the signal. This arrangement provides a "fast
attack"-"slow release" filter. The fast attack characteristic assures that
the initial syllables uttered by the talker are not lost.
The logarithm of the numerator of L.sub.2 is generated in an analogous
manner by circuit 110. The average of the logarithm of the sum of the
numerators of L.sub.1 and L.sub.2 is generated by amplifier 112 and
circuit 114. Circuit 114 operates in a manner analogous to circuit 104
described above. The output of circuit 114 is the logarithm of the
denominator of L.sub.1 and L.sub.2. Difference amplifiers 118 and 119
compute the difference of the logarithms of the numerators and the
denominators of L.sub.l and L.sub.2, respectively. The output of these
difference amplifiers is logarithm of L.sub.1 and L.sub.2.
While the above-described embodiments of the present invention have been
described in terms of a mixing system having two channels, it will be
apparent to those skilled in the art that these embodiments may be
generalized to systems having N channels, where N is any integer greater
than 1. In this case, the attenuator in the i.sub.Th channel has a level,
L.sub.1, given by
##EQU4##
An additional benefit provided by the present invention is "continuously
variable priority". As noted above, the constant x may be different for
different channels. Consider the case in which x is in the mid-position
(i.e. x=0.5) for all but one microphone channel. Then, if this microphone
has x set closer to the preamp signal, (i.e. x<0.5), this channel will
have easier access to the system and also cause more attenuation of other
channels, since it will be less affected by the signals on the other
channels. It will be apparent from the preceding discussion that multiple
levels of "continuous priority" can be set using different settings of the
microphone contribution for each channel.
It will be apparent to those skilled in the an that the identity of the
channel having priority may be changed automatically in response to the
usage patterns of the system. That is, the value of x used in setting the
attenuation level on a given channel can be changed in response to the
average value of the output of the channel. Here, the time over which the
average is taken would be substantially longer than that used in
generating the channel signal. Alternatively, the values of x in the
various channels can be set manually by the operator of the mixing
console. In this way, priority could be skewed towards the currently
active microphone, further improving the modulation immunity of the
system. This feature is particularly helpful for systems whose normal use
is a single talker at a time.
The above embodiments of the present invention have been described in terms
of a particular form of channel signal and a controller that utilizes the
ratio of the channel signal to the sum of the channel signals to determine
the gain of each channel. However, it will be apparent to those skilled in
the art that other forms of channel signals and other methods of combining
the channel signals to determine the channel gain may be used. In the case
of a ratio based system, any channel signal that is greater than the
channel's audio input signal for an active channel and less than the
channel's audio input signal for an inactive channel will provide
improvements over the prior art. Here, the channel's "audio input signal"
may be any signal that is proportional to the output of the microphone
connected to the channel in question.
While the above-described embodiments of the present invention have
utilized preamplifiers to generate the input signals to the attenuators,
it will be obvious to those skilled in the art that the preamplifiers can
be included in the microphones without departing from the teachings of the
present invention.
Various modifications to the present invention will become apparent to
those skilled in the art from the foregoing description and accompanying
drawings. Accordingly, the present invention is to be limited solely by
the scope of the following claims.
* * * * *
|
|
 |
|
 |
Description |
|
