40 TESTING ACOUSTICAL METHODS .. . energy available. However, since overall signal energy is very high, detection may still be feasible (Møhl, 1990). Implementation To explore this possibility we have devel- oped a tow-able acoustic sensor. The sensor - or acoustic fish - is made of a 2.5 m poly- ethylene tube, 11 cm in diameter, tapering in both ends. A shock absorber (2 m of thin- walled rubber tubing) connects the fish with the towing cable (100 m of 5 mm steel wire, 4 leads). Two hydrophones (sono- buoy surplus type), spaced 1 m apart, are suspended inside the water filled tube in rubber bands. The fish also has a pressure gauge for depth indication. 10 m in front of the fish a number of lead weights can be attacheđ to the wire in order to adjust tow- ing depth to towing speed. The fish is flooded with water at launch. This opera- tion requires the ship to be stopped. On board, the signals from the hydro- phones are fed to a two channel heterodyne converter with pass-band centre frequen- cies adjustable from 10 to 100 kHz. The bandwidth is 3 kHz, and the dynamic range is 40 dB. The Simrad SONAR r/v “Magnus Heinarsson” is equipped with a SimRad SU Survey P661E SONAR, operating at 18kHz. During the cruise we realized that this instrument could be utilised in its passive mode to listen for odontocetes when the ship was making 8 knt. Its working principle is that of a het- erodyne converter, but selectivity is intro- duced at the transducer level, as is direc- tionality. Findings Sperm whale (Physeter macrocephalus) A single specimen was spotted at an esti- mated distance of 5 NM. The ship proceed- ed at 2 knt towards the point of diving. The acoustic fish was deployed and signals recorded with the heterodyne converter set at 10 kHz. Repetition rate was steady at about 1 pulse every two seconds. A time series of a single pulse is given in Fig. Al, showing double path transmission (proba- bly due to reflection at the surface). The time difference between the two sets can be used to estimate the depth of the source, provided a range estimate is available. The somewhat higher signal amplitude in the delayed path can be interpreted as an indi- cation of the animal’s acoustical axis being more aligned with the reflecting point than with the acoustic fish. Also, the multi-pulsed structure so char- acteristic of this species is shown. From the interpulse interval of 4 ms, an estimate of 15 m for total body length of the specimen can be made (Adler-Fenchel, 1980). This information reveals the sex, since only males grow to this length. Although this information is no big surprise (only males are observed at these latitudes), it serves to show the kind of information obtainable with the acoustic fish. In Fig. A2 is shown the simultaneous output from the two transducers in the fish for the first pulse of a click. The time dif-

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