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| United States Patent |
6,324,319
|
|
Tselikov
, et al.
|
November 27, 2001
|
Spliced optical fiber coupler
Abstract
In general, the mode field pattern of a single-mode
polarization-maintaining fiber is symmetric. There are preferred axes for
the polarization states, but the intensity pattern emerging from the fiber
is rotationally symmetric. If a short piece of multi-mode fiber is spliced
onto the end of a polarization-maintaining single-mode fiber, it is
possible to change the apparent shape of the mode field. The use of a
fusion splicer affects the stress pattern in polarization-preserving
fiber, and introduces asymmetry into the shape of the fiber mode field. If
the spliced fiber is cleaved near the splice, and the asymmetry of the
fiber mode field is matched to the asymmetry of a laser diode beam, then
the laser beam is coupled efficiently into the fiber without the use of
additional beam-shaping optics. The asymmetric beam from the laser is
brought to a focus, which is also asymmetric. By matching the asymmetries
of the focused spot and the distorted mode field (caused by the addition
of the short piece of multi-mode fiber), good coupling is achieved into
the fiber. Once the light has entered the spliced fiber and propagated
past the splice, the mode field returns to its original symmetric pattern
and the light propagates in a single mode, as it would in an unspoiled,
single-mode polarization-maintaining fiber. The output from the unspoiled
end is still symmetric, and there is little attenuation caused by the
splice.
| Inventors:
|
Tselikov; Alexander (Fremont, CA);
Gerber; Ronald E. (Richfield, MN);
Gage; Edward C. (Apple Valley, MN);
Mowry; Gregory S. (Burnsville, MN)
|
| Assignee:
|
Seagate Technology LLC (Scotts Valley, CA)
|
| Appl. No.:
|
357782 |
| Filed:
|
July 21, 1999 |
| Current U.S. Class: |
385/28 |
| Intern'l Class: |
G02B 006/00; G02B 006/26 |
| Field of Search: |
385/28,1,11,56,51,36,147
|
References Cited [Referenced By]
U.S. Patent Documents
| 4709986 | Dec., 1987 | Hicks, Jr. | 385/51.
|
| 4832437 | May., 1989 | Kim et al. | 385/1.
|
| 5159481 | Oct., 1992 | Maeda et al. | 385/11.
|
Primary Examiner: Ullah; Akm E.
Attorney, Agent or Firm: Moser, Patterson & Sheridan, LLP
Parent Case Text
RELATED APPLICATIONS
The present invention is related and claims priority to Provisional
Application No. 60/111,470, filed Dec. 9, 1998, and is incorporated herein
by reference.
Claims
What is claimed is:
1. An optical apparatus for directing a laser light between a source and a
destination location that exhibits a first mode field along an optical
path between a source and a destination location, comprising:
a first optical element, wherein the first optical element is disposed in
the optical path, and wherein the first optical element receives the laser
light having a first mode field at an input and exhibits a second mode
field in the light at an output; and
a second optical element, wherein the second optical element is disposed in
the optical path and coupled to the output of the first optical element to
receive the light, and wherein the second optical element exhibits the
second mode field.
2. The optical apparatus as recited in claim 1, wherein said destination
location comprises a data storage location.
3. The optical apparatus as recited in claim 2, wherein the first mode
field comprises an asymmetric mode field, and wherein the second mode
field comprises a symmetric mode field, and the first optical element
comprises an anamorphic prism.
4. The optical apparatus as recited in claim 2, wherein the second optical
element comprises a single mode PM (polarization-maintaining) optical
fiber.
5. The optical apparatus as recited in claim 2, wherein the second optical
element comprises a multi-mode optical fiber.
6. The optical apparatus as recited in claim 2, wherein the second optical
element comprises an anamorphic prism.
7. The optical apparatus as recited in claim 2, wherein the light comprises
polarized light.
8. The optical apparatus as recited in claim 2, wherein the first optical
element comprises a single mode optical fiber, wherein the second optical
element comprises a multi-mode optical fiber, and wherein the first and
second optical element are coupled to each other.
9. The optical apparatus as recited in claim 2, wherein the first mode
field comprises a symmetric mode field, wherein the second mode field
comprises an asymmetric mode field, wherein the second optical element
comprises a single mode polarization maintaining optical fiber, and
wherein the first optical element comprises a multi-mode optical fiber.
10. A storage drive for directing a laser light exhibiting a first mode
field along an optical path between a source and a data storage location,
comprising:
a first optical element, the first optical element disposed in the optical
path, the first optical element comprising a second mode field; and a
second optical element, the second optical element disposed in the optical
path, wherein the second optical element matches the first and second mode
fields to each other, wherein the first mode field comprises a symmetric
mode field, wherein the second mode field comprises an asymmetric mode
field, wherein the first optical element comprises a polarization
maintaining optical fiber, and wherein the second optical element
comprises a multi-mode optical fiber, for matching the first and second
mode fields to each other.
11. The storage drive as recited in claim 10, wherein the second optical
element is disposed in the optical path between the source and the first
optical element.
12. The optical drive as recited in claim 10, wherein the storage drive
comprises a magneto-optical storage drive.
13. An optical apparatus for efficiently directing a laser light exhibiting
a first mode field along an optical path between a source and a data
storage location, comprising:
an optical element, wherein the optical element is disposed in the optical
path, and wherein the optical element exhibits a second mode field; and
optical matching means for matching the first and second mode fields to
each other, wherein the optical matching means is disposed in the optical
path.
14. The optical apparatus as recited in claim 13, wherein the first mode
field is asymmetric.
15. The optical apparatus as recited in claim 13, wherein the second mode
field is circularly symmetric.
16. The optical apparatus as recited in claim 13, wherein the optical
element comprises a single mode polarization maintaining optical fiber.
17. A method for directing a laser light along an optical path between a
source and a data location, comprising the steps of:
providing a source of light that exhibits a first mode field in the optical
path;
providing a first optical element that exhibits a second mode field in the
optical path; and
aligning the first and second fields to each other by providing a second
optical element in the optical path.
18. The method as recited in claim 17, wherein the first mode field is
asymmetric and the second mode field is symmetric.
19. The method as recited in claim 17, wherein the first optical element
comprises a single mode polarization maintaining optical fiber.
20. The method as recited in claim 17, wherein the second optical element
comprises a multi-mode optical fiber.
Description
SCOPE OF THE INVENTION
The present invention relates generally to altering the mode field pattern
exhibited by single-mode optical fibers and more particularly to altering
the mode field pattern exhibited by optical fibers that are used in
optical storage drives.
BACKGROUND
In magneto-optical storage systems that use magneto-optical (MO) recording
material deposited on a rotating disk, information may be recorded on the
disk as spatial variations of magnetic domains. During readout, a magnetic
domain pattern modulates an optical polarization, and a detection system
converts a resulting signal from optical to electronic format.
In one type of a magneto-optical storage system, a magneto-optical head
assembly is located on an actuator that moves the head to position the
head assembly over data tracks during recording and readout. A magnetic
coil is used to create a magnetic field that has a magnetic component in a
direction perpendicular to the disk surface. A vertical magnetization of
polarity, opposite to that of the surrounding magnetic material of the
disk medium, is recorded as a mark indicating zero or a one by first
focusing a beam of laser light to form an optical spot on the disk. The
optical spot functions to heat the magneto-optical material to a
temperature near or above a Curie point (a temperature at which the
magnetization may be readily altered with an applied magnetic field). A
current passed through the magnetic coil orients the spontaneous vertical
magnetization either up or down. This orientation process occurs in the
region of the optical spot where the temperature is suitably high. The
orientation of the magnetization mark is preserved after the laser beam is
removed. The mark is erased or overwritten if it is locally reheated to
the Curie point by the laser beam during a time the magnetic coil creates
a magnetic field in the opposite direction.
Information is read back from a particular mark of interest on the disk by
taking advantage of the magnetic Kerr effect so as to detect a Kerr
rotation of the optical polarization that is imposed on a reflected beam
by the magnetization at the mark of interest. The magnitude of the Kerr
rotation is determined by the material's properties (embodied in the Kerr
coefficient). The sense of the rotation is measured by established
differential detection schemes and, depending on the direction of the
spontaneous magnetization at the mark of interest, is oriented clockwise
or counter-clockwise.
Conventional magneto-optical heads tend to be based on relatively large
optical assemblies which make the physical size and mass of the head
rather bulky (typically 3-15 mm in a dimension). Consequently, the speed
at which prior art magneto-optical heads are mechanically moved to access
new data tracks on a magneto-optical storage disk is slow. Additionally,
the physical size of the prior art magneto-optical heads limits the
spacing between magneto-optical disks. Because the volume available in
standard height disk drives is limited, magneto-optical disk drives have
not been available as high capacity commercial products.
N. Yamada (U.S. Pat. No. 5,255,260) discloses a flying optical head for
accessing an upper and lower surface of a plurality of optical disks. The
flying optical head disclosed by Yamada describes an actuating arm that
has a static (fixed relative to the arm) mirror or prism mounted thereon,
for delivering light to and receiving light from a phase-change optical
disk. While the static optics described by Yamada provides access to both
surfaces of a plurality of phase-change optical disks contained within a
fixed volume, Yamada is limited by the size and mass of the optics.
Consequently, the performance and the number of optical disks that can be
manufactured to function within a given volume is also limited.
Utilization of optical fibers to deliver light to a storage location within
an optical disk drive allows for a lower profile optical path which can
increase the number of disks that can be vertically positioned within a
given form factor. In a magneto-optical storage drive,
polarization-maintaining optical (PM) fiber is typically used to convey
laser light delivered by inexpensive laser diodes. The mode field that is
exhibited by single-mode optical fiber is typically circularly symmetric.
Because the mode field of a Fabry Perot laser diode is typically
asymmetric, the mode field mismatch may create optical inefficiencies that
result in a reduced signal to noise ratio in the detected data signal.
What is needed, therefore, is a method and apparatus that enables a laser
source exhibiting an asymmetric mode field to be used with polarization
maintaining optical fiber so as to efficiently convey light between a
laser source and a storage location of an optical data storage system.
SUMMARY
The present invention includes an optical apparatus for directing a laser
light exhibiting a first mode field along an optical path between a source
and a data storage location. The optical apparatus may comprise: a first
optical element, wherein the first optical element is disposed in the
optical path, wherein the first optical element exhibits a second mode
field; and a second optical element, wherein the second optical element is
disposed in the optical path, and wherein the second optical element
matches the first and second mode fields to each other. The first mode
field may comprise a asymmetric mode field. The second mode field may
comprise an symmetric mode field. The asymmetric mode field may be
elliptical. The symmetric mode field may be circular. The first optical
element may comprise a single mode polarization maintaining optical fiber.
The second optical element may comprise a multi-mode optical fiber or a
anamorphic prism. The source may comprise a Fabry Perot laser diode.
The present invention may also comprise a method for directing a laser
light along an optical path between a source and a data location that
comprise the steps of: providing a source of light that exhibits a first
mode field in the optical path; providing a first optical element that
exhibits a second mode field in the optical path; and matching the first
and second fields to each other by providing a second optical element in
the optical path.
In the present invention the coupling efficiency into an optical fiber is
maximized when a focused spot size and shape are matched to the size and
shape of the optical fiber mode field. The light emerging from a laser
diode is generally asymmetric (in that light diverges more quickly along
one axis of the beam), and if a simple lens is used to focus the laser
light without any beam-shaping optics, the focused spot is asymmetric as
well. In general, the mode field of a single-mode PM fiber is symmetric.
The present invention modifies the mode field of the single-mode PM fiber,
and generates an asymmetry that matches that of the focused spot in order
to achieve efficient coupling.
In the present invention, a short piece of multi-mode fiber is fusion
spliced to a single-mode PM fiber. (A longer piece of multi-mode fiber may
be used during splicing, and then cleaved back.) Typical lengths of the
multi-mode fiber piece vary between 50% and 100% of the cladding diameter,
and the operation of the invention does not depend critically on the exact
length.
In order to achieve efficient coupling, the light from a laser source
should be focused onto the splice between the multi-mode fiber piece and
the single-mode PM fiber. Because the fiber materials on either side of
the splice are nearly identical in refractive index, there is very little
light reflected back to the laser from the splice. This helps reduce
feedback into the laser, and reduces laser noise. The reflection from the
other end of the piece of multi-mode fiber is out of focus with respect to
the laser; most of the reflected light does not re-enter the laser cavity,
and does not significantly contribute to the laser noise.
In the present invention, it is possible to align the polarization axes of
the PM optical fiber while the optical fiber tip is being aligned to a
focused beam from the source. If the focused beam spot size and shape are
matched to the size and shape of the optical fiber mode field, then any
misalignment between the polarization axes of the optical fiber and the
polarization axis of the beam will show up as a loss in coupling
efficiency. If the coupling efficiency is maximized, then the optical
fiber polarization axes are automatically aligned to the beam, and a
time-consuming alignment step can be avoided. Thus, a simple coupling
efficiency measurement (optical power) replaces a complicated polarization
measurement.
DESCRIPTION OF THE FIGURES
In FIG. 1, there is seen a magneto-optical storage and retrieval system;
In FIG. 2, there is seen as part of the laser optics module a laser-optics
assembly;
In FIG. 3, there is seen as part of the optics module an optical switch;
In FIG. 4, there is seen that a single-mode PM optical fiber may exhibit a
circularly symmetric mode field pattern;
In FIG. 5, there is seen one embodiment of the present invention;
In FIG. 6, there is seen a second embodiment of the present invention; and
In FIG. 7, there is seen a multi-mode fiber spliced to a single-mode PM
fiber.
DESCRIPTION OF THE INVENTION
Referring in detail now to the drawings wherein similar parts of the
invention are identified by like reference numerals, there is seen in FIG.
1 a magneto-optical storage and retrieval system 100, generally
illustrated in a perspective view. In a preferred embodiment, the
magneto-optical (MO) data storage and retrieval system 100 includes a set
of Winchester-type flying heads 106 that are adapted for use with a set of
double-sided first surface MO disks 107 (one flying head for each MO disk
surface). The set of flying heads 106 are coupled to a rotary actuator
magnet and coil assembly 120 by a respective suspension 130 and actuator
arm 105 so as to be positioned over the surfaces of the set of MO disks
107. In operation, the set of MO disks 107 are rotated by a spindle motor
so as to generate aerodynamic lift forces between the set of flying MO
heads 106 and the set of MO disks 107 and to maintain the set of flying MO
heads 106 in a flying condition above the upper and lower surfaces of the
set of MO disks 107. The lift forces are opposed by equal and opposite
spring forces applied by the set of suspensions 130. During non-operation,
the set of flying MO heads 106 are maintained statically in a storage
condition away from the surfaces of the set of MO disks 107. System 100
further includes an optics module 103 and a set of single-mode
polarization maintaining (PM) optical fibers 102 coupled thereto. The
optical fibers 102 each have a proximal optics module end and a distal
head end.
Referring now to FIG. 2, there is seen as part of the laser optics module
103 a laser-optics assembly 101. In the present invention, the optics
module 103 of FIG. 1 comprises laser-optics assembly 101, which includes a
laser source 231, such as a Fabry Perot laser source of a variety that is
well known in the art. The laser-optics assembly 101 further includes:
collimating optics 234, a leaky beam splitter 232, and a coupling lens
233. The laser-optics assembly 101 directs a P polarized laser beam 291
from the laser source 231 through the leaky beam splitter 232 and coupling
lens 233, and towards an optical switch 304 (see FIG. 3). The laser-optics
assembly 101 also receives S and P polarization components of a reflected
laser beam 292 from the surface of a particular MO disk 107. The reflected
laser beam 292 is directed by the coupling lens 233 and is routed by the
leaky beam splitter 232 towards a differential detector comprising: a
polarizing beam splitter 239, a mirror 235, and a set of photo-diodes 236.
After conversion by the set of photo-diodes 236, the differential signal
is processed by the differential amplifier 237 and is output as signal
294. The differential detector detects orthogonal S and P polarization
components of the reflected laser beam 292, with a differential signal
being preferably a sensitive measure of polarization rotation induced by a
Kerr effect at the surface of the particular MO disk 107.
Referring now to FIG. 3, there is seen as part of the laser optics module
103 an optical switch 304. The optical switch 304 is disposed between the
set of optical fibers 102 and the laser optics-assembly 101 and is shown
in a representative optical path that includes one of the set of PM
optical fibers 102, one of the set of flying MO heads 106, and one of the
set of MO disks 107. The optical switch 304 provides sufficient degrees of
selectivity so as to direct the outgoing laser beam 291 towards a
respective proximal end of a particular optical fiber 102. The outgoing
laser beam 291 exits the distal end of the optical fiber 102 and is
directed through the flying MO head 106 onto a surface recording layer 349
of a respective MO disk 107.
During writing of information, the outgoing laser beam 291 lowers a
coercivity of the surface recording layer 349 by heating a selected spot
of interest 340 to approximately the Curie point of the MO recording layer
349. The optical intensity of outgoing laser beam 291 is held constant,
while a time varying vertical bias magnetic field is used to define a
pattern of "up" or "down" magnetic domains perpendicular to the MO disk
107. This technique is known as magnetic field modulation (MFM).
Alternatively, outgoing laser beam 291 may be modulated in synchronization
with the time varying vertical bias magnetic field at the spot of interest
340 in order to better control domain wall locations and reduce domain
edge jitter. Subsequently, as the selected spot of interest 340 cools at
the surface layer 349, information is encoded at the surface of the
respective spinning disk 107.
During readout of information, the outgoing laser beam 291 (at a lower
power compared to writing) is selectively routed to the MO disk 107 such
that upon its reflection from the spot of interest 340 the Kerr effect
causes a polarization state of the reflected laser beam 292 to be rotated
either clockwise or counter clockwise (as indicated with arrow 363). The
aforementioned optical path is bi-directional in nature. Accordingly, the
reflected laser beam 292 is received through the flying MO head 106 and
enters the distal end of the optical fiber 102. The reflected laser beam
292 is directed by the PM optical fiber 102 towards the optical switch 304
and is selectively routed by the optical switch 304 towards the
laser-optics assembly 101 for subsequent optical-to-electrical signal
conversion.
Referring now to FIG. 4, there is seen that single-mode PM optical fibers
102 exhibit a circularly symmetric mode field pattern. In the present
invention, it is desired to efficiently couple the laser beam 291 from the
laser source 231 into the PM optical fiber 102 and to maintain a
sufficient signal to noise ratio of the signal 294 while doing so. It is
well known in the art that a laser beam exhibiting a circularly symmetric
mode field that is directed into an optical fiber exhibiting a circularly
symmetric mode field, will emerge from the optical fiber exhibiting its
original circular symmetric mode field. However, it is also well known in
the art that the laser beam 291 from diode laser sources such a Fabry
Perot laser source may exhibit an asymmetric mode field, for example an
elliptic mode field. Because the mode field of a Fabry Perot laser source
is typically asymmetric, a mode field mismatch between the laser source
231 and the PM optical fibers 102 may be created and thus result in
optical inefficiencies and reduced signal to noise ratio in the detected
data signal 294. Because an increased signal to noise ratio is preferred,
it follows that the mode field of the laser beam provided by the laser
source 231 should be matched as closely as possible to the mode field of
the PM optical fiber 102.
The advantages of mode field matching and the resulting concomitant
efficient coupling include: (1) the ability to use a lower-power (and less
expensive) laser may for a given application, (2) the same laser may be
used at a lower operating power (and greater reliability), and (3) the
alignment tolerances of the system may be loosened, compared with the
inefficient coupling case.
Referring now to FIG. 5, there is seen one embodiment of the present
invention. In this embodiment, a collimated laser beam 291 from the laser
source 231 may be directed towards an anamorphic prism 545. The laser beam
291 emerging from the prism 545 is preferably compressed in By choosing a
proper compression ratio, the asymmetric mode field of the laser beam 291
emerging from the prism may be made circular in profile. Because the
circularly symmetric mode field of the resulting laser beam 291 is coupled
into the circularly symmetric mode field of the optical fiber 102 a
desired optical efficiency may be achieved.
Referring now to FIG. 6, there is seen a second embodiment of the present
invention. In the second embodiment, the laser beam 291 is brought to
focus by a lens 646 (or combination of lenses). Because the laser beam 291
from the laser source 231 exhibits an asymmetric mode field, the beam 291
is focused as a spot with an asymmetric mode field. In this embodiment,
however, the circularly symmetric mode field exhibited by the PM optical
fiber 102 is altered by coupling the proximal end of the PM optical fiber
102 to a short piece of multi-mode optical fiber. As described below, this
combination of optical fibers exhibits an asymmetric mode field that is
matched to that of the laser beam 291. As in the first embodiment, because
the mode field of the laser beam 291 matches the mode field of the optical
fiber combination conveying it, optical inefficiencies are reduced to
provide improved signal to noise ratio in the signal 294. In an exemplary
embodiment of the present invention, coupling efficiencies are improved
about 20%.
In typical polarization-maintaining fiber applications, the alignment of
the polarization axes of a PM optical fiber to a polarized laser beam is a
difficult process. Typical alignment steps may include analysis of the
polarization state of the transmitted beam, or analysis of the noise
induced by polarization degradation. These are time-consuming steps, and
are preferably avoided if possible.
In the present invention, it is possible to align the polarization axes of
the PM optical fiber 102 while the optical fiber tip is being aligned to
the beam 291. If the focused beam 291 spot size and shape are matched to
the size and shape of the optical fiber 102 mode field, then any
misalignment between the polarization axes of the optical fiber 102 and
the polarization axis of the beam 291 shows up as a loss in coupling
efficiency. If the coupling efficiency is maximized, then the polarization
axes of the optical fiber 102 can be automatically aligned to the beam
291, and a time-consuming alignment step may be avoided. Thus, a simple
coupling efficiency measurement (optical power) may replace a complicated
polarization measurement.
It is understood that the polarization axis of the optical fiber 102 may be
also aligned by a rotatable half-wave plate (not shown) inserted in the
optical path of the beam 291.
Referring now to FIG. 7, there is seen a multi-mode fiber spliced to a
single-mode PM fiber. In the second embodiment it has been identified that
if a short piece of multi-mode optical fiber 747 is spliced to the
proximal end of a single-mode PM optical fiber 102, the shape of the mode
field exhibited by the optical fiber 102 may be altered. Multi-mode fiber
is a type of fiber that is well known in the art. The techniques required
for spicing optical fibers to each other are also well known in the art.
In the second embodiment, it has been identified that in the process of
splicing the multi-mode optical fiber 747 to the PM optical fiber 102, the
stress pattern in the fiber core of the PM optical fiber 102 is affected
such that mode field at the junction of the spliced optical fiber
combination is asymmetric, that little if any attenuation is introduced,
and that the polarization preserving qualities of the PM optical fiber 102
are minimally unaffected. Once the laser beam 291 from the laser source
231 propagates past the adiabatic taper region of the splice, the mode
field pattern is altered to be symmetric again, and the laser beam 291
exits the distal end of the optical fiber 102, 747 with a circular mode
field. Measurements have shown that the aspect ratio of the resulting
asymmetric mode field at the splice can be as made large as 3:1 and that
this ratio may be adjusted by changing the temperature during splicing,
such as with a fusion splice of a variety well known in the art.
In the second embodiment, by aligning the asymmetric mode field of the
laser beam 291 from the laser source 231 with the asymmetric mode field of
the PM and multi-mode optical fiber 102, 747 combination, improved
efficiency may be achieved. Because the apparent asymmetry of the optical
fiber 102, 747 combination arises from the fusion splice itself, it may be
possible to produce the same effect by altering the fiber drawing process.
If the fiber draw rate is changed during the drawing process, it may
change the apparent size of the mode field to produce a similar asymmetric
effect.
In typical fiber applications (in which there is no splice), the end of the
optical fiber is anti-reflection coated, but there is usually a finite
reflection into a cavity of the laser; this causes laser noise. In the
present invention as described above, a short piece of multi-mode fiber
747 is fusion spliced to a single-mode PM fiber 102. (A longer piece of
multi-mode fiber may be used during splicing, and then cleaved back.)
Typical lengths of the multi-mode fiber piece vary between 50% and 100% of
the cladding diameter. In order to achieve further efficient coupling, the
light from the laser 231 should be focused onto the splice between the
multi-mode fiber 747 and the single-mode PM fiber 102. Because the fiber
materials on either side of the splice are nearly identical in refractive
index, there is very little light reflected back to the laser from the
splice. This helps reduce feedback into the laser 231, and reduces laser
noise. The reflection from the other end of the piece of multi-mode fiber
747 is out of focus with respect to the laser 231; most of the reflected
light does not re-enter the laser cavity, and thus does not significantly
contribute to the laser noise.
While the present invention has been described in that of a magneto-optical
drive context, it is understood that the concepts described herein are
applicable to other technologies including communications and
telecommunications.
Thus, it is to be understood that the above description is illustrative
only and not limiting of the disclosed invention. It will be appreciated
that it would be possible to modify the size, shape and appearance and
methods of manufacture of various elements of the invention or to include
or exclude various elements and still remain within the scope and spirit
of this invention.
* * * * *
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