Improvements in Fibre Optic Distributed Sensing

1 . A method of distributed acoustic sensing comprising: repeatedly launching at least one interrogating pulse of coherent optical radiation into an optical fibre and detecting optical radiation which is Rayleigh backscattered from within said optical fibre; identifying a first stimulus acting on at least one sensing portion of the optical fibre, wherein said first stimulus results in an effective optical path length change within said sensing portion of at least the wavelength of the optical radiation; and determining the frequency of variation in backscatter intensity from said sensing portion in response to said first stimulus. 2 . A method as claimed in claim 1 comprising using said determined frequency to provide an indication of the effective rate of change induced by said first stimulus on said sensing portion. 3 . A method as claimed in claim 1 wherein said first stimulus has a strain component and the method comprises using said determined frequency to provide an indication of the effective rate of strain along the length of the optical fibre at said sensing portion. 4 . A method as claimed in claim 1 wherein said first stimulus has a temperature component and the method comprises using said determined frequency to provide an indication of the effective rate of temperature change at said sensing portion. 5 . A method as claimed in claim 1 where identifying said first stimulus acting on at least one sensing portion comprises analysing the backscatter intensity from said sensing portion to detect a signature characteristic of signal wrapping. 6 . A method as claimed in claim 5 wherein said signature characteristic of signal wrapping comprises a cyclic intensity variation and wherein said backscatter signal lacks any substantial harmonics at the frequency of said cycle variation. 7 . A method as claimed in claim 5 wherein said signature characteristic of signal wrapping comprises a cyclic intensity variation with a frequency which varies within a band. 8 . A method as claimed in claim 5 wherein said signature characteristic of signal wrapping has maximum and minimum values of backscatter intensity which correspond to determined reference maximum and minimum values of backscatter intensity. 9 . A method as claimed in claim 8 wherein said determined reference maximum and minimum values of backscatter intensity correspond to maximum and minimum values measured and/or predicted in response to a large amplitude stimulus. 10 . A method as claimed in claim 1 where identifying said first stimulus acting on at least one sensing portion comprises detecting a variation in backscatter intensity for a plurality of different sensing portions of the fibre with substantially the same frequency. 11 . A method as claimed in any preceding claim 1 where identifying said first stimulus acting on at least one sensing portion comprises interrogating the fibre with two series of pulses of different lengths and identifying a signal whose frequency is proportional to length of pulses in each series. 12 . A method as claimed in claim 1 where identifying said first stimulus comprises detecting an instance of a large amplitude strain. 13 . A method as claimed in claim 12 wherein said large amplitude strain is detected using at least one additional detector. 14 . A method as claimed in claim 1 comprising identifying a first stimulus acting on a plurality of sensing portions of the optical fibre and identifying the sensing portions which exhibit the greatest frequency of intensity variation is response to said first stimulus. 15 . A method as claimed in claim 1 comprising determining the frequency spread of the variation in backscatter intensity from said sensing portion in response to said first stimulus. 16 . A method as claimed in claim 15 comprising using said determined frequency spread to estimate the proportion of the sensing portion experiencing an optical path length change. 17 . A method as claimed in claim 1 comprising analysing the frequency of the variation in backscatter intensity from said sensing portion to detect a plurality of distinct frequency components and using detection of distinct frequency components as an indication of two discrete first stimuli acting on a sensing portion. 18 . A method as claimed in claim 1 used for seismic monitoring. 19 . A method as claimed in claim 18 used for determining quantitative strain rate information about an earthquake. 20 . A method of processing distributed acoustic sensing data comprising: identifying at least a first set of measurement data acquired from at least one sensing portion of a fibre optic distributed acoustic sensor in response to a first stimulus acting on said at least one sensing portion of the optical fibre, wherein said measurement data corresponds to the intensity of light which is Rayleigh backscattered from within said at least one sensing portion of the optical fibre when repeatedly interrogated by pulses of optical radiation; and wherein said first stimulus is a stimulus which results in an effective optical path length change within said sensing portion of at least the wavelength of the optical radiation; the method further comprising analysing said first set of measurement data to determine the frequency of variation in backscatter intensity from said sensing portion in response to said first stimulus. 21 . A method as claimed in claim 20 further comprising analysing measurement data from said at least one sensing portion to identify said first set. 22 . A distributed acoustic sensor apparatus comprising: an integrator configured to, in use, repeatedly generate at least one interrogating pulse of coherent optical radiation for launching into an optical fibre and detect optical radiation which is Rayleigh backscattered from within said optical fibre; and a processor configured to: identify a first stimulus acting on at least one sensing portion of the optical fibre, wherein said first stimulus results in an effective optical path length change within said sensing portion of at least the wavelength of the optical radiation; and determine the frequency of variation in backscatter intensity from said sensing portion in response to said first stimulus.