GB2191596A - Optical fibre cables - Google Patents

Abstract

An optical fibre cable comprises an optical fibre 1 effectively mechanically coupled in radial directions along its length to piezoelectric material 2 which makes electrical contact with axially-extending electrically- conductive material 4, 5 embodied in the outer protective sheathing of the cable for the optical fibre whereby electrical signals applied to the electrically-conductive material at points 6, 7 along the length of the optical fibre cause mechanical strain to be produced in the piezoelectric material which in turn induces phase modulation in light propagating along the mechanically coupled optical fibre. <IMAGE>

Description

SPECIFICATION Improvements relating to optical fibre cables This invention relates to optical fibre cables and relates more specifically to such cablesforuse in socalled non-invasive optical fibre communication systems in which data signals to be transmitted along an optical fibre highway of the cable may be applied non-invasivelyto the optical fibre highwayatdis- tributed points therealong.One such non-invasive communication system which forms the subject of our co-pending Patent Application No.216511 SA utilises piezoelectric transducers for imparting mechanical strains to the optical fibre highway at points therealong in response to electrical data signals applied thereto in order to produce phase modulation ofthe light propagating along the fibre which is arranged to be detected by a phase demo dulator at the far end of the fibre highway.

The present invention is directed to an optical fibre cable construction eminently suitable for use in noninvasive optical fibre communication systems.

According to the present invention an optical fibre cable comprises an optical fibre effectively mech anically coupled in radial directions along its length to piezoelectric material which is electrically in contact with axially extending electrically-conductive material embodied in the outer protective sheathing ofthecableforthe optical fibre whereby electrical signals applied to the electrically-conductive material at points along the length of the optical fibre cause mechanical strain to be produced in the piezoelectric material which in turn induces phase modulation in light propagating along the mechanically coupled optical fibre.

The optical fibre cable construction according to the invention provides for non-invasive coupling of data signals into the optical fibre highwaywhilst providing good protection for the optical fibre against mechanical damage.

In carrying outthe invention the piezoelectric material may be extruded overthe optical fibre or it may be provided in the form of a longitudinal strip orfilament of such material located in close proximity to the optical fibre so as to be closely mechanically coupled to itwherebythe expansion and contraction of the strip or filament in the radial direction ofthe optical fibre causes the latterto be mechanically strained for producing phase modulation of light propagating along the optical fibre highway.

The electrically conductive material may take the form of diametrically-opposed conductive regions (e.g. sectors or strips) embodied in the cable protective sheathing.

These opposed regions may be spaced at intervals along the length of the cable or if the electrically conductive regions are of relatively poor conductivity (e.g. electrically-conductive plastics material) they may extend over the entire length of the optical fibre cable without interruption so that the naturally lossy nature ofthe material is related upon to provide isolation between suitably spaced transmitter stations at which data is to be non-invasivelyinjected into the data highway.

The mechanical strain induced in the optical fibre highway due to the electrical excitation of the piezoelectric material by data signals injected at trans mitterstations along the cable length may be merely radially symmetrical compressions or expansions providing identical phase shifts in the different modes of any polarisation. However, the excited piezoelectric material may be arranged to apply a radially anisotropic strain to a polarisation-maintaining optical fibre so that one polarisation mode in the optical fibre is phase-modulated with respect to an orthogonal polarisation mode thereby causing in effect a modulation of the polarisationtransmitted bythe fibre which may be detected by a polarisation analyser located at the far end ofthe optical fibre highway.

Byway of example the present invention will now be described with reference to the accompanying drawing in which: Figures land 2 show radial and axial crosssectional views of an optical fibre cable constructed according to the present invention.

Referring to the drawings the optical fibre cable construction illustrated comprises an optical fibre 1 having extruded over its length a layer of piezoelectric material 2. An outer protective sheathing 3 forthe optical fibre comprises electrical insulating material which in the present embodiment has embodied therein axially spaced apart pairs ofdiametrically- opposed sectors 4 and 5 of electrically conductive material of relatively high conductivity.These pairs of opposed sectors 4 and 5 allowforthe injection into the optical fibre 1 of data signals at pre-selected points along the cable and for this purpose the data signals may be applied to a pair of conductive sectorsthrough electrodes such as the electrodes 6 and 7which may be sprung on to the cable surface as shown in the drawing so that they make good electrical contact with the respective conductive sectors.

The alternating data signals applied to the conductive sectors 4 and 5 through the electrodes 6 and 7 will produce radial straining ofthe piezoelectric layer2 which in turn will produce phase modulation ofthe light propagating along the optical fibre 1 dueto radial compression and expansion of the fibre. This phase modulation will be detected by a demodulator at the far end of the optical fibre.

The optical fibre 1 may be of the polarisationmaintaining type so that straining of the piezoelectric layer causes phase modulation of one polarisation mode of the fibre relative to another mode.

As previousiy mentioned, the piezo-electric layer may comprise a strip orfilament extending along the optical fibre in close proximity to the optical fibre so that it is closely mechanically coupled thereto and the conductive sectors may be replaced by continuous regions of electrically conductive material having poor conductivity which extend over the entire length of the optical fibre, the necessaryelectri- cal isolation being provided by the naturally lossy nature of the electrically conductive material.

1. An optical fibre cable comprising an optical

**WARNING** end of DESC field may overlap start of CLMS **.

Claims (8)

**WARNING** start of CLMS field may overlap end of DESC **. SPECIFICATION Improvements relating to optical fibre cables This invention relates to optical fibre cables and relates more specifically to such cablesforuse in socalled non-invasive optical fibre communication systems in which data signals to be transmitted along an optical fibre highway of the cable may be applied non-invasivelyto the optical fibre highwayatdis- tributed points therealong.One such non-invasive communication system which forms the subject of our co-pending Patent Application No.216511 SA utilises piezoelectric transducers for imparting mechanical strains to the optical fibre highway at points therealong in response to electrical data signals applied thereto in order to produce phase modulation ofthe light propagating along the fibre which is arranged to be detected by a phase demo dulator at the far end of the fibre highway. The present invention is directed to an optical fibre cable construction eminently suitable for use in noninvasive optical fibre communication systems. According to the present invention an optical fibre cable comprises an optical fibre effectively mech anically coupled in radial directions along its length to piezoelectric material which is electrically in contact with axially extending electrically-conductive material embodied in the outer protective sheathing ofthecableforthe optical fibre whereby electrical signals applied to the electrically-conductive material at points along the length of the optical fibre cause mechanical strain to be produced in the piezoelectric material which in turn induces phase modulation in light propagating along the mechanically coupled optical fibre. The optical fibre cable construction according to the invention provides for non-invasive coupling of data signals into the optical fibre highwaywhilst providing good protection for the optical fibre against mechanical damage. In carrying outthe invention the piezoelectric material may be extruded overthe optical fibre or it may be provided in the form of a longitudinal strip orfilament of such material located in close proximity to the optical fibre so as to be closely mechanically coupled to itwherebythe expansion and contraction of the strip or filament in the radial direction ofthe optical fibre causes the latterto be mechanically strained for producing phase modulation of light propagating along the optical fibre highway. The electrically conductive material may take the form of diametrically-opposed conductive regions (e.g. sectors or strips) embodied in the cable protective sheathing. These opposed regions may be spaced at intervals along the length of the cable or if the electrically conductive regions are of relatively poor conductivity (e.g. electrically-conductive plastics material) they may extend over the entire length of the optical fibre cable without interruption so that the naturally lossy nature ofthe material is related upon to provide isolation between suitably spaced transmitter stations at which data is to be non-invasivelyinjected into the data highway. The mechanical strain induced in the optical fibre highway due to the electrical excitation of the piezoelectric material by data signals injected at trans mitterstations along the cable length may be merely radially symmetrical compressions or expansions providing identical phase shifts in the different modes of any polarisation. However, the excited piezoelectric material may be arranged to apply a radially anisotropic strain to a polarisation-maintaining optical fibre so that one polarisation mode in the optical fibre is phase-modulated with respect to an orthogonal polarisation mode thereby causing in effect a modulation of the polarisationtransmitted bythe fibre which may be detected by a polarisation analyser located at the far end ofthe optical fibre highway. Byway of example the present invention will now be described with reference to the accompanying drawing in which: Figures land 2 show radial and axial crosssectional views of an optical fibre cable constructed according to the present invention. Referring to the drawings the optical fibre cable construction illustrated comprises an optical fibre 1 having extruded over its length a layer of piezoelectric material 2. An outer protective sheathing 3 forthe optical fibre comprises electrical insulating material which in the present embodiment has embodied therein axially spaced apart pairs ofdiametrically- opposed sectors 4 and 5 of electrically conductive material of relatively high conductivity.These pairs of opposed sectors 4 and 5 allowforthe injection into the optical fibre 1 of data signals at pre-selected points along the cable and for this purpose the data signals may be applied to a pair of conductive sectorsthrough electrodes such as the electrodes 6 and 7which may be sprung on to the cable surface as shown in the drawing so that they make good electrical contact with the respective conductive sectors. The alternating data signals applied to the conductive sectors 4 and 5 through the electrodes 6 and 7 will produce radial straining ofthe piezoelectric layer2 which in turn will produce phase modulation ofthe light propagating along the optical fibre 1 dueto radial compression and expansion of the fibre. This phase modulation will be detected by a demodulator at the far end of the optical fibre. The optical fibre 1 may be of the polarisationmaintaining type so that straining of the piezoelectric layer causes phase modulation of one polarisation mode of the fibre relative to another mode. As previousiy mentioned, the piezo-electric layer may comprise a strip orfilament extending along the optical fibre in close proximity to the optical fibre so that it is closely mechanically coupled thereto and the conductive sectors may be replaced by continuous regions of electrically conductive material having poor conductivity which extend over the entire length of the optical fibre, the necessaryelectri- cal isolation being provided by the naturally lossy nature of the electrically conductive material. CLAIMS

1. An optical fibre cable comprising an optical fibre effectively mechanically coupled in radial directions along its length to piezoelectric material which makes electrical contact with axially extending electrically-conductive material embodied in the outer protective sheathing of the cable for the optical fibre whereby electrical signals applied to the electrically-conductive material at points along the length ofthe optical fibre cause mechanical strain to be produced in the piezoelectric material which in turn induces phase modulation in light propagating along the mechanically coupled optical fibre.

2. An optical fibre cable as claimed in claim 1, in which the piezoelectric material is extruded over the optical fibre so that it is located in close proximityto the fibre.

3. An optical fibre cable as claimed in claim 1, in which the piezoelectric material is in the form of a longitudinal strip orfilament located in close proximityto the optical fibre.

4. An optical fibre cable as claimed in any preceding claim, in which the electrically conductive material defines diametrically-opposed conductive regions (e.g. sectors) embodied in the protective sheathing ofthe cable.

5. An optical fibre cable as claimed in claim 4, in which the opposed regions of conductive material are spaced at intervals along the length of the cable.

6. An optical fibre cable as claimed in any preceding claim, in which the optical fibre is a polarisation maintaining fibre and the piezoelectric material when excited provides a radially anisotropic strain to the fibre.

7. An optical fibre cable substantially as here it before described with reference to the accompany ing drawing.

8. An optical fibre communications system com prising an optical fibre cable as claimed in any preceding claim, in which electrical data signals are app lied non-invasivelytothe cable at spaced points therealong through electrodes making contact with the conductive material embodied in the cable sheathing.