Detection apparatus and method

What is claimed is: 1. A pipeline apparatus comprising: a pipe body including annular innermost and outermost fluid impermeable barrier layers; first and second electrically conductive members extending at least partially along the length of the pipe body between the innermost and outermost barrier layers and electrically isolated from one another to form an electrical transmission line; an end fitting coupled to at least one end of the pipe body; and a detection apparatus coupled to the end fitting; wherein the detection apparatus comprises: a signal generator coupled to the first and second electrically conductive members, the signal generator being arranged to generate an electrical test signal and to apply the test signal between the first and second electrically conductive members, the test signal comprising a pulse code modulated electrical signal; a receiver coupled to the first and second electrically conductive members and arranged to receive an electrical return signal comprising a reflection of the test signal; a correlator arranged to correlate the test signal with the return signal and to determine a correlation signal; and a processor arranged to detect variation of the correlation signal, and to determine if a detected variation is indicative of a pipe defect; wherein at least one of the electrically conductive members comprises an electrically conductive tape element; and wherein the signal generator and the receiver are coupled to a first end of the electrically conductive members, said pipeline apparatus further comprising a second detection apparatus, the second detection apparatus comprising: an impedance monitor coupled to and arranged to measure the impedance between an electrically conductive member extending at least partially along the length of the pipe body and a seawater electrode in contact with seawater surrounding at least part of the pipe body in response to an electrical test signal applied to the electrically conductive member at first and second frequencies; and a processor arranged to detect variation of the measured impedance for an electrical test signal at a first frequency, and if a variation of the measured impedance is detected, to determine if the variation is indicative of a pipe defect, and if so to determine the distance from the seawater electrode to a pipe defect by comparison of the measured impedances at the first and second frequencies. 2. A pipeline apparatus comprising: a pipe body including: a tubular inner sheath extending along a length of the pipe body and defining a fluid impermeable barrier layer; a tubular outer sheath extending along the length of the pipe body and defining a fluid impermeable barrier layer, the tubular inner sheath and the tubular outer sheath defining therebetween a pipe body annulus extending along the length of the pipe body; and an electrically conductive member extending at least partially along the length of the pipe body within the pipe body annulus; an end fitting coupled to said tubular inner sheath and said tubular outer sheath; a seawater electrode disposed separate from and outside of the pipe body and in contact with seawater surrounding at least a part of the flexible pipe; and a detection apparatus coupled to the end fitting, wherein the detection apparatus comprises: an impedance monitor coupled to the electrically conductive member and the seawater electrode, the impedance monitor being arranged to measure an impedance between the electrically conductive member and the seawater electrode through seawater surrounding at least part of the pipe body in response to an electrical test signal applied to the electrically conductive member at a first frequency and a second frequency; and a processor arranged to detect a variation in the impedance measured in response to the electrical test signal at the first frequency, and in an event a variation in the impedance is detected, determine whether the variation is indicative of a breach of the tubular outer sheath causing seawater to enter the pipe body annulus, and if so, determine a distance from the seawater electrode to the breach by comparing the impedance measured at the first frequency with the impedance measured at the second frequency. 3. The pipeline apparatus according to claim 2 , wherein the electrically conductive member comprises a metallic structural member of the pipe body. 4. The pipeline apparatus according to claim 2 , wherein the electrically conductive member comprises an electrically conductive tape element. 5. The pipeline apparatus according to claim 2 , further comprising a second detection apparatus, the second detection apparatus comprising: a signal generator coupled to a pair of electrically conductive members extending at least partially along the length of the pipe body and electrically isolated from one another to form an electrical transmission line, the signal generator being arranged to generate an electrical test signal and to apply the test signal between the pair of electrically conductive members, the test signal comprising a pulse code modulated electrical signal; a receiver coupled to the pair of electrically conductive members and arranged to receive an electrical return signal comprising a reflection of the test signal; a correlator arranged to correlate the test signal with the return signal and to determine a correlation signal; and a processor arranged to detect a variation in the correlation signal and in an event the variation in the correlation signal is detected, determine whether the detected variation is indicative of a breach of the tubular inner sheath or the breach of the tubular outer sheath causing fluid to enter the pipe body annulus; wherein at least one of the electrically conductive members comprises an electrically conductive tape element; and wherein the signal generator and the receiver are coupled to a first end of the electrically conductive members. 6. The pipeline apparatus according to claim 5 , wherein at least one of the electrically conductive members comprise a first metallic structural member of the pipe body. 7. A method of forming a pipeline apparatus, the method comprising: providing a pipe body including: a tubular inner sheath extending along a length of the pipe body defining a fluid impermeable barrier layer; a tubular outer sheath extending along the length of the pipe body defining a fluid impermeable barrier layer, the tubular inner sheath and the tubular outer sheath defining therebetween a pipe body annulus extending along the length of the pipe body; and an electrically conductive member extending at least partially along the length of the pipe body within the pipe body annulus; providing a seawater electrode, the electrode being disposed separate from and outside of the pipe body and in contact with seawater surrounding at least part of the flexible pipe; and coupling an end fitting to said tubular inner sheath and said tubular outer sheath; coupling a detection apparatus to the end fitting, wherein the detection apparatus comprises: an impedance monitor arranged to measure an impedance between the electrically conductive member and the seawater electrode through seawater surrounding at least part of the pipe body in response to an electrical test signal applied to the electrically conductive member at a first frequency and a second frequency; and a processor arranged to detect a presence of variation in the impedance measured in response to the electrical test signal at the first frequency, and in an event the presence of variation in the impedance is detected, determine whether the variation is indicative of a breach of the tubular outer sheath causing seawater to enter the pipe body annulus, and if so determi