[0001] This invnetion relates to contact microphones for use with cymbals, gongs, and similar
resonant percussion instruments, all of which will be referred to hereinafter for
convenience as "cymbals".
[0002] A cymbal-when struck undergoes a complex resonance in a var-iety of modes. However,
some of these modes do not propagate efficiently in air; this applies especially to
certain low frequencies. The result is that the sound perceived by a listener more
than a few centimetres from the cymbal contains vibrations corresponding to only some
of the vibrations in the cymbal.
[0003] Hence, there have hitherto been no contact microphones which provide acceptable amplification
or recording of the sound of a cymbal, since the electric signal produced has been
very different from the sound perceived by a listener. Non-contact microphones have
been equally unacceptable since they cannot be used without interference from other
instruments in an ensemble or from ambient noise.
[0004] One object of the present invention is to provide a novel contact microphone arrangement
capable of effective use with cymbals.
[0005] Accordingly, the present invention provides a contact microphone for use with a cymbal
(as hereinbefore defined), comprising at least one strip of piezoelectric polymeric
sheet material secured to the cymbal surface and having its longitudinal axis aligned
radially of the cymbal.
[0006] Other features and advantages of the invention will be apparent from the following
description of embodiments of the invention, given by way of example only, and referring
to the accompanying drawings, in which:
Fig. 1 is a perspective view of a cymbal having secured thereto a microphone forming
a first embodiment of the present invention;
Fig. 2 is a plan view to an enlarged scale of the embodiment of Fig. 1;
Fig. 3 is an underneath plan view of a cymbal having secured thereto a microphone arrangement
forming a second embodiment of the present invention; and
Figs. 4 and 5 are underneath plan views illustrating further embodiments of the invention.
[0007] Referring to Figs. 1 and 2, a cymbal 10, as is usual, has a dished, part-spherical
central portion 12 and a surrounding skirt portion 14 of shallow conical form. The
microphone of this embodiment comprises a first strip 16 and a second strip 18 of
a polymeric piezoelectric material, suitably polyvinylidene fluoride (PVDF); preferred
forms of this material will be discussed in detail below. The strips 16 and 18 are
provided on their major surfaces with metallised electrodes, and they are secured
to the surface of the cymbal 10 by any suitable means, such as adhesive or pressure
sensitive tape.
[0008] In this embodiment, the first strip 16 is arranged radially on the central portion
and gives an electrical output substantially corresponding to vibrations in the central
portion 12 when the cymbal 10 is struck. The second strip 18 is arranged circumferentially
on the skirt portion 14 and is of a predetermined length. When the cymbal is struck,
one mode of vibration induced is a low frequency wave travelling circumferentially
in the skirt portion 14. This wave gives rise to very little perceived sound, but
would form a major input to a conventional contact microphone. According to a preferred
feature of the invention, the second strip 18 has a length equal to one wavelength
of this mode, or to a whole number of wavelengths. The wavelength in question can
readily be determined by examination for a given cymbal. The result is that equal
and opposite voltages are induced at this frequency in the PVDF material, giving a
net output of nil, but permitting higher frequencies to be reproduced.
[0009] The transducers formed by the strips 16 and 18 can be connected in series or (preferably,
as shown in Fig. 2) in parallel to give a composite electrical output which when amplified
and reproduced will be aurally close to the perceived sound of the cymbal to a listener.
[0010] As shown in greater detail in Fig.2, connecting wires 20, 22 are attached, e.g. by
soldering, to the electrodes on th,e opposed faces of the strips 16, 18. The electrodes
may be formed by any suitable means such as printing with silver ink or vapour deposition
of a metal such as silver or aluminium, such techniques being well known per se. The
strips 16, 18 may conveniently be formed by cutting from pre-metallised sheets.
[0011] Preferably, the strips 16 and 18 are formed from a polarized polymeric piezoelectric
material such as polarized PV
DF. In the embodiment of Figs. 1 and 2, it is preferred that the main uniaxial mode
(D
31 mode) of the polarized material, is aligned axially of the strip, as indicated by
the arrows A, for maximum sensitivity.
[0012] A preferred material is prepared as follows. A base film is prepared from vinylidene
fluoride homopolymer, film grade resin (KYNAR (trade mark) 9816-30 from Pennwalt Corporation)
by melt extrusion. The base film is uniaxially stretch oriented .at a stretch ratio
ranging between about 4 and 5 to 1 to produce a film having a thickness of about 28u.
This thickness is not critical but is preferred for the present use.
[0013] The film is then electrically polarized (poled) in known manner by subjecting the
film to a pressure of about 300 psi, a temperature of about 65°C, and voltage of 15-18
kV. The temperature is held at 65°C for 10 minutes and the film is then permitted
to cool at a rate of about 2°C|min over a period of 18-20 min. At the end of this
cooling period, the voltage is decreased to zero and the film is removed and stabilised
under a pressure of about 350-400 psi and temperature of 40-60°C. The film is then
metallised as described above.
[0014] The same material may be used in the other embodiments of the invention which will
now be described.
[0015] Referring to Fig. 3, the microphone of this embodiment comprises a plurality of strips
30 each arranged radially of the cymbal, but in this embodiemnt having the principal
uniaxial mode of the material transverse to the longitudinal axis of the strip as
indicated by the arrows B. The strips 30 are positioned at irregular intervals around
the circumference of the cymbal 10; in the example shown, there are seven strips 30
at angular spacings of 15°, 40°, 25°,70°, 90°, 10° and 110°. The preferred number
of strips is in the range 6 to 12.
[0016] It is believed that the fidelity achieved by this embodiment is brought about for
the following reasons. When the cymbal is struck, its surface vibration which ip rapdly
attenuated or is cancelled in air. Moreover, the surface information at any given
point on the cymbal surface is essentially single phase, whereas the listener speaced
from the cymbal hears a randomised mixture of phase for each characteristic frequency
of the cymbal, the phase information being further randomised for the listener by
Doppler effects produced by the cymbal oscillating on its support after striking.
The irregular, quasi-random distribution of the strips 30 around the cymbal in this
embodiment is believed to produce a similar randomising of phase information in the
composite electrical output, the strips 30 to achieve this being conencted in parallel.
[0017] The strips 30 are suitably of metallised PVDF of the type detailed above. A presently
preferred width for the strips 30 is about 3.5 mm; a greater width would produce a
larger output but it has been found that wider strips tend to give a signal with too
much bass. The strips are preferably as long as is practical. It is in any event preferred
that in the case of a crash cymbal, where the skirt consists of a relatively thick
tapered inner portion surrounded by a relatively thin annular rim, the strips should
extend as far as the transition between the two parts of the skirt.
[0018] In certain cases, especially with small cymbals, it is possible to use a single radial
strip without a circumferential strip. This is illustrated in Fig. 4, wherein a cymbal
10 is provided with such a strip at 16'. In a small cymbal, the influence of the circumferential
travelling wave is small and the radial disposition of the strip 16' minimises pick-up
from it.
[0019] Fig. 5 illustrates an embodiment similar to those of Figs. 1 and 2 and Fig. 4, in
that a single PVDF film transducer 50 is used, this being of L-shape to provide a
radial portion 52 and a circumferential portion 54.
[0020] The materials used in the embodiments of Figs. 4 and 5 are suitably the same as in
the previous embodiments. The electrical signals produced by the embodiments of Figs.
4 and 5 and similar embodiments may not be truly representative of the sound of the
actual cymbal on which the microphone is mounted, but they would reproduce as cymbal-like
sounds.
[0021] The microphone may in principle be mounteed either on the upper surface of. the cymbal,
as in Figs. 1 and 2, or on the lower surface, as in Figs. 3 - 5. In practice, however,
it would be preferred to mount it on the lower surface where it cannot be struck by
the striking implement.
1. A contact microphone for use with a cymbal (as hereinbefore defined), characterised
in that it comprises at least one elongate strip (16; 16'; 30; 50)of piezoelectric
sheet material secured to the surface of the cymbal (10), the longitudinal axis of
the strip being aligned radially of the cymbal,-said strip being provided on its major
surfaces with electrodes for providing an electrical output.
2. The microphone of claim 1, further comprising a second elongate strip (18) of piezoelectric
sheet material provided on its major surfaces with electrodes, said second strip being
secured to the outer portion (14) of the cymbal (10) with its longitudinal axis aligned
circunferentially of the cymbal.
3. The microphone of claim 2, in which the second strip (18) is of a length approximating
a whole number of wavelengths of vibration propagating circumferentially in said outer
portion (14).
4. The microphone of claim 2 or claim 3, in which the piezoelectric sheet material
is a polarized polymeric material, the material of each strip (16, 18) being oriented
such that the principal uniaxial mode of the material is transverse to said axes.
5. The microphone of claim 1, further comprising at least one additional elongate
strip of piezoelectric sheet material (30) provided on its major faces with electrodes
and secured to the surface of the cymbal with its longitudinal axis aligned radially
of the cymbal.
6. The microphone of claim 5, in which there are a number of said strips (30) disposed
around the cymbal surface at irregular angular spacings.
7. The microphone of claim 6, in which said number 0238187 the range six to twelve.
8. The microphone of any of claims 5 to 7, in which the piezoelectric sheet material
is a polarized polymeric material, the material of each strip (30) being oriented
such that the principal uniaxial mode of the material is aligned with said axes.
9. The microphone of claim 4 or claim 8, in which said material is polarized polyvinylidene
fluoride, and each strip is about 3.5 mm wide.
10. The microphone of claim 1, in which said strip (50) is provided at its outer end
with a circumferentially-extending portion (54) to form an L-shaped transducer.