Distributed fibre optic sensing

The invention claimed is: 1. A method of distributed fibre optic sensing, comprising; performing distributed fibre optic sensing so as to generate at least one set of measurement signals over a period of time from each of a plurality of sensing channels of an optical fibre in response to at least one event of interest of a known type, wherein the optical fibre is deployed to run along a path of at least part of at least one rail track; for the or each set of measurement signals, determining a first parameter of each of the measurement signals, comparing the determined first parameters for different sensing channels with one another, identifying sensing channels where the determined first parameters differ by less than a defined amount as being associated with one another and forming at least one association matrix indicative of the sensing channels that are determined to be associated with one another; performing distributed fibre optic sensing to acquire a further set of measurement signals over a period of time from said sensing channels in response to a further unknown event of interest; and processing said further set of measurement signals based on said at least one association matrix to determine whether the same sensing channels are associated with one another to determine whether said further event of interest is of the known type, wherein the at least one association matrix comprises a set of measurement signals indicative of known events of interest, wherein the known events of interest comprise at least one of: a train on a first track, a train on a second track, a train passing event, a fault in a track, a break in the track, or a flooded track. 2. The method according to claim 1 further comprising determining a likelihood of association for at least one pair of sensing channels. 3. The method according to claim 2 wherein the association matrix stores, for each pair of sensing channels, the determined likelihood of association. 4. The method according to claim 1 wherein at least a first set of measurement signals comprises measurement signals from the sensing channels in response to each of a plurality of events of interest of a first type. 5. The method according to claim 4 wherein processing said measurement signals of the first set comprises taking a plurality of subsets of the measurement signals, where each subset corresponds to the measurement signals from one event of interest, processing the measurement signals of each subset to determine which sensing channels are associated with one another for that subset; and forming the association matrix by combining results for the plurality of subsets. 6. The method according to claim 5 , wherein processing said measurement signals to determine which sensing channels are associated with one another comprises determining a likelihood of association for at least one pair of sensing channels and wherein the likelihood of association for a pair of sensing channels is determined by determining the proportion of subsets in which that pair of channels are determined to be associated with one another. 7. The method according to claim 1 wherein the method comprises generating a plurality of sets of measurement signals and a corresponding association matrix for each set of measurement signals, wherein each set of measurement signals corresponds to measurement signals acquired in response to respective events of interest identified as being of a different type to one another. 8. The method according to claim 7 wherein characterising said further event of interest comprises determining whether the further event of interest matches one of the types of event of interest. 9. The method according to claim 7 wherein characterising said further event of interest comprises determining whether the further set of measurement signals exhibits channel associations that corresponds to one of the determined association matrices. 10. The method according to claim 1 wherein determining whether the further event of interest matches one of the identified types of event of interest comprises, as the further set of measurement signals are acquired: determining a channel association for the further event of interest; and determining the probability that the further event of interest is of a first type based on a probability, determined from the association matrix for events of the first type, that the channel association would be experienced if the event were of the first type. 11. The method according to claim 1 wherein the first metric is a measure of acoustic intensity of the measurement signal of a sensing channel. 12. The method according to claim 11 wherein a pair of sensing channels are identified as being associated with one another if the measure of acoustic intensity for each sensing channel is within 1 dB. 13. The method according to claim 1 wherein characterising the further event of interest comprises identifying any significant change in channel association for the further event of interest compared to a previously determined association matrix. 14. The method according to claim 1 , wherein the method comprises generating a plurality of sets of measurement signals and a corresponding association matrix for each set of measurement signals, wherein each set of measurement signals correspond to measurement signals acquired in response to respective events of interest identified as being of a different type to one another and wherein at least part of the optical fibre is deployed to run alongside a plurality of rail tracks and a train travelling on one rail track is identified as an event of interest of one type and a train travelling on another rail track is identified as an event of interest of a different type. 15. The method according to claim 14 , wherein the method determines which rail track the train is travelling on. 16. A method of distributed fibre optic sensing, comprising; performing distributed fibre optic sensing on an optical fibre deployed at least partly along the path of a rail track so as to generate a set of measurement signals over a period of time from each of a plurality of sensing channels of said optical fibre for each of one or more train passing events of a known type; determining a first parameter of each of the measurement signals, comparing the determined first parameters for different sensing channels with one another, identifying sensing channels where the determined first parameters differ by less than a defined amount as being associated with one another and forming an association matrix indicative of the sensing channels that are determined to be associated with one another; acquiring a further set of measurement signals from each of a plurality of sensing channels over a period of time in response to a further train passing event of an unknown type; and determining whether the further set of measurement signals exhibits a difference in channel association from the association matrix. 17. The method as claimed in claim 16 comprising forming a normalised set of measurement signals which is normalised based on the association matrix. 18. The method according to claim 16 comprising identifying a possible fault with the track based on an identified difference in channel association from the association matrix. 19. An apparatus, comprising; a distributed fibre optic sensor configured to interrogate an optical fibre deployed in an area of interest to detect measurement signals at each of a plurality of sensing channels of said optical fibre, wherein the optical