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Claims  |
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I claim:
1. In vibrating string musical devices which have a plurality of parallel
strings composed of magnetically susceptible materials, said strings being
oriented in a common string plane, a variable reluctance pickup for
asymmetrically sensing vibrations of strings and generating corresponding
electrical signals responsive thereto, comprising in combination,
means for forming a magnetic circuit in combination with a linear segment
of each string including,
means for shaping a single magnetic field region having a magnetic flux
gradient in a vertical direction (v) perpendicular to said string plane
and perpendicular to said strings (d .PHI. /dv) for producing large
changes of reluctance in said magnetic circuit responsive to motions of
said linear segments of said strings in said vertical direction, and
having a very small magnetic flux gradient in a horizontal direction (h)
perpendicular to said strings and parallel to said string plane (d .PHI.
/dh) where (d .PHI. /dh) << (d .PHI. /dv), for producing very small
changes of reluctance in said magnetic circuit responsive to motions of
said linear segments of said strings in said horizontal direction, said
shaped magnetic field region encompassing all said linear segments of said
strings, and
sensing means for sensing changes of reluctance in said magnetic circuit
and producing representative electric signals responsive thereto, said
sensing means being adapted for electrical connection, whereby the
electrical signals produced by said sensing means can be electronically
amplified and then converted into corresponding acoustical waves.
2. The variable reluctance pickup of claim 1 wherein said means for forming
a magnetic circuit in combination with a linear segment of each string
further includes,
a longitudinal magnetic element providing a magnetic field, said magnetic
element having a north and a south side providing a corresponding
north-south polarity axis oriented perpendicularly with respect to its
longitudinal axis, said magnetic element being oriented with its
longitudinal axis aligned perpendicular to and with its north-south
polarity axis aligned parallel to said linear segments of said strings,
said magnetic element being disposed proximate said string plane, and
a plurality of separate core elements composed of a magnetically
susceptible material, said plurality of core elements being divided into
north and south sets of core elements, said north set of core elements
being disposed contiguous to said north side of said magnetic element and
said south set of core elements being disposed contiguous to said south
side of said magnetic element, said core elements extending from said
magnetic element toward said string plane whereby an efficient magnetic
flux coupling between said linear segments of said string and said
magnetic element is established.
3. The variable reluctance pickup of claim 2 wherein the number of core
elements in said north set of core elements equals the number of core
elements in said south set of core elements, and each core element in said
north set of core elements is positioned on said north side of said
magnetic element opposite a space on said south side of said magnetic
element defined between two adjacent core elements in the south set of
core elements.
4. The variable reluctance pickup of claim 3 wherein each core element has
a planar end proximate the string plane parallel said strings, and
wherein said means for shaping a magnetic field region encompassing said
linear segments of said strings comprises,
a longitudinal north shaping face composed of a magnetically susceptible
material, said north shaping face being mounted on said ends of said north
set of core elements, said longitudinal north shaping face being oriented
perpendicularly with respect to said polarity axes, and
a longitudinal south shaping face composed of a magnetically susceptible
material, said south shaping face being mounted on said ends of said south
set of core elements, said longitudinal south shaping face also being
oriented perpendicularly with respect to said polarity axes whereby
magnetic flux emanating from said magnetic element through said core
elements is spread uniformly across the surface of said north and south
shaping faces.
5. The variable reluctance pickup of claim 4 wherein said string plane of
said vibrating string musical device has a width measured perpendicularly
with respect to said strings, and wherein said length, of said magnetic
element, of said north shaping face and of said south shaping face,
respectively, are at least equal to said width of said string plane.
6. The variable reluctance pickup of claim 5 wherein said north and south
shaping faces each have a rectangular-like planar surface proximate said
string plane, said planar surfaces being oriented in the same plane and
parallel said strings with said respective lengths oriented
perpendicularly with respect to the polarity axis of said magnetic
element.
7. The variable reluctance pickup of claim 6 wherein the length of the
linear segments of each string encompassed by the shaped magnetic field is
defined as the aperture of the pickup and wherein in a reference plane
perpendicular to and bisecting said aperture, said shaped magnetic field
has lines of equal magnetic field strength of a rectangular-like
configuration having a length dimension approximately equal to said length
of said north and south shaping faces.
8. The variable reluctance pickup of claim 7 wherein said sensing means for
sensing changes of reluctance in said magnetic circuit comprises a
plurality of coils formed of insulated conductive wire, each of said coils
being disposed around one of said core elements for generating
representative electrical signals responsive to changes of reluctance in
said magnetic circuit, said coils being electrically connected in series,
said serially connected coils being adapted for electrical connection
whereby electrical signals generated by said coils can be electronically
amplified and then converted into corresponding acoustical waves.
9. The variable reluctance pickup of claim 8 wherein said magnetic element
is insulatively mounted on a printed circuit board and wherein said
printed circuit board has a plurality of conductive strips for
electrically connecting said sensing coils in series.
10. The variable reluctance pickup of claim 9 wherein said sensing coils
are wound around said core elements in a section defined between said
shaping faces and a surface of said magnetic element nearest said string
plane.
11. The variable reluctance pick-up of claim 10 further defined in that
said coils are electrically connected for cancelling electrical signals
generated in said coils by external electrical fields.
12. The variable reluctance pickup of claim 21 wherein said means for
forming a magnetic circuit in combination with a linear segment of each
string further includes,
a longitudinal magnetic element providing a magnetic field, said magnetic
element having a north-south polarity axis oriented perpendicularly with
respect to its longitudinal axis, said magnetic element being disposed
proximate said string plane with said longitudinal axis and said
north-south polarity axis both oriented perpendicularly with respect to
said strings, said magnetic element further having a planar top surface
nearest said strings, and
a core element composed of magnetically susceptible material mounted on top
of said planar surface of said magnetic element and extending toward said
strings whereby an efficient magnetic flux coupling between said magnetic
element and said linear segment of said strings is established.
13. The variable reluctance pickup of claim 12 wherein said core element
has a length less than said length of said magnetic element, and
wherein said core element has a planar end surface parallel said top
surface of said magnetic element.
14. The variable reluctance pickup of claim 13 wherein said means for
shaping said magnetic field region encompassing said linear segments of
said strings comprises a shaping face composed of a magnetically
susceptible material, said shaping face being positioned on said planar
end surface of said core element and wherein said shaping face has a
thickness and a surface proximate said strings, said surface having a
rectangular-like figuration with a length at least equal to the length of
said magnetic element, whereby a magnetic field region is provided which
has a maximum magnetic flux gradient in a direction perpendicular to said
string plane and perpendicular to said strings which has a minimum
magnetic flux gradient in a direction perpendicular to said strings and
parallel to said string plane.
15. The variable reluctance pickup of claim 14 wherein said string plane
has a width measured perpendicularly with respect to said strings and
wherein said lengths of said shaping face and said magnetic element
respectively at least equal said width of said string plane.
16. The variable reluctance pickup of claim 15 wherein said sensing means
for sensing changes of reluctance in said magnetic circuit comprises a
coil formed of insulative conductive wire wound around said core element
for generating representative electrical signals responsive to changes of
reluctance in said magnetic circuit, said coil being adapted for
electrical connection whereby said electrical signals generated by said
coil can be electronically amplified and then converted into corresponding
acoustical waves.
17. The variable reluctance pickup of claim 16 wherein said string plane
has a curvature and said shaping face has a thickness dimension T and said
core element has a length dimension L, and
wherein the length of the core element and the thickness of the shaping
face are such that the magnitude of electrical signals from the coil
measured as a function of position along the length of said shaping face
traces a curve with a curvature corresponding to a curvature of a curve
defined by squaring distances measured between each string and a reference
plane through the coil parallel the top surface of the magnetic element.
18. The variable reluctance pickup of claim 11 wherein said printed circuit
board, said magnetic element, said core elements, said sensing coils, and
said shaping faces are potted in an insulative epoxy matrix.
19. The variable reluctance pickup of claim 17 wherein said magnetic
element, said core element, said coil and said shaping face are potted in
an insulative epoxy matrix.
20. The variable reluctance pickup of claim 11 wherein said string plane
has a curvature, said north and south shaping faces have a thickness
dimension T, said plurality of core elements each have a length dimension
L measured parallel the length of said shaping faces and the core elements
of said north set and of said south set are spaced a distance D apart, and
wherein the length of the core elements L, the thickness of the shaping
faces T and spacing distance D between the core elements of said north set
and of said south set are such that the magnitude of electrical signals
from the sensing coils measured as a function of position along the length
of said shaping faces traces a curve with a curvature corresponding to a
curvature of a curve defined by squaring distances measured between each
string and a reference plane through said coils parallel said shaping
faces.
21. In vibrating string musical devices which have a plurality of parallel
strings composed of magnetically susceptible materials, said strings being
oriented in a common string plane, a variable reluctance pickup for
asymmetrically sensing vibrations of strings and generating corresponding
electrical signals responsive thereto, comprising in combination,
means for forming a magnetic circuit in combination with a linear segment
of each string including,
means for shaping a single magnetic field region having a magnetic flux
gradient in a vertical direction (v) perpendicular to said string plane
and perpendicular to said strings (d .PHI. /dv) for producing large
changes of reluctance in said magnetic circuit responsive the motions of
said linear segments of said strings in said vertical direction, and
having a very small magnetic gradient in a horizontal direction (h)
perpendicular to said strings and parallel to said string plane (d .PHI.
/dh) where (d .PHI. /dh) approaches zero, ( (d .PHI. /dh) .fwdarw. 0), for
producing very small changes of reluctance in said magnetic circuit
responsive to motions of said linear segments of said strings in said
horizontal direction, said shaped magnetic field region encompassing all
said linear segments of said strings, and
sensing means for sensing changes of reluctance in said magnetic circuit
and producing representative electical signals responsive thereto, said
sensing means being adapted for electrical connection, whereby the
electrical signals produced by said sensing means can be electronically
amplified and then converted into corresponding acoustical waves. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
1. Field of the Invention
The invention relates to a variable reluctance pickup for steel string
musical instruments in which the vibrating strings cause variations of
reluctance in a magnetic circuit generating electrical signals which, upon
electronic amplification, are suitable for driving acoustic speaker
systems.
2. Description of the Prior Art
Generally, variable reluctance pickups for steel string musical instruments
comprise an arrangement of magnets and magnetically susceptible materials
which establish a magnetic circuit in combination with the playing
strings. As the strings vibrate, the changes in their position affect the
reluctance and magnetic flux of the magnetic circuit. A sensing coil is
inductively linked to the magnetic circuit for converting the variations
in magnetic flux into a corresponding electrical signal. The electrical
signals from the sensing coils is amplified electronically and fed into an
acoustic speaker system for producing musical sounds.
There are many different configurations of the basic elements of variable
reluctance pickup systems for steel string instruments. For example, U.S.
Pat. No. 2,235,983 (Demuth) describes the basic elements of a magnetic
pickup suitable for pianos and the like. U.S. Pat. No. 3,066,567 (Kelly)
describes a magnetic pickup system having a single, permanent magnetic
element with a plurality of pedestals to provide a specific pickup zone
for a given instrument string in combination with a single sensing coil.
U.S. Pat. No. 3,483,303 (Warner) describes a variable reluctance
transducer pickup system for steel string musical instruments in which an
attempt is made to isolate the magnetic circuits formed by adjacent
strings so as to minimize "cross-talk" between the various strings. U.S.
Pat. No. 3,571,483 (Davidson) describes a variable reluctance pickup
system having a plurality of isolated magnetic circuits, each specifically
designed to be substantially insensitive to the plane of string vibration.
Finally, U.S. Pat. No. 3,715,446 (Kozinski) describes a magnetic pickup
system having a balanced coil assembly for each string wherein each
assembly includes a bar magnet supporting two circular pole pieces and two
sensing coils disposed around the pole pieces.
Before discussing the disadvantages of prior art, variable reluctance
pickup systems, it is instructive to review the fundamental properties of
string instruments which give them their characteristic tones.
Basically, the tone of a plucked or a struck string instrument is judged by
the richness and complexity of the acoustic output in the "attack" or
beginning portion of a note. In acoustic string instruments, the bridge
structure constrains the motion of the soundboard such that those
components of string motion which are perpendicular to the plane of the
soundboard are well amplified, while those components of the string motion
which are parallel to the plane of the soundboard are not. The path
described by any arbitrarily small segment of a smoothly released, plucked
string is a precessing elliptical orbit of decreasing radius which rotates
about the quiescent position of the string. Accordingly, the asymmetrical
amplification of string motion provided by the bridge of an acoustic
instrument yields a rich, full and complex tone of continuously varying,
harmonic content. The richness and complexity of tones produced by
acoustic string instruments are the primary criterion of judging the
quality of such instruments.
In addition, the preferential or asymmetrical amplification provided by the
bridge structure in acoustic string instruments enhances the expressive
ability of the instrument. Specifically, the musician can control the
initial motion of the string by plucking either parallel to the soundboard
for a "thin or nasal" tone or perpendicular to the soundboard for a "full
or rich" tone.
Steel string guitars and other similar instruments have a particular
capability which distinguishes them from most other Western musical
instruments. This capability is referred to as "bending". "Bending" is
accomplished after a string is fretted and plucked by moving the fretting
finger with the string across the fingerboard, stretching the string. The
stretching of the string during "bending" can raise the pitch of the note
by as much as seven semi-tones, a factor which greatly enhances the
expressive capability of the instrument. However, "bending" a note also
results in a large displacement of the string from its normal vibrating
zone about the quiescent string position.
For variable reluctance pickup systems to have good tone (by acoustic
instrument standards), it must be highly asymmetrical in converting string
motion to electrical signal output. Further, such pickup systems have a
capability for high-frequency response in order to preserve the richness
and fullness of the varying harmonics in the "attack" portion of a note.
Finally, for steel string guitars and similar instruments, the pickup
systems must be insensitive to string displacement due to "bending".
The prior art variable reluctance pickup systems are characterized by
separate pole tip and/or pole pieces for each string. Each pole tip and/or
pole piece provides a distinct magnetic field region around the quiescent
position of each string. The distinct magnetic field regions of prior
pickup systems render them relatively insensitive to the plane of
vibration of the particular string.
For example, pickup systems with circular pole pieces provide a magnetic
field having the form of a symmetrical sinusoidal shell and a string
vibrating within such a magnetic field will generate approximately equal
magnitude electrical signals for string vibrations both parallel and
perpendicular to the string plane.
Another disadvantage of the prior art variable reluctance pickup systems
relates to their sensitivity to "bending". Specifically, the magnetic
field drops off between the individual pole tip and/or pole pieces.
Accordingly, the pickups will not uniformly sense a string vibration as
the string is displaced from its normal vibrating position during a
"bending" motion.
Prior art variable reluctance pickup systems having a single coil for
sensing variations of the magnetic circuits have very poor high-frequency
responses. Specifically, the impedance of a sensing coil in a magnetic
circuit increases with increasing frequency up to a maximum at a resonant
frequency whereupon the impedance of the coil decreases. Below the
resonant frequency, the impedance of the coil is dominated by inductive
effects. In explanation, the resulting variations in magnetic flux due to
string vibrations induce an electrical signal in the coil which, in turn,
creates another magnetic field which "bucks" or opposes the variations in
flux induced by the string (Lenz' Law). This effect "impedes" the signal
and increases with increasing frequency. Above the resonant frequency, the
impedance is influenced by the capacitive effects between turns of the
coil and between layers in the coil winding, i.e., the changing current in
one turn of the coil influences current in neighboring turns of the coil.
This effect becomes larger with increasing frequencies such that the coil
behaves as a capacitive reactance with turn-to-turn capacitive leakage to
ground. Accordingly, the output signal from the sensing coil falls off
rapidly above the self-resonant frequency. Both the inductances and the
cpacitance of a sensing coil vary linearly with the mean radius of the
coil. The mean radii in single-coil embodiments of prior art variable
reluctance pickups are large. Hence, the "attack" portion of a note is not
reproduced accurately.
SUMMARY OF THE INVENTION
The invented variable reluctance pickup for steel string musical
instruments provides a highly asymmetrical magnetic field for
preferentially sensing string vibration perpendicular to the string plane
and sounding board and generates representative electrical signals which,
upon electronic amplification and input into an acoustic speaker system,
produce tones or notes analogous to those produced by purely acoustical
string instruments.
The invented pickup system includes a common magnetic circuit for all
strings in the string plane formed by a single permanent bar magnet,
common shaping faces composed of magnetically susceptible materials
disposed proximate and parallel to the string plane, core elements
composed of magnetically susceptible materials for magnetically and
mechanically coupling the respective shaping faces to the poles of the bar
magnet and a plurality of sensing coils, each disposed around one of the
core elements, electrically connected in series. The shaping faces shape
the magnetic field region, encompassing the string plane to provide a
large magnitude magnetic flux gradient, in a direction perpendicular to
the string plane and a small magnitude magnetic flux gradient in a
direction parallel to the string plane (parallel to the soundboard).
The invented variable reluctance pickup system, because of the common
shaping faces, uniformly senses a string vibration as it is displaced from
its normal vibrating location during a "bending" motion.
Further, the combination of common shaping faces and series connection of
the sensing coils provide a single magnetic circuit, capable of sensing
and generating an electrical signal, corresponding to simultaneous
vibrations of different strings in the string plane.
The primary object of the invented high asymmetry, variable reluctance
pickup system is to produce an electronic signal which, upon amplification
and input into an acoustic speaker system, generates a tone of
constantly-changing, harmonic content at its leading edge, yielding the
rich and complex attack normally expected of the best acoustic
instruments.
Another primary object of the invented high asymmetry, variable reluctance
pickup system relates to providing a pickup which is insensitive to
"bending".
Still further objects, advantages and novel features of the invented high
asymmetry, variable reluctance pickup system will become apparent upon
examination of the accompanying figure and detailed description of a
preferred embodiment thereof.
DESCRIPTION OF THE FIGURES
FIG. 1 is a perspective view of an embodiment of a single face, high
asymmetry variable reluctance pickup having two common shaping faces.
FIG. 2 is a view taken along line 2 -- 2 of FIG. 1 with dotted lines
showing the summed magnetic field lines provided by the pickup.
FIG. 3 is a graph showing the magnetic field strength along a line
perpendicularly oriented across a string plane above a pickup system.
Curve I represents the field strength provided by the invented pickup
shown in FIG. 1 and Curve II represents a magnetic field strength provided
by conventional prior art pickups.
FIG. 4 is an embodiment of a single face, high asymmetry variable
reluctance pickup system having a single sensing face.
FIG. 5 is partial top view of the invented variable reluctance pickup
illustrating a "bending" motion.
FIG. 6 is a cross-section view taken along lines 6 -- 6 of FIG. 4.
FIG. 7 is a graph showing signal output as a function of position across
the pickup shown in FIG. 4.
DESCRIPTION OF PREFERRED EMBODIMENT
Referring to FIG. 1, the invented single face, high asymmetry variable
reluctance pickup has a single permanent bar magnet 11 mounted on a
printed circuit board 12. The bar magnet 11 may be composed of a ceramic
material. The pickup shown in FIG. 1 is designed to have the polarity axis
13 of the bar magnet 11 aligned parallel to the instrument strings.
Rectangular core elements 14 are mounted on the opposite long sides
(opposite poles) of the bar magnet 11. The core elements 14 are composed
of a magnetically susceptible material. The core elements 14 are
positioned in a staggered relationship with each other across the bar
magnet 11. Planar shaping faces 15 are mounted or positioned on the top
ends of the core elements 14. The shaping faces 15 are composed of a
magnetically susceptible material.
The bar magnet 11, the core elements 14 and the shaping faces 15 provide a
shaped magnetic field region designed to encompass the string plane of a
steel string musical instrument. Specifically, the bar magnet 11 is the
source of the magnetic field. The core elements 14 magnetically couple the
shaping faces 15 to bar magnet 11. The shaping faces spread the magnetic
field over their planar surfaces.
Sensing coils 16 are wound around the core elements 14 in a section between
the shaping faces 15 and the bar magnet 11. The sensing coils sense
changes in reluctance in a magnetic circuit formed by the vibrating
strings of the musical instrument, the shaping faces 15, the core elements
14, and the bar magnet 11.
In more detail, the shaping faces 15 phenomenologically shape the magnetic
field emanating from the bar magnet 11 to provide a maximum magnetic flux
gradient perpendicular to the string plane and a minimum magnetic flux
gradient parallel to the string plane. Referring to the cross-sectional
view of the pickup shown in FIG. 2, the lines 19 depict lines of equal
magnetic field strength (magnetic field lines). The magnetic field lines
depicted in FIG. 2 represent the summation of the magnetic field across
the aperture of the invented pickup. The aperture of a variable reluctance
pickup is, for purposes of this application, defined as the length of the
instrument's strings 18 which operatively form the magnetic circuit in
combination with the shaping faces 15, core elements 14 and bar magnet 11.
As is illustrated by the lines of equal magnetic field strength 19 shown in
FIG. 2, there is essentially no change in the magnetic field strength in a
plane parallel to the surface of the shaping faces 15 (parallel the string
plane). However, there is a change in the magnetic field in a direction
perpendicular to the plane of the shaping faces 15 (perpendicular to the
string plane). Thus, an instrument string 18 vibrating perpendicular to
the string plane (perpendicular to the plane of the shaping faces 15) will
cross a large number of field lines 19 to generate a corresponding large
change of reluctance in the magnetic circuit, which change in reluctance,
in turn, generates a large electrical signal. However, a string vibrating
parallel to the string plane, (parallel to the plane of the shaping faces
15) will cross relatively few, if any, field lines 19 to generate a
corresponding small change of reluctance in the magnetic circuit which, in
turn, generates a small electrical signal in the sensing coils 16.
Accordingly, the described pickup asymmetrically or preferentially
generates a signal responsive to changes in the string 18 position in a
plane perpendicular to the string plane.
The shaping faces 15 also spread the magnetic field provided by the bar
magnet 11 uniformly across the string plane. Referring to FIG. 3, the
magnetic field strength is shown as a function of position in the string
plane above a variable reluctance pickup. The dots 21 along the abscissa
of FIG. 3 represent the quiescent string position in the string plane.
(The strings are extending perpendicularly from the plane of the figure.)
Curve I depicts the magnetic field strength in the string plane provided
by the invented pickup. Curve II depicts the magnetic field strength in
the string plane provided by a conventional prior art pickup with
individual pole pieces for each string. As is illustrated, Curve I is
essentially flat, whereas Curve II shows a drop-off of magnetic field in
the regions between the quiescent string positions 21.
The spreading of the magnetic field uniformly across the string plane
allows "bending" without loss of signal. Specifically, there is no
drop-off in the magnitude of the changes of reluctance generated by a
vibrating string as it is moved from its normal vibrating zone about its
quiescent position during the "bending" motion. Moreover, both FIGS. 2 and
3 illustrate that the invented pickup preserves its asymmetrical
conversion of string vibration to electrical signals during a "bending"
motion.
In the single face, variable reluctance pickup shown in FIGS. 1 and 2, the
sensing coils 16 are electrically connected in series in a conventional
"humbucking" arrangement. The conductive strips 17 on the printed circuit
board 12 provide the electrical connection between the sensing coils 16.
The term "humbucking" is a descriptive term in the art describing a
condition whereby sensing coils of the pickup are connected such that
signals in the coils generated by external electric fields cancel out.
Such signals, if not cancelled out, would generate hum in the ultimate
acoustic output after amplification.
Specifically, changes in reluctance in the magnetic circuit produced by
string vibrations generate electrical signals in the coils 16 at the
opposite poles of the bar magnet 11 of the same polarity, whereas an
external electric field will generate electrical signals of opposite
polarity in the sensing coils on opposite poles of the bar magnet 11. The
signals of opposite polarity cancel out whereas the signals of the same
polarity add together.
In FIG. 2, the four sensing coils 16a, b, c, and d, each have an inside
lead and an outside lead. The inside lead of coil 16a is electrically
connected to the positive input of the amplifier system and its outside
lead is electrically connected to the inside lead of coil 16b. The outside
lead of coil 16b is connected to the outside lead of coil 16c on the
opposite side (opposite polarity) of the bar magnet. The inside lead of
coil 16c is then electrically connected to the outside lead of coil 16b
and the inside lead of coil 16d is electrically connected to the negative
input of the amplifier system. In essence, the coils 16 a and 16b are
wound in an opposite direction than coils 16c and 16d. Accordingly, an
external electric field will generate an electrical signal in coils 16a
and 16b of one polarity while generating an electrical signal in coils 16c
and 16d of opposite polarity and the summed electrical signal output of
the coils 16a - d is zero. However, since the coils 16a and 16b are
sensing changes of reluctance of one polarity and coils 16c and 16d are
sensing changes of reluctance of the opposite polarity, and since the
coils 16a and 16b are wound in an opposite direction than the coils 16c
and 16d, the coils 16 a and 16b will generate an electrical signal of the
same polarity as those generated by coils 16c and 16d responsive to a
change of reluctance in the magnetic circuit. Thus, it can be seen that a
"conventional humbucking arrangement" requires an equal number of sensing
coils 16 on each side (each pole) of the bar magnet 11.
FIG. 4 shows another embodiment of a single face, high asymmetry variable
reluctance pickup which includes a single permanent bar magnet 22 having a
north-south polarity axis oriented perpendicularly with respect to the
string plane as indicated by the arrow 21. The bar magnet 22 may be
composed of a ceramic material or other material capable of being
permanently magnetized. A single core element 23 composed of magnetically
susceptible material is mounted on one pole of the bar magnet 22. A planar
shaping face 24 also composed of a magnetically susceptible material is
secured to the opposite end of the core element 23. When the pickup, shown
in FIG. 4, is mounted in a string instrument, the rectangular surface area
of the shaping face 24 is proximate the string plane of the instrument.
The long sides of the shaping face 24 are positioned perpendicularly with
respect to the instrument strings. The plane of the rectangular face of
the shaping face 24 is parallel the string plane. The magnetic circuit is
formed by the bar magnet 22, the core element 23 and the shaping face 24
in combination with the instrument strings 25. (See FIG. 6). A sensing
coil 26 is wound around the core element 23 in the space between the
shaping face 24 and the top surface of the bar magnet 22.
The shaping face 24 shapes the magnetic field region in the string plane to
provide a maximum magnetic flux gradient in a direction perpendicular to
the string plane and a minimum magnetic flux gradient in a direction
parallel the string plane. The shaping face also spreads the magnetic
field region uniformly across the width of the string plane. Accordingly,
the pickup asymmetrically or preferentially converts the vertical
displacements of the instrument strings 25 into an electrical signal.
Also, the asymmetrical or preferential conversion does not abate or drop
off during a "bending" motion of a particular instrument string 25. In
particular, referring to FIG. 5, a string 25 can be moved from a vibrating
position about its normal quiescent position 27 to a vibrating position 28
shown by the dotted line during a "bending" motion without loss or
drop-off of signal.
The invented single face, variable reluctance pickup heretofore has been
discussed in context of planar or flat string planes. However, many string
instruments are constructed with a curved string plane. In instruments
having a curved string plane, it is possible to provide a signal output
curve from the pickup which corresponds to the curvature of the string
plane.
Specifically, in the embodiment of the invented single face, variable
reluctance pickup shown in FIG. 4, it is possible to determine the
"curvature of signal response" by varying the length of the core element
23 and the thickness of the shaping face 24. The "curvature of signal
response" from the pickup is the curve defined by the magnitude of
electrical signals from the coil or coils as a function of position along
the length of the shaping face. (See FIG. 7). The length of the core
element 23 also determines the diameter of the sensing coil 26. (As
pointed out previously, a smaller mean radius of the sensing coil reduces
the impedance of the coil, hence, enhancing its high-frequency response.)
It has been found, generally, that the curvature of signal response is
inversely related to the thickness (T) of the shaping face 24 and
inversely related to the length (L) of the core element 23. For a shaping
face 24 of a given length, a thicker shaping face will allow a shorter
core element with the same resulting curvature. Referring to the graph of
FIG. 7, the horizontal ordinate shows the respective ends and center line
of the embodiment of the invented pickup shown in FIG. 4. The vertical
ordinate designates the magnitude of the output signal generated by the
pickup. The curve 29 gives the curvature of the pickup, i.e., gain versus
position along the length of the pickup. The circles 30 in FIG. 7
designate the square of the distance measured from the quiescent string
positions to a reference plane through the coil 20 parallel the top
surface of the magnet 22.
It is not possible to define the exact relationship between the curvature
of signal response of the pickup, the core element length L and the pole
tip thickness T. Specifically, the width of the string plane and the
curvature of the string plane are determined by the instrument
construction and each instrument type would have a different width and
curvature. In general, however, the shaping face 24 and bar magnet 22
should have a length at least equal to the width of the instrument's
string plane. The curvature of signal response can then be adjusted for
the curvature of the string plane by measuring the output from the sensing
coil as a function of position along the length of the shaping face 24 and
of either the thickness T of the shaping face 24 or the length L of the
core element 23 or both.
The curvature of signal response of the pickup structure shown in FIG. 1
can be adjusted to the curvature of the string plane by varying the
spacing between the core elements 14 in addition to varying the core
lengths and shaping face thickness as previously discussed. Generally, the
curvature of signal response is inversly related to core element spacing.
The structures shown in FIGS. 1 and 4 are potted in an insulative epoxy 31.
The epoxy 31 forms a rigid matrix for holding the separate elements of the
pickup in a fixed relationship to one another. In addition, the epoxy
matrix 31 greatly increases the durability of the described pickups.
While the invented single face, high asymmetry variable reluctance pickup
for steel string musical instruments is described with respect to
particular embodiments, schematics and the like, numerous variations and
modifications can be effected within the spirit and the scope of the
invention as described above and as defined as set forth in the appended
claims.
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