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| United States Patent |
5,943,124
|
|
Haigh
|
August 24, 1999
|
Monitoring of an optical line
Abstract
An optical line system comprises: (1) an optical fiber that includes a
plurality of reflectors, for example Bragg gratings, located at different
positions along the optical fiber; and (2) a monitoring arrangement
located in the region of one end of the optical fiber for monitoring the
system by an optical reflectometry method in which light is reflected by
the reflectors. The system is characterized in that at least two of the
reflectors have reflectivities that differ from one another, the reflector
that is more distant from the monitoring arrangement having a higher
reflectivity than the Bragg grating that is nearer to the monitoring
arrangement. Preferably the reflectivities of the reflectors increases as
the distance from the monitoring arrangement increase, the reflectivities
preferably having the relationship (1) R.sub.n-1 -(2T.sup.2
R.sub.n+1)-(1+4T.sub.2 R.sub.n)1/2/2T.sup.2 R.sub.n where: R.sub.n is the
reflectivity of the n th relector from the monitoring arrangement,
R.sub.n-1 is the reflectivity of the (n-1)th reflector from the monitoring
arrangement, and T is the transmission coefficient of any branch that may
be present between the (n-1)th and the n th reflector (and is unity if no
such branch exists). Such a system has the advantage that the
signal-to-noise ratio of different reflectors is reduced.
| Inventors:
|
Haigh; Neil Richard (Wirral, GB)
|
| Assignee:
|
BICC Public Limited Company (London, GB)
|
| Appl. No.:
|
077985 |
| Filed:
|
October 27, 1998 |
| PCT Filed:
|
December 19, 1996
|
| PCT NO:
|
PCT/GB96/03126
|
| 371 Date:
|
October 27, 1998
|
| 102(e) Date:
|
October 27, 1998
|
| PCT PUB.NO.:
|
WO97/24821 |
| PCT PUB. Date:
|
July 10, 1997 |
Foreign Application Priority Data
| Current U.S. Class: |
356/73.1; 385/37 |
| Intern'l Class: |
G01N 021/41 |
| Field of Search: |
356/73.1
385/37,12
359/130
|
References Cited [Referenced By]
U.S. Patent Documents
Primary Examiner: Kim; Robert H.
Assistant Examiner: Nguyen; Tu T.
Attorney, Agent or Firm: Nath & Associates, Nath; Gary M.
Claims
I claim:
1. An optical line system which comprises:
(i) an optical fibre that includes a plurality of reflectors (G, 50, 51,
51', 52, 52', 53, 53') located at different positions along the optical
fibre; and
(ii) a monitoring arrangement (56) located in the region of one end of the
optical fibre for monitoring the system by an optical reflectometry method
in which light is reflected by the reflectors:
characterised in that at least two of the reflectors have reflectivities
that differ from one another, the reflector (G.sub.n) that is more distant
from the monitoring arrangement having a higher reflectivity than the
reflector (G.sub.n+1) that is nearer to the monitoring arrangement, so as
to give a generally constant signal-to-noise ratio of the reflected light
received by the monitoring arrangement.
2. A system as claimed in claim 1, in which the optical fibre includes at
least three reflectors (G) whose reflectivites increase in order of
distance from the monitoring arrangement.
3. A system as claimed in claim 2, wherein the difference between the
reflectivities of adjacent reflectors (G) increases in order of distance
from the monitoring arrangement.
4. A system as claimed in claim 1, which has no branches between the
penultimate reflector and the last reflector, and the penultimate
reflector has a reflectivity in the range of from 0.3 to 0.5 times the
reflectivity of the last reflector.
5. A system as claimed in claim 1, which includes a 2:1 branch (44, 46, 48)
between the penultimate reflector and the last reflector, and the
penultimate reflector has a reflectivity in the range of from 0.1 to 0.25
times the reflectivity of the last reflector.
6. A system as claimed in claim 1, wherein the optical fibre includes at
least three reflectors (G) whose reflectivities substantially are based on
the relationship (I):
##EQU4##
where: R.sub.n is the reflectivity of the n th reflector (G.sub.n) from
the monitoring arrangement,
R.sub.n-1 is the reflectivity of the (n-1)th reflector (G.sub.n-1) from the
monitoring arrangement, and
T is the transmission coefficient of any branch (44, 46, 48) that may be
present between the (n-1)th and the n th reflector (and is unity if no
such branch exists).
7. A system as claimed in claim 1, wherein the optical fibre includes at
least 20 reflectors (G), at least the three reflectors closest to the
monitoring arrangement having substantially the same reflectivities.
Description
This invention relates to optical line systems, and in particular, optical
line systems that are monitored. Such systems include, for example,
optical networks for telecommunications purposes which are monitored for
damage or deterioration, and optical sensor lines and networks which are
monitored to obtain information about some parameter such as temperature
or strain.
In such systems, it has been proposed to incorporate reflectors so that the
system can be monitored by a reflectometry method such as optical time
domain reflectometry (OTDR), optical frequency domain reflectometry (OFDR)
and the like. Examples of such systems are described in WO-A-90/06498 and
GB-A-2,280,326. WO-A-90/06498 describes an OTDR method for detecting
losses in a passive optical network (PON) that includes a number of
partial reflectors such as gratings at different positions along its
length. GB-A-2,280,326 describes a method of providing the integrity of
optical paths in an optical system, comprising sending an amplitude
modulated diagnostic signal into the system. A number of gratings in the
system produce a pattern of time spaced echoes unique to the particular
part of the system. However, one problem that exists with such systems is
the fact that the signal to noise ratio is not the same for all the
reflectors, especially if the line system contains a number of branches,
and the system may not have sufficient dynamic response to obtain clear
signals from the reflectors, especially from those reflectors remote from
the reflectometer.
According to the present invention, there is provided an optical line
system which comprises:
(i) an optical fibre that includes a plurality of reflectors located at
different positions along the optical fibre; and
(ii) a monitoring arrangement located in the region of one end of the
optical fibre for monitoring the system by an optical reflectometry method
in which light is reflected by the reflectors:
characterised in that at least two of the reflectors have reflectivities
that differ from one another, the reflector that is more distant from the
monitoring arrangement having a higher reflectivity than the reflector
that is nearer to the monitoring arrangement, so as to give a generally
constant signal-to-noise ratio of the reflected light received by the
monitoring arrangement.
Normally the optical fibre will contain more than two reflectors, for
example three or more in relatively simple systems but in other systems it
may contain significantly higher numbers e.g. at least ten reflectors or
even twenty or more reflectors. In such systems the reflectivities of the
reflectors preferably increase in order of the distance from the
monitoring arrangement, and most preferably not only do the reflectivities
increase but also the difference between the reflectivities of adjacent
reflectors increases in order of distance from the monitoring arrangement.
The line system according to the invention has the advantage that, by
increasing the reflectivities of the reflectors at the remote end of the
optical fibre the signal-to-noise ratio of the signals received at the
monitoring arrangement is significantly improved for those reflectors, and
so the difference between the signal-to-noise ratio of the reflectors
nearest the monitoring arrangement and the reflectors farthest from the
monitoring arrangement is reduced. In view of the reduction in variation
of intensity of the reflected signals, it is possible to set upper and/or
lower threshold values for the reflected signals thereby eliminating or
reducing crosstalk arising from secondary reflections occurring between
reflectors.
The particular form in which the reflectivities of the reflectors are
distributed along the optical fibre will depend, among other things, on
the configuration of the line system, and especially on whether and to
what extent it is branched. It is shown below that if one neglects
Rayleigh backscattering from the optical fibre, a substantially constant
signal-to-noise ratio is obtained from the reflectors in the optical line
system if the reflectivities of the reflectors are based on the
relationship:
##EQU1##
Where: R.sub.n is the reflectivity of the n th reflector from the
monitoring arrangement;
r.sub.n-1 is the reflectivity of the (n-1)th reflector from the monitoring
arrangement,
T is the transmission coefficient of any branch that may be present between
the (n-1)th and the n th reflector (and is unity if no such branch
exists).
In the case of a system which has no branches between the last two
reflectors, the most remote Bragg grating may have a reflectivity of about
100%, that is to say it will reflect substantially the entire monitoring
signal, in which case the penultimate reflector preferably has a
reflectivity in the range of 0.3 to 0.5 times that of the last reflector
and especially from 0.35 to 0.45 times that of the last reflector. In such
a system the antepenultimate reflector preferably has a reflectivity in
the range of 0.2 to 0.25 times that of the last reflector (if no
intervening branch exists). In such systems in which the transmission
coefficient T in the formula (I) above is unity, the relationship can be
expanded as a power series:
R.sub.n-1 =R.sub.n -2R.sub.n.sup.2 +5R.sub.n.sup.3 II
For all the reflectors apart from the last two or three the values for the
reflectivity are sufficiently small for the series to converge rapidly,
and it is often an acceptably close approximation to the formula (I) for
the reflectivities of the closest reflectors to be equal to one another,
i.e. to set
R.sub.n-1 =R.sub.n III
For example, for all reflectors of reflectivity of 0.1 or less, formula III
would give a variation in signal-to-noise ratio of not more than 20%,
while for reflectors of reflectivity of 0.02 or less, the variation would
be not more than 4%. Thus a system may comprise an optical fibre having a
large number of reflectors arranged along its length of generally equal
reflectivity, e.g. from 1 to 5%, while the three or four reflectors most
remote from the monitoring equipment have increasing reflectivities. In
the case of branched systems, for example telecommunications networks such
as passive optical networks (PONs) in which an optical fibre has a number
of branches between a head end and a number of end users, the difference
between the reflectivity of adjacent reflectors will need to be yet
greater. Thus, for example, if the system includes a 2:1 branch between
the penultimate reflector and the last reflector, the penultimate
reflector will typically have a reflectivity in the range of from 0.1 to
0.25, and especially from 0.15 to 0.2 times that of the last reflector.
Preferably the, or at least some of the reflectors are passive optical
reflectors which reflect part of the pulse at a defined wavelength or
range of wavelengths. A reflector may comprise a cleaved end of a fibre,
or a mirror (especially if it is the reflector farthest from the
monitoring arrangement) a tunable filter e.g. an acousto optic tunable
filter or a grating. Advantageously at least some of the gratings are
Bragg gratings formed within the optical fibre (preferably a single-mode
optical fibre). Such gratings may be formed by exposing the optical fibre
to beams of ultraviolet radiation that vary in intensity or which
interfere with one another so as to generate a periodic variation of
refractive index of the fibre core along its length. The gratings may be
formed by a number of methods for example by a light induced method as
described in U.S. Pat. No. 4,474,427, a two-beam interferametry method as
described in international patent application No. WO 86/01303 or a phase
mask method as described in U.S. Pat. No. 5,367,588, the disclosures of
which are incorporated herein by reference. Thus for example in one
arrangement, all the reflectors other than the most remote reflector from
the monitoring arrangement may comprise Bragg gratings, and the most
remote reflector may comprise a mirror, while in another arrangement all
the reflectors may comprise Bragg gratings. The reflectivities of the
gratings may be set by adjusting the material of the optical fibre, the
degree of irradiation with ultraviolet light or the length of the grating
(or by any combination thereof). Such gratings may be classified as type I
or type II gratings in which type II gratings generally exhibit higher
reflectivities, however they are characterised by a degree of damage to
the core/cladding interface of the fibre. Type II gratings generally
exhibit poorer transmission properties than type I gratings but may only
need only be employed as the grating that is most remote from the
monitoring arrangement, all the other gratings being type I.
Various optical line systems according to the present invention will now be
described by way of example with reference to the accompanying drawings in
which:
FIG. 1 shows a segment of an optical line system spanning two Bragg
gratings;
FIG. 2 shows schematically a linear optical line system according to the
invention;
FIG. 3 is a graphical representation of the reflectivities of the gratings
along one line system according to the invention; and
FIG. 4 shows an optical line system having a different topology which may
be employed in a passive optical network.
Referring to the accompanying drawings, FIG. 1 shown schematically part of
an optical line system comprising the n th Bragg grating G.sub.n from the
monitoring apparatus and the (n-1)th grating G.sub.n-1 from the monitoring
apparatus, the two gratings having a splitter S located therebetween. In
the simplest case of a linear system, i.e. one in which the splitter S
does not exist, if the intensity of the monitoring signal occurring at
point 1 of the system where it arrives at grating G.sub.n-1 is I.sub.n-1,
and the reflectivity of the grating is R.sub.n-1, then the intensity of
the reflected signal is I.sub.n-1 R.sub.n-1 and the intensity of the
transmitted signal is I.sub.n-1 (1-R.sub.n-1). The transmitted signal then
arrives at grating G.sub.n (assuming negligible Rayleigh backscattering)
with the result that the signal reflected by grating G.sub.n has an
intensity I.sub.n-1 (1-R.sub.n-1)(1-R.sub.n) and the transmitted signal
has an intensity I.sub.n-1 (1-R.sub.n-1)(1-R.sub.n). The reflected signal
then arrives back at grating G.sub.n-1 whereupon the fraction that is
transmitted through the grating is (1-R.sub.n) and the remainder is
reflected back again. Thus, the signal that has initially passed through
grating G.sub.n-1, been reflected by grating G.sub.n and has passed back
through grating G.sub.n-1, has an intensity I.sub.n-1 (1-R.sub.n-1).sup.2
R.sub.n. The optimum system is obtained by setting the intensity of the
reflection from grating G.sub.n-1 to be equal to the intensity of the
reflection from grating G.sub.n as seen at point 1 of the system, i.e.
I.sub.n-1 R.sub.n-1 =I.sub.n-1 (1-R.sub.n-1).sup.2 R.sub.n
cancelling I.sub.n-1 leads to the quadratic equation:
R.sub.n R.sup.2.sub.n-1 -(1+2R.sub.n)R.sub.n-1 +R.sub.n =0 IV
which has the solution:
##EQU2##
The other solution of the quadratic equation involves the intensity of the
signal increasing upon reflection and is not considered here.
Thus, the reflectivity of the grating that is most remote from the
monitoring arrangement may be set arbitrarily and the reflectivity of the
penultimate grating is given by equation V. This operation can then be
repeated for each grating using the reflectivity of the adjacent that has
previously been calculated.
FIG. 2 shows schematically a linear optical system having ten Bragg
gratings G.sub.1 to G.sub.10 and shows the reflectivity R.sub.n for each
grating required to produce a constant amplitude reflected signal at the
monitoring arrangement, the intensity of the reflections being maximised
by setting the reflectivity of the last grating G.sub.10 to unity. FIG. 3
is a graph of the reflectivities required for constant intensity of the
reflected signal in a slightly longer linear system having 19 Bragg
gratings, the most remote 10 gratings having the same reflectivities as
those shown in FIG. 2.
It can be observed from FIGS. 2 and 3 that only the few gratings most
remote from the monitoring arrangement have significant (and significantly
different) reflectivities: for example all the gratings in the system
other than the three most remote gratings have reflectivities less than
0.2, and all but the six most remote gratings have reflectivities less
than 0.1.This is true irrespective of the length of the system, so that
additional gratings could be incorporated into the system on the near end
of the fibre without affecting the reflectivities of the more remote
gratings. Indeed, it may be possible to obtain a good approximation to the
optimum condition of equal reflected signal intensity by incorporating a
series of gratings having uniform reflectivity. For example, if an array
of the ten most remote gratings of a longer system have reflectivities as
shown in FIG. 2 in which the lowest reflectivity grating G.sub.1 has a
reflectivity of 0.056 or 5.6%, an additional array of gratings can be
incorporated at the near end of G.sub.1, each having a constant
reflectivity in the range of from 1% to 5% (depending on the length of the
array) while maintaining a generally constant signal to noise ratio over
the entire length of the combined array.
In the case of a branched network, for example a PON, there will often be a
splitter S located between adjacent Bragg gratings as shown in FIG. 1. If
the splitter has a transmission coefficient T, the intensity of the signal
will be multiplied by T upon each transit of the signal through the
splitter. Thus T will typically have a value of 0.5 for a 2:1 splitter
and, in general, n.sup.-1 for an n:1 splitter. In this case, the signal
that has passed through grating G.sub.n-1 will have an intensity of
I.sub.n-1 (1-R.sub.n-1).sup.2 T.sup.2 R.sub.n. By setting this to equal
the intensity of the signal reflected from grating G.sub.n-1 (I.sub.n-1
R.sub.n-1) the quadratic equation VI is obtained
T.sup.2 R.sub.n R.sup.2.sub.n-1 -(1+2T.sup.2 R.sub.n) R.sub.n-1+ T.sup.2
R.sub.n =0 VI
which is the same as equation IV except that R.sub.n has been replaced by
T.sup.2 R.sub.n. The relationship for the reflectivity of the (n-1)th
grating then becomes:
##EQU3##
As an example of such a system, FIG. 4 shows a network which comprises an
exchange or head end 41 from which an optical fibre 42 extends. The
optical fibre 42 branches by means of 2:1 splitters 44, 46, and 48 into a
number of branches, and the fibre 42 together with each of the branches
thereof contains a Bragg grating 50, 51, 51',52, 52'and 53, 53', the last
gratings being located at end users 54 and 55. A monitoring arrangement 56
is located in the region of the exchange and is coupled into the fibre 42
by a 3 dB coupler 58.
If gratings 53 and 53' each have reflectivities of approximately 100%,
application of equation I leads to the reflectivities of the other
gratings as given in the following table:
TABLE
______________________________________
Grating Reflectivity (Rn)/%
______________________________________
53 100
52 17.2
51 3.8
50 1.0
______________________________________
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