![[US Patent & Trademark Office, Patent Full Text and Image Database]](/netaicon/PTO/patfthdr.gif)
| United States Patent |
6,301,420
|
|
Greenaway
, et al.
|
October 9, 2001
|
Multicore optical fibre
Abstract
An optical fiber for transmitting radiation comprising two or more core
regions, two or more core regions, each core region comprising a
substantially transparent core material and having a core refractive
index, a core length, and a core diameter, wherein said core regions are
arranged within a cladding region, said cladding region comprising a
length of first substantially transparent cladding material, having a
first refractive index, wherein said first substantially transparent
cladding material has an array of lengths of a second cladding material
embedded along its length, wherein the second cladding material has a
second refractive index which is less than said first refractive index,
such that radiation input to said fiber propagates along at least one of
said core regions. The cladding region and the core regions may be
arranged such that radiation input to said optical fiber propagates along
one or more said lengths of said core regions in a single mode of
propagation. The optical fiber may be used as a bend sensor, a spectral
filter or a directional coupler. The invention also relates to a method of
manufacturing a multicore optical fiber.
| Inventors:
|
Greenaway; Alan H. (Malvern, GB);
Lloyd; Peter A. (Farnborough, GB);
Birks; Timothy A. (Claverton Down, GB);
Russell; Philip S. (Claverton Down, GB);
Knight; Jonathan C. (Claverton Down, GB)
|
| Assignee:
|
The Secretary of State for Defence in Her Britannic Majesty's Government of (Farnborough, GB)
|
| Appl. No.:
|
070747 |
| Filed:
|
May 1, 1998 |
| Current U.S. Class: |
385/126; 65/409; 65/411; 385/115; 385/123 |
| Intern'l Class: |
G02B 006/02; C03B 037/15 |
| Field of Search: |
385/123,124,125,126,121,115,116
359/332
65/385,409,410,411,412
|
References Cited [Referenced By]
U.S. Patent Documents
| 4300816 | Nov., 1981 | Snitzer et al. | 384/126.
|
| 5155792 | Oct., 1992 | Vali et al. | 385/125.
|
| 5321257 | Jun., 1994 | Danisch | 250/227.
|
| 5802236 | Sep., 1998 | DiGiovanni et al. | 385/127.
|
| 5805751 | Sep., 1998 | Kewitsch et al. | 385/43.
|
Other References
Birks et al., "Full 2-D Photonic Bandgaps in Silica/Air Structures",
Electronic Letters, vol. 31 (22), p. 1942 (Oct. 1995).
|
Primary Examiner: Sanghavi; Hemang
Attorney, Agent or Firm: Nixon & Vanderhye P.C.
Claims
What is claimed is:
1. A multicore optical fibre for transmitting radiation comprising:
two or more core regions, each core region comprising a substantially
transparent core material and having a core refractive index, a core
length, and a core diameter, wherein said core regions are arranged within
a cladding region,
said cladding region having an effective index of refraction and comprising
a length of first substantially transparent cladding material, having a
first refractive index, wherein said first substantially transparent
cladding material has an array of lengths of a second cladding material
embedded along its length, wherein said second cladding material has a
second refractive index which is less than said first refractive index,
said core regions having a refractive index greater than said cladding
region and said core regions and said cladding region arranged to
propagate radiation input to said fibre along at least one of said core
regions by the principle of total internal reflection.
2. The fibre of claim 1, wherein said cladding region and said core regions
are arranged such that radiation input to said fibre propagates along at
least one of said core regions in a single mode of propagation.
3. The fibre of claim 1, wherein each of said core regions comprise the
same core material.
4. The fibre of claim 1 wherein said first substantially transparent
cladding material has a substantially uniform first refractive index.
5. The fibre of claim 1 wherein one or more of said core materials has a
substantially uniform core refractive index.
6. The fibre of claim 1, wherein said first substantially transparent
cladding material and said core materials are substantially the same.
7. The fibre of claim 1, wherein at least one of said first substantially
transparent cladding material and one of said core materials are silica.
8. The fibre of claim 1 wherein said array of lengths of said second
cladding material are an array of holes embedded along said length of said
first substantially transparent cladding material.
9. The fibre of claim 8 wherein said holes are a vacuum.
10. The fibre of claim 1 wherein said second cladding material is air.
11. The fibre of claim 1 wherein said second cladding material is a liquid.
12. The fibre of claim 1 wherein said second cladding material is a
substantially transparent material.
13. The fibre of claim 1 wherein said substantially transparent core
material of at least one of said core regions comprises a dopant.
14. The fibre of claim 1 wherein at least one of said first or second
cladding material comprises a dopant.
15. The fibre of claim 1, wherein said second cladding material comprises
an amount of the first cladding material.
16. A bend sensor comprising the multicore photonic crystal fibre of claim
1.
17. A directional coupler comprising the multicore photonic crystal fibre
of claim 1.
18. A spectral filter comprising the multicore photonic crystal fibre of
claim 1.
19. A method of manufacturing a multicore optical fiber comprising the
steps of:
(i) forming a fibre preform by arranging a plurality of composite rods in
an array, each of said rods comprising a first substantially transparent
cladding material, having a first refractive index, and each of said rods
having a length, wherein said rods have an array of lengths of a second
cladding material embedded along said rod lengths, wherein said second
cladding material has a second refractive index which is less than said
first refractive index,
(ii) arranging at least two rods comprising a substantially transparent
core material within said fibre preform, said core material having a
refractive index greater than said fibre preform and
(ii) drawing said fibre preform in fibre drawing apparatus to form said
multicore optical fibre wherein said core material and said first and
second cladding materials are arranged to propagate radiation input to
said fibre by the principle of total internal reflection.
Description
BACKGROUND OF THE INVENTION
1. Field of the Invention
The invention relates to an optical fibre having at least two cores for
propagating radiation. The invention also relates to a method of making
such a fibre.
2. Discussion of Prior Art
Optical fibres with two cores have been reported and applied to various
problems in optical sensing and telecommunications. The potential of
multicore fibres with more than two single-mode cores has also been
recognized [S. Prasad: "Focusing light into a multiple-core fiber II
application to ground-based interferometry", Optics Communications 115
(1995) 368-378]. For example, bend sensing in the plane has been
demonstrated using a four-core fibre, using a technique that can readily
be extended to the monitoring of bending in three dimensions [M. J. Gander
et al., "Bend measurements using multicore optical fiber", presented at
OFS 12 1997 ].
However, at present there are relatively few applications for multicore
optical fibres. This is because it is very difficult to make multicore
fibres with the required uniformity and geometrical accuracy. One way
which has been reported is to use an extension of the process previously
used to make two-core fibres. In this method, single-core preforms made by
standard vapour-phase techniques are precisely machined and are then
assembled to form a multicore preform. The multicore preform is then drawn
into fibre [G. Le Noane et al., "Ultra high density cables using a new
concept of bunched multicore monomode fibers: A key for future FTTH
networks", Proceedings of the International Wire & Cable Symposium (1994)
203-210]. This process, starting from a number of single core preforms, is
a time-consuming and costly process. Furthermore, the addition of each
extra core adds further complexity to the multicore preform. Higher
multiplicity core fibres are therefore increasingly difficult to
fabricate.
A single-mode photonic crystal fibre (PCF) is described by J. C. Knight et
al., "All silica single-mode optical fiber with photonic crystal
cladding", Optics Letters 21 (1996) 1547-1549 and is of relevance to the
present invention.
SUMMARY OF THE INVENTION
The present invention relates to a multicore optical fibre which can be
made more easily than known multicore fibre and each core of which is
capable of transmitting radiation in a single mode of propagation.
According to the present invention, a multicore optical fibre for
transmitting radiation comprises;
two or more core regions, each core region comprising a substantially
transparent core material and having a core refractive index, a core
length, and a core diameter, wherein said core regions are arranged within
a cladding region, said cladding region comprising a length of first
substantially transparent cladding material, having a first refractive
index, and wherein said first substantially transparent cladding material
has an array of lengths of a second cladding material embedded along its
length, wherein said second cladding material has a second refractive
index which is less than said first refractive index,
such that radiation input to said fibre propagates along at least one of
said core regions.
This provides an advantage over known multicore fibre in that, in the
preform, the core regions may be automatically positioned in the precise
geometry required without the need for accurate machining and assembly of
single-core preforms. In addition, each core region may be single mode
over a wide wavelength range.
The cladding region and the core regions may be arranged such that
radiation input to the fibre propagates along at least one of the core
regions in a single mode of propagation.
The first substantially transparent cladding material may have a
substantially uniform first refractive index. One or more of the core
materials may have a substantially uniform core refractive index. Each of
the core regions may comprise the same core material. The first
substantially transparent cladding material and the core materials may be
substantially the same. In a preferred embodiment, at least one of the
first substantially transparent cladding material and one of the core
materials may be silica.
The array of lengths of the second cladding material may be an array of
holes embedded along the length of the first substantially transparent
cladding material. The holes may be a vacuum. Alternatively, the second
cladding material may be air, liquid or a substantially transparent
material. The substantially transparent core material of at least one of
the core regions may comprise a dopant. At least one of the first or
second cladding material may comprise a dopant. The second cladding
material may comprise an amount of the first cladding material.
According to another aspect of the invention, a bend sensor comprises the
multicore photonic crystal fibre of the present invention.
According to another aspect of the invention, a directional coupler
comprises the multicore photonic crystal fibre of the present invention.
According to another aspect of the invention, a spectral filter comprises
the multicore photonic crystal fibre of the present invention.
According to another aspect of the invention, a method of manufacturing a
multicore optical fibre comprises the steps of;
(i) forming the fibre preform by arranging a plurality of composite rods in
an array, each of said rods comprising a first substantially transparent
cladding material, having a first refractive index, and each of said rods
having a length, wherein said rods have an array of lengths of a second
cladding material embedded along said rod lengths, wherein said second
cladding material has a second refractive index which is less than said
first refractive index,
(ii) arranging at least two rods comprising a substantially transparent
core material within said fibre preform, and
(ii) drawing said fibre preform in fibre drawing apparatus to form said
multicore optical fibre.
BRIEF DESCRIPTION OF THE DRAWINGS
The invention will now be described, by example only, with reference to the
following figures in which;
FIG. 1 shows the construction of a three-core photonic crystal fibre,
FIG. 2 shows a schematic end-view diagram illustrating the arrangement used
to make a six-core fibre,
FIG. 3 shows an optical micrograph of a three-core fibre,
FIG. 4 shows the far field pattern emerging from the end of a three-core
fibre when all three cores are illuminated,
FIG. 5 shows an example of a directional coupler device comprising
multicore photonic crystal fibre of the present invention and
FIG. 6 shows an example of a spectral filter comprising multicore photonic
crystal fibre of the present invention.
DETAILED DISCUSSION OF PREFERRED EMBODIMENTS
Single-core photonic crystal fibre is made by a stack and draw process as
described by J. C. Knight et al., "All silica single-mode optical fiber
with photonic crystal cladding", Optics Letters 21 (1996) 1547-1549. The
fibre comprises a cladding of an array of air holes that run along the
length of the fibre. The holes are arranged in a hexagonal honeycomb
pattern across the cross-section, with a spacing of the order of microns.
Such a repeating structure with a period of the order of an optical
wavelength is called a photonic crystal. However, the central hole is
absent, leaving a solid silica "defect" in the crystal structure that acts
as the core of the fibre. Light is guided in this core by total internal
reflection from the cladding, which effectively has a lower refractive
index. The effective index of the photonic crystal cladding has unusual
properties that can enable the fibre to be single-mode under all
circumstances, unlike conventional step-index fibres. This property is
governed by the size of the air holes.
The present invention relates to a multicore photonic crystal fibre. The
fibre has a photonic crystal structure but instead of having a single
central defect it has two or more defects introduced throughout the
structure. Despite the complex structure, the multicore fibre is
relatively simple to construct, and higher multiplicity core structures
are as easy to fabricate as less complex two or three core structures.
FIG. 1 shows a multicore photonic crystal fibre preform 1. This illustrates
the structure of a multicore photonic crystal when drawn into a fibre,
referred to generally as 10. The preform 1 may be made by stacking
substantially identical capillary rods 2 in an array. A number of the rods
2 in the array are replaced, at appropriate sites, with substantially
solid or substantially filled rods 3 of the same diameter as the rods 2.
The substantially solid or substantially filled rods 3 shall be referred
to as "cores" or "core regions". In the example shown in FIG. 1, the
preform used to make the fibre has three cores 3 arranged at the corners
of the equilateral triangle. The fibre 10 can then be drawn from this
preform 1 in conventional fibre drawing apparatus, such as a fibre drawing
tower. The resultant fibre remains stable, despite undergoing extreme
deformation and high temperatures during the drawing process.
The rods 2 comprise a first cladding material, having a first refractive
index, which is substantially transparent and is capable of being drawn
into a fibre. The rods 2 form a cladding region around the cores 3.
Typically, this first cladding material may be silica. Embedded along
their length the rods 2 have a second cladding material of a second
refractive index, the second refractive index being less than the first
refractive index. The cores 3 comprise a substantially transparent core
material and are arranged within the cladding region.
Typically, the rods 2 may be rods of silica. The rods may be hollow (i.e.
the second cladding material is air or a vacuum) or may be substantially
solid. By way of example, in preform state hollow rods 2 may have an
external diameter of between 0.5 mm and 2 mm and an internal diameter
between 0.5 mm and 1.8 mm. The length of the rods can be chosen to suit
the particular application for which the fibre is required. The stack
typically has ten or so rods 2 along each hexagonal edge and the stack
will still sit comfortably inside the furnace on a fibre drawing tower.
Preferably, the array of rods may be a hexagonal arrangement. In the final
state, the drawn fibre 10 may typically have a hole spacing of between 1
.mu.m to 10 .mu.m and a hole diameter of 0.1 .mu.m to 0.3 .mu.m.
The second cladding material within the rods 2 may be air-filled holes.
Alternatively, the second cladding material within the rods 2 may be
vacuum region (a vacuum having a refractive index less than that of the
first cladding material). Alternatively, the rods may be filled with any
material which has a lower refractive index than that of the first
cladding material (i.e. the material from which the rods are formed) and
is also capable of being drawn into a fibre, or the rods may be filled
with any such material which may be inserted into the rods after they have
been drawn to their small size. For example, the rods may be filled with
air or another gas (e.g. hydrogen or hydrocarbon), a solid material (e.g.
a different glass material having a different refractive index from that
of the first cladding material) or a liquid (e.g. water, aqueous solutions
or solutions of dyes). The rods may also be partially filled with an
amount of the first cladding material. The second cladding material within
the holes need not necessarily be transparent.
The core material may be any substantially transparent material but need
not necessarily be the same material as the first cladding material. In
one embodiment, the multicore PCF may be made entirely from undoped fused
silica so that the rods 2 are hollow silica rods and the cores 3 are
formed by solid rods of silica. The complete structure may therefore be
made entirely from fused silica.
Each of the cores may be formed from a different material and have
different propagation properties. Any one of the cores may be doped with a
dopant material, for example erbium or other rare earth elements.
Alternatively, or in addition, any one of the cores may be doped with a
material which will change the refractive index or make the glass
photosensitive, for example Boron or Germanium. It is also possible to
dope the cladding region (i.e. the first or second cladding material) with
any of the above mentioned materials.
FIG. 2 shows a schematic diagram of the end view of an arrangement of tubes
and rods used to make a six-core multicore PCF. The preform had six cores
3 arranged at the corners of a hexagon. The preforms can then be drawn
down into low-loss six-core fibre, as described above.
By varying the extent to which the rods collapse during fibre drawing
process, the cores may be made single-mode if required. The cores may also
be close enough together for directional coupling to take place between
them. A good approximation to the coupling beat length L.sub.B between two
PCF cores is given by the expression:
##EQU1##
which is based on the effective V-value discussed by T. A. Birks et al.,
"Endlessly single mode photonic crystal fiber", Optics Letters 22 91997)
961-963 and adapted from a well-known expression for two coupled
step-index cores [A. W. Snyder and J. D. love, "Optical waveguide Theory",
Chapman and Hall, London (1983)]. W and U are the familiar normalized
parameters of a step-index fibre with the same V, n.sub.0 is the index of
silica K.sub.1 is the modified Bessel function, and D is the separation of
the cores in multiples of .LAMBDA. (.LAMBDA. is the hole spacing).
For the six-core fibre shown in FIG. 2, having a hole spacing in the drawn
fibre of 2.5 .mu.m and a hole diameter of 0.3 .mu.m, the equation predicts
a two-core beat length of about 6 mm. This order of magnitude has been
confirmed by spectral coupling measurements.
FIG. 3 shows an optical micrograph of a three-core fibre (as shown in FIG.
1). The hole spacing is approximately 2.5 .mu.m after the fibre has been
drawn. Here, the cores are spaced far enough apart for Equation (1) to
predict that there is no directional coupling between them. Measurements
show this was the case. Hexagonally symmetric single mode patterns 10 can
be seen at each core. Light could be independently launched in any or all
of the cores.
The far field pattern emerging from the fibre shown in FIG. 3 with all
three cores illuminated is shown in FIG. 4. A three-wave interference
fringe pattern modulating a single-core PCF far field pattern is evident.
The fringe pattern moves when the fibre is bent in different ways part-way
along its length. The multicore fibre therefore has an application as a
bend sensor, whereby measurement of the relative shift in the fringe
pattern provides an indication of the extent by which the fibre is bent.
If the fibre is embedded in a structure, this therefore provides an
indication of the extent to which the structure is bent.
Compared to known multicore fibres, the multicore PCF provides the
advantage that, during fabrication, the core regions may be automatically
positioned in the precise geometry required, without the need for accurate
machining and assembly of single-core preforms. During the fabrication
process, the multicore photonic crystal preform (as shown in FIG. 1) is
drawn on a fibre drawing tower inside a furnace. Despite the high
fabrication temperatures required to draw the fibre, and the drawing down
of the preform to such small scales, the resultant fibre is stable with
core regions retaining the precise positions of the single preform. Hence,
multicore photonic crystal fibres can be fabricated more easily than
conventional mulitcore fibres. Furthermore, fibres with a high number of
cores can be made as easily and as reliably as fibres with just two or
three cores. Other stacking geometries may be adopted, for example
rectangular, by choosing an appropriate shape for stacking the rods. A
further advantage of the invention is that the raw materials from which
the preforms are made may be ordinary silica capillary rods or tubes. It
is not therefore necessary to make or otherwise procure any single-core
preforms as is the case for conventional multicore fibres. In addition,
fibres with cores coupled to different (or varying) extents can be drawn
from just one preform.
Another significant advantage is that each individual core can be
guaranteed to be single-mode at all wavelengths if required. The absence
of core dopants removes the problem of colour centre formation and
darkening that is a feature of conventional doped fibres, and makes
possible the transmission of high blue/green laser powers without
degradation.
The individual cores can be made to support a single mode or several modes
by changing the temperature at which the fibre is drawn, which controls
the internal diameter of the rods. Likewise, coupling (if any) between the
cores is determined by the drawing temperature as well as by the locations
of the cores. This structure offers the opportunity to study the coupling
between a possibly large number of cores under a variety of conditions.
For example, the fibre may also be used as a directional coupler device.
By way of example, FIG. 5 illustrates an example of part of a directional
coupler device 20 comprising multicore photonic crystal fibre of the
present invention, whereby input radiation 21 is input to core 3a and is
output (22) from both cores 3b and 3c.
Furthermore, the multicore fibre has applications in optical sensing, for
example as a bend sensor. The fibre may also be used to provide several
transmission lines within one structure, all of which may be single mode,
which may be used to transmit different signals through different lines,
for example in communications applications. As the cores within the fibre
can also be made to interact, the fibre can be arranged to provide a
filter, such that only radiation of certain wavelengths is transmitted to
a particular core. By way of example, FIG. 6 shows an illustration of an
example spectral filter device 30 comprising multicore photonic crystal
fibre of the present invention, whereby radiation 31 comprising wavelength
components .lambda..sub.1 and .lambda..sub.2 is input to core 3d and
radiation 32, 33, having wavelengths .lambda..sub.1 and .lambda..sub.2
respectively, is output from cores 3d and 3e respectively.
Further types of filter devices, for example grating assisted couplers,
become possible if at least one of the cores is photosensitive and one or
more Bragg gratings are written in the fibre, for example by exposure to
ultra violet light.
* * * * *
![[Image]](/netaicon/PTO/image.gif)
![[Home]](/netaicon/PTO/home.gif)
![[Boolean Search]](/netaicon/PTO/boolean.gif)
![[Manual Search]](/netaicon/PTO/manual.gif)
![[Number Search]](/netaicon/PTO/number.gif)
![[Help]](/netaicon/PTO/help.gif)
![[Bottom]](/netaicon/PTO/bottom.gif)
![[View Shopping Cart]](/netaicon/PTO/cart.gif)
![[Add to Shopping Cart]](/netaicon/PTO/order.gif)
![[Top]](/netaicon/PTO/top.gif)