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FIELD OF THE INVENTION
My present invention relates to a musical instrument of the electroacoustic
type having strings, tongues, bars or the like--referred to hereinafter as
vibratile tone-generating means--that can be excited into free
oscillations by a player. Typical instruments of this type are those with
plucked strings, such as guitars, but my invention also applies to
instruments such as electroacoustic pianos or vibraphones with
tone-generating means struck by hammers or mallets.
BACKGROUND OF THE INVENTION
In the instruments here contemplated, the oscillations of the several tone
generators thereof are picked up by associated electroacoustic transducers
converting them into electric audio signals. These transducers may operate
inductively, capacitively or piezoelectrically, for example; they may also
be constituted by strain gauges on a string-supporting bridge as described
in my prior U.S. Pat. Nos. 4,228,715 and 4,292,875. The transducers are
provided with output circuitry for acoustically reproducing the
oscillations of the corresponding tone generators, usually through a
loudspeaker, after suitable amplification. That output circuitry may
further include certain components, such as dynamic-range compressors and
sustainers, for electronically controlling the period during which an
audio signal persists beyond the instant of excitation of the associated
tone generator and for establishing a selected fade-out rate during that
period; circuitry of that kind is known primarily from electronic music
synthesizers, e.g. as described in U.S. Pat. No. 4,336,734 and others
referred to therein.
The aforedescribed components of electronic synthesizers, however, do not
operate satisfactorily in electroacoustic instruments designed to produce
natural-sounding tones in the fade-out phase. The length of the fade-out
period is limited by the extent to which the generated audio signal can be
amplified within an acceptable signal-to-noise ratio. When the noise
becomes excessive, the amplification must be instantly terminated so as to
cut off the sound. This is inconsistent with natural tone perception.
OBJECTS OF THE INVENTION
The general object of my present invention, therefore, is to provide an
improved electroacoustic musical instrument with means for controlling
fade-out in a natural-sounding way and with avoidance of the
aforementioned noise problem.
A more particular object is to facilitate the establishment of different
fade-out periods under the control of the player.
It is also an object of my invention to provide means letting a player
choose between controlled fade-out and sustained reverberation.
SUMMARY OF THE INVENTION
I have found, in accordance with my present invention, that the aforestated
objects can be achieved by including the tone-generating means in a system
designed to maintain the audio signals and their acoustic reproduction for
an extended and preferably variable period beyond the moment of original
excitation--e.g. the plucking of a string--by the player. I therefore
provide vibratory re-excitation means operatively coupled with the
tone-generating means and connected via a regenerative loop to the output
circuitry of the instrument for maintaining the tone-generating means in
an oscillatory state in response to a feedback signal derived from the
audio signals. The feedback loop includes amplitude-modulating means
connected to supervisory means for damping the feedback signal to control
the duration of the oscillatory period.
Pursuant to a more particular feature of my invention, the supervisory
means comprises an integrator connected to the output circuitry for
deriving a mean-amplitude signal from the audio signals transmitted
thereto, a memory for storing a peak value of these audio signals which
occurs immediately upon activation of the tone-generating means, and a
comparator of algebraic adder for differentially combining the
mean-amplitude signal with a diminishing reference signal obtained from
the memory with the aid of a discharge path progressively reducing the
magnitude of the stored value, the comparator feeding an error signal to a
control input of the amplitude-modulating means.
The discharge path of the memory may comprise adjustable impedance means
for varying the rate of diminution of the reference signal under the
control of setting means which could be a player-operable signal source,
e.g. a pedal, but could also be a frequency discriminator connected to the
output circuitry of the instrument in order to modify the rate of
diminution according to the fundamental frequency of a concurrently
generated oscillation, as more fully described hereinafter.
A further advantageous feature of my invention resides in the provision of
switchover means operable by the player for selectively connecting an
input of the comparator either to the peak memory or to a supply of an
alternate reference signal of constant magnitude.
The vibratory re-excitation means operatively coupled with the
tone-generating means as part of the regenerative-feedback loop may be
mechanically coupled with the instrument body, e.g. with the rib of a
guitar provided with the usual soundboard. When the body of a guitar or
similar string instrument is of the solid or nonresonant type, the
feedback may also take place by way of the string-supporting bridge. A
further possibility is to use a loudspeaker acoustically coupled with one
or more tone generators through an intervening air gap; such a loudspeaker
could, in fact, be one serving for the audible reproduction of the
generated oscillations.
A single loudspeaker or other vibratory exciter may have its input
connected through a summing stage to a plurality of channels of the
feedback loop serving the respective tone generators. It should be noted,
however, that the instrument may include tone generators not provided with
such feedback channels and thus not subject to fade-out or sustaining
control as discussed above.
BRIEF DESCRIPTION OF THE DRAWING
The above and other features of my invention will now be described in
detail with reference to the accompanying drawing the sole FIGURE of which
is a block diagram schematically showing a representative embodiment.
SPECIFIC DESCRIPTION
In the drawing I have shown a musical instrument 1, specifically a guitar,
with strings 2 to be plucked by a player, the strings being mounted on the
instrument body in close proximity to respective electroacoustic
transducers 3 which may be strain gauges carried on a bridge as described
and illustrated in my above-identified prior patents. These transducers
have individual output circuits of which, however, only one has been shown
and will be described in detail. That output circuit comprises a
preamplifier 15 whose output is connected, together with those of the
other preamplifiers not shown, via an amplitude limiter or damping circuit
20 to an outgoing lead 18 terminating at a load AA such as a loudspeaker
or group of loudspeakers in an auditorium. Lead 18, which may include
additional amplifier stages, carries the electric audio signal a,
corresponding to the oscillations of the string 2 associated with
preamplifier 15, along with similar output signals from further
preamplifiers if other strings are excited at the same time. The pitch of
string 2 may correspond, for example, to the diapason normal. The
lower-case letters designating certain signals correspond, in part, to
those appearing in FIG. A-1 of the chapter "Theory of Servomechanisms" of
the book "Servomechanism Practice" by W. R. Ahrendt and C. J. Savant, Jr.,
Ph.D., published 1960 by McGraw-Hill Book Company, Inc.
A signal converter 4 connected to the output of preamplifier 15,
essentially consisting of a half-wave rectifier, changes the bipolar
signal a into a unipolar signal h, i.e. into a pulsating current. Signal h
is applied in parallel to an integrator 10 and to a peak memory 13.
Integrator 10, which may be a low-pass filter, derives from signal h a
more gradually varying signal be proportional to the mean amplitude of
output signal a. An algebraic adder 24 compares this signal b with a
reference signal r which, in the illustrated position of a switch 9, is
delivered by the peak memory 13. The latter, resembling a conventional
sample-and-hold circuit, is shown schematically as including a storage
capacitor 13a and an adjustable resistor 13b connected in a discharge path
thereacross. The capacitor is charged through a nonillustrated one-way
component, such as an operational amplifier, to the highest value of the
unipolar voltage h emitted by converter 4. There is also shown a
short-circuiting switch 13c, i.e. an electronic gate, serving for the
quick discharge of capacitor 13a in response to a termination pulse p
appearing on an output lead 23 of a threshold circuit 11 which also
receives the mean-amplitude signal b from integrator 10. Circuit 11 is
triggered by a predetermined decrease of signal b, i.e. whenever its
absolute value drops below a certain level or when the decay rate of that
signal--as determined by a differentiator--exceeds a given limit.
Switch 9 is mechanically controlled, via a link 8a, by a player-operated
pedal 8 which also includes a potentiometer (not shown) connected to a
voltage source V. An output lead 8b of that potentiometer is connected, in
the illustrated position of a manual switch 25, to a control input of peak
memory 13 to apply thereto a setting command v which adjusts the discharge
resistance 13b to an extent determined by the position of pedal 8. The
player, therefore, may vary the discharge time--e.g. lengthen it--by
stepping on the pedal; lead 8b has several branches extending via
respective armatures of switch 25 to all the peak memories associated with
the respective transducers 3, preamplifiers 15 and converters 4. When the
pedal 8 is fully depressed, it displaces a spring-loaded lug 8c to reverse
the switch 9 which thereupon connects the additive input of comparator 24
to voltage source V by way of a manually adjustable level selector 12
whereby reference signal r assumes a value determined by the setting of
that selector. Lead 23 is also connected to a blocking input of level
selector 12 for disconnecting the switch 9 from voltage supply V whereby
reference signal r goes to zero regardless of the position of that switch
whenever threshold circuit 11 is active.
An error signal e, proportional to the difference between the
mean-amplitude signal b on the subtractive input and the reference signal
r on the additive input of comparator 24, is emitted on a lead 21 by a
bipolar control amplifier which is connected to the comparator output and
preferably has a low-pass characteristic. Lead 21 further extends to a
control input of amplitude limiter 20. A junction J, which has no physical
significance, symbolizes points anywhere in the system in which the error
signal e or its contributing signal b is encumbered by a disturbance u.
The encumbered error signal arrives at a control input of an amplitude
modulator 14 which lies in a feedback loop 5 extending from the output of
preamplifier 15 so as to carry the audio signal a. Modulator 14 changes
the amplitude of that audio signal so as to produce a feedback signal c
which is fed via a power amplifier 16 to a vibratory exciter 7; the latter
is shown to be designed as a loudspeaker whose diaphragm, however, also
has an extension 22 mechanically connectable with the body of instrument
1. The latter connection will be used when that body is a resonant belly
with a soundboard, as discussed above; even if that body is nonresonant,
any string 2 will be acoustically reverberated by sound waves from this
loudspeaker if its natural frequency (as modified by any fret onto which
it is pressed) corresponds to one of the components of that wave. Power
amplifier 16 also receives similar feedback signals from other channels of
loop 5. The drawing further shows a lead 17 extending from the output of
amplifier 16 to an ancillary load AE such as one or more additional
loudspeakers designed to generate an echo effect, taking into account the
delay introduced by the feedback.
The adjustable impedances symbolized by variable resistances at 12, 13b, 14
and 20 are preferably constituted by electronic devices such as
field-effect transistors of the insulated-gate (IGFET) type. Thus, for
example, components 14 and 20 may comprise IGFETs of the enhancement and
the depletion type, respectively, with gates tied to lead 21. In normal
operation, with mean-amplitude signal b at most equal to reference signal
r, error signal e on lead 21 will be of one polarity (e.g. positive) or
zero. If, however, the feedback should become excessive so that b>r, the
polarity of signal e will be reversed so that modulator 14 will become
substantially nonconductive while the normally fully conductive amplitude
limiter 20 will attenuate its outgoing signal component.
With storage capacitor 13a of memory 13 assumed to be initially discharged,
the plucking of a string 2 by the player generates signals a and h,
thereby charging the capacitor 13a to the peak of the largest amplitude.
When switch 9 is in its illustrated position, the capacitor charge
determines the magnitude of reference signal r fed to comparator 24 which,
of course, must have a very high input impedance so as not significantly
to contribute to the dissipation of that charge. With suitable design of
the active and passive circuit elements of components 10 and 11, the
magnitude of signal b differs but little from that of signal r at this
time. The resulting error signal e allows modulator 14 to pass a feedback
signal c sufficient to maintain the oscillation of the plucked string 2 at
or near its original level. With the capacitor charge gradually leaking
off via discharge impedance 13b, reference signal r diminishes over a
number of oscillatory cycles so that error signal e and feedback signal c
also decrease. If the string is not being plucked again at this stage, the
amplitude of its oscillation and that of audio signal a will be
correspondingly reduced so that the controlled signal b follows the
reference signal r whose rate of decay is determined by the setting of
impedance 13b. The player, therefore, may control that rate by stepping
more or less heavily on pedal 8 to lengthen or shorten the ensuing
fade-out period which ends when threshold circuit 11 emits the terminating
pulse p upon detecting a certain decrease in signal b as discussed above;
pulse p is also fed to a blocking input of comparator 24 for cutting off
the error signal e. The rapid discharge of capacitor 13a by the temporary
closure of switch 13c allows that capacitor to be recharged to a new
voltage peak when the associated string is again plucked.
If the player wishes to sustain the oscillation of the excited string for
an indefinite period, a full depression of pedal 8 will switch the
additive input of comparator 24 to the output of level selector 12 so that
reference signal r will have a constant value, which may be manually
adjusted, establishing a chosen volume for the tone generated by the
excited string. The reverberation of that string will be terminated
immediately when the player mutes the string by the touch of a finger,
with resulting activation of threshold circuit 11 by the disappearance of
signal h, or else the player may switch back to peak memory 13 for a
gradual fade-out.
In the drawing I have also shown a frequency discriminator 19 with an input
connected to the output of preamplifier 15 in order to detect the
fundamental frequency of audio signal a. With switch 25 moved into its
alternate position, discriminator 19 controls the rate of discharge of
storage capacitor 13a according to the magnitude of that fundamental
frequency. Since the decay period of the oscillations of a momentarily
excited string or other tone generator varies inversely with pitch, this
mode of operation likewise generates a natural-sounding fade-out effect.
Discriminator 19 could also be connected to the output of converter 4
carrying the raw-rectified signal h.
The control of output signal a by the loop 5 has the further advantage of
preventing the undesirable kind of acoustic feedback dreaded by performers
in a concert hall, auditorium or other closed environment.
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